• Title/Summary/Keyword: High pressure hydrogen storage system

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The Evaluation of Reliability for the High pressure hydrogen Storage System of Fuel Cell Vehicle(II) (연료전지자동차의 고압수소저장시스템 신뢰성 평가(II))

  • Choi, Young-Min;Kim, Sang-Hyun;Kim, Hyung-Ki;Jang, Gyu-Jin;Ahn, Byung-Ki;Lim, Tae-Won
    • 한국신재생에너지학회:학술대회논문집
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    • 2008.05a
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    • pp.37-40
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    • 2008
  • We have concentrated on the performance improvement of each part for durability, safety and cost of high pressure storage system for fuel cell vehicle so far. But for the mass production of fuel cell vehicle, it is necessary to evaluate durability and safety in system module. We built the standard to evaluate and collision safety of high pressure storage system for fuel cell vehicle, and could verify reliability of high pressure storage system.

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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.

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

  • Jang, Gyu-Jin;Choi, Young-Min;Ahn, Byung-Ki;Lim, Tae-Won
    • Journal of Hydrogen and New Energy
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    • v.19 no.4
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    • pp.266-275
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    • 2008
  • The performance improvement of each part for durability, safety and cost of high pressure storage system for fuel cell vehicle has been focused so far. However, for the mass production of fuel cell vehicle, it is necessary to evaluate durability and safety in system module and vehicle level. The test procedure to evaluate vibration and collision safety of high pressure hydrogen storage system for the fuel cell vehicle is established and its reliability is verified.

The Evaluation of Reliability for the High pressure hydrogen Storage System of Fuel Cell Vehicle (연료전지자동차의 고압수소저장시스템 신뢰성 평가)

  • Jang, Gyu-Jin;Choi, Young-Min;Ahn, Byung-Ki;Lim, Tae-Won
    • 한국신재생에너지학회:학술대회논문집
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    • 2007.11a
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    • pp.71-74
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    • 2007
  • We have concentrated on the performance improvement of each part for durability, safety and cost of high pressure storage system for fuel cell vehicle so far. But for the mass production of fuel cell vehicle, it is necessary to evaluate durability and safety in system module. We built the standard to evaluate vibration and collision safety of high pressure storage system for fuel cell vehicle, and could verify reliability of high pressure storage system.

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A Study on the Mechanical Method of Observing Winding Behavior by Charging and Discharging of Type II High Pressure Hydrogen Storage Tank (Type II 고압수소저장용기의 충전과 방출에 의한 권선 거동 관찰의 기계적 방법에 관한 연구)

  • KIM, SEUNGHWAN;HAN, JINMOOK;LEE, SUNGHEE;JUNG, YOUNGGUAN
    • Journal of Hydrogen and New Energy
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    • v.33 no.2
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    • pp.158-163
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    • 2022
  • The test method on the Type II high-pressure hydrogen storage tanks made of the metal wire hoop winding is a complex and high risk. Also closeup on the tank being test is difficult. In this study, we studied a mechanical test method for a high-pressure hydrogen tanks. This method must be simple, risk-free and possible to observe the change in microscopic behavior of a metal wire on a liner. As the results, it was possible to observe the microscopic behavior on the metal wire by the mechanical test method. Also, a simple and risk-free test was possible compared to the conventional test method for high pressure hydrogen tanks.

Failure Pressure Prediction of Composite Cylinders for Hydrogen Storage Using Thermo-mechanical Analysis and Neural Network

  • Hu, J.;Sundararaman, S.;Menta, V.G.K.;Chandrashekhara, K.;Chernicoff, William
    • Advanced Composite Materials
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    • v.18 no.3
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    • pp.233-249
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    • 2009
  • Safe installation and operation of high-pressure composite cylinders for hydrogen storage are of primary concern. It is unavoidable for the cylinders to experience temperature variation and significant thermal input during service. The maximum failure pressure that the cylinder can sustain is affected due to the dependence of composite material properties on temperature and complexity of cylinder design. Most of the analysis reported for high-pressure composite cylinders is based on simplifying assumptions and does not account for complexities like thermo-mechanical behavior and temperature dependent material properties. In the present work, a comprehensive finite element simulation tool for the design of hydrogen storage cylinder system is developed. The structural response of the cylinder is analyzed using laminated shell theory accounting for transverse shear deformation and geometric nonlinearity. A composite failure model is used to evaluate the failure pressure under various thermo-mechanical loadings. A back-propagation neural network (NNk) model is developed to predict the maximum failure pressure using the analysis results. The failure pressures predicted from NNk model are compared with those from test cases. The developed NNk model is capable of predicting the failure pressure for any given loading condition.

