casting technologies
Transcription
casting technologies
knowledge can unlock the full potential of your foundry operations. As a reliable and trusted supplier, Foseco can help you to improve mechanical properties, increase casting integrity, lower fume emissions, reduce waste or perhaps improve process control. Whatever your foundry requirements are, talk to us. A s i a Pa c i f i c Vol 58, No 3 September 2012 Your foundry and Foseco. The power of two. China • india • taiwan • Singapore Indonesia • THAILAND • Philippines Malaysia • Hong Kong • Japan • Europe USA • Australia • Korea • New Zealand l Treatment_NF_au_September_2012.indd 1 CASTING TECHNOLOGIES COMMITTED TO FOUNDRIES Phone: + (61) 2 9914 5500 Fax: + (61) 2 9914 5547 www.foseco.com.au * COVERAL and ALSPEK are trade marks of the Vesuvius Group, registered in certain countries, used under licence. 9/13/2012 9:15:58 AM CM SERIES MIXERS Sand Reclamation l Low Level System l Moulds can be fed directly from casting line l Mould Sizes up to 3Mtr x 2.5Mtr l Mould Weight up to 5 Tonnes l Capacities to 15TPH l l l l l l l FINE MESH SCREEN CASTING Gammavator l Idea for small foundries l Combined shakeout & sand elevation l Mould Sizes up to 1Mtr x 1Mtr l Mould Weight up to 500kg KNOCK OUT DECK SAND DISCHARGE VIBRATORY MOTORS PERFORATED PLATE DECK l OVERSIZE DISCHARGE WEDGEWIRE SCREEN l l l l CLEAN OUT DOOR l Single Heavy Duty Horizontal Barrel design has been proven to provide consistently coated sand grains with both resin and catalyst for complete chemical reaction. On demand mixing with no wasted first and last sand Standard sizes from 1TPH to 100TPH. Dual start spiral mixing blade arrangement with over-lapping blades to minimise internal buildup. Individually replaceable tungsten carbide tipped blades held captive in slotted shaft to prevent rotation. Both sides of mixing chamber swing away to provide easy access to the blades and shaft for periodic cleaning and maintenance procedures. Safety interlock on both access doors. Low sand level proving probes in inlet hoppers to prevent chemical injection when no sand is present. Pneumatically controlled adjustable sand rating and isolation gates. 320° rotation available on standard type mixers. Slewing Ring on Multiple Hopper Inlets. Multiple Pump Programs. Fault diagnostic and indication facility. System Status Display. High Intensity continuous sand mixers Standard type mixer with double door opening, displaying full accessibility to mixing shaft and blades for periodic cleaning and maintenance procedures. A new Joint Venture to Benefit the Foundry Industry Warill Engineering Sales (Aust) Pty Ltd, (WES) as of August 1st, 2012 has formed a joint venture company with Omega Foundry Machinery Ltd based in the UK. The new company will be known as WES Omega Foundry Machinery Pty Ltd, which will be based at the existing WES premises located in Dandenong. The company will be headed by Les Craig (Managing Director) and Peter Dimopoulos (Technical Director). WES Omega will be in a position to manufacture the Omega product range along with the continuation of the existing WES equipment. WES Omega will seek to see the improvement and extension of the pre-existing equipment range servicing the foundry industry in Australia, New Zealand and parts of South-East Asia. Tungsten carbide tip mixing blades held captive in slotted shaft to prevent rotation and provide efficient mixing action and lowest possible resin addition rates. Compliant Safety Interlock on barrel doors interlocked with Mixer Isolating Switch to provide safety for cleaning and maintenance. Sand inlet hoppers showing low level proving probes and sand rating and isolation gates. WES OMEGA FOUNDRY MACHINERY PTY LTD WES OMEGA FOUNDRY MACHINERY PTY LTD PH: +613 9794 8400 Fax: +613 9794 7232 Email: [email protected] Address: 16 Lanyon St, Dandenong Vic 3175, Australia PH: +613 9794 8400 Fax: +613 9794 7232 Email: [email protected] Address: 16 Lanyon St, Dandenong Vic 3175, Australia The technology of batch degassing for hydrogen removal from aluminium melts utilising different rotor designs Background Rotary degassing of liquid aluminium alloys is a widely used commercial process to control levels of hydrogen, alkali metals and inclusions in the melt prior to casting. However the time taken to reach the required quality standard can vary considerable depending on rotor design. A selection of different Foseco degassing rotors has been characterised in a comprehensive experimental program. The study has resulted in an Internet based simulation software for the degassing process in foundries with significantly improved degassing efficiency. A comprehensive theoretical understanding of the kinetics of aluminium degassing has been established in the past twenty years. Whilst there have been some published experimental tests of degassing theory in molten aluminium, in many cases key pieces of information are not reported or determined, such that a critical assessment of the underlying theory is compromised. Similarly, practical implementation of such understanding in usable shopfloor process models has met with difficulties owing to lack of knowledge concerning some key parameters. These include the stirring intensity dissipated in the melt, and its relationship to the average gas bubble size, and the mass transfer coefficient at the free surface of the melt. Gas porosity and inclusions In foundries today we recognise two major issues of molten metal quality; gas content and inclusions. The presence of porosity became even more problematic when age hardening alloys were developed, because near surface porosity invariably blistered on the surface. Additionally, a significant loss of mechanical properties, such as tensile strength was found with increasing porosity levels. to the lance outlet or to the bottom of the furnace, create typically finer bubbles of 10 to 20 mm in diameter; but even with them, the homogenising and bubble distribution is not optimal. Initially, the development of spinning injection systems with rotors attached solved the problem of insufficient gas distribution and delivered bubble sizes in the range of 3 to 10 mm in diameter. Hydrogen solubility Hydrogen comes from the water vapour in the atmosphere, which readily reacts with liquid aluminium to produce two problematic reaction products, i.e. alumina (inclusions) and hydrogen (gas). 2 Al (l) + 3 H2O (gas) = Al2O3 (s) + 3 H2 (gas). Aluminium has problems with hydrogen, not because it is particularly soluble in liquid aluminium, but because it is particularly insoluble in solid aluminium and so it comes out of solution during solidification. Solubility mainly depends on the temperature of the aluminium. Alloying elements such as magnesium also affect the hydrogen solubility. Theory and principals of hydrogen removal Hydrogen needs to be removed from the melt prior to casting with inert gases, such as argon or nitrogen being used to purge the melt. A given inert gas flow rate will have a greater interface area for smaller bubbles. Additionally, each bubble stays longer in the melt as the bubble gets smaller, since the terminal velocity is reduced and allows longer time for hydrogen transport. A deeper reaction zone in a ladle or crucible allows more time for equilibrium because the bubble stays in the melt longer before reaching the surface. Therefore, the design for a practical degasser needs to create the smallest bubbles low down in the treatment vessel, at a high velocity; mixing the melt at the same time to get a homogenous hydrogen distribution. Lance treatment was the beginning of industrial degassing, but lances tend to produce rather coarse bubbles between 10 and 50 mm in diameter without a wide bubble size distribution and offered limited melt homogenising. Porous blocks, either attached Figure 7. Comparison of inert gas bubble size generated by different systems [2] Power analysis of degasser rotors Figure 8. XSR Rotor The recently developed FDR and XSR rotors generate higher power than the traditional rotors. Therefore, these rotors create finer bubbles. The GBF XHT, predominantly used in the Asian foundry market, performs similarly to the best-in-class European designs. Mixing capabilities of degasser rotors A well designed degassing system will have two key attributes. Firstly, the melt will be rapidly mixed to achieve and maintain chemical and thermal homogeneity throughout the process. It is important that the time required to achieve good mixing is substantially less than the metal treatment time. Secondly, the turbulence generated by the rotor will result in small average size of inert gas bubbles, which the well mixed flow patterns will ensure are well distributed throughout the melt. At lower speeds of around 200 rpm, the FDR rotor needs about 40 seconds for effective mixing whilst other types need up to 3 times more. With increasing speed the differences between the rotor types becomes smaller. These observations are almost inline with experiences from foundry trials; FDR rotors start at a lower speed and have a good degassing performance. The FDR rotor is seen to perform well across the board at all diameters. It generally had a significantly shorter mixing time than the XSR rotor of equivalent diameter, primarily because the FDR rotor delivers more power into the liquid at a given speed. Batch degassing software Figure 1. Surface porosity visible on a casting Figure 2. Internal porosity visible on a machined face Figure 3. Tensile strength vs. porosity level [1] 2 www.metals.rala.com.au Figure 4. Hydrogen solubility in aluminium Figure 5. Effect of increased water vapour pressure on hydrogen solubility [2] Foseco’s non-ferrous Marketing and Technology team have worked with Technology Strategy Consultants to develop a web-based batchdegassing model. It has been designed as a tool to quickly analyse Figure 10. Mixing time comparison for 190 mm rotors foundries’ operations, and make suggestions for their improvement. The mathematical model behind this software is based on the best available published information, concerning the kinetics of hydrogen degassing (e.g. hydrogen solubility, diffusivity, mass transfer rates and stable bubble sizes). An extensive program was undertaken to provide specific information about individual rotors. The starting screen provides sub-menus for input of • alloy composition • ambient conditions • operating parameters • geometry of the treatment vessels • hydrogen initial level The operator can choose alloy compositions and crucible resp. ladle geometries from a list or input own values. Ambient conditions and operating parameters are foundry specific values, which are known or needed to optimise the degassing process. The initial hydrogen level is often unknown, but 0,3ml/100gAl is a common value and changes in this influence the curves insignificantly. The rotor menu includes different types of rotors at various diameters. By clicking one or more rotors the degassing curves are drawn in a diagram showing hydrogen level vs. time. The model calculates the degassing performance for each chosen rotor in percentage of hydrogen removed and the average treatment gas consumption. The input screen offers the option to use a The world is full of great treatment gas containing hydrogen. So there is a instance, to make premiu way to simulate upgassing of engineers who Figure 11. Screenshothands of batch processes as well. degassing software Our locally based teams A plotting menu enables the user to put in hydrogen levels measured with ALSPEK* developHinnovative soluti electrochemical hydrogen sensor; this data can then be plotted Our with products, in the diagram to compare predicted degassing curves real services an knowledge can unlock th foundry trial results. THE POWE As a reliable and trusted mechanical properties, in The research work undertaken is proving to be an important reduce waste or perhaps contributor to the understanding of hydrogen control in aluminium Conclusions melts and this will improve the ability to optimise this important Whatever your foundry re part of metal treatment practice. Foseco is finding the predictions of the degassing model to reflect the reality in production foundries. The degassing model is proving to be an effective tool for analysing and optimisingYour the degassing foundry and Foseco process. Each particular metal treatment station requires a particular set of parameters – rotor design, diameter and rotor speed. The model enables foundries to better understand the degassing process. They can easily compare different strategies: • shortest degassing time • increase consumables life COM • avoidance of overgassing By developing the scientific tests described earlier, Foseco has developed more efficient rotor designs which will achieve improved performance for the FDU and MTS degassing machines. * COVER METAL Casting Technologies September 2012 3 Metal Treatment_NF_au_September_2012.indd 1 Ajax Tocco Magnethermic ......................................................BG66 Huettenes-Albertus Australia . ............................................. BG73 Arun Technology ..................................................................... BG67 IMF ................................................................................................. 35 Beckwith Macbro Sands . .............................................. 60 / BG67 Inductotherm . ................................................................................ 5 Bruker Quantron GmbH.......................................................... BG67 Linn High Therm ............................................................. 60 / BG79 CAST CRC ......................................................................................... 57 Metal Casting Technologies Magazine ................ BG69 / BG79 Cast Metal Services ................................................... 14-15 / BG68 Magma Engineering Asia Pacific....................... 16-17 / 25 / BG74 Casting Solutions .................................................................... 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IFC-1 / BG80 G&C instrument Services ..................................................... 41 / 43 World Equipment Machine Sales ........................................ BG80 Hayes Metals ........................................................................... BG73 AUSTRALIA AUSTRALIA Electric Induction is the Fastest, most Precise Electric Induction is the Fastest, most Precise Talk to the Inductotherm’s Heating and Melting Systems Specialists for all your Forging, Heat Treatment, Brazing, Melting and Automatic Pouring (in Specialists Air, Vacuumfor orall Inert Atmospheres). Talk to the Inductotherm’s Heating and Melting Systems your Forging, Heat Treatment, Brazing, Melting Automatic Pouring (in Air, Vacuum or Inert Atmospheres). Retain your and competitive edge. Call Inductotherm now … Retain your competitive edge. Call Inductotherm now … INDUCTOTHERM GROUP AUSTRALIA PTY. LTD. Seaford, Victoria, AUSTRALIA 3198 THE MASTERS OF HIGH QUALITY INDUCTOTHERM GROUP AUSTRALIA PTY. LTD. Tel: 61 3Victoria, 9786 6000 Seaford, AUSTRALIA 3198 Fax: 61 3 9785 6000 3043 Tel: 61 3 9786 E-mail: Fax: 61 [email protected] 3 9785 3043 Internet: www.inductotherm.com.au E-mail: [email protected] Internet: www.inductotherm.com.au 4 www.metals.rala.com.au THE MASTERS HIGH QUALITY HEATINGOF & MELTING HEATING & MELTING SERVICE 24 HOURS/DAY - 7 DAYS/WEEK Tel: 61 3 9786 7000 SERVICE 24 HOURS/DAY - 7 DAYS/WEEK Tel: 61 3 9786 7000 Jimmy Loke Yoon Chee Director, Yoonsteel Foundry Malaysia Representative of FOMFEIA Mr Gopal Ramaswami National Secretary of the Institute of Indian Foundrymen, India Email: [email protected] Publisher & Managing Editor Barbara Cail Email: [email protected] Research and Technical Contributor Adjunct Professor Ralph Tobias Email: [email protected] Advertising & Production – Global Adam Cail Email: [email protected] Industry Associations Philippine Iron & Steel Institute (PISI), Room 518, 5th Floor, Ortigas Building, Ortigas Avenue, Pasig, Metro Manila Tel: +632 631 3065, Fax: +632 631 5781 New South Wales: The Secretary, Locked Bag 30, Bankstown NSW 2200, [email protected] Accounts Payable Cheryl Welsh Email: [email protected] Queensland: C/- PO Box 89, Acacia Ridge QLD 4110 Victoria: PO Box 4284, Dandenong South VIC 3164 Production Craig O’Neill Email: [email protected] Casting Technology New Zealand Inc. PO Box 1925, Wellington, New Zealand Tel: +64 4 496 6555, Fax: +64 4 496 6550 China Foundry Association 3rd Floor, A-32 Zizhuyuan Rd Haidian District, Beijing 100048, CHINA Tel: +86 10 6841 8899 Fax: +86 10 6845 8356 Web: www.foundry-china.com Subscription Rates Australia $AUD 99.65 (Includes GST) Overseas $AUD 125.40 (Includes Mailing) Federation of Malaysia Foundry & Engineering Industries Association (FOMFEIA), 8 Jalan 1/77B, Off Jalan Changi at Thambi Dollah 55100, Kuala Lumpur, Malaysia Tel: +603 241 8843, Fax: +603 242 1384 Published by RALA Information Services Postal: PO Box 134, Balmain NSW 2041, Australia Street: 1A/551 Mowbray Road, Lane Cove NSW 2066, Australia Phone: +61 2 9420 2080 Fax: +61 2 9420 5152 Web: www.metals.rala.com.au Mr Seksan Tangkoblab President Thai Foundrymen’s Society Dr John Pearce Metals Specialist MTEC National Metals and Materials Technology Centre, Thailand Western Australia: The Secretary, [email protected] Editorial and Subscriptions Melinda Cail Email: [email protected] CONTENTS Jack Frost World Consulting Specialist Foundry Process Engineer [email protected] Australian Foundry Institute South Australia: The Secretary, PO Box 288, North Adelaide SA 5006 Advertising & Production – China Ms. Angela Jiang Tel: +86 15 801 748 090 Email: [email protected] Mr Zhang Libo Executive Vice President China Foundry Association [email protected] Thai Foundry Association Khun Wiboolyos Amatyakul President Thai Foundry Association 86/6 1st Floor BSID Building Bureau of Supporting Industries Development Soi Trimitr, Rama IV Road Klongtoey Bangkok 10110 Thailand www.thaifoundry.com The Materials Process Technology Center Japan. Kikai Shinko Bldg, 3-5-8 Shiba-Koen, Minato-ku, Tokyo, 105 Japan Tel: +81 3 3434 3907, Fax: +81 3 3434 3698 31 04 ADVERTISER’S INDEX 12 EDITORIAL 18 ASIAN FOUNDRY OVERVIEW 18China By Daniel Allen 21 Australia By Nev Murray 26India By Dr. P. C. Maity Metalworking Industries Association of the Philippines Inc. Pacificador Directo, National President, MIAP, No. 55 Kanlaon St, Mandaluyong, 1501 Metro Manila, Philippines Tel: +632 775 391, Fax: +632 700 413 Pakistan Foundry Association 93-B, Hali Road, Gulberg-II Lahore, Pakistan Tel: + 92 (0) 42 3575 3619, (0) 42 3502 3525 Email. pakistanfoundryassociation@gmail. com/[email protected] Web. www.pfa.org.pk Copyright – No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form or by any means, electronic, mechanical, photocopying, recording or otherwise without permission of the publisher. 65 Buyer’s Guide South East Asian Iron & Steel Institute 2E 5th Floor Block 2, Worldwide Business Park Jalan Tinju 13/50, 40675 Shah Alam, Selangor Malaysia Tel: +603 5519 1102, Fax: +603 5519 1159, Email: [email protected] Japanese Association of Casting Technology Noboru Hatano, Technical Director, JACT, Nakamura Bldg, 9-13, 5-chome, Ginza,Chuo-ku, Tokyo, 104 Japan Tel: +81 3 3572 6824, Fax: +81 3 3575 4818 The Publisher reserves the right to alter or omit any article or advertisement submitted and requires indemnity from the advertisers and contributors against damages or liabilities that may arise from material published. Vol 58 No 3 September 2012 Philippine Metalcasting Association Inc. (PMAI), 1135 EDSA, Balintawak, Quezon City Metro Manila, Philippines Tel: +632 352 287, Fax: +632 351 7590 Institute of Indian Foundrymen IIF Center, 335 Rajdanga Main Road, East Kolkata Township P.O. Kolkata - 700107 India Tel: +91 33 2442 4489, +91 33 2442 6825 Fax: +91 33 2442 4491 Metal Casting Technologies is a technically based publication specifically for the Asia Pacific Region. The circulation reaches: • Foundries • Diecasters • Iron and steel mills • Testing labs • Planners & Designers – CIM-CAD-CAM Contents 30 New Zealand By Gordon Muldrew 31 Front Cover - Foseco MTS1500 Automated Metal Treatment Station. Also see pages 2-3, BG72, OBC. Pakistan By Abdul Rashid 32 Philippines By Prof John HD Bautista 34 Thailand By John Pearce 40 45CASTvacTM – an efficient vacuum technology for HPDC with low maintenance cost By Laihua Wang & Gary Savage 49 China Foundry Association 6 www.metals.rala.com.au Thai Foundry Association The Institute of Indian Foundrymen The Korean Foundrymen's Society Metal working Industry Association of the Philippines Federation of Malaysian Foundry & Engineering Industries Association South East Asian Iron & Steel Institute Use of PoDFA technique for rapid melt cleanliness assessment: a practical shop-floor tool for production of aluminum casting By Thawatchai Kantisitthiporn and Julathep Kajornchaiyakul 53 BACK TO BASICS 56 EVENTS 58 BACK TO THE FLOOR 61 WEBSITE SHOWCASE 65 BUYER’S GUIDE Australian Foundry Association TECHNICAL FEATURES 40Ferritic ductile irons: a revisit By John Pearce Balancing flow in vertically parted moulds By J. F. Meredith Melting metal for the virtual bronze foundry By Prof John HD Bautista Website showcase directory Company showcase directory METAL Casting Technologies September 2012 7 AUSTIN FOUNDRY RECLAIMS BURIED TREASURE ADVANTAGES AND FEATURES 4 Patented multi-chamber design combines lump crushing, sand scrubbing, sand conditioning, dual sand screening, and metal separation for the fastest payback. 4 The time-tested design has the best performance/highest yield (up to 97%) in the industry. Intake end 4 Significant savings from reduced binder consumption, lower new sand purchases, and minimal disposal costs. 4 Additional savings from conditioned and higher quality reclaimed sand (which is more uniform/consistent) lowers finishing costs and reduces casting scrap. High quality reclaimed sand 4 The patented design has the lowest operating cost per ton in the industry worldwide, with system sizes from 1-100 TPH 4 Highly efficient air-wash separation removes binder, dust, debris, and excess fines. 4 Continuous improvement and development have made us the world leader in sand reclamation. Sean GirdaukaS, V. P., auSTin FOundrY COrP. AUSTIN FOUNDRY CORP., of Sheboygan WI, is a gray and ductile iron jobbing shop that has been producing quality castings ranging in size from one pound to 5,000 pounds for a wide variety of industries since 1946. Their molds are chemically bonded with Furan and some Pepset binders. “We first considered a sand reclamation system a few years back, but with the recent downturn in the economy and our ever-increasing costs, becoming even more cost efficient became a priority. The cost savings potential of a DIDION® Sand Reclamation System became obvious”, says Sean Girdaukas, Vice President of AUSTIN FOUNDRY CORP. “We sent sand samples to DIDION for testing, using their Rotary Lump Crusher/Sand Reclaimer System. DIDION’S patented design crushed the hard lumps, scrubbed the binder off the sand grains, screened the sand twice, recirculated the screen overs, and separated tramp metal. After evaluating the test results and their proposal, we purchased and installed a DIDION® Sand Reclamation System. Installation was fast and easy. We are very pleased with the quality of the reclaimed sand and the system is extremely reliable.” “In the first eight months of use, we reclaimed over four million pounds of spent sand which would previously have been sent to a landfill. We were able to dramatically reduce our new sand purchases and disposal costs. In addition, we have been able to cut back on binder and catalyst usage with no ill effect. We anticipate saving a quarter million dollars annually. Helping the environment is saving us money”, concludes Girdaukas. Sean GirdaukaS, V. P., auSTin FOundrY COrP. Reclaimed clean tramp metal The team at Austin Foundry was excited to reclaim a buried treasure. Turn a waste stream into a revenue stream and keep the EPA and DNR inspectors happy. Contact DIDION to help you become more efficient and more profitable. DIDION INTERNATIONAL INC. Riverside lndustrial Centre 7000 West Geneva Drive St. Peters, MO 63376 phone, 636.278.8700 fax, 636.278.3155 email, info@ didion.com web, www.didion.com Reclaim your burie treasure d – contact DIDION. Concise clean system DIDION INTERNATIONAL INC. Riverside lndustrial Centre 7000 West Geneva Drive St. Peters, MO 63376 phone, 636.278.8700 fax, 636.278.3155 email, info@ didion.com web, www.didion.com COMPANY PROFILE COMPANY PROFILE The world’s most popular PCbased casting simulation system Why do over 630 companies and schools worldwide use SOLIDCast™? BECAUSE IT WORKS!! No other casting simulation program offers POWER, EASE OF USE and ACCURACY like SOLIDCast. S OLIDCast simulates castings poured in cast iron, steel, aluminum, copper-base, magnesium, nickelbased and almost any other alloy. A database of several hundred alloys, with all pertinent properties, is included. SOLIDCast can simulate molding processes such as sand, investment and permanent mold. You can use sleeves (insulating or exothermic), chills, hot topping, cooling channels, and just about anything else that is used in the metal casting process. SOLIDCast contains both Gating and Riser Design Wizards™, tools that allow you to rig new castings in just a few minutes, using actual simulation results, not guesses based on simple geometry. Since casting alloy, mold material and mold inserts are all considered, there is no more accurate way to rig a casting than with the Gating and Riser Design Wizards! Largest User Base in the World What does OPTICast do? Flow Path Tracing in an Aluminum Sand Casting Optimization of casting process design using SOLIDcast™ and HyperOpt® OPTICast™ is an amazing software tool that works in conjunction with the SOLIDCast™ solidification modeling system. OPTICast uses the HyperOpt® system from Altair Engineering, Inc., the leader in the field of optimization software. Dual Sprue Rigging System Designed by the SOLIDCast Gating and Riser Design Wizards Graphics are the most sophisticated available, with fully movable 3D models, X-ray images, high-resolution color plots and Windows video files. Send movies to anyone with a Windows PC! SOLIDCast lets you see how your casting will solidify before you make patterns, dies and costly mistakes. Pour test castings on the computer, not the foundry floor! Design gating systems and test them out before making your first casting. Casting simulation helps you to shorten lead times, produce higher quality and improve yield. All of this means lower costs, higher profits and improved marketability for your foundry. Why Use Casting Simulation From FSI? Original Riser Design Optmized Riser Design. 