3D Printing Market
By Technology (Stereolithography (SLA), Selective Laser Sintering (SLS), Electron Beam Melting (EBM), Fused Deposition Modeling (FDM), Direct Metal Laser Sintering (DMLS), Polyjet/MultiJet Printing (MJP), Others),
By Process (Powder Bed Fusion, VAT Polymerization, Material Jetting, Material Extrusion, Binder Jetting, Others),
By Application (Prototyping, Part Manufacturing, Tooling),
By Material (Thermoplastics [Acrylonitrile Butadiene Styrene (ABS), Polycarbonate (PC), Nylon/Polyamide, Other Thermoplastics], Metal [Stainless Steel, Aluminium, Titanium, Nickel], Others),
By End Use Industry (Automotive and Industrial, Aerospace and Defense, Healthcare and Pharma, Plastics and Jewelry, Energy, and Construction, Others),
By Region (North America, Europe, Asia-Pacific, Latin America, Middle East & Africa):
Global Analysis and Forecast 2023-2033
The global 3D Printing market showcased a revenue of USD 15.7 billion in 2022 and is projected to witness a compounded annual growth rate (CAGR) of more than 20.03% over the forecast period of 2023-2033.
Russia-Ukraine War Impact
Market Scope
About the Market
Impact of COVID-19
Global Economic Slowdown
Market Dynamics
Driver
Restrain
Opportunity
Recent Developments
Synopsis
How is this report helpful
FAQ's
Report Coverage
3D printing, in other words, additive manufacturing, is the process by which a digital file is used to create three-dimensional tangible, solid objects. These objects are fashioned by laying down sequential layers of material until the object is created, where each of these layers can be seen as an intricately carved cross-section of the object. 3D printing empowers manufacturers to produce complex shapes consuming less material as compared to traditional manufacturing methods. 3D printing has gained popularity rapidly because it makes manufacturing manageable for more people than ever. This is partially due to the price (the starting price for a basic 3D printer is about $300) but also the small size of the printers compared to traditional manufacturing.
As per the analysis over the forecast period, 3D printing and additive manufacturing will be critical in the evolution of bridging the gaps between the digital and physical worlds and setting new standards for business. The traditional economies of scale and scope are altering, setting the stage for a novel generation of market prospects and end-to-end supply network proficiencies. Along with 3D printers getting faster, their build volume and printable object size are also increasing. A few years ago, an archetypal high-end metal printer could only build an object that was smaller than 10 x 10 x 10 centimeters or a cubic liter. In 2019, multiple printers were available with a 30 x 30 x 30-centimeter volume, or 27 cubic liters. This permitted bigger objects to be made without necessitating printing and assembling smaller objects. Furthermore, at labs such as Oak Ridge National Laboratory with its Big Area Additive Manufacturing (BAAM) technology, progress is being made on exceptionally large build volumes, with the x, y, and z axes measured in meters rather than centimeters. Some huge companies are incoming in the 3D-printing market, corroborating the space and pushing the overall industry to modernize even faster. These large companies are fetching research investment, credibility, large customer bases, and marketing muscle, and fortuitously for the industry's growth, they are mostly escalating the inclusive pie rather than captivating sales away from prevailing players.
The demand for the 3D Printing market is majorly coming from the North American region, followed by Asia-Pacific and the European region. In the Asia-Pacific region, China is feasibly the biggest force behind 3D printing growth in the region owing to huge government support to promote the industry. China's 3D printing market was estimated to be worth $1.8 billion in 2018. Currently, it is the third-largest 3D printing market after the U.S. and Western Europe. Until recently, the Asia-Pacific region has been lagging in 3D printing adoption compared to North America and Europe. However, growing interest from APAC manufacturing companies and the introduction of many government-led strategies and policies have helped several countries within the region to succeed in creating a sustainable AM environment. In 2019, according to an Ernest and Young report, 78% of surveyed Chinese companies had already implemented 3D printing, and this explains a growing demand for smarter, more efficient production in China is on the rise. 3D printing is one technology companies are employing to meet this need.
Impact of the Russia-Ukraine War on the 3D Printing Market
There is a direct impact of the Russia-Ukraine war on the global 3D Printing market. However, the European region will witness the highest impact. Increased trade sanctions across the European region, followed by disruption in global trade routes, are one of the major factors imposed due to war and limiting business opportunities. 3D printing is immensely supportive in wartime because of its flexibility and speed, which diminishes the logistical nightmares of conveying needed supplies. Most 3D printers are moderately small and can be set up in basement bunkers, making them ideal for wartime production. Furthermore, the technology allows parts to be produced at scale in multiple locations at a time and for the designs to be shared digitally among numerous facilities or individual producers, making it, in some sense, designed for use during a crisis or war. For instance, in March 2022, a Warsaw-based 3D printing firm Sygnis supplied 20 printers and more than 800 pounds of the raw printing material called filament across the border to a 3D Tech Group in Lviv, located in western Ukraine. Ukraine's volunteer effort has printed over 10,000 items, including protective gear, tourniquets, and drones, using 3D printers. The crisis fueled the growth of the 3D printing market, making manufacturing things easier and highlighting the importance of 3D printing in today's world.
