3D Printed Batteries Market was valued at nearly US$ 26.08 Bn. in 2022 and the total revenue is expected to grow at 19.2% through 2022 to 2029, reaching US$ 89.20 Bn. By 2029. 3D-printed battery technology is manufacturing SSBs i.e. solid-state batteries on a large scale. 3D-printing is changing our globe and the technology is evolving rapidly and quickly becoming the basis of next-generation inventive 3D-printed energy buildings where batteries and super capacitors could be printed in essentially any shape.To know about the Research Methodology :- Request Free Sample Report Key players are involved in adopting sustainable strategies to gain competitive edges such as product up-gradation, new product launch, and collaborative agreements. Blackstone Company Develops 3D-Printed Solid-State Batteries: The Blackstone Company has been investing in the next generation of battery technology over its German subsidiary Blackstone Technology GmbH. This contains patented 3D-printing techniques and research into the mass manufacture of batteries, which has been exposed to propose greater energy density and an advanced number of charging cycles. The MMR report will also provide an accurate analysis of the contribution of the various segments to the growth of the 3D Printed Batteries market size. Based on the architectural process, the graphene-based Li-ion anodes segment expected to grow at the highest 45% CAGR during the forecast period. Li-ion battery capacity can be massively improved if, on the micro-scale, their electrodes have channels and pores.
3D Printed Batteries Market Regional Analysis:
North America 3D Printed Batteries Market was valued US$ xx Mn. in 2022 and is expected to reach a value of US$ xx Mn. by 2029, with a CAGR of 11% during the forecast period. Major Key players of 3D-printed batteries have been spending heavily in the U.S., particularly in the consumer electronics industry in the USA. Europe stood second largest in the 3D printed batteries market. APAC also plays important roles in 3D printed batteries market, with a market size of US$ xx Mn in 2022 and will be US$ xx Mn in 2029, with a CAGR of xx%. China’s rising defense budget, as well as the growing demand for advanced consumer electronics products in China, is prominent to the growth of 3D printed batteries market. Due to the covid-19 pandemic, the demand for 3D printing batteries has suffered because of the decline of electrical & electronics, automotive, and other industries. Though, with the recovery of all industry and high-performance properties of 3D printing batteries, the demand for metal 3D printing batteries is expected increase in the region by 2022. The objective of the report is to present a comprehensive analysis of the Global 3D Printed Batteries Market including all the stakeholders of the industry. The past and current status of the industry with forecasted market size and trends are presented in the report with the analysis of complicated data in simple language. The report covers all the aspects of the industry with a dedicated study of key players that includes market leaders, followers and new entrants. PORTER, SVOR, PESTEL analysis with the potential impact of micro-economic factors of the market has been presented in the report. External as well as internal factors that are supposed to affect the business positively or negatively have been analyzed, which will give a clear futuristic view of the industry to the decision-makers. The report also helps in understanding Global 3D Printed Batteries Market dynamics, structure by analyzing the market segments and projects the global market size. Clear representation of competitive analysis of key players by Application, price, financial position, Product portfolio, growth strategies, and regional presence in the Global 3D Printed Batteries Market make the report investor’s guide.3D Printed Batteries Market Scope: Inquire before buying
