Performance and optimization evaluation for integration of sCO2 power system into the aircraft propulsion system

Q1 Chemical Engineering International Journal of Thermofluids Pub Date : 2024-08-30 DOI:10.1016/j.ijft.2024.100798
L. Vesely , C. Bringhenti , J. Kapat , J.T. Tomita , M. Stoia
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Abstract

The aviation industry accounts for part of the CO2 emissions contributing to climate change. The industry has established a target to reduce 2050 net aviation carbon emissions by 50 % relative to 2005 levels. With this in mind, waste heat recovery is a key pathway to achieve reduced emissions and improve system efficiency. The waste heat may potentially be converted to electric power using a supercritical CO2 Brayton power cycle. The sCO2 power system offers the advantage of compactness owing to the high working fluid density, which is an important consideration for aircraft performance. The present work focuses on the integration of the sCO2 power system into the aircraft propulsion system and evaluation of its performance. Detailed optimization of the sCO2 waste heat system will be evaluated with a focus on cycle efficiency and net power under different operating conditions, including ground, takeoff, climb, cruise, and landing operations. The study is divided into two parts with two different turbofan engines, one with a nominal thrust of 30 kN and the other with a nominal thrust of 9 kN. The first part shows the effect and operation of the waste heat recovery unit under the different operating conditions. The second part is focused on cycle optimization and performance evaluation. The results demonstrate the potential of waste heat recovery during a range of operational conditions. The sCO2 cycle efficiency can reach between 25 and 39 % (depending on aircraft engine) with net power output in the range of 100 to 260 kW.

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将二氧化碳动力系统纳入飞机推进系统的性能和优化评估
航空业是造成气候变化的二氧化碳排放的一部分。航空业已制定了 2050 年航空碳净排放量比 2005 年减少 50% 的目标。有鉴于此,余热回收是实现减排和提高系统效率的关键途径。利用超临界二氧化碳布雷顿动力循环可将废热转化为电力。由于工作流体密度高,sCO2 动力系统具有结构紧凑的优点,这也是飞机性能的一个重要考虑因素。目前的工作重点是将 sCO2 动力系统集成到飞机推进系统中,并对其性能进行评估。将对 sCO2 废热系统进行详细的优化评估,重点是不同运行条件下的循环效率和净功率,包括地面、起飞、爬升、巡航和着陆操作。研究分为两部分,使用两台不同的涡扇发动机,一台的额定推力为 30 千牛,另一台的额定推力为 9 千牛。第一部分展示了废热回收装置在不同运行条件下的效果和运行情况。第二部分侧重于循环优化和性能评估。结果表明,在一系列运行条件下,余热回收都具有潜力。sCO2 循环效率可达 25% 至 39%(取决于飞机发动机),净输出功率在 100 至 260 千瓦之间。
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来源期刊
International Journal of Thermofluids
International Journal of Thermofluids Engineering-Mechanical Engineering
CiteScore
10.10
自引率
0.00%
发文量
111
审稿时长
66 days
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