Global Additive Manufacturing Market (2012 - 2017) - By Application [Medical Devices, Automotives, & Aerospace] & Technology [3D Printing, Laser Sintering, Stereolithography, Fused Deposition Modeling, Electron Beam Melting, & Tissue Engineeri

NEW YORK, Nov. 21, 2012 — (PRNewswire) — Reportlinker.com announces that a new market research report is available in its catalogue:

Global Additive Manufacturing Market (2012 – 2017) – By Application [Medical Devices, Automotives, & Aerospace] & Technology [3D Printing, Laser Sintering, Stereolithography, Fused Deposition Modeling, Electron Beam Melting, & Tissue Engineering]

http://www.reportlinker.com/p01022412/Global-Additive-Manufacturing-Market-2012-–-2017-–-By-Application-[Medical-Devices-Automotives--Aerospace]--Technology-[3D-Printing-Laser-Sintering-Stereolithography-Fused-Deposition-Modeling-Electron-Beam-Melting--Tissue-Engineering].html#utm_source=prnewswire&utm_medium=pr&utm_campaign=Orthopedic

Additive manufacturing is an automatic process used to create rapid prototypes and functional end-use parts. It takes virtual designs from Computer Aided Design (CAD) software, and transforms them into thin, virtual, horizontal layer-wise cross-sections, until the model is complete. The AM is a potentially growing market in every manufacturing sector with a global market of $1,843.2 million in 2012 and is expected to grow at a CAGR of 13.5% to reach $3,471.9 million by 2017.

The global additive manufacturing devices market has been segmented into different areas such as, automotives, consumer products, business machines, medical, academic, aerospace, government/military and others. Automotives or motor vehicles account for the largest share in this market, primarily due to the easy applications of 3D printing in the production of end-products (engines, spare parts, other interior, and exterior parts) as compared to other segments such as consumer products and business machines, which have limited usage in manufacturing of end-products. Rising healthcare expenditure in emerging economies provide growth opportunities for the additive manufacturing technologies, as new healthcare facilities have come up in these areas.

New and improved technologies, financial support from governments, large application area, rapid product development at a low cost, and ease of development of custom products are the major drivers that are slated to propel this market. However, a few pivotal factors restraining the growth of this market are regulatory hurdles in different countries, material characterization during development, and process control and understanding.

In this report, we are mainly focusing on medical applications of additive manufacturing. Within the medical industry, additive manufacturing is used in making end-products such as surgical equipments, prosthetics & implants, and scaffolds. The market is growing due to the rising incidence of surgeries, coupled with increasing awareness and advances in technology. Surgical equipments account for the largest share in this market due to their wide applicability.

Europe dominates the additive manufacturing for medical devices market in 2012, followed by North America. However, adoption of novel additive manufacturing technologies in the medical field is gaining momentum at a fast pace in emerging nations due to growing educational and awareness efforts of industry players among physicians and patients. Moreover, increasing healthcare expenditure, growing income levels, low cost of manufacturing, rapid product development, growing surgical procedures in lieu with medical tourism, and lesser competition than mature countries, have amplified interest of market players in emerging markets.

The key players in this market are 3D Systems Corporation (U.S.), 3T RPD (U.K.), Arcam AB (Sweden), Biomedical Modeling, Inc. (U.S.), Envisiontec GmbH (Germany), EOS GmbH Electro Optical Systems (Germany), Fcubic AB (Sweden), GPI Prototype and Manufacturing Services, Inc. (U.S.), Greatbatch, Inc. (U.S.), Layerwise NV (Belgium), Limacorporate SPA (Italy), Materialise NV (Belgium), Medical Modeling, Inc. (U.S.), and others.

