3D printing hardware and materials will hit US$49 billion in market size by 2034.
Impression 3D et fabrication additive 2024-2034 : technologies et perspectives de marché
Quatre-vingt lignes de prévisions sur 10 ans concernant 17 technologies d'impression 3D et 10 types de matériaux d'impression 3D. Comprend des analyses technologiques, des analyses de marché, des études comparatives, des profils d'acteurs pour l'impression 3D de polymères, de métaux, de céramiques, de composites et de construction
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3D Printing and Additive Manufacturing: A Dynamic and Innovative Industry
Since the invention of the first 3D printing technologies in the early 1980s, the 3D printing market has experienced a tremendous amount of growth, innovation, and interest. A niche technology until the expiration of a key patent in 2009, the 2010s allowed many startups to emerge offering cheap consumer-level 3D printers. The subsequent media frenzy in the early 2010s thrust 3D printing into the limelight; that frenzy was accompanied by major multinational corporations like Hewlett Packard and General Electric more substantially entering the 3D printing space. After years of hype, the industry has moved onto a more critical examination of the value-add that effective additive manufacturing adoption brings to businesses and supply chains. Despite the obstacles posed by the COVID-19 pandemic and subsequent macroeconomic uncertainty, the additive manufacturing market continues to find new applications and end-users. Understanding the evolution and current technical status of 3D printing is critical to understanding the future of this industry.
IDTechEx's 3D Printing and Additive Manufacturing 2024-2034 report provides insight into the industry's growth and future through expansive analysis of every corner of the market, from hardware and materials to software and services to applications. Any company in the 3D printing supply chain or looking to enter the industry will find valuable insights in this report, like materials suppliers, printer manufacturers, service providers, end-users, and more. This report breaks down the hardware market into 17 technology segments and the materials market into 10 segments to create 80 forecast lines across 12 different forecasts. The forecasts provide a ten-year outlook for 3D printer installation base, new installations, replacement unit sales, revenue from 3D printer sales, demand for 3D printing materials, and revenue from 3D printing materials sales.
3D Printing Hardware: Technology and Materials Analyses including Impartial Technical Benchmarking
IDTechEx's 3D printing industry report examines the industry from a materials-centric perspective. Each materials category is discussed from a technology and materials standpoint, providing key technical insights into the major additive manufacturing subspecialities:
- Polymers
- Metals
- Ceramics
- Composites
- Construction
Across these categories, IDTechEx individually analyzes over 30 printing technologies by their strengths, weaknesses, opportunities, and threats. In addition, information on hardware manufacturers, technology readiness levels, and key industries for each technology are provided to offer a full picture of each printing process from a technical and application perspective. Additionally, IDTechEx has conducted benchmarking studies within each material subspeciality to compare technologies by key parameters: build volume, build speed, resolution, price, and more. These comparisons were constructed through the extensive database of printer models and technical details collected by IDTechEx over the past seven years of 3D printing coverage. Through this impartial benchmarking, IDTechEx will highlight the advantages and disadvantages of each technology for its end-users.
Evolution of Market Shares for 3D Printing Technologies and Materials 2023-2034. Source: "3D Printing and Additive Manufacturing 2024-2034: Technology and Market Outlook ", which includes 80 10-year forecast lines in the report
To complement expansive technology breakdowns, IDTechEx takes an in-depth look into the established material classes of polymer, metal, and ceramic materials, including photopolymer resins, thermoplastic powders, thermoplastic filaments, metal powders, and ceramic materials. This discussion includes properties, advantages, disadvantages, applications, and suppliers for each of the main material categories.
Rounding out this extensive technology and material breakdown is an in-depth discussion of post-processing, software, scanners, and services in 3D printing, all of which are becoming increasingly important to an industry targeting mass market adoption. The extent of additive manufacturing's penetration in different target industries, such as aerospace, healthcare, automotive, and electric vehicles is explored through selected use cases, key news, important 3D printing players, and relevant OEM end-users in each application area.
Lastly, IDTechEx will present its research conducted since 2014 to offer its perspective on the current status of the 3D printing market. This includes rankings of the dominant technology segments by market share and emerging trends. IDTechEx's detailed industry analysis will also provide further context to the notable amount of movement in this industry with acquisitions, mergers, investments, and public offerings as additive manufacturing players position themselves for expansion.
Market Forecasts for 3D Printing Hardware and Materials
Using extensive primary and secondary research, IDTechEx has constructed detailed 10-year market forecast for the 3D printing market, looking at 3D printing hardware and materials through eighty different forecast lines. The hardware forecasts break the market down by install base, technology type, and unit sale type, while the materials forecasts segment the market into materials classes, polymer feedstock type, and metal feedstock type. This analysis reveals how hardware and materials sales will lead the industry to US$49 billion market size in 2034.
IDTechEx conducted exhaustive primary research with companies positioned throughout the entire 3D printing value chain for key insights into the trends impacting growth to 2034. This includes printer manufacturers, materials suppliers, software makers, and service providers. 150 company profiles have been included in the report including Stratasys, 3D Systems, EOS, Markforged, Evonik, and Desktop Metal, amongst others. These profiles give insight into the companies leading the industry, their position amongst their competitors, and the opportunities and challenges they face in the future.
