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Zeitschriften
Applied Mathematics and Nonlinear Sciences
Band 3 (2018): Heft 1 (June 2018)
Uneingeschränkter Zugang
Wall Properties and Slip Consequences on Peristaltic Transport of a Casson Liquid in a Flexible Channel with Heat Transfer
P. Devaki
P. Devaki
,
S. Sreenadh
S. Sreenadh
,
K. Vajravelu
K. Vajravelu
,
K. V. Prasad
K. V. Prasad
und
Hanumesh Vaidya
Hanumesh Vaidya
| 03. Okt. 2018
Applied Mathematics and Nonlinear Sciences
Band 3 (2018): Heft 1 (June 2018)
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Online veröffentlicht:
03. Okt. 2018
Seitenbereich:
277 - 290
Eingereicht:
05. Mai 2018
Akzeptiert:
15. Juni 2018
DOI:
https://doi.org/10.21042/AMNS.2018.1.00021
Schlüsselwörter
Peristaltic wave
,
wall effects
,
rigidity
,
casson liquid
,
heat transfer
© 2018 P. Devaki et al., published by Sciendo
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.
Fig. 1
Physical model of the problem
Fig. 2
Effect ofA1on the velocity distribution for fixed values ofx = 0.01,t = 0.4, ε = 0.2, ω = 0.1 τ0 = 0.1,A2 = 0.3,A3 = 0.5,ζ = 0.1
Fig. 3
Effect ofA2on the velocity distribution for Fixed values ofx = 0.01,t = 0.4, ε = 0.2, ω = 0.1 τ0 = 0.1, A1 = 0.1, A3 = 0.5, ζ = 0.1
Fig. 4
Effect ofA3on the velocity distribution for Fixed values ofx = 0.01,t = 0.4, ε = 0.2, ω = 0.1 τ0 = 0.1, A1 = 0.1, A2 = 0.3, ζ = 0.1
Fig. 5
Effect ofωon the velocity distribution for Fixed values ofx = 0.01,t = 0.4, ε = 0.2, ζ = 0.1 τ0 = 0.1, A1 = 0.1, A2 = 0.3, A3 = 0.5
Fig. 6
Velocity Distribution for differentτ0for fixed values ofx = 0.01,t = 0.4, ε = 0.2, ω = 0.1 ζ = 0.1, A1 = 0.1, A2 = 0.3, A3 = 0.5
Fig. 7
Velocity Distribution for differentζfor fixed values ofx = 0.01,t = 0.4, ε = 0.2, ω = 0.1 τ0 = 0.1, A1 = 0.1, A2 = 0.3, A3 = 0.5
Fig. 8
Effect ofBron the Temperature for fixed values ofx = 0.2,t = 0.l, ε = 0.1, ω = 0.1, τ0 = 0.1, A1 = 0.1, A2 = 0.3, A3 = 0.5
Fig. 9
Effect ofωon the temperature for fixed values ofx = 0.2,t = 0.1,ε = 0.1, Br = 1, τ0 = 0.1, A1 = 0.1, A2 = 0.3, A3 = 0.5
Fig. 10
Temperature profiles for differentτ0for fixed values ofx = 0.2,t = 0.1, ε = 0.1, ω = 0.1, Br = 1, A1 = 0.1, A2 = 0.3, A3 = 0.5
Fig. 11
Effect of elastic parameters on Temperature profiles for fixed values ofx = 0.2,t = 0.1,ε = 0.1, ω = 0.1, Br = 1, τ0 = 0.1
Fig. 12
Effect ofA1on Trapping (I)A1 = 0.5 (II)A1 = 0.6 (III)A1 = 0.8 for fixed values ofx = 0.01,t = 0.4,ε = 0.2, ω = 0.1, τ0 = 0.1,A2 = 0.3, A3 = 0.5,ζ = 0.1
Fig. 13
Effect ofA2on Trapping (I)A2 = 0.2 (II)A2 = 0.4 (III)A2 = 0.5 for fixed values ofx = 0.01,t = 0.4,ε = 0.2, ω = 0.1, τ0 = 0.1,A1 = 0.1, A3 = 0.5,ζ = 0.1
Fig. 14
Effect ofA3on Trapping (I)A3 = 0.1 (II)A3 = 0.3 (III)A3 = 0.5 for fixed values ofx = 0.01, t = 0.4, ε = 0.2, ω = 0.1, τ0 = 0.1, A1 = 0.1, A2 = 0.3, ζ = 0.1
Fig. 15
Effect ofωon Trapping (I)ω=–0.1 (II)ω=0 (III)ω=0.1 for fixed values ofx = 0.01,t = 0.4,ε = 0.2,τ0 = 0.1, A1 = 0.1, A2 = 0.3, A3 = 0.5, ζ = 0.1
Fig. 16
Effect ofτ0on Trapping (I)τ0 = 0.001 (II)τ0 = 0.01 (III)τ0 = 0.1 for fixed values ofx = 0.01,t = 0.4, ε = 0.2, ω=0.1, A1 = 0.1, A2 = 0.3, A3 = 0.5, ζ = 0.1
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