Scope of the Report

This research report categorizes the global additive manufacturing market into the following:

Global additive manufacturing market, by industry

AutomotivesConsumer productsBusiness machinesMedicalAcademicAerospaceGovernment/militaryOthersGlobal additive manufacturing market, by materials

Homogeneous materials

Polymers

Metals

Natural materials

Ceramics

Heterogeneous materials

Polymeric matrix

Metallic matrix

Ceramic matrix

Multiple materials

Global additive manufacturing for medical devices market

By ProductsSurgical equipmentSurgical guidessurgical instrumentsProsthetics & implantsOrthopedic implantsDental implantsCranio-maxillofacial implantsTissue engineeringPorous tissue engineering scaffoldsBy TechnologyElectron Beam Melting (EBM)Laser Beam Melting (LBM)Direct Metal Laser Sintering (DMLS)Selective Laser Melting (SLM)Selective Laser Sintering (SLS)Laser CusingPhotopolymerizationDigital Light ProcessingStereolithographyTwo-Photon PolymerizationDroplet Deposition (DD) or Extrusion based technologiesLow-temperature Deposition Manufacturing (LDM)Multiphase Jet Solidification (MJS)Fused Deposition Modeling (FDM)Three Dimensional Printing (3DP) or Adhesion BondingBy ApplicationOrthopaedicDentalCranio-MaxillofacialBio-EngineeringBy GeographyNorth AmericaEuropeAsiaRoW (Middle East, Africa, Russia, and Latin America)

TABLE OF CONTENTS

1 INTRODUCTION

1.1 KEY TAKE AWAYS

1.2 REPORT DESCRIPTION

1.3 MARKETS COVERED

1.4 STAKEHOLDERS

1.5 RESEARCH METHODOLOGY

1.5.1 MARKET SIZE

1.5.2 MARKET SHARE

1.5.3 KEY DATA POINTS FROM SECONDARY SOURCES

1.5.4 KEY DATA POINTS FROM PRIMARY SOURCES

1.5.5 ASSUMPTIONS

2 EXECUTIVE SUMMARY

3 MARKET OVERVIEW

3.1 INTRODUCTION

3.2 MARKET SEGMENTATION

3.2.1 GLOBAL ADDITIVE MANUFACTURING MARKET, BY INDUSTRY TYPE

3.2.2 GLOBAL ADDITIVE MANUFACTURING MARKET, BY MATERIALS

3.2.3 GLOBAL ADDITIVE MANUFACTURING SYSTEMS MARKET, BY VALUE & VOLUME ANALYSIS

3.2.4 GLOBAL ADDITIVE MANUFACTURING FOR MEDICAL DEVICES MARKET SEGMENTATION

3.2.4.1 By Products

3.2.4.2 By Technology

3.2.4.3 By Application

3.3 MARKET DYNAMICS

3.3.1 DRIVERS

3.3.1.1 New & improved technologies

3.3.1.2 Financial support from Governments

3.3.1.3 Large application area

3.3.1.4 Rapid product development at a low cost

3.3.1.5 Ease of development of custom products

3.3.2 RESTRAINTS

3.3.2.1 Regulatory hurdles in different countries

3.3.2.2 Material development & characterization

3.3.2.3 Process control & understanding

3.3.3 OPPORTUNITIES & THREATS

3.3.3.1 Rising of global AM market

3.3.3.2 Participation of small companies

3.3.3.3 Positive growth by mergers & acquisitions

3.3.3.4 Emerging research & development

3.3.4 TRENDS

3.4 UPCOMING TECHNOLOGIES

3.5 MARKET SHARE ANALYSIS

3.5.1 BY MATERIALS

3.5.2 BY TECHNOLOGY

3.5.3 BY APPLICATION

3.5.4 BY GEOGRAPHY

3.5.5 ADDITIVE MANUFACTURING FOR MEDICAL DEVICES MARKET, BY PLAYERS

3.5.6 ADDITIVE MANUFACTURING END PRODUCTS MARKET IN MEDICAL SEGMENT, BY PLAYERS

4 GLOBAL ADDITIVE MANUFACTURING, BY INDUSTRY TYPE 4.1 INTRODUCTION 4.2 MOTOR VEHICLES 4.3 CONSUMER PRODUCTS 4.4 BUSINESS MACHINES 4.5 MEDICAL INDUSTRY 4.6 ACADEMICS 4.7 AEROSPACE 4.8 GOVERNMENT/MILITARY 4.9 OTHERS (ARCHITECTURE, PALEONTOLOGY & FORENSIC PATHOLOGY)

