Thermal management for conjugate heat transfer of curved solid conductive panel coupled with different cooling systems using non-Newtonian power law nanofluid applicable to photovoltaic panel systems
| dc.contributor.author | Selimefendigil F. | |
| dc.contributor.author | Öztop H.F. | |
| dc.date.accessioned | 2024-07-22T08:04:50Z | |
| dc.date.available | 2024-07-22T08:04:50Z | |
| dc.date.issued | 2022 | |
| dc.description.abstract | Thermal performance features for a coupled conjugate thermo-fluid system with different cooling configurations (flat channel (F-C), grooved channel (G-C) and impinging jets (I-J)) are explored numerically by using non-Newtonian nanofluid. The numerical work is performed for different Reynolds numbers (100≤Re≤300), index of power law (0.8≤n≤1.2), height (0.1H≤b≤0.6H) and number (2≤N≤9) of corrugation in the G-C system, number (2≤Nj≤9) and distance (5w≤sx≤25w) between jets in the I-J flow system. Different volume fractions (0≤ϕ≤0.04) and particle sizes (20nm≤dp≤80nm) of nanoparticles are used. When systems operating at the highest and lowest Re are compared, 9 K, 11 K and 8 K temperature reduction are achieved for F-C, G-C and I-J cooling systems. However, I-J flow system at higher Re is very effective on the thermal performance improvement when shear thickening fluid is used. For the G-C flow system, increasing the height and number of the corrugation waves resulted in improvement in the thermal performance. Up to 46% increment in the Nu number (average) and reduction of 6.5 K in the average surface temperature are achieved with varying the height of the corrugation while these values are 17% and 1.6 K when wave number is increased. The average Nu number rises by about 32% and temperature drops by about 6.5 K when jet number is varied from 3 to 11, while these values are obtained as 8% and 4 K for when distance between jets are varied from sx=5w to sx=25w. For F-C, G-C and I-J flow systems, average Nu rises by about 15.5% and 14.5% and 16.3% for shear thinning fluid while they become 16.6%, 9.94% and 12.8% for shear thickening fluid at the highest solid volume fraction. As the nanoparticle size is increasing, there is 6% and 7% reduction in the average Nu number. Thermal performance estimations are made with four inputs and four outputs system by using artificial neural networks. © 2021 | |
| dc.identifier.DOI-ID | 10.1016/j.ijthermalsci.2021.107390 | |
| dc.identifier.issn | 12900729 | |
| dc.identifier.uri | http://akademikarsiv.cbu.edu.tr:4000/handle/123456789/12870 | |
| dc.language.iso | English | |
| dc.publisher | Elsevier Masson s.r.l. | |
| dc.subject | Cooling | |
| dc.subject | Cooling systems | |
| dc.subject | Nanofluidics | |
| dc.subject | Nanoparticles | |
| dc.subject | Neural networks | |
| dc.subject | Non Newtonian flow | |
| dc.subject | Photovoltaic cells | |
| dc.subject | Reynolds number | |
| dc.subject | Shear flow | |
| dc.subject | Shear thinning | |
| dc.subject | Thermoelectric equipment | |
| dc.subject | Thermoelectricity | |
| dc.subject | Volume fraction | |
| dc.subject | Flat channels | |
| dc.subject | Flow systems | |
| dc.subject | Grooved channel | |
| dc.subject | Impinging jet flow | |
| dc.subject | Jet impingement | |
| dc.subject | Nanofluids | |
| dc.subject | Non-newtonian | |
| dc.subject | Nu number | |
| dc.subject | PV system | |
| dc.subject | Thermal Performance | |
| dc.subject | Finite element method | |
| dc.title | Thermal management for conjugate heat transfer of curved solid conductive panel coupled with different cooling systems using non-Newtonian power law nanofluid applicable to photovoltaic panel systems | |
| dc.type | Article |