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1894041

絕氣推進系統市場報告:趨勢、預測與競爭分析(至2031年)

Air Independent Propulsion Systems Market Report: Trends, Forecast and Competitive Analysis to 2031
出版日期: | 出版商: Lucintel | 英文 150 Pages | 商品交期: 3個工作天內

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由於斯特林引擎、MESMA引擎和燃料電池市場的發展機會,全球絕氣推進(AIP)系統市場預計將保持強勁成長。預計到2031年,全球絕氣推進系統市場規模將達到1,710億美元,2025年至2031年間的年複合成長率(CAGR)為4.8%。推動該市場成長的關鍵因素包括:對安全可靠的水下軍事行動日益成長的需求、不依賴空氣推進技術的進步、傳統潛艇維修該技術的可行性,以及水下科學研究和探勘活動的不斷增加。

  • Lucintel 預測,在安裝類型類別中,由於造船和潛艇建造對技術進步的需求不斷成長,Line-Fit將在整個預測期內保持最大的細分市場。
  • 預計亞太地區在預測期內將經歷最高的成長率,因為各國購買隱形艦艇、攻擊型潛艦、巡邏艇、感測器、雷達、飛彈和自主系統,以增強其水面和水下艦隊的能力。

絕氣推進系統市場的新趨勢

在技術發展和策略重點轉變的驅動下,絕氣推進系統市場快速演變。關鍵的新興趨勢重塑絕氣推進系統市場的能力和範圍,並提升其在海軍作戰中的效能。以下重點介紹五大趨勢:

  • 混合式AIP系統:近年來,結合燃料電池和先進電池技術的混合絕氣推進系統應用日益廣泛。這些系統的高效設計不僅延長了水下續航時間,還提高了動力輸出效率。這種混合式設計能夠延長任務持續時間,並增強作戰柔軟性。
  • 燃料電池技術的進步:高性能燃料電池能夠實現更有效率、更可靠的AIP系統。例如,更高的功率密度降低了潛水艇升級的整體成本。這一趨勢有助於最大限度地延長水下作業時間,並減少對水面加油的依賴。
  • 更高的能量密度:更強大的儲能裝置,例如超級電容器和高容量電池,有助於提高AIP系統的效率。更高的能量密度可以延長水下作業時間,同時縮短充電間隔。這一趨勢拓寬了潛艇的應用範圍,並有助於延長其任務持續時間。
  • 隱蔽性與降噪:新型AIP系統在最佳化隱密性能的同時,著重提升降噪效果。系統設計和材料的創新改進了潛水艇的聲學特徵,使其更加安靜。這提高了作戰隱蔽性和效能,使其能夠在保持戰略優勢的同時,有效規避探測。
  • 模組化和可擴展設計:模組化和可擴展的AIP系統使潛艇設計更加柔軟性,能夠適應各種尺寸和類型的潛艇,並滿足不同的作戰需求。這一趨勢增強了配備AIP技術的潛艇的機動性和柔軟性。

總之,諸如混合動力技術、燃料電池技術進步、更高能量密度、更強隱身性能和模組化設計等絕氣推進系統市場的新興趨勢,改變潛艇的性能。這些趨勢推動了創新,並支持了更長的水下作戰,有助於提升戰略海軍優勢。

近期絕氣推進系統市場趨勢

絕氣推進系統的進步體現了戰略應用領域突破性的技術革新。關鍵進展表明,潛艦性能的提升和作戰效率的提高都取得了顯著成效。以下重點介紹五項值得關注的進展。

  • 燃料電池整合:先進的燃料電池整合技術提升AIP系統的效率和續航力。近期發展包括功率輸出的提升,使潛艇能夠在水下停留更長時間而無需浮出水面。這些進步有助於延長任務期限並提高作戰柔軟性。
  • 史特靈引擎改進:史特靈引擎技術的改進提高了AIP系統的效率。更高的熱效率延長了水下續航時間,更低的運行噪音等級增強了隱蔽性。這些改進正被應用於新型潛水艇設計。
  • 混合動力解決方案:先進電池和燃料電池的混合應用提升了系統性能,優於傳統的AIP架構。這種組合可提高能源效率,延長水下任務時間,並增強操作柔軟性。
  • 先進儲能技術:已開發出用於AIP(自主水下推進系統)的改良能源儲存系統,包括高容量電池和超級電容器。這些裝置具有更高的能量密度和更短的充電時間,提升了長時間水下作業的效能。這項技術的發展將大大促進戰略性海軍需求的實現。
  • 最佳化隱身性能:現代AIP系統目的是最大限度地降低噪音、減少聲學特徵並提高隱身性能。系統設計和材料的改進最大限度地降低了噪音,使潛艇更難被探測到,並提高了作戰效能。

燃料電池技術的進步、改進的史特靈引擎、混合動力解決方案、先進的儲能技術以及最佳化的隱身性能,顯著提高潛艇的能力,幫助它們完成長時間的任務,並實現經濟高效的行動。

目錄

第1章 執行摘要

第2章 市場概覽

  • 背景和分類
  • 供應鏈

第3章 市場趨勢與預測分析

  • 產業促進因素與挑戰
  • PESTLE分析
  • 專利分析
  • 法規環境

第4章 全球絕氣推進系統市場(依類型)

