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變頻器日常維護(hù)過程中,經(jīng)常遇到各種各樣的問題,如外圍線路問題,參數(shù)設(shè)定不良或機(jī)械故障。如果是變頻器出現(xiàn)故障,如何去判斷是哪一部分問題,在這里略作介紹。
一、靜態(tài)測(cè)試
1、測(cè)試整流電路
找到變頻器內(nèi)部直流電源的P端和N端,將萬(wàn)用表調(diào)到電阻X10檔,紅表棒接到P,黑表棒分別依到R、S、T,應(yīng)該有大約幾十歐的阻值,且基本平衡。相反將黑表棒接到端,紅表棒依次接到R、S、T,有一個(gè)接近于無(wú)窮大的阻值。將紅表棒接到N端,重復(fù)
以上步驟,都應(yīng)得到相同結(jié)果。如果有以下結(jié)果,可以判定電路已出現(xiàn)異常,A.阻值三相不平衡,可以說明整流橋故障。B.紅表棒接P端時(shí),電阻無(wú)窮大,可以斷定整流橋故障或起動(dòng)電阻出現(xiàn)故障。
2、測(cè)試逆變電路
將紅表棒接到P端,黑表棒分別接U、V、W上,應(yīng)該有幾十歐的阻值,且各相阻值基本相同,反相應(yīng)該為無(wú)窮大。將黑表棒接到N端,重復(fù)以上步驟應(yīng)得到相同結(jié)果,否則可確定逆變模塊故障.
二、動(dòng)態(tài)測(cè)試
在靜態(tài)測(cè)試結(jié)果正常以后,才可進(jìn)行動(dòng)態(tài)測(cè)試,即上電試機(jī)。在上電前后必須注意以下幾點(diǎn):
1、上電之前,須確認(rèn)輸入電壓是否有誤,將380V電源接入220V級(jí)變頻器之中會(huì)出現(xiàn)炸機(jī)(炸電容、壓敏電阻、模塊等)。
2、檢查變頻器各接播口是否已正確連接,連接是否有松動(dòng),連接異常有時(shí)可能導(dǎo)致變頻器出現(xiàn)故障,嚴(yán)重時(shí)會(huì)出現(xiàn)炸機(jī)等情況。
3、上電后檢測(cè)故障顯示內(nèi)容,并初步斷定故障及原因。
4、如未顯示故障,首先檢查參數(shù)是否有異常,并將參數(shù)復(fù)歸后,進(jìn)行空載(不接電機(jī))情況下啟動(dòng)變頻器,并測(cè)試U、V、W三相輸出電壓值。如出現(xiàn)缺相、三相不平衡等情況,則模塊或驅(qū)動(dòng)板等有故障
5、在輸出電壓正常(無(wú)缺相、三相平衡)的情況下,帶載測(cè)試。測(cè)試時(shí),最好是滿負(fù)載測(cè)試。
三、故障判斷
1、整流模塊損壞
一般是由于電網(wǎng)電壓或內(nèi)部短路引起。在排除內(nèi)部短路情況下,更換整流橋。在現(xiàn)場(chǎng)處理故障時(shí),應(yīng)重點(diǎn)檢查用戶電網(wǎng)情況,如電網(wǎng)電壓,有無(wú)電焊機(jī)等對(duì)電網(wǎng)有污染的設(shè)備等。
2、逆變模塊損壞
一般是由于電機(jī)或電纜損壞及驅(qū)動(dòng)電路故障引起。在修復(fù)驅(qū)動(dòng)電路之后,測(cè)驅(qū)動(dòng)波形良好狀態(tài)下,更換模塊。在現(xiàn)場(chǎng)服務(wù)中更換驅(qū)動(dòng)板之后,還必須注意檢查馬達(dá)及連接電纜。在確定無(wú)任何故障下,運(yùn)行變頻器。
3、上電無(wú)顯示
一般是由于開關(guān)電源損壞或軟充電電路損壞使直流電路無(wú)直流電引起,如啟動(dòng)電阻損壞,也有可能是面板損壞。
4、上電后顯示過電壓或欠電壓
一般由于輸入缺相,電路老化及電路板受潮引起。找出其電壓檢測(cè)電路及檢測(cè)點(diǎn),更換損壞的器件。
5、上電后顯示過電流或接地短路
一般是由于電流檢測(cè)電路損壞。如霍爾元件、運(yùn)放等。
6、啟動(dòng)顯示過電流
一般是由于驅(qū)動(dòng)電路或逆變模塊損壞引起。
7、空載輸出電壓正常,帶載后顯示過載或過電流該種情況一般是由于參數(shù)設(shè)置不當(dāng)或驅(qū)動(dòng)電路老化,模塊損傷引起。
In the daily maintenance process of frequency converter, we often encounter a variety of problems, such as peripheral circuit problems, poor parameter setting or mechanical failure. If the frequency converter fails, how to determine which part of the problem is briefly introduced here.
