2025年-2035年航天器热防护罩 & 隔热系统:技术和市场展望
对航天器再入大气层时使用的热防护罩(TPS)及隔热板进行颗粒技术评估,涵盖瓦片式、烧蚀式和可膨胀式等多种类型,并提供十年市场预测。
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本报告提供了对航天器热防护罩的技术展望。基于传统和新兴的热防护罩技术,本报告评估了不同材料与设计。同时,结合空间探索需求,本报告识别了热防护技术的新兴应用机遇,最终形成面向2035年的市场展望。
关键领域
太空产业综述
- 商业航天运营商在多个领域的崛起(如发射服务提供商、近地轨道(LEO)货物运输商业化)
- 商业航天运营商崛起对热防护材料设计的影响
- 货运/载人航天器发展时间轴
大气再入物理
- 再入物理与气动加热机制(对流/辐射热分析)
- 钝体设计原理与热防护系统必要性
- 热防护系统(TPS)的材料选择与设计,以及各类别的性能范围分析
瓦基热防护系统
- 瓦基热防护系统的密度、发射率、导热性和耐温极限。
- 瓦基系统的历史概述,从航天飞机时代到星舰。
- 组件类别的发展路径,包括高隔热瓦片、涂层、陶瓷毯和高温结构。
- 二氧化硅基瓦片、增强碳碳材料、TUFROC、星舰瓦片。
- 材料密度和耐温极限的基准比较。
可展开气动减速器
- 增加直径超出整流罩如何影响弹道系数和峰值加热。
- NASA的HIAD和LOFTID测试项目概述,包括使用的建造技术和材料。
- 可展开气动减速器如何解锁商业助推器的可重复使用性。
- 机械部署的气动减速器。
- 计划进行试飞的关键商业参与者。
烧蚀式热防护系统
- 在最具挑战性的再入环境中对烧蚀材料需求的概述。
- 烧蚀和热解传热机制的总结。
- 烧蚀材料家族及其发展时间线的总结。
- 蜂窝烧蚀体(如AVCOAT)。
- PICA热防护罩及其潜在的可重复使用性。
- 碳酚醛热防护罩。
- 新兴的3D编织热防护系统,例如NASA的HEEET。
预测
- 针对热防护系统的细化十年市场预测,按类别和运营商(政府与商业)划分。
执行摘要
太空产业概览
- 商业航天运营商的持续增长
- 微重力制造的兴起
- 商业化对材料设计的影响
- 货运与载人航天器的发展时间轴
大气再入
- 热防护系统的必要性及钝体设计理念
- 对流热与辐射热
- 热防护系统的压力与加热性能参数范围
瓦基热防护系统
- 材料要求
- 组件类别的发展路径
- 二氧化硅基瓦片、增强碳碳材料(Reinforced-carbon-carbon)、TUFROC、星舰瓦片
- 材料密度与耐温极限对比
可展开气动减速器
- 弹道系数及其对加热的影响
- HIAD与LOFTID测试项目
- 商业助推器可重复使用性
- 机械展开式气动减速器
烧蚀式热防护系统
- 烧蚀与热解传热机制
- 烧蚀材料家族及其发展时间线总结
- 蜂窝烧蚀体(例如AVCOAT)
- PICA热防护罩
- 碳酚醛热防护罩
- 3D编织热防护系统(如NASA的HEEET)
预测
Thermal protection systems (TPS) are designed to protect spacecraft from the enormous aerodynamic heating generated during the entry into an atmosphere. The hottest parts of the Space Shuttle during re-entry reached 1,650°C, while the Galileo probe that entered Jupiter's atmosphere reached 16,000°C. Protecting the spacecraft during this intense thermal heating is the sole purpose of a TPS - and since the earliest days of space travel, innovations and advancements in TPS have been crucial to enabling space missions. The space industry is rapidly evolving, with commercial operators beginning to take on roles in the emerging 'Space Economy' and seeking to reduce launch costs. Governmental agencies remain at the forefront of material science and development as mission goals become more ambitious, from landing greater payloads on Mars to exploring the outer planets. This report contextualizes the TPS requirements of different re-entry profiles and breaks down the core categories of TPS.
Performance envelopes for a range of thermal protection systems. Commercial interest is focused on insulation tiles through to PICA. Pressures and temperatures beyond this are only encountered in the exploration of outer planets or exceptionally large payloads - currently the mission domain of governmental agencies.
A new geometry for Starship seeks to solve the problems of the Shuttle-era TPS
For the 'lower' heating rates (1,650°C is still beyond the melting point of stainless steel) encountered on returning from a low-Earth-orbit (LEO) - high-temperature insulative silicon tiles are an often-used approach. Because the overall heat flux is lower, utilizing reusable TPS is possible and desirable as it lowers the cost to orbit and enables a higher launch cadence. The NASA Space Shuttle program was intended to provide a low-cost, rapidly reusable spacecraft that could ferry crew and cargo from the surface to a LEO. However, the Shuttle's TPS was plagued by high construction costs, lengthy maintenance requirements, and damaged tiles were the cause of the Columbia disaster.
