Volume 11, Issue 4
High Efficient Numerical Simulation of Infrared Radiation from a Hot Exhaust Nozzle

Haiyang Hu, Peng Bai & Qiang Wang

Commun. Comput. Phys., 11 (2012), pp. 1182-1204.

Published online: 2012-04

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  • Abstract

A coupled model, capable of simulating transonic flow, solid heat conduction, species transport, and gas radiation, is developed that provides better computational treatment of infrared radiation from hot exhaust nozzles. The modeling of gas radiation is based on a statistical narrow-band correlated-k analysis, whose parameters are deduced from the HITEMP line-by-line database. To improve computational efficiency, several methods are employed. A mixed analytical-numerical algorithm is described for the stiffness of the two-equation turbulence model and an alternating direction implicit pretreatment for the ill-conditioned matrix appearing in the coupled problem of flow and solid heat conduction. Moreover, an improved multigrid method and a symmetry plane treatment of the radiation transfer-energy equations are also introduced. Four numerical simulations are given to confirm the efficiency and accuracy of the numerical method. Finally, an account of the aerothermodynamics and infrared characteristics for two types of nozzles are presented. The infrared radiation intensity of the Chevron ejecting nozzle is clearly smaller than that of the common axisymmetric ejecting nozzle. All computations can be performed on a personal computer.

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@Article{CiCP-11-1182, author = {}, title = {High Efficient Numerical Simulation of Infrared Radiation from a Hot Exhaust Nozzle}, journal = {Communications in Computational Physics}, year = {2012}, volume = {11}, number = {4}, pages = {1182--1204}, abstract = {

A coupled model, capable of simulating transonic flow, solid heat conduction, species transport, and gas radiation, is developed that provides better computational treatment of infrared radiation from hot exhaust nozzles. The modeling of gas radiation is based on a statistical narrow-band correlated-k analysis, whose parameters are deduced from the HITEMP line-by-line database. To improve computational efficiency, several methods are employed. A mixed analytical-numerical algorithm is described for the stiffness of the two-equation turbulence model and an alternating direction implicit pretreatment for the ill-conditioned matrix appearing in the coupled problem of flow and solid heat conduction. Moreover, an improved multigrid method and a symmetry plane treatment of the radiation transfer-energy equations are also introduced. Four numerical simulations are given to confirm the efficiency and accuracy of the numerical method. Finally, an account of the aerothermodynamics and infrared characteristics for two types of nozzles are presented. The infrared radiation intensity of the Chevron ejecting nozzle is clearly smaller than that of the common axisymmetric ejecting nozzle. All computations can be performed on a personal computer.

}, issn = {1991-7120}, doi = {https://doi.org/10.4208/cicp.230410.090911s}, url = {http://global-sci.org/intro/article_detail/cicp/7406.html} }
TY - JOUR T1 - High Efficient Numerical Simulation of Infrared Radiation from a Hot Exhaust Nozzle JO - Communications in Computational Physics VL - 4 SP - 1182 EP - 1204 PY - 2012 DA - 2012/04 SN - 11 DO - http://dor.org/10.4208/cicp.230410.090911s UR - https://global-sci.org/intro/article_detail/cicp/7406.html KW - AB -

A coupled model, capable of simulating transonic flow, solid heat conduction, species transport, and gas radiation, is developed that provides better computational treatment of infrared radiation from hot exhaust nozzles. The modeling of gas radiation is based on a statistical narrow-band correlated-k analysis, whose parameters are deduced from the HITEMP line-by-line database. To improve computational efficiency, several methods are employed. A mixed analytical-numerical algorithm is described for the stiffness of the two-equation turbulence model and an alternating direction implicit pretreatment for the ill-conditioned matrix appearing in the coupled problem of flow and solid heat conduction. Moreover, an improved multigrid method and a symmetry plane treatment of the radiation transfer-energy equations are also introduced. Four numerical simulations are given to confirm the efficiency and accuracy of the numerical method. Finally, an account of the aerothermodynamics and infrared characteristics for two types of nozzles are presented. The infrared radiation intensity of the Chevron ejecting nozzle is clearly smaller than that of the common axisymmetric ejecting nozzle. All computations can be performed on a personal computer.

Haiyang Hu, Peng Bai & Qiang Wang. (2020). High Efficient Numerical Simulation of Infrared Radiation from a Hot Exhaust Nozzle. Communications in Computational Physics. 11 (4). 1182-1204. doi:10.4208/cicp.230410.090911s
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