%0 Journal Article %1 Zhu2004 %A Zhu, Jialing %A Zhang, Wei %D 2004 %J Geothermics %K 2004 design district-heating geothermal optimization plate-heat-exchanger %N 3 %P 337 - 347 %R 10.1016/j.geothermics.2003.08.013 %T Optimization design of plate heat exchangers (PHE) for geothermal district heating systems %U http://dx.doi.org/10.1016/j.geothermics.2003.08.013 %V 33 %X Plate heat exchangers (PHEs) are an important part of a geothermal heating system. If titanium is the material used for the PHE, then the latter will cost from about 25-30\% of the total cost of the heating system. This paper discusses the integrated optimal design of the materials, placement, size and flow-rate of a plate heat exchanger. With an input of data on the application technology, and economic and environmental parameters, a computer can be used to design the optimal placement, size and flow-rate of the PHEs. With this type of calculation, the computer can provide values for PHE size, flow-rate, flow paths and flow channels, with a minimum heat transfer area for a basic heat requirement. The paper also illustrates how the choice of PHE size, and the placement of the flow paths and flow channels influences the heat transfer area, producing a different design from that of a practical application (Tianjin, China). By optimizing its design, the PHEs will effectively be smaller than the real example given, with a consequent reduction in cost.

@article{Zhu2004, abstract = {Plate heat exchangers (PHEs) are an important part of a geothermal heating system. If titanium is the material used for the PHE, then the latter will cost from about 25-30\% of the total cost of the heating system. This paper discusses the integrated optimal design of the materials, placement, size and flow-rate of a plate heat exchanger. With an input of data on the application technology, and economic and environmental parameters, a computer can be used to design the optimal placement, size and flow-rate of the PHEs. With this type of calculation, the computer can provide values for PHE size, flow-rate, flow paths and flow channels, with a minimum heat transfer area for a basic heat requirement. The paper also illustrates how the choice of PHE size, and the placement of the flow paths and flow channels influences the heat transfer area, producing a different design from that of a practical application (Tianjin, China). By optimizing its design, the PHEs will effectively be smaller than the real example given, with a consequent reduction in cost.}, added-at = {2011-01-19T18:08:04.000+0100}, author = {Zhu, Jialing and Zhang, Wei}, biburl = {https://www.bibsonomy.org/bibtex/255d1353eeeb90e11331723a7781db841/thorade}, description = {ScienceDirect - Geothermics : Optimization design of plate heat exchangers (PHE) for geothermal district heating systems}, doi = {10.1016/j.geothermics.2003.08.013}, interhash = {9143e33d55f1bd314a98f5b819278341}, intrahash = {55d1353eeeb90e11331723a7781db841}, issn = {0375-6505}, journal = {Geothermics}, keywords = {2004 design district-heating geothermal optimization plate-heat-exchanger}, number = 3, pages = {337 - 347}, timestamp = {2012-11-02T18:14:02.000+0100}, title = {Optimization design of plate heat exchangers (PHE) for geothermal district heating systems}, url = {http://dx.doi.org/10.1016/j.geothermics.2003.08.013}, volume = 33, year = 2004 }