Abstract
Heat transfer enhancement techniques used in liquid piston gas compression can contribute to improving the efficiency of compressed air energy storage systems by achieving a near-isothermal compression process. This work examines the effectiveness of a simultaneous use of two proven heat transfer enhancement techniques, metal wire mesh inserts and spray injection methods, in liquid piston gas compression. By varying the dimension of the inserts and the pressure of the spray, a comparative study was performed to explore the plausibility of additional improvement. The addition of an insert can help abating the temperature rise when the insert does not take much space or when the spray flowrate is low. At higher pressure, however, the addition of spacious inserts can lead to less efficient temperature abatement. This is because inserts can distract the free-fall of droplets and hinder their speed. In order to analytically account for the compromised cooling effects of droplets, Reynolds number, Nusselt number, and heat transfer coefficients of droplets are estimated under the test conditions. Reynolds number of a free-falling droplet can be more than 1000 times that of a stationary droplet, which results in 3.95 to 4.22 times differences in heat transfer coefficients.
Highlights
Devastating impacts of fossil fuels on environments have been reported and recognized as a global issue [1]
Enhancement of heat transfer is key to increasing isothermal efficiency of a gas compression process by abating temperature rise during compression
Metal wire mesh inserts with three different geometries were used in addition to a spray injection technique
Summary
Devastating impacts of fossil fuels on environments have been reported and recognized as a global issue [1] This issue has been frequently discussed and it is highly critical to moderate the use of them [2,3]. Compressed air energy storage (CAES) stores air in the form of compressed air and restores the energy by the air expansion. It is considered as one of the promising bulk-scale energy storage options, owing to its economic and environmental advantages [9]. In an open accumulator system, air is drawn from the atmosphere for gas compression and stored in the accumulator [16] This concept was further studied in [12], which presents a control strategy for an open accumulator CAES. [20] reported that underwater CAES can achieve better efficiency over underground CAES for advanced adiabatic type CAES
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