Key aspects
This report provides the following information:
Technology trends, materials trends, & manufacturer analysis
- Detailed summaries of all 3D printing technologies by material class
- Comparison studies between polymer 3D printers of different technologies and metal 3D printers of different technologies
- Analysis for polymer 3D printing materials, broken into three feedstock categories and seventeen individual feedstock types
- Comprehensive discussion of metal 3D printing materials on the market by different manufacturers
- Exploration of auxiliary 3D printing categories, like post-processing, software, scanners, and services
- Overview of additive manufacturing applications in key industries like electric vehicles, aviation, healthcare, space, automotive, and more
- Summaries of emerging printer technologies
- Primary interviews with key companies.
Market Forecasts & Analysis:
- 10-year granular market forecasts of hardware by printer technology, material class, unit sales, install base
- Eighty forecast lines included across twelve forecasts
- 10-year granular market forecasts include polymer and metal materials demand and revenue by feedstock type
- Extensive discussion of the current economic climate's effects on the 3D printing industry and the market's current status through primary and secondary research analysis
| Report Metrics | Details |
|---|---|
| Historic Data | 2012 - 2022 |
| CAGR | The 3D printing market as generated by sales of 3D printers and 3D printing materials will reach US$49 billion by 2034, at a CAGR of 11% between 2024 and 2034. |
| Forecast Period | 2024 - 2034 |
| Forecast Units | Printer and Materials Revenue (billions USD), Printers (units), Materials (kilotonnes) |
| Regions Covered | Worldwide |
| Segments Covered | Technology Type, Material Class, New Installations, Replacement Installations, Polymer Feedstock Type, Metal Feedstock Type |
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.
Further information
If you have any questions about this report, please do not hesitate to contact our report team at research@IDTechEx.com or call one of our sales managers:
ASIA: +82 10 3896 6219
| 1. | EXECUTIVE SUMMARY |
| 1.1. | Why adopt 3D printing? |
| 1.2. | Material compatibility across 3D printing technologies |
| 1.3. | Drivers and restraints of growth for 3D printing |
| 1.4. | Overview of polymer 3D printing technologies |
| 1.5. | Breaking down polymer materials for 3D printing |
| 1.6. | Overview of metal 3D printing technologies |
| 1.7. | Overview of metal AM feedstock options |
| 1.8. | 3D printing ceramics - technology overview |
| 1.9. | Evaluation of Ceramic 3D Printing Technologies |
| 1.10. | Ceramic 3D printing materials on the market |
| 1.11. | Overview of post-processing techniques for metal additive manufacturing |
| 1.12. | Overview of post-processing techniques for polymer additive manufacturing |
| 1.13. | Relationship between 3D printing hardware and software |
| 1.14. | 3D scanner manufacturers - segmented by price and technology |
| 1.15. | Technology segmentation |
| 1.16. | Technology segmentation |
| 1.17. | Current 3D printing technology market share |
| 1.18. | Current market share of materials demand - revenue and mass |
| 1.19. | 3D printing market forecast 2024-2034 |
| 1.20. | 3D printing hardware market share in 2034 |
| 1.21. | 3D printing hardware market by process |
| 1.22. | 3D printing hardware market by process |
| 1.23. | 3D printing materials forecast 2024-2034 by material type - revenue and mass |
| 1.24. | 3D printing materials forecast by material type - discussion |
| 1.25. | Conclusions |
| 1.26. | Company profiles - 3D printer manufacturers |
| 1.27. | Company profiles - 3D printing materials, software, services |
| 2. | INTRODUCTION |
| 2.1. | Glossary: common acronyms for reference |
| 2.2. | Scope of Report |
| 2.3. | The different types of 3D printing processes |
| 2.4. | Material compatibility across 3D printing technologies |
| 2.5. | Why adopt 3D printing? |
| 2.6. | History of 3D printing: the rise of the hobbyist |
| 2.7. | Timeline of 3D printing metals |
| 2.8. | History of ceramic 3D printing companies |
| 2.9. | Business models: selling printers vs parts |
| 2.10. | Consumer vs prosumer vs professional |
| 2.11. | Use patterns and market segmentation |
| 2.12. | Drivers and restraints of growth for 3D printing |
| 3. | POLYMER HARDWARE |
| 3.1. | Polymer Printing Technologies |