3D Printed Batteries Market Report Coverage Details Base Year: 2022 Forecast Period: 2023-2029 Historical Data: 2017 to 2022 Market Size in 2022: US$ 26.08 Bn. Forecast Period 2023 to 2029 CAGR: 19.2% Market Size in 2029: US$ 89.20 Bn. Segments Covered: by Architectural process • Graphene-based PLA filaments • Graphene-based Li-ion anodes • Solid-state graphene super capacitors • Platinum-based electrodes • Others by Application • Energy storage devices • Electronics • Others 3D Printed Batteries Market, by Region
• North America (United States, Canada and Mexico) • Europe (UK, France, Germany, Italy, Spain, Sweden, Austria and Rest of Europe) • Asia Pacific (China, South Korea, Japan, India, Australia, Indonesia, Malaysia, Vietnam, Taiwan, Bangladesh, Pakistan and Rest of APAC) • Middle East and Africa (South Africa, GCC, Egypt, Nigeria and Rest of ME&A) • South America (Brazil, Argentina Rest of South America)3D Printed Batteries Market Key players are:
• Keracel • Neware • Solvay • Stratasys Ltd. • Materialise NV • 3D Systems • EOS GmbHn • GE Additive • SLM Solutions • EXOne • Voxeljet • HP Company • Envision Tec • Blackstone Resources AG • Tec.Fit • Enicon Energy & Infrastructure Co. • Pawsthetics • ConmatiX Engineering Solutions GmbH • Filament & meer • Blackstone Resources Frequently Asked Questions: 1. Which region has the largest share in Global 3D Printed Batteries Market? Ans: North America region held the highest share in 2022. 2. What is the growth rate of Global 3D Printed Batteries Market? Ans: The Global 3D Printed Batteries Market is growing at a CAGR of 19.2% during forecasting period 2023-2029. 3. What is scope of the Global 3D Printed Batteries Market report? Ans: Global 3D Printed Batteries Market report helps with the PESTEL, PORTER, COVID-19 Impact analysis, Recommendations for Investors & Leaders, and market estimation of the forecast period. 4. Who are the key players in Global 3D Printed Batteries Market? Ans: The important key players in the Global 3D Printed Batteries Market are – Keracel, Neware, Solvay, Stratasys Ltd., Materialise NV, 3D Systems, EOS GmbHn, GE Additive, SLM Solutions, EXOne, Voxeljet, HP Company, Envision Tec, Blackstone Resources AG, Tec.Fit, Enicon Energy & Infrastructure Co., Pawsthetics, ConmatiX Engineering Solutions GmbH, Filament & meer, Blackstone Resources. 5. What is the study period of this Market? Ans: The Global 3D Printed Batteries Market is studied from 2022 to 2029.
Global 3D Printed Batteries Market 1. Preface 1.1. Report Scope and Market Segmentation 1.2. Research Highlights 1.3. Research Objectives 2. Assumptions and Research Methodology 2.1. Report Assumptions 2.2. Abbreviations 2.3. Research Methodology 2.3.1. Secondary Research 2.3.1.1. Secondary data 2.3.1.2. Secondary Sources 2.3.2. Primary Research 2.3.2.1. Data from Primary Sources 2.3.2.2. Breakdown of Primary Sources 3. Executive Summary: Global 3D Printed Batteries Market Size, by Market Value (US$ Bn) 4. Market Overview 4.1. Introduction 4.2. Market Indicator 4.2.1. Drivers 4.2.2. Restraints 4.2.3. Opportunities 4.2.4. Challenges 4.3. Porter’s Analysis 4.4. Value Chain Analysis 4.5. Market Risk Analysis 4.6. SWOT Analysis 4.7. Industry Trends and Emerging Technologies 5. Supply Side and Demand Side Indicators 6. Global 3D Printed Batteries Market Analysis and Forecast 6.1. 