Recent advances in lunar base simulation

This article reports about the results of the latest computer runs of a lunar base simulation model. The lunar base consists of 20 facilities for lunar mining, processing and fabrication. The infrastructure includes solar and nuclear power plants, a central workshop, habitat and farm. Lunar products can be used for construction of solar power systems (SPS) or other spacecraft at several space locations. The simulation model evaluates the mass, energy and manpower flows between the elements of the system as well as system cost and cost of products on an annual basis for a given operational period. The 1983 standard model run over a fifty-years life cycle (beginning about the year 2000) was accomplished for a mean annual production volume of 78 180 Mg of hardware products for export resulting in average specific manufacturing cost of 8.4 $/kg and total annual cost of 1.25 billion dollars during the life cycle. The reference space transportation system uses LOX/LH₂ propulsion for which at the average 210 500 Mg LOX per year is produced on the moon. The sensitivity analysis indicates the importance of bootstrapping as well as the influence of market size, space transportation cost and specific resources demand on the mean lunar manufacturing cost. The option using lunar resources turns out to be quite attractive from the economical viewpoint. Systems analysis by this lunar base model and further trade-offs will be a useful tool to confirm this.     

空间太阳能电站构想及其相关技术的发展

文章介绍了太阳功率卫星（SPS）的发展背景、基本原理和系统构成,分析了实现SPS的主要技术条件。通过分析目前国际上建设SPS所开展的实验及其相关技术的发展,以期对中国未来发展空间太阳能电站技术提供借鉴。     

Study on Multi-Rotary Joints Space Power Satellite Concept

The Space Power Satellite(SPS) would be a huge spacecraft capturing the power of solar radiation in space and to supply electric power to the electric grid on the ground. The SPS concept was proposed by Dr. Peter Glaser in 1968. SPS have been studied now for exactly fifty years by many scientists in various countries. It has been regarded as one of the most promising energy projects of the future and has been attracting more attention in recent years. More and more Chinese scholars and experts are paying attention to the development of SPS. Due to the huge size, immense mass and high power of such a satellite system, there are many technical difficulties which exist to realize SPS. In this paper, recent SPS research and development activities are reviewed first. Various SPS concepts are analyzed and compared. The primary scheme of the Multi-Rotary joint SPS(MR-SPS) is described. The main feature is that the huge solar array comprising many separate small solar sub-arrays and each solar sub-array has two middle power rotary joints. So, the most challenging technology, the high-power rotary joint, is simplified by using many middlepower rotary joints hence the possibility of a single-point failure of a single rotary joint is avoided. This enables easy assembly of the modular solar arrays. Finally some key technologies of MR-SPS are analyzed.     

Comparison of advanced propulsion systems in cislunar space

Chemical engines fueled by LOX/aluminium powder, oxygen-fueled ion engines, solid core nuclear reactor engines and nuclear light bulb engines are analysed for transportation purposes in cislunar space. The markets envisaged are the nuclear waste disposal on the lunar surface and/or support of SPS construction in GEO. It is shown that the most fuel efficient permanent space transportation system is not necessarily the most economical choice due to high hardware cost.     

模块化多旋转关节空间太阳能电站方案设计

文章基于多旋转关节空间太阳能电站(MR-SPS)方案,以降低远距离高压电力传输技术难度为核心,提出一种更新的模块化多旋转关节空间太阳能电站概念。该方案在分布式太阳电池分阵和多导电旋转关节基础上,对于微波发射天线阵也进行了模块化设计和分布式布局,实现了太阳电池分阵和微波发射天线分阵的一一对应,形成多个独立的太阳能发电与能量传输模块,通过模块的扩展实现整个空间太阳能电站。该方案大幅简化了空间电力传输与管理的复杂性和在轨组装的难度。同时各个模块完全独立,组装后即可单独工作,也提高了系统的可靠性。     

