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3D印刷・付加製造の世界市場 (2020-2030年):COVID-19版

3D Printing and Additive Manufacturing 2020-2030: COVID Edition

出版日: | 発行: IDTechEx Ltd. | ページ情報: 英文 124 Slides | 納期: 即日から翌営業日

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3D印刷・付加製造の世界市場 (2020-2030年):COVID-19版
出版日: 2020年07月28日
発行: IDTechEx Ltd.
ページ情報: 英文 124 Slides
納期: 即日から翌営業日
  • 全表示
  • 概要
  • 目次
概要

新型コロナウイルス感染症 (COVID-19) の影響にもかかわらず、世界の3D印刷の市場は2030年には450億米ドルの規模に成長すると予測されています。

当レポートでは、世界の3D印刷・付加製造の市場を調査し、市場の定義と概要、主な印刷技術の概要・動向、プリンターの性能比較、技術開発の展望、主要産業における用途、利用事例、技術別の収益予測、主要企業のプロファイルなどをまとめています。

第1章 エグゼクティブサマリー

第2章 イントロダクション

第3章 ポリマー印刷プロセス

  • 粉末床溶融結合:選択的レーザー焼結(SLS)
  • バインダージェッティング:ポリマーバインダージェッティング
  • 押し出し:熱可塑性樹脂(TPE)
  • バット光重合:ステレオリソグラフィー(SLA)
  • バット光重合:デジタル光処理(DLP)
  • 材料噴射
  • シート積層:積層オブジェクト製造(LOM)

第4章 ポリマープリンター:比較

  • 価格:印刷プロセス別
  • 数量:印刷プロセス別
  • 精度:印刷プロセス別精
  • 価格・速度
  • 価格・精度
  • 価格・数量
  • 数量・精度
  • 数量・速度

第5章 金属印刷プロセス

  • 粉末床溶融結合:ダイレクトメタルレーザー焼結(DMLS)
  • 粉末床溶融結合:電子ビーム溶解(EBM)
  • 指向性エネルギー堆積:ブローパウダー
  • 指向性エネルギー沈着:溶接
  • バインダージェッティング:メタルバインダージェッティング
  • バインダージェッティング:サンドバインダージェッティング
  • シート積層:超音波積層造形(UAM)

第6章 新しい金属印刷プロセス

  • 押し出し:金属+ポリマーフィラメント(MPFE)
  • バット光重合:デジタル光処理(DLP)
  • 材料噴射:ナノ粒子噴射(NJP)
  • 材料噴射:電磁流体力学的堆積
  • 材料噴射:マイクロ流体電気めっき

第7章 金属プリンター:比較

  • 価格・精度
  • 価格・速度
  • 価格・数量
  • 速度・数量
  • 速度・精度
  • 精度・数量

第8章 セラミック印刷プロセス

  • 押し出し:クレイ
  • バット光重合:デジタル光処理(DLP)
  • サービスビューロー:その他のプロセス

第9章 3D印刷ソフトウェア技術

  • ソフトウェア部門の概要
  • ハードウェア・ソフトウェアの関係
  • 個人のソフトウェア利用
  • 専門業者によるソフトウェア利用
  • CAD
  • STLファイル
  • コンピューター支援エンジニアリング(CAE)
  • コンピューター支援製造(CAM):構築準備
  • アンメットニーズ

第10章 技術予測

第11章 ケーススタディ

第12章 航空宇宙・防衛

  • GE Aviation:LEAP燃料ノズル
  • Boeing 787 Dreamliner
  • Autodesk・Airbus
  • Airbus

第13章 医療・歯科

  • 外科用ツール
  • カスタムプレート・インプラント・バルブ・ステント
  • デジタル歯科・3Dプリンティング
  • その他の医療機器
  • 3Dプリンティング医薬品
  • 3Dバイオプリンティングプロセス

第14章 市場分析

  • 収益:主要既存3Dプリンターベンダー
  • 収益:新規3Dプリンターベンダー
  • 技術シェア

第15章 市場予測

  • COVID-19の影響
  • 総市場予測
  • エンドユーザー産業別
  • 金属・非金属部門
  • 機器・消耗品部門
  • プラスチック:印刷技術別

