Analysis on the Global Market for Shape Memory Materials (2015-2030) – ResearchAndMarkets.com

Shape Memory Alloys (SMA) are able to recover their initial shape after deformation has occurred when subjected to particular thermal conditions.

DUBLIN–(BUSINESS WIRE)–

The “The Global Market for Shape Memory Materials” report has been added to ResearchAndMarkets.com’s offering.

This report includes:

  • Applications and markets for shape memory alloys and shape memory polymers.
  • Analysis of shape memory materials by types and properties.
  • Patent analysis.
  • Assessment of economic prospects of the market for shape memory materials.
  • Market trends impacting the market for shape memory materials.
  • Main applications and markets for shape memory materials. Markets covered include biomedical, actuators across multiple markets, electronics, consumer goods, construction, tires, textiles, aerospace, soft robotics, automotive etc.
  • Shape memory market demand forecast (revenues), by type, market and region 2015-2030.
  • Shape memory materials producer profiles. Companies profiled include Awaji Materia Co., Ltd., ATI, Cambridge Mechatronics Limited, Dynalloy, Inc., Furukawa Electric Group, Maruho Hatsujyo Kogyo Co., Ltd., Nippon, re-fer AG, Shape Memory Medical, Inc., SAES Group, Sun Co. Tracking, VenoStent etc.

Shape memory materials are a widely-investigated class of smart materials capable of changing from one predetermined shape to another in response to a stimulus. The demand for structures capable of autonomously adapting their shape according to specific varying conditions has led to the development of shape memory materials such as Shape Memory Alloys (SMA) and Shape Memory Polymers (SMP).

Shape Memory Alloys (SMA) are able to recover their initial shape after deformation has occurred when subjected to particular thermal conditions. They possess superelastic behaviour, which allows large deformations with limited or no residual strain, and a high power-to-weight ratio. Other properties include biocompatibility, high corrosion resistance, high wear resistance and high anti-fatigue.

SMAs are used in couplings, actuators and smart materials and are particularly suitable for adaptive structures in electrical components, construction, robotics, aerospace and automotive industries. Systems based on SMA actuators are already in use in valves and drives, where they offer lightweight, solid state options to habitual actuators such as hydraulic, pneumatic and motor based systems.

SMA are used in many other applications such as medical, controllers for hot water valves in showers, petroleum industry, vibration dampers, ball bearings, sensors, miniature grippers, microvalves, pumps, landing gears, eyeglass frames, material for helicopter blades, sprinklers in fine alarm systems, packaging devices for electronic materials, dental materials, etc.

Shape memory polymers (SMPs) are a programmable (multi)stimuli-responsive polymers that change shape and stiffness through a thermal transition such as a glass transition. SMPs can recover their initial shape upon direct or Joule heating, radiation and laser heating, microwaves, pressure, moisture, solvent or solvent vapours and change in the pH values.

Shape-memory polymers differ from SMAs by their glass transition or melting transition from a hard to a soft phase which is responsible for the shape-memory effect. In shape-memory alloys, martensitic/austenitic transitions are responsible for the shape-memory effect. There are numerous advantages that make SMPs more attractive than shape memory alloys.

Key Topics Covered

1. Research Methodology

2. Executive Summary

2.1 Market Drivers

2.2 Applications

2.3 Market Challenges

3. Types

3.1 Shape Memory Alloys (SMA)

3.1.1 Nickel-Titanium (Ni-Ti) alloys

3.1.2 Copper-based SMAs

3.1.3 Other SMAs

3.1.4 Nickel-free SMAs

3.1.5 SMA actuators

3.1.6 Comparison of shape memory alloy types-advantages and disadvantages

3.2 Shape Memory Polymers (SMP)

3.2.1 Shape memory polyurethane films

3.2.2 Polyhedral oligosilsesquioxane (POSS) shape memory

3.2.3 Shape memory hydrogels

3.2.4 Diaplex

3.2.5 Carbon nanotubes SMPs

3.2.6 Graphene SMPs

4. Shape Memory Patenting

5. Markets and Applications

5.1 Biomedical

5.1.1 Stents

5.1.2 Dental braces

5.1.3 Coronary duct occluder

5.1.4 Prosthetics/Orthotics

5.1.5 Surgical devices

5.1.6 Sutures

5.1.7 Sensors

5.1.8 Tissue engineering

5.2 Electronics

5.2.1 Flexible electronics

5.2.2 Displays

5.2.3 3D printed shape memory alloys

5.3 Consumer Goods

5.3.1 Eyeglass frames

5.3.2 Home appliances

5.3.3 Toys

5.4 Construction

5.4.1 Structural engineering

5.4.2 Vibration dampers

5.5 Tires

5.5.1 Shape memory tires

5.6 Aerospace

5.6.1 SMA actuators

5.6.2 SMA composites

5.6.3 Space wheel

5.7 Textiles

5.7.1 Electronic textiles

5.7.2 Medical textiles

5.7.3 Insulating fabric

5.8 Soft Robotics

5.8.1 Soft actuators

5.9 Automotive

5.9.1 Actuators

5.9.2 Shape memory polymers

5.10 Other Markets

5.10.1 Water mixing valves

5.10.2 Fire dampers

5.10.3 Hot water valves

5.10.4 Oil and gas

5.10.5 Shape memory screws

5.10.6 Solar panels

6. Global Revenues and Regional Markets

6.1 Global market to 2030, total revenues (USD)

6.2 Global market to 2030, by market

6.3 Global market to 2030, by region

6.3.1 Shape memory market in North America

6.3.2 Shape memory market in Europe

6.3.3 Shape memory market in Japan

6.3.4 Shape memory market in China

7. Company Profiles

  • ATI
  • Awaji Materia Co. Ltd.
  • Cambridge Mechatronics Limited
  • Dynalloy, Inc.
  • Furukawa Electric Group
  • Maruho Hatsujyo Kogyo Co. Ltd.
  • Nippon
  • re-fer AG
  • SAES Group
  • Shape Memory Medical, Inc.
  • Sun Co. Tracking
  • VenoStent

