宇宙用極低溫市場:現狀分析與未來預測 (2024年～2032年)

預計預測期內（2024-2032 年），空間低溫市場將大幅成長約 7.14%。由於航太推進和燃料儲存應用對低溫技術的需求不斷增加，以及太空探索和科學任務領域的不斷進步，全球航太低溫市場正經歷強勁成長。隨著航太機構和私人公司將大量投資集中在深空探索上，小行星和彗星逐漸進入人類技術可及的範圍內，衛星不斷發射，商業太空計畫也開始啟動，很明顯，低溫技術將成為未來太空發展的基礎技術。冷卻設備、儲存液氫和液態氧等推進劑以及以高精度和高效率執行複雜任務是空間低溫系統提供的一些服務。其中包括望遠鏡和行星探索、地球觀測和衛星通訊等太空科學。這些領域通常需要具有特殊能力的高度複雜的系統才能在太空的極端條件下發揮作用。那些考慮此類發展的人專注於私人項目，而不是政府資助的任務，後者是太空低溫技術投資的主要貢獻者。北美、歐洲和亞太地區是太空低溫技術應用的關鍵地區，這些地區越來越關注太空旅遊、衛星星座和深空任務。

最近的趨勢是開啟低溫系統的新時代，預計這將推動其應用。例如，2025 年，Cryoport Inc. 宣布將推出 Cryoport Express(R) 低溫 HV3 運輸系統（ "HV3" ），這是一種用於運輸救生生物製劑和溫度敏感治療劑的最先進的低溫運輸系統。

太空低溫技術對於促進向清潔能源的轉變至關重要，因為它為專注於提高能源效率和永續性的太空任務提供動力。低溫系統用於冷卻關鍵的太空儀器以及火箭發射和衛星系統所需的推進系統中的推進劑儲存，最終為太空發射基礎設施做出貢獻。因此，我們可能會看到航太機構和私人公司在具有商業應用的任務中越來越多地使用低溫技術，例如追蹤和監測氣候變遷的地球觀測衛星、地球上的可再生能源基礎設施以及低溫技術在其他任務中的潛在應用。

考慮到這些變化，預計 2024 年至 2032 年間對空間低溫技術的需求將進一步增長。

根據冷卻類型，全球空間低溫學市場分為高溫冷卻裝置和低溫冷卻裝置。其中，低溫冷卻設備佔有相當大的市場佔有率。低溫冷卻系統在提高溫度範圍降至相當低的太空任務效率方面發揮著至關重要的作用。低溫冷卻系統對於冷卻天文任務、太空望遠鏡和衛星系統中使用的敏感科學儀器、偵測器和感測器至關重要。它也是火箭推進系統中儲存和管理液態氫、液態氧等低溫推進劑的必備冷卻裝置。對太空探索和詹姆斯韋伯太空望遠鏡等先進望遠鏡的需求不斷增長，繼續推動可靠、高性能低溫冷卻解決方案的發展。

全球空間低溫學市場依應用分為太空科學任務、地球觀測、電信應用、技術展示任務及低溫電子應用。其中，太空科學任務領域佔有很大佔有率。推動太空科學任務領域變革的因素包括對深空研究的投資、需要先進低溫系統的任務的長期性以及低溫技術在冷卻空間望遠鏡和探測器上的科學儀器方面的重要性。火星和月球等高調目標任務嚴重依賴尖端低溫技術來儲存和管理推進劑，以及依靠低溫技術來確保極端太空環境下儀器的功能。行星科學，加上詹姆斯韋伯太空望遠鏡等太空望遠鏡，正在推動人們對該領域的進一步興趣，進而加速該科學研究領域對低溫解決方案的需求。

為了更了解空間低溫技術的市場應用情況，我們根據北美（美國、加拿大和歐洲其他地區）、歐洲（德國、法國、英國、西班牙、義大利和歐洲其他地區）、亞太地區（中國、日本、印度和亞太其他地區）和世界其他地區的全球影響力對市場進行了分析。歐洲佔據空間低溫學市場的大部分佔有率，預計在預測期內將保持穩定的成長率。該地區的創新、永續性和可重複使用的火箭技術正在推動市場成長。隨著歐洲太空任務（包括月球和火星任務）的不斷增加，對尖端低溫系統的需求將會增加。低溫技術的商業化也將顯著提升歐洲在全球航太領域的影響力。

市場的主要參與者包括泰雷茲、Absolut System、住友重工有限公司、液化空氣集團、牛津儀器、派克漢尼汾公司、霍尼韋爾國際公司、RICOR、Creare 和諾斯羅普·格魯曼公司。

目錄

第1章 市場概要

• 市場定義
• 主要目的
• 相關利益者
• 限制事項

第2章 分析方法或前提條件

• 分析流程
• 分析方法
• 受訪者簡介

第3章 摘要整理

• 產業摘要
• 各市場區隔預測
  • 市場成長的強度
• 地區展望

第4章 市場動態

• 促進因素
• 機會
• 阻礙因素
• 趨勢
• PESTEL分析
• 需求面分析
• 供給面分析
  • 企業合併·收購 (M&A)
  • 投資情勢
  • 產業洞察：領先的新創公司及其獨特的策略

