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There has been an increasing demand for 3D Printing Medical Devices Industry in a global scheme, so several market analysts have dedicated time and effort to get into the bottom of the trend and see whether there’s basis for this significant market performance. With the most current research data, analysts were able to understand the concept behind global 3D Printing Medical Devices Industry.
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Historical data, as well as current statistics from governmental and private sectors are used to project the status of the market in the present day and to predict its position in the next 5 years. Taking into account marketing reports from 2016 and evaluating several factors that affect market growth, there is has been a clear result.
Market research reports for the global 3D Printing Medical Devices Industry included detailed segmentation of international products, analysis of supply and demand trends, 5-year forecast of market growth, volumes of historic brand market, analysis of the production, importation and exportation, and transparent market methodology. In-depth studies regarding 3D Printing Medical Devices Industry, with data from 2016 and projects of compound annual growth rates (CAGRs) are also used as basis for research. Lastly, there are examinations of the global demand for the market and profiles of the major players of the industry.
With all the data gathered and analyzed using SWOT analysis, there was a clearer picture of the competitive landscape of the global 3D Printing Medical Devices Industry. Sources for the future market growth were uncovered and outlying competitive threats also surfaced. There was strategic direction eminent in the market and this shows in the key trends and developments studied. By getting market background and using current norms, policies, and trends of other leading markets for cross-references, market data was completed.
In conclusion, evaluation of the significant performance of the global 3D Printing Medical Devices Industry is led by various analysis tools and in-depth research reports. Cross-references are employed to finalize and establish clear results.
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Table of Contents:
Part I 3D Printing Medical Devices Industry Overview
Chapter One 3D Printing Medical Devices Industry Overview
1.1 3D Printing Medical Devices Definition
1.2 3D Printing Medical Devices Classification Analysis
1.3 3D Printing Medical Devices Application Analysis
1.4 3D Printing Medical Devices Industry Chain Structure Analysis
1.5 3D Printing Medical Devices Industry Development Overview
1.6 3D Printing Medical Devices Global Market Comparison Analysis
Chapter Two 3D Printing Medical Devices Up and Down Stream Industry Analysis
2.1 Upstream Raw Materials Analysis
2.2 Down Stream Market Analysis
Part II Asia 3D Printing Medical Devices Industry (The Report Company Including the Below Listed But Not All)
Chapter Three Asia 3D Printing Medical Devices Market Analysis
3.1 Asia 3D Printing Medical Devices Product Development History
3.2 Asia 3D Printing Medical Devices Process Development History
3.3 Asia 3D Printing Medical Devices Industry Policy and Plan Analysis
3.4 Asia 3D Printing Medical Devices Competitive Landscape Analysis
3.5 Asia 3D Printing Medical Devices Market Development Trend
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NEW YORK, Jan 17, 2017 (PR Newswire Europe via COMTEX) — NEW YORK, January 17, 2017 /PRNewswire/ –
Technological advancements and high customization potential coupled with growing adoption in various industries to drive Brazil 3D printing market by 2021
According to a recently released TechSci Research report, “Brazil 3D Printing Market [https://www.techsciresearch.com/report/brazil-3d-printing-market-by-printer-type-personal-3d-printer-vs-industrial-3d-printer-by-maintenance-service-system-maintenance-contract-training-etc-by-material-plastics-metal-etc-competition-forecast-opportunities/866.html ] , By Printer Type, By Maintenance & Service, By Material, Competition Forecast & Opportunities, 2011 – 2021″, the 3D printing market in Brazil is anticipated to cross $400 Million by 2021. With growing adoption of 3D printers in various end user industries such as automotive, aerospace & defence, healthcare, consumer electronics, etc. for numerous applications including prototyping, designing, Research & Development (R&D), etc., the 3D printing market in the country is expected to grow at a robust pace over the next five years.
Browse 28 market data Tables and 38 Figures spread through137 Pages and an in-depth TOC on
“Brazil 3D Printing Market” https://www.techsciresearch.com/report/brazil-3d-printing-market-by-printer-type-personal-3d-printer-vs-industrial-3d-printer-by-maintenance-service-system-maintenance-contract-training-etc-by-material-plastics-metal-etc-competition-forecast-opportunities/866.html
Brazil Aerospace Industry Market Size, By Value, 2010-2015 (USD Billion)
Market Size, by Value Year (USD Billion) 2010 6.70 2011 6.80 2012 7.50 2013 7.00 2014 6.40 2015 6.90 Source: Aerospace Industries Association (AIA), Brasil
Plastic is the most preferred type of 3D printing material in Brazil for various applications including various toys, prototypes, kitchenware, miniatures, etc. South East region accounted for the lion’s share in the country’s 3D printing market in 2015. Sao Paulo, Brazil’s most populous state, falls under this region and contributed around 40% of the country’s total GDP in 2015. Sao Paulo’s logistics and transportation infrastructure is considered to be the best in Brazil, and comprises a vast network of modern highways, an international airport and well-developed waterways and railroads. Few of the leading players operating in Brazil 3D printing market include EnvisionTech, EOS, 3D Systems and Stratasys, among others.
