Exactly correct Steve, all circuits have to observe the rules not just the R/R.

Yes R/R(+) has the higher potential than the battery or the load that is what is causing current to flow from R/R(+) to battery/load.

The stator actually is even higher at times which is how it forward biases the diodes to get current to flow through to the R/R(+) out.

Thanks for the Kudos, I'm hoping this makes it clearer why R/R connections are so important.

I am also surprised by the small size of the R/R (-) Since the wire is small coming out of the R/R it needs to be as short as practical.

Yep that is right on. I think the zener's break down voltage is actually lower but it is compared to a voltage divided 14V output for ratio regulation.

This is really another topic, I think the current implementations dont open the stator winding connections, but rather stay cooler because they don't use diodes in the lower legs of the rectified, they implement synchronous rectification by switching FET's on and off as a diode would. The FET's have much lower on resistance so it drops less voltage and create less heat.

Excellent,

Bakalorz,
I think that you are changing the rules a little including an AC v.s. strictly DC analysis, but that is OK. The original current flows for each option are show with the R/R as the only source of current. This is know to be the case when running down the road at say 3-5K RPM. If "Charging System" is operating properly the voltage at the terminals of the battery will be at 13.5V plus and so the battery can't source current. In the link I provided is a 1 Ghz bandwith scope plot using a current clamp to measure the current out of the R/R(+) lead. The average is about 10 amps. Even though there is some AC on top there is no indication of negative flow out of the R/R(+). In addition although I did not provide the plot, I described current going into the battery as being very similar to the plot shown, it simply varied with RPM. The most I could get out of it was 2 amps average.
It is possible of course for there to be a small instantaneous current coming from the battery during a dip in the ripple.

But here is the issue, if I take your two cases, and assume that there is some duty cycling back and forth between these two #5 and #7, your #7 ignores the continuous Amp average output of the R/R. In the plot below is my GS1100ED charging at 3000 RPM. There is no letup or spiking in the current flow on to cause a reversal. and so your #7 really violates the known behavior.

This is all true. The only time the R/R is not a source is when the engine is not turning.

I think the question as posed is accurate and representative of the electrical theory as well as the GS charging implementation. #5 is the correct answer as all current operates in a circuit.

All current coming from R/R(+) has to be returned on R/R(-).

The currents to the R/R(-) complete the crcuit for the currents in the stator.

It may be A$$ kissing but this is really the best answer to why I started the Contest.

Mad GS 750 You get a whole bunch of EXTRA POINTS (little arrows)

-> -> -> -> ->
-> -> -> -> ->
-> -> -> -> ->

And the 5 R/R connections especially.

After reading this thread, it is probably easier to understand why these two ground leads (one to the side plate where the solenoid mounts which leads to the R/R mounting) and the 2nd which goes to the battery box.

Both ground wires are crimped into the harness but the harness did not burn. This shows there was alot of current going from one ground to another ground. It was enough to over heat the ground wires and smoke off all of the plastic insulation.

I opened up the wrap around the harness which is why it is unbundled. None of those wires got hot other than being next to the smoking grounds.

This is how I found my GS750 EX right after I bought it. I read the stator pages and cleaned all my connections and everythiing was fine.

Before doing all this work I had already ordered new parts. Eventually I replaced the stator, but the same OEM R/R is still working with the improved grounds and heat sinking.

#4 current flows from a higher potential + to a lower potential -.

I have a question about SPG.
I have read that it is an invitation to corrosion... Is this true? And if so, how can it be prevented or kept to a minimum?

Dialectric greace would slow corosion down.

Using all the same type of lugs helps. As in all aluminum or all coper etc.




Its amazing what you learn when people are challenged

This contest was a great Idea

Ok, we have a fair amount to go over, and I need to use stuff from several posts, and I'm having issues with the forum getting them all to quote, so anything I write will be red, and anything of yours I'm quoting will be black, also the forum has a length limit so this will be two parts ...

Hang on, its a doosie, and ... Here we go ...


Before we start, just to clarify for any lurkers; the way the regulator regulates is that when the voltage starts to get too high, it briefly shorts the stator internally, and then lets it charge again. It does these cycles many hundreds of times per second. The period during which it is shorting is called shunting.

The first thing I want to establish is that when the regulator is shunting, there is Absolutely NO current ... Zip, Zero ... coming or going from the regulator to the battery or the rest of the bikes systems ...

One of the figures you provided shows this nicely:



Note what you wrote in your fourth sentence:
IT IS IMPORTANT TO NOTE NONE OF THE SHORTED CURRENT EVER PASSES THROUGH OUR CUT SET
BOLDED AND CAPITALIZED by you.

So there is NO current coming out of the regulator.

The three upper bridge diodes prevent any backflow of current the wrong way into the R/R. (with the exception of an insignificant amount that can still flow to the trigger circuitry)

So there is no current crossing the purple cut line you convientiently provided

So do you see that during shunting, there is absolutely no current being provided by the R/R to either the battery or the rest of the loads on the motorcycle ?

So as far as the battery and loads are concerned ... during shunting it's as if everything to the left side of the figure is erased and doesn't exist.

So now lets look at whats on the right side of the cut line, what's over there ???

A battery and some loads ... do those loads still require power ... do the lights, coils and ignitor shut down for 40-50 percent of the time when the system is regulating (you mentioned a duty cycle of about 40-50 percent in one of your other posts) or do they still keep functioning.

Those loads still require power, and convieniently they are still connected to a battery ... so when the regulator shunts and stops providing current, the battery takes over and supplies the loads during the period of shunting ... when the shunting period is over, the R/R starts to provide current to both supply the loads and replace the charge that just came out of the battery (plus a little extra to keep it charged) again.

Which is exactly what I described in my first post, using your figure 5 and my figure 7.

What causes the battery to alternately provide current and be charged as this cycle goes along? basically the voltage at its terminals: When there is no current from the regulator, the loads pull the voltage below the battery's resting voltage at the time (this resting voltage is significantly raised compared to the batteries normal resting voltage because the battery was just being charged a millisecond ago) When the regulator provides current, it raises the system voltage enough to cause the battery to accept charge.

So as the regulator alternately provides current and shunts, the battery voltage alternately bounces up and down by a fraction of a volt, causing the battery to alternately recieve charging current (from the R/R, which is also running the loads at that point)(your figure 5 that everyone likes) and then supply current (to the loads) (My figure 7 in my first post in the thread)

All this is a more detailed explanation of exactly what I wrote before.

Now lets look at your post ...



Continued next post, forum length limits

Continued from previous


Boy this got long, but ... In Conclusion:

I have demonstrated that my description is correct, according to the theory as shown in the Suzuki manual and your scope traces.

And since I was the only one to describe the actual operation of the R/R system accurately, correctly, and to such a level of detail, showing important features not even hinted at by anyone else;
I believe you owe me a shiny new (used) regulator.
(Sorry Rusty Bronco)


If you disagree with any point, I'll be more than happy to discuss any further points of contention.


Take it to your EE buddies at work, see what they say.


Further, I actively invite comments and especially questions from any of the other bystanders in the forum:
This was supposed to be an educational contest, and we learn by asking.


By the way, this contest has been one of the most interesting series of posts in a while, thanks for running it.


I am greatly looking forward to your reply.

I never said there was no current coming from the R/R or crossing the cut set. I posted that there is no shunting current crossing the cut set. I also posted a plot of output current from the R/R(+) RED output that shows there is 10 amp output maintained at 3000 RPM. I'll stop here.