3D Printing: Market Scope
The 3D printing market is divided into five segments technology, process, application, material, and end-use industry. Furthermore, these segments are subdivided into respective categories and cross-referenced to North America, Europe, Asia-Pacific, Latin America, and Middle East & Africa for regional analysis. The technology segment is further categorized into stereolithography (SLA), selective laser sintering (SLS), electron beam melting (EBM), fused deposition modeling (FDM), direct metal laser sintering (DMLS), polyjet/multijet printing (MJP) and others. The process segment is segregated into powder bed fusion, vat polymerization, material jetting, material extrusion, and binder jetting. The application segment of the 3D printing market is bifurcated into prototyping, part manufacturing, and tooling. With respect to material, the industry is analyzed by thermoplastics [acrylonitrile butadiene styrene (ABS), polycarbonate (PC), nylon/polyamide, other thermoplastics], metal [stainless steel, aluminum, titanium, nickel] and others. The end-use industry segment is segregated into automotive and industrial, aerospace and defense, healthcare and pharma, plastics and jewelry, energy, construction, and others. Each of these segments is further classified into regions: North America, Europe, Asia-Pacific, Latin America, and Middle East & Africa. The historical dataset of 2018-2022 is provided in the report, whereas the forecast period of 2023-2033 is offered.
Stereolithography (SLA) will witness the highest growth rate within the Technology segment
Stereolithography (SLA) shows a fulfilling revenue generation in the technology segment. Stereolithography uses a vat of liquid curable photopolymer resin and an ultraviolet laser to shape the object's layers one at a time. The laser beam traces a cross-section of the part pattern on the surface of the liquid resin for each layer. Exposure to the ultraviolet laser light cures and solidifies the pattern traced on the resin and fuses it to the layer below. After the pattern has been traced, the SLA's elevator platform descends by a distance equal to the thickness of a single layer, typically 0.05 mm to 0.15 mm (0.002″ to 0.006″). Then, a resin-filled blade sweeps across the cross-section of the part, re-coating it with fresh material. The subsequent layer pattern is traced on this new liquid surface, joining the previous layer. Depending on the object & print orientation, SLA often necessitates the use of sustenance structures. SLA parts have the maximum resolution and accuracy, the sharpest details, and the smoothest surface textures of all 3D printing technologies, but the main advantage of stereolithography lies in its adaptability. Material manufacturers have created innovative SLA resin formulations with a wide range of optical, mechanical, and thermal properties to match the standard, engineering, and industrial thermoplastics. Advancements in 3D printing technology continue to modify the way businesses approach prototyping and production. For instance, in April 2019, Formlabs launched Form 3 and Form 3L, powered by Low Force Stereolithography (LFS). These new printers offer unbelievable print quality, lighter supports, and a platform for more cutting-edge materials and applications. The LFS process impeccably balances to a build volume five times larger than the normal desktop 3D printers with Form 3L. The ease of use and quality of Stereolithography (SLA) makes it an outright choice of technology for the 3D printing market.
The VAT Polymerization will capture the highest market share between 2023-2033
It is observed that the VAT Polymerization segment would be capturing a higher market share in the process segment. In vat photopolymerization, a liquid photopolymer (i.e., plastic) in a vat is selectively cured by light-activated polymerization. Hence, the process is also referred to as light polymerization. Stereolithography is a VAT Polymerization process. Vat polymerization techniques are effective for producing items with a clean surface finish and fine details. As a result, they are perfect for a variety of dental and medical applications, low-run prototype injection molding, and jewelry. Also, this technology works at a swift speed to give exceedingly abridged products. The rising need for high precision and level finish of the Vat Photosensitization 3D printing technique empowers its widespread application in particular areas such as healthcare, automotive, aerospace, defense, and construction. It is prophesied that demand will surge significantly over the coming years. The growing interest of companies in this process for 3D printing is likely to make it the most preferred process during the forecast period.
The Part Manufacturing segment will capture the highest market share in the coming years
Part manufacturing is capturing a larger market share in the applications segment during the forecast period. Developments in AM make it commercially fascinating for manufacturers and asset-heavy companies struggling with their spare parts management to start building a digital inventory for spare parts printing. From time to time, asset-heavy companies have to wait weeks for the replacement of a fragmented spare part, which adversely impacts the uptime of their assets. The ancillary to have all parts in stock and express-delivered is a huge cost or pressure on balance sheets. Thus, additive manufacturing makes it possible to produce spare parts in small quantities, even single items, at a remarkably low cost. Transportation time and costs are saved since parts can also be printed locally. Several trains with printed spare parts are already in use in the Netherlands. The NS, the Dutch Railways, can now replace dozens of train parts with printed parts. Likewise, in 2018, NS's German sister Deutsche Bahn printed 15,000 spare parts for its trains. ERIKS, a Dutch industrial products provider with over 900,000 parts in stock, has also started printing some spare parts. The high cost and time-saving provided by additive manufacturing will make part manufacturing more popular during the forecast period.
