Anomalous Ammeter Readings + Loss of Alternator

Updates: (and thank you to all who continue to parse through this and offer suggestions :) )

Did another test flight today and couldn't get the alternator to fail. Amps/Voltages looked the same as yesterday's reported values.

Following the test flight I spent the next several hours verifying every electrical line I could think of in the aircraft. Cowl off, seats out, got up under the panel with bright lights + telescoping mirrors and lots of photos.

ENGINE COMPARTMENT WIRES:
This is the area where I found stuff I didn't like.

When the alternator got rewired at annual I think the cables from the alternator got moved down so now they're resting directly on the exhaust pipes from the engine. From my own diagnosis the wires look like they're not doing great down there.
There's some black gunk building up under the black shielded cable (the bigger wire / lower gauge line), and the smaller white cable appears to be a bit dirty and also with some brown marks (burns?).

mirror reflection, brown marks on the white line look like burns? (if it is, not sure if from heat or electrical load)
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There's some black crud building right where the black shielded (big) wire is resting on the exhaust. Is it from the heat? Or rubbing against it and causing chaffing/friction? Combo of both?
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Here's the big/small wires coming off the alternator itself
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Most sections of the wire near the engine compartment look a little dirty/aged, but I do not see any exposed wire.
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Couple spots where its worn through the shielding by the ties but wire insulation still looks fully intact.
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INTERIOR WIRES:
From what I could tell the interior wires all seemed to have good, sturdy, shielded connections to their terminals. It's complicated as all hell back there, but every wire seemed to be firmly attached and in good condition (1 exception).
Also I found a couple links from the breaker box that don't seem to line up with the component they're hooked up to. I have to investigate that a bit more. I'm going to look at these a bit more in my photos before I post.
 
Agree - nothing should ever be in contact with the exhaust. Not sure that is the cause of your issue, but you should definitely fix that. Did you say that your aircraft just came out of Annual? If so, I am troubled that it wasn’t found then…
 
Agree - nothing should ever be in contact with the exhaust. Not sure that is the cause of your issue, but you should definitely fix that. Did you say that your aircraft just came out of Annual? If so, I am troubled that it wasn’t found then…
Well... It just came out of annual and during annual the shop reinstalled the alternator with a new bracket and changed the wiring.

I brought the plane back with my alternator troubles and they reverified the lines are OK last week. So there's been eyes repeatedly on these lines specifically over the last 1-2 weeks, I don't think it's an oversight so much as an intentional wiring layout which they might have thought was better.

I'm not sure if this is the root cause, but I don't think it's helping matters any. The issue I experience occurs during high power settings at takeoff/climbout, which means lots of heat. So correlation is there, we'll have to find out empirically if it's the causation too.
 
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The output cable on the alternator looks rather stressed. If possible, I'd try flipping it 180 degrees so the cable approaches from beneath.

What did the annual and alternator work cost? (rhetorical question) Regardless, it was too much.
 
Those look like intake pipes to me (the 2nd and 3rd pictures), not exhaust (can see the chipped up gray paint), not that it should be in contact with those either for chaffing reasons, but at least they shouldn't be red hot.
 
Those look like intake pipes to me (the 2nd and 3rd pictures), not exhaust (can see the chipped up gray paint), not that it should be in contact with those either for chaffing reasons, but at least they shouldn't be red hot.
You're correct that they're intake pipes. But where I couldn't get the camera positioned to show the contact - they were in contact with the exhaust pipes to the side.
 
What I did as a test is I gently pulled the wires up on top like they used to be. This keeps them away from resting on the intake and wrapping around towards exhaust to alternator. Going to see if that makes any difference. No rewiring (I wouldn't do that myself). But this was literally just gently moving their routing.

At a minimum there's a lot less tension on them in this position than when them ran below...

Green is new position, red is old.
 

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Shifting the wires back to where they were seems to have resulted in the static sound on takeoff and crackling noise to go away, so that's a win.

But after a 40 min cruise I did a full stop taxi back and on my 2nd takeoff the alternator current dropped off again.
Ammeter went to 0, voltage dropped to 12.5 - 12.7 showing its pulling off battery (normally at 14.1 - 14.3 when alt is working). Didn't catch the precise moment it failed but prior to that ammeter/voltages all looked OK for takeoff.
Reduced power a little, flipped alternator off then back on again and ALT power came back...

