Your search keyword '"Fangqiu Li"' showing total 2 results

1. Optimization and environmental and economic impact evaluation of the micro-energy network system on the basis of the load characteristics analysis

Author

Yuzhou Tang, Qiao Ma, Qingsong Wang, Fangqiu Li, Xueliang Yuan, and Hongwei Liu

Subjects

Economics and Econometrics, Environmental Engineering, Total cost, business.industry, Management, Monitoring, Policy and Law, Environmental economics, General Business, Management and Accounting, Renewable energy, Electricity generation, Distributed generation, Environmental Chemistry, Environmental science, Environmental impact assessment, Economic impact analysis, Electricity, business, Life-cycle assessment

Abstract

Micro-energy networks have been widely used in power distribution systems. Previous studies have not addressed how to avoid these networks being dependent on the grid, due to the instability of distributed energy sources, or the lack of specific quantification of environmental and economic benefits. To understand the overall potential of the micro-energy network system for reducing environmental impacts, a life cycle assessment was conducted for the industrial park in Jinan. The analysis used a “cradle to gate” system boundary and a 1-year operation of the micro-energy network as the functional unit. The HOMER software was applied to build the research object’s micro-energy network model and to carry out load analysis. The environmental impact and financial costs of the micro-energy network system have been estimated for different combinations of gas turbine units and water chilling units. The results show that all optimized scenarios could achieve an environmental impact reduction of more than 50% when compared to the initial scenario, regardless of the benefits of exporting surplus electricity. A reduction in environmental impacts as high as 71% could be achieved in optimized scenarios, although total costs would be 13% higher. The categories of freshwater ecotoxicity, marine ecotoxicity, human carcinogenic toxicity, and human noncarcinogenic toxicity were determined as the key impact categories. The impact of different electricity generation and the environmental benefits of exporting electricity are discussed. We concluded that micro-energy networks integrating natural gas and renewable energy technologies could bring about significant environmental benefits.

Published

2021

2. In-plane and out-of-plane dynamics of curved pipes conveying fluid by integral transform method

Author

Fangqiu Li, Jian Su, Chen An, and Menglan Duan

Subjects

Physics, 0209 industrial biotechnology, Partial differential equation, Mechanical Engineering, Applied Mathematics, General Engineering, Aerospace Engineering, Natural frequency, 02 engineering and technology, Mechanics, Integral transform, Industrial and Manufacturing Engineering, Displacement (vector), Physics::Fluid Dynamics, Vibration, 020901 industrial engineering & automation, Flow (mathematics), Ordinary differential equation, Automotive Engineering, Boundary value problem

Abstract

This study presents a new solution for the dynamic behavior of in-plane and out-of-plane motion of a curved pipe conveying fluid, using the generalized integral transform technique (GITT). The system of sixth- and fourth-order partial differential equations governing three-dimensional motion of the curved pipe is integral transformed into three coupled systems of second-order ordinary differential equations, which are solved numerically by using the NDSolve routine of Mathematica. Excellent convergence behavior of the GITT solution is shown by comparing the vibration deflections at different points along the curved pipe centerline obtained with of different truncation orders. The results of natural frequencies and vibration responses compare well with available results in the literature obtained by other methods. Furthermore, we investigate the dynamic behavior of the curved pipe with different axial forces, flow velocities and other vibration parameters. A relationship between boundary conditions and axial forces is provided, and a series of vibration displacement and velocity trajectories is obtained. It is shown that the GITT is a convenient and effective mathematical method for vibration analysis of the curved pipe conveying fluid and can be used for further study of the dynamics of variable-curvature curved pipes.

Published

2019