// Pinout configuration const int grinderPin = 9, pumpPin = 8, boilerPin = 6, powderPin = 7, wheelPin = 10, invertWheelPin = 11, powderSensorPin = 2, vaporSensorPin = 5, tempSensorPin = A7, wheelStartSensorPin = 4, wheelEndSensorPin = 3, redLED = 13, greenLED = 12; // Global string String readString; // Thermistor config // WARNING! while the old coffee machine used a PTC thermistor, this was replaced with an NTC one as it was more readily available // Code must be adjusted accordingly if a PTC resistor is used once more! int Vo; float R1 = 10000; // <-- change this value to the resistance of the fixed resistor (so don't change PLS!) float logR2, R2, T, Tc, Told; float c1 = 7.9e-04, c2 = 1.85e-04, c3 = 2e-07; // Here's where you can perform actual calibration // Variable to store desired Max boiler Temp int desiredTemp = 70; // Variables to Store errors: int unrecoverableErr = 0; int warning = 0; // Variables for cleaning and other maintenance int dry = 0; int noCoffee = 0; // Milliseconds to delay between each cycle const int milliseconds = 10; int timeratio = 1; // pumpRatio is = seconds to pump water for and will be updated over serial int pumpRatio = 15; // This next variable is used to get current "time" in ms and break out of while cycles that need a time limit safeguard unsigned long startTime; void setup() { // put your setup code here, to run once: // first we set pins as I/O and initialize outputs LOW pinMode(boilerPin, OUTPUT); pinMode(pumpPin, OUTPUT); pinMode(grinderPin, OUTPUT); pinMode(powderPin, OUTPUT); pinMode(wheelPin, OUTPUT); pinMode(invertWheelPin, OUTPUT); pinMode (redLED, OUTPUT); pinMode (greenLED, OUTPUT); pinMode(powderSensorPin, INPUT); pinMode(vaporSensorPin, INPUT); pinMode(tempSensorPin, INPUT); pinMode(wheelStartSensorPin, INPUT); pinMode(wheelEndSensorPin, INPUT); digitalWrite(grinderPin, LOW); digitalWrite(pumpPin, LOW); digitalWrite(boilerPin, LOW); digitalWrite(powderPin, LOW); digitalWrite(wheelPin, LOW); digitalWrite(invertWheelPin, LOW); digitalWrite(redLED, LOW); digitalWrite(greenLED, LOW); // timeratio easily allows to determine how many cycles are required to make 1s pass (ms * ratio = 1s) timeratio = 1000/milliseconds; // initialize serial: Serial.begin(9600); delay(100); Serial.write("Arduino running :)\n"); } void loop() { // put your main code here, to run repeatedly: // Check if unrecoverable error has occurred: if (unrecoverableErr == 1) { delay(100); Serial.write("Error has occurred.\n"); delay(100); Serial.write("Check machine and restart\n"); digitalWrite(greenLED, LOW); while (true){ digitalWrite(redLED, HIGH); delay(1000); digitalWrite(redLED, LOW); delay(1000); } } // check if data has been sent on serial from ESP or PC: if (Serial.available() > 0) { // read the incoming data: (we only care about the first few characters, I've chosen 4) readString = ""; serialRead(); String incomingData = readString.substring(0,4); if (incomingData == "read") { digitalWrite(greenLED, HIGH); } if (incomingData == "rist") { // set parameters for ristretto: delay(100); Serial.write("Ristretto\n"); pumpRatio = 12; } if (incomingData == "espr") { // set parameters for espresso: delay(100); Serial.write("Espresso\n"); pumpRatio = 15; } if (incomingData == "long") { // set parameters for lungo: delay(100); Serial.write("Lungo\n"); pumpRatio = 18; } // check if the incoming data is "make": if (incomingData == "make") { // run the code to make coffee: delay(100); Serial.write("Making some coffee!