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“Increasing market for luxury cars coupled with growing need for various functionalities in cars including gesture control enabled navigational systems are fueling the investments by vehicle manufacturers for manufacturing and designing of car parts such as chassis using 3D printing for faster production, better durability and improved innovative design.”, said Mr. Karan Chechi, Research Director with TechSci Research, a research based global management consulting firm.
“Brazil 3D Printing Market, By Printer Type, By Maintenance & Service, By Material, Competition Forecast & Opportunities, 2011 – 2021″ has evaluated the future growth potential of Brazil 3D printing market and provides statistics and information on market size, structure and future market growth. The report intends to provide cutting-edge market intelligence and help decision makers take sound investment evaluation. Besides, the report also identifies and analyzes the emerging trends along with essential drivers, challenges and opportunities in Brazil 3D printing market.
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This report studies Medical 3D Printing Materials in Global market, especially in North America, Europe, China, Japan, Southeast Asia and India, focuses on top manufacturers in global market, with capacity, production, price, revenue and market share for each manufacturer, covering
Regenovo Biotechnology (Shining 3D Tech)
Market Segment by Regions, this report splits Global into several key Regions, with production, consumption, revenue, market share and growth rate of Medical 3D Printing Materials in these regions, from 2011 to 2021 (forecast), like
Split by product type, with production, revenue, price, market share and growth rate of each type, can be divided into
Split by application, this report focuses on consumption, market share and growth rate of Medical 3D Printing Materials in each application, can be divided into
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Table of Contents
Global Medical 3D Printing Materials Market Research Report 2016
1 Medical 3D Printing Materials Market Overview
1.1 Product Overview and Scope of Medical 3D Printing Materials
1.2 Medical 3D Printing Materials Segment by Type
1.2.1 Global Production Market Share of Medical 3D Printing Materials by Type in 2015
1.3 Medical 3D Printing Materials Segment by Application
1.3.1 Medical 3D Printing Materials Consumption Market Share by Application in 2015
1.3.4 Hearing Aid
1.3.6 Medical Devices
1.4 Medical 3D Printing Materials Market by Region
1.4.1 North America Status and Prospect (2011-2021)
1.4.2 Europe Status and Prospect (2011-2021)
1.4.3 China Status and Prospect (2011-2021)
1.4.4 Japan Status and Prospect (2011-2021)
1.4.5 Southeast Asia Status and Prospect (2011-2021)
1.4.6 India Status and Prospect (2011-2021)
1.5 Global Market Size (Value) of Medical 3D Printing Materials (2011-2021)
2 Global Medical 3D Printing Materials Market Competition by Manufacturers
2.1 Global Medical 3D Printing Materials Capacity, Production and Share by Manufacturers (2015 and 2016)
2.2 Global Medical 3D Printing Materials Revenue and Share by Manufacturers (2015 and 2016)
2.3 Global Medical 3D Printing Materials Average Price by Manufacturers (2015 and 2016)
2.4 Manufacturers Medical 3D Printing Materials Manufacturing Base Distribution, Sales Area and Product Type
2.5 Medical 3D Printing Materials Market Competitive Situation and Trends
2.5.1 Medical 3D Printing Materials Market Concentration Rate
2.5.2 Medical 3D Printing Materials Market Share of Top 3 and Top 5 Manufacturers
2.5.3 Mergers & Acquisitions, Expansion
7 Global Medical 3D Printing Materials Manufacturers Profiles/Analysis
7.1.1 Company Basic Information, Manufacturing Base and Its Competitors
7.1.2 Medical 3D Printing Materials Product Type, Application and Specification
22.214.171.124 Type I
126.96.36.199 Type II
7.1.3 Stratasys Medical 3D Printing Materials Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)
7.1.4 Main Business/Business Overview
7.2.1 Company Basic Information, Manufacturing Base and Its Competitors
7.2.2 Medical 3D Printing Materials Product Type, Application and Specification
188.8.131.52 Type I
184.108.40.206 Type II
7.2.3 Formlab Medical 3D Printing Materials Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)
7.2.4 Main Business/Business Overview
7.3 ACS material
7.3.1 Company Basic Information, Manufacturing Base and Its Competitors
7.3.2 Medical 3D Printing Materials Product Type, Application and Specification
220.127.116.11 Type I