European Sail Tower SPS concept

Based on a DLR-study in 1998/99 on behalf of ESA/ESTEC called “System Concepts, Architectures and Technologies for Space Exploration and Utilization (SE&U)” a new design for an Earth-orbiting Solar Power Satellite (SPS) has been developed. The design is called “European Sail Tower SPS” and consists mainly of deployable sail-like structures derived from the ongoing DLR/ESA solar sail technology development activity. Such a SPS satellite features an extremely light-weight and large tower-like orbital system and could supply Europe with significant amounts of electrical power generated by photovoltaic cells and subsequently transmitted to Earth via microwaves. In order to build up the sail tower, 60 units - each consisting of a pair of square-shaped sails - are moved from LEO to GEO with electric propulsion and successively assembled in GEO robotically on a central strut. Each single sail has dimensions of 150m × 150 m and is automatically deployed, using four diagonal light-weight carbon fiber (CFRP) booms which are initially rolled up on a central hub. The electric thrusters for the transport to GEO could also be used for orbit and attitude control of the assembled tower which has a total length of about 15 km and would be mainly gravity gradient stabilized. Employing thin film solar cell technology, each sail is used as a solar array and produces an electric power in orbit of about 3.7 MW_e. A microwave antenna with a diameter of 1 km transmits the power to a 10 km rectenna on the ground. The total mass of this 450 MW SPS is about 2100 tons. First estimates indicate that the costs for one kWh delivered in this way could compete with present day energy costs, if launch costs would decrease by two orders of magnitude. Furthermore, mass production and large numbers of installed SPS systems must be assumed in order to lower significantly the production costs and to reduce the influence of the expensive technology development. The paper presents the technical concept and an economic assessment as well as results of a recent solar sail deployment ground demonstration at DLR's facilities in Cologne.     

充气太阳能帆板展开动力学数值模拟预报

充气太阳能帆板是一种通过气体驱动支撑管展开的新型太阳能帆板。首先简要介绍其研究进展，然后针对充气展开支撑管，提出了分段式充气体积控制模型，基于LS—DYNA模拟了空间环境下Z型折叠充气太阳能帆板在支撑管无约束与有轴向约束控制时的展开过程，分析了支撑管每折叠段的气压变化，上横板的动力学特性以及基板的平面外振动，预报了展开过程中支撑管与基板的接触碰撞，并通过悬吊式展开试验验证了计算结果。结果表明，本文计算能够预报充气太阳能帆板在空间展开的动力学特性。     

Space light: space industrial enhancement of the solar option

The solar option can be enhanced significantly by space light technology. Reflectors in suitable orbits beam to Earth measured amounts of sunlight, the most versatile and bio-compatible energy source. The multitude of space light functions ranges from night illumination of rural and urban areas (by Lunetta systems) to photosynthetic production enhancement for the growth of food and of biomass for conversion to chemical fuels, local agricultural irradiation for crop drying and weather stabilization and to electric power generation by irradiating suitable photovoltaic or thermal ground receivers at night or by adding to the natural solar energy input during daytime (Soletta systems).

The Lunetta and Soletta concepts, developed by the author during the past ten years, building on the foundations laid by the great space pioneer Prof. H. Oberth (1928), are reviewed, along with their socio-economic merits. An assessment of terrestrial alternatives shows that many useful functions have no practical alternative, the major exception being electric power generation. Three systems are selected, bracketing the broad versatility of space light—Lunetta, Powersoletta and a large Biosoletta for large-scale seafood production in Antarctic and Artic waters. The systems, and several maintenance and supply requirements are described, sized and analyzed, along with suitable orbit selection for different applications. Models are developed for rural and urban area lighting, power generation at selected sites around the globe with photovoltaic and thermal ground stations and for the large-scale production of seafood at high southern and northern latitudes with ample nutrient upwell, but insufficient annual supply of solar energy. The economics of these systems is analyzed.     

Simulation model for the operation of space freighters

This paper makes the attempt to illustrate the need for a detailed operational analysis of future space transportation systems with the help of computer-based simulation models. The basic approach deemed suitable for such a systems simulation is explained in some detail. A reference program (100,000 Mg payload per year during 25 years) for a reference mission (heavy cargo transport to GEO for SPS construction) has been selected. A base-line launch vehicle (fully reusable ballistic all chemical three stage vehicle) has been defined, which is considered a serious applicant for such a mission. It was found that the take-off mass of this type of vehicle should be as large as practical from the viewpoint of cost-effectiveness. The example chosen has a GLOW of 10,000 Mg and lifts more than 100 Mg to GEO.With consideration of the operational parameters the simulation model evaluates the annual production rates, inventory of stages, utilization of facilities and operational cost, which amount within this frame of reference to about 96 $/kg net payload delivered to GEO in terms of 1980 dollars and contribute the main share to the total transportation cost.     

