Development of the aeromagnetic space debris deorbiting system

Lapkhanov, Erik; Khoroshylov, S.V.

doi:10.15587/1729-4061.2019.179382

Cited by 16 publications

(26 citation statements)

References 16 publications

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“…Taking these shortcomings into account, a new design scheme of an aeromagnetic deorbiting system with executive devices based on permanent magnets was proposed in [4]. This system was proposed for deorbiting worked-out spacecraft from low Earth orbits as a part of the solution to the global problem of choking of the near-Earth space.…”

Section: Literature Review and Problem Statementmentioning

confidence: 99%

“…This system was proposed for deorbiting worked-out spacecraft from low Earth orbits as a part of the solution to the global problem of choking of the near-Earth space. The results of studies using a nonlinear discrete controller in [4] have shown its performance and advantages compared to the electromagnetic systems. However, no complete analysis and synthesis of the law of angular motion control were provided.…”

Section: Literature Review and Problem Statementmentioning

confidence: 99%

“…orientation of aerodynamic elements perpendicular to a dynamic flow of incoming atmosphere [4] in order to increase braking force in solving the problem of deorbiting worked-out spacecraft [5][6][7][8][9][10][11][12];…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, executive devices with permanent magnets (EDPM) have been proposed. Their use reduces on-board energy consumption for orientation control [4]. In turn, minimum on-board energy consumption when using EDPM is provided only for rough stabilization.…”

Section: Introductionmentioning

confidence: 99%

“…Thus, the proposed EDPMs are appropriate for application in the space-related problems that do not require precision spacecraft orientation. One such problem is the uniaxial stabilization of spacecraft equipped with an aeromagnetic deorbiting system (AMDS) [4].…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Synthesizing an algorithm to control the angular motion of spacecraft equipped with an aeromagnetic deorbiting system

Алпатов¹,

Khoroshylov²,

Lapkhanov³

2020

EEJET

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Section: Literature Review and Problem Statementmentioning

confidence: 99%

Section: Literature Review and Problem Statementmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Synthesizing an algorithm to control the angular motion of spacecraft equipped with an aeromagnetic deorbiting system

Алпатов¹,

Khoroshylov²,

Lapkhanov³

2020

EEJET

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Potato Sprout Inhibition and Tuber Quality after Post-Harvest Treatment with Rosemary (Rosmarinus Officinalis L.) Leaves and Branches

Talei

Bina

Valdiani

et al. 2017

HIJ

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Storage of potatoes is one of the most important concerns in maintaining freshness and nutritional quality in the storage process. To achieve this, an experiment was carried out with five different storage conditions at various temperatures using fresh rosemary leaves and branches with three replicates. The results revealed that storage of potatoes at 25°C with rosemary leaves and branches resulted in the lowest sprout development and weight loss after 10 weeks. This was significantly different from either 4°C or 30°C. The findings indicated the potential of rosemary fresh leaves and branches to improve potato storage life considering its simplicity and efficacy in decreasing the storage cost, the weight loss and sprouting without causing any environmental toxicity. In addition, the potential of rosemary could be used to other fruits and vegetables to investigate further the possible role of rosemary application to prevent fungal rot.

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Features of the use of magnetic controls in a coarse stabilization of spacecraft with aeromagnetic deorbit systems

Lapkhanov¹

2020

Teh. Meh.

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The development of hybrid deorbit means for used spacecraft is a promising line in the elaboration of space debris mitigation technologies. The main objective of this line is a search for optimal solutions in the development of new means for spacecraft removal from near-Earth orbits with account for certain operating limitations on the use of existing deorbit systems. So the advantage of hybrid deorbit means lies in broadening the scope of application of modern deorbit systems by combining certain technical features of each of them when developing a new system. One of the lines in the development of hybrid means for space debris deorbit is the development of aeromagnetic deorbit systems for removing used spacecraft from low-Earth orbits. This class of systems features the possibility of controlled deorbit when using aerodynamic flat sailing elements. The control objective is the angular stabilization of a flat aerodynamic element perpendicular to the incident atmospheric flow.. Studies have shown that this stabilization of a flat sailing element increases the aerodynamic drag by 20-40 % and reduces the deorbit time by 25-30 % as compared to nonoriented deorbit, which broadens the scope of application of aerodynamic sailing deorbit systems. In aeromagnetic deorbit systems, the control actuators are magnetic attitude control systems (MACSs). The main criterion for the MACS effectiveness in a particular mission is a minimum of onboard power consumption. This may be achieved by using permanent-magnet actuators or spacecraft electromagnets (magnetorquers) in the rough stabilization mode. In its turn, in the rough stabilization mode the onboard power consumption is minimized when using time-shared control methods for the magnetorquers and a nonlinear discrete control law for the permanent-magnet actuators. The aim of this paper is to develop methodological foundations for the use of permanent-magnet actuators and magnetorquers in the attitude control of used spacecraft with aeromagnetic deorbit systems. The paper makes an analytical comparison of the use of permanent-magnet actuators and magnetorquers depending on the spacecraft design features, mass, size, and energy characteristics and presents an algorithm of MACS choice for spacecraft of various classes equipped with aeromagnetic deorbit systems.

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Development of the aeromagnetic space debris deorbiting system

Cited by 16 publications

References 16 publications

Synthesizing an algorithm to control the angular motion of spacecraft equipped with an aeromagnetic deorbiting system

Synthesizing an algorithm to control the angular motion of spacecraft equipped with an aeromagnetic deorbiting system

Potato Sprout Inhibition and Tuber Quality after Post-Harvest Treatment with Rosemary (Rosmarinus Officinalis L.) Leaves and Branches

Features of the use of magnetic controls in a coarse stabilization of spacecraft with aeromagnetic deorbit systems

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