Why diode boards fail

by Bruce Schadel, June 2013

At 51,000 miles, I noticed the alternator light on my ‘92 ‘GS glowing at idle. Time for a new diode
board (again), I thought. When I removed the board, I found that both of the upper rubber mounting posts were broken–the stud end bolted to the board had come unbonded from the rubber. It was clear from the discoloration of the metal that those studs had gotten very hot. This occurrence is not uncommon as many Airhead owners know, but others who have written on the subject seem not to have noticed what I have.
The problem has been discussed extensively, but my observation suggests that solid mounts and a
bunch of ground wires with soldered lugs are not really going to fix it.

In the world of electricity, current times resistance equals power. If the resistance is in a bad
connection, power is wasted there as heat. Power from the alternator is supposed to replace the
power supplied to the bike and therefore keep the battery charged. But the bad connection I refer
to is at the point where the diode board is bolted to the studs.The voltage drop there causes the
the regulator to flog the alternator more to maintain the desired voltage at the battery. And that makes even more heat at the bad connection.

In the case of the two diode boards I have, the high resistance was on the diode board, between the
heatsink and the hollow rivet that contacts the mount and/or ground wire lug(s). It’s not at the
points where the diode leads are soldered to the board and therefore, it’s not because the leads
weren’t bent over. Sure, a bent-over lead would increase the thermal mass at that point and allow
it to absorb more heat before melting, but the real problem is at those rivets.

Below, I describe how I salvaged a failed diode board, but before going further I would like to
acknowledge that there are aftermarket diode boards that are both cheaper and better than the stock item as far as I know (I don’t own one yet). They are constructed differently and probably do not exhibit the problem I’ve seen with the BMW parts. I frankly recommend the aftermarket option over my kluge. I’m not selling anything here, my objective is to convey a bit of insight.

An aside: There is yet another dimension to the reliability issue. Will the stock charging system,
in otherwise good working order, leave you with a flat battery in the middle of a National Forest
somewhere because you rode all day at 1500 rpm to get there? If that bothers you Bunky, either wire up a switch so you can turn off the headlight when offroad or look into a higher-output alternator system.
Still here? Too cheap to buy another diode board if you can fix one of the dead ones in your junk
box? Just curious? Read on. The upper heatsink on the board is meant to be grounded, but the actual current path is from the aluminum heatsink through a cadmium-plated steel spacer, then through a hollow brass rivet and finally to the ring lug on the wire to engine ground.

My ohmmeter told the story: There was a high resistance between the heatsink and the spacer AND
between the spacer and the rivet on both sides. Pack rat that I am, I had kept the original diode
board in my junk box and when I measured that one I found the same thing.

The high resistance at the rivets explains the overheating.  Normal engine heat, occasional
moisture and the galvanic action between dissimilar metals cause the resistance to rise, creating
more heat which accelerates the process. And the excessive heat volatilizes some component of the
phenolic material, reducing its thickness and thus the clamping pressure of the rivet. Failure
seems inevitable.

I also found on both boards that several diodes, large and small, needed to be resoldered to the
circuit board, but I believe that was caused by the heat coming from the mounting area. That is,
the failed solder joints were a result, not a cause of the failure. The diodes themselves all
tested good.

It’s often recommended to replace the rubber mounts with solid ones for better cooling and
grounding (and so they can’t break again) and to add more or larger grounding wires. Sure, carrying away the excess heat is good, but it does not address the cause and doesn’t recover the wasted power.

Rather than buy another diode board, I decided to refurbish one. First I carefully inspected the
solder joints with a magnifying glass and resoldered the suspect ones. Then I drilled the heads of
the two brass rivets on the back side to release the steel spacers. I used a sharp wood chisel to
cut away the protruding portion of the rivets and filed them flush with the heatsink. After
replacing the broken rubber mounts, I slipped one of the released spacers over each upper mounting stud, followed by a ground wire lug, followed by a #10 star washer (external tooth lock washer) before installing the board. The star washer makes up for the lost thickness of the end of the rivet, but more importantly, it concentrates the clamping pressure onto a dozen small teeth which bite into both the heatsink and the lug to ensure a reliable low-resistance connection between them.

17,000 miles later, it’s still working perfectly. It cost me nothing and I’ve even got a good spare
(the first failed board).

A word of warning: The resistance heating can char the phenolic piece holding the assembly
together, making it fragile. The best time to apply this fix is when the board is new, or at least
before it fails. A failed board could be too badly damaged to salvage.

Here is the assembly sequence: The spacer goes on the stud first and allows the grounding lug to lay flat; The star washer goes between the lug and the heatsink making a low­ resistance connection between them.