Microencapsulated phase change material (MPCM) slurry is consisted of a base fluid in which MPCM is dispersed. Due to apparent high heat capacity associated with phase change process, MPCM slurry can be used as a viable heat transfer fluid (HTF) for turbulent flow conditions. Heat transfer and fluid flow properties of the slurry in turbulent flow (3000 < Re < 6000) were determined experimentally. Dynamic viscosity of the MPCM slurry was measured at different temperatures close to the melting point of the material (20–30 °C). Pressure drop measurements under turbulent flow conditions were recorded for 6 MPCM samples at various concentrations. The pressure drop of the MPCM slurry was comparable to that of water despite the higher viscosity of the slurry. The effect of heat flux, MPCM mass concentration, flow rate and the type of phase change material was investigated. The effective heat capacity of slurry at the location where phase change occurs was found to be considerably higher than that of water. A nondimensional Nusselt number correlation was proposed in order to facilitate design of heat transfer loops with MPCM slurries as working fluid.
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University of Alabama at Birmingham,
Birmingham, AL 35294
e-mail: taherian@uab.edu
and Industrial Distribution,
Texas A&M University,
College Station, TX 77843
and Industrial Distribution,
Texas A&M University,
College Station, TX 77843
Henderson, NV 89014
and Industrial Distribution,
Texas A&M University,
College Station, TX 77843
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Research-Article
Fluid Flow and Heat Transfer Characteristics of Microencapsulated Phase Change Material Slurry in Turbulent Flow
Hessam Taherian,
University of Alabama at Birmingham,
Birmingham, AL 35294
e-mail: taherian@uab.edu
Hessam Taherian
1
Department of Mechanical Engineering
,University of Alabama at Birmingham,
1720 2nd Avenue S
,Birmingham, AL 35294
e-mail: taherian@uab.edu
1Corresponding author.
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Jorge L. Alvarado,
and Industrial Distribution,
Texas A&M University,
College Station, TX 77843
Jorge L. Alvarado
Department of Engineering Technology
and Industrial Distribution,
Texas A&M University,
3367 TAMU
,College Station, TX 77843
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Kalpana Tumuluri,
and Industrial Distribution,
Texas A&M University,
College Station, TX 77843
Kalpana Tumuluri
Department of Engineering Technology
and Industrial Distribution,
Texas A&M University,
3367 TAMU
,College Station, TX 77843
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Curt Thies,
Henderson, NV 89014
Curt Thies
Thies Technology Inc.
,921 American Pacific Dr. Suite 309
,Henderson, NV 89014
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Chan-Hyun Park
and Industrial Distribution,
Texas A&M University,
College Station, TX 77843
Chan-Hyun Park
Department of Engineering Technology
and Industrial Distribution,
Texas A&M University,
3367 TAMU
,College Station, TX 77843
Search for other works by this author on:
Hessam Taherian
Department of Mechanical Engineering
,University of Alabama at Birmingham,
1720 2nd Avenue S
,Birmingham, AL 35294
e-mail: taherian@uab.edu
Jorge L. Alvarado
Department of Engineering Technology
and Industrial Distribution,
Texas A&M University,
3367 TAMU
,College Station, TX 77843
Kalpana Tumuluri
Department of Engineering Technology
and Industrial Distribution,
Texas A&M University,
3367 TAMU
,College Station, TX 77843
Curt Thies
Thies Technology Inc.
,921 American Pacific Dr. Suite 309
,Henderson, NV 89014
Chan-Hyun Park
Department of Engineering Technology
and Industrial Distribution,
Texas A&M University,
3367 TAMU
,College Station, TX 77843
1Corresponding author.
Contributed by the Heat Transfer Division of ASME for publication in the JOURNAL OF HEAT TRANSFER. Manuscript received June 12, 2013; final manuscript received February 6, 2014; published online March 13, 2014. Assoc. Editor: Wilson K. S. Chiu.
J. Heat Transfer. Jun 2014, 136(6): 061704 (7 pages)
Published Online: March 13, 2014
Article history
Received:
June 12, 2013
Revision Received:
February 6, 2014
Citation
Taherian, H., Alvarado, J. L., Tumuluri, K., Thies, C., and Park, C. (March 13, 2014). "Fluid Flow and Heat Transfer Characteristics of Microencapsulated Phase Change Material Slurry in Turbulent Flow." ASME. J. Heat Transfer. June 2014; 136(6): 061704. https://doi.org/10.1115/1.4026863
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