0
     

Report Added
Report already added
Industrial 3D Printing Market with COVID-19 Impact Analysis, by Offering (Printers, Materials, Software, Services), Application, Process, Technology, Industry (Aerospace & Defense, Automotive) and Geography - Global Forecast to 2026

Industrial 3D Printing Market with COVID-19 Impact Analysis, by Offering (Printers, Materials, Software, Services), Application, Process, Technology, Industry (Aerospace & Defense, Automotive) and Geography - Global Forecast to 2026

The industrial 3D printing market is expected to grow from USD 2.1 billion in 2021 and is projected to reach USD 5.2 billion by 2026; it is expected to grow at a CAGR of 20.0% during the forecast period. As AM is industrializing, software are playing a significant role across all areas of the AM workflow. While design, CAD, and simulation have always been a necessity in the AM process, the manufacturing of industry-grade and lightweight parts requires software that can adequately cope with the specific needs of the process. There is also a growing demand for 3D printing services as it helps in reducing manufacturers’ costs attributed to the reduction in person-hours and material loss from the conventional manufacturing process.

“Market for industrial 3D printing services to have highest CAGR during the forecast period”

The industrial 3D printing market for services is expected to grow at the highest CAGR during the forecast period. For many companies, 3D printing is unfeasible due to the high associated costs. Thus, 3D printing services are high in demand as they do not require high initial capital expenditure. Services such as consultation and shipping are also covered under 3D printing services.

“Electron beam melting technology segment to have highest growth throughout the forecast period”

The electron beam melting technology segment is expected to witness the highest growth during the forecast period. Electron beam melting technology has proven to be a cost-effective additive manufacturing (AM) solution in the manufacturing of orthopedic implants and parts used in the aerospace industry. The technology offers design freedom and stacking capabilities. EBM helps to build high-strength parts that make the most of the native properties of the metals used in the process, eliminating impurities that may accumulate when using casting metals or other fabrication methods. Although the market for EBM is relatively small due to the high costs of printers, it is witnessing high adoption for printing critical components for the aerospace & defense, petrochemical, automotive, and medical industries.

“Market for healthcare industry to grow at highest CAGR during the forecast period”

The industrial 3D printing market for the healthcare industry is expected to grow at the highest CAGR during the forecast period. 3D printing in healthcare is a fast-growing subsector. Due to decreased costs of 3D printers and increased availability of CAD/CAM medical software, many hospitals worldwide are acquiring 3D printers. New technological developments have enabled healthcare advances with 3D printing. For instance, customized 3D-printed surgical instruments such as scalpel handles, forceps, or clamps that reduce operating time and provide better surgical outcomes are manufactured from materials such as stainless steel, nylon, titanium alloys, and nickel. The advancements in 3D printing technology are expected to enable healthcare providers to offer a high degree of customized care.

“Market in APAC to grow at highest CAGR during the forecast period”

The industrial 3D printing market in APAC is expected to witness the fastest growth during the forecast period. This region is a lucrative market for industrial 3D printing, owing to industrial development and improving economic conditions. This region constitutes approximately 60% of the world’s population, resulting in the high growth of various industries, such as automotive and healthcare. Global manufacturers having their presence in APAC in terms of manufacturing facilities, distribution systems, and sales offices are easing the supply of 3D printing components in this region. Establishing regional centers for industrial 3D printing training, research, and education in Asian countries is expected to provide skilled operators for 3D printing systems. These factors are expected to contribute to the regional market growth.

In the process of determining and verifying the market size for several segments and subsegments gathered through secondary research, extensive primary interviews have been conducted with key industry experts in the industrial 3D printing market space. The break-up of primary participants for the report has been shown below:
•By Company Type: Tier 1 – 40%, Tier 2 – 35%, and Tier 3 – 25%
•By Designation: C-level Executives – 35%, Directors – 40%, and Others – 25%
•By Region: North America –40%, APAC– 30%, Europe – 20%, and RoW – 10%
The report profiles key players in the industrial 3D printing market with their respective market ranking analysis. Prominent players profiled in this report are Stratasys (US), 3D Systems (US), Materialise (Belgium), EOS (Germany), GE Additive (US), ExOne (US), voxeljet (Germany), HP (US), SLM Solutions (Germany), Renishaw (UK), Protolabs (US), CleenGreen3D (Ireland), Optomec (US), Groupe Gorgé (France), Ultimaker (The Netherlands), Beijing Tiertime (China) XYZprinting (Taiwan), Höganäs (Sweden), Covestro (Royal DSM) (Germany), Desktop Metal (US), Nano Dimension (Israel), Formlabs (US), Carbon (US), TRUMPF (Germany), and Markforged (US).

Research Coverage:
This research report categorizes the industrial 3D printing market on the basis of offering, process, technology, application, industry, and geography. The report describes the major drivers, restraints, challenges, and opportunities pertaining to the industrial 3D printing market and forecasts the same till 2026 (including analysis of COVID-19 impact on the market). Apart from these, the report also consists of leadership mapping and analysis of all the companies included in the industrial 3D printing ecosystem.

Key Benefits of Buying the Report
The report would help leaders/new entrants in this market in the following ways:
1.This report segments the industrial 3D printing market comprehensively and provides the closest market size projection for all subsegments across different regions.
2.The report helps stakeholders understand the pulse of the market and provides them with information on key drivers, restraints, challenges, and opportunities for market growth.
3.This report would help stakeholders understand their competitors better and gain more insights to improve their position in the business. The competitive landscape section includes competitor ecosystem, product launches, deals, and expansions.
4.The analysis of the top 25 companies, based on the strength of the market rank as well as the product footprint will help stakeholders visualize the market positioning of these key players.
Table of Contents

