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市場調查報告書
商品編碼
1534925
太空太陽能發電市場:現況分析與預測(2024-2032)Space-Based Solar Power Market: Current Analysis and Forecast (2024-2032) |
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太空太陽能發電系統包括在太空收集太陽能並透過導電路徑將其傳輸到地球。太空太陽能發電的技術流程是利用太陽能板在太空中發電,借助反射鏡和充氣鏡將太陽輻射集中到太陽能電池板上,然後透過微波或雷射傳輸到地球。一些在天基太陽能板領域運作的重要公司已經實施了以下措施來利用太空能源:例如:今年早些時候,宣布計劃發射一英里長的太陽能電池板,目標是到2035年將能量傳回地球。與僅在白天發電的屋頂太陽能板相比,太空太陽能發電具有多種優勢。太空太陽能發電全年365天99%的時間發電,進一步拉動了太空太陽能發電市場的需求。
太空太陽能發電市場依太陽能衛星類型分為微波發射太陽能衛星和雷射發射太陽能衛星。微波發射太陽能電池衛星在太空太陽能發電市場中佔有很大佔有率。其主要原因是技術發展先進、示範實驗成功、安全風險低。然而,如果利用雷射進行電力傳輸的研究和開發取得進展並解決當前的問題,未來雷射傳輸太陽能衛星的市場佔有率可能會增加。
太空太陽能發電市場分為發電應用與太空應用。發電領域在空間太陽能發電中佔據較大佔有率,因為其在滿足世界能源需求、提供持續清潔能源供應以及促進環境永續發展方面具有巨大潛力。與太空應用相比,SBSP 在發電方面的可擴展性和廣泛影響使其成為更實質和變革性的應用,太空應用不可或缺,但更專業且範圍有限。
為了更了解太空太陽能發電(SBSP)產業的市場實施情況,市場為北美(美國、加拿大等北美地區)、歐洲(德國、英國、法國、西班牙、義大利、及其他歐洲地區),根據亞太地區(中國、印度、日本、亞太地區其他地區)和世界其他地區的全球影響力進行分析。北美在 SBSP 市場上的廣泛佔有率是由技術實力、大量金融投資、強大的機構支持和戰略合作夥伴關係推動的。該地區以最近的計畫和合作為代表,對創新和永續能源解決方案的承諾使其成為太空太陽能開發和部署的全球領導者。隨著SBSP技術的不斷進步,北美領導層希望在實現這項革命性能源的潛力方面發揮關鍵作用。例如,在美國,Northrop Grumman公司與美國空軍研究實驗室建立了持續的合作夥伴關係並投資了 1億美元,為 SBSP 提供先進技術。
進入該市場的主要公司有AZUR SPACE Solar Power、Northrop Grumman、Airbus Defence and Space、China Academy of Space Technology、Borrego、Blue Origin、Airbus、Solaren Corporation、Caltech、European Space Agency等。
目錄
第1章 市場介紹
- 市場定義
- 主要目的
- 利害關係人
- 限制
第2章 研究方法或前提
- 調查過程
- 調查方法
- 受訪者簡介
第3章 執行摘要
- 行業概況
- 依細分市場進行預測
- 市場成長的力量
- 區域展望
第4章 市場動態
- 促進因素
- 機會
- 抑制因素
- 趨勢
- PESTEL 分析
- 需求方分析
- 供給面分析
- 併購
- 投資場景
- 產業洞察:主要新創公司及其獨特策略
第5章 價格分析
- 區域價格分析
- 影響價格的因素
第6章 2022-2032年全球太空太陽能發電市場收入
第7章 太陽能發電衛星類型市場分析
- 微波發射太陽能衛星
- 雷射發射太陽能衛星
第8章 應用市場分析
- 發電
- 太空用途
第9章 依地區劃分的市場分析
- 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
- 世界其他地區
第10章 價值鏈分析
- 邊際分析
- 進入市場的公司名單
第11章 競爭態勢
- 競爭對手儀表板
- 競爭市場定位分析
- 波特五力分析
第12章 公司簡介
- AZUR SPACE 太陽能發電
- 公司概況
- 主要財務狀況
- SWOT分析
- 產品組合
- 近期趨勢
- Northrop Grumman
- Airbus Defence and Space
- China Academy of Space Technology
- Borrego
- Blue Origin
- Solaren Corporation
- Caltech
- European Space Agency
第13章 縮寫與假設
第14章 附錄
Space photovoltaic system concerns the collection of the sun's energy in space and then beaming it through a conductive path to the Earth. Space-based solar panel technological process engulfs the use of solar panels to generate solar power in space with the help of reflectors or inflatable mirrors for focusing solar radiation onto solar panels and then transmitting it to the earth through a Microwave or Laser. A few of the important companies operating in the context of space-based solar panels have been implementing the following measures to utilize the energy in space. For instance: Early this year, it unveiled a plan of sending up a lineup of one-mile solar panels aiming to make energy beams back to Earth by 2035. Space-based solar power has several advantages unlike the solar panels on the roof that produce electricity only during the day, space-based solar power produces electricity, 24/7 99 % of the year which is further driving the demand for space-based solar power market.
