• Title/Summary/Keyword: High Pressure Hydrogen Cylinder

Search Result 33, Processing Time 0.021 seconds

Development of the High Pressure Hydrogen Gas Cylinder(Type4) for Fuel Cell Vehicle;Design Qualification Tests (연료전지 차량용 고압기체수소 저장용기(Type4)개발;설계검증시험)

  • Yoo, Gye-Hyoung;Ju, Yong-Sun;Heo, Seok-Bong;Jeon, Sang-Jin;Kim, Jong-Lyul;Lee, Jong-Hee
    • 한국신재생에너지학회:학술대회논문집
    • /
    • 2007.11a
    • /
    • pp.193-196
    • /
    • 2007
  • We developed and tested the high pressure hydrogen gas cylinder(type4) for fuel cell vehicle. The working pressure is 350bar. We conducted material tests, production tests and design qualification tests on the developed cylinders according to modified NGV2-2000(hydrogen). The high pressure hydrogen gas cylinder met all the design qualification requirements of ANSI/CSA NGV2-2000 and acquired NGV2 certification from independent inspection agency.

  • PDF

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
    • /
    • v.18 no.3
    • /
    • pp.233-249
    • /
    • 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.

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
    • /
    • v.22 no.4
    • /
    • pp.520-526
    • /
    • 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 Air-tightness of High Pressure Liquid Hydrogen Pumping System at the Low Temperature (액체수소용 초저온 고압 피스톤 펌프의 기밀성 향상에 관한 기초연구)

  • Lee, Jonggoo;Lee, Jongmin;Lee, Jongtai
    • Journal of Hydrogen and New Energy
    • /
    • v.24 no.4
    • /
    • pp.302-310
    • /
    • 2013
  • As an initial step to develop a liquid hydrogen pump of piston type operated under cryogenic and high pressure, leakage and piston head shape for the piston pump were discussed with temperature and pressure. As the results, the leakage depended on correlation among density, viscosity, clearance area by the low temperature. In order to reduce the leakage, it was found that the air-tightness can be improved by minimizing contact surface between piston and cylinder, and also increasing pressure in-cylinder can reduce piston clearance. Among the proposed piston shapes, D type piston shape had the most air-tightness. D type piston had smaller contact surface than other piston shape and easier expansion of cup shape by pressure. The leakage of D type piston shape was found about 7%, compared with A type piston shape. But it was required that analyze about vapor lock by friction and wear resistance.

Combustion Control through the DME Injection Timing in the Hydrogen-DME Partially Premixed Compression Ignition Engine (DME 분사 시기 조절을 통한 수소-DME 부분 예혼합 압축착화 연소 제어)

  • Jeon, Jeeyeon;Bae, Choongsik
    • Journal of the Korean Society of Combustion
    • /
    • v.18 no.1
    • /
    • pp.27-33
    • /
    • 2013
  • Hydrogen-dimethy ether(DME) partially premixed compression ignition(PCCI) engine combustion was investigated in a single cylinder compression ignition engine. Hydrogen and DME were used as low carbon alternative fuels to reduce green house gases and pollutant. Hydrogen was injected at the intake manifold with an injection pressure of 0.5 MPa at fixed injection timing, $-210^{\circ}CA$ aTDC. DME was injected directly into the cylinder through the common-rail injection system at injection pressure of 30 MPa. DME inejction timing was varied to find the optimum PCCI combustion to reduce CO, HC and NOx emissions. When DME was injected early, CO and HC emissions were high while NOx emission was low. As the DME injection was retarded, the CO and HC emissions were decreased due to high combustion efficiency. NOx emissions were increased due to the high in-cylinder temperature. When DME were injected at $-30^{\circ}CA$ aTDC, reduction of HC, CO and NOx emissions was possible with high value of IMEP.

Development of high-pressure Type 3 composite cylinder for compressed hydrogen storage of fuel cell vehicle (차량용 200bar 급 Type 3 복합재 압력용기의 개발 및 설계인증시험)

  • Chung, Sang-Su;Park, Ji-Sang;Kim, Tae-Wook;Chung, Jae-Han
    • Proceedings of the Korean Society For Composite Materials Conference
    • /
    • 2005.04a
    • /
    • pp.203-206
    • /
    • 2005
  • The objective of study on composite cylinder for alternative fuel vehicle is to develop safe, efficient, and commercially viable, on-board fuel storage system for the fuel cell vehicle or natural gas vehicle that use highly compressed gaseous fuel such as hydrogen or natural gas. This study presents the whole procedure of development and certification of a type 3 composite cylinder of 207bar service pressure and 70 liter water capacity, which includes design/analysis, processing of filament winding, and validation through various testing and evaluation. Design methods of liner configuration and winding patterns are presented. Three dimensional, nonlinear finite element analysis techniques are used to predict burst pressure and failure mode. Design and analysis techniques are verified through burst and cycling tests. The full qualification test methods and results for validation and certification are presented.

