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Armstrong`s Wood Coating Quality Journey: Quality Improvements in
Armstrong’s Wood Coating Quality Journey: Quality Improvements in UV Wood Finishing Gary A. Sigel Armstrong World Industries Lancaster, PA Presented at RadTech 2010, Baltimore, MD, May 24, 2010 Abstract Finishing system requirements for wood flooring are based on Voice of the Customer (VOC) as it relates to end user specifications including: wood species, width, stain color, gloss, coating/wood visual and overall durability and maintenance. Because different plants have different UV finishing lines, variability in the UV process can cause manufacturing issues. Controlling the variability has been a major part of our quality improvement efforts. This paper begins with a history of Armstrong’s flooring and UV/EB chemistry development followed by Armstrong’s Wood Coatings Quality Journey. Within the quality journey, this paper will review three primary steps: 1) Finishing Process Specifications, 2) Statistical Process Control, and 3) Product Quality Control. A sigma process map will identify CTC (Critical to Customer attributes) and CTQ (Critical to Quality) input variables for the Finishing Process Specifications. The associated CTQs reviewed include: sanding, UV stains and finishing. Quality improvement in color matching, UV finishing system requirements, e.g., coating structure/performance, and statistical process control methodology for monitoring coating parameters and radiometry across multiple plants will be reviewed. AWI History of Product Development For 150 years, Armstrong has created and maintained a strong brand by manufacturing high quality products. Beginning in 1860 with the production of cork bottle caps for juices and water, Armstrong realized the importance of quality and ongoing process improvement as evidenced by its purchase of cutting machines that improved product quality by reducing cork size variation and increased volume. By 1899, Armstrong Cork had become the largest manufacture of cork. Leadership continued to drive new product development as documented by the credo “Let the buyer have faith.”1 Nine years into the 20th century, Armstrong began taking scrap cork and producing linoleum flooring in Lancaster PA. This marked the beginning of what would become the largest residential vinyl flooring operation (Figure 1). Armstrong acquired wood flooring manufacturing capability in 1998 with the purchase of Triangle Pacific. The acquisition included three brands (Bruce, Hartco and Robbins), six engineered wood flooring plants, six solid hardwood flooring plants, adhesives and floor care manufacturing, warehousing, an installation training facility, corporate office, and several cabinet manufacturing plants (Figure 2). All of the plants had UV cure finish lines. Although similar in concept, the lines at the different plants were quite different from one another. Differences included: the type and manufacturer of equipment, line layout, capacity and type of stain system (various plants used water based, solvent based, and 100% solids stains), and the total business was serviced by three different finish material suppliers. The variability of the lines and finish systems and processes from plant to plant posed problems in manufacturing the same products in different plants. Understanding and controlling the differences between the manufacturing facilities, in a way that was transparent to our customers, marked the beginning of the Armstrong wood floor coatings “Quality Journey.” 2 Armstrong’s Entry into UV/EB Wear Layers Armstrong has been producing radiation curable wear layers on its products for over 35years while continuing to develop finish systems that provide improvements in wear resistance, scratch resistance, stain resistance, color stability and other properties that impact CTC demands (Figure 3).3 In 1976, Armstrong introduced its first UV curable coating, purchased from W. R. Grace, and based on “thiolene” chemistry. The coating delivered “no wax” performance to a “do it yourself installation” (DIY) market. One year later, Armstrong had developed and began producing its first UV curable coating based on acrylate chemistry. The coating was a combination of UV and moisture cure based on a polyester urethane acrylate. By 1979, Armstrong had eliminated the need for the moisture component within the UV curable coating in favor of a more environmentally sustainable 100% solids UV cure system. The new coating was based on proprietary polyester acrylates, known internally as Duracote I. The next real breakthrough was the development of urethane acrylate chemistry based on NCO terminated polyester prepolymers. These polymers were further reacted with hydroxyalkyl acrylates to form an acrylated urethane oligomer. That was blended with other materials to form the final coating. This coating became the workhorse coating for residential tile for next several years. Armstrong’s next major breakthrough came in 1992 with the development of Sol-Gel chemistry. A patented coating was applied as a thin microscopic coating on top of standard urethane acrylate coating to give the CTQ and CTC attributes of excellent stain resistance and scratch resistance. In 1995, Armstrong launched its first nitrogen inerted UV curable coating on vinyl sheet goods based on polyester acrylate coating that again gave the CTQ attributes of stain and scratch resistance. Elements of Armstrong’s Wood Coatings Quality Journey Previously, we published the elements of the quality process that evolved from the Wood Coatings Quality Journey (Figure 4). More detail regarding this process can be reviewed in the cited reference. As highlighted in the center, the journey began with the customer. Also, as implied by the circular format, the journey continues to loop back to the customer through the product development process as summarized below: 1. Customer Quality Requirements are gloss, texture, color, performance and price. Each product has a specification that is unique to the product structure and the targeted market segment. 