IDAX300/350

IDAX300/350 - Analyseur de diagnosic d'isolement

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À propos du produit

Mesure et analyse automatique de la teneur en eau, facteur de puissance/tan delta et conductivité de l'huile
Température individuelle de correction du facteur de puissance/tan delta et de la conductivité de l'huile
Mesures 40% plus rapides avec le nouveau IDAX 5.0SW
Appareil de test multi-fonctions pour transformateurs
Résultats fiables dans des environnements perturbés
Technologie reconnue; les appareils IDA/IDAX sont utilisés sur le terrain depuis plus de 10 ans

Le IDAX300 est un appareil très compact utilisé avec ordinateur externe. Le IDAX350 a un ordinateur intégré mais peut également être utilisé avec un ordinateur externe.

Les appareils IDAX300 et IDAX350 assurent une évaluation précise et fiable de l'état de l'isolement des transformateurs, des traversées, des générateurs et des câbles. Le système IDAX maximise les résultats des activités de maintenance, ce qui permet d'optimiser son régime et sa durée de vie utile.

Les IDAX300 et IDAX350 sont plus petits, plus légers et plus rapides que leurs prédécesseurs IDAX200 et IDAX206. Leur précision est plus élevée et ils fournissent des données fiables, grâce à l'analyse de réponse en fréquence diélectrique, aussi connue sous le nom de spectroscopie de domaine en fréquence, pour des résultats fiables même avec de fortes interférences. Le logiciel de pointe rend les tests plus faciles et rapides, ce qui permet d'évaluer l'huile et la teneur en eau d'un transformateur en 22 minutes (20°c).

Caractéristiques techniques

Input voltage: 100 - 240 V, 50/60 Hz (±10%)
Max output current (AC): 50 mA peak
Max output voltage (AC): 200 V peak
Test type: Capacitance and dissipation/power factor

Pour en savoir plus, consultez la documentation technique

Dépannage

The display has the message, “Measured output voltage is outside specified limits” (error 347)

There are a few possible reasons and countermeasures for this:

1. The generator output is earthed/grounded.

You should:

Check the measurement setup and disconnect the ground.
Change the measurement configuration if you cannot disconnect the terminal of the test object from ground.

2. The generator output is connected to a measuring electrode (input or ground).

You should:

Check the measurement setup.
Disconnect measuring or guard electrodes from the generator output.
Don't connect the generator output to either measuring or guard electrodes.

3. High stray capacitances to ground are present or the test object has a high capacitance.

You should:

Lower the highest frequency used in measurement.
Lower the test voltage.

4. If you try to use an old version of the IDAX software (version 3.2 or earlier), but the firmware in the IDAX is for the IDAX software 4.0 or newer, the IDAX software does not understand the incapability and it usually results in error 347.

Please check the IDAX software and if you are using version 3.2 or earlier, upgrade to 4.0 or newer (this new software will automatically upgrade the firmware if necessary).

The display has the message, “Measured capacitances don’t match” (error 364)

Values of capacitance measured for different configurations are in disagreement. This includes the UST, GST-Guard, and GST-Ground. When performing a UST measurement, the measuring electrode is connected together with the ground electrode, or is connected to ground:

You should:

Check the measurement setup and make sure that the measuring electrode is connected to a non-grounded terminal of the test object and that the ground electrode is connected to ground.
Check cable connectors for damage.
Measure the resistance between the chassis and guard electrode. It should be 1.2 to 1.4 ohms. If resistance is lower than this, there is a short-circuit in the instrument.

The display has the message, “The specimen capacitance is below the limit” (error 365)

If the measured capacitance is below the limit specified in C-file by MinSpecimenC, then possible reasons and countermeasures include:

The measured capacitance is higher than 10 pF. However, the specimen size is very small which results in a low value of capacitance:
- Change the limit set by MinSpecimenC to an approximately 10 % lower value than the measured capacitance.
- Select another measurement configuration, if possible.
If the measured capacitance is lower than 10 pF, then most likely, there is no contact with the test specimen:
- Check connections with the specimen for loose contacts.
- Check the measurement cables for damage.

For more information of actual measured capacitance, please see Message Window.

The display has the message, “The specimen capacitance is above the limit” (error 366)

A measured capacitance above the limit specified in the test plan by MaxSpecimenC is usually due to the large size of a test object, resulting in high values of capacitance:

Change the limit set by MaxSpecimenC to an approximately 10 % higher value than the measured capacitance.
Select another measurement configuration, if possible.
A decrease in test voltage allows for measuring at higher frequencies

The display has the message, “The measured DC current > MaxDCCurrent” (error 367)

If the measured DC current exceeds the limits set in the test plan by MaxDCCurrent, then the most common reason is too low a resistance between the measurement electrode and guard. For example, measuring a UST configuration between high and low voltage windings of a two-winding transformer, the low voltage winding has too low an impedance to ground (inductive voltage transformer connected, internal damage of transformer, neutral connected to ground via a Peterson coil). For a GST measurement, the same applies to guard electrodes, i.e., a guard electrode with too low a resistance to ground may introduce DC currents.

Make sure that the floating electrode has a high resistance to ground. If that’s not possible, use another setup (e.g., measure to ground without use of guard).

It is possible to increase the limit level for DC current in the Measurement Template, but only when the difference is very small and all other possibilities are excluded.

The display has the message, “The measured hum current > MaxHumCurrent” (error 368)

If the measured interference or hum current exceeds the limits set in the test plan by MaxHumCurrent, then the level of interference is very high. Try to reduce the interference level by:

Disconnecting the still connected busbars that pick up interference.
Selecting another setup, e.g., a CHG+CHL is much less influenced by interference compared to CHG.
As a last option, it is possible to increase the limit for hum current in the Measurement Template.

Interprétation des résultats de test

General

Megger’s IDAX software provides an analysis of moisture content, oil conductivity, and temperature corrected, line frequency PF/DF test results. It is important that you supply the insulation temperature of the asset under test for an accurate assessment.

For a new transformer, the moisture content in the solid insulation is commonly targeted to be less than 0.5 % by weight. As the transformer gets older, the moisture content will typically increase around 0.05 % per year for a sealed conservator transformer and by approximately 0.2 % per year for free-breathing transformers. In an old and/or severely deteriorated transformer, the moisture content can be greater than 4 %. The graph below provides moisture interpretation criteria by Megger and different standards bodies. In agreement between them is that moisture content above 2 % in a transformer requires attention.

Recommended criteria for assessment of water, given by percent by weight, in the solid insulation of transformers.

These acceptance criteria are somewhat ‘broad-brush’. Generally, for higher voltage class transformers, less percentage moisture by weight contamination can be tolerated.

The criticality of addressing a wet transformer is also elevated when the transformer is excessively loaded. When coupled with exposure to higher temperatures, such as those resulting from overloading, the transformer insulation may age rapidly. In addition, moisture awareness is a critical data point for system operators who may otherwise unwittingly cause a transformer winding failure through emergency switching and loading, if these activities result in an increase in temperature that exceeds a wet transformer’s bubble inception temperature.