• Title/Summary/Keyword: regenerative energy

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Development of Regenerative Energy Storage System for An Electric Vehicle Using Super-Capacitors (슈퍼커패시터를 이용한 전기차량용 회생제동 에너지 저장장치 개발)

  • Chung, Dae-Won
    • The Transactions of The Korean Institute of Electrical Engineers
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    • v.60 no.3
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    • pp.544-551
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    • 2011
  • This paper presents the circuit arrangement and effective control method of regenerative energy storage system for an electric vehicle using super-capacitors as the braking energy storage element. A bi-directional controlled current flow of the DC-DC converters with the capacitor bank is connected in parallel with battery, and is controlled so that the whole of the braking energy is effectively absorbed into the capacitors and released back to the electric motor upon acceleration. The converter needs the series-parallel switching circuit for making the best use of the series capacitors and for limiting the step-up ratio of the boost converter. The proposed methods are verified by computer simulation and experimental set-up. They are usefully applied to the electric vehicles such as green cars, electric motorcycles, bike, etc which are power- supplied by the electric batteries.

Are Flywheels Right for Rail?

  • Read, M.G.;Smith, R.A.;Pullen, K.R.
    • International Journal of Railway
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    • v.2 no.4
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    • pp.139-146
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    • 2009
  • Vehicle braking in non-electrified rail systems wastes energy. Advanced flywheel technology presents a way to capture and reuse this braking energy to improve vehicle efficiency and so reduce the operating costs and environmental impact of diesel trains. This paper highlights the suitability of flywheels for rail vehicle applications, and proposes a novel mechanical transmission system to apply regenerative braking using a flywheel energy storage device. A computational model is used to illustrate the operation and potential benefits of the energy storage system.

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Development of Regenerative Braking Control Algorithm for In-wheel Motor Type Fuel Cell Electric Vehicles Considering Vehicle Stability (차량 안정성을 고려한 인휠모터 방식 연료전지 전기자동차용 회생제동 알고리즘 개발)

  • Yang, D.H.;Park, J.H.;Hwang, S.H.
    • Transactions of The Korea Fluid Power Systems Society
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    • v.7 no.2
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    • pp.7-12
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    • 2010
  • In these days, the researches about hybrid and fuel cell electric vehicles are actively performed due to the environmental contamination and resource exhaust. Specially, the technology of regenerative braking, converting heat energy to electric energy, is one of the most effective technologies to improve fuel economy. This paper developed a regenerative braking control algorithm that is considered vehicle stability. The vehicle has a inline motor at front drive shaft and has a EHB(Electo-hydraulic Brake) system. The control logic and regenerative braking control algorithm are analyzed by MATLAB/Simulink. The vehicle model is carried out by CarSim and the driving simulation is performed by using co-simulation of CarSim and MATLAB/Simulink. From the simulation results, a regenerative braking control algorithm is verified to improve the vehicle stability as well as fuel economy.

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Maximum Power Recovery of Regenerative Braking in Electric Vehicles Based on Switched Reluctance Drive

  • Namazi, Mohammad Masoud;Saghaiannejad, Seyed Morteza;Rashidi, Amir;Ahn, Jin-Woo
    • Journal of Electrical Engineering and Technology
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    • v.13 no.2
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    • pp.800-811
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    • 2018
  • This paper presents a regenerative braking control scheme for Switched Reluctance Machine (SRM) drive in Electric Vehicles (EVs). The main purpose is to maximize the recovered energy during battery charging by taking into account the nonlinear physical characteristics of the Switched Reluctance Machine. The proposed regenerative braking method employs the back-EMF in the generation process as a complicated position-dependent voltage source. The proposed maximum power recovery (MPR) operation of the regenerative braking is first based on the maximization of the extracted power from the machine and then the maximization of the power transferred to the battery. The maximum power extraction (MPE) from SRM is based on maximizing the energy conversion ratio by the calculation of the optimum PWM switching duty cycle, turn-on, and turn-off angles. By using the impedance matching theorem that allows the maximum power transfer (MPT) of the MPE, the proposed MPR is achieved. The parametric averaged value modeling of the machine phase currents in the chopping control mode is used for MPR realization. By following this model, a nonlinear equivalent input resistance is derived for the battery internal resistance matching. The effectiveness of the proposed regenerative braking method is demonstrated through simulation results and experimental implementation.

