ChivaTech
/
Project_PrincipleOverview_G_YunNan_2025


			
				
					
						
						
							123456789101112131415161718192021222324252627282930313233343536373839404142434445464748495051525354555657585960616263646566676869707172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122123124125126127128129130131132133134135136137138139140141142143144145146147148149150151152153154155156157158159160161162163164165166167168169170171172173174175176177178179180181182183184185186187188189190191192193194195196197198199200201202203204205206207208209210211212213214215216217218219220221222223224225226227228229230231232233234235236237238239240241242243244245246247248249250251252253254255256257258259260261262263264265266267268269270271272
							1
00:00:00,000 --> 00:00:05,893
在110千伏高压电网的电力设备中，断路器用于电网分合

2
00:00:05,894 --> 00:00:09,769
要求它不但具备切断空载和带负荷的线路

3
00:00:09,769 --> 00:00:12,454
线路过负荷时也需安全切断

4
00:00:12,454 --> 00:00:15,554
以及当线路出现故障如短路时

5
00:00:15,554 --> 00:00:17,364
依然能够切断线路

6
00:00:17,364 --> 00:00:19,634
来保护高压线路和设备

7
00:00:19,640 --> 00:00:21,880
确保电网稳定运行

8
00:00:21,881 --> 00:00:25,721
它由三个相同执行机构去分断三相电源

9
00:00:25,721 --> 00:00:27,836
它的进线从上端进入

10
00:00:27,836 --> 00:00:30,027
输出端在中间的端子上

11
00:00:30,027 --> 00:00:31,852
打开它的绝缘套装

12
00:00:31,852 --> 00:00:34,692
它的静触点是上端的铜银圆棒

13
00:00:34,692 --> 00:00:36,927
动触头是下端的铜银套管

14
00:00:37,535 --> 00:00:40,645
让我们看一下动触头是怎样运动的

15
00:00:40,645 --> 00:00:42,995
我们假设现在线路已接通

16
00:00:42,995 --> 00:00:44,835
并且断路器触点闭合

17
00:00:45,442 --> 00:00:49,097
它的动触点通过外部操作机构进行操作

18
00:00:49,097 --> 00:00:50,742
这里有两种情况

19
00:00:50,742 --> 00:00:55,335
当线路出现故障而自动跳闸或者我们手动切断线路

20
00:00:55,335 --> 00:00:58,602
这两种情况断开都是相同过程

21
00:00:58,602 --> 00:01:00,762
操作机构有两个弹簧

22
00:01:00,762 --> 00:01:02,752
两个弹簧均已加载

23
00:01:02,752 --> 00:01:05,855
操作机构箱上端有合闸储能弹簧

24
00:01:05,855 --> 00:01:11,242
横担里有分闸储能弹簧 目前两个弹簧均已加载

25
00:01:11,242 --> 00:01:14,407
两个分闸继电器铁芯和柱塞连接

26
00:01:14,407 --> 00:01:16,767
当我们需要分闸和保护跳闸时

27
00:01:17,362 --> 00:01:19,487
首先释放分闸信号

28
00:01:19,487 --> 00:01:22,972
分闸电磁铁吸合带动铁芯向上运动

29
00:01:22,972 --> 00:01:25,122
推动闸移动触碰到联板

30
00:01:25,122 --> 00:01:26,357
释放卡锁

31
00:01:26,357 --> 00:01:29,967
分闸弹簧释放能量拉动轴顺时针旋转

32
00:01:29,967 --> 00:01:31,192
平行杆运动

33
00:01:31,192 --> 00:01:33,322
联动拐臂逆时针转动

34
00:01:33,322 --> 00:01:38,735
拉动触头杆向下运动 脱离静触头从而实现分闸

35
00:01:38,736 --> 00:01:40,731
现在线路是断开的

36
00:01:40,731 --> 00:01:42,841
我们将线路重新合闸

37
00:01:42,841 --> 00:01:44,956
首先释放合闸信号

38
00:01:44,956 --> 00:01:46,816
合闸电磁铁吸合

39
00:01:46,816 --> 00:01:48,281
铁芯向上运动

40
00:01:48,281 --> 00:01:50,436
带动闸锁释放滚轮

41
00:01:50,436 --> 00:01:52,486
上端储能弹簧释放

42
00:01:52,486 --> 00:01:53,921
凸轮撞击拐臂

43
00:01:53,922 --> 00:01:55,892
拉动竖轴向下运动

44
00:01:55,892 --> 00:01:57,522
使轴逆时针运动

45
00:01:57,522 --> 00:01:59,617
轴转动的带动杆运动

46
00:01:59,617 --> 00:02:02,016
压缩分闸储能弹簧储能

47
00:02:02,016 --> 00:02:04,171
同时带动平行轴运动

48
00:02:04,171 --> 00:02:06,306
联动拐臂顺时针转动

49
00:02:06,306 --> 00:02:09,736
使动触头向上运动实现合闸

50
00:02:09,736 --> 00:02:12,886
注意此时一起带动压缩分闸弹簧

51
00:02:12,886 --> 00:02:15,151
同时为分闸弹簧储能

52
00:02:15,151 --> 00:02:17,506
迅速为下一次分闸做好了准备

53
00:02:18,123 --> 00:02:21,558
这使的断路器具备了一次重合闸的机会

54
00:02:21,558 --> 00:02:24,816
可以防止误跳闸和瞬时性故障出现

55
00:02:24,816 --> 00:02:29,043
大大提高了供电的可靠性减小了停电的次数

56
00:02:29,043 --> 00:02:31,248
为了使合闸弹簧储能

57
00:02:31,248 --> 00:02:34,078
我们在侧面安装了一台储能电机

58
00:02:34,078 --> 00:02:36,416
储能时是通过电机旋转

59
00:02:36,416 --> 00:02:38,741
电机齿轮联动拉动滚轮

60
00:02:38,741 --> 00:02:41,496
联动两个棘爪交替偏心运动

61
00:02:41,496 --> 00:02:45,616
拉动储能杆向下压缩弹簧进行储能

62
00:02:45,617 --> 00:02:48,727
由于六氟化硫一直密封在套管中

63
00:02:48,727 --> 00:02:50,847
他是有害的且会污染环境

64
00:02:51,471 --> 00:02:54,216
但我们却一直需要它的高压存在

65
00:02:54,216 --> 00:02:55,886
我们会安装压力表

66
00:02:55,886 --> 00:02:57,737
持续显示它的压力

67
00:02:57,737 --> 00:03:01,217
压力下降会立即补充气体或处理

68
00:03:01,218 --> 00:03:05,524
以上就是110千伏断路器的构造和工作原理