12% Yield Improvement. OPTICast actually automates the simulation process! Start with an initial design for a casting, with gating and risering, typically created in the SOLIDCast modeling system, using the Gating and Riser Design Wizards™. Then select the following elements: Design Variables: Design elements that are allowed to vary. For example, the height and diameter of a riser. It could also be the metal pouring temperature, or the preheat temperature of an investment shell. Constraints: Used to determine whether a particular design is acceptable. For example, the foundry engineer might specify a minimum acceptable yield percentage, or a maximum acceptable level of macroporosity. The Objective Function: States what the foundry engineer is trying to achieve. Examples might be to maximize the yield, minimize shrinkage or minimize solidification time. Once these elements are identified, the user then launches an Optimization Run. This consists of a series of simulations in which the design conditions are varied under the control of HyperOpt, model changes are made and simulation results are evaluated, all completely automatically, until the desired result is achieved. Using OPTICast, the foundry engineer can start with an initial design and allow the computer to do the work of modifying the design and running simulations to achieve an optimum result. Now the technology of automated design is brought to the foundry in the form of a practical and easy-to-use design tool. OPTICast can help you to improve your yield and your quality to an optimum point, while freeing design engineers from the repetitive task of trial-and-error design. Easiest to Use Fastest Results Solidification Analysis Lowest Cost to Buy and Use Flexible Payment Plans Available Multiple Language Versions Mold Filling Authorized agents: Casting Solutions Pty Ltd – Australia [email protected] TEMC Metal and Chemical Co Ltd – Taiwan [email protected] EDS Technologies Pvt Ltd – India [email protected] Hysim – Fdy China Hodgen Tech Co Lt [email protected] de.com.cn World Wide Support Visit us at Stand 14 AFI Conference www.finitesolutions.com Feeding Zone Analysis for Riser Design 10 www.metals.rala.com.au Integrated Gating and Riser Design Casting simulation for the working foundry METAL Casting Technologies September 2012 11 contributors EDITORIAL DANIEL ALLEN Based in London and Beijing, awardwinning writer and photographer Daniel Allen has journeyed widely across Europe, Asia, Africa and the Americas. His work has featured in numerous publications, including the Guardian, National Geographic, Discovery Channel magazine, Geographical, Esquire and CNN Traveller. Wiboolyos Amatyakul President, Thai Foundry Association commenced production of its first ever Chinese-designed car for by inadequate infrastructure, skilled workers, scale, and domestic the Indian market. This is a major step for the US automaker as supply networks, as well as by political and intellectual-property it tries to scale up in a market where foreign companies have risks. Low worker productivity, corruption, and the risk to personal struggled. India’s love for the small car and its highly competitive safety are added concerns in some countries. and price-sensitive market have confounded many of the world’s john hermes d. bautista PMAI Technical Consultant phases. It will vary dramatically depending on labor content, India-specific cars. transportation costs, China’s competitive strengths, and the The world economic infrastructure is very uncertain and Barbara Cail Dr. P. C. Maity Metal Casting and Materials Engineer jeff f. meredith Casting Solutions Pty Ltd Gordon Muldrew Gordon holds an Advanced Trade Certificate in Moulding and a Certificate from the AFS in Gating & Riser Design. He has been involved in the metal casting industry for over 25 years specialising in methoding and computer simulation. Gordon is Sales Manager for MetCast Services Ltd and is currently the Chairman of Casting Technology New Zealand Inc. Neville A Murray Has given numerous technical papers at local and international foundry conferences. Previously Meehanite metallurgist. Past secretary of the Australian Ductile Iron Producers Association. Currently President of the Australian Master Patternmakers Association. john pearce Metals Specialist, MTEC National Metals and Materials Technology Centre, Thailand Manufacturing renaissance is inevitable O nce again we have great pleasure in bringing you the Asian Foundry Overview for the metal casting industry in the Asian market. In the year which has passed, the strength and weaknesses in the global economy have caused enormous change, particularly in Europe and this change will continue. The world of certainty is no more. Metals magazine, as you all know is distributed throughout Asia Pacific, specifically through the membership of the China Foundry Association, Thai Foundry Association, Pakistan Foundry Association and the Institute of Indian Foundrymen. We also have subscribers in Malaysia, Japan, South Korea, Italy, Spain and the US. So in this Annual edition we try to filter what are the trends and expected impacts for global manufacturing which has a flow-on affect for metal castings - the enabling industry. Since last year’s Metals Annual, when we reported that China was then the biggest global manufacturer of automobiles – requiring metal castings components, it still retains this position. However, signals are now loud and clear that there is a downward sales trend for autos in China as a result of its, and the world’s economic slowdown. In China, as well as their global clients, this has been caused by reduced demand brought about by Abdul Rashid Secretary, Pakistan Foundry Association high savings rates and fluctuations and uncertainty with unemployment. However, there is a strong prediction that Chinese consumers are expected to buy 25.5 million vehicles in 2015. And while the world’s auto economy is in a painful state it’s interesting to note that in China, General Motors have 12 www.metals.rala.com.au This reallocation of global manufacturing is in its very early major automakers who try to compete with brands selling small, strategic needs of individual companies. However, over the recent there is no doubt that by the time I write next year’s editorial past the shift of manufacturing to China was due largely to lack column it will be profoundly different. The difference, amongst of sufficient progress in automation of manufacturing processes. other economic elements, will be revealed through a probable Until automation is optimised, labor costs will remain the great manufacturing renaissance. This will be brought about by the dictator. forced changes in manufacturing costs, environmental issues and the deep deficits in skilled labor for the foundries. For more than a decade now, deciding where to build a While we normally focus heavily on car auto components when we publish our Metals Annual Asian Foundry Overview it is worth stating that there is a vast amount of research being done manufacturing plant to supply the world was simple for many in the US on lightweight metals, such as aluminum, magnesium companies. With its seemingly limitless supply of low-cost labor and titanium; also advanced high strength ferrous casting alloys and an enormous, rapidly developing domestic market, an like austempered ductile iron, compacted graphite iron and high artificially low currency, and significant government incentives strength steels. The research is investigating casting methods to to attract foreign investment, China was the clear choice. Now, produce various vital defense and commercial components for however, a combination of economic forces is fast eroding the US market in the shortest possible time. The research will China’s cost advantage. And it is evident that Detroit has gone help new production technologies, advancements in the metal through a tough repositioning of its auto infrastructure and is alloys to enhance properties and performance and extending beginning to see the light for increased auto production driven the state of the science in net shape manufacturing and rapid by a new formula of quality and cost. It has an increasingly prototype/production technology. However, the overall trend in flexible workforce and a resilient corporate sector, and is the global automotive parts market is pointing to a revamped becoming more attractive as a place to manufacture. Indeed the manufacturing approach. New materials, new designs and Boston Consulting Group believes that sometime around 2015, the move into new technologies are completely changing the manufacturing in some parts of the US will be just as economical traditional auto parts industry. This will directly affect jobs and as manufacturing in China. They point out that wage and benefit while it creates demand for new skills, it will relegate old skills increases of 15 to 20 percent per year at the average Chinese to history. The primary need in this area will be retraining and factory will slash China’s labor-cost advantage over low-cost ongoing study. states in the US. And the added costs of transportation, duties, supply chain risks, industrial real estate, and other costs when Please enjoy what we offer as great reading on the following pages. fully accounted for; the cost savings of manufacturing in China rather than in some US states will become minimal within the next five years. It seems evident that we could be looking at an economic renaissance as some manufacturing will shift from China to nations with lower labor costs, such as Vietnam, Indonesia, and Mexico. But these nations’ ability to absorb the higher-end Barbara Cail manufacturing that would otherwise go to China will be limited Managing Editor METAL Casting Technologies September 2012 13 Contact CMS Technical Sales Cast Metal Services ...your partner in foundry solutions 3 Methods Engineering 3 Ferro Alloys 3 Moulding & Core Making 3 Refractories 3 Moulding Consumables 3 Tech Support 3 Abrasives 3 Hollow Ware 3 Pattern Making Supplies and Services for ALL YOUR FOUNDRY NEEDS & SOLUTIONS QUEENSLAND • JOHN SAAD General Manager • GLENN PEARCY Trading Manager Business Development • STEVE HALL Sales and Operations Manager • JULIA MARSH- QLD.Sales coordinator • PETER STAFFORD Metallurgist - Foundry Engineer • MARK DAWSON Metallurgist - Methods Engineer • JOHN SHANNON Technical Manager Refractories NEW SOUTH WALES • PAUL GALLOVICH NSW Regional Sales Manager • STEVE HARMON - National Sales Manager Steel Works & Smelters • GARY BRYDE Chemist - Refractories Engineer • MICK NOLAN Product Development Manager VICTORIA • WOLFGANG MAIER VIC Regional Sales Manager SOUTH AUSTRALIA • PETER Di ROSA SA Regional Sales Manager WESTERN AUSTRALIA • IAN MOUNTFORD WA Regional Sales Manager UNITED KINGDOM • BRIAN BLAIR UK Regional Sales Manager CHINA • ZHENG YOU JIANG Regional Sales Manager Head Office Postal: PO Box 22, Northgate Qld 4051 Offices: 275 Toombul Rd, Northgate Qld 4013 T: +61 7 3266 6266 F: +61 7 3266 6366 E: [email protected] Branches located in: Brisbane, Sydney, Melbourne, Adelaide & Perth Overseas offices: UK, China & Malaysia NZ Distributors: Metcast Services Limited. Auckland NZ 14 www.metals.rala.com.au METAL Casting Technologies September 2012 15 COMPANY PROFILE COMPANY PROFILE METAL Casting Technologies September 2012 17 CHINA By Daniel Allen Clean, Green & Lean, the Chinese foundry industry looks to a sophisticated and sustainable future T o meet the demands of a rampant national economy, to boost exports, to remain competitive and profitable, and to lessen its huge environmental burden - these are the challenging tasks facing the Chinese foundry industry today. It is no longer enough to focus solely on quantity. Chinese foundries have to think smart, operate smart and produce smart. Only by doing this can they move up the value chain and establish China as a true foundry superpower. Over the last decade the development of the Chinese foundry industry has mirrored the breakneck development of the Chinese economy. From 16.26 million tons in 2002, industrial output had jumped to nearly 40 million tons by 2010, accounting for 40% of world casting production. As casting quality and production process sophistication have risen over this period, more of the country’s domestic needs have been met and the import of complex castings from overseas has dropped. Today, China is rightly viewed as the world’s preeminent foundry nation. Yet for all the impressive statistics, the country’s foundry industry now faces an array of serious challenges, many of which will drive radical change over the next decade. These problems include underinvestment in modern technology and equipment, inefficient use of energy and raw materials, rising 18 www.metals.rala.com.au labour costs and a scarcity of skilled labour, and a pressing need to reduce environmental contamination and degradation. “Despite recent growth, the foundry industry in China still lags way behind the industries of advanced economies such as America and Japan,” says Galen Wang, Marketing Manager of the Dandong Ruiding Founding Co., Ltd. “In a way, the demands of a surging Chinese economy, coupled with rising domestic consumption and foreign investment, mean the Chinese foundry industry has no alternative but to drag itself into the 21st century.” There are currently around 30,000 foundries operating in China, and installed capacity far exceeds actual demand. These foundries vary hugely in term of scale, technology, management expertise and casting quality, and this wideranging disparity is one of the major reasons for the industry’s operational inefficiency, high energy use and levels of pollution. More than 90% of China’s foundries have a poor environmental record, poor working conditions, and employ outdated equipment. According to targets set out in China’s 12th Five Year Plan, the number of Chinese foundries will drop from 30,000 to approximately 20,000 by 2015, with a further reduction to 10,000 by 2020. Despite this drastic decrease, the aim is to ramp up total castings production to 50 million tons by 2015, with a total sales value of RMB 750 billion (US$120 billion). To meet this target, the average production volume of each remaining Chinese foundry will rise from around 1,200 tons today, to 2,500 tons by 2015, and 5,000 tons by 2020. According to the China Foundry Association, growth in castings production will be far from uniform over the next decade. “Every sector will exhibit a different growth rate,” says Thomas Gao, Director of the International Communications Department at the China Foundry Association (CFA). “We expect the production of automotive castings to rise 10%, machine tools by 3%, heavy steel-power by 5% and infrastructure-related castings by 6%. Steel mill castings will actually drop by 2%.” Stricter environmental controls have already caused the closure of many small and medium-sized Chinese foundries, which generally employ open, cupola-style furnaces that cause the greatest levels of pollution. Remaining foundries are having to invest significantly in pollution control equipment, which is a having a knock-on effect on prices, reducing competitiveness domestically and on the global market. “Over the next five to 10 years the total number of Chinese foundries will decrease sharply, principally because of growing competition and stricter pollution control legislation,” says Galen Wang. “However, actual output will also be affected by pollution control and to provide much-needed employment in rural areas. “The clustering of Chinese foundries has already significantly helped the industry develop,” says Thomas Gao. “When done properly clustering can help to reduce energy use, cut emissions and lower production costs, he continues. “It also creates more opportunities for co-operation in areas such as training, finance, marketing and exports.” In China, every ton of ductile cast iron produced consumes an average of 550 to 700 kg coal - it only takes the equivalent of 300 to 400 kg in developed countries. For every one ton of steel castings produced, coal consumption is around 800 kg, compared to 500 kg overseas. There is clearly plenty of scope for boosting energy efficiency. Until now, with the exception of a few large enterprises such “Over the next five to 10 years the total number of Chinese foundries will decrease sharply, principally because of growing competition and stricter pollution control legislation” the condition of the global economy, as well as the strategy of foundry bosses. Despite the targets, it’s difficult to estimate how output will develop with all the variables involved.” “As the Chinese foundry industry restructures, the overarching business model will change from captive type castings consumption to independent, profit driven enterprises with a greater emphasis on environmental protection and natural resource conservation,” adds Gopal Padki, ex-CEO of Foseco China and Group Vice President of China’s Shengquan Group. “This will inevitably lead to mergers and joint management of key strategic groups under government bodies for the automotive, energy turbine, diesel, railway, tractor, mining and pipe industries.” At present the Chinese foundry industry is aggregated in six main geographical clusters, and this trend is likely to continue. A growing number of foundries and foundry complexes are now situated away from large urban centres, to help with as the China FAW Group, which already employs sophisticated production and pollution reduction technology, most Chinese foundries have paid little heed to the environmental damage they may be causing. This is about to change. According to the 12th Five Year Plan, 30% of China’s foundries are tasked with achieving the standard of industrialised and developed countries in terms of energy savings and emissions reductions by 2015, while waste disposal and emissions will reach national or local standards. Energy consumption will be reduced by 10 % and waste discharge by 15%. Investment in environmental protection currently accounts for only 5% of the total investment by Chinese foundries – to meet targets this figure will have to rise sharply. The development of environmentally-friendly raw materials and end products needs to be given greater consideration, while the “3 R” principle of reducing, reusing and recycling should become the industry code of practice. METAL Casting Technologies September 2012 19 Investment in sulphur dioxide and carbon capture technology, and emphasis on cleaner, renewable energies, is vital. This will increase future costs for capital investment, and also increase the cost of operations for both existing and newer business enterprises. In the longer term, however, reduced energy use will benefit foundries, especially in light of uncertainty over oil prices and power costs. Despite targets and good intentions, environmental protection and economic profit are not often comfortable bedfellows. Even in well-governed cities there are invariably some foundries that ought to be fined, and some that need to be closed for severely polluting local air and water. Unfortunately, while these enterprises contribute hefty tax revenue and are a good source of employment, the inclination to act against them may be low. “I think most Chinese foundries have the desire to be green and efficient, but it all comes down to money,” says Galen Wang. “Still, compared with developed countries, environmental investment in China is far from enough. To achieve green casting we have heavy responsibilities and also great potential. With the right mindset, strategy and investment, I believe we can change China from a big casting country into a green casting power in the near future.” In a nation where the lion’s share of rainfall and snowmelt occur in the south, China is no stranger to regional water scarcity and issues around hydro-engineering. Today, however, surging economic growth has exacerbated the problem to choking point. China’s expanding industrial sector, which already consumes 70 percent of the nation’s energy, sucks up more energy every year. In turn, rising energy demands mean that China’s enormous reserves of coal – mostly located in the desiccated north – are having to be exploited. Production and consumption of coal has already tripled since 2000, and government analysts project China’s energy companies will need to increase coal production by a further 30 percent by 2020. The knock-on problem here is that Chinese coal production uses a lot of water. In fact, the water needed for mining, processing and consuming Chinese coal accounts for the largest share of the country’s industrial water use - a fifth of all the water consumed nationally. With climate change already impacting on water resource levels across China, the western and northern regions – where many of China’s foundries are located – will face severe water shortages. With this in mind, Chinese foundries must look at measures to reduce their water consumption, based around new 20 www.metals.rala.com.au Bright minds are essential for the development of Chinese foundry technology. technology and production processes, and efforts to ramp up recycling and water efficiency on both a micro and macro level. China’s hourly manufacturing labour rates are currently way below rates in Japan (US$27.80) and Taiwan (US$8.68), but roughly level with nations like the Philippines ($1.68), and slightly higher than those in India. Still, pay hikes within the foundry industry have been fairly significant over the last few years, and cheap labour can no longer be relied upon to give Chinese foundries a cutting edge. While the Chinese foundry industry currently employs 1.5 to 1.6 million people, many foundries are finding it increasingly difficult to attract and retain workers, partly because foundry work is considered dirty and unrewarding. To change this perception, working conditions and pay need to be improved, and skills training improved. As of June 2010, 16 training bases had been established by the CFA across China, allowing more than 10,000 technicians and skilled workers to be trained annually. Bright minds are essential for the development of Chinese foundry technology. Within the industry, basic and applied research has to be enhanced for developing new technologies, materials and equipment. Computer simulations need to be introduced to improve production processes and the quality of commonly-used metallic materials - this is particularly crucial for the acceleration of high-end equipment manufacturing. Software jointly developed by Tsinghua University and Huzhong University of Science and Technology has already been put into widespread use to improve casting quality and reduce waste. “When it comes to technological progress, the trick is to be innovative and profitable,” says Gopal Padki. “In these times of immense uncertainty, global slowdown and domestic pressures, the Chinese foundry industry needs to innovate not only in technology, but in business, training and management too.” Until now China has been regarded as an unstoppable force in the global castings arena. The recent upward trend in foreign investment in the Chinese foundry industry is a reflection of its inherent strength, resilience, and huge potential for growth. While moves up the value chain within the industry have so far been tentative, and growing pains are inevitable, widespread benchmarking with western standards is an indication of Beijing’s determination to make China a true foundry superpower. The next few years should certainly prove interesting. AUSTRALIA W By Nev Murray e are very good at what we do! The Australian foundry industry is adequately capable with technical excellence, expertise and capacity to service our own requirements for castings, although hampered by costs. Australia has foundries in all the main cities. Modern up to date equipment is predominant in line with ‘world best practice’ with high pressure touch screen high volume greensand machines, loop line chemically bonded systems using, Furan, Alkaline phenolic, Phenolic urethane, Sodium silicate, Shell, Cold box, high pressure and gravity die casting and extensive Heat treatment facilities. Foundry manufacturing plant and equipment is designed and made in Australia to suit local conditions. Established metal casting categories include; Iron, Steel, Ductile and ADI, non-ferrous, high pressure and Gravity Die casting, Investment, Art and sculpture, Ingot manufacture, centrifugally spun ductile pipe. Although not strictly ‘foundry’ there are also a number of large ‘con cast’ steel billet plants in Australia. Foundries range from small well run family owned to large ‘multi-national’ owned operations. Some have been successfully in business since the 1950’s. In recent years a few large Australian foundries have ventured into establishing foundries in China and India, with mixed results. Quality control – environment and computers Predominately Australian foundries incorporate integrated quality procedures to ISO9001 and ISO9002 or other suitable and appropriate controls to maintain casting integrity and customer requirements. The ‘full bag’ of computerised 3D simulation methoding systems is well established in Australia, as are internationally, with all their technically competitive superiority claims. Australian foundries employ qualified Patternmakers, Metallurgists, Accountants, Sales and marketing personnel and usually have modern laboratory facilities to back up the skills. Multi axis computerised Cad-Cam and Rapid prototyping is used in well-equiped pattern shops.. Most foundries have a formal Workplace Health and Safety Policy and Environmental Management Policy in accordance with enforced state legislations. Foundry owners and managers travel extensively overseas to international conferences and keep a close eye on economic and technical developments. Survival of the fittest Currently our industry manufacturing sector, except mining, is under pressure from rising costs and a sluggish economy due to the international financial crisis, not unlike other economies in the developed countries. Our worldwide competitiveness in manufactured goods is suffering with our dollar high against the US greenback, pulsing up and down between 0.90 and1.031 from our more usual comfortable position of .60 and .80. SOURCE: DELOITTE ACCESS ECONOMICS 1.10 1.00 0.90 0.80 0.70 0.60 2004 2008 2012 2016 $us per $A exchange rate Australia however, with a stable government, strong regulated banking system and doggedly persistent and determined attitude to recover will pull out of this and, unassisted, recover to a brighter future. The American and European economic experiences still bleeding tears of money will not substantially undermine our basic sound economy because Australia does not depend on them for exported castings - they like our coal and iron ore. Our exports of iron ore and coal are stronger than ever with projected increased world market share at good prices. Coal exports are expected to increase 100% in the next 2 years. Our ability to supply may stretch our current resources. Raw materials and consumables This is the stuff we apply heat to, and then turn it into castings. Apart from our own returns, bought scrap, sand and non-ferrous ingot, most of it is imported. Many years ago Pig iron was made in Australia by BHP and sold for $78.00 a tonne in about 1970. A special high grade of Pig was made by ‘Wundowie’ in Western Australia using charcoal instead of coke specifically METAL Casting Technologies September 2012 21 On-site, at-line and in the laboratory - from SPECTRO and its metal analyzers you can expect: for making SG ( Ductile iron ), and everybody used it. BHP cut costs and stoped local production in 1972 and imported Pig from China and Brazil. Wundowie soon closed, the imported poor quality pig iron eventually improved and it is now all imported. For good ductile iron production we import Sorrell metal (Swedish Pig iron) or a ductile grade from South Africa. No locally made Pig iron is available to our foundries. All other ferrous alloys (lots of them) are imported, particularly from China. Most of the other consumables, previously made here, are imported as the supply companies find it more attractive to buy cheaper from overseas. Foundries have no alternative but to shoulder the extra costs. What we have to put up with! Australian Foundries operate in an environment created by themselves, Government and international pressure. Our unemployment CPI is currently running at 5.1% (average of all states) and inflation running at 1.2%. (July) being the lowest in 13 years. The RBA has three times this year reduced the official cash rate currently at 3.5%. The banks have followed the RBA lead, to encourage the building sector and manufacturing business for investment in new equipment, expansion and employment, with banks currently at around 6%. In Australia we enjoy a reasonably high standard of living and a clean environment. This reflects in a requirement for foundries, legislated by Government ‘Work Cover’ regulations, to create safe working conditions and a clean pollution free environment legislated by the National Environment Protection Authority. Australia also has a generous compulsory ‘workers compensation’ system which financially compensates workers injured at work. These strongly enforced industry regulations cover, noise, heat, hazardous areas, emissions, disposal of waste, transport and protective clothing. These add considerable extra costs to making a casting. The Australian federal government has recently imposed a ‘profit tax’ on the ‘cashed up’ mining industry, and more recently, this year, a ‘carbon tax’ on the big carbon dioxide generators specifically aimed at the coal fired power generators. These measures to claw out cash from these sectors, although they can afford it, will obviously kick in as higher costs to foundries when they jack up electricity prices and services to try and offset their new tax liabilities. Where do our castings go? Just about the only thing we don’t do a lot of is export. In the past, Australia enjoyed a healthier export market than it now has e.g. to the US. All aspects of industry use castings in some form although major consumers are mining, crushing and processing, automotive, agriculture, water supply and reticulation, building, rail, road construction and transport. Our shipbuilding has protracted. We make world class castings in manganese steel, hi chrome and Ni Cr irons for; mining, wear applications, ground engaging and crushing industries as well as large rubber lined slurry pumps and anything you can’t afford to have worn out in a hurry. A huge range of castings are made for general engineering applications and other manufacturing industries from bottle moulds for glass works to manhole covers, grating, automotive components, valves and fittings for water reticulation and sewer lines and thousands of die castings. Before the current dollar crisis Australian made aluminium nickel bronze marine propellers enjoyed a good export market. Imported castings and survival at any cost Talk with SPECTRO and find out why SPECTRO‘s metal analyzers are an investment in better efficiency and higher profitability. Tel. +852.2976.9162 Fax +852.2976.9542 [email protected] www.spectro.com Considerable quantities of castings are imported due to competitive pricing from overseas, and this is a situation which has existed for many years, much to the grumblings from the locals. Many castings are imported by ‘sales outlet’ establishments who resell although some of our long established local foundries are importing castings made for them at low cost in Asia. Imported castings come from China, India, Malaysia, Vietnam, Germany and New Zealand. Past experience has seen lobby groups and industry associations All aspects of industry use castings in some form although major consumers are mining, crushing and processing, automotive, agriculture, water supply and reticulation, building, rail, road construction and transport. 22 www.metals.rala.com.au Metal Analysis with SPECTRO Analyzers - Perfect analysis solutions with innovative technologies - Fast and precise measurements, plus ease of use and reliability - Outstanding performance and flexibility - Comprehensive service and analytical expertise of the market leader - Unrivaled price-to-performance-ratio Please visit us at: JAIMA/JASIS 2012, 5 - 7 September, Tokyo, Japan Guangzhou Mould Exhibition 2012, 19 - 21 September, Guangzhou, China NDT 2012, 31 October - 2 November, Shanghai, China THE FULL PICTURE ! pressuring their politicians to load import tariffs on imported castings and give favourable consideration to local manufacturers tendering on Government contracts. The pressure worked and in the 1980’s the Federal Government introduced a plan to help the foundries invest in new equipment and efficiency measures by significantly raising import Tariffs to 40% for a trial time. In 1996 The Federal Industry Commission reported that due to lack of effect the tariff be reduced (40%) to 5% in line with an overall reduction of tariffs on imports. How we got where we are! The iron foundry industry in Australia started in early colonial days although very little is recorded. Ship building did foster the building of some large foundries from the mid 1800’s. A number of large privately owned steel foundries had been established in Sydney, Australia in the 1930’s producing manganese steel castings for mining, earth moving and ship building, including heavy cast steel chain. A government ship building complex was built in 1900 including an iron foundry, steel foundry and a bronze foundry. During the Second World War these foundries were ‘protected industries’ and prospered when Sydney became a ‘safe’ maintenance location for allied ship repairs. Hadfields Steel Works Ltd. became very successful and profitable, casting large ships anchors and chain for aircraft carriers, battle ships and cruisers. Ingots and automotive In 1915 Australia’s largest company BHP was formed as a steel maker and later in 1935 merged with A.I.S. (Australian Iron and Steel) with blast furnaces to become a world leader in steel making, and also with large foundries producing 30 tonne cast iron ingot moulds and iron, steel and non-ferrous castings necessary in the processes of blast furnace operation and associated maintenance programmes. Eventually BHP was operating about 9 foundries around Australia. Not many are left today. The Australian automotive manufacturing industry started with General Motors building a foundry here in 1947. Subsequently the Ford Motor Company and then Chrysler motors (later to become Mitsubishi Australia) built foundries here. The disappearing act There are not as many foundries in Australia today as there were 40/50 years ago. This is common with other Western developed countries particularly when iron foundries were using cupolas, but new larger modern foundries have been built which make more castings with fewer people, less noise and are environmentally improved. Mergers, take overs and foundry upgrades have offset to some extent the closures. In the last 12 months there have been 2 mergers and 2 closures. A sad note is that General Motors and Mitsubishi Australia have closed their foundries (2010), leaving Ford Australia the only vehicle manufacturing company still operating a foundry in Australia today. With falling engine block production Ford invested 20 million dollars and geared up in 2010, under an agreement with global components supplier Bosch, for the upgraded plant to be a centre of excellence for brake rotor castings to fill the foundry capacity. Current reports, at the time of going to press, are that Ford Australia’s foundry is under a cloud of uncertain existence due to falling car sales. In 2012 Ford received 34 million dollars from the Australian Government under the Automotive Competitiveness and Investment Scheme program Industry Assistance grants to assist its survival in Australia. Ford said thanks but it can’t guarantee producing in Australia after 2016, and in July this year announced it will be putting off 440 jobs. Currently Industry information indicates that Ford Detroit US (the boss), is unhappy with the prospects of manufacturing in Australia so the current Falcon will be only cosmetically tweaked for next years and a totally new model is not expected to be made in Australia in the future. Ford is important to us and we hope we don’t lose them. References: 3. Australian Financial Review. 1. RBA Reserve Bank of Australia. 4. Mr. John Adlard. AFI, MPA historical archives. 2. ABS Australian Bureau of Statistics. The Australian automotive manufacturing industry started with General Motors building a foundry here in 1947. 24 www.metals.rala.com.au Casting process insight and understanding can be calculated in advance. Simulation creates transparency, enhances knowledge and provides the basis for making the right decisions. Predictable casting quality strengthens your collaboration with customers and has a lasting effect on their trust in you. Contact in Asia: MAGMA Engineering Asia Pacific Pte Ltd 25 International Business Park, #03-76/79 German Centre Singapore 609916 Phone: +65 6564 3435 Fax: +65 6564 0665 [email protected] www.magmasoft.com.sg Optimize Core Performance Trust your most complex cores to INCAST ®. The ideal combination of geometry, density and particle size distribution, INCAST improves critical core making and casting properties including binder utilization, permeability and dimensional stability. Higher strength cores, better surface finish and increased efficiency and yield are the INCAST advantages. These sands are engineered for the metalcaster. INDIA A By Dr. P. C. Maity bout 4600 foundry industries in India are producing 9.05 million metric tons of castings according to the latest data of 45th census of castings. 70% of the castings are grey cast iron, 9% ductile iron, 12% steel and other nonferrous is 9%. 80% of the foundries are small scale category and are labour intensive. Medium scale and large scale industries are of 10% each and are either semimechanised or mechanised. Indian foundry industry provide jobs to about 0.5 million people directly and 1.5 million people indirectly. The industry is making a contribution of INR 7000 per ton to the national exchequer in the form of excise and other duties. The export of castings in 2010/11 touched US$ 215 million. It appears that India would continue to hold 2nd position in the world in terms of tonnage of casting produced. China produced largest volume of castings at 39.6 million metric tons. United States produced total 8.238 million metric tons holding third position in the world. Other countries in this series are Germany, Japan, Russia and Brazil producing 4.794, 4,757, 4.2 and 3.24 million metric tons respectively. Declined car market Recently, the car sales in India has declined due to high interest rates, high fuel prices and slow pace of economic growth. Most of the customers buy a car financed by banks. As the interest rate has increased in recent times, it has affected the sale of cars. Similarly increase in fuel price has been enormous in last few years. These factors have reduced the sale of cars. In May, 2012, car sales in India grew only by 2.78% at 163,229 units compared to 158,809 units in May 2011, which is the slowest growth since October 2011 when car sales declined by 23.77%. In the first two months of 2012-13, almost all the passenger car makers were forced to rationalise production at their plants since the decline of growth rate in car sales. GM India has initiated suspension of production for one day per week in order to avoid piling up of inventories. Tata Motors had to close their Jamshedpur plant for three days at the end of June 2012 for the same reason. Vision plan 2020 The large gap in production in castings between India and China along with the fact that the foundry industry is not able to keep up with the local demand both in terms of quantity and quality have motivated The Institute of Indian Foundrymen (IIF) to draw a Vision Plan 2020 for the foundry industry and recommend the needed initiatives to materialise the vision. To prepare the vision plan a detailed survey of 325 foundry units from different regions with varying size and products was carried out and 100 CEOs and decision makers were consulted for their views. The collected data was analysed to draw the vision plan through identifying the key issues and the steps to be taken to overcome various constraints. Twenty interventions were suggested on the basis of various findings of the analysis: l To make the Indian foundry an attractive entity for all the stakeholders l To make foundry a viable investment option ranking equally among other available alternatives l Employees enjoy staying there l The industry becomes a clean and environmentally friendly l To realise a natural growth with the above and emerge as a leading supplier of quality castings to the global market covering all sectors by 2020. Some of the important interventions suggested in the vision plan are creation of Technology Upgradation Fund (TUF), capacity consolidation by moving all similar units to a common location and the facilities housed there, creation of new capacity via “Green channel clearance” for giving approvals and allocation of suitable land in the foundry park / cluster through Indian or Foreign Direct Investment(FDI), common testing and It appears that India would continue to hold 2nd position in the world in terms of tonnage of casting produced. processing facilities, low cost mechanisation, developing training facilities and R&D centers, health care of workers etc. The vision plan is to be implemented in two phases of five years each. The total investment proposed under the project is INR 21.34 billion to help the foundry industry to move towards a production level of 11 million tons. The survey revealed the readiness of the units to accept the proposed interventions. Foundry Park inaugurated in Howrah Under the initiative of Indian Foundry Association (IFA), Foundry Cluster Development Association and the Government of West Bengal, a Foundry Park was inaugurated by the chief minister of West Bengal Ms. Mamata Banerjee on Feb. 4, 2012. At the initial phase, 60 foundry units, an Industrial Training Institute, environmental laboratory, tool room would be set up by investing INR 8 billion that would employ 40,000 people directly or indirectly. Shortage of skilled manpower in foundry industries – tackling the issue. Shortage of skilled manpower in foundries is a common issue for all countries producing castings including India. As discussed in last overview, initiative has been taken by IIF to set up “Sector Skill Council – Foundry” to upgrade the skill of foundry workforce. Two centres at Coimbatore and Belgaum foundry clusters have already been inaugurated recently under this scheme. It is a long term program and the benefits of it are expected over the years. In the meantime, various efforts by the stakeholders are on the way to provide skilled manpower to the metal casting industries. The Centre for Foundry Education and Research (CFER) at Ahmedabad set up by Bhagwati groups and friends with support from Government of Gujarat has initiated six months’ training programme to train workers for foundry industry. The training consists of two months theory classes followed by four months’ on-the-job training in different foundries. Two batches of 30 students have already completed the training and all of them are employed. CFER has also initiated Supervisor’s re-training programmes. At the initiative of Dr. P. N. Bhagwati and support from Government of Gujarat, Bhagwati-ITI Kubernagar Foundry Training Centre was inaugurated ® CORE AND MOULDING SANDS For more information and availability: [email protected] ® INCAST is a trademark. All rights reserved. ©2011 26 www.metals.rala.com.au Supercharge Your Green Sand System on 15 December, 2011 at ITI Kubernagar, Ahmedabad premises under “Skill Development” initiative of Industries and Mines Department of Government of Gujarat. ITI Kubernagar in collaboration with CFER has started Foundry Trade Apprentice course of one year duration for the first time that covers both classroom as well as practical training. Another training center has been inaugurated on 17 December, 2011 at IIF, southern region premises in Chennai by Mr. Gaurav Kapur, Director, Gargi HA. It is named as “Gargi HA Training Center” and has facility for training 55 persons. It is equipped with high tech facilities for conducting training programmes and seminars for workers, supervisors and managers of foundry industries. Recently, the Western Region of IIF has taken initiative to train shop floor workers on various topics such as moulding practices, core shooting practices, aluminium foundry practices, steel foundry practices etc. through local languages. These training programmes are to be conducted at different chapters of IIF, for which trainers are being arranged. Energy Efficiency improvement is another area of the training schedule. These training programmes are expected to start shortly. To attract students of engineering institutes towards foundry industries, a new initiative was taken for the first time during the 60th Indian Foundry Congress held on March 2-4, 2012 at Bengaluru. During the programme “Students Meet Young Foundry Leaders”, a few new generation foundry leaders shared their experiences and views on the burning issue of acute dearth of skilled manpower in the foundry sector. A distinguished panel of young foundry leaders deliberated on showcasing the modern Indian foundry, unconventional employment opportunities in the modern Indian foundry, knowledge and skill gap between industry expectation and educational institution and role of modern Indian foundry in enhancing student skills. Students showed keen interest to the presentations by young foundry leaders. Another recent development in this direction is the establishment of the National Knowledge Network (NKN): E-Foundry. The NKN is a state-of-the-art multi-gigabit pan-India network for providing a high speed backbone for knowledge related institutions in India, with the objective of creating highly trained professionals. Using this facility, the NKN:E-Foundry was launched for academic institutes on the National Education Day, 11th November 2011 and was formally opened to the foundry industry on the eve of the 60th Indian Foundry Congress held on March 2-4 2012 at Bengaluru. The NKN core committee commissioned the E-Foundry project, since a readily usable knowledge base on foundry was available. It is a free online resource of knowledge and technology in casting design and simulation having high quality content developed by experts that works under interactive and collaborative learning environment. The major resources available at the E-Foundry are lesson movies in casting design and simulation, online simulation lab and other learning resources containing technical papers and abstracts related to foundry. It is expected that the E-Foundry project would act as a catalyst to attract and retain young engineers to the metal casting industry. Indian Foundry Congress 2012 The 60th Indian Foundry Congress was held at Bengaluru during 2-4 March, 2012. About 1700 delegates attended the congress. It was accompanied by IFEX-2012 (8th Exhibition on Foundry Technology, Equipments and suppliers) and 2nd Asia Foundry Forum. The exhibition was inaugurated on 2nd March 2012 by IIF’s past president Mr. S. Thiagharajan. About 280 exhibitors (including 79 exhibitors from abroad) had displayed their products and services covering an area of approx. 15,000 sq. Meters. Four countries, namely, Japan, Italy, Germany and China had group participation. The Congress was inaugurated on the first day at 4-30 PM. By Mr. C. R. Swaminathan, Chairman, Organizing Committee of the Congress. Minister for large and medium scale industries of Karnataka state Mr M. R. Nirani announced during the inauguration that the government will set up a foundry cluster at Dobbaspet in next six months. It was also announced to set up Foundry Innovation Center at To attract students of engineering institutes towards foundry industries, a new initiative was taken for the first time during the 60th Indian Foundry Congress... 