EEVblog Electronics Community Forum
Electronics => Repair => Topic started by: adilmalik on August 30, 2016, 07:02:38 pm
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I got my hands on a faulty Keithley 2100 6.5 digit DMM. The problem is that the voltage and resistance readings seem disconnected from the front sockets. Its clear something has gone wrong inside.
After opening the case i identified two burnt SMD resistors. The problem is there are absolutely no service manuals available for this thing! I contacted keithley but they refused to help and insisted i send it in for service.
so...How does one identify a burnt SMD resistor for replacement.
(https://s13.postimg.org/uco9lp5nb/20160830_191444.jpg)
PS: if i have no luck, i am thinking i can short out R321, because R321,R322 and L303 seems like some sort of high frequency filter, the wire left of the inductor is connected to the front banana jacks and the right is going to the digital section.
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This looks like a digital output judging by the opto-isolator i guess, perhaps a way to identify this is by following the traces and drawing a small schematic to judge the values from the rest of the circuit, you should start by removing both resistors. BTW i couldnt find a data sheet for U305 (likely an opto isolator)
where does the other end of L303 go?
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Hi,
my guess seems right, i shorted out the resistor and viola the meter is back. The readings are a bit lower than expected, but this is on all ranges so im guessing its a calibration issue.
However, the error codes have gone up in count. With the old blown resistors i had 4 error, now ive replaced them with The Universal resistor (1kOhm ofc) and i have 9 errors.
Does anyone have a keithley 2100 they could pop open and read off the values for the resistors please?
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Hope you can find info here:
https://doc.xdevs.com/doc/Keithley/2100/
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If you post a larger picture showing where that is I can open mine up and look.
Also, any idea what caused this?
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If you post a larger picture showing where that is I can open mine up and look.
Also, any idea what caused this?
That would be great! Please see this photo, i have made a circle around the area;
(https://s4.postimg.org/6wfc0i42l/20160831_114249.jpg)
Yes, i think im pretty sure this was caused by an overvoltage condition on the input. If i look at the error codes i get: 612, 614, and 618. All of these are related to the 1000 voltage range. Im very shocked that the resistors blew instead of what appears to be MOVs at the side.
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This looks like a digital output judging by the opto-isolator i guess, perhaps a way to identify this is by following the traces and drawing a small schematic to judge the values from the rest of the circuit, you should start by removing both resistors. BTW i couldnt find a data sheet for U305 (likely an opto isolator)
where does the other end of L303 go?
The left end connects to the input jacks where as the other one goes into the shielded digitizer board to the ADC. However, it does seem weird why there would be optoislolators between the input and the ADC.
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I have only this one:
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I have only this one:
Perfect! i will order these and hopefully the error codes go away. Any idea what size these resistors are? im thinking 1206?
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This looks like a digital output judging by the opto-isolator i guess, perhaps a way to identify this is by following the traces and drawing a small schematic to judge the values from the rest of the circuit, you should start by removing both resistors. BTW i couldnt find a data sheet for U305 (likely an opto isolator)
where does the other end of L303 go?
The left end connects to the input jacks where as the other one goes into the shielded digitizer board to the ADC. However, it does seem weird why there would be optoislolators between the input and the ADC.
U305 is AQV258 Panasonic Solid State Relays, for switching ranges I would guess.
You can have a look at the K2000 schematic, the design is rather similar https://dev.xdevs.com/attachments/download/672/K2000.pdf
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Beat me to it on the pics.
I am going to open mine up again soon anyway. I think I want to recap at least some of it.
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This looks like a digital output judging by the opto-isolator i guess, perhaps a way to identify this is by following the traces and drawing a small schematic to judge the values from the rest of the circuit, you should start by removing both resistors. BTW i couldnt find a data sheet for U305 (likely an opto isolator)
where does the other end of L303 go?
The left end connects to the input jacks where as the other one goes into the shielded digitizer board to the ADC. However, it does seem weird why there would be optoislolators between the input and the ADC.
U305 is AQV258 Panasonic Solid State Relays, for switching ranges I would guess.