List of Tables

Table 1. Market drivers for the use of shape memory materials

Table 2. Applications and market for shape memory materials

Table 3. Market challenges for shape memory materials

Table 4. Properties of shape memory alloys

Table 5. Types of shape memory alloys, by materials

Table 6. Nitinol properties

Table 7. Applications of shape memory materials in actuators

Table 8. Comparison of shape memory types

Table 9. Main shape memory materials patent assignees

Table 10. Location of shape memory materials patent filings 2008-2018

Table 11. Applications of shape memory materials in medical and stage of development

Table 12. Applications of shape memory materials in electronics and stage of development

Table 13. Applications of shape memory materials in consumer goods and stage of development

Table 14. Applications of shape memory materials in construction and stage of development

Table 15. Applications of shape memory materials in aerospace and stage of development

Table 16. Applications of shape memory materials in textiles and stage of development

Table 17. Applications of shape memory materials in soft robotics and stage of development

Table 18. Applications of shape memory materials in automotive and stage of development

Table 19. Applications of shape memory materials in other markets and stage of development

Table 20. The global market for shape memory materials, total, revenues (USD) 2015-2030

Table 21. Global market for shape memory materials, by market, revenues (USD) 2015-2030

Table 22. The global market for shape memory materials, by region, revenues (USD) 2015-2030

List of Figures

Figure 1. Shape memory materials

Figure 2. Phase transformation process for SMAs

Figure 3. Shape memory cycle

Figure 4. Shape memory materials patent applications 2001-2018

Figure 5. Stent based on film polyurethane shape memory polymer

Figure 6. Shape memory dental braces

Figure 7: Self-healing shape memory polymer patent schematic

Figure 8. SMA incorporated into eyeglass frames

Figure 9. The global market for shape memory materials, total, revenues (USD) 2015-2030

Figure 10. Global market for shape memory materials, by market, revenues (USD) 2015-2030

Figure 11. The global market for shape memory materials, by region, revenues (USD) 2015-2030

For more information about this report visit https://www.researchandmarkets.com/r/i15arv

View source version on businesswire.com: https://www.businesswire.com/news/home/20190912005419/en/

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Global Shape Memory Materials Market Report 2019: Types & Properties, Applications, Patent …

Applications and markets for shape memory alloys and shape memory polymers. Analysis of shape memory materials by types and properties.

Dublin, Sept. 12, 2019 (GLOBE NEWSWIRE) — The “The Global Market for Shape Memory Materials” report has been added to ResearchAndMarkets.com’s offering.

This report includes:

  • Applications and markets for shape memory alloys and shape memory polymers.
  • Analysis of shape memory materials by types and properties.
  • Patent analysis.
  • Assessment of economic prospects of the market for shape memory materials.
  • Market trends impacting the market for shape memory materials.
  • Main applications and markets for shape memory materials. Markets covered include biomedical, actuators across multiple markets, electronics, consumer goods, construction, tires, textiles, aerospace, soft robotics, automotive etc.
  • Shape memory market demand forecast (revenues), by type, market and region 2015-2030.
  • Shape memory materials producer profiles. Companies profiled include Awaji Materia Co., Ltd., ATI, Cambridge Mechatronics Limited, Dynalloy, Inc., Furukawa Electric Group, Maruho Hatsujyo Kogyo Co., Ltd., Nippon, re-fer AG, Shape Memory Medical, Inc., SAES Group, Sun Co. Tracking, VenoStent etc.

Shape memory materials are a widely-investigated class of smart materials capable of changing from one predetermined shape to another in response to a stimulus. The demand for structures capable of autonomously adapting their shape according to specific varying conditions has led to the development of shape memory materials such as Shape Memory Alloys (SMA) and Shape Memory Polymers (SMP).

Shape Memory Alloys (SMA) are able to recover their initial shape after deformation has occurred when subjected to particular thermal conditions. They possess superelastic behaviour, which allows large deformations with limited or no residual strain, and a high power-to-weight ratio. Other properties include biocompatibility, high corrosion resistance, high wear resistance and high anti-fatigue.

SMAs are used in couplings, actuators and smart materials and are particularly suitable for adaptive structures in electrical components, construction, robotics, aerospace and automotive industries. Systems based on SMA actuators are already in use in valves and drives, where they offer lightweight, solid state options to habitual actuators such as hydraulic, pneumatic and motor based systems.

SMA are used in many other applications such as medical, controllers for hot water valves in showers, petroleum industry, vibration dampers, ball bearings, sensors, miniature grippers, microvalves, pumps, landing gears, eyeglass frames, material for helicopter blades, sprinklers in fine alarm systems, packaging devices for electronic materials, dental materials, etc.

Shape memory polymers (SMPs) are a programmable (multi)stimuli-responsive polymers that change shape and stiffness through a thermal transition such as a glass transition. SMPs can recover their initial shape upon direct or Joule heating, radiation and laser heating, microwaves, pressure, moisture, solvent or solvent vapours and change in the pH values.