  • 吸引力分析:依類型
  • 英鎊
  • MESMA
  • 燃料電池
  • 其他

第5章 全球絕氣推進系統市場(依安裝類型)

  • 吸引力分析:依安裝類型
  • Line-Fit
  • 維修和安裝

第6章 區域分析

第7章 絕氣推進系統市場

  • 北美絕氣推進系統市場(依類型)
  • 北美絕氣推進系統市場(依安裝類型)
  • 美國絕氣推進系統市場
  • 墨西哥絕氣推進系統市場
  • 加拿大絕氣推進系統市場

第8章 歐洲絕氣推進系統市場

  • 歐洲絕氣推進系統市場(依類型)
  • 歐洲絕氣推進系統市場(依安裝類型)
  • 德國絕氣推進系統市場
  • 法國絕氣推進系統市場
  • 西班牙絕氣推進系統市場
  • 義大利絕氣推進系統市場
  • 英國絕氣推進系統市場

第9章 亞太地區絕氣推進系統市場

  • 亞太地區絕氣推進系統市場(依類型)
  • 亞太地區絕氣推進系統市場(依安裝類型)
  • 日本的絕氣推進系統市場
  • 印度絕氣推進系統市場
  • 中國的絕氣推進系統市場
  • 韓國絕氣推進系統市場
  • 印尼絕氣推進系統市場

第10章 ROW絕氣推進系統市場

  • ROW絕氣推進系統市場(依類型)
  • ROW絕氣推進系統市場(依安裝類型)
  • 中東絕氣推進系統市場
  • 南美洲絕氣推進系統市場
  • 非洲絕氣推進系統市場

第11章 競爭分析

  • 產品系列分析
  • 運作整合
  • 波特五力分析
  • 市場佔有率分析

第12章 機會與策略分析

  • 價值鏈分析
  • 成長機會分析
  • 全球絕氣推進系統市場的新趨勢
  • 戰略分析

第13章 價值鏈主要企業的公司概況

  • 競爭分析
  • Saab
  • Siemens
  • China Shipbuilding Industry
  • UTC Aerospace Systems
  • Lockheed Martin
  • Naval
  • General Dynamics

第14章 附錄

The future of the global air independent propulsion systems market looks promising with opportunities in the stirling, MESMA, and fuel cell markets. The global air independent propulsion systems market is expected to reach an estimated $171 billion by 2031 with a CAGR of 4.8% from 2025 to 2031. The major drivers for this market are growth in the need for secure and safe military operations undersea, improvements in air-independent propulsion technology and the ability to refit conventional submarines with these technologies, along with the increase in underwater science and exploration activities.

  • Lucintel forecasts that, within the fit category, line-fit will remain the largest segment over the forecast period due to rising need for technology advancement in the shipbuilding and submarine building.
  • In terms of regions, APAC is expected to witness highest growth over the forecast period because the countries are purchasing stealthy warships, attack submarines, patrol boats, sensors, radars, missiles, and autonomous systems to upgrade their surface and subsurface naval capabilities.

Emerging Trends in the Air Independent Propulsion Systems Market

Driven by technological developments and changing strategic priorities, the air independent propulsion systems market is rapidly evolving. Key emerging trends are reshaping the capabilities and applications of air independent propulsion system market, making them more effective in naval operations. Here are five key trends:

  • Hybrid AIP Systems: In recent years, there has been an increase in the use of hybrid air independent propulsion system featuring fuel cells and advanced battery technologies. Underwater endurance has been extended due to these systems' high-efficiency designs, while power optimization has also improved. This hybridization facilitates longer missions and increased operational flexibility.
  • Fuel Cell Technology Advancements: Better-performing fuel cells result in more efficient and reliable AIP systems. Examples include higher power densities, which lower overall costs for improving submarines' performance. This trend helps maximize underwater operational durations, reducing dependence on surface air.
  • Enhanced Energy Density: More powerful energy storage devices, such as supercapacitors and high-capacity batteries, contribute to better performance in terms of AIP system efficiency. Greater energy density enables longer underwater operation times, coupled with quicker recharging intervals. This trend expands the possibilities for submarine applications and assists in lengthening their missions.
  • Stealth and Noise Reduction: New AIP systems focus on noise reduction while optimizing stealth capabilities. Submarines are becoming quieter with improved acoustic signatures as a result of innovations in system design and materials. This makes them more stealthy and effective in operations, preserving strategic advantages and avoiding detection.
  • Modular and Scalable Designs: Modular and scalable AIP systems have allowed submarines to be designed flexibly. They can be adjusted to suit different sizes and types of submarines, meeting various operational requirements. This trend enhances the flexibility and mobility of subs equipped with AIP technology.

In conclusion, the emerging trends concerning air independent propulsion systems market, such as hybrid technologies, fuel cell advancements, higher energy densities, enhanced stealth features, and modular designs, are changing submarine capabilities. These trends encourage innovation and support longer-duration underwater operations, promoting strategic naval advantages.

