Flat polymer loop thermosyphons

Vasiliev, L.; Grakovich, L.; Rabetsky, M.; Zhuravlyov, A.; Vassiliev Jr., L.

doi:10.1515/aoter-2018-0004

Artykuł - szczegóły

Tytuł artykułu

Flat polymer loop thermosyphons

Autorzy

Vasiliev L. , Grakovich L. , Rabetsky M. , Zhuravlyov A. , Vassiliev Jr. L.

Treść / Zawartość

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Identyfikatory

DOI

10.1515/aoter-2018-0004

Warianty tytułu

Języki publikacji

Abstrakty

The flat horizontal polymer loop thermosyphon with flexible transport lines is suggested and tested. The thermosyphon envelope consists of a polyamide composite with carbon based high thermal conductive micro-, nanofilaments and nanoparticles to increase its effective thermal conductivity up to 11 W/(m°C). Rectangular capillary mini grooves inside the evaporator and condenser of thermosyphon are used as a mean of heat transfer enhancement. The tested working fluid is R600. Thermosyphon evaporator and condenser are similar in design, have a long service life. In this paper three different methods (transient, quasi-stationary, and stationary) have been used to determine the thermophysical properties of polymer composites used as an envelope of thermosyphon, which make it possible to design a wide range of new heat transfer equipment. The results obtained contribute to establish the viability of using polymer thermosyphons for ground heat sinks (solar energy storage), gas-liquid heat exchanger applications involving seawater and other corrosive fluids, efficient cooling of superconductive magnets impregnated with epoxy/carbon composites to prevent wire movement, enhance stability, and diminish heat generation.

Słowa kluczowe

thermosyphon heat pipe heat transfer cooling technologies air conditioning refrigeration LED cooling systems

termosyfon rura cieplna wymiana ciepła technologie chłodnicze klimatyzacja chłodnictwo

Wydawca

Wydawnictwo Instytutu Maszyn Przepływowych PAN
Komitet Termodynamiki i Spalania PAN

Czasopismo

Archives of Thermodynamics

Rocznik

2018

Tom

Vol. 39, no 1

Strony

75--90

Opis fizyczny

Bibliogr. 19 poz., rys.

Twórcy

autor

Vasiliev L.

Leonard_Vasiliev@rambler.ru

Porous Media Laboratory, Luikov Heat and Mass Transfer Institute of National Academy of Sciences of Belarus, 15 Brovka St., 220072 Minsk, Belarus

autor

Grakovich L.

Porous Media Laboratory, Luikov Heat and Mass Transfer Institute of National Academy of Sciences of Belarus, 15 Brovka St., 220072 Minsk, Belarus

autor

Rabetsky M.

Porous Media Laboratory, Luikov Heat and Mass Transfer Institute of National Academy of Sciences of Belarus, 15 Brovka St., 220072 Minsk, Belarus

autor

Zhuravlyov A.

Porous Media Laboratory, Luikov Heat and Mass Transfer Institute of National Academy of Sciences of Belarus, 15 Brovka St., 220072 Minsk, Belarus

autor

Vassiliev Jr. L.

Porous Media Laboratory, Luikov Heat and Mass Transfer Institute of National Academy of Sciences of Belarus, 15 Brovka St., 220072 Minsk, Belarus

