Dynamic Behavior Analysis and Stability Control of Tethered Satellite Formation Deployment

Zhang, Kangyu; Lu, Kuan; Gu, Xiaohui; Fu, Chao; Zhao, Shibo

doi:10.3390/s22010062

Cited by 8 publications

(3 citation statements)

References 31 publications

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“…This pulling force turns the potential energy of the debris into kinetic energy. Space tether systems are varying in terms of many different aspects, such as open-loop or closed-loop control (Sun and Zhong, 2020;Zhu et al, 2021) and rigid or elastic (Zhao et al, 2020;Razzaghi et al, 2021;Shan and Shi, 2021;Hu et al, 2022;Zhang et al, 2022). Space tethers are very famous and have a wide range of application areas.…”

Section: Tethering Methodsmentioning

confidence: 99%

ET-Class: An Energy Transfer-Based Classification of Space Debris Removal Methods and Missions

Yalçin¹,

Martinez²,

Delisle³

et al. 2022

Front. Space Technol.

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Space debris is positioned as a fatal problem for current and future space missions. Many effective space debris removal methods have been proposed in the past decade, and several techniques have been either tested on the ground or in parabolic flight experiments. Nevertheless, no uncooperative debris has been removed from any orbit until this moment. Therefore, to expand this research field and progressing the development of space debris removal technologies, this paper reviews and compares the existing technologies with past, present, and future methods and missions. Moreover, since one of the critical problems when designing space debris removal solutions is how to transfer the energy between the chaser/de-orbiting kit and target during the first interaction, this paper proposes a novel classification approach, named ET-Class (Energy Transfer Class). This classification approach provides an energy-based perspective to the space debris phenomenon by classifying how existing methods dissipate or store energy during the first contact.

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Section: Tethering Methodsmentioning

confidence: 99%

ET-Class: An Energy Transfer-Based Classification of Space Debris Removal Methods and Missions

Yalçin¹,

Martinez²,

Delisle³

et al. 2022

Front. Space Technol.

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show abstract

“…While these efforts displays a huge leap in space debris removal and tests showed promising results, harpoons are still associated with high risks of additional debris production due to the forces required to penetrate the target's surface material while preventing a large impulse generation and thus pushing the target from its current course. Furthermore, complex rope dynamics between chaser and target have not been investigated in this mission and present a technical challenge (Zhang et al, 2021). Both, nets and harpoons offer great opportunities for their adaptation by using biological models as inspiration.…”

Section: Existing Bio-inspired Debris Removal Conceptsmentioning

confidence: 99%

Biomimetics for innovative and future-oriented space applications - A review

Banken

Oeffner²

2023

Front. Space Technol.

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Nature benefits from a progressive evolution over millions of years, always adapting and finding individual solutions for common problems. Hence, a pool of diverse and efficient solutions exists that may be transferable to technical systems. Biomimetics or bio-inspiration has been used as a design approach for decades, revolutionizing products and processes throughout various industries. Thus, multiple examples can also be found in the space sector, since many characteristics found in biological organisms are also essential for space systems like response-stimuli adaptability, robustness and lightweight construction, autonomy and intelligence, energy efficiency, and self-repair or healing capabilities. This review focuses on biomimetics within the field of aerospace engineering and summarizes existing bio-inspired concepts such as drilling tools (wood wasp ovipositor drilling), telescopes (lobster eye optics), or gasping features (gecko feet adhesion capabilities) that have already been conceptualized, partially tested, and applied within the space sector. A multitude of biological models are introduced and how they may be applicable within the space environment. In particular, this review highlights potential bio-inspired concepts for dealing with the harsh environment of space as well as challenges encountered during rocket launches, space system operations and space exploration activities. Moreover, it covers well-known and new biomimetic concepts for space debris removal and on-orbit operations such as space-based energy production, servicing and repair, and manufacture and assembly. Afterwards, a summary of the challenges associated with biomimetic design is presented to transparently show the constraints and obstacles of transferring biological concepts to technical systems, which need to be overcome to achieve a successful application of a biomimetic design approach. Overall, the review highlights the benefits of a biomimetic design approach and stresses the advantage of biomimetics for technological development as it oftentimes offers an efficient and functional solution that does not sacrifice a system’s reliability or robustness. Nevertheless, it also underlines the difficulties of the biomimetic design approach and offers some suggestions in how to approach this method.

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“…Zhang et al [ 9 ] analysed the nonlinear dynamic behaviour of tethered satellite formation systems in tethered space systems (TSSs) based on a simplified rigid-rod tether model. Two new stability control laws were proposed based on the tether release rate and tether tension for controlling the variation of tether length.…”

mentioning

confidence: 99%

Advanced Sensing, Fault Diagnostics, and Structural Health Management

et al. 2022

Sensors

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Dynamic Behavior Analysis and Stability Control of Tethered Satellite Formation Deployment

Cited by 8 publications

References 31 publications

ET-Class: An Energy Transfer-Based Classification of Space Debris Removal Methods and Missions

ET-Class: An Energy Transfer-Based Classification of Space Debris Removal Methods and Missions

Biomimetics for innovative and future-oriented space applications - A review

Advanced Sensing, Fault Diagnostics, and Structural Health Management

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