• Title/Summary/Keyword: HCNG 충전소

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A Trends Analysis on Safety for CNG/HCNG Complex Fueling Station (CNG/HCNG 복합충전소의 안전에 관한 동향분석)

  • Lee, Seung-Hyun;Kang, Seung-Kyu;Sung, Jong-Gyu;Lee, Young-Soon
    • Journal of the Korean Institute of Gas
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    • v.15 no.2
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    • pp.1-8
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    • 2011
  • In this research, the safety trends and technologies of HCNG, a mixture of hydrogen and natural gas, are analyzed. This is an attracting alternative fuels to meet the strengthened automotive exhaust gas emission standards. HCNG is very important opportunities and challenges in that it is available the existing CNG infrastructures, meets the strengthened emission standards, and the technical, social bridge of the coming era of hydrogen. It is essential for the commercialization of HCNG that hydrogen - compressed natural gas blended fuel for use in preparation of various safety considerations included accidents scenario, safety distance, hydrogen attack, ignition sources and fire detectors are examined. Risk assessments also are suggested as one of permission procedure for HCNG filling station.

Consequence Analysis of Hydrogen Blended Natural Gas(HCNG) using 3D CFD Simulation (CFD를 활용한 수소-천연가스 혼합연료에 대한 피해영향 분석)

  • Kang, Seung-Kyu;Bang, Hyo-Jung;Jo, Young-Do
    • Journal of the Korean Institute of Gas
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    • v.17 no.5
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    • pp.15-21
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    • 2013
  • This study evaluated comparison of the risk according to the type of fuel by three-dimensional simulation tool(FLACS). The consequence analysis of fire explosion and jet-fire was carried out in the layout of a typical high-pressure gas filling stations using CNG, hydrogen and 30%HCNG. Under the same conditions, hydrogen had a 30kPa maximum overpressure, CNG had a 0.4kPa and HCNG had a 3.5kPa. HCNG overpressure was 7.75 times higher than the CNG measurement, but HCNG overpressure was only 11.7% compared to hydrogen. In case of flame propagation, hydrogen had a very fast propagation characteristics. On the other hand, CNG and HCNG flame propagation velocity and distance tended to be relatively safe in comparison to hydrogen. The estimated flame boundary distance by jet-fire of hydrogen was a 5.5m, CNG was a 3.4m and HCNG was a 3.9m.

Analysis on the Explosion Risk Characteristic of Hydrogen blended Natural Gas (HCNG 혼합연료의 폭발 위험 특성 분석)

  • Kang, Seung-Kyu;Kim, Young-Gu;Kwon, Jeong-Rak
    • Journal of Energy Engineering
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    • v.23 no.4
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    • pp.223-229
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    • 2014
  • This study investigated the explosion characteristics of HCNG fuel using a simulation tool. The damage caused by the storage container explosion and vapor cloud explosion in a gas station was predicted. In case of an vapor cloud explosion in the HCNG station, 50~200kPa explosion pressure was predicted inside the station. When the cylinder explosion was occurred, in case of hydrogen, the measured influential distance of overpressure was 59m and radiant heat was 75m. In case of CNG, influential distance of overpressure was 89m and radiant heat was 144m would be estimated. In case of 30% HCNG that was blended with hydrogen and CNG, influential distance of overpressure was 81m and radiant heat was 130m were measured. The damage distance that explosive overpressure and radiant heat influenced CNG was seen as the highest. HCNG that was placed between CNG and hydrogen tended to be seen as more similar with CNG.

The trend of domestic and foreign development and hereafter subjects of Hydrogen-Compressed Natural Gas(HCNG) Vehicles (수소-압축천연가스(HCNG) 자동차 국내외 개발동향 및 향후과제)

  • Lee, Youngchul;Han, Jeongok;Lee, Joongseong;Chae, Jeongmin;Hong, Seongho
    • 한국신재생에너지학회:학술대회논문집
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    • 2010.06a
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    • pp.226.2-226.2
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    • 2010
  • 수소경제로 가는 길목에서의 압축천연가스에 수소를 첨가한 수소-압축천연가스(HCNG)는 자동차 연료로서의 뛰어난 효과로 인해 미국, 캐나다, 유럽 등에서는 강화되고 있는 자동차의 배출가스 규제에 대해 만족할 수 있는 차세대 천연가스 자동차의 대안으로서 관련 기술개발과 실증사업에 주력하고 있다. 향후 수소시대의 도래에 즈음하여 HCNG의 사용은 수소사용에 대한 인식 향상과 아울러 수소사용을 안정적으로 공급할 수 있는 토대를 마련하고 수소제조 등 여러 분야에서 기술개발을 할 수 있는 부가적인 효과가 있다고 하겠다. 따라서 최근 국내에서 시내버스와 청소차등에서 천연가스 차량의 보급이 확대되고 있고, 충전소도 점차 확대되고 있는 상황에서 HCNG 연료의 적용가능성을 확인하기 위한 연구가 진행되고 있다. 본 논문에서는 선진국과 국내의 기술개발 현황을 소개하고 향후 우리에게 필요한 과제가 무엇인지를 생각해보는 기회를 갖고자 하였다.