Troubleshooting continues...
 
Shifting the wires back to where they were seems to have resulted in the static sound on takeoff and crackling noise to go away, so that's a win.

But after a 40 min cruise I did a full stop taxi back and on my 2nd takeoff the alternator current dropped off again.
Ammeter went to 0, voltage dropped to 12.5 - 12.7 showing its pulling off battery (normally at 14.1 - 14.3 when alt is working). Didn't catch the precise moment it failed but prior to that ammeter/voltages all looked OK for takeoff.
Reduced power a little, flipped alternator off then back on again and ALT power came back...

Troubleshooting continues...
Do you have the older electromechanical regulator or an Alternator Control Unit?

The ACUs are susceptible to sharp, short system voltage spikes caused by RF leakage from com antenna cables and connectors. Their internal overvolt detector is super-sensitive, requiring only microamps to fire it, and will drop the alternator offline if such a spike is detected. Next time you run the airplane, hit the push-to-talk and watch the ammeter.

Another case of newer and more complex not being necessarily better, especially in older airplanes. I ran into this one in a 185, and found the antenna connector above the headliner corroded with crud caused by condensed water vapor from the breathing of the airplane's occupants. Cleaned it up and the whole alternator problem went away.
 
@Dan Thomas
Would this be my voltage regulator that you're referring to, or an integrated component with the alternator?

It looks like my voltage regulator is new-ish.
PXL_20240616_190719366.jpg

I can go hunting for another component if it's not the above that you're referring to!

But I will run the airplane today and press PTT and watch the ammeter. May not fly it until I do more troubleshooting.
 
@Dan Thomas
Would this be my voltage regulator that you're referring to, or an integrated component with the alternator?

It looks like my voltage regulator is new-ish.
View attachment 130241

I can go hunting for another component if it's not the above that you're referring to!

But I will run the airplane today and press PTT and watch the ammeter. May not fly it until I do more troubleshooting.
That looks like an ACU. Sensitive.
 
Setup my portable oscilloscope test lead to read off the INPUT of the over-voltage protector (its input comes from the OUTPUT of the voltage regulator -- pictured below in the diagram with the red arrow). Grounded appropriately.
I taped it to the mount on the front of my yoke with 1 second resolution so I could easily glance down at it and see any anomalies (it will show a trailing view of history).
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I tested:
Avg
: ~14.30 V
Max: ~14.90 V
Min: ~13.75 V

Bus voltage and amp voltage remained at normal levels as detailed in earlier posts. Amps ~5-8 after plane has been running for a while, bus voltage 14.1-14.3V.

Adding/removing loads did not produce a significant voltage change.
Signal appears consistent with a variance of only ~0.2V on either side of the average voltage.
No crackling/static in the headset (haven't had ANY since moving the wires off the intake/next to exhaust -- and back to where there is less tension on them). There was no alternator issues in today's flight.

I did notice 1 thing:

- After I shut the plane down (but left oscope running with ALT switch ON and Master switch ON), it continued to read between 13.7 - 14.3 volts. That was unexpected. The volt meter that reads voltage off the bus will drop to battery voltage after engine shutdown. I'm not sure if there is a capacitor or something in the voltage relay or alternator itself that causes it to continue to show that voltage after the engine shuts down. I left it there for about 20-30 seconds before flipping the ALT switch off (but kept master ON). At that point the voltage dropped to 0 at the over-voltage protector, which is the value I expected to see after turning the engine off...
 
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In pictures...
This is where I measured. At the terminal on the over voltage relay, which is fed the red wire from the voltage regulator.
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In pictures...
This is where I measured. At the terminal on the over voltage relay, which is fed the red wire from the voltage regulator.
View attachment 130321
Your connection isn't what you think it is. The OV protector input is connected to the positive battery bus through the alternator field fused connection, and that voltage is fed through the master switch to the OV unit, and then to the input of the voltage regulator.