You can have a look at the K2000 schematic, the design is rather similar https://dev.xdevs.com/attachments/download/672/K2000.pdf
Correct :-+ I mistook the Q for an O in the part number.
@Adil, you may want to check U305 for functionality, better order a spare just in case.
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This looks like a digital output judging by the opto-isolator i guess, perhaps a way to identify this is by following the traces and drawing a small schematic to judge the values from the rest of the circuit, you should start by removing both resistors. BTW i couldnt find a data sheet for U305 (likely an opto isolator)
where does the other end of L303 go?
The left end connects to the input jacks where as the other one goes into the shielded digitizer board to the ADC. However, it does seem weird why there would be optoislolators between the input and the ADC.
which input jack? voltage or current?
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This looks like a digital output judging by the opto-isolator i guess, perhaps a way to identify this is by following the traces and drawing a small schematic to judge the values from the rest of the circuit, you should start by removing both resistors. BTW i couldnt find a data sheet for U305 (likely an opto isolator)
where does the other end of L303 go?
The left end connects to the input jacks where as the other one goes into the shielded digitizer board to the ADC. However, it does seem weird why there would be optoislolators between the input and the ADC.
U305 is AQV258 Panasonic Solid State Relays, for switching ranges I would guess.
You can have a look at the K2000 schematic, the design is rather similar https://dev.xdevs.com/attachments/download/672/K2000.pdf
Correct :-+ I mistook the Q for an O in the part number.
@Adil, you may want to check U305 for functionality, better order a spare just in case.
I was thinking the same, if the resistors went, it would be best to change this too. Although the meter seems to work fine now albeit some errors on the high voltage ranges
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This looks like a digital output judging by the opto-isolator i guess, perhaps a way to identify this is by following the traces and drawing a small schematic to judge the values from the rest of the circuit, you should start by removing both resistors. BTW i couldnt find a data sheet for U305 (likely an opto isolator)
where does the other end of L303 go?
The left end connects to the input jacks where as the other one goes into the shielded digitizer board to the ADC. However, it does seem weird why there would be optoislolators between the input and the ADC.
which input jack? voltage or current?
Should have been more clear, the voltage channel.
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I dont think anything beyond U305 have suffered so just replace it and see what you get.
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BTW, anyone with this meter really ought to replace their filter caps if they haven't already. At least the "Stone" brand caps are known to fail.
Mine did:
https://www.eevblog.com/forum/repair/keithley-2100-at-spec-mode-err-599-repair/ (https://www.eevblog.com/forum/repair/keithley-2100-at-spec-mode-err-599-repair/)
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oh thanks for the heads up. My meter seems to be in fairly good nick, got it for $90 off ebay ;D ;D
However, once ive just noticed that it is making a humming noise from the PSU section. Nothing too serious, i only noticed it when i removed all ambient noise from the room. Any ideas ? bad caps?
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$90 is a great deal! I think I got mine for $300 after I found an issue and got a partial refund. Pretty amazing meter for less than the price of a Fluke 87V. Mine was working at the time. The issue turned out to be a dirty gang switch, which I just sprayed with contact cleaner. Of course I had to break the (current) cal seal to fix it.
A lot of powersupplies/transformers hum. I never noticed this meter making much noise, but the case is always on. Might not be a bad idea to at least change those big 1000uF caps (including the one closer to the front of the unit, right next to the transformer). They are all placed too close to heat sources for my liking.
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Finally got the resistors and replaced them. Error codes still persist, but meter seems to be functioning correctly. I believe one of the self test circuitry might have been damaged during the over voltage condition. Ive found the following:
To check the operation of the internal current sources the meter outputs a constant current and measures the voltage across the precision caddock resistor divider. The unit has the following model USVD2-B10M-025-02:http://www.caddock.com/Online_catalog/Mrktg_Lit/TypeUSVD_HVD.pdf (http://www.caddock.com/Online_catalog/Mrktg_Lit/TypeUSVD_HVD.pdf). These are 2 resistors, bonded as a ceramic sandwich. The larger 990K resistor which has the pins on the extreme end of the package seems to be spot on, but the smaller 100K resistor which has its pins on the inside measures 0.28Kohms :(. But as i cannot remove the resistor and both its pins are on the PCB whilst i measure it may just be wrong. Can someone measure the values of the resistor on pins 2 and 3 and report the value please?
