火箭电动帮浦市场 - 全球与区域分析：按最终用户、火箭类别、帮浦类型和国家进行分析和预测（2025-2035 年）

电动火箭泵市场透过提供比传统涡轮泵系统更简单、更具成本效益和永续的替代方案，在改变现代太空推进方面发挥关键作用。

先进的电池供电电动帮浦引擎因其降低的复杂性、更高的可靠性和重启能力，对小型运载火箭和上面级的发展至关重要。随着商业卫星发射、可重复使用太空系统和混合动力推进技术的加速应用，对高效能电动帮浦的需求空前高涨。电动帮浦可提供精确的推进剂输送、低维护要求和灵活的任务操作，使其成为新型太空任务的基础。有效的实施可以降低发射成本，整合绿色推进剂，并推动可重复使用平台的发展，从而使电动泵成为支持全球太空经济下一阶段发展的关键驱动力。

主要市场统计数据
预测期	2025-2035
2025年评估	4590万美元
2035年预测	7100万美元
复合年增长率	4.46%

市场概览

在现实情境下，全球电动火箭帮浦市场规模预计将从2024年的3,350万美元成长到2035年的7,100万美元，预测期间（2025-2035年）的复合年增长率为4.46%。预计这一成长轨迹将受到卫星星系需求成长、深空探勘力度加大以及私营发射运营商作用不断扩大等因素的支持。

电池能量密度提升、积层製造和混合电力推进设计等技术进步，使得电动帮浦能够应用于新的任务领域。虽然目前的应用主要集中在小型运载火箭上，例如 Rocket Lab 的 Electron 火箭，但未来将其整合到中型运载火箭和轨道级中变得越来越可行。

从最终用户来看，商业发射运营商引领市场

商业发射业者仍然是关键客户，预计将从2024年的3,090万美元成长到2035年的6,280万美元。该细分市场的主导地位是基于实际计算。小型发射专案需要可靠、可重新启动的推进系统，用于卫星群建造、共享卫星的分散式发射以及精确的入轨机动。电动泵送推进系统透过减少活动部件数量和消除热气管道来缩短设计週期，并且更容易整合到上面级的有限空间中。对于面临进度和成本限制的营运商而言，模组化、可重启性和可製造性的结合是关键优势。

依火箭等级划分，小型运载火箭引领市场

小型运载火箭市场预计将从2024年的3,350万美元成长到2035年的6,910万美元。电动帮浦非常适合此推力范围，能够实现精确的油门控制、干净的重启和多次燃烧，使其成为敏捷分级、卫星群分阶段和灵活发射的理想选择。对于开发人员而言，从压力供料系统转向电动泵循环可以提高燃烧室压力和性能，而无需承担涡轮泵的全部复杂性，因此对于质量、体积和集成时间至关重要的快速推进项目来说，电动泵是一个颇具吸引力的临时解决方案。

按帮浦类型划分，燃油供给帮浦引领市场

燃油输送帮浦主导市场，预计将从2024年的2,520万美元成长到2035年的5,470万美元。输送泵是电动帮浦引擎的核心，负责设定燃烧室压力、控製油门范围，并支援液体和混合动力引擎的多次重启。它们的核心作用，以及透过预先认证的电动帮浦+控制器套件实现模组化的途径，解释了这个细分市场的规模和稳定性。

按地区划分，北美领先市场

北美继续保持区域领先地位，这得益于其拥有唯一商业性运营的电动泵送轨道运载火箭、众多级间集成商和电动泵专家，以及公共和私人对小型发射服务的投资。该地区的活动得益于其测试和认证基础设施、强大的增材製造能力以及低温硬体和电子元件供应网路。北美市场预计将从2024年的29,201,100美元增长至2035年的58,219,700美元，而欧洲和亚太地区预计将在2030年代实现增长，这得益于小型发射活动、上面级概念以及混合电力推进演示的增加。

本报告调查了全球火箭电动帮浦市场，并总结了主要趋势、市场影响因素分析、法律制度、技术和专利分析、市场规模趋势和预测、各个细分市场、地区/主要国家的详细分析、竞争格局和主要企业的概况。

目录

执行摘要

范围和定义

第一章市场：产业展望

• 趋势：现况与未来影响评估
  • 液态推进剂火箭广泛采用电动泵
  • 泵送推进技术研究与发展进展.
  • 扩大低推力电力推进的应用
• 供应链概览
  • 价值链分析
• 监管状况
• 研发评审
  • 专利申请趋势（按国家和公司）
• 相关利益者分析
  • 使用案例
  • 最终用户和购买标准
• 正在进行的贸易政策分析
• 市场动态
  • 市场驱动因素
  • 市场挑战
  • 市场机会

