%0 Journal Article %1 pangborn2015comparison %A Pangborn, Herschel %A Alleyne, Andrew G. %A Wu, Ning %D 2015 %J International Journal of Refrigeration %K 2015 comparison heat-exchanger modelling %N 0 %P 101 - 114 %R 10.1016/j.ijrefrig.2015.01.009 %T A comparison between finite volume and switched moving boundary approaches for dynamic vapor compression system modeling %U http://dx.doi.org/10.1016/j.ijrefrig.2015.01.009 %V 53 %X Most work in dynamic heat exchanger modeling for control design can be classified as either a finite volume or a moving boundary formulation. These approaches represent fundamentally different discretization approaches and are often characterized as contrasting accuracy with simulation speed. This work challenges that characterization by validating finite volume and moving boundary heat exchanger models with experimental data from a vapor compression system in order to demonstrate that these approaches are capable of achieving similar levels of accuracy. However, there are differences. The moving boundary model is found to have faster simulation speed, while the finite volume model is more flexible for adaptation to heat exchangers of different physical configuration. The formulation of each modeling approach used in this work is described in detail and techniques to increase simulation speed and avoid numerical issues in implementation are discussed.

@article{pangborn2015comparison, abstract = {Most work in dynamic heat exchanger modeling for control design can be classified as either a finite volume or a moving boundary formulation. These approaches represent fundamentally different discretization approaches and are often characterized as contrasting accuracy with simulation speed. This work challenges that characterization by validating finite volume and moving boundary heat exchanger models with experimental data from a vapor compression system in order to demonstrate that these approaches are capable of achieving similar levels of accuracy. However, there are differences. The moving boundary model is found to have faster simulation speed, while the finite volume model is more flexible for adaptation to heat exchangers of different physical configuration. The formulation of each modeling approach used in this work is described in detail and techniques to increase simulation speed and avoid numerical issues in implementation are discussed. }, added-at = {2015-04-09T08:59:51.000+0200}, author = {Pangborn, Herschel and Alleyne, Andrew G. and Wu, Ning}, biburl = {https://www.bibsonomy.org/bibtex/2d35f0f1087adbb014a1ef96f37bf0375/thorade}, description = {A comparison between finite volume and switched moving boundary approaches for dynamic vapor compression system modeling}, doi = {10.1016/j.ijrefrig.2015.01.009}, interhash = {502b1b6bf3abf485588b31048f5ebc0a}, intrahash = {d35f0f1087adbb014a1ef96f37bf0375}, issn = {0140-7007}, journal = {International Journal of Refrigeration }, keywords = {2015 comparison heat-exchanger modelling}, number = 0, pages = {101 - 114}, timestamp = {2015-04-09T08:59:51.000+0200}, title = {A comparison between finite volume and switched moving boundary approaches for dynamic vapor compression system modeling }, url = {http://dx.doi.org/10.1016/j.ijrefrig.2015.01.009}, volume = 53, year = 2015 }