LY3NJ AC100/110 BY OMI 歐姆龍繼電器 歐姆龍繼電器資料 歐姆龍
LY3NJ AC100/110 BY OMI 歐姆龍繼電器 歐姆龍繼電器資料 歐姆龍
歐姆龍一級(jí)經(jīng)銷商武漢三駿特價(jià)供應(yīng)歐姆龍繼電器等全系列產(chǎn)品
武漢三駿聯(lián)眾科技有限公司
聯(lián)系人:李瓊毅 手機(jī):15071050439
電話:027-59847936 傳真:027-59803775
QQ: 1042051412 、1980919739
郵件:lizippmm@163.com
網(wǎng)址:http://www.wh3j.com/
聯(lián)系地址:武漢市武昌區(qū)丁字橋路51號(hào)弘業(yè)駿園A座1603
AB(羅克韋爾)��、ABB�、歐姆龍、西門子�、三菱 、TURCK(圖爾克)���、P+F(倍加福)���、IFM(愛(ài)福門)�、 SICK(施克) ����、KEYENCE(基恩士)、SUNX(神視)�、BALLUFF(巴魯夫)、SMC���、FESTO(費(fèi)斯托) ��、ASCO����、IDEC(和泉)�、YASKAWA(安川)、德國(guó)E+H (恩格斯豪斯)��、羅斯蒙特��、橫河川儀、美國(guó)HONEYWELL ���、明緯電源MW �����、富士FUJI、山特UPS電源�����、FLUKE(福祿克)�、施耐德
繼電器與形狀和動(dòng)作時(shí)間的關(guān)系
繼電器的動(dòng)作時(shí)間由延遲時(shí)間(線圈時(shí)間常數(shù)、慣性力矩引起的)��、接點(diǎn)切換時(shí)間等決定�����, 但是這些值根據(jù)繼電器的形狀而不同����。例如, 鐵芯和可動(dòng)鐵片之間空
隙較大的繼電器�, 帶電磁鐵(使用磁氣電阻較大的材質(zhì)) 的繼電器中, 為降低其電感系數(shù)的值而縮小時(shí)間常數(shù)����, 但反而減少了吸引力����, 吸引可動(dòng)鐵片所需的時(shí)
間也變長(zhǎng)��。這種傾向��, 在直流操作繼電器中尤為顯著��。因?yàn)殡姶盆F的吸引力與鐵芯�、可動(dòng)鐵片間的空隙的平方成反比, 降低后發(fā)生這種現(xiàn)象�����。因此在高速繼電器
中���, 可縮小空隙����, 使用高透磁率材料��, 減少線圈卷線等。
在交流操作下��, 由于啟動(dòng)時(shí)流通的電流大于額定電流��, 與直流操作不同���, 與形狀無(wú)關(guān)��。
此外���, 對(duì)于慣性力矩��, 間接驅(qū)動(dòng)形比較有效�, 在可動(dòng)鐵片開(kāi)始動(dòng)作時(shí)不會(huì)施加較大的負(fù)載載荷。
另外�����, 接點(diǎn)的切換時(shí)間幾乎由可動(dòng)鐵片的動(dòng)作直接傳達(dá)�, 因此其動(dòng)作應(yīng)盡可能地小, 而且為通過(guò)動(dòng)作全行程順利動(dòng)作�����, 要考慮載荷和吸引力的平衡。接點(diǎn)的反
彈受可動(dòng)鐵片的動(dòng)作速度��, 可動(dòng)部分的重量�����, 接點(diǎn)彈簧的彈性等要素的影響���。
一般接點(diǎn)彈簧���、接觸片的形狀、制動(dòng)塊的構(gòu)造等應(yīng)緩和動(dòng)作時(shí)的沖擊能量�����。
線圈外加電壓(電流)與動(dòng)作時(shí)間的關(guān)系繼電器的動(dòng)作時(shí)間受線圈的外加電壓(電流) 支配����。如下圖所示, 施加若干超出動(dòng)作電壓的電壓時(shí)���, 線圈電流達(dá)到動(dòng)
作電流之前的時(shí)間�;克服可動(dòng)部慣性到可動(dòng)部開(kāi)始動(dòng)作之前的時(shí)間��;吸引力克服負(fù)載載荷, 可動(dòng)部加速���, 接點(diǎn)切換之前的時(shí)間�����, 由于任何一個(gè)都延長(zhǎng)�����, 因此其
動(dòng)作時(shí)間也大幅延長(zhǎng)�����。
另一方面�����, 施加大幅超過(guò)動(dòng)作電壓的電壓時(shí), 任何一個(gè)都縮短��,動(dòng)作時(shí)間也提前���。