第5章 價格分析

• 價格分析:各地區
• 價格的影響因素

第6章 全球宇宙用極低溫的市場收益 (2022～2032年)

第7章 市場分析:冷卻類別

• 高溫冷卻設備
• 低溫冷卻設備

第8章 市場分析:各用途

• 宇宙科學任務
• 地球觀測
• 通訊用途
• 技術演示任務
• 低溫電子應用

第9章 市場分析:溫度

• 120k以下
• 120～150k
• 150k以上

第10章 市場分析:各地區

• 北美
  • 美國
  • 加拿大
  • 其他北美地區
• 歐洲
  • 德國
  • 英國
  • 法國
  • 義大利
  • 西班牙
  • 其他歐洲地區
• 亞太地區
  • 中國
  • 日本
  • 印度
  • 其他亞太地區
• 全球其他地區

第11章 價值鏈分析

• 限制分析
• 市場參與企業的一覽

第12章 競爭情形

• 競爭儀表板
• 企業的市場定位分析
• 波特的五力分析

第13章 企業簡介

• Thales
  • 企業概要
  • 主要的財務指標
  • SWOT分析
  • 產品系列
  • 近幾年趨勢
• Absolut System
• Sumitomo Heavy Industries Ltd
• Air Liquide
• Oxford Instrument
• Parker Hannifin Corporation
• Honeywell International Inc.
• Ricor
• Creare
• Northrop Grumman Corporation

第14章 縮寫與前提條件

第15章 附錄

The space cryogenic industry is a fast-growing sector of the aerospace industry, where cryogenic technology is used to sustain missions to space. Cryogenic is the science of producing and working with materials at very low temperatures, generally below -150°C. Eventually, Space cryogenics becomes integral to rocket propulsion, utilizing liquid oxygen and liquid hydrogen as the propellants with the highest energy density. These cryogens are the propellants to put the spacecraft into orbit and beyond. The drivers for this market are an increase in space exploration and satellite launches, coupled with a demand for efficient propulsion systems. Moreover, the improvements in cryogenic storage, insulation materials, and liquefaction technology are supportive of the growth of this market. With an increase in investments by government space agencies and private players, the space cryogenic market is anticipated to flourish and contribute to the future of space exploration and travel.

The Space Cryogenic Market is expected to grow at a significant rate of around 7.14% during the forecast period (2024-2032). The market for Space Cryogenics on a global scale is witnessing robust growth owing to ongoing advancements in the areas of space exploration and scientific missions in addition to the increasing requirements of cryogenic technology for space propulsion and fuel storage applications. As much of the investment is focused on deep space exploration by space agencies and private players alike, as asteroids and comets come within reach of human technology, launching satellites, and beginning commercial space ventures, it seems clear that cryogenics is the future cornerstone technology for space development. Cooling of instruments, storage of propellants such as liquid hydrogen and liquid oxygen, and enabling complex missions with very high precision and efficiency are some of the services provided by space cryogenic systems. The maximum thrust comes from the following areas in terms of their cryogenic applications: space science, such as telescopes and planetary exploration; earth observation; and satellite communication as these sectors generally require very soliciting systems with special capabilities to function at the extreme conditions of space. Those looking into such developments have contributed a major share to the investments that are being put in for space cryogenics, more tied toward private-sector projects than government-sponsored missions. North America, Europe, and Asia-Pacific are the leading regions in the adoption of space cryogenics, with an increasing emphasis on space tourism, satellite constellations, and missions to deep space.

Some of the recent developments that are anticipated to drive the adoption are the launch of new-age cryogenic systems. For instance, in 2025, Cryoport Inc. announced to launch State-of-the-Art Cryoport Express(R) Cryogenic HV3 Shipping System ("HV3") a Cryogenic Shipping System for Transporting Lifesaving Biologics and Temperature-Sensitive Therapies.

Space Cryogenics is vital in facilitating a shift towards clean energy because it powers space missions focused on improving energy efficiency and sustainability. Cryogenic systems use cooling technology for critical space instruments and propellant storage for propulsion systems required during rocket launches and satellite systems, which ultimately contribute towards space-based launch infrastructure. Cryogenics will, therefore, be used increasingly by space agencies and private companies for missions that tend to be of commercial application, such as Earth observation satellites that track and monitor climate change, renewable energy infrastructures on Earth, as well as potential use of cryogenics on other possible missions.

Considering all the changes, the market is anticipated to rise further promoting the demand for Space Cryogenic during 2024-2032.

Based on Cooling Type, the Global Space cryogenic market is bifurcated into high-temperature coolers and low-temperature coolers. Of these low-temperature coolers have held a remarkable market share. Low-temperature coolers play a very important role in enhancing the efficiency of space missions, where temperature ranges can drop to levels quite low. The low-temperature coolers are crucial to the cooling of sensitive scientific instruments, detectors, and sensors that are employed in astronomic missions, space telescopes, and satellite systems. They also provide essential cooling for the storage and management of cryogenic propellants like liquid hydrogen and liquid oxygen in the rocket propulsion systems. Increased demand for space exploration and advanced telescopes such as the James Webb Space Telescope will always be a factor driving the growth of reliable, high-performance low-temperature cooling solutions.

