Research on the safe transmission power of mine radio wave explosion prevention

SUN Jiping; PENG Ming

doi:10.13272/j.issn.1671-251x.18184

Volume 50 Issue 3

Mar. 2024

Turn off MathJax

Article Contents

Abstract

References

Journal of Mine Automation > 2024 > 50(3): 1-5. > DOI: 10.13272/j.issn.1671-251x.18184

SUN Jiping, PENG Ming. Research on the safe transmission power of mine radio wave explosion prevention[J]. Journal of Mine Automation，2024，50（3）：1-5. DOI: 10.13272/j.issn.1671-251x.18184

Citation:

SUN Jiping, PENG Ming. Research on the safe transmission power of mine radio wave explosion prevention[J]. Journal of Mine Automation，2024，50（3）：1-5. DOI: 10.13272/j.issn.1671-251x.18184

Citation:

SUN Jiping, PENG Ming. Research on the safe transmission power of mine radio wave explosion prevention[J]. Journal of Mine Automation，2024，50（3）：1-5. DOI: 10.13272/j.issn.1671-251x.18184

PDF (511 KB)

Research on the safe transmission power of mine radio wave explosion prevention

School of Artificial Intelligence, China University of Mining and Technology-Beijing, Beijing 100083, China

More Information

Received Date: March 05, 2024
Revised Date: March 10, 2024
Available Online: March 17, 2024

Abstract

Abstract

High power radio waves emitted by mobile communication systems such as 5G, 5.5G, WiFi6, WiFi7, UWB, ZigBee, as well as personnel and vehicle positioning systems in mines, pose a risk of igniting gas and coal dust. Therefore, it is necessary to set a reasonable threshold for the explosion-proof safe power of radio waves emitted by explosion-proof radio equipment, and limit the power of radio waves emitted by explosion-proof radio equipment. The European standard CLC/TR 50427:2004 Assessment of inadvertent ignition of flammable atmospheres by radio-frequency radiation-Guide specifies a threshold for the safe reception and ignition power of radio waves in explosive gas environments. But it lacks content on the threshold for the safe transmission power of radio waves. Although the national standard GB/T 3836.1-2021 Explosive atmospheres-Part 1:Equipment-General requirements and the international standard IEC 60079-0:2017 Explosive atmospheres-Part 0:Equipment-General requirements have relevant provisions on the safe transmission power threshold for radio wave explosion protection, they mistakenly modify the safe reception ignition power threshold for radio wave explosion protection in the European standard CLC/TR 50427:2004 to the safe transmission power threshold for radio wave explosion protection. It greatly reduces the maximum transmission power allowed by radio equipment in explosive atmospheres. There’s a lack of slender structural objects such as cranes that can serve as receiving antennas in coal mines. The existing radio communication and positioning systems in mines operate at frequencies far greater than 30 MHz. Therefore, the threshold for the safe reception and ignition power of radio waves should be 8 W, instead of the radio wave explosion-proof safe transmission power threshold of 6 W specified in the national standard GB/T 3836.1-2021 and the international standard IEC 60079-0:2017. When the energy of the radio waves emitted by the transmitting antenna is fully absorbed by the equivalent antenna, which is the most unfavorable for wireless explosion-proof transmission and coupling, and the operating frequency of the radio equipment is the equivalent antenna resonance frequency, the reception and ignition power reaches its maximum. It is half of the total power received by the equivalent antenna, that is, half of the transmission power. In practical engineering, both radio transmission efficiency and coupling efficiency are not equal to 1. Therefore, the threshold for safe transmission power of radio waves should be more than twice the threshold for safe reception and ignition power of radio waves. The threshold for the safe reception and ignition power of underground radio waves in coal mines is 8 W. Therefore, the threshold for the safe transmission power of underground radio waves in coal mines should be greater than 16 W.
- mine radio waves,
- explosion proof safety,
- reception and ignition power,
- transmission power

FullText(HTML)

References (22)