The regulated voltage output is then routed to the alternator field voltage, which varies the alternator voltage output. The alternator output voltage is routed to the alternator circuit protection breaker, the master solenoid, and then to the battery positive and the battery bus.

Your scope is displaying the OV unit output, which is the same as battery and main bus voltage. A connection to the voltage regulator output, which flows to the field voltage terminal on the alternator, will provide information to its response to changing loads.

The OV unit input and output voltage is just a pass through of the battery and main bus voltage. The unit doesn't change or affect the system voltage, it just monitors it and trips if the voltage exceeds the preset upper limit.
 
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Your connection isn't what you think it is. The OV protector input is connected to the positive battery bus through the fused connection, and that voltage is fed through the master switch to the OV unit, and then to the input of the voltage regulator.

The regulated voltage output is then routed to the alternator field voltage, which varies the alternator voltage output. The alternator output voltage is routed to the alternator circuit protection breaker, the master solenoid, and then to the battery positive and the battery bus.

Your scope is displaying the OV unit output, which is the same as battery and main bus voltage. A connection to the voltage regulator output, which flows to the field voltage terminal on the alternator, will provide information to its response to changing loads.

The OV unit input and output voltage is just a pass through of the battery and main bus voltage. The unit doesn't change or affect the system voltage, it just monitors it and trips if the voltage exceeds the preset upper limit.
Thank you very much, appreciate the details there. This is beyond the normal small circuits I'm accustomed to working on.

I'll reconnect with the A&P and verify the placement... Clearly I misinterpreted :) .
 
Your connection isn't what you think it is. The OV protector input is connected to the positive battery bus through the alternator field fused connection, and that voltage is fed through the master switch to the OV unit, and then to the input of the voltage regulator.

The regulated voltage output is then routed to the alternator field voltage, which varies the alternator voltage output. The alternator output voltage is routed to the alternator circuit protection breaker, the master solenoid, and then to the battery positive and the battery bus.

Your scope is displaying the OV unit output, which is the same as battery and main bus voltage. A connection to the voltage regulator output, which flows to the field voltage terminal on the alternator, will provide information to its response to changing loads.

The OV unit input and output voltage is just a pass through of the battery and main bus voltage. The unit doesn't change or affect the system voltage, it just monitors it and trips if the voltage exceeds the preset upper limit.
That.
 
- After I shut the plane down (but left oscope running with ALT switch ON and Master switch ON), it continued to read between 13.7 - 14.3 volts. That was unexpected. The volt meter that reads voltage off the bus will drop to battery voltage after engine shutdown. I'm not sure if there is a capacitor or something in the voltage relay or alternator itself that causes it to continue to show that voltage after the engine shuts down. I left it there for about 20-30 seconds before flipping the ALT switch off (but kept master ON). At that point the voltage dropped to 0 at the over-voltage protector, which is the value I expected to see after turning the engine off...
Strange. You didn't have the oscilloscope's "Hold" function activated, did you?
 
I just double checked a video of it to confirm it was not in HOLD/STOP mode.

EDIT: After about 20s of the aircraft engine being switched off it dropped to battery voltage. But it was not instant. It took time for it to drop. Once I flipped off alternator switch it dropped to zero.
 
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Must have been a capacitor inside the regulator, possibly an electrolytic filter on the input, yet it should have drained off through the regulator field, since the field's power comes though that line. There is no mechanism or circuitry to shut off the field from the regulator when the alternator stops turning.

Very odd.
 
Must have been a capacitor inside the regulator, possibly an electrolytic filter on the input, yet it should have drained off through the regulator field, since the field's power comes though that line. There is no mechanism or circuitry to shut off the field from the regulator when the alternator stops turning.

Very odd.
@Dan Thomas
Sorry for the red herring this was actually my mistake (again). I rewatched the video a few more times and the problem is I had a trigger set on the scope from when I was testing it out because I wanted to capture any falling voltages (which did not occur during my normal testing).
It went into STOP mode on the falling edge of the voltage, but because of the zoomed out time resolution that was not obvious in my video; only once it resumed after a pause from the trigger did it update and show the lower voltage. I just picked up this cheap handheld scope yesterday and I'm not as well versed in using it as my normal scope.