線圈外加電壓和動(dòng)作時(shí)間的關(guān)系如上所述�����, 但線圈外加電壓與其他特性也有關(guān)系����, 因此規(guī)定了線圈額定電壓
線圈溫度和動(dòng)作
繼電器溫度一發(fā)生變化, 繼電器接點(diǎn)彈簧的彈性��、摩擦狀態(tài)����、線圈電阻等也發(fā)生變化。但是�, 其中對(duì)動(dòng)作時(shí)間產(chǎn)生較大影響的是線圈電阻的變化。已經(jīng)在繼電器
的動(dòng)作原理部分對(duì)這一點(diǎn)進(jìn)行了說(shuō)明����。電磁鐵的動(dòng)作與電流有關(guān)。在直流電磁鐵下��, 電流可表示為以下公式����。
i : 線圈電流
R : 線圈電阻
E : 線圈外加電壓
ι : 線圈的時(shí)間常數(shù)L/R
t : 從電壓外加時(shí)經(jīng)過(guò)的時(shí)間
在這里線圈溫度若是上升, 如前面所述���, 線圈電阻在0.4%/℃下變大�, 線圈時(shí)間常數(shù)(L/R) 的R (線圈直流電阻) 也變大,因此接點(diǎn)的等待時(shí)間就縮短�����, 動(dòng)
作時(shí)間也在變快的方向上產(chǎn)生作用����。相反, 線圈電阻的增加引起線圈電流的減少���, 因此在電壓操作的繼電器中�����, 動(dòng)作時(shí)間反而變長(zhǎng)�。下圖表示關(guān)于電壓操作和
電流操作各自動(dòng)作時(shí)間相對(duì)于線圈溫度而發(fā)生的變化�。
如大型繼電器那樣動(dòng)作時(shí)間要花費(fèi)數(shù)10ms的繼電器���, 即使溫度變化�����, 也不會(huì)發(fā)生較大變化��, 在10ms以下的小型繼電器中可以看到溫度引起的變化的傾向��。
MY2NJ AC100/110 BY OMZ
MK3P-I
MK2P-I
MY2NJ AC110/120 BY OMZ
MY2NJ AC12 BY OMZ
MY2NJ AC200/220 BY OMZ
MY2NJ AC220/240 BY OMZ
MY2NJ AC24 BY OMZ
MY2NJ AC50 BY OMZ
MY2NJ AC6 BY OMZ
MY2NJ DC100/110 BY OMZ
MY2NJ DC12 BY OMZ
MY2NJ DC24 BY OMZ
MY2NJ DC48 BY OMZ
MY2NJ DC6 BY OMZ
MY4NJ AC100/110 BY OMZ
MY4NJ AC110/120 BY OMZ
MY4NJ AC12 BY OMZ
MY4NJ AC200/220 BY OMZ
MY4NJ AC220/240 BY OMZ
MY4NJ AC24 BY OMZ
MY4NJ AC48 BY OMZ
MY4NJ AC6 BY OMZ
MY4NJ DC100/110 BY OMZ
MY4NJ DC12 BY OMZ
MY4NJ DC24 BY OMZ
MY4NJ DC48 BY OMZ
MY4NJ DC6 BY OMZ
LY2NJ AC100/110 BY OMI
LY2NJ AC110/120 BY OMI
LY2NJ AC200/220 BY OMI
LY2NJ AC220/240 BY OMI
LY2NJ AC24 BY OMI
LY2NJ DC100/110 BY OMI
LY2NJ DC12 BY OMI
LY2NJ DC24 BY OMI
LY2NJ DC48 BY OMI
LY2NJ DC6 BY OMI
LY2NJ-D2 DC24 BY OMI
LY3NJ AC100/110 BY OMI
LY3NJ AC110/120 BY OMI
LY3NJ AC200/220 BY OMI
LY3NJ DC100/110 BY OMI
LY3NJ DC24 BY OMI
LY4NJ AC100/110 BY OMI
LY4NJ AC110/120 BY OMI
LY4NJ AC200/220 BY OMI
LY4NJ AC24 BY OMI
LY4NJ DC100/110 BY OMI
LY4NJ DC12 BY OMI
LY4NJ DC24 BY OMI
LY4NJ DC48 BY OMI
G2R-1 AC100/(110) BY OMB
G2R-1 AC110 BY OMB