第二章 应用

• 使用摘要
• 火箭电动帮浦市场（按最终用户划分）
  • 商业发射运营商
  • 政府/私人太空计划
• 火箭电动帮浦市场（依火箭类别）
  • 小型运载火箭
  • 中型和大型运载火箭

第三章 产品

• 产品摘要
• 火箭市场电动帮浦（按帮浦类型）
  • 燃油供给帮浦
  • 引擎冷却泵

第四章 区域

• 区域摘要
• 北美洲
  • 市场成长动力
  • 市场问题
  • 按用途
  • 按产品
  • 按国家
• 欧洲
  • 市场成长动力
  • 市场问题
  • 按用途
  • 按产品
  • 按国家
• 亚太地区
  • 市场成长动力
  • 市场问题
  • 按用途
  • 按产品
  • 按国家
• 其他地区
  • 市场成长动力
  • 市场问题
  • 按用途
  • 按产品
  • 按地区

第五章市场：竞争基准化分析与公司概况

• 下一个前沿
• 地理评估
• 公司简介
  • Rocket Lab USA, Inc.
  • Impraise Systems
  • Ebara Corporation
  • Sierra Space Corporation
  • Innospace Co., Ltd.
  • Kratos Defense & Security Solutions, Inc.
  • Nammo AS
  • P3 Technologies, LLC
  • Concept NREC
  • Gilmour Space Technologies

第六章调查方法

This report can be delivered within 1 working day.

Introduction to the Electric Pumps for Rocket Market

The electric pumps for rocket market plays a pivotal role in transforming modern space propulsion by offering a simpler, more cost-effective, and sustainable alternative to traditional turbopump systems. Electric pump-fed engines, powered by advanced batteries, have become central to the evolution of small-lift rockets and upper stages due to their reduced complexity, enhanced reliability, and restart capabilities. As the adoption of commercial satellite launches, reusable space systems, and hybrid propulsion accelerates, the need for efficient electric pumps has never been more critical. Electric pumps ensure precise propellant delivery, lower maintenance needs, and improved mission flexibility, making them a cornerstone of emerging space missions. Effective adoption supports lower launch costs, green propellant integration, and the advancement of reusable platforms, positioning electric pumps as a key enabler of the next phase of the global space economy.

KEY MARKET STATISTICS
Forecast Period	2025 - 2035
2025 Evaluation	$45.9 Million
2035 Forecast	$71.0 Million
CAGR	4.46%

Market Introduction

In 2024, the global electric pumps for rocket market was valued at $33.5 million under a realistic scenario and is projected to reach $71.0 million by 2035, growing at a CAGR of 4.46% from the forecast period 2025-2035. Its growth trajectory is expected to be fueled by several factors, including the rising demand for satellite constellations, the push for deep-space exploration, and the growing role of private launch providers.

Technological advancements in battery energy density, additive manufacturing, and hybrid-electric propulsion designs are enabling the scaling of electric pumps into new mission profiles. While adoption is currently concentrated in small-lift vehicles such as Rocket Lab's Electron, future integration into medium-class launchers and orbital transfer stages is becoming increasingly feasible.

Key stakeholders in the market include commercial launch companies, government space agencies, propulsion system developers, and aerospace research institutions. Collectively, they are driving innovations to expand the role of electric pumps beyond niche applications, while addressing challenges such as battery mass limitations and competition from established turbopump architectures.

Market Impact

The electric pumps for rocket market is poised to make a substantial impact on both the economy and the environment. As the demand for small-satellite launches, CubeSats, and deep-space missions continues to rise, the adoption of efficient electric pumps becomes increasingly critical.

Economic Impact

The market will contribute to innovation and competitiveness by lowering propulsion system complexity and development costs.

Startups and new entrants gain opportunities through modular pump architectures and reduced barriers to entry.

Supports the expansion of satellite launches and orbital transfer missions, enhancing the commercial space economy.

Environmental Impact

• Facilitates the adoption of green propellants such as methane and hydrogen, reducing carbon footprint.
• Enhances reusability and modularity, reducing material waste in launch systems.
• Improves operational sustainability by enabling multiple restarts and efficient mission flexibility.

The expansion of this market will also support the transition to a more sustainable and modular space industry. Electric pumps enable design simplicity, cost-effectiveness, and compatibility with reusable rockets, making them an essential part of future propulsion architectures.