A metal segment within the material to witness the highest CAGR during the forecast timeframe
The forecast timeframe has predicted the proliferation in demand for metal material for the 3D printing market. The innovations in the metal-printing field are accredited to the increased demand for metal as a material. Many metal parts have been printed using selective laser sintering (SLS) in the last few years. This process is relatively slow and expensive, and it requires a near-vacuum environment. A more recent technology called binder jet metal printing was made widely available in 2019, which halved the time required to produce each part. Metal printing is predominantly seeing debauched growth in China, with Bright Laser Technologies and Shining 3D developing metal laser-based 3D printers. For example, Shining 3D expanded its line of AM products with the release of the EP-M150 3D printer, which is suited to small metal 3D printing applications, one example being dental crowns. The printer is known to be proficient in producing 500 crowns using only 1 kg of metal powder. Between 2017 and 2018, a 3D-printing industry survey showed that, although plastic was still the most common material, its share in 3D printing fell from 88 percent to 65 percent in that single year alone, while the share of metal printing rose from 28 percent to 36 percent. With increasing applications of 3D printing in the automotive and aerospace industry, metal will dominate the market in terms of material during the forecast period.
The aerospace and Defense segment within the End-Use Industry will witness the highest CAGR during the forecast timeframe
The aerospace and defense segment will capture the highest market share in the end-use industry during the forecast time period. The first 3D-printed aircraft parts used were in 2014 in an Airbus test aircraft with a small titanium bracket. The usage of additive manufacturing has escalated rapidly since then owing to maximizing production output, shortening time-to-market, reducing costs, and more. 3D printing can help companies with a daunting stockpile of orders slash their production time. For instance, in November 2018, Airbus reported a backlog of more than 7,000 aircraft. Likewise, in September 2018, Boeing's backlog of commercial aircraft was close to 6,000. With the on-demand manufacturing, easy customization, and part consolidation enabled by additive manufacturing, aerospace manufacturers can significantly shorten their time-to-market. According to a report by Deloitte, Aerospace manufacturers using additive manufacturing can reduce time-to-market by 64 percent. 3D printing has the potential to alleviate an aircraft by 55 percent, according to Airbus CTO Grazia Vittadini. An average-sized plane flown by many popular commercial airlines weighs 90,000 pounds (excluding fuel and passengers). However, a reduction of 55% would bring it down to a little over 40,000 pounds. Since the mass of an aircraft is unswervingly associated with its fuel consumption over the useful life of the airframe, this will decline the number of fuel planes consumed. 3D printing increases the sustainability of the aerospace industry, in other words. As for the defense industry, Airbus engineers in the defense and space division found out that additive manufacturing is the most resourceful approach for creating satellite parts. The designers and engineers objectified many of the benefits of 3D printing using titanium. For example, the dearth of waste led to cost savings, and part alliance reduced the hours spent in assembly. The augmented geometry resulted in advanced performance without traditional manufacturing restrictions, and the lightweight components created fuel savings for the entire project. 3D printing's biggest benefit to the defense industry may be its ability to produce functional electric components in addition to mechanical parts. With additive manufacturing, OEMs can churn out circuit boards and antennas at a portion of the time, cost, and materials.
North America is to witness the highest growth rate during the forecast period
The demand for the 3D Printing market is mainly coming from the North American region during the forecast period. The high adoption rate of 3D printing in the region, coupled with technological advancements and the growing aviation and automotive industry in the region, are fueling the growth in the region. During Covid 19 pandemic, America Makes, a private-public partnership focused on growing the US additive manufacturing industry, played a significant role in convening regulatory bodies and connecting them to individual makers to confirm equipment was being made properly. Products such as surgical face masks, face shields, and gowns needed to be made to exacting specifications during the pandemic, and so America Makes, which is a national institute and part of the Manufacturing USA network, worked with senates from agencies such as the National Institutes of Health, Veterans Health Administration, and the Food and Drug Administration to acquire specifications and pass them on to individuals. The demand for customized products in the region is another factor triggering market growth.
Impact of COVID-19 on 3D Printing Market
COVID-19 significantly impacted the 3D Printing market in terms of blocked distribution channels forcing economies to become self-sustained. The dramatic role it played earlier in 2020 in alleviating shortages of personal protective equipment (PPE) for health workers on the front lines of the COVID-19 pandemic was a very visible reminder of how far flexible additive manufacturing (AM) technologies have come in just a few years, and their growing value as a source of stability in a volatile and uncertain world. The COVID-19 pandemic and subsequent lockdowns revealed weaknesses in current supply chains that led many manufacturing companies to re-evaluate their supply chain strategy in several dimensions making 3D printing the best alternative. As borders began to close, many manufacturers faced stockouts of spare parts. To avoid shortages, they reached out to local 3D printing service providers to enlist their help when they were running short of stock. In 2018, 24% of 900 manufacturing companies surveyed by the EY organization used 3D printing technology. However, by the end of 2019, 65% reported deploying it in their regular manufacturing line, out of a sample operating in 9 industries based in 13 leading manufacturing countries. The pandemic accelerated the adoption of additive manufacturing. It became the need of the hour for major manufacturers.
