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1474057

全球 3D 列印高性能塑膠市場 - 2024-2031

Global 3D Printing High Performance Plastic Market - 2024-2031

出版日期: 2024年05月02日 | 出版商:

DataM Intelligence | 英文 204 Pages | 商品交期: 最快1-2個工作天內

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簡介目錄

概述

全球3D列印高性能塑膠市場2023年達到1.22億美元，預計到2031年將達到6.645億美元，2024-2031年預測期間複合年成長率為23.6%。

可 3D 列印的高性能聚合物提供無與倫比的可自訂性和設計自由度。企業透過快速迭代設計、創建原型和根據特定客戶規格客製化零件來縮短上市時間並提高產品獨特性。與傳統製造流程相比，3D 列印能夠消除模具並縮短交貨時間，這對企業來說具有經濟優勢。當高性能塑膠零件可以小批量、按需生產或具有複雜的幾何形狀而無需增加模具成本時，效率和競爭力就會提高。

醫療保健產業正在將 3D 列印製造的高性能聚合物用於義肢、植入物、醫療設備和客製化醫療保健解決方案。這些材料的生物相容性、穩定性和可自訂性使其非常適合醫療應用，從而推動了市場的成長。與傳統生產方法相比，3D 列印高性能塑膠可以透過減少材料浪費、能源使用和碳排放來幫助實現永續發展目標。積層製造的材料回收和再利用能力進一步增強了其環境吸引力。

由於政府對高性能塑膠 3D 列印的認可不斷增加，北美成為市場的主導地區，這有助於推動預測期內該地區市場的成長。例如，2024 年 4 月 16 日，3D Systems 宣布 FDA 批准 3D 列印 PEEK 顱骨植入物。與傳統機械加工製造的同類植入物相比，這種方法製造的患者專用顱骨植入物使用的材料減少了 85%，這可以節省昂貴的原料（如植入式 PEEK）的成本。此外，該印表機基於無塵室的架構和簡化的後處理程序使其能夠在醫院現場更快地生產患者專用的醫療設備，同時保持成本控制。

動力學

3D 列印技術的進步

3D列印技術的發展提高了列印效率和列印速度。正因為如此，生產商現在可以更快地生產高性能塑膠零件，從而縮短交貨時間並提高產量水平。隨著現代 3D 列印機解析度的提高和更精細的細節能力，可以生產出具有出色表面品質和精度的複雜而細緻的高性能塑膠零件。因此，需要精確幾何形狀和緊密公差的應用可以從 3D 列印中受益。

由於一些先進的 3D 列印技術可實現多材料列印，因此可以在單一列印作業中使用多種高性能聚合物或材料組合。這種適應性增加了 3D 列印高性能塑膠實現的功能和應用範圍。由於大幅面 3D 列印技術的發展，可以使用高性能聚合物生產更大、更複雜的零件。這對於需要大型零件的行業尤其有幫助，包括建築、汽車和航空航太。

業界對輕量化和高性能零件的需求不斷成長

航空航太業不斷尋找輕質材料來提高飛機性能，同時降低燃料消耗。 ULTEM 和聚醚醚酮等高性能聚合物是管道系統和支架等耐熱且耐用組件的首選。如果汽車產業要實現減少污染的目標，輕量化至關重要。碳纖維增強聚合物和丙烯腈丁二烯苯乙烯衍生物是用於 3D 列印輕質零件（例如引擎零件和結構元件）的高性能塑膠的例子。

醫療保健產業需要高性能塑膠來製造手術設備和醫療器材。醫用級聚醯胺、PEEK、鈦合金和其他生物相容性材料經過3D 列印，可製造為每位患者量身定做的手術導板、植入物、義肢和牙科組件，這些組件具有最佳的機械品質和相容性。消費性電子產品製造商在 3D 列印中採用高性能聚合物來生產用於穿戴式裝置和無人機的堅固且輕質的組件。建議使用 ABS 和尼龍等材料，因為它們具有更好的電絕緣性能、抗衝擊性和熱穩定性。

高性能材料成本高

高性能材料的昂貴特性使得 3D 列印技術對於新創公司或小型公司來說難以承受。對於資金有限的公司來說，購買這些用品、專用機械和後處理儀器所需的初始費用可能難以負擔。成本敏感性在汽車、航空航太和醫療保健等行業很常見，這些行業是 3D 列印中高性能樹脂的大消費者。製造零件的整體成本可能會受到材料成本高的影響，這可能會影響這些行業的利潤率和競爭力。