Bibliografia

[1] Vasiliev L. Jr.: Heat exchange device made of polymeric material. U.S. Patent No. US 20 110 067 843.
[2] Bielinski H., Mikielewicz J.: Application of a two-phase thermosyphon loop with minichannels and a minipump in computer cooling. Arch. Thermodyn. 37(2016), 1, 3–16, DOI: 10.1515/aoter-2016-0001.
[3] Bielinski H.: Validation of the generalized model of the two-phase thermosyphon loop based on experimental measurements of volumetric flow rate. Arch. Thermodyn. 37(2016), 3, 109–138, DOI: 10.1515/aoter-2016-0023.
[4] Wu G.-W., Chen S.-L., Shih W.-P.: Lamination and characterization of a polyethylenterephthalate flexible micro heat pipe. Frontiers in Heat Pipes (FHP) 3(2012), 2, 023003, DOI: 10.5098/fhp.v3.2.3003, Available at www.ThermalFluidsCentral.org.
[5] Mochizuki M., Akbarzadeh A., Nguyen T.: A review of practical applications of heat pipes and innovative application of opportunities for global warming. In: Heat Pipes and Solid Sorption Transformation: Fundamentals and Practical Applications (L.L. Vasiliev and S. Kakaç, Eds.), CRC Press/Taylor & Francis Group, Boca Raton, FL, 2013, 145–212.
[6] Vasiliev L.L., Vassiliev L.L., Jr.: Heat pipes and thermosyphons for thermal management of solid sorption machines and fuel cells. In: Heat Pipes and Solid Sorption Transformation: Fundamentals and Practical Applications (L.L. Vasiliev and S. Kakaç, Eds.), CRC Press/Taylor & Francis Group, Boca Raton, FL, 2013, 213–258.
[7] Carlberg B., Ye L.L., Liu J.: Polymer-metal nanofibrous composite for thermal management of microsystems. Mater. Lett. 75(2012), May 15, 229–232.
[8] Kim K.J., Shahinpoor M.: Ionic polymer-metal composites: II. Manufacturing techniques. Smart Mater. Struct. 12(2003), 1, 65–79.
[9] Slepicka P., Fidler T., Vasina A., Svorsik V.: Ripple-like structure on PLLA induced by gold deposition and thermal treatment. Mater Lett. 79(2012), July 15, 4–6.
[10] Bledzki A.K., Gassan J.: Composites reinforced with cellulose based fibers. Prog. Polym. Sci. 24(1999), 2, 221–227.
[11] Stankovich S., Dikin D. A., Dommett G.H.B., Kohlhaas K.M., Zimney E.J., Stach E.A., Piner R.D., Nguyen SB. T., Ruoff R.S.: Graphene-based composite materials. Nature 442(2006), July 20, 282–286.
[12] Lipatov Y.S., Nesterov A.E., Ignatova T.D., Nesterov D.A.: Effect of polymer-filler surface interactions on the phase separation in polymer blends. Polymer 43(2002), 3, 875–883.
[13] Bogdanovich S.P., Grakovich L.P., Vasiliev L.L.: Heat-conductive polymerous material on basis of thermoelastolayers. In: Proc. Int. Conf. Polymeric Composite Materials and Tribology, Polycomtrib-2011, Gomel, 2011, 78–84.
[14] Oshman C., Shi B., Li C., Yang R., Lee Y.C., Peterson G.P., Bright V.M.: The development of polymer-based flat heat pipes. IEEE/ASME J. Microelectromech. Syst. 20(2011), 2, 410–417, DOI: 10.1109/JMEMS.2011.2107885.
[15] Luikov A.V.: Theory of Heat Conduction. Vysshaya Shkola, Moscow 1967 (in Russian).
[16] Luikov A.V., Vasiliev L.L., Tanaeva S.A., Domorod L.S.: Experimental investigation of thermal properties of glass-fiber-resin materials from 10 to 400 K. Lett. Heat Mass Transfer l(1974), 1, 7–12.
[17] Vasiliev L.L. et al.: A method for combined investigation of the thermophysical characteristics of materials over the temperature range 4.2-400 K. J. Eng. Physics 17(1969), 6, 1567–1569.
[18] Bol’shakov Yu.V., Vasiliev L.L., Pozvonkov E.M.: Measuring the thermophysical properties of materials in the 20–300 ◦K temperature range. J. Eng. Physics Thermophys. 24(1973), 6, 721–725. DOI:10.1007/BF00831670.
[19] Vasiliev L.L., Grakovich L.P., Rabetsky M.I., Vasiliev L.L. Jr.: Grooved heat pipes evaporators with porous coating. In: Proc. 16th Int. Heat Pipe Conf., Lyon, May 20–24, 2012, 289–294.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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