Research on energy-saving optimal control method of belt conveyor in coal mine
-
摘要: 由于煤炭生产的不连续性,使带式输送机常常处于空载、轻载及很少达到满载的运行状态,造成电能浪费,同时加剧了设备磨损。目前解决该问题的方法是根据煤流量对带式输送机进行调速控制。但目前的方法较少考虑带式输送机之间煤流的上下游接续关系、煤流量传感器安装位置、检测误差、信息滞后及带速改变过程中的时序关系等。针对上述问题,依据带式输送机驱动功率与运行阻力和带速的关系,得出了带式输送机最优节能运行条件和最佳节电率;根据最优节能运行条件、带式输送机上下游接续方式与物料平衡关系、额定运输质量与额定带速,得出了带式输送机最优节能控制条件下的最小带速与最优带速控制系数;考虑煤流量传感器安装位置、检测误差、信息滞后及带速改变过程中的时序关系等因素,提出了一种带式输送机节能优化控制方法。该方法根据上游带式输送机的煤流量,计算得到最优节能控制条件下下游带式输送机优化节能控制的给定带速变化曲线,依据该曲线实现对下游带式输送机带速的调节。利用搭建的带式输送机模拟节能实验平台,对最佳节电率进行了检验,结果表明:带式输送机在最优节能运行条件下的最佳节电率为20.9%~76.5%,但在实际运输系统中,由于带速不能连续调节,所以不可能达到最优运行工况。将带式输送机节能优化控制方法应用于柠条塔煤矿101号主提升带式输送机控制中,结果表明:该方法实现了煤流的平稳接续,节电率为9.1%~43.9%,节能效果明显。Abstract: Due to the discontinuity of coal production, the belt conveyor is often in the running state of no-load, light load and rarely full load. This causes a waste of electricity and exacerbates the wear and tear of equipment. At present, the method to solve this problem is to control the velocity of belt conveyor according to the information of coal flow. However, the current method seldom considers the connection relationship between the upstream and downstream of the coal flow between the belt conveyors, the installation position of the coal flow sensor, the detection error, the information lag and the timing sequence relationship in the process of belt velocity change. In order to solve the above problems, according to the relationship between driving power, running resistance and belt velocity of belt conveyor, the optimal energy-saving running condition and the optimal energy-saving rate of belt conveyor are obtained. According to the optimal energy-saving running conditions, the relationship between upstream and downstream connection mode of belt conveyor and material balance, rated transportation quality and rated belt velocity, the minimum belt velocity and optimal belt velocity control coefficient under the optimal energy-saving control conditions of belt conveyor are obtained. According to the installation position of the coal flow sensor, the detection error, the information lag and the time sequence relationship of the belt velocity change process, an energy-saving optimal control method of belt conveyor is proposed. According to the coal flow information of the upstream belt conveyor, this method calculates the given curve of the belt velocity change of the downstream belt conveyor under the optimal energy-saving control condition. The adjustment of the belt velocity of the downstream belt conveyor is realized according to the curve. By using the simulated energy-saving experiment platform of belt conveyor, the optimal power saving rate is tested. The results show that the optimal power saving rate of belt conveyor under the optimal energy-saving running condition is 20.9%-76.5%. However, in the actual transportation system, because the belt velocity can not be adjusted continuously, it is impossible to achieve the optimal running condition. The energy-saving optimal control method of belt conveyor is apply to the control of the No. 101 main hoisting belt conveyor in Ningtiaota Coal Mine. And the result shows that this method realizes the smooth connection of coal flow, and the power saving rate is 9.1%-43.9%. The energy saving effect is obvious.
-
图 7 带式输送机模拟节能实验平台
Figure 7. Simulation energy-saving experimental platform of belt conveyor
表 1 不同填充率和转速下的电动机驱动功率
Table 1. Driving powers of motor at different filling rate and rotate speed
$ \gamma $ 驱动功率/W $ {n_{\text{N}}} $ $ 0.8{n_{\text{N}}} $ $ 0.6{n_{\text{N}}} $ $ 0.4{n_{\text{N}}} $ $ 0.2{n_{\text{N}}} $ 0 1541.7 1247.8 957.8 668.9 390.1 0.2 2114.3 1678.1 1284.5 893.4 497.8 0.4 2406.9 1931.8 1481.7 968.6 575.1 0.6 2977.0 2389.1 1806.2 1236.7 698.7 0.8 3520.9 2785.0 2092.5 1461.7 871.6 1.0 4111.1 3321.6 2508.7 1744.6 1132.4 
下载: 导出CSV
表 2 不同填充率下的最佳节电率
Table 2. Optimal power saving rate under different filling rate
$ \gamma $ 0 0.2 0.4 0.6 0.8 ${\lambda _{\max } } /{\text{%}}$ 74.7 76.5 59.8 39.3 20.9
下载: 导出CSV
表 3 带式输送机基本参数
Table 3. Basic parameters of belt conveyors
