亚临界和超临界朗肯蒸汽循环,温度最高可达 900°C,绝对压力最高可达 400 bara

Osama A. Marzouk
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If the absolute pressure and temperature of the superheated steam are both above the critical values for water (220.6 bara and 374.0°C), the cycle is classified as “supercritical.” Otherwise, the cycle is classified as “subcritical.” This study considers the impact of the temperature and pressure, independently, on the performance of a steam Rankine cycle. Starting from a representative condition for a subcritical cycle (600°C peak temperature and 50 bara peak absolute pressure), either the peak temperature or the peak absolute pressure of the cycle is increased with regular steps (up to 900°C, with a temperature step of 50°C, and up to 400 bara, with a pressure step of 50 bar). The variation of five scale-independent performance metrics is investigated in response to the elevated temperature and the elevated pressure. Thus, a total of 10 response curves are presented. When the temperature increased, all the five response variables were improved in a nearly linear profile. On the other hand, increasing the pressure did not give a monotonic linear improvement for each response variable. In particular, the cycle efficiency seemed to approach a limiting maximum value of 45% approximately, where further increases in the pressure cause diminishing improvements in the efficiency. When varying the peak pressure, an optimum minimum ratio of (water-mass-to-output-power) is found at 203 bara, although the cycle efficiency still increases beyond this value. In the present research work, the web-based tool for calculating steam properties by the British company Spirax Sarco Limited, and the software program mini-REFPROP by NIST (United States National Institute of Standards and Technology) were used for finding the necessary specific enthalpies (energy content) of water at different stages within the steam cycle. Both tools were found consistent with each other, as well as with the Python-based software package Cantera for simulating thermo-chemical-transport processes. The results showed that if the peak temperature reaches 900°C, a gain of about 5 percentage points (pp) in the thermal cycle efficiency becomes possible (compared to the case of having a base peak temperature of 600°C), as the predicted efficiency was found to increase from 38.60% (base case) to 43.67%. For the influence of the steam peak pressure, operating in the subcritical regime but close to the critical point appears to be a good choice given the gradual decline in efficiency gains at higher pressures. About 4.7 percentage point increase was found at the high subcritical peak pressure of 200 bara (compared to a base subcritical peak pressure of 50 bara). 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摘要

朗肯循环是一个封闭的蒸汽动力热力学循环,其中工作流体(特别是作为液体、蒸汽和液汽混合物的水)可用于将热量转化为机械能(轴旋转)。这种循环及其变体通过公用事业规模的火力发电厂(如燃煤发电厂和核电厂)广泛用于发电。在以蒸汽为基础的郎肯循环中,在蒸汽涡轮机部分内发生有用的膨胀过程之前,水必须被加压和加热到非常热的高压水蒸气形式,称为 "过热蒸汽"。如果过热蒸汽的绝对压力和温度都高于水的临界值(220.6 bara 和 374.0°C),则循环被归类为 "超临界"。否则,循环被归类为 "亚临界"。本研究分别考虑了温度和压力对蒸汽朗肯循环性能的影响。从一个具有代表性的亚临界循环条件(峰值温度 600°C,峰值绝对压力 50 bara)开始,循环的峰值温度或峰值绝对压力有规律地逐级升高(最高可达 900°C,温度升高 50°C;最高可达 400 bara,压力升高 50 bar)。针对升高的温度和压力,研究了五个与规模无关的性能指标的变化。因此,共呈现了 10 条响应曲线。当温度升高时,所有五个响应变量都以近乎线性的曲线得到改善。另一方面,压力的增加并没有使每个响应变量得到单调的线性改善。特别是,循环效率似乎接近 45% 左右的极限最大值,压力的进一步增加会导致效率的逐步提高。当改变峰值压力时,在 203 巴时发现了(水-质量-输出功率)的最佳最小比率,尽管循环效率在此值之后仍会增加。在本研究工作中,我们使用了英国 Spirax Sarco 有限公司的网络蒸汽属性计算工具和 NIST(美国国家标准与技术研究院)的软件程序 mini-REFPROP,以计算蒸汽循环不同阶段所需的水比焓(能量含量)。结果发现,这两种工具相互一致,也与基于 Python- 的 Cantera 软件包(用于模拟热化学传输过程)一致。结果表明,如果峰值温度达到 900°C,热循环效率可提高约 5 个百分点(pp)(与基础峰值温度为 600°C 的情况相比),预测效率从 38.60%(基础情况)提高到 43.67%。考虑到蒸汽峰值压力的影响,在亚临界状态下运行但接近临界点似乎是一个不错的选择,因为在压力较高时,效率收益会逐渐下降。在 200 bara 的高亚临界峰值压力下(与 50 bara 的基本亚临界峰值压力相比),效率提高了约 4.7 个百分点。研究结果还显示,蒸汽轮机出口处的液态水滴质量分数从 600°C 时的 11.00% 降至 900°C 时的 1.48%,这是有利的。该质量分数从 50 bara 时的 11.00% 增长到 400 bara 时的 27.89%,这是不可接受的。在 600°C 和 900°C 之间,过热温度每升高 100°C,循环热效率就会提高约 1.69 个百分点,同时汽轮机出口处的蒸汽质量也会提高约 3.17 个百分点。
