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I do not agree that the 1300 violates the NMRA standard. Here's the actual sentence at issue: Digital Decoders intended for "N" and smaller scales shall be designed to withstand a DC voltage of at least 24 volts as measured at the track. The point I've been making since I chimed in on this thread is that that kind of statement must refer to the RMS voltage, not the peak voltage.
Getting back to the word "spikes", I wonder how these various DC power packs behave during short-period transients associated with things like intermittent losses and reconnections of electrical contacts between track and pick-up wheels, and short-period short-circuits like occur on Atlas Code 80 switch frogs with wide wheels passing over them.
You don't get an inductive kick off a transformer secondary when you interrupt the load on it for an instant. Unlike a motor winding, something about a transformer causes it to not store energy that would be released from a collapsing magnetic field that way it does in a motor. I admit, I'm on shakey ground here as my AC and magnetics theory is not sharp, but have read this in more than one place over the years and I accept it as true.Given that, I don't see how a spike would come out of the power pack just because wheel pickup goes intermittent.And since the transformer secondary can't deliver more than 25 volts and there are no capacitors in the circuit, so I do not see anywhere that a "spike" can come from.I'll take this opportunity to repeat my request for a 1370 test subject to borrow and open. I want to investigate some things in that unit that may shed light on the 1300.
I'll take this opportunity to repeat my request for a 1370 test subject to borrow and open. I want to investigate some things in that unit that may shed light on the 1300.
The problem, however, is that DCC power supplies use square waves (as Peteski altered me to earlier). As such, the peak voltage = the rms voltage. So when a user puts a meter on the track on a DCC system and measures, say, 16 v, the spec would say "that's okay" because on a DCC system, that 14v would also be the peak (whether the user realizes that or not). But in the case of the 1300, the meter would read 16v and there would be peaks of 25v.I think this is a situation that the spec did not take into account.
Max, any damage that the railpower 1300 or any other DC powerpack might cause a decoder has nothing to do with a DCC waveform. Measuring DCC waveform RMS voltage accurately is a whole other discussion. The way I read it, that 24VDC in the standard applies to analog mode. If that's not what they intended, they did a very poor job communicating their intent. But maybe there's nothing surprising about that. All I'm saying is if they meant that 24VDC to apply to high frequency waveform peaks, they darn well should have said so. Because only a more-than-typically-knowledgeable hobbyist would even glance upon the thought that they might have meant that, instead of meaning an RMS i.e. 'what i measure with my non-scope meter' voltage.
I know how you are interpreting that sentence, but I think it's clear what they meant. They did not mean it had to withstand "any voltage of 24 or more". The modifier "or higher" is clumsily placed in the sentence.It means the decoder must withstand a DC voltage of 24 or more - or in other words, at least 24v. If it withstands 24, it meets the spec. If it can withstand 50, it meets the spec. If it can only withstand 23, it does not.
I don't know if you would get inductive spikes from momentary power loss, but you will get reverse-voltage spikes, if the loco has a flywheel, or the motor has enough rotating mass to act as one. That's why, on DC, you sometimes see the rear headlight flashing when going forwards, or vice-versa. It isn't noticeable with bulbs, but with LEDs it shows very nicely. However, the voltage shouldn't be higher than the track voltage, and DCC decoders don't care about input polarity, so I wouldn't think it would be a problem.
Max: Thank you! Would that still be the case when the spike is shorted through an LED headlight?Peteski: That's good to know, but what about reverse voltage to the decoder itself? Especially in light of Max's comment about the possible voltages involved? Or is there enough capacitance in even basic decoders to prevent momentary contact losses from affecting the motor?In any case, this wouldn't be unique to the Railpower 1300, as dirty track/wheels are independent of the power supply.
I think Peteski covered it all, but yes, the inductive spike would go back through an LED in reverse. Most LEDs have a reverse breakdown voltage high enough that they can handle it and will not conduct and will not burn out. But white LEDs were notorious for being damaged this way because they have lower reverse breakdown limits than other types. It is often recommended to wire a Schottky diode in reverse across the LED to conduct the spike around the LED. Schottky types turn on quicker than a conventional silicon diode. Sometimes people use a little ceramic capacitor across the LED. You just need something that will conduct more instantly than the LED to short the spike out.In my case, I used the little ceramic cap and it does seem to have worked. I have not had the rectifier fail since I put the cap in.
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Topic: Railpower 1300 testing (Read 41006 times)