第16章 総論

第17章 企業プロファイル

  • 3D Ceram
  • 3D Systems Europe
  • Aleph Objects, Inc
  • Arcam AB
  • AREVO Inc
  • Beijing Tiertime Technology Co Ltd
  • BMW
  • Boeing
  • BotFactory
  • Buzz Technology
  • Carbon3D
  • Carima Ltd
  • CERADROP
  • ChemCubed
  • Concept Laser GMBH
  • Cytosurge
  • Dassault Systemes
  • Dyson
  • Efesto LLC
  • envisionTEC Gmbh
  • EOS GmbH
  • EPSRC
  • Fabrisonic LLC
  • FEINTECHNIK R Rittmeyer GmbH
  • Ford Motor Company
  • Formlabs
  • Fraunhofer
  • Fripp Design Ltd
  • HOGANAS
  • Hybrid Manufacturing Technologies
  • Impossible Objects
  • Leapfrog 3D Printers
  • Lockheed Martin
  • Luxexcel
  • MarkForged
  • Materialise
  • Nascent Objects, Inc
  • Norsk Titanium
  • Optomec
  • Photocentric
  • Printrbot
  • PRODWAYS
  • QuesTek Innovations LLC
  • Realizer GmbH
  • Reebok International
  • Ricoh
  • Rize Inc
  • Roland DGA Corporation
  • Sciaky Inc
  • Siemens AG
  • Sinterit
  • SLM Solutions NA
  • Solidscape
  • Stratasys
  • The ExOne Company
  • trinckle 3D GmbH
  • Ultimaker B.V
  • Voltera
  • Volvo Construction Equipment
  • Voxel8
  • Voxeljet Technology GmbH
  • Wanhao
  • ZMorph
目次

"Despite COVID the 3D printing market will be worth $45bn in 2030."

After initial commercialisation in the 1990s, 3D printing underwent a period of intense interest in 2013. Key players were quick to capitalise on this interest, enjoying exponential revenue growth between 2013 and 2016 as a result. Since then, the hype has subsided and additive manufacturing is starting to find its place among other manufacturing methods. In particular, focus has now shifted towards the digitisation of workflows and the manufacture of production quality final products. Several industries are now seriously analysing the benefits and competitive edge that 3D printing can lend their operations, and the most eagerly anticipated technological innovations are catering to these professional users. Although all signs point to a period of seriousness and readjustment in the 3D printing market as it transitions to cater to the needs of this user group, there remains enormous potential for growth over the next decade: IDTechEx forecasts that the global market for 3D printing equipment, materials, software and services will be worth $45bn by the year 2030.

Technology and Applications

Today, the 3D printing market comprises multiple different printer technologies. This report takes an in-depth look into established printer types including Vat Photopolymerisation (SLA/DLP/CLIP), Powder Bed Fusion (SLS/DMLS/EBM); Material Extrusion, Material Jetting, Binder Jetting, Directed Energy Deposition and Sheet Lamination. Key technological capabilities, applicable markets, SWOT analyses and key manufacturers are discussed for each established printer type. In addition, nascent printer technologies are introduced, and their technological capabilities evaluated.

Market analysis

This report forecasts the overall 3D printing market to 2030, with in depth discussion of currently commercialised and emerging printer technologies. The current state of the printer market is analysed, and long-range forecasts from 2020-2030 for revenue by technology, revenue stream and end user industry are evaluated.

IDTechEx conducted exhaustive primary research with companies positioned throughout the entire 3D printing value chain for key insights into the trends impacting growth to 2030. Over 60 company profiles have been included in the report including Stratasys, 3D Systems, EOS, Concept Laser GmbH and Arcam AB, amongst others.

Key questions that are answered in this report:

  • How will COVID impact the 3D printing industry?
  • What are the current and emerging printer technology types in 2020?
  • How do metrics such as price, build speed, build volume and precision vary by printer type?
  • What are the strengths and weaknesses of different 3D printing technologies?
  • Which printers support different material classes?
  • What is the current installed base of 3D printers?
  • What is the price range of 3D printers by technology type?
  • What are the market shares of those active in the market?
  • What are the key drivers and restraints of market growth?
  • How will sales of different printer types evolve from 2020 to 2030?

Analyst access from IDTechEx

All report purchases include up to 30 minutes telephone time with an expert analyst who will help you link key findings in the report to the business issues you're addressing. This needs to be used within three months of purchasing the report.