大批量或大規模應用的 3D 列印高性能聚合物的能力受到費用的限制。如果使用高性能聚合物 3D 列印的經濟性不足以證明支出合理，製造商可能會選擇使用傳統生產技術或更便宜的材料。 3D 列印高性能聚合物的價格可能會影響顧客對價格敏感的消費類別（如堅固產品或消費性電子產品）的選擇。實現市場可接受性需要在承受能力和性能之間取得平衡。

High-performance polymers that can 3D printed provide unmatched customizability and design freedom. Businesses shorten time-to-market and improve product distinctiveness by quickly iterating designs, creating prototypes and customizing parts to particular client specifications. The capacity of 3D printing to eliminate tooling and reduce lead times over traditional manufacturing processes is financially advantageous to businesses. When high-performance plastic components may be produced in small quantities, on-demand or with intricate geometries without increasing tooling costs, efficiency and competitiveness are boosted.

High-performance polymers made by 3D printing are being used by the healthcare industry for prostheses, implants, medical equipment and customized healthcare solutions. The materials' biocompatibility, stabilizability and customizability make them perfect for medical applications, which is driving growth in the market. When compared to conventional production methods, 3D printing high-performance plastics can help accomplish sustainability goals by lowering material waste, energy usage and carbon emissions. The environmental appeal of additive manufacturing is further enhanced by its capacity for material recycling and reuse.

North America is a dominating region in the market due to the growing government approval for the 3D printing of high-performance plastic helps to boost regional market growth over the forecast period. For instance, on April 16, 2024, 3D Systems announced FDA clearance for 3D-printed PEEK cranial implants. When compared to comparable implants made by conventional machining, this method creates patient-specific cranial implants using up to 85% less material, which can result in cost savings for a costly raw material like implantable PEEK. Additionally, the printer's cleanroom-based architecture and streamlined post-processing procedures enable it to produce patient-specific medical equipment at the hospital site more quickly while maintaining cost containment.

Dynamics

Advancements in 3D Printing Technologies

Technological developments in 3D printing have resulted in increased printing efficiency and higher printing rates. Because of this, producers now create high-performance plastic components faster, cutting lead times and raising output levels all around. With the increased resolution and finer detail capabilities of modern 3D printers, it is possible to produce complicated and detailed high-performance plastic components with excellent surface quality and precision. Because of this, applications requiring exact geometries and close tolerances benefit from 3D printing.

Diverse high-performance polymers or combinations of materials can be employed in a single print job due to some advanced 3D printing technologies that enable multi-material printing. The range of functions and applications achieved by 3D printing high-performance plastics is increased by this adaptability. Larger and more intricate pieces are produced using high-performance polymers because of developments in large-format 3D printing. The is especially helpful for sectors that need large-scale components, including construction, automotive and aerospace.

Growing Industry Demand for Lightweight and High-Performance Parts

The aerospace industry continually searches for lightweight materials to increase aircraft performance while reducing fuel consumption. High-performance polymers, such as ULTEM and polyetheretherketone are the preferred choice for heat-resistant and long-lasting components, such as ducting systems and brackets. Lightweighting is crucial if the automotive industry is to satisfy pollution reduction objectives. Carbon fiber-reinforced polymers and acrylonitrile butadiene styrene derivatives are examples of high-performance plastics used in the 3D printing of lightweight components, such as engine parts and structural elements.

High-performance plastics are needed by the healthcare industry for surgical equipment and medical devices. Medical-grade polyamides, PEEK, titanium alloys and other biocompatible materials are 3D printed to manufacture surgical guides, implants, prostheses and dental components that are customized for each patient and have the best mechanical qualities and compatibility. Manufacturers of consumer electronics employ high-performance polymers in 3D printing to produce strong and lightweight components for wearables and drones. Materials including ABS and nylon are recommended because of their better electrical insulating properties, impact resistance and thermal stability.

High Cost of High-Performance Materials

The costly nature of high-performance materials makes 3D printing technology unaffordable for startups or smaller companies. For companies with limited financing, the initial outlay necessary to acquire these supplies, specialized machinery and post-processing instruments may be unaffordable. Cost-sensitivity is common in industries including automotive, aerospace and healthcare, which are big consumers of high-performance resins in 3D printing. The whole cost of manufacturing parts and components can be impacted by the high cost of materials, which could affect these industries' profit margins and competitiveness.

The capacity to 3D print high-performance polymers in huge volumes or for large-scale applications is constrained by expenses. If the economics of 3D printing using high-performance polymers do not justify the expenditure, manufacturers may choose to use conventional production techniques or less expensive materials. The price of 3D printing high-performance polymers might affect customer choices in price-sensitive consumer categories like strong products or consumer electronics. Achieving market acceptability requires striking a balance between affordability and performance.

