ODEN AT primary current injection test system
Modular and configurable
Modular design to permit optimal user configuration of output current versus unit size and weight; if the testing scope changes, the user can add extra current units to expand capabilities
Compact and portable
Compact transport cart facilitates portability into switchgear rooms with limited space; the control unit and current units can be quickly removed and reattached to transport easily through tight corridors
Unique I/30 function
The I/30 function allows the current to be pre-set using a low current to prevent tripping the circuit breaker on its thermal setting when testing the instantaneous characteristic
Über das Produkt
- Die einzigartige l/30-Funktion ermöglicht die Vorabeinstellung des Prüfstroms auf die Bürde mit kleinen Strömen
- Modularer Aufbau für optimale Konfiguration des Ausgangsstroms im Vergleich zur Gerätegröße
- Erleichtert die Inbetriebnahme von Schaltanlagen, Stromwandlern und Leistungsschaltern mit Überstromauslösern
- Kompakter Transportwagen für kleine Schutzschalterräumen
Für effiziente Primärprüfungen
Das leistungsstarke Primärprüfsystem ODEN dient zur Primärprüfung von Schutzrelaiseinrichtungen und Leistungsschaltern. Außerdem kann es zum Prüfen der Übersetzungsverhältnisse von Stromwandlern und sonstigen Anwendungen, die hohe Ströme benötigen, einsetzt werden. Die einzigartige l/30-Funktion ermöglicht es, den Strom im Voraus auf „Niedrigstrom“ einzustellen, wodurch ein Erhitzen der Messprobe und somit auch eine Verfälschung der Testergebnisse verhindert wird
Drei Versionen verfügbar
Das Primärprüfsystem besteht aus einer Steuereinheit, die zusammen mit einer, zwei oder drei Transformatoreinheiten verwendet wird. Es stehen folgende Ausführungen bei den Transformatoreinheiten zur Wahl: Typ S, Typ X und Typ H. Die Transformatoreinheiten S und X sind identisch mit Ausnahme, dass die Einheit X über einen zusätzlichen 30/60 V Ausgang verfügt. Die Transformatoreinheit H ist sogar für höheren Strom bemessen. So kann ein ODEN System auf geeignete Art konfiguriert werden. Alle Teile sind tragbar und ODEN kann rasch zusammengebaut und angeschlossen werden.
Weitere Lektüre und Webinare
Verwandte Produkte
Fehlerbehebung
There are three possible causes for this:
- Check the miniature circuit breaker (F2); flip the switch to fully off, then back on.
- Overheating may have triggered the thermal protection. This will reset itself automatically after the ODEN AT cools down.
- There is an interrupted circuit.
- Check the connections to the object you are testing. If you are testing a breaker, check that it is closed.
- Check the connection between the control unit and the current unit.
- For series connection, check that a series connection cable is being used and is connected correctly.
Either the fuse (F1) has blown, which you can locate on the left side of the control unit, or there is no mains power. Check that you have plugged the mains cable in correctly and that mains voltage is present.
- Check if the stop condition is set to INT and F2 is off. Close F2.
- Check if the stop condition is set to INT and if the output circuit is open.
- Change the stop condition or close the output circuit.
- If the output current is just a small percentage of the measurement range, either increase the current, decrease INT-level, or use range or output with a lower current rating.
You need to calibrate the zero offset.
- Disconnect all current units from the control unit and make sure the input for ammeter 2 is open.
- Short the voltmeter input.
- Press the “SYSTEM” button.
- Simultaneously press the “ESC” and “ENTER” buttons and quickly turn the “CHANGE” knob clockwise until “CALIBRATION” appears; press “ENTER”.
- Choose “0 DC OFFSET” and press “ENTER”.
- Wait until the relays stop clicking, then press “ENTER” again.
- Press “ESC” twice to leave the calibration menu.
- Disconnect the cable on the shorted voltmeter.
There are several causes for this:
- The settings in the output block on the control panel need to be corrected.
- Select “HIGH I” if you are using the high current output.
- Select 0-30/60 V if you are using the low current output on a type X current.
- Select “PARALLEL” if you have the current units connected in parallel or only one current unit connected.
- Select “SERIES” if you have the current units connected in series.
- “SERIES” is selected in the “OUTPUT” block, and unused current units are connected to the control unit. Disconnect unused current units.
- “ODEN AT” is set for DC Measurement while AC is generated. (Fault will be approx. 10 %) - DC measurements shall only be activated if you have equipped the ODEN AT with a DC box. Select the proper setting for DC Measurement (submenu system).
- The test object has a higher impedance than expected. Increase the voltage applied from ODEN AT by connecting the current units in series or use the low current output if you have a type X current unit.