2. Finishing System Requirements are defined by customer requirements. This includes the chemistry, number of layers, thickness of layers and properties of layers which collectively provide the appearance and performance of the finish system. 3. Manufacturing Equipment Specifications are driven by capability to make the specified finish system. Key specification elements include: type of sanding equipment; number and type of coating stations; number, wavelength and power of UV lamps at each station; spacing between each component; coating delivery and storage systems; VOC/waste remediation; and quality control measurement. 4. Raw Material Purchasing Processes ensures that ingredients for manufacture are capable of producing a product that meets customer requirements if applied at the correct thickness and properly UV cured. 5. Finishing Process Specifications defines specific sanding machine set-up, coating machine and UV lamp operating parameters. Good quality specifications in combination with equipment capability will produce products that meet customer requirements. Once the finish system is defined, the next task is defining what manufacturing process equipment is required to apply the system which, in turn, determines which plants can manufacture the product. 6. Statistical Process Control is good manufacturing practice involving tracking key process parameters on a periodic basis. The data is used to create upper and lower process control limits and determine if the manufacturing process is in control. 7. Product Quality Control ensures several quality measures are in place beginning with incoming wood to kiln drying, ripping, side matching, end matching and finishing based on statistical process control. 8. Quality Audits are conducted at each plant to ensure that no gaps exist in our internal and external quality control process. 9. Product Development screens new product concepts based on probability of success. Probability of Success guidelines follows a similar pathway to that of the “Quality Journey.” Such criteria include commercial success, manufacturing success, ease of implementation, capital and return on investment (ROI). Going forward, this paper will focus on steps 5-7 on the quality loop beginning with Finish Process Specifications and ending with Product Quality Control (Figure 4). Finishing Process Specifications Sigma process mapping of finish lines is a method used to identify parameters that affect performance. Finishing Process Specifications begin with sanding and end with multiple applied layers of coating to produce the final product (Figure 5). Finishing Process Specifications are based on the end use customer requirements. For flooring, the most important attribute to customers is appearance. This includes a combination of UV stain color, coating texture and gloss level. Figure 5 shows typical steps for a wood finish line. Each step in the process represents an input variable that could result in variation. This variation is controlled by Standard Operating Procedures (SOP), Raw Material Specifications (RMS), and Statistical Process Control (SPC) methodology. Each step has multiple input parameters that affect the CTQ and CTC attributes, and the objective of each manufacturing plant is to control the process. It is instructive to consider sanding as an example (Figure 6). Key input variables4,5 are the type of sanding equipment, the grit sequence used, the abrasive paper manufacturer, how much material must be removed in each sanding step, and the consistency of smoothness required as the wood enters the finish line. The last point is an important linkage. If significant variation in final product color is not acceptable, then the sanding requirements can be adjusted accordingly. Another key process step that can lead to product variation is staining. There are four steps in the stain process that are important: 1) application of the stain, 2) leveling the stain, 3) removal of carrier (water or solvent) if the stain is not a 100% solids system, and 4) UV curing the stain (Figure 7). Within each step there are several parameters that can ultimately affect color. In the end, the final product must meet shade, visual and performance specifications. Most flat stock manufacturers now use roll coaters to apply stains, although some still use spray equipment. For either system, it is important to match the applicator characteristics to the type of stain being used. Referring to Figure 7, some typical input machine variables that affect shade