| 3.1.1. | Extrusion: thermoplastic filament |
| 3.1.2. | Extrusion: thermoplastic pellet |
| 3.1.3. | Powder bed fusion: selective laser sintering (SLS) |
| 3.1.4. | Powder bed fusion: multi-jet fusion |
| 3.1.5. | Vat photopolymerisation: stereolithography (SLA) |
| 3.1.6. | Vat photopolymerisation: digital light processing (DLP) |
| 3.1.7. | Material jetting: photopolymer |
| 3.2. | Polymer Printer Benchmarking |
| 3.2.1. | Introduction to Polymer 3D Printing Technologies |
| 3.2.2. | Benchmarking: Maximum Build Volume |
| 3.2.3. | Benchmarking: Build Rate |
| 3.2.4. | Benchmarking: Z Resolution |
| 3.2.5. | Benchmarking: XY Resolution |
| 3.2.6. | Benchmarking: Price vs Build Volume |
| 3.2.7. | Benchmarking: Price vs Build Rate |
| 3.2.8. | Benchmarking: Price vs Z Resolution |
| 3.2.9. | Benchmarking: Build Rate vs Build Volume |
| 3.2.10. | Benchmarking: Build Rate vs Z Resolution |
| 3.2.11. | Averages of Polymer 3D Printing Technologies |
| 4. | POLYMER MATERIALS |
| 4.1. | Introduction |
| 4.1.1. | Breaking down polymer materials for 3D printing |
| 4.2. | Photopolymer Resins |
| 4.2.1. | Introduction to photopolymer resins |
| 4.2.2. | Chemistry of photosensitive resins |
| 4.2.3. | Chemistry of photopolymer resins |
| 4.2.4. | Chemistry of photosensitive resins |
| 4.2.5. | Resins - advantages and disadvantages |
| 4.2.6. | General purpose resins - overview |
| 4.2.7. | Engineering resins - overview |
| 4.2.8. | Flexible resins - overview |
| 4.2.9. | Castable resins - overview |
| 4.2.10. | Healthcare resins - overview |
| 4.2.11. | Extrusion resins - overview |
| 4.2.12. | Viscous photosensitive resins |
| 4.2.13. | Photosensitive resin suppliers |
| 4.3. | Thermoplastic powders |
| 4.3.1. | Introduction to thermoplastic powders |
| 4.3.2. | Engineering (nylon) powder - overview |
| 4.3.3. | Flexible powder - overview |
| 4.3.4. | Composite powder - overview |
| 4.3.5. | High temperature powder - overview |
| 4.3.6. | Engineering (other) powder - overview |
| 4.3.7. | Thermoplastic powders: post-processing |
| 4.3.8. | Thermoplastic powder suppliers |
| 4.4. | Thermoplastic filaments |
| 4.4.1. | Introduction to thermoplastic filaments |
| 4.4.2. | General purpose filaments - overview |
| 4.4.3. | Engineering filaments - overview |
| 4.4.4. | Flexible filaments - overview |
| 4.4.5. | Reinforced filaments - overview |
| 4.4.6. | High temperature filaments - overview |
| 4.4.7. | Support Filaments - overview |
| 4.4.8. | Fillers for thermoplastic filaments |
| 4.4.9. | Thermoplastic filament suppliers |
| 4.4.10. | Procurement of thermoplastic filaments |
| 5. | METAL HARDWARE |
| 5.1. | Established Metal Printing Technologies |
| 5.1.1. | Powder bed fusion: direct metal laser sintering (DMLS) |
| 5.1.2. | Powder bed fusion: electron beam melting (EBM) |
| 5.1.3. | Directed energy deposition: powder |
| 5.1.4. | Directed energy deposition: wire |
| 5.1.5. | Binder jetting: metal binder jetting |
| 5.1.6. | Binder jetting: sand binder jetting |
| 5.1.7. | Sheet lamination: ultrasonic additive manufacturing (UAM) |
| 5.2. | Emerging Metal Printing Technologies |
| 5.2.1. | Emerging Printing Processes - Overview |
| 5.2.2. | Extrusion: metal-polymer filament (MPFE) |
| 5.2.3. | Extrusion: metal-polymer pellet |
| 5.2.4. | Extrusion: metal paste |
| 5.2.5. | Vat photopolymerisation: digital light processing (DLP) |
| 5.2.6. | Material jetting: nanoparticle jetting (NPJ) |
| 5.2.7. | Material Jetting: magnetohydrodynamic deposition |
| 5.2.8. | Material jetting: electrochemical deposition |
| 5.2.9. | Material jetting: cold spray |
| 5.2.10. | Binder jetting advancements |
| 5.2.11. | Developments in PBF and DED: energy sources |
| 5.2.12. | Developments in PBF and DED: low-cost printers |
| 5.2.13. | Developments in PBF and DED: new technologies |
| 5.2.14. | Processes with a metal slurry feedstock |
| 5.2.15. | Alternative emerging DMLS variations |
| 5.3. | Metal printers: comparison and benchmarking |
| 5.3.1. | Metal Additive Manufacturing: Technology Overview |
| 5.3.2. | Benchmarking: Maximum Build Volume |
| 5.3.3. | Benchmarking: Build Rate |
| 5.3.4. | Benchmarking: Z Resolution |
| 5.3.5. | Benchmarking: XY Resolution |
| 5.3.6. | Benchmarking: Price vs Build Volume |
| 5.3.7. | Benchmarking: Price vs Build Rate |
| 5.3.8. | Benchmarking: Price vs Z Resolution |
| 5.3.9. | Benchmarking: Build Rate vs Build Volume |
