Controlling existing relays
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Latching relays - I can see a small latch physically move when I switch on / off the lights. I think they might be powering my button lights as well since there are a thin wire connected to each relay in addition to the 230V wire. At least that thin wire must be for the impulse making the relay switch. Does this simplify things @Sparkman ?
@TimO , could you visualize how you have connected the different parts, or better yet use my uploaded pic to show me how I should connect everything?
Greatly appreciated!
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It would be nice if your relays could hold with DC voltage. Do you have a chance to remove one of them, just to try it? Use a 24 DC voltage and try to make a relay click to close. See if it holds. If it does than you can use Mosfets to control them. Be careful, 220AC is lethal.
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Latching relays - I can see a small latch physically move when I switch on / off the lights. I think they might be powering my button lights as well since there are a thin wire connected to each relay in addition to the 230V wire. At least that thin wire must be for the impulse making the relay switch. Does this simplify things @Sparkman ?
@TimO , could you visualize how you have connected the different parts, or better yet use my uploaded pic to show me how I should connect everything?
Greatly appreciated!
@twosh said:
Latching relays - I can see a small latch physically move when I switch on / off the lights. I think they might be powering my button lights as well since there are a thin wire connected to each relay in addition to the 230V wire. At least that thin wire must be for the impulse making the relay switch. Does this simplify things @Sparkman ?
Yes it does, you would need to wire the new Arduino controlled relay in parallel with the existing wires (the ones to contact A1 and A2). One side of the 24 VAC power supply should be connected to either A1 or A2 and then the other side of the AC supply is connected through the switch to the other terminal. Just hook up the new relay the same way using the same 24VAC power supply if possible.
Also, if you want to know the status of the light, you could add voltage/current sensors on the output side that would connect to an input pin on the Arduino. If you're not comfortable working on the high-voltage side, you could measure the pulses on the 24VAC side as well.
Cheers
Al -
If they don't hold, then you can use a semiconductor called triac. Here is how you use one:
It is not 240V AC that you are going to regulate, it is going to be your relays 24V AC control signal. And load is your relay. -
Thanks guys! I will try to get a friend over who knows his stuff when it comes to electricity to help me out with the wiring.
Breaking it down, I'll need one arduino for controlling the relay board, and if I want a dimmer I would need to rig another Arduino with a dimmer circuit after each 230v relay I want to dim the lamps for.
@ceech - nice! I'll keep that diagram as an option as well - it would basically eliminate the need for the Arduino relay board I guess.
Thanks again!
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If they don't hold, then you can use a semiconductor called triac. Here is how you use one:
It is not 240V AC that you are going to regulate, it is going to be your relays 24V AC control signal. And load is your relay. -
found a kit on Ebay, but it's pricey.
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@ceech Just wondering, did you get a chance to test this circuit? I've been wanting to do this for a while., guess will be my next project. Will be great if I could get a kit on Ebay. :)
@jeylites No, I didn't try. It will work, though. You can try on a breadboard. You don't even need all the elements. Remove the 100ohm resistor and 0,1uF cap for testing. And the resistors can be replaced with similar. Be careful with the mains voltage, please. I'm tempted to make some boards just to try.
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@jeylites No, I didn't try. It will work, though. You can try on a breadboard. You don't even need all the elements. Remove the 100ohm resistor and 0,1uF cap for testing. And the resistors can be replaced with similar. Be careful with the mains voltage, please. I'm tempted to make some boards just to try.
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If they don't hold, then you can use a semiconductor called triac. Here is how you use one:
It is not 240V AC that you are going to regulate, it is going to be your relays 24V AC control signal. And load is your relay.@ceech said:
If they don't hold, then you can use a semiconductor called triac. Here is how you use one:
It is not 240V AC that you are going to regulate, it is going to be your relays 24V AC control signal. And load is your relay.Based on @jeylites comments I'm starting to think that this triac circuit completely replaces the current relay (not just the Arduino relay board), as well as adding dimmer functionality - is this correct? Confused
But would I loose the current physical buttons' functionality or could those also be wired into the triac?
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@ceech said:
If they don't hold, then you can use a semiconductor called triac. Here is how you use one:
It is not 240V AC that you are going to regulate, it is going to be your relays 24V AC control signal. And load is your relay.Based on @jeylites comments I'm starting to think that this triac circuit completely replaces the current relay (not just the Arduino relay board), as well as adding dimmer functionality - is this correct? Confused
But would I loose the current physical buttons' functionality or could those also be wired into the triac?