3D Printed Batteries Market Size & Y-o-Y Growth Analysis 6.1.1. North America 6.1.2. Europe 6.1.3. Asia Pacific 6.1.4. Middle East & Africa 6.1.5. South America 7. Global 3D Printed Batteries Market Analysis and Forecast, By Application 7.1. Introduction and Definition 7.2. Key Findings 7.3. 3D Printed Batteries Market Value Share Analysis, By Application 7.4. 3D Printed Batteries Market Size (US$ Bn) Forecast, By Application 7.5. 3D Printed Batteries Market Analysis, By Application 7.6. 3D Printed Batteries Market Attractiveness Analysis, By Application 8. Global 3D Printed Batteries Market Analysis and Forecast, By Architectural process 8.1. Introduction and Definition 8.2. Key Findings 8.3. 3D Printed Batteries Market Value Share Analysis, By Architectural process 8.4. 3D Printed Batteries Market Size (US$ Bn) Forecast, By Architectural process 8.5. 3D Printed Batteries Market Analysis, By Architectural process 8.6. 3D Printed Batteries Market Attractiveness Analysis, By Architectural process 9. Global 3D Printed Batteries Market Analysis, by Region 9.1. 3D Printed Batteries Market Value Share Analysis, by Region 9.2. 3D Printed Batteries Market Size (US$ Bn) Forecast, by Region 9.3. 3D Printed Batteries Market Attractiveness Analysis, by Region 10. North America 3D Printed Batteries Market Analysis 10.1. Key Findings 10.2. North America 3D Printed Batteries Market Overview 10.3. North America 3D Printed Batteries Market Value Share Analysis, By Application 10.4. North America 3D Printed Batteries Market Forecast, By Application 10.4.1. Energy storage devices 10.4.2. Electronics 10.4.3. Others 10.5. North America 3D Printed Batteries Market Value Share Analysis, By Architectural process 10.6. North America 3D Printed Batteries Market Forecast, By Architectural process 10.6.1. Graphene-based PLA filaments 10.6.2. Graphene-based Li-ion anodes 10.6.3. Solid state graphene super capacitors 10.6.4. Platinum-based electrodes 10.6.5. Other 10.7. North America 3D Printed Batteries Market Value Share Analysis, by Country 10.8. North America 3D Printed Batteries Market Forecast, by Country 10.8.1. USA 10.8.2. Canada 10.9. North America 3D Printed Batteries Market Analysis, by Country 10.10. USA 3D Printed Batteries Market Forecast, By Application 10.10.1. Energy storage devices 10.10.2. Electronics 10.10.3. Others 10.11. USA 3D Printed Batteries Market Forecast, By Architectural process 10.11.1. Graphene-based PLA filaments 10.11.2. Graphene-based Li-ion anodes 10.11.3. Solid state graphene super capacitors 10.11.4. Platinum-based electrodes 10.11.5. Other 10.12. Canada 3D Printed Batteries Market Forecast, By Application 10.12.1. Energy storage devices 10.12.2. Electronics 10.12.3. Others 10.13. Canada 3D Printed Batteries Market Forecast, By Architectural process 10.13.1. Graphene-based PLA filaments 10.13.2. Graphene-based Li-ion anodes 10.13.3. Solid state graphene super capacitors 10.13.4. Platinum-based electrodes 10.13.5. Other 10.14. North America 3D Printed Batteries Market Attractiveness Analysis 10.14.1. By Application 10.14.2. By Architectural process 10.15. PEST Analysis 10.16. Key Trends 10.17. Key Developments 11. Europe 3D Printed Batteries Market Analysis 11.1. Key Findings 11.2. Europe 3D Printed Batteries Market Overview 11.3. Europe 3D Printed Batteries