18.104.22.168 Type II
7.3.3 ACS material Medical 3D Printing Materials Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)
7.3.4 Main Business/Business Overview
7.4.1 Company Basic Information, Manufacturing Base and Its Competitors
7.4.2 Medical 3D Printing Materials Product Type, Application and Specification
22.214.171.124 Type I
126.96.36.199 Type II
7.4.3 EnvisionTEC Medical 3D Printing Materials Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)
7.4.4 Main Business/Business Overview
7.5.1 Company Basic Information, Manufacturing Base and Its Competitors
7.5.2 Medical 3D Printing Materials Product Type, Application and Specification
188.8.131.52 Type I
184.108.40.206 Type II
7.5.3 EOS Medical 3D Printing Materials Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)
7.5.4 Main Business/Business Overview
7.6.1 Company Basic Information, Manufacturing Base and Its Competitors
7.6.2 Medical 3D Printing Materials Product Type, Application and Specification
220.127.116.11 Type I
18.104.22.168 Type II
7.6.3 Organovo Medical 3D Printing Materials Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)
7.6.4 Main Business/Business Overview
7.7 Regenovo Biotechnology (Shining 3D Tech)
7.7.1 Company Basic Information, Manufacturing Base and Its Competitors
7.7.2 Medical 3D Printing Materials Product Type, Application and Specification
22.214.171.124 Type I
126.96.36.199 Type II
7.7.3 Regenovo Biotechnology (Shining 3D Tech) Medical 3D Printing Materials Capacity, Production, Revenue, Price and Gross Margin (2015 and 2016)
7.7.4 Main Business/Business Overview
8 Medical 3D Printing Materials Manufacturing Cost Analysis
8.1 Medical 3D Printing Materials Key Raw Materials Analysis
8.1.1 Key Raw Materials
8.1.2 Price Trend of Key Raw Materials
8.1.3 Key Suppliers of Raw Materials
8.1.4 Market Concentration Rate of Raw Materials
8.2 Proportion of Manufacturing Cost Structure
8.2.1 Raw Materials
8.2.2 Labor Cost
8.2.3 Manufacturing Expenses
8.3 Manufacturing Process Analysis of Medical 3D Printing Materials
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Sheridan’s Centre for Advanced Manufacturing and Design Technologies (CAMDT) is expanding its capabilities after a major funding announcement.
The Honourable Reza Moridi, Minister of Research, Innovation and Science, was joined by Amrit Mangat, MPP for Mississauga-Brampton South at Sheridan’s Davis Campus to announce the $2 million investment.
The contribution of $763,183 coming from the Ontario Research Fund, matches a previously-announced contribution from the Canada Foundation for Innovation. This funding, combined with over $400,000 in industry contributions, amounts to a $2 million investment in Sheridan.
“Our government recognizes the importance of investing in our innovation ecosystem,” said Minister Moridi. “We are proud to support the work of people in Mississauga and Brampton who are at the forefront of scientific discovery. Their research will pave the way for future advancements that will help Ontario compete and win in the global economy.”
The investment will go towards The Advanced Multi-material Additive Manufacturing: Product and Process Project, under the leadership of Dr. Farzad Rayegani, Director of Sheridan’s Centre for Advanced Manufacturing and Design Technologies (CAMDT). New equipment will be introduced into the lab, allowing for a wider range of material options.
As more and more materials become available and the technology advances, additive manufacturing can be used within a number of different industries including medical, automotive, aerospace, and more.
“This investment offers tremendous potential for new partnership opportunities with small and medium-sized businesses, as well as for new advances in the health care sector,” said Dr. Jeff Zabudsky, Sheridan’s President and Vice Chancellor. “It will also expand the variety of research and innovation opportunities where our students – the innovators of tomorrow – can make a difference.”
The report, named “Global 3D Printing for Healthcare Market”, provides a Detailed overview of the 3D Printing for Healthcare Market related to overall world. Report assesses the size of the 3D Printing for Healthcare market and also estimates the valuation of the Global 3D Printing for Healthcare market by the end of the given forecast period. Worldwide report on ” 3D Printing for Healthcare Market” includes a comprehensive study of the 3D Printing for Healthcare market and defines the key terminologies as well as 3D Printing for Healthcare market classifications for the benefit of new entrants to the Worldwide 3D Printing for Healthcare market.
