• Title/Summary/Keyword: Hydrogen Tank in Vehicles

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Prediction of Changes in Filling Time and Temperature of Hydrogen Tank According to SOC of Hydrogen (수소 잔존 용량에 따른 수소 탱크 충전 시간 및 온도 변화 예측)

  • LEE, HYUNWOO;OH, DONGHYUN;SEO, YOUNGJIN
    • Journal of Hydrogen and New Energy
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    • v.31 no.4
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    • pp.345-350
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    • 2020
  • Hydrogen is an green energy without pollution. Recently, fuel cell electric vehicle has been commercialized, and many studies have been conducted on hydrogen tanks for vehicles. The hydrogen tank for vehicles can be charged up to 70 MPa pressure. In this study, the change in filling time, pressure, and temperature for each hydrogen level in a 59 L hydrogen tank was predicted by numerical analysis. The injected hydrogen has the properties of real gas, the temperature is -40℃, and the mass flow rate is injected into the tank at 35 g/s. The initial tank internal temperature is 25℃. Realizable k-epsilon turbulence model was used for numerical analysis. As a result of numerical analysis, it was predicted that the temperature, charging time, and the mass of injected hydrogen increased as the residual capacity of hydrogen is smaller.

Thermal analysis of a LH2 storage for vehicles (자동차용 액체수소 저장 용기의 열해석)

  • Oh, Byeong Soo;Jung, Jin Sam
    • Journal of Hydrogen and New Energy
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    • v.10 no.3
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    • pp.151-157
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    • 1999
  • The development of hydrogen vehicles has been actively progressed in the developed countries such as U. S., Japan and Germany. The most important technology of using hydrogen fuel is to develope a compatible storage tank with respect to the fossil fuel tank. Among many storage methods, the liquid hydrogen is the most desirable state because of the lowest volume and weight. The metal hydride tank is too heavy and the compressed hydrogen tank is too bulky. Because of these reasons, it is the principal purpose to analyze the theoretical heat transfer for designing and manufacturing an actual $LH_2$ tank. The insulation methods of the room between inner and outer vessel are non-vacuum, vacuum, vacuum with MLI(Multi-Layer Insulation). According to the results of the numerically calculated heat leak through the walls of the $LH_2$ tank, the vacuum insulated tank has 20 times and the MLI tank has 5616 times less heat leak than the non-vacuum tank.

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An Experimental Study on the Explosion of Hydrogen Tank for Fuel-Cell Electric Vehicle in Semi-Closed Space (반밀폐공간에서 발생되는 차량용 수소연료탱크 폭발 실험)

  • Park, Jinouk;Yoo, Yongho;Kim, Hwiseong
    • Journal of Auto-vehicle Safety Association
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    • v.13 no.4
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    • pp.73-80
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    • 2021
  • Recently, Korea has established a plan for the supply of hydrogen vehicles and is promoting the expansion of the supply. Risk factors for hydrogen vehicles are hydrogen leakage, jet fire, and explosion. Therefore Safety measures are necessary for this hazard. In addition, risks in semi-closed spaces such as tunnels, underground roads, and underground parking lots should be analyzed. In this study, an explosion experiment was conducted on a hydrogen tank used in a hydrogen vehicle to analyze the risk of a hydrogen vehicle explosion accident that may occur in a semi-closed space. As results, the effect on the structure and the human body was analyzed using the overpressure and impulse values for each distance generated during the explosion.

Analysis of Back-to-back Refueling for Heavy Duty Hydrogen Fuel Cell Vehicles Using Hydrogen Refueling Stations Based on Cascade System (캐스케이드 시스템 기반 수소 충전소를 이용한 대형 수소 연료 전지 차량 연속 충전 분석)

  • GYU SEOK SHIM;BYUNG HEUNG PARK
    • Journal of Hydrogen and New Energy
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    • v.35 no.3
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    • pp.300-309
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    • 2024
  • Hydrogen utilization in the transportation sector, which relies on fossil fuels, can significantly reduce greenhouse gas by using to hydrogen fuel cell vehicles, and its adoption depends performance of hydrogen refueling station. The present study developed a model to simulate the back-to-back filling process of heavy duty hydrogen fuel cell vehicles at hydrogen refueling stations using a cascade method. And its quantitatively evaluated hydrogen refueling station performance by simulating various mass flow rates and storage tank capacity combinations, analyzing vehicle state of charge (SOC) of vehicles. In the cascade refueling system, the capacity of the high-pressure storage tank was found to have the greatest impact on the reduction of filling time and improvement of efficiency.

Simulation of Temperature Behavior in Hydrogen Tank During Refueling Using Cubic Equations of State (3차 상태방정식을 이용한 수소 충전 온도 거동 모사)

  • PARK, BYUNG HEUNG
    • Journal of Hydrogen and New Energy
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    • v.30 no.5
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    • pp.385-394
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    • 2019
  • The analysis of temperature behavior of a hydrogen tank during refueling is of significance to clarify the safety of the compressed hydrogen storage in vehicles since the temperature at a tank rises with inflow of hydrogen. A mass balance and an energy balance were combined to obtain analytical model for temperature change during the hydrogen refueling. The equation was coupled to Peng-Robinson-Gasem (PRG) equation of state (EOS) for hydrogen. The PRG EOS was adopted after comparison with other four different cubic EOSs. A parameter of the model was determined to fit data from experiments of various inlet flow rates and temperatures. The temperature and pressure change with refueling time were obtained by the developed model. The calculation results revealed that the extent of precooling was more effective than the flow rate control.