Market Value Share Analysis, By Application 11.4. Europe 3D Printed Batteries Market Forecast, By Application 11.4.1. Energy storage devices 11.4.2. Electronics 11.4.3. Others 11.5. Europe 3D Printed Batteries Market Value Share Analysis, By Architectural process 11.6. Europe 3D Printed Batteries Market Forecast, By Architectural process 11.6.1. Graphene-based PLA filaments 11.6.2. Graphene-based Li-ion anodes 11.6.3. Solid state graphene super capacitors 11.6.4. Platinum-based electrodes 11.6.5. Other 11.7. Europe 3D Printed Batteries Market Value Share Analysis, by Country 11.8. Europe 3D Printed Batteries Market Forecast, by Country 11.8.1. UK 11.8.2. France 11.8.3. Germany 11.8.4. Italy 11.8.5. Spain 11.8.6. Norway 11.8.7. Russia 11.9. Europe 3D Printed Batteries Market Analysis, by Country 11.10. UK 3D Printed Batteries Market Forecast, By Application 11.10.1. Energy storage devices 11.10.2. Electronics 11.10.3. Others 11.11. UK 3D Printed Batteries Market Forecast, By Architectural process 11.11.1. Graphene-based PLA filaments 11.11.2. Graphene-based Li-ion anodes 11.11.3. Solid state graphene super capacitors 11.11.4. Platinum-based electrodes 11.11.5. Other 11.12. France 3D Printed Batteries Market Forecast, By Application 11.12.1. Energy storage devices 11.12.2. Electronics 11.12.3. Others 11.13. France 3D Printed Batteries Market Forecast, By Architectural process 11.13.1. Graphene-based PLA filaments 11.13.2. Graphene-based Li-ion anodes 11.13.3. Solid state graphene super capacitors 11.13.4. Platinum-based electrodes 11.13.5. Other 11.14. Germany 3D Printed Batteries Market Forecast, By Application 11.14.1. Energy storage devices 11.14.2. Electronics 11.14.3. Others 11.15. Germany 3D Printed Batteries Market Forecast, By Architectural process 11.15.1. Graphene-based PLA filaments 11.15.2. Graphene-based Li-ion anodes 11.15.3. Solid state graphene super capacitors 11.15.4. Platinum-based electrodes 11.15.5. Other 11.16. Italy 3D Printed Batteries Market Forecast, By Application 11.16.1. Energy storage devices 11.16.2. Electronics 11.16.3. Others 11.17. Italy 3D Printed Batteries Market Forecast, By Architectural process 11.17.1. Graphene-based PLA filaments 11.17.2. Graphene-based Li-ion anodes 11.17.3. Solid state graphene super capacitors 11.17.4. Platinum-based electrodes 11.17.5. Other 11.18. Spain 3D Printed Batteries Market Forecast, By Application 11.18.1. Energy storage devices 11.18.2. Electronics 11.18.3. Others 11.19. Spain 3D Printed Batteries Market Forecast, By Architectural process 11.19.1. Hospital 11.19.2. Child Care Center 11.19.3. Nursing Center 11.19.4. Home Care 11.20. Norway 3D Printed Batteries Market Forecast, By Application 11.20.1. Energy storage devices 11.20.2. Electronics 11.20.3. Others 11.21. Norway 3D Printed Batteries Market Forecast, By Architectural process 11.21.1. Graphene-based PLA filaments 11.21.2. Graphene-based Li-ion anodes 11.21.3. Solid state graphene super capacitors 11.21.4. Platinum-based electrodes 11.21.5. Other 11.22. Russia 3D Printed Batteries Market Forecast, By Application 11.22.1. Energy storage devices 11.22.2. Electronics 11.22.3. Others 11.23. Russia 3D Printed Batteries Market Forecast, By Architectural process 11.23.1. Graphene-based PLA filaments 11.23.2. Graphene-based Li-ion anodes 11.23.3. Solid state graphene super capacitors 11.23.4. Platinum-based electrodes 11.23.5. Other 11.24. Europe 3D Printed Batteries Market Attractiveness Analysis 11.24.1. By Application 11.24.2. By Architectural process 