Numerical Simulation Analysis of the Hydrogen-Blended Natural Gas Leakage and Ventilation Processes in a Domestic House

Li, Minghao; Chen, Shuangqing; Jiang, Weidong; Li, Yuchun; Xu, Zhe; Guan, Bing; Wang, Xingwang; Lin, Xiaoqiang; Liu, Tianqing

doi:10.1021/acsomega.3c03551

Cited by 4 publications

(2 citation statements)

References 21 publications

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“…Therefore, it is of great significance to study the leakage law of natural gas small holes under hydrogen doping conditions to ensure the safe operation of pipelines. Li conducted a study on the leakage of HBNG from small holes in a domestic house, simulated the distribution of gas leakage under different ventilation scenarios with doors and windows open and closed, and analyzed the reasons for the change in the volume of the harmful gas cloud [20]. Zhang developed a mathematical model of HBNG delivery, examined the hydraulic and thermal effects of hydrogen blending on natural gas pipelines and pipeline networks, and discussed how hydrogen blending ratios (HBR) affects centrifugal compressor performance and combined pipeline and compressor operating points [21].…”

Section: Introductionmentioning

confidence: 99%

Investigation of Hydrogen-Blended Natural Gas Pipelines in Utility Tunnel Leakage and Development of an Accident Ventilation Strategy for the Worst Leakage Conditions

Xu,

Guan,

Wei

et al. 2024

Applied Sciences

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The development of hydrogen-blended natural gas (HBNG) increases the risk of gas transportation and presents challenges for pipeline security in utility tunnels. The objective of this study is to investigate the diffusion properties of HBNG in utility tunnels and evaluate the effectiveness of various ventilation mechanisms. The numerical simulation software Fluent 2023 R1 is applied to simulate and analyze the leakage of small holes in a HBNG pipeline in the natural gas compartment. By examining the leaking behavior of HBNG through small holes in different circumstances, we aimed to identify the most unfavorable operational situation for leakage. Subsequently, we analyzed the ventilation strategy for sub-high-pressure pipes at various pressure levels in this unfavorable condition. This study’s findings demonstrate that blending hydrogen improves the gas diffusion capacity and increases the likelihood of explosion. The primary factors that influence the pattern of leakage are the size of the leaking holes and the pressure of the pipeline. The gas compartment experiences the most unfavorable working conditions for natural gas pipeline leaks when there are higher pressures, wider leak openings, higher hydrogen blending ratios (HBRs), and leaks in close proximity to an air inlet. When the HBR is 20%, the minimum accident ventilation rates for pressures of 0.4 MPa and 0.8 MPa are 15 air changes per hour and 21 air changes per hour, respectively. The maximum allowable wind speed for accident ventilation is 5 m/s, as regulated by China’s national standard, GB 50838-2015. This regulation makes it difficult to minimize the risk of leakage in a 1.6 MPa gas pipeline. It is recommended to install a safety interlock device to quickly shut off the pipeline in the event of a leak in order to facilitate the dispersion of the substance.

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Section: Introductionmentioning

confidence: 99%

Investigation of Hydrogen-Blended Natural Gas Pipelines in Utility Tunnel Leakage and Development of an Accident Ventilation Strategy for the Worst Leakage Conditions

Xu,

Guan,

Wei

et al. 2024

Applied Sciences

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“…It also found that installing a partition wall in the ceiling between the living room and kitchen reduced the response time of gas alarm. 16 Yu conducted a similar study on the partition wall and wind speed on leaked gas distribution. It is found that a height of the partition walls of about 30 cm is optimal for the triggering of alarms.…”

Section: ■ Introductionmentioning

confidence: 99%

Numerical Simulation Investigation on Natural Gas Leakage under Different Kitchen Layouts in China

Chen,

Li,

et al. 2023

ACS Omega

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The safety of an open kitchen is a controversial topic in China. In this study, natural gas leakage and ventilation processes under an open kitchen layout and closed kitchen layout are simulated by CFD. The evolution of a hazardous gas cloud and the triggering behaviors of alarms are analyzed and discussed. For closing all windows in the leakage process, the state of the partition door is a major factor. A closed kitchen layout with a closing partition door performs best in confining a hazardous gas cloud. At this point, it is difficult for a hazardous gas cloud to appear in the living area. With the partition door open, the gas cloud develops rapidly. For opening windows in the leakage process, a large scale hazardous gas cloud is not able to form under all layouts. For alarm-triggering behaviors, a closed kitchen layout when closing the partition door also performs best. When opening the partition door, alarms cannot trigger stably under all layouts. For the ventilation process, hazardous gas cloud dissipation under an open kitchen layout is slightly faster than the closed kitchen layout. Under a weak convection effect, there is a transition stage which delays the time point for exhausting leaked gas. Based on the analysis, some recommendations for accident prevention are proposed. Residents should try to use closed kitchens and close partition doors when not cooking. If open kitchens are used, multiple alarms with lower trigger values should be installed. It is better to choose a ceiling type for gas alarms. The windows of the house are recommended to select two layers type. Higher layers can open during the ventilation process to accelerate the exhaust of leaked gas. These recommendations provide a reference for preventing fires and explosions.

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CFD analysis of leakage and diffusion characteristics in the buried hydrogen-blended natural gas pipeline

Liu,

Wang,

Liang

et al. 2024

International Journal of Hydrogen Energy

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Numerical Simulation Analysis of the Hydrogen-Blended Natural Gas Leakage and Ventilation Processes in a Domestic House

Cited by 4 publications

References 21 publications

Investigation of Hydrogen-Blended Natural Gas Pipelines in Utility Tunnel Leakage and Development of an Accident Ventilation Strategy for the Worst Leakage Conditions

Investigation of Hydrogen-Blended Natural Gas Pipelines in Utility Tunnel Leakage and Development of an Accident Ventilation Strategy for the Worst Leakage Conditions

Numerical Simulation Investigation on Natural Gas Leakage under Different Kitchen Layouts in China

CFD analysis of leakage and diffusion characteristics in the buried hydrogen-blended natural gas pipeline

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