| 5.3.10. | Benchmarking: Build Rate vs Z Resolution |
| 5.3.11. | Overview of Metal 3D Printing Technologies |
| 5.3.12. | Maximums & Minimums of Metal 3D Printing Technologies |
| 6. | METAL MATERIALS |
| 6.1. | Metal powders |
| 6.1.1. | Overview of Metal AM Feedstock Options |
| 6.1.2. | Powder morphology specification |
| 6.1.3. | Water or gas atomization |
| 6.1.4. | Plasma atomization |
| 6.1.5. | Electrochemical atomization |
| 6.1.6. | Powder morphology depends on atomization process |
| 6.1.7. | Powder morphology depends on atomization process |
| 6.1.8. | Metal Compatibility with Printing Technologies |
| 6.1.9. | Suppliers of metal powders for AM |
| 6.1.10. | Titanium powder - overview |
| 6.1.11. | Titanium powder - main players |
| 6.1.12. | Titanium powder - main players |
| 6.1.13. | Key material start-ups for metal additive manufacturing |
| 6.1.14. | Recycled titanium feedstocks |
| 6.1.15. | Metal powder bed fusion post processing |
| 6.1.16. | Barriers and limitations to using metal powders |
| 6.2. | Other metal feedstocks |
| 6.2.1. | Metal wire feedstocks |
| 6.2.2. | Metal + polymer filaments |
| 6.2.3. | Metal + polymer filaments: BASF Ultrafuse |
| 6.2.4. | Metal + photopolymer resin |
| 6.3. | Emerging metal materials |
| 6.3.1. | Expanding the aluminum AM material portfolio |
| 6.3.2. | 3D printing with copper: huge potential with many challenges |
| 6.3.3. | Expanding the copper AM material portfolio |
| 6.3.4. | High entropy alloys for AM |
| 6.3.5. | Amorphous alloys for AM |
| 6.3.6. | Emerging aluminum alloys and MMCs |
| 6.3.7. | Multi-metal material solutions |
| 6.3.8. | Materials informatics for additive manufacturing materials |
| 6.3.9. | Materials informatics for additive manufacturing materials |
| 6.3.10. | Tungsten powder and nanoparticles |
| 7. | CERAMIC HARDWARE |
| 7.1. | Ceramic Printing Technologies |
| 7.1.1. | 3D printing ceramics - technology overview |
| 7.1.2. | Extrusion: ceramic paste |
| 7.1.3. | Extrusion: ceramic-polymer filament |
| 7.1.4. | Extrusion: ceramic-polymer pellet |
| 7.1.5. | Vat photopolymerisation: stereolithography (SLA) |
| 7.1.6. | Vat photopolymerisation: digital light processing (DLP) |
| 7.1.7. | Material jetting: nanoparticle jetting (NPJ) |
| 7.1.8. | Binder jetting: ceramic binder jetting |
| 7.1.9. | Why are there no commercial SLS ceramic printers? |
| 7.1.10. | Why are there no commercial SLM ceramic printers? |
| 7.2. | Ceramic Printers: Benchmarking |
| 7.2.1. | Ceramic: Build Volumes by Printer Manufacturer |
| 7.2.2. | Ceramic: Minimum Z Resolution by Printer Manufacturer |
| 7.2.3. | Ceramic Benchmarking: Z Resolution vs Build Volume |
| 7.2.4. | Ceramic: Minimum XY Resolution by Printer Manufacturer |
| 7.2.5. | Ceramic: Build Speed by Technology Type |
| 7.2.6. | Ceramic Benchmarking: Build Volume vs Price |
| 7.2.7. | Ceramic Benchmarking: Z Resolution vs Price |
| 7.2.8. | Evaluation of Ceramic 3D Printing Technologies |
| 8. | CERAMIC MATERIALS |
| 8.1. | Introduction to ceramic 3D printing materials |
| 8.2. | Classification: by feedstock type |
| 8.3. | Classification: by application |
| 8.4. | Classification: by chemistry |
| 8.5. | Ceramic 3D printing materials on the market |
| 8.6. | Bioceramics |
| 8.7. | Mechanical properties of 3DP ceramic materials |
| 8.8. | Thermal properties of 3DP ceramic materials |
| 8.9. | Average densities of 3DP ceramic materials |
| 8.10. | Flexural strength vs density - 3DP ceramic materials |
| 8.11. | Alumina comparison - AM vs non AM |
| 8.12. | Zirconia comparison - AM vs non AM |
| 8.13. | Silicon carbide and nitride comparison |
| 8.14. | Ceramic-matrix composites (CMCs) |
| 8.15. | Ceramic-matrix composites (CMCs) |
| 8.16. | Ceramics as reinforcement in 3D printing |
| 8.17. | Manufacturers of ceramics for 3D printing |
| 9. | COMPOSITE HARDWARE |
| 9.1. | Polymer composites - overview |
| 9.2. | Chopped fiber thermoplastic filament extrusion |
| 9.3. | Continuous fiber thermoplastic filament extrusion |
| 9.4. | Continuous fiber thermoplastic tape extrusion |
| 9.5. | Sheet lamination |
| 9.6. | Powder bed fusion: selective laser sintering (SLS) |
| 9.7. | Continuous fiber thermoset extrusion |
| 9.8. | Composite vat photopolymerization |
| 10. | COMPOSITE MATERIALS |
| 10.1. | Composite material feedstock: introduction |
| 10.2. | Material assessment: matrix considerations |
| 10.3. | Material assessment: mechanical properties |