Sorry for the time waste on that one, my fault.
 
Alright, let's try this again and see if I can measure what I'm supposed to...

I calibrated the scope, verified calibration with a couple tests, then connected a probe to the field-output line coming off the voltage regulator. The blue arrow below shows where the back probe was slid inside the transparent sleeve.
Ground run only. Collected data during idle, 1500 RPM, 2000 RPM.

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The voltage was the same throughout the whole range of RPMs and electrical loads. Here I've pictured a general sample.
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The voltage is centered around 8.3V +/- ~2.5V, which is lower than I would have expected and also a lot messier than I would have expected (which doesn't mean a ton since this is literally the first time I've ever measured this spot :) ).
From previous measurements at the OV unit, it seems like the VR is getting the right input voltage per the data sheet.
When I temporarily add load to the system (landing light, fuel pump, etc) I see a a small (~1-3V), quick (<100ms) spike in voltage but then it goes back to looking like the above.

My A&P is working with me the TS plan and helping me make sense of the measurements, and on Monday we're going to be a doing more tests together, but thought I'd solicit the wisdom of PoA in case there are any troubleshooting thoughts.
 
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After lots of troubleshooting on/off over the last 2 weeks a new alternator is getting installed.

Due to the issue being intermittent It took a lot of testing but in the end, after only many probes being hooked up, the alternator made it easy for us: it unceremoniously failed on start-up and couldn't be brought back to life. At that time we had bus measurements at the OV relay, the field wire (both coming out of the VR in the cabin and at the alternator terminal), and bus voltage as measured at the cigar lighter. We also had confirmation all test leads and leads on the alternator were secure.

In general we found the problems were correlated with higher engine power settings and seemed less correlated (or even uncorrelated) with electrical demand on the system. The A&P and a generous consultant EE that volunteered his time to help had agreed that the alternator failing fit the bill as the culprit. We were firing up the plane one final time for a ground run to try and confirm a thesis on that when it finally failed.

So after all that we've concluded without doubt that the alternator needs to go; that'll happen tomorrow. Fingers crossed there's no other issues, but I'm cautiously optimistic that we've solved it. After scouring the logs backwards and forwards I can't find any entry about maintenance or inspection of the alternator since 1992 (1361 tach hours ago). So... It had a good run. I was a bad owner for not giving it any attention over my 600+ h of ownership.

I don't think I'm going to give it back for the core credit, though ACS has said it would be eligible. Instead I think I want to take it apart and see what failed and just get a better understanding of how it really works.
 
Have followed your thread with interest; I have an intermittently tripping field CB.
30hrs smoh tsio-550, including a (non-Kelly) 100A alternator o/h.
Followed BandC’s (VR mfg) troubleshooting guide, which it passed - B&C recommended a new hi capacity VR. (no change)
All grounds confirmed perfect, I even added some new ones; all connections in this airplane corrosion-free, clean, tight, pass the pull-test.
New wires CB to VR & VR to Alt.
Tried changing the master relay & flyback diode.
Bypassed the Master & Alt switches.
None of this has helped so the alternator went off for o’ scope testing, waiting on results, return of repaired or new alternator.

Intermittent problems, and time constraints sometimes require the judicious use of the parts cannon.
 
After scouring the logs backwards and forwards I can't find any entry about maintenance or inspection of the alternator since 1992 (1361 tach hours ago). So... It had a good run. I was a bad owner for not giving it any attention over my 600+ h of ownership.
Yup. Most likely the field brushes are shot. Alternators need those brushes checked every 500 hours. In fact, some newer airplanes need it done more often. We bought a 172SP with the full Garmin G1000 suite, and at the first 500 hour I found the brushes 2/3 gone. They wouldn't have made it to 1000 hours. All those avionics draw a lot more amps than the steam-gauges did, so the brushes have to carry more current in order to get more output. I reduced the inspection interval to 300 hours for that airplane.

I'm not convinced that your alternator is the source of all your problems, though. I think there will be more to the story.