Based on application the global space cryogenic market is segmented into space science missions, earth observations, telecom applications, technology demonstration missions, and cryo-electronic applications. Of these space science missions segment has held the major market share. Some of the factors causing increasing changes in the Space Science Missions segment are deep space research investments; a requirement for advanced cryogenic systems due to the nature of long-duration missions; and the critical importance of cryogenics in cooling scientific instruments for space telescopes and detectors. High-profile missions, targeting Mars, the Moon, etc., depend extensively on state-of-the-art cryogenic technology to store or manage propellants, as well as on cryogenic technologies to deliver instrumentation functionality under extreme space environments. Planetary science coupled with space telescopes like the James Webb Space Telescope have furthered interest in the area and, thus, accelerated demand for cryogenic solutions in this line of scientific research.

For a better understanding of the market adoption of the Space Cryogenic market, the market is analyzed based on its worldwide presence in countries such as North America (U.S., Canada, and the Rest of North America), Europe (Germany, France, U.K., Spain, Italy, Rest of Europe), Asia-Pacific (China, Japan, India, Rest of Asia-Pacific), Rest of World. Europe holds a significant share of the Space Cryogenic market and is anticipated to maintain a steady growth rate over the forecast period. Innovation, sustainability, and reusable rocket technology for the region are driving the growth of the market. With the continued proliferation of European space missions, such as to the Moon and Mars, the demand for cutting-edge cryogenic systems will increase. Cryogenic technology commercialization will also significantly enhance Europe's presence in the global space sector.

Some of the major players operating in the market include Thales, Absolut System, Sumitomo Heavy Industries Ltd, Air Liquide, Oxford Instrument, Parker Hannifin Corporation, Honeywell International Inc., RICOR, Creare, and Northrop Grumman Corporation.

TABLE OF CONTENTS

1.Market Introduction

• 1.1. Market Definitions
• 1.2. Main Objective
• 1.3. Stakeholders
• 1.4. Limitation

2.Research Methodology Or Assumption

• 2.1. Research Process Of The Space Cryogenic Market
• 2.2. Research Methodology Of The Space Cryogenic Market
• 2.3. Respondent Profile

3.Executive Summary

• 3.1. Industry Synopsis
• 3.2. Segmental Outlook
  • 3.2.1. Market Growth Intensity
• 3.3. Regional Outlook

4.Market Dynamics

• 4.1. Drivers
• 4.2. Opportunity
• 4.3. Restraints
• 4.4. Trends
• 4.5. Pestel Analysis
• 4.6. Demand Side Analysis
• 4.7. Supply Side Analysis
  • 4.7.1. Merger & Acquisition
  • 4.7.2. Investment Scenario
  • 4.7.3. Industry Insights: Leading Startups And Their Unique Strategies

5.Pricing Analysis

• 5.1. Regional Pricing Analysis
• 5.2. Price Influencing Factors

6.Global Space Cryogenic Market Revenue (USD Mn), 2022-2032F

7.Market Insights By Cooling Type

• 7.1. High Temperature Coolers
• 7.2. Low-Temperature Coolers

8.Market Insights By Application

• 8.1. Space Science Missions
• 8.2. Earth Observation
• 8.3. Telecom Application
• 8.4. Technology Demonstration Mission
• 8.5. Cryo-Electronic Application

9.Market Insights By Temperature

• 9.1. Less Than 120 K
• 9.2. 120-150 K
• 9.3. More Than 150 K

10.Market Insights By Region

• 10.1. North America
  • 10.1.1. U.S.
  • 10.1.2. Canada
  • 10.1.3. Rest Of North America
• 10.2. Europe
  • 10.2.1. Germany
  • 10.2.2. U.K.
  • 10.2.3. France
  • 10.2.4. Italy
  • 10.2.5. Spain
  • 10.2.6. Rest Of Europe
• 10.3. Asia-Pacific
  • 10.3.1. China
  • 10.3.2. Japan
  • 10.3.3. India
  • 10.3.4. Rest Of Asia-Pacific
• 10.4. Rest Of World

11.Value Chain Analysis

• 11.1. Marginal Analysis
• 11.2. List Of Market Participants

12.Competitive Landscape

• 12.1. Competition Dashboard
• 12.2. Competitor Market Positioning Analysis
• 12.3. Porter Five Forces Analysis

13.Company Profiled

• 13.1. Thales
  • 13.1.1. Company Overview
  • 13.1.2. Key Financials
  • 13.1.3. Swot Analysis
  • 13.1.4. Product Portfolio
  • 13.1.5. Recent Developments
• 13.2. Absolut System
• 13.3. Sumitomo Heavy Industries Ltd
• 13.4. Air Liquide
• 13.5. Oxford Instrument
• 13.6. Parker Hannifin Corporation
• 13.7. Honeywell International Inc.
• 13.8. Ricor
• 13.9. Creare
• 13.10. Northrop Grumman Corporation

14.Acronyms & Assumption

15.Annexure