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The T-Trak standard is Kato #6 turnouts for the mainlines. Kato #6s are always power-routing. Kato #4s can be either, based on positions of a couple of screws on the underside. Mine have always been power-routing out of the box. T-Trakers who want to use Kato #4s are directed to do some mods on the turnouts (filing points and stock rail notches), so specifying that they must be power routing isn't any substantial additional burden. But, there is the problem that the instructions are backwards, so some might inadvertently be made non-power-routing. But, that can easily be checked with a multimeter.
Almost certainly. DCC components are almost always more expensive to replace.The more I think about this the more I think that just using DCC circuit breakers might actually be enough to protect "the expensive stuff".
Max, that brings up the question about what to use for an "electronic fast-acting interrupter" for the DC circuit(s). Do you have a specific component that works for DC? I am thinking that it really should be in the DC power pack, where it can get continuous voltage, instead of being wired into the track output, where the voltage can range from zero to ~12 volts, based on throttle position. I guess you could externally power an appropriately designed external component wired into the track circuit, perhaps using the "accessory" output of the DC power pack, but that is usually AC power at maybe 18 volts rms. A battery might work if the interrupter's circuit is designed to fail open when the battery dies, so that it is "fail safe".
Thanks, Max. I understand the Hall Effect sensor. But, to make a circuit breaker, there still needs to be some steady power to the actual circuit breaking apparatus, whether it is a relay or something electronic.Are the circuit breaking mechanisms in the DC power packs made these days so inadequate that we should be adding some other device to do the job? Or is it just the really old power packs that are the concern?
Yikes! The Model Power Tech 7 is what is being used at the club, and, over a year, the temperatures change by large amounts (50s to 90s) in that building while the layouts are running. So, building an add-on circuit breaker system seems like both a good idea and a non-trivial task.
Max, you posted that your design includes 3 transistors, and previously posted that the trigger design needs to be temperature compensated if it includes transistors. It was the temperature compensation that drew the "yikes" response.So, I'm asking if the design you have is temperature compensated sufficiently for a range of ~50 to ~95 degrees F that my club experiences over a year.