1INTRODUCTION38
1.1STUDY OBJECTIVES38
1.2MARKET DEFINITION AND SCOPE39
1.2.1INCLUSIONS AND EXCLUSIONS39
1.3STUDY SCOPE40
FIGURE 1INDUSTRIAL 3D PRINTING MARKET: SEGMENTATION40
1.3.1YEARS CONSIDERED41
1.4CURRENCY & PRICING41
1.5STAKEHOLDERS41
1.6SUMMARY OF CHANGES42
2RESEARCH METHODOLOGY43
2.1RESEARCH DATA43
FIGURE 2INDUSTRIAL 3D PRINTING MARKET: RESEARCH DESIGN43
2.1.1SECONDARY AND PRIMARY RESEARCH45
2.1.1.1Key industry insights46
2.1.2SECONDARY DATA46
2.1.2.1List of key secondary sources46
2.1.2.2Key data from secondary sources47
2.1.3PRIMARY DATA48
2.1.3.1Breakdown of primary interviews48
2.1.3.2Key data from primary sources49
2.2MARKET SIZE ESTIMATION49
2.2.1BOTTOM-UP APPROACH50
2.2.1.1Approach for obtaining market size using bottom-up analysis (demand side)50
FIGURE 3MARKET SIZE ESTIMATION METHODOLOGY: BOTTOM-UP APPROACH50
FIGURE 4MARKET SIZE ESTIMATION METHODOLOGY: (DEMAMD SIDE)—IDENTIFICATION OF ASPS AND SHIPMENTS OF INDUSTRIAL 3D PRINTERS50
2.2.2TOP-DOWN APPROACH51
2.2.2.1Approach to arrive at the market size using top-down analysis (supply side)51
FIGURE 5MARKET SIZE ESTIMATION METHODOLOGY: TOP-DOWN APPROACH51
FIGURE 6MARKET SIZE ESTIMATION METHODOLOGY: (SUPPLY SIDE)—ARRIVING AT TOTAL MARKET SIZE52
2.2.3MARKET PROJECTIONS52
2.3MARKET BREAKDOWN AND DATA TRIANGULATION53
FIGURE 7DATA TRIANGULATION53

2.4RESEARCH ASSUMPTIONS AND LIMITATIONS54
2.4.1ASSUMPTIONS54
2.4.2LIMITATIONS55
2.5RISK ASSESSMENT55
3EXECUTIVE SUMMARY57
TABLE 1SCENARIOS IN TERMS OF RECOVERY OF GLOBAL ECONOMY57
3.1REALISTIC SCENARIO58
3.2OPTIMISTIC SCENARIO58
3.3PESSIMISTIC SCENARIO58
FIGURE 8GROWTH PROJECTIONS OF INDUSTRIAL 3D PRINTING MARKET IN REALISTIC, OPTIMISTIC, AND PESSIMISTIC SCENARIOS59
FIGURE 9IMPACT OF COVID-19 ON INDUSTRIAL 3D PRINTING MARKET59
FIGURE 10PROTOTYPING APPLICATION TO DOMINATE INDUSTRIAL 3D PRINTING MARKET IN 202160
FIGURE 11PRINTERS SEGMENT TO HOLD LARGEST MARKET SHARE DURING FORECAST PERIOD60
FIGURE 12DIRECT METAL LASER SINTERING TECHNOLOGY TO LEAD INDUSTRIAL
3D PRINTING MARKET DURING FORECAST PERIOD61
FIGURE 13AEROSPACE & DEFENSE SEGMENT TO HOLD LARGEST MARKET SHARE DURING FORECAST PERIOD61
FIGURE 14NORTH AMERICA TO HOLD LARGEST SHARE OF INDUSTRIAL 3D PRINTING MARKET IN 202162
4PREMIUM INSIGHTS63
4.1ATTRACTIVE OPPORTUNITIES IN INDUSTRIAL 3D PRINTING MARKET63
FIGURE 15ADVANCEMENTS IN 3D PRINTING TECHNOLOGY AND AFFORDABILITY ARE FACTORS DRIVING GROWTH OF INDUSTRIAL 3D PRINTING MARKET63
4.2INDUSTRIAL 3D PRINTING MARKET, BY OFFERING64
FIGURE 16PRINTERS SEGMENT TO HOLD LARGEST MARKET SHARE IN 202664
4.3INDUSTRIAL 3D PRINTING MARKET, BY PROCESS64
FIGURE 17POWDER BED FUSION PROCESS TO ACCOUNT FOR LARGEST MARKET SHARE DURING FORECAST PERIOD64
4.4INDUSTRIAL 3D PRINTING MARKET, BY INDUSTRY65
FIGURE 18AEROSPACE & DEFENSE INDUSTRY TO ACCOUNT FOR LARGEST MARKET SHARE DURING FORECAST PERIOD65
4.5INDUSTRIAL 3D PRINTING MARKET IN NORTH AMERICA, BY OFFERING AND INDUSTRY65
FIGURE 19PRINTERS SEGMENT AND AEROSPACE & DEFENSE INDUSTRY HELD LARGEST SHARES OF NORTH AMERICAN INDUSTRIAL 3D PRINTING MARKET IN 202165
4.6INDUSTRIAL 3D PRINTING MARKET, BY COUNTRY66
FIGURE 20CHINA TO REGISTER HIGHEST CAGR IN INDUSTRIAL 3D PRINTING MARKET DURING FORECAST PERIOD66

