%0 Journal Article %1 Guanghui2002 %A Su, Guanghui %A Fukuda, Kenji %A Morita, Koji %A Pidduck, Mark %A Jia, Dounan %A Matsumoto, Tatsuya %A Akasaka, Ryo %D 2002 %J Journal of Nuclear Science and Technology %K 2002 evaporation flow heat-transfer %N 11 %P 1190-1198 %T Applications of Artificial Neural Network for the Prediction of Flow Boiling Curves %U http://dx.doi.org/10.3327/jnst.39.1190 %V 39 %X An artificial neural network (ANN) was applied successfully to predict flow boiling curves. The databases used in the analysis are from the 1960’s, including 1,305 data points which cover these parameter ranges: pressure P=100–1,000 kPa, mass flow rate G=40–500kg/m2·s, inlet subcooling ΔTsub=0–35°C, wall superheat ΔTw=10–300°C and heat flux Q=20–8,000 kW/m2. The proposed methodology allows us to achieve accurate results, thus it is suitable for the processing of the boiling curve data. The effects of the main parameters on flow boiling curves were analyzed using the ANN. The heat flux increases with increasing inlet subcooling for all heat transfer modes. Mass flow rate has no significant effects on nucleate boiling curves. The transition boiling and film boiling heat fluxes will increase with an increase in the mass flow rate. Pressure plays a predominant role and improves heat transfer in all boiling regions except the film boiling region. There are slight differences between the steady and the transient boiling curves in all boiling regions except the nucleate region. The transient boiling curve lies below the corresponding steady boiling curve.

@article{Guanghui2002, abstract = {An artificial neural network (ANN) was applied successfully to predict flow boiling curves. The databases used in the analysis are from the 1960’s, including 1,305 data points which cover these parameter ranges: pressure P=100–1,000 kPa, mass flow rate G=40–500kg/m2·s, inlet subcooling ΔTsub=0–35°C, wall superheat ΔTw=10–300°C and heat flux Q=20–8,000 kW/m2. The proposed methodology allows us to achieve accurate results, thus it is suitable for the processing of the boiling curve data. The effects of the main parameters on flow boiling curves were analyzed using the ANN. The heat flux increases with increasing inlet subcooling for all heat transfer modes. Mass flow rate has no significant effects on nucleate boiling curves. The transition boiling and film boiling heat fluxes will increase with an increase in the mass flow rate. Pressure plays a predominant role and improves heat transfer in all boiling regions except the film boiling region. There are slight differences between the steady and the transient boiling curves in all boiling regions except the nucleate region. The transient boiling curve lies below the corresponding steady boiling curve.}, added-at = {2011-05-31T10:36:05.000+0200}, author = {Su, Guanghui and Fukuda, Kenji and Morita, Koji and Pidduck, Mark and Jia, Dounan and Matsumoto, Tatsuya and Akasaka, Ryo}, biburl = {https://www.bibsonomy.org/bibtex/2198bbbbbce8956b9bf320b3a7d233c2e/thorade}, interhash = {2aad489a4bcd371a22bc3f4dcc266eb2}, intrahash = {198bbbbbce8956b9bf320b3a7d233c2e}, journal = {Journal of Nuclear Science and Technology}, keywords = {2002 evaporation flow heat-transfer}, number = 11, pages = {1190-1198}, timestamp = {2012-01-10T11:11:27.000+0100}, title = {Applications of Artificial Neural Network for the Prediction of Flow Boiling Curves}, url = {http://dx.doi.org/10.3327/jnst.39.1190}, volume = 39, year = 2002 }