Can I bribe a response with mediocre photos? This one is from my recent 1800 mile road trip through upper & lower Michigan a few weeks back and was taken near Copper Harbor, MI at a rest stop along a gorgeous bit of lakeshore highway full of butterfly inducing whoops, dips & twisties....

I think a negative means you had the black and red wires backwards (probobly on the multimeter). Unless checking diodes, you can normally assume an absolute value when checking voltage.

This test require that the digital multimeter be set to the "diode check" position, not DC volts. Did you use this setting when you checked it?

In my opinion, the bench tests for the stator and R/R are useful only when you are buying one from a junk yard or somewhere where it can't be tested on the bike. Static bench test results may pass, but the components can still fail under load when installed and rigorous actual working conditions and heat are applied.

The best tests are run at 5,000 rpm: The disconnected OEM stator leads should have equal voltage of about 80VAC. Aftermarket stators may test with 50 volts or more due to wiring differences, but should still have equal readings on all three leads.

If the stator tests OK, all connections are clean and well grounded, and the bike won't charge over 14VDC at 5,000 rpm, then the R/R should be replaced. I would just plug in your SH232-12 R/R and see if the battery charges properly. Don't bother with bench testing it. Make sure that the sense wire is connected to a circuit which is hot only when the ignition is on, like the tail light. If you want to connect the red lead directly to the battery, try a 15A fuse first or a 20A if it blows. I would recommend that you not do this, but connect it to the normal red lead connection in the wiring harness. Running the R/R ground wire directly to the negative battery terminal is a good idea. A good R/R should charge the battery in the 14.0-14.8 range at 5,000 rpm.

You know, I didn't switch it to diode testing until later when it specifies to do so. That may explain my funny readings. Now that I have time to attack this again, I'll try more intensive testing this weekend.

I'll post a pic of the RR that I have later to see if anyone can help identify it...

Thanks for the input!

Here's pics of the yet unknown RR - if anyone recognizes it please let me know!

Start from scratch on RR problem

Okay, I know the stator/RR subject gets beaten to death quite a bit on this board, but I think it's because of the shortcomings of the info available on the the Stator Papers. You inevitably end up searching through scores of posts on the subject here in the forums to get more info (which you find) but sometimes there are inconsistencies and contradicting info that you also find.

For instance, the RR on my bike gives questionable readings for each of the tests concerning just it - and if you consider it failing the solutions don't make sense in my situation (clean connections - cripes, I soldered new ones with no change!) or there is no solution (e.g., my readings fall between pass and fail for Test Phase C). I even made a 14 guage Y lead with which I connected the RR (+) out directly to the battery (+) via a 20 amp blade fuse which had no effect on readings when the solution said 'bad connections'. Anyway, here are my results from beginning to end:

BATTERY IS BRAND NEW & FULLY CHARGED.
Battery charge with ignition off: 12.62V (engine not running)
Battery charge with ignition on: 12.2V (and falling - engine not running)
START
Battery charge idle (1200RPM): 12.27V
Battry charge revving (2500RPM) 12.28V
Battery charge revving (4500-5000RPM): 12.26V
MultiMeter (-) to BAT (+) | MM (+) to RR (+): -.42V (V) or -.28 (Diode) (passing supposed to be <.2V - yes my readings are negative (-) values!)
MM (+) to BAT (-) | MM (-) to RR (-): bypassed [lead straight to BAT (-)]
TEST PHASE B
Stator 3 wire resistance reading: all around 1.0 Ohms
Stator short test: all read infinite resitance (no short)
Stator AC readings: all three are at 35V (idle) and 80V (5000RPM)
TEST PHASE C
RR disconnected.
MM (+) to RR (+) | MM (-) to each Yellow: each reads 1.32V (<1.0V=fail, >1.5V=pass, 1.3V=?)
MM (-) to RR (+) | MM (+) to each Yellow: .41V, .41V and .42V (~.5V =pass)
MM (-) to RR (-) | MM (+) to each Yellow: each read 1.32V (again, falling between pass & fail)
MM (+) to RR (-) |MM (-) to each Yellow: each read .40, .41 and .41 (again, ~.5V=pass)

I ran these test a couple of times (charging the battery between) with consistent results.