Shape-memory polymers differ from SMAs by their glass transition or melting transition from a hard to a soft phase which is responsible for the shape-memory effect. In shape-memory alloys, martensitic/austenitic transitions are responsible for the shape-memory effect. There are numerous advantages that make SMPs more attractive than shape memory alloys.

Key Topics Covered

1. Research Methodology

2. Executive Summary

2.1 Market Drivers

2.2 Applications

2.3 Market Challenges

3. Types

3.1 Shape Memory Alloys (SMA)

3.1.1 Nickel-Titanium (Ni-Ti) alloys

3.1.2 Copper-based SMAs

3.1.3 Other SMAs

3.1.4 Nickel-free SMAs

3.1.5 SMA actuators

3.1.6 Comparison of shape memory alloy types-advantages and disadvantages

3.2 Shape Memory Polymers (SMP)

3.2.1 Shape memory polyurethane films

3.2.2 Polyhedral oligosilsesquioxane (POSS) shape memory

3.2.3 Shape memory hydrogels

3.2.4 Diaplex

3.2.5 Carbon nanotubes SMPs

3.2.6 Graphene SMPs

4. Shape Memory Patenting

5. Markets and Applications

5.1 Biomedical

5.1.1 Stents

5.1.2 Dental braces

5.1.3 Coronary duct occluder

5.1.4 Prosthetics/Orthotics

5.1.5 Surgical devices

5.1.6 Sutures

5.1.7 Sensors

5.1.8 Tissue engineering

5.2 Electronics

5.2.1 Flexible electronics

5.2.2 Displays

5.2.3 3D printed shape memory alloys

5.3 Consumer Goods

5.3.1 Eyeglass frames

5.3.2 Home appliances

5.3.3 Toys

5.4 Construction

5.4.1 Structural engineering

5.4.2 Vibration dampers

5.5 Tires

5.5.1 Shape memory tires

5.6 Aerospace

5.6.1 SMA actuators

5.6.2 SMA composites

5.6.3 Space wheel

5.7 Textiles

5.7.1 Electronic textiles

5.7.2 Medical textiles

5.7.3 Insulating fabric

5.8 Soft Robotics

5.8.1 Soft actuators

5.9 Automotive

5.9.1 Actuators

5.9.2 Shape memory polymers

5.10 Other Markets

5.10.1 Water mixing valves

5.10.2 Fire dampers

5.10.3 Hot water valves

5.10.4 Oil and gas

5.10.5 Shape memory screws

5.10.6 Solar panels

6. Global Revenues and Regional Markets

6.1 Global market to 2030, total revenues (USD)

6.2 Global market to 2030, by market

6.3 Global market to 2030, by region

6.3.1 Shape memory market in North America

6.3.2 Shape memory market in Europe

6.3.3 Shape memory market in Japan

6.3.4 Shape memory market in China

7. Company Profiles

  • ATI
  • Awaji Materia Co. Ltd.
  • Cambridge Mechatronics Limited
  • Dynalloy, Inc.
  • Furukawa Electric Group
  • Maruho Hatsujyo Kogyo Co. Ltd.
  • Nippon
  • re-fer AG
  • SAES Group
  • Shape Memory Medical, Inc.
  • Sun Co. Tracking
  • VenoStent

List of Tables

Table 1. Market drivers for the use of shape memory materials

Table 2. Applications and market for shape memory materials

Table 3. Market challenges for shape memory materials

Table 4. Properties of shape memory alloys

Table 5. Types of shape memory alloys, by materials

Table 6. Nitinol properties

Table 7. Applications of shape memory materials in actuators

Table 8. Comparison of shape memory types

Table 9. Main shape memory materials patent assignees

Table 10. Location of shape memory materials patent filings 2008-2018

Table 11. Applications of shape memory materials in medical and stage of development

Table 12. Applications of shape memory materials in electronics and stage of development

Table 13. Applications of shape memory materials in consumer goods and stage of development

Table 14. Applications of shape memory materials in construction and stage of development

Table 15. Applications of shape memory materials in aerospace and stage of development

Table 16. Applications of shape memory materials in textiles and stage of development

Table 17. Applications of shape memory materials in soft robotics and stage of development

Table 18. Applications of shape memory materials in automotive and stage of development

Table 19. Applications of shape memory materials in other markets and stage of development

Table 20. The global market for shape memory materials, total, revenues (USD) 2015-2030

Table 21. Global market for shape memory materials, by market, revenues (USD) 2015-2030

Table 22. The global market for shape memory materials, by region, revenues (USD) 2015-2030

List of Figures

Figure 1. Shape memory materials

Figure 2. Phase transformation process for SMAs

Figure 3. Shape memory cycle

Figure 4. Shape memory materials patent applications 2001-2018

Figure 5. Stent based on film polyurethane shape memory polymer

Figure 6. Shape memory dental braces

Figure 7: Self-healing shape memory polymer patent schematic

Figure 8. SMA incorporated into eyeglass frames

Figure 9. The global market for shape memory materials, total, revenues (USD) 2015-2030

Figure 10. Global market for shape memory materials, by market, revenues (USD) 2015-2030

Figure 11. The global market for shape memory materials, by region, revenues (USD) 2015-2030

For more information about this report visit https://www.researchandmarkets.com/r/jmhoo2

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Global Additive Manufacturing Markets to 2023: Machines, Materials, Technologies, Applications …

3D Systems; Arcam AB; Carbon, Inc; Digital Metals; Eos Gmbh – Electro-Optical Systems; Envisiontec, Inc; Flash Forge Corporation; Formlabs, Inc …

Dublin, Sept. 12, 2019 (GLOBE NEWSWIRE) — The “Additive Manufacturing – Machines, Materials, Technologies, Applications, New Developments, Industry Structure and Global Markets” report has been added to ResearchAndMarkets.com’s offering.

