Read PDF - Foundry Trade Journal
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Read PDF - Foundry Trade Journal
Improved casting quality through advanced flow control technology The introduction of modern graphite containing flow control systems has brought a new dimension to the discharge of liquid metal from bottom pour ladle systems. Previous technologies presented the foundryman with a number of problems, any of which could have resulted in a bad pour and possible defective castings. Using the latest in both materials and design, the ROTOLOK* systems incorporating either VISO* or VAPEX* refractories overcome many of these issues and can lead to reduced costs and improved productivity, says Rudi Bittniok of Foseco Germany. The use of bottom pouring technology in steel foundries has become an industry standard; in many foundries it has replaced the use of lip pouring ladles for mould filling. The benefits of bottom pour ladles include: reduced slag in the casting, easier filling of the mould, a reliable system, a controlled pouring stream, and faster pouring. In combination with modern lining materials, the foundry now has the opportunity to achieve the high quality requirements demanded of many castings. This can be achieved by reducing temperature loss from the ladle during pouring, together with casting more moulds while the metal is at the required pouring temperature. The shape of the stopper head and the nozzle seat area are important parameters to obtain optimised control of the metal flow. Fig.1 Left: one-shot stopper in KALTEK ladle, right: ROTOLOK stopper head 274 Bottom pour technology was introduced using a disposable stopper rod system. This comprised of a steel rod lined with ceramic sleeves and an alumina-graphite stopper head; the ceramic sleeves and the stopper head had to be glued together with a high temperature resistant ceramic cement, like SUREBOND. After assembling, it was necessary to dry the system in an oven prior to use. Foseco has improved this system by introducing the ROTOLOK* stopper head for single use stopper rod systems. The unique ROTOLOK system comprises of an alumina-graphite stopper head and a separate ceramic thread. This ceramic thread is located on the steel stopper rod. The alumina-graphite stopper head is then screwed on to the thread and therefore on to the stopper bar. This system ensures there is no direct contact between the metallic rod and the graphite head, preventing thermal stresses in the stopper head during filling and casting. This is a significant benefit compared to the old system where the metal rod was screwed directly in the stopper head. The thermal Fig.2 FTJ November 2012 Melting Technology Fig.3 Different nose geometries Fig.5 Nozzle flow capacities Fig.6 Attachment possibilities Fig.4 Surface contact areas by having different nose designs. stress could cause cracks during the casting process. This disposable system is the only way of applying bottom-pouring technology with a stopper rod for large and/or tall ladles, where the whole rod system is longer than two metres. The application of mono-block stopper technology Many modern steel foundries use multi-life monoblock stopper technology. The idea originates in steel plants where similar technology is used for tundish applications in long casting campaigns. Foseco’s flow control products are available in two main formulations - VAPEX* and VISO*. VISO VISO is based on carbon bonded alumina graphite, produced using isostatic-pressing technology. The products offer excellent thermal shock and oxidation resistance, making them particularly suited as a mono-block stopper for application with molten steel. In steel foundry ladle applications the VISO stoppers are normally removed from the ladle after the casting period and cleaned before being reused. VAPEX VAPEX is a highly dimensionally accurate extruded product, based on a refractory combination of graphite and alumina. VAPEX offers excellent erosion and oxidation resistance and maintains high mechanical strength over a long operational time period. VAPEX was originally designed to be used in iron foundries with automated pouring; its excellent refractory properties also qualified it as an ideal material for nozzles used in ladle pouring of molten steel. All standard nozzle shapes are available with a range of inner bore diameters; products can also be made to specific customer specifications. The selection of the correct material and shapes for the flow control system in a ladle or pouring box has a significant impact on the pouring of the castings. Inadequate flow control devices can result in many problems. The stopper/nozzle can leak and FTJ November 2012 Fig.7 Assembling of UNIROD Fig.8 Stopper rod storage Fig.9 Preheating curve occasionally fail, resulting in uncontrollable flow of molten metal from the ladle - this is an obvious safety issue. A worn or blocked nozzle will give inconsistent flow rates and mould fill times. Incorrect shape of the stopper and nozzle will result in poor metal flow attributes; the metal will not flow in a consistent stream and may spray out of the nozzle resulting in casting defects from oxidation, air entrapment and erosion of the pouring cup by the metal stream. The use of VAPEX cross bore nozzles will further improve the integrity and consistency of the metal flow into the mould. The system has already been explained in the Foseco Foundry Practice 251(1). 