EZ-Thump 12 kV, model v3, cable fault location system
Lightweight for ultimate portability
Weighing less than 33 kg, it is the most compact cable fault location on the market
Battery and AC mains/line operated
Battery and AC line operation, with a field-replaceable battery, enables simultaneous AC operation and battery charging
High and low resistance pre-location
Integrated TDR for low resistance faults and Arc Reflection Method (ARM) for high resistance faults
Precise pinpointing of faults
A single-stage capacitor surge discharge delivers 500 J at 12 kV. An acoustic/electromagnetic receiver provides ‘thunder and lightning’ pinpointing
About the product
The EZ-Thump 12 kV, model v3, cable fault location system makes fault finding on underground MV power cables easier than ever! This all-in-one fault locator has been designed specifically to be readily transportable – it will fit into an average-sized car – and easy to operate, even for inexperienced users. The EZ-Thump 12 kV is an ideal choice for first responders and its extensive capabilities make it well-suited to more demanding applications.
The EZ-Thump 12 kV incorporates a single-stage capacitor surge discharge system that delivers 500 J at 12 kV. An integrated time-domain reflectometer (TDR) facilitates the pre-location of low resistance faults and, by using the Arc Reflection Method (ARM), high resistance faults. In addition, the EZ-Thump 12 kV can be used in conjunction with an acoustic/electromagnetic receiver, such as the DigiPhone 2, to pinpoint the precise location of faults. Sheath testing and sheath fault location are also supported.
The instrument includes advanced safety features as standard, such as the F-OHM system that automatically checks that earth/ground connections have been made correctly and, if detects a problem, will inhibit testing. It also has an emergency stop function and a key-switch safety interlock.
All of the instrument’s functions are controlled with a single rotary knob and the test results are shown on a bright colour display that is easy to read even in bright sunlight. No settings are needed when the instrument is used in automatic mode; users connect the test set to the cable and switch it on. The cable end and the fault location are then automatically detected and displayed. More experienced users can access expert mode to optimise results in particularly challenging applications.
Lightweight and exceptionally compact, the EZ-Thump 12 kV can be powered either from an AC mains supply or its internal rechargeable battery. These features mean you can use the EZ-Thump in any location, even where access is difficult and no mains supply is available. The internal battery is designed to have a long operating life, but when replacement eventually becomes necessary, you can do so in the field.
Technical specifications
- Power source
- AC line
- Power source
- Battery
- Test type
- Portable cable fault location
FAQ / Frequently Asked Questions
There are many techniques, including:
Basic tests
- DC test to determine flashover voltage
- Sheath fault test
- VLF test to determine flashover voltage
Pre-location
- Pulse reflection measurements
- TDR measurements
- ARM (arc reflection method)
- ARM Plus
- ARM power burning
- Decay plus (ARM – igniting the fault using a dc generator)
- Decay (travelling wave method, oscillation method)
- Current catching (ICE)
- Three-phase current catching (ICE)
- ICE Plus (low-voltage networks only)
- High voltage bridge method (pre-locating sheath faults)
- Voltage-drop method (pre-locating sheath faults)
Fault conversion
- Burning
- Performance burning
Route tracing
- Line location
- Line routing
Pinpointing
- Audio frequency generator
- Shock discharges (acoustic field method, acoustic pinpointing)
- Pinpointing sheath fault
Cable and phase identification
- Phase identification earthed
- Phase identification and phase determination on live systems
There are five stages in determining cable fault locations:
- fault classification – identifying the type of fault
- pre-location – determining the distance to the fault
- route tracing – determining the route of the cable
- pinpointing – identifying the exact position of the fault
- cable identification – identifying which of several cables is faulty
If you can charge the cable, you can ‘thump’ it, and that’s exactly what the pinpointing function of the EZ-Thump does. Accurate pinpoint fault location of the typical high-resistance/flashover faults is achieved using the ‘thunder and lightning’ method, whereby the 500 J surge generator (thumper) and an acoustic/electromagnetic receiver are used.
The EZ-Thump weighs just 33 kg and is compact enough to fit inside an average-sized car. It’s ideal for difficult-to-reach locations, such as rural and inner city areas, because you can easily transport it.
The maximum circuit length that the EZ-Thump can test depends on the cable type, but as a rule of thumb, we generally say 3 km - giving 1.5 km for either end. In some circumstances, it can do more.
