I am not being overly critical - that is how it is. It works! Since it is in a fiddleyard, the public will not see this unprototypical behaviour. The system will also run DCC, but again when the relay is triggered the train will come to an abrupt stop - more gentle if a stay-alive is fitted - and care must be exercised, that such locos do not over-run into the next section. Set the speed of locos in staging slow enough, so this does not occur. Leave sufficient gap between the sensor and the next section. Also, the sound (if fitted) will stop - the DCC train will be effectively dead. If the same DCC feed is then restored to the tracks, the train will take off, as it would following a power drop-out due to a short-circuit.
Here is an infra-red sensor from Heathcote Electronics in the UK...
http://www.heathcote-electronics.co.uk/
Heathcote Electronics products are imported and promoted in Australia by Warren Herbert and his company Gwydir Valley Models, from Glen Innes, NSW.
http://www.gwydirvalleymodels.com/
Most devices come under the title IRDOT - Infra-Red-Detection-Of-Trains.
Here is one such product - an IRDOT 2 - and on the right hand side, two black boxes marked OKO. These are the relays. Each one is a single-pole-double-throw relay, but together they represent a DPDT switch (which comes standard with most DC controllers to allow locomotives to be reversed).
[CLICK ON THE IMAGES TO SEE THEM FULL SCREEN]
[HIT ESCAPE TO RETURN TO THE BLOG]
With an IRDOT 2 (with relays) in conjunction with an IRDOT 1 (which has no relays) placed a distance apart on a section of track, it is possible to run a locomotive or train backwards and forwards between the two sensors in a shuttle operation. At each end, the train can be held stationary for a controllable period of time, then the DPDT switching by the relays will reverse the current, and the train will head off in the opposite direction and continue indefinitely doing the same thing at either end of the track. Here is a simple demonstration of that operation on a section of test track and a DC locomotive.
[CLICK THE BOX IN THE LOWER RIGHT CORNER TO WATCH VIDEOS FULL SCREEN] [CLICK AGAIN IN THAT BOX TO RETURN TO THE BLOG]
Using the same section of test track, and just two sensors (we do not need the relays on this occasion) wired to an NCE MINI PANEL we can control a DCC locomotive to run with far greater subtlety. We can do slow starts, we can brake gently to a stop - no jerks - and we can include whistles, lights and bells (if available and required).
In this image we can see the two wires running back to the MINI PANEL from the sensors, then a spiral cable connecting the MINI PANEL to a SB5 smart booster, that is actually controlling the train, with the commands coming from the MINI PANEL.
This is the beast doing all the heavy-lifting - an NCE MINI PANEL. In a future post I will describe how to program this device.
Returning to our DC fiddleyard - let's try to store a train. Thomas approaches with Annie and Clarabel, and runs all the way through the yard to the blue sensor. We want him to wait here, so when the relays open he stops, with a bit of a shudder. If we want him to go onto the mainline and do some work, we press the blue button, which supplies some power, and Thomas lurches off with his coaches onto the layout.
When more trains enter storage, they close-up nose-to-tail behind trains that have previously entered staging. BLUE Thomas is already being held. If he were to leave, both relays would close, and power from the second relay would energize PINK Thomas to move up. That is NOT going to happen just now, we want to see what happens to GREEN Thomas. He is receiving power because the green relays are closed. Not only does he have power in the section he is in, but also in the section ahead of him. He will run all the way up to the green sensor, open those relays and stop. If BLUE Thomas is released, the other two will advance, in that ABRUPT manner I have been speaking about, until they are also waiting, ready for their turn on the layout.
It is possible to program the same thing into a MINI PANEL and run a nose-to-tail storage yard with DCC. [Again, I will describe the programming of MINI PANELs in a separate post.] In the following video we see three locos being controlled, and there are three IRDOT sensors set up as well. One locomotive enters the mainline and runs through our beautifully landscaped layout and returns to the fiddleyard behind the scenes - the yard is full - so it is held short of the entry point. The next loco then moves up, and the third, making way for the waiting engine to go into storage. Once this happens, the lead engine can take to the layout and do its tour of duty.
We can observe one of the downsides to this system - the MINI PANEL is quite linear - it does not do well at multi-tasking - it can only take on one job at a time. It can only run one engine at a time. In fairness, it does a great job at this, gently accelerating and braking our locomotives. We could have this system running out on the mainline in public view, stopping trains very gently at signals and starting them again, (also very gently) when the line is clear. I am sure the public and occasional visitor would be impressed. [In a future post, I will discuss how this is achieved.]
BUT... if we want to have one MINI PANEL controlling the yard, and one MINI PANEL controlling the mainline, the two controllers are going to have to HANDSHAKE. There is a problem running a loco between two controllers. When it crosses over from one to the other, the engine's wheels allow signals to cross-contaminate section A and section B. So during the electronic handshake, we build in a delay, allowing the train leaving section A to completely leave that section before the possibly FASTER power for section B is applied. The handshake will also have to be applied when the loco leaves the mainline section and returns to the yard.
This operation too will be the subject of a future post.
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