The rapidly growing selection of materials, new approaches to automation, and increases in speed are allowing for growth in applications for 3D printing across industries, ranging from aerospace and automotive to durable goods, healthcare, dental care and jewellery.

Study Goals and Objectives

This study focuses on providing data about the size and growth of markets, company profiles, and industry trends in AM machines, materials and processes. The goal of this report is to provide a detailed and comprehensive multi-client study of the markets in North America, Europe, Japan, China and the rest of the world (RoW) for these machines, materials and processes, as well as potential business opportunities.

A primary objective of this report is a thorough coverage of underlying economic issues driving the development of AM machines, materials and processes, as well as assessments of advanced types of AM machines, materials and processes that are being developed. Another important objective is to provide realistic market data and forecasts of growth for AM machines, materials and processes.

This study provides the most thorough and up-to-date assessment that can be found anywhere on the subject. The study also provides extensive quantification of the many important facets of worldwide market development for AM machines, materials and processes. This, in turn, contributes to a determination of the kinds of strategic responses companies may adopt in order to compete in these dynamic markets.

Users of AM machines, materials and processes in developed markets must contend with twin pressures – to innovate and, at the same time, to reduce costs. New applications for AM machines, materials and processes have been proposed in recent years. This equipment study condenses all these business-related issues and opportunities.

This report has been prepared to highlight the many new developments in the additive manufacturing industry. Some of the technology segments are mature, while others are still emerging. Application segments have also been widening. These developments have created a need for a formal analysis of the technological and business issues, trends in technology, application and competition between countries and regions in this market.

Reasons for Doing the Study

The diversified businesses of AM machines, materials and processes are complex and fast-moving, with manufacturers increasingly adopting a truly global view of the market. Around the world, consumers are demanding high quality as well as extremely long cycle life. In this challenging market, manufacturers have attempted to achieve growth through company mergers and acquisitions and by implementing global strategies.

Recognizing the new emerging technologies and applications, the author has conducted a detailed study and updated technology developments and markets. This report identifies and evaluates new markets and new product developments that show potential growth for AM machines, materials and processes.

The report provides practical and cautionary advice and guidelines for managers, researchers, educators and investors in organizations around the world.

Format and Scope

The market data contained in this report quantify opportunities for AM machines, materials and processes equipment. In addition to product types, this report also covers the merits and future prospects of these businesses, including corporate strategies, information technologies, and the means for providing these highly advanced product and service offerings.

This report also covers in detail the economic and technological issues regarded by many as critical to the industry’s current state of change. It provides a review of the AM machines, materials and processes industry and its structure, and of the many companies involved in providing these products.

The competitive positions of the main players in the market, and the strategic options they face, also are discussed, along with such factors as marketing, distribution and operations.

Report Summary

Rapid Prototyping (RP) remains the dominant application of polymer AM processes and is well established in the market. Many of the aforementioned technologies are limited to RP, as they do not allow for processing of common engineering materials (polymers, metals, ceramics and composites thereof) with sufficient mechanical properties.

Besides RP, AM for rapid tooling also makes up some of the current AM activity involving the fabrication of molds and dies. For manufacturing applications of AM processes, notable areas of success include the production of medical devices such as dental crowns and hearing aids. Rapid tooling also has been applied to the production of consumer products, including high-value lighting goods and electronics.

The aerospace sector also has found a number of applications, often driven by the possibilities of improving buy-to-fly ratios and reducing the weight of components through design optimization. Other areas benefitting from rapid tooling include automotive, jewelry, architecture and defense applications.

AM offers the potential for developing complex, customized products that are prohibitively expensive to produce in current manufacturing settings. AM is poised to bring about a revolution in the way products are designed, manufactured, and distributed to end-users. The technology has gained significant academic as well as industry interest due to its ability to create complex geometries with customizable material properties. AM has also inspired the development of the maker movement by democratizing design and manufacturing.

Major findings of this report are:

  • According to the new study, the 2018 market for AM machines, materials and processes is projected to reach $6,500 million in 2018. It is expected to grow at a compound annual growth rate (CAGR) of 24.5% from 2018 through 2023, to reach $19,500 million in 2023.
  • Products revenue top 48%, followed by Service Revenue with 38% and other miscellaneous with 14%
  • The 2018 global market for AM machines, materials and processes by application is comprised of motor vehicles, aerospace, industry/business machines, medical devices and products /dental, government/military, architecture, consumer products/electronics, academics institutions and others.
  • The 2018 global market for additive manufacturing machines, materials and processes by technology, segmented into seven different categories, includes material extrusion, power bed fusion, vet photo-polymerization, material jetting, binder jetting, directed energy deposition, and sheet lamination or laminated object manufacturing (LOM).
  • In 2018, the AM machines, materials and processes market in North America has the highest market share, followed by Europe, Japan, and China. By 2023, North America is projected to retain the highest market share. By 2023, China is projected to show the highest CAGR%.

