Abstract
With the expansion of cities, district heating (DH) networks are playing an increasingly important role. The energy consumption due to the time delay caused by the transport of the medium in the DH network is enormous, especially in large networks. The study of time delay is necessary for the operation and optimization of DH networks. Compared with previous studies of constant flow rates and ideal pipeline (without regard to branches, elbows, variable pipe diameters, etc), this paper simulates a DH network in Tianjin University, China, by establishing the actual engineering model in a Computational Fluid Dynamics (CFD) method to analyze the time delay. The CFD model has great advantages in terms of computational cost and application range compared to theoretical calculations. The peak-valley method was used to verify the correctness of the time delay simulation model. Results show that the time delay calculated by the CFD model is consistent with the actual time delay obtained from the measured data. Based on this model, the parameters that affect the time delay are furtherly analyzed. Four key parameters, including flow rate, pipe length, pipe diameter, and water supply temperature are summarized. The results show that the flow rate, pipe length and pipe diameter have a great influence on the time delay of the DH network, while the temperature has little effect on the time delay. The time delay of the DH network system has a significant impact and can provide services for optimal control of the system.
Highlights
district heating (DH) (District heating) networks are considered a very efficient option for providing heating and domestic hot water to buildings, for densely populated areas [1]
This paper focused on the calculation method of the time delay of the DH network system, which was determined by establishing a Computational Fluid Dynamics (CFD) model
A model based on the CFD method to determine the time delay of the DH network was proposed
Summary
DH (District heating) networks are considered a very efficient option for providing heating and domestic hot water to buildings, for densely populated areas [1]. Improving the heating performance of DH networks, one of the most important components in district heating systems, has a significant influence on the promotion of energy efficiency [3]. The dynamic features of DH consumers and networks usually influence the operational effect of the DH system heavily because of the time delays in the DH system [5]. It may take a huge amount of time for the further located ends to response to heat injection. The optimization of system control [9,10] to reduce the energy losses caused by time delays has attracted more and more scholars’ attention
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