A Lokaveer, Thomas Anjana, Maliyekkal Yasir, S Yogahariharan, Akash Dewangan, Saurabh Kishor Mahajan, Sakshi Aravind Tembhurne, Gunja Subhash Gupta, Devashish Bhalla, Anantha Datta Dhruva, Aloke Kumar, Koushik Viswanathan, Vikram Khaire, Anand Narayanan, Priyadarshnam Hari
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引用次数: 0
摘要
SSPACE 天体生物学有效载荷(SAP)系列,从 SAP-1 项目开始,旨在低地球轨道上进行原位微生物学实验。该有效载荷系列旨在了解空间微生物有机体的行为,特别是那些对人类健康至关重要的微生物有机体的行为,以及微重力和太阳/银河辐射造成的相应影响。SAP-1的重点是研究对人类有益的细菌Bacillus clausii和Bacillus coagulans。其目的是为微重力条件下的天体生物学实验提供一个空间实验室。为这些实验开发的硬件是本土的,通过控制压力、温度和细菌的营养流来满足自主微生物学实验的独特要求。构成核心设计的旋转平台被创新性地用于调节营养物质与休眠细菌的流动和混合。在 SSPACE 开发的技术示范模型已经取得了可喜的成果,目前正在努力进行改进,以适应太空条件,并为与纳米卫星或太空舱集成做好准备。预期的有效载荷将非常紧凑,大小约为 1U (10 厘米 x 10 厘米 x 10 厘米),功耗小于 5 瓦,并为各种微生物研究提供灵活性。
The SSPACE Astrobiology Payload (SAP) series, starting with the SAP-1 project
is designed to conduct in-situ microbiology experiments in low earth orbit.
This payload series aims to understand the behaviour of microbial organisms in
space, particularly those critical for human health, and the corresponding
effects due to microgravity and solar/galactic radiation. SAP-1 focuses on
studying Bacillus clausii and Bacillus coagulans, bacteria beneficial to
humans. It aims to provide a space laboratory for astrobiology experiments
under microgravity conditions. The hardware developed for these experiments is
indigenous and tailored to meet the unique requirements of autonomous
microbiology experiments by controlling pressure, temperature, and nutrition
flow to bacteria. A rotating platform, which forms the core design, is
innovatively utilised to regulate the flow and mixing of nutrients with dormant
bacteria. The technology demonstration models developed at SSPACE have yielded
promising results, with ongoing efforts to refine, adapt for space conditions,
and prepare for integration with nanosatellites or space modules. The
anticipated payload will be compact, approximately 1U in size (10cm x 10cm x
10cm), consume less than 5W power, and offer flexibility for various
microbiological studies.