1 エグゼクティブ・サマリー
2 序文
2.1 概要
2.2 ステークホルダー
2.3 調査範囲
2.4 調査方法
2.4.1 データマイニング
2.4.2 データ分析
2.4.3 データの検証
2.4.4 リサーチアプローチ
2.5 リサーチソース
2.5.1 一次調査ソース
2.5.2 セカンダリーリサーチソース
2.5.3 前提条件
3 市場動向分析
3.1 はじめに
3.2 推進要因
3.3 抑制要因
3.4 機会
3.5 脅威
3.6 アプリケーション分析
3.7 新興市場
3.8 Covid-19の影響
4 ポーターズファイブフォース分析
4.1 供給者の交渉力
4.2 買い手の交渉力
4.3 代替品の脅威
4.4 新規参入の脅威
4.5 競争上のライバル関係
5 航空宇宙用複合材料の世界市場：繊維種類別
5.1 はじめに
5.2 ガラス繊維
5.3 炭素繊維
5.4 アラミド繊維
5.5 その他の繊維タイプ
6 航空宇宙用複合材料の世界市場：マトリックス種類別
6.1 はじめに
6.2 ポリマーマトリックス
6.3 金属マトリックス
6.4 セラミックマトリックス
7 航空宇宙用複合材料の世界市場：航空機種類別
7.1 はじめに
7.2 民間航空機
7.3 ビジネス・一般航空機
7.4 民間ヘリコプター
7.5 軍用機
7.6 ジェットエンジン
7.7 その他の航空機タイプ
8 航空宇宙用複合材料の世界市場、製造プロセス別
8.1 導入
8.2 AFP（自動ファイバー・プレースメント）／ATL（自動テープ・レイアップ）
8.3 レイアップ
8.4 樹脂トランスファー成形
8.5 フィラメントワインディング
9 航空宇宙用複合材料の世界市場、用途別
9.1 はじめに
9.2 民間航空
9.3 軍用航空
9.4 宇宙
9.5 その他の用途
10 航空宇宙用複合材料の世界市場、地域別
10.1 はじめに
10.2 北アメリカ
10.2.1 アメリカ
10.2.2 カナダ
10.2.3 メキシコ
10.3 ヨーロッパ
10.3.1 ドイツ
10.3.2 イギリス
10.3.3 イタリア
10.3.4 フランス
10.3.5 スペイン
10.3.6 その他のヨーロッパ
10.4 アジア太平洋
10.4.1 日本
10.4.2 中国
10.4.3 インド
10.4.4 オーストラリア
10.4.5 ニュージーランド
10.4.6 韓国
10.4.7 その他のアジア太平洋地域
10.5 南アメリカ
10.5.1 アルゼンチン
10.5.2 ブラジル
10.5.3 チリ
10.5.4 その他の南アメリカ地域
10.6 中東/アフリカ
10.6.1 サウジアラビア
10.6.2 アラブ首長国連邦
10.6.3 カタール
10.6.4 南アフリカ
10.6.5 その他の中東/アフリカ地域
11 主要開発
11.1 契約、パートナーシップ、提携、合弁事業
11.2 買収と合併
11.3 新製品上市
11.4 事業拡大
11.5 その他の主要戦略
12 企業プロフィール
12.1 Safran SA
12.2 Toray Industries, Inc.
12.3 Collins Aerospace
12.4 Mitsubishi Chemical Corporation
12.5 Honeywell International Inc.
12.6 DuPont
12.7 AIM Aerospace, Inc.
12.8 Hexcel Corporation
12.9 Teijin Limited
12.10 Evonik Industries AG
12.11 Solvay Group
12.12 General Electric
12.13 Huntsman Corporation
12.14 Bally Ribbon Mills
12.15 Royal Ten Cate N.V
12.16 Materion Corporation
表一覧
表1 航空宇宙用複合材料の世界市場展望、地域別（2022-2030年） （$MN）
表2 航空宇宙用複合材料の世界市場展望、繊維種類別 （2022-2030） （$MN）
表3 航空宇宙用複合材料の世界市場展望、ガラス繊維別 （2022-2030） （$MN）
表4 航空宇宙用複合材料の世界市場展望、炭素繊維別 （2022-2030） （$MN）
表5 航空宇宙用複合材料の世界市場展望、アラミド繊維別 （2022-2030） （$MN）
表6 航空宇宙用複合材料の世界市場展望、その他の繊維種類別 （2022-2030） （$MN）
表7 航空宇宙用複合材料の世界市場展望、マトリックス種類別 （2022-2030） （$MN）
表8 航空宇宙用複合材料の世界市場展望、ポリマーマトリクス別 （2022-2030） （$MN）
表9 航空宇宙用複合材料の世界市場展望、金属マトリックス別 （2022-2030） （$MN）
表10 航空宇宙用複合材料の世界市場展望、セラミックマトリックス別 （2022-2030） （$MN）
表11 航空宇宙用複合材料の世界市場展望、航空機種類別 （2022-2030） （$MN）
表12 航空宇宙用複合材料の世界市場展望、民間航空機別 （2022-2030） （$MN）
表13 航空宇宙用複合材の世界市場展望、ビジネス・一般航空機別 （2022-2030） （$MN）
表14 航空宇宙用複合材料の世界市場展望、民間ヘリコプター別 （2022-2030） （$MN）
表15 航空宇宙用複合材の世界市場展望、軍用機別 （2022-2030） （$MN）
表16 航空宇宙用複合材料の世界市場展望、ジェットエンジン別 （2022-2030） （$MN）
表17 航空宇宙用複合材料の世界市場展望、その他の航空機種類別 （2022-2030） （$MN）
表18 航空宇宙用複合材料の世界市場展望、製造プロセス別 （2022-2030） （$MN）
表19 航空宇宙用複合材の世界市場展望、AFP（自動繊維配置）/ATL（自動テープレイアップ）別 （2022-2030） （$MN）
表20 航空宇宙用複合材料の世界市場展望、レイアップ別 （2022-2030） （$MN）
表21 航空宇宙用複合材料の世界市場展望、樹脂トランスファー成形別 （2022-2030） （$MN）
表22 航空宇宙用複合材料の世界市場展望、フィラメントワインディング別 （2022-2030） （$MN）
表23 航空宇宙用複合材料の世界市場展望、用途別 （2022-2030） （$MN）
表24 航空宇宙用複合材料の世界市場展望、民間航空機別 （2022-2030） （$MN）
表25 航空宇宙用複合材料の世界市場展望、軍用航空別 （2022-2030） （$MN）
表26 航空宇宙用複合材料の世界市場展望、宇宙別 （2022-2030） （$MN）
表27 航空宇宙用複合材料の世界市場展望、その他の用途別 （2022-2030） （$MN）
注）北アメリカ、ヨーロッパ、APAC、南アメリカ、中東/アフリカ地域の表も上記と同様に表記しています。