Yes indeed, this is a dimmer not a Relay. If you need a relay functionality you could employ a solid state relay or mechanical one. Why I say this is the waveform gets altered when going through Traic and its not good for certain electronic items.Excluding a light bulb. See picture below for better understating. I wish i could explain more but in the process of doing something...LOL
I didn't quite understand what you meant by "current physical buttons" ....
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@ceech said:
If they don't hold, then you can use a semiconductor called triac. Here is how you use one:
It is not 240V AC that you are going to regulate, it is going to be your relays 24V AC control signal. And load is your relay.Based on @jeylites comments I'm starting to think that this triac circuit completely replaces the current relay (not just the Arduino relay board), as well as adding dimmer functionality - is this correct? Confused
But would I loose the current physical buttons' functionality or could those also be wired into the triac?
@twosh Yes, it is adding the dimmer functionality, but you would need an additional optocoupler and bridge rectifier for it to work. The MOC3061 IC knows about zero crossing of the AC signal and cuts some signal as @jeylites explained. That shouldn't bother you for now. As long as you apply 5V or 0V on the input side, the circuit behaves as a switch.
Let's not completely replace everything at the moment. Let us say that we are just going to add this circuit to your 24V AC relay coil. You can still use the physical switch. But remember - the voltage fed into the BTA41 triac should be 24V AC in this case. -
Want to share my progress since my 8 relay arrived today! :)
I've successfully modified the relay example sketch to use two analogue pins for the 7:th and 8:th relays, so everything software wise is fine for now.
I connected one of the arduino relay outputs to one of my house relays for testing and succeeded to get the house relay to switch on by having the arduino relay low. But I can't get the house relay to turn off again, no matter if I turn the arduino relay high, nor low again. I had to use the physical light switch to turn the relay off again.
What am I missing..?
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Here's my sketch @jeylites !
I'm using this 8 channel relay board: http://www.ebay.com/itm/181242936438?rmvSB=true
Had to switch the GPIO HIGH/LOW values around compared to the original sketch, and added two analogue pins controlling channel 7 and 8 on the board.
// Example sketch showing how to control physical relays. // This example will remember relay state even after power failure. #include <MySensor.h> #include <SPI.h> #define RELAY_1 3 // Arduino Digital I/O pin number for first relay (second on pin+1 etc) #define RELAY_1A 0 // Arduino Analog I/O pin number for first relay (second on pin+1 etc) #define NUMBER_OF_RELAYS 6 // Total number of attached relays #define NUMBER_OF_ANALOG_RELAYS 2 // Total number of attached relays #define RELAY_ON 0 // GPIO value to write to turn on attached relay #define RELAY_OFF 1 // GPIO value to write to turn off attached relay MySensor gw; void setup() { // Initialize library and add callback for incoming messages gw.begin(incomingMessage, AUTO, true); // Send the sketch version information to the gateway and Controller gw.sendSketchInfo("Relay", "1.0 AD"); // Fetch relay status for (int sensor=1, pin=RELAY_1; sensor<=NUMBER_OF_RELAYS;sensor++, pin++) { // Register all sensors to gw (they will be created as child devices) gw.present(sensor, S_LIGHT); // Then set relay pins in output mode pinMode(pin, OUTPUT); // Set relay to last known state (using eeprom storage) digitalWrite(pin, gw.loadState(sensor)?RELAY_ON:RELAY_OFF); } // Fetch and present the analogue relays int sensor=NUMBER_OF_RELAYS+1; gw.present(sensor++, S_LIGHT); pinMode(A0, OUTPUT); digitalWrite(A0, gw.loadState(sensor)?RELAY_ON:RELAY_OFF); gw.present(sensor++, S_LIGHT); pinMode(A1, OUTPUT); digitalWrite(A1, gw.loadState(sensor)?RELAY_ON:RELAY_OFF); } void loop() { // Alway process incoming messages whenever possible gw.process(); } void incomingMessage(const MyMessage &message) { // We only expect one type of message from controller. But we better check anyway. if (message.type==V_LIGHT) { // Change relay state if (message.sensor <= NUMBER_OF_RELAYS) digitalWrite(message.sensor-1+RELAY_1, message.getBool()?RELAY_ON:RELAY_OFF); else if (message.sensor == NUMBER_OF_RELAYS+1) //First analogue sensor digitalWrite(A0, message.getBool()?RELAY_ON:RELAY_OFF); else //Second analogue sensor digitalWrite(A1, message.getBool()?RELAY_ON:RELAY_OFF); // Store state in eeprom gw.saveState(message.sensor, message.getBool()); // Write some debug info Serial.print("Incoming change for sensor:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(message.getBool()); } } -
