CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS

kumar, arvind; PARKASH, OM; Sikarwar, Basant

CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS

Om PARKASH, (Amity University Haryana, Department of Mechanical Engineering, Gurgaon, India / JC Bose University of Science and Technology, Department of Mechanical Engineering, YMCA, Faridabad, India)

Arvind KUMAR, (JC Bose University of Science and Technology, Department of Mechanical Engineering, YMCA, Faridabad, India)

Basant Singh SIKARWAR (Amity University Uttar Pradesh, Department of Mechanical Engineering, Noida, India)

Journal of Thermal Engineering

3 0

Yıl: 2021 Cilt: 7 Sayı: 4 Sayfa Aralığı: 951 - 969 Metin Dili: İngilizce İndeks Tarihi: 09-12-2021

CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS

Öz:

The present work shows the slurry flow characteristics of glass beads having density 2470 kg/m3 at different Prandtl number through a horizontal pipeline. The simulation is conducted by Eulerian two-phase model using RNG k-ε turbulence closure in available commercial software ANSYS FLUENT. The transportation of solid particulates has the settling behaviour in the slurry pipeline and that leads to the sedimentation and blockage of the pipeline resulting more power and pressure drop in the pipeline. Therefore, it is important to know the transport capability of the solid particulates at different Prandtl fluids to minimise the pressure loss. The fluid properties at four Prandtl numbers i.e. 1.34, 2.14, 3.42 and 5.83 is used to carry the solid concentration ranges from 30-50 % (by volume) at mean flow-velocity ranging from 3 to 5 ms-1 . The obtained computational results are validated with the published data in the literature. The results show that the pressure-drop rises with escalation in flow velocity and solid concentration at all Prandtl number. It is found that the suspension stability enhancement is considerable for lower range of Prandtl number and decreases for higher range of Prandtl number. Finally, glass beads concentration contours, velocity contours, concentration profile, velocity profiles and pressure drop are predicted to understand the slurry flow for chosen Prandtl numbers.

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APA	PARKASH O, kumar a, Sikarwar B (2021). CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS. , 951 - 969.
Chicago	PARKASH OM,kumar arvind,Sikarwar Basant CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS. (2021): 951 - 969.
MLA	PARKASH OM,kumar arvind,Sikarwar Basant CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS. , 2021, ss.951 - 969.
AMA	PARKASH O,kumar a,Sikarwar B CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS. . 2021; 951 - 969.
Vancouver	PARKASH O,kumar a,Sikarwar B CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS. . 2021; 951 - 969.
IEEE	PARKASH O,kumar a,Sikarwar B "CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS." , ss.951 - 969, 2021.
ISNAD	PARKASH, OM vd. "CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS". (2021), 951-969.

APA	PARKASH O, kumar a, Sikarwar B (2021). CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS. Journal of Thermal Engineering, 7(4), 951 - 969.
Chicago	PARKASH OM,kumar arvind,Sikarwar Basant CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS. Journal of Thermal Engineering 7, no.4 (2021): 951 - 969.
MLA	PARKASH OM,kumar arvind,Sikarwar Basant CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS. Journal of Thermal Engineering, vol.7, no.4, 2021, ss.951 - 969.
AMA	PARKASH O,kumar a,Sikarwar B CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS. Journal of Thermal Engineering. 2021; 7(4): 951 - 969.
Vancouver	PARKASH O,kumar a,Sikarwar B CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS. Journal of Thermal Engineering. 2021; 7(4): 951 - 969.
IEEE	PARKASH O,kumar a,Sikarwar B "CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS." Journal of Thermal Engineering, 7, ss.951 - 969, 2021.
ISNAD	PARKASH, OM vd. "CFD MODELING OF SLURRY PIPELINE AT DIFFERENT PRANDTL NUMBERS". Journal of Thermal Engineering 7/4 (2021), 951-969.