G2R-1 AC12 BY OMB
G2R-1 AC120 BY OMB
G2R-1 AC200/(220) BY OMB
G2R-1 AC220
G2R-1 AC220 BY OMB
G2R-1 AC24 BY OMB
G2R-1 AC240 BY OMB
G2R-1 AC50 BY OMB
G2R-1 AC6 BY OMB
G2R-1 DC100 (Q)
G2R-1 DC110 BY OMB
G2R-1 DC12 BY OMB
G2R-1 DC24 BY OMB
G2R-1 DC48 BY OMB
G2R-1 DC5 BY OMB
G2R-14 AC100/(110) BY OMB
G2R-14 AC110 BY OMB
G2R-14 AC12 BY OMB
G2R-14 AC120 BY OMB
G2R-14 AC200/(220) BY OMB
G2R-14 AC220 BY OMB
G2R-14 AC230 BY OMB
G2R-14 AC24 BY OMB
G2R-14 AC240 BY OMB
G2R-14 AC50 BY OMB
G2R-14 AC6 BY OMB
G2R-14 DC12 BY OMB
G2R-14 DC18 BY OMB
G2R-14 DC24 BY OMB
G2R-14 DC48 BY OMB
G2R-14 DC5 BY OMB
G2R-14 DC6 BY OMB
G2R-14-H DC12 BY OMB
G2R-14-H DC24 BY OMB
G2R-14-H DC48 BY OMB
G2R-14-H DC5 BY OMB
G2R-14-H DC6 BY OMB
G2R-14-T130 DC12 BY OMB
G2R-14-U DC12
G2R-1A AC100/(110) BY OMB
G2R-1A AC110 BY OMB
G2R-1A AC12 BY OMB
G2R-1A AC120 BY OMB
G2R-1A AC200/(220) BY OMB
G2R-1A AC220 BY OMB
G2R-1A AC230 BY OMB
G2R-1A AC24 BY OMB
G2R-1A AC240 BY OMB
G2R-1A DC12 BY OMB
G2R-1A DC24 BY OMB
G2R-1A DC48 BY OMB
G2R-1A DC5 BY OMB
G2R-1A DC6 BY OMB
G2R-1A DC9 BY OMB
G2R-1A4 AC100/(110) BY OMB
G2R-1A4 AC12 BY OMB
G2R-1A4 AC120 BY OMB
G2R-1A4 AC200/(220) BY OMB
G2R-1A4 AC220 BY OMB
G2R-1A4 AC24 BY OMB
G2R-1A4 AC240 BY OMB
G2R-1A4 DC12 BY OMB
G2R-1A4 DC24 BY OMB
G2R-1A4 DC48 BY OMB
G2R-1A4 DC5 BY OMB
G2R-1A4 DC6 BY OMB
G2R-1A4-ASI DC12 BY OMB
G2R-1A4-H DC12 BY OMB
G2R-1A4-H DC24 BY OMB
G2R-1A4-H DC48 BY OMB
G2R-1A4-H DC5 BY OMB
G2R-1A4-H DC6 BY OMB
G2R-1A4-U DC48
G2R-1A-5 DC12 BY OMB
G2R-1A-ASI DC12 BY OMB
G2R-1A-ASI DC24 BY OMB
G2R-1A-ASI DC48 BY OMB
G2R-1A-ASI DC5 BY OMB
G2R-1A-ASI DC6 BY OMB
G2R-1A-E AC110 BY OMB
G2R-1A-E AC12 BY OMB
G2R-1A-E AC120 BY OMB
G2R-1A-E AC220 BY OMB
G2R-1A-E AC24 BY OMB
G2R-1A-E AC240 BY OMB
G2R-1A-E AC48 BY OMB
G2R-1A-E DC100
G2R-1A-E DC12 BY OMB
G2R-1A-E DC24 BY OMB
G2R-1A-E DC48 BY OMB
G2R-1A-E DC5
G2R-1A-E DC5 BY OMB
G2R-1A-E DC6 BY OMB
G2R-1A-E-5 DC12 BY OMB
