A novel cryogenic cycle by using a binary mixture as working fluids and combined with a vapor absorption process was proposed to improve the energy recovery efficiency of an LNG (liquefied natural gas) cold power generation. The cycle was simulated with seawater as the heat source and LNG as the heat sink, and the optimization of the power generated per unit LNG was performed. Tetrafluoromethane (CF(4)) and propane (C(3)H(8)) were employed as the working fluids. The effects of the working fluid composition, the recirculation rate of the C(3)H(8)-rich solution and the turbine intermediate pressure were investigated. In the cryogenic absorber, the C(3)H(8)-rich liquid absorbs the CF(4)-rich vapor so that the mixture exhausting from the turbine can be fully condensed at a reduced pressure. This reduction of turbine back pressure can considerably improve the cycle efficiency. The presented cycle was compared with the C(3)H(8) ORC (organic Rankine cycle), to show such performance improvement. It is found that the novel cycle is considerably superior to the ORC. The efficiency is increased by 66.3% and the optimized LNG recovery temperature is around -60 degrees C.

• 出版日期2011-5
• 单位中山大学