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Subcritical and supercritical Rankine steam cycles, under elevated temperatures up to 900°C and absolute pressures up to 400 bara
The Rankine cycle is a conceptual arrangement of four processes as a closed vapor power thermodynamic cycle, where a working fluid (especially water as a liquid, as a vapor, and as a liquid-vapor mixture) can be used to convert heat into mechanical energy (shaft rotation). This cycle and its variants are widely used in electric power generation through utility-scale thermal power plants, such as coal-fired power plants and nuclear power plants. In the steam-based Rankine cycle, water should be pressurized and heated to be in the form of very hot high-pressure water vapor called “superheated steam,” before the useful process of expansion inside a steam turbine section occurs. If the absolute pressure and temperature of the superheated steam are both above the critical values for water (220.6 bara and 374.0°C), the cycle is classified as “supercritical.” Otherwise, the cycle is classified as “subcritical.” This study considers the impact of the temperature and pressure, independently, on the performance of a steam Rankine cycle. Starting from a representative condition for a subcritical cycle (600°C peak temperature and 50 bara peak absolute pressure), either the peak temperature or the peak absolute pressure of the cycle is increased with regular steps (up to 900°C, with a temperature step of 50°C, and up to 400 bara, with a pressure step of 50 bar). The variation of five scale-independent performance metrics is investigated in response to the elevated temperature and the elevated pressure. Thus, a total of 10 response curves are presented. When the temperature increased, all the five response variables were improved in a nearly linear profile. On the other hand, increasing the pressure did not give a monotonic linear improvement for each response variable. In particular, the cycle efficiency seemed to approach a limiting maximum value of 45% approximately, where further increases in the pressure cause diminishing improvements in the efficiency. When varying the peak pressure, an optimum minimum ratio of (water-mass-to-output-power) is found at 203 bara, although the cycle efficiency still increases beyond this value. In the present research work, the web-based tool for calculating steam properties by the British company Spirax Sarco Limited, and the software program mini-REFPROP by NIST (United States National Institute of Standards and Technology) were used for finding the necessary specific enthalpies (energy content) of water at different stages within the steam cycle. Both tools were found consistent with each other, as well as with the Python-based software package Cantera for simulating thermo-chemical-transport processes. The results showed that if the peak temperature reaches 900°C, a gain of about 5 percentage points (pp) in the thermal cycle efficiency becomes possible (compared to the case of having a base peak temperature of 600°C), as the predicted efficiency was found to increase from 38.60% (base case) to 43.67%. For the influence of the steam peak pressure, operating in the subcritical regime but close to the critical point appears to be a good choice given the gradual decline in efficiency gains at higher pressures. About 4.7 percentage point increase was found at the high subcritical peak pressure of 200 bara (compared to a base subcritical peak pressure of 50 bara). The results of this study also showed that the liquid water droplet mass fraction at the steam turbine exit diminishes from 11.00% at 600°C to only 1.48% at 900°C, which is favorable. This mass fraction grows from 11.00% at 50 bara to 27.89% at 400 bara, which is not acceptable. Every 100°C increase in the superheating temperature between 600°C and 900°C was found to cause aa increase in the cycle thermal efficiency by about 1.69 percentage points, and simultaneous a beneficial increase in the steam quality at the turbine exit by about 3.17 percentage points.
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