Numerical simulation of thermal performance of bionic waste heat utilization equipment filled with nanofluids

Jianglin Tu; Cong Qi; Liang Sun; Yuxing Wang; Zhibo Tang

Korean Journal of Chemical Engineering, Vol.39, No.6, 1412-1423, June, 2022

DOI10.1007/s11814-021-1047-2 Export Citation

Numerical simulation of thermal performance of bionic waste heat utilization equipment filled with nanofluids

Jianglin Tu, Cong Qi^†, Liang Sun, Yuxing Wang, and Zhibo Tang

School of Low-carbon Energy and Power Engineering, China University of Mining and Technology, Xuzhou 221116, China

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This paper, mainly through designing a reinforced structure from the perspective of bionics and substituting a new heat exchange working medium for the traditional working medium, attempted to figure out the thermal performance of the waste heat recovery device. By means of numerical method, the following five factors, namely the effects of Reynolds number (Re=1,300-1,800), the new heat transfer medium (CuO-H2O nanofluids), the angular frequency of the bionic reinforced structure (ω=20 rad/s, ω=25 rad/s, ω=30 rad/s), the amplitude of the bionic reinforced structure (A=1 mm, A=2mm, A=3 mm), and the phase shift of the bionic reinforced structure (α=0° , 90° , 180° ) were probed so as to reveal their effects on the thermal performance of the waste heat recovery unit as well as the latent influencing mechanism. It was found that the improvement of the thermal transmission performance of the afterheat recovery unit synchronizes with the increase of angular frequency, amplitude and phase shift.

Keywords:Nanofluids;Bionic Structure;Waste Heat Utilization Equipment;Thermal Performance

[References]

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[2] Wang X, Gao X, Bao K, Hua C, Han X, Chen G, Int. J. Therm. Sci., 28, 246 (2019)

[3] Jin H, Lin G, Guo Y, Bai L, Wen D, Renew. Energy, 145, 2337 (2020)

[4] Li Z, Selimefendigil F, Sheikholeslami M, Shafee A, Alghamdi M, Microsyst. Technol., 26(2), 333 (2020)

[5] Afrand M, Shahsavar A, Sardari PT, Sopian K, Salehipour H, Sol. Energy, 188, 83 (2019)

[6] Selimefendigil F, Bayrak F, Oztop HF, Renew. Energy, 125, 193 (2018)

[7] Selimefendigil F, Öztop HF, Renew. Energy, 162, 1076 (2020)

[8] Khanmohammadi S, Saadat-Targhi M, Ahmed FW, Afrand M, Int. J. Hydrog. Energy, 45, 6934 (2020)

[9] Sheikholeslami M, Arabkoohsar A, Jafaryar M, J. Energy Resour. Technol.-Trans. ASME, 142(11), 1 (2020)

[10] Wang X, Yan X, Gao N, Chen G, J. Therm. Sci., 29(6), 1504 (2020)

[11] Qi C, Luo T, Liu M, Fan F, Yan Y, Energy Conv. Manag., 197, 111877 (2019)

[12] Selimefendigil F, Öztop HF, J. Clean Prod., 279, 123426 (2021)

[13] Qiu L, Sang D, Feng Y, Huang H, Zhang X, Chem. Eng. Process., 151, 107915 (2020)

[14] Qi C, Li K, Li C, Shang B, Yan Y, Int. Commun. Heat Mass Transf., 114, 104589 (2020)

[15] Pourmehran O, Rahimi-Gorji M, Hatami M, Sahebi S, Domairry G, J. Taiwan Inst. Chem. Eng., 55, 49 (2015)

[16] Sheikholeslami M, Bhatti MM, Shafee A, Li Z, Comput. Thermal. Scien., 11(5), 475 (2019)

[17] Sheikholeslami M, Jafaryar M, Saleem S, Li Z, Shafee A, Jiang Y, Int. J. Heat Mass Transf., 126, 156 (2018)

[18] Qi C, Chen T, Tu J, Wang Y, Korean J. Chem. Eng., 37(12), 2104 (2020)

[19] Izadi M, Naderi S, J. Mech. Eng., 49(4), 9 (2019)

[20] Wang X, Yan Y, Meng X, Chen G, Appl. Therm. Eng., 157, 113761 (2019)

[21] Selimefendigil F, Öztop HF, Int. J. Heat Mass Transf., 178, 121623 (2021)

[22] Wang X, Wright E, Gao N, Lin Y, Int. J. Therm. Sci., 1383, 1 (2020)

[23] Nguyen Q, Sedeh SN, Toghraie D, Kalbasi R, Karimipour A, J. Braz. Soc. Mech. Sci. Eng., 42(9), 1 (2020)

[24] Ghaneifar M, Raisi A, Ali HM, Talebizadehsardari P, J. Therm. Anal. Calorim., 143(3), 2761 (2021)

[25] Yan SR, Kalbasi R, Toghraie D, Tian XX, Nguyen Q, Karimipour A, Math. Meth. Appl. Sci., 46, 6576 (2020)

[26] Pourfattah F, Arani AAA, Babaie MR, Nguyen HM, Asadi A, Int. J. Heat Mass Transf., 143, 118518 (2019)

[27] Sajjadi H, Delouei AA, Izadi M, Mohebbi R, Int. J. Heat Mass Transf., 132, 1087 (2019)

[28] Sheremet MA, Rashidi MM, Alex. Eng. J., 60(3), 2769 (2021)

[29] Sarafraz M, Arjomandi M, Int. Commun. Heat Mass Transf., 94, 39 (2018)

[30] Selimefendigil F, Öztop HF, Int. J. Heat Mass Transf., 129, 265 (2019)

[31] Naphon P, Wiriyasart S, Arisariyawong T, Nakharintr L, Int. J. Heat Mass Transf., 131, 329 (2019)

[32] Qi C, Li K, Li C, CIESC J., 72(4), 2006 (2021)

[33] Cheng NS, Law AWK, Powder Technol., 129, 156 (2003)

[34] Barletta A, Int. J. Heat Mass Transf., 52(21), 5266 (2009)

[35] Hamilton RL, Crosser O, Ind. Eng. Chem. Fundam., 1(3), 187 (1962)

[36] Kumar S, Prasad SK, Banerjee J, Appl. Math. Model., 34(3), 573 (2010)

[37] Gong J, Min C, Qi C, Wang E, Tian L, Int. Commun. Heat Mass Transf., 43, 53 (2013)

[38] Qi C, Tu J, Ding Z, Wang Y, Sun L, Wang C, Asia-Pac. J. Chem. Eng., e2668, 1 (2021)

[39] Zhao N, Guo L, Qi C, Chen T, Cui X, Energy Conv. Manag., 181, 235 (2019)