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Metal and Ceramic Injection Molding

BCC Research
October 1, 2008
267 Pages - SKU: WA1926635

Abstract Table of Contents Related Reports

STUDY GOAL AND OBJECTIVES

BCC’s goal in conducting this study is to analyze the current status of the ceramic and metal injection molding (MIM) technology and business. The report covers both powder and liquid processes for metal injection molding. When referring to ceramic and/or metal powder injection molding, the term powder injection molding (PIM) is often used. The term thixo-molding is often used to refer to liquid metal injection molding. All of the processes have the injection molding machine in common, and are at times undertaken by the same companies, which may also be plastic injection molders. The report is designed to provide an overview of the current technology, new developments, business opportunities, and an assessment of the markets. The goals of this report are to:

Provide an overview of ceramic and metal injection molding technology.
Explain and forecast the rapid growth of Asian producers in the shifting global marketplace
Understand the current industry structure and future trends.
Analyze the business for potential new developments and trends.
Identify and analyze applications and markets for potential for growth of this technology and business.
Review and analyze the patents awarded over the past five years and assess technological trends.
Explain and forecast the economic pressures facing raw materials for these industries.
Describe the business problems facing the industry.

The study’s primary goal is to give readers a clear understanding of the ceramic and metal injection technology and business and growth potential over the next five years. BCC uses 2009 as the base year, since this report was completed in late 2008. Data for 2009 are forecast based on estimated, full 2008 data. The knowledge of both the market and technological trends will help companies prepare for future developments. The knowledge will be helpful in improving business strategies for growth and success in the marketplace.

REASON FOR DOING THE STUDY

Ceramic and metal injection molding is a near net shape manufacturing technology that is extremely cost effective in producing small complex parts. The technology is growing in importance as design engineers develop new components that require greater mechanical strength than offered by synthetic materials. Concurrently, there is a trend toward miniaturization. At the same time, there is an enormous drive to reduce costs. This has a two-pronged effect on ceramic and metal injection molding: 1) New designs combine functionality or eliminate processing steps, requiring a more complex design that can only be achieved through injection molding; 2) There are drives to boost scale, thus making injection molding a more attractive economic option than competing processes such as machining. Metal injection molding also has environmental advantages over casting, while also reducing energy costs.

Meanwhile, the technologies are vastly improving, particularly in the area of powder size. Better simulation and control systems are being commercialized for injection molding machines processing materials other than plastics. New furnaces also improve economies of scale for big-ticket markets, such as automotive. New standards have also opened bigger markets for ceramic and injection molding, which only started to become an important commercial industry in the last 15 years. The technology is being used to manufacture parts and components for the aerospace, automotive, electronics, telecommunications, consumer, medical, and dental industries.

When MIM technology was developed, there was significant excitement in the industry. Very high growth rates were projected and a significant number of companies came into being to utilize this technology. While initial projections were overblown, the industry has grown significantly. Growth rates slowed some in the 2006 to 2008 period because of soaring metals prices, a slowing auto market, and spotty economic conditions globally. BCC forecasts the industry is due for another growth spurt.

This is the first and only study to include ceramic and metal as powder injection molding, and to include thixo-molding for liquid metals, such as magnesium and aluminum. This is important because these parts are all made on the same equipment and compete in the same markets—sometimes even for the same parts. Any report that fails to include all three processes is inadequate.

BCC also is issuing this report because of significant changes taking place in the global industry structure. Powder injection molding was invented in the United States in the early 1970s by two engineers named Karl Zueger and Raymond E. Wiech, Jr. The United States had a strong lead, with Europe and Japan quickly following. Now the growth is shifting to China and other Asian countries. This report defines the trend and its impact on existing companies in the business.

INTENDED AUDIENCE

This report is extremely important to anyone currently in the metal or ceramic injection molding business: those who are considering entry to the market, investors in the marketplace, and those who will be strongly affected by the development of this sector. These groups are described below.

