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    • Mathematical modeling of thermal fields inside Foton-M Spacecraft.

    Paper number

    IAC-05-A2.2.02

    Author

    Prof. Nickolay N. Smirnov, Moscow Lomonosov State University, Russia

    Coauthor

    Dr. Oleg Ivashnyov, Moscow Lomonosov State University, Russia

    Coauthor

    Mrs. Anfisa E. Kazakova, Central Specialised Design Bureau of, Russia

    Year

    2005

    Abstract
    The goal of the present investigation was determining thermal fields established inside the scientific module of the spacecraft Foton-M. The motivation for the study was an essentially non-uniform heat release from different pieces of equipment incorporated in the capsule, and strong requirements for temperature range allowable for operation of other pieces of equipment, especially equipment designed for biotechnological experiments. 
To make thermal fields more uniform within the module special fans are used to facilitate convective heat exchange. Some extra heat is removed from the capsule with the help of special gas-liquid cooler. Extra heat generated by scientific equipment is absorbed by the gas filling the capsule and transported by convective flows to the gas-liquid heat exchanger, which absorbs the heat and transfers it to the outer section, which radiates heat into the outer space. The rate of cooling is controlled by the flow rate of heat carrying fluid.
The goal of the project was to develop a mathematical model of the convective heat exchange process inside the capsule filled in with scientific equipment. The gravitational convection was neglected due to its low velocities under small mean temperature gradients present in the capsule, and relatively high convective velocities induced by fans. Being unable to resolve all the equipment and connecting cables in its detailed composition, and in order to avoid difficulties with boundary conditions needed on all impermeable boundaries we developed the concept of quasi-permeable medium, which was implemented to perform numerical simulations of convective flows inside the module. The balance between heat sources and sinks allowed to determine the qusi-steady temperature field inside the capsule.
The present investigation was supported by the contract of Russian Space Agency and by the grant of the President of Russian Federation (19.2003.1).
    Abstract document

    IAC-05-A2.2.02.pdf

    Manuscript document

    IAC-05-A2.2.02.pdf (🔒 authorized access only).

    To get the manuscript, please contact IAF Secretariat.