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Mystery part!!! Could it cause charging system problem? Pic in post

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    #1

    Mystery part!!! Could it cause charging system problem? Pic in post

    Ok GS'ers, heres the deal. My regulator/rectifier wasn't even hooked up!!! Instead my stator wires run to this.
    \/ \/ \/ \/ \/ \/ \/ \/ \/ \/ \/ \/ \/ \/ \/


    Now my guess is that it is a voltage regulator off a car and that it is the root of my charging system problems. My stator throws out 76 volts at 5k rpms but it doesn't reach the battery. Your insight and expert advice will be much appreciated as I am soooooo itching to ride this bad boy.
    Tags: None
    #2
    I think you're right. Take the auto voltage regulator, search out the previous owner and install it in an appropriate place so he will understand your displeasure. LOL

    The three stator yellow AC output wires MUST be connected to the rectifier three yellow AC input wires.
    The black (neg) and red (pos) wires coming from the R/R are 12 v DC output and should be connected to battery.

    E.
    Komorebi-The light filtering through the trees.

    I would rather sit on a pumpkin and have it all to myself than be crowded on a velvet cushion. H.D.T.

    Comment

      #3
      they run through the fuse box and are distributed from there actually if i'm correct

      Comment

        #4
        Its more efficient and less problematical to take a more direct route. :-)

        E.


        Originally posted by bigs_gs View Post
        they run through the fuse box and are distributed from there actually if i'm correct
        Komorebi-The light filtering through the trees.

        I would rather sit on a pumpkin and have it all to myself than be crowded on a velvet cushion. H.D.T.

        Comment

          #5
          Yeah but the fuse keeps my electronics from doubling over to a toaster.

          Comment

            #6
            The electronics are draw and are already supplied from the fuse block.
            The charging system is input. There are two common faults with the charging system. 1. the stator drops a leg and produces insufficient amperage. 2. The
            R/R burns out the high limit side and charges at too high a voltage. Fuses protect against too high an amperage draw. Voltage doesnt blow them.
            If your R/R goes belly up and starts shoving 18 volts into the battery/electrical system, the fuse is not going to blow, but the electronics will, the headlight bulb will burn out, the Ignition system will burn up, but not the fuse. You can run 1000 volts through that fuse and it wont do a thing to it. Its amperage/flow that will melt it.

            E.

            Originally posted by bigs_gs View Post
            Yeah but the fuse keeps my electronics from doubling over to a toaster.
            Last edited by earlfor; 05-08-2007, 11:05 PM.
            Komorebi-The light filtering through the trees.

            I would rather sit on a pumpkin and have it all to myself than be crowded on a velvet cushion. H.D.T.

            Comment

              #7
              It is a regulator, it looks a lot like the one that was on my Yamaha. They don't handle a lot of power, like around 200-250watts. I would swap it for a more robust unit.

              Comment

                #8
                Thanks clone. And earlfor, heat blows fuses not amperage. If a high voltage heats up the wires it will burn the solder filament.

                Comment

                  #9
                  Seems to be a chicken or egg situation. It takes amperage to make heat. LOL
                  E.


                  Originally posted by bigs_gs View Post
                  Thanks clone. And earlfor, heat blows fuses not amperage. If a high voltage heats up the wires it will burn the solder filament.
                  Komorebi-The light filtering through the trees.

                  I would rather sit on a pumpkin and have it all to myself than be crowded on a velvet cushion. H.D.T.

                  Comment

                    #10
                    fuses?

                    Well then... why in the world do they rate the capacity of fuses in AMPS as opposed to volts?

                    You are partially correct. When an AMPERAGE higher than the rated value tried to go through the fuse, it overheats, as designed, and melts the "filament" electrode.

                    Comment

                      #11
                      As voltage increases for a given load so does the amperage.

                      Current=Voltage/Resistance

                      If it was possible to have fuses that blow at a certain voltage then it would never blow unless you reg/rec fried out. Now in this situation if you had a short (ie. starter relay) somewhere on your bike you would melt the wires and not blow the fuse.
                      Last edited by Flatline_Racing; 05-09-2007, 11:49 PM.
                      Feel The Pulse!

                      1982 GS1100E with Tracy one piece body
                      2007 Roadstar Midnight Warrior

                      ebay cntgeek

                      Comment

                        #12
                        NO, if load remains constant and voltage is increased, then amperage required will decrease.

                        E.



                        Originally posted by Flatline_Racing View Post
                        As voltage increases for a given load so does the amperage.

                        Current=Voltage/Resistance
                        Komorebi-The light filtering through the trees.

                        I would rather sit on a pumpkin and have it all to myself than be crowded on a velvet cushion. H.D.T.

                        Comment

                          #13
                          Ok, both of you, here's what get you confused:

                          Earlfor: Yr. assumption applies for power (Watt)
                          P = U x I (Power = Voltage x Current)
                          - Increase the voltage with same load (in Watt) and the current will decrease.

                          The loads on a bike is mainly resistive, making Ohms law apply:

                          U = R x I (Voltage = Resistanse x Current)

                          or:

                          I = U/R ( Current = Voltage / Resistanse in Ohm )

                          Assuming the load is a light bulb, the resistance is near to constant, and this is effectively the load.
                          Combining the two formulaes gives
                          P = U^2 / R( Power = Voltage squared over Resistance)

                          Which of course shows that power actualy increases with the square of a voltage increase. That is double the voltage and you quadrupple the power over the same load.

                          This discussion was about current draw, but as it has already been pointed out - current draw is just the function of voltage over the "almost" constant resistance.

                          -blo

                          Comment

                            #14
                            Originally posted by blo View Post
                            Ok, both of you, here's what get you confused:

                            Earlfor: Yr. assumption applies for power (Watt)
                            P = U x I (Power = Voltage x Current)
                            - Increase the voltage with same load (in Watt) and the current will decrease.

                            The loads on a bike is mainly resistive, making Ohms law apply:

                            U = R x I (Voltage = Resistanse x Current)

                            or:

                            I = U/R ( Current = Voltage / Resistanse in Ohm )

                            Assuming the load is a light bulb, the resistance is near to constant, and this is effectively the load.
                            Combining the two formulaes gives
                            P = U^2 / R( Power = Voltage squared over Resistance)

                            Which of course shows that power actualy increases with the square of a voltage increase. That is double the voltage and you quadrupple the power over the same load.

                            This discussion was about current draw, but as it has already been pointed out - current draw is just the function of voltage over the "almost" constant resistance.

                            -blo
                            GREAT reading...I happen to like math! \\/ :-D It almost always settles the dispute.

                            Comment

                              #15
                              Thank You. :-) Thats what I thought I said. Apparently, I was only clear in my own mind. hehehehe

                              E.


                              [quote=blo;634070]Ok, both of you, here's what get you confused:

                              Earlfor: Yr. assumption applies for power (Watt)
                              P = U x I (Power = Voltage x Current)
                              - Increase the voltage with same load (in Watt) and the current will decrease.
                              Komorebi-The light filtering through the trees.

                              I would rather sit on a pumpkin and have it all to myself than be crowded on a velvet cushion. H.D.T.

                              Comment

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