Industrial Impact

Electrically driven pump-fed architectures are reshaping propulsion development workflows, vendor ecosystems, and qualification pathways. On the hardware side, the bill of materials is pivoting toward high-speed electric machines, cryogenic-capable bearings and seals, ruggedized power electronics, and battery systems qualified for rapid discharge and extreme thermal cycling. That shift is accelerating additive manufacturing for impellers, housings, and tight-tolerance interfaces, shortening iteration loops and compressing lead times from prototype to hot-fire. The result is a supply chain that increasingly combines precision machining + AM, high-reliability electronics, and subsystem bundling (motor-pump, controller, and thermal interfaces as an integrated kit) to de-risk program schedules.

At the same time, test and certification activity is migrating upstream; more flow benches, cryo-loops, and endurance rigs are being added at the pump supplier level so launch primes can accept "pre-qualified" line-replaceable units. This unlocks a lighter integration burden at the stage/vehicle level, especially for small-lift and upper-stage modules that value modular, restartable units over bespoke turbomachinery. The model favors specialist pump houses and motor-drive firms partnering closely with launch primes and stage integrators, while opening space for new entrants, particularly those with AM competencies and COTS-hardened power electronics to participate in orbital-class propulsion programs.

Market Segmentation

Segmentation 1: by End User

• Commercial Launch Providers
• Government / Civil Space Programs

Commercial Launch Providers to Lead the Electric Pumps for Rocket Market (by End User)

Commercial launch providers remain the anchor customer, rising from $30.9 million in 2024 to $62.8 million by 2035. The segment's leadership reflects a pragmatic calculus; small-lift programs need reliable, restartable propulsion for constellation buildout, rideshare dispersion, and precise injection maneuvers. Electrically driven pump-fed architectures reduce moving-part counts and eliminate hot-gas plumbing, shortening design cycles and easing integration into tightly packaged upper stages. For providers under schedule and cost pressure, that combination of modularity, restartability, and manufacturability is decisive.

A second growth engine is the standardization of motor-pump kits, pre-qualified, cryo-capable units bundled with controllers and thermal interfaces. This enables repeatable propulsion stacks across vehicle variants and block upgrades without re-engineering turbomachinery, so teams can scale flight cadence with fewer unique parts and faster subsystem swaps. Commercial teams also benefit from COTS-hardened power electronics and additive manufacturing (AM) of impellers/housings, which reduce lead times for spares and iterative tweaks discovered during flight ops. The net effect is a virtuous loop; more launches are expected to drive more reuse and learning, which will compress non-recurring engineering and sustain the commercial segment's lead through 2035.

Segmentation 2: by Rocket Class

• Small-Lift Launch Vehicles
• Medium and Heavy-Lift Vehicles

Small-Lift Launch Vehicles to Dominate the Electric Pumps for Rocket Market (by Rocket Class)

Small-lift launch vehicles lead the class mix, expanding from $33.5 million in 2024 to $69.1 million by 2035. Electric pumps are naturally suited to this thrust regime; they deliver precise throttling, clean restarts, and multi-burn profiles without hot-gas turbines, making them ideal for agile staging, constellation phasing, and responsive launch. For developers, moving from pressure-fed systems to electric-pump cycles elevates chamber pressure and performance without inheriting full turbopump complexity, an attractive middle ground for fast-moving programs where mass, volume, and integration time are precious.

As constellation deployment proliferates and upper stages shoulder more on-orbit maneuvering, small-lift platforms remain the primary beachhead for electric pump-fed cycles. Meanwhile, early beachheads in medium/heavy-lift roles will likely emerge in upper stages and specialty modules as pack-level energy density and thermal mitigation improve. This progression keeps small-lift dominant through the forecast while allowing selective migration upward as engineering trade-offs evolve.

Segmentation 3: by Pump Type

• Fuel Feed Pumps
• Engine Cooling Pumps

Fuel Feed Pumps to Lead the Electric Pumps for Rocket Market (by Pump Type)

Fuel feed pumps are the dominant product, growing from $25.2 million in 2024 to $54.7 million by 2035. Feed pumps sit at the heart of electric pump-fed engines; they set chamber pressure, enable throttling windows, and support multi-restart profiles across both liquid and hybrid engines. Their centrality to the propulsion bill of materials and the path to modularization via pre-qualified motor-pump + controller kits explains the segment's scale and resilience.