Engineers and business managers who are looking for cost-effective solutions to vexing performance or cost problems in products they are currently developing.
Engineers working for existing ceramic and metal injection molding companies. They can see how they stack up against the state-of-the art in design and manufacturing.
Entrepreneurs who will be able to identify new areas for application of this technology and thus use it to start new businesses. Particularly important in this category are plastic injection molders in the United States and Europe who are taking a beating from low prices, Asian competition, and declining demand.
The current manufacturers who use the PIM and thixo-molding manufacturing processes. They will understand the global nature of this business, the existing competition, the fluid nature of the industry structure as well as potential opportunities to use the technology to increase their PIM production and sales.
The businesses that will be able to understand the current industry structure and competition so as to identify threats and opportunities. This information will be useful to anyone considering an investment in the industry.
The report also provides information that would help a reader understand the MIM business and assist in evaluation of a new business plan, or evaluation of stock values of a publicly owned company that participates in the businesses such as BASF (BF on the New York Stock Exchange) or Precision Castparts (NYSE: PCP)..
Other individuals will also find this report valuable. Scientists and academia will use it to understand the business and identify the areas for research and training of personnel to support the industry.

CHAPTER ONE: INTRODUCTION: STUDY GOAL AND OBJECTIVES; REASONS FOR DOING THE STUDY; REASONS FOR DOING THE STUDY (CONTINUED); INTENDED AUDIENCE; SCOPE OF REPORT; SCOPE OF REPORT (CONTINUED); INFORMATION SOURCES; ANALYST’S CREDENTIALS; RELATED BCC REPORTS; BCC ONLINE SERVICES; DISCLAIMER
CHAPTER TWO: EXECUTIVE SUMMARY: EXECUTIVE SUMMARY
CHAPTER THREE: POWDER INJECTION MOLDINGINDUSTRY OVERVIEW: INTRODUCTION; THE PROCESS; POWDER PRODUCTION; FEEDSTOCK PREPARATION; INJECTION MOLDING; DEBINDING; SINTERING; DESIGNING FOR MIM; ADVANTAGES OF PIM; ADVANTAGES OF PIM (CONTINUED); DISADAVANTAGES OF PIM; PIM PRODUCT QUALITY; PIM PRODUCTS AND MARKET SECTORS
CHAPTER FOUR: POWDER INJECTION MOLDING TECHNOLOGY: INTRODUCTION; DESIGN OF THE PART AND INJECTION MOLD; DESIGN OF THE PART AND … (CONTINUED); METAL, CERAMIC AND ALLOY MATERIALS; ATOMIZATION (METALS); REDUCTION OF OXIDES (METALS); CARBONYL DECOMPOSITION (METALS); COMMINUTION (METALS); OTHER METHODS FOR METALS; FINE GRINDING (CERAMICS); CHEMICAL VAPOR DEPOSITION (CERAMICS); BINDERS; SOLVENT DEBINDING; FEEDSTOCKS; INJECTION MOLDING; DEBINDING; SINTERING; SINTERING (CONTINUED)
