An Adaptive Charging Control Strategy for Electric Vehicles Based on Wi-Fi Technology

The uncertainty of driving area, the power load control of charging facility and charging rates make electric vehicles(EVs) facing different charging facilities, so it is necessary to control charging in the charging process. An adaptive electric vehicle charging control strategy was proposed in this paper. The strategy uses wifi for communication, communicating with charging pile through wifi, charging facilities and electric vehicles can exchange parameters to achieve adaptive control of the charging process. And experiment was conducted for verification.

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The Application of PLC in the Electric Vehicle AC Charging Technology

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.860-863.1159 ◽

2013 ◽

Vol 860-863 ◽

pp. 1159-1163

Author(s):

Shi Ming Xu ◽

Heng Lu ◽

Shuo Liu ◽

Feng Wu

Keyword(s):

Adaptive Control ◽

Electric Vehicle ◽

Power Grid ◽

National Standards ◽

Load Control ◽

Charging Infrastructure ◽

Electric Vehicle Charging ◽

Communication Modes ◽

Vehicle Charging ◽

Over Time

Electric vehicle charging, since the uncertainty of the travel area, and the different load control of the charging infrastructure grid and the different rates over time, needs to face different charging devices and use different charging parameters. The situation is very complex, so electric vehicle needs to be adaptive control for various situations in the charging process. Aiming at the communication between electric vehicle and power grid, there is no relevant national standards promulgated. After comparing several possible communication modes, I choose to use the PLC communication, and SDP for charging device to automatically obtain and connections. Charging parameter passing through the communication between the electric vehicle and charging facilities, in order to realize the adaptive control of electric vehicle charging.

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Voltage-Based Droop Control of Electric Vehicles in Distribution Grids under Different Charging Power Levels

Energies ◽

10.3390/en14133905 ◽

2021 ◽

Vol 14 (13) ◽

pp. 3905

Author(s):

Muhandiram Arachchige Subodha Tharangi Ireshika ◽

Ruben Lliuyacc-Blas ◽

Peter Kepplinger

Keyword(s):

Electric Vehicle ◽

Electric Vehicles ◽

Control Mechanism ◽

Droop Control ◽

Distribution Grid ◽

Electric Vehicle Charging ◽

Charging Control ◽

Vehicle Charging ◽

The Impact ◽

Distribution Grids

If left uncontrolled, electric vehicle charging poses severe challenges to distribution grid operation. Resulting issues are expected to be mitigated by charging control. In particular, voltage-based charging control, by relying only on the local measurements of voltage at the point of connection, provides an autonomous communication-free solution. The controller, attached to the charging equipment, compares the measured voltage to a reference voltage and adapts the charging power using a droop control characteristic. We present a systematic study of the voltage-based droop control method for electric vehicles to establish the usability of the method for all the currently available residential electric vehicle charging possibilities considering a wide range of electric vehicle penetrations. Voltage limits are evaluated according to the international standard EN50160, using long-term load flow simulations based on a real distribution grid topology and real load profiles. The results achieved show that the voltage-based droop controller is able to mitigate the under voltage problems completely in distribution grids in cases either deploying low charging power levels or exhibiting low penetration rates. For high charging rates and high penetrations, the control mechanism improves the overall voltage profile, but it does not remedy the under voltage problems completely. The evaluation also shows the controller’s ability to reduce the peak power at the transformer and indicates the impact it has on users due to the reduction in the average charging rates. The outcomes of the paper provide the distribution grid operators an insight on the voltage-based droop control mechanism for the future grid planning and investments.