By contrast, engine-cooling pumps remain a smaller niche, increasing from $8.3 million to $16.3 million. Many architectures route regenerative cooling through the main feed loop or rely on hybrid designs where dedicated cooling pumps are unnecessary, especially in small-lift stages where simplicity and mass efficiency are paramount. The growth that does occur is tied to longer burns and higher chamber heat flux, where independent thermal circuits buy extra margin for reusable upper stages.

Segmentation 4: by Region

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

North America to Lead the Electric Pumps for Rocket Market (by Region)

North America retains regional leadership, supported by the only commercially operational electric-pump orbital vehicle, a dense cluster of stage integrators and motor-pump specialists, and sustained public-private investment in small-lift services. Regional activity is underpinned by test/qualification infrastructure, strong AM capacity, and supply networks for cryogenic hardware and electronics. North America is expected to scale from $29,201.1 thousand in 2024 to $58,219.7 thousand by 2035, while Europe and Asia-Pacific expand off rising small-lift activity, upper-stage concepts, and hybrid-electric propulsion pilots through the 2030s.

Crucially, the region's certification and operations ecosystem, from vacuum and vibration labs to range access and on-orbit operations, reduces integration risk and time-to-flight for pump-fed stacks. As commercial providers push cadence and multi-mission flexibility, North America's combination of industrial depth + program throughput maintains its lead while other regions close the gap via targeted upper-stage and OTV deployments.

Demand: Drivers, Limitations, and Opportunities

Market Demand Drivers: Constellations, Upper-Stage Maneuvering, and Modularization

The primary pull is constellation logistics, frequent, precise insertions, and phasing maneuvers that reward restartable, throttleable upper stages. Electric pumps simplify engine plumbing, reduce moving-part counts, and support multi-burn operations without hot-gas turbines, which is compelling for small-lift and OTV missions where packaging space, fast turnarounds, and mission agility dominate. For manufacturers, AM-enabled impellers/housings, COTS-hardened drives, and pre-qualified subassemblies compress schedule risk, allowing faster debug cycles and more launches per year. As agencies and primes prioritize responsive launch, electric pumps' plug-and-play behavior fits quick-turn stage ops and modular upper-stage stacks that can be mixed, matched, and serviced with minimal re-engineering.

The second driver is modularity, Modular motor-pump units and clean, electrically driven plumbing reduce refurbishment touch labor between sorties. Combined with maturing thermal mitigation and controller health monitoring, programs can extend useful life and restart counts, improving economics for high-cadence commercial services and deepening the business case for electric pumps in upper-stage fleets.

Market Challenges: Pack-Level Energy Density, Thermal Management, and Turbopump Heritage

The binding constraint remains pack-level specific energy; while cell chemistries trend upward, complete battery packs (cooling, containment, safety, BMS) lag, limiting burn duration and thrust scalability for larger cores. High-rate discharge drives thermal and lifetime stresses that must be mitigated by cooling and protective structures, adding mass and eroding the benefits at higher thrust classes. In parallel, entrenched turbopump heritage with decades of flight records and a deep vendor ecosystem sets a formidable benchmark for reliability, especially in medium/heavy-lift environments where energy density shortfalls are most acute. In the near term, this confines most electric-pump roles to small-lift vehicles and upper stages while the tech matures.

Engineering headwinds also include cavitation control at cryogenic inlets, high-speed bearing durability, and controller fault-tolerance across long burns. Each solution tends to trade mass for margin (e.g., additional cooling, shielding, or redundancy), which can dilute the system-level gains for bigger vehicles unless pack performance advances in tandem.

Market Opportunities: Small-Lift Standardizations, Hybrid-Electric Upper Stages, and Regional Ecosystems

Standardized small-lift motor-pump kits with proven cryo performance, restart matrices, and life-test artifacts can be replicated across families and block upgrades, amplifying fleet commonality and spare pooling. In upper stages, hybrid-electric concepts (electric feeds + regenerative cooling or hybrid motors) offer a tractable bridge into higher-energy missions while pack technologies catch up, enabling precise delta-V trim, long loiter, and multi-destination profiles. Regionally, North America's large test base and AM footprint, Europe's cryogenic pump R&D, and Asia-Pacific's growing small-lift cohort open JV and licensing pathways that share NRE and accelerate commercialization of cryo-capable electric pumps through 2035. These partnerships are already visible in the supplier and program maps captured in the report's regional and product breakouts.

How can this report add value to an organization?

Product/Innovation Strategy: This report offers valuable insights into advancements in electric pump-fed propulsion technologies and solutions. By gaining a comprehensive understanding of the market and evaluating the associated challenges and opportunities, stakeholders can assess the potential impact on their operations. It enables organizations to identify emerging technologies and trends in electric pump development, allowing them to align their innovation strategies and stay competitive in this evolving market.