28 www.metals.rala.com.au It is expected that the E-Foundry project would act as a catalyst to attract and retain young engineers to the metal casting industry. Bengaluru to conduct R&D work related to metal casting. Technical sessions were held over the next two days. About 60 technical papers were presented by authors from India and overseas. The first technical paper was presented by Prof M. C. Flemings, MIT, USA on the topic “Metal casting Innovations, 1952-2012 and Beyond”. After informing the delegates that his own career in metal casting ranges from 1952 to 2012, Prof. Flemings initially pointed out the meaning of the words “Innovation” and “Invention”. Thereafter he discussed various important innovations / inventions during 1952 to 2012. These were Ductile Iron, Ceramic shell investment casting, lost foam casting, single casting, Hitchiner Process, use of computers for simulation, molten metal filtration etc. He pointed out that ductile iron and ceramic shell investment casting were the two most important inventions that impacted on the global foundry business heavily. Prof. Flemings also mentioned a few inventions which may influence the future of the foundry industry. These are SLIC process (combination of investment casting and lost foam casting), ablation casting, 3D printing of sand moulds, rapid prototyping, metal matrix composites, further development in modelling and simulation, magnesium alloy castings etc. The Tech-Mart session focussed on “Automation in Fettling and Casting Finishing” where three companies made presentation about their products and technologies related to this operation. Energy Forum was another event during the Congress where dignitaries participated in the event various issues related to energy conservation. Valedictory session was the last event during which best paper awards and awards for best stalls in the exhibition were distributed. Green sand systems work harder and last longer with TRUBOND®. These sodium bentonite grades mull in quickly and undergo a controlled hydration to develop a stronger, more elastic adhesive. TRUBOND delivers excellent green compressive and hot strength properties and maintains its working bond in repetitive exposure to high heat loads and metal temperatures. SODIUM BENTONITE For more information and availability: [email protected] ® TRUBOND is a registered trademark. All rights reserved. ©2011 NEW ZEALAND I By Gordon Muldrew n researching this article I looked back on some previous versions. All of them start out how tough the last year has been and that the economic outlook is grim etc. But yet here we still are (well most of us) making castings and hopefully a dollar or two. Henry Ford once quoted “Business is never so healthy as when, like a chicken, it must do a certain amount of scratching around for what it gets”. New Zealand’s GDP increased in the March quarter by 1.1% with manufacturing up by 1.8% being the largest contributor. So there are some signs of life but the general feeling is that it is a tough environment for New Zealand foundries. Earthquake-related rebuilding is expected to provide substantial impetus to economic activity in coming years, even though recent aftershocks are likely to delay some rebuilding by 1 to 2 quarters. However we don’t expect this to have a big impact on the foundry industry. There have been a couple of closures of smaller foundries with their work being absorbed by other existing foundries. One foundry has recently changed ownership and another larger foundry is currently up for sale. It is an uncertain time for the staff at this particular foundry. We hope that it will be sold and that the new owners can take the foundry forward into the future. Investment in plant and equipment has typically been low but some of the larger foundries are investing in new equipment this year which is good to see. Foundries associated with the extractive/mining industry seem to have better workloads at present than most others. This will of course depend on China and its continued growth. Our export market has continued to be challenging due to the high exchange rate of the New Zealand dollar. CTNZ hosted the annual AFI conference in Queenstown last October/November. Attendance was good with many Australian companies making the effort to visit the conference and one of our top tourist attractions. Feedback from the participants was excellent and all had a good time. We would like to thank all those that attended. We have just held a smaller conference in Taupo with speakers from Australia and local experts presenting papers on a range of topics. Attendance was good with a couple of Australians making it over once again. We encourage CTNZ members to return the favour and attend the upcoming AFI conference in Sydney. The annual AFI conferences always have excellent technical content and it is a good opportunity to network and catch up with old friends. There is no foundry training school in this country and the current level of those involved in formal training is low. For many years we have relied on skilled migrants to top up the trades and tertiary trained technical positions. We have even let some Australians in! The size of our industry makes it difficult to develop training to a higher standard and this isn’t likely to improve. In spite of the difficulties faced by our industry some companies are leveraging their competitive advantage, and they are prospering. In many cases the successful business is high value, niche focused and operating where design and services are bundled in with the castings. We are extraordinarily good at problem solving and devising innovative solutions. Our successful operations are the ones that offer small run, highly technical, high value castings or are foundries owned by business that manufacture their own high value niche product that incorporate castings and hold onto the foundry for strategic reasons. “Success is going from failure to failure without loss of enthusiasm” – Winston Churchill Investment in plant and equipment has typically been low but some of the larger foundries are investing in new equipment this year which is good to see. 30 www.metals.rala.com.au PAKISTAN P By Abdul Rashid akistan is a country of 180 million people with 1800 foundries operating with an installed capacity of 350,000 tons per year of grey, SG iron, steel and nonferrous castings. This does not include aluminium die casting industry which is still working as small scale jobbing foundries. Most of these foundries are engaged in the production of automotive parts, tractors, sugar mills machinery parts, cement factories consumables, chemical factories consumables, agriculture implements, heavy industrial castings, agriculture implements, pumps, valves, electric motors, textile and cement machinery, processing industries and others. The inception of tractor and automotive assemblers introduced product quality awareness among the foundry industry. The interchange-ability and quality consistency of cast components required process mechanization and proper control of input materials. Developed countries have started shifting their casting requirements to developing Asian countries including Pakistan. We export foundry products to many countries in the world like USA, Germany, UK, Brazil, Netherlands etc. Our export during the year 2008-09 was US$60 million, 2009-10 it was US$57 million and in the year 2010-2011 it was US$67 million. Pakistan has tremendous growth potential and the world foundries can benefit from: l Low labour cost l Large population with a strong domestic demand l Construction cost for new casting facilities and completion time is low l Health & Safety compliances for molding binders are not stringent as the developed world l Tooling cost and local development of auxiliary foundry equipment is low Despite current economic situation, Pakistan is set to become a market for 500,000 cars and 2.5 million motor cycles in addition to bus, truck and farm machinery sectors. To fulfil the future demands of casting in Pakistan as well as for export destinations the Japanese/ Chinese auto giants and all, interested to invest with their strong foot print in Pakistan, Chief Guest and the President of PFA visiting 3rd International Foundry Congress & Exhibition – held every two years or their overseas vendors may invest in the foundry sector in Pakistan in order to reap the profits of the rising demand in Pakistan. The balance sheets of multinationals which are already operating in Pakistan for five to six decades by now bear testimony to the fact that there is large potential for profits to be made in Pakistan and virtually every multinational operating in Pakistan is a blue chip company. Agricultural machinery sector will also be the engine of growth here and abroad as more and more Pakistani farm machinery begins to be exported. The big growth in this sector will create an ever increasing demand on vendor industries and particularly on foundries. Major challenges being faced by Pakistani foundries l Even though the tooling cost is low, the quality needs tremendous improvement through technology guidance l Assistance in development of sufficient infrastructure l Guidance in Indigenous development of foundry consumables l Guidance in development of training programs. In order to get a share from the world market, Pakistan needs properly trained manpower, equipment, allied tools and a consistent quality of raw material in order to meet the global requirements of finished castings at competitive price. Such an initiative from developed countries will guide developing countries like Pakistan so that the technology growth in foundry industry may make this world a better place to live. PFA warmly invites all readers of Metal Casting Technologies Magazine to participate in 4th International Foundry Congress & Exhibitions to be held on Dec 5 & 06 – 2012 at Lahore Pakistan. For detail please visit www.pfa.org.pk METAL Casting Technologies September 2012 31 PHILIPPINES T By Prof. John H.D. Bautista he Philippine Metalcasting industry is beset by many problems calling for attention, but not getting the attention that is required. At best, attention is halfhearted, meaning there is lack of sincerity and political will. For sometime now, low-priced castings from China are exerting a lot of pressure on our Metalcasting Industry in order to preserve its domestic market. If we cannot compete in our own domestic market with imported castings from China, the more we cannot compete in the world market. Indications are that, if the present situation persists, the Philippine domestic market may be lost to China. This is a grave problem that we have to address quickly and adequately. In the face of this problem, we have the other related and relevant problems. Listed below are the problems that need immediate attention. 1. Scrap metals are being exported and, because of the present dollar exchange, the domestic foundries cannot compete with the foreign buyers. This is slowly killing the foundry industry in the Philippines. Since the Philippine government is cashstrapped, would it not be nice to slap an export levy on scrap metal exports so that the playing field may be leveled? PMAI would suggest an export levy of two pesos per kilo of scrap exported or one that is graduated depending on the metal being exported. 2. The present electric power cost is unreasonably high, and still getting higher. We wish that MERALCO, our electric utility company, would give a lower rate for off-peak operations to serve as an incentive for factories to operate at night when the electrical load of MERALCO is lighter. The last known demand charge was P575.00 per kilowatt maximum demand in 2011, just last year. There is a continually increasing cost of electric power. The charges of the electric utility company for energy (KWH) and demand (KW) are tabulated below showing the historical increases as gathered from the Manila Electric Company (MERALCO – the electric utility company of the region) Billing Department. We are still suffering from this situation today as the demand charge has gone from P12.60 per Kw. maximum demand in 1985 to P575.00 per Kw. maximum demand in 2011; an increase of 4,563 percent in 26 years! Today, a foundry that operates a 1,000 Kw. induction furnace would pay PHP575,000.00 per month regardless of whether the furnace was operated only one day in the month or 25 days at 24 hours/day in the month. On the other hand, energy charge has gone from P1.79 per Kwh in 1985 to P6.82 per Kwh. in 2011; an in-crease of only 381 percent in 26 years! It would be expected that the rate of increase in both charges should be almost equal as the cost elements would be susceptible to both inflation and price-level changes. But when the rates of increase differ very much (when the change in demand charge is almost ten times that of the change in energy charge), something must be very, very wrong! If this cannot be “moderated,” the alternative solution is for the industry to generate its own electric power and this could be done only through the clustering of the companies in the Metal Engineering Industry. By operating its own power plant, demand charge could be eliminated as this is merely a penalty for companies in a grid or network that reach peak load at about the same time, making it difficult for the utility companies to cope with the irregularity. Electrical load could more easily be determined and supervised in a cluster. An additional advantage for a cluster would be the possible “synergy” among the companies in the cluster with each doing what it does best! 3. Productivity in foundries is very low. This can be solved by more mechanization, but this cannot be done because of the high cost of money. We are not financial experts; but, if we were, we could recommend ways of lowering effective interest rates. We feel that our financial experts are not looking this way. They seem to be interested only in stock-market-like financial operations. 4. The importation of second-hand machinery is preventing Item 1985 1995 2005 2007 2011 Energy Charge per KWH used P1.79 P2.94 P6.89 P6.43 P6.82 P12.60 P25.001 P382.00 2 P542.00 3 P575.00 Demand Charge per KW max. demand Note: 1. By April 1997, this was increased to P220.00 per KW maximum demand. 2. This is an average figure (P366.32 to P406.12) as the demand charge was now based on the input voltage. 3. The average demand charge for the year 2006 was P429.39 per KW maximum demand. 32 www.metals.rala.com.au the industry from embarking on an honest-to-goodness machine-building program. This country needs a good Machine-building Industry if it wants to align itself with the more progressive, more advanced countries. This can be done. Just ask those from the Metalworking Sector, aside from those in the Metalcasting Sector. We need the government to listen, because we have been telling government what to do, but it refuses to listen to us; instead it listens to the “traders.” More shopping malls are being put up and less factories. No wonder we have a high GNP, but a very low GDP. Result: the Philippine peso deteriorates vis-à-vis the US dollar. Is the government asking for more foreign investors in the manufacturing sector? This will never happen while the business climate is more conducive to trading than manufacturing. The sad fact here is that trading uses only a small fraction of the personnel used by manufacturing, besides contributing only a small fraction of the value-added that is possible with manufacturing; hence our growing unemployment rate in the face of a rising GNP. A paradox? 5. Technical smuggling is another problem that needs to be controlled. The government should be swift in dealing with such smugglers. From where we stand it seems that there is an unholy alliance somewhere; as Hamlet said, “Something is rotten in the State of Denmark.” 6. Finally, can the government agencies, especially the DENR (Department of Energy and Natural Resources), LLDA (Laguna Lake Development Authority), and MMDA (Metro Manila Development Authority), lower the level of their harassment of our Metalcasting Industry to the tolerance level that is being given to the trucks, trailers, busses, and jeepneys, all of which are actually those responsible for the greater percentage of our air pollution? Our foundries do not generate that much amount of pollution (less than 5%); besides foundries take the necessary steps to minimize both air and water pollution. Then, again, there is probably an unholy alliance that we do not know about. Just wondering, because, in this country, whenever there is a possibility of an unholy alliance, the probability is extremely high that it will happen — maybe 99.9%? THAILAND GDP Growth % Thailand Brunei Philippines D By John Pearce uring 2011 manufacturing industry in Thailand, especially the automotive and electronic sectors, suffered severe disruption from the effects on parts supplies of the tsunami disaster in Japan and then from the catastrophic floods in central Thailand that lasted from October through into the early part of 2012. The Thai Automobile Industry Association (TAIA) estimated that these unforeseen events resulted in production losses of at least 300,000 vehicles during 2011 causing a fall in annual vehicle output to 1.49 million. During the previous ten years or so, Thailand had shown steady economic growth averaging 4% from 2000 to 2007 with the industrial sector accounting for around 40% of GDP. During the global economic crisis between 2008 and 2009, Thailand’s economy contracted by about 2.3%, similar to other countries in Extent of flooding in a Thai foundry melting shop 1.5 2.8 3.7 Singapore Malaysia Myanmar Vietnam Indonesia Cambodia 4.9 5.2 5.5 5.8 6.4 6.7 Laos 8.3 ASEAN GDP Growth by Country in 2011 the region but bounced back in 2010 with expansion at 7.8%, the highest rate since 1995. The 2011 floods, the worst in 70 years, caused widespread damage to many industrial estates and production plants in the central region of Thailand reducing economic growth to the lowest of all the ASEAN countries. Around 900 companies including several foundries and die-casting shops on seven industrial estates suffered from damage and production losses due to flooding. However, in spite of the disruption, Thailand still managed to export industrial products to the value of USD 167.9 billion, accounting for 73.4% of total exports. To prevent future damage from flooding the Thai Government has initiated a number of new water resource management schemes. Plans are also underway to develop new industrial estates in NE Thailand and to develop cluster arrangements between companies to enable switching of production between plants in the event of any future problems. During the global economic crisis between 2008 and 2009, Thailand’s economy contracted by about 2.3%, similar to other countries in the region but bounced back in 2010 with expansion at 7.8%, the highest rate since 1995. 34 www.metals.rala.com.au FOUNDRY EQUIPMENT DIVISION PIPE HANDLING DIVISION SHOT-BLASTING MACHINE DIVISION I.M.F. Impianti Macchine Fonderia S.r.l. CORE-SHOOTING MACHINE DIVISION 21016 Luino (Va) Italy Ph.+ 39 0332 542424 Fax+ 39 0332 542626 [email protected] www.imf.it and by publishing regular newsletters and a quarterly technical Metal Castings Journal in Thai. During and after the flood crisis the TFA provided advice and practical assistance to affected foundries and related businesses with information on recovery and refurbishment funding, etc. to restore plant and facilities. Advancing aluminium technology The TFA Board for 2011-2012 The 2012 situation is now looking much brighter with most manufacturing plants having been renovated. Production has restarted and is gradually returning back to normal levels such that the TAIA has recently revised its production forecast for 2012 up to 2.2 million vehicles. This means that the Metal casters supplying auto- and motor-cycle parts, and those supplying the electrical goods and electronics sectors are operating at full speed. During the year the Thai Foundry Association (TFA) has continued to help develop metal casting capability by organizing seminars and plant visits, by supporting conferences in metallurgy and materials Dr. P. Dulyapraphant of MTEC explains the advantages of squeeze casting 36 www.metals.rala.com.au The month of June saw three major metal related meetings held in Bangkok, beginning with a seminar on “Advances and Technologies in Aluminium Casting”. The event, attended by 120 delegates, was held on 5th June 2012 at the Bureau of Supporting Industries Development (BSID) Centre which also houses the offices the TFA and the Iron & Steel Institute of Thailand (ISIT). BSID, which is under the Dept. of Industrial Promotion, Ministry of Industry, organized the seminar together with the TFA, the National Metals and Materials Technology Centre (MTEC) and the Office of Higher Education Admission. The first of two keynote talks was given by Prof. Merton C Flemings from Massachusetts Institute of Technology (MIT) on “Sixty Years of Casting Innovations. What Next?” with a special focus on developments in Al casting processes including semi-solid and lost foam. In the second keynote Mr. Sei Maeda, who is based in Thailand as the Chief of the Technical Centre and Executive Vice-President of Toyota Motor Asia Pacific Engineering & Manufacturing, Staff from the Iron & Steel Institute of Thailand (ISIT). ISIT provides technical, training, public relations and marketing services to the Thai metals industry. ISIT has a well equipped technical & testing centre situated in the BSID complex. Left to right. Mr. Prakob Janma (BSID host) with Prof. Flemings, Mr. Maeda & Dr. Jessada Wannasin gave an overview of “Trends of Utilizing Aluminium for Automotive”. His talk focused on how the application of Al cast parts to replace steel and cast iron in engine & drive train and body & chassis applications has saved weight and contributed to improved fuel efficiency and reduced emissions. He announced that a new Toyota plant to produce Al cylinder blocks was under construction in Thailand with production due to start in January 2014. He said that all Al foundries must strive to reduce casting defects, improve their use and accuracy of CAE and develop in line inspection technology. The current status, progress and future of Al castings production in Thailand was then covered in the following papers: l “Progress in Al Castings R&D and Production in Thailand” Dr. J. Pearce (MTEC) l “Advancement in Melt Treatment of Al Alloys” Dr. C. Limmaneevichitr (King Mongkut’s University of Technology Thonburi) Speakers Dr. T. Babul, Dr. J. Pearce & Mr. Funitani with Thanaporn Korad, the conference organizer from MTEC. “Squeeze Casting: New Opportunity for Thai Automotive Parts Suppliers” Dr. P Dulyapraphant (MTEC) l “Semi-Solid Metal Technology: Research, Development and Applications in Thailand” Dr. J. Wannasin (Prince of Songkla University) l “Towards Enhanced Competitiveness in Production of Al Castings” Dr. J. Kajornchaiyakul (MTEC) As outlined in June 2012 MCT [1] Thai Al casting producers have very little involvement in R&D as such but like the ferrous sector they are increasingly interacting with Thai universities and MTEC to solve technical problems. The conclusion from the seminar discussion was that such interaction was having a positive effect in improving overall capability of the industry. Towards further development in Thai die-casting know how Dr. Dulyapraphant of MTEC announced that a new HPDC facility would soon be available in the MTEC Pilot Plant at the Thailand Science Park. This will support improvements in die design, optimization of process variables and development of squeeze casting. l He announced that a new Toyota plant to produce Al cylinder blocks was under construction in Thailand with production due to start in January 2014. METAL Casting Technologies September 2012 37 Innovation in Materials Science and Technology The aluminium event was immediately followed by the 7th International Conference on Materials Science and Technology organized by MTEC and held from 7-8th June at Swissotel Le Concorde, Bangkok. Looking back over his many years of experience at MIT, Prof. Flemings also gave a plenary talk at this event, this time on “Innovations in Materials Science and Engineering: From Research to Market”. The other plenary lecture related to metals was given by Prof. Teruo Kishi, Advisor to and a Former President of the National Institute for Materials Science (NIMS) in Japan. Prof. Kishi focused on the environment and future supplies of raw materials in his presentation on “Materials research for Green Innovation and Critical Materials”. MSAT-7 was attended by over 400 people with six separate sessions held on each of the two days. A number of presentations covered metal casting during the sessions on Metals, Alloys & Intermetallic Compounds, Materials for Energy & Environment, and Simulation, Design & Manufacturing. The casting topics, providing examples of some of the current research in Thailand, included casting of sterling silver jewelry alloys, surface layers in HPDC components, indirect squeeze casting of auto-parts, runner design in HPDC, and defects & microstructure in thixo-cast Al alloys. Heat treatment – energy and the future At the end of June the hot topic was Heat Treatment and Surface Engineering, particularly the use of energy aspects. MTEC together with the International Federation of Heat Treatment & Surface Engineering (IFHTSE) organized the 1st International Conference on Energy and the Future of Heat Treatment and Delegates with staff and guides at the new Tohken Thermo Training Centre in Chonburi 38 www.metals.rala.com.au Surface Engineering – “EFhtse 2012”, which was held at the Emerald Hotel Bangkok during 25-27th June. Heat treatment & surface engineering (HTSE) together with foundry, forming & fabricating, and machining are recognized by government organizations in Thailand as key supporting industries for manufacturing. However, probably because HTSE processes are widely spread across many companies, there is no real focus for HTSE in Thailand [2]. There is no heat treatment society as such in Thailand but the TFA, the Thai Machinery Association (TMA), the Thai Tool and Die Industry Association (TDIA) and the Thai Corrosion of Metals and Materials Association (TCMMA) are all involved with HTSE and, recognizing the need to increase heat treatment know how, were active supporters of the Bangkok conference. Sponsorship for the event was provided by Thai Parkerizing Co. Ltd. and by Thai Tohken Thermo Co. Ltd who are the two major providers of contract HTSE services to Thai industries; both companies have Japanese based parent organizations. The conference technical programme began with a plenary talk by Dr. Stan Lynch of the Defence Science and Technology Organization, Australia, who reviewed the potential of FrictionStir Processing in surface engineering notably to improve the fatigue and corrosion resistance of cast propellers for ships, to eliminate porosity and increase ductility in cast Al alloy, and, using portable equipment, to eliminate cracks in structures which have occurred in service. Other plenary talks covered energy conservation and renewable energy, global HTSE research trends, thermal spraying, new trends in carburizing, plasma nitriding and Thai government policy on energy efficiency. Warm welcome for EFhtse delegates at the new Thai Parkerizing plant in Rayong Heat treatment & surface engineering (HTSE) together with