Segment Analysis

The global 3D printing high performance plastic market is segmented based on type, form, technology, application, end-user and region.

Growing Industrial Adoption of Polyamide (PA) 3D Printing High Performance Plastic

Based on the type, the 3D printing high performance plastic market is segmented into Polyamide (PA), Polyetheramide (PEI), Polyetheretherketone (PEEK), Polyetherketoneketone (PEKK), Reinforced HPPs and others.

Due to its flexibility and adaptability, polyamide is used in a variety of 3D printing applications. The process may offer components with different strengths, toughness and flexibilities according to the particular needs of the final application's components. Due to these characteristics, it is used to create functional prototypes, tooling parts and final products which have to be structurally sound and long-lasting. Because polyamide is resistant to a wide range of substances, including oils, solvents and chemicals, it is used in situations where exposure to abrasive conditions is a problem. The components made with polyamide in 3D printing have greater lifetime and durability because of this chemical resistance.

Growing product launches of Polyamide powder in the market help to boost segment growth over the forecast period. For instance, on October 24, 2023, Evonik launched the world's first PA12 powder for 3D printing based on bio-circular raw material. It is 100% of the substitution of fossil feedstock with bio-circular raw material from waste cooking oil. It offers 74% less CO2 emissions compared to its castor oil-based polyamides.

Geographical Penetration

North America is Dominating the 3D Printing High-Performance Plastic Market

North America has an extremely advanced technological infrastructure. The comprises cutting-edge research centers and state-of-the-art 3D printing facilities. The area is a center for 3D printing technology, polymer chemistry and materials science research and innovation. To create creative, high-performance plastic materials specifically suited for 3D printing applications, leading educational institutions, research facilities and business partners work together to boost market share and competitiveness.

3D printing is one of the additive manufacturing technologies in North America. 3D printing has been extensively utilized by industries like consumer products, automotive and healthcare to facilitate the quick fabrication of high-performance plastic components, as well as customized production and prototyping. North America is home to various significant companies in the globally high-performance plastic 3D printing industry. The businesses significantly contribute to the power of the region with their vast resources, experience and market reach. Additionally, North American companies often lead in innovation and product development, driving market trends and standards.

Competitive Landscape

The major global players in the market include Arkema, DSM, Stratasys, Ltd, 3D Systems, Inc., Evonik Industries AG, Victrex plc., Solvay, Oxford Performance Materials, SABIC and ENVISIONTEC INC.

COVID-19 Impact Analysis

Disruptions to global supply networks were among the pandemic's initial effects. Travel restrictions and reduced production in key industrial locations have an impact on the availability of raw materials required for high-performance polymer 3D printing. The gave rise to supply shortages and price swings, which impacted market stability. The outbreak altered the dynamics of customer demand for high-performance, 3D-printable polymers. Demand declined in other industries, particularly in the early phases of the pandemic, although increased demand was observed in the aerospace and healthcare sectors because of applications such as medical equipment and prototypes.

The demand for 3D-printed, high-performance polymers in the healthcare sector surged dramatically during the epidemic. The was motivated by a demand for components for diagnostic instruments, personal protective equipment and medical equipment. High-performance polymers, such as polyethylene terephthalate glycol, were extensively used in these applications. The outbreak sparked technological advancements in the business and increased the application of 3D printing in several fields. Businesses and academic institutes focused on developing new materials, improving printing methods and addressing supply chain flaws. The improved the qualities and applications of high-performance polymers and led to advances in 3D printing.

Russia-Ukraine War Impact Analysis

Due to commercial delays, border restrictions and logistical difficulties, the war has affected supply chains. Major suppliers of raw materials for high-performance plastics like polyamide and polyethylene consist of Russia and Ukraine. The globally market is experiencing shortages and price volatility as a result of this change. The price of high-performance polymers for 3D printing has fluctuatedbecause of the unpredictable and volatile nature of the conflict. The cost of producing components and materials for 3D printing has increased due to the rising price of raw materials such as polyethylene.

The geopolitical tensions between Ukraine and Russia have rendered supply chain stability a problem. Businesses could reconsider their procurement strategies and diversify their suppliers to lower geopolitical risk, which might alter market dynamics. Supply chain interruptions and increased raw material costs have affected production capacity and output in the market for 3D-printed high-performance plastics. The has therefore affected end-user cost, lead times and product availability, which have short-term negative effects on demand.