CHAPTER FIVE: PIM INDUSTRY STRUCTURE: INTRODUCTION; POWDER AND FEEDSTOCK MANUFACTURERS; MIM PARTS AND COMPONENTS MANUFACTURERS; SOLIDMICRON TECHNOLOGIES PTE. LTD., SINGAPORE; EQUIPMENT MANUFACTURERS; GLOBALIZATION; MIM INDUSTRY STRUCTURE; MARKET SIZE AND SHARES; INDUSTRY ASSOCIATIONS; INDUSTRY ASSOCIATIONS (CONTINUED); PIM RESEARCH LEADERS; PIM INDUSTRY STRUCTURE—SUMMARY; MIM INDUSTRY)
CHAPTER SIX: COMPETITIVE PROCESSES: CASTING; CONVENTIONAL POWDER METALLURGY; POWDER PRESSING; SOLID STATE SINTERING; CONTINUOUS POWDER PROCESSING; MACHINING; DIRECT MANUFACTURING; TRADITIONAL INJECTION MOLDING; LEAD REPLACEMENT; HEAVY COMPOUNDS; HYBRID PROCESSES
CHAPTER SEVEN: POWDER INJECTION MOLDING COMPANY PROFILES: ABBOTT FURNACE COMPANY; ACCELLENT INC.; ACELENT TECHNOLOGIES PTE LTD; ACUPOWDER INTERNATIONAL, LLC; ADVANCED CERAMETRICS, INC; ADVANCED MATERIALS TECHNOLOGIES PTE LTD; ADVANCED METALWORKING PRACTICES; ADVANCED POWDER PRODUCTS; ADVANCED TECHNOLOGY & MATERIALS CO.; ADVANTAGE METAL POWDERS, INC; AFFINITY INTERNATIONAL LLC (USA); AG MATERIALS INC; AKRON PORCELAIN & PLASTICS CO.; ALBEROX, A DIVISION OF MORGAN ADVANCED CERAMICS, INC.; ALCOA HOWMET; ALD VACUUM TECHNOLOGIES AG; ALLIANCE SA; AMERICAN CHEMET CORP; AMERICAN ORTHODONTICS; AMETEK, INC.—SPECIALTY METAL PRODUCTS DIV; AMPAL, INC. (USB); ARBURG GMBH CO KG; ARC SEIBERSDORF RESEARCH GMBH; ASBURY GRAPHITE MILLS, INC; ATC, INC; AVS, INC./ADVANCED VACUUM SYSTEMS; BASF CORP.; BASF EAST ASIA R. HQ LTD.; BASF AG; BONGEN TITANIUM CO., LTD; BRITT MANUFACTURING CO.; CABOT CORP.; CARPENTER POWDER PRODUCTS; CENTORR VACUUM INDUSTRIES; CERADYNE, INC.; CERAMET TECHNOLOGIES PTE LTD; CERAMCO, INC; C.I. HAYES; CENTER FOR INNOVATIVE SINTERED PRODUCTS; CERAMTEC NORTH AMERICA CORP.; CITIZEN WATCH CO.; CLARIANT PIGMENTS AND ADDITIVES DIVISION; CM FURNACES INC; CONTINUOUS METAL TECHNOLOGY, INC; COORSTEK; CORE-TECH, INC.; CPS TECHNOLOGIES CORP.; CREMER THERMOPROZESSANLAGEN GMBH; CYPRESS INDUSTRIES; DSH TECHNOLOGIES, LLC; DONCASTERS PRECISION CASTINGS; DOU YEE TECHNOLOGIES PTE LTD; DURON PLASTICS LTD; DYNAMIC ENGINEERING, INC; ECKA GRANULES OF AMERICA LP; EGIDE UK LTD; ELNIK SYSTEMS; EMIL BRÖLL GMBH & CO; ENGINEERED SINTERINGS & PLASTICS, INC.; EPSON ATMIX CORP; ETA SA MANUFACTURE HORLOGÈRE SUISSE; EVERSUN TECHNOLOGY CO., LTD; F.W. WINTER, INC. & CO; FLOMET LLC; FORM PHYSICS, LLC; FRAUNHOFER INSTITUTE; GKN SINTER METALS; GKN SINTER METALS GMBH (MIM); GOCERAM AB; H.C. STARCK, INC; HERBERT KUGELE; HITACHI METALS AMERICA LTD.; HITACHI METALS LTD.