| 10.4. | Material assessment: price and performance benchmarking |
| 10.5. | Material assessment: price and performance benchmarking |
| 10.6. | Complete material list: short carbon fiber |
| 10.7. | Complete material list: short glass fiber |
| 10.8. | Complete material list: powder |
| 10.9. | Complete material list: continuous fiber |
| 10.10. | Benchmarking study by independent research institute |
| 10.11. | Key composite 3D printing material news and developments |
| 10.12. | Recycled carbon fiber as feedstock material |
| 10.13. | Nanocarbon additive: property advantages |
| 10.14. | Nanocarbon additive: commercial activity |
| 11. | PRINTERS AND MATERIALS FOR CONSTRUCTION 3D PRINTING |
| 11.1. | A brief history of concrete 3D printing |
| 11.2. | The drivers behind 3D printed concrete |
| 11.3. | The drivers behind 3D printed concrete |
| 11.4. | Main categories of concrete AM technology |
| 11.5. | Cartesian ("gantry") extrusion |
| 11.6. | Cartesian ("gantry") extrusion |
| 11.7. | Robotic extrusion |
| 11.8. | Robotic extrusion |
| 11.9. | Binder jetting |
| 11.10. | Materials for concrete 3D printing |
| 11.11. | Notable concrete 3D printing projects |
| 11.12. | Notable concrete 3D printing projects |
| 11.13. | Notable concrete 3D printing projects |
| 11.14. | Notable concrete 3D printing projects |
| 11.15. | Barriers to adoption of concrete 3D printing |
| 11.16. | Outlook for concrete 3D printing |
| 11.17. | Concrete 3D printing companies |
| 11.18. | Clay 3D printing for construction |
| 11.19. | Thermoset 3D printing for construction |
| 12. | POST-PROCESSING FOR ADDITIVE MANUFACTURING |
| 12.1. | Introduction to post-processing |
| 12.2. | Why is post-processing done after 3D printing? |
| 12.3. | Overview of post-processing techniques for metal additive manufacturing |
| 12.4. | Overview of post-processing techniques for polymer additive manufacturing |
| 12.5. | Material removal |
| 12.6. | Process-inherent treatments |
| 12.7. | Surface finishing techniques |
| 12.8. | Other post-processing treatments |
| 12.9. | AM post-processing companies |
| 12.10. | Pain points for post-processing in AM |
| 13. | SOFTWARE, SCANNERS, AND SERVICES |
| 13.1. | Software for 3D printing |
| 13.1.1. | Overview of 3D printing software segments |
| 13.1.2. | Relationship between 3D printing hardware and software |
| 13.1.3. | Hobbyist 3D printing software usage |
| 13.1.4. | Professional 3D printing software usage |
| 13.1.5. | 3D scanning software |
| 13.1.6. | Computer aided design (CAD) |
| 13.1.7. | .STL files |
| 13.1.8. | Computer aided engineering (CAE): topology |
| 13.1.9. | Computer aided engineering (CAE): process simulation |
| 13.1.10. | Computer aided manufacture (CAM): build preparation |
| 13.1.11. | Integrated CAD/CAE/CAM suites |
| 13.1.12. | Workflow management solutions |
| 13.1.13. | Pain points in 3D printing software |
| 13.1.14. | Developers of 3D printing software |
| 13.1.15. | Developers of 3D printing software |
| 13.1.16. | Developers of 3D printing software |
| 13.2. | 3D Scanning |
| 13.2.1. | Introduction to 3D scanning |
| 13.2.2. | Laser triangulation |
| 13.2.3. | Structured light |
| 13.2.4. | 3D computed tomography |
| 13.2.5. | Price segmentation of 3D scanners |
| 13.2.6. | 3D scanner manufacturers - segmented by price and technology |
| 13.2.7. | 3D scanners in additive manufacturing |
| 13.2.8. | Industries using 3D scanners with 3D printing |
| 13.3. | Production services for 3D printing |
| 13.3.1. | What are 3D printing service bureaus? |
| 13.3.2. | What does a service bureau do? |
| 13.3.3. | What does a service bureau do? |
| 13.3.4. | Value proposition behind service bureaus |
| 13.3.5. | Design for additive manufacturing (DfAM) |
| 13.3.6. | Notable 3D printing service bureaus |
| 13.3.7. | Notable 3D printing service bureaus |
| 13.3.8. | Notable 3D printing service bureaus |
| 13.3.9. | Challenges facing additive manufacturing service bureaus |
| 13.3.10. | Outlook for 3D printing service bureaus |
| 13.3.11. | List of selected 3D printing service bureaus |
| 14. | APPLICATIONS FOR ADDITIVE MANUFACTURING |
| 14.1. | 3D Printing for Healthcare |
| 14.1.1. | Most popular 3D printing technologies in healthcare |
| 14.1.2. | Polymers used in medical 3D printing |
| 14.1.3. | Medical applications of polymer 3D printing |
| 14.1.4. | Medical applications of 3D printing by polymer type |
| 14.1.5. | 3D printing as a surgical tool |