By Type

Polyamide (PA)
Polyetheramide (PEI)
Polyetheretherketone (PEEK)
Polyetherketoneketone (PEKK)
Reinforced HPPs
Others

By Form

Filament and Pellet
Powder

By Technology

Fused Deposition Modelling (FDM)
Selective Laser Sintering (SLS)

By Application

Prototyping
Tooling and Functional Part Manufacturing

By End-User

Medical and Healthcare
Aerospace and Defense
Transportation
Oil and Gas
Consumer Goods
Others

By Region

North America
- U.S.
- Canada
- Mexico
Europe
- Germany
- UK
- France
- Italy
- Spain
- Rest of Europe
South America
- Brazil
- Argentina
- Rest of South America
Asia-Pacific
- China
- India
- Japan
- Australia
- Rest of Asia-Pacific
Middle East and Africa

Key Developments

On November 21, 2023, Stratasys launched 3D Printing Materials including Somos WeatherX 100, as well as the development of its Kimya PC-FR and FDM HIPS-validated materials for the F900 for Manufacturing Grade Prototyping in the market. More production applications and an increased expansion of material alternatives accessible in the market are made possible by the advent of these new materials.
On May 04, 2021, Evonik launched implant-grade PEEK filament for medical applications in 3D printing. The PEEK filament, which is sold under the brand name VESTAKEEP i4 3DF, is an implant-grade material that is derived from Evonik's very viscous, high-performance VESTAKEEP i4 G polymer.
On November 16, 2022, Hexagon and Stratasys launched 3D-printed PEKK's light-weighting potential for aerospace engineers with simulation. Customers of Stratasys get unique insights from these thoroughly verified simulations, enabling them to launch more sustainable aircraft and spacecraft and lighter components more quickly.

Why Purchase the Report?

To visualize the global 3D printing high performance plastic market segmentation based on type, form, technology, application, end-user and region, as well as understand key commercial assets and players.
Identify commercial opportunities by analyzing trends and co-development.
Excel data sheet with numerous data points of 3D printing high performance plastic market-level with all segments.
PDF report consists of a comprehensive analysis after exhaustive qualitative interviews and an in-depth study.
Product mapping available as excel consisting of key products of all the major players.

The global 3D printing high performance plastic market report would provide approximately 78 tables, 75 figures and 204 Pages.

Target Audience 2024

Manufacturers/ Buyers
Industry Investors/Investment Bankers
Research Professionals
Emerging Companies

1.Methodology and Scope

1.1.Research Methodology
1.2.Research Objective and Scope of the Report

2.Definition and Overview

3.Executive Summary

3.1.Snippet by Type
3.2.Snippet by Form
3.3.Snippet by Technology
3.4.Snippet by Application
3.5.Snippet by End-User
3.6.Snippet by Region

4.Dynamics

4.1.Impacting Factors
- 4.1.1.Drivers
  - 4.1.1.1.Advancements in 3D Printing Technologies
  - 4.1.1.2.Growing Industry Demand for Lightweight and High-Performance Parts
- 4.1.2.Restraints
  - 4.1.2.1.High Cost of High-Performance Materials
- 4.1.3.Opportunity
- 4.1.4.Impact Analysis

5.Industry Analysis

5.1.Porter's Five Force Analysis
5.2.Supply Chain Analysis
5.3.Pricing Analysis
5.4.Regulatory Analysis
5.5.Russia-Ukraine War Impact Analysis
5.6.DMI Opinion

6.COVID-19 Analysis

6.1.Analysis of COVID-19
- 6.1.1.Scenario Before COVID-19
- 6.1.2.Scenario During COVID-19
- 6.1.3.Scenario Post COVID-19
6.2.Pricing Dynamics Amid COVID-19
6.3.Demand-Supply Spectrum
6.4.Government Initiatives Related to the Market During Pandemic
6.5.Manufacturers Strategic Initiatives
6.6.Conclusion

7.By Type

7.1.Introduction
- 7.1.1.Market Size Analysis and Y-o-Y Growth Analysis (%), By Type
- 7.1.2.Market Attractiveness Index, By Type
7.2.Polyamide (PA)*
- 7.2.1.Introduction
- 7.2.2.Market Size Analysis and Y-o-Y Growth Analysis (%)
7.3.Polyetheramide (PEI)
7.4.Polyetheretherketone (PEEK)
7.5.Polyetherketoneketone (PEKK)
7.6.Reinforced HPPs
7.7.Others

8.By Form

8.1.Introduction
- 8.1.1.Market Size Analysis and Y-o-Y Growth Analysis (%), By Form
- 8.1.2.Market Attractiveness Index, By Form
8.2.Filament and Pellet*
- 8.2.1.Introduction
- 8.2.2.Market Size Analysis and Y-o-Y Growth Analysis (%)
8.3.Powder

