Publication detail

Spray cooling by solid jet nozzles using alumina/water nanofluids

BELLEROVÁ, H. TSENG, A. POHANKA, M. RAUDENSKÝ, M.

Original Title

Spray cooling by solid jet nozzles using alumina/water nanofluids

English Title

Spray cooling by solid jet nozzles using alumina/water nanofluids

Type

journal article in Web of Science

Language

en

Original Abstract

The hot steel plate with embedded thermocouple was sprayed by nanofluid Al/water. The inverse heat transfer technique was then applied to convert the measured temperatures into the heat transfer coefficient (HTC) for different nanoparticle fractions and different nanofluid flow rates. The results showed 45% decrease of HTC with nanoparticle fraction increasing from 0 to 16.45%. The HTC corelations with the nanoparticle fraction and spray cooling conditions were also reported.

English abstract

The hot steel plate with embedded thermocouple was sprayed by nanofluid Al/water. The inverse heat transfer technique was then applied to convert the measured temperatures into the heat transfer coefficient (HTC) for different nanoparticle fractions and different nanofluid flow rates. The results showed 45% decrease of HTC with nanoparticle fraction increasing from 0 to 16.45%. The HTC corelations with the nanoparticle fraction and spray cooling conditions were also reported.

Keywords

Alumina nanoparticle, Heat transfer coefficient, Nanofluids, Solid jet, Spray cooling

RIV year

2012

Released

01.12.2012

Publisher

Elsevier

Location

Paříž

Pages from

127

Pages to

137

Pages count

12

URL

Documents

BibTex


@article{BUT94598,
  author="Hana {Bellerová} and Ampere An-Pei {Tseng} and Michal {Pohanka} and Miroslav {Raudenský}",
  title="Spray cooling by solid jet nozzles using alumina/water nanofluids",
  annote="The hot steel plate with embedded thermocouple was sprayed by nanofluid Al/water. The inverse heat transfer technique was then applied to convert the measured temperatures into the heat transfer coefficient (HTC) for different nanoparticle fractions and different nanofluid flow rates. The results showed 45% decrease of HTC with nanoparticle fraction increasing from 0 to 16.45%. The HTC corelations with the nanoparticle fraction and spray cooling conditions were also reported.",
  address="Elsevier",
  chapter="94598",
  doi="10.1016/j.ijthermalsci.2011.10.017",
  institution="Elsevier",
  number="12",
  volume="62",
  year="2012",
  month="december",
  pages="127--137",
  publisher="Elsevier",
  type="journal article in Web of Science"
}