The Evaluation of Fire Reliability for the High Pressure Hydrogen Storage System of Fuel Cell Vehicle (I) (연료전지자동차의 고압수소저장시스템 국부화재 신뢰성 평가 (I))

  • Kim, Sang-Hyun;Choi, Young-Min;Hang, Ki-Ho;Shim, Ji-Hyun;Hang, In-Cheol;Lim, Tae-Won
    • Journal of Hydrogen and New Energy
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    • v.22 no.4
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    • pp.520-526
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    • 2011
  • In recent years, it is very important that hydrogen storage system is safe for user in any circumstances in case of crash and fire. Because the hydrogen vehicle usually carry high pressurized cylinders, it is necessary to do safety design for fire. The Global Technical Regulation (GTR) has been enacted for localized and engulfing fire test. High pressure hydrogen storage system of fuel cell electrical vehicles are equipped with Thermal Pressure Relief Device (TPRD) installed in pressured tank cylinder to prevent the explosion of the tank during a fire. TPRDs are safety devices that perceive a fire and release gas in the pressure tank cylinder before it is exploded. In this paper, we observed the localized and engulfing behavior of tank safety, regarding the difference of size and types of the tanks in accordance with GTR.

A Study on the Modeling of Fueling Hydrogen Tank in Vehicle Using Dispenser (디스펜서를 이용한 차량용 연료 탱크 수소 충전 모델링에 관한 연구)

  • Choi, Ji Ah;Ji, Sang Won;Jang, Ji Seong
    • Journal of Drive and Control
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    • v.19 no.2
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    • pp.36-44
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    • 2022
  • Hydrogen energy as an alternative source of energy has been receiving tremendous support around the world, and research is being actively conducted accordingly. However, most of the studies focus on hydrogen storage tanks and only are few studies on interpreting the hydrogen filling system itself. In this study, with reference to SAE J2601, a hydrogen fueling protocol, a simulation model was developed that can confirm the behavior of the vehicle's internal tank during hydrogen fueling. With respect to factors such as fuel supply temperature, ambient temperature, and pressure increase rate, the developed model can check the change of temperature and pressure in the tank and the state of hydrogen charging during hydrogen fueling. The validity of the developed simulation model was confirmed by comparing the simulation results with the experimental results presented in SAE J2601.

Parametric Study of Shape Design for Strength Performance Enhancement of Bellows in Hydrogen Compressor-embedded Refueling Tank (수소 압축기 내장형 충전 탱크의 벨로우즈 강도 성능 향상을 위한 형상 설계 파라미터 연구)

  • Ji-Hyoung Kim;Chang-Yong Song
    • Journal of the Korean Society of Industry Convergence
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    • v.27 no.1
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    • pp.39-46
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    • 2024
  • As the development of hydrogen vehicles has accelerated in recent years, it is necessary to develop a storage tank for hydrogen fueling stations capable of high-pressure charging, and for this purpose, a new system with a compressor-embedded refueling tank is required. In this study, the parametric study of shape design based on strength performance evaluation was carried out to find the optimal shape design of bellows, the core component of compressor-embedded refueling tank for a newly developed hydrogen refueling station capable of high-pressure charging above 1,000 bar. The design factors for parametric study were contour shape and radius of bellows, and the performance factors were the maximum stress and the gap distance in the contact direction. In the shape design of the compressor bellows for hydrogen refueling station considered in this study, it was found that adjusting the contour radius is an appropriate design method to improve the compression performance and structural safety.

Experimental and Numerical Study on the Hydrogen Refueling Process (고압 수소 충전 시스템에 대한 실험 및 수치해석)

  • Lee, Taeck-Hong;Kim, Myoung-Jin;Park, Jong-Kee
    • Journal of Hydrogen and New Energy
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    • v.18 no.3
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    • pp.342-347
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    • 2007
  • The research on production and application of hydrogen as an alternative energy in the future is being carried out actively. It hydrogen storage is necessary in order that user use hydrogen economically without much difficulty. Among the ways of hydrogen storage the method which is compressed hydrogen gas by high pressure is easier for application than other methods. In this study, we have been calculated gas with changing pressure and temperature variation of container wall through applied to mass and energy balance equation when compressing hydrogen by high pressure, and also to Beattie-Bridgeman equation of state for the kinetic of hydrogen. We will apply above date as a preliminary for design of hydrogen storage tank.

Development of Fuel Economy Measurement Technology for Fuel Cell Electric Vehicle (수소연료전지차 연비 평가기술 개발)

  • Jung, Young-Woo;Park, Jeong-Kyu;Ye, Chang-Hwan;Park, Jong-Jin;Oh, Hyung-Seuk
    • 한국신재생에너지학회:학술대회논문집
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    • 2007.11a
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    • pp.152-155
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    • 2007
  • Fuel cell electric vehicles (FCEVs) using hydrogen gas are zero emission vehicles, thus emission measurement for combustion vehicles is not applicable. The hydrogen gas consumption for fuel economy will be measured by the stabilized pressure/temperature method, mass flow method and electrical current method, etc. In this research, weight method with a newly manufactured test equipment is applied to measure the hydrogen consumption because above 3-methods have a deviation. The hydrogen consumption is directly calculated by the weight differences of the external hydrogen tank before and after the chassis dynamometer test. Ultimately the fuel economy for FCEVs is obtained with a deviation less than 1% in all chassis dynamometer tests.

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