预应力下空间站柔性太阳翼动力学特性分析

空间站柔性太阳翼上有以下预应力:1)在轨工作时,会周期性进出地球阴影区,结构温度会发生周期性的变化,温差在结构上产生了热应力;2)中央桁架斜拉杆上作用有展开预应力;3)柔性阵面上施加有张紧力。这些预应力都会引起几何刚度,从而改变太阳翼结构的动力学特性。文章使用Abaqus非线性动力学求解功能,首先对中央桁架部分和柔性阵面部分分别建立有限元模型,研究预应力对太阳翼动力学特性的影响,发现只有柔性阵面上的张紧力影响最为显著;然后针对完整的太阳翼结构,考虑阵面张紧力作用下,研究其动力学特性,并与未考虑预应力引起的刚度变化时的结构动力学特性进行对比分析。     

Scenarios which may lead to the rise of an asteroid-based technical civilisation

In a previous paper, the author described a hypothetical development path of technical civilisations which has the following stages: planet dwellers, asteroid dwellers, interstellar travellers, interstellar space dwellers. In this paper, several scenarios are described which may cause the rise of an asteroid-based technical civilisation. Before such a transition may take place, certain space technologies must be developed fully (now these exist only in very preliminary forms): closed-cycle biological life support systems, space manufacturing systems, electrical propulsion systems. After mastering these technologies, certain events may provide the necessary financial means and social impetus for the foundation of the first asteroid-based colonies. In the first scenario, a rich minority group becomes persecuted and they decide to leave the Earth. In the second scenario, a "cold war"-like situation exists and the leaders of the superpowers order the creation of asteroid-based colonies to show off their empires' technological (and financial) grandiosity. In the third scenario, the basic situation is similar to the second one, but in this case the asteroids are not just occupied by the colonists. With several decades of hard work, an asteroid can be turned into a kinetic energy weapon which can provide the same (or greater) threat as the nuclear arsenal of a present superpower. In the fourth scenario, some military asteroids are moved to Earth-centred orbits and utilised as "solar power satellites" (SPS). This would be a quite economical solution because a "military asteroid" already contains most of the important components of an SPS (large solar collector arrays, power distribution devices, orbit modifying rocket engine), one should add only a large microwave transmitter.     

The USSR and space power plants

The American idea of a Solar Power Satellite was proposed for the first time in 1968 by Peter Glaser in a famous article in Science. This concept has since been the subject of many theoretical studies, and of some limited practical studies (mainly about microwave energy transmission) in the USA with funding from NASA and the Department of Energy (DOE). Some evaluations have been also conducted in Western Europe, particularly within the European Space Agency (ESA). But very little is generally known about the attitude towards SPS of the second main space power: the USSR. Soviet literature on SPS is much less abundant, but it does exist. Very interesting articles on the subject have been written by leading Soviet space experts. Some of these articles are analysed here, and the practical meanings of the ex[ressed opinions, generally very favourable, are investigated in view of the growing Soviet space capability.     

Evolution and logistics of an early lunar base

The planned construction of a permanently manned space station in low earth orbit has reopened the discussion about the establishment of a manned lunar base within the next 25 years for exploration of the Moon and space. Several studies demonstrate that a lunar base very modest in size may cost $50 to 90 billion spread over 25 years which would fit into the expected NASA budget for this period. Having these cost in mind the authors present a concept having a greater effectiveness based on the following operational characteristics: (1) The development of a low cost heavy-lift launch vehicle for cargo transportation and propellant supply reduces the specific transportation cost by one order of magnitude compared to the existing Space Shuttle system. (2) Orbital transfer vehicles with LOX/LH2 technology should be preferred over advanced propulsion systems because of proved technology and cost reduction by utilization of lunar produced LOX. (3) The evolution of the lunar base towards a lunar colony and manufacturing facility could only be initiated by a powerful transportation system allowing for cost-effective space construction projects and manned spaceflight to other planets.The lunar base program of this paper is based on a schedule considering a 8 years development, 5 years lunar base assembly and 20 years operational phase during which the lunar crew will increase from 60 to 180 people. Launch rates will be 10 shuttle launches and 10 HLLV launches p.a. at the average. Development costs of the transportation and lunar base system will amount to $29 billion. Adding hardware and operational costs for lunar base assembly results in the acquisition cost of $49 billion. Total life cycle costs are estimated to be in the order of $101 billion considering a 20 years operational phase which will cost $2.6 billion p.a. at the average. For the 2508 man-years spent in lunosphere the relative cost will be $40.2 million per man-year of which space transportation will cost $25.0 million per man-year.     