Key Topics Covered

Introduction

Executive Summary

  • Summary Table Global Market Size/Percentage Share for Additive Manufacturing Products, Service and Other Revenues, 2018 and 2023
  • Summary Figure Global Market Size/Percentage Share for Additive Manufacturing Products, Service and Other Revenues 2018-2023

Industry Overview

  • Industrial Usage
  • Hobbyist and Home Usage
  • Industry Overview of Third-Party Service Bureaus.
  • Table 1 Additives Manufacturing/3Dp Service Bureaus Business Models
  • Printer Makes/Models and Their Areas of Use
  • Table 2 2018 Printer Makes/Models and Their Uses
  • Table 3 Desktop Additive Manufacturing/3Dp Models Costing Less Than $20,000
  • Overview of Additive Manufacturing Ecosystem
  • Table 4 Classification of Additive Manufacturing Processes V/S Applications
  • Additive Manufacturing Process Steps

Technology Overview

  • Table 5 Definitions of Key Terms in Additive Manufacturing
  • Process Control in AM Machines
  • Basic Processes and Materials in AM
  • Table 6 Plastics Typically Used in Additive Manufacturing
  • Table 7 Metals Typically Used in Additive Manufacturing
  • Table 8 Features of Additive Manufacturing Processes
  • Table 9 Advantages of Additive Manufacturing Processes
  • Table 10 Typical Sizes/Volumes of Machines Used in Additive Manufacturing Processes
  • Types of Additive Manufacturing Technology
  • Table 11 Classification of Additive Manufacturing Processes By Astm International
  • Material Extrusion AM Processes
  • Powder Bed Fusion AM Processes
  • Table 12 Powder Bed Fusion Additive Manufacturing Processes
  • Vat Photo-Polymerization AM Processes
  • Material Jetting AM Processes
  • Binder Jetting Additive Manufacturing Processes
  • Sheet Laminations
  • Directed Energy Deposition
  • Software Used in AM
  • Table 13 3D Software Packages for Additive Manufacturing Machines
  • New Technology Developments in Additive Manufacturing Machines Through 2018
  • Table 14 New Technology Developments in Additive Manufacturing Machines Through 2018

Applications

  • Automotives
  • Table 15 Additive Manufacturing Examples in Automotives
  • Aerospace
  • Table 16 Uses of Additive Manufacturing in Aerospace
  • Industry/Business Machines
  • Table 17 Uses of Additive Manufacturing in Industry/Business Machines
  • Medical Applications
  • Additive Manufacturing of Non-Invasive Prosthetics
  • Surgical Tools and Guides
  • Dental Devices
  • Implantable Orthopedic Devices
  • Bioprinting
  • Regulations for Medical Devices Produced By Additive Manufacturing
  • Table 18 Important Regulations for Medical Devices Produced By Additive Manufacturing
  • Government and Military Applications
  • Qualification of AM Parts in Aerospace Applications
  • Table 19 Important Regulations for Aerospace Devices Produced By Additive Manufacturing
  • Additive Manufacturing Applications in Architecture
  • Table 20 Additive Manufacturing in Architecture
  • Consumer Products/Electronics/Education/Academic Institutes
  • Table 21 Consumer Products/Electronics/Academics and Other Applications of Additive Manufacturing
  • Post Process Control in Additive Manufacturing
  • Table 22 Post Process Control in Additive Manufacturing
  • Limitations of Additive Manufacturing

Markets

  • Evolution of Printer and Materials Technologies
  • Developing Value Chain
  • Widespread Innovations
  • Market Indicators
  • Drivers To Development and Adoption
  • Market According To System Types
  • Table 23 References for Market Size and Growth Rate Projections for Additive Manufacturing Machines, Materials and Processes
  • U.S. Additives Shipments
  • Table 24 U.S. Additives Shipments in 2011
  • Table 25 Segmented Global Market for Additive Manufacturing Machines and Other Inputs Through 2023
  • Figure 1A Segmented Global Market for Additive Manufacturing Machines and Other Inputs Through 2023
  • Figure 1B Segmented Global Market for Additive Manufacturing Machines and Other Inputs in 2023
  • Table 26 Global Market for Additive Manufacturing Machines By Form Factor Through 2023
  • Figure 2 Global Market for Additive Manufacturing Machines By Form Factor Through 2023
  • Table 27 Global Market for AM Machines By Technology Through 2023
  • Figure 3A Global Market for AM Machines By Technology in 2018
  • Figure 3B Global Market for AM Machines By Technology in 2023
  • Table 28 Global Market for AM Machines By Application Sectors Through 2023
  • Figure 4A Global Market of AM Machines By Application Sectors in 2018
  • Figure 4B Global Market of AM Machines By Application Sectors in 2023
  • Table 29 Summary of Global Market of AM Machines By Region Through 2023
  • Figure 5 Summary of Global Market of AM Machines By Region Through 2023