The promise of rapidly reusable silicon-tile based insulation remains appealing, and SpaceX has opted for this TPS for its Starship upper-stage. However, several key design differences of Starship could potentially negate some of the cost and performance problems of the Starship. The report breaks down how tile shape, spacecraft geometry, and choice of substructure material could all contribute to greater TPS performance. The report also outlines the developments of the key subcategories of reusable TPS, from advanced carbon-carbon and other hot structures to developments in high emissivity coatings and TUFROC, offering performance data and material composition throughout.
Inflatable TPS - an emerging option at the forefront of development
One of the fundamental constraints of any launched spacecraft is the 'rocket-fairing', that is, the width of the rocket nose at launch. However, the physics of atmospheric entry favors the largest heat shield diameter possible. A novel and emerging technique is to use an inflatable or mechanically expandable TPS that is stowed on launch but expands before re-entry. This is seen as a viable way to enable greater payload missions, with some commercial operators also pursuing this avenue for LEO cargo return. This approach comes with a host of technical challenges, but great advancements are being made, and in 2022, NASA completed the first successful LEO re-entry with its LOFTID (Low Earth Orbit Flight Test of an Inflatable Decelerator). The report unpacks the key material opportunities in these TPS, such as aerogel insulators, high-temperature ceramic fabrics, and the need for solid-gas generators. Potential applications for this development are also examined, including high-value booster engine return, high-altitude landings, and higher payload delivery.
Ablators - from Apollo to Orion
Generic ablator structure beginning with a substrate material (often carbon or silica fibers) which are impregnated with a resin (phenolic resin is common) and additives (such as silica micro balloons). An additional structure (such as a honeycomb matrix) may be added for support. Pyrolysis converts the 'virgin' material into 'char, ' transferring heat away from the structure. Source: IDTechEx.
An ablative TPS is the ultimate form of protection, used when a spacecraft's reentry speed means all other options would simply not stand up to the heat. Ablation can aptly be described asenergy management through material consumption, and the ablator itself disintegrates in a controlled manner during re-entry, transferring away heat and protecting the substructure beneath. Ablators have been used from lunar returns (AVCOAT honeycomb on Apollo) to entry into Jupiter (Carbon Phenolic). This report breaks down the material families of ablators, highlighting their material construction, installation, and performance envelopes. Historical context is provided, such as the atrophy of Carbon Phenolic capabilities due to the cessation of aerospace-grade Rayon production, and where 3D-woven fabrics may fit in as a replacement. Commercially developed variants, such as SpaceX's PICA-X (Phenolic impregnated carbon ablator-X) are covered, as well as assessing the potential semi-reusability of ablators well within their performance envelope.
Industry overview and market analysis
As part of its research, IDTechEx has examined several existing and upcoming space cargo/crew vehicles with a variety of TPS selections. Factors such as launch cadence, dimensions, and material selection provide a detailed assessment of the state of the industry. This extensive market analysis also forms the foundation of IDTechEx's market forecasts for TPS systems up to 2035, split by material demand (in m2) and USD.
IDTechEx's research includes coverage of several key players and projects in space crew and cargo transfer vehicles, a key application of TPS. Source: IDTechEx.
Key Aspects
A review and context of the space industry
- The emerging presence of commercial space operators for a variety of purposes (launch operators, commercial LEO cargo transfer)
- Implications of commercialization on material design for thermal protection systems
- Development timeline of cargo and crewed spacecraft
Atmospheric Entry
- Overview of reentry physics and atmospheric heating (split by convective and radiative heat.
- Blunt body concept and the need for thermal protection systems.
- Material selection and design for TPS, and performance envelopes for a variety of categories.
Tile-based TPS
- Density, emissivity, conductivity and temperature limits for tile-based TPS.
- Historical overview of tile-based systems, from the Shuttle-era to Starship.
- Development pathway of component categories, from high-insulation tiles, coatings, ceramic blankets, and hot structures
- Silica based tiles, Reinforced-carbon-carbon, TUFROC, Starship tiles
- Material density and temperature limit benchmarking
Expandable Aerodynamic Decelerators
- How increasing the diameter beyond the launch fairing affects ballistic coefficient and peak heating.
- Overview of NASA's HIAD and LOFTID test programs, including construction techniques and materials used.
- How expandable aerodynamic decelerators could unlock commercial booster reusability.
- Mechanically deployable aerodynamic decelerators
- Key commercial players with test-flights planned.
Ablative TPS
- Overview of the need of ablators in the most challenging reentry environments.