Growth/Marketing Strategy: The electric pumps for rocket market is growing steadily, driven by the rising adoption of small satellite launch vehicles and hybrid propulsion solutions. Companies are forming strategic partnerships and expanding operations to capture this demand. By offering advanced propulsion solutions that emphasize efficiency, sustainability, and modularity, organizations can tap into new markets, optimize mission architectures, and enhance brand positioning in the global space industry.

Competitive Strategy: The report provides detailed analysis and profiling of key players in the electric pumps for rocket market, including Rocket Lab, Innospace, Ebara Corporation, Sierra Space, and Gilmour Space Technologies. It thoroughly examines market dynamics and the competitive landscape, enabling readers to understand positioning and strategies across the industry. This allows organizations to refine competitive strategies and identify opportunities for differentiation and growth.

Research Methodology

Factors for Data Prediction and Modelling

• The base currency considered for the electric pumps for rocket market analysis is the US$. Currencies other than the US$ have been converted to the US$ for all statistical calculations, considering the average conversion rate for that particular year.
• The currency conversion rate has been taken from the historical exchange rate of the Oanda website.
• The information in this report is based on in-depth primary interviews, surveys, and secondary analysis.
• Where relevant information was not available, proxy indicators and extrapolation were employed.
• Any economic downturn in the future has not been taken into consideration for the market estimation and forecast.
• Technologies currently in use are expected to persist, with no major breakthroughs assumed during the forecast horizon.

Market Estimation and Forecast

The electric pumps for rocket market research study involves the usage of extensive secondary sources, such as certified publications, articles from recognized authors, white papers, annual reports of companies, directories, and major databases to collect useful and effective information for an extensive, technical, market-oriented, and commercial study of the lithium-ion battery recycling market.

The market engineering process involves the calculation of the market statistics, market size estimation, market forecast, market crackdown, and data triangulation (the methodology for such quantitative data processes has been explained in further sections). The primary research study has been undertaken to gather information and validate the market numbers for segmentation types and industry trends of the key players in the market.

Primary Research

The primary sources involve industry experts from the electric pumps for rocket market and various stakeholders in the ecosystem. Respondents such as CEOs, vice presidents, marketing directors, and technology and innovation directors have been interviewed to obtain and verify both qualitative and quantitative aspects of this research study.

The key data points taken from primary sources include:

• validation and triangulation of all the numbers and graphs
• validation of report segmentations and key qualitative findings
• understanding the competitive landscape
• validation of the numbers of various markets for the market type
• percentage split of individual markets for geographical analysis

Secondary Research

The electric pumps for rocket market research study involves the usage of extensive secondary research, directories, company websites, and annual reports. It also makes use of databases, such as Hoovers, Bloomberg, Businessweek, and Factiva, to collect useful and effective information for an extensive, technical, market-oriented, and commercial study of the global market. In addition to the data sources, the study has been undertaken with the help of other data sources and websites, such as the Census Bureau, OICA, and ACEA.

Secondary research has been done to obtain crucial information about the industry's value chain, revenue models, the market's monetary chain, the total pool of key players, and the current and potential use cases and applications.

The key data points taken from secondary research include:

• market segmentations and shares
• data for market value
• key industry trends of the top players in the market
• qualitative insights into various aspects of the market, key trends, and emerging areas of innovation
• quantitative data for mathematical and statistical calculations

Table of Contents

Executive Summary

Scope and Definition

1 Market: Industry Outlook

• 1.1 Trends: Current and Future Impact Assessment
  • 1.1.1 Widespread Adoption of Electric Pumps in Liquid-Propellant Rockets
  • 1.1.2 Rising Research and Development in Pump-Fed Propulsion
  • 1.1.3 Rising Adoption of Low-Thrust Electric Propulsion
• 1.2 Supply Chain Overview
  • 1.2.1 Value Chain Analysis
• 1.3 Regulatory Landscape
• 1.4 Research and Development Review
  • 1.4.1 Patent Filing Trend (by Country, and Company)
• 1.5 Stakeholder Analysis
  • 1.5.1 Use Case
    • 1.5.1.1 Case Study - Space Zone India - RHUMI-1 Reusable Hybrid Rocket (2024)
  • 1.5.2 End User and Buying Criteria
• 1.6 Ongoing Trade Policies Analysis
• 1.7 Market Dynamics
  • 1.7.1 Market Drivers
    • 1.7.1.1 Rising Demand for Satellite and Deep-Space Missions
    • 1.7.1.2 Efficiency Gains and Cost Reduction in Electric Pumps as Compared to Conventional Turbopumps
  • 1.7.2 Market Challenges
    • 1.7.2.1 Complexities Associated with Added Mass and Costs of High-Performance Batteries
    • 1.7.2.2 Intense Competition from Established Turbopump and Hybrid Systems
  • 1.7.3 Market Opportunities
    • 1.7.3.1 Rising Popularity of Small Launchers, CubSats, and Upper Stages