After you have confirmed the exact fault location by pinpointing, you must excavate the cable so that the fault can be confirmed visually. The fault is sometimes evident because of external signs such as cracks, breaks, burning, and general damage. However, there may often be no visible damage with the fault contained inside an apparently sound cable.
Pinpointing is the identification of the fault’s exact location. Pinpointing is carried out directly over the cable. The most common technique relies on detecting acoustic and electromagnetic signals emitted at the fault location when the cable is being surged by a surge generator (thumper). A sensitive ground microphone and electromagnetic pickup, used in conjunction with an amplifier, detect these signals.
Pre-location is used to indicate the distance to the fault. While modifying the fault to create conditions more suitable for a particular pre-location technique may occasionally be necessary, it is always best to pre-locate the fault with conditions as found. Several recognised methods of pre-location assist rapid, accurate, and safe location of faults. These include:
- Pulse echo (low voltage pre-location)
- Arc reflection (high voltage pre-location)
- Arc Reflection Plus (ARP)
- Differential Arc Reflection (DART)
- Impulse current (high voltage pre-location)
- Voltage decay (high voltage pre-location)
The results obtained with these techniques will allow the approximate location of the fault to be determined. Still, the accuracy of the results is affected by many factors, including changes in cable types, cable size, and joints, which affect the velocity factor of the cable under test. The lay of the cable is a vital factor as any results obtained with pre-location relate to the actual length of the physical cable, which may be very different from the length of the cable route!
Perhaps not from a theoretical point of view, but from a real-world point of view, the TDR should fit the cable/application.
Old paper-lead cables pose a big challenge when fault locating due to their different physical construction compared to modern solid dielectric cables. Instead of having to deal with carbon and air like in faulted XLPE- or EPR-insulated cables, PILC cables are made of lapped paper impregnated with mass or oil.Breaking down a fluid insulation medium, igniting and stabilising an arc in a fluid, and capturing useful fault traces with the radar is all far more difficult on paper cables than on solid dielectric cables. In particular, breakdown voltages of high resistance faults may be very high, and low resistance faults do occur significantly more often.To be truly effective on paper-lead cables, the fault location system used must have a high DC hipot, sufficient energy for cap discharge, and a modern TDR. With its 40 kV DC hipot, 2000 Joules at 32 kV and a radar with Multishot and de-attenuation features, the STX40 is well-equipped to be successful in finding faults even on PILC cables.
Occupational safety and safe working conditions are paramount for us and our customers. Therefore, Megger products are designed to be the safest in the market. The STX40 is no exception.The unit meets the strict requirements of VDE 0104. Equipped with a ground loop monitoring circuit (F-Ohm) and a touch potential monitoring circuit (F-U or F-Voltage), STX40 is a milestone and is the portable fault location system with the highest safety standards in the market by far.
Further reading and webinars
Related products
Troubleshooting
It’s possible that your EZ-Thump 12 kV was damaged in transit, for example, by being thrown off a truck. While events like that should not happen, unfortunately mishandling is common because the units are heavy and bulky. The units look robust, and indeed they are, but there are limits. There is sensitive circuitry on board that may need replacement. Please return the instrument to the Megger Repair Department.
The test unit may have been connected to a live line. You can only operate this unit on de-energised lines, otherwise the resulting extensive damage may necessitate component replacement. Please return the instrument to the Megger Repair Department.
Interpreting test results
The sectionalising technique is used to troubleshoot single-phase medium voltage (MV) distribution loop circuits and identify a faulted section so that you can quickly switch it out, re-energise the rest of the circuit, and keep the power outage to a minimum. The advantage is that you can identify the faulted section working from one set-up point without going from transformer to transformer to either remove the fuses or to sand the elbows off at each transformer.
For this purpose, a low voltage (LV) reflection image is taken and scanned for impedance changes related to the cable end and the transformers. The latter ones indicate the location of the transformers. A second reflection image of a TDR pulse is taken while an electrical arc is ignited by a sudden discharge of the charged capacitor at the fault location.
By lying both traces on each other, the fault location (where the two traces diverge) is identified. The transformers' reflections provide landmarks to identify the faulted cable segment. You will switch out the faulty segment by pulling the elbows to the left and right sides of the fault. Service to all customers is provided by closing the normally open point within the distribution loop.
