Research and formulation of coal mine information comprehensive bearer network standards
-
摘要: 为满足煤矿监控、定位、视频、音频、远控、5G等不同业务对时延、可靠性、带宽等指标的不同需求,煤矿信息综合承载网应具有下列功能:① 网络切片功能,支持FlexE接口技术或信道化子接口技术,将端口带宽资源划分到不同网络切片中;不同网络切片之间的业务彼此隔离承载,互不影响。② 网络切片在线带宽扩容功能,带宽调整过程中业务不出现丢包。③ 网络切片设置掉电保护功能。④ 符合IEEE 802.3和TCP/IP协议,支持IPv6协议和IPv6业务承载,支持IPv4、IPv6业务同时承载。⑤ 支持万兆光接口、千兆光接口、10/100/1 000 Mbit/s自适应接口,核心与汇聚节点宜支持5万兆及以上光接口。⑥ 宜采用环形或双环结构。⑦ 业务质量实时监测功能,实时监测指定业务的时延、抖动和丢包率情况。⑧ 1588v2时钟同步功能,支持5G基站业务接入。煤矿信息综合承载网的主要技术指标应满足下列要求:① 光端口传输距离应≥20 km;电端口传输距离应≥100 m。② 骨干网传输速率应≥10 Gbit/s;接入网传输速率应≥1 Gbit/s。③ 不同帧长的丢包率均≤0.01%(在70%网络流量负载条件下)。④ 单节点传输时延应≤1 ms(当以太网帧帧长度为1 518 byte时)。⑤ 节点转发抖动≤100 μs。⑥ 单接口支持切片数量应≥5。⑦ FlexE接口技术最小带宽应≤1 Gbit/s;信道化子接口技术最小带宽应≤2 Mbit/s。⑧ 网络重构自愈时间应≤50 ms。⑨ 在电网停电后,承载网设备在备用电源下的连续工作时间应≥4 h。Abstract: In order to meet the different requirements of coal mine monitoring, positioning, video, audio, remote control, 5G and other services for latency, reliability, bandwidth and other indicators, the coal mine information comprehensive bearer network should have the following functions. ① The network slicing function supports FlexE interface technology or channelized sub interface technology, and divides port bandwidth resources into different network slices. The services between different network slices are isolated and carried by each other without affecting each other. ② The online bandwidth expansion function of network slicing ensures that there is no packet loss during the bandwidth adjustment process. ③ Network slices set the power-off protection function. ④ The network complies with IEEE 802.3 and TCP/IP protocols, supports IPv6 protocol and IPv6 service bearer, and supports both IPv4 and IPv6 services simultaneously. ⑤ The network supports 10GE optical interface, 1GE optical interface, 10/100/1000 Mbit/s adaptive interface. The core and aggregation nodes should support optical interfaces of 50GE or above. ⑥ It is advisable to use a circular or double ring structure. ⑦ The real time monitoring function for business quality, monitors the delay, jitter, and packet loss rate of specified services in real time. ⑧ 1588v2 clock synchronization function supports 5G base station service access. The main technical indicators of the coal mine information comprehensive bearer network should meet the following requirements. ① The optical port transmission distance should be ≥ 20 km. The transmission distance of the electrical port should be ≥ 100 meters. ② The transmission rate of the backbone network should be ≥ 10 Gbit/s. The transmission rate of the access network should be ≥ 1 Gbit/s. ③ The packet loss rate for different frame lengths is ≤ 0.01% (under 70% network traffic load conditions). ④ The single node transmission delay should be ≤ 1 ms (when the Ethernet frame length is 1518 bytes). ⑤ Node forwarding jitter should be ≤100 μs. ⑥ The number of slices supported by a single interface should be ≥ 5. ⑦ The minimum bandwidth of FlexE interface technology should be ≤1 Gbit/s. The minimum bandwidth of channelized sub interface technology should be ≤ 2 Mbit/s. ⑧ The self-healing time of network reconstruction should be ≤ 50 ms. ⑨ After a power outage in the power grid, the continuous working time of the bearer network equipment under standby power supply should be ≥ 4 hours.
-
Keywords:
- coal mine intelligence /
- coal mine information /
- bearer network /
- network slicing /
- FlexE
-
-
[1] 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.
[2] 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.
[3] 孙继平,张高敏. 矿用5G频段选择及天线优化设置研究[J]. 工矿自动化,2020,46(5):1-7. SUN Jiping,ZHANG Gaomin. Research on 5G frequency band selection and antenna optimization setting in coal mine[J]. Industry and Mine Automation. 2020.46(5):1-7.