11.25. PEST Analysis 11.26. Key Trends 11.27. Key Developments 12. Asia Pacific 3D Printed Batteries Market Analysis 12.1. Key Findings 12.2. Asia Pacific 3D Printed Batteries Market Overview 12.3. Asia Pacific 3D Printed Batteries Market Value Share Analysis, By Application 12.4. Asia Pacific 3D Printed Batteries Market Forecast, By Application 12.4.1. Energy storage devices 12.4.2. Electronics 12.4.3. Others 12.5. Asia Pacific 3D Printed Batteries Market Value Share Analysis, By Architectural process 12.6. Asia Pacific 3D Printed Batteries Market Forecast, By Architectural process 12.6.1. Graphene-based PLA filaments 12.6.2. Graphene-based Li-ion anodes 12.6.3. Solid state graphene super capacitors 12.6.4. Platinum-based electrodes 12.6.5. Other 12.7. Asia Pacific 3D Printed Batteries Market Value Share Analysis, by Country 12.8. Asia Pacific 3D Printed Batteries Market Forecast, by Country 12.8.1. China 12.8.2. India 12.8.3. Japan 12.8.4. South Korea 12.8.5. Australia 12.8.6. Malaysia 12.8.7. Indonesia 12.8.8. Vietnam 12.9. Asia Pacific 3D Printed Batteries Market Analysis, by Country 12.10. China 3D Printed Batteries Market Forecast, By Application 12.10.1. Energy storage devices 12.10.2. Electronics 12.10.3. Others 12.11. China 3D Printed Batteries Market Forecast, By Architectural process 12.11.1. Graphene-based PLA filaments 12.11.2. Graphene-based Li-ion anodes 12.11.3. Solid state graphene super capacitors 12.11.4. Platinum-based electrodes 12.11.5. Other 12.12. India 3D Printed Batteries Market Forecast, By Application 12.12.1. Energy storage devices 12.12.2. Electronics 12.12.3. Others 12.13. India 3D Printed Batteries Market Forecast, By Architectural process 12.13.1. Graphene-based PLA filaments 12.13.2. Graphene-based Li-ion anodes 12.13.3. Solid state graphene super capacitors 12.13.4. Platinum-based electrodes 12.13.5. Other 12.14. Japan 3D Printed Batteries Market Forecast, By Application 12.14.1. Energy storage devices 12.14.2. Electronics 12.14.3. Others 12.15. Japan 3D Printed Batteries Market Forecast, By Architectural process 12.15.1. Graphene-based PLA filaments 12.15.2. Graphene-based Li-ion anodes 12.15.3. Solid state graphene super capacitors 12.15.4. Platinum-based electrodes 12.15.5. Other 12.16. South Korea 3D Printed Batteries Market Forecast, By Application 12.16.1. Energy storage devices 12.16.2. Electronics 12.16.3. Others 12.17. South Korea 3D Printed Batteries Market Forecast, By Architectural process 12.17.1. Graphene-based PLA filaments 12.17.2. Graphene-based Li-ion anodes 12.17.3. Solid state graphene super capacitors 12.17.4. Platinum-based electrodes 12.17.5. Other 12.18. Australia 3D Printed Batteries Market Forecast, By Application 12.18.1. Energy storage devices 12.18.2. Electronics 12.18.3. Others 12.19. Australia 3D Printed Batteries Market Forecast, By Architectural process 12.19.1. Graphene-based PLA filaments 12.19.2. Graphene-based Li-ion anodes 12.19.3. Solid state graphene super capacitors 12.19.4. Platinum-based electrodes 12.19.5. Other 12.20. Malaysia 3D Printed Batteries Market Forecast, By Application 12.20.1. Energy storage devices 12.20.2. Electronics 12.20.3. Others 12.21. Malaysia 3D Printed Batteries Market Forecast, By Architectural process 12.21.1. Graphene-based PLA filaments 12.21.2. Graphene-based Li-ion anodes 12.21.3. Solid state graphene super capacitors 12.21.4. Platinum-based electrodes 12.21.5. Other 12.22. Indonesia 3D Printed Batteries Market Forecast, By Application 12.22.1. Energy storage devices 