According to Stratistics MRC, the Global Aerospace Composites Market is accounted for $46.82 billion in 2024 and is expected to reach $87.57 billion by 2030 growing at a CAGR of 11.0% during the forecast period. Aerospace composites are cutting-edge materials designed to satisfy the aerospace industry's strict specifications. Their main constituents consist of a matrix, typically made of polymer, reinforced with fibers like glass, carbon, or aramid. These composite materials are perfect for use in aircraft and spacecraft applications because of their outstanding strength-to-weight ratio, high stiffness, and superior resistance to corrosion and fatigue. Furthermore, their application results in aircraft that are lighter, more fuel-efficient, perform better, and last longer.

According to the American Institute of Aeronautics and Astronautics (AIAA), the use of aerospace composites has become a critical component in modern aircraft design, offering enhanced performance and fuel efficiency while significantly reducing the weight of the aircraft.

Market Dynamics:

Driver:
Increased need for lightweight materials
Manufacturers of aircraft are always looking for ways to lighten their products to improve performance and fuel economy. When compared to conventional metals like aluminum, aerospace composites, like carbon fiber-reinforced polymers, offer better strength-to-weight ratios. This weight loss translates into reduced fuel consumption and increased operational effectiveness. Moreover, the use of lightweight composites becomes more important as the aviation industry concentrates on lowering operating costs and increasing aircraft range.

Restraint:
High starting prices
High material and manufacturing costs are associated with the creation and processing of aerospace composites. When compared to more conventional materials like steel or aluminum, the cost of advanced manufacturing machinery, specialized processes, and raw composite materials can be very high. Smaller manufacturers or businesses aiming to use composites for applications where cost is a concern may find it prohibitive due to this substantial upfront cost. Additionally, the total cost is also influenced by the difficulty and expense of incorporating these materials into the current production lines.