—SPECIALTY STEEL COMPANY; HOEGANAES CORP; HOPTEC GROUPE FORSYM; INCO SPECIAL PRODUCTS; INDO-US MIM TEC PVT. LTD; INETI; INJECTAMAX CORP.; INSTITUT FÜR WERKZEUGMASCHINEN AND BETRIEBSTECHNIK; INTERNATIONAL SPECIALTY PRODUCTS (ISP); ITB PRECISIETECHNIEK; KINETICS, INC.; KLÄGER SPRITZGUSS GMBH & CO; LATITUDE MANUFACTURING TECHNOLOGIES; LEISTRITZ CORP.; MATERIALS PROCESSING INC; MATHSON INDUSTRIES, INC; MAXON MOTOR AG; MEGAMET SOLID METALS, INC; METAL POWDER PRODUCTS CO; METAOR; MICROCERAM; MIMECRISA; MIMFLOW TECHNOLOGIES LLC; MIMFORMS LLC; MIMITALIA SRI; MKS KUNSTSTOFFSPRITZGUSS GMBH; MMG ENGINEERED COMPONENTS; MOMENTIVE PERFORMANCE MATERIALS INC; MORGAN TECHNICAL CERAMICS; NANOVAL GMBH & CO. KG; NEGRI BOSSI; NETSHAPE TECHNOLOGIES; NIPPON ATOMIZED METAL POWDERS CORP.; NOVAMET SPECIALTY PRODUCTS CORP.; OBE OHNMACHT & BAUMGARTNER GMBH & CO.; OM GROUP, INC; ONISHI LITE INDUSTRY CO., LTD.; ORTHO ORGANIZERS, INC.; PARMATECH CORP.; PCC-AFT.; PELTSMAN CORP.; PHILLIPS PLASTICS CORP.; PHILLIPS PLASTICS CORP. (CONTINUED); POLYALLOYS INJECTED METALS; POLYMER TECHNOLOGIES, INC.; PORITE TAIWAN CO. LTD; PRECIMED S.A.; QUEBEC METAL POWDERS LTD; QINETQ NANOMATERIALS LTD; RAPIDUS USA, LLC; RAUSCHERT TECHNICAL CERAMICS; REMINGTON ARMS COMPANY, INC; RETCO TOOL CO; RIFMET LTD.; ROCKY MOUNTAIN ORTHODONTICS; RPM ENGINEERING CORP.; RYER, INC.; SAFFROSHINE ORGANICS PVT. LTD.; SANDVIK OSPREY LTD.; SCHUNK SINTERMETALLTECHNIK GMBH; SCM METAL PRODUCTS, INC.; SEMBACH GMBH & CO KG; SHANDONG JINZHU POWDER INJECTION MANUFACTURE CO.; SHANGHAI FUTURE HI-TECH CO., LTD; SINTER METAL TECHNOLOGIES; SINTEZ RUS MIM; SMALL PRECISION TOOLS; SMITH METAL PRODUCTS; SOLIDMICRON TECHNOLOGIES PTE. LTD; SSI TECHNOLOGIES, INC; SUN STAR INC; SUMITOMO METAL MINING CO., LTD; SUPERIOR TECHNICAL CERAMICS CORP.; TAISEI KOGYO CO., LTD.; TAIWAN SINTERED METALS CO. LTD.; TEIBOW CO., LTD.; THERMAL TECHNOLOGY, INC.; THYSSENKRUPP PRESTA AG; TIJET MEDIZINTECHNIK GMBH; TLS TECHNIK GMBH & CO; TOHNO SEIMITSU CO., LTD.; TOPMIM INTERNATIONAL; ULTRAFINE POWDER TECHNOLOGY, INC.; UNITED STATES BRONZE POWDERS, INC; UTRON, INC; WESTLAND CORP; WITTMANN-BATTENFELD; WITTMAN-BATTENFELD OF AMERICA, INC; WORLD CLASS TECHNOLOGY; ZOLLERN-MIMTEC; ZSCHIMMER & SCHWARZ GMBH & CO
CHAPTER EIGHT: PIM MATERIALS: INTRODUCTION; PRODUCTION OF POWDERS; SOLID-STATE REDUCTION; ATOMIZATION; ELECTROLYSIS; CHEMICAL; PIM MATERIALS; STAINLESS STEELS; Martensitic Stainless Steels; Ferritic Stainless Steels; Austenitic Stainless Steels; LOW ALLOY STEELS; NICKEL AND NICKEL ALLOYS; CONTROLLED EXPANSION ALLOYS; COBALT AND COBALT ALLOYS; COPPER AND COPPER ALLOYS; RHENIUM; TITANIUM; TUNGSTEN; ALUMINUM; MARKET SHARES OF CERAMICS, METALS AND ALLOYS; MIM ECONOMIC ISSUES; STAINLESS STEEL; CARBON STEEL; TUNGSTEN; COPPER; NICKEL; Nickel (Continued)
