![]() |
市场调查报告书
商品编码
1715256
2025-2035年全球航太3D列印市场Global Aerospace 3D Printing Market 2025-2035 |
行业概览
2024 年航太3D 列印市场规模为 36 亿美元,预计 2035 年将达到 202 亿美元,预测期内(2025-2035 年)的复合年增长率为 17.0%。 3D列印在航太工业中用于製造火箭和飞机零件。这项技术可以製造出更轻、更耐用、更便宜的零件。它减少了组装所需的零件数量,使车辆更轻、更省油。 3D列印在航太产业越来越受欢迎。它有助于製造复杂而轻质的零件,提高燃油效率并降低製造成本。此外,它还可以製造使用传统方法难以或不可能製造的零件。越来越多的航太公司正在使用 3D 列印来简化生产并创造新的设计。美国国家航空暨太空总署和其他政府组织等太空探索公司专注于投资太空探索计画的 3D 技术。例如,2021 年 12 月,Fleet Space Technologies 推出了一颗完全由 3D 列印的卫星,作为其新星座 Alpha 的一部分。它将提供亚秒级的延迟,开启一种经济有效的方式来实现全球前所未有的连接。 《国际航空航太杂誌》(IJAAA)预计 3D 列印将进一步扩展,强调其在建造天体栖息地以及现场製造太空船和卫星零件方面的潜力。
Global Aerospace 3D Printing Market Size, Share & Trends Analysis by Offerings (Printers, Materials, Software and Services), by Printer Technology (Direct Metal Laser Sintering (DMLS), Fused Deposition Modeling (FDM), Continuous Liquid Interface Production (CLIP), Stereolithography (SLA), Selective Laser Sintering (SLS), Others), by Platform (Aircraft, UAVs, Spacecraft), by End-User (OEM, MRO), and Forecast Period (2025-2035)
Industry Overview
Aerospace 3D printing market size was $3.6 billion in 2024, and is projected to reach $20.2 billion in 2035, growing at a CAGR of 17.0% during the forecast period (2025-2035). 3D printing is used in the aerospace industry to build rockets and plane parts. This technology creates lighter, more durable, and cheaper components. It reduces the number of parts needed for assembly, making the vehicles lighter and more fuel-efficient. 3D printing is getting more popular in the aerospace industry. It helps make complex and lightweight components, improving fuel efficiency and cutting manufacturing costs. Also, it allows making parts that are hard or impossible to create using traditional methods. More aerospace companies are using 3D printing to simplify their production and create new designs. Space exploration companies such as NASA and other government organizations are focused on investing in 3D technology for space exploration programs. For instance, in December 2021, Fleet Space Technologies unveiled an entirely 3D-printed satellite as part of their new constellation, Alpha. It will provide a sub-second latency, unlocking a cost-effective means to achieve unprecedented connectivity around the world. The International Journal of Aviation, Aeronautics, and Aerospace (IJAAA) anticipates further expansion of 3D printing, highlighting its potential for constructing celestial habitats and for the in-situ manufacturing of spacecraft and satellite components.
Market Dynamics
Increasing Adoption of Lightweight Materials and Cost-Efficiency
The need for lightweight parts in the aerospace industry is a major factor contributing to the growth of 3D printing solutions. The high-performance sectors such as automotive and aerospace, producing lightweight metal components act as a Holy Grail. As a result, manufacturers are constantly looking for new approaches to design and producing lighter metal components with improved part performance. For instance, in November 2023, Markforged Releases Vega, an Ultra High-Performance Material Designed for 3D Printing Aerospace Components on the FX20. It not only offers exceptional strength but also is expected to reduce weight, cost efficiency, and time savings. 3D printing technology creates parts layer by layer, using material only where needed, requiring less material for production and thus bringing down the manufacturing cost. 3D printing makes complexity an advantage, opening the door to the affordable fabrication of intricate, lightweight metal parts. In addition to being cost-effective for creating lighter metal components, 3D printing is faster than other types of manufacturing processes. Additive manufacturing, a tool-less technology, directly produces parts from digital files, greatly speeding the manufacturing process.
Complex and Customized Component Production
3D printing enables the creation of highly complex and customized components that are difficult to manufacture. 3D printing technology simplifies parts by consolidating multiple components into a single, streamlined unit, reducing complexity, assembly time, and supply chain intricacy. The faster production capabilities of 3D printing, compared to traditional manufacturing methods, enable rapid prototyping and iteration of designs, enhancing the speed and efficiency of aircraft production. This is beneficial for producing low-volume, high-value aerospace components such as turbine blades, fuel nozzles, and satellite brackets. The aerospace industry has witnessed significant advancements in high-end polymers for 3D printing applications. These materials are designed to meet the stringent requirements of aerospace components, offering superior mechanical properties, chemical resistance, and high-temperature stability. Some of the most commonly used materials in aerospace 3D printing include high-performance polymers, flame-retardant polymers, thermoplastic composites, polymer matrix composites, and many more. The ability to produce parts on-demand also reduces reliance on traditional supply chains, making it easier to manufacture spare parts in remote locations, such as space stations or military bases.
Market Segmentation
3D Printing Aerospace
3D printing, or additive manufacturing, is a production technique that creates a three-dimensional object from a computer-aided design (CAD) file. The term covers several different processes, all involving one or more materials - most often plastic, metal, wax, or composite - being deposited layer by layer to build a shape. 3D printing technology helps the aerospace industry in various ways such as streamlining and simplifying the design workflow, producing lighter, stronger parts, consolidating multiple parts into one single part, minimizing waste of extremely expensive raw materials, accelerating time to market, improving cost and resource efficiency, and optimizing inventory and logistics. Aircraft manufacturers and suppliers are among the largest users of 3D printing. All the leading commercial aircraft makers (Airbus, Boeing, Bombardier, and Embraer) and engine suppliers (GE Aviation, Pratt & Whitney, Rolls-Royce, and Safran) have adopted 3D printing in their processes.
The global aerospace 3D Printing market is further segmented based on geography including North America (the US, and Canada), Europe (UK, Italy, Spain, Germany, France, and the Rest of Europe), Asia-Pacific (India, China, Japan, South Korea, and Rest of Asia), and the Rest of the World (the Middle East & Africa, and Latin America. Among these, North America is anticipated to hold the largest share of the market across the globe, owing to industry trends such as Industry 4.0 and the increasing collaboration in various companies to enhance the printing ability of complex and lightweight materials.
North America Region Dominates the Market
North America holds the largest market share in aerospace 3D printing. The growing trend towards digitalization and industry 4.0 initiatives accelerates the adoption of additive manufacturing in the aerospace sector. This digital approach enhances collaboration between designers, engineers, and manufacturers, accelerating product development cycles and enabling faster time-to-market for new aircraft and spacecraft. North American aerospace companies embrace digital transformation, and additive manufacturing as an integral part of their strategy for achieving greater efficiency and competitiveness in the global market.
The major companies serving the aerospace 3D printing market include Stratasys, 3D Systems Corporation, EOS GmbH, Materialise N.V., Nikon SLM Solutions AG, and others. The market players are considerably contributing to the market growth by the adoption of various strategies including mergers and acquisitions, partnerships, collaborations, funding, and new product launches, to stay competitive in the market.
Recent Development