appearance are shown for a roller applicator system. These include: roll type, down pressure, stain type (100% solids vs. solvent or water based), viscosity (temperature dependent), and evaporation rate (solvent or water base) during the drying step. Leveling can be accomplished by one or more techniques, such as wiping, brushing or allowing for “open time” before the curing step. Removal of the carrier can be accomplished by air drying, but more effectively using an oven. Equipment manufacturers offer a wide variety of options. Selection depends on the properties of the carrier, local regulations, and tradeoffs between capital expense targets, and floor space. Finally, for UV curable systems, the drying process for the stain also includes the UV lamps. As with the standard oven, the choice of UV lamps depends on the product application, cost considerations, regulatory requirements and available process footprint. Options include: medium pressure UV mercury arc lamps, microwave powered lamps, or UV LED (light emitting diode) systems. If recommended by the stain supplier, special options such as “additive lamps” that have small quantities of materials like gallium or iron can be used as well. For wood flooring, the final manufacturing step of applying the finish coatings really a series of separate manufacturing processes. In simple terms, it is analogous to applying several coats of paint. In reality, each coating has a distinct purpose. Every coat/cure station has a set of specifications that must be met. Figure 8 shows an example of a four station UV “flat line” finish system. Depending on the desired finish appearance, a line such as the one shown could have additional stations, or features. For example, the line shown has only roll type applicators. Stations could be substituted with spray modules, pre-metered applicators like curtains or slot die, or air knife applicators. Regardless of applicator type, there are common process control parameters including: temperature of the liquid finish, applicator type, line speed of conveyor, substrate temperature, and the final coating weight applied. Downstream from the applicator station are the same three steps described above for staining: leveling the coating, removal of carrier (water or solvent) if the coating is not a 100% solids system, and UV curing the coating. The discussion below assumes 100% solids for each of the coatings, since that would tend to optimize space, and minimize emissions and energy requirements. After application of each layer of the wet finish coating, that layer must be allowed to level as described above for the stain systems. Using control charts, individual coating layers and total thickness can be monitored to ensure SOPs are followed. Figure 9 illustrates this concept by monitoring the thickness of individual UV coating layers for a single product at a single plant. All applied coating thickness must lie between upper and lower process specifications. Figure 9 also illustrates how multiple plants can ensure thickness specifications are met for a product regardless of its manufacturing location. The use of radiometry to monitor UV processing has been a consistent message in RadTech publications over the years8, 9. For the example wood finish line in Figure 8, this holds true. For each finishing line UV station a set of UV cure parameters must be defined, and periodically measured and recorded. Key process variables include the number and type of UV lamp, the applied power, type of reflectors; distance between the UV source and the substrate, and the temperature of the substrate. These parameters are really the same parameters that must be tracked for any UV curing process. Successful monitoring can be accomplished by: x Providing each plant with modern UV radiometers and software x Implementing procedures to measure and record UV output x Monitoring energy UV output for each UV curing station x Performing a preventative maintenance to avoid potential problems. A course of action should be included in the plant SOP if the lamps are not operating within the UV range specified. Figure 10 shows an example of what happens if two lamps are off. The effect downstream could result in gloss being below specification. UV lamp uniformity across machine direction or length of bulb is another CTQ parameter that must be continuously monitored. UV output at both ends (AMD) of the web or product should fall within specified range. Failure to meet specifications can result in poor product performance downstream, e.g., gloss out of specification or cycles to taber wear-through below specification. To illustrate this concept, a plot of gloss across machine direction for a medium gloss product is illustrated in Figure 11. Although the gloss range falls within the process specification, the gloss of product on the end lanes shows a statistical decrease in gloss vs. end and middle lanes. A plot of UV energy density vs. inches across machine direction for a gloss setting lamp on the final cure UV lamp oven was constructed (UVA ). Product Quality Control Product Quality Control for inspection of finished product can be broken down into two primary elements: Color match and product performance. Color match The final test of a quality wood finish process is when product is inspected and