CHAPTER NINE: CERAMIC MATERIALS: ENGINEERING PROFILES; ALUMINA (AL2O3, 99.8% PURE ALUMINA); ALUMINA (AL2O3, 96% PURE ALUMINA); ZIRCONIA-TOUGHENED ALUMINA (AL2O3 + STABILIZED ZRO2); ZIRCONIA (ZRO2, Y2O3-STABILIZED); CERAMIC ECONOMIC PROFILES; ALUIMINA; ZIRCONIA
CHAPTER TEN: MARKETS AND APPLICATIONS: OVERVIEW; MARKET POTENTIAL; WIDE RANGE OF MARKETS; COST EFFECTIVENESS; NEW PRODUCT DEVELOPMENT; COST-EFFECTIVE TECHNOLOGY FOR POWDER PRODUCTION; MARKETS FOR PIM COMPONENTS; MARKET SIZE; METAL INJECTION MOLDING; AUTOMOTIVE; Automotive (Continued); CONSUMER PRODUCTS; Consumer Products (Continued); MECHANICAL; MEDICAL; REGIONAL FACTORS; CERAMIC INJECTION MOLDING; INVESTMENT CASTING CORES; CONSUMER PRODUCTS; MEDICAL; Medical (Continued); IT/OFFICE AUTOMATION; INDUSTRIAL/MECAHNICAL; REGIONAL FACTORS
CHAPTER ELEVEN: POWDER INJECTION MOLDING PATENT ANALYSIS
CHAPTER TWELVE: POWDER INJECTION MOLDING PATENT ABSTRACTS: U.S. PATENT NO. 7,387,763; U.S. PATENT NO. 7,368,515; U.S. PATENT NO. RE40,273; U.S. PATENT NO. 7,361,995; U.S. PATENT NO. 7,351,765; U.S. PATENT NO. 7,351,371; U.S. PATENT NO. 7,347,968; U.S. PATENT NO. 7,335,696; U.S. PATENT NO. 7,303,722; U.S. PATENT NO. 7,288,222; U.S. PATENT NO. 7,285,088; U.S. PATENT NO. 7,279,126; U.S. PATENT NO. 7,275,896; U.S. PATENT NO. 7,275,329; U.S. PATENT NO. 7,259,219; U.S. PATENT NO. 7,259,212; U.S. PATENT NO. 7,237,730; U.S. PATENT NO. 7,235,211; U.S. PATENT NO. 7,232,473; U.S. PATENT NO. 7,199,211; U.S. PATENT NO. 7,199,174; U.S. PATENT NO. 7,192,546; U.S. PATENT NO. 7,189,277; U.S. PATENT NO. 7,183,360; U.S. PATENT NO. 7,172,725; U.S. PATENT NO. 7,172,333; U.S. PATENT NO. 7,163,569; U.S. PATENT NO. RE39,445; U.S. PATENT NO. 7,144,957; U.S. PATENT NO. 7,134,345; U.S. PATENT NO. 7,132,479; U.S. PATENT NO. 7,131,597; U.S. PATENT NO. 7,126,276; U.S. PATENT NO. 7,117,596; U.S. PATENT NO 7,103,981; U.S. PATENT NO. 7,097,393; U.S. PATENT NO. 7,094,821; U.S. PATENT NO. 7,063,815; U.S. PATENT NO. 7,052,710; U.S. PATENT NO. 7,036,550; U.S. PATENT NO. 7,036,227; U.S. PATENT NO. 7,018,583; U.S. PATENT NO. 6,997,401
CHAPTER THIRTEEN: LIQUID METAL INJECTION MOLDING: THIXO-MOLDING; INTRODUCTION; TECHNOLOGY; TECHNOLOGY (CONTINUED); COMMERICAL ISSUES; THIXO CHALLENGES; NEW TECHNOLOGY; XYLOY MOLDING
