Two power plant schemes that reduce CO_2 emission and employ natural gas reforming were analyzed and discussed. The first one integrates natural gas reforming technology for efficiency improvement with an oxy-fuel combined power system (OXYF-REF), with water as the main work fluid. The reforming heat is obtained from the available turbine exhaust heat, and the produced syngas is used as fuel with oxygen as the oxidizer. The turbine working fluid can expand down to a vacuum, producing a high-pressure ratio and thus more net work. The second system integrates natural gas reforming in a precombus-tion decarbonization scheme using chemical absorption technology for the CO2 removal (PCD-REF). The gas turbine is the conventional air-based one with compressor inter-cooling. Supplementary combustion is employed to elevate the turbine exhaust temperature and thus achieve a much higher methane conversion rate (96.9%). Both systems involve internal heat recuperation from gas turbine exhausts, and particular attention has been paid to the integration of the heat recovery chain to reduce the related exergy destruction. The systems are simulated and their thermal efficiency, overall and component exergy losses, and CO_2 removal capacity are compared. The OXYF-REF system has a higher energy efficiency, of 51.4%, and higher CO_2 removal, but the product CO_2 has lower purity, of 84%. The PCD-REF system has a thermal efficiency of 46%, the captured CO_2 is 99% pure, and the CO_2 specific emission is 58.5 g/kW h.
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机译:分析并讨论了两种减少CO_2排放并采用天然气重整的电厂方案。第一个将以天然气为主要工作流体的含氧燃料联合动力系统(OXYF-REF)集成了天然气重整技术以提高效率。重整热量是从可用的涡轮机废气中获得的,生成的合成气用作燃料,氧作为氧化剂。涡轮工作流体可以向下膨胀至真空,从而产生高压比,从而产生更多的净功。第二个系统将天然气重整技术集成到燃烧前的脱碳方案中,该方案使用化学吸收技术去除CO2(PCD-REF)。燃气轮机是传统的基于空气的燃气轮机,具有压缩机中冷功能。采用辅助燃烧来提高涡轮机排气温度,从而实现更高的甲烷转化率(96.9%)。这两个系统都涉及从燃气轮机废气中回收内部热量,并且已经特别注意了热回收链的集成以减少相关的火用破坏。对系统进行了仿真,并比较了它们的热效率,整体和组件的火用损失以及CO_2的去除能力。 OXYF-REF系统具有更高的能源效率(51.4%)和更高的CO_2去除率,但产物CO_2的纯度更低(84%)。 PCD-REF系统的热效率为46%,捕获的CO_2纯度为99%,CO_2的比排放为58.5 g / kW h。
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