Recent Developments in the Air Independent Propulsion Systems Market

Advances in air independent propulsion systems reflect breakthrough technology improvements for strategic applications. Key developments represent progress toward better submarine capabilities and greater operational efficiency. Here are five notable developments:

  • Fuel Cell Integration: Advanced fuel cell integration increases the efficiency and endurance of AIP systems. Recent developments include power output enhancement, allowing submarines to stay submerged for longer durations without surfacing. These advancements support extended missions and enhance operational flexibility.
  • Stirling Engine Enhancements: There have been improvements in Stirling engine technology, leading to more efficient AIP systems. These advancements include increased thermal efficiency, contributing to longer underwater endurance and reduced operational sound levels, which enhance stealth characteristics. These developments are being incorporated into new submarine designs.
  • Hybrid Power Solutions: Hybridization of advanced batteries with fuel cells has improved overall system performance for conventional AIP architectures. This combination leads to increased energy efficiency and extended underwater missions, enhancing operational flexibility.
  • Advanced Energy Storage: Improved energy storage systems, such as high-capacity batteries and supercapacitors, have been developed to support AIP. These devices offer increased energy density and reduced recharging times, contributing to better performance during longer underwater operations. This development has a significant impact on fulfilling strategic naval requirements.
  • Stealth Optimization: Modern AIP systems aim to minimize noise, reduce acoustic signatures, and improve stealth. Noise is minimized through improvements in system design and materials, making submarines less detectable and improving operational efficiency.

Advances in fuel cell technology, Stirling engine enhancements, hybrid power solutions, advanced energy storage, and stealth optimization are majorly improving submarine capabilities, supporting long-term mission accomplishment, and offering cost-effective operations.

Strategic Growth Opportunities in the Air Independent Propulsion Systems Market

The market for air independent propulsion systems offers several strategic growth opportunities, driven by growing technological advancements and increasing demand for naval capabilities. Identifying these openings enables stakeholders to exploit emerging trends and extend their market presence. Here are five main opportunities for growth:

  • Advanced Fuel Cell Technologies: Investing in the research and deployment of advanced fuel cell technologies offers significant potential for growth. Improved fuel cell performance can increase the power output and efficiency of AIP systems, raising demand for state-of-the-art solutions targeting naval applications.
  • Hybrid AIP Solutions: Another opportunity is the development of hybrid AIP systems that combine fuel cell technology with evolved batteries. These hybrids offer greater operational efficiency, making it possible for submarines to support longer underwater missions. Such capabilities are attractive to naval forces seeking enhanced operational flexibility.
  • Energy Storage Innovations: Innovations in energy storage, such as high-capacity batteries or supercapacitors, can drive the growth of AIP systems. Improved energy densities and faster recharging times enhance overall system performance, meeting the requirements of modern-day submarines and creating new market opportunities.
  • Stealth and Acoustic Management: Focusing on acoustic management technologies and stealth optimization could lead to an increase in the sales of AIP systems. Submarines with reduced sound signatures will be highly valued by defense organizations looking for covert operations capabilities.
  • Modular and Scalable Designs: Developing modular and scalable AIP systems offers another growth opportunity. Flexible designs that can be adapted to different submarine types allow operational demands to be met, expanding the market base for AIP technologies.

Strategic growth opportunities within air independent propulsion systems include advancing fuel cell technologies, developing hybrid solutions, innovating energy storage devices, optimizing stealth, and enhancing modular designs. Taking advantage of these opportunities could result in market expansion and more effective naval operations.

Air Independent Propulsion Systems Market Driver and Challenges

Various technological, economic, and regulatory factors influence the air independent propulsion systems market. Understanding these drivers and challenges is crucial for stakeholders looking to navigate the market and make informed decisions.

The factors responsible for driving the air independent propulsion systems market include:

  • Technological Advancements: Market growth is propelled by innovations in fuel cells, Stirling engines, hybrid systems, and other aspects of AIP technology. Submarine performance, such as endurance, improves with these advancements, increasing adoption rates and further development of AIP systems.
  • Increasing Naval Capabilities: Efficient AIP systems are required due to the growing demand for advanced naval capabilities and extended underwater operations. The improvements in performance and stealth have boosted market demand for submarines equipped with AIP systems, aligning with defense strategies.
  • Focus on Stealth and Covert Operations: The development of AIP systems with lower acoustic signatures and improved stealth capabilities is driven by the emphasis on stealth and covert operations. These advancements enhance operational effectiveness and appeal to defense organizations that require such capabilities.
  • Government Investments and Defense Budgets: Increased government investments in defense and naval modernization programs are fueling market growth. Funds allocated to research, development, and acquisition of advanced AIP systems support technological advancements and expand the market segment.
  • Strategic Defense Requirements: The need for advanced AIP systems is driven by strategic defense requirements, such as longer underwater endurance and increased operational flexibility. This need supports the development and deployment of cutting-edge technologies in naval applications.

Challenges in the air independent propulsion systems market are:

  • High Development and Acquisition Costs: The high costs involved in developing or acquiring sophisticated AIP systems can hinder adoption, especially in nations with limited defense budgets. Infrastructure spending may also limit market growth.
  • Complex Maintenance and Support: AIP systems require complex maintenance, and operational efficiency can be affected by a lack of skilled personnel or adequate facilities. These factors may increase the total cost of ownership (TCO).
  • Regulatory and Export Controls: Compliance with regulatory and export controls poses challenges for the AIP systems market. Changes in regulations may affect technology transfers and expansion into international markets, making it difficult to navigate regions with differing restrictions.

