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封面
市场调查报告书
商品编码
1610977

太空产业环境永续性的成长机会

Growth Opportunities for Environmental Sustainability in the Space Industry
出版日期: | 出版商: Frost & Sullivan | 英文 68 Pages | 商品交期: 最快1-2个工作天内

价格
简介目录

促进太空经济环境永续性的创新、法规结构和合作策略

在世界应对气候变迁的迫切需求的支持下,太空产业正迅速发展成为环境永续性的关键驱动力。本研究重点关注卫星技术、创新製造流程和战略伙伴关係关係的进步如何塑造永续太空营运的未来,并为该领域的市场参与企业和相关人员识别关键的成长机会。随着对基于卫星的环境解决方案的需求迅速增长,合成孔径雷达 (SAR) 和高光谱遥测影像等技术使得对重要环境变量的精确监测成为可能。这些进步将支持农业、能源、城市规划和自然资源管理等各产业的永续性努力,同时也有助于实现联合国永续发展目标(SDG)等全球目标。该报告还强调了积层製造和在轨服务、组装和製造(ISAM)技术的变革潜力。积层製造有助于生产更轻、更有效率的卫星零件,从而降低发射成本和排放。 ISAM 提供创新的在轨维护解决方案,延长卫星的使用寿命并最大限度地减少太空碎片。这些技术将共同提高营运效率并促进整个太空价值链的永续性。航太部门必须克服诸如高昂的初始成本、不断变化的监管环境以及碎片管理的技术复杂性等挑战。但透过利用先进的分析、促进国际合作以及投资尖端绿色技术,太空产业正在走向更永续的未来,无论是在地球上还是在轨道上。

目录

战略问题

  • 为什么成长如此困难?
  • The Strategic Imperative 8(TM)
  • 太空产业环境永续性的三大战略挑战的影响
  • 成长机会推动Growth Pipeline Engine(TM)

成长机会分析

  • 生长促进因子
  • 促生长因子分析
  • 成长抑制因素
  • 成长抑制因素分析
  • 计划概况

太空产业与联合国永续发展目标之间的合作

  • 联合国永续发展目标
  • SDGs
  • 经济发展目标
  • 环境发展目标
  • 主要应用技术

太空火箭和地面部分的永续性

  • 太空火箭和地面部分
  • 太空火箭和地面部分:推进剂
  • 竞争格局:推进剂
  • 太空火箭和地面部分:可重复使用的火箭
  • 竞争格局:太空火箭
  • 太空火箭和地面部分:製造
  • 竞争格局:积层製造技术
  • 市场成熟度与时间范围:太空火箭和地面领域的永续技术

太空的永续性

  • 太空的永续性
  • 太空永续性:太空碎片清除和脱轨系统
  • 竞争格局:ADR
  • 太空永续性:在轨定序
  • 竞争环境:在轨定序
  • 太空永续性:轨道拥堵
  • 竞争环境:SSA和STM公司
  • 太空永续性:反卫星测试
  • 市场成熟度和时间范围:轨道上的永续性

永续性法规和倡议

  • 与太空永续性相关的主要法规和倡议

成长机会领域

  • 成长机会一:环保应用
  • 成长机会2:积层製造技术
  • 成长机会 3:在轨服务、组装和製造 (ISAM)

附录与后续步骤

  • 成长机会的好处和影响
  • 行动项目和后续步骤
  • 附件清单
  • 免责声明
简介目录
Product Code: KA8E-66

Technological Innovations, Regulatory Frameworks, and Collaborative Strategies to Drive Environmental Sustainability in the Space Economy

The space industry is rapidly evolving as a critical driver of environmental sustainability, underpinned by the urgent global need to combat climate change. This study identifies the key growth opportunities for market participants and stakeholders in the sector, focusing on how advancements in satellite technology, innovative manufacturing processes, and strategic partnerships are shaping the future of sustainable space operations. As demand for satellite-enabled environmental solutions surges, technologies such as synthetic aperture radar (SAR) and hyperspectral imaging are enabling precise monitoring of critical environmental variables. These advancements support sustainability efforts across industries, including agriculture, energy, urban planning, and natural resource management, while contributing to global objectives like the United Nations' sustainable development goals (SDGs). The report also highlights the transformative potential of additive manufacturing and in-orbit servicing, assembly, and manufacturing (ISAM) technologies. Additive manufacturing facilitates the production of lighter, more efficient satellite components, reducing launch costs and emissions. ISAM offers innovative solutions for in-orbit maintenance, extending satellite lifespans and minimizing space debris. Together, these technologies enhance operational efficiency and drive sustainability across the space value chain. The space sector has to navigate challenges such as high initial costs, evolving regulatory landscapes, and the technical complexities of debris management. However, by leveraging advanced analytics, fostering international collaboration, and investing in cutting-edge green technologies, the industry is well-positioned to lead the charge toward a more sustainable future, both on Earth and in its orbit.

Table of Contents

Strategic Imperatives

  • Why is it Increasingly Difficult to Grow?
  • The Strategic Imperative 8™
  • The Impact of the Top 3 Strategic Imperatives on Environmental Sustainability in the Space Industry
  • Growth Opportunities Fuel the Growth Pipeline Engine™

Growth Opportunity Analysis

  • Growth Drivers
  • Growth Drivers Analysis
  • Growth Restraints
  • Growth Restraint Analysis
  • Project Outline

Aligning the Space Industry with the UN SDGs

  • UN SDGs
  • SDGs
  • Economic Development Goals
  • Environmental Development Goals
  • Technologies-Key Applications

Sustainability of the Space Launch Vehicles and the Ground Segment

  • Space Launch Vehicles and the Ground Segment
  • Space Launch Vehicles and the Ground Segment-Propellants
  • Competitive Landscape-Propellants
  • Space Launch Vehicles and the Ground Segment-Reusable Launch Vehicles
  • Competitive Landscape-Space Launch Vehicles
  • Space Launch Vehicles and the Ground Segment-Manufacturing
  • Competitive Landscape-Additive Manufacturing
  • Market Maturity vs. Time Horizon-Sustainable Technologies for the Space Launch Vehicles and the Ground Segment

Sustainability in Space

  • Sustainability in Space
  • Sustainability in Space-Space Debris Removal and Deorbiting Systems
  • Competitive Landscape-ADR
  • Sustainability in Space-In-orbit Servicing
  • Competitive Environment-In-orbit Servicing
  • Sustainability in Space-Orbital Congestion
  • Competitive Environment-SSA and STM Companies
  • Sustainability in Space-Anti-satellite Testing
  • Market Maturity vs. Time Horizon-In-orbit Sustainability

Sustainability Regulations and Initiatives

  • Key Space Sustainability Regulations and Initiatives

Growth Opportunity Universe

  • Growth Opportunity 1: Environmental Applications
  • Growth Opportunity 2: Additive Manufacturing
  • Growth Opportunity 3: In-orbit Servicing, Assembly, and Manufacturing (ISAM)

Appendix & Next Steps

  • Benefits and Impacts of Growth Opportunities
  • Action Items & Next Steps
  • List of Exhibits
  • Legal Disclaimer