2 Application

• 2.1 Application Summary
• 2.2 Electric Pumps for Rocket Market (by End-User)
  • 2.2.1 Commercial Launch Providers
  • 2.2.2 Government/ Civil Space Programs
• 2.3 Electric Pumps for Rocket Market (by Rocket Class)
  • 2.3.1 Small-Lift Launch Vehicles
  • 2.3.2 Medium and Heavy-Lift Vehicles

3 Products

• 3.1 Product Summary
• 3.2 Electric Pumps for Rocket Market (by Pump Type)
  • 3.2.1 Fuel Feed Pumps
  • 3.2.2 Engine Cooling Pumps

4 Region

• 4.1 Regional Summary
• 4.2 North America
  • 4.2.1 Driving Factors for Market Growth
  • 4.2.2 Factors Challenging the Market
  • 4.2.3 Application
  • 4.2.4 Product
  • 4.2.5 North America by Country
    • 4.2.5.1 U.S.
      • 4.2.5.1.1 Application
      • 4.2.5.1.2 Product
    • 4.2.5.2 Canada
      • 4.2.5.2.1 Application
      • 4.2.5.2.2 Product
• 4.3 Europe
  • 4.3.1 Driving Factors for Market Growth
  • 4.3.2 Factors Challenging the Market
  • 4.3.3 Application
  • 4.3.4 Product
  • 4.3.5 Europe by Country
    • 4.3.5.1 Germany
      • 4.3.5.1.1 Application
      • 4.3.5.1.2 Product
    • 4.3.5.2 France
      • 4.3.5.2.1 Application
      • 4.3.5.2.2 Product
    • 4.3.5.3 U.K.
      • 4.3.5.3.1 Application
      • 4.3.5.3.2 Product
    • 4.3.5.4 Italy
      • 4.3.5.4.1 Application
      • 4.3.5.4.2 Product
    • 4.3.5.5 Spain
      • 4.3.5.5.1 Application
      • 4.3.5.5.2 Product
    • 4.3.5.6 Rest-of-Europe
      • 4.3.5.6.1 Application
      • 4.3.5.6.2 Product
• 4.4 Asia-Pacific
  • 4.4.1 Driving Factors for Market Growth
  • 4.4.2 Factors Challenging the Market
  • 4.4.3 Application
  • 4.4.4 Product
  • 4.4.5 Asia-Pacific by Country
    • 4.4.5.1 China
      • 4.4.5.1.1 Application
      • 4.4.5.1.2 Product
    • 4.4.5.2 Japan
      • 4.4.5.2.1 Application
      • 4.4.5.2.2 Product
    • 4.4.5.3 South Korea
      • 4.4.5.3.1 Application
      • 4.4.5.3.2 Product
    • 4.4.5.4 India
      • 4.4.5.4.1 Application
      • 4.4.5.4.2 Product
    • 4.4.5.5 Rest-of-Asia-Pacific
      • 4.4.5.5.1 Application
      • 4.4.5.5.2 Product
• 4.5 Rest-of-the-World
  • 4.5.1 Driving Factors for Market Growth
  • 4.5.2 Factors Challenging the Market
  • 4.5.3 Application
  • 4.5.4 Product
  • 4.5.5 Rest-of-the-World by Region
    • 4.5.5.1 Middle East and Africa
      • 4.5.5.1.1 Application
      • 4.5.5.1.2 Product
    • 4.5.5.2 Latin America
      • 4.5.5.2.1 Application
      • 4.5.5.2.2 Product