Technological developments, the growth of naval capabilities, increased focus on stealth, government investments, and defense strategies are the primary drivers behind the expansion of the air independent propulsion systems market. However, challenges such as high costs, complex maintenance, and regulatory compliance must also be addressed. Balancing these drivers and obstacles is crucial for the future development of the market.

List of Air Independent Propulsion Systems Companies

Companies in the market compete on the basis of product quality offered. Major players in this market focus on expanding their manufacturing facilities, R&D investments, infrastructural development, and leverage integration opportunities across the value chain. With these strategies air independent propulsion systems companies cater increasing demand, ensure competitive effectiveness, develop innovative products & technologies, reduce production costs, and expand their customer base. Some of the air independent propulsion systems companies profiled in this report include-

  • Saab
  • Siemens
  • China Shipbuilding Industry
  • UTC Aerospace Systems
  • Lockheed Martin
  • Naval
  • General Dynamics

Air Independent Propulsion Systems by Segment

The study includes a forecast for the global air independent propulsion systems by type, fit, and region.

Air Independent Propulsion Systems Market by Type [Analysis by Value from 2019 to 2031]:

  • Stirling
  • Mesma
  • Fuel Cell
  • Others

Air Independent Propulsion Systems Market by Fit [Analysis by Value from 2019 to 2031]:

  • Line-Fit
  • Retrofit

Air Independent Propulsion Systems Market by Region [Analysis by Value from 2019 to 2031]:

  • North America
  • Europe
  • Asia Pacific
  • The Rest of the World

Country Wise Outlook for the Air Independent Propulsion Systems Market

Submarine operations are transformed by air independent propulsion systems, which improve underwater endurance and stealth capabilities. Recent changes in technology, efficiency, and strategic applications are important as nations seek to enhance their naval capacities and adapt to new operational demands. Notable developments in the US, China, Germany, India, and Japan include:

  • United States: The US is advancing its air independent propulsion systems technology with a greater emphasis on integrating fuel cell systems and modern lithium-ion battery technologies. Current initiatives focus on increasing submarine endurance and operational range, supported by ongoing studies of hybrid AIP systems. These advancements aim to maintain the country's strategic superiority and extend its submarine operational capabilities.
  • China: China has made significant progress in air independent propulsion systems technology, concentrating on the development of air-independent fuel cells. Recent milestones include integrating high-efficiency AIP systems into new submarine classes for improved stealth and endurance. China's indigenous AIP development plans will reduce external dependency and improve naval efficiency.
  • Germany: Germany has been a leader in proprietary Stirling engine-based air independent propulsion systems technology. Recent improvements include enhanced performance and efficiency of Stirling engines, leading to better underwater endurance and stealth. German submarines feature various models, each incorporating the country's developed AIP systems, underscoring Germany's technological edge in naval operations.
  • India: India is making progress in developing indigenous air independent propulsion systems to strengthen its submarine capabilities. Recently, tests were conducted on an Indian-designed fuel cell-based AIP system integrated into the country's submarine fleet. This development will enhance the Indian Navy's stealth capabilities and operational range, aligning with defense objectives.
  • Japan: Japan is improving its air independent propulsion systems technology, focusing on enhancing the efficiency of its fuel cell systems. Advanced AIP systems have been integrated into new submarine classes, increasing both underwater endurance and stealth. These advancements support Japan's strategic interests and improve operational efficiency at sea.

Features of the Global Air Independent Propulsion Systems Market

  • Market Size Estimates: Air independent propulsion systems market size estimation in terms of value ($B).
  • Trend and Forecast Analysis: Market trends (2019 to 2024) and forecast (2025 to 2031) by various segments and regions.
  • Segmentation Analysis: Air independent propulsion systems market size by type, fit, and region in terms of value ($B).
  • Regional Analysis: Air independent propulsion systems market breakdown by North America, Europe, Asia Pacific, and Rest of the World.
  • Growth Opportunities: Analysis of growth opportunities in different type, fit, and regions for the air independent propulsion systems market.
  • Strategic Analysis: This includes M&A, new product development, and competitive landscape of the air independent propulsion systems market.

Analysis of competitive intensity of the industry based on Porter's Five Forces model.

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This report answers following 11 key questions:

  • Q.1. What are some of the most promising, high-growth opportunities for the air independent propulsion systems market by type (stirling, MESMA, fuel cell, and others), fit (line-fit and retrofit), and region (North America, Europe, Asia Pacific, and the Rest of the World)?
  • Q.2. Which segments will grow at a faster pace and why?
  • Q.3. Which region will grow at a faster pace and why?
  • Q.4. What are the key factors affecting market dynamics? What are the key challenges and business risks in this market?
  • Q.5. What are the business risks and competitive threats in this market?
  • Q.6. What are the emerging trends in this market and the reasons behind them?
  • Q.7. What are some of the changing demands of customers in the market?
  • Q.8. What are the new developments in the market? Which companies are leading these developments?
  • Q.9. Who are the major players in this market? What strategic initiatives are key players pursuing for business growth?
  • Q.10. What are some of the competing products in this market and how big of a threat do they pose for loss of market share by material or product substitution?
  • Q.11. What M&A activity has occurred in the last 5 years and what has its impact been on the industry?