| 14.1.6. | Using models to improve patient care, standards and efficiency |
| 14.1.7. | 3D printing custom plates, implants, valves and stents |
| 14.1.8. | 3D printing custom plates, implants, valves and stents |
| 14.1.9. | Case study: hip replacement revision surgery |
| 14.1.10. | Case study: canine cranial plate in titanium |
| 14.1.11. | 3D printing external medical devices |
| 14.1.12. | Case study: hearing aids |
| 14.1.13. | Case study: orthotic insoles |
| 14.1.14. | High temperature thermoplastic filaments and powders |
| 14.1.15. | Photosensitive resins |
| 14.1.16. | Titanium alloy powders |
| 14.1.17. | Bioactive ceramic filaments and resins |
| 14.1.18. | 3D printing during the COVID-19 pandemic |
| 14.1.19. | Case study: parts for ventilators |
| 14.1.20. | 3D printing in pharmaceuticals |
| 14.1.21. | 3D printed pharma: novel dissolution profiles |
| 14.1.22. | 3D printed pharma: personalized medication |
| 14.1.23. | 3D printed pharma: novel drugs and drug testing |
| 14.1.24. | 3D printed pharma: commercial status and regulatory overview |
| 14.1.25. | Digital dentistry and 3D printing |
| 14.1.26. | Digital dentistry workflow |
| 14.1.27. | Photopolymer resins for dentistry |
| 14.1.28. | Case study: Invisalign |
| 14.1.29. | Case study: dental models |
| 14.1.30. | Regulatory overview for polymer 3D printing in dentistry |
| 14.1.31. | 3D printed orthodontics |
| 14.1.32. | Case study: implantable dental devices and prostheses |
| 14.1.33. | Case study: mandibular reconstructive surgery |
| 14.2. | 3D Printing in Aviation, Space, and Defense |
| 14.2.1. | GE Aviation: LEAP fuel nozzles |
| 14.2.2. | GE Aviation: next-gen RISE engine |
| 14.2.3. | GE Aviation: bleed air parts and turboprop engines |
| 14.2.4. | GE Aviation and Boeing 777X: GE9X engines |
| 14.2.5. | Boeing 787 dreamliner: Ti-6Al-4V structures |
| 14.2.6. | Boeing: gearboxes for Chinook helicopters |
| 14.2.7. | Boeing and Maxar Technologies: satellites |
| 14.2.8. | Airbus and Eutelsat: satellites |
| 14.2.9. | Autodesk and Airbus: optimised partition wall |
| 14.2.10. | Airbus: bracket |
| 14.2.11. | RUAG Space and Altair: antenna mount |
| 14.2.12. | Hofmann: oxygen supply tube |
| 14.2.13. | Relativity Space: rockets |
| 14.2.14. | Composite 3D printing: UAVs and satellites |
| 14.2.15. | OEM AM Strategy - GE |
| 14.2.16. | OEM AM Strategy - Airbus |
| 14.2.17. | OEM AM Strategy - Boeing |
| 14.2.18. | OEM AM Strategy - Rolls-Royce |
| 14.3. | Other Industries Using Additive Manufacturing |
| 14.3.1. | Automotive |
| 14.3.2. | Motorsport |
| 14.3.3. | Marine |
| 14.3.4. | Oil and Gas |
| 14.3.5. | Power Generation |
| 14.3.6. | Manufacturing Plants |
| 14.3.7. | Consumer Goods |
| 14.3.8. | Art and Design |
| 14.3.9. | Electronics |
| 14.4. | Application Spotlight: Additive Manufacturing for Electric Vehicles |
| 14.4.1. | IDTechEx's electric vehicle definitions |
| 14.4.2. | Overview of electric vehicle markets |
| 14.4.3. | Electric car markets: another year of growth |
| 14.4.4. | What are the challenges for EV adoption? |
| 14.4.5. | AM in EVs: opportunities and barriers |
| 14.4.6. | Selected automotive player engagement with AM |
| 14.4.7. | 3D printing for EVs: prototyping |
| 14.4.8. | 3D printing for EVs: tools, jigs, and fixtures |
| 14.4.9. | 3D printing for EVs: electric motors |
| 14.4.10. | 3D printing for EVs: electric motor components |
| 14.4.11. | 3D printing for EVs: electric motor components |
| 14.4.12. | 3D printing for EVs: lithium-ion batteries (LIBs) |
| 14.4.13. | 3D printing for EVs: solid-state batteries (SSBs) |
| 14.4.14. | 3D printing for EVs: solid-state batteries (SSBs) |
| 14.4.15. | 3D printing for EVs: thermal management |
| 14.4.16. | 3D printing for EVs: thermal management |
| 14.4.17. | 3D printing for EVs: thermal management |
| 14.4.18. | 3D printing for EVs: other components |
| 14.4.19. | 3D printing for EVs: interior and body parts |
| 14.4.20. | Luxury EVs: an opportunity for AM |
| 14.4.21. | Luxury EVs: an opportunity for AM |
| 14.4.22. | Summary: additive manufacturing for electric vehicles |
| 15. | MARKET ANALYSIS |
| 15.1. | Financial Landscape for 3D Printing 2022 |
| 15.1.1. | Investment and M&A activity in AM: 2022 vs 2021 |
| 15.1.2. | AM-related companies going public in 2022 |
| 15.1.3. | AM-related companies going public in 2022: discussion |
| 15.1.4. | Notable AM mergers and acquisitions in 2022 |