CHAPTER FOURTEEN: LIQUID INJECTION MOLDING COMPANY PROFILES: AB COMPONENTS; ADVANCED FORMING TECHNOLOGY—A DIVISION OF PRECISION CASTPARTS CORP; ADVANCED PROCESSING & MATERIALS; COOL POLYMERS; DATUMAG INC.; EF TECHNOLOGY (KUNSHAN) LTD; FCMP; G-MAG INTERNATIONAL; G-MAG EUROPE GMBH; HONG YA INDUSTRIAL; HUSKY INJECTION MOLDING SYSTEMS; JSW PLASTICS MACHINERY, INC; JURONG HUA-YE NEW TECHNOLOGY INDUSTRY CO. LTD; MG PRECISION; NEUE MATERIALIEN FUERTH GMBH; NISSEI PLASTIC INDUSTRIAL CO. LTD; NYPRO, INC.; PARKWAY PRODUCTS; PHILLIPS PLASTICS; PLUSTECH INC.; RAYCON INDUSTRIES, INC.,; SHANGHAI ZIYAN ALLOY TECHNOLOGY CO. LTD.; SIRRIS; TENMA CORPORATION; THIXOMAT; TOYO KAKO CO., LTD.; TOYOTA BOSHOKU CORP; VUJANOVIC HOLDING B.V; WAFFER; YAMAHA FINE TECHNOLOGIES; YORK IMPERIAL PLASTICS
CHAPTER FIFTEEN: LIQUID INJECTION MOLDING PATENT ABSTRACTS: U.S. PATENT NO. 7,341,094; U.S. PATENT NO. 7,343,959; U.S. PATENT NO. 7,353,858; U.S. PATENT NO. 7,331,375; U.S. PATENT NO. 7,237,594; U.S. PATENT NO. 7,232,305; U.S. PATENT NO. 7,163,046; U.S. PATENT NO. RE39,291
CHAPTER SIXTEEN: MAJOR CHALLENGES: MAJOR CHALLENGES; MAJOR CHALLENGES (CONTINUED); MAJOR CHALLENGES (CONTINUED)
APPENDIX: GLOSSARY OF TERMS: GLOSSARY OF TERMS; GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED); GLOSSARY OF TERMS (CONTINUED)
LIST OF TABLES: SUMMARY TABLE 1 GLOBAL SALES OF MIM COMPONENTS; (POWDER) BY REGION, THROUGH 2014 ($ MILLIONS); SUMMARY TABLE 2 GLOBAL SALES OF CIM COMPONENTS BY; REGION, THROUGH 2014 ($ MILLIONS); SUMMARY TABLE 3 LIQUID METAL MOLDING REVENUES BY; REGION, THROUGH 2014; TABLE 1 ADVANTAGES OF POWDER INJECTION MOLDING; TABLE 2 DISADVANTAGES OF POWDER INJECTION MOLDING; TABLE 3 COMPARISON OF METAL INJECTION MOLDING WITH; SELECTED METAL FORMING TECHNOLOGIES; TABLE 4 METAL INJECTION MOLDED PRODUCTS BY MARKET; SECTORS; TABLE 5 A COMPARISON OF WATER AND GAS ATOMIZATION; PROCESSES; TABLE 6 FEEDSTOCKS FOR PIM; TABLE 7 MAJOR FIRMS SUPPLYING POWDERS AND; FEEDSTCOKS TO THE MIM INDUSTRY; TABLE 8 MAJOR NORTH AMERICAN FIRMS; MANUFACTURING PIM PARTS AND COMPONENTS; TABLE 9 MAJOR NON-U.S. FIRMS MANUFACTURING MIM; PARTS AND COMPONENTS; TABLE 10 MAJOR COMPANIES SUPPLYING EQUIPMENT TO THE PIM; COMPONENT MANUFACTURERS; TABLE 11 PIM CAPACITY AND MARKET SIZE BY GEOGRAPHICAL; REGION, 2009 ($ MILLIONS); TABLE 12 GLOBAL SALES OF PIM COMPONENTS BY REGION,; THROUGH 2014 ($ MILLIONS); TABLE 13 SALES AND MARKET SHARE OF MAJOR MIM COMPANIES; IN THE NORTH AMERICAN MIM MARKET, 2009 ($ MILLIONS, %); TABLE 14 SALES AND MARKET SHARES OF MAJOR MIM COMPANIES; IN THE JAPANESE MIM MARKET, 2009 ($ MILLIONS, %); TABLE 15 SALES AND MARKET SHARES OF MAJOR ASIAN MIM; COMPANIES, EXCLUDING JAPAN, 2009 ($ MILLIONS, %); TABLE 16 SALES AND MARKET SHARES OF MAJOR EUROPEAN MIM,; 2009 ($ MILLIONS, %); TABLE 17 GLOBAL SALES AND MARKET SHARES OF MAJOR MIM; COMPANIES, 2009 ($ MILLIONS, %); TABLE 18 NORTH AMERICAN POWDER SHIPMENTS BY; TYPE OF MATERIAL AND PRODUCTION FOR MIM,; THROUGH 2014 (SHORT TONS); TABLE 19 PIM MATERIALS; TABLE 20 ALLOYS USED IN MIM STEELS; TABLE 21 NOMINAL COMPOSITIONS OF SOME