基于数字孪生框架的可重复使用航天器任务规划动态可靠性预测方法

B. Gao, Yumei Ye, Xin Pan, Qiang Yang, W. Xie, S. Meng, Y. Huo
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引用次数: 0

摘要

可重复使用航天器在降低航天发射成本方面具有巨大的潜力。结构可靠性评估是可重复使用航天器任务规划的关键。提出了一种基于数字孪生框架的任务规划动态可靠性预测方法。该方法通过动态贝叶斯网络实现不确定性集成和动态模型更新。当预测的结构可靠性水平低于阈值或出现着陆撞击等意外情况时,需要设置维修点。然后,框架可以吸收检测数据,动态更新结构的可靠度。因此,它支持维修间隔的动态调整、结构故障的早期预警和风险量化的任务规划。通过考虑航天器简化结构在疲劳载荷和着陆冲击下单点裂纹扩展的数值算例进行了验证。结果表明,该方法可以对裂纹尺寸预测进行校正,减小了预测的不确定性。可靠性预测中着陆撞击概率的合理选择有助于维修间隔的控制。利用新的检验数据进行模型更新可以提高航天器的可靠性,表明该方法可以实现航天器寿命的潜在延长。
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A Dynamic Reliability Prognosis Method For Reusable Spacecraft Mission Planning Based On Digital Twin Framework
Reusable spacecraft has great potential in reducing space launch cost. Structural reliability evaluation is critical for mission planning of reusable spacecraft. A dynamic reliability prognosis method based on digital twin framework is proposed for mission planning in the paper. In this method, Uncertainties integration and dynamic model updating are implemented through a dynamic Bayesian network. A maintenance point is set when the predicted structural reliability level is lower than a threshold or unexpected conditions such as landing impact occur. Then, inspected data can be assimilated by the framework to dynamically update the structural reliability. Thus, it supports dynamic adjustment of maintenance interval, early warning of structure failure, and mission planning with quantified risk. A numerical example considering single point crack growth under fatigue load and landing impact of a simplified spacecraft structure is used for demonstration. Results show that the crack size predictions can be calibrated by inspected data and its uncertainties can be reduced. The proper selection of landing impact probability in reliability prediction is helpful to control the maintenance interval. The reliability of the spacecraft can be increased through model updating with new inspected data, representing a potential lifetime extension can be realized by the proposed method.
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CiteScore
5.20
自引率
13.60%
发文量
34
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