foundry, forming & fabricating, and machining are recognized by government organizations in Thailand as key supporting industries for manufacturing Following the technical sessions a day tour was arranged for delegates to visit the Thai Tohken Thermo plant in Chonburi and a new Thai Parkerizing plant on the Hemaraj Eastern Seaboard Industrial Estate in Rayong. In education and training for Thai industry both companies lead by example. In 2011 Thai Tohken opened a new purpose built training and technical centre for both operator and supervisor training running courses with co-operation from Suranaree University. Around 120 workers have also spent time at the Thai Tohken plants in Japan for on-the-job training. Thai Parkerizing provides scholarships to secondary and high school students and to university students at 9 public universities. The company also supports Thai R&D via research funding as the Thai Parkerizing Chair Professor Award and via Best Paper Awards at Thai conferences. Following on from EFhtse 2012, on 28th June some 160 Thai delegates attended a one-day seminar for industry on “Heat Treatment and Surface Engineering – Practical Improvements for Thai Industries” at the Chaophya Park Hotel in Bangkok. This was supported by the Ministry of Science and Technology and organized by MTEC, TMA, TFA, and the Thai-German Institute (TGI). Improved use of HTSE processes is a key part of a TGI based project on the Enhancement of Mould and Die Industry Competitiveness. With an emphasis on practical aspects the seminar covered the following topics which were considered to be relevant to the further development of Thai heat treatment: l “Residual Stress: Advantages, Disadvantages and Measurement Methods” Dr. P. Juijerm (Kasetsart University, Bangkok). l “Metallurgy in the Heat Treatment of Superalloys” Dr. P. Wangyao (Chulalongkorn University, Bangkok). l “Japan Quality Control and Manufacturing Technology in Heat Treatment” Dr. K. Funatani (IMST Institute, Japan). l “Quenching and Tempering of Steels – Methods, Applications and Practical Problems” Dr. T. Babul (Institute of Precision Mechanics, Poland). l “Heat Treatment in the Foundry Industry” Dr. J. Pearce (MTEC). Future development Over recent years the Thai cast metals industry has expanded with the rapid growth of the automotive and electronic/electrical sectors to concentrate on production of grey and ductile irons and Al alloy parts. Capacity is estimated at around one million tonnes per year of iron castings and some 100,000 tonnes of Al alloy, mainly as high pressure die-castings. There are also a number of well established jobbing ferrous foundries producing a range of steel castings including High Manganese and Stainless grades and alloy cast irons such as Ni-Hards, Ni-Resists and High Cr irons. Cu base alloys are also produced for water, architectural and lighting fittings. In general in the Thai SME foundries further progress is needed to improve process controls, to reduce energy waste and to pay more attention to environmental aspects particularly in the use chemical binders and coatings, fume and dust control, noise reduction and in the handling and disposal of slag and dross. The Ministry of Science & Technology is now operating under a new five year plan for 2012-2016 with the target of increasing the amount of R&D spending from the present 0.2% of GPD up to 2% by the end of this period, with the number of research workers rising from the present 8 per 10,000 of population to 15. The cast metals industry and engineering in general must find ways to tap into this extra funding. Potential areas for the future development in the Thai cast metals sector include: l The introduction of compacted graphite irons and austempered ductile iron into the automotive and general engineering sectors l Magnesium based castings for auto-parts and electronics l Improved production of corrosion and heat resisting steels l Special alloys for use in power generation such as Ni-base l Ti alloy castings. n References 1.J. Pearce: “Recent aluminium castings research in Thailand”. Metal Casting Technologies (2012) Vol.58 No.2 June pp.16-19. 2.J.T.H. Pearce et Al: “Global 21 part 17: Heat treatment and surface engineering in the metals industry in Thailand”. International Journal of Heat Treatment & Surface Engineering (2011) Vol.5 No.4 pp.140-144. METAL Casting Technologies September 2012 39 te c hn i c al f eature Ferritic ductile irons: a revisit By John Pearce Introduction T he mechanical properties of correctly treated Ductile Irons are directly related to the nature of their matrix structures. Depending on composition and casting variables these irons can be produced as-cast or in the heat treated condition with ferritic, ferrite + pearlite, pearlitic, acicular or austenitic matrix structures to give a wide range of strength and ductility values or to provide additional heat, corrosion or wear resistance. Irons with predominantly ferritic matrix structures normally provide tensile strength levels of at least 350-400 MPa with ductility of 15-22% combined with excellent machinability. A typical microstructure is shown in Figure 1. Factors influencing the production and structure & properties of ferritic ductile irons were determined via detailed research by Gilbert [1] and Barton [2] at BCIRA and by Cox [3, 4] at International Nickel over 40 years ago. Over the last 15 years research interest in ferritic ductile irons has been renewed particularly with respect to the following applications: l Replacing conventional Grade 500/7, which has a mixed ferrite + pearlite matrix, by a fully ferritic iron giving equivalent mechanical performance but with improved, more consistent machinability [5, 6] l Producing castings for turbines to generate energy by wind power [7, 8] l Improving the performance of exhaust manifolds and turbocharger housings for vehicles using Si-Mo irons [9, 10] l Production of weight saving thin walled castings for vehicle components [11, 12] This short review revisits ferritic ductile irons to outline some of these developments. Producing ferritic matrix structures Most Ductile Iron (DI) castings used to be heat treated to achieve the required matrix structures [13]. The use of pure charge materials (pure pig irons and Sorelmetal) together with improvements in nodularisation and inoculation treatments Fig 1. Microstructure of ferritic ductile iron produced by annealing [13]. now allows most ferritic grades to be produced as-cast without the need for annealing. Impure pig irons and steel scrap contain pearlite forming elements (e.g. Sb, As, Sn, V, Mo, Mo, Mn, Cu, and Ni) such that their use must be limited. Inoculation must encourage high nodule numbers which firstly reduce the severity of any cell boundary segregation of P and carbide forming elements, and secondly decrease the diffusion distances for C to deposit onto the nodules during solid state cooling. The lower the nodule number the greater is the tendency for intercellular pearlite to form especially if the Mn content is above 0.2% or impurity elements are not limited [2]. In as-cast ferritic DI the Mn level must be below 0.2% but can be up to 0.5% if castings are to be annealed. Intercellular segregation effects become more severe as casting section size increases so control of impurity levels and especially Mn, Cr and P contents become even more important when larger castings are to be produced [14, 15]. Depending on charge materials to produce a ferritic matrix as cast the Si level may need to be increased from 2.22.4% to 2.7-2.8%. Si promotes ferrite formation as austenite decomposes during cooling through the critical temperature Intercellular segregation effects become more severe as casting section size increases so control of impurity levels and especially Mn, Cr and P contents become even more important when larger castings are to be produced. 40 www.metals.rala.com.au Fig 2. The effect of %Si content on Charpy V notch impact properties of ferrite ductile irons [1]. range. Unfortunately Si also reduces toughness raising the ductile to brittle fracture transition temperature (Figure 2) hence the %Si level must be carefully controlled if the low temperature impact property specifications at -20 and -40oC in ISO 1083:2004 and ASTM A874-98(2009) etc. are to be satisfied [1, 16-19]. To achieve the required low temperature toughness the final Si content is normally limited to 2.25% together with Mn (<0.2%), Cr (<0.5%) and P (<0.02%) and the castings must normally be annealed [18, 19]. Annealing involves heating the castings to 850-920oC and holding for 2-10 hours followed by controlled furnace cooling between 800 and 650oC or furnace cooling to 680-720oC and then holding for 4-20 hours. Sub-critical annealing is not suitable since it gives insufficient homogenization and also produces a sub-grain structure in the ferrite matrix which is detrimental to toughness [17, 18]. With regard to impact properties inoculation should give sufficiently high nodule numbers needed to minimise intercellular carbides but it should not be excessive since the graphite nodules assist fracture lowering impact strength in the ductile range [19]. The addition of Ni increases the proof and tensile strengths of annealed ferritic DI reducing elongation, but it can provide a better combination of strength and ductility than that obtainable with as-cast ferrite & annealed ferrite-pearlite matrix irons (Figure 3). The addition of up to 1%Ni is recommended to meet proof and tensile strength requirements in the reduced Si level grades designed for low temperature toughness [3, 4, 18-20]. Recent work [21] has confirmed the beneficial effect of Ni on strength and on toughness in the low temperature range. Fig 3. Beneficial effect of Ni on 0.1% proof stress-%elongation relationship in annealed ductile irons [3, 20]. Belec Spectrometers Vario Lab n Options for many base & element channel selections! n Many configurations including single or dual stands, probe & stand. n Available as Bench top or with lower cabinet configuration. Compact PORT n Portable spectrometer. n Available with Argon probe for accurate measurement of elements including C, S, P. n Many options & extras including a quick change-over spark stand. G & C Instrument Services Pty Ltd Phone: (02) 4981 7255 Email: [email protected] Talk with a Belec representative at the AFI Conference Stand 12 METAL Casting Technologies September 2012 41 te c hn i c al f eature turbines are up to 120m in height and weigh 450 tonnes. From European experience it is reported by Roedter [7, 24] that the average weight of DI cast components needed to generate 1MW is around 13.5 tonnes. The parts include rotor hubs, shafts, and nacelle frames etc. The targets already set for renewable power in Europe and China suggest that wind power generation will continue to increase by 25% from 2010 to 2020, and then by another 25% between 2020 and 2030 – a large market for large ferritic DI castings. This has stimulated renewed interest in developing improved understanding of the production and metallurgy of these irons and on their service performance [2527]. Experience and problems encountered in producing large section DI and the avoidance of structural and other defects are well reported in papers published in the 60s and 70s [e.g. 2, 15, 28]. Together with more recent reports [e.g. 18, 29] these can provide invaluable information for foundries wishing to satisfy the high technical demands of this market. Heat resistant ferritic ductile irons Fig 4. Charpy V notch impact properties for higher Si ferritic ductile irons compared with conventional grades 400/15 (ferritic) and 500/7 (ferrite +pearlite) [6, 22]. Substitution for ferrite-pearlite Grade ISO 1083/500-7 In the 500/7 (FCD 50) intermediate grade the matrix structure can vary from near fully ferritic to near fully pearlite in different sections of the same casting, and there is also similar variation between castings situated at different positions in multi-cavity moulds. This variation not only gives rise to variations in mechanical properties within and between castings but also causes considerable difficulties in machining. Detailed studies in Sweden have shown that conventional 500/7 can be safely replaced by an as-cast fully ferritic iron with %Si levels of 3.63.85% for components such as front axle housings for load dumpers and front wheel hubs for trucks [5, 6]. Mechanical testing [22] has revealed that the Si strengthened fully ferritic material is slightly tougher that ferritic-pearlitic iron having the Fig 5. Form of “chunky” graphite in heavy section ductile iron [2] same tensile strength (Figure 4) and that fatigue properties are equivalent. The 3.7%Si grade is now standardized as ISO 1083/ JS/500/10; one example of its use is in hydraulic rotators where it has given 75% reduction in hardness variation within castings resulting in a 30% increase in cutting tool life [23]. Heavy castings for wind power The demand for alternative green sources of energy has lead to the rapid development of the wind power industry, notably in Europe, together with a demand for reliable and safe performance from cast components in Grade 400/18LT ferritic DI [7, 8, 24-26]. The LT denotes the requirement for the iron to satisfy an average V-notched Charpy value of 12J when tested at -20oC. Low temperature toughness is critical in wind turbines located in N. Europe, China, N. America, etc and offshore to cope with exposure to severe weather. Large The demand for alternative green sources of energy has lead to the rapid development of the wind power industry, notably in Europe, together with a demand for reliable and safe performance from cast components in Grade 400/18LT ferritic DI. 42 www.metals.rala.com.au Si-Mo ferritic DI can withstand maximum service temperatures of up to 950oC. Increasing the Si content in ductile irons to between 4-6% Si raises the ferrite to austenite transformation temperature producing a stable ferritic matrix which is resistant to growth and oxidation. Although Mo is a strong carbide former it is added to these irons in amounts up to 2% to improve high temperature strength and thermal fatigue properties and to provide sufficient creep resistance over long periods of service in castings used in furnaces and for vehicle parts subject to thermal cycling such as exhaust manifolds and turbo-charger bodies [9, 10]. The C content is reduced to around 3% to improve mechanical properties and to minimise problems with fluidity during filling thin sections. Some recent work [30] has focused on the prevention of “chunky” graphite in castings (Figure 5) since these irons, as well as austenitic DI, appear to be more sensitive to the presence of rare earth elements in smaller sections than unalloyed irons. In normal ferritic DI grades chunky graphite can be a problem in heavy sections and must be avoided in the wind power castings mentioned above. The high Si level in Si-Mo iron reduces ductility and toughness but this does not normally cause problems in assembly, maintenance or service. The irons can be used as-cast but heat treatment may be required to decompose or spherodise intercellular carbides especially if up to 2%Cr is included in the composition. The chemical compositions and microstructures of Si-Mo DI intended for high temperature service automobiles are covered by the US SAE standard J2582:2004. These irons are not as heat resistant as the austenitic 35%Ni-5%Si-2%Cr DI grade or austenitic stainless steel but they offer a more economic option for manufacturers. problems encountered in producing large section DI and the avoidance of structural and other defects are well reported in papers published in the 60s and 70s. Thin wall ductile iron castings Progressive improvements in pre-conditioning of melts and in subsequent nodularisation and inoculation treatments can enable the production of ductile irons free from eutectic carbides in section sizes down to 2.5mm thus providing the opportunity for weight saving in vehicle parts [31]. Progress in this area has followed on from the US Dept. of Energy initiative Belec Spectrometers “IN-SPECT” BENCHTOP n Extensive channel options n Excellent precision n Latest 5GSO System n Easy to use n Compact construction G & C Instrument Services Pty Ltd Phone: (02) 4981 7255 Email: [email protected] Talk with a Belec representative at the AFI Conference Stand 12 METAL Casting Technologies September 2012 43 te c hn i c al f eature which began in 1998 to develop capability for the manufacture of lightweight iron castings [11]. Since then considerable data has been obtained on how microstructures and mechanical properties of thin wall castings can compare favorably with thicker sections [e.g. 11, 12, 32]. Machined thin wall (2.5-6mm) plates have shown equivalent or higher properties compared to usual (12.7mm) sections but without machining the thin plates can show inferior and variable properties if the surface finish is rougher than a threshold level [11, 12]. To produce thin section castings moulds with greater dimensional accuracy are needed and the mould surface and pouring & filling conditions have to be more closely controlled with extra attention to the design of the gating system [33]. To produce ferritic matrix thin sections a high degree of nucleation is needed to ensure a high nodule number and to avoid inverse chill at the later stages of solidification [34, 35]. Ductile Iron is now 64 years old but engineers still need it and thanks to continued feeding by R&D efforts it seems to be getting younger all the time. n CASTvac —an efficient vacuum technology for HPDC with low maintenance cost TM Laihua Wang1, 2, a, Gary Savage1, b CAST CRC Limited, CSIRO Process Science and Engineering. 2 Wanda Technology Pty Ltd, Melbourne, Australia a) [email protected] b) [email protected] 1 References: G.N.J. Gilbert: “Review of recent work on the mechanical properties of nodular cast iron”. Foundry Trade Journal, 1966, Vol.120, May 19, pp.667672; May 26, pp.713-724. R. Barton: “Factors influencing the production of as-cast ferritic nodular (SG) iron”. BCIRA Journal, 1970, Vol.18, pp.534-541. G.J. Cox & J.D. O’Loughlin: Foundry Trade Journal, 1971, Vol. 131, p.833. G.J. Cox: “The impact properties of different types of ferritic spheroidal graphite cast iron”. British Foundryman, 1973, Vol.66, pp. L.E. Bjorkegren & K. Hamberg: “Ductile iron with better machinability compared to conventional grades”. Foundryman, 1998, Vol. 91, pp.386-391. L.E. Bjorkegren & K. Hamberg: “Silicon alloyed ductile iron with excellent ductility and machinability”. Foundryman, 2001, Vol. 94, pp.42-48. H. Roedter & M. Gagne: “Ductile Iron for Heavy Section Wind Mill Castings: A European Experience”. Proceedings of 2003 Keith Mills Symposium on Ductile Cast Iron, October 2003, South California, USA, 7pp. I. Riposan et Al: “Performance of heavy ductile iron castings for windmills” China Foundry, 2010, May, Vol.7, pp.163-170. H. Roedter: “4-6% Silicon Ductile Irons for High Temperature Service”. Suggestions for Ductile Iron Production No. 102, RTIT publication, 2006, March, 2pp. D. Li et Al: “Solidification Behaviour, Microstructure, Mechanical Properties, Hot Oxidation and Thermal Fatigue resistance of High Silicon SiMo Nodular Cast Irons”. Paper 2004-01-0792, SAE 2004 World Congress, 2004, March, Detroit, US. L.P. Dix et Al: “Static Mechanical Properties of Ferritic and Pearlitic Lightweight Ductile Iron Castings”. AFS Transactions, 2003, Vol.111, pp.11491164. D.M. Stefanescu et Al: “Study of the Effect of Some Process Variables on the Surface Roughness and the Tensile Properties of Thin Wall Ductile iron Castings”. AFS Transactions, 2007, Vol.115, pp.637-646. J. Pearce: “Heat Treatment of Ductile Irons”. Metal Casting Technologies, 2003, Vol.49, March, pp.22-26. G. Jolly & G.N.J. Gilbert: “Segregation in nodular iron and its influence on mechanical properties”. British Foundryman, 1967, Vol.60, pp.79-92. R. Barton: “Control of microstructure and mechanical properties in large section as-cast nodular iron castings”. BCIRA Journal, 1976, Vol.20, pp.176186. “Effects of silicon in nodular (SG) iron”. BCIRA Broadsheet 211-1, BCIRA 1982, 4pp. “Factors influencing the ductile or brittle behaviour of nodular irons”. BCIRA Broadsheet 212, BCIRA 1982, 4pp. M.J. Fallon: “Experiences in the Manufacture of Ductile Irons”. The Foundryman, 1995, vol.88, pp.308-318. R.D. Forrest; “Meeting low temperature property specifications in ductile 44 www.metals.rala.com.au iron”. Suggestions for Ductile iron Production No. 82, RTIT publication, 2006, March, 2pp. G.J. Cox: “The effect of composition on the microstructures and mechanical properties of as-cast and heat treated SG iron”. Giesserei 1983, Vol.50, pp.9398. J. Lacaze et Al: “Influence of 1% addition of Ni on structural and mechanical properties of ferritic ductile irons” Materials Science & Technology, 2012, Vol.28, 603-608. L.E. Bjorkegren & K. Hamberg: “Silicon Alloyed Ductile Iron with Excellent Ductility and Machinability”. Proceedings of 2003 Keith Mills Symposium on Ductile Cast Iron, October 2003, South California, USA, pp.70-80. R. Larker. “Solution strengthened ferritic ductile iron ISO 1083/JS/500-10 provides superior consistent properties in hydraulic rotators”. China Foundry, 2009, Vol. 6, November, pp.343-351. H. Roedter: “Powerful Ductile Iron Castings for Wind Energy Applications”. Suggestions for Ductile iron Production No. 110, RTIT publication, 2006, March, 3pp. I. Riposan et Al. “Influencing factors on as-cast and heat treated 400-18 ductile iron grade characteristics”. China Foundry 2007 Vol.4 pp300-303. C. Labrecque & P.M. Cabanne. “Low temperature impact strength of heavy section ductile iron castings: effects of microstructure and chemical composition”. China Foundry 2011 Vol.8 February pp. 66-73. J. Sertucha et Al: “Effect of alloying on mechanical properties of as cast ferritic nodular cast irons”. Materials Science & Technology 2012 Vol.28 pp.184-191. R. Barton: “Experience in the prevention of defects in nodular iron castings”. BCIRA Journal, 1968, Vol.16, pp.554-567. P.M. Cabanne et Al: “Production of Heavy and Thick Ductile Iron Castings (Process Review and Potential Defects)”. Indian Foundry Journal, 2010, Vol.56, pp.33-42. R. Logan et Al: “An investigation of chunky graphite defects in SiMo iron used for high temperature applications”. Indian Foundry Journal, 2011, Vol.57, pp.41-48. F.R. Juretzko et Al: “Precondition of ductile Iron Melts for Light Weight Castings- Effect on Mechanical Properties and Microstructure”. AFS Transactions, 2004, Vol.112, pp. 773-785. A. Javaid et Al: “Effect of microstructure on the Mechanical Properties of Thin-Wall Ductile Iron Castings”. AFS Transactions, 2001, Vol.109, pp. 10971114. P. David et Al: “Gating system design to cast thin wall ductile iron plates”. Foundry Trade Journal, 2009, Vol. 182, pp.119-126. A. Javaid et Al: “Critical conditions for obtaining carbide-free microstructure in thin- wall ductile irons”. AFS Transactions, 2002, Vol. 110, pp. 889-898. K.M. Pederson & N.S. Tiedje: “Undercooling, nodule count and carbides in thin walled ductile cast iron”. Foundry trade Journal, 2009, Vol. 182, pp. 54-57. Abstract V acuum technology is considered to be the effective method to remove air from the die cavity in the high pressure die casting (HPDC) process. The key component of the technology is the vacuum valve. It opens to apply vacuum to the cavity, and closes to prevent metal entering the vacuum system. The most popular method currently used in the industry is the mechanical valve. Its major shortcoming is its reliability, which causes machine downtime due to metal blockage when the valve fails to shut off. A new type of vacuum valve, called CASTvacTM, has been developed in Australia under the CAST CRC program with a research team from CSIRO. The technology is now licensed to Wanda Technology. The nature of CASTvacTM is a threedimensional chill block which consists of no moving parts. It is therefore as robust as a conventional two-dimensional chill block, and never fails to terminate the liquid metal. It has a large venting area which provides a high evacuating efficiency compatible to the mechanical valve. It fits in the same die pocket as the popular mechanical valve and requires a low projected area. CASTvacTM has been implemented in an industrial plant for six years. The benefit by reducing the machine downtime has been demonstrated. A cost model has been developed and is presented in this paper. This model indicates machine downtime and valve service were the major cost sources. Introduction Vacuum technology has existed in the die casting industry for more than half a century. The technology has evolved from a shut-off valve with the assistance of a simple PLC control, to advanced mechanical valves with sophisticated logical controls, which are currently in wide use. The benefit of using vacuum to improve the casting quality is straightforward and has been proven in the industry for some time. However, its adoption is still limited. The barrier may be due to a number of factors including ease of use, cost, and willingness of customers to accept castings with limited porosity. The early vacuum system consisted of a shut-off valve with a simple PLC control actuated by the plunger position. To prevent metal ingress into the vacuum line, the valve was normally shut off before the change-over from the first stage to the second stage of plunger speed. When the vacuum source was cut off, air would quickly be drawn back through the gaps into the cavity. Badal et al reported the leak rate could be as high as 230mbar/sec for the tested die1. This leak reduced the level of vacuum previously generated in