You were getting 8 volts at the regulator output. That's normal, and it will vary as the load increases or decreases. If you turn the landing lights on, it will go up as the voltage regulator senses a voltage drop in the system due to the increased load and it will send more current to the field to strengthen the magnetic field to generate more current in the stator for the output. If you run the engine RPM up and down the field voltage will increase on RPM drop and decrease on RPM rise, since the rotating field rotor generates more current as it goes faster.

Three things that affect electromagnetic power generation: Number of turns of wire in the coil, speed of the magnetic field cutting through the coil, and the strength of that magnetic field. We can't change the number of turns in the stator coils to control the output. The RPM is whatever we need to fly, and we can't go changing that to get the voltage to where we need it. So we vary the field current via the voltage regulator, and more current in means more current out as the output voltage rises.
 
Have followed your thread with interest; I have an intermittently tripping field CB.
30hrs smoh tsio-550, including a (non-Kelly) 100A alternator o/h.
Followed BandC’s (VR mfg) troubleshooting guide, which it passed - B&C recommended a new hi capacity VR. (no change)
All grounds confirmed perfect, I even added some new ones; all connections in this airplane corrosion-free, clean, tight, pass the pull-test.
New wires CB to VR & VR to Alt.
Tried changing the master relay & flyback diode.
Bypassed the Master & Alt switches.
None of this has helped so the alternator went off for o’ scope testing, waiting on results, return of repaired or new alternator.

Intermittent problems, and time constraints sometimes require the judicious use of the parts cannon.
Spot on about replacing parts at some point, but I really liked approaching this problem methodically and getting measurements to properly diagnose it. My past approach has been to fire up the parts cannon right off the bat to minimize downtime, but it's high time I invested more time learning about the systems.

I'm curious, with your breaker popping was it correlated to some settings? Like a high load or high engine power? By no means am I qualified to offer troubleshooting advice, but I'd like to see if there's any similarity to mine.

Also, sounds like a powerful bird with a TSIO550 and an alternator cranking out at 100A! That's nearly twice mine :)
 
Yup. Most likely the field brushes are shot. Alternators need those brushes checked every 500 hours. In fact, some newer airplanes need it done more often. We bought a 172SP with the full Garmin G1000 suite, and at the first 500 hour I found the brushes 2/3 gone. They wouldn't have made it to 1000 hours. All those avionics draw a lot more amps than the steam-gauges did, so the brushes have to carry more current in order to get more output. I reduced the inspection interval to 300 hours for that airplane.

I'm not convinced that your alternator is the source of all your problems, though. I think there will be more to the story.

You were getting 8 volts at the regulator output. That's normal, and it will vary as the load increases or decreases. If you turn the landing lights on, it will go up as the voltage regulator senses a voltage drop in the system due to the increased load and it will send more current to the field to strengthen the magnetic field to generate more current in the stator for the output. If you run the engine RPM up and down the field voltage will increase on RPM drop and decrease on RPM rise, since the rotating field rotor generates more current as it goes faster.

Three things that affect electromagnetic power generation: Number of turns of wire in the coil, speed of the magnetic field cutting through the coil, and the strength of that magnetic field. We can't change the number of turns in the stator coils to control the output. The RPM is whatever we need to fly, and we can't go changing that to get the voltage to where we need it. So we vary the field current via the voltage regulator, and more current in means more current out as the output voltage rises.
Thanks Dan!

But for once I'm really, really, really hoping you're wrong ;) (about there being more to the story). Hope this alternator cures what ails my bird!

I should draw a curve showing field voltage as measured after the VR; I do have the data after we went out and collected it. It's not a shape I was expecting.

Your explanation makes sense but it's not what I saw (given a constant electrical load). For instance, on takeoff, highest RPMs but AFTER finishing the retracting gear the voltage peaked at more than 14V. It *never* got anywhere near that on the ground at low RPMs with the same electrical load (except 12.2V field charge prior to starting the engine). Whether idle (1000), or through run up speeds (2000), it never got anywhere near the levels it reached at takeoff.

What I found is low RPMs (idle/ground run) was 7-9.5V. Takeoff 10-14. In slow cruise 7-10V. In fast cruise (near 75% power) closer to 8-14V. This was with an A&P and an A&P designed experiment. One of the things that was concerning was the periodic field voltage dropping all the way to 0.5V but *not* because the OV unit tripped. The EE suggested what may be happening is poor contact within the alternator where the system is "requesting" more current then immediately receiving an increase once contact is made again (which happens on the millisecond scale) and dropping voltage immediately after that.

