DUBLIN, Oct. 9, 2018 /PRNewswire/ --
The "Ceramics Additive Manufacturing Markets 2017-2028" report has been added to ResearchAndMarkets.com's offering.
The report titled, Ceramics Additive Manufacturing Markets 2017-2028 projects that the ceramics 3D printing market is expected to generate overall revenues for over $3.6 billion, driven by strong CAGR in end-use part production.
In this second report from the researcher on ceramics additive manufacturing, readers will learn about the most up to date market data and analysis of market trends at the professional and industrial level. The report breaks down the ceramics 3D printing opportunity across numerous user industries as well as different AM technologies, materials and material supports, part types and geographical market regions.
The report analyzes pros, cons and generated revenues of the dominant AM technologies for processing ceramics, both technical (advanced) and traditional /(clay-like). These include material extrusion, photopolymerization and binder jetting 3D printing technologies. Currently available high-end industrial system data are complemented by a deep analysis of new and emerging technologies such as low-cost hardware systems and new jetting processes. All analyses are supported with hardware and material market shipments, sales, installations, and future forecasts through 2028 to provide a fully comprehensive insight into the future of ceramic 3D printing.
In 2018, the ceramics additive manufacturing market is focusing on AM part production, benefiting from the experience acquired by adopters and system OEM's who are working with metal and polymer technologies. Ceramics AM, however, presents a distinct set of advantaged and challenges which are explored in detail in this report, along with the latest successful use cases. The researcher believes that a proper understanding of the opportunity in ceramics 3D printing technology worldwide requires both a deep understanding of the individual nature of each print technology, but also an understanding of the interrelationship between these technologies and a specific family of ceramic materials, to fully understand how they can be integrated within current industrial manufacturing options.
Companies developing materials and providing ceramics additive manufacturing services or specific applications have come to understand that additive manufacturing's extreme geometric capabilities are proving to ideal for production of complex ceramic parts in all major ceramic adoption segments. These include the aerospace, automotive, marine, energy, electronics, medical, dental and biomedical segments, which are already among the first adopters of AM technologies. In this report the researcher will provide updated information on all major players and movers in the ceramic AM market, including Lithoz, 3D Ceram Sinto, Admatec, Prodways, Tethon 3D, 3D Systems, Kwambio, voxeljet, ExOne, HP, Johnson Matthey, Nanoe, XJet and several more.
From the Report:
- In this currently forecasted timeline, ceramics AM adoption will experience an inflection point after 2025 as all major AM technologies that support ceramics production come to maturity and enjoy a sufficient presence in the market to support actual serial production. The researcher is currently forecasting that this shift will be driven by imitating and benefiting from the experience of powder metal additive manufacturing. In particular the adoption of CIM- (ceramics injection molding) based additive manufacturing processes is expected to drive larger batch production in the same way as MIM- (metal injection molding) based additive processes are now expected to significantly expand AM adoption and throughput capabilities, lowering costs.
- Final parts value for both technical and traditional ceramic parts is expected to represent the most significant opportunities driving the market for the medium to long term future. Compared to relatively low revenues generated by technical and traditional ceramic materials, this trend indicated that in ceramics AM more than in any other material family, the primary value is in the process. This means that that additively manufacturing a ceramic part increases the value of the material used to produce it several times.
- Ceramics AM technologies are now largely available so perhaps the biggest challenge to address today is the creation of market demand. Many companies that produce ceramic components, especially advanced ceramic components, could be benefiting significantly from subassemblies and DfAM (Design for Additive Manufacturing) ceramic parts but in many cases still need to imagine, envision, design and develop the parts that will make ceramic AM processes and materials truly cost effective.