Table of Contents

1. Executive Summary

2. Market Overview

  • 2.1 Background and Classifications
  • 2.2 Supply Chain

3. Market Trends & Forecast Analysis

  • 3.2 Industry Drivers and Challenges
  • 3.3 PESTLE Analysis
  • 3.4 Patent Analysis
  • 3.5 Regulatory Environment

4. Global Air Independent Propulsion Systems Market by Type

  • 4.1 Overview
  • 4.2 Attractiveness Analysis by Type
  • 4.3 Stirling: Trends and Forecast (2019-2031)
  • 4.4 MESMA: Trends and Forecast (2019-2031)
  • 4.5 Fuel Cell: Trends and Forecast (2019-2031)
  • 4.6 Others: Trends and Forecast (2019-2031)

5. Global Air Independent Propulsion Systems Market by Fit

  • 5.1 Overview
  • 5.2 Attractiveness Analysis by Fit
  • 5.3 Line-Fit: Trends and Forecast (2019-2031)
  • 5.4 Retrofit: Trends and Forecast (2019-2031)

6. Regional Analysis

  • 6.1 Overview
  • 6.2 Global Air Independent Propulsion Systems Market by Region

7. North American Air Independent Propulsion Systems Market

  • 7.1 Overview
  • 7.2 North American Air Independent Propulsion Systems Market by Type
  • 7.3 North American Air Independent Propulsion Systems Market by Fit
  • 7.4 United States Air Independent Propulsion Systems Market
  • 7.5 Mexican Air Independent Propulsion Systems Market
  • 7.6 Canadian Air Independent Propulsion Systems Market

8. European Air Independent Propulsion Systems Market

  • 8.1 Overview
  • 8.2 European Air Independent Propulsion Systems Market by Type
  • 8.3 European Air Independent Propulsion Systems Market by Fit
  • 8.4 German Air Independent Propulsion Systems Market
  • 8.5 French Air Independent Propulsion Systems Market
  • 8.6 Spanish Air Independent Propulsion Systems Market
  • 8.7 Italian Air Independent Propulsion Systems Market
  • 8.8 United Kingdom Air Independent Propulsion Systems Market

9. APAC Air Independent Propulsion Systems Market

  • 9.1 Overview
  • 9.2 APAC Air Independent Propulsion Systems Market by Type
  • 9.3 APAC Air Independent Propulsion Systems Market by Fit
  • 9.4 Japanese Air Independent Propulsion Systems Market
  • 9.5 Indian Air Independent Propulsion Systems Market
  • 9.6 Chinese Air Independent Propulsion Systems Market
  • 9.7 South Korean Air Independent Propulsion Systems Market
  • 9.8 Indonesian Air Independent Propulsion Systems Market

10. ROW Air Independent Propulsion Systems Market

  • 10.1 Overview
  • 10.2 ROW Air Independent Propulsion Systems Market by Type
  • 10.3 ROW Air Independent Propulsion Systems Market by Fit
  • 10.4 Middle Eastern Air Independent Propulsion Systems Market
  • 10.5 South American Air Independent Propulsion Systems Market
  • 10.6 African Air Independent Propulsion Systems Market

11. Competitor Analysis

  • 11.1 Product Portfolio Analysis
  • 11.2 Operational Integration
  • 11.3 Porter's Five Forces Analysis
    • Competitive Rivalry
    • Bargaining Power of Buyers
    • Bargaining Power of Suppliers
    • Threat of Substitutes
    • Threat of New Entrants
  • 11.4 Market Share Analysis

12. Opportunities & Strategic Analysis

  • 12.1 Value Chain Analysis
  • 12.2 Growth Opportunity Analysis
    • 12.2.1 Growth Opportunities by Type
    • 12.2.2 Growth Opportunities by Fit
  • 12.3 Emerging Trends in the Global Air Independent Propulsion Systems Market
  • 12.4 Strategic Analysis
    • 12.4.1 New Product Development
    • 12.4.2 Certification and Licensing
    • 12.4.3 Mergers, Acquisitions, Agreements, Collaborations, and Joint Ventures

13. Company Profiles of the Leading Players Across the Value Chain

  • 13.1 Competitive Analysis
  • 13.2 Saab
    • Company Overview
    • Air Independent Propulsion Systems Business Overview
    • New Product Development
    • Merger, Acquisition, and Collaboration
    • Certification and Licensing
  • 13.3 Siemens
    • Company Overview
    • Air Independent Propulsion Systems Business Overview
    • New Product Development
    • Merger, Acquisition, and Collaboration
    • Certification and Licensing
  • 13.4 China Shipbuilding Industry
    • Company Overview
    • Air Independent Propulsion Systems Business Overview
    • New Product Development
    • Merger, Acquisition, and Collaboration
    • Certification and Licensing
  • 13.5 UTC Aerospace Systems
    • Company Overview
    • Air Independent Propulsion Systems Business Overview
    • New Product Development
    • Merger, Acquisition, and Collaboration
    • Certification and Licensing
  • 13.6 Lockheed Martin
    • Company Overview
    • Air Independent Propulsion Systems Business Overview
    • New Product Development
    • Merger, Acquisition, and Collaboration
    • Certification and Licensing
  • 13.7 Naval
    • Company Overview
    • Air Independent Propulsion Systems Business Overview
    • New Product Development
    • Merger, Acquisition, and Collaboration
    • Certification and Licensing
  • 13.8 General Dynamics
    • Company Overview
    • Air Independent Propulsion Systems Business Overview
    • New Product Development
    • Merger, Acquisition, and Collaboration
    • Certification and Licensing