Disclaimer: This is me also playing a game of telephone between two trained A&Ps and people with advanced knowledge on electricity, so please forgive any ignorance in my descriptions!

If there's more tests I should conduct post alternator install, I'm all ears.
 
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with your breaker popping was it correlated to some settings? Like a high load or , high engine power?

It only happened at 2400+rpm, and higher power settings ie above 28"MP - never on the ground, never entering or in the pattern, or on approach.
Climb and cruise, yes.
Also not associated with high loads ie hydraulic pump or lighting.
 
What I found is low RPMs (idle/ground run) was 7-9.5V. Takeoff 10-14. In slow cruise 7-10V. In fast cruise (near 75% power) closer to 8-14V. This was with an A&P and an A&P designed experiment. One of the things that was concerning was the periodic field voltage dropping all the way to 0.5V but *not* because the OV unit tripped. The EE suggested what may be happening is poor contact within the alternator where the system is "requesting" more current then immediately receiving an increase once contact is made again (which happens on the millisecond scale) and dropping voltage immediately after that.
Don't forget that there are two voltages going on here. The one you measured at the regulator is the field voltage, and it will vary according to RPM and load. It will never hit 14 volts. The other is the alternator output voltage, measured at the alternator or is breaker at the bus, or at the voltage regulator's input from the ALT switch. That one should be at battery voltage until startup, then go to around 14 volts and stay there the whole time the engine is running.

"Poor contact within the alternator" will not drop the field voltage from the regulator to zero. The regulator will supply max voltage, trying to get the alternator output up if the field brushes are not working right. Max field voltage won't be more than about 11 volts or so, since there are resistors in the regulator.
 
Don't forget that there are two voltages going on here. The one you measured at the regulator is the field voltage, and it will vary according to RPM and load. It will never hit 14 volts. The other is the alternator output voltage, measured at the alternator or is breaker at the bus, or at the voltage regulator's input from the ALT switch. That one should be at battery voltage until startup, then go to around 14 volts and stay there the whole time the engine is running.

"Poor contact within the alternator" will not drop the field voltage from the regulator to zero. The regulator will supply max voltage, trying to get the alternator output up if the field brushes are not working right. Max field voltage won't be more than about 11 volts or so, since there are resistors in the regulator.
Thanks Dan.
Regarding the explanation of what's occurring in the alternator, I'm likely repeating something incorrectly (sorry). The electrical engineer was theorizing about the cause and fitting an explanation to the data, I just sort of scribbled down some notes. Probably some translation error.

As for the field wire: we measured it simultaneously from two places. In the cabin from the VR, and then at the terminal of the alternator itself. This is a screenshot of it measured from the field wire coming out of the voltage regulator at high power settings.

V(max) was very briefly 14.25V, but it also had brief periods where it pulled low to nearly 0... Then on the next startup the alternator just straight up died.

Screenshot_20240625-202812.png

Headed to the field to get the new alternator installed. Going to take the old one apart and snap photos to show it's condition.

If you have suggestions about tests I can do after the install to verify the other components, I'm happy to try them with my mech!
 
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Note: we actually never ended up measuring alternator output voltage before it died. That was an experiment we didn't get to before the alternator failed.
 
V(max) was very briefly 14.25V, but it also had brief periods where it pulled low to nearly 0... Then on the next startup the alternator just straight up died.
Those drops to near zero tell me that there is some issue with the regulator or the power's path to it. We take another look at the wiring:

1719441580432.png

The alternator field breaker or the alternator switch might have oxidized contacts that are intermittently cutting the power. The overvoltage relay might be failing. The regulator itself might be failing. If the system still acts up with the new alternator, it's time to start reading voltages at the bus, at the breaker terminals, at the switch terminals, and at the connections between the overvolt sensor and regulator. Don't overlook some loose terminal screws, and also look for wires loose or corroded in the crimp terminals. Green stuff is corrosion.

