Note: The information on this page is in process of being updated - in particular the Series current source circuitry has been changed to better accomodate 48v operation.
In general, all controllers made by 4QD are designed to work over a wide operating voltage range: the limits are set by the operating voltages on the MOSFETs and maybe other semiconductors, the relays and by the power dissipation in the current source transistor used for the internal supply. See Pro, Scoota, NCC and VTX series controllers. Internal power supply and protection circuitry for a description of how the powering works. The powering arrangements on the Uni are similar.
This means that essentially the same controller may be used on 12, 24 or 36 with only relatively minor changes. 48v operation is not quite so simple as this can rise to voltages well above the specifications of many common semiconductors, so several semiconductors are changed. It is therefore not acceptable to modify a controller to work on a voltage higher than that for which it was originally specified but a high voltage controller may be used at lower voltages by altering or removing the relay dropper resistor. However, in general the 12v, 24v and 36v versions use the same components.
In general the changes and components to check on all controllers are:
12v controllers use a 12v coil (resistance approx 150 Ohms)
Other controllers use a 24v coil (resistance approx 500 Ohms)
The relay manufacturer specified an operating voltage tolerance of typically 80% to 160% at an ambient temperature of 25°C.
36v and 48v controllers have a resistor in series with the coil.
The diagram below shows where this resistor is fitted. Beneath the resistor is a scratch-through consisting of two large copper lands with a thin track between. This track must be cut when fitting the resistor (or the resistor will be bridged out)
For converting a 24v Uni:
For converting a 12v Uni:
Warning: these values were correct at the time this page was written but several different manufacturers make the relay type used. If the coil resistance changes, so too will the value of this extra resistor.
Generally the same MOSFETs are used for 12v, 24v and 36v. Only the 48v version uses different MOSFETs.
The current source on 12v, 24 and 36v controllers is a TO92 transistor delivering about 30 milliamps. At 36v this drops some 28v so dissipates about 700mW so gets very hot! On 48v it would self-destruct (over 1 watt) so we fit a TO39 (metal cased) transistor with a heatsink. This is a factory-fit and is not suitable for retro-fitting!
Commonly 50v, OK for 12v to 36v but not for 48v which requires 63v capacitors.
This feature is not fitted to Uni series controllers.
12v, 24v and 36v controllers all use 47v.
48v controllers use 56v.
The position on the overvoltage zener is marked OVZ on the drawing above.
The pot circuit consists of a 10K resistor feeding the battery supply to a 6v2 to give a stable reference voltage to the pot. For 12v operation this resistor is reduced to 1K. If this resistor is not changed, the zener voltage will not be reached. However the 12v value of 1K can be used on 24v or 36v, but both zener and resistor will get hot (though within their ratings).