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Journal Biomedical Radioelectronics №3 for 2016 г.
Article in number:
Thermal design of device for safe platelet storage media containing transfusion
Authors:
A.G. Gudkov Dr.Sc. (Eng.), Professor, Moscow State Technical University n.a. Bauman. E-mail: profgudkov@gmail.com A.V. Chernyshev Dr.Sc. (Eng.), Professor, Moscow State Technical University n.a. Bauman. E-mail: av-chernyshev@yandex.ru M.S. Zelenov Post-graduate Student, Moscow State Technical University n.a. Bauman. E-mail: mszelenov@gmail.com M.A. Levchuk Student, Moscow State Technical University n.a. Bauman. E-mail: martin256@mail.ru A.F. Bobrikhin Head of Department, LTD «NPI FIRM «HYPERION», Moscow. E-mail: bobrihin@yandex.ru V.N. Lemondzhava Head of Department, LTD «NPI FIRM «HYPERION», Moscow. E-mail: ooo.giperion@gmail.com V.Yu. Leushin Ph.D. (Eng.), Deputy General Director, LTD «NPI FIRM «HYPERION», Moscow. E-mail: ooo.giperion@gmail.com I.N. Marzhanovsky Laboratory Assistant, Moscow State Technical University n.a. Bauman. E-mail: vankrutoi@gmail.com
Abstract:
A thermal design of the biological objects device safe storage is completed. Three-dimensional models of the safe storage considering multi-layer walls are constructed. There are a selection of the experimentally determined data about the materials used in construction: emissivity , thermal conductivity , gas-dynamic and hydrodynamic parameters of media , integrated energy characteristics of the purchased units. The optimal method is chosen, the grid partitioning of the computational domain with the additional thickening grid in areas of high interest is done. The grid model is transferred to the environment of the numerical solution. The initial and boundary conditions are given. The computational experiments with subsequent analysis of the temperature distribution on the computational domain and parameters change graphs in process of time are completed. The recommendations to structure adjustment of safe storage device and control system are composed.
Pages: 80-86
References

 

  1. CHernyshev A.V.Povyshenie ehffektivnosti programmiruemykh termostatirujushhikh ustrojjstv na osnove termoehlektricheskikh mikrookhladitelejj // Konversija v mashinostroenii. 2002. № 6. S. 134-139
  2. CHernyshev A.V.Osnovy teorii rascheta ehlektropnevmomekhanicheskogo oborudovanija dlja analiza DNK // Nauchnoe priborostroenie. 2002. T. 12. № 1. S. 53-65.
  3. CHernyshev A.V., Belova O.V. Metod matematicheskogo modelirovanija teplovykh istochnikov v termoehlektricheskikh ehlementakh Pelte // Nauchnoe priborostroenie. 2004. T. 14. № 1. S. 51-57.
  4. CHernyshev A.V.Issledovanie teplofizicheskikh processov v termobloke amplifikatora DNK // Biomedicinskie tekhnologii i radioehlektronika. 2005. № 9. S. 40-46.
  5. Kreith F., Black W.Z.Basic Heat Transfer.USA, New York: Harper and Row. 1980. 556 p.
  6. Versteeg H.K.,Malalasekera W. An introduction to computational fluid Dynamics. TheFiniteVolumeMetod. England: Longman & Technical. 1995. 267 p.
  7. ANSYS FLUENT 12.0. Theory Guide[EHlektronnyjjresurs]/ ANSYS, Inc, 2009. - URL:http://users.ugent.be/ ~mvbelleg/flug-12-0.pdf (Dataposeshhenija: 16.02.2016)