Determining the faulted section
An LV pulse is fed into the cable. The reflection image is processed by the transformer identification software. After a few seconds, the reference trace shows the distance to the cable end.
The red fault trace is shown in the display if a voltage breakdown occurs. The red fault marker is automatically set to the position where both traces diverge. The fault is referenced by the two closest transformers, identifying the cable section containing the fault.
Verifying a faulted cable section
The hi-pot test, within the context of sectionalising, is done to confirm that the section of cable identified as faulted during the preceding sectionalising procedure is actually faulted. Perform a hi-pot test after the identified cable section has been isolated at the two closest transformers.
Note: you must not perform a DC hi-pot test with the transformers still connected to the faulted cable section.
During the rise in voltage, the display will show the maximum charging current of the High Voltage Power Supply (HVPS) until the cable is fully charged. Once this occurs, the current will drop to the actual leakage current level. The insulation resistance is displayed. This scenario is observed if the cable has no insulation breakdown. If a flashover breakdown occurs, the high voltage will be shut off.
Depending on whether or not a breakdown takes place during the test, the display will present one of the following results:
- Breakdown at XX kV - A voltage breakdown occurred at the indicated test voltage.
- No flashover - The cable has withstood the applied DC test voltage. If possible, repeat the test with a higher voltage (do not exceed the maximum permissible voltage).
- Cable not chargeable - The test voltage could not charge the cable. This scenario is typically due to a short (fault) in the cable, creating maximum current output.
- Low resistance at XX kV - Due to the substantial leakage current level, the HV source cannot charge the cable beyond the indicated voltage value.
A hi-pot/breakdown test is used to test the dielectric strength of a cable under DC HV conditions and, in cases where the cable fails, it provides the breakdown voltage.
During the voltage rise, the display will show the maximum current of the HVPS until the cable is fully charged. Once this occurs, the current will drop to the actual leakage current level. The insulation resistance is displayed. This scenario is observed if the cable has no insulation breakdown. Otherwise, the high voltage will be shut off when the flashover/breakdown occurs.
Determining the dielectric strength of the cable
Depending on whether a breakdown takes place during the test,
the display will present one of the following results:
- Breakdown at XX kV - A voltage breakdown took place at the indicated test voltage, meaning there was a flashover at the fault.
- No flashover - The cable has withstood the applied DC test voltage. In this case, no current will be indicated. If required, repeat the test with a higher voltage (do not exceed the maximum permissible voltage).
- Cable not chargeable - The test voltage could not charge the cable. This scenario typically occurs when a short circuit condition is present in the cable (zero voltage and max current).
- Low resistance at XX kV XX MΩ - The HV source cannot charge the cable beyond the indicated voltage value due to a substantial leakage current level; this suggests the presence of a very low resistance fault (some voltage and high current). You must not interpret the voltage indication as the flashover voltage. Given the high leakage current, it is merely the voltage that the HVPS can build.
The EZ-Thump applies the widely approved and well-known ARM to pre-locate a high resistance MV cable fault.
Locating the fault is accomplished by comparing a reflection image (impedance) taken with an LV pulse (reference trace) to a reflection image (impedance) taken when an arc, ignited by the sudden discharge of the charged capacitor, was present at the fault location (fault trace). With this method, the two measured traces diverge at the position where the arc causes a negative reflection (impedance change) of the TDR pulse, indicating the fault location.
You can use the thumping mode to pinpoint a high resistance fault between a phase conductor and the neutral conductor of an MV cable; between two phase conductors of a 'belted' MV cable; between two phase conductors of an LV cable, or between the phase conductor and earth/ground of an LV cable.
The EZ-THUMP provides an internal surge generator to continuously feed high voltage pulses into the defective cable, producing a flashover (arcing) at the fault position. You can pinpoint the fault using a magnetic/acoustic detector (such as the digiPHONE+) for best results or with a simple acoustic detector with distinct and well understood limitations. The criterion for pinpointing with a simple acoustic detector is the greatest loudness of the flashover noise at the fault location or, in the case of a magnetic/acoustic measurement, the smallest propagation time difference between the speed of light and speed of sound, where it is not the loudest sound, but the first after receiving magnetic signal. The latter is more accurate and can be used in all high resistance fault situations and even for pinpointing faults in conduits.