5 Markets - Competitive Benchmarking & Company Profiles

• 5.1 Next Frontiers
• 5.2 Geographic Assessment
• 5.3 Company Profiles
  • 5.3.1 Rocket Lab USA, Inc.
    • 5.3.1.1 Overview
    • 5.3.1.2 Top Competitors
    • 5.3.1.3 Target Customers
    • 5.3.1.4 Key Personal
    • 5.3.1.5 Analyst View
    • 5.3.1.6 Market Share, 2024
  • 5.3.2 Impraise Systems
    • 5.3.2.1 Overview
    • 5.3.2.2 Top Products/Product Portfolio
    • 5.3.2.3 Top Competitors
    • 5.3.2.4 Target Customers
    • 5.3.2.5 Key Personal
    • 5.3.2.6 Analyst View
  • 5.3.3 Ebara Corporation
    • 5.3.3.1 Overview
    • 5.3.3.2 Top Products/Product Portfolio
    • 5.3.3.3 Top Competitors
    • 5.3.3.4 Target Customers
    • 5.3.3.5 Key Personal
    • 5.3.3.6 Analyst View
    • 5.3.3.7 Market Share, 2024
  • 5.3.4 Sierra Space Corporation
    • 5.3.4.1 Overview
    • 5.3.4.2 Top Competitors
    • 5.3.4.3 Target Customers
    • 5.3.4.4 Key Personal
    • 5.3.4.5 Analyst View
    • 5.3.4.6 Market Share, 2024
  • 5.3.5 Innospace Co., Ltd.
    • 5.3.5.1 Overview
    • 5.3.5.2 Top Products/Product Portfolio
    • 5.3.5.3 Top Competitors
    • 5.3.5.4 Target Customers
    • 5.3.5.5 Key Personal
    • 5.3.5.6 Analyst View
    • 5.3.5.7 Market Share, 2024
  • 5.3.6 Kratos Defense & Security Solutions, Inc.
    • 5.3.6.1 Overview
    • 5.3.6.2 Top Competitors
    • 5.3.6.3 Target Customers
    • 5.3.6.4 Key Personal
    • 5.3.6.5 Analyst View
    • 5.3.6.6 Market Share, 2024
  • 5.3.7 Nammo AS
    • 5.3.7.1 Overview
    • 5.3.7.2 Top Competitors
    • 5.3.7.3 Target Customers
    • 5.3.7.4 Key Personal
    • 5.3.7.5 Analyst View
    • 5.3.7.6 Market Share, 2024
  • 5.3.8 P3 Technologies, LLC
    • 5.3.8.1 Overview
    • 5.3.8.2 Top Competitors
    • 5.3.8.3 Target Customers
    • 5.3.8.4 Key Personal
    • 5.3.8.5 Analyst View
    • 5.3.8.6 Market Share, 2024
  • 5.3.9 Concept NREC
    • 5.3.9.1 Overview
    • 5.3.9.2 Top Competitors
    • 5.3.9.3 Target Customers
    • 5.3.9.4 Key Personal
    • 5.3.9.5 Analyst View
    • 5.3.9.6 Market Share, 2024
  • 5.3.10 Gilmour Space Technologies
    • 5.3.10.1 Overview
    • 5.3.10.2 Top Competitors
    • 5.3.10.3 Target Customers
    • 5.3.10.4 Key Personal
    • 5.3.10.5 Analyst View
    • 5.3.10.6 Market Share, 2024

6 Research Methodology

• 6.1 Data Sources
  • 6.1.1 Primary Data Sources
  • 6.1.2 Secondary Data Sources
  • 6.1.3 Data Triangulation
• 6.2 Market Estimation and Forecast

