• 제목/요약/키워드: Battery Pack

검색결과 175건 처리시간 0.028초

바이모달트램에 탑재된 리튬폴리머배터리팩의 온도에 따른 운전특성분석 (Driving Characteristics Analysis with Temperatures of Lithium Polymer Battery Pack for Bimodal Tram)

  • 이강원;장세기
    • 한국전기전자재료학회:학술대회논문집
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    • 한국전기전자재료학회 2010년도 하계학술대회 논문집
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    • pp.292-292
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    • 2010
  • Bimodal Tram is driven by both engine and Lithium Polymer battery pack which consists with 168 cells of LPB(80Ah, 650Vdc). LPB pack is very frequently charged and discharged in driving. Temperature inside of LPB pack makes an great effect on both charging and discharging capacity which seem to be related with LPB internal resistance. LPB internal resistance is increasing or little decreasing with the decreased temperature under 10 - $20^{\circ}C$ and the increased temperature over $30^{\circ}C$ which is similar to the temperature characteristics of single LPB cell. This paper has analyzed the driving characteristics of LPB pack for bimodal tram is running with either battery mode or hybrid mode.

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바이모달트램용 LPB팩에 적용될 Battery Management System 개발 (Development of BMS applying to LPB Pack in Bimodal Tram)

  • 이강원;장세기;남종하;강덕하;배종민
    • 한국전기전자재료학회:학술대회논문집
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    • 한국전기전자재료학회 2009년도 하계학술대회 논문집
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    • pp.477-477
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    • 2009
  • Bimodal Tram developed by KRRI is driven by a series Hybrid propulsion system which has both the CNG engine, generator and LPB(Lithium Polymer Battery) pack. It has three driving modes; Hybrid mode, Engine mode and Battery mode. Even in case of Battery mode, LPB pack to get enough power to drive the vehicle only by itself onsists of 168 LPB cells(80Ah per lcell), 650V. It is important thing to manage LPB pack in a right way, which will extend the lifetime of LPB cells and operate in the hybrid mode effectively. This paper has shown the development of battery management system(12 BMS, 1 BMS per 14cells) to manage LPB pack which is connected with CAN(Controller Area Network) each other and measure the voltage, current, temperature and also control the cooling fan inside of LPB pack. Using the measured data, BMS can show the SOC(State of Charge), SOH(State of Health) and other status of LPB pack including of the cell balancing.

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배터리팩 시험기를 위한 2단 구성 AC-DC 컨버터의 Si와 SiC의 손실 및 온도 비교 분석 (Analysis and Comparison of Switching Losses and Temperature using Si and SiC devices applied in Two Stage AC-DC Converter for Battery Pack Testing System)

  • 성호재;최형준;홍석진;현승욱;원충연
    • 전력전자학회:학술대회논문집
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    • 전력전자학회 2016년도 전력전자학술대회 논문집
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    • pp.397-398
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    • 2016
  • This paper analyzes switching losses, efficiency and temperature depending on Si and SiC devices applied in two stage AC-DC converter. To evaluate the charge and discharge performance and stability of the battery pack, there is a need for a battery pack testing system. To do battery charge and discharge experiment used in battery pack test, A topology, two stage AC-DC converter, has been built. SiC devices more decrease switching losses than that of Si. Also, cooling system was applied in Si and SiC devices. When using SiC devices, it can be confirmed that the size of heat sink is reduced for small loss.

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직렬형 하이브리드 굴절차량용 대용량 LPB 팩의 적용 및 성능 평가 (Performance Evaluation for Application of Large Capacity LPB Pack Equipped to Series Hybrid Articulated Vehicle)

  • 이강원;목재균
    • 한국전기전자재료학회논문지
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    • 제25권11호
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    • pp.930-937
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    • 2012
  • Newly developed Series hybrid low-floor articulated vehicle which can meet both road and railway running conditions. It has the rated driving speed of 80 km/h and three driving modes with hybrid(engine+battery) driving mode, engine driving mode, battery driving mode. The battery driving mode requires the several 10 km running without additional charging operation. The vehicle has been equipped with LPB (lithium polymer battery) pack for the series hybrid propulsion system. LPB pack consists of 168 cells (3.7 V in a cell, 80 Ah) in series, DC Circuit breaker, mechanical rack, BMS (battery management system). This paper has shown the design process of LPB pack and application to the vehicle. Driving results in the road was successful to be satisfied with the requirement of the series hybrid vehicle.

저항 열화 기반의 배터리 팩 편차 파라미터 추출 방안 및 검출 알고리즘 (Detection Algorithm and Extract of Deviation Parameters for Battery Pack Based on Internal Resistance Aging)

  • 송정용;허창수
    • 한국전기전자재료학회논문지
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    • 제31권7호
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    • pp.515-520
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    • 2018
  • A large number of lithium-ion batteries are arranged in series and parallel in battery packs, such as those in electric vehicles or energy storage systems. As battery packs age, their output power and energy density drop because of voltage deviation, constant and non-uniform exposure to abnormal environments, and increased contact resistance between batteries; this reduces application system efficiency. Despite the balancing circuit and logic of the battery management system, the output of the battery pack is concentrated in the most severely aged unit cell and the output is frequently limited by power derating. In this study, we implemented a cell imbalance detection algorithm and selected parameters to detect a sudden decrease in battery pack output. In addition, we propose a method to increase efficiency by applying the measured testing values considering the operating conditions and abnormal conditions of the battery pack.