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY

  • 1.1. Major material-process relationships
  • 1.2. Why adopt 3D printing?
  • 1.3. Revenues of some older major 3DP printer vendors
  • 1.4. Revenues of some newer 3DP printer vendors
  • 1.5. Impact of COVID-19
  • 1.6. Total market forecast
  • 1.7. Metal vs non-metal segmentation
  • 1.8. Equipment vs consumables segmentation
  • 1.9. End user industry segmentation
  • 1.10. Drivers and restraints of growth

2. INTRODUCTION

  • 2.1. Glossary: common acronyms for reference
  • 2.2. Scope of report
  • 2.3. The seven different types of 3D printing processes
  • 2.4. Major material-process relationships
  • 2.5. Why adopt 3D printing?
  • 2.6. History of 3D printing: the rise of the hobbyist
  • 2.7. History of 3D printing metals
  • 2.8. Business models: securing future revenues
  • 2.9. Consumer vs prosumer vs professional
  • 2.10. Use patterns and market segmentation
  • 2.11. The desktop 3D printer explosion
  • 2.12. Drivers and restraints of growth

3. POLYMER PRINTING PROCESSES

  • 3.1. Powder bed fusion: Selective Laser Sintering (SLS)
  • 3.2. Binder jetting: polymer binder jetting
  • 3.3. Extrusion: Thermoplastics (TPE)
  • 3.4. Vat photopolymerisation: Stereolithography (SLA)
  • 3.5. Vat photopolymerisation: Digital Light Processing (DLP)
  • 3.6. Material jetting
  • 3.7. Sheet lamination: Laminated Object Manufacturing (LOM)

4. POLYMER PRINTERS: COMPARISON

  • 4.1. Machine prices by printing process
  • 4.2. Build volumes by printing process
  • 4.3. Precision by printing process
  • 4.4. Price vs speed
  • 4.5. Price vs precision
  • 4.6. Price vs Volume
  • 4.7. Volume vs precision
  • 4.8. Volume vs speed

5. METAL PRINTING PROCESSES

  • 5.1. Powder bed fusion: Direct Metal Laser Sintering (DMLS)
  • 5.2. Powder bed fusion: Electron Beam Melting (EBM)
  • 5.3. Directed energy deposition: Blown Powder
  • 5.4. Directed energy deposition: Welding
  • 5.5. Binder jetting: Metal Binder Jetting
  • 5.6. Binder jetting: Sand Binder Jetting
  • 5.7. Sheet lamination: Ultrasonic Additive Manufacturing (UAM)

6. NEW METAL PRINTING PROCESSES

  • 6.1. Extrusion: Metal + polymer filament (MPFE)
  • 6.2. Vat photopolymerisation: Digital Light Processing (DLP)
  • 6.3. Material jetting: nanoparticle jetting (NJP)
  • 6.4. Material jetting: magnetohydrodynamic deposition
  • 6.5. Material jetting: microfluidic electroplating

7. METAL PRINTERS: COMPARISON

  • 7.1. Price versus precision
  • 7.2. Price versus speed
  • 7.3. Price versus volume
  • 7.4. Speed versus volume
  • 7.5. Speed versus precision
  • 7.6. Precision versus volume

8. CERAMIC PRINTING PROCESSES

  • 8.1. Extrusion: Clay
  • 8.2. Vat photopolymerisation: Digital Light Processing (DLP)
  • 8.3. Service bureaus: additional processes

9. 3D PRINTING SOFTWARE TECHNOLOGY

  • 9.1. Overview of 3D printing software segments
  • 9.2. Relationship between 3D printing hardware and software
  • 9.3. Hobbyist 3D printing software usage
  • 9.4. Professional 3D printing software usage
  • 9.5. Computer Aided Design (CAD)
  • 9.6. .STL files
  • 9.7. Computer Aided Engineering (CAE): Topology
  • 9.8. Computer Aided Engineering (CAE): process simulation
  • 9.9. Computer Aided Manufacture (CAM): Build preparation
  • 9.10. Unmet needs in 3D printing software

