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- GW22型
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- 110千伏隔离开关是三相一体柱式垂直断口双臂折叠式高压
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- 00:00:06,350 --> 00:00:07,280
- 电压电器
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- 00:00:07,280 --> 00:00:09,440
- 在110千伏线路中
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- 00:00:09,440 --> 00:00:11,270
- 它往往配合断路器
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- 00:00:11,270 --> 00:00:13,210
- 用于分合和隔离线路
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- 00:00:13,210 --> 00:00:15,090
- 以及对线路可靠接地
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- 00:00:15,093 --> 00:00:18,483
- 保证了倒闸操作的严谨性和安全性
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- 00:00:18,483 --> 00:00:20,203
- 上端触头为进线
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- 00:00:20,203 --> 00:00:21,483
- 中间为出线
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- 00:00:21,483 --> 00:00:24,633
- 折叠运动和夹紧运动复合协同设计
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- 00:00:24,640 --> 00:00:27,746
- 兼顾了操作效率与电气稳定性
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- 00:00:27,747 --> 00:00:31,127
- 它由隔离刀闸系统和接地系统组成
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- 00:00:31,127 --> 00:00:33,397
- 隔离刀闸用于分合线路
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- 00:00:33,397 --> 00:00:36,133
- 接地系统用于给线路做可靠接地
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- 00:00:36,133 --> 00:00:39,563
- 隔离刀闸又分为操作机构和执行机构
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- 00:00:39,563 --> 00:00:42,800
- 他俩之间通过机械的紧密配合去实现
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- 00:00:42,800 --> 00:00:47,627
- 操作机构是将电能 通过电机旋转转换成机械能
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- 00:00:47,627 --> 00:00:50,447
- 电机运转带动涡轮减速机运转
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- 00:00:50,447 --> 00:00:54,107
- 减速后经齿盘带动竖轴及旋转瓷瓶旋转
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- 00:00:54,107 --> 00:00:57,587
- 联动水平横杆和其他俩旋转瓷瓶运动
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- 00:00:57,587 --> 00:00:59,797
- 迫使大臂向上做切线运动
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- 00:00:59,800 --> 00:01:02,070
- 并压缩内部的弹簧储能
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- 00:01:02,070 --> 00:01:05,020
- 经齿盘带动二臂同样向上伸展
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- 00:01:05,020 --> 00:01:07,040
- 夹头碰到上端线路后
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- 00:01:07,040 --> 00:01:09,780
- 大臂指尖压缩二臂里面的触杆
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- 00:01:09,780 --> 00:01:11,940
- 从而让夹头夹紧线路
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- 00:01:11,940 --> 00:01:13,907
- 并压缩内部弹簧储能
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- 00:01:13,907 --> 00:01:15,747
- 从而完成合闸
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- 00:01:15,747 --> 00:01:16,817
- 分闸时
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- 00:01:16,817 --> 00:01:18,657
- 电机会反方向运转
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- 00:01:18,657 --> 00:01:21,747
- 在机械能和里面储能弹簧的能量下
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- 00:01:21,747 --> 00:01:23,187
- 夹紧触头分开
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- 00:01:23,187 --> 00:01:24,887
- 展臂向下收缩
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- 00:01:24,887 --> 00:01:28,287
- 通过齿轮箱驱动上导电管做复合运动
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- 00:01:28,287 --> 00:01:32,007
- 连杆系统改变力的方向并带动下导电管转动
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- 00:01:32,013 --> 00:01:34,827
- 形成有明显垂直断口的分闸
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- 00:01:34,827 --> 00:01:36,717
- 当线路需要检修时
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- 00:01:36,717 --> 00:01:39,217
- 可将接地刀闸做可靠接地
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- 00:01:39,217 --> 00:01:40,987
- 通过操作机构的电机
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- 00:01:40,987 --> 00:01:44,037
- 将电能转换成执行机构的机械能
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- 00:01:44,037 --> 00:01:47,453
- 电机转动经涡轮减速机转换成竖杆转动
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- 00:01:47,453 --> 00:01:49,953
- 带动接地刀闸做切线运动
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- 00:01:49,953 --> 00:01:51,663
- 到达接地静触点
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- 00:01:51,663 --> 00:01:53,253
- 实现明显可靠接地
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- 00:01:53,814 --> 00:01:57,194
- 为实现线路的冷储备形成了完美闭环
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- 00:01:57,194 --> 00:01:59,544
- 更为我们的安全保驾护航
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- 00:01:59,544 --> 00:02:01,507
- 它三相一体式设计方案
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- 00:02:01,507 --> 00:02:05,107
- 可以确保在电力系统中进行开关操作时
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- 00:02:05,107 --> 00:02:07,907
- 三个相位的开关状态始终保持一
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- 00:02:07,907 --> 00:02:09,627
- 提高了操作效率
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- 00:02:09,627 --> 00:02:11,447
- 增强了系统稳定性
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- 00:02:11,447 --> 00:02:13,974
- 降低了故障风险和维护成本
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- 00:02:13,974 --> 00:02:18,414
- 其垂直式结构也减小了体积 可节省安装空间
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