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2467B focus/astigmatism anomaly...
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solder very insulated wire to point on board?
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not idea, though. Harvey On 8/16/2019 6:02 PM, Chuck Harris wrote:
Hi George, |
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I think it's a viable technique; although there are more things to remember not to touch. Only LOOK at the null detector, don't try to fiddle it...
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If I tried this, you better believe I'd have one hand behind my back. Dave Wise -----Original Message-----
From: [email protected] [mailto:[email protected]] On Behalf Of Chuck Harris Sent: Friday, August 16, 2019 2:32 PM To: [email protected] Subject: Re: [TekScopes] 2467B focus/astigmatism anomaly... You're scaring me Dave.... -Chuck Harris Dave Wise wrote: If you have another power supply that can make 15KV, you could assemble a differential voltmeter using the supply, a battery-powered voltmeter as null detector, and another voltmeter to measure the supply output once you have it nulled. The detector should have autoranging turned off, and have protection diodes across its input. |
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All the more reason why I don't fiddle with high voltage.? If a CRT in one of my instruments dies, I'll look for a replacement instrument or buy an LCD kit.? The one with the dead CRT will then become a parts mule.I don't want to become a human french fry!Jim Ford?Sent from my Verizon, Samsung Galaxy smartphone
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-------- Original message --------From: Dave Wise <david_wise@...> Date: 8/16/19 3:31 PM (GMT-08:00) To: [email protected] Subject: Re: [TekScopes] 2467B focus/astigmatism anomaly... I think it's a viable technique; although there are more things to remember not to touch.? Only LOOK at the null detector, don't try to fiddle it...If I tried this, you better believe I'd have one hand behind my back.Dave Wise-----Original Message-----From: [email protected] [mailto:[email protected]] On Behalf Of Chuck HarrisSent: Friday, August 16, 2019 2:32 PMTo: TekScopes@...: Re: [TekScopes] 2467B focus/astigmatism anomaly...You're scaring me Dave....-Chuck HarrisDave Wise wrote:> If you have another power supply that can make 15KV, you could assemble a differential voltmeter using the supply, a battery-powered voltmeter as null detector, and another voltmeter to measure the supply output once you have it nulled.? The detector should have autoranging turned off, and have protection diodes across its input.> > I'm feeling a mad-scientist vibe, makes me wish I had a 15KV supply :)> > Dave Wise> > Let my creation LIIIIIVE!!!!!> >
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John Griessen
On 8/16/19 5:31 PM, Dave Wise wrote:
I think it's a viable technique; although there are more things to remember not to touch. Only LOOK at the null detector, don't try to fiddle it...Yeah... it's why I'm going to all the trouble of reversing polarity of my 40kV supply. You don't want to use it in reverse for the same reasons not to float your scope to measure power circuits. Too much HV case surface and "things" in your space ready to kill. |
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John said:
"I've got a 40kV Glassman 2kW I'm in the middle of converting from positive to negative." Going negative, eh? Sounds like something for a fusor project. I have two Spellman negative 60 kV, 3 kW units, planned for fusor work long ago. Alas, I'll probably never get around to it - it's still decades down the priority list. Anyway, back to the discussion, I gather that the desired measurements are in the 3 kV region or less, and are DC. Everyone working on old scopes should have at least a medium (3-5 kV) HVDC probe if they want to poke around in the CRT cathode circuits. It seems that there should be plenty of cheap new or used ones available. I've collected a few TV service 30-40 kV type ones over the years for very cheap - they're not needed much any more for their original purpose, but I guess there are also plenty of people fooling around with HV for other fun purposes. The old TV ones made for anode ultor measurements can be used down to medium ranges with good resolution if you're using a DVM. The top-ends of the ones I've seen are typically 600-1000 megs, and the bottom-ends hooked to much lower resistances to scale it for the intended readout device, sometimes even a small built-in meter movement. Regardless of what the probe was supposed to go with, you can always modify the bottom circuitry to work with whatever you want. What counts is the big top resistor being intact, and a high enough value to not overload the DUT. The rest is very adaptable, especially if the whole thing can be disassembled. So, you don't have to find an "exact" right probe that matches your meter, since you can tweak it around as necessary. This opens up a lot more options for