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市場調查報告書

層積造型 (AM:Additive Manufacturing) 的鈦市場機會:2017年

Titanium Opportunities in Additive Manufacturing - 2017

出版商 SmarTech Markets Publishing LLC 商品編碼 343017
出版日期 內容資訊 英文 89 Pages
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層積造型 (AM:Additive Manufacturing) 的鈦市場機會:2017年 Titanium Opportunities in Additive Manufacturing - 2017
出版日期: 2016年11月30日 內容資訊: 英文 89 Pages
簡介

本報告提供層積造型 (AM:Additive Manufacturing) 上鈦的市場機會相關調查,提供您主要終端用戶產業上的金屬AM與鈦利用趨勢,各種AM技術與鈦金屬粉利用趨勢,並彙整供應鏈與主要企業,金屬3D列印硬體設備的年度銷售台數·成長率·用戶數(裝機量),AM用鈦粉末的需求·收益之10年預測 (各產業) 等資料。

第1章 金屬·鈦層積造型市場的狀況:12個月的檢討

  • 影響鈦需求的金屬層積造型主要趨勢
    • 品質保證主張
    • 零件檢驗流程
    • 金屬AM專用印刷準備&模擬軟體
  • 市場·用途的追蹤調查:AM鈦零組件和主要市場上價值
    • 航太產業上金屬AM和鈦
    • 整形外科部門的金屬AM和鈦
    • 牙科部門的金屬AM和鈦
    • 汽車·運輸產業上金屬AM和鈦
  • 層積造型供應鏈的鈦粉末
  • 本章的要點

第2章 層積造型技術和鈦金屬粉的活用

  • AM技術用鈦粉末的主要特徵
    • AM用球狀鈦金屬粉的一般必要條件
  • 金屬粉體熔化成型技術技術和相關的金屬粉製造相關考察
    • 雷射金屬粉體熔化成型技術
    • 電子束金屬粉體熔化成型技術
  • 定向能源系統 (Blown Powder) 和相關的金屬粉製造相關考察
  • 線型定向能源累積技術與市場相關考察
  • 層積造型用鈦粉末的終端用戶相關考察
  • 本章的要點

第3章 層積造型用鈦木材分析:製造法·企業·供應鏈

  • 鈦粉末供應鏈相關考察
  • 利用鈦粉末的層積造型法
    • 氣體噴霧
    • 等離子噴霧
    • 新的造型法
  • AM產業上競爭鈦材料
  • 有影響力的AM用鈦粉末供應商·經銷商·市場佔有率分析
    • AP&C
    • GKN Hoeganaes
    • LPW Technology
    • Metalysis
    • Praxair Surface Technologies
    • Puris, LLC
    • Tekna
    • 大阪chitaniumutekunorojizu
    • Pyrogenesis
    • H.C. Starck
    • ATI Metals Corp.
    • Z3DLab

第4章 層積造型用鈦粉末的10年預測:摘要

  • 預測手法檢討
  • 金屬3D列印硬體設備的預測
    • 年度銷售台數·市場成長率
    • 用戶數(裝機量)
  • 鈦粉末需求·收益:各產業
    • 航太
    • 汽車
    • 醫療
    • 牙科
    • 服務局·珠寶·其他

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目錄
Product Code: SMP-AM-TI2017-1116

SmarTech Publishing was the first industry analysis firm to publish a report on the market opportunities emerging from additively manufactured titanium. In this story, we bring the story up to date with a full analysis on the markets for of AM utilizing metal powders and other titanium feedstocks in modern commercial additive manufacturing systems.

We believe that titanium printing is becoming the largest opportunity for metal additive manufacturing materials, with revenues exceeding all other alloy groups used in metal AM over the next ten-year period. Sought after primarily for its high strength to weight ratio, biological inertness, and other desirable properties when combined with additive layer manufacturing, titanium alloys are burgeoning in the medical, aerospace, automotive, dental, and consumer products industries.

With GE purchasing a controlling share in one of the largest titanium additive manufacturing companies in the world, and thus gaining a significant stake in the supply chain for titanium powders used in additive manufacturing systems, the titanium supply chain has been thrust into short term uncertainty. The market is responding to significantly increased demand for high quality, traceable, and exceptionally pure titanium materials for additive manufacturing, with a number of new market entrants having taken place in 2016 and more planned for 2017. Capacity expansions at existing leaders in the titanium powder supply chain are underway, thus creating a chaotic future scenario with potentially over a billion dollars on the line in the future.

As a specialty study in a specific material, this report presents our latest -- and highly granular -- market forecast data as well as critical market analysis for use of titanium in key industries adopting AM, as well as considerations for the future adoption and use in other applications. The primary opportunity factors related to the broader supply chain, primary providers of AM titanium powder and other forms, and analysis of the print technologies and powder production processes all combine to help business development and strategy professionals determine how to focus their efforts in titanium powder, parts, and print technologies.