Mergers, Acquisitions and Divestitures

  • Table 30 Summary of Acquisitions, Mergers and Deals During 2014-2018

Patents

  • Table 31 U.S. Patents Granted for Additive Manufacturing Machines, Materials and Processes
  • From January 2014 Through June 2018
  • Overview of International U.S. Patent Activity in Additive Manufacturing Machines
  • Table 32 Number of U.S. Additive Manufacturing Patents Assigned By Region From January 2014 Through June 2018 Table 33 Top U.S. Patent Assignees for Additive Manufacturing Machines, Materials and Processes From January 2014 Through June 2018
  • Figure 6 Top U.S. Patent Assignees for Additive Manufacturing Machines, Materials and Processes
  • From January 2014 Through June 2018
  • Listing of U.S. Patents for Top Additive Manufacturing Machines, Materials and Processes
  • Direct Writing for Additive Manufacturing Systems
  • 3D Printing Colorization
  • Method and Apparatus for Adding Detail To A 3D Solid Model Using A Secondary Geometric Representation
  • Part Material for Electrophotography-Based Additive Manufacturing
  • Direct Writing for Additive Manufacturing Systems
  • Method for Printing Three-Dimensional Parts With Part Strain Orientation
  • Registration and Overlay Error Correction of Electrophotographically Formed Elements in an Additive Manufacturing System
  • Consumable Assembly With Payout Tube for Additive Manufacturing System
  • Layer Transfusion With Transfixing for Additive Manufacturing
  • Layer Transfusion for Additive Manufacturing
  • Electrophotography-Based Additive Manufacturing With Pre-Sintering
  • Encoded Consumable Materials and Sensor Assemblies for Use in Additive Manufacturing Systems
  • Polymer-Based Molds and Methods of Manufacturing Thereof
  • Method for Printing Three-Dimensional Items With Semi-Crystalline Build Materials
  • Layer Transfusion With Transfixing for Additive Manufacturing
  • 3D Printed Auxetic Structures
  • Methods for the Manufacture of Intraluminal Endoprosthesis
  • Additive Manufacturing Technique for Printing Three-Dimensional Parts With Printed Receiving Surfaces
  • Method and System for Building Painted Three-Dimensional Objects
  • Systems and Methods for Creating Near Real-Time Embossed Meshes
  • Method of Printing A Three-Dimensional Article
  • Powder Compositions and Methods of Manufacturing Articles Therefrom
  • Polyester Powder Compositions, Methods and Articles
  • Additive Manufacturing With Polyamide Consumable Materials
  • Additive Manufacturing Method for Building Three-Dimensional Objects With Core-Shell Arrangements
  • Additive Manufacturing With Virtual Planarization Control
  • Additive Manufacturing With Polyamide Consumable Materials
  • Support Structures and Deposition Techniques for 3D Printing
  • Infiltrated Articles Prepared By A Laser Sintering Method & Method of Manufacturing the Same
  • 3-D Object System Incorporating Two Materials in One Layer
  • Three-Dimensional Printing Material System and Method
  • Powder Compositions and Methods of Manufacturing Articles Therefrom
  • Direct Writing for Additive Manufacturing Systems
  • Compositions and Methods for Selective Deposition Modelling
  • Printing System for Forming Three Dimensional Objects
  • Three-Dimensional Printing Material System and Method
  • Powder Distribution for Laser Sintering Systems
  • Printing System for Forming Three Dimensional Objects
  • Solid Imaging Systems, Components Thereof, and Methods of Solid Imaging
  • Compositions and Methods for Selective Deposition Modelling
  • Compositions and Methods for Selective Deposition Modelling
  • Build Material and Applications Thereof

Company Profiles

Section 1: Manufacturers of AM Machines

  • 3D Systems
  • Arcam AB
  • Carbon, Inc
  • Digital Metals
  • Eos Gmbh – Electro-Optical Systems
  • Envisiontec, Inc
  • Flash Forge Corporation
  • Formlabs, Inc
  • Ge Additive Group
  • HP Inc
  • M3D, LLC
  • Mark Forged
  • Matsuura Machinery USA
  • Methods 3D, Inc
  • Monoprice, Inc
  • Nano Dimension Inc
  • Optomec Corporation
  • Protolabs Inc
  • Renishaw Inc
  • Sciaky, Inc
  • SLM Solutions Gmbh
  • Stratasys, Inc
  • Trumpf Inc
  • Ultimaker Bv
  • Voxeljet Ag
  • Xyz Taiwan

Section 2 – Manufacturers of AM Metal Powder

  • Ap&C Advanced Powders and Coatings Inc
  • Heraeus Germany Gmbh & COG
  • Hoeganaes Corporation (A GKN Company)
  • Hoganas AB
  • LPW Technology Ltd
  • Sandvik Osprey Ltd
  • Gkn Additive

Section 3 – Manufacturers of AM Polymer Powder

  • Advanced Laser Materials, LLC
  • Basf Se
  • CRP Technology Sl
  • Sigma Labs Inc

Section 4 – Manufacturers and Suppliers of AM Software

  • Altair Engineering
  • Autodesk Inc
  • Siemens Process Industries and Drives

Section 5 – Contract Manufacturers / AM Service

  • Bureaus
  • 3I-Print
  • Arconic
  • Concurrent Technologies Corporation
  • Digital Alloys, Inc
  • Fit Ag
  • Forecast 3D
  • Gkn Hoeganaes (A Gkn Company)
  • GPI Prototype & Manufacturing Services, LLC
  • Materialise Nv
  • I3D MFG
  • Imperial Machine & Tool Co
  • Method 3D
  • The National Centre for Additive Manufacturing (Ncam)
  • Oerlikon AM (Citim Gmbh)
  • Protolabs Company
  • Rostec Russia
  • Sculpteo
  • Slice MFG Studios
  • Wipro3D

Section 6 – AM End Users

  • Bosch Service
  • Caterpillar
  • Ge Centre for Additive Technology Advancement
  • Harbec, Inc
  • Jabil Company
  • Materials Solutions Limited
  • Moog Inc
  • Triumph Group Inc

Section 7 – AM Consultants

For more information about this report visit https://www.researchandmarkets.com/r/9i8y0f

Research and Markets also offers Custom Research services providing focused, comprehensive and tailored research.