Edit: There is a remote possibility that the field circuitry inside the alternator is shorting to ground. That would pull the field voltage to near zero.

The regulator's output seem pretty choppy, I think, even without the occasional voltage drops.

Cessna, in their service manuals for the restart airplanes, make mention of the master/alternator switch in the inspection section of the manuals. They want that switch replaced every four years to avoid system failures due to oxidizing contacts.
 
Those drops to near zero tell me that there is some issue with the regulator or the power's path to it. We take another look at the wiring:

View attachment 130635

The alternator field breaker or the alternator switch might have oxidized contacts that are intermittently cutting the power. The overvoltage relay might be failing. The regulator itself might be failing. If the system still acts up with the new alternator, it's time to start reading voltages at the bus, at the breaker terminals, at the switch terminals, and at the connections between the overvolt sensor and regulator. Don't overlook some loose terminal screws, and also look for wires loose or corroded in the crimp terminals. Green stuff is corrosion.

Edit: There is a remote possibility that the field circuitry inside the alternator is shorting to ground. That would pull the field voltage to near zero.

The regulator's output seem pretty choppy, I think, even without the occasional voltage drops.

Cessna, in their service manuals for the restart airplanes, make mention of the master/alternator switch in the inspection section of the manuals. They want that switch replaced every four years to avoid system failures due to oxidizing contacts.
Thanks again, Dan.
Quick question: where did you get that wiring diagram? The digital copy I have is from the POH for my serial# but is much more cluttered showing the entire electrical system on 1 condensed page, this one is higher quality and easier to read. Do you know where I can get a copy?

Also, the drops to near zero were of concern to the A&P and EE alike for the reason you mentioned. As for investigating culprits:
(1) The switch was brought up as an easy check but then skipped in favor of testing alternator. The rationale was that the switch was unlikely to be the cause based on the behavior (every time you reset the switch it behaves again for at least a little bit of time). And it's only an issue at higher engine settings.
(2) We didn't even consider looking at oxidized contacts at the breaker box. I took a picture of the breaker box (below) and contacts
(3) Bell206 had DM'd me the bench testing procedure for the OV unit in case we have to do that; that's something my A&P offered to test
(4) We didn't investigate the voltage regulator very much because frankly it deemed the least likely to have a problem based on age alone. The OV relay looks factory original, the alternator was 32y old, and the VR looked like a nearly brand new solid state unit. I'll call Lamar to get a copy of their TS guide if they have one. It wouldn't hurt to have on hand.

Looking for corrosion on any terminals/contacts is something I can do even at my remedial skill level :) . I'll do some research on best way to clean them and then do it this weekend.
For reference (re the oxidized contacts), this is a picture of my breaker box. Unfortunately I can't see the top contacts of the field wire (blue) and the output wire (green). It looks like all I can see from this perspective is just a red jumper going between two breakers...
1719449590146.png

In the end I'm going to really hope that the new ALT fixes it (along with a new field wire that got run today), but I won't challenge the distinct possibility that there could be multiple, correlated issues here (like the alternator failing and the OV unit having trouble, etc). It may be part of what made finding this more tricky. There wasn't one obvious culprit to point at until the alternator keeled over and died.

If I'm still seeing any issues tomorrow or beyond I won't hesitate to switch back into troubleshooting mode and get readings at all the junctions you mention.
Also, I'll post photos of the disassembled alternator so we can see just how bad it looks inside :D
 
Thanks again, Dan.
Quick question: where did you get that wiring diagram? The digital copy I have is from the POH for my serial# but is much more cluttered showing the entire electrical system on 1 condensed page, this one is higher quality and easier to read. Do you know where I can get a copy?

Also, the drops to near zero were of concern to the A&P and EE alike for the reason you mentioned. As for investigating culprits:
(1) The switch was brought up as an easy check but then skipped in favor of testing alternator. The rationale was that the switch was unlikely to be the cause based on the behavior (every time you reset the switch it behaves again for at least a little bit of time). And it's only an issue at higher engine settings.
(2) We didn't even consider looking at oxidized contacts at the breaker box. I took a picture of the breaker box (below) and contacts
(3) Bell206 had DM'd me the bench testing procedure for the OV unit in case we have to do that; that's something my A&P offered to test
(4) We didn't investigate the voltage regulator very much because frankly it deemed the least likely to have a problem based on age alone. The OV relay looks factory original, the alternator was 32y old, and the VR looked like a nearly brand new solid state unit. I'll call Lamar to get a copy of their TS guide if they have one. It wouldn't hurt to have on hand.