3D Printing: Market Dynamics
The market dynamics section of the report covers a depth analysis of drivers, restraints, and opportunities impacting the 3D Printing market. The report also encompasses major market strategies practiced by the industry, followed by patent analysis, product analysis, competitive benchmarking of companies, PORTER and PESTLE analysis of the 3D Printing industry, pricing analysis, and geographic competitiveness to provide a detailed understanding. The major players operating in the market are 3D Systems Corporation, EOS, Envisiontec, Inc., GE Additive, HP, Markforged, Materialise NV, Renishaw, Stratasys Ltd., and Ultimaker. These companies cumulatively hold the majority of the 3D Printing market share and actively undergoes strategic development, such as new product launch, merger, collaboration, business expansion, acquisition, and long-term contracts to ensure market penetration. These companies also largely focus on research and development to gain competitiveness in the market. A detailed analysis of these companies is offered in the report.
Driver: Significant investments by the government to become self-sufficient boost the market growth
The increasing market Demand for 3D printing is a collective outcome of the growing interest of governments to become self-sufficient, resulting in them turning to the 3D printing market to attain that goal. It has led to governments investing substantially and implementing policies working in favor of the market. In 2017, the Chinese government issued the 'Additive Manufacturing Industry Development Action Plan,' which forms part of the 'Made in China 2025' strategic roadmap for the country's manufacturing sector, outlining long-term ambitions and development goals to make China one of the leading 3D printing nations. One of the highlights of the plan is a goal to introduce over 100 AM pilot projects across ten key industries, including the medical, cultural, educational, and Internet sectors. To accomplish these goals, China is fostering promising AM companies, backing standardization for the Chinese AM industry, and investing in 3D printing workforce development. In 2015, China founded the first 3D Printing College in the world, Baiyun-Winbo 3D Printing Technology College, located in Guangzhou. The country also has plans to install 3D printers in 4,00,000 elementary schools. Initiatives such as these will benefit the Chinese economy in the long term, as the people will be educated and skilled in 3D technology from a young age. South Korea also has a strong focus on 3D printing growth, with the government establishing a 3D printing roadmap for R&D in 2014, which aims to support the existing industry with an integrated ecosystem that consents players to easily use and connect with 3D printing technology. Central and local governments have recognized eight 3D printing regional centers across the country to deliver 3D printing infrastructure and consulting services. The race to establish a self-sustainable economy will fuel the 3D printing market growth.
Restrain: Lack of awareness and understanding about 3D printing hinder the market growth
3D printing is a relatively new industry and has been the next big thing since 2012. Consumer knowledge about 3D printing is very restricted, and they do not understand how much it can do. AMFG found that customers had vital knowledge gaps about the proficiencies and limitations of 3D printing. This lack of knowledge extends from entry-level consumers to massive businesses. Consumers also do not understand how reasonably priced 3D printing can be. While the market has grown considerably, it has left consumers lost on "how much the service does or should cost." Most consumers still view 3D printing as a revolutionary technology of tomorrow, while in reality, the tech is already at their fingertips. For instance, in August 2022, research was conducted to study Malaysia's consumer response to 3D food printing technology. In this study, the respondents exhibited a low awareness of 3D food printing, which led to a preliminary neutral defiance towards the technology. This is due to a lack of knowledge and no acquaintance with that technology. Respondents' readiness to consume 3D printed food and their benefit discernment towards the technology suggested a positive attitude, while a negative attitude was subsidized by food technology neophobia and foreignness. Fascinatingly, the respondents' attitudes were enhanced suggestively with the assistance of the infographic included in the survey as the medium for the respondents to have an inkling about 3D food printing. This illustrates that information delivery is important in developing consumers about 3D printing, or this could reduce the adoption rate of additive printing and hinder market growth.
Opportunity: Increasing demand for customized products coupled with reduced waste to create market demand
The 3D Printing market shows promising opportunities in the North American region and developing countries of other regions. This is largely observed due to increasing consumers' demand for customized products and reduced waste generation from manufacturing products using 3D printing, complying with zero waste policies of various governments. For a long time, customization in the retail world was offered through the same product in different colors and sizes, but now, offering items that are approximately the right size or an acceptable color is not good enough. Consumers are seeking items specifically tailor-made for them. Consumers are progressively expecting larger mass customization of products and services globally. According to a survey by YouGov, the personalization economy saw a demand increase from 17% to 26% between 2015-18. In other words, at least one in four Americans say they have purchased a personalized product for themselves or someone else. About 30% of surveyed Americans expressed at least some interest in personalized products, and one in four said they had personalized a product for themselves or someone else, up from one in six in 2015. At the same time, consumers realize that this is still a luxury and are willing to pay more for it. Forty-six percent of surveyed Americans in the YouGov survey said they are willing to pay for personalization, and 19% of those who had never previously personalized a product are also willing to pay more. Along with delivering superior products, 3D printing is environmentally friendly. Experts say 3D printing in the construction industry can reduce waste by 95% or more. Depending on the technology, it has the potential to unlock truly zero-waste construction, eliminating approximately 4.4 pounds per square foot, on average, that go to landfills. With increasing personalization trends and minimal waste generation, 3D printing is likely to see a surge in market demand.