G2R-1A-E-ASI AC100/(110) BY OM
G2R-1A-E-ASI AC240 BY OMB
G2R-1A-E-ASI DC12 BY OMB
G2R-1A-E-TU-5 DC24 BY OMB
G2R-1A-H DC12 BY OMB
G2R-1A-H DC24 BY OMB
G2R-1A-H DC48 BY OMB
G2R-1A-H DC5 BY OMB
G2R-1A-H DC6 BY OMB
G2R-1-ASI DC12 BY OMB
G2R-1-ASI DC24 BY OMB
G2R-1-ASI DC48 BY OMB
G2R-1-ASI DC5 BY OMB
G2R-1-ASI DC6 BY OMB
G2R-1A-T AC100/(110) BY OMB
G2R-1A-T DC12 BY OMB
G2R-1A-T DC24 BY OMB
G2R-1A-T130 DC24 BY OMB
G2R-1A-TV8-ASI DC12
G2R-1AZ DC12
G2R-1AZ DC24
G2R-1AZ4 DC12
G2R-1AZ4 DC24
G2R-1AZ4 DC48
G2R-1-E AC110 BY OMB
G2R-1-E AC120 BY OMB
G2R-1-E AC200 BY OMB
G2R-1-E AC220 BY OMB
G2R-1-E AC24 BY OMB
G2R-1-E AC240 BY OMB
G2R-1-E AC48 BY OMB
G2R-1-E DC100
G2R-1-E DC12 BY OMB
G2R-1-E DC24 BY OMB
G2R-1-E DC48 BY OMB
G2R-1-E DC5 BY OMB
G2R-1-E DC6 BY OMB
G2R-1-E-ASI DC24 BY OMB
G2R-1-E-T130 DC12 BY OMB
G2R-1-E-T130 DC24 BY OMB
G2R-1-H DC12 BY OMB
G2R-1-H DC24 BY OMB
G2R-1-H DC48 BY OMB
G2R-1-H DC5 BY OMB
G2R-1-H DC6 BY OMB
G2R-1-S AC110(S) BY OMB
G2R-1-S AC120(S) BY OMB
G2R-1-S AC230(S) BY OMB
G2R-1-S AC24(S) BY OMB
G2R-1-S AC240(S) BY OMB
G2R-1-S DC100(S) BY OMB
G2R-1-S DC110(S) BY OMB
G2R-1-S DC12(S) BY OMB
G2R-1-S DC24(S) BY OMB
G2R-1-SD DC12(S) BY OMB
G2R-1-SD DC24
G2R-1-SD DC24(N) BY OMB
G2R-1-SD DC24(S) BY OMB
G2R-1-SKVD DC24
G2R-1-SN AC100/(110)(N) BY OMB
G2R-1-SN AC100/(110)(S) BY OMB
G2R-1-SN AC110(S) BY OMB
G2R-1-SN AC120(S) BY OMB
G2R-1-SN AC220(S) BY OMB
G2R-1-SN AC230(S) BY OMB
G2R-1-SN AC24(S) BY OMB
G2R-1-SN AC240(S) BY OMB
G2R-1-SN DC100(S) BY OMB
G2R-1-SN DC110(S) BY OMB
G2R-1-SN DC12(S) BY OMB
G2R-1-SN DC24(S) BY OMB
G2R-1-SN DC48(S) BY OMB
G2R-1-SN DC6(S) BY OMB
G2R-1-SND DC100 (S) BY OMB
G2R-1-SND DC12(S) BY OMB
G2R-1-SND DC24(S) BY OMB
G2R-1-SND DC48(S) BY OMB
G2R-1-SNDI DC24(S) BY OMB
G2R-1-SNI DC24(S) BY OMB
G2R-1-S-T130 DC24(N) BY OMB
G2R-1-T AC100/(110) BY OMB
G2R-1-T AC110 BY OMB
G2R-1-T AC220 BY OMB
G2R-1-T130 DC24 BY OMB
G2R-1-TV8-ASI DC12 BY OMB
G2R-1Z AC240.