Also the humming noise is coming from the transformers, it becomes a lot quieter once the meter heats up.
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Yeah, I saw that. I will check for you later tonight.
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When I measure the interior two pins, which I believe are pins 2 and 3, I get 231 Ohms.
The outer pins are 9.9MegOhms.
Hope this helps.
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On yours are you able to see the capacitance and voltage ratings for C834 and C836, which are the two electrolytics next to the voltage regulators, but closest to the front of the unit? I cannot read those values without removing them, and I wanted to make sure I had the right values on hand before I did that.
Thanks.
Edit: with the shield removed I can read them as 100uF 25V
Also I see four more electrolytics under the shield. I wonder if replacing those would affect the calibration.
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I see the same values for the capacitors.
Ok i made a mistake, i can measure then to be around 231 ohms aswell! Phew it looks good then. But now, im even more confused with the error messages, the error message says that it tries to configure the 500nA current source to product a voltage across the caddock resistor, and because it has failed the 500nA source has failed. The other error i get is to do with the high voltage attenuator failure. Any idea how i can check these?
PS: Can you send me a photo of the meter without the shielding please.
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I put the shielding back on...
It is easy to take off... Two screws, then slide the bottom piece towards the front back of the meter gently about 3-4mm. It has a couple of tabs that hold the two pieces together. At first I was worried it was being held on my thermal paste, but there is nothing contacting the shield.
Did you buy this meter broken, and thus have no clue what caused the problem, or did you break it on your end, and if so, how?
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FYI, mine is stamped OCT 2008 on the outside of the metal chassis, under the outer beige cover.
For you volt nuts: It has the VRE310J reference.
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BTW, you might want to post the error codes on the Keithley forum (and then tell us what they say :-+). The seem to offer up some technical info when you ask.
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I bought this meter on ebay, no clue what happened to it. From the first insepction, i saw the two burned resistors so it seems it was some kind of over voltage fault. This is confirmed by the error messages that point towards faults on the high voltage measuring circuitry.I get these errors:
612 Ohms 500 nA source failed: This test configures to the 10V DC range with the internal 10M
100:1 divider R204 connected across the input. The 500nA ohms current source is connected to
produce a nominal 5V signal. A 20ms ADC measurement is performed and the result is checked
against a limit of 5V ± 1V.
614 DC 1000V zero failed: This test configures to the 1000V DC range with no input applied. A
20ms ADC measurement is performed and the result is checked against a limit of 0V ± 5 mV.
618 DC high voltage attenuator failed: This test configures to the 1000 V DC range. The 500nA
ohms current source is connected to produce a nominal 5V signal. A 20ms ADC measurement is
performed and the result is checked against a limit of 5V ± 1V.
The thing that relates the errors is the 500nA current source.
Thanks for the de-shielding instructions!
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Did you check the power rails? Just a good practice.
Maybe finding the 1000V attenuator will take care of two issues. I will be in mine again shortly. I will see what I see, but I am no expert.
Also, check the font/rear panel input switch (the long white gang switch). I had problems with mine. A little contact cleaner fixed it.
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Did you check the power rails? Just a good practice.
Maybe finding the 1000V attenuator will take care of two issues. I will be in mine again shortly. I will see what I see, but I am no expert.
Also, check the font/rear panel input switch (the long white gang switch). I had problems with mine. A little contact cleaner fixed it.
Ok opened the shielding as per your instructions and viola I found another burnt resistor! the resistor seems to be at the input of an analog devices op amp that has been set up as a buffer, I remove the resistor and replaced with my decade resistance box and all the error messages are gone! also I found out why I was getting higher readings than expected: tweaking the value of the resistor with my decade resistance box, I saw that for larger resistances I got a DCV reading much larger than expected so it's probably because this resistor got burnt and its value increased.
so now all I want is someone to kindly send me a photo of that resistors value under the shielding :)
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Here are a couple of pics. My board looks a little different.
