Viscosity measurements on colloidal dispersions (nanofluids) for heat transfer applications

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • David C. Venerus
  • Jacopo Buongiorno
  • Rebecca Christianson
  • Jessica Townsend
  • In Cheol Bang
  • Gang Chen
  • Sung Jae Chung
  • Minking Chyu
  • Haisheng Chen
  • Yulong Ding
  • Frank Dubois
  • Grzegorz Dzido
  • Denis Funfschilling
  • Quentin Galand
  • Jinwei Gao
  • Haiping Hong
  • Mark Horton
  • Linwen Hu
  • Carlo S. Iorio
  • Andrzej B. Jarzebski
  • Yiran Jiang
  • Stephan Kabelac
  • Mark A. Kedzierski
  • Chongyoup Kim
  • Ji-Hyun Kim
  • Sukwon Kim
  • Thomas McKrell
  • Rui Ni
  • John Philip
  • Naveen Prabhat
  • Pengxiang Song
  • Stefan Van Vaerenbergh
  • Dongsheng Wen
  • Sanjeeva Witharana
  • Xiao-Zheng Zhao
  • Sheng Qi Zhou

Externe Organisationen

  • Illinois Institute of Technology
  • Massachusetts Institute of Technology (MIT)
  • Franklin W. Olin College of Engineering
  • Ulsan National Institute of Science and Technology
  • Tokyo Institute of Technology
  • University of Pittsburgh
  • University of Leeds
  • Université libre de Bruxelles (ULB)
  • Silesian University of Technology
  • The Chinese University of Hong Kong
  • South Dakota School of Mines & Technology
  • Helmut-Schmidt-Universität/Universität der Bundeswehr Hamburg
  • National Institute of Standards and Technology (NIST)
  • Korea University
  • Indira Gandhi Centre for Atomic Research
  • Queen Mary University of London
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Aufsatznummer44582
Seitenumfang7
FachzeitschriftApplied Rheology
Jahrgang20
Ausgabenummer4
Frühes Online-Datum9 Okt. 2010
PublikationsstatusVeröffentlicht - 2010
Extern publiziertJa

Abstract

This article reports viscosity data on a series of colloidal dispersions collected as part of the International Nanofluid Property Benchmark Exercise (INPBE). Data are reported for seven different fluids that include dispersions of metal-oxide nanoparticles in water, and in synthetic oil. These fluids, which are also referred to as 'nanofluids,' are currently being researched for their potential to function as heat transfer fluids. In a recently published paper from the INPBE study, thermal conductivity data from more than 30 laboratories around the world were reported and analyzed. Here, we examine the influence of particle shape and concentration on the viscosity of these same nanofluids and compare data to predictions from classical theories on suspension rheology.

ASJC Scopus Sachgebiete

Zitieren

Viscosity measurements on colloidal dispersions (nanofluids) for heat transfer applications. / Venerus, David C.; Buongiorno, Jacopo; Christianson, Rebecca et al.
in: Applied Rheology, Jahrgang 20, Nr. 4, 44582, 2010.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Venerus, DC, Buongiorno, J, Christianson, R, Townsend, J, Bang, IC, Chen, G, Chung, SJ, Chyu, M, Chen, H, Ding, Y, Dubois, F, Dzido, G, Funfschilling, D, Galand, Q, Gao, J, Hong, H, Horton, M, Hu, L, Iorio, CS, Jarzebski, AB, Jiang, Y, Kabelac, S, Kedzierski, MA, Kim, C, Kim, J-H, Kim, S, McKrell, T, Ni, R, Philip, J, Prabhat, N, Song, P, Van Vaerenbergh, S, Wen, D, Witharana, S, Zhao, X-Z & Zhou, SQ 2010, 'Viscosity measurements on colloidal dispersions (nanofluids) for heat transfer applications', Applied Rheology, Jg. 20, Nr. 4, 44582. https://doi.org/10.3933/ApplRheol-20-44582
Venerus, D. C., Buongiorno, J., Christianson, R., Townsend, J., Bang, I. C., Chen, G., Chung, S. J., Chyu, M., Chen, H., Ding, Y., Dubois, F., Dzido, G., Funfschilling, D., Galand, Q., Gao, J., Hong, H., Horton, M., Hu, L., Iorio, C. S., ... Zhou, S. Q. (2010). Viscosity measurements on colloidal dispersions (nanofluids) for heat transfer applications. Applied Rheology, 20(4), Artikel 44582. https://doi.org/10.3933/ApplRheol-20-44582
Venerus DC, Buongiorno J, Christianson R, Townsend J, Bang IC, Chen G et al. Viscosity measurements on colloidal dispersions (nanofluids) for heat transfer applications. Applied Rheology. 2010;20(4):44582. Epub 2010 Okt 9. doi: 10.3933/ApplRheol-20-44582
Venerus, David C. ; Buongiorno, Jacopo ; Christianson, Rebecca et al. / Viscosity measurements on colloidal dispersions (nanofluids) for heat transfer applications. in: Applied Rheology. 2010 ; Jahrgang 20, Nr. 4.
Download
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AU - Venerus, David C.

AU - Buongiorno, Jacopo

AU - Christianson, Rebecca

AU - Townsend, Jessica

AU - Bang, In Cheol

AU - Chen, Gang

AU - Chung, Sung Jae

AU - Chyu, Minking

AU - Chen, Haisheng

AU - Ding, Yulong

AU - Dubois, Frank

AU - Dzido, Grzegorz

AU - Funfschilling, Denis

AU - Galand, Quentin

AU - Gao, Jinwei

AU - Hong, Haiping

AU - Horton, Mark

AU - Hu, Linwen

AU - Iorio, Carlo S.

AU - Jarzebski, Andrzej B.

AU - Jiang, Yiran

AU - Kabelac, Stephan

AU - Kedzierski, Mark A.

AU - Kim, Chongyoup

AU - Kim, Ji-Hyun

AU - Kim, Sukwon

AU - McKrell, Thomas

AU - Ni, Rui

AU - Philip, John

AU - Prabhat, Naveen

AU - Song, Pengxiang

AU - Van Vaerenbergh, Stefan

AU - Wen, Dongsheng

AU - Witharana, Sanjeeva

AU - Zhao, Xiao-Zheng

AU - Zhou, Sheng Qi

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PY - 2010

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N2 - This article reports viscosity data on a series of colloidal dispersions collected as part of the International Nanofluid Property Benchmark Exercise (INPBE). Data are reported for seven different fluids that include dispersions of metal-oxide nanoparticles in water, and in synthetic oil. These fluids, which are also referred to as 'nanofluids,' are currently being researched for their potential to function as heat transfer fluids. In a recently published paper from the INPBE study, thermal conductivity data from more than 30 laboratories around the world were reported and analyzed. Here, we examine the influence of particle shape and concentration on the viscosity of these same nanofluids and compare data to predictions from classical theories on suspension rheology.

AB - This article reports viscosity data on a series of colloidal dispersions collected as part of the International Nanofluid Property Benchmark Exercise (INPBE). Data are reported for seven different fluids that include dispersions of metal-oxide nanoparticles in water, and in synthetic oil. These fluids, which are also referred to as 'nanofluids,' are currently being researched for their potential to function as heat transfer fluids. In a recently published paper from the INPBE study, thermal conductivity data from more than 30 laboratories around the world were reported and analyzed. Here, we examine the influence of particle shape and concentration on the viscosity of these same nanofluids and compare data to predictions from classical theories on suspension rheology.

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