Scheduling Electric Buses in Public Transport: Modeling of the Charging Process and Analysis of Assumptions

IF 2.1 4区管理学 Q3 OPERATIONS RESEARCH & MANAGEMENT SCIENCE

Naval Research Logistics Pub Date : 2020-01-01 DOI:10.23773/2020_4

Nils Olsen, N. Kliewer

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引用次数: 14

Abstract

The Electric Vehicle Scheduling Problem (E-VSP) complicates traditional bus scheduling for public transport by restricting the range of the buses. To compensate for these limitations, detours to charging stations become necessary in order to charge the vehicle batteries. Charging is a nonlinear process with regard to real conditions, especially when taking partial and opportunity charging into account. However, within most existing solution methods for the E-VSP, the work of charging a vehicle battery is substantially simplified. In most cases, charging is assumed to be performed within linear or even constant time windows. In this paper, we analyze the impact of simplifying assumptions about charging times of electric buses on solutions of the E-VSP. Therefore, we propose charging models reflecting the nonlinear charging process precisely. Furthermore, we enhance an existing solution method for the E-VSP and provide an algorithm for incorporating partial and opportunity charging. Through a comprehensive computational study using real-world bus timetables, we identify major discrepancies between model assumptions and real charging behaviours of electric buses. On the one hand, we show that the assumption of constant charging times generally leads to overestimated time windows for charging, which increases the total costs. On the other hand, we demonstrate that assuming linear charging times underestimates the time windows actually required for charging, widely leading to infeasible vehicle rotations. We investigate this issue by using the technical data of lithium-ion batteries, which are mainly used in practice at present.

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公共交通电动公交车调度:充电过程建模与假设分析

电动汽车调度问题(E-VSP)通过限制公交车的行驶距离，使传统的公交调度复杂化。为了弥补这些限制，必须绕道充电站才能给汽车电池充电。在实际条件下，充电是一个非线性过程，特别是考虑部分充电和机会充电时。然而，在大多数现有的E-VSP解决方案中，汽车电池的充电工作大大简化了。在大多数情况下，假定充电是在线性或甚至恒定的时间窗口内进行的。本文分析了简化电动公交车充电时间假设对电动公交车充电时间问题求解的影响。因此，我们提出了能准确反映非线性充电过程的充电模型。此外，我们改进了现有的E-VSP求解方法，并提供了一种结合部分充电和机会充电的算法。通过对真实世界公交车时间表的综合计算研究，我们确定了模型假设与电动公交车实际充电行为之间的主要差异。一方面，我们证明了充电时间不变的假设通常会导致充电时间窗口的高估，从而增加了总成本。另一方面，我们证明，假设线性充电时间低估了充电实际所需的时间窗口，广泛导致不可行的车辆旋转。我们利用目前在实践中主要使用的锂离子电池的技术数据来研究这一问题。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Naval Research Logistics 管理科学-运筹学与管理科学

CiteScore

4.20

自引率

4.30%

发文量

审稿时长

8 months

期刊介绍： Submissions that are most appropriate for NRL are papers addressing modeling and analysis of problems motivated by real-world applications; major methodological advances in operations research and applied statistics; and expository or survey pieces of lasting value. Areas represented include (but are not limited to) probability, statistics, simulation, optimization, game theory, quality, scheduling, reliability, maintenance, supply chain, decision analysis, and combat models. Special issues devoted to a single topic are published occasionally, and proposals for special issues are welcomed by the Editorial Board.