A Charging-as-a-Service Platform for Charging Electric Vehicles On the Move: New Vehicle Routing Model and Solution (2104.00730v1)

Abstract: Range anxiety has been the main challenge for the mass-adoption of electric vehicles (EVs). The emerging mobile electric-vehicle-to-electric-vehicle (mE2) charging technology, which allows an EV with the extra battery to charge the other EV on the move, offers a promising solution. Even though the physical feasibility of this new technology has been confirmed, we still face many operation problems. For example, how can we efficiently pair and route an electricity provider (EP) to a demand (ED) without introducing an extra detour? Motivated by this view, this study develops a Charging-as-a-Service (CaaS) platform, which seeks to dispatches the commercial EPs to serve the EDs, for cultivating this emerging charging service towards the low EV penetration environment. Mathematically, the CaaS platform is modeled as a vehicle routing problem (i.e., mE2-VRP), which optimally dispatches the EPs to approach and serve the EDs on the move while minimizing the EP fleet size and fulfilling all service requests. To adapt the CaaS platform to the online application in practice, we develop the Clustering-aided Clarke and Wright Savings (CCWS) algorithm to efficiently decompose and then solve the large-scale mE2-VRP by parallel computing. Our numerical experiments built upon citywide (Chicago) and statewide (Florida) found that the CCWS algorithm outperforms existing commercial solvers, and it enables us to investigate the performance of the CaaS platform under a realistic large-scale setup in a city or state. The CaaS performs better in low EV penetration markets while traffic congestion is mild and EDs require energy earlier. We can improve the performance by developing proper pricing strategies according to the EDs' energy requests and trip lengths.