It opens the “Manual” section of the October 2015 issue. So, three off-the-shelf white kits should work fine, but if you were using the red/yellow kits, you would want to substitute in a different resistor value, perhaps 150 ohms or so.This piece marks my third by-line in Popular Science. One note is that our white Flickery Flame kits are designed to run from 4.5 V DC, but the red/yellow Flickery Flame kits are designed to run from 3 V. If your machine’s output circuit was rated for 0.25 A, then you would have enough power to run three Flickery Flame kits off of that one output. You could also run flickery flame kits directly from that 4.5 V DC.
6.3 V AC will give you roughly 4.5 V DC with this circuit– enough voltage to power two LEDs in series, or one in series with a resistor. This circuit can be made as simply as four diodes plus a capacitor, or with an off-the-shelf bridge rectifier (e.g., Jameco Part number 178001, $0.29) and a capacitor (say Jameco part number 93761). You can read more about this see an example application, here: Īs far as the AC goes, I would recommend that you build a basic AC to DC converter, such as the “Full-wave Rectifier with Smoothing Capacitor” described here: With several flickering LEDs, each in series with several more LEDs, you can make a wide and striking effect. For example, one flickering can be used in series with one or more non-flickering LEDs, and will cause all of the LEDs in that series-driven set to flicker together. However, there are some good ways to get the basic result that you are after. Think of the processor in each LED as being a bit like a computer– when you remove power (whether that’s by switching it with AC or by putting it in series with an LED that blinks off its power), it reboots, and never gets to run its flickering program. The flickering LEDs cannot be used in series, nor directly driven by AC. This topic was modified 4 years, 2 months ago by Windell Oskay.
My kits should arrive this week and I’m hoping it’s possible to do what I’m after with these kits. The RadioShack kit has a miniswitch that I considered running long wires to the coin door and operating the switch manually, if I can’t figure out a way to wire it into the game, but I’d prefer an in-circuit solution. I would love to be able to have this just power on with my game. A slightly lower powered #47 bulb is 6.3V with. The standard #44 bulb for a pinball backbox general illumination is 6.3V with. My questions are:ġ) Can I wire three flickery flame kits together in series and use one battery pack?Ģ) If yes for #1, can I wire all three from a) one battery back OR better yet b) convert it to AC for use in the pinball general illumination circuit? This led me to finding the Flickery Flame kit which looks to be the perfect size for my needs. The instructions mention you can wire up to 3 in a row so, I look up the yule log kit and it is no longer to be found anywhere online. But the board is a bit oversized and I would actually need 2 additional kits to wire in serial for the full effect I am after.
I put it together and it sort of works for the backglass feature, but runs on 4 AA batteries, so 6V. I got to thinking about what it would take to reproduce something similar, and it dawned on me that 5 years ago, I bought a Yule Log fire sim LED kit from RadioShack and had never assembled it. That person was supposed to be building kits for people, but as of a year ago, he has fallen silent. I have a pinball machine that has a backglass feature that is perfect for some flickery backlighting and someone created something similar to a Flickery Flame kit and wired it to their pinball light circuit.