\n"); makeCoffee(); } if (incomingData == "dryr") { // run the code to make a dry run (no powder, no water): delay(100); Serial.write("DryRun\n"); dry = 1; makeCoffee(); } if (incomingData == "noco") { // run the code to make a dry run (no powder, nor water): delay(100); Serial.write("NoCo\n"); pumpRatio = 12; noCoffee = 1; makeCoffee(); } if (incomingData == "pump") { // run the code to just pump water: pumpRatio = 12; Pump(); } if (incomingData == "pres") { // only press Press(); } if (incomingData == "unpr") { // only unpress unPress(); } if (incomingData == "heat") { // only heat desiredTemp = 85; Heat(); } if (incomingData == "clea") { // clean machine delay(100); Serial.write("s-clean\n"); dry = 1; makeCoffee(); noCoffee = 1; makeCoffee(); delay(100); Serial.write("S-cleaning done.\n"); } } delay(milliseconds); } // this is how we read the input void serialRead() { while (Serial.available()) { delay(10); if (Serial.available() > 0) { char c = Serial.read(); readString += c;} } } void Grind() { digitalWrite(greenLED, LOW); delay(100); Serial.write("grinding...\n"); digitalWrite(grinderPin, HIGH); startTime = millis(); while (true) { delay(milliseconds); if (digitalRead(powderSensorPin) == HIGH) { digitalWrite(grinderPin, LOW); delay(100); Serial.write("Grinding Done\n"); break; } if (millis() - startTime > 30000) { delay(100); Serial.write("Warning, grinding took too long!\n"); delay(100); Serial.write("Out of Coffee?\n"); warning = 1; break; } } digitalWrite(greenLED, HIGH); } void Drop() { digitalWrite(greenLED, LOW); delay(100); Serial.write("dropping...\n"); digitalWrite(powderPin, HIGH); delay(1000); digitalWrite(powderPin, LOW); delay(100); Serial.write("Dropped\n"); digitalWrite(greenLED, HIGH); } void Heat() { digitalWrite(greenLED, LOW); digitalWrite(redLED, HIGH); startTime = millis(); delay(100); Serial.write("Heating to "); delay(100); Serial.print(desiredTemp); delay(100); Serial.write(" C\n"); Tc = 0; Told = -100; // monitor temperature and adjust boilerPin as needed: while (true) { // read temperature from tempSensorPin: Vo = analogRead(tempSensorPin); R2 = R1 * (1023.0 / (float)Vo - 1.0); logR2 = log(R2); T = (1.0 / (c1 + c2*logR2 + c3*logR2*logR2*logR2)); Tc = (T - 273.15); if (millis() - startTime > 1000) { Told = Tc; // support variable to store temp at beginning, so that we can be sure it's increasing } // check if temperature is within the acceptable range and break out of the loop without error if done heating: if (Tc > desiredTemp) { // temperature is within range, so break out of the loop: digitalWrite(boilerPin, LOW); delay(100); Serial.write("reached desired temp\n"); delay(100); Serial.print(Tc); delay(100); Serial.write(" C\n"); digitalWrite(redLED, LOW); break; } if (Tc < -100) { delay(100); Serial.write("u-Thermocouple: unplugged or failed\n"); digitalWrite(boilerPin, LOW); unrecoverableErr = 1; break; } if (millis() - startTime > 20000 && Tc - Told < 5) { delay(100); Serial.write("p-Thermocouple: positioning or relay fault\n"); digitalWrite(boilerPin, LOW); unrecoverableErr = 1; break; } if (millis() - startTime > 30000) { delay(100); Serial.write("h-taking too long, continuing...\n"); digitalWrite(boilerPin, LOW); digitalWrite(redLED, LOW); break; } // We do this at the end so that the relay is not uselessly cycled digitalWrite(boilerPin, HIGH); delay(milliseconds); } digitalWrite(greenLED, HIGH); } void Press() { digitalWrite(greenLED, LOW); delay(100); Serial.write("pressing...