F5G industrial optical ring network communication technology and its application and prospect in coal mines
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摘要: 矿井传统有线通信网络存在带宽固定、有效利用率低、时延较高、系统配置不灵活等问题,无法满足矿井智能化业务发展需求。矿用5G及WiFi6无线通信存在巷道衰减大、 可靠性不及有线通信的问题。针对F5G(第5代固定网络)工业光环网通信技术的特点,指出F5G工业光环网通信技术是矿井有线通信的发展趋势。介绍了 F5G工业光环网的2个关键技术:10 Gibit/s PON(无源光网络)技术、数智光分配网(DQ ODN)技术;比较了F5G工业光环网与传统有线网络在网络时延、电气安全、业务安全、施工安全、维护安全等方面的优势。结合F5G工业光环网通信技术在煤矿井下应用的需求特点及建设实例,分析了F5G工业光环网通信技术在井下工业远程控制、高清视频回传、工业网络迁移、远程故障诊断、无线网络信号回传等场景的具体应用,指出F5G工业光环网通信技术在矿井应用的不足与前景:① 基于F5G工业光环网通信技术的矿用设备种类较少。② 在不同场景的适应性、不同业务种类的适配性方面有待提升。③ F5G工业光环网通信技术在系统接口与协议方面与传统以太环网通信接口相同,终端设备无需更改适配即可接入使用,是未来煤矿场景工业网络的有效解决方案。④ 煤矿应结合自身实际情况建设F5G试点,以实际场景支撑F5G工业光环网通信技术的应用与研究。Abstract: The traditional wired communication network in coal mines has problems such as fixed bandwidth, low effective utilization, high time-delay, and inflexible system configuration. This cannot meet the development needs of intelligent business in coal mines. Mining 5G and WiFi6 wireless communication has the problem of large roadway attenuation and lower reliability than wired communication. According to the characteristics of F5G (the fifth generation fixed networks) industrial optical ring network communication technology, it is pointed out that F5G industrial optical ring network communication technology is the development trend of mine wired communication. Two key technologies of F5G industrial optical ring network are introduced. They are 10 Gibit/s PON (passive optical network) technology and digital quick optical distribution network (DQ ODN) technology. The advantages of F5G industrial optical ring network and traditional wired network in network delay, electrical safety, business safety, construction safety and maintenance safety are compared. Based on the demand characteristics and construction examples of F5G industrial optical ring network communication technology applied in coal mines, this paper analyzes the specific applications of F5G industrial optical ring network communication technology in scenarios such as underground industrial remote control, high-definition video transmission, industrial network migration, remote fault diagnosis, and wireless network signal transmission. It points out the shortcomings and prospects of F5G industrial optical ring network communication technology in coal mines. ① There are few types of mining equipment based on F5G industrial optical ring network communication technology. ② There is still room for improvement in the adaptation of scenarios and different business types. ③ The F5G industrial optical ring network communication technology is the same as the traditional Ethernet ring network communication interface in terms of system interface and protocol. The terminal equipment can be accessed and used without changing the adaptation. It is an effective solution for the industrial network in the future coal mine scenario. ④ Coal mines should build F5G pilot projects based on their own actual conditions to support the application and research of F5G industrial optical ring network communication technology with actual scenarios.
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图 2 F5G工业光环网连接视频终端
Figure 2. Connection mode between F5G industrial optical ring network and video terminal
图 3 F5G工业光环网承载WiFi基站
Figure 3. F5G industrial optical ring network carring WiFi base station
表 1 F5G网络与传统网络时延对比
Table 1. F5G network and traditional network delay comparison
类型 配置帧/bit 最小时延/μs 最大时延/μs 平均时延/μs F5G网络 262 29.66 405.21 76.734 1 280 42.49 411.63 88.602 1 518 45.36 418.47 94.704 传统网络 262 28.30 8 762.81 5 320.05 1 280 42.97 8 762.87 2 713.12 1 518 47.14 8 788.44 3 969.04 
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[1] 朱德娟. 基于现代化矿井的通信技术[J]. 电子技术与软件工程,2020(9):17-18.ZHU Dejuan. Communication technology based on modern mines[J]. Electronic Technology & Software Engineering,2020(9):17-18. [2] 罗红霞. 矿井融合调度通信系统设计[J]. 工矿自动化,2021,47(增刊2):81-83.LUO Hongxia. Design of mine integrated dispatching communication system[J]. Industry and Mine Automation,2021,47(S2):81-83. [3] 余明高,阳旭峰,郑凯,等. 我国煤矿瓦斯爆炸抑爆减灾技术的研究进展及发展趋势[J]. 煤炭学报,2020,45(1):168-188. doi: 10.13225/j.cnki.jccs.YG19.1422YU Minggao,YANG Xufeng,ZHENG Kai,et al. Progress and development of coal mine gas explosion suppression and disaster reduction technology in China[J]. Journal of China Coal Society,2020,45(1):168-188. doi: 10.13225/j.cnki.jccs.YG19.1422 [4] 魏景新,靳文涛. 基于ZigBee技术的煤矿井下自组网定位系统设计[J]. 