Establishment and Analysis of Energy Consumption Model of Heavy-Haul Train on Large Long Slope

Lu, Qijing; He, Bangbang; Wu, Mingzhe; Zhang, Zhichun; Luo, Jiantao; Zhang, Yankui; He, Runkai; Wang, Kunyu

doi:10.3390/en11040965

Cited by 21 publications

(21 citation statements)

References 23 publications

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“…In addition, with the development of the technology and the increased demand of batteries, the cost of the batteries will be gradually reduced, thereby greatly improving the application potential of the proposed system. Moreover, in some railways with large slopes, more regenerative braking energy will be generated [17]. In these railways, the economic benefits of the proposed system will be more obvious.…”

Section: Figure 20mentioning

confidence: 99%

“…However, the distribution power of a conventional railway station on the ground is considerably smaller than the regenerative power [16]. Therefore, the RBE would be surplus, flowing back to the public grid or being stored in an energy storage system.Optimizing operation timetable is a low-cost solution for reducing energy consumption of railways by increasing the coexistence time of the traction and braking trains in the same electric section without auxiliaries [1,17,18]. However, owing to unanticipated occurrences often emerging during the actual operation, such as the temporary addition or cancellation of trains, equipment failure, bad weather, and so on, the trains cannot consistently run according to the optimized operation timetable.…”

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confidence: 99%

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Energy-Storage-Based Smart Electrical Infrastructure and Regenerative Braking Energy Management in AC-Fed Railways with Neutral Zones

Gao

et al. 2019

Energies

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This paper presents a modified power supply system based on the current alternating current (AC)-fed railways with neutral zones that can further improve the eco-friendliness and smart level of railways. The modified system complements the existing infrastructure with additional energy-storage-based smart electrical infrastructure. This infrastructure comprises power electronic devices with energy storage system connected in parallel to both sides of each neutral zone in the traction substations, power electronic devices connected in parallel to both sides of each neutral zone in section posts, and an energy management system. The description and functions of such a modified system are outlined in this paper. The system allows for the centralized-and distributed-control of different functions via an energy management system. In addition, a control algorithm is proposed, based on the modified system for regenerative braking energy utilization. This would ensure that all the regenerative braking energy in the whole railway electrical system is used more efficiently. Finally, a modified power supply system with eight power supply sections is considered to be a case study; furthermore, the advantages of the proposed system and the effectiveness of the proposed control algorithm are verified.The installation of equipment that provide clean energy from renewable sources (e.g., solar panels and wind generators) to feed the traction loads in rail may have a significant impact in the energy costs and CO 2 emissions of a railway system, increasing the environment friendliness of the railway [4][5][6]. The introduction of renewable energy is to partially reduce the depletion of non-renewable energy resources and thus reduce CO 2 emissions. These outcomes have been favored by scholars and many countries, such as North American, European, China, and Japan [6,7]. But in practice, the traction energy consumption of railways has not been reduced.By contrast, the efficient driving and regenerative braking schemes differ the renewable energy scheme. They can essentially reduce the traction energy consumption of railways.Efficient driving is an effective way to reduce the traction energy consumption of rolling stock. Typically, the running state of vehicles comprises three phases: braking, speed-holding (cruising) and acceleration. At present, many literatures have studied the efficient driving and realize the traction energy savings through the optimum combination of these phases [8][9][10][11][12][13]. To implement such trajectories and maximize savings, some auxiliary systems, such as driver advisory systems (DAS) [10,11] and automatic train operation (ATO) [12,13], must be provided to drivers. The trials of such systems have shown savings of 5-18%. However, with efficient driving, the savings of energy consumption may sacrifice service quality, such as the train speed, stopping time, etc. [1].Regenerative braking energy (RBE) recovery is a simple and efficient way to reduce energy consumption, which cannot influence the operati...

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Section: Figure 20mentioning

confidence: 99%

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confidence: 99%

Energy-Storage-Based Smart Electrical Infrastructure and Regenerative Braking Energy Management in AC-Fed Railways with Neutral Zones

Gao

et al. 2019

Energies

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“…Therefore, if the RBE cannot be used by the traction trains in the same power supply sector, a large amount of RBE is fed back to the power system through the traction substation (TS). As a result, there is a great impact on the utility grid [6][7][8], which can not only lead to an increase in the catenary voltage but also affect the safe operation of the utility grid. At the same time, this situation can also increase the loss of the RBE in the transmission line and reduce the effective utilization rate.…”

Section: Introductionmentioning

confidence: 99%

“…To date, several solutions have been proposed by many scholars to adequately utilize the RBE of traction power supply systems. These are mainly categorized into three groups: energy storage, optimizing the train schedule and adding the power regulation devices [5][6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

“…If the RBE can be directly utilized by other traction trains, the system will be more efficient. Reference [7] presents that the coexistence time of the traction train and brake train in the same power supply arm can be prolonged by optimizing the train schedule without affecting the traffic volume and safety, the utilization rate of RBE is improved. The scheme does not need to add any electrical devices, and the cost is relatively low.…”

Section: Introductionmentioning

confidence: 99%

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An Optimized Regulation Scheme of Improving the Effective Utilization of the Regenerative Braking Energy of the Whole Railway Line

Gao

et al. 2019

Energies

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With respect to the problems of great impact on the utility grid, the increasing catenary voltage, the limited utilization rate of the regenerative braking energy (RBE) and the irreducible cost of electricity for locomotives caused by the RBE generated by electric locomotives of the whole railway line cannot be fully utilized in traction power supply systems. An energy management system (EMS) integrating electrical energy and information is proposed in this paper. A corresponding optimization algorithm is also proposed to calculate the distribution of the regenerative braking power in the whole railway line. The structure and working principle of the EMS are introduced. The basic principle and detailed steps of the proposed algorithm are given. Finally, the optimization calculation and simulation are carried out, the effectiveness and feasibility of the proposed EMS and the optimization algorithm are verified.

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Optimal guaranteed cost intermittent control to the efficient movement of freight trains

Ruan

Mashino

et al. 2022

ISA Transactions

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Establishment and Analysis of Energy Consumption Model of Heavy-Haul Train on Large Long Slope

Cited by 21 publications

References 23 publications

Energy-Storage-Based Smart Electrical Infrastructure and Regenerative Braking Energy Management in AC-Fed Railways with Neutral Zones

Energy-Storage-Based Smart Electrical Infrastructure and Regenerative Braking Energy Management in AC-Fed Railways with Neutral Zones

An Optimized Regulation Scheme of Improving the Effective Utilization of the Regenerative Braking Energy of the Whole Railway Line

Optimal guaranteed cost intermittent control to the efficient movement of freight trains

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