CONTACT: ResearchAndMarkets.comLaura Wood, Senior Press Managerpress@researchandmarkets.comFor E.S.T Office Hours Call 1-917-300-0470For U.S./CAN Toll Free Call 1-800-526-8630For GMT Office Hours Call +353-1-416-8900

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Global Healthcare Enterprise Content Management Market 2019-2023: Competitive Landscape …

This unstructured content holds most of the critical patient data, which is … deep-learning (DL), Big Data analytics and intelligent text-mining features …

DUBLIN, Sept. 9, 2019 /PRNewswire/ — The “Global Enterprise Content Management Market for Healthcare, Forecast to 2023” report has been added to ResearchAndMarkets.com’s offering.

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Global Enterprise Content Management Market for Healthcare, Forecast to 2023 provides a comprehensive analysis on the global ECM market for healthcare and outlines the competitive landscape, top predictions, global trends, and key growth opportunities.

The report also discusses healthcare trends by region based on increasing interest in digital data management. In addition, this report presents information on important companies to keep track of, and lists both established and new enterprises, chosen by the author’s analytical team.

For over two decades, healthcare systems across the globe have considered digitisation a priority and have invested heavily in eHealth systems. This has resulted in the extensive proliferation of several clinical and non-clinical information systems in healthcare organizations. These information systems are capable of handling structured content generated within the application framework; any unstructured content generated from external sources is excluded from the workflow due to lack of compatibility factors.

In a clinical context, while most electronic medical/health records (EMR/EHR) manage structured content, even the best systems cannot afford to manage unstructured data such as paper documents, faxes, images, photos, and rich multi-media data contents generated across the care setting. In a non-clinical context, ECM solutions complement administrative, operational, and financial information systems in a healthcare enterprise by allowing end users to efficiently aggregate, store, and manage diverse content generated across the enterprise.

Globally, healthcare organizations are struggling to manage patient data and relevant content in a structured format. A robust enterprise content management strategy can help healthcare organizations to streamline the complex process. Therefore, healthcare ECM is becoming crucial in a modern care setting to complement the shortcomings of existing EHR systems. The crucial need to securely access and analyse data along the patient’s care journey is driving demand for new-generation content management technology platforms.

The author finds that on average, a modern healthcare organization generates approximately 70-75% of unstructured content from existing clinical and non-clinical information systems. This unstructured content holds most of the critical patient data, which is either lost or omitted during electronic transactions, resulting in uncertainty about inefficient healthcare data management standards. Lack of healthcare content management strategies limits organizational access to valuable information and makes it difficult for clinicians to access the right information at the right time.

Furthermore, the healthcare industry will witness core ECM systems transitioning to enterprise content service platforms with the entire technology framework built around data to support many facets of enterprise content. The data-driven platform will be powered by smart APIs and web services to leverage advanced services such as artificial intelligence (AI), machine-learning (ML), deep-learning (DL), Big Data analytics and intelligent text-mining features for improved healthcare outcomes.

Key Issues Addressed

  • What are the key market trends and industry dynamics in the enterprise content management market for healthcare? What is the future potential for ECM solutions in healthcare?
  • What is the current market scenario? How much growth is expected? Which are the major market segments? What will be the impact of external trends on each business segment?
  • Who are the major participants in the global ECM market for healthcare? What are their solution and service offerings, product features, capabilities, and technical specifications?
  • What is driving the ECM market for healthcare? What are the restraints impacting growth opportunities for ECM solutions in the global healthcare market?
  • What are the important business model considerations for healthcare stakeholders and providers? Are there any unmet customer needs? Is there an untapped opportunity in this market?
  • Are the existing ECM solutions offered by solution vendors meeting end-user needs?

Key Topics Covered:

1. Executive Summary

  • Global ECM Market for Healthcare – 4-Decade Perspective
  • Global Healthcare System – Current Status
  • Key Findings – Total ECM Market for Healthcare
  • Study Scope and Segmentation
  • Key Questions this Study will Answer
  • Enterprise Content Management for Healthcare – Definitions
  • Market Engineering Measurements
  • CEO’s Perspective
  • Key Findings – Geographic Outlook
  • Key Findings – Healthcare ECM Growth Indicators
  • Total ECM Market for Healthcare – Segment Maturity Curve
  • At the Point of Convergence – Enterprise Content Services Platform
  • Executive Summary – 4 Big Predictions

2. Enterprise Content Service Platforms

  • ECM Transition to Enterprise Content Service Platforms
  • Next-Generation Healthcare Content Service Platform
  • Future of New-Generation Healthcare Content Services
  • Evolution of Enterprise Content Management Systems
  • Healthcare ECM – Product Features Adoption Curve
  • Analysis of Key in ECM Suite Product Features Required by Providers

3. Enterprise Imaging Platform and Unified VNA

  • Enterprise Imaging and Unified VNA Strategy
  • Enterprise Imaging and Key Benefits to Providers
  • Key Technology Enabler For a Holistic Patient View

4. Healthcare ECM Trends

  • Top 6 Trends for ECM Vendors in 2019
  • ECM Platform – Select Use Cases in the Healthcare Industry
  • Top 6 Factors Influencing Healthcare Content Management
  • Top Predictions – Healthcare ECM

5. Market Overview

  • Market Overview – Definitions
  • Market Overview – Segmentation
  • Key Market Segmentation by Solutions
  • Market Segmentation by Use Case and Applications
  • Hospital IT Ecosystem – Clinical and Non-clinical Information Systems

6. Dynamics Catalysing Global Market Growth – Key Market Trends

  • Geographical Opportunity Analysis for Healthcare ECM Systems
  • Industry Dynamics Impacting HCS Platform Market
  • EU-General Data Protection Regulation (EU-GDPR)
  • ECM Helping Providers Comply with EU-GDPR Regulations