References

[1]	孙继平. 煤矿用5G通信系统标准研究制定[J]. 工矿自动化,2023,49(8):1-8. SUN Jiping. Research and development of 5G communication system standards for coal mines[J]. Journal of Mine Automation,2023,49(8):1-8.
[2]	孙继平. 智能矿山信息综合承载网与网络切片路由器[J]. 智能矿山,2023,4(1):14-17. SUN Jiping. Intelligent mine information comprehensive bearer network and network slicing router[J]. Journal of Intelligent Mine,2023,4(1):14-17.
[3]	孙继平. 煤矿智能化与矿用5G和网络硬切片技术[J]. 工矿自动化,2021,47(8):1-6. SUN Jiping. Coal mine intelligence,mine 5G and network hard slicing technology[J]. Industry and Mine Automation,2021,47(8):1-6.
[4]	丁序海,潘涛,彭铭,等. 煤矿井下无线电波对人体的影响[J]. 工矿自动化,2022,48(11):84-92,144. DING Xuhai,PAN Tao,PENG Ming,et al. Influence of underground radio wave on human body in coal mine[J]. Journal of Mine Automation,2022,48(11):84-92,144.
[5]	孙继平. 煤矿智能化与矿用5G[J]. 工矿自动化,2020,46(8):1-7. SUN Jiping. Coal mine intelligence and mine-used 5G[J]. Industry and Mine Automation,2020,46(8):1-7.
[6]	孙继平,陈晖升. 智慧矿山与5G和WiFi6[J]. 工矿自动化,2019,45(10):1-4. SUN Jiping,CHEN Huisheng. Smart mine with 5G and WiFi6[J]. Industry and Mine Automation,2019,45(10):1-4.
[7]	CLC/TR 50427:2004 Assessment of inadvertent ignition of flammable atmospheres by radio-frequency radiation-Guide[S].
[8]	GB/T 3836.1—2021 爆炸性环境第1部分:设备通用要求[S]. GB/T 3836.1-2021 Explosive atmospheres-Part 1:Equipment-General requirements[S].
[9]	IEC 60079-0:2017 Explosive atmospheres-Part 0:Equipment-General requirements[S].
[10]	孙继平,彭铭,潘涛,等. 无线电波防爆安全阈值研究[J]. 工矿自动化,2023,49(2):1-5. SUN Jiping,PENG Ming,PAN Tao,et al. Research on the safety threshold of radio wave explosion-proof[J]. Journal of Mine Automation,2023,49(2):1-5.
[11]	潘涛,彭铭,徐会军,等. 煤矿井下无线电波防爆安全阈值及测试方法[J]. 智能矿山,2023,4(1):78-82. PAN Tao,PENG Ming,XU Huijun,et al. Safety thresholds and test methods for radio wave explosion protection in underground coal mines[J]. Journal of Intelligent Mine,2023,4(1):78-82.
[12]	孙继平,梁伟锋,彭铭,等. 煤矿井下无线传输衰减分析测试与最佳工作频段研究[J]. 工矿自动化,2023,49(4):1-8. SUN Jiping,LIANG Weifeng,PENG Ming,et al. Analysis and testing of wireless transmission attenuation in coal mine underground and research on the optimal operating frequency band[J]. Journal of Mine Automation,2023,49(4):1-8.
[13]	张高敏,刘毅,彭铭. UWR−FDTD矿井电磁波数值分析方法[J]. 煤炭学报,2022,47(11):4157-4166. ZHANG Gaomin,LIU Yi,PENG Ming. Numerical analysis method of the electromagnetic fields in coal mine roadway using UWR-FDTD[J]. Journal of China Coal Society,2022,47(11):4157-4166.
[14]	张高敏,刘毅,彭铭. FDTD矿井无线传输特性分析方法研究[J]. 煤炭科学技术,2022,50(11):202-212. ZHANG Gaomin,LIU Yi,PENG Ming. Resarch on the FDTD analysis method of wireless transmission characteristics in underground mine[J]. Coal Science and Technology,2022,50(11):202-212.
[15]	孙继平. 煤矿机器人电气安全技术研究[J]. 煤炭科学技术,2019,47(4):1-6. SUN Jiping. Research on electrical safety technology of coal mine robot[J]. Coal Science and Technology,2019,47(4):1-6.
[16]	BS 6656:2002 Assessment of inadvertent ignition of flammable atmospheres by radio-frequency radiation-Guide[S].
[17]	梁伟锋,孙继平,彭铭,等. 煤矿井下无线电波防爆安全功率阈值研究[J]. 工矿自动化,2022,48(12):123-128,163. LIANG Weifeng,SUN Jiping,PENG Ming,et al. Research on safe power threshold of radio wave explosion-proof in coal mine[J]. Journal of Mine Automation,2022,48(12):123-128,163.
[18]	BS 6656:1991 Guide to prevention of inadvertent ignition of flammable atmospheres by radio-frequency radiation[S].
[19]	邵水才,郭旭东,彭铭,等. 煤矿井下无线传输分析方法[J]. 工矿自动化,2022,48(10):123-128. SHAO Shuicai,GUO Xudong,PENG Ming,et al. Coal mine underground wireless transmission analysis method[J]. Journal of Mine Automation,2022,48(10):123-128.
[20]	田子建,降滉舟,常琳,等. 半波振子结构在井下5G辐射场中的安全性分析[J]. 工矿自动化,2023,49(6):159-167. TIAN Zijian,JIANG Huangzhou,CHANG Lin,et al. Safety analysis of half wave oscillator structure in underground 5G radiation field[J]. Journal of Mine Automation,2023,49(6):159-167.
[21]	孙继平,贾倪. 矿井电磁波能量安全性研究[J]. 中国矿业大学学报,2013,42(6):1002-1008. SUN Jiping,JIA Ni. Safety study of electromagnetic wave energy in coal mine[J]. Journal of China University of Mining & Technology,2013,42(6):1002-1008.
[22]	邱关源. 电路[M]. 6版. 北京:高等教育出版社,2022. QIU Guanyuan. Electric circuits[M]. 6th ed. Beijing:Higher Education Press,2022.