Table of Contents

Chapter One: State of Metal and Titanium Additive Manufacturing Market-Trailing Twelve-Month Review

  • 1.1 Key Trends in Metal Additive Manufacturing Influencing Demand for Titanium
    • 1.1.1 Development of Quality Assurance Initiatives in Metal AM
    • 1.1.2 Development of Part Testing Processes for Titanium Components Made via Metal AM
    • 1.1.3 Development of Metal AM-Specific Print Preparation and Simulation Software
  • 1.2 Market and Application Tracking - Additively Manufactured Titanium Components and Their Value in Key Markets
    • 1.2.1 Metal AM and Titanium in Aerospace
      • 1.2.1.1 Titanium Aluminide Additive Manufacturing in Aerospace
      • 1.2.1.2 Titanium Helping Drive Metal AM in Aerospace Beyond Aircraft Engine Applications
      • 1.2.1.3 Military and Space Segments Driving Increased Titanium AM Demand in 2016
    • 1.2.2 Metal AM and Titanium in Orthopedics Stronger Than Previously Projected
    • 1.2.3 Metal AM and Titanium in Dentistry
      • 1.2.3.1 Applying Titanium Additive Manufacturing Technology to the Increasing Dental Implant Market
      • 1.2.3.2 New Dental Application Segment for Oral Appliance Therapy Sleep Apnea Devices Being Dominated by Titanium
    • 1.2.4 Metal AM and Titanium in Automotive and Transportation
      • 1.2.4.1 New 3D Print-Enabled Automotive Design and Manufacturing Platforms Could Bring Metal AM to New Heights in Transportation
      • 1.2.4.2 Metal AM in Automotive Being Driven by Demand for Aluminum and Steel During the Short Term
  • 1.3 Titanium Powder for Additive Manufacturing Supply Chain in Transition Phase
    • 1.3.1 GE Acquisitions Throw Titanium Powder Capacity into Question
    • 1.3.2 Metal Powder Market Surging to Fill in Capacity Gaps for Titanium Powder in AM
    • 1.3.3 Summary of Latest Market Projections for Titanium Metal Powder Demand
  • 1.4 Key Points from this Chapter

Chapter Two: Additive Manufacturing Technologies and Utilization of Titanium Metal Powders

  • 2.1 Primary Titanium Powder Characteristics for AM Technology
    • 2.1.1 General Requirements for Spherical Titanium Metal Powders for AM
  • 2.2 Metal Powder Bed Fusion Technology and Related Metal Powder Production Considerations
    • 2.2.1 Laser-Based Metal Powder Bed Fusion
    • 2.2.2 Electron Beam-Based Metal Powder Bed Fusion
  • 2.3 Blown Powder Directed Energy Systems and Related Metal Powder Production Considerations
  • 2.4 Wire-Based Directed Energy Deposition Technology and Market Considerations
  • 2.5 End-User Considerations for Titanium Powder in Additive Manufacturing
    • 2.5.1 Increasing Demand for Titanium Powder with Technical Performance Standards
    • 2.5.2 End-User Considerations for Use of Titanium Additive Manufacturing in Medical Markets
      • 2.5.2.1 Powder Bed Fusion in Implants Increasingly Fragmented, Hold Implications for Titanium Powder Production
      • 2.5.2.2 Competition in Orthopedic Implants from Outside the Metals Segment
  • 2.6 Key Points From this Chapter

Chapter Three: Analysis of Titanium Materials for Additive Manufacturing - Production Methods, Players, and Supply Chain

  • 3.1 Supply Chain Considerations for Titanium Powder
  • 3.2 Production Methods for Titanium Powder for AM
    • 3.2.1 Gas-Based Atomization Methods
    • 3.2.2 Plasma-Based Atomization Methods
    • 3.2.3 Emerging AM Powder Production Methods
      • 3.2.3.1 Electrolysis (Metalysis)
      • 3.2.3.2 Experimental Processes
  • 3.3 Competing Titanium Materials in the AM Industry
    • 3.3.1 Titanium Versus Nickel Superalloys, Cobalt Chrome, and Aluminum in AM
  • 3.4 Influential AM Titanium Powder Suppliers, Resellers, and Market Share Analysis
    • 3.4.1 AP&C
    • 3.4.2 GKN Hoeganaes
    • 3.4.3 LPW Technology
    • 3.4.4 Metalysis
    • 3.4.5 Praxair Surface Technologies
    • 3.4.6 Puris, LLC
    • 3.4.7 Tekna
    • 3.4.8 Osaka Titanium
    • 3.4.9 Pyrogenesis
    • 3.4.10 H.C. Starck
    • 3.4.11 ATI Metals Corp.
    • 3.4.12 Z3DLab

Chapter Four: Summary of Ten-Year Forecasts for Titanium Powders in Additive Manufacturing