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The Trend of Domestic and Foreign Development and Hereafter Subjects of Hydrogen-Compressed Natural Gas (HCNG) Vehicles (수소-압축천연가스(HCNG) 자동차 국내외 개발동향 및 향후과제)

  • Lee, Young-Chul;Han, Jeong-Ok;Lee, Joong-Seong;Chae, Jeong-Min;Hong, Seong-Ho
    • New & Renewable Energy
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    • v.6 no.3
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    • pp.30-38
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    • 2010
  • 수소경제로 가는 길목에서의 압축천연가스에 수소를 첨가한 수소-압축천연가스(HCNG)는 자동차 연료로서의 뛰어난 효과로 인해 미국, 캐나다, 유럽 등에서는 강화되고 있는 자동차의 배출가스 규제에 대해 만족할 수 있는 차세대 천연가스 자동차의 대안으로서 관련 기술개발과 실증사업에 주력하고 있다. 향후 수소시대의 도래에 즈음하여 HCNG의 사용은 수소사용에 대한 인식 향상과 아울러 수소사용을 안정적으로 공급할 수 있는 토대를 마련하고 수소제조 등 여러 분야에서 기술개발을 할 수 있는 부가적인 효과가 있다고 하겠다. 따라서 최근 국내에서 시내버스와 청소차등에서 천연가스 차량의 보급이 확대되고, 충전소도 점차 확대되고 있는 상황에서 HCNG 연료의 적용가능성을 확인하기 위한 연구가 진행되고 있다. 본 논문에서는 인프라 관점에서의 선진국과 국내의 기술개발 현황을 소개하고 향후 우리에게 필요한 과제가 무엇인지를 생각해보는 기회를 갖고자 하였다.

Analysis of Experimental Results on Hydrogen Generator for HCNG (HCNG용 수소제조장치 실험 및 결과분석)

  • Lee, Youngchul;Han, Jeongok;Lee, Joongseong;Kim, Yongcheol;Cho, Youngah;Kim, Sangmin;Kim, Heongtae
    • Journal of Hydrogen and New Energy
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    • v.26 no.2
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    • pp.89-95
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    • 2015
  • Pollution emission control of the 20th century, for transportation energy, are being enhanced, and then as alternative to this, because hydrogen emit only water gas emissions to be environmentally friendly energy, so hydrogen as a sustainable clean energy is in the limelight. Used in compressed natural gas engines to mix hydrogen and natural gas in both domestic and international technology development and demonstration is being carried out. The hydrogen-compressed natural gas(HCNG) charging infrastructure can be used to build a hydrogen infrastructure in the transitional aspects of a future hydrogen economy society. In this paper, for a demonstration of HCNG charging infrastructure we made and operated a $30Nm^3/h$ hydrogen generating unit and analyzed the result of the operation. We was identified the operating conditions of a reforming reactor and water gas shift reactor from an analysis result, the thermal efficiency was calculated according to the operating conditions of the total hydrogen production process.

Explosion Simulations for the Quantitative Risk Analysis of New Energy Filling Stations (신에너지 충전소의 정량적 위험성 평가를 위한 폭발 시뮬레이션)

  • Dan, Seung-Kyu;Park, Kyung-Jun;Kim, Tae-Ok;Shin, Dong-Il
    • Journal of the Korean Institute of Gas
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    • v.15 no.1
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    • pp.60-67
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    • 2011
  • The interest about new and renewable energy is increasing to reduce the burden of problems by depletion of fossil fuels and air pollutions. For example, LNG/CNG and LPG are expected to be replaced, especially in transportation use, by HCNG mixture and DME-LPG mixture, respectively. Because these new energies are still flammable gases, it is not inherently safe from the explosion. In this research, the quantitative risk analysis for using alternative mixtures in existing recharging facilities has been studied by using three types of explosion models (TNT equivalency model, PHAST and CFD-based FLACS) to manage the risk effectively. The differences of results by models were compared against, and the practical ways of when and how to use these models were suggested. It was also predicted that conventional gas filling stations would be converted as new energy stations without additional explosion risk.

Process Simulation of HCNG Refueling System (HCNG 충전 시스템 공정모사)

  • Kim, Sang-Min;Han, Jeong-Ok;Lee, Yeong-Cheol;Lee, Joong-Seong;Kim, Yong-Cheol;Chae, Jeong-Min;Hong, Seong-Ho
    • Journal of the Korean Institute of Gas
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    • v.17 no.5
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    • pp.1-7
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    • 2013
  • In this study, simulation work of HCNG refueling system was performed. The hydrogen was produced from steam reforming process by natural gas. The conversion of natural gas is increased as SCR is increased. but it was no significant difference more than 3 of SCR and fuel throughput is increased as GHSV is increased. Both conversion and fuel throughput levels was optimized when the $1700h^{-1}$ of GHSV. CNG was compressed from low pressure natural gas. For the mixing of $H_2$ and CNG is mixed with the high pressure conditions such as 400bar of $H_2$ and 250bar of natural gas. Single-stage compression was required more power than multi stage. So, multi stage compression was suggested for high pressure compression. We calculated the intermediate pressure to minimize total required power of compressors. The intermediate pressure for $H_2$ and natural gas were derived at 61 and 65 bar, respectively.