5MARKET OVERVIEW67
5.Table of Contents

1INTRODUCTION67
5.2MARKET DYNAMICS68
FIGURE 21IMPACT OF DRIVERS AND OPPORTUNITIES ON INDUSTRIAL 3D PRINTING MARKET68
FIGURE 22IMPACT OF RESTRAINTS AND CHALLENGES ON INDUSTRIAL 3D PRINTING MARKET69
5.2.1DRIVERS69
5.2.1.1Increased focus on high-volume production using 3D printing69
5.2.1.2Advancements in 3D printing software70
FIGURE 233D PRINTING SOFTWARE ECOSYSTEM71
5.2.1.3Growing demand for 3D printing services71
5.2.1.4Development of advanced 3D printing materials71
5.2.2RESTRAINTS72
5.2.2.1High capital requirement for additive manufacturing72
TABLE 2RESTRAINTS – 2017 VS. 202072
5.2.2.2Lack of standardization72
5.2.3OPPORTUNITIES73
5.2.3.1Smart manufacturing with Industry 4.073
5.2.3.2Increasing investments in core printing technologies and specialized software73
FIGURE 24SHARES OF 3D PRINTING INVESTMENTS MADE THROUGH DIFFERENT CHANNELS73
5.2.3.3Positive impact of COVID-19 on 3D printing market74
5.2.4CHALLENGES74
5.2.4.1Threat of copyright violation74
5.2.4.2Adverse impact of large-scale 3D printing on environment74
5.3TARIFFS AND REGULATIONS74
5.3.1TARIFFS RELATED TO 3D PRINTERS74
5.4REGULATIONS75
5.4.1ASTM INTERNATIONAL75
5.4.2ISO TC 62177
5.5CASE STUDIES77
5.5.1FRAZER-NASH USED ADDITIVE MANUFACTURING TO PRODUCE FASTENERS REQUIRED DURING AIRCRAFT ASSEMBLY77
5.5.2RENISHAW HELPED HIETA TO MOVE METAL ADDITIVE MANUFACTURING FROM PROTOTYPING TO COMMERCIAL PRODUCTION OF ITS HEAT EXCHANGERS77
5.5.3METAL 3D PRINTING USED TO DEVELOP WISHBONE COMPONENT FOR MOTO2 MOTORCYCLE77
5.5.4IMR, RENISHAW, AND NTOPOLOGY IMPLEMENTED ADDITIVE MANUFACTURING FOR SPINAL IMPLANTS78
5.5.5EGAN ADOPTED DIGITAL WORKFLOW FOR REMOVABLE PARTIAL DENTURES78
5.5.6LOCKHEED MARTIN 3D PRINTS FUEL TANK SIMULATION WITH HELP FROM STRATASYS DIRECT MANUFACTURING78
5.5.7STRATASYS DIRECT MANUFACTURING BUILT FIRST 3D PRINTED PARTS TO FUNCTION ON EXTERIOR OF SATELLITE78
5.5.8FORD 3D PRINTED PARTS FOR ITS MUSTANG SHELBY GT500 SPORTS CAR79
5.5.9NANO DIMENSION AND HARRIS CORPORATION MANUFACTURED
3D-PRINTED CIRCUIT BOARD FOR RF AMPLIFIERS79
5.5.103D SYSTEMS PRODUCES ON-DEMAND MEDICAL EQUIPMENT DURING COVID-1979
5.6PRICING ANALYSIS79
TABLE 3ASP OF VARIOUS TYPES OF 3D PRINTERS BASED ON TECHNOLOGY80
5.7VALUE CHAIN ANALYSIS80
FIGURE 25VALUE CHAIN ANALYSIS OF INDUSTRIAL 3D PRINTING ECOSYSTEM: MATERIAL, SOFTWARE PROVIDERS, AND MANUFACTURING PHASES CONTRIBUTING THE MAXIMUM VALUE80
5.8ECOSYSTEM/MARKET MAP82
FIGURE 26INDUSTRIAL 3D PRINTING MARKET ECOSYSTEM82
FIGURE 27INDUSTRIAL 3D PRINTING MARKET PLAYER ECOSYSTEM83
5.8.1MATERIAL SUPPLIERS83
5.8.1.1Polymer providers83
5.8.1.2Metal providers83
5.8.2SOFTWARE PROVIDERS84
5.8.3PRINTER PROVIDERS84
5.9INDUSTRIAL 3D PRINTING MARKET: SUPPLY CHAIN84
5.10TECHNOLOGY ANALYSIS85
TABLE 4EMERGING 3D PRINTING TECHNOLOGIES85
5.10.1KEY EMERGING TECHNOLOGIES86
5.10.1.1Hybrid manufacturing86
5.10.2ADJACENT TECHNOLOGIES86
5.10.2.1CNC machining86
5.11TECHNOLOGY TRENDS86
5.11.1SHIFT TOWARD SERVICE PROVIDERS FOR FUNCTIONAL PARTS87
5.11.2DEVELOPMENT OF NEW MATERIALS IN INDUSTRIAL 3D PRINTING MARKET87
TABLE 5EMERGING TRENDS WITH MATERIALS IN 3D PRINTING MARKET87
5.12PATENT ANALYSIS88
FIGURE 28NUMBER OF PATENTS GRANTED FOR 3D PRINTING IN A YEAR, 2010-202088
FIGURE 29TOP 10 COMPANIES WITH THE HIGHEST NUMBER OF GRANTED 3D PRINTING PATENTS IN THE LAST 10 YEARS88
5.12.1LIST OF MAJOR PATENTS89
5.13TRADE DATA92
5.13.1IMPORT SCENARIO92
FIGURE 30IMPORT DATA FOR HS CODE 8443, BY COUNTRY, 2016–202092
TABLE 6IMPORT DATA FOR HS CODE 8443, BY COUNTRY, 2016–2020 (USD BILLION)93
5.13.2EXPORT SCENARIO93
FIGURE 31EXPORT DATA FOR HS CODE 8443, BY COUNTRY, 2016–202093
TABLE 7EXPORT DATA FOR HS CODE 8443, BY COUNTRY, 2016–2020 (USD BILLION)94
5.14PORTER’S FIVE FORCES ANALYSIS95
TABLE 8PORTER’S FIVE FORCES IMPACT ON THE INDUSTRIAL 3D PRINTING MARKET95
FIGURE 32PORTER’S FIVE FORCES ANALYSIS: INDUSTRIAL 3D PRINTING MARKET95
5.14.1THREAT OF NEW ENTRANTS96
5.14.2THREAT OF SUBSTITUTES96
5.14.3BARGAINING POWER OF SUPPLIERS96
5.14.4BARGAINING POWER OF BUYERS96
5.14.5INTENSITY OF COMPETITIVE RIVALRY97
5.15TRENDS AND DISRUPTIONS IMPACTING CUSTOMERS97
FIGURE 33YC-YCC SHIFT FOR THE INDUSTRIAL 3D PRINTING MARKET97
6INDUSTRIAL 3D PRINTING MARKET, BY OFFERING98
6.Table of Contents