3D Printing Market: Recent Developments
- In March 2022, the specialty chemicals company Evonik and Australia's 3D printer manufacturer Asiga collaborated on photopolymer-based 3D printing for large-scale industrial manufacturing. Evonik is contributing its proficiency in developing and manufacturing ready-to-use photopolymer materials, while Asiga is bringing its innovative strength in DLP 3D printers with its open material architecture to the joint effort.
- In June 2020, Forward AM and HP, the leader in industrial end-to-end 3D printing solutions, expanded their strategic alliance to advance digital manufacturing. This expansion is a shared vision of both companies to help convert industries, enable sustainable production, and enable their customers to shape additive manufacturing industrialization.
- In December 2020, Stratasys acquired Origin for $100 million as a key part of its strategy to lead in polymer 3D printing for manufacturing. In April 2021, Stratasys introduced the Stratasys Origin One 3D printer, designed for end-use manufacturing applications. The Origin One system uses proprietary P3 technology to produce parts in high performance materials with industry-leading accuracy, repeatability, and time to part.
3D Printing Market: Synopsis
The study of the 3D Printing market offers revenue and growth data sets of segments provided at the global, regional, and country levels. The report offers the historical data set for 2018-2022 and the forecast period of 2023-2033. For analysis, Quadrant Market Insights (QMI) has segregated the 3D Printing market into five major segments as follows:
By Technology
- Stereolithography (SLA)
- Selective Laser Sintering (SLS)
- Electron Beam Melting (EBM)
- Fused Deposition Modeling (FDM)
- Direct Metal Laser Sintering (DMLS)
- Polyjet/Multijet Printing (MJP)
- Others
By Process
- Powder Bed Fusion
- VAT Polymerization
- Material Jetting
- Material Extrusion
- Binder Jetting
- Others
By Application
- Prototyping
- Part Manufacturing
- Tooling
By Material
- Thermoplastics
- Acrylonitrile Butadiene Styrene (ABS)
- Polycarbonate (PC)
- Nylon/Polyamide
- Other Thermoplastics - Metal
- Stainless Steel
- Aluminium
- Titanium
- Nickel - Others
By End Use Industry
- Automotive and Industrial
- Aerospace and Defense
- Healthcare and Pharma
- Plastics and Jewellery
- Energy and Construction
- Others
The regional analysis of the 3D Printing market is as follows:
North America
- U.S.
- Canada
- Mexico
Europe
- UK
- Germany
- France
- Russia
- Italy
- Spain
- Rest of Europe
Asia-Pacific
- China
- India
- Japan
- Australia
- Rest of Asia-Pacific
Latin America
- Brazil
- Mexico
- Argentina
- Chile
Middle East & Africa
- South Africa
- UAE
- Saudi Arabia
- Israel
Key players operating in the 3D Printing industry are:
- 3D Systems Corporation
- EOS
- Envisiontec, Inc.
- GE Additive
- HP
- Markforged
- Materialise NV
- Renishaw
- Stratasys Ltd.
- Ultimaker
3D printing Market: Who Should Purchase, and How It Will Help Readers
- The report is best suited for top-level decision-makers, individuals who are supposed to take a leadership role or require market research to start a business, independent researchers, research institutes, and anyone who wishes to gain detailed strategic insights into the 3D printing market.
- This report provides a qualitative and quantitative analysis of the market segments, current trends, estimations, and dynamics of the 3D printing market analysis from 2018 to 2033 to identify the prevailing market opportunities.
- Market research and information related to key drivers, restraints, and opportunities are offered.
- Porter's five forces and PESTLE analysis highlight the potency of buyers and suppliers to enable stakeholders' market profit-oriented business decisions and strengthen their supplier-buyer network.
- An in-depth analysis of the 3D printing segmentation assists in determining the prevailing market opportunities.
- Major countries in each region are mapped according to their revenue contribution to the global market.
- Market player positioning facilitates benchmarking and provides a clear understanding of the present position of the market players.
- The report includes an analysis of the regional and global 3D printing industry trends, key players, market segments, application areas, and market growth strategies.
- The report offers insights from primary interviews and CXOs of major industry players. It also offers a comprehensive contact and event repository to ensure future collaborations among industry stakeholders.
3D printing Market: Frequently Asked Questions (FAQ)
Q: How big is the 3D printing market?
A: The global 3D Printing market showcased a revenue of USD 15.7 billion in 2022 and is projected to witness a compounded annual growth rate (CAGR) of more than 20.03% over the forecast period of 2023-2033.
Q: Does the report have several 3D printing numbers bifurcated by segments and regions?
A: The report offers a total number of 3D printing market, further bifurcated into segments and regions. Please refer to the TOC page for more information.
Q: What are the major trends in the 3D printing market?
A:The attempt by national governments to become self-sufficient, increase disposable income in developing regions, and increase demand for customized products affect market growth of the 3D Printing market.