It looks like "01B", "018", or most likely "013". It was not clear even under a magnifier.
A meter shows it to be 1K Ohms.
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Wider view...
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Here are a couple of pics. Mine board looks a little different.
It looks like "01B", "018", or most likely "013". It was not clear even under a magnifier.
A meter shows it to be 1K Ohms.
Thanks! I believe the resistor is not soo critical as long as its a stable one. I will need to re calibrate the meter tho :/
PS: i found the date code, mine is dated Oct 2011.
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Wider view...
Interesting, you seem to have a different opamp than me. I have a analog devices
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Which op amp? Which reference IC do you have? Mine is the VRE310J
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Which op amp? Which reference IC do you have? Mine is the VRE310J
Its alive! And seems to be within calibration too! I checked it with another 6.5 Meter i have and they agree with each other! All the errors have gone too :-+ :-+ :-+ :-+
The opamp the resistor i asked you is connected to. I have an AD822 and you seem to have OP282. All of your opamps seem to be different to mine.
I have the same voltage reference.
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Nice job! :-+
And great deal on your meter...
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Hi,
sorry for stealing the thread, but I'm not sure if I have a real problem...
I bought Keithley 2100 from eBay as faulty, it shows overload for DC voltage measurement at 10V range and lower, if nothing is connected to the meter,
but it shows 0 for 100V and 1000V, as it should, and it shows reasonable values (very close to actual value, I will try to check precision) for 10V and lower ranges if connected to lab power supply.
All self test are OK..
After switching from 100V to 10V range, it's clearly visible how is reading dropping very fast (~ 1 second) from 0 to negative values and eventually reaching overload.
I reckon that behavior for lower ranges is not normal?
Thanks for any suggestions or advises!
Jacob
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The behavior is about normal:
The ranges up to 10 V are very high input impedance. For these ranges it is normal that an open input is not reading 0 or a value very close to it. Even a few 10's pA of bias current can be enough to slowly drive the input to overload.
The bias current might be a little on the high side if the voltage changes rather fast. To test one could have a 10 M resistor across the input and take that reading to get a measurement of the bias current. It should be below about 100 pA, thus less than 1 mV with the 10 M resistor.
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The high impedance input behavior is normal, but yours does seem to go very fast. I would check the power rails. The electrolytic capacitors in these are known to go bad. Mine was kind enough to alert me to this with an error code.
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Yeah not bad idea to replace those caps before they puke up if they are known (rubbish)
Kind of depends if your planning to use it a lot if so i would do recap when you order some components.
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Yeah not bad idea to replace those caps before they puke up if they are known (rubbish)
Kind of depends if your planning to use it a lot if so i would do recap when you order some components.
Absolutely, I would replace all of them next time you are in there... especially if they are branded "Stone." Those were the ones that died on mine. They started to bulge, but luckily had not leaked yet.
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Yeah no point to keep known bad caps. Of course OP will make his mind as what will be best option to him some people do not bother changing caps at all before there is a pop and smoke :blah: We are all different :-DD
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Thank you!
Measured bias current: (1Meg -> -6.3mA) 6.3nA (consistent with other values too)
All electrolytic caps have been replaced (original was rubicon though)
I've checked most of "obviously precise" resistors and resistors burned in adilmalik's meter, they seems to be fine... voltage reference seems to be fine.
I checked keithley 2000 schematics, 2100 is reasonably similar, but I don't know what should I check, in relation to the issue.
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6.3 nA is really a little too high for the bias current.
May guess would be one of the JFETs in the input switching went bad. With some luck one could find the culprit with local heating/cooling. Chances are high that the current would go up / down if the already bad JFETs gets a little warmer or colder. So with a well isolated heater or cold rod one could test the JFETs (likely SOT23 form factor).
One point that could be measured directly would be the bootstrapping of the over-voltage protection. This point should be rather close to the input voltage.
How is the offset in the 100 V range ? If not compensated numerical, one would expect some -63 mV. One should also so a small (e.g. 0.6 mV range) difference between open and shorted.