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Optimized Strategic Planning of Future Norwegian Low-Voltage Networks with a Genetic Algorithm Applying Empirical Electric Vehicle Charging Data

Electricity ◽

10.3390/electricity2010006 ◽

2021 ◽

Vol 2 (1) ◽

pp. 91-109

Author(s):

Julian Wruk ◽

Kevin Cibis ◽

Matthias Resch ◽

Hanne Sæle ◽

Markus Zdrallek

Keyword(s):

Genetic Algorithm ◽

Electric Vehicle ◽

Electric Vehicles ◽

Low Voltage ◽

Network Planning ◽

Voltage Regulation ◽

Electric Vehicle Charging ◽

Vehicle Charging ◽

The Impact

This article outlines methods to facilitate the assessment of the impact of electric vehicle charging on distribution networks at planning stage and applies them to a case study. As network planning is becoming a more complex task, an approach to automated network planning that yields the optimal reinforcement strategy is outlined. Different reinforcement measures are weighted against each other in terms of technical feasibility and costs by applying a genetic algorithm. Traditional reinforcements as well as novel solutions including voltage regulation are considered. To account for electric vehicle charging, a method to determine the uptake in equivalent load is presented. For this, measured data of households and statistical data of electric vehicles are combined in a stochastic analysis to determine the simultaneity factors of household load including electric vehicle charging. The developed methods are applied to an exemplary case study with Norwegian low-voltage networks. Different penetration rates of electric vehicles on a development path until 2040 are considered.

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Energy Management System Optimization of Drug Store Electric Vehicles Charging Station Operation

Sustainability ◽

10.3390/su13116163 ◽

2021 ◽

Vol 13 (11) ◽

pp. 6163

Author(s):

Yongyi Huang ◽

Atsushi Yona ◽

Hiroshi Takahashi ◽

Ashraf Mohamed Hemeida ◽

Paras Mandal ◽

...

Keyword(s):

Power Generation ◽

Electric Vehicle ◽

Electric Vehicles ◽

System Optimization ◽

Mixed Integer ◽

Charging Station ◽

Electric Vehicle Charging ◽

Photovoltaic Power ◽

Vehicle Charging ◽

Charging Stations

Electric vehicle charging station have become an urgent need in many communities around the world, due to the increase of using electric vehicles over conventional vehicles. In addition, establishment of charging stations, and the grid impact of household photovoltaic power generation would reduce the feed-in tariff. These two factors are considered to propose setting up charging stations at convenience stores, which would enable the electric energy to be shared between locations. Charging stations could collect excess photovoltaic energy from homes and market it to electric vehicles. This article examines vehicle travel time, basic household energy demand, and the electricity consumption status of Okinawa city as a whole to model the operation of an electric vehicle charging station for a year. The entire program is optimized using MATLAB mixed integer linear programming (MILP) toolbox. The findings demonstrate that a profit could be achieved under the principle of ensuring the charging station’s stable service. Household photovoltaic power generation and electric vehicles are highly dependent on energy sharing between regions. The convenience store charging station service strategy suggested gives a solution to the future issues.

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An Optimal Control Algorithm with Reduced DC-Bus Current Fluctuation for Multiple Charging Modes of Electric Vehicle Charging Station

World Electric Vehicle Journal ◽

10.3390/wevj12030107 ◽

2021 ◽

Vol 12 (3) ◽

pp. 107

Author(s):

Tao Chen ◽

Peng Fu ◽

Xiaojiao Chen ◽

Sheng Dou ◽

Liansheng Huang ◽

...

Keyword(s):

Electric Vehicle ◽

Electric Vehicles ◽

Control Algorithm ◽

Current Fluctuation ◽

Charging Station ◽

Electric Vehicle Charging ◽

Three Phase ◽

Optimization Control ◽

Dc Bus ◽

Vehicle Charging

This paper presents a systematic structure and a control strategy for the electric vehicle charging station. The system uses a three-phase three-level neutral point clamped (NPC) rectifier to drive multiple three-phase three-level NPC converters to provide electric energy for electric vehicles. This topology can realize the single-phase AC mode, three-phase AC mode, and DC mode by adding some switches to meet different charging requirements. In the case of multiple electric vehicles charging simultaneously, a system optimization control algorithm is adopted to minimize DC-bus current fluctuation by analyzing and reconstructing the DC-bus current in various charging modes. This algorithm uses the genetic algorithm (ga) as the core of computing and reduces the number of change parameter variables within a limited range. The DC-bus current fluctuation is still minimal. The charging station system structure and the proposed system-level optimization control algorithm can improve the DC-side current stability through model calculation and simulation verification.

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