欧州の大型衛星推進システム市場：サブシステム・国別の分析・予測 (2025-2040年)

欧州の大型衛星推進システムの市場規模は、2040年までに1億7,750万ドルに達すると予測されています。

欧州市場における大型衛星推進システムには、化学推進、電気推進、コールドガス推進、ハイブリッドスラスターといった多様な軌道上推進技術が含まれており、いずれも重量級衛星の軌道投入、姿勢保持、運用終了時のマヌーバーに不可欠です。

同地域での需要は、航行衛星コンステレーションの拡大、高度な地球観測プラットフォームの整備、大容量通信衛星の展開増加といった要因により引き続き牽引されています。これらはすべて、高精度の軌道上昇および長期的な姿勢保持を必要とします。

欧州の宇宙事業者に対し、スケーラブルで経済的かつ持続可能なソリューションを提供するために、モジュール型ハイブリッドステージ、グリーン化学推進システム、大推力の電気式ホール効果スラスターといった技術革新がますます採用されつつあります。

この市場は競争が激しく、欧州の既存メーカーと世界的な航空宇宙リーダーが、欧州宇宙機関 (ESA) や各国の宇宙計画と連携しています。事業者が推進剤の効率、軌道上のデブリの軽減、ミッションの柔軟性を重視し、再利用可能な推進システムや次世代電気アーキテクチャーへの投資に拍車がかかるにつれて、調達戦略は進化しています。その結果、欧州の大型衛星推進システム市場は、技術革新、民間セクターの参入拡大、そして現代の衛星ミッションにおける性能需要の高まりによって急速に変革を遂げています。

市場の分類

セグメンテーション1：サブシステム別

• 化学スラスター
  • 推進剤タンク
  • ポンプ
  • 燃料・酸化剤バルブ
• 電気スラスター
  • 推進剤タンク
  • ポンプ
• コールドガススラスター
  • ガス貯蔵タンク
  • 推進チャンバー/ノズル
  • ポンプ
• ハイブリッドスラスター
  • 推進剤タンク
  • 推進室/ノズル
• ポンプ

セグメンテーション2：地域別

• 欧州

当レポートでは、欧州の大型衛星推進システムの市場を調査し、主要動向、市場影響因子の分析、法規制環境、技術・特許の分析、市場規模の推移・予測、各種区分・地域/主要国別の詳細分析、競合情勢、主要企業のプロファイルなどをまとめています。

目次

エグゼクティブサマリー

市場/製品の定義

第1章 地域

• 大型衛星推進システム市場 (地域別)
  • 欧州

第2章 スラスターと規制分析

• スラスターの分析 (用途別)
  • ハイブリッドスラスター
  • コールドガススラスター
  • 化学スラスター (高温ガスおよび温ガス)
  • 電動スラスター
  • アナリストの視点
• 規制分析 (国別)
  • 英国
  • フランス
  • ドイツ

第3章 調査手法

List of Figures

• Figure 1: Key Players in the Large Satellite Propulsion System Market
• Figure 2: Data Triangulation
• Figure 3: Assumptions and Limitations