G2R-1Z DC12
G2R-1Z DC24
G2R-1-Z DC24
G2R-1Z4 DC24
G2R-1Z4 DC5
G2R-2 AC100/(110) BY OMB
G2R-2 AC110 BY OMB
G2R-2 AC12 BY OMB
G2R-2 AC120 BY OMB
G2R-2 AC200/(220) BY OMB
G2R-2 AC220 BY OMB
G2R-2 AC230 BY OMB
G2R-2 AC24 BY OMB
G2R-2 AC240 BY OMB
G2R-2 DC100 (Q)
G2R-2 DC100 BY OMB
G2R-2 DC110 (Q)
G2R-2 DC12 BY OMB
G2R-2 DC24 BY OMB
G2R-2 DC48 BY OMB
G2R-2 DC5 BY OMB
G2R-2 DC6 BY OMB
G2R-24 AC100/(110) BY OMB
G2R-24 AC110 BY OMB
G2R-24 AC12 BY OMB
G2R-24 AC120 BY OMB
G2R-24 AC200/(220) BY OMB
G2R-24 AC220 BY OMB
G2R-24 AC24 BY OMB
G2R-24 AC240 BY OMB
G2R-24 AC50 BY OMB
G2R-24 DC100
G2R-24 DC110 BY OMB
G2R-24 DC12
G2R-24 DC12 BY OMB
G2R-24 DC24
G2R-24 DC24 BY OMB
G2R-24 DC48
G2R-24 DC48 BY OMB
G2R-24 DC5
G2R-24 DC5 BY OMB
G2R-24 DC6
G2R-24 DC6 BY OMB
G2R-24-H DC6 BY OMB
G2R-24-Z DC12
G2R-2A AC100/(110) BY OMB
G2R-2A AC110 BY OMB
G2R-2A AC12 BY OMB
G2R-2A AC120 BY OMB
G2R-2A AC200/(220) BY OMB
G2R-2A AC220 BY OMB
G2R-2A AC24 BY OMB
G2R-2A AC240 BY OMB
G2R-2A AC6 BY OMB
G2R-2A DC100 (Q)
G2R-2A DC110 (Q)
G2R-2A DC12 BY OMB
G2R-2A DC24 BY OMB
G2R-2A DC48 BY OMB
G2R-2A DC5 BY OMB
G2R-2A DC6 BY OMB
G2R-2A DC9 BY OMB
G2R-2A4 AC100/(110) BY OMB
G2R-2A4 AC110 BY OMB
G2R-2A4 AC12 BY OMB
G2R-2A4 AC200/(220) BY OMB
G2R-2A4 AC220 BY OMB
G2R-2A4 AC24 BY OMB
G2R-2A4 AC240 BY OMB
G2R-2A4 AC50 BY OMB
G2R-2A4 AC6 BY OMB
G2R-2A4 DC12
G2R-2A4 DC24
G2R-2A4 DC24 BY OMB
G2R-2A4 DC48
G2R-2A4 DC5
G2R-2A4 DC6
G2R-2A4-ASI AC100/(110)
G2R-2A4-U DC24
G2R-2A-ASI DC12 BY OMB
G2R-2A-ASI-T130 DC24 BY OMB
G2R-2A-AUL DC12
G2R-2A-H DC12 BY OMB
G2R-2A-H DC24
G2R-2A-H DC24 BY OMB
G2R-2A-SKVD DC12
G2R-2A-T130 DC24 BY OMB
G2R-2-AUL DC48
G2R-2-H DC12
G2R-2-H DC24
G2R-2-H DC24 BY OMB
G2R-2-H DC48
G2R-2-H DC48 BY OMB
G2R-2-H DC5 BY OMB
G2R-2-H DC6
G2R-2-S AC110(S) BY OMB
G2R-2-S AC120(S) BY OMB
G2R-2-S AC200/(220)(S) BY OMB
G2R-2-S AC24(S) BY OMB
G2R-2-S AC240(S) BY OMB
G2R-2-S DC100(S) BY OMB
G2R-2-S DC110(S) BY OMB
G2R-2-S DC12(S) BY OMB
G2R-2-S DC24(N) BY OMB
G2R-2-S DC24(S) BY OMB
G2R-2-S DC5(S) BY OMB
G2R-2-SD DC100(S) BY OMB
G2R-2-SD DC12(S) BY OMB
G2R-2-SD DC24(N) BY OMB
G2R-2-SD DC24(S) BY OMB
G2R-2-SKVD AC220
G2R-2-SKVD DC12