Q: How can I get the sample Report on the 3D printing market?
A: The 3D printing market report sample can be obtained on demand from the website. Also, 24*7 chat support and direct call services are provided to procure the sample report
Q: Is it possible to purchase a specific or customized report as per my needs
A: Yes, it is possible to purchase a specific part of the report or edit the scope of the report at your convenience. Feel free to drop us the mail/talk to our customer support or schedule a conversation to procure a customized report.
Report Coverage
- Technology
- Process
- Application
- Material
- End Use Industry
- North America
- Europe
- Asia-Pacific
- Latin America
- Middle East & Africa
- Significant investments by the government to become self-sufficient boost the market growth
- Increasing demand for customized products coupled with reduced waste to create market demand
- Lack of awareness and understanding about 3D printing hinder the market growth
3D Systems Corporation, EOS, Envisiontec, Inc., GE Additive, HP, Markforged, Materialise NV, Renishaw, Stratasys Ltd., and Ultimaker.
1. Introduction
1.1 Report Description
1.1.1 Definition
1.1.2 Abbreviations
1.2 Key Market Segments
1.3 Benefits to Stakeholders
1.4 Research Methodology
1.4.1 Market Scoping
1.4.1.1 Problem Identification
1.4.1.2 Defining the Market
1.4.2 Market Estimation
1.4.2.1 Data Mining
1.4.2.2 Product Analysis
1.4.2.3 Application Analysis
1.4.2.4 Market Engineering and Forecasting
1.4.2.4.1 Bottom-up Demand Side
1.4.2.4.2 Bottom-up Supply side
1.4.3 Market Authentication
1.4.3.1 Data Triangulation
1.4.3.1.1 Top-down Supply Side
1.4.3.1.2 Top-down Demand Side
1.4.3.1.3 Data Triangulation
1.4.3.2 Primary Insights and Industry feedback
1.4.4 Report Writing
2. Executive Summary
2.1 Market Snapshot
2.2 Macro Trends, Global Economic Factors and Import/Export Insights
2.3 Primary Insights
2.4 Technology Insights
2.5 Process Insights
2.6 Application Insights
2.7 Material Insights
2.8 End Use Industry Insights
2.9 Regional Insights
3. Market Overview
3.1 Market Segment and Scope
3.2 Top Investment Pockets
3.3 Key Strategic Initiatives
3.4 3D Printing Market Industry Ecosystem
3.5 Market Evolution
3.6 Patent Analysis
3.7 Technology Landscape
3.8 Regulatory Infrastructure
3.9 Porter’s Analysis
3.9.1 Bargaining Power of Buyer
3.9.2 Bargaining Power of Supplier
3.9.3 Threat of New Entrants
3.9.4 Threat of Substitutes
3.9.5 Industry Rivalry
3.10 PESTLE Analysis
3.11 Market Dynamics
3.11.1 Drivers
3.11.2 Restrains
3.11.3 Opportunities
3.12 Impact of COVID-19 on 3D Printing Market
3.13 Russia-Ukraine War Impact on 3D Printing Market
3.14 Growth Share Matrix
3.15 3D Printing Market Quadrant
4. 3D Printing Market, By Technology
4.1 Major Impacting Factors, By Technology
4.1.1 Key Market Trends and Growth Factors
4.1.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.1.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.2 Stereolithography (SLA)
4.2.1 Key Market Trends and Growth Factors
4.2.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.2.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.3 Selective Laser Sintering (SLS)
4.3.1 Key Market Trends and Growth Factors
4.3.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.3.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.4 Electron Beam Melting (EBM)
4.4.1 Key Market Trends and Growth Factors
4.4.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.4.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.5 Fused Deposition Modeling (FDM)
4.5.1 Key Market Trends and Growth Factors
4.5.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.5.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.6 Direct Metal Laser Sintering (DMLS)
4.6.1 Key Market Trends and Growth Factors
4.6.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.6.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.7 Polyjet/Multijet Printing (MJP)
4.7.1 Key Market Trends and Growth Factors
4.7.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.7.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
4.8 Others
4.8.1 Key Market Trends and Growth Factors
4.8.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
4.8.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
5. 3D Printing Market, By Process
5.1 Major Impacting Factors, By Process
5.1.1 Key Market Trends and Growth Factors
5.1.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
5.1.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
5.2 Powder Bed Fusion
5.2.1 Key Market Trends and Growth Factors
5.2.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
5.2.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
5.3 VAT Polymerization
5.3.1 Key Market Trends and Growth Factors
5.3.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
5.3.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
5.4 Material Jetting
5.4.1 Key Market Trends and Growth Factors
5.4.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
5.4.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
5.5 Material Extrusion
5.5.1 Key Market Trends and Growth Factors
5.5.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
5.5.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
5.6 Binder Jetting
5.6.1 Key Market Trends and Growth Factors
5.6.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
5.6.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
5.7 Others
5.7.1 Key Market Trends and Growth Factors
5.7.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
5.7.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
6. 3D Printing Market, By Application
6.1 Major Impacting Factors, By Application
6.1.1 Key Market Trends and Growth Factors
6.1.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
6.1.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
6.2 Prototyping
6.2.1 Key Market Trends and Growth Factors
6.2.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
6.2.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
6.3 Part Manufacturing
6.3.1 Key Market Trends and Growth Factors
6.3.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
6.3.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
6.4 Tooling
6.4.1 Key Market Trends and Growth Factors
6.4.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
6.4.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7. 3D Printing Market, By Material
7.1 Major Impacting Factors, By Material
7.1.1 Key Market Trends and Growth Factors
7.1.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.1.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.2 Thermoplastics
7.2.1 Key Market Trends and Growth Factors
7.2.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.2.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.2.4 Acrylonitrile Butadiene Styrene (ABS)
7.2.4.1 Key Market Trends and Growth Factors
7.2.4.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.2.4.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.2.5 Polycarbonate (PC)
7.2.5.1 Key Market Trends and Growth Factors
7.2.5.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.2.5.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.2.6 Nylon/Polyamide
7.2.6.1 Key Market Trends and Growth Factors
7.2.6.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.2.6.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.2.7 Other Thermoplastics
7.2.7.1 Key Market Trends and Growth Factors
7.2.7.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.2.7.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.3 Metal
7.3.1 Key Market Trends and Growth Factors
7.3.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.3.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.3.4 Stainless Steel
7.3.4.1 Key Market Trends and Growth Factors
7.3.4.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.3.4.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.3.5 Aluminium
7.3.5.1 Key Market Trends and Growth Factors
7.3.5.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.3.5.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.3.6 Titanium
7.3.6.1 Key Market Trends and Growth Factors