boxed. All product is scrutinized by the inspection and boxing teams on the line. Armstrong facilities follow industry standard practices, mixed with proprietary systems and technology, to ensure the best possible match. The matching process actually starts with incoming raw material COAs (certificates of analysis) and QC to make sure that the applied stain is the correct color. Finished product is carefully inspected and compared to standards. Appropriate measurements such as gloss and smoothness are compared to specifications. Data from these processes are tracked using SPC and scorecard systems, and that data is periodically compared to customer satisfaction data. This information is reviewed constantly by manufacturing management, and presented in management reviews as a way to identify opportunities for improvement. Figures 12 and 13 show how matching the voice of the customer to statistical process contral can help ensure a more consistent color. Customers may understand that wood is a natural product, and may have intrinsic variation in color. However, as shown in the figure, differences can occur which are visible, and objectionable to customers. In Figure 13, SPC analysis shows how finsish line operators can track and adjust color if needed to meet customer expectations. Product Performance Plant quality control (QC) managers further inspect the flooring for a host of CTQs that include finish-related items. Finish CTQs include gloss level, crosshatch adhesion, coating cure and resistance to checking (Figure 14). Intervals for the different tests are defined by the ability of the plant to consistently pass the QC test. For the UV cured finish, statistical process control over the coating application weights and UV process parameters ensure that product durability, as measured by tests such as Taber Abrasion7, Gardner Scrub and Hoffman Scrape, can be performed at low frequency. Performing tests at the proper frequency, and documenting the results, allows plant QC managers to focus on operational activities and process improvement. This focus is what drives continuous improvement and increased productivity. And productivity is a key to keeping costs in line. This is very important because price to the customer is a key CTC attribute. Conclusions Quality improvements in UV finishing systems begin with CTC attributes, which can be combined with sigma mapping of manufacturing processes to identify inputs that effect CTQ attributes. Each process in the value map will have a set of process or material variables that can ultimately affect one of the key quality attributes. Each step in the process has input variables that must be controlled by SOPs and work instructions to reduce variation in the final product. The elements presented in this paper can be applied to other similar systems. One thing is for certain: the journey always begins and ends in the same place - with the customer. References: 1. 2. 3. 4. 5. 6. 7. 8. 9. William A. Mehler, Jr., Let The Buyer Have Faith, Publisher: Armstrong World Industries, Lancaster, Pa. 1987 J.Ross, G. Sigel, Title: Armstrong’s Wood Coatings Quality Journey, May\June Radtech Report 2006. J. Ross, Title: UV & EB in the Flooring Industry-Reducing Greenhouse GAS Emissions & HAPs, July/August 2007. G. Fitzel, Title: Sanding 101, Hardwood Floors, October/November 2008 H. Grivna, Title: Widebelt Sanding: Principles Data Source Process Optimization, 2005 Fundamentals of Color And Appearance Seminar, Gretag Macbeth Global Services. ASTM Test D4060-01. Title: Standard Test Method for Abrasion Resistance of organic Coatings by the Taber Abraser J. Raymont, Radiometers, The Best of Intentions, SGIA Journal, 3rd Quarter 2002, p39 R. W. Stowe, Title: Practical aspects of irradiance and energy density, RadTech Europe 1999, November 8-10, Berlin, Germany Gary Sigel May 24, 2010 Quality Improvements in UV Wood Finishing Historical of Armstrong Product Development Elements of Armstrong’s Wood Coating Quality Journey Finish Process Specifications Product Quality Control Conclusions Acknowledgements Quality Improvements in UV Wood Finishing Residential Tile Linoleum Sheet 1914 Laminate Wood 1998 Armstrong has a Long History of Understanding CTC Attributes Cork 1860 Figure 1: Armstrong’s History of Products “Let the Buyer Have Faith” Bruce – Armstrong– Robbins – HomerWood – Capella – Beverly, WV; Center, TX; Jackson, TN; Kunshan, China ; Somerset, KY; Statesville, NC; Titusville, PA; Vicksburg MS; West Plains, MS; Warren, AK; Plant Locations – Markets – Brands – Figure 2. Armstrong Entry Into Wood Markets, Brands and Plant Locations High End Tile Sheet Goods: roto type structures; 6' to 14' wide Solarian Tile Solarian Tile Wood 1992 1995 1996 1996 1996 Wood PE-Acrylate Solarian Tile 1980 1998 Sol-Gel Solarian Tile 1979 Triangle Pacific: Bruce, Hartco, Robins brands acquired by Armstrong Al2O3, UV urethane matrix EB Adhesive Duracote VII Duracote IV Duracote I Solarian Tile 1977 Description First UV coating Armstrong 1st UV coating, B1392A Bolgiano Application Solarian Tile Year 1976 Considered breakthrough coating; wear, scratch, stain resistance First polyester based UV Urethane acrylate oligomer optimized, Using modeling to design PE UV Polyester acrylate oligomer Superior wear and stain designed by using predictive modeling. resistance