G2R-2-SKVD DC24
歐姆龍繼電器有很多,具體有
:LYJ、MYJ系列���;
微型功率繼電器:G2R-口-S;G2A;
I/O繼電器:G7T;
小型功率繼電器:MK
終端繼電器:G6B,G6C,G6M,G6D,G6RN,G6S
功率繼電器:G7G,G7X
特殊動(dòng)作繼電器:G4Q,MYA,G9B
G2R-2-SN AC100/(110)(S) BY OMB
G2R-2-SN AC110(S) BY OMB
G2R-2-SN AC12(S) BY OMB
G2R-2-SN AC200/(220)(N) BY OMB
G2R-2-SN AC220(S) BY OMB
G2R-2-SN AC230(S) BY OMB
G2R-2-SN AC24(S) BY OMB
G2R-2-SN AC240(S) BY OMB
G2R-2-SN DC110(S) BY OMB
G2R-2-SN DC12(S) BY OMB
G2R-2-SN DC24(S) BY OMB
G2R-2-SN DC48(S) BY OMB
G2R-2-SN DC6(S) BY OMB
G2R-2-SND DC100(S) BY OMB
G2R-2-SND DC12(N) BY OMB
G2R-2-SND DC12(S) BY OMB
G2R-2-SND DC24(N) BY OMB
G2R-2-SND DC24(S) BY OMB
G2R-2-SND DC48(N) BY OMB
G2R-2-SND DC48(S) BY OMB
G2R-2-SND DC5(S) BY OMB
G2R-2-SNDI DC12(S) BY OMB
G2R-2-SNDI DC24(S) BY OMB
G2R-2-SNDI DC48(S) BY OMB
G2R-2-SNDI DC6(S) BY OMB
G2R-2-SNI AC110(S) BY OMB
繼電器上發(fā)生的故障中�, 多半是接點(diǎn)接觸性問(wèn)題所引起的�, 根據(jù)負(fù)載條件不同, 其故障內(nèi)容也有所不同。負(fù)載條件可大致分為微小能源· 水平(小功率電路) ��、
中間能源· 水平、高能源· 水平。
微小能源· 水平, 嚴(yán)格地來(lái)講稱為機(jī)械性接觸電路, 是指不會(huì)因熱����、放電等接點(diǎn)的接觸狀態(tài)而發(fā)生變化的負(fù)載條件�。但是在實(shí)際情況中���, 即使施加某種程度的電
壓�����, 由于接觸狀態(tài)不變化�, 因此包含其負(fù)載條件在內(nèi)��, 進(jìn)行定義。對(duì)接觸狀態(tài)不產(chǎn)生影響的界限電壓稱為接點(diǎn)軟化電壓(Softening Voltage)���, 銀為0.09V、金
為 0.08V���、鉑為0.25V��、鎢為0.6V�。
中間能源· 水平是指引起輕度放電現(xiàn)象的負(fù)載條件�, 從接點(diǎn)軟化電壓到電弧開(kāi)始放電的電壓。電弧開(kāi)始放電的電壓����, 銀為12V、金為15V��、鉑為17.5V�、鎢為15V,
10%的鈀銀合金為11V�����。
高能源· 水平是指電弧開(kāi)始放電電壓以上的電壓�。
有關(guān)接點(diǎn)的特殊問(wèn)題
接點(diǎn)根據(jù)使用方法會(huì)發(fā)生特殊現(xiàn)象。
G2R-2-SNI AC120(S) BY OMB
G2R-2-SNI AC230(S) BY OMB
G2R-2-SNI AC24(S) BY OMB
G2R-2-SNI DC24(S) BY OMB
G2R-2-T130 DC24 BY OMB
G2R-2-Z DC48
繼電器線圈在非工作狀態(tài)下暴露在高溫、高濕的環(huán)境中��, 而且線圈卷線和鐵芯等其他金屬之間有電位差時(shí)����,如果它們之間的絕緣不充分�, 兩者間流通的離子化電
流, 將可能腐蝕線圈上所卷的銅線�����。與在金屬上進(jìn)行電鍍的作用相同�,通過(guò)酸����、堿等,將可促進(jìn)該作用����。在以往的繼電器中, 往往忽視這種現(xiàn)象���, 但是最近在
卷軸材方面開(kāi)發(fā)出了特性較好的塑料�, 而且卷線的絕緣材也開(kāi)發(fā)出了聚氨酯類�����、聚脂、聚酰胺、特氟龍等特性優(yōu)良的材料�����, 減少了一部分危險(xiǎn)性��。要防止電氣腐
蝕�����,應(yīng)避免在高溫���、高濕中保管及使用�。在電路構(gòu)成方面應(yīng)注意開(kāi)關(guān)的位置����, 使其不在卷線上施加+電位, 需要考慮+接地等。
LY3NJ AC100/110 BY OMI 歐姆龍繼電器 歐姆龍繼電器資料 歐姆龍
LY3NJ AC100/110 BY OMI 歐姆龍繼電器 歐姆龍繼電器資料 歐姆龍