- Summary of ablative and pyrolysis heat transfer mechanisms
- Summary of ablator families and development timeline
- Honeycomb ablators (e.g. AVCOAT)
- PICA heat shields, and its potential reusability.
- Carbon Phenolic heat shields
- Emerging 3D Woven thermal protection systems, such as NASA's HEEET
Forecasts
- Granular 10-year market forecasts for TPS, split by category and operators (governmental vs commercial).
| Report Metrics | Details |
|---|---|
| Historic Data | 1991 - 2024 |
| CAGR | The global market for Thermal Protection Systems for Spacecraft will reach US$90 million in 2035, a CAGR of 3.3% compared with 2024. |
| Forecast Period | 2025 - 2035 |
| Forecast Units | USD, Area (m2) |
| Regions Covered | Worldwide |
| Segments Covered | Thermal protection systems; ablative systems, tile-based systems |
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| 1. | EXECUTIVE SUMMARY |
| 1.1. | Thermal Protection Systems - Introduction |
| 1.2. | The Space Industry is Changing |
| 1.3. | Commercial Orbital Launches Growing Rapidly |
| 1.4. | Reusable Entry/Transfer Vehicles - Cargo and Crewed |
| 1.5. | LEO Partially Reusable Return Vehicle Testing Timeline |
| 1.6. | Thermal Protection Systems & 'Aerobraking' |
| 1.7. | Options for Decelerating |
| 1.8. | Peak Heat, Total Heat, and Stagnation Pressure |
| 1.9. | Categories of Thermal Protection System |
| 1.10. | TPS Performance Envelope (1) |
| 1.11. | TPS Performance Envelope |
| 1.12. | Role of Industry in Material and Manufacturing of Heat Shields |
| 1.13. | Forecasting Overview |
| 1.14. | Annual Installation Area of Thermal Protection Systems |
| 1.15. | Market Value of TPS, 1991-2035 |
| 1.16. | TPS Market Value Forecast (1) |
| 1.17. | TPS Market Value Forecast (2) |
| 2. | SPACE INDUSTRY |
| 2.1. | Thermal Protection Systems - Introduction |
| 2.2. | The Space Industry is Changing |
| 2.3. | Commercial Interest in Space |
| 2.4. | Commercial Orbital Launches Growing Rapidly |
| 2.5. | Orbital Launches by Country of Operator, 1957-2024 |
| 2.6. | BEO Launches Remain Low |
| 2.7. | SpaceX a Dominant Player Among Launch Providers |
| 2.8. | Space Mission Domain |
| 2.9. | Microgravity manufacturing |
| 2.10. | Commercialization of Space - Implications for Material Design |
| 2.11. | Cargo and Crew Capsules - TPS Enables Reusability |
| 2.12. | Cargo and Crew Transportation |
| 2.13. | Reusable Entry/Transfer Vehicles - Cargo and Crewed |
| 2.14. | Reusable Entry/Transfer Vehicles - Cargo and Crewed |
| 2.15. | LEO Partially Reusable Return Vehicle Testing Timeline |
| 2.16. | Partial Reusability |
| 2.17. | Partial Reusability - TPS Options |
| 2.18. | Crew/Cargo Return Vehicles |
| 3. | ATMOSPHERIC RE-ENTRY |
| 3.1. | Tsiolkovsky's Rocket Equation |
| 3.2. | Thermal Protection Systems & 'Aerobraking' |
| 3.3. | Atmospheric Entry - Overview |
| 3.4. | Energy of Orbital Vehicles |
| 3.5. | Options for Decelerating |
| 3.6. | Blunt Body Concept |
| 3.7. | Convective vs Radiative Heat |
| 3.8. | Peak Heat, Total Heat, and Stagnation Pressure |
| 3.9. | Categories of TPS |
| 3.10. | Categories of Thermal Protection System |
| 3.11. | Thermal Protection Systems |
| 3.12. | Cost and Performance |
| 3.13. | TPS Peak Heating and Pressure Limits |
| 3.14. | TPS Performance Envelope (1) |
| 3.15. | TPS Performance Envelope (2) |
| 3.16. | Role of Industry in Material and Manufacturing of Heat Shields |
| 4. | TILE-BASED TPS |
| 4.1. | Reusable TPS Overview |
| 4.2. | Material Requirements for Reusable TPS |
| 4.3. | Importance of Surface Emissivity |
| 4.4. | Thermal Conductivity |