Space solar power vs space communications

To meet the future needs of energy on Earth, the transmission of solar power from space is being extensively studied. Since the power station will occupy a position in the geostationary orbit and will use radio frequency spectrum for transmission of energy to Earth, the relative benefits of space solar power and space communications should be considered. The resource allocation of orbit-spectrum to a power station requires a sacrifice from space communications as they both utilize similar limited resources. The power station is to energy what communication is to information. While the cost of energy is going up, the cost of information processing, storage, sharing and transmission is decreasing. Also, increased means of communication are used as a measure of energy conservation. With the advent of computer communication and the Large Scale Integrated (LSI) microprocessors, the technique of multiple access, message switching and satellite switching can be cost-effectively combined. The computer-satellite communication will allow information resource sharing among large numbers of users besides the conventional application of space communications. Since space communication means work effectively in many other areas where ultimate energy use and conservation is possible, the space solar power will not be able to compete or substitute on the basis of equality and social benefits. But, as the transmission technology is similar for both areas, the R & D effort for solar power will certainly increase efficiency and reduce cost for space communications.     

Concept study on Deep Space Orbit Transfer Vehicle

In this paper, the concept of Orbit Transfer Vehicle for Deep Space Exploration (Deep Space OTV) is proposed, and its effectiveness and feasibility are discussed. Basic concept is the separation of two functions required for the deep space exploration, the transportation to the destination, and the exploration at the destination. Deep Space OTV is a spacecraft specialized for the transportation to the deep space destination. It is an expendable spacecraft propelled by solar electric propulsion. The payload of Deep Space OTV is Explorer, which is a spacecraft specialized for the exploration at the deep space destination. The effectiveness of the concept is discussed qualitatively, focused on the merits of the separations of two functions. The feasibility of Deep Space OTV is discussed based on the conceptual design of the spacecraft and its applicability to deep space missions. Several deep space missions are modeled and the payload capacity of Deep Space OTV is estimated. The missions include Asteroid rendezvous, Mars orbiter, Lunar lander, and so on.     

多旋转关节空间太阳能电站概念方案设计

对于国际上典型的空间太阳能电站概念方案进行了分析,在此基础上提出了一种新的概念方案--多旋转关节空间太阳能电站,并给出总体构型和主要分系统初步方案设计结果。该方案采用多个相互独立的太阳电池子阵代替了传统的整体式太阳电池阵,以多个中等功率的导电旋转关节替代传统的极高功率的旋转关节,不仅解决了传统空间太阳能电站方案中的极大功率导电旋转关节技术难题,还可以避免导电关节的单点失效问题,模块化的设计也使得系统的组装和构建更加可行。     

Design-to-Cost Applied Within an Integrated System Model

In an environment of declining financial budgets for space projects, new approaches - such as Design-To-Cost - are being implemented to improve today's satellite design processes. Using an example of a current mission (the power subsystem of the Solar Probe spacecraft) under study at NASA's Jet Propulsion Laboratory, the main part of the paper discusses an Integrated System Model (structured into a performance model, a cost model, and an effectiveness model) that is part of a model-based design process used to perform cost-effectiveness trades. A simulation tool is used during the first step to size the components of the power subsystem, and then simulate its performance during operation. The determined dimensions are transferred into an EXCEL^TM-spreadsheet and linked to the components' costs. With a cost accounting tool that combines cost estimating relationships with the Work Breakdown Structure of the power subsystem, the life-cycle cost of each alternative design concept is computed. To determine the cost-risk of the different design alternatives for each component, cost probability distributions are introduced. By performing Monte-Carlo simulations, cost sensitivities are revealed. In the next step of the trade study process, the effectiveness of the alternatives is analyzed. Having determined cost and effectiveness, estimates can be made for where the different alternatives lie in the design space. The last part of the paper identifies the main drivers for the spacecraft's performance and cost. Finally it is shown how the mission design benefited from the Integrated System Model and from the application of Design-To-Cost.     

地空导弹防太阳辐射的论证、设计与试验

介绍了太阳辐射的基本概念、能量分布情况及其对地空导弹武器装备的影响，给出了论证地空导弹武器环境适应性时太阳辐射强度取值的依据、降低太阳辐射影响的措施和太阳辐射试验的参数取值依据以及对试验设备的要求，可供从事环境适应性论证、设计与试验工作的人员参考。     

The role of international organizations in SPS

Based on simulation of an SPS business case (described in the appendix), the requirements and options for international cooperation in the development and operation of solar power satellites (SPS) and power receiving plants on the ground (rectennas) are discussed. Industrial matters and financial aspects are included. Four specific near-term actions are suggested that fit within the responsibilities of international organisations such as the World Bank and EIB, IEA, ITU, WHO and UNCOPUOS.