Coating inerted under nitrogen. Hybrid coating applied over Urethane Superior properties; Improved on Acrylate; Sol-Gel Epoxy system; cationic scratch and stain epoxy cure; cycloaliphatic diepoxides; No wax, improved on scuffing, scratching, maintenance No Wax, Improved wear, improved processing First UV moisture B stage system: PE urethane acrylate UV Urethane acrylate oligomer; CTC Attributes No Wax, Improved wear Chemistry Thiol-ene chemistry Triangle PacificArmstrong Armstrong Multiple UV coating vendors based on UV urethane acrylate chemistry. EB curable urethane acrylate. Significant improvement over Duracote IV Easier installation of tile, Armstrong EB curable adhesive on the back of tile improved adhesion Superior wear and scratch Use of refractory particles to compete resistance; S-33 Taber Triangle Pacific with laminate >1000cycles, Permion wearlayer Armstrong Armstrong Armstrong Armstrong Armstrong Vendor W. R. Grace Armstrong UV/EB Coating Historical Figure 3. Armstrong’s History of CTQ Attributes For UV/EB Wearlayers 7 Product Quality Control 8 Quality Audits 6 Statistical Process Control 9 New Product Development 5 Finishing Process Specifications The Quality Journey Starts And Ends With Customer 1 Customer Quality Requirements 4 Raw Material Purchasing Process 3 Manufacturing Equipment Specifications 2 Finishing System Requirements Figure 4. Elements of Armstrong’s Wood Quality Journey Figure 5. Wood Finishing Value Process Map Stain Appearance Darker With Medium Grit - Type of equipment - Grit sequence - Sandpaper vendor - Stock removal at each head - Color varies with grit How you control variation among sanders: Medium Fine Stock removal at each sander head: Rough Same grit sequence Figure 6. Feeding & Sanding Input ‘x’s That Effect CTQ’s Stain Roll Coater HMO & Stain Oven CTQ's Type of bulb color visual; soft & hard grain Defect free fibers Adhesion color uniformity Recognize Sources of Variation Stain skips shade appearance CTQ's Stain viscosity stain prep: match to shade COA nip pressure roller age dwell time x's UV Stain # of bulbs Bulb Power air change rate temperature roll type down pressure x's HMO x's Figure 7. Stain Process Inputs ‘x’s That Effect CTQ ‘y’s UV Lights UV Lights x's line speed roll type down pressure ctg temperature Coating weight Bulb type Reflector shape Power setting CTQ’s smoothness gloss adhesion HA Sealer Sealer UV Lights Wet-on-Wet Topcoats Low CTQ’s Affected • Adhesion • Gloss • Durability High Coating Too Brittle UV Cure Energy Coating Too Soft Optimum Cure Zone Input ‘x’s Can Have A Major Impact On Big ‘Y’ CTQ: UV Process Window B-Stage Lights Topcoat #1 Figure 8. Typical Four Station UV Finish Line Plant 3 Each Coat/Cure Station Has A Set of Specifications That Must Be Met Plant 1 Plant 2 Figure 9. Statistical Process Control Charts Plant 4 UV Cure Energy High Coating Too Brittle Stain Sealer 1 Sealer 2 Topcoat Final Topcoat 50 Gloss Gloss 60 What If Two Lamps Are Off? UV Measurement Drives Consistent Finish Quality How Armstrong improved & sustains a high quality UV finish process? • All plants are equipped with spectral radiometers to track UV lamp output. • SOPs and special training for operators • PM processes to minimize downtime and special cause events Low Coating Too Soft Optimum Cure Zone UV Process Window Figure 10. Process Quality Control 18.5 21.5 24.5 27.5 30.5 33.5 36.5 39.5 42.5 45.5 48.5 51.5 54.5 57.5 Relative Position Across Lamp UV Measurement Drives Consistent Finish Quality 80 85 90 95 100 105 Monitoring UV Lamp Uniformity AMD mJ/cm2 What If Lamp Uniformity Off? Figure 11. Statistical Process Control Charts For Plant Radiometry: AMD UV Output Must Be Uniform: CTQ Gloss Mj/cm2 Critical To Customer (CTQ) attributes for stain primarily focus on shade match inter plant and intra plant for same products made at multiple plants. To address variation that can exists between observers and qualitative observations made on shade match, Armstrong utilizes an objective color measurement system to reduce UV stain variation between plants. Figure 12. Voice of the Customer: Shade Match A Statistical Process Must Be Put In Place to Control Color Variation. Figure 13. Quality Color Metrics Must Be In Place To Ensure Stain Color Match Meets CTQ Attributes for UV stains . Color Gloss Coating Adhesion Durability Radiometry 2000 1500 1000 500 0 4 3 2 1 0 Structure 1 Structure 2 Structure 3 (mils) (mils) (mils) 2500 5 Effect of HAS Thickness on Taber Performance Figure 14. Product Quality Control HAS SEALER1 SANDING SEALER HAS SEALER2 1st Topcoat 2nd Topcoat 3rd Topcoat The elements presented in this paper can be applied to other similar systems. One thing is for certain: the journey always begins and ends in the same place- with the customer. Each step in the process has input variables that must be controlled by SOPs and work instructions to reduce variation in the final product. Each process in the value map will have a set of process or material variables that can ultimately affect one of the key attributes. The sigma process map presented began with sanding and ended with product quality control. Quality improvements in UV finishing systems begin with sigma attributes , which can be combined with sigma mapping of manufacturing processes to identify inputs that effect CTQ Conclusions
