Long Distance Intrinsically Safe Power Supply Technology in Coal Mines

LIU Yahui

Safety in Coal Mines > 2020 > 51(9): 118-121.

LIU Yahui. Long Distance Intrinsically Safe Power Supply Technology in Coal Mines[J]. Safety in Coal Mines, 2020, 51(9): 118-121.

Citation:

LIU Yahui. Long Distance Intrinsically Safe Power Supply Technology in Coal Mines[J]. Safety in Coal Mines, 2020, 51(9): 118-121.

Citation:

LIU Yahui. Long Distance Intrinsically Safe Power Supply Technology in Coal Mines[J]. Safety in Coal Mines, 2020, 51(9): 118-121.

Long Distance Intrinsically Safe Power Supply Technology in Coal Mines

LIU Yahui

More Information

Published Date: September 19, 2020

Graphical Abstract

Abstract

Abstract

Based on the problem of weak remote power supply capacity of intrinsically safe power supply in coal mines, according to the centralized power supply mode of point-to-point power supply in the field, this paper analyzes the fault phenomenon caused by insufficient power supply capacity of intrinsically safe equipment when working in the field, and analyzes the reasons for the reduction of intrinsically safe power supply capacity. Based on the transient characteristics of intrinsically safe equipment and the internal resistance of power supply cable, the methods of restraining the impulse current of intrinsically safe equipment and raising the voltage through the middle of the line to reduce the line loss are proposed to improve the remote power supply capacity of intrinsically safe power supply. The experiments show that the remote power supply capability of the intrinsically safe power supply system can be effectively improved by the methods, and the power supply distance can be effectively extended under the same output power condition.
- monitoring system,
- intrinsically safe power supply,
- long distance power supply,
- impulse current,
- transient suppression

FullText(HTML)

References (10)

References

[1]	谢俊生,王森,游青山.矿井安全监控电源系统的研究[J].工矿自动化,2010,36(7):71-74.
[2]	秦笑寒.永城煤矿安全监控系统设计与实现[D].大连:大连理工大学,2016.
[3]	林引.矿用本安型远程中继电源设计[J].工矿自动化,2016,42(11):19-22.
[4]	李志.关于延长对瓦斯传感器供电距离方法的探讨[J].煤矿安全,2012,43(2):67-69.
[5]	詹敏华.基于PLC的矿用皮带机电气控制系统应用研究[D].淮南:安徽理工大学,2016.
[6]	张冰倩.基于数据融合技术的煤矿安全监控系统研究[D].葫芦岛:辽宁工程技术大学,2012.
[7]	AQ 6201—2019煤矿安全监控系统通用技术要求[S].
[8]	煤安监函[2016]5号《煤矿安全监控系统升级改造技术方案》[A].
[9]	汤朝明.矿用传感器超远距离传输技术研究[J].矿业安全与环保,2012,39(3):44-46.
[10]	王文清.提高矿用本安电源带载能力的研究与实践[J].煤炭工程,2008,40(11):104-106.

[1]	WANG Dashun. Study on evolution law of maximum principal deviatoric stress and plastic zone distribution in roadway surrounding rock[J]. Safety in Coal Mines, 2023, 54(8): 118-127.
[2]	HAN Sen, WANG Weijun, PENG Gang. Relationship between plastic zone of roadway and coal and gas outburst hole[J]. Safety in Coal Mines, 2022, 53(12): 155-162.
[3]	LI Jianwei, LIANG Wenxu, FU Wei. Simulation and application of borehole plastic zone range based on gas drainage effect[J]. Safety in Coal Mines, 2022, 53(3): 170-174,180.
[4]	YANG Chuangqian, FENG Guorui. Numerical Simulation on Stress Distribution Law During Upward Mining in Wedge Pillar Mining Area[J]. Safety in Coal Mines, 2020, 51(5): 56-60.
[5]	YE Jinsheng, JING Laiwang, CUI Lei, ZHOU Jian, CHEN Siyu. Influence Analysis of Rock Dilatancy on Plastic Zone Displacement of Surrounding Rock of Roadway[J]. Safety in Coal Mines, 2018, 49(5): 194-197.
[6]	HAO Binbin, LI Guodong, LUO Feng. Floor Stress Distribution Characteristics and Mechanism of Floor Heave Under the Influence of Mining[J]. Safety in Coal Mines, 2017, 48(5): 206-209,213.
[7]	WANG Zhiqiang, XU Jie, LIU Hongjun, XING Ruijun, WANG Jianming, MA Qifei, ZHOU Wei. Analysis on Plastic Damage Zone Under the Key Strata of "Three Soft" Coal Seam[J]. Safety in Coal Mines, 2017, 48(2): 181-184.
[8]	SUN Lihui, JI Hongguang, ZENG Peng, JIANG Hua. Variability Characteristics Simulation of Roadway Plastic Zone in Different Side Pressure Coefficients[J]. Safety in Coal Mines, 2015, 46(11): 227-230.
[9]	NIU Zongjie, HU Yaoqing, WANG Chenlong, SHAO Mingwei. Influence of Support System in Roof-control Area on Relationship Mechanics Between Surrounding Rock and Support[J]. Safety in Coal Mines, 2014, 45(10): 194-197.
[10]	SUN Yingfeng, SUN Xiaoyuan, CAO Jialin, SHAO Shengyang, RONG Tao. Distribution Laws of Crossing Boreholes Plastic Zone in Coal Seam Gas Drainage[J]. Safety in Coal Mines, 2014, 45(10): 4-6.

Cited By

Cited by

Periodical cited type(3)

1.	高碧峰，王果. 河南省新安煤田郁山井田深部煤层及工程地质特征研究. 煤炭技术. 2024(04): 105-108 .
2.	王平，陈国兴，程爱平，李吉民，黄春源，杜澳宇. 不同类型充填体上巷道底板应力解析计算模型研究. 矿业研究与开发. 2024(12): 83-93 .
3.	白杰. 深部巷道破坏机理研究. 山西冶金. 2019(06): 71-73 .

Other cited types(3)

Get Citation

XML

Article views (84) PDF downloads (1) Cited by(6)

Turn off MathJax

Article Contents

Abstract

References

Long Distance Intrinsically Safe Power Supply Technology in Coal Mines

Abstract

References

Related Articles

Cited by

Periodical cited type(3)

Other cited types(3)

Catalog

Long Distance Intrinsically Safe Power Supply Technology in Coal Mines

Abstract

References

Related Articles

Cited by

Periodical cited type(3)

Other cited types(3)

Catalog

Export File

Citation

Format

Content