1INTRODUCTION99
FIGURE 34INDUSTRIAL 3D PRINTING OFFERINGS99
FIGURE 35PRINTERS SEGMENT TO HOLD LARGEST SHARE OF INDUSTRIAL 3D PRINTING MARKET DURING FORECAST PERIOD99
TABLE 9INDUSTRIAL 3D PRINTING MARKET, BY OFFERING,
2017–2020 (USD MILLION)99
TABLE 10INDUSTRIAL 3D PRINTING MARKET, BY OFFERING,
2021–2026 (USD MILLION)100
6.2PRINTERS100
6.2.13D PRINTER IS PRIMARY HARDWARE COMPONENT USED IN INDUSTRIAL ADDITIVE MANUFACTURING100
TABLE 11INDUSTRIAL 3D PRINTING MARKET FOR PRINTERS, BY REGION,
2017–2020 (USD MILLION)101
TABLE 12INDUSTRIAL 3D PRINTING MARKET FOR PRINTERS, BY REGION,
2021–2026 (USD MILLION)101
6.3MATERIALS101
6.3.1MANUFACTURERS ARE INVESTING IN R&D FOR DEVELOPING NEW MATERIALS TO MEET GROWING DEMAND FOR 3D-PRINTED PRODUCTS101
FIGURE 36TYPES OF INDUSTRIAL 3D PRINTING MATERIALS102
FIGURE 37PLASTICS SUB-SEGMENT TO HOLD LARGEST SHARE OF INDUSTRIAL
3D PRINTING MARKET FOR MATERIALS IN 2026102
TABLE 13INDUSTRIAL 3D PRINTING MARKET FOR MATERIALS, BY TYPE,
2017–2020 (USD MILLION)102
TABLE 14INDUSTRIAL 3D PRINTING MARKET FOR MATERIALS, BY TYPE,
2021–2026 (USD MILLION)103
TABLE 15INDUSTRIAL 3D PRINTING MARKET FOR MATERIALS, BY REGION,
2017–2020 (USD MILLION)103
TABLE 16INDUSTRIAL 3D PRINTING MARKET FOR MATERIALS, BY REGION,
2021–2026 (USD MILLION)103
6.3.2PLASTICS104
TABLE 17INDUSTRIAL 3D PRINTING MARKET FOR PLASTICS, BY PLASTIC MATERIAL TYPE, 2017–2020 (USD MILLION)104
TABLE 18INDUSTRIAL 3D PRINTING MARKET FOR PLASTICS, BY PLASTIC MATERIAL TYPE, 2021–2026 (USD MILLION)104
6.3.2.1Thermoplastics104
6.3.2.1.1Acrylonitrile butadiene styrene (ABS)104
6.3.2.1.1.1Acrylonitrile butadiene styrene is mainly used in form of filaments, powders, or resins in 3D printing104
TABLE 19GENERAL TECHNICAL SPECIFICATIONS OF ABS105
6.3.2.1.2Polylactic acid (PLA)105
6.3.2.1.2.1Polylactic acid is derived from natural resources that are not petrochemical based105
TABLE 20GENERAL TECHNICAL SPECIFICATIONS OF PLA106
6.3.2.1.3Nylon106
6.3.2.1.3.1Nylon filament is useful for making objects that require flexibility and strong self-bonding between layers106
TABLE 21GENERAL TECHNICAL SPECIFICATIONS OF NYLON106
6.3.2.1.4Others107
6.3.2.1.4.1Polypropylene107
TABLE 22GENERAL TECHNICAL SPECIFICATIONS OF POLYPROPYLENE107
6.3.2.1.4.2Polycarbonate107
TABLE 23GENERAL TECHNICAL SPECIFICATIONS OF POLYCARBONATE108
6.3.2.1.4.3Polyvinyl alcohol (PVA)108
TABLE 24GENERAL TECHNICAL SPECIFICATIONS OF PVA108
6.3.2.1.5Photopolymers109
6.3.3METALS109
TABLE 25INDUSTRIAL 3D PRINTING MARKET FOR METALS, BY TYPE,
2017–2020 (USD MILLION)109
TABLE 26INDUSTRIAL 3D PRINTING MARKET FOR METALS, BY TYPE,
2021–2026 (USD MILLION)110
6.3.3.1Steel110
6.3.3.1.1Stainless steel is infused with other materials such as bronze for 3D printing110
6.3.3.2Aluminum110
6.3.3.2.1Aluminum is mostly used to build complex models, small series of models, and functional models110
6.3.3.3Titanium111
6.3.3.3.1Direct metal laser sintering used to design 3D model with titanium111
TABLE 27INDUSTRY-WISE PROPERTIES AND APPLICATIONS OF TITANIUM111
6.3.3.4Alloys (Inconel and CoCr)111
6.3.3.4.1Parts 3D-printed with Inconel can withstand extreme environmental conditions111
6.3.3.5Other metals112
6.3.3.5.1Gold112
6.3.3.5.1.1Gold is mostly used for making jewelry by using wax 3D printing and lost wax casting112
6.3.3.5.2Silver112
6.3.3.5.2.1Silver is mainly used for producing jewelry and ornaments112
6.3.3.5.3Other metal powders112
6.3.4CERAMICS112
6.3.4.1Glass113
6.3.4.1.1SLS and FDM are most commonly implemented methods to 3D print objects using glass powders113
6.3.4.2Silica113
6.3.4.2.1Silica is used for polishing and grinding of glass and stones in 3D printing113
6.3.4.3Quartz113
6.3.4.3.1Quartz material is known for its thermal and chemical stability113
6.3.4.4Other ceramics113
6.3.5OTHER MATERIALS113
6.4SOFTWARE114
6.4.1SOFTWARE PROGRAMS ARE REQUIRED TO DEVELOP 3D DIGITAL MODELS114
FIGURE 38TYPES OF INDUSTRIAL 3D PRINTING SOFTWARE114
FIGURE 39PRINTING SUB-SEGMENT TO HOLD LARGEST SHARE OF INDUSTRIAL
3D PRINTING MARKET FOR SOFTWARE IN 2026114
TABLE 28INDUSTRIAL 3D PRINTING MARKET FOR SOFTWARE, BY TYPE,
2017–2020 (USD MILLION)115
TABLE 29INDUSTRIAL 3D PRINTING MARKET FOR SOFTWARE, BY TYPE,
2021–2026 (USD MILLION)115
TABLE 30INDUSTRIAL 3D PRINTING MARKET FOR SOFTWARE, BY REGION,
2017–2020 (USD MILLION)115
TABLE 31INDUSTRIAL 3D PRINTING MARKET FOR SOFTWARE, BY REGION,
2021–2026 (USD MILLION)116
6.4.2DESIGN SOFTWARE116
6.4.2.1Design software in industrial 3D printing is used to create parts, assemblies, and drawings116
6.4.3INSPECTION SOFTWARE117
6.4.3.1Inspection software is developed to check compliance of 3D-printed products with required specifications117
6.4.4PRINTING SOFTWARE117
6.4.4.1Printing software ensures high precision of parts developed
via printers117
6.4.5SCANNING SOFTWARE117
6.4.5.1Scanning software allows users to scan physical objects and create digital models or designs117
6.5SERVICES117
6.5.13D PRINTING TECHNOLOGY IS CHANGING HOW COMPANIES PRODUCE AND ADD VALUE TO THEIR PRODUCTS THROUGH SERVICES117
FIGURE 40TYPES OF INDUSTRIAL 3D PRINTING SERVICES118
FIGURE 41MANUFACTURING SOLUTION SEGMENT TO HOLD LARGER SHARE OF INDUSTRIAL 3D PRINTING MARKET FOR SERVICES IN 2021118
TABLE 32INDUSTRIAL 3D PRINTING MARKET FOR SERVICES, BY TYPE,
2017–2020 (USD MILLION)118
TABLE 33INDUSTRIAL 3D PRINTING MARKET FOR SERVICES, BY TYPE,
2021–2026 (USD MILLION)119
TABLE 34INDUSTRIAL 3D PRINTING MARKET FOR SERVICES, BY REGION,
2017–2020 (USD MILLION)119
TABLE 35INDUSTRIAL 3D PRINTING MARKET FOR SERVICES, BY REGION,
2021–2026 (USD MILLION)119
6.5.2MANUFACTURING SERVICES120
6.5.2.1Manufacturing services include technical services, training services, quality management services, applications, and R&D services120
6.5.3CONSULTING SERVICES120
6.5.3.1Consulting services help manufacturing companies set up production facilities and assess product performance and quality120
6.6IMPACT OF COVID-19 ON 3D PRINTER OFFERINGS120
6.6.1MOST-AFFECTED SEGMENT120
6.6.2LEAST-AFFECTED SEGMENT120
7INDUSTRIAL 3D PRINTING MARKET, BY PROCESS121
7.Table of Contents