List of Figures

• Figure 1: Global Electric Pumps for Rocket Market (by Scenario), $Million, 2025, 2030, and 2035
• Figure 2: Global Electric Pumps for Rocket Market, 2024-2035
• Figure 3: Top 5 Countries, Global Electric Pumps for Rocket Market, $Million, 2024
• Figure 4: Global Market Snapshot, 2024
• Figure 5: Global Electric Pumps for Rocket Market, $Million, 2024 and 2035
• Figure 6: Electric Pumps for Rocket Market (by Platform), $Million, 2024, 2030, and 2035
• Figure 7: Electric Pumps for Rocket Market (by Rocket Class), $Million, 2024, 2030, and 2035
• Figure 8: Electric Pumps for Rocket Market (by Product), $Million, 2024, 2030, and 2035
• Figure 9: Electric Pumps for Rocket Market Segmentation
• Figure 10: Supply Chain Analysis
• Figure 11: Value Chain Analysis
• Figure 12: Satellite and Deep-Space Missions: Driving the Electric Pump Proplusion Revolution
• Figure 13: Projected Global Stationary Battery Storage Capacity (by Scenario), 2020-2050
• Figure 14: Global Electric Pumps for Rocket Market (by End-User), $Million, 2024, 2030, and 2035
• Figure 15: Global Electric Pumps for Rocket Market (by Rocket Class), $Million, 2024, 2030, and 2035
• Figure 16: Global Electric Pumps for Rocket Market, Commercial Launch Providers Value, $Million, 2024-2035
• Figure 17: Global Electric Pumps for Rocket Market, Government/ Civil Space Programs Value, $Million, 2024-2035
• Figure 18: Global Electric Pumps for Rocket Market, Small-Lift Launch Vehicles Value, $Million, 2024-2035
• Figure 19: Global Electric Pumps for Rocket Market, Medium and Heavy-Lift Vehicles Value, $Million, 2024-2035
• Figure 20: Global Electric Pumps for Rocket Market, (by Pump Type) Value, $Million, 2024, 2030, and 2035
• Figure 21: Global Electric Pumps for Rocket Market, Fuel Feed Pumps Value, $Million, 2024-2035
• Figure 22: Global Electric Pumps for Rocket Market, Engine Cooling Pumps Value, $Million, 2024-2035
• Figure 23: U.S. Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 24: Canada Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 25: Germany Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 26: France Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 27: U.K. Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 28: Italy Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 29: Spain Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 30: Rest-of-Europe Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 31: China Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 32: Japan Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 33: South Korea Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 34: India Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 35: Rest-of-Asia-Pacific Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 36: Middle East and Africa Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 37: Latin America Electric Pumps for Rocket Market, $Thousand, 2024-2035
• Figure 38: Data Triangulation
• Figure 39: Top-Down and Bottom-Up Approach
• Figure 40: Assumptions and Limitations

List of Tables

• Table 1: Market Snapshot
• Table 2: Competitive Landscape Snapshot
• Table 3: Trends: Current and Future Impact Assessment
• Table 4: Key Organizations Contributing to the Growth of Liquid-Propellant Rockets
• Table 5: Key Organizations Contributing to the Growth of Pump-Fed Propulsion
• Table 6: Regulatory/Certification Bodies in Electric Pumps for Rocket Market
• Table 7: Key Electric Pump for Rocket Engine Patents, By Country and Company
• Table 8: Key Operational Use Cases for Electric Pumps for Rocket Market
• Table 9: Primary End Users of Electric Pumps for Rocket Market and their Operational Focus
• Table 10: Electric Pump for Rocket Procurement Drivers - Core Buying Criteria and Industry Examples
• Table 11: Country/Region Specific Policies in Electric Pumps for Rocket Market
• Table 12: Drivers, Challenges, and Opportunities, 2024-2035
• Table 13: Lower Cost, Higher Performance Electric Pumps Leading in Rocket Propulsion Technology
• Table 14: Electric Pumps for Rocket Market (by Region), $Thousand, 2024-2035
• Table 15: North America Electric Pumps for Rocket Market (by End User), $Thousand, 2024-2035
• Table 16: North America Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 17: North America Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 18: U.S. Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 19: U.S. Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 20: U.S. Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 21: Canada Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 22: Canada Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 23: Canada Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 24: Europe Electric Pumps for Rocket Market (by End User), $Thousand, 2024-2035
• Table 25: Europe Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 26: Europe Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 27: Germany Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 28: Germany Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 29: Germany Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 30: France Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 31: France Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 32: France Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 33: U.K. Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 34: U.K. Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 35: U.K. Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 36: Italy Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 37: Italy Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 38: Italy Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 39: Spain Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 40: Spain Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 41: Spain Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 42: Rest-of-Europe Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 43: Rest-of-Europe Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 44: Rest-of-Europe Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 45: Asia-Pacific Electric Pumps for Rocket Market (by End User), $Thousand, 2024-2035
• Table 46: Asia-Pacific Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 47: Asia-Pacific Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 48: China Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 49: China Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 50: China Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 51: Japan Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 52: Japan Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 53: Japan Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 54: South Korea Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 55: South Korea Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 56: South Korea Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 57: India Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 58: India Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 59: India Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 60: Rest-of-Asia-Pacific Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 61: Rest-of-Asia-Pacific Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 62: Rest-of-Asia-Pacific Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 63: Rest-of-the-World Electric Pumps for Rocket Market (by End User), $Thousand, 2024-2035
• Table 64: Rest-of-the-World Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 65: Rest-of-the-World Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 66: Middle East and Africa Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 67: Middle East and Africa Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 68: Middle East and Africa Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035
• Table 69: Latin America Electric Pumps for Rocket Market (by End-User), $Thousand, 2024-2035
• Table 70: Latin America Electric Pumps for Rocket Market (by Rocket Class), $Thousand, 2024-2035
• Table 71: Latin America Electric Pumps for Rocket Market (by Pump Type), $Thousand, 2024-2035