| 15.1.5. | Notable AM mergers and acquisitions in 2022: discussion |
| 15.1.6. | 3D printing private funding: 2021 vs 2022 |
| 15.1.7. | 3D printing private funding: 2021 vs 2022 |
| 15.1.8. | Top 10 funding rounds in 3D printing in 2022 |
| 15.1.9. | Bankruptcies in AM in 2022 |
| 15.1.10. | Lay-offs and other news in AM in 2022 |
| 15.2. | Financial Landscape for 3D Printing 2023 |
| 15.2.1. | Investment and M&A activity in AM: 2023 vs 2022 |
| 15.2.2. | AM-related companies going public: 2021-2023 |
| 15.2.3. | Notable AM mergers and acquisitions: 2022 |
| 15.2.4. | Notable AM mergers and acquisitions: 2023 |
| 15.2.5. | Notable AM mergers and acquisitions: 2023 |
| 15.2.6. | Technology comparison: Stratasys vs Desktop Metal vs 3D Systems |
| 15.2.7. | 3D printing private funding: 2021-2023 |
| 15.2.8. | 3D printing private funding: 2023 |
| 15.2.9. | 3D printing private funding trends in 2023 |
| 15.2.10. | Other recent news in 3D printing |
| 15.2.11. | Common themes in recent 3D printing success stories |
| 15.2.12. | Common themes in recent divestures and exits from 3D printing |
| 15.3. | Historic Growth and Trends for 3D Printing |
| 15.3.1. | AM steadily growing into important high-value applications |
| 15.3.2. | Interesting trends for additive manufacturing |
| 15.3.3. | Crucial challenges for additive manufacturing |
| 15.3.4. | Additive manufacturing: key takeaways for solutions providers |
| 15.3.5. | 3D printing hardware historic revenue growth |
| 15.3.6. | Evolution of market shares for seven 3D printing processes |
| 15.3.7. | Technology segmentation |
| 15.3.8. | Technology segmentation |
| 15.3.9. | Current 3D printing technology market share |
| 15.3.10. | Current market share of materials demand - revenue and mass |
| 16. | MARKET FORECASTS |
| 16.1. | Introduction |
| 16.1.1. | 3D printing market forecast 2024-2034 |
| 16.2. | 3D Printing Hardware Forecasts |
| 16.2.1. | Forecast methodology and presentation of findings |
| 16.2.2. | 3D printing hardware market forecast 2024-2034 |
| 16.2.3. | 3D printing hardware market forecast by technology |
| 16.2.4. | 3D printing hardware market by technology |
| 16.2.5. | 3D printing hardware market by process |
| 16.2.6. | 3D printing hardware market by process |
| 16.2.7. | 3D printing hardware market by material |
| 16.2.8. | 3D printing hardware market by unit sale type |
| 16.2.9. | 3D printing hardware unit sales by technology |
| 16.2.10. | 3D printing install base by technology |
| 16.2.11. | 3D printing hardware market share in 2034 |
| 16.3. | 3D Printing Material Forecasts |
| 16.3.1. | Forecast methodology and presentation of findings |
| 16.3.2. | 3D printing materials forecast by material type - mass and revenue |
| 16.3.3. | 3D printing materials forecast by material type - Discussion |
| 16.3.4. | Polymer 3D printing materials forecast by feedstock - mass and revenue |
| 16.3.5. | Polymer Materials Forecast by Feedstock - Discussion |
| 16.3.6. | Metal 3D printing materials forecast by feedstock - mass and revenue |
| 16.3.7. | Metal AM Materials Forecast by Feedstock - Discussion |
| 17. | CONCLUSIONS |
| 17.1. | Key trends for 3D printing materials |
| 17.2. | Key trends for 3D printing hardware |
| 17.3. | Conclusions |
| 17.4. | Company profiles - 3D printer manufacturers |
| 17.5. | Company profiles - 3D printing materials, software, services |
| 18. | COMPANY PROFILES |
| 18.1. | 3D printer manufacturers |
| 18.1.1. | 3D Ceram Sinto |
| 18.1.2. | 3D Systems |
| 18.1.3. | 3D Systems (2022 Update) |
| 18.1.4. | 3D Systems (2023 Update) |
| 18.1.5. | 9T Labs |
| 18.1.6. | 9T Labs (2021 Update) |
| 18.1.7. | Aconity3D |
| 18.1.8. | ADDere |
| 18.1.9. | Addilan |
| 18.1.10. | Additive Industries |
| 18.1.11. | Admatec |
| 18.1.12. | AIM3D |
| 18.1.13. | Anisoprint |
| 18.1.14. | APS TechSolutions |
| 18.1.15. | APS TechSolutions (2021 Update) |
| 18.1.16. | Arevo |
| 18.1.17. | Arris Composites |
| 18.1.18. | Axtra3D |
| 18.1.19. | Azul3D |
| 18.1.20. | BCN3D Technologies |
| 18.1.21. | BeAM Machines |
| 18.1.22. | Bond3D |
| 18.1.23. | Chiron |
| 18.1.24. | Continuous Composites |
| 18.1.25. | Desktop Metal |
| 18.1.26. | DMG Mori |
| 18.1.27. | Electroimpact |
| 18.1.28. | EOS |
| 18.1.29. | Evolve Additive Solutions |
| 18.1.30. | Exaddon |
| 18.1.31. | ExOne |
| 18.1.32. | Foundry Lab |
| 18.1.33. | Fraunhofer IKTS |
| 18.1.34. | GE Additive |
| 18.1.35. | Gefertec |