7.3.6.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.3.6.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.3.7 Nickel
7.3.7.1 Key Market Trends and Growth Factors
7.3.7.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.3.7.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
7.4 Others
7.4.1 Key Market Trends and Growth Factors
7.4.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
7.4.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8. 3D Printing Market, By End Use Industry
8.1 Major Impacting Factors, By End Use Industry
8.1.1 Key Market Trends and Growth Factors
8.1.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
8.1.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8.2 Automotive and Industrial
8.2.1 Key Market Trends and Growth Factors
8.2.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
8.2.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8.3 Aerospace and Defense
8.3.1 Key Market Trends and Growth Factors
8.3.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
8.3.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8.4 Healthcare and Pharma
8.4.1 Key Market Trends and Growth Factors
8.4.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
8.4.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8.5 Plastics and Jewellery
8.5.1 Key Market Trends and Growth Factors
8.5.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
8.5.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8.6 Energy and Construction
8.6.1 Key Market Trends and Growth Factors
8.6.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
8.6.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
8.7 Others
8.7.1 Key Market Trends and Growth Factors
8.7.2 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
8.7.3 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
9. 3D Printing Market, By Region
9.1 Global Market Trends and Growth Factors
9.2 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.3 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.4 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.5 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.5.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.5.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.6 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.7 Market Size and Forecast, by Region, 2018-2033, (USD Billion)
9.8 North America
9.8.1 Key Market Trends and Growth Factors
9.8.2 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.8.3 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.8.4 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.8.5 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.8.5.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.8.5.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.8.6 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.8.7 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
9.8.8 U.S.
9.8.8.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.8.8.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.8.8.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.8.8.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.8.8.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.8.8.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.8.8.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.8.9 Canada
9.8.9.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.8.9.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.8.9.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.8.9.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.8.9.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.8.9.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.8.9.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.8.10 Mexico
9.8.10.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.8.10.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.8.10.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.8.10.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.8.10.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.8.10.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.8.10.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.9 Europe
9.9.1 Key Market Trends and Growth Factors
9.9.2 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.9.3 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.9.4 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.9.5 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.9.5.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.9.5.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.9.6 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.9.7 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
9.9.8 UK
9.9.8.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.9.8.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.9.8.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.9.8.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.9.8.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.9.8.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.9.8.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.9.9 Germany
9.9.9.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.9.9.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.9.9.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.9.9.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.9.9.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.9.9.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.9.9.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.9.10 France
9.9.10.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.9.10.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.9.10.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.9.10.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.9.10.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.9.10.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.9.10.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.9.11 Russia
9.9.11.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.9.11.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.9.11.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.9.11.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.9.11.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.9.11.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.9.11.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.9.12 Italy
9.9.12.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.9.12.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.9.12.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.9.12.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.9.12.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.9.12.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.9.12.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.9.13 Rest of Europe
9.9.13.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.9.13.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.9.13.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.9.13.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.9.13.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.9.13.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.9.13.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.10 Asia-Pacific
9.10.1 Key Market Trends and Growth Factors
9.10.2 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.10.3 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.10.4 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.10.5 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.10.5.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.10.5.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.10.6 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.10.7 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
9.10.8 China
9.10.8.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.10.8.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.10.8.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.10.8.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.10.8.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.10.8.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.10.8.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.10.9 India