14. Appendix

  • 14.1 List of Figures
  • 14.2 List of Tables
  • 14.3 Research Methodology
  • 14.4 Disclaimer
  • 14.5 Copyright
  • 14.6 Abbreviations and Technical Units
  • 14.7 About Us
  • 14.8 Contact Us

List of Figures

  • Figure 1.1: Trends and Forecast for the Global Air Independent Propulsion Systems Market
  • Figure 2.1: Usage of Air Independent Propulsion Systems Market
  • Figure 2.2: Classification of the Global Air Independent Propulsion Systems Market
  • Figure 2.3: Supply Chain of the Global Air Independent Propulsion Systems Market
  • Figure 3.1: Driver and Challenges of the Air Independent Propulsion Systems Market
  • Figure 3.2: PESTLE Analysis
  • Figure 3.3: Patent Analysis
  • Figure 3.4: Regulatory Environment
  • Figure 4.1: Global Air Independent Propulsion Systems Market by Type in 2019, 2024, and 2031
  • Figure 4.2: Trends of the Global Air Independent Propulsion Systems Market ($B) by Type
  • Figure 4.3: Forecast for the Global Air Independent Propulsion Systems Market ($B) by Type
  • Figure 4.4: Trends and Forecast for Stirling in the Global Air Independent Propulsion Systems Market (2019-2031)
  • Figure 4.5: Trends and Forecast for MESMA in the Global Air Independent Propulsion Systems Market (2019-2031)
  • Figure 4.6: Trends and Forecast for Fuel Cell in the Global Air Independent Propulsion Systems Market (2019-2031)
  • Figure 4.7: Trends and Forecast for Others in the Global Air Independent Propulsion Systems Market (2019-2031)
  • Figure 5.1: Global Air Independent Propulsion Systems Market by Fit in 2019, 2024, and 2031
  • Figure 5.2: Trends of the Global Air Independent Propulsion Systems Market ($B) by Fit
  • Figure 5.3: Forecast for the Global Air Independent Propulsion Systems Market ($B) by Fit
  • Figure 5.4: Trends and Forecast for Line-Fit in the Global Air Independent Propulsion Systems Market (2019-2031)
  • Figure 5.5: Trends and Forecast for Retrofit in the Global Air Independent Propulsion Systems Market (2019-2031)
  • Figure 6.1: Trends of the Global Air Independent Propulsion Systems Market ($B) by Region (2019-2024)
  • Figure 6.2: Forecast for the Global Air Independent Propulsion Systems Market ($B) by Region (2025-2031)
  • Figure 7.1: North American Air Independent Propulsion Systems Market by Type in 2019, 2024, and 2031
  • Figure 7.2: Trends of the North American Air Independent Propulsion Systems Market ($B) by Type (2019-2024)
  • Figure 7.3: Forecast for the North American Air Independent Propulsion Systems Market ($B) by Type (2025-2031)
  • Figure 7.4: North American Air Independent Propulsion Systems Market by Fit in 2019, 2024, and 2031
  • Figure 7.5: Trends of the North American Air Independent Propulsion Systems Market ($B) by Fit (2019-2024)
  • Figure 7.6: Forecast for the North American Air Independent Propulsion Systems Market ($B) by Fit (2025-2031)
  • Figure 7.7: Trends and Forecast for the United States Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 7.8: Trends and Forecast for the Mexican Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 7.9: Trends and Forecast for the Canadian Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 8.1: European Air Independent Propulsion Systems Market by Type in 2019, 2024, and 2031
  • Figure 8.2: Trends of the European Air Independent Propulsion Systems Market ($B) by Type (2019-2024)
  • Figure 8.3: Forecast for the European Air Independent Propulsion Systems Market ($B) by Type (2025-2031)
  • Figure 8.4: European Air Independent Propulsion Systems Market by Fit in 2019, 2024, and 2031
  • Figure 8.5: Trends of the European Air Independent Propulsion Systems Market ($B) by Fit (2019-2024)
  • Figure 8.6: Forecast for the European Air Independent Propulsion Systems Market ($B) by Fit (2025-2031)
  • Figure 8.7: Trends and Forecast for the German Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 8.8: Trends and Forecast for the French Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 8.9: Trends and Forecast for the Spanish Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 8.10: Trends and Forecast for the Italian Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 8.11: Trends and Forecast for the United Kingdom Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 9.1: APAC Air Independent Propulsion Systems Market by Type in 2019, 2024, and 2031
  • Figure 9.2: Trends of the APAC Air Independent Propulsion Systems Market ($B) by Type (2019-2024)
  • Figure 9.3: Forecast for the APAC Air Independent Propulsion Systems Market ($B) by Type (2025-2031)
  • Figure 9.4: APAC Air Independent Propulsion Systems Market by Fit in 2019, 2024, and 2031
  • Figure 9.5: Trends of the APAC Air Independent Propulsion Systems Market ($B) by Fit (2019-2024)
  • Figure 9.6: Forecast for the APAC Air Independent Propulsion Systems Market ($B) by Fit (2025-2031)
  • Figure 9.7: Trends and Forecast for the Japanese Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 9.8: Trends and Forecast for the Indian Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 9.9: Trends and Forecast for the Chinese Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 9.10: Trends and Forecast for the South Korean Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 9.11: Trends and Forecast for the Indonesian Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 10.1: ROW Air Independent Propulsion Systems Market by Type in 2019, 2024, and 2031
  • Figure 10.2: Trends of the ROW Air Independent Propulsion Systems Market ($B) by Type (2019-2024)
  • Figure 10.3: Forecast for the ROW Air Independent Propulsion Systems Market ($B) by Type (2025-2031)
  • Figure 10.4: ROW Air Independent Propulsion Systems Market by Fit in 2019, 2024, and 2031
  • Figure 10.5: Trends of the ROW Air Independent Propulsion Systems Market ($B) by Fit (2019-2024)
  • Figure 10.6: Forecast for the ROW Air Independent Propulsion Systems Market ($B) by Fit (2025-2031)
  • Figure 10.7: Trends and Forecast for the Middle Eastern Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 10.8: Trends and Forecast for the South American Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 10.9: Trends and Forecast for the African Air Independent Propulsion Systems Market ($B) (2019-2031)
  • Figure 11.1: Porter's Five Forces Analysis of the Global Air Independent Propulsion Systems Market
  • Figure 11.2: Market Share (%) of Top Players in the Global Air Independent Propulsion Systems Market (2024)
  • Figure 12.1: Growth Opportunities for the Global Air Independent Propulsion Systems Market by Type
  • Figure 12.2: Growth Opportunities for the Global Air Independent Propulsion Systems Market by Fit
  • Figure 12.3: Growth Opportunities for the Global Air Independent Propulsion Systems Market by Region
  • Figure 12.4: Emerging Trends in the Global Air Independent Propulsion Systems Market