10. TECHNOLOGY FORECAST

  • 10.1. EU Roadmap for Technical AM Development
  • 10.2. EU Roadmap of Grand Challenges served by AM
  • 10.3. Supersonic metal powder jetting
  • 10.4. Multiphoton lithography
  • 10.5. The rise of multimaterial printing
  • 10.6. 3D scanners and medical imaging techniques
  • 10.7. Generative design for product lightweighting
  • 10.8. LCD stereolithography 3D Printing
  • 10.9. 4D printing materials

11. APPLICATION CASE STUDIES

  • 11.1. Increasing value of 3D printed objects
  • 11.2. Prototyping

12. AEROSPACE AND DEFENCE

  • 12.1. GE Aviation: LEAP fuel nozzles
  • 12.2. Boeing 787 Dreamliner: Ti-6Al-4V structures
  • 12.3. Autodesk and Airbus: optimised partition wall
  • 12.4. Airbus: bracket

13. MEDICAL AND DENTAL

  • 13.1. 3D printing as a surgical tool
  • 13.2. 3D printing custom plates, implants, valves and stents
  • 13.3. Digital dentistry and 3D printing
  • 13.4. Other medical devices
  • 13.5. 3D printing pharmaceuticals
  • 13.6. 3D Bioprinting Process

14. MARKET ANALYSIS

  • 14.1. Revenues of some older major 3DP printer vendors
  • 14.2. Revenues of some newer 3DP printer vendors
  • 14.3. Technology market share

15. MARKET FORECAST

  • 15.1. Forecast methodology and presentation of findings
  • 15.2. Impact of COVID-19
  • 15.3. Total market forecast
  • 15.4. End user industry segmentation
  • 15.5. Metal vs non-metal segmentation
  • 15.6. Equipment vs consumables segmentation
  • 15.7. Plastics segmented by printing technology

16. CONCLUSIONS

  • 16.1. 3D printing is still a highly innovative technology

17. COMPANY PROFILES

  • 17.1. 3D Ceram
  • 17.2. 3D Systems Europe
  • 17.3. Aleph Objects, Inc
  • 17.4. Arcam AB
  • 17.5. AREVO Inc
  • 17.6. Beijing Tiertime Technology Co Ltd
  • 17.7. BMW
  • 17.8. Boeing
  • 17.9. BotFactory
  • 17.10. Buzz Technology
  • 17.11. Carbon3D
  • 17.12. Carima Ltd
  • 17.13. CERADROP
  • 17.14. ChemCubed
  • 17.15. Concept Laser GMBH
  • 17.16. Cytosurge
  • 17.17. Dassault Systemes
  • 17.18. Dyson
  • 17.19. Efesto LLC
  • 17.20. envisionTEC Gmbh
  • 17.21. EOS GmbH
  • 17.22. EPSRC
  • 17.23. Fabrisonic LLC
  • 17.24. FEINTECHNIK R Rittmeyer GmbH
  • 17.25. Ford Motor Company
  • 17.26. Formlabs
  • 17.27. Fraunhofer
  • 17.28. Fripp Design Ltd
  • 17.29. HÖGANÄS
  • 17.30. Hybrid Manufacturing Technologies
  • 17.31. Impossible Objects
  • 17.32. Leapfrog 3D Printers
  • 17.33. Lockheed Martin
  • 17.34. Luxexcel
  • 17.35. MarkForged
  • 17.36. Materialise
  • 17.37. Nascent Objects, Inc
  • 17.38. Norsk Titanium
  • 17.39. Optomec
  • 17.40. Photocentric
  • 17.41. Printrbot
  • 17.42. PRODWAYS
  • 17.43. QuesTek Innovations LLC
  • 17.44. Realizer GmbH
  • 17.45. Reebok International
  • 17.46. Ricoh
  • 17.47. Rize Inc
  • 17.48. Roland DGA Corporation
  • 17.49. Sciaky Inc
  • 17.50. Siemens AG
  • 17.51. Sinterit
  • 17.52. SLM Solutions NA
  • 17.53. Solidscape
  • 17.54. Stratasys
  • 17.55. The ExOne Company
  • 17.56. trinckle 3D GmbH
  • 17.57. Ultimaker B.V
  • 17.58. Voltera
  • 17.59. Volvo Construction Equipment
  • 17.60. Voxel8
  • 17.61. Voxeljet Technology GmbH
  • 17.62. Wanhao
  • 17.63. ZMorph
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