Step-by-Step Evaluation of the Fuel Switch From Kerosene to Hydrogen On the Thermodynamic Cycle in Gas Turbine Engines

Alexander Görtz, Björn Schneider
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Abstract

Hydrogen combustion engines are one of the few possible ways forward to drastically reduce climate impact of aviation. While there is many information about the engine performance of hydrogen combustion engines it is not clear to which extend each property of the fuel switch effects the engines thermodynamic cycle and component behavior. The basic architecture is identical for both fuels but it is not known to which extend already existing and fully designed components can be used for the new application. In this work the basic differences between both fuels are presented using a thermodynamic model of simplified turbojet. The archived knowledge is applied to a reference turbofan for an application similar to an Airbus A320 while burning hydrogen. Different effects occurring during the fuel switch, e.g. higher water loading after combustion and lower fuel mass flow, will be looked at separately. A retrofitted engine towards hydrogen combustion will use 1.5% less energy for the same thrust while operating at 60 K lower temperatures. The working line in the compressors will also switch towards higher mass flow rates despite the higher working fluid quality after combustion. Additionally, a new designed turbofan is presented on preliminary level for a constant fan diameter, to address the effects of different thrust requirements and has a 3.6% lower specific energy consumption.
逐步评估燃气涡轮发动机热力循环中从煤油到氢气的燃料转换
氢气内燃机是大幅减少航空对气候影响的少数可行方法之一。虽然有许多关于氢气发动机性能的信息,但还不清楚燃料开关的每种特性对发动机热力学循环和部件性能的影响程度。这两种燃料的基本结构是相同的,但现有的、完全设计好的部件在多大程度上可以用于新的应用却不得而知。在这项工作中,使用简化涡轮喷气发动机的热力学模型介绍了两种燃料的基本差异。在燃烧氢气时,将存档知识应用于与空客 A320 类似的涡扇参考应用。在燃料转换过程中出现的不同影响,如燃烧后更高的水负荷和更低的燃料质量流量,将分别进行研究。改装为氢燃烧的发动机在相同推力下可减少 1.5% 的能量消耗,同时工作温度降低 60 K。尽管燃烧后的工作流体质量更高,但压缩机的工作管路也将转向更高的质量流量。此外,还初步介绍了一种新设计的涡轮风扇,其风扇直径恒定,可满足不同的推力要求,比能耗降低了 3.6%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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