Opportunity:
Developments in composite technologies
Innovative and reasonably priced solutions are being developed as a result of continuous research and development in composite materials. Aerospace composites can be made more affordable and perform better owing to innovations like nano composites, bio-based resins, and better manufacturing processes like 3D printing and automated fiber placement. Moreover, these developments have the potential to spur the creation of new applications and raise the sustainability and efficiency of aerospace components.

Threat:
Market volatility and economic fluctuations
The aerospace sector is extremely susceptible to shifts in the market and economic cycles. Budgets for defense, investment in new aerospace projects, and demand for air travel can all be impacted by economic downturns, recessions, or geopolitical unrest. These variations may result in a decline in the market for aerospace composites, which would impact the earnings and expansion opportunities of producers. Furthermore, alterations in government funding for aerospace and defense initiatives may impact the composites market as a whole.

Covid-19 Impact:
Due to production halts, supply chain disruptions, and project delays in the aviation and space industries, the COVID-19 pandemic had a substantial effect on the aerospace composites market. Due to travel restrictions and a decline in demand for air travel, the aerospace industry experienced a temporary slowdown in the adoption of composite materials and aerospace projects, as well as a reduction in orders and financial strain. Moreover, on the other hand, the pandemic also sharpened attention to innovation and digitalization, generating a surge in curiosity about more sustainable and effective manufacturing techniques.

The Carbon Fiber segment is expected to be the largest during the forecast period
The carbon fiber segment has the largest market share in the aerospace composites market. Because of their remarkable stiffness, strength-to-weight ratio, and thermal stability, carbon fiber composites are highly preferred in aerospace applications. These characteristics are essential for improving performance and fuel economy while lowering the total weight of the aircraft. Additionally, the market dominance of carbon fiber composites can be attributed to their widespread application in structural components such as wings, fuselages, and interior parts. They are essential to modern aerospace engineering because of their superior mechanical qualities and resilience to harsh environments.

The Ceramic Matrix segment is expected to have the highest CAGR during the forecast period
The Ceramic Matrix Composites segment of the Aerospace Composites Market is growing at the highest CAGR. Because of their remarkable mechanical qualities, high temperature resistance, and lightweight design, ceramic matrix composites are becoming more and more valuable in aerospace applications. These composites are perfect for parts like turbine engines and thermal protection systems that are subjected to severe temperatures and harsh conditions. Furthermore, their quick adoption and expansion in the aerospace industry are being fueled by their capacity to preserve structural integrity and performance under extreme stress.

Region with largest share:
In the market for aerospace composites, North America has the largest share. The strong aerospace sector in the area, which includes well-known aircraft manufacturers like Lockheed Martin and Boeing, as well as its sophisticated R&D capabilities, is the main drivers of this dominance. The adoption of composite materials has accelerated due to the region's focus on lightweight and fuel-efficient aircraft. Moreover, North America's dominant position in the aerospace composites market is further cemented by the growing demand for both military and commercial aircraft, as well as the existence of a well-established supply chain.

Region with highest CAGR:
The aerospace composites market is growing at the highest CAGR in the Asia-Pacific region. The aerospace industry is growing quickly in nations like China, India, and Japan as a result of rising defense spending, rising air travel demand, and the rise of regional aircraft manufacturers. The high growth is largely due to the region's emphasis on producing aircraft domestically and on using cutting-edge composite materials to increase fuel economy and lower emissions. Furthermore, the market's growth is also being accelerated by large R&D expenditures and the expanding number of international aerospace companies operating in the area.

Key players in the market
Some of the key players in Aerospace Composites market include Safran SA, Toray Industries, Inc., Collins Aerospace, Mitsubishi Chemical Corporation, Honeywell International Inc., DuPont, AIM Aerospace, Inc., Hexcel Corporation, Teijin Limited, Evonik Industries AG, Solvay Group, General Electric, Huntsman Corporation, Bally Ribbon Mills, Royal Ten Cate N.V and Materion Corporation.

Key Developments:
In June 2024, DuPont announced it has signed an agreement to acquire Donatelle Plastics Incorporated, a leading medical device contract manufacturer specializing in the design, development and manufacture of medical components and devices. The transaction is expected to close in the third quarter 2024, subject to satisfaction of customary closing conditions and receipt of regulatory approvals.

In July 2024, Honeywell has entered into a long-term agreement with Air India Limited, India’s premier global airline and a part of the Tata Group, to provide Auxiliary Power Unit (APU) aftermarket support for both the existing and new fleets.

