a) AC CDI, in which the HVAC (about 180V) is obtained from the source coil inside the magneto housing.
b) DC CDI, in which the HVAC is generated by circuitry inside the CDI, from 12VDC.
Then there are further 2 types in AC-CDI and CD-CDI which are usually used in performance bikes or heavy bikes. They are equipped with microprocessor to provide advance ignition curve for better burning of fuel inside the cylinder head. The captioned tester circuit is designed to test the CDIs without microprocessors.
Accordingly, two circuits are presented here. Studying both the circuits will reveal that the lower circuit is the portion of the first circuit. The first circuit is to test AC-CDIs. The transformer T1 converts 220VAC from mains to 12VAC and then T2 re-converts 12VAC to 220VAC. This set-up is to isolate the rest of the circuit from grid mains. This 220VAC is fed into the CDI's HV Input, replacing the HVAC which is obtained from bike's source coil.
The rectifier bridge converts 12VAC into 12VDC and C1 smoothes it. The SCR U2 is used to stop the 12VAC supply to T2, which will be discussed shortly.
The IC U1 is 555 timer configured as an astable multivibrator with duty cycle about 20% and frequency about 17Hz. The generated pulse train will replace the triggering coil pulse at fixed rate of about (17 x 60 =) 1020 RPM. The output is fed into the CDI's Trigger Input and the ground is connected to the (-)ve rail. The output is also connected to the gate of the SCR via R4. Whenever there is a positive pulse, the SCR will temporarily cut-off the 12VAC supply to T2. Hence, 220VAC supply to CDI will be paused. This is necessary to avoid a shorted path when the SCR inside the CDI is dumping the charge of the main capacitor.
The CDI's output is connected to one end of the primary of an ignition coil. The other end is connected to the (-)ve rail. One end of the secondary of the ignition coil is connected to a spark gap and the other end is connected to the (-)ve rail. The second end of the spark gap is also connected to the (-)ve rail. A strong spark across the gap will indicate that the CDI is good.
If the CDI under test is DC-CDI, the lower circuit will be used. The connections will be the same except the power supply will be 12VDC. The HVAC supply is built-in inside the CDI. A good CDI will fire strong spark across the gap.
|Circuit Exchange International||Return to TestGear||https://www.cxi1.co.uk|