@article{scholars13997, note = {cited By 0; Conference of 2nd Regional Conference on Mechanical and Marine Engineering, ReMME 2018 ; Conference Date: 7 November 2018 Through 9 November 2018; Conference Code:235599}, year = {2020}, doi = {10.1007/978-981-15-0002-2{$_3$}{$_7$}}, publisher = {Springer Science and Business Media Deutschland GmbH}, journal = {Lecture Notes in Mechanical Engineering}, title = {A Study of a Heat Exchanger Sizing of a Gas Turbine Inlet Air Cooling for Power Enhancement}, pages = {361--368}, keywords = {Air intakes; Cooling; Efficiency; Gas compressors; Gases; Heat exchangers, Cooling plants; District cooling; Gas turbine efficiency; Gas turbine inlet air cooling; Inlet-air cooling; PETRONAS; Power enhancement; Pressure loss; Sizing; Turbine inlets, Gas turbines}, url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85077896034&doi=10.1007\%2f978-981-15-0002-2\%5f37&partnerID=40&md5=cf5de6ad7b5e640da49045a96ff7d997}, abstract = {A gas turbine operated at the University Technology PETRONAS Gas Turbine District Cooling Plant produces an average of 3258{\^A} kWh with 30 of estimated gas turbine efficiency. A previous study done by the writer has shown of 20 increase in the efficiency of a gas turbine with the implementation of the turbine inlet air cooling. The sizing of the Heat Exchanger needed to be determined as the existing air inlet is only a 30{\^A} ft2 flange attached directly to the compressor of the gas turbine. This studies conclude that a 320{\^A} ft2 heat exchanger is needed in order to reduce the air inlet fluctuations (a range of 23{\^a}??34{\^A} {\^A}oC) to 15{\^A} {\^A}oC. By placing the heat exchanger in the gas turbine, a significant Pa pressure loss of approximately 187.55 was experienced. {\^A}{\copyright} 2020, Springer Nature Singapore Pte Ltd.}, issn = {21954356}, author = {Salim, D. A. and Majid, M. A. A. and Nordin, A.}, isbn = {9789811500015} }