List of Tables

  • Table 1.1: Growth Rate (%, 2023-2024) and CAGR (%, 2025-2031) of the Air Independent Propulsion Systems Market by Type and Fit
  • Table 1.2: Attractiveness Analysis for the Air Independent Propulsion Systems Market by Region
  • Table 1.3: Global Air Independent Propulsion Systems Market Parameters and Attributes
  • Table 3.1: Trends of the Global Air Independent Propulsion Systems Market (2019-2024)
  • Table 3.2: Forecast for the Global Air Independent Propulsion Systems Market (2025-2031)
  • Table 4.1: Attractiveness Analysis for the Global Air Independent Propulsion Systems Market by Type
  • Table 4.2: Market Size and CAGR of Various Type in the Global Air Independent Propulsion Systems Market (2019-2024)
  • Table 4.3: Market Size and CAGR of Various Type in the Global Air Independent Propulsion Systems Market (2025-2031)
  • Table 4.4: Trends of Stirling in the Global Air Independent Propulsion Systems Market (2019-2024)
  • Table 4.5: Forecast for Stirling in the Global Air Independent Propulsion Systems Market (2025-2031)
  • Table 4.6: Trends of MESMA in the Global Air Independent Propulsion Systems Market (2019-2024)
  • Table 4.7: Forecast for MESMA in the Global Air Independent Propulsion Systems Market (2025-2031)
  • Table 4.8: Trends of Fuel Cell in the Global Air Independent Propulsion Systems Market (2019-2024)
  • Table 4.9: Forecast for Fuel Cell in the Global Air Independent Propulsion Systems Market (2025-2031)
  • Table 4.10: Trends of Others in the Global Air Independent Propulsion Systems Market (2019-2024)
  • Table 4.11: Forecast for Others in the Global Air Independent Propulsion Systems Market (2025-2031)
  • Table 5.1: Attractiveness Analysis for the Global Air Independent Propulsion Systems Market by Fit
  • Table 5.2: Market Size and CAGR of Various Fit in the Global Air Independent Propulsion Systems Market (2019-2024)
  • Table 5.3: Market Size and CAGR of Various Fit in the Global Air Independent Propulsion Systems Market (2025-2031)
  • Table 5.4: Trends of Line-Fit in the Global Air Independent Propulsion Systems Market (2019-2024)
  • Table 5.5: Forecast for Line-Fit in the Global Air Independent Propulsion Systems Market (2025-2031)
  • Table 5.6: Trends of Retrofit in the Global Air Independent Propulsion Systems Market (2019-2024)
  • Table 5.7: Forecast for Retrofit in the Global Air Independent Propulsion Systems Market (2025-2031)
  • Table 6.1: Market Size and CAGR of Various Regions in the Global Air Independent Propulsion Systems Market (2019-2024)
  • Table 6.2: Market Size and CAGR of Various Regions in the Global Air Independent Propulsion Systems Market (2025-2031)
  • Table 7.1: Trends of the North American Air Independent Propulsion Systems Market (2019-2024)
  • Table 7.2: Forecast for the North American Air Independent Propulsion Systems Market (2025-2031)
  • Table 7.3: Market Size and CAGR of Various Type in the North American Air Independent Propulsion Systems Market (2019-2024)
  • Table 7.4: Market Size and CAGR of Various Type in the North American Air Independent Propulsion Systems Market (2025-2031)
  • Table 7.5: Market Size and CAGR of Various Fit in the North American Air Independent Propulsion Systems Market (2019-2024)
  • Table 7.6: Market Size and CAGR of Various Fit in the North American Air Independent Propulsion Systems Market (2025-2031)
  • Table 7.7: Trends and Forecast for the United States Air Independent Propulsion Systems Market (2019-2031)
  • Table 7.8: Trends and Forecast for the Mexican Air Independent Propulsion Systems Market (2019-2031)
  • Table 7.9: Trends and Forecast for the Canadian Air Independent Propulsion Systems Market (2019-2031)
  • Table 8.1: Trends of the European Air Independent Propulsion Systems Market (2019-2024)