STAINLESS STEELS,; WT %; TABLE 22 THE TYPE OF STAINLESS STEELS AND THEIR MIM USES; IN MEDICAL INSTRUMENTS; TABLE 23 TITANIUM AND TI-6AL-4V ALLOY COMPOSITIONS, WT %; TABLE 24 SHARE OF MIM MARKET BY METALS AND ALLOYS, 2009; AND 2014 (%); TABLE 25 HISTORICAL AND FORECAST PRICES OF MIM METALS,; THROUGH 2014 ($/LB, AVERAGE FOR A YEAR); TABLE 26 SHARE OF CIM MARKET BY MATERIALS, 2009 AND 2014 (%; SALES VALUE); TABLE 27 ENGINEERING PROFILE OF ALUMINA (99.8%); TABLE 28 ENGINEERING PROFILE OF ALUMINA (96%); TABLE 29 ENGINEERING PROFILE OF ZIRCONIA-TOUGHENED; ALUMINA; TABLE 30 ENGINEERING PROFILE OF ZIRCONIA-TOUGHENED; ALUMINA; TABLE 31 HISTORICAL AND FORECAST PRICES OF CERAMIC; MATERIALS (DOLLARS PER METRIC TON); TABLE 32 FACTORS CONTRIBUTING TO GROWTH OF PIM; COMPONENTS; TABLE 33 GLOBAL SALES OF MIM COMPONENTS BY MARKET; SECTORS, THROUGH 2014 ($ MILLIONS); TABLE 34 MIM SALES BY REGIONAL MARKET, 2009 ($ MILLIONS); TABLE 35 GLOBAL SALES OF CIM COMPONENTS BY MARKET; SECTOR, THROUGH 2014 ($ MILLIONS); TABLE 36 CIM SALES BY REGIONAL MARKET, 2009 AND 2014 ($; MILLIONS); TABLE 37 LIQUID INJECTION MOLDING METAL MATERIALS; TABLE 38 HOW MAGNESIUM PROERITES STACK UP AGINST KEY; COMPETITORS; TABLE 39 INSTALLED BASE, THIXO-MOLDING MACHINES BY; REGION, THROUGH 2014 (UNITS); TABLE 40 INSTALLED BASE, THIXO-MOLDING MACHINES BY; REGION, THROUGH 2014 (METRIC TONS OF CAPACITY); TABLE 41 MATERIAL CONTENT PER CAR (VEHICLES, EXCLUDING; TRUCKS) (POUNDS); TABLE 42 HISTORICAL AND PROJECTED COSTS FOR; MAGNESIUM VERSUS KEY COMPETITORS (DOLLARS; PER POUND); TABLE 43 MELTING POINTS OF METALS
LIST OF FIGURES: SUMMARY FIGURE REGIONAL PERCENTAGE SHARE OF SALES OF; MIM COMPONENTS, 2009 AND 2014 (%); FIGURE 1 GLOBAL SALES OF PIM COMPONENTS BY REGION, 2009; AND 2014 ($ MILLIONS); FIGURE 2 MARKET SHARE OF MAJOR COMPANIES IN THE NORTH; AMERICAN MIM MARKET, 2009 (%); FIGURE 3 MARKET SHARE OF MAJOR COMPANIES IN THE; JAPANESE MIM MARKET, 2009 (%); FIGURE 4 SHARE OF MIM MARKET BY METALS AND ALLOYS, 2009; (%); FIGURE 5 HISTORICAL AND FORECAST PRICES OF MIM METALS,; 2005-2014 ($/LB, AVERAGE FOR A YEAR); FIGURE 6 SHARE OF CIM MARKET BY MATERIALS, 2009 AND 2014 (%; SALES VALUE); FIGURE 7 GLOBAL SALES OF MIM COMPONENTS BY MARKET; SECTORS, 2009 (%); FIGURE 8 GLOBAL SALES OF CIM COMPONENTS BY MARKET; SECTORS, 2009 (%); FIGURE 9 GLOBAL SALES OF CIM COMPONENTS BY REGION, 2009; FIGURE 10 TREND IN U.S. PATENTS FOR POWDER INJECTION; MOLDING, 2002-2007 (NUMBER OF PATENTS AWARDED; ANNUALLY); FIGURE 11 U.S. PATENTS AWARDED BY REGION IN 2007 AND FIRST; 6 MONTHS OF 2008 (%); FIGURE 12 INSTALLED BASE, THIXO-MOLDING MACHINES BY; REGION, 2009 AND 2014 (%)

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