Numerical Analysis of Discharge Flow in Type III Hydrogen Tank with Different Gas Models (Type III 수소 저장 용기에서 가스 모델(gas model)에 따른 배출(discharge) 현상의 수치 해석적 연구)

  • KIM, MOO-SUN;RYU, JOON-HYOUNG;JUNG, SU YEON;LEE, SEONG WOO;CHOI, SUNG WOONG
    • Journal of Hydrogen and New Energy
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    • v.31 no.6
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    • pp.558-563
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    • 2020
  • Hydrogen is attracting attention as an alternative energy source as an eco-friendly fuel without emitting environmental pollutants. In order to use hydrogen as an energy source, technologies such as hydrogen production and storage must be used, and new storage methods are being studied. In this study, the behavior of hydrogen in the storage tank were numerically studied under high-pressure hydrogen discharge conditions in a Type III hydrogen tank. Numerical results were compared with the experimental value and the results were quantitatively analyzed to verify the numerical implementation. With the results of pressure and temperature values under a given discharge condition, the Redich-Kwong gas model showed the adequate models with the smallest error between numerical and experimental results.

Development of a Thermal Model for Discharge Behavior of MH Hydrogen Storage Vessels (MH 수소저장 장치의 방출시 열거동 모사 수치 모델 개발)

  • O, Sang-Kun;Cho, Sung-Wook;Yi, Kyung-Woo
    • Journal of Hydrogen and New Energy
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    • v.22 no.2
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    • pp.178-183
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    • 2011
  • Metal hydride alloys are a promising type of material in hydrogen storage applications, allowing for low-pressure, high-density storage. However, while many studies are being performed on enhancing the hydrogen storage properties of such alloys, there has been little research on large-scale storage vessels which make use of the alloys. In particular, large-scale, high-density storage devices must make allowances for the inevitable generation or absorption of heat during use, which may negatively impact functioning properties of the alloys. In this study, we develop a numerical model of the discharge properties of a high-density MH hydrogen storage device. Discharge behavior for a pilot system is observed in terms of temperature and hydrogen flow rates. These results are then used to build a numerical model and verify its calculated predictions. The proposed model may be applied to scaled-up applications of the device, as well as for analyses to enhance future device designs.

Investigation of Thermal Management Parameters of Metal Hydride Based Hydrogen Storage System (금속수소화물 기반 수소저장시스템의 열관리 인자 조사)

  • PARK, CHU SIK;KIM, JONG WON;BAE, KI KWANG;JEONG, SEONG UK;KANG, KYOUNG SOO
    • Journal of Hydrogen and New Energy
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    • v.29 no.3
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    • pp.251-259
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    • 2018
  • Metal hydride based hydrogen storage under moderate temperature and pressure gives the safety advantage over the gas and liquid storage methods. Still solid-state hydrogen storage including metal hydride is below the DOE target level for automotive applications, but it can be adapted to stationary or miliary application reasonably. In order to develop a modular solid state hydrogen storage system that can be applied to a distributed power supply system composed of renewable energy - water electrolysis - fuel cell, the heat transfer and hydrogen storage characteristics of the metal hydride necessary for the module system design were investigated using AB5 type metal hydride, LCN2 ($La_{0.9}Ce_{0.1}Ni_5$). The planetary high energy mill (PHEM) treatment of LCN2 confirmed the initial hydrogen storage activation and hydrogen storage capacity through surface modification of LCN2 material. Expanded natural graphite (ENG) addition to LCN2, and compression molding at 500 atm improved the thermal conductivity of the solid hydrogen storage material.

A Study on the Metal Wire for Hoop Wrapping of Type 2 High Pressure Tank (Type 2 고압용기 권선용 금속선재에 관한 연구)

  • HAN, JINMOOK;CHOI, SOOKWANG;LEE, SUNGHEE;CHO, KYUNGCHUL;HWANG, CHULMIN;JUNG, YOUNGUAN
    • Journal of Hydrogen and New Energy
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    • v.30 no.4
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    • pp.338-346
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    • 2019
  • During last years, hydrogen refueling infrastructure test and devices research for hydrogen station presented a significant growth consisting of the commercialization of fuel cell electric vehicles (FCEVs). However, we still have many challenges for making commercial hydrogen stations such as increased safety and cost reduction. This study demonstrates the low cost hydrogen storage tank (type 2) and effective winding method for high pressure hydrogen storage. We use numerical analysis to verify stress changes inside the wire according to the winding condition. Also liner size, winding wire size and wire tension were studied for the safety and cost down. Results show that the stress of winding wire decreased with increased winding angle and increased the liner diameter. On the other hand, the stress of winding wire increased according to the increased wire thickness and tension.