[4] MT/T 1131—2011 矿用以太网[S] . MT/T 1131-2011 Ethernet for the mine[S].
[5] GB/T 21671—2008 基于以太网技术的局域网系统验收测评规范[S]. GB/T 21671-2008 Acceptance test specification for local area network(LAN) systems based on ethernet technology[S].
[6] YD/T 1160—2001 接入网技术要求——基于以太网技术的宽带接入网[S]. YD/T 1160-2001 Access network technical specification-broadband access network based on ethernet technology[S].
[7] MT/T 1081—2008 矿用网络交换机[S]. MT/T 1081-2008 Network switch for a coal mine[S].
[8] 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.
[9] 中国电信,华为技术有限公司. 灵活以太网技术白皮书(2018版)[EB/OL]. [2024-03-27]. https://carrier.huawei.com/~/media/CNBG/Downloads/Spotlight/5g/20180920.pdf. China Telecom,Huawei Technologies Co. ,Ltd. White paper on flexible ethernet technology(2018 edition)[EB/OL]. [2024-03-27]. https://carrier.huawei.com/~/media/CNBG/Downloads/Spotlight/5g/20180920.pdf.
[10] 孙继平,程加敏. 煤矿智能化信息综合承载网[J]. 工矿自动化,2022,48(3):1-4,90. SUN Jiping,CHENG Jiamin. Coal mine intelligent information comprehensive carrier network[J]. Journal of Mine Automation,2022,48(3):1-4,90.
[11] 孙继平. 矿井人员位置监测技术[J]. 工矿自动化,2023,49(6):41-47. SUN Jiping. Mine personnel position monitoring technology[J]. Journal of Mine Automation,2023,49(6):41-47.
[12] 孙继平,田子建. 矿井图像监视系统与关键技术[J]. 煤炭科学技术,2014,42(1):65-68. SUN Jiping,TIAN Zijian. Image monitoring system and key technology in underground mine[J]. Coal Science and Technology,2014,42(1):65-68.
[13] 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.
[14] 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.
[15] 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.
[16] 孙继平. 煤矿事故特点与煤矿通信、人员定位及监视新技术[J]. 工矿自动化,2015,41(2):1-5. SUN Jiping. Characteristics of coal mine accidents and new technologies of coal mine communication,personnel positioning and monitoring[J]. Industry and Mine Automation,2015,41(2):1-5.
[17] 孙继平,江嬴. 矿井车辆无人驾驶关键技术研究[J]. 工矿自动化,2022,48(5):1-5,31. SUN Jiping,JIANG Ying. Research on key technologies of mine unmanned vehicle[J]. Journal of Mine Automation,2022,48(5):1-5,31.
[18] 孙继平. 煤矿信息化与智能化要求与关键技术[J]. 煤炭科学技术,2014,42(9):22-25,71. SUN Jiping. Requirement and key technology on mine informationalization and intelligent technology[J]. Coal Science and Technology,2014,42(9):22-25,71.
[19] 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.
[20] YD/T 3992—2021 灵活以太网(FlexE)链路接口测试方法[S]. YD/T 3992-2021 Test methods for flexible ethernet(FlexE) interface of link[S].
[21] YD/T 1240—2002 接入网设备测试方法——基于以太网技术的宽带接入网设备[S]. YD/T 1240-2002 Test method for access network-broadband access based on ethernet technology[S].
[22] YD/T 3918—2021 接入网设备测试方法 支持网络切片的光线路终端(OLT)[S]. YD/T 3918-2021 Test methods for access network optical line terminal(OLT) supporting network slicing[S].
[23] YD/T 4609—2023 切片分组网络(SPN)南向接口测试方法[S]. YD/T 4609-2023 Test method of slicing packet networks(SPN) equipment southbound interface[S].
[24] YD/T 4446—2023 切片分组网络(SPN)设备测试方法[S]. YD/T 4446-2023 Test methods for slicing packet networks(SPN) equipment[S].
-
期刊类型引用(2)
1. 张晓海,田慕琴,张敏龙,宋建成,许春雨,聂鸿霖,杨永锴. 智能工作面液压支架电液控制系统端头控制器设计. 工矿自动化. 2023(08): 30-36 . 
本站查看
2. 邢震. 智能矿山综合管控平台研究进展及发展路径. 工矿自动化. 2023(09): 147-154 . 本站查看
其他类型引用(0)
下载:
计量
- 文章访问数: 238
- HTML全文浏览量: 53
- PDF下载量: 57
- 被引次数: 2