finding something usable. For simple analysis, treat the big resistor as a current source from the applied HV. The bottom end will always be nearly zero, comparatively, so it's a constant current at a certain applied HV. That's what's available to produce your desired low voltage output signal - it's just a matter of scaling things properly to convenient values with the bottom end termination circuitry. BTW, that current is also the amount that will be available to flow into you or your equipment if you fail to properly ground the bottom end of the dividing system. It should be small, like 50 uA or less worst-case, so not a serious shock hazard. But, it's backed up by the applied HV, so it can jump just the same, and it can be quite a surprise. That's also why the big top resistor has to be good - properly rated for the voltage, properly packaged, and clean. If it were to break down, it won't isolate you anymore, so instead of a little tingle or snap, you could get a very noticeable shock, depending on the HV source impedance and the breakdown characteristics. Always be sure to properly connect that ground lead before use, and you won't need to experience any of these reminders. You can roll your own too, suitable for low power, 3 kV applications, without getting too fancy, packaging-wise, if you have a decent collection of HV, high-value resistors, and can make things out of plastic tubing. Ed |
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When I worked in a military cal centre we had lots of Tek 545s, HP 180s and
a smattering of 465s. There was more than a fair share of weak CRTs and HV supplies issues. I used to slide the HV probe under the rubber cap where the HV clipped onto the CRT. If you are nervous doing that pre position it, then turn on the scope. And it is sage advise, one hand behind the back or in the pocket. The rest is experience and respect.... Ken As a side note, all the 545s used metallized ceramic standoffs for point to point wiring. Every scope came with a little spool of silver bearing solder to solder on those ceramic pieces.. On Friday, August 16, 2019, Ed Breya via Groups.Io <edbreya= [email protected]> wrote: John said: |
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Well, now yuzz made me look. After looking through the whole thread, I got curious about the actual situation. I got the 2465B/2467B manual and found the CRT section schematics. I was surprised at how different these are between the 65B and 67B.
Anyway, as I understand it, the issue is that the trace drifts out of focus slightly over time, and apparently it can't be re-focused (with the focus pot) the same without also adjusting the astigmatism pot. Is this basically the deal? It looks like only the focus voltage is fairly high, and in a fairly high resistance environment, so the measurement desired is mainly about getting a good reading on this medium-HV signal, without upsetting the circuit too much. Right? First, I'd expect the focus voltage to drift a little with ambient temperature and due to self-heating differences at different focus settings. The Q4432 circuit is just a shunt-feedback amplifier, with the base near zero volts, but subject to Vbe change with temperature. CR4433 may give a bit of temperature compensation, but not much. I assume Q4432 being PNP, is probably a small-signal type like TO-92 or SMT size, good for Vcbo around 350-400V. The collector operating voltage should be around 0-300V, and the current should be relatively constant around 85 uA. So, the bottom of the focus string should be able to move by about 300V, attenuated by the string to a much lower amount at the electrode. The dissipation in Q4432 is small, but can change quite a bit, from nearly zero to about 25 mW. So, my first guess would be that the focus drift is normal - it is a simple analog circuit, after all - and the reason the astigmatism control needs to help, is that the focus voltage gets to be slightly out of range for full control. If you adjust R4430 "focus range" pot more toward the bottom side, it may expand it enough to regain the proper coverage. Whenever you change the front panel focus control, it changes the dissipation in Q4432, so it may take some time to settle at a new operating point, and will still be subject to drift. If Q4432 is readily accessible, heating or cooling it may show what's going on. Another possibility is that Q4432 is on the verge of breakdown, which could have big effects, including apparent bi-stable behavior. Be sure it's the right specified type, and is not compromised. If all the normal operating conditions are right, it shouldn't be subjected to more than 400V or so, with any settings. Even if it did break down, the current is very limited, so shouldn't be able to damage it. Good luck. Ed |
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Chuck Harris
Hi Raymond,