the cavity; a further limitation was the gas would have no chance to be expelled as the valve was closed. Since the early 1980s, more advanced vacuum valves have been developed and are commercially available, such as gasfree (GF)2, 3. These types of valves are shut off mechanically by the metal impact or by sensing the metal front during the The technology has evolved from a shut-off valve with the assistance of a simple PLC control, to advanced mechanical valves with sophisticated logical controls, which are currently in wide use. METAL Casting Technologies September 2012 45 te c hn i c al f eature Fig. 1: The CASTvacTM fixed and moving half valves. Fig. 2: CASTvacTM in semi-closed position. Fig. 3: Comparison of the evacuation efficiency of CASTvacTM with the popular mechanical valve and the conventional chill vent using the same pocket width as CASTvacTM. very last stages of cavity filling. The mechanical type of valve is highly efficient since it extracts air until the end of the cavity fill, but its weakness is in the complexity of the mechanical shut off mechanism, which can be prone to blockage in the harsh die casting environment. Conventional chill vents are also commonly used with vacuum, but their weakness is the small evacuation area which restricts the rate of air evacuation. Typically the gap in the washboard area is less than 1mm in depth and about 100mm in width. To increase its evacuation area, the chill vent has to be made wider. This will increase the die projected area, and as a consequence increase the risk of die flash. The simple vacuum system and the conventional chill vent used with vacuum offer low evacuation efficiency. Considering the additional cost and maintenance, die casters have limited incentive to adopt these vacuum systems. The mechanical valves offer lower reliability and productivity due to unpredictable machine stoppages. remain small in order to terminate the flowing molten metal. In addition, to avoid die modification, our industry partners specified the new valve would need to be compatible with the existing die pocket dimensions for the mechanical valve they were already using. An innovative concept was developed by constructing a folded washboard with its major chill faces at a right angle to the die parting face, instead of parallel to the parting face of the conventional chill vent. This would allow the new valve to have nearly four times the venting area of the conventional chill vent using the same die footprint. Such an increased venting area enables vacuum performance to meet that achieved by mechanical valves. This innovation has been patent protected. The product from this innovation was named CASTvac™, as it was developed by CAST CRC Limited. A CASTvac™ valve is illustrated in Fig. 1 (the two halves side-by-side) and Figure 2 (two halves semi-closed). It can be imagined that a continuous venting pathway will be formed when the two halves are engaged. An additional benefit of CASTvacTM is that the venting area is increased without sacrificing the die projected area which is an important resource for the die designer. This is a result of the forces generated from the metal pressure acting on the major faces of the washboard, which are directed at right angles to the die parting face, counteracting each other. For instance, the machine clamping force required to hold the same venting area will be reduced from 360 tonnes for a conventional chill vent to 87 tonnes for a typical size of CASTvacTM valve (calculated from a metal pressure 80MPa and the available venting area). The valve has been implemented in production for six years and made over one million shots on 800-tonne to 2500-tonne HPDC machines in a die casting plant. After six years’ service the first valve is still operating in good working condition. There have been no blockages reported on this, or the other valves, since put into operation. CASTvac™ is produced in three sizes—small, medium, and large—to match the equivalent sizes of the most popular mechanical valve currently on the market. Figures 1 and 2 above show a medium-sized CASTvac™ with TiN surface coating. Its evacuation performance, which was an important aspect of the design goal, was measured with a bench test and is illustrated in Figure 3. It compares CASTvac™ with the equivalent-sized mechanical valve and a conventional chill vent. As can be seen, the evacuation efficiency of CASTvacTM is compatible with the mechanical valve, and is much better than the conventional chill vent using the same pocket width as CASTvacTM. CASTvacTM valve contains a built-in ejection mechanism, which eliminates the requirement for die modification for ejector pins, and facilitates the valve change. It also contains internal cooling, and a built-in air blast for self-cleaning. CASTvacTM The development of a new vacuum valve was an outcome of a challenge posed by industry to have a vacuum valve that was immune from the blockages they experienced with their mechanical shut-off valves. The aim of the development was therefore to design and construct a valve which was reliable and whose evacuation efficiency could match the mechanical valve. To achieve this reliability, an ideal design would be for a valve with no moving parts. The mechanism of the conventional chill vent was naturally considered (a so-called ‘valveless’ approach). However, increasing the venting area for a conventional chill vent can only be achieved by extending the width of the zigzag washboard since the gap size has to 46 www.metals.rala.com.au The cost model of using vacuum-assisted die casting As suggested by Robbins4, “to calculate the approximate true cost of downtime, simply subtract the actual cost of the alloy used per hour from the selling price of the castings produced per hour”. Using this method, the cost of the machine downtime can be estimated to be $US300 per hour on average for industrialised countries. All data used for this calculation for a generic die casting plant are listed in Table 1. Readers can use their own data as an input for the calculation. Fig. 4: The approximate cost of using mechanical valve and CASTvacTM ($US/annum/machine) Cost of machine time 300 $US/hour Cost of labour in tool room 80 $US/hour Time for changing valves during machine stop 30 minutes/ change Time for machine warm-up 15 minutes Warm-up shots per stoppage 6 shots 0.10 $US/kg 10 kg Cost of re-melting alloy Weight of a full shot Table 1: Basic data used for the cost model The $US300/hour cost of machine downtime shown in Table 1 already includes operator costs. A stoppage of 30 minutes for the valve change-over, for example, plus 15 minutes for the machine warm-ups will cost $US225. The cost to remelt 60kg of aluminium is small (~$US6). Therefore, each machine stoppage will cost approximately $US231. It is not uncommon for a mechanical valve to be blocked once per day. For a die casting plant running six days a week and 50 weeks a year, the downtime will cost $US69,300. If the stoppage is reduced to once per week, the cost will be reduced to $US11,550, representing a direct saving of $US57,750 per machine per year just from fewer machine stoppages. It has been proven in a die casting plant that this is achievable by replacing the mechanical valve with CASTvacTM valve. Another significant component of the cost is the service of the valves. This again relates to valve blockage. It is estimated that one hour is required for the toolmaker to clean the valve and the vacuum line, and then recondition the valve back to METAL Casting Technologies September 2012 47 te c hn i c al f eature an operational condition. This will cost $US24,000 per year for the mechanical valve. Changing to CASTvacM will save $US16,000, based on the same assumption above. The other sources of costs include spare parts for the valve, repair (refurbishing) of the valve, and the capital cost to purchase the valve. When all of the costs are added together, it will cost $US109,233/annum/machine to run mechanical valves, compared to $US28,283 for CASTvacM. This has been plotted in Figure 4. The direct cost saving will be approximately $US81,000. The same data are plotted in a pie chart and shown in Figure 5. This shows the major saving, by using CASTvacTM, comes from improved machine downtime rates. The second largest contribution to the saving is the reduction of service time, which is related to valve blockage. The valve cost is relatively small compared with the operational costs. Fig. 5: The cost saving distributions. Conclusion The technical and cost benefits in using vacuum-assisted die casting have been discussed in this paper. The additional cost associated with the operation of the valve is an issue to many die casters. The cost model developed in this paper has indicated that machine downtime is the biggest cost component of using a conventional mechanical vacuum valve. CASTvacTM is an efficient and reliable vacuum valve that will significantly reduce the operational cost of vacuum die casting. Gary Savage BAppSc (Metallurgy) (UniSA), GradDip (Computing) (Monash) Gary Savage is the Program Manager for Casting Technology at CAST, and Stream Leader for Light Weighting and Durability at the CSIRO’s Future Manufacturing Flagship. His responsibilities include providing research leadership and project management in the fields of die casting and continuous casting. Gary’s primary research interests focus on high pressure die casting of aluminium and magnesium alloys. He has a strong record of transferring research outcomes into industry through adoption, licenses, and commercialisation. Gary has been with CSIRO since 1999. Prior to this, he spent 10 years at BHP Research with a focus on rolling mill rolls, thermal fatigue, wear, and hot rolling technologies. 48 www.metals.rala.com.au References 1. A. Badal, Y. Longa, P. Hairy, “Effectiveness of the Vacuum Technique in Pressure Die Casting” in Die Casting Engineer, July 2001, pp 54-60. 2. A. Wolodkowicz, “Vacuum Die Casting: Its Benefits and Guidelines”, NADCA 16th International Die Casting Congress and Exposition, 30 September–3 October 1991, paper T91-071. 3. L. Wang, M. Gershenzon, V. Nguyen, G. Savage, “An Innovative Device for Vacuum and Air Venting”, CastExpo’05, St Louis, Missouri, 16–19 April 2005, paper T05-073. 4. P. Robbins, http://www.castool.com/blog/2009/10/for-survival-cutdowntime/ Laihua Wang BAppSc (Eng.) (Beijing Univ Sc &Tech), PhD (Central Iron & Steel Research Institute, Beijing) Laihua Wang is a senior research scientist in the Casting Technology Group of CSIRO’s Process Science and Engineering division. He graduated from Beijing University of Science and Technology in Bachelor degree in 1982, and attained his PhD in 1990. He has worked in steelmaking and die casting research for the past 25 years, specialising in fluid flow and solidification modelling, and technology development. He has led a number of research and development projects, and developed CASTvacTM, an innovative vacuum valve for the high pressure die casting process. He has authored or co-authored more than 20 papers in the field. Use of PoDFA technique for rapid melt cleanliness assessment: a practical shop-floor tool for production of aluminum casting By Thawatchai Kantisitthiporn and Julathep Kajornchaiyakul Abstract T he present study demonstrates how the PoDFA (Porous Disc Filtration Apparatus) technique can be enhanced for rapid melt cleanliness assessment. This is based on an additional analysis of data in terms of weight of the filtered aluminum versus time duration pertaining to the filtration. A series of PoDFA tests on an aluminum casting alloy were conducted. During each PoDFA test corresponding data set of filtration weight and time were recorded and analyzed. The longer the time duration required for one kilogram of the aluminum to flow through the filter suggested that the liquid metal exhibited lesser cleanliness. The analysis was in good agreement with metallographic investigation based on standard PoDFA practice. The analysis yields characteristic data that can be made useful as a practical shop-floor tool. 1. Introduction Liquid metal quality is one of the important factors influencing final quality of cast aluminum alloy. Inclusions in molten metal can degrade castability, formability, machinability, surface finishing and mechanical properties. Several techniques may be used to evaluate cleanliness of liquid aluminum, for example, K-Mold, LAIS, LiMCA, ALSPEK, ultrasonic techniques, and filtration techniques [1, 2]. A rapid or real-time method for practical assessment in the foundry is preferrable. Among these techniques, the Prefil Footprinter is claimed as the only method that can provide both real-time assessment via a characteristic curve of filtrated weight versus filtation time as well as metallographic analysis for indentifying inclusions [3]. Prefill Footprinter (developed by N-Tech) and PoDFA (Porous Disc Filtration Apparatus; developed by Alcan) are based on filtration techniques which employ different principles for melt cleaniness assessment. The Prefill Footprinter can be used for evaluating melt cleanliness via both real-time and metallographic analysis. The PoDFA is based only on metallographic examination. Figure 1 shows principle of the Prefill Footprinter technique. The liquid aluminium is forced through a fine filter by pressurization and the progression of filtrated weight versus filtration time recorded for real-time assessment [4, 5]. Flow behavior based on such data, i.e. filtrated weight vs. filtration time, may be analysed further by first and second derivations as presented by X. Cao [3, 6-9]. On the other hand, the PoDFA technique is based on a vacuum method as shown in Figure 2 [5, 10-14]. Liquid aluminium is encouraged to flow through a fine filter by reduced pressure but there is no characteristic data recording for real-time assessessment. Both types of filtration technique are able to indentify and quantify inclusions in the cake solidified on-top of the filter using suitable metallographic examination. Liquid aluminium is encouraged to flow through a fine filter by reduced pressure but there is no characteristic data recording for real-time assessessment. METAL Casting Technologies September 2012 49 te c hn i c al f eature Fig 1. Schematic Showing Principle of Prefill Footprinter Technique. Fig 2. Schematic Showing Principle of PoDFA Technique. One objective of this present work is to study feasibility of using the PoDFA technique as a practical real-time assessement without any modification of the standard apparatus. Data recording by a stopwatch was used for evaluating melt cleanliness of an aluminium alloy. Using ADC12, a high pressure die casting Al alloy, as test material characteristic curves were obtained by recording the progession of filtration time at each 0.05 kilogram filtered weight of liquid metal by standard PoDFA practice. These curves were analyzed for comparison with the results of metallographic examination of the residual filter cake. technique. Each sample whose weight was about 2 kilogram was charged into a SiC crucible and heated up to 8000C. Each molten sample was poured into a preheated PoDFA crucible fitted with a standard alumina filter containing 30 pores per inch (ppi). The pouring was controlled with careful tilting in order to avoid turbulence and additional oxide formation. At 6850C a vacuum was applied to initiate flow through the filter. Progession of filtration time was recorded by a stopwatch at each 0.05 kilogram of filtrated weight of the melt. Plotted data of corresponding characteristic flow curves were then made for real-time assessment. Testpieces in form of the aluminium cake solidified on-top of the filter at the end of testing were subjected to metallographic examimnation. Inclusion type and content were investigated. The cakes were prepared in accordance with the PoDFA test standard practice. Complete details of the PoDFA test and analysis procedures are available [10, 12-13]. Total inclusion concentration area per kilogram was calculated as follows: 2. Experimental details Table 1 shows the standard composition of the aluminium alloy used in this study. Two samples of the alloy were taken from a die casting foundry. The samples were subjected to remelting using an electric resistance furnace prior to melt cleanliness assessment by the PoDFA Total Inclusion (mm2/kg) = Mean Measured Residue Area (mm2) x Inclusion Area Fraction Filtered Metal Mass (kg) Alloy ADC12 Fig 3. Filtration time versus filtrate weight curves of PoDFA technique Alloying Elements (wt. %) Cu Mg Si Fe Mn Ni Zn Cr Sn Ti Al 1.5-3.5 0.3 max 9.6-12 1.3 max 0.5 max 0.5 max 1.0 max - 0.3 max - balanced Table 1. Standard composition of the aluminum alloy used in the experiment. Sample No. Inclusion Concentration (mm2/kg) Aluminium Oxide Films Concentration (count/kg) Type of Inclusions in Cake Area ADC12 No.01 32 0.88 MgO, Oxide Film, Spinel, Al4C3B ADC12 No.02 40 2.81 Spinel Crystal, Al4C3B, Oxide Film Table 2. Summary of oxide and inclusions content by metallographic analysis of PoDFA technique. 50 www.metals.rala.com.au 3. Results and discussion Figure 3 is characteristics of the test data from the application of PoDFA technique. The figure shows the progression of filtration time versus filtrated weight of each melt sample. There are clear differences in filtration time between the two samples based on an equal filtered weight. The filtration time of sample ADC12 No.2 appears to increase at a higher rate than that of ADC12 No.1 after the filtrated weigh reached about 0.5 kg. Based on this characteristic curve, ADC12 No.02 is expected be less clean compared to ADC12 No.01. This is in good agreement with metallographic examination following the standard PoDFA technique as summarized in Table 2. The amount of oxides and other inclusions content are 32 and 40 counts/ kg, and 0.88 and 2.81 mm2/kg for ADC12 No.01 and ADC12 No.02, respectively. The nature and distribution of the oxides and inclusions as examined by optical microscopy are illustrated in Figure 4. In addition to the amount of oxides and inclusions content, the decrease in fluidity of the melt sample due to decreasing melt temperature during the test is another factor affecting the filtration time. Thus it is important to closely control the melt temperature when performing this test. Other factors such as vacuum pressure, variation in chemical composition, and so on, that may affect the characteristic test data, must also be considered. Fig 4a. Sample number 01. Fig 4b. Sample number 02. Figs 4a & 4b. Representative micrographs of the PoDFA samples showing oxide and inclusions in the cake area: (a) ADC12 No.01 and (b) ADC12 No.02. METAL Casting Technologies September 2012 51 Back to te c hn i c al f eature 4. Concluding remarks 1. This technique may be suitable for use as a “Go: No-Go” tool by comparing characteristic curves with a reference curve from the same alloy with acceptable cleanliness. 2. Testing conditions such as vacuum pressure, melting temperature and chemical composition of test samples and reference samples must be suitably controlled to avoid misleading results caused by variations in liquid aluminium fluidity. 3. The metallographic analysis based on the standard PoDFA technique is still necessary in order to determine types and amount of oxides and inclusions content. This is very important for proper improvement of melt treatment practices toward favorable cleanliness. Acknowledgements This present investigation was sponsored by Foundry Engineering Laboratory, National Metal and Materials Technology Center (MTEC). n B a s i c s [4] P.G. Enright et al: “Characterisation of Molten Metal Quality Using the Pressure Filtration Technique”. American Foundry Society, 2003. Balancing flow in vertically parted moulds [5] B. Prillhofer et al: “Nonmetallic Inclusions in The Secondary Aluminum Industry for The Production of Aerospace Alloys”. TMS, 2008, pp.603-608. J. F. Meredith, Casting Solutions Pty Ltd References [1] M.B. Djurdjevic et al: “Melt Quality Control at Aluminum Casting Plants”. Association of Metallurgical Engineers of Serbia (AMES), MJoM 2010 Vol.16 (1), pp.63-76. [2] D.V. Neff: “Evaluating Molten Metal Cleanliness for Producing High Integrity Aluminum Die Castings”. Die Casting Engineer, September 2004. [3] Xinjin Cao: “A New Analysis of Pressure Filtration Curves for Liquid Aluminum Alloys”. Scripta Materialia, 2005 Vol.52, pp.839–842. [6] X. Cao: “A New Indirect Method of Measuring The Contents of Solid Inclusions in Liquid Aluminium Alloys”. J Mater Sci, 2006 Vol.41, pp.4285–4292. [7] X. Cao: “Pressure Filtration Tests of Liquid Al–Si Cast Alloys: I. Flow Behaviour”. Materials Science and Engineering A, 2005 Vol.403, pp.101-111. [8] X. Cao: “Pressure Filtration Tests of Liquid Al–Si Cast Alloys: II. Best-Fitted Equations for Filtrate Weight versus Filtration Time Curves”. Materials Science and Engineering A, 2005 Vol.403, pp.94100. [9] X. Cao et al: “Examination and verification of the filtration mechanism of cake mode during the pressure filtration tests of liquid Al–Si cast alloys”. Materials Science and Engineering A, 2005 Vol.408, pp.234-242. [10] C. Stanica et al: “Aluminum Melt Cleanliness Performance Evaluation Using PoDFA Technology”. U.P.B. Sci. Bull. Series B, 2009 Vol.71, pp.107-114 [11] J. Wannasin et al” “Evaluation of Methods for Metal Cleanliness Assessment in Die Casting”. Journal of Materials Processing Technology, 2007 Vol.191, pp.242-246. [12] L.Liu et al: “Assessment of Melt Cleanliness in A356.2 Aluminium Casting Alloy Using the Porous Disc Filtration Apparatus Technique: Part I Inclusion Measurements”. Journal of Materials Science, 1997 Vol.32, pp.5901-5925. [13] L.Liu et al: “Assessment of Melt Cleanliness in A356.2 Aluminium Casting Alloy Using the Porous Disc Filtration Apparatus Technique: Part II Inclusion Analysis”. Journal of Materials Science, 1997 Vol.32, pp.5927-5944. [14] K. Haberl et al: “Characterization of the Melt Quality and Impurity Content of an LM25 Alloy”, Metallurgical and Materials Transactions B, 2009 Vol.40B, pp.812-821. Introduction T he production of castings using high speed vertically parted green sand moulding lines is well established in the foundry industry. The mould production rates of these machines are such that cycle times are often significantly less than 10 seconds. The total pouring time of a mould must be less than the machine cycle time, otherwise the pouring sequence would slow down the moulding machine. This requirement, and the vertical orientation of the mould usually necessitate high flow rates and stream velocities which in turn can lead to defects such as sand and slag inclusions and poor surface finish. Often, there are multiple pattern impressions arranged on different levels in the mould. In order to avoid excessively high flow rates and velocities it is desirable to balance the flow in the gating system so that castings on all levels are filling at the same time. Fig 1. Computer flow modelling of the above design confirms the flow rate at each level is reasonably uniform. Basic theory of gating design Mr. Thawatchai Khantisitthiporn e-mail : [email protected] Mr. Thawatchai Khantisitthiporn received his Bachelor and Master Degrees in Production Engineering and Metallurgical Engineering, respectively, from King Mongkut’s University of Technology Thonburi. His research thesis was based on a study of the mechanical metallurgy of wrought aluminium alloys for extrusion. He is a research engineer at MTEC, where his work involves processing of aluminium alloys with special emphasis on melt quality. Dr. Julathep Kajornchaiyakul email : [email protected] Dr. Julathep Kajornchaiyakul graduated in 1992 with a B.Eng. in Metallurgical Engineering from Chulalongkorn University, Bangkok, Thailand. He then undertook post-graduate studies in the US obtaining his M.Sc. in “Mechanical Metallurgy: 52 www.metals.rala.com.au Deformation Processing of Metals” from the Colorado School of Mines, Golden in 1996, and his Ph.D. in “Brittle Materials Manufacturing: Abrasive Machining & Processing” at University of Connecticut in Storrs in June 2000. Since September 2000 he has been working as a R&D Engineer at MTEC – the National Metal and Materials Technology Center under the National Science and Technology Development Agency (NSTDA) of Thailand. He is now a Principal Researcher in the Design & Engineering Research Unit at MTEC working mainly on Foundry Engineering and Aluminium Processing. He is also the Research Unit Director. He is the current Chairperson of the Aluminium Technology Forum of Thailand and an Advisory Board Committee Member of the Thai Foundry Association (former Thai Foundrymen’s Society). He is also a member of the Technical Committer of the Federation of Thai Industry’s Clustering Development Board relating to Machinery and Metallurgical Industries. The design of a gating system is often based on the requirement to meet a desired fill time. This may be based on experience with certain types of castings or it may also be based on a calculation involving the weight poured, the type of alloy and the critical section thickness to be poured or it may be determined by a machine cycle time. Having established a fill time, and given the weight and density of the casting, it is possible to calculate a volumetric flow rate (cubic inches/sec or cc/sec) using the formula: Fig 2. Mould Filling sequence at 10% filled. Flow rate = Volume/Fill Time Next, it is necessary consider how far the metal will fall when it is poured, which gives a metal velocity (using Newton’s laws of motion for a free-falling body). Knowing the velocity and the volumetric flow rate, the cross-sectional