Originally Posted by
philwsailz
Glad to see you got a source for the image Jughead! Sorry about not getting your PM until this morning.
An item often overlooked, yet really a major contributor to trim pops is the fact that we are energizing a magnetic coil in the valve solenoids. When we hit a switch we pour 12 volts into the coil creating the magnetic portion of a linear motor, causing a hunk of magnetized steel to move, opening a valve. When we release the switch, we turn off the voltage, the magnetic field collapses.... the steel actuator returns to rest, moving through the coil.... Ther are three events total, one being the switch being hit. Then two separate events when you release the switch, although simultaneous... Both potentially making noise.
On the topic of magnetic fields collapsing in coils, how many of you know how a magneto works on a PWC, lawnmower or motorcycle? Flying a magnet by a coil we induce a current and a voltage in the coil called the primary coil. Then the points open, (same as releasing a switch) creating a similar collapsing magnetic field. The collapsing magnetism in the primary coil induces a current and a very high voltage in the secondary coil, which is connected directly to the spark plug! Bottom-line a coil will create a lot of energy when you REMOVE power from it, just like the switch can create a spark which makes its own noise. This in part explains why sometimes you hear pops both when you press the trim switch AND release it.
The second thing to consider when you release the trim switch is the part of the solenoid that moves inside the coil that opens the valve. When you release power, that magnetized metal MOVES from the valve-open position to the valve-closed position. When you move a magnet past a coil what do you get????? ding ding ding.... voltage and current...
So considering this and thinking it through there are actually several contributors all aligned against you in any solenoid controlled device... both when you push the switch AND when you release it.
I am of the opinion that the capacitor installation benefits a trim circuit in two ways. First, when hitting the trim switch to energize the solenoid, the capacitor slows the transition from zero volts to 12 volts in the solenoid coil as a function of charging the capacitor. If viewed upon an oscilloscope the capacitor "rounds over" the sharp transition from zero volts to 12 volts.
Then when the switch is released the capacitor absorbs the transient created by the collapsing magnetic field, shunting it slowly to ground, (slowly is a very relative term here...).
I try to keep my explanations relatively simple, but this one went a little further than usual. Hopfully it makes sense?
Phil
Kicker