1INTRODUCTION122
FIGURE 42INDUSTRIAL 3D PRINTING MARKET, BY PROCESS122
FIGURE 43POWDER BED FUSION PROCESS TO HOLD LARGEST SHARE OF INDUSTRIAL 3D PRINTING MARKET DURING FORECAST PERIOD123
TABLE 36INDUSTRIAL 3D PRINTING MARKET, BY PROCESS,
2017–2020 (USD MILLION)123
TABLE 37INDUSTRIAL 3D PRINTING MARKET, BY PROCESS,
2021–2026 (USD MILLION)123
7.2BINDER JETTING124
7.2.1BINDER JETTING WORKS WITH ALL TYPES OF MATERIALS AVAILABLE IN POWDERED FORMS124
FIGURE 44BINDER JETTING PROCESS125
TABLE 38INDUSTRIAL 3D PRINTING MARKET FOR BINDER JETTING, BY APPLICATION, 2017–2020 (USD MILLION)125
TABLE 39INDUSTRIAL 3D PRINTING MARKET FOR BINDER JETTING, BY APPLICATION, 2021–2026 (USD MILLION)125
7.3DIRECT ENERGY DEPOSITION126
7.3.1DIRECT ENERGY DEPOSITION MACHINE HAS HEAD THAT CONSISTS OF NOZZLE AFFIXED TO MULTI-AXIS ARM126
FIGURE 45DIRECT ENERGY DEPOSITION PROCESS126
TABLE 40INDUSTRIAL 3D PRINTING MARKET FOR DIRECT ENERGY DEPOSITION,
BY APPLICATION, 2017–2020 (USD MILLION)126
TABLE 41INDUSTRIAL 3D PRINTING MARKET FOR DIRECT ENERGY DEPOSITION,
BY APPLICATION, 2021–2026 (USD MILLION)127
7.4MATERIAL EXTRUSION127
7.4.1FUSED DEPOSITION MODELING (FDM) IS USED IN MATERIAL EXTRUSION PROCESS127
FIGURE 46MATERIAL EXTRUSION PROCESS127
TABLE 42INDUSTRIAL 3D PRINTING MARKET FOR MATERIAL EXTRUSION,
BY APPLICATION, 2017–2020 (USD MILLION)128
TABLE 43INDUSTRIAL 3D PRINTING MARKET FOR MATERIAL EXTRUSION,
BY APPLICATION, 2021–2026 (USD MILLION)128
7.5MATERIAL JETTING128
7.5.1MATERIAL JETTING IS ALSO KNOWN AS MULTI-JET MODELING, DROP ON DEMAND, THERMOJET, INKJET PRINTING, AND PHOTOPOLYMER JETTING128
FIGURE 47MATERIAL JETTING PROCESS129
TABLE 44INDUSTRIAL 3D PRINTING MARKET FOR MATERIAL JETTING, BY APPLICATION, 2017–2020 (USD MILLION)129
TABLE 45INDUSTRIAL 3D PRINTING MARKET FOR MATERIAL JETTING, BY APPLICATION, 2021–2026 (USD MILLION)129
7.6POWDER BED FUSION130
7.6.1POWDER BED FUSION PROCESS USES ELECTRON OR LASER BEAMS TO MELT AND FUSE MATERIAL POWDERS130
FIGURE 48POWDER BED FUSION PROCESS130
TABLE 46INDUSTRIAL 3D PRINTING MARKET FOR POWDER BED FUSION,
BY APPLICATION, 2017–2020 (USD MILLION)130
TABLE 47INDUSTRIAL 3D PRINTING MARKET FOR POWDER BED FUSION,
BY APPLICATION, 2021–2026 (USD MILLION)131
7.7SHEET LAMINATION131
7.7.1SHEET LAMINATION PROCESS IS MOSTLY USED WHEN METAL OR PAPER IS USED AS PRINTING MATERIAL131
FIGURE 49SHEET LAMINATION PROCESS131
TABLE 48INDUSTRIAL 3D PRINTING MARKET FOR SHEET LAMINATION,
BY APPLICATION, 2017–2020 (USD MILLION)132
TABLE 49INDUSTRIAL 3D PRINTING MARKET FOR SHEET LAMINATION,
BY APPLICATION, 2021–2026 (USD MILLION)132
7.8VAT PHOTOPOLYMERIZATION132
7.8.1VAT PHOTOPOLYMERIZATION PROCESS USES STEREOLITHOGRAPHY AND DIGITAL LIGHT PROCESSING TECHNOLOGIES132
FIGURE 50VAT PHOTOPOLYMERIZATION PROCESS133
TABLE 50INDUSTRIAL 3D PRINTING MARKET FOR VAT PHOTOPOLYMERIZATION,
BY APPLICATION, 2017–2020 (USD MILLION)133
TABLE 51INDUSTRIAL 3D PRINTING MARKET FOR VAT PHOTOPOLYMERIZATION,
BY APPLICATION, 2021–2026 (USD MILLION)133
8INDUSTRIAL 3D PRINTING MARKET, BY TECHNOLOGY134
8.Table of Contents

