Your search keyword '"Chen, Daochuan"' showing total 2 results

1. Performance improvement of vapor-injection heat pump system by employing PVT collector/evaporator for residential heating in cold climate region.

Author

Yao, Jian, Zheng, Sihang, Chen, Daochuan, Dai, Yanjun, and Huang, Mingjun

Subjects

*AIR source heat pump systems, *HEAT pumps, *ELECTRIC heating, *HEATING, *THERMAL efficiency, *SOLAR heating, COLD regions

Abstract

The adoption of vapor injection (VI) cycle could overcome the defects of the conventional one-stage air source heat pump (ASHP) system under extremely low ambient temperature conditions. Nevertheless, the ASHP system with VI cycle still could not operate efficiently due to the low evaporating temperature in the fin-tube evaporator. For such a situation, the PVT (Photovoltaic/Thermal) collector/evaporator could reach higher evaporating temperature attributed to its physical structure, thereby improving the system COP. This study proposes the detailed mathematical model of the vapor-injection heat pump system by incorporating PVT collector/evaporator and verifies the effectiveness of the proposed system. Parametric studies have been then conducted. The proposed system can operate off-grid and its COP can reach 4.0 at the ambient temperature of −10 °C and the solar irradiation of 500 W/m2. The practical electrical efficiency of PV panels achieves at 15.1%, whereas the thermal efficiency of the system is 44.8%. A hybrid control method including three modes has been also proposed based on the results for improving the system performance. The levelized cost of heat (LCOH) of this system is 0.054 $/kWh, which is 51.5% lower than that of electric heating system (0.111 $/kWh). • A PVT based vapor-injection heat pump system was proposed for residential heating. • A hybrid control method was established for better system performance. • The influences of real-time working conditions on system performance were studied. • The comparative analysis was conducted between the proposed system and ASHP system. [ABSTRACT FROM AUTHOR]

Published

2021

2. Economic analysis and optimization of combined solar district heating technologies and systems.

Author

Huang, Junpeng, Fan, Jianhua, Furbo, Simon, Chen, Daochuan, Dai, Yanjun, and Kong, Weiqiang

Subjects

*HEAT storage devices, *SOLAR thermal energy, *ELECTRIC heating systems, *GROUND source heat pump systems, *HEAT storage, *SOLAR heating, *SOLAR collectors, *HEAT pumps

Abstract

To find an optimal economic solution for solar district heating (SDH) in China, an evaluation model based on the levelized cost of heat (LCoH) is developed. A Python program is developed to calculate the LCoH of SDH systems using the quasi-dynamic test method. Based on these calculations, the trend of LCoH with solar collector area under different heating load intensities, heating terminal units, heated areas and land rents is discussed. The optimal solar collector area and the solar fraction are determined for combinations of solar thermal with four types of auxiliary heat sources, including air source heat pumps, ground source heat pumps, gas boilers and gas boilers with seasonal heat storage. The calculations show an economic optimal solar fraction of 11%–33% for a SDH system with heat pumps. High dependency of LCoH on network temperature is found for a SDH system with gas boilers. Seasonal heat storage minimizes LCoH of a SDH system with gas boilers at 100% solar fraction. The findings can be used as a reference for local authorities, consultants and engineers in the early energy planning to determine the optimal proportion of solar energy in a district heating system with the lowest operating cost. • An optimal solar fraction of 11%–33% for a SDH system with heat pumps. • High dependency of LCoH on network temperature for a SDH system with gas boilers. • Heat storage minimizes LCoH of a SDH system with gas boilers at 100% solar fraction. • The higher the heat demand, the greater the solar contributed economic benefits are. • With biomass >1100 CNY/ton, the biomass heating system reduces LCoH by adding solar. [ABSTRACT FROM AUTHOR]

Published

2019