Key Topics Covered:
Chapter One: The Continuously Evolving Role of Ceramic Materials in Additive Manufacturing
1.1 Key Indicators that the Ceramics AM Market is Growing
1.1.1 Large Industrial Groups Driving Innovation
1.1.2 Ceramics AM Expanding into Low-cost Accessibility
1.1.3 Cement Materials Extrusion Growing Larger
1.1.4 Enter Glass
1.1.5 Cross Segment Drivers
1.2 Overview of Ceramics AM Materials
1.3 Primary Ceramic 3D Printing Technologies
1.3.1 Stereolithography
1.3.2 Binder Jetting and CIM
1.3.3 Material Extrusion (MEAM)
1.4 Industrial Segments of Application for Technical Ceramics
1.4.1 Electronics and Optics
1.4.2 Aerospace and Defense
1.4.3 Automotive and Rail
1.4.4 Maritime and Energy
1.4.5 Biomedical and Dental
1.5 Industrial Segments of Application for Traditional Ceramics
1.5.1 Tooling, Foundry Cores and Molds
1.5.2 Art, Design and Consumer Products
1.6 Notable Trends in Major Adopting Industries for 3D-Printed Ceramics
1.6.1 Ceramics for Bioprinting Applications
1.7 Implementation Timeline
1.8 Summary of Ten-year Forecasts for 3D Printed Ceramics
1.8.1 Forecast of Ceramics AM Hardware Revenues by Segment
1.8.2 Forecast of ceramics AM hardware revenues by geographic locations
1.9 Methodology
1.10 Key Points from this Chapter
Chapter Two: Evolution of Ceramics Additive Manufacturing and Associated Markets
2.1 Stereolithography (Vat Photopolymerization) of Technical Ceramics
2.1.1 High-end Ceramics Stereolithography
2.1.2 Developments in Low Cost Ceramics Stereolithography
2.2 Ceramics Binder Jetting
2.2.1 Industrial Binder Jetting of Ceramics
2.2.2 Developments in Low-cost Ceramics Stereolithography
2.3 Pneumatic Extrusion Technologies for Ceramics
2.3.1 Industrial Extrusion of Traditional and Advanced Ceramics
2.3.2 Low-cost Ceramic Extrusion for Consumer Products
2.4 Current Status of Ceramics Selective Laser Sintering
2.5 Other AM Processes for Ceramics
2.5.1 NanoParticle Jetting
2.5.2 CIM-based Processes
2.6 Ten-year Forecasts of Ceramics 3D Printing Hardware
2.7 Key Points from this Chapter
Chapter Three: Ceramics Materials and Media Used in Different 3D Printing Technologies
3.1 Primary Ceramic Materials Used in AM
3.1.1 Zircon-based ceramics
3.1.2 Alumina-based Ceramics
3.1.3 Silicon-based Ceramics
3.1.4 Calcium-based Ceramics
3.1.5 Cement-based Materials
3.1.6 Clays
3.1.7 Glass
3.1.8 Ceramic Injection Molding (CIM) Materials
3.2 Slurry Ceramic Materials for Photopolymerization Processes
3.2.1 Zirconia in Photopolymerization Processes
3.2.2 Alumina in Photopolymerization Processes
3.2.3 Silica in Photopolymerization Processes
3.2.4 TCP and HA in Photopolymerization Processes
3.2.5 Ten-year Forecast of Ceramics Materials for Photopolymerization Processes
3.3 Powder Ceramic Materials for Binder Jetting Processes
3.3.1 Silica Sand
3.3.2 Zircon
3.3.3 Terracotta, Clay and Porcelain for Binder Jetting
3.3.4 Technical Ceramic Powders for Binder Jetting
3.3.5 Ten-year Forecast of Powder Ceramics Materials for Binder Jetting Processes
3.4 Paste Ceramic Materials for Material Extrusion Processes
3.4.1 Cements for Extrusion 3D Printing
3.4.2 Ceramic Materials for Microextrusion 3D Printing
3.4.3 Ten-year Forecast of Paste Ceramic Materials for Extrusion Processes
3.5 Ceramic Materials for Other AM Processes
3.6 Ten-year Forecast for Ceramics AM Materials
3.6.1 Total Materials Market Ten-year Forecast
3.6.2 Forecast of Ceramics AM Materials Revenues by Geographic Locations
3.7 Key Points from this Chapter
Chapter Four: Parts and Services
4.1 Ceramics AM Services
4.1.1 Specialized Technical Ceramics AM Services
4.1.2 Specialized Traditional Ceramics AM Services
4.1.3 Non-specialized AM Services
4.2 Ten-year Forecast of Ceramics AM Services
4.3 Ceramics AM End-users
4.4 Application Cases in Major Vertical Markets for Ceramics 3D Printing
4.4.1 3D Printing of High-performance Ceramic Parts for Aerospace, Automotive
4.4.2 Medical and Biomedical Applications
4.4.3 Dental applications
4.4.4 Jewelry and Luxury Goods
4.4.5 Electronics
4.4.6 Energy
4.5 Ten-year Forecast of Ceramics AM Parts Value
4.5.1 Forecast of Revenues and Unit Demand for Ceramics AM Applications
4.5.2 Forecast of ceramics AM applications revenues by geographic locations
4.6 Key Points from this Chapter
Companies Mentioned
- Lithoz
- 3D Ceram Sinto
- Admatec
- Prodways
- Tethon 3D
- 3D Systems
- Kwambio
- voxeljet
- ExOne
- HP
- Johnson Matthey
- Nanoe
- XJet
For more information about this report visit https://www.researchandmarkets.com/research/9wdltz/3_6_bn_ceramics?w=5
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