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I'm still documenting my DCC install, but life gets in a way of the project. Will post it as time allows.My install will be covered in https://www.therailwire.net/forum/index.php?topic=56254.0As for "popping the shell", on this loco, it is anything but easy popping. This is a complex beast.Are the DCC versions out in the wild already? I'm also curious as to way Kato handled their install. Whatever they did, it required lots of precision manual labor.
I guess I missed the "tender" part. I just didn't consider that part of the DCC-fication of this model to be difficult. Since you are new here (that was your 1st post) I had no idea about your level of knowledge, or your plans.As far as making DCC conversion easy, due to the unconventional dual motor design, I really don't see any easy solutions Kato could have used to make this a DCC friendly DCC install. Funny thing is that Kato designers were most likely aware that Kato would be installing decoders in those engines and as you mentioned, except for come channels in the boiler frame for the wires, and maybe a PC board at the back of the boiler, there are no allowances for easy DCC install. The headlight is also a big issue. I wonder if they have special headlight PC board made for their DCC installs.I do like the idea of a custom PC board in the tender with a Nex18 connector (for when the decoder has to be removed/replaced) As for handling dual motors, I'm also in the dark. From what Kelly (ex. Kato USA DCC installer) mentioned when installing ESU decoders in Kato H0 P-42 diesels which also use dual coreless motors, the decoder handles it well. For chuff timing, as I understand it, the decoder is not "smart" enough to be able to distinguish between the revolutions of each engine's motor (since they are wired in parallel to a single motor output). BEMF based chuff timing can be fairly accurate, but to be in perfect sync, a cam would have to be used. Even with the cams, a dual cam input would be needed for true sync of the articulated engine (or using 2 decoders - one for each engine).EDIT: There is no separate adjustment for chuffs for both engines. You will has have to adjust for 8 chuffs per driver revolution (ant that will likely not sound very realistic since they will always be evenly spaced).
FURTHER EDIT: I am noticing that the wires on the videos shown before seem to be disguised as brake lines - a nice implementation. This answers most of my questions.
The way decoders determine the chuff triggering is not very well known to me, but they certainly use a feedback from the motor. The BEMF feedback loop is most likely candidate for that. There are also CVs which are used to properly set the timing with any gear ratio, but a physical cam is the most accurate way to sync the chuffs with not only driver rotation but with the correct rotation angle of the wheels. Yes, having each engine's cam in parallel connected to a single cam sensor would generate accurate chuff sync. But this is not something that is usually done in N scale (but it is done in larger scales).For more details on virtual cam synchronization procedure see the decoders manual. ESU LokSound has the process described in section 13.3 of the LokSound 5 manual. The best virtual cam I have worked with is in the old QSI decoders.I am also aware that Kato is going to use Soundtraxx decoders, but I did not know that it would be custom made for this model. Makes sense.Brake lines? Which video is that?
In the first video linked above watch the locomotive roll by - the wire setup is really clean. I'll look at virtual cam synchronization soon.
I watched the video multiple times and I didn't see any wires which would act as a cam. Maybe you could take a screen shot of the video and point out where you see those wires? Mechanical cams are usually hidden inside the frame.Also, the chuffs are not set up properly. you can clearly hear and see only 4 chuffs per driver resolution, which is correct for a 2-cylinder non-articulated loco. Simple articulate locos will produce 8 chuffs per driver revolution because each engine with its separate set of cylinders produces 4 chuffs per its driver revolution. But depending on the synchronization of the engines, sometimes the chuffs are distinctly audible, while other times they will blend together. That is the effect chat could only be achieved using a cam in each engine.However in N scale steam loco sound the chuffs are often set to less than prototypical because models are usually operated using out-of-scale (too fast) speeds and the extremely fast chuffs would not sound good.
I wan't referring to wires used for cams, only the wires between locomotive and tender to provide electrical connection between the decoder and lights.
There is a fella on Facebook, his page is called N scale Shenanigans. He just put 2 decoders in a Big Boy. Not sure why, I didn't really follow along, but I think it was so 1 set of drivers can slip when giving too much throttle. Here is a link to his page, or group, what ever it is. You may have to scroll down a few posts.https://www.facebook.com/search/top?q=n%20scale%20shenanigans
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Topic: Kato Big Boy K Rail DCC Install Photos Request (Read 1858 times)
