共查询到17条相似文献,搜索用时 908 毫秒
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对航天器太阳电池阵分流技术进行了归纳总结,对PWM,S3R和S4R三种开关分流调节技术进行了详细的原理分析,比较总结各自的技术特点。并对S3R和S4R技术进行了深入研究,对S3R技术进行了详细的设计与计算,对S4R技术典型工况进行了详细分析与实验验证。同时对三种开关分流技术做出了评价。 相似文献
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一种新的航天器电源系统拓扑 总被引:3,自引:2,他引:1
介绍了一种新的航天器电源系统拓扑结构,通过采用最大功率跟踪控制器控制顺序开关系统调节(S3R)分流调节器,并使用升压变换器获得稳定的100V一次输出母线,使得太阳电池阵功率被充分使用。这种拓扑结构已被用于欧洲贝皮·哥伦布水星探测器,并可为我国航天器电源技术发展提供借鉴。 相似文献
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针对航天器平台一级能源变换高压大功率的应用需求,采用并联式DC/DC变换器的最大功率点跟踪(MPPT)拓扑结构,设计一种顺序开关分流最大功率调节(S~3MPR)电源控制器。为了解决传统S~3MPR技术的算法电路复杂、跟踪精度低等问题,兼顾航天器应用环境的特殊性,通过采用模拟电路实现的方式设计出一种基于交错扰动方法的MPPT控制算法电路。该算法可以实现太阳电池阵电压电流输出较大范围内精确跟踪其最大功率输出。研制了5 kW功率(10路太阳电池阵)的原理样机对设计进行试验验证,结果表明:电源控制器性能良好,满足高压大功率航天器平台的应用需求。 相似文献
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S4R功率调节技术在航天器上的仿真研究与实现 总被引:1,自引:1,他引:0
对于大功率母线的航天器,传统的母线功率调节技术因为诸多缺点已经不能适应母线功率不断增大的要求。S4R作为一种新型的卫星母线调节技术能够很好的控制母线电压,同时具有优良的电池充、放电特性和很高的效率。在对国、内外S4R技术研究的基础上,从S4R的工作原理出发,给出了S4R功率调节技术的实现策略。在此基础上进行了实际电路的仿真分析,最后给出了部分实际的工作波形.并展望了其应用前景。 相似文献
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高压大功率及模块化安装的卫星功率平台,采用S4R(Sequential Series Shunt Switch Regulator)功率调节技术。针对提高高压大功率空间EPS的效率及动态响应,采用非线性重叠调用和2阶噪声整形调制技术,解决了基于S4R型功率EPS单纯增加输出滤波电容来提高平台动态性能及效率问题。仿真及实验结果表明了该方法的有效性。 相似文献
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提出一种深空探测器电源系统设计方案,采用高转换效率三结砷化镓太阳电池、半刚性基板轻量化技术及高比能锂离子蓄电池组;提出并采用一种基于顺序开关分流(S3R)结构的扰动交错法最大功率点跟踪(MPPT)技术,提高了太阳能源利用率;提出并采用一种适应空间电源的机内测试技术(BIT),以提升电源自主管理能力。32%效率三结砷化镓太阳电池及其半刚性基板,已经通过鉴定试验验证。能量密度195W·h/kg的钴酸锂离子蓄电池组及MPPT和BIT技术,已经应用到国内航天器正样产品;经过验证,MPPT追踪速度为毫秒级,追踪精度可达98%。文章提出的设计可为深空探测器电源系统轻量化和电源能量自主管理需求提供解决途径。 相似文献
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电源系统的稳定性是保证载人航天器在轨飞行可靠安全的要素之一。文章研究了应用混合型功率调节技术的电源系统放电调节器的建模方法,获得了系统开环传递函数,进行了仿真验证,在此基础上分析了影响放电调节器稳定性的因素,表明系统中存在过大的延迟会使系统的稳定性大幅降低甚至造成不稳定,地面试验结果验证了此结论的正确性。 相似文献
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《中国航天(英文版)》2019,(2)
A 28 V-half-regulated power bus topology and an integrated PCDU(Power Conditioning and Distribution Unit) were adopted to meet the energy demand for the Chang'e 4 relay satellite. This paper first introduces the mission features and composition of the PSDS(Power Supply and Distribution System) for the Chang'e 4 relay satellite. Due to this satellite's unusual orbit, operational mode and project restrictions, special analysis and design was conducted on the PSDS from the perspective of weight-reduction, power management, and reliability and so on. Extreme low temperature storage of SA(Solar Array) was considered and how the antenna affects the SA was analyzed. A new kind of high-specific-energy 45 Ah(Ampere-hour) battery cell was used for the first time. To make sure that the satellite would successfully pass the long shadow zones, a 100% DOD(Depth of Discharge) experiment was carried out on the battery. Since the sunlight is almost always available and there are very few times for the battery to charge or discharge, battery care to extend its lifetime is also discussed. PCDU is a device that integrates power conditioning and power distribution in one unit. The PCDU on Chang'e 4 relay satellite can output more power with less weight because of the adoption of a 28 V-half-regulated power bus topology which was also used for the first time and used lighter material for its mechanical framework. Experiment under low temperature on PCDU was conducted as well and a hot backup equalizing charge technique which is beneficial to keep performance of the battery is illustrated. The power distribution module, which is a module of PCDU, enhances the power utilization security by utilizing a static impedance measurement and build-in-test to avoid possible short circuits. As for EED(Electrical Explosive Device) module, a protection plug was specially designed and three switches with different functions were connected in series to prevent the EED from exploding by error. In addition, the allowable minimum EED bus voltage for each EED was evaluated in case of low battery voltage caused by the possible postponement of the launching time. Complete verification experiments on the ground were conducted to confirm the correctness of the design and on-orbit test data conformed to the expected results and theoretical calculation. The power supply and distribution system has been working normally since the day the Chang'e 4 relay satellite was launched into space. 相似文献
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