1INTRODUCTION135
FIGURE 51INDUSTRIAL 3D PRINTING TECHNOLOGIES135
FIGURE 52DIRECT METAL LASER SINTERING TECHNOLOGY TO LEAD INDUSTRIAL
3D PRINTING MARKET DURING FORECAST PERIOD136
TABLE 52INDUSTRIAL 3D PRINTING MARKET, BY TECHNOLOGY,
2017–2020 (USD MILLION)136
TABLE 53INDUSTRIAL 3D PRINTING MARKET, BY TECHNOLOGY,
2021–2026 (USD MILLION)137
TABLE 54INDUSTRIAL 3D PRINTING MARKET, BY TECHNOLOGY, 2017–2020 (UNITS)137
TABLE 55INDUSTRIAL 3D PRINTING MARKET, BY TECHNOLOGY, 2021–2026 (UNITS)138
8.2STEREOLITHOGRAPHY139
8.2.1STEREOLITHOGRAPHY USES UV LASERS TO CURE AND SOLIDIFY THIN LAYERS OF PHOTO-REACTIVE RESIN139
8.2.2ADVANTAGES AND DISADVANTAGES OF STEREOLITHOGRAPHY 3D PRINTERS139
TABLE 56INDUSTRIAL 3D PRINTING MARKET FOR STEREOLITHOGRAPHY,
BY APPLICATION, 2017–2020 (USD MILLION)140
TABLE 57INDUSTRIAL 3D PRINTING MARKET FOR STEREOLITHOGRAPHY,
BY APPLICATION, 2021–2026 (USD MILLION)140
8.3FUSED DEPOSITION MODELING (FDM)140
8.3.1FDM IS HIGHLY USED TO CREATE CONCEPT MODELS AND FUNCTIONAL PARTS140
8.3.2ADVANTAGES AND DISADVANTAGES OF FUSED DEPOSITION MODELING TECHNOLOGY140
TABLE 58INDUSTRIAL 3D PRINTING MARKET FOR FDM, BY APPLICATION,
2017–2020 (USD MILLION)141
TABLE 59INDUSTRIAL 3D PRINTING MARKET FOR FDM, BY APPLICATION,
2021–2026 (USD MILLION)141
8.4SELECTIVE LASER SINTERING (SLS)142
8.4.1SELECTIVE LASER SINTERING 3D PRINTING TECHNOLOGY USES LASER BEAM TO FUSE POWDERED THERMOPLASTICS142
8.4.2ADVANTAGES AND DISADVANTAGES OF SELECTIVE LASER SINTERING142
TABLE 60INDUSTRIAL 3D PRINTING MARKET FOR SLS, BY APPLICATION,
2017–2020 (USD MILLION)142
TABLE 61INDUSTRIAL 3D PRINTING MARKET FOR SLS, BY APPLICATION,
2021–2026 (USD MILLION)143
8.5DIRECT METAL LASER SINTERING (DMLS)143
8.5.1DIRECT METAL LASER SINTERING IS USED FOR BUILDING METALLIC OBJECTS143
8.5.2ADVANTAGES AND DISADVANTAGES OF DIRECT METAL LASER SINTERING143
TABLE 62INDUSTRIAL 3D PRINTING MARKET FOR DMLS, BY APPLICATION,
2017–2020 (USD MILLION)144
TABLE 63INDUSTRIAL 3D PRINTING MARKET FOR DMLS, BY APPLICATION,
2021–2026 (USD MILLION)144
8.6POLYJET PRINTING144
8.6.1POLYJET 3D PRINTING TECHNOLOGY IS USED TO DEVELOP MODELS WITH INTRICATE DETAILS AND COMPLEX GEOMETRIES144
8.6.2ADVANTAGES AND DISADVANTAGES OF POLYJET PRINTING145
TABLE 64INDUSTRIAL 3D PRINTING MARKET FOR POLYJET PRINTING, BY APPLICATION, 2017–2020 (USD MILLION)145
TABLE 65INDUSTRIAL 3D PRINTING MARKET FOR POLYJET PRINTING, BY APPLICATION, 2021–2026 (USD MILLION)145
8.7INKJET PRINTING146
8.7.1INKJET 3D PRINTING INVOLVES SELECTIVE DEPOSITION OF LIQUID BINDING AGENT TO JOIN POWDER PARTICLES146
8.7.2ADVANTAGES AND DISADVANTAGES OF INKJET PRINTING146
TABLE 66INDUSTRIAL 3D PRINTING MARKET FOR INKJET PRINTING, BY APPLICATION, 2017–2020 (USD MILLION)146
TABLE 67INDUSTRIAL 3D PRINTING MARKET FOR INKJET PRINTING, BY APPLICATION, 2021–2026 (USD MILLION)147

8.8ELECTRON BEAM MELTING (EBM)147
8.8.1ELECTRON BEAM MELTING TECHNOLOGY PRODUCES HIGH-DENSITY PARTS AND HAVE RELATIVELY GOOD MECHANICAL PROPERTIES147
8.8.2ADVANTAGES AND DISADVANTAGES OF ELECTRON BEAM MELTING147
TABLE 68INDUSTRIAL 3D PRINTING MARKET FOR EBM, BY APPLICATION,
2017–2020 (USD MILLION)147
TABLE 69INDUSTRIAL 3D PRINTING MARKET FOR EBM, BY APPLICATION,
2021–2026 (USD MILLION)148
8.9LASER METAL DEPOSITION (LMD)148
8.9.1LASER METAL DEPOSITION TECHNOLOGY INVOLVES REPAIR, CLADDING, AND PRODUCTION OF PARTS148
8.9.2ADVANTAGES AND DISADVANTAGES OF LASER METAL DEPOSITION148
TABLE 70INDUSTRIAL 3D PRINTING MARKET FOR LMD, BY APPLICATION,
2017–2020 (USD MILLION)149
TABLE 71INDUSTRIAL 3D PRINTING MARKET FOR LMD, BY APPLICATION,
2021–2026 (USD MILLION)149
8.10DIGITAL LIGHT PROCESSING (DLP)149
8.10.1DLP 3D PRINTING TECHNOLOGY IS SIMILAR TO STEREOLITHOGRAPHY AS BOTH TECHNOLOGIES USE PHOTOPOLYMERS AS MATERIALS149
8.10.2ADVANTAGES AND DISADVANTAGES OF DIGITAL LIGHT PROCESSING149
TABLE 72INDUSTRIAL 3D PRINTING MARKET FOR DLP, BY APPLICATION,
2017–2020 (USD MILLION)150
TABLE 73INDUSTRIAL 3D PRINTING MARKET FOR DLP, BY APPLICATION,
2021–2026 (USD MILLION)150
8.11LAMINATED OBJECT MANUFACTURING (LOM)150
8.11.1LAMINATED OBJECT MANUFACTURING USES SHEET LAMINATION PROCESS THAT INVOLVES PAPER AS PRINTING MATERIAL AND ADHESIVES FOR BINDING SHEETS150
8.11.2ADVANTAGES AND DISADVANTAGES OF LAMINATED OBJECT MANUFACTURING150
TABLE 74INDUSTRIAL 3D PRINTING MARKET FOR LOM, BY APPLICATION,
2017–2020 (USD MILLION)151
TABLE 75INDUSTRIAL 3D PRINTING MARKET FOR LOM, BY APPLICATION,
2021–2026 (USD MILLION)151
8.12OTHERS151
TABLE 76INDUSTRIAL 3D PRINTING MARKET FOR OTHERS, BY APPLICATION,
2017–2020 (USD MILLION)151
TABLE 77INDUSTRIAL 3D PRINTING MARKET FOR OTHERS, BY APPLICATION,
2021–2026 (USD MILLION)152
9INDUSTRIAL 3D PRINTING MARKET, BY APPLICATION153
9.Table of Contents