1、 Static test
1. Test rectifier circuit
Find the p-terminal and N-terminal of the DC power supply inside the converter, adjust the multimeter to the resistance X10, connect the red meter rod to the P, and press the black meter rod to the R, s and t respectively, which should have a resistance value of about tens of ohms and be basically balanced. On the contrary, connect the black meter rod to the end, and connect the red meter rod to R, s and t successively, with a resistance value close to infinity. Connect the red indicator rod to the N end, repeat
All the above steps should get the same result. If there are the following results, it can be determined that the circuit has been abnormal. A. the three-phase imbalance of resistance value can indicate the fault of rectifier bridge. B. When the red meter bar is connected to the p-terminal, the resistance is infinite, so it can be concluded that the rectifier bridge is faulty or the starting resistance is faulty.
2. Test inverter circuit
Connect the red meter rod to the P end, and connect the black meter rod to the U, V and W respectively. There should be several tens of ohm resistance values, and the resistance values of each phase are basically the same, and the reverse phase should be infinite. Connect the black meter bar to the N terminal, repeat the above steps to get the same result, otherwise the inverter module fault can be determined
2、 Dynamic test
After the static test results are normal, the dynamic test can be carried out, that is, power on the test machine. Pay attention to the following points before and after power on:
1. Before power on, it is necessary to confirm whether the input voltage is wrong. If the 380V power supply is connected to the 220V frequency converter, there will be explosion (explosion capacitance, varistor, module, etc.).
2. Check whether the connectors of the frequency converter have been connected correctly, whether the connection is loose, and if the connection is abnormal, the frequency converter may sometimes fail, or even explode.
3. After power on, detect the fault display content and preliminarily determine the fault and cause.
4. If no fault is displayed, first check whether the parameters are abnormal, and reset the parameters, start the inverter under no-load (without motor), and test the output voltage of u, V, w three-phase. In case of phase loss, three-phase imbalance, etc., the module or drive board is faulty
5. Under the condition that the output voltage is normal (no phase loss, three-phase balance), carry out on load test. When testing, it is best to test at full load.
3、 Fault judgment
1. Rectifier module damaged
Generally, it is caused by grid voltage or internal short circuit. Replace the rectifier bridge when the internal short circuit is eliminated. When dealing with faults on site, it is important to check the power grid of users, such as the power grid voltage, whether there are welding machines and other equipment that pollute the power grid.
2. Inverter module damaged
Generally, it is caused by motor or cable damage and drive circuit failure. After repairing the driver circuit, replace the module when the driver waveform is in good condition. After replacing the drive board in the field service, the motor and connecting cable must also be checked. Run the frequency converter without any fault.
3. No display when power on
Generally, it is caused by the damage of switching power supply or soft charging circuit, which makes the DC circuit free of DC. If the starting resistance is damaged, it may also be panel damage.
4. Overvoltage or undervoltage displayed after power on
Generally, it is caused by input phase loss, circuit aging and circuit board damp. Find out the voltage detection circuit and detection point, and replace the damaged device.
5. Over current or short circuit to ground after power on
Generally, the current detection circuit is damaged. Such as hall element, operational amplifier, etc.
6. Start display overcurrent
Generally, it is caused by the damage of driving circuit or inverter module.
7. No load output voltage is normal, overload or over-current will be displayed after load, which is generally caused by improper parameter setting or aging of driving circuit and module damage.