  • 4.1 Methodology Review
  • 4.2 Metal 3D Printing Hardware Forecasts
    • 4.2.1 Annual Unit Sales and Market Growth
    • 4.2.2 Install Base
  • 4.3 Titanium Powder Demand and Revenues by Vertical Industry
    • 4.3.1 3D-Printed Titanium in Aerospace
    • 4.3.2 3D-Printed Titanium in Automotive
    • 4.3.3 3D-Printed Titanium in Medical
    • 4.3.4 3D-Printed Titanium in Dentistry
    • 4.3.5 3D-Printed Titanium in Service Bureaus, Jewelry, and Other Applications

About SmarTech Publishing

About the Analyst

Acronyms and Abbreviations Used In this Report

List of Exhibits

  • Exhibit 1-1: Top Short-Term 3D Print Material Opportunities for Commercial Aerospace and General Aviation
  • Exhibit 1-2: Total Titanium Mix in Aerospace 3D Printing Applications - Multi-Year Evolution
  • Exhibit 1-3: Beneficial Traits of 3D-Printed Orthopedic Implants
  • Exhibit 1-4: Total Projected AM Titanium Powder Demand Comparison, Medical Applications, 2014-2024
  • Exhibit 1-5: Total Printed Dental Implant Components Opportunity, 2015-2025
  • Exhibit 1-6: Total Projected Sleep Related Oral Appliance Therapy Devices Printed, 2015-2025
  • Exhibit 1-7: Total Projected AM Metal Powder Demand (All Alloy Groups and Technologies), Automotive Applications, 2015-2026
  • Exhibit 1-8: Total Projected 3D-Printed Titanium Metal Powder Demand, 2014-2026 (tons)
  • Exhibit 1-9: Total Projected 3D-Printed Titanium Metal Powder Revenue, 2014-2026
  • Exhibit 2-1: Current Metal Additive Manufacturing Technology Hierarchy
  • Exhibit 2-2: Laser Metal Powder Bed Fusion System Parameters
  • Exhibit 2-3: Electron-Based Powder Bed Fusion System Parameters
  • Exhibit 2-4: Powder-Based Directed Energy Deposition System Parameters
  • Exhibit 2-5: Total Projected Wire Versus Powder Metal AM System Install Base, Global, 2015-2025
  • Exhibit 2-6: Total Projected AM Wire Versus Powder Titanium Alloy Shipments, Global, 2015-2025
  • Exhibit 2-7: Wire-Based AM Industry Demand Comparison
  • Exhibit 2-8: 3D Printable Implant Material Comparison
  • Exhibit 2-9: Titanium versus PEKK Orthopedic Implant Material Revenue Mix ($US Millions) - 2014-2024
  • Exhibit 3-1: AM Metal Powder Production Process Flow
  • Exhibit 3-2: Comparison of Titanium Powder Production Techniques for Use in Additive Manufacturing
  • Exhibit 3-3: Currently Available Specialty Titanium Alloys for AM
  • Exhibit 3-4: Potential Future Specialty Titanium Alloys for AM
  • Exhibit 4-1: Total Projected Annual Metal 3D Printing System Unit Sales, by Technology - 2015-2026
  • Figure 4-2: Total Projected Metal System Install Base, by Technology - 2015-2026
  • Figure 4-3: Total Annual Titanium Metal Powder Demand, by Type - Aerospace Industry, 2014-2026
  • Figure 4-4: Total Annual Titanium Metal Powder Revenue, Aerospace Industry - 2014-2026
  • Exhibit 4-5: Total Annual Titanium Metal Powder Demand by Type, Automotive Industry - 2014-2026
  • Exhibit 4-6: Total Annual Titanium Metal Powder Revenue, Automotive Industry - 2014-2026
  • Exhibit 4-7: Total Annual Titanium Metal Powder Demand by Type, Medical Industry - 2014-2026
  • Exhibit 4-8: Total Annual Titanium Metal Powder Revenue, Medical Industry - 2014-2026
  • Exhibit 4-9: Total Annual Titanium Metal Powder Demand, Dental Industry - 2014-2026
  • Exhibit 4-10: Total Annual Titanium Metal Powder Revenue, Dental Industry - 2014-2026
  • Exhibit 4-11: Total Annual Titanium Metal Powder Demand, Non-Specialty Service Bureaus - 2014-2026
  • Exhibit 4-12: Total Annual Titanium Metal Powder Revenue, Non-Specialty Service Bureaus - 2014-2026
  • Exhibit 4-13: Total Annual Titanium Metal Powder Demand, Jewelry Industry - 2014-2026
  • Exhibit 4-14: Total Annual Titanium Powder Demand, Other Industries -2014-2026
  • Exhibit 4-15: Total Annual Titanium Powder Revenue, Other Industries -2014-2026
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