List of Tables

• Table 1: Market Segmentations for Large Satellite Propulsion System Market
• Table 2: Key Regulations for Europe Large Satellite Propulsion System Market
• Table 3: Key Opportunities for Large Satellite Propulsion System Market
• Table 4: Large Satellite Propulsion System Market (by Region), $Million, 2024-2040
• Table 5: Large Satellite Propulsion System Market (by Region), Units, 2024-2040
• Table 6: Europe Large Satellite Propulsion System Market (by Subsystem), $Million, 2024-2040
• Table 7: Europe Large Satellite Propulsion System Market (by Subsystem), Units, 2024-2040
• Table 8: Europe Large Satellite Propulsion System Market (by Chemical Thruster), $Million, 2024-2040
• Table 9: Europe Large Satellite Propulsion System Market (by Chemical Thruster), Units, 2024-2040
• Table 10: Europe Large Satellite Propulsion System Market (by Electric Thruster), $Million, 2024-2040
• Table 11: Europe Large Satellite Propulsion System Market (by Electric Thruster), Units, 2024-2040
• Table 12: Europe Large Satellite Propulsion System Market (by Cold Gas Thruster), $Million, 2024-2040
• Table 13: Europe Large Satellite Propulsion System Market (by Cold Gas Thruster), Units, 2024-2040
• Table 14: Europe Large Satellite Propulsion System Market (by Hybrid Thruster), $Million, 2024-2040
• Table 15: Europe Large Satellite Propulsion System Market (by Hybrid Thruster), Units, 2024-2040
• Table 16: France Large Satellite Propulsion System Market (by Subsystem), $Million, 2024-2040
• Table 17: France Large Satellite Propulsion System Market (by Subsystem), Units, 2024-2040
• Table 18: France Large Satellite Propulsion System Market (by Chemical Thruster), $Million, 2024-2040
• Table 19: France Large Satellite Propulsion System Market (by Chemical Thruster), Units, 2024-2040
• Table 20: France Large Satellite Propulsion System Market (by Electric Thruster), $Million, 2024-2040
• Table 21: France Large Satellite Propulsion System Market (by Electric Thruster), Units, 2024-2040
• Table 22: France Large Satellite Propulsion System Market (by Cold Gas Thruster), $Million, 2024-2040
• Table 23: France Large Satellite Propulsion System Market (by Cold Gas Thruster), Units, 2024-2040
• Table 24: France Large Satellite Propulsion System Market (by Hybrid Thruster), $Million, 2024-2040
• Table 25: France Large Satellite Propulsion System Market (by Hybrid Thruster), Units, 2024-2040
• Table 26: Germany Large Satellite Propulsion System Market (by Subsystem), $Million, 2024-2040
• Table 27: Germany Large Satellite Propulsion System Market (by Subsystem), Units, 2024-2040
• Table 28: Germany Large Satellite Propulsion System Market (by Chemical Thruster), $Million, 2024-2040
• Table 29: Germany Large Satellite Propulsion System Market (by Chemical Thruster), Units, 2024-2040
• Table 30: Germany Large Satellite Propulsion System Market (by Electric Thruster), $Million, 2024-2040
• Table 31: Germany Large Satellite Propulsion System Market (by Electric Thruster), Units, 2024-2040
• Table 32: Germany Large Satellite Propulsion System Market (by Cold Gas Thruster), $Million, 2024-2040
• Table 33: Germany Large Satellite Propulsion System Market (by Cold Gas Thruster), Units, 2024-2040
• Table 34: Germany Large Satellite Propulsion System Market (by Hybrid Thruster), $Million, 2024-2040
• Table 35: Germany Large Satellite Propulsion System Market (by Hybrid Thruster), Units, 2024-2040
• Table 36: U.K. Large Satellite Propulsion System Market (by Subsystem), $Million, 2024-2040
• Table 37: U.K. Large Satellite Propulsion System Market (by Subsystem), Units, 2024-2040
• Table 38: U.K. Large Satellite Propulsion System Market (by Chemical Thruster), $Million, 2024-2040
• Table 39: U.K. Large Satellite Propulsion System Market (by Chemical Thruster), Units, 2024-2040
• Table 40: U.K. Large Satellite Propulsion System Market (by Electric Thruster), $Million, 2024-2040
• Table 41: U.K. Large Satellite Propulsion System Market (by Electric Thruster), Units, 2024-2040
• Table 42: U.K. Large Satellite Propulsion System Market (by Cold Gas Thruster), $Million, 2024-2040
• Table 43: U.K. Large Satellite Propulsion System Market (by Cold Gas Thruster), Units, 2024-2040
• Table 44: U.K. Large Satellite Propulsion System Market (by Hybrid Thruster), $Million, 2024-2040
• Table 45: U.K. Large Satellite Propulsion System Market (by Hybrid Thruster), Units, 2024-2040
• Table 46: Rest-of-Europe Large Satellite Propulsion System Market (by Subsystem), $Million, 2024-2040
• Table 47: Rest-of-Europe Large Satellite Propulsion System Market (by Subsystem), Units, 2024-2040
• Table 48: Rest-of-Europe Large Satellite Propulsion System Market (by Chemical Thruster), $Million, 2024-2040
• Table 49: Rest-of-Europe Large Satellite Propulsion System Market (by Chemical Thruster), Units, 2024-2040
• Table 50: Rest-of-Europe Large Satellite Propulsion System Market (by Electric Thruster), $Million, 2024-2040
• Table 51: Rest-of-Europe Large Satellite Propulsion System Market (by Electric Thruster), Units, 2024-2040
• Table 52: Rest-of-Europe Large Satellite Propulsion System Market (by Cold Gas Thruster), $Million, 2024-2040
• Table 53: Rest-of-Europe Large Satellite Propulsion System Market (by Cold Gas Thruster), Units, 2024-2040
• Table 54: Rest-of-Europe Large Satellite Propulsion System Market (by Hybrid Thruster), $Million, 2024-2040
• Table 55: Rest-of-Europe Large Satellite Propulsion System Market (by Hybrid Thruster), Units, 2024-2040
• Table 56: Companies Manufacturing Hybrid Thrusters
• Table 57: Companies Manufacturing Cold Gas Thrusters
• Table 58: Companies Manufacturing Chemical Thrusters
• Table 59: Companies Manufacturing Electric Thrusters