[1]	YIN Hao, ZHU Longji. Power distribution control of hybrid energy storage system for mining electric locomotives[J]. Journal of Mine Automation, 2025, 51(5): 114-119, 154. DOI: 10.13272/j.issn.1671-251x.2025030086
[2]	WEI Zhao, YANG Dashan, LIANG Lin. Control strategy for mine emergency microgrid based on PLC communication[J]. Journal of Mine Automation, 2024, 50(S1): 194-199.
[3]	YUAN Jingbo, JU Yunpeng, YANG Longyue, LYU Chengyang. Research on control strategy of energy storage converter of mine local ventilator[J]. Journal of Mine Automation, 2020, 46(2): 65-72. DOI: 10.13272/j.issn.1671-251x.2019050061
[4]	XU Yongfeng. Design of monitoring and communication system for the third power point of coal mine[J]. Journal of Mine Automation, 2016, 42(3): 81-83. DOI: 10.13272/j.issn.1671-251x.2016.03.019
[5]	LI Meixiang, ZHOU Zhong, ZHANG Yong. Study of large capacity power supply used for coal mine emergency facilities[J]. Journal of Mine Automation, 2014, 40(3): 9-11. DOI: 10.13272/j.issn.1671-251x.2014.03.002
[6]	CHEN Feng, GUO Jia-hu, WANG Heng. Modeling Simulation of Double-fed Wind Power Generation System Based on DIgSILENT/PowerFactory[J]. Journal of Mine Automation, 2012, 38(12): 66-70.
[7]	TIAN Wei-ming. Design of Battery Management System of Mine-used DC Power Supply[J]. Journal of Mine Automation, 2012, 38(7): 88-90.
[8]	GAO Juan, WANG Su-yu, LI Rui, ZHU Xin-ping, GAO Feng, DU Yi-bo, MU Jing, TIAN Jie, WU Miao. Design of a Novel Electrical Control System for Boom-type Roadheader Based on Power Panel and PCC[J]. Journal of Mine Automation, 2011, 37(4): 6-10.
[9]	HE Fei, FAN Peng, WANG Yu-feng. Application Research of Computation of Power Flow for Coal Mine Power SUpply SYstem Based on PowerWorld[J]. Journal of Mine Automation, 2010, 36(2): 49-52.
[10]	HAN Jin-hong, LI Yu-qua. Parameters Testing System of Charging Power Supply for Lamp Battery of Coal Mine Based on Virtual Instrument[J]. Journal of Mine Automation, 2009, 35(12): 109-111.

Cited By

Cited by

Periodical cited type(1)

张娜，彭文韬，赵强，汝洪芳，吴信元. 基于MBE-YOLO的轻量化井下行人检测模型. 矿业研究与开发. 2025(05): 192-199 .

Other cited types(3)

PENG Ming

School of Artificial Intelligence, China University of Mining and Technology-Beijing, Beijing 100083, China

Get Citation

PDF

XML

Article Metrics

Article views (564) PDF downloads (94) Cited by(4)

Research on the safe transmission power of mine radio wave explosion prevention