Based on the solar satellite type, the space-based solar power market is segmented into microwave-transmitting solar satellites and laser-transmitting solar satellites. Microwave-transmitting solar satellites cater to a significant share of the space-based solar power market. This is primarily due to their advanced technological development, successful demonstrations, and lower safety risks. However, as research and development in laser-based power transmission progress and solutions to current challenges, the market share for laser-transmitting solar satellites could increase in the future.
Based on the application, the space-based solar power market is bifurcated into electricity generation and space applications. The electricity generation segment caters to a more significant share of space-based solar power due to its vast potential to address global energy needs, provide a continuous and clean energy supply, and contribute to environmental sustainability. The scalability and broader impact of SBSP in electricity generation make it a more substantial and transformative application compared to space applications, which are essential but more specialized and limited in scope.
For a better understanding of the market adoption of the space-based solar power industry, 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, UK, France, Spain, Italy, Rest of Europe), Asia-Pacific (China, India, Japan, and Rest of Asia-Pacific), Rest of World. North America's extensive share in the SBSP market is driven by a combination of technological prowess, significant financial investments, strong institutional support, and strategic partnerships. The region's commitment to innovation and sustainable energy solutions, exemplified by recent projects and collaborations, positions it as a global leader in the development and deployment of space-based solar power. As SBSP technology continues to advance, North America's leadership aims to play a crucial role in realizing the potential of this revolutionary energy source. For instance: In the US, ongoing partnerships, and investments of $100 million between Northrop Grumman and the U.S. Air Force Research Laboratory have been established to provide advanced technology for SBSP.
Some of the major players operating in the market include AZUR SPACE Solar Power, Northrop Grumman, Airbus Defence and Space, China Academy of Space Technology, Borrego, Blue Origin, Airbus, Solaren Corporation, Caltech, and European Space Agency.
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 Based Solar Power Market
- 2.2. Research Methodology of the Space Based Solar Power 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 BASED SOLAR POWER MARKET REVENUE (USD MN), 2022-2032F
7.MARKET INSIGHTS BY SOLAR SATELLITE TYPE
- 7.1. Microwave Transmitting Solar Satellite
- 7.2. Laser Transmitting Solar Satellite
8.MARKET INSIGHTS BY APPLICATION
- 8.1. Electricity Generation
- 8.2. Space Applications
9.MARKET INSIGHTS BY REGION
- 9.1. North America
- 9.1.1. U.S.
- 9.1.2. Canada
- 9.1.3. Rest of North America
- 9.2. Europe
- 9.2.1. Germany
- 9.2.2. UK
- 9.2.3. France
- 9.2.4. Italy
- 9.2.5. Spain
- 9.2.6. Rest of Europe
- 9.3. Asia-Pacific
- 9.3.1. China
- 9.3.2. Japan
- 9.3.3. India
- 9.3.4. Rest of Asia-Pacific
- 9.4. Rest of World
10.VALUE CHAIN ANALYSIS
- 10.1. Marginal Analysis
- 10.2. List of Market Participants
11.COMPETITIVE LANDSCAPE
- 11.1. Competition Dashboard
- 11.2. Competitor Market Positioning Analysis
- 11.3. Porter Five Forces Analysis
12.COMPANY PROFILED
- 12.1. AZUR SPACE Solar Power
- 12.1.1. Company Overview
- 12.1.2. Key Financials
- 12.1.3. SWOT Analysis
- 12.1.4. Product Portfolio
- 12.1.5. Recent Developments
- 12.2. Northrop Grumman
- 12.3. Airbus Defence and Space
- 12.4. China Academy of Space Technology
- 12.5. Borrego
- 12.6. Blue Origin
- 12.7. Solaren Corporation
- 12.8. Caltech
- 12.9. European Space Agency
