ModeDisplay/Assets/GameAssets/03.Models/01.500kV变压器-ODFPS-250000型/Materials/油枕C.mat

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ModeDisplay/Assets/GameAssets/03.Models/500kV变压器运行原理额外模型/Materials/油_01.mat

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ModeDisplay/Assets/GameAssets/03.Models/500kV变压器运行原理额外模型/Materials/绕组C_动态效果 1.mat

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ModeDisplay/Assets/Scripts/OperatingPrinciple/CoilPolarWipe/CoilPolarWipe_WithOffset.shader

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ModeDisplay/Assets/Scripts/OperatingPrinciple/线圈电流/red.mat

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ModeDisplay/Assets/Scripts/OperatingPrinciple/线圈电流/yellow.mat

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ModeDisplay/Assets/StreamingAssets/SubTitles/原理/500kV变压器电磁特性.srt

@@ -43,278 +43,278 @@
 这就是电磁感应现象
 
 12
-00:00:25,374 --> 00:00:28,794
+00:00:25,074 --> 00:00:28,494
 如果将磁铁换成一组接通直流电的线圈
 
 13
-00:00:28,794 --> 00:00:30,214
+00:00:28,494 --> 00:00:29,214
 根据安培定律
 
 14
-00:00:30,214 --> 00:00:33,960
+00:00:29,214 --> 00:00:32,960
 通电的线圈也会产生一个与磁铁相似的磁场
 
 15
-00:00:33,961 --> 00:00:35,981
+00:00:32,961 --> 00:00:35,481
 若接入的是交流电源
 
 16
-00:00:35,981 --> 00:00:38,071
+00:00:35,481 --> 00:00:37,571
 由于电流方向不断变化
 
 17
-00:00:38,071 --> 00:00:40,521
+00:00:37,571 --> 00:00:40,021
 磁场方向也会周期性反转
 
 18
-00:00:40,521 --> 00:00:43,581
+00:00:40,021 --> 00:00:43,081
 临近的线圈就会被动的切割磁通线
 
 19
-00:00:43,581 --> 00:00:45,541
+00:00:43,081 --> 00:00:44,541
 从而生成感应电流
 
 20
-00:00:45,541 --> 00:00:47,774
+00:00:44,541 --> 00:00:47,274
 实现非接触式能量传递
 
 21
-00:00:47,774 --> 00:00:49,161
+00:00:47,274 --> 00:00:48,661
 即隔空输电
 
 22
-00:00:49,161 --> 00:00:52,921
+00:00:48,661 --> 00:00:51,921
 但因多数磁通线未被利用 传输效率较低
 
 23
-00:00:52,921 --> 00:00:57,627
+00:00:51,921 --> 00:00:56,627
 我们引入一个高磁导率铁芯 并在两端分别缠绕线圈
 
 24
-00:00:57,628 --> 00:00:59,728
+00:00:56,628 --> 00:00:58,728
 铁芯提供低磁阻路径
 
 25
-00:00:59,728 --> 00:01:02,418
+00:00:58,728 --> 00:01:01,418
 使磁场集中在铁芯内部传播
 
 26
-00:01:02,418 --> 00:01:04,748
+00:01:01,418 --> 00:01:03,748
 从而达到集中磁通的效果
 
 27
-00:01:04,748 --> 00:01:06,068
+00:01:03,748 --> 00:01:05,068
 在这种结构中
 
 28
-00:01:06,068 --> 00:01:08,768
+00:01:05,068 --> 00:01:07,768
 连接电源的一侧称为初级线圈
 
 29
-00:01:08,768 --> 00:01:11,428
+00:01:07,768 --> 00:01:10,428
 输出电流的一侧为次级线圈
 
 30
-00:01:11,428 --> 00:01:16,268
+00:01:10,428 --> 00:01:15,268
 根据法拉第电磁感应定律 感应电压与线圈匝数成正比
 
 31
-00:01:16,268 --> 00:01:18,698
+00:01:15,268 --> 00:01:17,698
 此时次级线圈的匝数更多
 
 32
-00:01:18,698 --> 00:01:20,878
+00:01:17,698 --> 00:01:19,878
 那么输出的电压就会升高
 
 33
-00:01:20,878 --> 00:01:22,681
+00:01:19,878 --> 00:01:21,681
 称为升压变压器
 
 34
-00:01:22,682 --> 00:01:25,612
+00:01:21,682 --> 00:01:24,612
 反之如果是初级线圈的匝数更多
 
 35
-00:01:25,612 --> 00:01:27,612
+00:01:24,612 --> 00:01:26,612
 那么输出的电压则变低
 
 36
-00:01:27,612 --> 00:01:29,415
+00:01:26,612 --> 00:01:27,415
 称为降压变压器
 
 37
-00:01:29,416 --> 00:01:31,776
+00:01:28,016 --> 00:01:30,276
 这就是变压器的基本原理
 
 38
-00:01:31,776 --> 00:01:36,456
+00:01:30,276 --> 00:01:34,456
 根据结构形式不同 变压器可分为芯式和壳式两类
 
 39
-00:01:36,456 --> 00:01:39,556
+00:01:34,456 --> 00:01:37,556
 我们所展示的是一台壳式降压变压器
 
 40
-00:01:39,556 --> 00:01:41,166
+00:01:37,556 --> 00:01:39,166
 其结构较为特殊
 
 41
-00:01:41,166 --> 00:01:43,336
+00:01:39,166 --> 00:01:41,336
 具备500kV的高压输入
 
 42
-00:01:43,336 --> 00:01:44,636
+00:01:41,336 --> 00:01:42,636
 以及两个输出
 
 43
-00:01:44,636 --> 00:01:48,396
+00:01:42,636 --> 00:01:45,896
 分别为220kV的中压主输出和10kV
 