The insulation of any high or medium voltage shielded power cable is protected from water ingress by a jacket made from XLPE or PVC. The sheath test checks if the jacket's integrity has been compromised, typically during installation.
With a sheath test, you can test the dielectric strength of the cable jacket by applying a DC voltage of up to 5 kV between the cable shield (concentric neutral) and ground. Any leakage indicates a fault in the jacket. During the voltage rise, the display will show the maximum current of the HVPS until the cable is fully charged. Once this occurs, the current will drop to the leakage current level. The insulation resistance is then displayed. This scenario is observed if the cable has no insulation breakdown. Otherwise, the high voltage will be shut off when the flashover/breakdown occurs.
Depending on whether a breakdown takes place during the test, the display will present one of the following results:
- Breakdown at XX kV - A voltage breakdown occurred at the indicated test voltage.
- No flashover - The cable jacket has withstood the applied DC test voltage. The test can be repeated using the menu item.
- Cable not chargeable - The test voltage could not charge the cable shield. This scenario typically occurs when a short circuit condition is present in the circuit (fault in the jacket).
- Low resistance at XX kV XX MΩ - The HV source cannot charge the cable beyond the indicated voltage value due to a substantial leakage current level; this suggests the presence of a very low resistance fault (some voltage and high current). You must not interpret the voltage indication as the flashover voltage. Given the high leakage current, it is merely the voltage that the HVPS can build.
You should follow a failed sheath test with fault locating the sheath fault (in direct buried cables). The test method is based on the step voltage method (earth gradient method). You can perform this with any EZ-Thump serving as an HV pulse generator (limited to 5 kV). An additional receiver is required to read the strength and polarity of the earth gradient voltage (e.g., Megger ESG-NT or Digiphone+2 ) to pinpoint the sheath fault.
When approaching the fault position, the step voltage increases quickly and decreases to a zero reading directly over the fault and then will swing to a substantial voltage of the opposite polarity when going past the fault.
User guides and documents
Software and firmware updates
ETray Software
ETray software update warning - applies to T3090, EZ-RESTORE, EZ-THUMP AND SMART-THUMP:
Prior to updating the affected products to software version 2.5.2/0.43 or later, you must first consult the factory via the contact information provided below to determine if your instrument hardware can support the upgrade. Failure to consult the factory prior to performing software upgrades could leave your instrument in a state that will require it to be sent in for repair. Please have the following information ready before you call:
- Instrument model and serial number
- ETray Hardware revision which is determined by using the 'ETray revision software' located below.
Contact Us - Customer Service: 1-800-723-2861
FAQ / Frequently Asked Questions
Arc Reflection Method (ARM) is ideal for MV URD type power cables. However, you can use ARM on other class cables. In essence, what’s required is simply a shielded cable. Megger offers ARM units that operate at 3 to 4 kV maximum output for lower voltage class shielded cables.
None that we are aware of, particularly when dealing with MV power cables.
Such an occurrence can happen, particularly with high resistance faults. Often, the best solution is to use the arc reflection method of fault location. This test method involves sending a high voltage pulse down the cable, which causes a temporary arc at the site of the fault. The arc is sustained briefly by a filter built into the arc reflection test set. Because of its low impedance, the arc looks like a short-circuit fault that can be localised with a TDR. However, the time interval between the high voltage pulse and the TDR pulse is critical to obtain good results.
For this reason, Megger has pioneered a method known as ARM(R). With this, not one but fourteen TDR pulses are automatically sent along the cable at varying time intervals after the high voltage pulse. The resulting TDR traces are recorded separately. In almost every case, one of these will clearly show the distance to the fault.
From a practical point of view, no, ARM would not cause more damage to a faulted 69 kV class cable. Remember, ARM pre-locates the fault with one or so impulses. This pre-location distance reduces the number of thumper impulses required to pinpoint the fault.
A paper examining the effects of thumping is Hartlein, R.A., et al., “Effects of voltage surges on extruded dielectric cable life project update,” IEEE Transactions on Power Delivery (Vol 9, Iss 2), 1994.
The far end is never grounded while thumping or doing single ARM shots, regardless of cable length. Doing so would provide a direct path to ground for the HV pulse.
Yes, the Arc Reflection Method is ideal for concentric secondary cables. The only caution is to make sure the operator does not apply more than the required voltage if using a high capacity unit.