바이모달트램용 LPB Management System 개발 및 적용 (Development and Application of LPB Management System for Bimodal Tram)

  • 이강원;목재균
    • 전기학회논문지P
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    • 제64권4호
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    • pp.231-235
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    • 2015
  • Bimodal Tram developed by KRRI is driven by a series Hybrid propulsion system which has both the CNG engine, generator and LPB(Lithium Polymer Battery) pack. It has three driving modes; Hybrid mode, Engine mode and Battery mode. Even in case of Battery mode, LPB pack to get enough power to drive the vehicle only by itself onsists of 168 LPB cells(80Ah per lcell), 650V. It is important thing to manage LPB pack in a right way, which will extend the lifetime of LPB cells and operate in the hybrid mode effectively. This paper has shown the development of battery management system(12 BMS, 1 BMS per 14cells) to manage LPB pack which is connected with CAN(Controller Area Network) each other and measure the voltage, current, temperature and also control the cooling fan inside of LPB pack. Using the measured data, BMS can show the SOC(State of Charge), SOH(State of Health) and other status of LPB pack including of the cell balancing.

RSM 방법에 의한 리튬이온 배터리 팩의 최적 설계 (Study on Optimization of Li-ion Battery Pack Design by RSM)

  • 주강우;장경민;김광선
    • 반도체디스플레이기술학회지
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    • 제14권1호
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    • pp.39-43
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    • 2015
  • This paper is to derive information about the optimal shape of the pack has a minimum temperature range of a Li-ion battery equipped with a module. We selected the shape of the pack in order to reduce the temperature deviation between the batteries as a variable. And we derived the experimental points with a minimum of DOE by D-optimal. We analyzed the temperature and the flow within the battery pack by using a numerical analysis verified in previous studies. We derive the equation for the temperature variation in the objective function using the RSM and performed optimization. As a result, it was confirmed that with the variation in the $1.706e-4^{\circ}C$ when to apply an optimized shape.

배터리 팩 수치해석 해의 비교를 통한 병렬연산 효율성 연구 (A Study for Parallel Computing Efficiency Comparing Numerical Solutions of Battery Pack)

  • 김광선;장경민
    • 반도체디스플레이기술학회지
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    • 제15권2호
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    • pp.20-25
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    • 2016
  • The parallel computer cluster system has been known as the powerful tool to solve a complex physical phenomenon numerically. The numerical analysis of large size of Li-ion battery pack, which has a complex physical phenomenon, requires a large amount of computing time. In this study, the numerical analyses were conducted for comparing the computing efficiency between the single workstation and the parallel cluster system both with multicore CPUs'. The result shows that the parallel cluster system took the time 80 times faster than the single work station for the same battery pack model. The performance of cluster system was increased linearly with more CPU cores being increased.

Parameter Design and Power Flow Control of Energy Recovery Power Accumulator Battery Pack Testing System

  • Bo, Long;Chong, Kil To
    • Journal of Electrical Engineering and Technology
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    • 제8권4호
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    • pp.787-798
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    • 2013
  • This paper proposes a special power circuit topology and its corresponding control strategy for an energy recovery power accumulator battery pack testing system (PABPTS), which is particularly used in electric vehicles. Firstly, operation principle and related parameter design for the system are illustrated. Secondly, control strategy of the composite power converter for PABPTS is analyzed in detail. The improved scheme includes a high accuracy charge and discharge current closed loop. active power reference for the grid-side inverter is provided by the result of multiplication between battery pack terminal voltage and test current. Simulation and experimental results demonstrate that the proposed scheme could not only satisfy the requirements for PABPTS with wide-range current test, but also could recover the discharging energy to the power grid with high efficiency.

재사용 ESS를 위한 리튬 배터리 덴드라이트 보호 알고리즘 제안 (Proposal Protection Algorithm of Dendritic Lithium for Battery Second Use ESS)

  • 송정용;허창수
    • 한국전기전자재료학회논문지
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    • 제31권6호
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    • pp.422-426
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    • 2018
  • The lithium-ion battery pack of an electric vehicle (EV) deserves to be considered for an alternative use within smart-grid infrastructure. Despite the long automotive service life, EV batteries retain over 70~80% of their initial capacity. These battery packs must be managed for their reliability and safety. Therefore, a battery management system (BMS) should use specific algorithms to measure and estimate the status of the battery. Most importantly, the BMS of a grid-connected energy storage system (ESS) must ensure that the lithium-ion battery does not catch fire or explode due to an internal short from uncontrolled dendrite growth. In other words, the BMS of a lithium-ion battery pack should be capable of detecting the battery's status based on the electrochemical reaction continuously until the end of the battery's lifespan. In this paper, we propose a new protection algorithm for a dendritic lithium battery. The proposed algorithm has applied a parameter from battery pack aging results and has control power managing.