1INTRODUCTION154
FIGURE 53INDUSTRIAL 3D PRINTING MARKET, BY APPLICATION154
FIGURE 54PROTOTYPING APPLICATION SEGMENT TO HOLD LARGER SHARE OF INDUSTRIAL 3D PRINTING MARKET DURING FORECAST PERIOD154
TABLE 78INDUSTRIAL 3D PRINTING MARKET, BY APPLICATION,
2017–2020 (USD MILLION)155
TABLE 79INDUSTRIAL 3D PRINTING MARKET, BY APPLICATION,
2021–2026 (USD MILLION)155
9.2PROTOTYPING156
9.2.1PROTOTYPING IS BECOMING GLOBALLY ACCEPTED METHODOLOGY IN INDUSTRIAL MANUFACTURING PROCESSES156
TABLE 80INDUSTRIAL 3D PRINTING MARKET FOR PROTOTYPING, BY INDUSTRY, 2017–2020 (USD MILLION)157
TABLE 81INDUSTRIAL 3D PRINTING MARKET FOR PROTOTYPING, BY INDUSTRY, 2021–2026 (USD MILLION)157
TABLE 82INDUSTRIAL 3D PRINTING MARKET FOR PROTOTYPING, BY TECHNOLOGY, 2017–2020 (USD MILLION)158
TABLE 83INDUSTRIAL 3D PRINTING MARKET FOR PROTOTYPING, BY TECHNOLOGY, 2021–2026 (USD MILLION)158
TABLE 84INDUSTRIAL 3D PRINTING MARKET FOR PROTOTYPING, BY PROCESS,
2017–2020 (USD MILLION)159
TABLE 85INDUSTRIAL 3D PRINTING MARKET FOR PROTOTYPING, BY PROCESS,
2021–2026 (USD MILLION)159
9.3MANUFACTURING159
9.3.13D PRINTING ENABLES INEXPENSIVE MANUFACTURING OF PRODUCTS IN SMALLER VOLUMES159
TABLE 86INDUSTRIAL 3D PRINTING MARKET FOR MANUFACTURING, BY INDUSTRY, 2017–2020 (USD MILLION)160
TABLE 87INDUSTRIAL 3D PRINTING MARKET FOR MANUFACTURING, BY INDUSTRY, 2021–2026 (USD MILLION)161
TABLE 88INDUSTRIAL 3D PRINTING MARKET FOR MANUFACTURING, BY TECHNOLOGY, 2017–2020 (USD MILLION)161
TABLE 89INDUSTRIAL 3D PRINTING MARKET FOR MANUFACTURING, BY TECHNOLOGY, 2021–2026 (USD MILLION)162
TABLE 90INDUSTRIAL 3D PRINTING MARKET FOR MANUFACTURING, BY PROCESS, 2017–2020 (USD MILLION)162
TABLE 91INDUSTRIAL 3D PRINTING MARKET FOR MANUFACTURING, BY PROCESS, 2021–2026 (USD MILLION)163
10INDUSTRIAL 3D PRINTING MARKET, BY INDUSTRY164
10.Table of Contents