I then installed a '78 SH232-12 - I spliced a 14 guage Y (w/soldered bullet connectors) to the tailight positive lead and connected that to the black wire of this RR. I was bit disturbed by the low reading of 10.7V at this wire - is this significant? I ran a lead directly from the RR green wire to the battery (-) terminal and all other connections are otherwise the same as other RR. Here are my test results:

BATTERY FULLY CHARGED.

Battery charge with ignition off: 13.08V (engine not running)
Battery charge with ignition on: 12.5V (and falling - engine not running)
START
Battery charge idle (1200RPM): 13.1V
Battery charge revving (2500RPM): 15.1V
Battery charge revving (4500-5000RPM): 15.5V to 16.0V
MultiMeter (-) to BAT (+) | MM (+) to RR (+): completely depended on RPMs - below 1000RPMs is passing but it continues to rise with RPMS & reaches a 'failing' level .21V at about 2000RPM
MM (+) to BAT (-) | MM (-) to RR (-): bypassed [lead straight to BAT (-)]
TEST PHASE B -- same as previous test.
Stator 3 wire resistance reading: all around 1.0 Ohms
Stator short test: all read infinite resitance (no short)
Stator AC readings: all three are at 35V (idle) and 80V (5000RPM)
TEST PHASE C
RR disconnected.
Testing this Honda RR via the above method simply doesn't work, so I have no readings to provide.


So I guess, the SH-232-12 is working but I'm concerned about the fact that it is charging so high and that it has variable readings for the positive lead test. I tried the Y cable/blade fuse lead that I made earlier on the RR as well & got even higher charging readings so the diagnosis that there's a bad connection to the battery (+) doesn't fly here. I'm assuming that the variable readings are because of the 'sense wire' (tail-light lead) and perhaps the low reading (10.7V) I get there can be the cause of the higher than ideal charging rate, right?

And, finally, a real question:

Since these old GS bikes seem to spend a lot of time around 5kRPM, is it okay to have an RR that is spitting out nearly 16V at that range? Will I be buying batteries left & right? Is there anything I can do (add) to drop that voltage down?

I know I'm long winded (fast typer) so thanks for hanging in there if you've bothered to read this far...

I think your problem is the low voltage on the tailight wire that you have the 232 voltage sensor wire connected to. Voltage on the tailight should be close to the same as voltage at the battery terminals with the engine not running. I think if you will locate and correct the voltage drop on your tailight wire, you will find the 232 will regulate the charge rate correctly. Or, you could connect the sensor wire to another supply source such as the ignition switch.
It would be a better choice to fix the original problem though in my opinion.
The charging voltage youre getting now is way too high. It will shorten bulb life and ignition system life plus cook batteries. Average charge rate when tooling down the highway with everything on is no more than 14.2 to 14.6 regardless of how high the rpm. Up to about 14.8 is ok, but thats the max you want to see. Low 14's is better.

Earl


[QUOTE=shamer]
I then installed a '78 SH232-12[/B] - I spliced a 14 guage Y (w/soldered bullet connectors) to the tailight positive lead and connected that to the black wire of this RR. I was bit disturbed by the low reading of 10.7V at this wire - is this significant? I ran a lead directly from the RR green wire to the battery (-) terminal and all other connections are otherwise the same as other RR. Here are my test results:

Yes, the whole point of the voltage sense wire is to read the true battery voltage instead of reading through the R/R output wire which may be inaccurate if a connection(s) are corroded. The voltage drop in the tail light circuit is significant and will cause the R/R to read the battery voltage as only 10.7V.

When the sense wire reads an inaccurate low voltage, the R/R will raise the output voltage to an unacceptably high voltage trying to match its output to the bogus battery voltage from the sense wire. Your tail light is probably much dimmer than it should be, and a voltage drop of this magnitude should definitely be fixed.

Thanks a ton, guys - I really appreciate you taking the time to walk me through this.