There is a high inrush current due to remanence. To remedy this:
- Disconnect all current units.
- Set the “FINE” knob in the “CURRENT ADJUST” block to 40 %.
- Press “ON+TIME” and turn the knob up to 100 % and then down to 0 %.
- Connect one current unit. No load should be connected to it.
- Press “ON+TIME” and set the “FINE” knob to 100 %.
- Slowly increase the “COARSE” adjustment to its maximum.
- Press “OFF” and set the “COARSE” and “FINE” adjustments to 0.
- Connect the next current unit without any load connected and repeat the procedure from step 5.
Note: If the problem appears at step 6, try loading some current from the unit. If the problem occurs at step 6 for the second and third current units, proceed with only the newly added current units connected.
You have selected 0-30/60 V in “OUTPUT” to measure current from the low current output, and there is no low-current output on the current unit. You should cancel the 0-30/60 V setting or connect a current unit with a low-current/high voltage output.
In “OUTPUT", you opted to measure current from the 0-30/60 V low current output when the switches on the current units are set differently. Make sure all the switches on the current units have the same settings.
Ensure that you have connected current units of the same type.
The instrument is not activated. Activate the instrument in the “V/A-METER” menu option if its indicator lamp is not lit.
The stop condition is met, but “AUTO OFF” is not activated. Press “RESET” if you want the generation time displayed.
The measurement time needs to be longer, the “HOLD" function cannot present any frozen readings, or there needs to be more time for a range to be selected automatically. Either increase the measurement time or select a fixed range.
The magnitudes of the input signals are too great for the fixed preset range, or the “AUTO” range does not have enough time to function properly for high speed cycles. (“OF” = Overflow). Repeat the measurement or select a fixed range.
No ratio can be calculated because the measurement current is 0. Generate current to resolve this.
The ammeter cannot present measured values for the generated current because different current units are connected, or the current unit is unknown because it is not calibrated. Verify that all current units are of the same type or, if needed, calibrate the current unit(s).
Increase the INT-level, or use a range or output with a higher current rating.
Some manufacturers equip circuit breakers with a ground fault sensor that detects a phase imbalance or current flowing through the ground circuit. The ground fault sensor must be disabled to perform the standard trip tests of long time, short time, and instantaneous trip tests.
Auswertung der Prüfergebnisse
Proper primary injection testing of low voltage circuit breakers (LVCB) will confirm that they trip at the correct times and can properly isolate a fault. A coordination study is performed, and parameters are set to minimise the amount of interruption to other equipment. The characteristics of the circuit breakers are presented in the form of trip curves, and each circuit breaker will have a unique trip curve published by the manufacturer. The trip curves will have bands, or limits, that show how long it takes for the circuit breaker to trip when a certain amount of current is applied; the current is typically presented in multiples of the rated current. As long as the circuit breaker trips within the specified band, it operates correctly. You may perform up to four primary injection test types to verify that the LVCB is working correctly: a long time test, short time test, instantaneous test, and earth/ground fault test. The long, short, and ground fault tests all have a delay component. In contrast, the instantaneous test trips the circuit breaker immediately.
The long time test is a test of the overload function and requires two settings. The first setting is the pickup, which determines the load current level that is tolerable before an overload condition occurs. The second setting is the time delay that determines how long the overload condition is acceptable. Systems are generally designed to handle overload conditions for a short time. Still, damage will occur if the overload persists for too long. You typically perform a long time test at 3 times the rated current.
The short time test is also an overload test with a pickup time like the long time test but has a shorter duration with a higher current. Typical currents are at 6 times the rated current. A short time setting on the breaker is used to allow high current loads for a short duration, for example, a motor starting.
The instantaneous trip conditions test the breaker under fault conditions. Therefore, there is no intentional time delay built in, and the breaker should trip within milliseconds. If the circuit breaker fails to trip and clear the fault, this may result in damage to equipment or personnel. Additionally, an upstream breaker may need to clear the fault, resulting in other electrical system components unrelated to the fault being shut down. An instantaneous trip is typically tested using 8 to 12 times the rated current.
An earth/ground fault trip in the circuit breaker occurs when higher-than-normal currents flow through the ground path. Like the long time and short time functions, the ground fault has both a pickup current and a delay time. Both can be adjusted to fit the coordination study. There is typically a maximum delay that is permitted from ground fault conditions.
Each test is performed separately for each phase. As long as the trip time falls between bands on the time-current curves, the circuit breaker is considered to be in working condition.
Note: the ground fault sensor must be disabled to test long, short, and instantaneous trips.