Publication de 12 numéros par an
ISSN Imprimer: 1091-028X
ISSN En ligne: 1934-0508
Indexed in
NUMERICAL STUDY OF POROUS BLUNT NOSECONE TRANSPIRATION COOLING UNDER SUPERSONIC INCOMING FLOW
RÉSUMÉ
The study is focused on the porous blunt nosecone transpiration cooling process under supersonic incoming flow conditions using a two-domain approach based on the preconditioned density-based algorithm. The protection mechanism of blunt nosecone transpiration cooling and the effects of coolant injection rate on transpiration cooling performance are discussed. Results indicate that the bowshock is pushed off the wall by coolant injection and the boundary layer becomes thicker. The effect becomes increasingly obvious with increasing injection rate. Transpiration cooling can protect the downstream noncooling wall. With increasing coolant injection rate, the increase in the cooling effect at the leading edge is larger than that at the noncooling area downstream. Transpiration cooling performs better and skin friction is reduced, but the pressure drop for porous domains increases.
-
Su Hao, Wang Jianhua, He Fei, Chen Liang, Ai Bangcheng, Numerical investigation on transpiration cooling with coolant phase change under hypersonic conditions, International Journal of Heat and Mass Transfer, 129, 2019. Crossref
-
Leontiev Alexandr, Saveliev Andrei, Kichatov Boris, Kiverin Alexey, Korshunov Alexey, Sudakov Vladimir, Effect of gaseous coolant temperature on the transpiration cooling for porous wall in the supersonic flow, International Journal of Heat and Mass Transfer, 142, 2019. Crossref
-
Kalapana M., Vijaya R. Bhuvana, Mass transfer on MHD convection flow past an infinite vertical porous plate, INTERNATIONAL CONFERENCE ON MATHEMATICAL SCIENCES AND APPLICATIONS (ICMSA-2019), 2246, 2020. Crossref
-
Krishna M. Veera, Analytical study of chemical reaction, Soret, Hall and ion slip effects on MHD flow past an infinite rotating vertical porous plate, Waves in Random and Complex Media, 2022. Crossref
-
Gopal Ch. H. K., Sudhakar M., Masthan Rao S., Chemical reaction on hydromagnetic natural convective flow over an unlimited perpendicular permeable plate, Heat Transfer, 2022. Crossref
-
Liu Jian, Xu Mengyao, Zhang Rongdi, Zhang Xirui, Xi Wenxiong, Progress of Porous/Lattice Structures Applied in Thermal Management Technology of Aerospace Applications, Aerospace, 9, 12, 2022. Crossref