area of flow required can be calculated. It is then necessary to adjust this flow area for friction loss or shape factors, and finally to apportion this area so that there is the desired rate of flow at all of the various gates into the casting. It is also necessary to establish the “choke” point of the gating system, so that elements downstream (or upstream) from the choke can be oversized sufficiently to avoid excessive velocities and Fig 3. Mould Filling sequence at 30% filled. METAL Casting Technologies September 2012 53 maintain the choke (the point of maximum velocity) at the correct point in the gating system. This will generally ensure the correct rate of flow in all portions of the gating system, with liquid metal delivered at the required flow rate into the casting cavity. The next piece of information required for gating calculations is the height through which the metal will drop. In the case of horizontal gating, this is the effective height of the sprue (the vertical pipe down which the metal initially flows). For vertical gating, this may be the cumulative height from the top of the mould down to each component. In any case, the velocity of the metal after falling through this height can be calculated from a fairly simple relationship: V = √(2gH) Where: V = velocity, g = acceleration of gravity H = height through which the liquid has fallen This formula is based on basic Newtonian physics, and describes the velocity of any body free-falling in a gravitational field. Now, given the known velocity and the known volumetric flow rate, the cross-sectional area of flow of the liquid metal can be calculated simply from the following equation: Flow Area = Volumetric Flow Rate/Velocity This is the basic calculation which is used in gating design. When calculating flow areas, consideration must also be given to shape efficiencies and friction losses. According to research, for example, a square tapered sprue has an efficiency of around 74%; this means that an area calculated according to the above formula must be increased by a factor of (1/0.74) or 1.351 to account for the energy losses associated with flowing through this type of shape. Also, in flowing through runner systems, the liquid metal loses energy through friction with the channel walls. This friction loss, which is usually expressed as a percentage, must be compensated for by increasing the area of the downstream runner segments. Balancing flow rates on all levels As the flow rate at each level is proportional to the height the metal stream has fallen and the cross sectional area of the choke at that level, it follows that a countermeasure to variable flow rates at different levels in the mould is to proportion the choke cross sections at each level in such a way as to get similar flow rates through them. This approach requires the cross sectional area of the chokes to reduce as the height the metal stream drop increases which means the castings at the lowest level have the smallest choke area and this area increases at each level towards the upper most. The following formula provides a means of determining the appropriate choke area to achieve balanced flow rates at each level in the mould. A = G/t x d x f√(2gH) Where: A = Area of choke G = Weight of metal required to pass through choke t = Required fill time d = density of molten metal f = loss factor g = acceleration of gravity (9810 mm/s2) H = height through which the liquid has fallen This formula can be simplified if it is made specific for a particular alloy type where the density of the molten metal is known and the gravitational constant ignored. In which case the formula becomes: Cast Irons: - A = 1036 x G/t x f√H Copper Base: - A = 850 x G/t x f√H Aluminium Alloys: - A = 3100 x G/t x f√H In the above: A = mm2, G = kg t = seconds H = mm Practical example In the example shown in figure 1, there are 12 ductile iron castings arranged on 6 levels. Figures 2 – 6 show the Mould Filling sequence. The choke areas were calculated according to the above formula for cast irons. It can be seen the choke areas reduce from position 1 through to the lowest level at position 6. The plot in figure 7 shows the time (represented by colour) at which each part of the entire mould was filled. The relatively even banding of colour on each casting indicates a balanced flow rate. n References 1. Finite Solutions Inc literature PACIFIC RIM FOUNDRY SERVICES Buying and Selling Second Hand and Remanufactured Foundry Equipment Fig 4. Mould Filling sequence at 50% filled Fig 5. Mould Filling sequence at 75% filled Visit our new NEW Online Second Hand NEW Foundry Equipment store. Large Selection of equipment, competitive pricing. Check us out! www.pacrim.com.au We also do Foundry Equipment Asset Evaluations and Liquidations Pacific Rim Foundry Services – Pacific Rim Casting & Patternmaking Supplies Pacific Rim Safety Products – Pacific Rim Foundry Equipment Tel: 61 2 8883 2997 Fax: 61 2 8883 2895 Mobile 0419 433 238 Email:[email protected] Fig 6. Mould Filling sequence at 90% filled 54 www.metals.rala.com.au Fig 7. Colour representation of Fill Time. METAL Casting Technologies September 2012 55 EVENTS ALUMINIUM 2012 When: 9-11 October 2012 Where: Messe Düsseldorf - Germany Summary: ALUMINIUM is the world’s leading trade show and B2B-meeting place for the aluminium industry. It brings together high-calibre buyers, manufacturers, processors and suppliers. In Düsseldorf innovative products, the latest technology and services from primary aluminium production to semi-finished and finished products will be showcased. Web: http://www.aluminium-messe.com/ 43rd Australasian Conference & Exhibition: Advanced Foundry Innovation When: 21-24 October 2012 Where: Crown Plaza Coogee Beach – Coogee – Sydney, Australia Summary: The conference series is an effective peer discussion and practical forum bringing together Foundry Managers, CEOs, suppliers, technologists and operating personnel, in a social yet informative forum. The conference will include a large trade exhibition allowing suppliers to the industry an opportunity to exhibit their products and services, while giving foundry operators the opportunity to view and inspect the latest developments in the industry. For those that like to get out and about, we have site tours organised to Safety Expo at Homebush Bay, Nuclear Reactor (ANSTO) at Lucas Heights and the Sell & Parker Steel Shredding Facility. Web: http://afiaustralia.org/nsw Tube India International 2012 & Metallurgy India 2012 When: 30 Oct – 1 November 2012 Where: Bombay convention & Exhibition Centre Mumbai, India Summary: Also running concurrently is Energy efficiency and cost effective technologies for the metallurgical industry. Web: www.steelmetallurgy.com Email: [email protected] The 4th (2012) China (Shanghai) International Foundry Industry Exhibition When: 7-9 November 2012 Where: China Shanghai International Exhibition Center – Shanghai, China Summary: The exhibition will be attended by more than 50,000 professionals from more than 20 countries around the world. Web: http://www.foundry-expo.cn./ Email: [email protected] Indian Industrial Trade Fairs When: 21-24 November 2012 Where: India Expo Centre, Greater Noida - Delhi, India Summary: Five fairs CeMAT India, MDA India, Surface India, Industrial Automation India & Laser India. Email: [email protected] 56 www.metals.rala.com.au EVENTS EUROMOLD -World Fair for Moldmaking and Tooling, Design and Application Development When: 27-30 November 2012 Where: Frankfurt am Main, Exhibition Center – Frankfurt, Germany Summary: EuroMold is the world-wide leading trade fair for Moldmaking and Tooling, Design and Application Development and presents products and services, technology and impulses for tomorrow’s markets. The whole process chain “From Design to Prototyping to Series Production” is represented at EuroMold. A unique fair concept that closes the gap between industrial designers, product developers, producers, suppliers, and end-users. Web: http://www.euromold.com 4th International Foundry Congress & Exhibition (IFCE) 2012 When: 5-6 December 2012 Where: Pearl Continental Hotel, Lahore - Pakistan Summary: The THEME of Congress is “Dunya Hamari Mandi” - Industrializing Pakistan. PFA is engaged in the development of the foundry sector including technical gradation and skills development. The economic development of Pakistan cannot be over emphasized without the importance of the foundry engineering industry. 4th IFCE – 2012 will pave the path for development of the Pakistan foundry industry and the SME sector. This mega event will provide an opportunity for members of the casting industry to interact with international and domestic machinery and equipment manufacturers, suppliers and foundry technologists. The 4th IFCE – 2012 will provide a forum to eminent academicians and technologist from around the world to come together and to discuss the growth of the foundry industry in Pakistan and Asian countries. PFA will organize multiple workshops and discussions during the congress on certain problems faced by the foundry industry. Web: http://www.pfa.org.pk IFEX 2013 – 9th edition of International Exhibition on Foundry Technology, Equipment Supplies When: January 27 – 29, 2013 Where: Salt Lake Stadium Ground, Kolkata – India Summary: The 9th International Exhibition on Foundry Technology, Equipment and Supplies & 4th Cast India Expo concurrent with 61st Indian Foundry Congress will be an excellent platform for companies from India and around the world to showcase their state-of-the art technologies and services. Over the years IFEX has emerged as the most important platform for the foundry industry of the Indian Sub-Continent with its rotational policy to organize the Fair in different zones of India (North, South, East & West) on a pre-defined cycle helps its exhibitors to reach their potential customers from all over the country. In addition the success of the two previous Cast India Expo’s held concurrently to IFEX has prompted the inclusion of the third edition Cast India Expo 2013. The presence of these casting manufacturers as exhibitors in the same venue will provide a ready customer base for Indian and international suppliers. CastExpo 2013 When: 6-9 April 2013 Where: America’s Center - St. Louis, Missouri – USA Summary: Building upon the success of the 116th Metalcasting Congress in Columbus, CastExpo ‘13 will be better than ever as it brings together the Metalcasting Supply Chain for 4 days you can’t afford to miss! Sponsored solely by the American Foundry Society (AFS), CastExpo is the single largest trade show and exposition for metalcasting in the Americas. CastExpo’13 in St. Louis will offer metalcasters, suppliers, and casting buyers and designers the opportunity to connect and educate themselves on the latest and greatest metalcasting has to offer. Web: http://www.afsinc.org 117th Metalcasting Congress When: 6-9 April 2013 Where: America’s Center - St. Louis, Missouri - USA Summary: The American Foundry Society (AFS) has issued a call for papers for the 117th Metalcasting Congress, to be held in conjunction with CastExpo 2013. All papers must be relevant to the metal casting industry and must contribute to the enhancement of metalcasting quality and productivity, covering topics such as operations, new technologies, procedures, processes and other innovations, and casting design and purchasing. For more information on submitting on submitting a paper to the 117th Metalcasting Congress, contact Steve Robison, AFS senior technical director. Email: [email protected] 14th Guangzhou International Die Casting & Industrial Furnace Exhibition When: 16-18 June 2013 Where: China Import and Export Fair Pazhou Complex, Guangzhou – China Summary: The 14th Guangzhou International Die Casting & Industrial Furnace Exhibition will deliver multi-faceted platforms for business interaction providing opportunities to attract potential customers. Visitors will include Product Managers, Product Developers, Designers, Purchase and Sales Managers. Professionals related to the field of machine tools, components & accessories, precision tools & other related products are the target visitors. The exhibition profile includes cold chamber die-casting machine, hot chamber die-casting machine, low-pressure casting machine, extrusion press, auxiliary equipment, environmental protection and safety technology, Casting products and manufacturing technology smelting, heat treatment equipment and energy-saving technologies for foundry environment, labour protection equipment and supplies for foundry, Precision Casting, Other special products and foundry equipment. Email: [email protected] YOUR COMPETITIVE EDGE CAST is the premier innovation network for the metal manufacturing industry. Since 1993, we have been bringing commercial acumen and research expertise together to meet the challenges you face in today’s competitive global market. CAST’s research expertise in aluminium, magnesium, titanium, and ferrous metals has helped build industry capability from melt to manufacture and beyond, with a proven track record of helping businesses like yours: • increase their market share • exploit new global markets • win important contracts • lower energy emissions and consumption. Whether your business is large or small, CAST enhances your R&D capabilities, helping build your competitive edge, and create new opportunities at home and abroad. We can even help you identify and apply for government grants and funding, stretching your R&D investment further. To learn more about the CAST advantage, and how we can help your business today, call +61 7 3366 6271 or email [email protected] Ph: +61 7 3366 6271 Fax: +61 7 3346 9373 Email: [email protected] www.cast.org.au M e ta l : M a n u fa ct u r i n g : r e S e a r c H Back to the Melting metal for the virtual bronze foundry By Prof. John H. D. Bautista, PEE, RMetE, MBA; Technical Consultant, Phil. Metalcasting Association., Inc. T he choice of melting furnace depends on the types and sizes of castings to be made. If small melts are needed to produce small castings, the pit-type, cokefired furnace may be used. If larger melts are needed, the oil-fired, crucible furnace of the fixed pouring type would be indicated, especially if large quantities of borings and turnings are used in the charge. Where the castings required are average – for example, from 50 to 100 kgs. (100 to 200 lbs.) – and where it is necessary at times to melt nickel or other high melting point alloys, and where ideal working conditions around the furnaces are considered important with particular regard to the absence of heat and noise, then the high-frequency, lift-coil type of crucible furnace is indicated. In this type, no ladles or ladle heaters are required, and no mixing is needed. Pit-type coke-fired furnaces In pit-type, coke-fired furnaces, the crucible in placed into a pit that contains the foundry coke. The coke is fired and the crucible is preheated. It should be carefully packed so that as much metal as possible is charged at the first loading. None of the metal charged should project above the crucible; this helps to keep the metal from coming into contact with the furnace gases. To ensure this, a lid consisting of an old crucible bottom could be used; this will fit nicely over the crucible and prevent overloading. It should be borne in mind that copper and high-copper alloys absorb gas when red hot, even while in the solid state. There is no objection to preheating the metal to be charged so long as it is not allowed to get red-hot. In all melting processes of this nature, speed is of the essence. The crucible should therefore have reached red-heat in the furnace before the metal is charged into it. The practice is to avoid the use of charcoal or flux cover, thus giving the gases already in the metal a chance to escape. The melt should be considered ready when the temperature is about 500C. (100º F.) above the pouring temperature. As a matter of routine, it is hardly practicable to take the temperature with a pyrometer while the crucible is in the furnace, but a good melter soon gets to be able to judge when the metal is ready. In removing the crucible from the furnace, care should be taken to see that the tongs fit around the contour of the crucible so that the pressure is distributed and squeezing of the more or less plastic hot crucible avoided. After the tongs have been removed and the crucible placed in the pouring shank, the metal should 58 www.metals.rala.com.au be stirred quietly in a manner to mix well, but not to expose the surface any more than is necessary. It should then be skimmed, and if any deoxidizer is to be added, this should be carefully stirred-in and the temperature taken. The crucible should then be allowed to stand until the predetermined casting temperature is reached, the temperature being tested with the pyrometer from time to time, stirring just before taking the temperature. When the correct temperature is reached, the metal is again skimmed and poured. In some cases, it may be an advantage to cover the metal with thoroughly dry charcoal (pieces of about 1 cm. or ½-inch diameter, free from all fine dust), or a carbon disk may be floated on the metal. Oil-fired, crucible-type furnaces With this type of furnaces, care should be taken to effectively ventilate the furnace area. The best thing is to have a large pipe hung in front of the furnace flame into which the flame can easily enter. This tube connects with a blower system and discharges into the outside atmosphere. The whole of the furnace is covered by a hood that itself has a large pipe connected to the same blower system. This hood should extend far enough in front to cover the ladle into which the furnace is to be emptied. This will catch any lead and zinc fumes that are evolved during the pouring of the metal. Successful melting in this type of furnace depends on keeping the flame properly adjusted at all times. To do this, each furnace should have its own blower and its own oil pressure system; having a battery of furnaces on one pressure system for air and oil means that a change in pressure occurs as one or more furnaces are added to or subtracted from the battery. There should be a good ordinary valve away from the furnace burner and another, a needle valve capable of very fine adjustment, at the burner itself. In operating the furnace, the flame is controlled so that the exit flame is sharp in outline, not lambent, and nearly, but not quite, yellowish-white in color with possibly a greenish tinge. If it is definitely yellowish-white, there is an excess of oil. This flame control is the secret of good furnace operation, with its attendant fast melting and satisfactory metal. A slightly oxidizing flame is desired in order to prevent the absorption of hydrogen gas into the melt as the excess oxygen in the flame will react with the hydrogen and produce water vapor that can be discharged into the atmosphere. The oxygen absorbed in the melt can afterwards be removed by deoxidizers. There is no way that hydrogen in the melt could be removed, so prevent it in getting into the melt. The condition of the flame as to oxidizing or reducing may be determined by placing in it a piece of zinc slab, about 20-cms. x 3-cms. square (8-inches long x 1¼-inch square). Hold it there for 5 seconds. If the zinc has a smoky or black appearance, the flame is reducing; if oxidizing, the zinc remains unchanged. The furnace should be at a bright red heat before metal is charged and as much of the metal as possible put into the furnace at one time – unless there are borings or turnings in the charge, in which case these are placed in brown paper bags and thrown into the bath of molten metal and stirred-in well. The furnace is emptied into a ladle. This ladle is lined with refractory; it is thoroughly dried and then brought to a red heat each time it is used. The ladle should be thoroughly scraped out after each pour and kept as clean as possible, especially at the lip, otherwise dross and dirt will get into the molds when castings are poured. Corrective additions such as tin, lead, zinc, and phosphor-copper are placed on the bottom of the ladle just before tapping so the molten metal covers them and the general disturbance of the tapping-pour mixes them. In addition, the melt should be stirred well with a clean, heavy iron skimmer, which should be replaced before it gets too hot, in order to reduce iron contamination. In general, no covering of charcoal or flux is used. An exception to this is when the fuel is natural gas having a high and variable content of sulphur. In such a case, it has been found beneficial to throw in with the charge a sufficient amount of soda ash to form a covering over the molten metal, not less than 4 mm. (1/8-inch) thick, thus preventing the sulphurous gas from entering the metal. In the interest of economy, and as a further check on furnace operation, a reliable oil meter should be put in the fuel line of each furnace. Regular forms should be provided and the furnacetender should keep track of the oil consumed for each heat. If the oil consumption goes up it indicates the probability of the furnace flame having been wrong, too little air or too much oil having been present. High-frequency, lift-coil induction furnace The operation of this type of furnace is simplicity itself. The crucible is the furnace and is placed on a truck running on a short track, long enough to hold two crucibles; one is surrounded by a liftcoil while the other is being loaded. The fact that the crucibles are some 45 cms. (2½ feet) from the ground does away with any stooping during loading or carrying to the pouring point. The crucible is loaded, the hood lowered, the current turned on, and the melting proceeds. When the pouring temperature is reached, the lift-coil is raised, the crucible carried to the molding floor and the molds poured, and the other crucible that has been previously loaded is moved over to the lift-coil. As the crucible is taken directly from the truck to the pouring spot, a temperature of only 250C. (500F.) above the pouring temperature is required. There is no need to mix the metal as this has been done automatically by the induced currents that were set up in the melt. Ordinarily no charcoal or flux is used. This is the best type of melting furnace; but it is more expensive than the oil-fired, crucible-type of furnace which could be fabricated in-house, if necessary. Items Gun Metal Bearing Metal Ounce Metal Copper 88.0% 80.0% 85.0% Tin 8.0% 10.0% 5.0% Lead 0.0% 10.0% 5.0% Zinc 4.0% 0.0% 5.0% High castability High castability High castability Yield strength, psi 18,000 17,000 17,000 Tensile strength, psi 40,000 32,000 34,000 Elongation, % in 2 inches 20 12 25 Brinell hardness, (500kg.) 68 65 60 Casting temperature, 0F 1900 1900 1900 Heat treatment None None None General purpose General bearings Plumbing fittings Properties: Applications Product composition METAL Casting Technologies September 2012 59 Back to the WEBSITE SHOWCASE Sample foundry procedure in melting tin bronzes Metal. It is assumed that composition ingots shall be used for the main charge. Melting. Using an oil-fired, crucible furnace and where pressure tightness is not a consideration, nor maximum density a requisite, these alloys may be melted without flux in an oxidizing atmosphere, taking the usual precautions mentioned above. (For use as bearings, porosity is a beneficent factor as this helps in retaining an oil film.) Efficient stirring is essential, as the lead will 2011 11:43 Seite 1 segregate rapidly when molten metal containing it is in a quiescent state. In cases where pressure-tightness and maximum density are desired, the following procedure should be followed, based on Walpole’s flux method. 1. Prepare the flux by mixing equal parts by weight of dry copper mill scale (this is the cheapest from of CuO), dry clean silica sand, powdered fused borax. Keep in a suitable container to avoid la\MCT and 2011 2012.qxp 90 x 135 mm absorption of moisture. 2. Use enough flux to maintain a cover ¼-inch thick over the molten metal under the conditions of melting. Generally 3% References: (a) Harold J. Roast, Cast Bronze, The American Society for Metals. (b) Metals Handbook, Desk Edition, 1985 Beckwith Macbro www.linn.de Turbine blades, turbocharger wheels. γ-TiAl, Ti, Ni-basis, Al, Mg. Resin Coated Sands Induction heated precision centrifugal fine casting systems up to 2 kg Ti /TiAl, 3 kg Steel, 1 kg Al/Mg, e.g. Production line for γ-TiAl consisting of mould pre heating rotary hearth furnace, conveyor furnace for annealing of castings under protective gas and centrifugal casting unit. Rotary hearth furnace for pre heating of ceramic casting moulds for TiAl, Ti, Pt, Ni-basis. Up to 1100 °C. 3 turn tables (Ø 940 mm). 60 www.metals.rala.com.au of the weight of the metal to be treated is sufficient. Where the phosphorus content of the charge exceeds 0.05%, a larger amount of flux may be required. 3. Put the flux in with the metal as it is charged to the melting unit. 4. Melt as rapidly as possible under an oxidizing atmosphere. 5. When the metal has reached the desired temperature, stir the flux well into it, to further the oxidizing process. 6. Transfer to a pouring container and throw dry silica sand onto and over the metal to thicken the flux and facilitate its removal by skimming. 7. Skim and add 100 grams (4 oz.) of the 15% phosphor-copper per 50 kgs. (100 lbs.) of metal for purpose of deoxidation. 8. Stir well, exposing as little of the metal to the air as is practicable, and leave for at least 2 minutes before pouring. 