7. Drivers and Restraints – Total ECM Market for Healthcare

  • Market Drivers
  • Drivers Explained
  • Market Restraints
  • Restraints Explained

8. Forecast and Trends – Total ECM Market for Healthcare

  • Market Engineering Measurements
  • Forecast Assumptions and Definitions
  • Revenue Forecast
  • Revenue Forecast Discussion
  • Percent Revenue Forecast by Region
  • Revenue Forecast by Region
  • Revenue Forecast Discussion
  • Pricing Analysis
  • Pricing Model
  • Healthcare ECM – Professional Service Contracts Trends

9. Demand Analysis – Total ECM Market for Healthcare

  • Global Demand Analysis
  • Demand Analysis Discussion

10. Competitive Environment

  • Competitive Market Structure
  • Detailed Vendor Segmentation
  • Detailed Vendor Segmentation – Description
  • Merger, Acquisition, and Partnership Assessment
  • More Global Healthcare ECM Vendors

11. Future Perspectives – Growth Opportunities

  • Five Growth Opportunities Critical for Future Success
  • Strategic Business Imperatives for Success and Growth of Healthcare ECM Vendors

12. Product Offerings Segment Analysis

  • Percent Revenue Forecast by Product Offerings

13. Installation of New ECM for Healthcare Segment Analysis

  • Market Engineering Measurements
  • Revenue Forecast

14. Renewal of Existing ECM for Healthcare Segment Analysis

  • Market Engineering Measurements
  • Revenue Forecast

15. Software Product and Professional Services Segment Analysis

  • Percent Revenue Forecast by Software and Professional Services

16. ECM Software Product Licenses Segment for Healthcare Analysis

  • Market Engineering Measurements
  • Revenue Forecast
  • Percent Revenue Forecast by Sub-segment
  • On-premise ECM Software Sub-segment for Healthcare – Revenue Forecast
  • ECM Cloud Services Sub-segment for Healthcare – Revenue Forecast

17. ECM Systems Professional Services Segment for Healthcare Analysis

  • Market Engineering Measurements
  • Revenue Forecast
  • Percent Revenue Forecast by Sub-segment
  • ECM System Implementation and Maintenance Services Sub-segment – Revenue Forecast
  • ECM System Consulting and Support Services Segment Sub-Segment – Revenue Forecast

Companies Mentioned

  • Agfa Healthcare
  • Alfresco
  • Box
  • Chartmaxx
  • Confluence
  • Contentverse
  • Docushare
  • DocuWare
  • Everteam
  • Fabasoft Cloud
  • Hyland
  • IBM
  • Laserfiche
  • M-Files
  • Microsoft
  • Newgen Software
  • Nuxeo
  • OpenText
  • Oracle Corp
  • Paperport
  • Ricoh
  • Seismic
  • Springcm
  • Streamline Health
  • Veeva Vault
  • Xerox

For more information about this report visit https://www.researchandmarkets.com/r/hfu6cg

Research and Markets also offers Custom Research services providing focused, comprehensive and tailored research.

Media Contact:

Research and Markets

Laura Wood, Senior Manager

press@researchandmarkets.com

For E.S.T Office Hours Call +1-917-300-0470

For U.S./CAN Toll Free Call +1-800-526-8630

For GMT Office Hours Call +353-1-416-8900

U.S. Fax: 646-607-1907

Fax (outside U.S.): +353-1-481-1716

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Digital Gazette Security Digitalisation, Q2 2019: Digital Policing, Critical Infrastructure and …

The author provides a brief quarterly analysis on key news that have shaken up … IoT, Big Data, and Data Analytics; recent partnerships; and insights.

DUBLIN, Sept. 9, 2019 /PRNewswire/ — The “Digital Gazette – Security Digitalisation, Q2 2019” report has been added to ResearchAndMarkets.com’s offering.

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The digital transformation has made further progression into the security market during Q2, from a digital policing, critical infrastructure and government perspectives.

The author provides a brief quarterly analysis on key news that have shaken up the digital security market. It also provides an overview on key developments, financial performance highlights and contracts in the industry, plus the relevant partnerships and M&A forged amongst its stakeholders around the world during the second quarter of 2019 against the backdrop of digital transformation in this space.

The Digital Gazette also sheds light on the digital champions involved in Cloud Computing, Artificial Intelligence, Robotics, IoT, Big Data, and Data Analytics; recent partnerships; and insights.

After covering Brexit in the Q1 Digital Gazette, the Analyst Corner explores this time the hidden challenges met when embracing the digital transformation with uses cases taken from leading economies.

Key Topics Covered:

1. Executive Summary

2. Q2 Overview

Q2 Digital Highlights

Q2 Financials

Competition Corner

Q2 – Major Contracts Highlights

Analyst Corner

3. The Last Word

Q2 Takeaways

For more information about this report visit https://www.researchandmarkets.com/r/emy1w3

Research and Markets also offers Custom Research services providing focused, comprehensive and tailored research.

Media Contact:

Research and Markets

Laura Wood, Senior Manager

press@researchandmarkets.com

For E.S.T Office Hours Call +1-917-300-0470

For U.S./CAN Toll Free Call +1-800-526-8630

For GMT Office Hours Call +353-1-416-8900

U.S. Fax: 646-607-1907

Fax (outside U.S.): +353-1-481-1716

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View original content:http://www.prnewswire.com/news-releases/digital-gazette-security-digitalisation-q2-2019-digital-policing-critical-infrastructure-and-government-perspectives-300914112.html

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