@twosh Try this sketch below it works. You can change outputs around by changing
const int relayPin [] = {A2, A3, A4, A5, A6, A7};&const int buttonPin[] = {3, 4, 5, 6, 7, 8};// This is the final sketch // Example sketch showing how to control physical relays. // This example will remember relay state even after power failure. #include <MySensor.h> #include <SPI.h> #include <Bounce2.h> #define RELAY_ON 0 // switch around for realy HIGH/LOW state #define RELAY_OFF 1 // MySensor gw; //#define RADIO_ID 8 // Radio Id, whatever channel you assigned to #define noRelays 6 const int relayPin[] = {A2, A3, A4, A5, A6, A7}; const int buttonPin[] = {3, 4, 5, 6, 7, 8}; class Relay // relay class, store all relevant data (equivalent to struct) { public: int buttonPin; // physical pin number of button int relayPin; // physical pin number of relay byte oldValue; // last Values for key (debounce) boolean relayState; // relay status (also stored in EEPROM) }; Relay Relays[noRelays]; Bounce debouncer[noRelays]; MyMessage msg[noRelays]; void setup(){ gw.begin(incomingMessage, AUTO, true); delay(250); gw.sendSketchInfo("MultiRelayButton", "0.9b"); delay(250); // Initialize Relays with corresponding buttons for (int i = 0; i < noRelays; i++){ Relays[i].buttonPin = buttonPin[i]; // assign physical pins Relays[i].relayPin = relayPin[i]; msg[i].sensor = i; // initialize messages msg[i].type = V_LIGHT; debouncer[i] = Bounce(); // initialize debouncer debouncer[i].attach(buttonPin[i]); debouncer[i].interval(5); pinMode(Relays[i].buttonPin, INPUT_PULLUP); pinMode(Relays[i].relayPin, OUTPUT); Relays[i].relayState = gw.loadState(i); // retrieve last values from EEPROM digitalWrite(Relays[i].relayPin, Relays[i].relayState? RELAY_ON:RELAY_OFF); // and set relays accordingly gw.send(msg[i].set(Relays[i].relayState? true : false)); // make controller aware of last status gw.present(i, S_LIGHT); // present sensor to gateway delay(250); } } void loop() { gw.process(); for (byte i = 0; i < noRelays; i++){ debouncer[i].update(); byte value = debouncer[i].read(); if (value != Relays[i].oldValue && value == 0){ Relays[i].relayState = !Relays[i].relayState; digitalWrite(Relays[i].relayPin, Relays[i].relayState?RELAY_ON:RELAY_OFF); gw.send(msg[i].set(Relays[i].relayState? true : false)); gw.saveState( i, Relays[i].relayState );} // save sensor state in EEPROM (location == sensor number) Relays[i].oldValue = value; } } // process incoming message void incomingMessage(const MyMessage &message){ if (message.type == V_LIGHT){ if (message.sensor <noRelays){ // check if message is valid for relays..... previous line if [[[ (message.sensor <=noRelays){ ]]] Relays[message.sensor].relayState = message.getBool(); digitalWrite(Relays[message.sensor].relayPin, Relays[message.sensor].relayState? RELAY_ON:RELAY_OFF); // and set relays accordingly gw.saveState( message.sensor, Relays[message.sensor].relayState ); // save sensor state in EEPROM (location == sensor number) } } } -
Thanks a lot @jeylites !
A couple of question; you are using physical buttons mapped to your pins d3-d8 - 6 in total. The rest of the digital pins are taken up by the radio I guess, since they are for me. Does that mean that this sketch is limited to 6 relays as well since the Relay class seems to match one button pin with one relay pin. Or can I just define 6 buttons and 8 relays, like this?
const int relayPin[] = {A0, A1, A2, A3, A4, A5, A6, A7}; const int buttonPin[] = {3, 4, 5, 6, 7, 8, NULL, NULL};I could use the A0-A7 pins for my 8 relays but I'm unsure if the above 6+NULL+NULL buttons to 8 relays mapping will cause problems?
To clarify, the problem I'm facing when using my sketch above is not that the arduino relays would not obey, it is that the relays controlled by the arduino relays stays "on" all the time. The physical buttons i keep mentioning are connected to the HOUSE relays (i.e. lightswitches), not to the Arduino.
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Found some specs on my house relays: http://www.switchtec.co.uk/relay_catalog/129_LR-28.pdf
It's the esmi nr-8251 latching relay if this helps!