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The required astigmatism voltage wanders all over the place, never to return to a previous position. So, let's say it starts at 23.7V. After running for an hour without a beam on, I turn the beam on, and it will be fuzzy. I can restore the very best sharp focus by adjusting just the astigmatism voltage.... to a new value. Now, I let the scope run for another hour beam off... and when I turn the beam back up, it will again be fuzzy, and once again I can return it to best sharp focus by adjusting just the astigmatism voltage... The astigmatism voltage is rock stable, and will always be exactly where I set it. But the voltage required for focus wanders up and down. I never have to touch the focus adjustment. -Chuck Harris Raymond Domp Frank wrote: Chuck, |
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Chuck Harris
Hi Jim,
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The 15KV is pretty harmless, as it has very little capacitance, and as a result, few Joules of energy, and very low current. It won't stop a healthy heart, just annoy the owner. Getting across the anode supply feels like you got a good zap from a carpet in the winter... and is about as harmful. The low voltage power supply's inverter is loaded with voltages that can kill you. -Chuck Harris Jim Ford wrote: All the more reason why I don't fiddle with high voltage. If a CRT in one of my instruments dies, I'll look for a replacement instrument or buy an LCD kit. The one with the dead CRT will then become a parts mule.I don't want to become a human french fry!Jim Ford |
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Chuck Harris
I'm not at all nervous about anode voltages, I have
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been zapped numerous times. The 2465 family's CRT is right tight to a mumetal shield, so Tektronix glued the anode cap on with silicon RTV. The anode wire does have a connector, but I would rather not have to cobble things too much. -Chuck Harris Ken Eckert wrote: When I worked in a military cal centre we had lots of Tek 545s, HP 180s and |
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Try tapping on the tube.? It may have a disconnected element internally.
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Regards On 8/16/2019 11:55 PM, Chuck Harris wrote:
Hi Raymond, |
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True enough that higher voltage can actually be safer than LV. And from what I understand, larger currents of around 1 A can actually stop the heart, and it will start beating on its own again. Smaller currents, above 70 mA IIRC, will cause the heart to fibrillate, a condition from which it will not recover on its own. Hence the defibrillators that pump an amp or so through the heart to get it to stop and then start up again. Not that I've actually tried this! I did get a zap from 120 VDC a couple years ago at work, perhaps through my wrist strap. We're not supposed to wear the ESD wrist straps when working with >50 V or >25 A circuits, but the RF power amplifiers are quite ESD sensitive, so we are supposed to wear them. Nobody has figured out exactly what we really should be doing yet.
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I understand that ESD strikes from static electricity in dry areas can exceed 30 kV. I worked at one place in the mid 1990's where we had carpeted floors, and in the winter in Southern California when the Santa Ana winds blow very dry air off the desert, we would generate some pretty serious sparks. The path to the nearest restroom was a few hundred feet long, and we would get bad zaps when grabbing the door handle, so I took to pulling out a key and letting it get the zap. Ancient history now. Jim ------ Original Message ------
From: "Chuck Harris" <cfharris@...> To: [email protected] Sent: 8/16/2019 9:04:01 PM Subject: Re: [TekScopes] 2467B focus/astigmatism anomaly... Hi Jim, |
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Chuck Harris
Hi Ed,
Ed Breya via Groups.Io wrote: Well, now yuzz made me look. After looking through the whole thread, I got curious about the actual situation. I got the 2465B/2467B manual and found the CRT section schematics. I was surprised at how different these are between the 65B and 67B.No, only the astigmatism pot has to be moved... resulting in a brand new value on the astigmatism grid for optimum focus. It looks like only the focus voltage is fairly high, and in a fairly high resistance environment, so the measurement desired is mainly about getting a good reading on this medium-HV signal, without upsetting the circuit too much. Right?Basically, the astigmatism control supply is a low impedance voltage source that goes from 0 to 87V. It drives an electrostatic lens that focuses on one axis, and the focus grid drives a second electrostatic lens that focuses on the other axis. Together the astigmatism and focus bring the beam to a circular shape. My thought is the only way a new astigmatism voltage for optimal focus can be required is if the beam current has changed between the gun's anode #1 and the astigmatism lens. If you can believe the stacking of the electrodes shown in the schematic, the focus lens comes before the astigmatism, and after the anode #1. And, it is the toughest to meter, as it is 1.4KV roughly, and about 15M resistance. I didn't give Q4432 much thought... perhaps I should, as it would shift the focus electrode voltage quite nicely... It is an MPSA94, which is about as you surmised, VCBO and VCEO = 400V -Chuck Harris
