Abstract
Integration of large-scale cluster electric vehicles (EVs) and their spatial-temporal transfer randomness are likely to affect the safety and economic operation of the distribution network. This paper investigates the spatial-temporal distribution prediction of EVs’ charging load and then evaluates the reliability of the distribution network penetrated with large-scale cluster EVs. To effectively predict the charging load, trip chain technology, Monte Carlo method and Markov decision process (MDP) theory are employed. Moreover, a spatial-temporal transfer model of EVs is established, and based on which, an EV energy consumption model and a charging load prediction model are constructed with consideration of temperature, traffic condition and EV owner’s subjective willingness in different scenarios. With the application of sequential Monte Carlo method, the paper further evaluates distribution network reliability in various charging scenarios. In the evaluation, indices including per unit value (PUV), fast voltage stability index (FVSI), loss of load probability (LOLP), system average interruption frequency index (SAIFI), system average interruption duration index (SAIDI), and expected energy not supplied (EENS) are incorporated. To validate the proposed prediction model and evaluation method, a series of numerical simulations are conducted on the basis of taking the traffic-distribution system of a typical city as an example. The result demonstrates that the proposed spatial-temporal transfer model is more practical in charging load prediction than the popularly used Dijkstra’s shortest path algorithm. Moreover, high temperature, congestion and the increment of EV penetration rate will further weaken distribution network reliability.
Highlights
With a new round of scientific and technological revolution and industrial transformation, the electric vehicles (EVs) industry is entering a new stage of accelerated development
per unit value (PUV) AND fast voltage stability index (FVSI) To further evaluate the effect of charging load on the voltage stability of distribution network, indices including PUV and FVSI have been applied and Figure 13 displays their specific values at each DNN in different charging scenarios
In this paper, the spatial-temporal distribution prediction model of EV charging demand and reliability evaluation method for distribution network penetrated with EVs have been presented and analyzed
Summary
With a new round of scientific and technological revolution and industrial transformation, the EV industry is entering a new stage of accelerated development. VOLUME 8, 2020 model with EV spatial-temporal distribution has been proposed on the basis of cell agent theory and Dijkstra method It aimed to plan EV trip path and predict EV charging load. With the application of quasi-dynamic simulation method, Zhang et al [28] have studied the influence of EVs penetration and their battery capacities on the reliability of distribution network These works have failed to quantitively analyze the impact of EVs charging load on the distribution network reliability resulting from high temperature and congestion. Since the travel path of EVs can directly affect the spatial-temporal distribution of charging load, MDP is employed to simulate the travel path of EVs. Subsequently, standard MDP model can be described by a TABLE 2. Both transition randomness and optimal path (i.e. the least time consuming path) have been taken into consideration in path simulation, which is more realistic
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