12.22.2. Electronics 12.22.3. Others 12.23. Indonesia 3D Printed Batteries Market Forecast, By Architectural process 12.23.1. Graphene-based PLA filaments 12.23.2. Graphene-based Li-ion anodes 12.23.3. Solid state graphene super capacitors 12.23.4. Platinum-based electrodes 12.23.5. Other 12.24. Vietnam 3D Printed Batteries Market Forecast, By Application 12.24.1. Energy storage devices 12.24.2. Electronics 12.24.3. Others 12.25. Vietnam 3D Printed Batteries Market Forecast, By Architectural process 12.25.1. Graphene-based PLA filaments 12.25.2. Graphene-based Li-ion anodes 12.25.3. Solid state graphene super capacitors 12.25.4. Platinum-based electrodes 12.25.5. Other 12.26. Asia Pacific 3D Printed Batteries Market Attractiveness Analysis 12.26.1. By Application 12.26.2. By Architectural process 12.27. PEST Analysis 12.28. Key Trends 12.29. Key Developments 13. Middle East & Africa 3D Printed Batteries Market Analysis 13.1. Key Findings 13.2. Middle East & Africa 3D Printed Batteries Market Overview 13.3. Middle East & Africa 3D Printed Batteries Market Value Share Analysis, By Application 13.4. Middle East & Africa 3D Printed Batteries Market Forecast, By Application 13.4.1. Energy storage devices 13.4.2. Electronics 13.4.3. Others 13.5. Middle East & Africa 3D Printed Batteries Market Value Share Analysis, By Architectural process 13.6. Middle East & Africa 3D Printed Batteries Market Forecast, By Architectural process 13.6.1. Graphene-based PLA filaments 13.6.2. Graphene-based Li-ion anodes 13.6.3. Solid state graphene super capacitors 13.6.4. Platinum-based electrodes 13.6.5. Other 13.7. Middle East & Africa 3D Printed Batteries Market Value Share Analysis, by Country 13.8. Middle East & Africa 3D Printed Batteries Market Forecast, by Country 13.8.1. GCC Countries 13.8.2. South Africa 13.8.3. Nigeria 13.8.4. Egypt 13.9. Middle East & Africa 3D Printed Batteries Market Analysis, by Country 13.10. GCC 3D Printed Batteries Market Forecast, By Application 13.10.1. Energy storage devices 13.10.2. Electronics 13.10.3. Others 13.11. GCC 3D Printed Batteries Market Forecast, By Architectural process 13.11.1. Graphene-based PLA filaments 13.11.2. Graphene-based Li-ion anodes 13.11.3. Solid state graphene super capacitors 13.11.4. Platinum-based electrodes 13.11.5. Other 13.12. South Africa 3D Printed Batteries Market Forecast, By Application 13.12.1. Energy storage devices 13.12.2. Electronics 13.12.3. Others 13.13. South Africa 3D Printed Batteries Market Forecast, By Architectural process 13.13.1. Graphene-based PLA filaments 13.13.2. Graphene-based Li-ion anodes 13.13.3. Solid state graphene super capacitors 13.13.4. Platinum-based electrodes 13.13.5. Other 13.14. Nigeria 3D Printed Batteries Market Forecast, By Application 13.14.1. Energy storage devices 13.14.2. Electronics 13.14.3. Others 13.15. Nigeria 3D Printed Batteries Market Forecast, By Architectural process 13.15.1. Graphene-based PLA filaments 13.15.2. Graphene-based Li-ion anodes 13.15.3. Solid state graphene super capacitors 13.15.4. Platinum-based electrodes 13.15.5. Other 13.16. Egypt 3D Printed Batteries Market Forecast, By Application 13.16.1. Energy storage devices 13.16.2. Electronics 13.16.3. Others 13.17. Egypt 3D Printed Batteries Market Forecast, By Architectural process 13.17.1. Graphene-based PLA filaments 13.17.2. Graphene-based Li-ion anodes 13.17.3. Solid state graphene super capacitors 13.17.4. Platinum-based electrodes 13.17.5. Other 13.18. Middle East & Africa 3D Printed Batteries Market Attractiveness