| 4.5. | Temperature and Density |
| 4.6. | Reusable TPS Material Development Pathway |
| 4.7. | Spacecraft Geometry Affects Heating |
| 4.8. | Silica Based Tiles |
| 4.9. | Reinforced Carbon-Carbon (RCC) - (1) |
| 4.10. | Reinforced Carbon-Carbon (RCC) - (2) |
| 4.11. | RCC/ACC Manufacturing Overview |
| 4.12. | TUFROC |
| 4.13. | Advanced TUFROC |
| 4.14. | NASA Space Shuttle Orbiter vs SpaceX Starship |
| 4.15. | SpaceX Starship TPS |
| 4.16. | Thermal Conductivity and Density of Reusable TPS |
| 4.17. | Temperature Limits and Material Densities |
| 4.18. | Emissivity of TPS |
| 4.19. | TPS Component Manufacturers |
| 5. | EXPANDABLE AERODYNAMIC DECELERATORS |
| 5.1. | Overview |
| 5.1.1. | Expandable Aerodynamic Decelerators |
| 5.1.2. | Opportunities Enabled by EADs |
| 5.1.3. | Challenges for EADs |
| 5.1.4. | The Ballistic Coefficient |
| 5.1.5. | Ballistic Coefficient - Impact on Heat Flux |
| 5.1.6. | Venus Missions - Ballistic Coefficient and Peak Heating |
| 5.1.7. | Diameter on Heating |
| 5.1.8. | Options for Increasing the Ballistic Coefficient |
| 5.2. | HIAD |
| 5.2.1. | HIAD Deployment |
| 5.2.2. | NASA HIAD Construction |
| 5.2.3. | Material Selection for F-TPS |
| 5.2.4. | F-TPS |
| 5.2.5. | F-TPS Temperature |
| 5.2.6. | Aerogels for F-TPS |
| 5.2.7. | Gas-Generators |
| 5.2.8. | ATMOS PHOENIX - Commercial IAD |
| 5.2.9. | Booster Reusability |
| 5.2.10. | ULA Vulcan BE-4 Reusability |
| 5.3. | MDAD |
| 5.3.1. | NASA ADEPT |
| 5.3.2. | ADEPT Construction - Spiderweave |
| 5.3.3. | Commercial MDADs |
| 6. | ABLATIVE TPS |
| 6.1. | Overview |
| 6.1.1. | Ablative TPS |
| 6.1.2. | Ablation Introduction |
| 6.1.3. | High Energy Heatshield Environment |
| 6.1.4. | Surface Ablation Mechanisms |
| 6.1.5. | Pyrolysis |
| 6.1.6. | Material Requirements for Ablative Systems |
| 6.1.7. | Summary of Ablator Families(1) |
| 6.1.8. | Summary of Ablator Families (2) |
| 6.1.9. | Ablative TPS Timeline |
| 6.1.10. | Ablative Materials - Categorization by Form |
| 6.1.11. | Families of Ablators |
| 6.1.12. | NASA TPS Portfolio Development |
| 6.2. | Honeycomb Ablators |
| 6.2.1. | Material Composition of an Ablator (1) |
| 6.2.2. | Material Composition of an Ablator (2) |
| 6.2.3. | Honeycomb Ablators |
| 6.2.4. | Avcoat - Apollo to Orion |
| 6.2.5. | Orion Switch to Tiled Avcoat |
| 6.2.6. | Compositions of Silicone Ablators |
| 6.3. | PICA |
| 6.3.1. | PICA |
| 6.3.2. | PICA Production |
| 6.3.3. | PICA-X for SpaceX Dragon |
| 6.3.4. | Reusability of Ablators |
| 6.4. | Carbon Phenolic |
| 6.4.1. | Carbon Phenolic |
| 6.5. | 3D Woven TPS |
| 6.5.1. | Woven Thermal Protection Systems |
| 6.5.2. | HEEET |
| 6.5.3. | Woven TPS Range of Densities |
| 6.5.4. | Woven TPS Performance Envelope |
| 6.5.5. | Woven TPS for Compression Pads on Orion |
| 7. | FORECASTS |
| 7.1. | Forecasting Overview |
| 7.2. | Cost per kg to Orbit |
| 7.3. | TPS Cost Progression (1) |
| 7.4. | TPS Cost Progression (2) - Ablative |
| 7.5. | TPS Cost Progression (3) - Tile-Based |
| 7.6. | TPS Cost Progression (3) - Tile-Based |
| 7.7. | Number of Flights, 1991-2024 |
| 7.8. | SpaceX a Dominant Player Among Launch Providers |
| 7.9. | Annual Installation Area of Thermal Protection Systems |
| 7.10. | Market Value of TPS, 1991-2035 |
| 7.11. | TPS Market Value Forecast (1) |
| 7.12. | TPS Market Value Forecast (2) |
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2025年-2035年航天器热防护罩 & 隔热系统:技术和市场展望
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到2035年,TPS的市场规模将达9000万美元
报告统计信息
| 幻灯片 | 152 |
|---|---|
| 预测 | 2035 |
| 已发表 | Mar 2025 |
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