Looking for corrosion on any terminals/contacts is something I can do even at my remedial skill level :) . I'll do some research on best way to clean them and then do it this weekend.
For reference (re the oxidized contacts), this is a picture of my breaker box. Unfortunately I can't see the top contacts of the field wire (blue) and the output wire (green). It looks like all I can see from this perspective is just a red jumper going between two breakers...
View attachment 130646

In the end I'm going to really hope that the new ALT fixes it (along with a new field wire that got run today), but I won't challenge the distinct possibility that there could be multiple, correlated issues here (like the alternator failing and the OV unit having trouble, etc). It may be part of what made finding this more tricky. There wasn't one obvious culprit to point at until the alternator keeled over and died.

If I'm still seeing any issues tomorrow or beyond I won't hesitate to switch back into troubleshooting mode and get readings at all the junctions you mention.
Also, I'll post photos of the disassembled alternator so we can see just how bad it looks inside :D
Something isn't correct. The device with the jumper on it (a breaker?) isn't connected to the bus as I would expect. The other end of the jumper is connected directly to the bus. What's going on there?
 
Quick question: where did you get that wiring diagram? The digital copy I have is from the POH for my serial# but is much more cluttered showing the entire electrical system on 1 condensed page, this one is higher quality and easier to read. Do you know where I can get a copy?
http://www.mikeg.net/library/files/pa28-service.pdf The diagrams you want are on pages 4G15 and 4G16, which are on page 801 of the pdf, and on 4G20, 21, 22, 23, or 24 depending on the details of your system. pdf pages 805 thru 809.
We didn't even consider looking at oxidized contacts at the breaker box. I took a picture of the breaker box (below) and contacts
The contacts we are concerned with are inside the switch and breaker. They open and close to complete or break the circuit. Can't see them unless you bust the switch or breaker open.
Also, I'll post photos of the disassembled alternator so we can see just how bad it looks inside
Yes, please do. It might answer some questions.
Something isn't correct. The device with the jumper on it (a breaker?) isn't connected to the bus as I would expect. The other end of the jumper is connected directly to the bus. What's going on there?
1719456607575.png

Or maybe you're looking at this, a segment of the overall wiring diagram:

1719456889748.png

Electrically nearly identical to the other diagram, but showing where the actual connections are. A bit weird.
 
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Something isn't correct. The device with the jumper on it (a breaker?) isn't connected to the bus as I would expect. The other end of the jumper is connected directly to the bus. What's going on there?
Thanks, I thought something looked a little strange there.
1719464760011.png

The purple arrow points to the other end of the jumper line and it's a fairly new addition to the plane (a G5 installed by an avionics shop).
For whatever reason it looks like the breaker the avionics shop used does not fit neatly in that slot the purple arrow points to, so they ran a jumper line from it's terminal there over to piggyback on the same bus connection with the field wire?

Here's the front view of the panel. The red line indicating where I believe the jumper is linking.
1719465047596.png
 
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http://www.mikeg.net/library/files/pa28-service.pdf The diagrams you want are on pages 4G15 and 4G16, which are on page 801 of the pdf, and on 4G20, 21, 22, 23, or 24 depending on the details of your system. pdf pages 805 thru 809.

The contacts we are concerned with are inside the switch and breaker. They open and close to complete or break the circuit. Can't see them unless you bust the switch or breaker open.

Yes, please do. It might answer some questions.

View attachment 130648

Or maybe you're looking at this, a segment of the overall wiring diagram:

View attachment 130649

Electrically nearly identical to the other diagram, but showing where the actual connections are. A bit weird.
Thanks for the link Dan.

And thank you for the heads up. I didn't know you would physically open up a breaker or switch to examine the contacts. That's not something I'd do on my own, I'll have to ask my A&P to look at those.

Will have more info tomorrow...
 
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