| 18.1.36. | Hoganas (including Digital Metal) |
| 18.1.37. | HP 3D Printing |
| 18.1.38. | Impossible Objects |
| 18.1.39. | Inkbit |
| 18.1.40. | JuggerBot3D |
| 18.1.41. | Kumovis |
| 18.1.42. | Lithoz |
| 18.1.43. | Lithoz (2022 Update Interview) |
| 18.1.44. | Mantle |
| 18.1.45. | Markforged |
| 18.1.46. | Markforged (2023 Update) |
| 18.1.47. | Massivit 3D |
| 18.1.48. | Massivit 3D (2021 Update Interview) |
| 18.1.49. | MELD Manufacturing |
| 18.1.50. | Meltio |
| 18.1.51. | Meltio (2023 Update) |
| 18.1.52. | Metallum3D |
| 18.1.53. | Moi Composites |
| 18.1.54. | MX3D |
| 18.1.55. | Nano Dimension |
| 18.1.56. | Nanoscribe |
| 18.1.57. | Nexa3D |
| 18.1.58. | Nexa3D (2023 Update) |
| 18.1.59. | nScrypt |
| 18.1.60. | One Click Metal |
| 18.1.61. | Optomec |
| 18.1.62. | Optomec (2021 Update) |
| 18.1.63. | Optomec (2023 Update) |
| 18.1.64. | Orbital Composites |
| 18.1.65. | Photocentric |
| 18.1.66. | Photosynthetic |
| 18.1.67. | Prima Additive |
| 18.1.68. | Quantica |
| 18.1.69. | Quantica (2023 Update) |
| 18.1.70. | Rapidia |
| 18.1.71. | Renishaw |
| 18.1.72. | Roboze |
| 18.1.73. | Sciaky |
| 18.1.74. | SK-Fine |
| 18.1.75. | SLM Solutions |
| 18.1.76. | SPEE3D |
| 18.1.77. | SphereCube |
| 18.1.78. | Stratasys |
| 18.1.79. | Stratasys (2021 Update) |
| 18.1.80. | Stratasys (2022 Update) |
| 18.1.81. | Tethon3D |
| 18.1.82. | Titomic |
| 18.1.83. | Tritone Technologies |
| 18.1.84. | TRUMPF |
| 18.1.85. | Ultimaker |
| 18.1.86. | UpNano |
| 18.1.87. | ValCUN |
| 18.1.88. | Velo3D |
| 18.1.89. | Velo3D (2022 Update Interview) |
| 18.1.90. | WAAM3D |
| 18.1.91. | WAAM3D (2022 Update Interview) |
| 18.1.92. | Xerox |
| 18.1.93. | Xerox (2023 Update) |
| 18.1.94. | Xi'an Bright Laser Technology |
| 18.1.95. | Xolo |
| 18.1.96. | XJet |
| 18.2. | Materials Companies |
| 18.2.1. | 3D Strong |
| 18.2.2. | 6K |
| 18.2.3. | 6K Additive (2023 Update) |
| 18.2.4. | AlphaPowders |
| 18.2.5. | AlphaPowders (2023 Update) |
| 18.2.6. | BASF |
| 18.2.7. | Carpenter |
| 18.2.8. | Covestro |
| 18.2.9. | Elementum3D |
| 18.2.10. | Equispheres |
| 18.2.11. | Evonik |
| 18.2.12. | Gamma Alloys |
| 18.2.13. | Glassomer |
| 18.2.14. | Headmade Materials |
| 18.2.15. | Huntsman |
| 18.2.16. | Lubrizol |
| 18.2.17. | Materic: Synteris |
| 18.2.18. | Mechnano |
| 18.2.19. | Metalysis |
| 18.2.20. | Metalysis (2020 Update Interview) |
| 18.2.21. | Mitsubishi Chemical |
| 18.2.22. | Mitsubishi Chemical (2022 Update Interview) |
| 18.2.23. | Molecular Rebar Design |
| 18.2.24. | NanoAL |
| 18.2.25. | Nanoe |
| 18.2.26. | Oxford Performance Materials |
| 18.2.27. | Reflow |
| 18.2.28. | SAFINA |
| 18.2.29. | Schunk Carbon Technology |
| 18.2.30. | SGL Carbon |
| 18.2.31. | Solvay |
| 18.2.32. | TANIOBIS |
| 18.2.33. | Uniformity Labs |
| 18.2.34. | Victrex |
| 18.2.35. | Z3DLAB |
| 18.3. | Software and Services |
| 18.3.1. | 3D Inductors |
| 18.3.2. | 3T Additive Manufacturing |
| 18.3.3. | 3DEO |
| 18.3.4. | Addoptics |
| 18.3.5. | Addoptics (2023 Update) |
| 18.3.6. | Dassault Systemes |
| 18.3.7. | DyeMansion |
| 18.3.8. | FormAlloy |
| 18.3.9. | Graphite Additive Manufacturing |
| 18.3.10. | Guaranteed |
| 18.3.11. | Holo |
| 18.3.12. | Hyperganic |
| 18.3.13. | Luxexcel |
| 18.3.14. | Luxexcel (2023 Update) |
| 18.3.15. | MetShape |
| 18.3.16. | Norsk Titanium |
| 18.3.17. | OPT Industries |
| 18.3.18. | PrinterPrezz |
| 18.3.19. | Ricoh 3D |
| 18.3.20. | Seurat Technologies |
| 18.3.21. | Synbiosys |
| 19. | APPENDIX |
| 19.1. | 3D printing market forecast 2024-2034 |
| 19.2. | 3D printing hardware market forecast by technology |
| 19.3. | 3D printing hardware market by material |
| 19.4. | 3D printing hardware market by unit sale type |
| 19.5. | 3D printing hardware unit sales by technology |
| 19.6. | 3D printing install base by technology |
| 19.7. | 3D printing materials forecast by material type -mass |
| 19.8. | 3D printing materials forecast by material type - revenue |
| 19.9. | Polymer AM materials forecast by feedstock -mass |
| 19.10. | Polymer AM materials forecast by feedstock - revenue |
| 19.11. | Metal 3D printing materials forecast by feedstock - mass |
| 19.12. | Metal 3D printing materials forecast by feedstock - revenue |
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Report Statistics
| Slides | 477 |
|---|---|
| Companies | 152 |
| Forecasts to | 2034 |
| Published | Jan 2024 |
| ISBN | 9781835700099 |
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