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Chuck Harris
Hi George,
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There are rules, and there are rules. Behavior when working on a 40KV power line is very different than behavior when working on a 40KV CRT anode supply. One can source enough current to vaporize the probe, and the other can merely taunt the probe with its cross words... These probes are meant for low current applications, and to be held by hand. There are sever warnings about not using the probe on high current or without the grounding clip attached to a ground... for obvious reasons. -Chuck Harris george edmonds via Groups.Io wrote: Hi Chuck |
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Hi Chuck
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I agree with you except that I am old enough to remember things like projection TV's where the EHT was not low current. I have also worked on high voltage electrostatic clean room filters which were not at all friendly. After some sixty years of experience I just don't like holding probes when measuring high voltages. Even the involuntary reflex from a low current shock can cause serious injury. I have seen Radio Hams using these 40KV probes to check the Anode voltages on PA Tubes (Valves) with about 3KV present which is directly mains derived and extremely lethal. Best wishes, keep up your enjoyable postings. George. On Saturday, August 17, 2019, 2:24:53 PM GMT+1, Chuck Harris <cfharris@...> wrote: Hi George, There are rules, and there are rules.? Behavior when working on a 40KV power line is very different than behavior when working on a 40KV CRT anode supply.? One can source enough current to vaporize the probe, and the other can merely taunt the probe with its cross words... These probes are meant for low current applications, and to be held by hand.? There are sever warnings about not using the probe on high current or without the grounding clip attached to a ground... for obvious reasons. -Chuck Harris george edmonds via Groups.Io wrote: ? Hi Chuck |
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On Sat, Aug 17, 2019 at 03:14 PM, Chuck Harris wrote:
The beam current definitely changes each time between turning intensity down and up again, as the case describes. Although I can understand a jittery/jumping Q4432 role, is there a reason *not* to suspect C4403 leakage? You *did* find a broken Q4402 earlier, didn't you? And where/how does the intensity down/then up scenario cause Q4432 to make its jump, since normally there's (virtually) no (change in) current in the focus electrode circuit? Still sitting on my earlier post... Raymond |
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Chuck Harris
Hi Raymond,
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I agree that C4403 needs to be investigated. It will be a week, or so, before I have any parts in hand to try. C4403's intended purpose is to make moving changes to the focus as the trace moves about on the screen. Lifting one leg should stabilize the focus issues, if C4403, or the dynamic focus circuitry, is part of the problem. Something killed Q4402, be it old age, physical abuse, or a random zap from C4403. Ordinarily, I would think that the backwards diodes CR4410 and CR4411 should have protected against all but the largest insults... Maybe they are compromised too? -Chuck Harris Raymond Domp Frank wrote: On Sat, Aug 17, 2019 at 03:14 PM, Chuck Harris wrote:The beam current definitely changes each time between turning intensity down and up again, as the case describes. Although I can understand a jittery/jumping Q4432 role, is there a reason *not* to suspect C4403 leakage? You *did* find a broken Q4402 earlier, didn't you? And where/how does the intensity down/then up scenario cause Q4432 to make its jump, since normally there's (virtually) no (change in) current in the focus electrode circuit? Still sitting on my earlier post... |
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Hi Chuck,
On Sun, Aug 18, 2019 at 07:52 PM, Chuck Harris wrote: Yes Lifting one leg should stabilize the focus issues, if C4403,I'm curious, probably easy to do. Raymond |
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Chuck Harris
Hi Raymond,
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The scope has been running all afternoon with the capacitor removed, and frankly I can't even tell it is gone... A lot of circuitry for such little affect. However, the anomaly continues exactly as before. I think it is time to pick on Q4432, Q4440, and all of those high resistance resistors in the focus chain. -Chuck Harris Raymond Domp Frank wrote: Hi Chuck, |
Raymond Domp Frank
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