The distribution of electrical power in a car through the use of switches, fuses and relays is about as old as the car itself. However, Australian aftermarket electronics manufacturer MoTeC has now released a range of Power Distribution Modules (PDM) that replace much of this traditional wiring. The advantages include lighter weight, much better electronic protection of circuits, and the ability to implement smart switching. The cheapest PDM costs AUD$1870. OverviewThe PDM comprise software-configurable systems that use internally mounted, high-power output transistors. The base unit PDM15 has 15 outputs (eight 20 amp outputs and seven 8 amp outputs) and 16 switch inputs. Also available are the PDM30 (30 outputs, 16 inputs), the PDM16 (16 outputs, 12 inputs) and the PDM 32 (32 outputs, 23 inputs). Note that ‘like’ outputs can be paralleled for extra current capability. For example, three 20 amp outputs can be wired in parallel for a 60 amp load. The PDM15 and PDM16 use magnesium alloy cases and weigh just 260 and 270 grams, respectively. The larger PDM16 and PDM32 use alloy cases and weigh in at 330 and 405 grams. As this diagram shows, the PDM completely replaces the fuse and relay boxes.
WiringThe easiest way of seeing how a PDM can be used is to compare traditional and PDM wiring. This diagram shows the conventional wiring for a fuel pump and electric radiator fan (thermofan). Each circuit requires a fuse and a relay, with the heavy current cables running right back to the ignition switch (or main fuse box). The low current side of the radiator fan relay is controlled in this diagram by the ECU – but this could also have been done by a temperature switch.
This diagram shows the same system but using a PDM. As can be seen, the PDM removes the need for relays and fuses, in addition to simplifying the heavy current wiring.
Darren Reynolds, a MoTeC development engineer, runs a PDM in his SR20 turbo-engined Nisan Bluebird. In that car the PDM controls items like the lights, wipers and horn. This is the factory wiring loom that was surplus after the PDM was installed. FunctionsSo why use a PDM? As the high currents are switched by transistors, there is no need for relays. Relays can be unreliable in harsh environments and weigh more than using the PDM. The PDM replaces the need for individual circuit fuses. Instead, current monitoring is carried out by the PDM. Each circuit can have a software-specified maximum current (programmable in 1 amp steps). The PDM uses internal software to simulate the temperature rise of a wire subjected to current overload. This allows the system to cope with short-term current gulps (like those that occur when switching on electric motors) but still be sensitive enough to protect wiring in the event of a true overload. In addition, the PDM can be programmed to try reconnecting the circuit after a fault condition has caused a shut-down. The PSD can be programmed to perform special switching functions. These include:
For example, the immobiliser / alarm system can be configured like this: To start engine
Alarm triggers
Alarm Output
Clearing Alarm Condition
Horn Operation
Because all of these outcomes are programmable, any of these aspects can be changed. For example, an existing switch other than the horn button can be used. In addition to the outputs being programmable, the inputs can also be software-configured. For example, anti-bounce and variable hysteresis functions can be implemented to provide better reliability in accepting switch inputs. Switch inputs are required to connect to ground (that is, when the switch is operated, the input to the PDM is pulled to 0 volts) and so switches need to be configured in this way. (Note: many standard switches in cars don’t do this, instead connecting to battery voltage when closed.) While the inputs to the PDM can be configured to switch when a certain voltage is reached, the inputs are not currently ratiometric, meaning that as battery voltage fluctuates, so can the switching point. Thus, at this stage, sensors (eg coolant temp sensors) cannot be connected to the PDM to allow direct operation of the radiator fan. (Instead, in this example, a temp switch would need to be used. We understand that ratiometric inputs are under development.) With the connection of the PDM to a MoTeC ‘hundred series’ ECU or dash, much more sophisticated logic can be implemented. For example, as shown here, the radiator fan can be controlled on the basis of engine temperature, ground speed, engine rpm and a cool-down switch input. In addition, with CAN connection, single pushbutton engine ‘auto start’ can be implemented (as occurs in some current cars that use smart pushbutton start), and current logging and dashboard fault indication can occur. Another function of the PDM is monitoring. A laptop PC can be used to instantly see the status of:
...and some other information. The PDM is rated to run at a continuous 100 degrees C, a temperature that will be attained with all loads running at maximum current. The mounting location should take this maximum temp into account. ConclusionThe PDM has potentially great value in a variety of cars. We can see it being very useful in racing machines (its primary design purpose), but also in ultra-lightweight vehicles and home-builts. We’d like to see better, flowchart-based software for configuring the internal logic functions, and also PWM control of outputs (allowing for example light dimming, fuel pump speed control and radiator fan speed control) – and we understand that such improvements are being actively considered. But even as it is now, the PDM has the potential to revolutionise power wiring in cars.
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