The New-To-Triumphs Manual
- by Pete Snidal (C)2004
The Charging System
This part of the electrical system is responsible for maintaining the battery in a state of charge, by making DC power available to the various system loads - ignition and lights - with the rest of the power produced going to the battery, which accumulates power to be drawn upon when required.
The Alternator
The alternator is the heart of the charging system. Its function is to produce alternating electrical current (AC) by converting mechanical energy from the drive side of the engine crankshaft. It is located in the primary chaincase.
The Rectifier
The rectifier's function is to convert the Alternating Current from the alternator to Direct Current (DC.) This is necessary for battery charging - the battery can only store electrical energy as DC, although otherwise the lights and even ignition would run on AC.
The Voltage Regulator
The alternator's output (and therefore that of the rectifier as well) varies with engine rpm. To prevent overvoltage from damaging the other components of the system, a voltage regulator is necessary. It limits the maximum system voltage to just under 14 Volts. 13.8 is ideal, but anything over 12.5 will put a charge into the battery. System voltage is drawn down by loads, such as the ignition and lights, so the voltage regulator requirement is not full-time.
Although the original Lucas system incorporates separate rectifier and (Zener) voltage regulator, many aftermarket systems, such as the Tympanium (TM), Boyer Powerbox (TM), and Podtronics (TM) are one-piece rectifier-voltage regulator combinations.
The Battery
This is a vital component of a healthy charging system. It not only stores energy against low-rpm high-load requirements (such as sitting in traffic with lights on), but also aids in voltage regulation during periods of high alternator output.
The Capacitor
This optional add-on is a Good Idea (TM). A capacitor (4000 uFd, 50VDC rating) acts as a short-term battery, smoothing out the pulses of the pulsating DC rectifier output. In cases of dead battery starting, it will actually "hold over" alternator pulses between ignition system requirements to enable starting. This means that the timing of the alternator pulse and that of the spark at the plug don't have to be coordinated. In English, it means your bike will start with a dead battery - or no battery at all, which it won't without a "cap." The capacitor is connected in parallel with the rest of the system - its own little circuit - across the battery terminals, the rectifier output, wherever you like.
A. Single-Phase Systems
AC may be generated in various numbers of "phases" - this has to do with the number of poles in the rotating magnet, and how the field coils are connected. Pre-OIF, Lucas used a single-phase system.
B. 3-Phase Systems
Shown above is the single-phase charging system. Alternators can be made more efficient by a slight wiring and rectifier change, which makes them 3-phase. The major differences are how the alternator's 3 pairs of coils are connected internally, and the addition of a different (3-phase) alternator.

Note that now there are 3 AC conductors to the rectifier, and that the rectifier has 3 pairs of diodes in it instead of 2. Why 3-phase is more efficient is beyond the scope of this manual - for more information, consult an electical text. Connections internal to components are shown as black lines. Note also that the Lucas - and the Shindegen replacements - are built for (-) ground systems, ie the mounting studs are Negative. No sense of tradition, those people!

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