  • Table 8.2: Forecast for the European Air Independent Propulsion Systems Market (2025-2031)
  • Table 8.3: Market Size and CAGR of Various Type in the European Air Independent Propulsion Systems Market (2019-2024)
  • Table 8.4: Market Size and CAGR of Various Type in the European Air Independent Propulsion Systems Market (2025-2031)
  • Table 8.5: Market Size and CAGR of Various Fit in the European Air Independent Propulsion Systems Market (2019-2024)
  • Table 8.6: Market Size and CAGR of Various Fit in the European Air Independent Propulsion Systems Market (2025-2031)
  • Table 8.7: Trends and Forecast for the German Air Independent Propulsion Systems Market (2019-2031)
  • Table 8.8: Trends and Forecast for the French Air Independent Propulsion Systems Market (2019-2031)
  • Table 8.9: Trends and Forecast for the Spanish Air Independent Propulsion Systems Market (2019-2031)
  • Table 8.10: Trends and Forecast for the Italian Air Independent Propulsion Systems Market (2019-2031)
  • Table 8.11: Trends and Forecast for the United Kingdom Air Independent Propulsion Systems Market (2019-2031)
  • Table 9.1: Trends of the APAC Air Independent Propulsion Systems Market (2019-2024)
  • Table 9.2: Forecast for the APAC Air Independent Propulsion Systems Market (2025-2031)
  • Table 9.3: Market Size and CAGR of Various Type in the APAC Air Independent Propulsion Systems Market (2019-2024)
  • Table 9.4: Market Size and CAGR of Various Type in the APAC Air Independent Propulsion Systems Market (2025-2031)
  • Table 9.5: Market Size and CAGR of Various Fit in the APAC Air Independent Propulsion Systems Market (2019-2024)
  • Table 9.6: Market Size and CAGR of Various Fit in the APAC Air Independent Propulsion Systems Market (2025-2031)
  • Table 9.7: Trends and Forecast for the Japanese Air Independent Propulsion Systems Market (2019-2031)
  • Table 9.8: Trends and Forecast for the Indian Air Independent Propulsion Systems Market (2019-2031)
  • Table 9.9: Trends and Forecast for the Chinese Air Independent Propulsion Systems Market (2019-2031)
  • Table 9.10: Trends and Forecast for the South Korean Air Independent Propulsion Systems Market (2019-2031)
  • Table 9.11: Trends and Forecast for the Indonesian Air Independent Propulsion Systems Market (2019-2031)
  • Table 10.1: Trends of the ROW Air Independent Propulsion Systems Market (2019-2024)
  • Table 10.2: Forecast for the ROW Air Independent Propulsion Systems Market (2025-2031)
  • Table 10.3: Market Size and CAGR of Various Type in the ROW Air Independent Propulsion Systems Market (2019-2024)
  • Table 10.4: Market Size and CAGR of Various Type in the ROW Air Independent Propulsion Systems Market (2025-2031)
  • Table 10.5: Market Size and CAGR of Various Fit in the ROW Air Independent Propulsion Systems Market (2019-2024)
  • Table 10.6: Market Size and CAGR of Various Fit in the ROW Air Independent Propulsion Systems Market (2025-2031)
  • Table 10.7: Trends and Forecast for the Middle Eastern Air Independent Propulsion Systems Market (2019-2031)
  • Table 10.8: Trends and Forecast for the South American Air Independent Propulsion Systems Market (2019-2031)
  • Table 10.9: Trends and Forecast for the African Air Independent Propulsion Systems Market (2019-2031)
  • Table 11.1: Product Mapping of Air Independent Propulsion Systems Suppliers Based on Segments
  • Table 11.2: Operational Integration of Air Independent Propulsion Systems Manufacturers
  • Table 11.3: Rankings of Suppliers Based on Air Independent Propulsion Systems Revenue
  • Table 12.1: New Product Launches by Major Air Independent Propulsion Systems Producers (2019-2024)
  • Table 12.2: Certification Acquired by Major Competitor in the Global Air Independent Propulsion Systems Market