Dynamic Analysis on the Tail Gate System for Vehicle with the Energy Regenerative Brake of Hydraulic Driven Systems (유압 구동계 에너지 재생 브레이크를 적용한 자동차 테일게이트 개폐장치에 대한 동특성 해석)

  • Choi, Soon-Woo;Huh, Jun-Young
    • Transactions of The Korea Fluid Power Systems Society
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    • v.7 no.2
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    • pp.19-26
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    • 2010
  • The typical trunk lid system for vehicle is composed of a hinge having 4-bar link and gas lifter. Here, the energy regenerative brake of hydraulic driven systems is applied to the tail gate system for vehicle and removed the gas lifter. The new tail gate system is composed of a hydraulic pump by electric motor, a hydraulic motor, four check valves, an accumulator, a relief valve and a directional control valve. The dynamic characteristics of the hydraulic motor system, such as the surge pressure and response time, are investigated in both brake action and acceleration action. The capacity selection method of accumulator by mathematical model is based upon trial and error approach and computer simulation by AMEsim software is carried out.

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A Study on the Design of the Flywheel Energy Storage Device to Store the Regenerative Energy (회생에너지 저장용 플라이휠 에너지 저장 장치 설계에 관한 연구)

  • Lee, Jun-Ho;Park, Chan-Bae;Lee, Byeong-Song
    • The Transactions of The Korean Institute of Electrical Engineers
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    • v.62 no.7
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    • pp.1045-1052
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    • 2013
  • In this study we deal with design procedures for the flywheel energy storage system that has the capacity to store the regenerative energy produced from the railway vehicles. The flywheel energy storage system (FESS) stores the regenerative electrical energy into the high speed rotational flywheel, by conversion the electrical energy into the mechanical rotational energy. Thus the FESS is composed of the energy conversion components, such as the motor and generator, mechanical support components, such as the rotational rotor, the magnetic bearings to support the rotor, and the digital controller to control the air gap between the rotor and the magnetic bearings. In this paper the design procedures for the rotor operating at the rigid mode and the magnetic bearings to support the rotational rotor without contact are presented.

Effects of Individual Components on the System Performance in a Desiccant Cooling System (제습냉방시스템에서 요소성능이 시스템성능에 미치는 영향)

  • Chang, Young-Soo;Lee, Dae-Young
    • Korean Journal of Air-Conditioning and Refrigeration Engineering
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    • v.19 no.10
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    • pp.687-694
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    • 2007
  • Cycle simulation is peformed for two types of the desiccant cooling system incorporating a regenerative evaporative cooler. The cooling capacity and COP are evaluated at various effectiveness values of the regenerative evaporative cooler, the desiccant rotor and the sensible heat exchanger. As either of the effectiveness of the regenerative evaporative cooler or the humidity effectiveness of the desiccant rotor increases, both the cooling capacity and COP increase, but the enthalpy leak ratio gives the opposite effect on the system performance. It is found that COP of cycle A mainly depends on the humidity effectiveness of the desiccant rotor, while for cycle B enthalpy leak ratio of desiccant rotor has the major impact on COP. The effect of the sensible heat exchanger on the cooling capacity is small about 1/10 compared with those of other components.

Multi-Level Inverter for Regenerative Breaking of SRM (SRM의 회생제동을 위한 멀티레벨 인버터)

  • Lee S. H.;Ahn G. S.;Park S. J.;Ahn J. W,
    • Proceedings of the KIPE Conference
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    • 2001.07a
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    • pp.239-242
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    • 2001
  • Energy recovery in the regenerative region is very important when SRM(Switched Reluctance Motor) is used in traction drive. This is because that to reduce energy toss during mechanical breaking and/or to have a high efficiency drive during breaking. To control excitation voltage in motor operation and regenerative voltage in the generator operation in the SRM, multi-level voltage control is effective. This paper proposes multi-level inverter which is useful for motoring and regenerative operation in SRM. The proposed method is verified by experiment.

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Full Electric Vehicle Power System simulation with regenerative braking (회생 제동을 사용하는 전기자동차 시스템 구성 설계)

  • Jin, Young-Goun;Kim, Eou-Jung
    • Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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    • 2010.05a
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    • pp.365-368
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    • 2010
  • Full Electric Vehicle needs regenerative braking system by it's limitation of energy storage capacity. In this study, we suggest the system trade-off strategy between regenerative braking system with ultra capacitor and vichile enegry efficency. Simulation with the UDDS scheduling show the relations of energy storage sizing, efficiency of regenerative braking system and ultra capacitor sizing.

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Design and Control of DC/AC Converters in Parallel with Diode Rectifiers for Regenerative Applications

  • Gao, Zhigang;Li, Rui;Lu, Qi
    • Journal of Power Electronics
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    • v.17 no.4
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    • pp.1071-1087
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    • 2017
  • This paper introduces a DC/AC converter, which can be connected in parallel with a diode rectifier for regenerative applications. The DC/AC converter is supposed to transmit regenerative energy to the power grid when a motor is braking. Isolation transformers are not needed in the topology, which can reduce the size and cost. An analysis of the zero-order current existing in the system is carried out. In addition, algorithms to minimize the zero-order current, control the power factor and keep the DC bus voltage stable are discussed. A 55kW industrial prototype is built to verify the proposed analysis and control strategies.