9.By Technology

9.1.Introduction
- 9.1.1.Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
- 9.1.2.Market Attractiveness Index, By Technology
9.2.Fused Deposition Modelling (FDM)*
- 9.2.1.Introduction
- 9.2.2.Market Size Analysis and Y-o-Y Growth Analysis (%)
9.3.Selective Laser Sintering (SLS)

10.By Application

10.1.Introduction
- 10.1.1.Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
- 10.1.2.Market Attractiveness Index, By Application
10.2.Prototyping*
- 10.2.1.Introduction
- 10.2.2.Market Size Analysis and Y-o-Y Growth Analysis (%)
10.3.Tooling and Functional Part Manufacturing

11.By End-User

11.1.Introduction
- 11.1.1.Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
- 11.1.2.Market Attractiveness Index, By End-User
11.2.Medical and Healthcare*
- 11.2.1.Introduction
- 11.2.2.Market Size Analysis and Y-o-Y Growth Analysis (%)
11.3.Aerospace and Defense
11.4.Transportation
11.5.Oil and Gas
11.6.Consumer Goods
11.7.Others

12.By Region

12.1.Introduction
- 12.1.1.Market Size Analysis and Y-o-Y Growth Analysis (%), By Region
- 12.1.2.Market Attractiveness Index, By Region
12.2.North America
- 12.2.1.Introduction
- 12.2.2.Key Region-Specific Dynamics
- 12.2.3.Market Size Analysis and Y-o-Y Growth Analysis (%), By Type
- 12.2.4.Market Size Analysis and Y-o-Y Growth Analysis (%), By Form
- 12.2.5.Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
- 12.2.6.Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
- 12.2.7.Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
- 12.2.8.Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
  - 12.2.8.1.U.S.
  - 12.2.8.2.Canada
  - 12.2.8.3.Mexico
12.3.Europe
- 12.3.1.Introduction
- 12.3.2.Key Region-Specific Dynamics
- 12.3.3.Market Size Analysis and Y-o-Y Growth Analysis (%), By Type
- 12.3.4.Market Size Analysis and Y-o-Y Growth Analysis (%), By Form
- 12.3.5.Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
- 12.3.6.Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
- 12.3.7.Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
- 12.3.8.Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
  - 12.3.8.1.Germany
  - 12.3.8.2.UK
  - 12.3.8.3.France
  - 12.3.8.4.Italy
  - 12.3.8.5.Spain
  - 12.3.8.6.Rest of Europe
12.4.South America
- 12.4.1.Introduction
- 12.4.2.Key Region-Specific Dynamics
- 12.4.3.Market Size Analysis and Y-o-Y Growth Analysis (%), By Type
- 12.4.4.Market Size Analysis and Y-o-Y Growth Analysis (%), By Form
- 12.4.5.Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
- 12.4.6.Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
- 12.4.7.Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
- 12.4.8.Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
  - 12.4.8.1.Brazil
  - 12.4.8.2.Argentina
  - 12.4.8.3.Rest of South America
12.5.Asia-Pacific
- 12.5.1.Introduction
- 12.5.2.Key Region-Specific Dynamics
- 12.5.3.Market Size Analysis and Y-o-Y Growth Analysis (%), By Type
- 12.5.4.Market Size Analysis and Y-o-Y Growth Analysis (%), By Form
- 12.5.5.Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
- 12.5.6.Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
- 12.5.7.Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
- 12.5.8.Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
  - 12.5.8.1.China
  - 12.5.8.2.India
  - 12.5.8.3.Japan
  - 12.5.8.4.Australia
  - 12.5.8.5.Rest of Asia-Pacific
12.6.Middle East and Africa
- 12.6.1.Introduction
- 12.6.2.Key Region-Specific Dynamics
- 12.6.3.Market Size Analysis and Y-o-Y Growth Analysis (%), By Type
- 12.6.4.Market Size Analysis and Y-o-Y Growth Analysis (%), By Form
- 12.6.5.Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
- 12.6.6.Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
- 12.6.7.Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User

13.Competitive Landscape

13.1.Competitive Scenario
13.2.Market Positioning/Share Analysis
13.3.Mergers and Acquisitions Analysis

14.Company Profiles

14.1.Arkema*
- 14.1.1.Company Overview
- 14.1.2.Product Portfolio and Description
- 14.1.3.Financial Overview
- 14.1.4.Key Developments
14.2.DSM
14.3.Stratasys, Ltd
14.4.3D Systems, Inc.
14.5.Evonik Industries AG
14.6.Victrex plc.
14.7.Solvay
14.8.Oxford Performance Materials
14.9.SABIC
14.10.ENVISIONTEC INC.

LIST NOT EXHAUSTIVE