基本参数 带式输送机 1号 2号 3号 4号 长度/m 2500 2000 2000 160 装机功率/kW 1500 1500 3000 132 输送量/(t·h−1) 3000 3000 4000 4000 额定带速/(m·s−1) 4.0 4.0 4.0 4.0 煤流量测距/m l1=300 l2=300 l3=280 —
下载: 导出CSV
表 4 加速与减速过程接续时段
Table 4. Connection time interval in acceleration and deceleration process
加速过程(0.8~3.2 m/s) 减速过程
(3.2~2.4 m/s)时段 时长/s 时段 时长/s $ \Delta {t_{11}} $ 12 $ \Delta {t_{21}} $ 12 $ \Delta {t_{12}} $ 23 $ \Delta {t_{22}} $ 63 $ \Delta {t_{13}} $ 30 $ \Delta {t_{23}} $ 10 $ \Delta {t_{14}} $ 10 $ \Delta {t_{24}} $ 10
下载: 导出CSV
表 5 不同工况下驱动功率统计
Table 5. Powers statistics under different working conditions
${\gamma _3}$ 驱动功率/kW $ {k_3} $ $\lambda / {\text{%}}$ $ {P_{{\text{GT}}.{\text{max}}}} $ ${P'_{ {\text{GT} }{\text{.min} } } }$ 0 981 364 0.2 62.9 (0,0.2] 1335 749 0.2 43.9 (0.2,0.4] 1658 1201 0.4 27.6 (0.4,0.6] 2036 1634 0.6 19.7 (0.6,0.8] 2397 2178 0.8 9.1 (0.8,1.0] 2799 2799 1.0 −
下载: 导出CSV
-
[1] 蒋卫良,韩东劲. 我国煤矿带式输送机现状与发展趋势[J]. 煤矿机电,2008,29(1):1-6. doi: 10.3969/j.issn.1001-0874.2008.01.001JIANG Weiliang,HAN Dongjin. Development situation and tendency of native mining belt conveyor[J]. Colliery Mechanical & Electrical Technology,2008,29(1):1-6. doi: 10.3969/j.issn.1001-0874.2008.01.001 [2] 郭伟东,李明,亢俊明,等. 基于机器视觉的矿井输煤系统优化节能控制[J]. 工矿自动化,2020,46(10):69-75.GUO Weidong,LI Ming,KANG Junming,et al. Optimal energy saving control of mine coal transportation system based on machine vision[J]. Industry and Mine Automation,2020,46(10):69-75. [3] 王瑾. 井下胶带输送机自适应控制系统的设计[J]. 工矿自动化,2011,37(4):94-96.WANG Jin. Design of adaptive control system of belt conveyor of coal mine underground[J]. Industry and Mine Automation,2011,37(4):94-96. [4] 孙伟,王慧,杨海群. 带式输送机变频调速节能控制系统研究[J]. 工矿自动化,2013,39(4):98-101. doi: 10.7526/j.issn.1671-251X.2013.04.027SUN Wei,WANG Hui,YANG Haiqun. Research of energy-saving control system with frequency-conversion speed-regulation for belt conveyor[J]. Industry and Mine Automation,2013,39(4):98-101. doi: 10.7526/j.issn.1671-251X.2013.04.027 [5] 雷汝海,赵强. 矿井带式输送机节能优化与智能控制系统研究[J]. 煤炭技术,2017,36(12):184-186.LEI Ruhai,ZHAO Qiang. Research of energy saving optimization and intelligent control system of mine belt conveyor[J]. Coal Technology,2017,36(12):184-186. [6] 郝洪涛,杨庭杰,张超. 基于负载估计的带式输送机系统节能控制方法研究[J]. 煤炭科学技术,2021,49(7):139-146.HAO Hongtao,YANG Tingjie,ZHANG Chao. Research on energy saving control method of belt conveyor system based on load estimation[J]. Coal Science and Technology,2021,49(7):139-146. [7] 刘鸿利. 基于载荷检测的煤矿带式输送机控制系统[J]. 工矿自动化,2018,44(10):81-84.LIU Hongli. Coal mine belt conveyor control system based on load detection[J]. Industry and Mine Automation,2018,44(10):81-84. [8] 张振文, 宋伟刚. 带式输送机工程设计与应用[M]. 北京: 冶金工业出版社, 2015.ZHANG Zhenwen, SONG Weigang. Engineering design and application of belt conveyor[M]. Beijing: Metallurgical Industry Press, 2015. [9] 周广林,韩忠惠,张继通. 基于分形维数的大型带式输送机动态特性研究[J]. 煤炭科学技术,2019,47(2):125-130.ZHOU Guanglin,HAN Zhonghui,ZHANG Jitong. Research on dynamic characteristics of large belt conveyor based on fractal dimension[J]. Coal Science and Technology,2019,47(2):125-130. [10] 张雅俊,乔铁柱. 基于速度控制的多级带式输送机顺序启动方法[J]. 工矿自动化,2017,43(1):52-55.ZHANG Yajun,QIAO Tiezhu. Method of sequence start of multi-level conveyors based on speed control[J]. Industry and Mine Automation,2017,43(1):52-55. [11] 张治璞. 王家山煤矿大倾角带式输送机的选型设计及安装[J]. 煤矿机电,2013,34(3):50-54. doi: 10.3969/j.issn.1001-0874.2013.03.015ZHANG Zhipu. Type selection design and installation of large angle belt conveyor at Wangjiashan Mine[J]. Colliery Mechanical & Electrical Technology,2013,34(3):50-54. doi: 10.3969/j.issn.1001-0874.2013.03.015 [12] 张乐,王渊. 煤矿主井带式输送机选型设计[J]. 煤矿 机械,2014,35(7):6-8.ZHANG Le,WANG Yuan. Belt conveyor type selection design of main shaft in coal mine[J]. Coal Mine Machinery,2014,35(7):6-8. [13] 张科利,高赟,陈洋. 陕煤集团柠条塔煤矿主输送系统顺煤流启动研究及应用[J]. 煤炭技术,2016,35(3):229-231.ZHANG Keli,GAO Yun,CHEN Yang. Research and application of direct coal flow start of main belt conveying system in Ningtiaota Coal Mine[J]. Coal Technology,2016,35(3):229-231. -
点击查看大图
图(8) / 表(5)
计量
- 文章访问数: 368
- HTML全文浏览量: 51
- PDF下载量: 64
- 被引次数: 0
