The dual spark CDI unit from cncengines.com arrived promptly after it was ordered. At 1.75" x 2.75" x 1" this new version of their ignition comes potted inside its own enclosure but is larger than the PC board units I've purchased in the past. The second coil in this particular model may account for some of the extra size. Testing showed the outputs fire on the rising edge of the input pulse (i.e. magnet moving away from the Hall sensor) which is how the previous generation units functioned.
My plan is to place the ignition behind a control panel that I'm adding to the stand near the front of the engine. In order to accommodate the starter, a sealed 12V lead-acid battery will be used for power. Since the CDI requires something less than 6V, it will receive its power through a step-down converter installed inside the control panel's housing. A second adjustable converter will be used to regulate the flow of a recirculating fuel pump that will supply fuel to the carburetor bowl. I've used these inexpensive converters in the past with no issues so far:
https://www.amazon.com/gp/product/B07DYPMPJG/?tag=skimlinks_replacement-20
A pair of holes were drilled through the side of the enclosure above each converter board in order to access its adjustment pot and for a light pipe to make its onboard led visible from outside.
The housing will also contain a 30 amp starter relay as well as a version of the Hall indicator circuit board that I've used on all my other CDI-fired engines. This indicator uses an led to display the state of the Hall sensor without need for powering up the CDI and dealing with its high voltage. This has been very convenient for engine timing and troubleshooting in the past.
The housing for the control panel will eventually contain a mixture of small signal, high voltage, and high power circuitry all operating in close proximity. Both converters as well as the CDI contain high frequency oscillators that, along with the starter relay, will generate plenty of electrical noise. I spent time arranging models inside a virtual housing in order to come up with a placement that will hopefully minimize interferences among them.
The control panel was recessed into the rear of its housing. This will bring a number of otherwise protruding switches and indicator lights within the protective envelope of the enclosure. The real reason for doing this, though, was to make an otherwise boring box into something a little more interesting to work on. The enclosure was milled from a chunk of ebay Delrin that wound up mostly as chips. Fortunately, the block was thick enough to yield a slice for its cover.
The panel connectors for the Hall cable, starter motor, and fuel pump will be JB Welded into the rear side of the enclosure. Since Delrin's slick surface isn't conducive to good adhesion, the joints were designed with internal irregularities which will grip and stabilize the essentially potted connectors. A standard Futaba J servo connector will be used for the Hall sensor cable, but the RC aisles of a local hobby shop were shopped for the other two connectors.
In order to help test the starter system, I made a temporary clear plastic plate to support the outer ends of its driven shafts inside the cam box. This will allow me to see the chain drives in operation since they will later be hidden behind the cam box cover.
The plug wires will be brought out through the enclosure's cover in order to keep them as far away from the Hall sensor wiring as practicable. I had a bit of fun with the cover design which resulted in a lot of extra machining to make it look like a heat radiator. Even though the enclosure may seem to be larger than necessary, it looks like it will be filled almost completely with electronics. - Terry
My plan is to place the ignition behind a control panel that I'm adding to the stand near the front of the engine. In order to accommodate the starter, a sealed 12V lead-acid battery will be used for power. Since the CDI requires something less than 6V, it will receive its power through a step-down converter installed inside the control panel's housing. A second adjustable converter will be used to regulate the flow of a recirculating fuel pump that will supply fuel to the carburetor bowl. I've used these inexpensive converters in the past with no issues so far:
https://www.amazon.com/gp/product/B07DYPMPJG/?tag=skimlinks_replacement-20
A pair of holes were drilled through the side of the enclosure above each converter board in order to access its adjustment pot and for a light pipe to make its onboard led visible from outside.
The housing will also contain a 30 amp starter relay as well as a version of the Hall indicator circuit board that I've used on all my other CDI-fired engines. This indicator uses an led to display the state of the Hall sensor without need for powering up the CDI and dealing with its high voltage. This has been very convenient for engine timing and troubleshooting in the past.
The housing for the control panel will eventually contain a mixture of small signal, high voltage, and high power circuitry all operating in close proximity. Both converters as well as the CDI contain high frequency oscillators that, along with the starter relay, will generate plenty of electrical noise. I spent time arranging models inside a virtual housing in order to come up with a placement that will hopefully minimize interferences among them.
The control panel was recessed into the rear of its housing. This will bring a number of otherwise protruding switches and indicator lights within the protective envelope of the enclosure. The real reason for doing this, though, was to make an otherwise boring box into something a little more interesting to work on. The enclosure was milled from a chunk of ebay Delrin that wound up mostly as chips. Fortunately, the block was thick enough to yield a slice for its cover.
The panel connectors for the Hall cable, starter motor, and fuel pump will be JB Welded into the rear side of the enclosure. Since Delrin's slick surface isn't conducive to good adhesion, the joints were designed with internal irregularities which will grip and stabilize the essentially potted connectors. A standard Futaba J servo connector will be used for the Hall sensor cable, but the RC aisles of a local hobby shop were shopped for the other two connectors.
In order to help test the starter system, I made a temporary clear plastic plate to support the outer ends of its driven shafts inside the cam box. This will allow me to see the chain drives in operation since they will later be hidden behind the cam box cover.
The plug wires will be brought out through the enclosure's cover in order to keep them as far away from the Hall sensor wiring as practicable. I had a bit of fun with the cover design which resulted in a lot of extra machining to make it look like a heat radiator. Even though the enclosure may seem to be larger than necessary, it looks like it will be filled almost completely with electronics. - Terry
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