275 Melting Technology Fig.12 Grinding tool Fig.10 Preheating station Fig.11 Cleaning station The correct choice of the stopper geometry to prevent leakages or the sticking effect The choice of the correct stopper/nozzle design has a direct influence on the performance of the system, and the prevention of molten metal leakage or stopper sticking. The golden rule is: ‘graphite to graphite’. Foseco always recommends the use of VISO graphite containing stoppers along with a VAPEX graphite containing nozzle to ensure the potential for sticking is minimised. The use of pressed standard clay nozzles or pressed alumina nozzles with mono-block stoppers which have different thermal expansions under hot load, can disturb the casting process and impact on the flow of the metal stream. Furthermore, the stopper head geometry will also influence the metal stream. In steel foundry applications it is recommended to use a roundshaped stopper nose compared to a pointed head stopper nose to reduce the contact area of the stopper/nozzle pair. Different stopper head geometries For very small casting weights and fast opening campaigns, the pointed nose is suitable, as this provides improved control for small castings. This is mainly applicable to iron auto-pouring furnaces. The output of the nozzle and its flow rate is usually determined by the inside diameter of the nozzles inner bore and the height of opening of the stopper: Attachment of the mono-block stopper The attachment system for the stopper to the metallic rod connected to the gooseneck, or ladle arm, is an important feature to assure an optimum stopper movement control. Foseco offers a choice of fully proven attachment systems: • UNIROD attachment • Roto-Rod attachment • Tundish-Rod attachment The UNIROD system is preferred by steel foundries and the Tundish-Rod attachment is common practice in auto pouring lines in grey iron foundries. The Roto-rod attachment is similar to UNIROD® (fig.7) but the thread is incorporated on a ceramic insert. For both systems a special metallic stopper rod is necessary, it is important that the metallic rod contains a central bore. This vent hole allows for the escape of moisture from inside the stopper during its temperature increase. Preparation area An adequately equipped area must be available for the preparation and stocking of the flow control system. A rack which allows the vertical 276 positioning of the stoppers is recommended to facilitate all the assembly operations. When such a rack is used, shock absorbing devices are useful to protect the stopper glaze against damage and cracks. The unique attachment of UNIROD provides the most rigid, secure and leak-proof assembly between the stopper and the support-rod. Preheating The correct preheating of the stopper is an important operation, which is too often neglected. Even when the assembly, setting and handling operations of a stopper have all been done correctly, it is possible to damage the ceramic through poor preheating practice. Correct preheating is important to avoid thermal shock to the refractory components. The preheating must follow a similar curve as shown in fig.9. Cleaning of the stopper The stopper can be used for up to 15 heats. After the casting process and the cool down of the equipment, the stopper should be cleaned carefully on a horizontal cleaning station. The slag should be removed carefully with a small hammer. A suitable nozzle shaped device is used to shape the stopper nose so that the radius fits the nozzle. A special anti-sticking coating can be applied to the stopper. Outlook The usage of the mono-block stopper technology offers many benefits in the iron and steel foundry casting process. With this multi-use system, the foundry is able to cast many more heats before replacing the stopper with a new one. This reduces gas costs by reducing refractory preheating and creates less waste than single use stopper rod components. In the future we will see increased application of mono-block stoppers in conjunction with better insulating ladle refractories like KALTEK*, where no or minimal preheating of the system is necessary. Contact: Paul Jeffs, UK technical manager, Vesuvius UK Limited – Foseco Foundry Division, Tamworth, Staffordshire B78 3TL UK. Tel: +44 (0) 1827 289999, email: [email protected] web: www.foseco.com 1. Foseco Foundry Practice 251 is available direct from the company as per the above contact details. www.foseco.com * ROTOLOK, VAPEX, VISO and KALTEK are Trade Marks of the Vesuvius Group, registered in certain countries, used under licence. FTJ November 2012