1INTRODUCTION165
FIGURE 55INDUSTRIES IN INDUSTRIAL 3D PRINTING MARKET165
FIGURE 56AEROSPACE & DEFENSE INDUSTRY TO ACCOUNT FOR LARGEST SHARE OF INDUSTRIAL 3D PRINTING MARKET DURING FORECAST PERIOD166
TABLE 92INDUSTRIAL 3D PRINTING MARKET, BY INDUSTRY,
2017–2020 (USD MILLION)166
TABLE 93INDUSTRIAL 3D PRINTING MARKET, BY INDUSTRY,
2021–2026 (USD MILLION)167
10.2AUTOMOTIVE168
10.2.1PROTOTYPING IS BECOMING GLOBALLY ACCEPTED METHODOLOGY IN INDUSTRIAL MANUFACTURING PROCESS168
TABLE 94INDUSTRIAL 3D PRINTING MARKET FOR AUTOMOTIVE INDUSTRY,
BY APPLICATION, 2017–2020 (USD MILLION)169
TABLE 95INDUSTRIAL 3D PRINTING MARKET FOR AUTOMOTIVE INDUSTRY,
BY APPLICATION, 2021–2026 (USD MILLION)169
TABLE 96INDUSTRIAL 3D PRINTING MARKET FOR AUTOMOTIVE INDUSTRY, BY REGION, 2017–2020 (USD MILLION)169
TABLE 97INDUSTRIAL 3D PRINTING MARKET FOR AUTOMOTIVE INDUSTRY, BY REGION, 2021–2026 (USD MILLION)169
10.3AEROSPACE & DEFENSE170
10.3.13D PRINTING ALLOWS FOR RELATIVELY INEXPENSIVE PRODUCTION OF PRODUCTS IN SMALLER VOLUMES170
TABLE 983D PRINTING OFFERINGS FOR AEROSPACE & DEFENSE INDUSTRY170
TABLE 99INDUSTRIAL 3D PRINTING MARKET FOR AEROSPACE & DEFENSE INDUSTRY, BY APPLICATION, 2017–2020 (USD MILLION)171
TABLE 100INDUSTRIAL 3D PRINTING MARKET FOR AEROSPACE & DEFENSE INDUSTRY, BY APPLICATION, 2021–2026 (USD MILLION)171
TABLE 101INDUSTRIAL 3D PRINTING MARKET FOR AEROSPACE & DEFENSE INDUSTRY, BY REGION, 2017–2020 (USD MILLION)171
TABLE 102INDUSTRIAL 3D PRINTING MARKET FOR AEROSPACE & DEFENSE INDUSTRY, BY REGION, 2021–2026 (USD MILLION)172
10.4FOOD & CULINARY172
10.4.13D PRINTING HELPS TO CREATE COMPLEX SHAPES USED IN FOOD & CULINARY INDUSTRY172
TABLE 1033D PRINTERS DESIGNED FOR FOOD MANUFACTURING172
TABLE 104INDUSTRIAL 3D PRINTING MARKET FOR FOOD & CULINARY INDUSTRY,
BY APPLICATION, 2017–2020 (USD MILLION)173
TABLE 105INDUSTRIAL 3D PRINTING MARKET FOR FOOD & CULINARY INDUSTRY,
BY APPLICATION, 2021–2026 (USD MILLION)173
TABLE 106INDUSTRIAL 3D PRINTING MARKET FOR FOOD & CULINARY INDUSTRY,
BY REGION, 2017–2020 (USD MILLION)173
TABLE 107INDUSTRIAL 3D PRINTING MARKET FOR FOOD & CULINARY INDUSTRY,
BY REGION, 2021–2026 (USD MILLION)173
10.5PRINTED ELECTRONICS174
10.5.13D PRINTING ALLOWS FOR RELATIVELY INEXPENSIVE PRODUCTION OF PRODUCTS IN SMALLER VOLUMES174
TABLE 108INDUSTRIAL 3D PRINTING MARKET FOR PRINTED ELECTRONICS INDUSTRY, BY APPLICATION, 2017–2020 (USD MILLION)174
TABLE 109INDUSTRIAL 3D PRINTING MARKET FOR PRINTED ELECTRONICS INDUSTRY, BY APPLICATION, 2021–2026 (USD MILLION)175
TABLE 110INDUSTRIAL 3D PRINTING MARKET FOR PRINTED ELECTRONICS INDUSTRY, BY REGION, 2017–2020 (USD MILLION)175
TABLE 111INDUSTRIAL 3D PRINTING MARKET FOR PRINTED ELECTRONICS INDUSTRY, BY REGION, 2021–2026 (USD MILLION)175
10.6FOUNDRY & FORGING176
10.6.13D PRINTING HAS EMERGED AS ESTABLISHED TECHNOLOGY IN FOUNDRY INDUSTRY176
TABLE 112INDUSTRIAL 3D PRINTING MARKET FOR FOUNDRY & FORGING INDUSTRY,
BY APPLICATION, 2017–2020 (USD MILLION)176
TABLE 113INDUSTRIAL 3D PRINTING MARKET FOR FOUNDRY & FORGING INDUSTRY,
BY APPLICATION, 2021–2026 (USD MILLION)176
TABLE 114INDUSTRIAL 3D PRINTING MARKET FOR FOUNDRY & FORGING INDUSTRY,
BY REGION, 2017–2020 (USD MILLION)177
TABLE 115INDUSTRIAL 3D PRINTING MARKET FOR FOUNDRY & FORGING INDUSTRY,
BY REGION, 2021–2026 (USD MILLION)177
10.7HEALTHCARE177
10.7.1METALS, POLYMERS, AND CERAMICS ARE WIDELY USED 3D PRINTING MATERIALS IN HEALTHCARE INDUSTRY177
TABLE 116INDUSTRIAL 3D PRINTING MARKET FOR HEALTHCARE INDUSTRY,
BY APPLICATION, 2017–2020 (USD MILLION)178
TABLE 117INDUSTRIAL 3D PRINTING MARKET FOR HEALTHCARE INDUSTRY,
BY APPLICATION, 2021–2026 (USD MILLION)178
TABLE 118INDUSTRIAL 3D PRINTING MARKET FOR HEALTHCARE INDUSTRY, BY REGION, 2017–2020 (USD MILLION)179
TABLE 119INDUSTRIAL 3D PRINTING MARKET FOR HEALTHCARE INDUSTRY, BY REGION, 2021–2026 (USD MILLION)179
10.8JEWELRY179
10.8.1JEWELERS USE CAD AND HIGH-RESOLUTION 3D PRINTERS TO CREATE
3D-PRINTED PATTERNS179
TABLE 1203D PRINTERS DESIGNED FOR JEWELRY MANUFACTURING180
TABLE 121INDUSTRIAL 3D PRINTING MARKET FOR JEWELRY INDUSTRY,
BY APPLICATION, 2017–2020 (USD MILLION)180
TABLE 122INDUSTRIAL 3D PRINTING MARKET FOR JEWELRY INDUSTRY,
BY APPLICATION, 2021–2026 (USD MILLION)181
TABLE 123INDUSTRIAL 3D PRINTING MARKET FOR JEWELRY INDUSTRY, BY REGION, 2017–2020 (USD MILLION)181
TABLE 124INDUSTRIAL 3D PRINTING MARKET FOR JEWELRY INDUSTRY, BY REGION, 2021–2026 (USD MILLION)181
10.9OIL & GAS182
10.9.13D PRINTING IS USED TO MAKE PARTS USED IN OIL & GAS INDUSTRY THAT EXHIBIT CHEMICAL AND HEAT RESISTANCE182
TABLE 125INDUSTRIAL 3D PRINTING MARKET FOR OIL & GAS INDUSTRY,
BY APPLICATION, 2017–2020 (USD MILLION)182
TABLE 126INDUSTRIAL 3D PRINTING MARKET FOR OIL & GAS INDUSTRY,
BY APPLICATION, 2021–2026 (USD MILLION)183
TABLE 127INDUSTRIAL 3D PRINTING MARKET FOR OIL & GAS INDUSTRY, BY REGION, 2017–2020 (USD MILLION)183
TABLE 128INDUSTRIAL 3D PRINTING MARKET FOR OIL & GAS INDUSTRY, BY REGION, 2021–2026 (USD MILLION)183
10.10CONSUMER GOODS184
10.10.13D PRINTING ALLOWS TO ACHIEVE HIGH DESIGN FREEDOM IN MAKING COMPLEX GEOMETRIES184
TABLE 129INDUSTRIAL 3D PRINTING MARKET FOR CONSUMER GOODS INDUSTRY,
BY APPLICATION, 2017–2020 (USD MILLION)184
TABLE 130INDUSTRIAL 3D PRINTING MARKET FOR CONSUMER GOODS INDUSTRY,
BY APPLICATION, 2021–2026 (USD MILLION)185
TABLE 131INDUSTRIAL 3D PRINTING MARKET FOR CONSUMER GOODS INDUSTRY,
BY REGION, 2017–2020 (USD MILLION)185
TABLE 132INDUSTRIAL 3D PRINTING MARKET FOR CONSUMER GOODS INDUSTRY,
BY REGION, 2021–2026 (USD MILLION)185
10.11OTHERS186
TABLE 133INDUSTRIAL 3D PRINTING MARKET FOR OTHER INDUSTRIES,
BY APPLICATION, 2017–2020 (USD MILLION)186
TABLE 134INDUSTRIAL 3D PRINTING MARKET FOR OTHER INDUSTRIES,
BY APPLICATION, 2021–2026 (USD MILLION)186
TABLE 135INDUSTRIAL 3D PRINTING MARKET FOR OTHER INDUSTRIES, BY REGION, 2017–2020 (USD MILLION)187
TABLE 136INDUSTRIAL 3D PRINTING MARKET FOR OTHER INDUSTRIES, BY REGION, 2021–2026 (USD MILLION)187
10.12IMPACT COVID-19 PANDEMIC ON VARIOUS INDUSTRIES187
10.12.1MOST-AFFECTED INDUSTRY187
10.12.2LEAST-AFFECTED INDUSTRY188

Report Title: Industrial 3D Printing Market with COVID-19 Impact Analysis, by Offering (Printers, Materials, Software, Services), Application, Process, Technology, Industry (Aerospace & Defense, Automotive) and Geography - Global Forecast to 2026


Your Details
Valid Invalid number

SELECT A FORMAT

ADD TO CART BUY NOW