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Hi,
thank you!
I'm attaching thermal image of board, one JFET (looks to be input switching) is really hotter, I will try to take thermal images for different ranges (this one is for 10V) to see if there is any difference.
100V range is holding 0 very nicely, there is a small ADC noise of few last digits but it's really random (fluctuating around zero).
Could you please roughly describe how to measure "bootstrapping of the over-voltage protection" and how to confirm that JFET is bad by measurement?
I don't need full manual just few points.
Thank you very much!
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A leaky JFET should not get really warm at that current level ( a few nA). However if a FET gets really hot from other parts, it will leak.
As the 100 V range seems to be Ok, chances are the culprit is the JFET that is turned on in the 100 V /1000V range.
An in circuit measurement is difficult for the JFETs. There is a chance to find the bad ones from local heating or cooling.
To check the bootstrapping of the overvoltage protection, one should measure the voltage at the protection diodes, where the resistor for bootrapping goes to. It should follow the input rather close (only a few mV off).
It might be a good idea to get at least a crude schematics of the input section by reverse engineering. Chances are the Keithley 2000 is similar.
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It might be a good idea to get at least a crude schematics of the input section by reverse engineering. Chances are the Keithley 2000 is similar.
Unlikely since the 2100 is not designed and built by Keithley themselves. It is the illegitimate sibling of the 2000 family of DMMs. Perhaps it should not bear the Keithley name at all, and be called the "Snow 2100" :-DD
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A small update, I started to do simple reverse engineering of the input circuitry (I found later that somebody did it few days before me, https://www.eevblog.com/forum/repair/keithley-2100-repair-jfet-issue/msg1359980/#msg1359980 (https://www.eevblog.com/forum/repair/keithley-2100-repair-jfet-issue/msg1359980/#msg1359980) ) and realized that Q204 a Q203 are connected in parallel, then I finally realized (complete brain fart from my side |O ) what Kleinstein meant by testing JFETs with cold/hot rod, so I did soldering iron and freeze spray test on FETs, only Q204 reacted to cold temperatures (leakage was double??), high temperature had only very small effect on both Q204 and Q203. So I removed Q204 and leakage current dropped to 100pA! New MMBF4393Ls are already on their way with new relays (classic and solid state AQV258), is there any point in replacing other components (LT1050, OP282, other FETs,...) just in case?
Thank you!
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It is odd to see a bad part to show more leakage when cold. The more normal way would be more leakage when hot. Anyway broken parts sometimes do odd things.
Congratulations to finding the fault.
It might be worth checking the solder joints for the over-voltage protection (e.g. sprac gaps), maybe MOVs.
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Hi,
thank you! It's actually mostly your merit :-+ , thanks again Kleinstein!
I bought this faulty meter to look inside and learn something by hands-on experience, and it was a big success!
And as a bonus meter seems to work fine after repair, I will try to roughly test it's precision, but I don't really have any suitable references at this moment.
There is only one last annoying/suspicious thing, meter has a big(?) offset from zero, it's reading 0.18mV with leads shorted, the same for amps, 0.18mA for 1A and 3A range, 0.035mA for lower amps ranges (gain 0.2?), is it a fault? Is there any way how to "fix" this offset (beside "NULL" button of course ;) ) ?
Thank you!
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The meter likely has a software function to compensate for input amplifier offset. So a kind of null function, but more permanent.
If this function was used by the previous owner with the bad higher bias current this would likely also result in extra offset.
So checking the offset calibration should be the first step.
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Hi!
No schematics included unfortunately, but the Keithley is the same as the Picotest/Array M3500A and a Service Manual with at (least!) A Full Component-Level Board Parts List (down to individual Rs and Cs!) with PCB layout drawings is provided so you can check what you've fitted is here:-
https://www.picotest.com/downloads/M3500/M3500A%20Service%20Manual%2020111031.pdf (https://www.picotest.com/downloads/M3500/M3500A%20Service%20Manual%2020111031.pdf)
Chris Williams
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Thanks! This is worth raising this thread from the dead. Very helpful. Thank you.