WARNING: Not the sort of experements to be carried out by the inexperienced, this is NOT the Beginners Section. The output current of the Insulation tester is very strictly limited and has a current trip. The capacitor though is capable of life/underwear threatening energy delivery!
Second warning: Long text!
A couple of weeks back, I repaired a Hunting Hivolt 10kV Insulation tester...
https://www.eevblog.com/forum/repair/hunting-hivolt-_check-it_-10kv-insulation-tester-restored-to-health/While testing the leakage of various transformers in my scrap box, it rapidly became clear that I needed a discharge probe! It's surprising how much energy the inter-winding capacitance of small a well insulated transformer can retain.
The problem is, how to safely and painlessly discharge these capacitances at up to 10kV? The largest high voltage capacitor in my collection is an EFCO 22nF plastic film (ok it's rated at 5kV but exhibits no leakage 10kV), it actually measures just short of 25nF (before and after). This seems like an adequate upper capacitance limit - I'm never going to test anything with more parasitic capacitance than that (at that voltage anyway) and
never going to use it on connected equipment!
Ok, lets get started...
Test 1: A straight ground lead. This produced a bright blue metal removing arc and a loud crack that startled my wife two rooms away.
Well that wasn't going to be a viable long term solution! I wasn't quite expecting such drama from 22nF! I tested with a 250nF cap at 3kV, much less dramatic, but still noisy. No surprising as it would be holding a similar amount of energy (around 2.2J) as the 10kV one.
Time to try current limiting resistors (going from bottom to top in the attached photo)...
Test 2: A 500R 5W RCL/IWAKI Wirewound resistor. Theoretically this would limit the discharge current at 10kV to 20A, ignoring the drop of the arc discharge which is presumably quite low impedance. Surprisingly better, still a crack and a neat blue arc but nowhere near as dramatic. Similar results at 3kV with the other cap. The question was, how much voltage was actually being dropped across the resistor. 20A also seemed like quite a damaging amount of discharge current for the test subject too.
Time for a larger value...
Test 3: A 68k 2.5W(ish) film resistor (I believed thick film - it looks thick, but not so sure now). Not a good one! It blew the side out of the resistor and made a very loud crack and flash saying "
I am not a resistor at 10kV!". Unsurprisingly it read open circuit after the test. I'd obviously jumped too high in resistance at the same time as using the wrong resistor type - Yes, I
was half expecting something like this to happen - but not the expulsion of material.
Ok, Let's go for the highest value wirewound resistor that I've got, wirewounds are good for surge...
Test 4: 15k 6W Vitreous wirewound. Rather successful, no destruction, no flashover, reasonably quiet. Strangely the discharge changed from thin, brigh blue and sharply defined, to a less well defined yellowish coloured arc. I wasn't sure whether this was due to lower current density, longer discharge duration...or maybe oscillation due to resistor inductance. The other thing on my mind was the potential for flashover between adjacent turns of the element winding, possibly leading to unpredictable loud cracks a-la Tests 1 and 3 (although I'm sure the glaze wouldn't fly off). I did test it over a fair number of discharges though.
One more try for now then - I'm running out of resistor types. Carbon Composition are supposed to have good surge tolerance, aren't they. Let's try one of those...
Test 5: 22k 2W 1970s Carbon composition. First of all, it had aged up to 25k before I even started testing, however a very successful test (surprisingly), no drama, no flashover. The arc has the same yellow colour as Test 4 (not resistor inductance then). I've repeated this test 50 - 100 times now, with many of the discharges in quick succession (as fast as the tester could recharge the cap). It got very slightly warm at times but that's it. Measuring the resistance afterwards, it is still around 25k (pretty much hidden in the temperature coefficient). I've also tested repeatedly with the 250nF at 3kV too.
I knew that Carbon composition had a good reputation for surge resistance but this is pretty extreme. Ignoring the arc drop, it is passing around 400mA at 10kV, thats a 4kW pulse through a 2W resistor, repeatedly! Of course I've no way of knowing how much the resistance is dropping during the discharge, or the voltage drop across the, now cooler, arc. Even so, the fact that its measured value hasn't changed implies that any internal flashover isn't causing damage, and it is definitely limiting the discharge energy at least as well as the 15k wirewound.
I've adopted this resistor for the probe for now (top of photo). Yes, I've been dipping into the Lidl heatshrink kit again (
). It should at least limit any flying debris if the resistor comes apart!
I know it's not very scientific because I was using whatever I had in the parts bin . Don't throw all of those old Carbon composition resistors just yet though! Thoughts and ideas welcome.
Home
Help
Search
Login
Register
