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Conclusions and future work
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- Acknowledgment This work is conducted under the collaborative framework OpenLab “PSA@Morocco - Sustainable mobility for Africa”. References
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4. Conclusions and future work
In this paper, we have introduced a charging strategy for multiple EVs charging demands using charging stations with several charging points. The objective is to remedy to the long waiting problem of EVs within charging stations. We have proposed a predictive algorithm based on predictive function principles. Basics and parameters of this function in the context of charging process are explained. According to these parameters, the prediction of the average charging time and charging rate using this trade-off approach is explained. The obtained results are compared using two use cases: full charging of EV batteries and using required energy according to the arrival of charging requests. A numerical example is worked out and the obtained results are reported and compared for these considered cases. As perspectives of this work, we further develop the proposed charging system and integrate the real time data. Furthermore, we will compare this approach with another one developed in our previous works using (max, +) algebra. We will evaluate the performances of both approaches in terms of the minimization of EVs waiting and maximization of their charging using VSIMRTI framework. Furthermore, accurate battery modelling is another on-going work [21] that will be adapted for successful prediction of SoC and the electric driving range as well. Acknowledgment This work is conducted under the collaborative framework OpenLab “PSA@Morocco - Sustainable mobility for Africa”. References [1] W. Ait-Cheik-Bihi, M. Bakhouya, J. Gaber, R. Outbib, E. Coatanea, X. Z. Gao, K. Zenger, “Towards an integrated service-oriented energy management platform for plugin hybrid electric vehicles“, 2012 IFAC Workshop on Multivehicle Systems, Espoo, Finland, 2012. [2] O.Sundstrӧm and C.Binding, “Planning electric-drive vehicle charging under constrained grid conditions,” in International Conference on Power System Technology, 2010. [3] Y. He, B. Venkatesh andss L. Guan, “Optimal scheduling for charging and discharging of electric vehicles,” vol. 3, no. IEEE transactions on smart grid, 2012. [4] J. Kang, S. J. Duncan and D. N. Mavris, “Real-time scheduling techniques for electric vehicle charging in support of frequency regulation,” Procedia Computer Science, no. Elsevier, pp. 767-775, 2013. [5] H. Qin and W. Zhang, “Charging scheduling with minimal waiting in a network of electric vehicles and charging stations,” in Proceedings of the Eighth ACM international workshop on Vehicular inter-networking, ACM, 2011, pp. 51-60. [6] A. Ruzmetov, A. Nait-Sidi-Moh, M. Bakhouya and J. Gaber, “Towards an optimal assignment and scheduling for charging electric vehicles,” IEEE, Morocco, 2013. [7] A. Ruzmetov, A. Nait-Sidi-Moh and J. Gaber, “A (max - plus)-based approach for charging management of electric vehicles,” in The 2nd World Conference on Complex Systems(WCCS14), Agadir, Morocco, 2014. [8] A. Lahlou1, F. Ossart, E. Boudard, F. Roy, M. Bakhouya, “A dynamic programming approach for thermal comfort control in electric vehicles“, in the 2018 Vehicle Power and Propulsion Conference (VPPC), Chicago, Illinois, USA, 2018. [9] B. Saeid, J. M. Scott, C. F. Joel and K. F. Hosam, “Plug-in hybrid electric vehicle charge pattern optimization for energy cost and battery A. Nait-Sidi-Moh et al. / Procedia Computer Science 141 (2018) 127–134 133 6 NaitSidiMoh et al./ Procedia Computer Science 00 (2018) 000–000 requests (𝑛𝑛 !" ), which are received at a given time. Furthermore, the found average charging rates (𝜆𝜆(𝑗𝑗)) and the average charging times (𝑡𝑡 ! ) based on accordingly the equations (2), and (3), (4), (5) will be main parameters to determine the charging rates and times of EVs set individually. The two considered scenarios: with and without considering required energy for EVs are used to show the differences between the proposed charging policies. The Gantt chart of Fig. 5 (a) shows the charging time and waiting time for each EV without considering the needed energy for charging requests. Without considering this energy, each EV is planned to be fully charged, consequently certain EVs have to wait for long time. Thus the accumulation of waiting times becomes more and more raised with the arrival of other charging requests. However, by considering the required energy of each demand and the inter-arrival of all charging requests, the predictive charging time varies from minimum charging time 𝐶𝐶𝐶𝐶 !"# , corresponding in our case to the minimum accepted charging rate 𝑃𝑃 !"# , to the arrival time of the next accepted charging request, which is limited by 𝐶𝐶𝐶𝐶 !"# . If the next charging demand arrives after 𝐶𝐶𝐶𝐶 !"# , the charging point is free and can be used at any time. In this case, the EVs will be charged with at least an accepted amount of energy and the accumulated waiting of EVs can be considerably reduced. The Gantt chart depicted in Fig. 5 (b) illustrates the results of this second case. Here, we consider that the needed battery energy varies between 20 and 80 %. We keep our first charging condition that charges each battery at least 50%, when the next EV charging demand arrives before the desired time and the battery can be charged for more than 50%. (a) (b) Fig. 5. Waiting time and charging time (a) without needed energy, (b) with considering needed energy Furthermore, Fig. 6 (a) presents the difference between desired charging rates (according to the needed energy of each EV) and proposed charging rates. The needed energy is considered in this case for showing the comparison between the two approaches. We can see the difference of the desired charging rate and the proposed charging rate. The proposed charging rate is less than the desired charging rate because it depends on the requested time interval. In Figure 6 (b), distinguishable differences of the waiting times for the two studied cases are presented. The large scale reducing of the waiting times is compared to the battery SoC and charging without this information. Battery energy information, such as the SoC and related charging technology (slow or fast charging) can be helpful for the companies of energy distribution and smart grids in order to schedule daily loading costs. When the decision of charging EVs with 100% of energy is not kept, the accumulation of EVs waiting times can be reduced till 49.8%. NaitSidiMoh et al./ Procedia Computer Science 00 (2018) 000–000 7 (a) (b) Fig. 6. (a) the difference between the desired and proposed charging rate, (b) the waiting time evolution Yüklə 1,11 Mb. Dostları ilə paylaş:
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