Analysis 13.18.1. By Application 13.18.2. By Architectural process 13.19. PEST Analysis 13.20. Key Trends 13.21. Key Developments 14. South America 3D Printed Batteries Market Analysis 14.1. Key Findings 14.2. South America 3D Printed Batteries Market Overview 14.3. South America 3D Printed Batteries Market Value Share Analysis, By Application 14.4. South America 3D Printed Batteries Market Forecast, By Application 14.4.1. Energy storage devices 14.4.2. Electronics 14.4.3. Others 14.5. South America 3D Printed Batteries Market Value Share Analysis, By Architectural process 14.6. South America 3D Printed Batteries Market Forecast, By Architectural process 14.6.1. Graphene-based PLA filaments 14.6.2. Graphene-based Li-ion anodes 14.6.3. Solid state graphene super capacitors 14.6.4. Platinum-based electrodes 14.6.5. Other 14.7. South America 3D Printed Batteries Market Value Share Analysis, by Country 14.8. South America 3D Printed Batteries Market Forecast, by Country 14.8.1. Brazil 14.8.2. Mexico 14.8.3. Argentina 14.9. South America 3D Printed Batteries Market Analysis, by Country 14.10. Brazil 3D Printed Batteries Market Forecast, By Application 14.10.1. Energy storage devices 14.10.2. Electronics 14.10.3. Others 14.11. Brazil 3D Printed Batteries Market Forecast, By Architectural process 14.11.1. Graphene-based PLA filaments 14.11.2. Graphene-based Li-ion anodes 14.11.3. Solid state graphene super capacitors 14.11.4. Platinum-based electrodes 14.11.5. Other 14.12. Mexico 3D Printed Batteries Market Forecast, By Application 14.12.1. Energy storage devices 14.12.2. Electronics 14.12.3. Others 14.13. Mexico 3D Printed Batteries Market Forecast, By Architectural process 14.13.1. Graphene-based PLA filaments 14.13.2. Graphene-based Li-ion anodes 14.13.3. Solid state graphene super capacitors 14.13.4. Platinum-based electrodes 14.13.5. Other 14.14. Argentina 3D Printed Batteries Market Forecast, By Application 14.14.1. Energy storage devices 14.14.2. Electronics 14.14.3. Others 14.15. Argentina 3D Printed Batteries Market Forecast, By Architectural process 14.15.1. Graphene-based PLA filaments 14.15.2. Graphene-based Li-ion anodes 14.15.3. Solid state graphene super capacitors 14.15.4. Platinum-based electrodes 14.15.5. Other 14.16. South America 3D Printed Batteries Market Attractiveness Analysis 14.16.1. By Application 14.16.2. By Architectural process 14.17. PEST Analysis 14.18. Key Trends 14.19. Key Developments 15. Company Profiles 15.1. Market Share Analysis, by Company 15.2. Competition Matrix 15.2.1. Competitive Benchmarking of key players by price, presence, market share, and R&D investment 15.2.2. New Product Launches and Product Enhancements 15.2.3. Market Consolidation 15.2.3.1. M&A by Regions, Investment and Vehicles 15.2.3.2. M&A Key Players, Forward Integration and Backward Integration 15.3. Company Profiles: Key Players 15.3.1. Keracel. 15.3.1.1. Company Overview 15.3.1.2. Financial Overview 15.3.1.3. Product Portfolio 15.3.1.4. Business Strategy 15.3.1.5. Recent Developments 15.3.1.6. Development Footprint 15.3.2. Neware 15.3.3. Solvay 15.3.4. Stratasys Ltd. 15.3.5. Materialise NV 15.3.6. 3D Systems 15.3.7. EOS GmbHn 15.3.8. GE Additive 15.3.9. SLM Solutions 15.3.10. EXOne 15.3.11. Voxeljet 15.3.12. HP Company 15.3.13. Envision Tec 15.3.14. Blackstone Resources AG 15.3.15. Tec.Fit 15.3.16. Enicon Energy & Infrastructure Co. 15.3.17. Pawsthetics 15.3.18. ConmatiX Engineering Solutions GmbH 15.3.19. Filament & meer 15.3.20. Blackstone Resources 16. Primary Key Insights