  • PDF

Safety Evaluation Based on Structural Analysis of Cylinder Valves for Fuel Cell Vehicles (구조해석을 이용한 수소 연료전지 자동차 압력용기 밸브의 안전성 평가)

  • Lee, Hyo Ryeol;Ahn, Jung Hwan;Shin, Jin Oh;Kim, Hwa Young
    • Journal of the Korean Society of Manufacturing Technology Engineers
    • /
    • v.25 no.3
    • /
    • pp.189-197
    • /
    • 2016
  • Green vehicles include electric vehicles, natural gas vehicles, and fuel cell vehicles (FCVs). In FCVs, pressure vessels have cylinder valves to control hydrogen flow. These valves should be of high quality in terms of safety because hydrogen is stored at ultra-high pressure in pressure vessels. Hence, safety evaluation of these valves is necessary to secure the safety of the FCV. A structural analysis of the cylinder valve was conducted in this study by using a commercial finite element analysis code. The results showed that the safety factor of valve component ranged 1.06-186.44. After categorizing, the stress components at critical points of the cylinder valve parts were evaluated using the corresponding allowable design criteria in the ASME code. The pressurization cycle test was performed as per the regulation to evaluate the safety of the valve.

Effects of DME/Diesel as an ignition promoter on combustion of hydrogen homogeneous charge compression ignition (수소-예혼합 압축착화 엔진에서 착화제인 DME/diesel이 엔진 연소에 미치는 영향)

  • Jeon, Jeeyeon;Park, Hyeonwook;Bae, Choonsik
    • 한국연소학회:학술대회논문집
    • /
    • 2013.06a
    • /
    • pp.37-40
    • /
    • 2013
  • Hydrogen-dimethy ether (DME) and hydrogen-diesel compression ignition engine combustion were investigated and compared each other in a single cylinder compression ignition engine. Hydrogen and DME were used as low carbon alternative fuels to reduce green house gases and pollutant. Hydrogen was injected at the intake manifold with an injection pressure of 0.5 MPa at fixed injection timing, $-210^{\circ}CA$ aTDC. DME and diesel were injected directly into the cylinder through the common-rail injection system at injection pressure of 30 MPa. DME and diesel inejction timing was varied to find the optimum CI combustion to reduce CO, HC and NOx emissions. When DME was injected early, CO and HC emissions were high while NOx emission was low. Fuel consumption, heat release rate, and exhaust emissions were measured to analyze each combustion characteristics of each ignition promoter. Fuel consumption was decreased when diesel was used as an ignition promoter. This is due to the lower volatility of diesel which created more stratified charge than DME.

  • PDF

Development of Measurement Technology for Uptake and Diffusivity of Hydrogen gas in Rubber Materials using Volumetric Analysis (부피 분석법을 이용한 고무 소재의 수소 기체 장입량 및 확산도 측정 기술 개발)

  • LEE, JI HUN;JUNG, JAE KAP;BAEK, UN BONG;CHUNG, KI SOO
    • Journal of Hydrogen and New Energy
    • /
    • v.33 no.1
    • /
    • pp.67-76
    • /
    • 2022
  • We developed a technology that can measure the hydrogen uptake and diffusivity of rubber materials by using the volumetric analysis method and diffusivity analysis program through the measurement of the water level in the graduated cylinder. In this method, hydrogen gas is charged at a certain pressure for a certain period of time for a rubber material exposed to a high-pressure hydrogen gas environment, and then the pressure is reduced to measure the change in the water level in the graduated cylinder in real time, and based on the measured value, it is a technology that can evaluate hydrogen uptake and diffusivity using diffusivity analysis program. Using this method, the hydrogen uptake and diffusivity of the NBR material were measured with respect to the change in the type and weight ratio of the filler used to improve the physical properties of the rubber material. In addition, uncertainty analysis was performed on the diffusivity measurement method.

Fire Safety evaluation of High Pressure Hydrogen System for FCEV (연료전지차량용 고압수소저장시스템의 화재 안전성 평가)

  • Choi, Young-Min;Jang, Gyu-Jin;Kim, Sang-Hyun;Hang, Ki-Ho;Hang, In-Cheol;Ahn, Byung-Ki;Lim, Tae-Won
    • Journal of Hydrogen and New Energy
    • /
    • v.20 no.3
    • /
    • pp.188-193
    • /
    • 2009
  • Fuel cell vehicles are equipped with Pressure Relief Devices(PRDs) installed in pressure tank cylinder to prevent the explosion of the tank during a fire. PRDs are safety devices that perceive a fire and release gas in the pressure tank cylinder before it is exploded. But if the PRD does not actuate, because either the PRD fails or can't be surrounded by the flame of a fire, the tank will rupture and produce a blast wave and hydrogen fire ball. In this paper, we observed the fire behavior of actual fuel cell vehicle, comparing with that of gasoline vehicle.