I made some progress on the VTVM this week
I started by replacing the old 16uf/150V main filter capacitor with a new 20uf/250V filter capacitor. I looked at the schematic for the IM-13 VTVM and later models and they upped the capacitance to 20uf so I thought it would be fine. The circuits appeared to be identical.
I read a little about the battery eliminator and how essential it was so I removed the positive (+) cup from the PC board too:
I followed WhatsThat's lead and constructed the battery eliminator on a disc of Phenolic board and a nylon standoff. It was bolted to the main PC board but the center post isn't used for the positive (+) connection anymore, that trace was not used because it was easier to move the blue wire (+) to the new board instead. Nothing was modified in the VTVM to make it fit and the battery eliminator is all "solder" joints and no "bolted" joints like the old battery connections were:
BD139, all of the carbon composite resistors were replaced with Vishay MRS25 (under 1%) metal films. Here's an old 150K and a new 10MOhm:
The resistors with the red dots are the AB carbon composite resistors that I replaced. With the humidity here in North Carolina being so high, I take no chances using/keeping carbon composite resistors in my projects:
The probe's input .047uf/1600V blocking capacitor was replaced with a 3kV Cornell Dubilier. I bought the 3kV instead of the 2kV size because the 3kV cap has a smaller diameter and it fit better. Zero "leakage" too:
I didn't read about any issues with the Selenium rectifier, but when I bring the power up on the VTVM, I'll put my oscilloscope probe on its output and on the battery eliminator output as well to see what they measure and look like:
Well, I searched through my parts and found this 800v bridge rectifier. It has round leads and a weird pinout (- ~ + ~) that I bought by mistake for a past project. But it fits the spot pretty good. The distance between the positive (+) and the negative (-) lead of the rectifier matched the spacing of the PC board. I measured the voltage drop of the old Selenium rectifier and it is 4.24v. The new Vishay bridge rectifier (part# VS-2KBB80) measured 1.21v. No worries now about the Selenium rectifier failing
Now here's the odd job. I'm reading the manual and it states that if you're unable to obtain DC balance, check capacitors C5 and C6 (.005uf/400v discs). And if the AC function is inoperative or unable to to be calibrated, check capacitors C3 and C4 (.02uf/400v discs). Since there are only four capacitors like this in the IM-11, I'll pull and test them:
So, after reading the tolerance printed on the body of the capacitors, I say to myself "wow, these are loose and should test good"
Here's a .005uf. I watched Mr. Carlson's Lab's video where he says that these capacitors rarely test bad. From here on, I'll check these type of disc capacitors just as I would an electrolytic. It appears that these will drift over time:
So I matched two 630v Murata C0G capacitors that measured 4820pf and put them in their places:
Measuring the old .02uf/400v discs went in the same direction, low, about 30% so I replaced them with new Murata X7R .022uf capacitors:
I plan to use this VTVM to peak coils and such so I made a set of test leads. I used Thermax RG316-DS coax, a Switchcraft 588 1/4" plug, and two E-Z Hook mini- grabbers:
I also read that replacing the front panel's filament bulb with an LED will shave around 135mA of current on the 6.3v windings too.
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