In February 2024, Safran Helicopter Engines has signed a support-by-the-hour contract renewal with ADAC Heliservice for the engines powering ADAC Luftrettung and ANWB Medical Air Assistance H145 helicopter fleets. This SBH® contract covers in-service support and MRO (maintenance, repair and overhaul) for around 50 Arriel 2E engines.

Fiber Types Covered:
• Glass Fiber
• Carbon Fiber
• Aramid Fiber
• Other Fiber Types

Matrix Types Covered:
• Polymer Matrix
• Metal Matrix
• Ceramic Matrix

Aircraft Types Covered:
• Commercial Aircraft
• Business & General Aviation
• Civil Helicopters
• Military Aircrafts
• Jet Engines
• Other Aircraft Types

Manufacturing Processes Covered:
• AFP (Automated Fiber Placement)/ ATL (Automated Tape Layup)
• Lay-up
• Resin Transfer Molding
• Filament Winding

Applications Covered:
• Commercial Aviation
• Military Aviation
• Space
• Other Applications

Regions Covered:
• North America
US
Canada
Mexico
• Europe
Germany
UK
Italy
France
Spain
Rest of Europe
• Asia Pacific
Japan
China
India
Australia
New Zealand
South Korea
Rest of Asia Pacific
• South America
Argentina
Brazil
Chile
Rest of South America
• Middle East & Africa
Saudi Arabia
UAE
Qatar
South Africa
Rest of Middle East & Africa

What our report offers:
- Market share assessments for the regional and country-level segments
- Strategic recommendations for the new entrants
- Covers Market data for the years 2022, 2023, 2024, 2026, and 2030
- Market Trends (Drivers, Constraints, Opportunities, Threats, Challenges, Investment Opportunities, and recommendations)
- Strategic recommendations in key business segments based on the market estimations
- Competitive landscaping mapping the key common trends
- Company profiling with detailed strategies, financials, and recent developments
- Supply chain trends mapping the latest technological advancements

