Urban energy transformation is important to promote China’s energy transformation,to facilitate ecological civilization construction,and to achieve the goal of carbon peak and carbon neutrality.In recent years,Huzhou...Urban energy transformation is important to promote China’s energy transformation,to facilitate ecological civilization construction,and to achieve the goal of carbon peak and carbon neutrality.In recent years,Huzhou,a city of Zhejiang Province,has actively promoted the"ecology+power"city construction.It has explored an innovative mode of urban energy transformation and gained rich practical experience,which has widely attracted attention at home and abroad.Based on field research,this paper makes a comprehensive collation of policies and practical experience of Huzhou’s"ecology+power"mode and summarizes the mode characteristics and promotion value of Huzhou’s urban energy transformation.Finally,taking Huzhou as a sample,we put forward some policy suggestions of China’s urban energy transformation.展开更多
This study reports a new model of an air standard Dual-Miller cycle(DMC) with two polytropic processes and heat transfer loss.The two reversible adiabatic processes which could not be realized in practice are replaced...This study reports a new model of an air standard Dual-Miller cycle(DMC) with two polytropic processes and heat transfer loss.The two reversible adiabatic processes which could not be realized in practice are replaced with two polytropic processes in order to more accurately reflect the practical working performance. The heat transfer loss is taken into account. The expressions of power output, thermal efficiency, entropy generation rate(EGR) and ecological function are addressed using finite-time thermodynamic theory. Through numerical calculations, the influences of compression ratio, cut-off ratio and polytropic exponent on the performance are thermodynamically analyzed. The model can be simplified to other cycle models under specific conditions, which means the results have an certain universality and may be helpful in the design of practical heat engines. It is shown that the entropy generation minimization does not always lead to the best system performance.展开更多
文摘Urban energy transformation is important to promote China’s energy transformation,to facilitate ecological civilization construction,and to achieve the goal of carbon peak and carbon neutrality.In recent years,Huzhou,a city of Zhejiang Province,has actively promoted the"ecology+power"city construction.It has explored an innovative mode of urban energy transformation and gained rich practical experience,which has widely attracted attention at home and abroad.Based on field research,this paper makes a comprehensive collation of policies and practical experience of Huzhou’s"ecology+power"mode and summarizes the mode characteristics and promotion value of Huzhou’s urban energy transformation.Finally,taking Huzhou as a sample,we put forward some policy suggestions of China’s urban energy transformation.
基金supported by the National Natural Science Foundation of China(Grant No.51576207)
文摘This study reports a new model of an air standard Dual-Miller cycle(DMC) with two polytropic processes and heat transfer loss.The two reversible adiabatic processes which could not be realized in practice are replaced with two polytropic processes in order to more accurately reflect the practical working performance. The heat transfer loss is taken into account. The expressions of power output, thermal efficiency, entropy generation rate(EGR) and ecological function are addressed using finite-time thermodynamic theory. Through numerical calculations, the influences of compression ratio, cut-off ratio and polytropic exponent on the performance are thermodynamically analyzed. The model can be simplified to other cycle models under specific conditions, which means the results have an certain universality and may be helpful in the design of practical heat engines. It is shown that the entropy generation minimization does not always lead to the best system performance.
