EXPERIMENTAL UNIT FOR DETERMINING BODY WEIGHT OF ASTRONAUTS AND LIGHT-WEIGHT OBJECTS IN ZERO-GRAVITY CONDITIONS

Main Article Content

Oleksii Kolomiitsev
Volodymyr Komarov
Oleh Dmitriiev
Volodymyr Pustovarov
Ruslan Oliinyk

Abstract

The transition of an astronaut into zero gravity leads to a certain restructuring of the body, including the redistribution of fluid flows in it. The process of dehydration of the body is stimulated, the astronaut loses weight. Knowledge of the regularities of changes in an astronaut's body weight, keeping it within normal limits thanks to a rational load distribution, rest, physical exercises, and a well-thought-out diet are extremely necessary in order to provide the astronaut with the most favorable conditions for adaptation in zero gravity, as well as to better prepare him for his return to Earth. Returning materials for scientific research and experiments, as well as equipment, from the space station to Earth also requires high-precision determination of the low weight of objects. The object of the research is an experimental unit that allows measuring the weight (parameters) of the astronaut’s body and the small weight of objects (equipment, devices, etc.) that oscillate. The subject of research is the frequency of natural oscillations of the dynamic system. The purpose of scientific work is the development of an experimental unit for determining the weight of the astronaut’s body and the low weight of objects in zero gravity. Conclusions. An experimental setup for determining the body weight of astronauts and the low weight of objects (control objects – СО) in zero gravity is proposed. For high-precision determination of the weight of the СО in zero gravity, the natural frequency (NF) was chosen as a diagnostic parameter. In the experimental installation, the weight of the OC is determined by changing the NF of the dynamic system "control object – moving anchor" depending on the attached weight of the СO. The essence of the work of the experimental unit is revealed, and its general appearance and structural scheme are presented.

Article Details

How to Cite
Kolomiitsev, O., Komarov, V., Dmitriiev, O., Pustovarov, V., & Oliinyk, R. (2022). EXPERIMENTAL UNIT FOR DETERMINING BODY WEIGHT OF ASTRONAUTS AND LIGHT-WEIGHT OBJECTS IN ZERO-GRAVITY CONDITIONS. Advanced Information Systems, 6(3), 92–98. https://doi.org/10.20998/2522-9052.2022.3.12
Section
Applied problems of information systems operation
Author Biographies

Oleksii Kolomiitsev, National Technical University "Kharkiv Polytechnic Institute", Kharkiv

Doctor of Technical Sciences, Professor, Professor of Department «Computer engineering and programming»

Volodymyr Komarov, Central research institute of armament and military technique of Military Powers of Ukraine, Kyiv

candidate of technical sciences, Chief of research department

Oleh Dmitriiev, Flight Academy of the National Aviation University, Kropyvnytskyi

Doctor of technical sciences, associate professor, the head of department

Volodymyr Pustovarov, Kharkiv representative office of general customer – the State space agency of Ukraine, Kharkiv

candidate of technical sciences, chief of group

Ruslan Oliinyk, State Scientific Research Institute of Armament and Military Equipment Testing and Certification, Chernihiv

Chief of Section

References

Eiderman, V.L. (1980), Theory of mechanical oscillations, Higher school, Moscow, 408 p.

Ananiev, I.V. & Colvin, N.M. (1969), Influence of local rigidity of rods on the frequency of natural oscillations, AI, 120 p.

Mikishev, G.N. & Rabinovich, B.I. (1968), Dynamics of a rigid body with cavities partially filled with liquid, Mashinostroenie, Moscow, 532 p.

Rumyantsev V.V. (1957), “Rotation stability of a rigid body with an ellipsoidal cavity filled with liquid”, Applied mathematics and mechanics, Vol. 21, no. 6, pp. 740-748.

(1980), “Vol. 3. Oscillations of machines, structures and their elements”, Vibration in technology: Handbook, 544 p.

Chandaeva, S.A. (1994), Physics and people, AT "Aspect Press", Moscow, 136 p.

(2021), Body weight and weightlessness, available at: http://um.co.ua/13/13-7/13-72477.html.

(2021), Space scales, available at: https://habr.com/ru/post/379349/.

(2021), How people are weighed in zero gravity on the ISS, available at: https://pikabu.ru/story/ .

(2021), Invented a non-contact method of weighing people in zero gravity, available at: https://www.unn.com.ua

(2021), Weightless body mass meter, available at: http://wiki-org.ru/wiki/Измеритель_массы_тела_в_невесомости.

Bezrodny D.A. (2017), Gravimetry. Book 1. Theoretical foundations of gravimetry, Taras Shevchenko National University, Kyiv, 188 p., available at: http://www.geol.univ.kiev.ua/lib/gravimetriya1.pdf.

Kolomiitsev, O., Komarov, V., Dmitriiev, O., Pustovarov, V. and Oliinyk, R. (2022), “Method for controlling the frequency of eigentones for determination of the astronaut’s body weight and small weight in zero gravity”, Advanced Information Systems, Vol. 6, No. 2, pp. 74–81, doi: https://doi.org/10.20998/2522-9052.2022.2.12.