1 Executive Summary
2 Preface
2.1 Abstract
2.2 Stake Holders
2.3 Research Scope
2.4 Research Methodology
2.4.1 Data Mining
2.4.2 Data Analysis
2.4.3 Data Validation
2.4.4 Research Approach
2.5 Research Sources
2.5.1 Primary Research Sources
2.5.2 Secondary Research Sources
2.5.3 Assumptions
3 Market Trend Analysis
3.1 Introduction
3.2 Drivers
3.3 Restraints
3.4 Opportunities
3.5 Threats
3.6 Application Analysis
3.7 Emerging Markets
3.8 Impact of Covid-19
4 Porters Five Force Analysis
4.1 Bargaining power of suppliers
4.2 Bargaining power of buyers
4.3 Threat of substitutes
4.4 Threat of new entrants
4.5 Competitive rivalry
5 Global Aerospace Composites Market, By Fiber Type
5.1 Introduction
5.2 Glass Fiber
5.3 Carbon Fiber
5.4 Aramid Fiber
5.5 Other Fiber Types
6 Global Aerospace Composites Market, By Matrix Type
6.1 Introduction
6.2 Polymer Matrix
6.3 Metal Matrix
6.4 Ceramic Matrix
7 Global Aerospace Composites Market, By Aircraft Type
7.1 Introduction
7.2 Commercial Aircraft
7.3 Business & General Aviation
7.4 Civil Helicopters
7.5 Military Aircrafts
7.6 Jet Engines
7.7 Other Aircraft Types
8 Global Aerospace Composites Market, By Manufacturing Process
8.1 Introduction
8.2 AFP (Automated Fiber Placement)/ ATL (Automated Tape Layup)
8.3 Lay-up
8.4 Resin Transfer Molding
8.5 Filament Winding
9 Global Aerospace Composites Market, By Application
9.1 Introduction
9.2 Commercial Aviation
9.3 Military Aviation
9.4 Space
9.5 Other Applications
10 Global Aerospace Composites Market, By Geography
10.1 Introduction
10.2 North America
10.2.1 US
10.2.2 Canada
10.2.3 Mexico
10.3 Europe
10.3.1 Germany
10.3.2 UK
10.3.3 Italy
10.3.4 France
10.3.5 Spain
10.3.6 Rest of Europe
10.4 Asia Pacific
10.4.1 Japan
10.4.2 China
10.4.3 India
10.4.4 Australia
10.4.5 New Zealand
10.4.6 South Korea
10.4.7 Rest of Asia Pacific
10.5 South America
10.5.1 Argentina
10.5.2 Brazil
10.5.3 Chile
10.5.4 Rest of South America
10.6 Middle East & Africa
10.6.1 Saudi Arabia
10.6.2 UAE
10.6.3 Qatar
10.6.4 South Africa
10.6.5 Rest of Middle East & Africa
11 Key Developments
11.1 Agreements, Partnerships, Collaborations and Joint Ventures
11.2 Acquisitions & Mergers
11.3 New Product Launch
11.4 Expansions
11.5 Other Key Strategies
12 Company Profiling
12.1 Safran SA
12.2 Toray Industries, Inc.
12.3 Collins Aerospace
12.4 Mitsubishi Chemical Corporation
12.5 Honeywell International Inc.
12.6 DuPont
12.7 AIM Aerospace, Inc.
12.8 Hexcel Corporation
12.9 Teijin Limited
12.10 Evonik Industries AG
12.11 Solvay Group
12.12 General Electric
12.13 Huntsman Corporation
12.14 Bally Ribbon Mills
12.15 Royal Ten Cate N.V
12.16 Materion Corporation
List of Tables
Table 1 Global Aerospace Composites Market Outlook, By Region (2022-2030) ($MN)
Table 2 Global Aerospace Composites Market Outlook, By Fiber Type (2022-2030) ($MN)
Table 3 Global Aerospace Composites Market Outlook, By Glass Fiber (2022-2030) ($MN)
Table 4 Global Aerospace Composites Market Outlook, By Carbon Fiber (2022-2030) ($MN)
Table 5 Global Aerospace Composites Market Outlook, By Aramid Fiber (2022-2030) ($MN)
Table 6 Global Aerospace Composites Market Outlook, By Other Fiber Types (2022-2030) ($MN)
Table 7 Global Aerospace Composites Market Outlook, By Matrix Type (2022-2030) ($MN)
Table 8 Global Aerospace Composites Market Outlook, By Polymer Matrix (2022-2030) ($MN)
Table 9 Global Aerospace Composites Market Outlook, By Metal Matrix (2022-2030) ($MN)
Table 10 Global Aerospace Composites Market Outlook, By Ceramic Matrix (2022-2030) ($MN)
Table 11 Global Aerospace Composites Market Outlook, By Aircraft Type (2022-2030) ($MN)
Table 12 Global Aerospace Composites Market Outlook, By Commercial Aircraft (2022-2030) ($MN)
Table 13 Global Aerospace Composites Market Outlook, By Business & General Aviation (2022-2030) ($MN)
Table 14 Global Aerospace Composites Market Outlook, By Civil Helicopters (2022-2030) ($MN)
Table 15 Global Aerospace Composites Market Outlook, By Military Aircrafts (2022-2030) ($MN)
Table 16 Global Aerospace Composites Market Outlook, By Jet Engines (2022-2030) ($MN)
Table 17 Global Aerospace Composites Market Outlook, By Other Aircraft Types (2022-2030) ($MN)
Table 18 Global Aerospace Composites Market Outlook, By Manufacturing Process (2022-2030) ($MN)
Table 19 Global Aerospace Composites Market Outlook, By AFP (Automated Fiber Placement)/ ATL (Automated Tape Layup) (2022-2030) ($MN)
Table 20 Global Aerospace Composites Market Outlook, By Lay-up (2022-2030) ($MN)
Table 21 Global Aerospace Composites Market Outlook, By Resin Transfer Molding (2022-2030) ($MN)
Table 22 Global Aerospace Composites Market Outlook, By Filament Winding (2022-2030) ($MN)
Table 23 Global Aerospace Composites Market Outlook, By Application (2022-2030) ($MN)
Table 24 Global Aerospace Composites Market Outlook, By Commercial Aviation (2022-2030) ($MN)
Table 25 Global Aerospace Composites Market Outlook, By Military Aviation (2022-2030) ($MN)
Table 26 Global Aerospace Composites Market Outlook, By Space (2022-2030) ($MN)
Table 27 Global Aerospace Composites Market Outlook, By Other Applications (2022-2030) ($MN)
Note: Tables for North America, Europe, APAC, South America, and Middle East & Africa Regions are also represented in the same manner as above.