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Introduction to Europe Large Satellite Propulsion System Market

The Europe large satellite propulsion system market is projected to reach $177.5 million by 2040. The European market for large satellite propulsion systems includes a variety of in-space thrust technologies, including as chemical, electric, cold-gas, and hybrid thrusters, all of which are necessary for heavyweight satellite orbit insertion, station-keeping, and end-of-life maneuvers. Demand in the area is still being driven by the expanding navigation constellations, sophisticated Earth observation platforms, and growing deployment of high-throughput communication satellites, all of which require precision orbit-raising and long-duration station-keeping. In order to provide European space operators with scalable, economical, and sustainable solutions, technological innovations like modular hybrid stages, green chemical propulsion systems, and high-thrust electric Hall-effect thrusters are being embraced more and more. The market is competitive, with both established European manufacturers and global aerospace leaders collaborating with organizations like the European Space Agency (ESA) and national space programs. Procurement strategies are evolving as operators place greater emphasis on propellant efficiency, orbital debris mitigation, and mission flexibility, fueling investment in reusable propulsion systems and next-generation electric architectures. Consequently, Europe's large satellite propulsion system market is undergoing rapid transformation, shaped by technological innovation, growing private-sector participation, and the escalating performance demands of modern satellite missions.

Market Introduction

The market for large satellite propulsion systems in Europe is constantly developing as a result of commercial satellite programs, aggressive government space efforts, and continued investments in cutting-edge in-space mobility technologies. Propulsion technologies, ranging from chemical and electric to cold-gas and hybrid systems, are essential for the insertion of heavy satellite orbits, station-keeping, attitude control, and deorbiting.

Demand across Europe is being driven by the expansion of high-throughput communication satellites, regional navigation constellations like Galileo, and next-generation Earth observation platforms. The European Space Agency (ESA) and national agencies in countries like France, Germany, and Italy are leading high-profile missions, while commercial aerospace businesses are increasingly contributing to innovation and manufacturing skills.

Technological advancements in the area include the increasing use of green chemical propulsion systems, modular hybrid stages made for cost-effectiveness and scalability, and high-thrust electric propulsion like Hall-effect thrusters. Global aerospace leaders and European manufacturers are working together to improve mission flexibility, debris mitigation techniques, and propellant efficiency.

The market for large satellite propulsion systems in Europe is expected to continue evolving due to technological advancements, strategic alliances, and the increasing performance requirements of contemporary satellite missions. This is because of the market's emphasis on sustainability, adherence to strict EU space regulations, and long mission lifetimes.

Market Segmentation

Segmentation: By Subsystem

• Chemical Thruster
  • Propellant Tank
  • Pump
  • Fuel and Oxidizer Valve
• Electric Thruster
  • Propellant Tank
  • Pump
• Cold Gas Thruster
  • Gas Storage Tank
  • Propulsion Chamber/Nozzle
  • Pump
• Hybrid Thruster
  • Propellant Tank
  • Propulsion Chamber/Nozzle
• Pump

Segmentation 2: by Region

• Europe

Europe Large Satellite Propulsion System Market Trends, Drivers and Challenges

Market Trends

• Increasing adoption of high-thrust electric propulsion systems, including Hall-effect thrusters, for geostationary and deep-space missions.
• Growing integration of green chemical propellants to meet EU sustainability and safety regulations.
• Expansion of European mega-constellation projects for broadband internet coverage.
• Rising use of modular and hybrid propulsion architectures to enhance mission flexibility.
• Strengthened collaboration between ESA, national agencies, and private aerospace firms for R&D and manufacturing.

Key Market Drivers

• Strong government funding through ESA and national space programs to advance indigenous propulsion technologies.
• Rising demand for high-throughput communication and Earth observation satellites in both civil and defense sectors.
• Strategic emphasis on space autonomy to reduce dependence on non-European propulsion systems.
• Growing commercial space activity driven by NewSpace companies across the region.