 44
-00:01:48,396 --> 00:01:51,096
+00:01:45,896 --> 00:01:48,596
 或35kV的辅助低压输出
 
 45
-00:01:51,096 --> 00:01:51,776
+00:01:48,596 --> 00:01:49,276
 其中
 
 46
-00:01:51,776 --> 00:01:54,916
+00:01:49,276 --> 00:01:52,916
 高压绕组与中压绕组共用部分线圈
 
 47
-00:01:54,916 --> 00:01:56,666
+00:01:52,916 --> 00:01:54,666
 利用自耦降压技术
 
 48
-00:01:56,666 --> 00:02:00,016
+00:01:54,666 --> 00:01:57,016
 通过改变中压侧抽头匝数实现主降压
 
 49
-00:02:00,016 --> 00:02:04,296
+00:01:57,016 --> 00:02:02,296
 低压绕组则为单独的线圈 在共用铁芯的最里端
 
 50
-00:02:04,296 --> 00:02:05,776
+00:02:02,296 --> 00:02:03,776
 在线圈绕制前
 
 51
-00:02:05,776 --> 00:02:08,386
+00:02:03,776 --> 00:02:05,886
 需先对铁芯包裹一层绝缘片
 
 52
-00:02:08,386 --> 00:02:09,836
+00:02:05,886 --> 00:02:07,336
 并套上绝缘筒
 
 53
-00:02:09,836 --> 00:02:12,856
+00:02:07,336 --> 00:02:10,356
 以防止低压线圈与铁芯直接接触
 
 54
-00:02:12,856 --> 00:02:17,522
+00:02:10,356 --> 00:02:14,922
 随后 依次绕上内层的低压线圈与外层的高中压线圈
 
 55
-00:02:17,522 --> 00:02:22,216
+00:02:14,922 --> 00:02:19,716
 所有绕组均采用高导电率的铜制成 横截面为矩形
 
 56
-00:02:22,216 --> 00:02:25,156
+00:02:19,716 --> 00:02:22,656
 矩形相比圆形的排布更加紧凑
 
 57
-00:02:25,156 --> 00:02:27,226
+00:02:22,656 --> 00:02:24,726
 拥有更好的空间利用率
 
 58
-00:02:27,226 --> 00:02:30,042
+00:02:24,726 --> 00:02:27,542
 同时有利于增加线径以降低电阻
 
 59
-00:02:30,042 --> 00:02:31,562
+00:02:27,542 --> 00:02:28,962
 提高散热效率
 
 60
-00:02:31,563 --> 00:02:33,573
+00:02:28,963 --> 00:02:31,073
 铜导线外包覆绝缘纸
 
 61
-00:02:33,573 --> 00:02:36,593
+00:02:31,073 --> 00:02:33,993
 这种材料耐高温、绝缘性强且不易老化
 
 62
-00:02:37,150 --> 00:02:38,810
+00:02:33,650 --> 00:02:35,310
 在这个三相系统中
 
 63
-00:02:38,810 --> 00:02:40,900
+00:02:35,310 --> 00:02:37,400
 电流按顺序流通绕组
 
 64
-00:02:40,900 --> 00:02:45,203
+00:02:37,400 --> 00:02:41,703
 每个绕组的电压波与其他电压波的相位相差120度
 
 65
-00:02:45,203 --> 00:02:48,910
+00:02:41,703 --> 00:02:45,410
 他们接力输出从而产生连续稳定的电流
 
 66
-00:02:48,910 --> 00:02:53,310
+00:02:45,410 --> 00:02:50,310
 在外层的高压、中压共用绕组上还会延伸出多个抽头
 
 67
-00:02:53,310 --> 00:02:55,460
+00:02:50,310 --> 00:02:52,960
 其全部连接有载分接开关
 
 68
-00:02:56,017 --> 00:02:59,717
+00:02:52,977 --> 00:02:54,717
 旁边的电机驱动装置可通过改变匝数的方式
 
 69
-00:02:59,717 --> 00:03:01,127
+00:02:54,717 --> 00:02:57,127
 来调节输出的电压
 
 70
-00:03:01,684 --> 00:03:04,550
+00:02:57,184 --> 00:02:59,950
 所有组件安装于密封油箱内部
 
 71
-00:03:04,550 --> 00:03:07,900
+00:02:59,950 --> 00:03:03,900
 油箱顶部设有五个引出电流的绝缘套管
 
 72
-00:03:07,900 --> 00:03:11,680
+00:03:03,900 --> 00:03:08,240
 分别为高压、中压、高压中性点及两个低压套管
 
 73
-00:03:12,244 --> 00:03:16,844
+00:03:08,244 --> 00:03:12,844
 这些套管是绝缘结构 防止高压击穿油箱壳体
 
 74
-00:03:16,844 --> 00:03:19,264
+00:03:12,844 --> 00:03:15,264
 油箱内部填充绝缘矿物油
 
 75
-00:03:19,264 --> 00:03:21,854
+00:03:15,264 --> 00:03:17,854
 具备良好绝缘性和热稳定性
 
 76
-00:03:21,854 --> 00:03:23,584
+00:03:17,854 --> 00:03:19,584
 可有效冷却内部绕组
 
 77
-00:03:24,151 --> 00:03:26,561
+00:03:19,651 --> 00:03:22,561
 在油箱上方还设置了油枕
 
 78
-00:03:26,561 --> 00:03:28,581
+00:03:22,561 --> 00:03:24,581
 用于储存备用绝缘油
 
 79
-00:03:28,581 --> 00:03:30,631
+00:03:24,581 --> 00:03:26,631
 同时它还可以过滤湿气
 
 80
-00:03:30,631 --> 00:03:32,297
+00:03:25,631 --> 00:03:27,297
 保证油质的纯度