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I suppose the relays are impulse relays, which need a impulse to change the state (on/off). I'm using the Relay-Modules you mentioned above to control my impulse relays. My impulse relays are controlled with 230V. The relays are connected in parallel to the existing switches and use a 100ms impulse to change the state.
Works like a charme.@TimO said:
I suppose the relays are impulse relays, which need a impulse to change the state (on/off). I'm using the Relay-Modules you mentioned above to control my impulse relays. My impulse relays are controlled with 230V. The relays are connected in parallel to the existing switches and use a 100ms impulse to change the state.
Works like a charme.Could you share your experience in more detail? It feels like you have accomplished what I would like to happen at this point. :)
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Here's my sketch @jeylites !
I'm using this 8 channel relay board: http://www.ebay.com/itm/181242936438?rmvSB=true
Had to switch the GPIO HIGH/LOW values around compared to the original sketch, and added two analogue pins controlling channel 7 and 8 on the board.
// Example sketch showing how to control physical relays. // This example will remember relay state even after power failure. #include <MySensor.h> #include <SPI.h> #define RELAY_1 3 // Arduino Digital I/O pin number for first relay (second on pin+1 etc) #define RELAY_1A 0 // Arduino Analog I/O pin number for first relay (second on pin+1 etc) #define NUMBER_OF_RELAYS 6 // Total number of attached relays #define NUMBER_OF_ANALOG_RELAYS 2 // Total number of attached relays #define RELAY_ON 0 // GPIO value to write to turn on attached relay #define RELAY_OFF 1 // GPIO value to write to turn off attached relay MySensor gw; void setup() { // Initialize library and add callback for incoming messages gw.begin(incomingMessage, AUTO, true); // Send the sketch version information to the gateway and Controller gw.sendSketchInfo("Relay", "1.0 AD"); // Fetch relay status for (int sensor=1, pin=RELAY_1; sensor<=NUMBER_OF_RELAYS;sensor++, pin++) { // Register all sensors to gw (they will be created as child devices) gw.present(sensor, S_LIGHT); // Then set relay pins in output mode pinMode(pin, OUTPUT); // Set relay to last known state (using eeprom storage) digitalWrite(pin, gw.loadState(sensor)?RELAY_ON:RELAY_OFF); } // Fetch and present the analogue relays int sensor=NUMBER_OF_RELAYS+1; gw.present(sensor++, S_LIGHT); pinMode(A0, OUTPUT); digitalWrite(A0, gw.loadState(sensor)?RELAY_ON:RELAY_OFF); gw.present(sensor++, S_LIGHT); pinMode(A1, OUTPUT); digitalWrite(A1, gw.loadState(sensor)?RELAY_ON:RELAY_OFF); } void loop() { // Alway process incoming messages whenever possible gw.process(); } void incomingMessage(const MyMessage &message) { // We only expect one type of message from controller. But we better check anyway. if (message.type==V_LIGHT) { // Change relay state if (message.sensor <= NUMBER_OF_RELAYS) digitalWrite(message.sensor-1+RELAY_1, message.getBool()?RELAY_ON:RELAY_OFF); else if (message.sensor == NUMBER_OF_RELAYS+1) //First analogue sensor digitalWrite(A0, message.getBool()?RELAY_ON:RELAY_OFF); else //Second analogue sensor digitalWrite(A1, message.getBool()?RELAY_ON:RELAY_OFF); // Store state in eeprom gw.saveState(message.sensor, message.getBool()); // Write some debug info Serial.print("Incoming change for sensor:"); Serial.print(message.sensor); Serial.print(", New status: "); Serial.println(message.getBool()); } }@twosh Based on the spec sheet, I believe your existing latching relays need a 35ms pulse to turn them on and off.
The standard relay sketch to control your new relays is meant to turn the relays on based on a command from the controller and then another command from the controller to turn them off. It also maintains the relay state by saving them to EEPROM, and sets them to last state on power-up, etc. You don't need most of that. All you need to do is set the relay to on, wait 35 milliseconds and then set the relay to off based on a toggle command from the controller.
Take a crack at simplifying the sketch, post your results and I, or others, can help with the next steps.
The one thing to note is that with this system, you won't know if the light is on or on, all you can do is toggle current status. You would have to add current sensors or something like that to be able to know the state. Are there LEDs on the existing system that are on when the light is on and off when the lights are off?
Cheers
AlPS Have you measured the voltage to the control side of the existing latching relay when operated by a switch?