When I first noted the low measurement at that wire, I did check the bullet connections leading to the tailight & they all seemed fine. I have not popped the tailight itself open yet & as you can probably tell, electrics aren't my strong point - is there anything in particular to watch out for? What kind of things cause voltage drop? I know distance and resistance can do that - and many lightly corroded connections could raise the resistance of the path & lower the voltage, right? Is that it? I mean, this seems like a pretty significant drop...

Thanks again!

Shawn

Yes, it's usually corroded or loose connections or bad grounds that cause this type of voltage drop, or a combination of same. It could also be a bad switch, i.e., if the ignition switch was not making good contact it could drop voltage all over the bike.

Corrosion on connectors isn't always easily seen, as all it takes is a thin film of oxidation to raise the resistance enough to cause a voltage drop. Radio Shack has a closeout on Caig DeoxIT, which is a very effective oxidation remover. It is normally very spendy, but Radio Shack is selling it for $1.97 if you can still find it. Electrical grease is also helpful in preventing corrosion.

I'll make a note of that - I actually find myself at my neighborhood Radio Shack fairly often, but unfortunately they seem to becoming more of a Five & Dime than what I expect them to be so that's beginning to happen less frequently...

Well, I went through a good portion of the wiring and spent a lot of time just taking connectors apart & putting them back together, using a bit of WD-40, sandpaper & bulb grease when possible. Made a little difference anyway - I'm at a maximum of 15.7V through the revs up to 5800RPM and at idle (~1200RPM) it flirts with 13V. Is this acceptable yet? [-o&lt;

The only other thing to note is that when I pulled the headlamp bulb I discovered that the sensor wire connection went from its 10.7V up to 11.4V. Seems pretty significant, but I'm not sure what that tells me other than that headlight sucks up a bit of juice. As I connected/disconnected the lamp you could see the difference in the brightness of the tail light (it was twilight out). Does this tell you anything?

The rear turnsignals and tailight are usually isolated and rely on a wire for ground which usually terminates in a ring connector held down with a bolt. I would check grounds on the tailight assembly/turnsignals before progressing to trying to track down voltage drops and corrosion in the 12v+ supply wires.
Oftentimes, I have found voltage drops are cumulative and dont find all of the problem in a single connector or location.

Earl

No. 15.7V is way too high and will fry the battery.

Yes and no. Yes, turning the ignition/lights on without the engine running puts a load on the battery and will cause the voltage reading to drop a bit as long as it is loaded without charging. No, this isn't sufficient to explain the size of the voltage drop at the sensor connection.

My theory is that the corrosion problem can't always be eliminated by a simple cleaning of connector surfaces. Crimped connectors are typically made of a different material than the wiring, and have a different coefficient of thermal expansion. That is, when the wire and crimped terminal go through enough heat/cooling cycles, the crimp connection may be compromised and air may enter and form oxidation between the inside of the crimp and the wire. Cleaning the oxidation from outer surfaces helps, but doesn't reach the critical inside of the crimp. I think that to bring the wiring back to original conductivity, you would have to install new crimped connectors or solder the wires together. If a person doesn't have the right know-how and tools, they can do a really poor job of installing new crimp connectors. Same with soldering, but most people on this forum have solved electrical connection corrosion problems by removing the connectors and soldering the wires together.

Fixing the voltage drop is an interesting challenge, but I would want to be certain that the R/R is working properly before investing too much time running down voltage drops. I would temporarily connect the sense wire directly to the battery positive terminal and start the engine and run it at 5,000 rpm to see if the voltage stabilizes in the 14.0-14.8 range. If so, this is the proof of the pudding that you have a good R/R and the voltage drop is causing the overvoltage condition. If not, the R/R is bad and you will need to get another. Don't worry about the temporary connection of the sense wire to the hot terminal. It isn't normally done this way because it will cause a battery drain when the ignition is off. This is why it's connected after the ignition is turned on.

Turning off the headlight and it resulting in a temporary voltage increase (engine running) is normal. Sorry, but 15.7 volts is completely unacceptable. Maximum acceptable under any condition, at any rpm, is 14.8v. I have returned new R/R's that charged at 15 volts as faulty and they have been replaced by dealers at no charge.

Earl