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Series: ASM Handbook
Volume: 4B
Publisher: ASM International
Published: 30 September 2014
DOI: 10.31399/asm.hb.v04b.a0005933
EISBN: 978-1-62708-166-5
... Abstract Nanofluids offer a completely different behavior of wetting kinetics and heat-removal characteristics, which are exploited in industrial heat treatment for quenching. This article provides information on the important thermophysical properties of nanofluids, namely, thermal...
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Published: 01 February 2024
Fig. 2 Nanofluids, (a) Newtonian; (b) non-Newtonian. Source: Ref 18
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Published: 01 February 2024
Fig. 3 Specific heat vs. temperature plot for various nanofluids showing (a) increasing and (b) decreasing trend. Source: Ref 23
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Published: 01 February 2024
Fig. 4 Wetting front velocity for copper nanofluids. Source: Ref 33
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Published: 01 February 2024
Fig. 6 Effect of agitation on cooling rate of copper nanofluids. Source: Ref 34
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Published: 01 February 2024
Fig. 13 Cooling curves and cooling rate curves for (a) AlN nanofluids and (b) TiO 2 nanofluids. Source: Ref 39
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Published: 01 February 2024
Fig. 17 (a) Surface heat flux vs. surface temperature curve for CNT nanofluids; (b) effect of agitation rate on the surface heat flux vs. surface temperature curve for 0.5 wt% CNT nanofluid. Source: Ref 4
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Published: 01 February 2024
Fig. 18 Peak heat flux vs. bath temperature for CNT nanofluids. Source: Ref 44
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Published: 01 February 2024
Fig. 19 19 (a) Cooling curves for CNT nanofluids; (b) surface heat flux vs. temperature curves CNT nanofluids. Source: Ref 31
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Published: 01 February 2024
Fig. 22 Variation of critical cooling rates at critical temperature for nanofluids under (a) still condition, (b) 500 rpm, (c) 1000 rpm, and (d) 1500 rpm agitation rates. Source: Ref 27
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Series: ASM Handbook
Volume: 4F
Publisher: ASM International
Published: 01 February 2024
DOI: 10.31399/asm.hb.v4F.a0007005
EISBN: 978-1-62708-450-5
... Abstract This article details investigations on the characterization of various nanofluids as quenchants for industrial heat treatment. It provides a discussion on the preparation, stability, thermophysical properties, and wetting characteristics of nanofluids. The article explains...
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Published: 01 February 2024
Fig. 14 Time required to remove a specified amount of heat from the probe for (a) AlN nanofluids, and (b) TiO 2 nanofluids. Source: Ref 39
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Published: 30 September 2014
Fig. 8 Images showing the contact angle of (a) water, (b) 0.001 vol% nanofluid (NF), (c) 0.005 vol% NF, (d) 0.01 vol% NF, (e) 0.05 vol% NF, (f) 0.01 vol% NF, and (g) 0.05 vol% NF. Source: Ref 131
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Published: 01 February 2024
Fig. 5 Cooling curves and cooling rate curves of copper nanofluid and deionized water. Source: Ref 34
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Published: 01 February 2024
Fig. 24 Cooling curves of repeated quenching in 0.1 vol% alumina nanofluid. Source: Ref 2
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Published: 01 February 2024
Fig. 10 Effect of preparation method on the maximum cooling rates for polymer nanofluids. Source: Ref 37
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Published: 01 February 2024
Fig. 1 Effect of (a) temperature, and (b) volume concentration on the thermal conductivity of alumina nanofluid. Source: Ref 17
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Published: 30 September 2014
Fig. 6 Microstructure of AISI 1070 steel specimen (a) quenched in water and (b) quenched in 0.01% nanofluid. Source: Ref 128
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Published: 30 September 2014
Fig. 7 Scanning electron micrographs of top surface of steel after cooling with (a) water and (b) nanofluid. Source: Ref 129
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Published: 01 February 2024
Fig. 20 Cooling curves and cooling rate curves for (a) graphene and (b) MWCNT nanofluids. Source: Ref 30 , Ref 45
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