9. Pour into the molds; a residual phosphorus content of 0.05 to 0.03% is desirable. All grades of resin coated sand used for shell molding and shell cores for ferrous and non-ferrous applications PRODUCTS n Range of resin strengths from 1.0% to 5.0%. n Silica, Zircon, Chromite coated sands or blended mixes. FOR SAL E n Coated Sands of different AFS SHELL C typically from 50-90 AFS. MACHINORE ES n Thermal Reclaimed Coated Sands. SHEL LM MACHINOULD n Frac Sand. ES Services n Full technical and trouble shooting service. n On-site shell core and shell molding facility to evaluate the product applications. n Laboratory facility to ensure product quality. Contact : Rob Dalla Via 30 Devon Road Devon Meadows, Melbourne Telephone: +61 3 5995 4244 Mobile: 0417 332 723 Fax: +61 3 5995 5030 E-mail: [email protected] Website: www.beckwithmacbro.com.au METAL Casting Technologies September 2012 61 ajaxtocco.com aruntechnology.com beckwithmacbro.com.au fein.com.au finitesolutions.com foundry-eqpt.com bradken.com.au bruker-elemental.com bisley.com.au foseco.com.au gcinstrument.com.au huettenes-albertus.com cast.org.au castingtechnologynz.org didion.com imfluino.it inductotherm.com.au linn.de 62 www.metals.rala.com.au METAL Casting Technologies September 2012 63 magmasoft.com.sg pacrim.com.au powerhammer.com rala.com.au sibelco.com spectro.com/lab metalsonline.rala.com.au synchroerp.com warill.com.au Ajax Tocco Magnethermic . ..................................... 66 Hayes Metals............................................................. 73 Arun Technology ....................................................... 67 Huettenes-Albertus Australia................................... 73 Beckwith Macbro Sands............................................ 67 Linn High Therm . ..................................................... 79 Bruker Quantron GmbH . .......................................... 67 Magma Engineering Asia Pacific.............................. 74 Casting Solutions . .................................................... 69 Metal Casting Technologies Magazine ........... 69 / 78 Cast Metal Services....................................................68 Powerhammer Company......................................76-77 CMC Cometals............................................................ 69 Sibelco ....................................................................... .75 Didion International ................................................ 70 Spectro Analytical ..................................................... 78 Fein Power Tools........................................................ 73 World Equipment Machine Sales . ..........................80 Finite Solutions...........................................................71 WES Omega Foundry Machinery.............................80 Foseco ......................................................................... 72 64 www.metals.rala.com.au METAL Casting Technologies September 2012 65 EVERYTHING YOU NEED FOR METALS ANALYSIS PRECISELY MORE AFFORDABLE MOLTEN METAL ARUN Technology, world leader and pioneer of CCD based spectrometers for metals analysis. Specifically designed for the metals industry, whether sorting scrap or bar-stock with it s ‘A’ series portable units, or to meet today’s ever demanding quality control requirements for the foundry, casting, extrusion, recycling plant or workshop with the new PolySpek series of desktop spectrometers, ARUN Technology has the solution. Headquarters For: The new PolySpek line-up now includes the PolySpek Junior, offering a low-cost, yet flexible answer combining all of the necessary components into one compact desktop unit. Each instrument is supplied ready to go complete with original factory calibrations and utilises intuitive software designed with simplicity in mind. Coreless Induction Furnaces Channel Induction Furnaces ARUN Technology for your metals analysis. Simple, rapid and accurate analysis made more widely available and more cost effective than ever before. For the complete control of your metals including all major alloying and refining elements PolySpek is the answer. INDUCTION MELTING Melting Holding Duplexing Beckwith Macbro Resin Coated Sands All grades of resin coated sand used for shell molding and shell cores for ferrous and non-ferrous applications PRODUCTS n Range of resin strengths from 1.0% to 5.0%. n Silica, Zircon, Chromite coated sands or blended mixes. FOR SAL E n Coated Sands of different AFS SHELL C typically from 50-90 AFS. MACHINORE ES n Thermal Reclaimed Coated Sands. SHEL L MOULD M ACHINES n Frac Sand. Services n Full technical and trouble shooting service. n On-site shell core and shell molding facility to evaluate the product applications. n Laboratory facility to ensure product quality. ARUN Technology MetalScan Limited. 16 The Brunel Centre, Newton Road, Manor Royal, Crawley, W. Sussex, RH10 9TU United Kingdom Ferrous Tel: +44 (0) 1293-513123 Fax: +44 (0) 1293-521507 E-mail: [email protected] Web: www.aruntechnology.com Non-Ferrous Contact : Rob Dalla Via 30 Devon Road Devon Meadows, Melbourne Telephone: +61 3 5995 4244 Mobile: 0417 332 723 Fax: +61 3 5995 5030 E-mail: [email protected] Website: www.beckwithmacbro.com.au High Power Jet Flow Inductors Solutions for Metal Analysis Out of One Hand: Optical Emission Spectrometers CS/ONH-Analyzers Ajax TOCCO Magnethermic® Corporation Handheld XRF Analyzers 1745 Overland Ave Warren, OH U.S.A. 44483 Tel: 800-547-1527 Tel: +1-330-372-8511 THE GLOBAL FORCE IN INDUCTION TECHNOLOGY Fax: +1-330-372-8608 www.ajaxtocco.com Optimize your Analysis Process and Quality www.bruker.com ELEMENTAL ANALYSIS Innovation with Integrity METAL Casting Technologies September 2010 66 www.metals.rala.com.au 69 BE One Stop Shop_engl_190x135 .indd 1 26.07.2011 14:46:27 METAL Casting Technologies September 2012 67 Casting Solutions Pty Ltd PO Box 131, Moorebank, NSW, 2170 Australia Tel: +61 2 9792 3782, Fax: +61 2 9792 3782, Email: [email protected], Mob: 0412 178 895 Contact: Jeff Meredith – Director Category: Foundry Consultants Products & Services SORELMETAL High Purity Pig Iron: Australian agents for SorelMetal High Purity Pig Iron. Produced by Richards Bay Iron and Titanium Pty Ltd South Africa Nodulants & Inoculants: • Elkem a/s Norway. Exclusive Australian Agent Refractories: • CMS manufactures a selected range of premium grade Castables, Ramming Materials, Mortars and Furnace Linings etc. developed to suit the customer’s Specifications and applications. Nickel: • Stocks held in all Australian states • Mayerton Refractories UK. Australasian Agent (Furnace & Ladle Refractory Bricks) • CMS manufacture a complete range of Refractories and Pre-cast shapes • Services include selection, installation auditing and supply for Foundry EAF. Induction and Heat Treatment Furnaces and Ladles. Refractory Hollowware: • Mayerton Refractories UK.- Australasian Distributors • Cooinda Ceramics - manufactures of the EZY-FLO range of first quality Ceramic Hollowware Foundry Equipment: • Omega Foundry Equipment UK. Australian Agent • A1 Roper UK. Ladles and accessories – Australian Distributors • Whiting Equipment Canada Inc. Electric Arc Furnaces & metallurgical EquipmentAustralian Agent • PowerHammer Riser removal equipment – Australian Agent • Equipois Inc. manufactures of the Zero Gravity Arm - Australasian agent Ferro Alloys: • CMS can offer the largest, most comprehensive, complete range of Ferro Alloys and Metal Powders • Services include Charge calculations, melting procedures etc., for Grey and Nodular Irons. Indium: • Australian Agent for Indium Corporation of America Recarburiser: • Synthetic Graphite, Graphitised Petroeum Coke & Gas Calcined Anthracite Oxy Lance Pipes: • Shinto Japan – Australian/NZ Agent Filters: • Exclusive distributors for the SQ range of ceramic filters for all grades of ferrous and non-ferrous metals Slag Coagulant: • Castkleen range of Slag Coagulants for all applications Sands: • Southern Pacific Sands. Exclusive Foundry distribution of local Silica Moulding Sands • Premium grade Zircon Sand Australian distributors for Sibelco • Chromite Sand - CMS are distributors for Rand York Minerals Premium Foundry Grade Chromite Sand • Olivine Sand Bentonite: • CMS Superior Bond High Performance Bentonite Mould and Core Binder Systems: • CMS are the exclusive agents for the full range of SQ Resin Binders and Catalysts – including Furan, Alkaline Phenolic Co2 and liquid hardener cured, Air Setting Polyurethane Resin, Cold Box and Hot Box Resin Systems Refractory Mould Coatings: • CMS manufacture a full range of Foundry refractory Mould Coatings, in water and Solvent suspensions and dry powder blends based on Zircon, Graphite, Magnesite, Olivine and Alumina and a range of auxlilary products including adhesives, RIMS Anti Veining additive Methoding Software & Service • CMS use and recommend NovaCast Methoding Software - CMS are the exculsive agents for Australia and New Zealand for NovaCast AB Sweden • CMS services include technical support in casting methoding, gating, and riser design / selection, 3D modeling filling / solidification simulation plus general technical support FEEDING AIDS: • CMS insulating riser tiles – ISOtop hot topping and insulating compounds. Pattern Making Supplies: • Ebalta pattern resins and toolong boards Australian agents. • CB Vents, Dowels & Sockets etc., Steel Shot: • TAIWANABRATOR Steel Shot – Australian Distributors Abrasives: • CMS can offer a complete range of high quality Abrasives especially formulated for the Foundry Industry Welding wire: CMS offer a competitive range of Welding Wire Grahite Electrodes: • Graphite Electrodes 6inch to 28inch all lengths, HP, SHP, UHP CMS are exclusive agents for Fangda China HEAD OFFICE Postal: PO Box 22 Northgate Qld 4013. Offices: 275-277 Toombul Road, Northgate Qld 4013 T: +61 7 3266 6266 F: +61 7 3266 6366 E: [email protected] Australian Branches: Sydney, Melbourne, Adelaide & Perth. NZ Distributors: Metcast Services Limited. Auckland NZ Overseas Offices: UK, China & Malaysia 68 www.metals.rala.com.au Products: SOLIDCast, FLOWCast, OPTICast simulation software. www.finitesolutions.com Services: l metallurgical l solid modelling l flow, solidification and optimisation modelling of castings l casting methoding service l defect analysis l training Level 5, 4-8 Woodville Street Hurstville NSW 2220 PO Box 113, Hurstville BC NSW 1481 Tel: 61 2 9585 6222 Fax: 61 2 9580 8680 Email: [email protected] Website: www.cometals.com.au Contact: General manager: Colin ILES – [email protected] NSW: Gary Bartlett – [email protected] QLD: Dave Miller – [email protected] VIC: Kathy Sevald – [email protected] SA: Brad Walsh – [email protected] WA: Alan Dunn – [email protected] Ferro alloys: David Osborne – [email protected] Foundry: Martin Spence – [email protected] Aluminium: Chris Baker – [email protected] Categories: Equipment and Suppliers Industries served: Foundry, steel, aluminium smelter Product range: • Ferro alloys • Steel Shot • Inoculants • Master Alloys • Metals • Grain Refiners • Minerals • Fluxes • Refractories • Electrodes • Nodulrisers • Pig Iron • Nickel • Recarburisers Distributors for Ashland Pacific products: • Resins • Catalysts • Refractory Coatings • Feeding Aids Services: Stocking, financing, delivery and storage of raw materials for foundries steel mills and smelters. HIT THE BULLSYEYE EVERY TIME METAL CASTING TECHNOLOGIES Integrated communication platforms SUPPLIERS – Exclusive email broadcasts INTEGRATED – Print and ONLINE reader engagement POWERFUL Database reach – FASTER Connection and response Score a direct hit with your communications Speak with Adam for details on +61 2 9420 2080 / [email protected] METAL Casting Technologies September 2012 69 Why Use Casting Simulation From FSI? Largest User Base in the World Easiest to Use Fastest Results Solidification Analysis Integrated Gating and Riser Design Lowest Cost to Buy and Use Flexible Payment Plans Available Multiple Language Versions Mold Filling World Wide Support Visit us at Stand 14 AFI Conference www.finitesolutions.com Feeding Zone Analysis for Riser Design 70 www.metals.rala.com.au 72 www.metals.rala.com.au Casting simulation for the working foundry METAL Casting Technologies September 2012 71 F O S E C O FEIN Power Tools Pty. Ltd. Made in Germany Since 1867 26 Fallon Drive Dural NSW 2158 PO Box 202, Cherrybrook NSW 2126 Tel: 02 0651 5966 Fax: 02 9651 5988 Email: [email protected] Contact: Gary Weber – Managing Director, Ryan Weber – Technical Manager Category: Consumable supplier Industries supplied: Foundry Product range: Cold box binders and catalysts Hot box resins Resins for shell moulding Furan resins Resin coated sand Inorganic binders Special sands Coatings Alkaline phenolic binders Alkaline phenolic for CO2 curing binders for ester curing * FEIN Angle Grinders * FEIN Straight Grinders FOSECO LOCATIONS AUSTRALIA Phone: 61 2 9914 5500 Fax: 61 2 9914 5547 MALAYSIA Phone: 60 33176 0448 Fax: 60 33176 0608 PHILIPPINES Phone: 63 2 850 6654 Fax: 63 2 850 6638 TAIWAN Phone: 886 8 722 8108 Fax: 886 8 722 8182 THAILAND Phone: 66 2 2613164 Fax: 66 2 2613168 INDIA Phone: 91 2137 668100 Fax: 91 2137 668360 INDONESIA Phone: 62 21 460 5555 Fax: 62 21 460 3489 NEW ZEALAND Phone: 64 9 274 4559 Fax: 64 9 274 5981 CHINA Shanghai Phone: 86 21 3367 8188 Fax: 86 21 3367 8166 WEBSITES www.foseco.com.cn www.foseco.com.au www.foseco.com www.vesuvius.com YOUR TOTAL SOLUTION PROVIDER * FEIN High Frequency Grinders Foseco is part of the worldwide Foseco Group of companies, which has been associated with global metallurgical industries for more than 70 years, and, is an innovative and progressive organisation. Foseco’s regional laboratory facilities allow our products to be tailor-made to the exact requirements of our local customers. These same facilities also provide technical support to many of our customers’ processes and allows for local research and development. Foseco supply a wide range of products to the metal casting industry, further product information is available from your local Foseco office. * GRIT Belt Grinders ISOMOL* HOLCOTE* RHEOTEC* FENOTEC* FUROTEC* ECOLOTEC* POLITEC* POLISET VELOSET* KALMIN* KALMINEX* KALPUR* SEDEX* STELEX* SIVEX* FC CARBONIN* INOCULIN* COVERAL* FEEDEX* KALTEK* INSURAL* MTS VESUVIUS Refractory solvent based coatings Refractory water based coatings Refractory water based dip coatings Selfset alkaline phenolic binder system Furane binder system CO2 cured cold box system Phenolic urethane Amine cured cold box Selfset phenolic urethane binder system Sodium silicate self set systems Range of insulating feeder sleeves Range of exothermic feeder sleeves Direct pour systems Iron filtration Steel filtration Aluminium filtration Range of melt carbon raisers Range of inoculants Fluxes for aluminium Exothermic feeder Sleeves Insulating ladle lining system Insulating refractories for aluminium Automated Metal Treatment Station for Aluminium Crucible range Foseco also supply, release agents, die coatings, furnace and ladle linings & refractories LOCAL KNOWLEDGE GLOBAL RESOURCES *registered trade marks of the Vesuvius Group registered in certain countries. 72 www.metals.rala.com.au * FEIN Drills * FEIN MultiMaster Call us today - 1300 798 688 Visit - www.fein.com.au Office Locations:New South Wales, Victoria, Queensland, Western Australia and South Australia PART OF THE HAYES METAL REFINERIES GROUP - ESTABLISHED 1927 FOR AUSTRALIA’S AND NEW ZEALAND’S LARGEST RANGE OF ALLOY INGOTS FOR FOUNDRIES AND THE DIE CASTING INDUSTRY Producers and / or Distributors of a Comprehensive Range of: ■ Copper Alloy Ingots & 15% Phosphor Copper Shot ■ Primary Grade Aluminium Foundry Alloy Ingots ■ Secondary Aluminium Foundry & Diecasting Alloys ■ White Metal Alloys & Specialty Solder Alloy Ingots ■ Zinc Aluminium Alloy Ingots Technical Support by way of full in-house Analytical Laboratory Call CallAustralian AustralianSales Sales on on+61 +61229627 96277150 7150 Hayes Hayes Metals Pty Ltd - Sydney Offices Office (Incorporating (incorporating Dinga Enterprises) 25-31 Riverstone NSW 2765 and 25-31 Hobart Hobart St., Street 106 Mileham St.,2765 South Windsor NSW 2756 Riverstone NSW Fax: Fax: +61 +61 22 9627 9627 7041 7041 E-mail: E-mail: [email protected] [email protected] CallNew NewZealand ZealandSales Sales Call +649 9633 6334000 4000 onon+64 Hayes Metals Ltd -Limited Hayes Metal RefiPty neries Auckland Office Auckland Offi ce 8 Edinburgh Street 8 Edinburgh Street Onehunga Auckland 1061 Onehunga Auckland 1061 NZNZ Fax: +61 2 9627 7041 Fax: +64 9 636 4004 E-mail: [email protected] E-mail: [email protected] www.hayesmetals.co.nz www.hayesmetals.co.nz METAL Casting Technologies September 2012 73 FND CORP 1FA4-UAL_FND.CORP1F-A4-UAL 11-08-22 9:10 AM Page 1 SHAPE THE FUTURE ! Quality Castings Start Here Supplier selection is more than physical properties and delivered prices. It represents the selection of a partner with the resources to help achieve your quality, productivity and environmental goals. Sibelco offers a complete portfolio of silica and low expansion refractory sands, bentonite clays and custom blends. Given more options, foundries can more effectively match mineral performance with casting objectives. Our organisation is applications driven. With a dedicated materials research lab and proven foundry experts, our strength is the ability to deliver products, technology and service as a single, integrated system. Whether your goal is to optimise performance, maximise strength, improve finish, increase yield or speed up shakeout, we have a solution. Sibelco Australia Limited Tel.: +613 9586 5400 Fax: +613 9586 5411 E-mail: [email protected] Worldwide: www.metalcaster.com Casting process simulation is geared toward the reduction of energy consumption, raw material use and the environmental impact of your foundry. Increasing demands require even more flexibility and faster decisions on your part. Meeting these challenges depends on technically and economically sound solutions. Optimized Reality – this is where simulation with MAGMA shows its strength. MAGMA Engineering Asia-Pacific Pte Ltd 25 International Business Park #03-76/79 German Centre Singapore 609916 Phone +65 656 434 35 Fax +65 656 406 65 [email protected] www.magmasoft.com.sg 74 www.metals.rala.com.au All rights reserved. © 2011 METAL Casting Technologies September 2012 75 Model # m Model 55 mm KG Joules xmm m KG 55 45 2 500 115 110 115 65 5 1000 165 175 $ Casting Degating Hammers 铸件浇口清除锤 Model 115 m Marteaux de fonderie pneumatiques Model 815 Model 215 Giesserei Schusshammer 215 m 90 10 2000 225 250 Martelli pneumatici per le fonderie : 캐스팅 게이트 브레이크 해머 415 Model 415 120 20 3000 300 450 m Martelos para quebrar os canales de vazamento Молотки для отбивки литников Martillos para quebrar canales de colada Model 615 615 140 5000 350 600 815 190 8000 480 850 1655 250 16000 625 2950 m Model 815 m m Model 1655 76 www.metals.rala.com.au x PowerHammer Company 16295 SW 85th Ave Portland, OR 97224 • USA www.powerhammer.com Tel: +503 598 9894 www.linn.de Turbine blades, turbocharger wheels. γ-TiAl, Ti, Ni-basis, Al, Mg. Induction heated precision centrifugal fine casting systems up to 2 kg Ti /TiAl, 3 kg Steel, 1 kg Al/Mg, e.g. Production line for γ-TiAl consisting of mould pre heating rotary hearth furnace, conveyor furnace for annealing of castings under protective gas and centrifugal casting unit. The Best in Metal Analysis Unique flexibility, highest precision, stability and analytical speed – when your daily analyses require more than mediocrity, you’re equipped with the best for every analytical task with the new SPECTROLAB. For demanding metal analysis, the SPECTROLAB offers you: – Lowest operating costs due to reduced argon consumption and lengthened maintenance intervals – Unique flexibility and precision due to the hybrid optic that combines the advantages of PMT and CCD technology – Highest stability and speed due to the simultaneous signal processing and optimized excitation conditions with a plasma generator Find details at Tel +852.2976.9162, [email protected] www.spectro.com/lab. Please visit us at: JAIMA/JASIS 2012, 5 - 7 September, Tokyo, Japan Guangzhou Mould Exhibition 2012, 19 - 21 September, Guangzhou, China NDT 2012, 31 October - 2 November, Shanghai, China Rotary hearth furnace for pre heating of ceramic casting moulds for TiAl, Ti, Pt, Ni-basis. Up to 1100 °C. 3 turn tables (Ø 940 mm). HIT THE BULLSYEYE EVERY TIME METAL CASTING TECHNOLOGIES Integrated communication platforms SUPPLIERS – Exclusive email broadcasts INTEGRATED – Print and ONLINE reader engagement POWERFUL Database reach – FASTER Connection and response Score a direct hit with your communications Speak with Adam for details on +61 2 9420 2080 / [email protected] METAL Casting Technologies September 2012 79 WES OMEGA FOUNDRY MACHINERY PTY LTD 16 Lanyon Street Dandenong Vic 3175 Tel: +61 3 9794 8400 Fax: +61 3 9794 7232 Email: [email protected] Contact: Les Craig and Peter Domopoulos l l l l l l l SPECIALISING IN: l Foundry Equipment and Engineering l Foundry layout drawings l Research and Development of new equipment l Modify existing equipment designs to suit a variety of applications l Service and Spare parts INDUSTRIES SUPPLIED: Foundry equipment for a wide range of materials handling applications PRODUCT RANGE: l Foundry engineering l Chemically bonded sand moulding systems l Continuous sand mixers l Vibrating compaction tables l Rollover draw machines l Mould painting manipulators l Mould closing manipulators l Indexing belt & rollover conveyors l Dry attrition sand reclamation systems l Primary lump reducers l Pneumatic sand transporter l Secondary scrubbing equipment l Fluid bed cooler classifier l l l l l l l l l l l l l l l Dust collection systems Sand storage silos Thermal reclamation systems Cold box core machines Shell core machines Gas generators Fume scrubbers Sand heaters Sand coolers Full range of vibratory equipment Vibratory furnace scrap charge feeders Vibratory sand/casting conveyors Vibratory accumulating and sorting conveyors Vibratory sand lump reducers Vibratory compaction tables Full range of sand testing equipment Full range of geared ladles Simpson green sand mixing equipment Didion rotary media drums Hunter match plate moulding and handling systems Vulcan Engineering fox grinders and action robots EMI Equipment automated moulding systems and re-manufactured equipment. SERVICES: Application evaluation; foundry design engineering; in house manufacturing programme; in house testing of equipment; supervision of installation of equipment on site commissioning of equipment; after sales service and equipment spare parts. ASSOCIATED COMPANIES: Hunter Automated Machinery – Match Plate Moulding and Mould Handlings Systems Didion International – Rotary Media Drums and Sand Casting Separation Simpson Technologies – Green Sand Mixing and Sand testing Equipment Vulcan Engineering – Fox Grinders and Action Robots. EMI Equipment – Automated Moulding Systems and Re-Manufactured Equipment. The 14th Guangzhou International Die Casting & Industrial Furnace Exhibition World Equipment and Machine Sales Company specialize in Exporting Second Hand Foundry Machines l DISAmatic Molding Machine l INDUCTOTHERM Induction Melting Furnaces l SINTO and HUNTER Molding Lines, With Handling l SPECTRO and BAIRD Spectrometers l LECO Carbon, Sulfur, Hydrogen, Nitrogen Testers l LAEMPE and LORAMENDI Core Cells. Complete l Core Making Equipment, Shell, Cold Box, Isocure l Shot Blast and Fettling Equipment, Wheelabrator l BMM and OSBORN Jolt Squeeze Molding Machines l COMPLETE FOUNDRIES FOR RE-LOCATION!!! AUTOMOTIVE FOUNDRY LINE FOR SALE, 1997 ABB 12T Twin Power Induction Melting Furnace, 6000 Kw, w/Spectro Disa 2013 Mk5B, 535 X 650, Pattern Changer, Core Setter, AMC, SBC Didion MD-100 Media Drum Wheelabrator Continuous Type Rocker Barrel Shot Blast Machine Governed By: Ministry of Commerce of the People's Republic of China Department of Foreign Trade Approved By: The Department of Foreign Trade & Economic Cooperation of Guangdong Province Organized By: Come visit us at our new 100,000 sq ft warehouse. Home of over 500 used foundry machines World Equipment & Machine Sales Co. 611 Cochran Road, Solon, Ohio 44139 U.S.A., Tel: 440-519-1745 Fax: 440-519-1748 www.foundry-eqpt.com [email protected] 80 www.metals.rala.com.au Contact Guangzhou Julang Exhibition Design Co., Ltd. Andy Cheng Tel: 0086-20-38621253 Fax: 0086-20-3862 0781 Email: [email protected] Show time: 16-18June, 2013 Venue: Ground Floor, B Area, China Import and Export Fair Pazhou Complex (No.380,Yuejiang Zhong Road, Guangzhou, China) The 14th CHINA (GUANGZHOU) INT'L METAL & METALLURGY EXHIBITION www.castingchina-gz.com COATINGS FILTRATION FEEDING SYSTEMS MELT SHOP REFRACTORIES METAL TREATMENT BINDERS CRUCIBLES COVERAL* I FDU I MTS I ALSPEK* THE POWER OF 2 The world is full of great double acts. Our technology and your foundry, for instance, to make premium-grade casting products. Or your castings in the hands of engineers who produce great technology that serves us every day. Our locally based teams of foundry specialists are on hand to help you develop innovative solutions to suit your metallurgical needs. Our products, services and expertise coupled with your skills and process knowledge can unlock the full potential of your foundry operations. As a reliable and trusted supplier, Foseco can help you to improve mechanical properties, increase casting integrity, lower fume emissions, reduce waste or perhaps improve process control. Whatever your foundry requirements are, talk to us. Your foundry and Foseco. The power of two. COMMITTED TO FOUNDRIES * COVERAL and ALSPEK are trade marks of the Vesuvius Group, registered in certain countries, used under licence. Phone: + (61) 2 9914 5500 Fax: + (61) 2 9914 5547 www.foseco.com.au