This report points out the 3D Printing for Healthcare Market drivers and restraints affecting the growth of the 3D Printing for Healthcare market. It also cites the various 3D Printing for Healthcare Industry opportunities for the 3D Printing for Healthcare market to grow in the next couple of years.The report studies the global 3D Printing for Healthcare market on the basis of major product types and end user segments. The report related to 3D Printing for Healthcare Market also compiles data from relevant industry bodies to forecast the growth of each of the segments related 3D Printing for Healthcare Market Scenario.
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Of all the materials that have been formatted for 3D printing—particularly in the medical and aerospace industries—titanium has become the eye of the prize. Whether it’s used to produce a 3D printed vertebral implant, a beak replacement for an injured macaw, or even for building fire-fighting drones, there’s no denying the presence that titanium materials have in the increasingly expansive metal 3D printing market. It seemed that there was nowhere to go but up for this valuable metal alloy, but a recent study from the Pittsburgh, Pennsylvania-based Carnegie Mellon University suggests that the current state of 3D printed titanium may be ‘fatally flawed’.
After conducting deep x-rays on 3D printed titanium, researchers have discovered porosity within the material, which stems back to the powder-based production technique. Using the most popular form of titanium, Ti-gAI-4V (6% aluminum and 4% vanadium), the team from Carnegie Mellon turned to the Illinois-based US Department of Energy’s (DOE’s) Argonne National Laboratory to help analyze the material with intense synchrotron x-rays and an advanced rapid imaging tool known as microtomography. Their findings showed that when titanium powders are used with a Selective Laser Melting (SLM) 3D printer or an Electron Beam Melting (EBM) technique, gas is trapped in the resulting liquid layer, which creates porous bubbles within the 3D printed metal.
These minute spaces can range from a couple to a few hundred microns, and are also randomly distributed, causing a potential fault line in objects that are produced with titanium powder material. This news is especially alarming because of the immense value 3D printed titanium now has in the medical and aerospace industries. Not only has titanium allowed for patient-specific implants and customized aerospace parts, it has also reduced cost and waste while doing so. This critical research is certainly alarming for the aerospace industry, which requires components that usually endure massive amounts of stress. It’s less of an issue for medical applications, considering that any form of titanium is seen as a stronger material than the bone that it is replacing.
Though processes like SLM have proven beneficial in many ways, this research may lead to some changes in the way titanium—along with other metal-based materials—is 3D printed. The research team found that the power, speed, and spacing of the printer’s laser beam could all impact the porosity within the titanium 3D print. The CMU researchers observed the porosity within several samples of Ti-6Al-4V, all of which were printed with differing parameters using an EBM process. Although these adjusted parameters helped the research team to reduce porosity in the 3D printed titanium, they were unable to eliminate it completely.
“Relative to printing speed and spacing, if you decrease the power level and the melt pool becomes too small, you may leave behind unmelted powder, which is a source of porosity,” said Anthony Rollett, Professor of Materials Science and Engineering at CMU. “However, if you increase the power level too much, you risk creating deep holes, called keyholes, with the electron beam that also leave behind voids.”
According to the CMU research, it’s nearly impossible to completely eliminate porosity from titanium, but they also believe that there is a sweet spot somewhere between unmelted powder and too much powder that could optimize the way that 3D printed titanium is produced. The research team will now turn to researching titanium in its powder stage, which Rollett believes could be the stage in which porosity begins. The research findings were published in the Journal of Minerals, Metals, and Materials Society, entitled “Evaluating the Effect of Processing Parameters on Porosity in Electron Beam Melted Ti-6Al-4V via Synchrotron X-ray Microtomography“, which was co-authored by Rollett, Ross Cunningham, Sneha P. Narra, Tugce Ozturkt, and Jack Beuth.
This study is certainly alarming for the 3D printing community as a whole, as metal 3D printing has been slowly integrated into a much broader range of applications. But the news should be most worrisome to those within aerospace industry, which has been looking to increase their use of 3D printed titanium for mission critical components. Though aerospace companies like Boeing and Airbus may need to take a step back and reexamine their implementation of 3D printed titanium parts, the increasingly well-researched industry should be able to persevere and overcome.
[Source: Argonne National Laboratory]