\n"); // Reset Press before every coffee digitalWrite(invertWheelPin, HIGH); delay(1000); digitalWrite(invertWheelPin, LOW); digitalWrite(wheelPin, HIGH); startTime = millis(); while (true) { delay(milliseconds); if (digitalRead(wheelEndSensorPin) == HIGH) { digitalWrite(wheelPin, LOW); delay(100); Serial.write("Pressed\n"); break; } if (millis() - startTime > 15000) { delay(100); Serial.write("p-end of pressing not detected\n"); digitalWrite(wheelPin, LOW); unrecoverableErr = 1; break; } } digitalWrite(greenLED, HIGH); } void unPress() { digitalWrite(greenLED, LOW); delay(100); Serial.write("unPressing...\n"); // Reset Press before every coffee digitalWrite(wheelPin, HIGH); delay(1000); digitalWrite(wheelPin, LOW); digitalWrite(invertWheelPin, HIGH); startTime = millis(); while (true) { delay(milliseconds); if (digitalRead(wheelStartSensorPin) == HIGH) { delay(1500); digitalWrite(invertWheelPin, LOW); delay(100); Serial.write("UnPressed\n"); break; } if (millis() - startTime > 15000) { delay(100); Serial.write("u-end of unPressing not detected\n"); digitalWrite(invertWheelPin, LOW); unrecoverableErr = 1; break; } } digitalWrite(greenLED, HIGH); } void Pump() { digitalWrite(greenLED, LOW); delay(100); Serial.write("pumping Water...\n"); digitalWrite(pumpPin, HIGH); delay(1000*pumpRatio); digitalWrite(pumpPin, LOW); delay(100); Serial.write("Pumping water done\n"); digitalWrite(greenLED, HIGH); } void makeCoffee() { // code to make coffee goes here... // It would be much smarter to break down complicated functions into subroutines: press/unpress etc... // Hence that's what we'll have done by the time the first release goes public ;) // makeCoffee() can still run all the same, but clean() can use the same press/unpress code! // care must be taken to place these functions earlier in the code, or the compiler will rightfully freak out while (true) { desiredTemp = 75; Heat(); // First we pre-heat the boiler if (unrecoverableErr == 1) { break; } if (dry == 0 && noCoffee == 0) { Grind(); // Grinding some nice roasted coffee beans! } // If grinder won't stop, coffee probably need to be refilled. if (warning == 1) { delay(100); Serial.write("refill coffee and send cont command\n"); while (true) { // check if data has been sent on serial from ESP or PC: if (Serial.available() > 0) { // read the incoming data: (we only care about the first few characters, I've chosen 4) readString = ""; serialRead(); String incomingData = readString.substring(0,4); if (incomingData == "cont") { // coffee refilled, making is allowed to continue Serial.write("Refilled\n"); warning = 0; Grind(); // Grinding some nice roasted coffee beans! if (warning == 1) { unrecoverableErr = 1; Serial.write("g-failure: second grinding failure, check grinder!\n"); } break; } } } } // Stop if grinding failed a second time if (unrecoverableErr == 1) { break; } delay(1000); // this delay is mandatory to prevent powder spillage caused by grinder inertia. unPress(); // unpressing the press to reset the machine if (unrecoverableErr == 1) { break; } Drop(); // Dropping the powder in the press delay(1000); Press(); // Self explainatory if (unrecoverableErr == 1) { break; } if (dry == 0) { digitalWrite(boilerPin, HIGH); delay(1000); Pump(); // Pump ratio (in seconds) will be read from serial input in final release digitalWrite(boilerPin, LOW); } delay(3000); // Allow pressure to wane unPress(); // unpressing the press to reset the machine if (unrecoverableErr == 1) { break; } delay(100); Serial.write("Complete!\n"); dry = 0; noCoffee = 0; break; } }