中国煤炭,2017,43(3):84-88. doi: 10.3969/j.issn.1006-530X.2017.03.018WEI Jingxin,JIN Wentao. Design of underground coal mine ad-hoc network positioning system based on ZigBee technology[J]. China Coal,2017,43(3):84-88. doi: 10.3969/j.issn.1006-530X.2017.03.018 [5] 刘晗蕖. 面向5G的承载网发展趋势探讨[J]. 广西通信技术,2018(3):42-46. doi: 10.3969/j.issn.1008-3545.2018.03.009LIU Hanqu. Research on the development trend of 5G-oriented bearing network[J]. Guangxi Communication Technology,2018(3):42-46. doi: 10.3969/j.issn.1008-3545.2018.03.009 [6] 肖荣军,徐义光. 高带宽需求的PON网络技术升级方案初步探讨[J]. 江苏通信,2019,35(5):57-59,68. doi: 10.3969/j.issn.1007-9513.2019.05.016XIAO Rongjun,XU Yiguang. Preliminary discussion on the PON network technology upgrade scheme with high bandwidth demand[J]. Jiangsu Communications,2019,35(5):57-59,68. doi: 10.3969/j.issn.1007-9513.2019.05.016 [7] 彭齐琼. 固网F5G的趋势及应用场景分析[J]. 电信技术,2019(增刊1):96-98.PENG Qiqiong. Trend and application scenario analysis of fixed network F5G[J]. Telecommunication Technology,2019(S1):96-98. [8] 高谦,罗卫国. 激活“闲置资源” 构建“共享光网”——太原移动城域光纤网智能化探索与实践[J]. 电信技术,2013(5):16-19. doi: 10.3969/j.issn.1000-1247.2013.05.005GAO Qian,LUO Weiguo. Activate "idle resources" to build "shared optical network" − Intelligent exploration and practice of Taiyuan mobile city optical fiber network[J]. Telecommunication Technology,2013(5):16-19. doi: 10.3969/j.issn.1000-1247.2013.05.005 [9] 王洋. 基于宽带布尔混沌的光纤故障特性检测[D]. 太原: 太原理工大学, 2021.WANG Yang. Optical fiber fault characteristic detection based on broadband Boolean chaos[D]. Taiyuan: Taiyuan University of Technology, 2021. [10] 黄海峰. 盘点2022光网络产业:F5G演进让一切成为可能[J]. 大数据时代,2023(1):60-67.HUANG Haifeng. Overview of optical network industry in 2022:F5G made everything possible[J]. Big Data Time,2023(1):60-67. [11] 任立全,张钊. 无源光网络在某综合医院中的设计与应用[J]. 智能建筑电气技术,2020,14(5):67-70. doi: 10.13857/j.cnki.cn11-5589/tu.2020.05.015REN Liquan,ZHANG Zhao. Design and application of passive optical network in a general hospital[J]. Electrical Technology of Intelligent Buildings,2020,14(5):67-70. doi: 10.13857/j.cnki.cn11-5589/tu.2020.05.015 [12] 丘栋,陆以夫,陈娟,等. 智能变电站光缆全套解决方案[J]. 广西电力,2015,38(1):57-59,76. doi: 10.3969/j.issn.1671-8380.2015.01.015QIU Dong,LU Yifu,CHEN Juan,et al. A full set of solutions to optical fiber cable in intelligent substation[J]. Guangxi Electric Power,2015,38(1):57-59,76. doi: 10.3969/j.issn.1671-8380.2015.01.015 [13] 张静. 电力光纤故障检测及抢修最优路径方法研究[D]. 保定: 华北电力大学, 2013.ZHANG Jing. Research of electrical optical cable fault detection and repair optimum path method[D]. Baoding: North China Electric Power University, 2013. [14] 王天惠. 基于多测点信息的辐射状配电网故障定位研究[D]. 成都: 西华大学, 2020.WANG Tianhui. Research on radial distribution network falut location based on multi-measurement information[D]. Chengdu: Xihua University, 2020. [15] 吴文臻, 温良. F5G技术在煤矿井下的应用[J]. 智能矿山, 2022, 3(9): 68-71.WU Wenzhen, WEN Liang. Application of F5G technology in underground coal mine[J]. Intelligent Mine, 2022, 3(9): 68-71. [16] 温良,吴文臻,李起伟. 矿用F5G架构的智能化煤矿建设方案研究[J]. 煤炭科学技术,2022,50(11):176-182.WEN Liang,WU Wenzhen,LI Qiwei. Study on intelligent coal mine construction scheme of F5G architecture[J]. Coal Science and Technology,2022,50(11):176-182. [17] 王家旭,王文成,王浩年. 浅析基于5G技术的物联网应用[J]. 中国新通信,2019,21(16):117-118. doi: 10.3969/j.issn.1673-4866.2019.16.098WANG Jiaxu,WANG Wencheng,WANG Haonian. The application of the internet of things based on 5G technology[J]. China New Telecommunications,2019,21(16):117-118. doi: 10.3969/j.issn.1673-4866.2019.16.098 [18] 李松蹊. 智能变电站网络架构改进的研究[D]. 沈阳: 沈阳工程学院, 2019.LI Songqi. Research on optimization of intelligent substation network structure[D]. Shenyang: Shenyang Institute of Engineering, 2019. [19] 孙洪勤. 深部开采热环境治理及通风系统研究[D]. 青岛: 山东科技大学, 2012.SUN Hongqin. The study of thermal environment deep mining and its ventilation optimization[D]. Qiangdao: Shandong University of Science and Technology, 2012. [20] 陈士松. 梁家煤矿工业以太环网升级研究与应用[J]. 山东煤炭科技,2017(11):166-167. doi: 10.3969/j.issn.1005-2801.2017.11.071CHEN Shisong. Research and application of Ethernet ring network upgrade in Liangjia Coal Mine Industry[J]. Shandong Coal Science and Technology,2017(11):166-167. doi: 10.3969/j.issn.1005-2801.2017.11.071 [21] 王坚. 浅谈5G和广播电视网络的融合发展[J]. 数字传媒研究,2018,35(12):52-54. doi: 10.3969/j.issn.2096-0751.2018.12.013WANG Jian. Integration development of 5G and radio & television network[J]. Research on Digital Media,2018,35(12):52-54. doi: 10.3969/j.issn.2096-0751.2018.12.013 -
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