Current research and ways of capturing mechanical energy are discussed in this paper. By the aid of the comprehensive thermodynamic analysis and Aspen simulation tool, the amount of a vailable work that can be produc...Current research and ways of capturing mechanical energy are discussed in this paper. By the aid of the comprehensive thermodynamic analysis and Aspen simulation tool, the amount of a vailable work that can be produced from capturing the pressure energy has been calculated. Based on the comprehensive thermodynamic analysis, two systems have been proposed to capture pressure energy of natural gas to generate electricity. In this study, the expression of exergy is given which can be used in evaluating purposes. A problem with this multidisciplinary study is the complicated boundary condition. In conclusion, a technical prospect on recoverable natural gas pressure energy has been presented based on total energy system theory.展开更多
为研究高超声速风洞部件的气动特性,运用空气的亥姆霍兹能状态方程和输运物性方程组,计算超高压工况下空气的热物性参数。将计算结果与美国国家标准与技术研究院(National Institute of Standards and Technology,NIST)数据库的实验数...为研究高超声速风洞部件的气动特性,运用空气的亥姆霍兹能状态方程和输运物性方程组,计算超高压工况下空气的热物性参数。将计算结果与美国国家标准与技术研究院(National Institute of Standards and Technology,NIST)数据库的实验数据进行比较,得到相对误差值。结果表明,空气亥姆霍兹能状态方程和输运物性方程组计算得到的空气热物性参数与NIST标准实验数据相比误差较小,可以应用于超高压状态下的空气热物性计算。展开更多
基金Supported by Tianjin Institute of Urban Construction(03046)
文摘Current research and ways of capturing mechanical energy are discussed in this paper. By the aid of the comprehensive thermodynamic analysis and Aspen simulation tool, the amount of a vailable work that can be produced from capturing the pressure energy has been calculated. Based on the comprehensive thermodynamic analysis, two systems have been proposed to capture pressure energy of natural gas to generate electricity. In this study, the expression of exergy is given which can be used in evaluating purposes. A problem with this multidisciplinary study is the complicated boundary condition. In conclusion, a technical prospect on recoverable natural gas pressure energy has been presented based on total energy system theory.
文摘为研究高超声速风洞部件的气动特性,运用空气的亥姆霍兹能状态方程和输运物性方程组,计算超高压工况下空气的热物性参数。将计算结果与美国国家标准与技术研究院(National Institute of Standards and Technology,NIST)数据库的实验数据进行比较,得到相对误差值。结果表明,空气亥姆霍兹能状态方程和输运物性方程组计算得到的空气热物性参数与NIST标准实验数据相比误差较小,可以应用于超高压状态下的空气热物性计算。
基金the major scientific instruments and equipment development project of the Ministry of Science and Technology,China(2012YQ18011805)the science and technology project from the technology bureau of Chengdu(2014HM0100099SF)the project of science and technology innovation team of Sichuan province(2015TD0020)