Challenges

• High development and qualification costs for next-generation propulsion systems.
• Stringent compliance requirements with EU space safety and debris mitigation policies.
• Competition from established non-European propulsion providers.
• Limited availability of certain raw materials and components, creating supply chain vulnerabilities.

How can this report add value to an organization?

Product/Innovation Strategy: The product segment helps the reader understand the different types of products available in the Europe region. Moreover, the study provides the reader with a detailed understanding of the large satellite propulsion system market by products based on propulsion subsystems.

Growth/Marketing Strategy: The Europe large satellite propulsion system market has seen major development by key players operating in the market, such as business expansion, partnership, collaboration, and joint venture. The favored strategy for the companies has been synergistic activities to strengthen their position in the large satellite propulsion system market.

Methodology: The research methodology design adopted for this specific study includes a mix of data collected from primary and secondary data sources. Both primary resources (key players, market leaders, and in-house experts) and secondary research (a host of paid and unpaid databases), along with analytical tools, have been employed to build the predictive and forecast models.

Table of Contents

Executive Summary

Market/Product Definition

1 Regions

• 1.1 Large Satellite Propulsion System Market (by Region)
  • 1.1.1 Europe
    • 1.1.1.1 Europe Large Satellite Propulsion System Market (by Subsystem)
    • 1.1.1.2 Europe (by Country)
      • 1.1.1.2.1 France
        • 1.1.1.2.1.1 France Large Satellite Propulsion System Market (by Subsystem)
      • 1.1.1.2.2 Germany
        • 1.1.1.2.2.1 Germany Large Satellite Propulsion System Market (by Subsystem)
      • 1.1.1.2.3 U.K.
        • 1.1.1.2.3.1 U.K. Large Satellite Propulsion System Market (by Subsystem)
      • 1.1.1.2.4 Rest-of-Europe
        • 1.1.1.2.4.1 Rest-of-Europe Large Satellite Propulsion System Market (by Subsystem)

2 Thruster and Regulatory Analysis

• 2.1 Analysis of Thrusters (by Application)
  • 2.1.1 Hybrid Thruster
    • 2.1.1.1 Maneuvering and Attitude Control
    • 2.1.1.2 End-of-Life Deorbiting
    • 2.1.1.3 Orbit Transfer
    • 2.1.1.4 Docking
    • 2.1.1.5 Station Keeping (Impulse Bits)
    • 2.1.1.6 In-Orbit Transportation
  • 2.1.2 Cold Gas Thruster
    • 2.1.2.1 Maneuvering and Attitude Control of Satellites
    • 2.1.2.2 Astronaut Maneuvering (Spacewalk)
    • 2.1.2.3 End-of-Life Deorbiting
    • 2.1.2.4 Reaction Wheel Unloading
    • 2.1.2.5 Orbit Transfer
    • 2.1.2.6 Launch Vehicle Roll Control
  • 2.1.3 Chemical Thruster (Hot and Warm Gas)
    • 2.1.3.1 Maneuvering and Attitude Control
    • 2.1.3.2 Landing Control for Interplanetary Landers
    • 2.1.3.3 Launch Vehicle Roll Control
  • 2.1.4 Electric Thruster
    • 2.1.4.1 Maneuvering and Orientation Control
    • 2.1.4.2 Primary Propulsion for Deep Space Missions
    • 2.1.4.3 Attitude Control for Microsatellites
    • 2.1.4.4 Station Keeping (Impulse Bits)
  • 2.1.5 Analyst Perspective
• 2.2 Regulatory Analysis (by Country)
  • 2.2.1 U.K.
    • 2.2.1.1 The Space Industry Regulations 2021
    • 2.2.1.2 European Space Agency (ESA) Industrial Policy Committee
    • 2.2.1.3 European Cooperation for Space Standardization/Slovenian Institute for Standardization (SIST)
      • 2.2.1.3.1 SIST EN 16603-35:2014
      • 2.2.1.3.2 ECSS-E-ST-35-06
  • 2.2.2 France
    • 2.2.2.1 Centre National D'Etudes Spatiales (CNES)
  • 2.2.3 Germany
    • 2.2.3.1 Germany Federal Office of Economics and Export Control (BAFA)
      • 2.2.3.1.1 Regulation (EU) 2021/821 - Dual-Use Export Controls

3 Research Methodology

• 3.1 Data Sources
  • 3.1.1 Primary Data Sources
  • 3.1.2 Secondary Data Sources
• 3.2 Data Triangulation