doi: 10.17586/2226-1494-2020-20-1-132-140


ENERGY STORAGE DEVICE OPTIMIZATION IN PERIPHERY-TYPE DOCKING ASSEMBLY

Y. V. Rasskazov, I. E. Chernyshev


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Rasskazov Ya.V., Chernyshev I.E. Energy storage device optimization in periphery-type docking assembly. Scientific and Technical Journal of Information Technologies, Mechanics and Optics, 2020, vol. 20, no. 1, pp. 132–140 (in Russian). doi: 10.17586/2226-1494-2020-20-1-132-140


Abstract
The paper considers selection of parameters of the spacecraft periphery-type docking assembly. The kinematic scheme of its docking mechanism is based on the Gough-Stewart platform. Constructive implementation of its linear elements in operation is called the rods, and the controlled element is called a docking ring. The docking mechanism is characterized by the ability to accumulate the kinetic energy of spacecraft approach rather than to dampen it. To achieve this, anenergy storage device is placed into each rod and incorporates a non-linear spiral spring mechanism. The energy storage device absorbs the kinetic energy of spacecraft approach and prevents its return after latching. The spiral spring mechanism implements a predetermined rod compression diagram and provides the necessary docking resistance force for spacecraft approach. The paper presents a general view of the rod compression diagram and the restrictions imposed on it. The model of the rod compression diagram is given, which is characterized by the introduction of a variable spring rate coefficient, and the method for identification of parameters is described. The method uses the calculation of the minimum mass of the spring mechanism. The method of parameters selection for a nonlinear spiral spring mechanism is given with predetermined dimension restrictions. The proposed methods can be used in the energy storage device optimization of the periphery-type docking assembly.

Keywords: spacecraft, docking mechanism, parallel manipulator, Gough-Stewart platform, parameters optimization, energy accumulation, nonlinear spiral spring mechanism

Acknowledgements. The work was carried out as part of the investment project at S.P. Korolev Rocket and Space Public Corporation Energia.

References
1. Yaskevich A.V., Pavlov V.N., Chernyshev I.E., Rasskazov Ya.V., Zemtsov G.A., Karpenko A.A. Peripheral docking adapter. Patent RU2657623, 2018. (in Russian)
2. Gough V.E. Contribution to discussion of papers on research in Automobile stability, control, and tyre performance. Proc. Auto Div., Inst. Mech. Eng, 1956, vol. 171, pp. 392–394.
3. Stewart D. Platform with six degrees of freedom. Proceedings of the Institution of Mechanical Engineers, 1965, vol. 180(1), no. 15, pp. 371–386.
4. Claessens D., Preud’Homme F., Paijmans B. Development of the International Berthing and Docking Mechanism compatible with the International Docking System Standard. Proc. 63rd International Astronautical Congress, IAC-2012, October 1-5, Naples, Italy, pp. IAC-12,B3,7,9,x15451. Available at: http://iafastro.directory/iac/ archive/browse/IAC-12/B3/7/15451/ (accessed: 28.01.2020).
5. Dittmer H., Gracia O., Caporicci M., Paijmans B., Meuws D. The International berthing Docking Mechanism (IBDM): Demonstrating full compliance to the International Docking System Standard (IDSS). Proc. 66th International Astronautical Congress, IAC 2015, October 12-16, Jerusalem, Israel, pp. IAC-15,B3,7,7,x30720. Available at: https://iafastro.directory/iac/archive/browse/IAC-15/B3/7/30720/ (accessed: 23.07.2019).
 6.  MotaghediP.,GhofranianS.FeasibilityoftheSIMACfortheNASA Docking System. AIAA Space and Astron. forum and expos (SPACE 2014),2014,pp.1–8.Availableat:https://ntrs.nasa.gov/archive/nasa/ casi.ntrs.nasa.gov/20140009916.pdf (accessed: 23.07.2019).
7.  Ghofranian S., Chuang L-P., Motaghedi P. Spacecraft Docking System.PatentUS20150266595A1.Availableat:http://google.com/patents/US20150266595 (accessed: 23.07.2019).
8.  McFatter J., Keiser K., Rupp T. NASA Docking System Block 1: NASA’snewdirectelectricdockingsystemsupportingISSandfuture human space exploration. Proc. 44th Aerospace Mechanism Symposium, NASA Glenn Research Center, 2018, pp. 471–484. Available at: https://hdl.handle.net/2060/20180002828 (accessed: 28.01.2020).
9.  RasskazovYa.V.Energyaccumulatordeviceforanewperipheraldocking mechanism. Space technique and technologies, 2019, no. 3(26), pp. 39– 46. (in Russian). doi:10.33950/spacetech-2308-7625-2019-3-39-46
10.  Yaskevich A.V., Chernyshev I.E. Choice of energy accumulator parametersforanewperipheraldockingmechanism.Spacetechnique and technologies, 2019, no. 2(25), pp. 55–66. (in Russian). doi: 10.33950/spacetech-2308-7625-2019-2-55-66
11.  Syromjatnikov V.S Androgynous peripheral mating unit and damper of shock-absorbing and actuating system for this unit. Patent RU 2131829. 1999. (in Russian)
12.  Ilina V.A., Silaev P.K. MAXIMA Analytic Computing System for Theoretical Physicists. Moscow, Lomonosov Moscow State University, 2007, 112 p. (inRussian)
13.  Rasskazov Y.V. The function model of docking unit nonlinear spiral springmechanism.IzvestiyaTulGU.Technicalsciences,2018,no.10, pp. 307–317. (in Russian)
14.  Gevondian T.A. Spring Engines: Theory, Calculation, Control and TestingMethods.Moscow,OborongizPubl.,1956,368p.(inRussian)
Yaskevich A.V. Spacecraft docking dynamic features by using a peripheralmechanismwithaccumulationofapproachkineticenergy. Space technique and technologies, 2019, no. 4(27), pp. 109–120. (in Russian)


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