5 APPLICATION OF MATERIAL USED IN ADDITIVE MANUFACTURING FOR MEDICAL PRODUCTS

5.1 INTRODUCTION

5.2 HOMOGENEOUS MATERIALS

5.2.1 POLYMERS

5.2.2 METALS

5.2.3 CERAMICS

5.2.4 NATURAL MATERIALS

5.3 HETEROGENEOUS MATERIALS

5.3.1 POLYMERIC MATRIX

5.3.2 METALLIC MATRIX

5.3.3 MULTIPLE MATERIALS

5.4 APPLICATION OF MATERIAL USED IN ADDITIVE MANUFACTURING FOR MEDICAL PRODUCTS

6 GLOBAL ADDITIVE MANUFACTURING DEVICES MARKET (VALUE & VOLUME ANALYSIS) 6.1 INTRODUCTION 6.1.1 3D PRINTERS 6.1.2 3D BIO-PRINTERS

7 GLOBAL ADDITIVE MANUFACTURING FOR MEDICAL DEVICES MARKET, BY PRODUCTS

7.1 INTRODUCTION

7.2 SURGICAL EQUIPMENT

7.2.1 SURGICAL GUIDES

7.2.1.1 Dental guides

7.2.1.2 Cranio-Maxillofacial (CMF) guides

7.2.1.3 Orthopedic guides

7.2.2 SURGICAL INSTRUMENTS

7.2.2.1 Retractors

7.2.2.2 Scalpels

7.2.2.3 Surgical fasteners

7.2.3 PROSTHETICS & IMPLANTS

7.2.3.1 Standard implants

7.2.3.1.1 Standard orthopedic implants

7.2.3.1.2 Standard dental implants

7.2.3.1.3 Standard cranio-maxillofacial implants

7.2.3.2 Custom implants

7.2.3.2.1 Custom orthopedic implants

7.2.3.2.2 Custom dental implants

7.2.3.2.3 Custom cranio-maxillofacial implants

7.2.4 TISSUE ENGINEERING

7.2.4.1 Porous scaffolds

7.2.4.1.1 Bone & cartilage scaffolds

7.2.4.1.2 Ligament & tendon scaffolds

8 GLOBAL ADDITIVE MANUFACTURING FOR MEDICAL DEVICES MARKET, BY TECHNOLOGY 8.1 INTRODUCTION 8.2 ELECTRON BEAM MELTING (EBM) 8.3 LASER BEAM MELTING 8.3.1 DIRECT METAL LASER SINTERING (DMLS) 8.3.2 SELECTIVE LASER MELTING (SLM) 8.3.3 SELECTIVE LASER SINTERING (SLS) 8.3.4 LASER CUSING 8.4 PHOTOPOLYMERIZATION 8.4.1 DIGITAL LIGHT PROCESSING (DLP) 8.4.2 STEREOLITHOGRAPHY (SLA) 8.4.3 TWO-PHOTON POLYMERIZATION (2PP) 8.5 DROPLET DEPOSITION (DD) OR EXTRUSION-BASED TECHNOLOGIES 8.5.1 LOW-TEMPERATURE DEPOSITION MANUFACTURING (LDM) 8.5.2 MULTIPHASE JET SOLIDIFICATION (MJS) 8.5.3 FUSED DEPOSITION MODELING (FDM) 8.5.4 THREE DIMENSIONAL PRINTING (3DP) OR ADHESION BONDING

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