9.10.9.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.10.9.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.10.9.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.10.9.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.10.9.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.10.9.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.10.9.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.10.10 Japan
9.10.10.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.10.10.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.10.10.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.10.10.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.10.10.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.10.10.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.10.10.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.10.11 Australia
9.10.11.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.10.11.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.10.11.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.10.11.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.10.11.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.10.11.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.10.11.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.10.12 Rest of Asia-Pacific
9.10.12.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.10.12.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.10.12.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.10.12.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.10.12.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.10.12.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.10.12.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.11 Latin America
9.11.1 Key Market Trends and Growth Factors
9.11.2 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.11.3 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.11.4 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.11.5 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.11.5.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.11.5.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.11.6 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.11.7 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
9.11.8 Brazil
9.11.8.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.11.8.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.11.8.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.11.8.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.11.8.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.11.8.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.11.8.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.11.9 Argentina
9.11.9.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.11.9.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.11.9.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.11.9.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.11.9.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.11.9.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.11.9.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.11.10 Mexico
9.11.10.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.11.10.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.11.10.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.11.10.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.11.10.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.11.10.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.11.10.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.11.11 Chile
9.11.11.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.11.11.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.11.11.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.11.11.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.11.11.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.11.11.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.11.11.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.12 Middle East and Africa
9.12.1 Key Market Trends and Growth Factors
9.12.2 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.12.3 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.12.4 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.12.5 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.12.5.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.12.5.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.12.6 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.12.7 Market Size and Forecast, by Country, 2018-2033, (USD Billion)
9.12.8 South Africa
9.12.8.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.12.8.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.12.8.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.12.8.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.12.8.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.12.8.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.12.8.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.12.9 UAE
9.12.9.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.12.9.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.12.9.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.12.9.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.12.9.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.12.9.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.12.9.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.12.10 Saudi Arabia
9.12.10.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.12.10.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.12.10.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.12.10.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.12.10.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.12.10.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.12.10.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
9.12.11 Israel
9.12.11.1 Market Size and Forecast, by Technology, 2018-2033, (USD Billion)
9.12.11.2 Market Size and Forecast, by Process, 2018-2033, (USD Billion)
9.12.11.3 Market Size and Forecast, by Application, 2018-2033, (USD Billion)
9.12.11.4 Market Size and Forecast, by Material, 2018-2033, (USD Billion)
9.12.11.4.1 Market Size and Forecast, by Thermoplastics, 2018-2033, (USD Billion)
9.12.11.4.2 Market Size and Forecast, by Metal, 2018-2033, (USD Billion)
9.12.11.5 Market Size and Forecast, by End Use Industry, 2018-2033, (USD Billion)
10. Competitive Benchmarking & Company Profiles
10.1 Competitive Benchmarking
10.1.1 Company Market Share
10.1.2 Product Mapping
10.1.3 Competitive Heat map
10.2 3D Systems Corporation
10.2.1 Company Overview
10.2.2 Financial Analysis
10.2.3 Product Offering
10.2.4 Strategic Initiatives
10.2.5 SWOT
10.2.6 Ansoff Matrix
10.3 EOS
10.3.1 Company Overview
10.3.2 Financial Analysis
10.3.3 Product Offering
10.3.4 Strategic Initiatives
10.3.5 SWOT
10.3.6 Ansoff Matrix
10.4 Envisiontec, Inc.
10.4.1 Company Overview
10.4.2 Financial Analysis
10.4.3 Product Offering
10.4.4 Strategic Initiatives
10.4.5 SWOT
10.4.6 Ansoff Matrix
10.5 GE Additive
10.5.1 Company Overview
10.5.2 Financial Analysis
10.5.3 Product Offering
10.5.4 Strategic Initiatives
10.5.5 SWOT
10.5.6 Ansoff Matrix
10.6 HP
10.6.1 Company Overview
10.6.2 Financial Analysis
10.6.3 Product Offering
10.6.4 Strategic Initiatives
10.6.5 SWOT
10.6.6 Ansoff Matrix
10.7 Markforged
10.7.1 Company Overview
10.7.2 Financial Analysis
10.7.3 Product Offering
10.7.4 Strategic Initiatives
10.7.5 SWOT
10.7.6 Ansoff Matrix
10.8 Materialise NV
10.8.1 Company Overview
10.8.2 Financial Analysis
10.8.3 Product Offering
10.8.4 Strategic Initiatives
10.8.5 SWOT
10.8.6 Ansoff Matrix
10.9 Renishaw
10.9.1 Company Overview
10.9.2 Financial Analysis
10.9.3 Product Offering
10.9.4 Strategic Initiatives
10.9.5 SWOT
10.9.6 Ansoff Matrix
10.10 Stratasys Ltd.
10.10.1 Company Overview
10.10.2 Financial Analysis
10.10.3 Product Offering
10.10.4 Strategic Initiatives
10.10.5 SWOT
10.10.6 Ansoff Matrix
10.11 Ultimaker
10.11.1 Company Overview
10.11.2 Financial Analysis
10.11.3 Product Offering
10.11.4 Strategic Initiatives
10.11.5 SWOT
10.11.6 Ansoff Matrix
11. Industry Connects and Upcoming Seminars
