/* 60W PD Powered Automatic Reflow Hoteplate Author: tobychui Firmware version for v6 or above PCB Notes: - Temperature sensing is done using 1k 1% resistor and a 100k Thermistor You might need to change the code if you are using other values - If you are using the type-C 6p version of the reflow PCB, and after pluggin in the type C cable no led lights up, try flip the type C cable upside down Button Mappings (Active Low, aka not pressing = HIGH) Start Btn: P1.4 Stop Btn: P1.7 Download Settings CH552 16Mhz (internal, 3.3V or 5V) */ #include /* Hardware Definations */ #define TEMP_PIN 11 //P1.1 #define HEATER_PIN 34 //P3.4 #define LED_PREHEAT 15 //P1.5 #define LED_REFLOW 16 //P1.6 #define START_BTN 14 //P1.4 #define STOP_BTN 17 //P1.7 /* Software Definations */ //Timing settings. Each cycle is approximately 100ms #define HOLDSTART_TIME 30 //START Button hold down time in cycles #define HOLDSTOP_TIME 10 //STOP Button hold down time in cycles #define SOAKING_TIME 600 //SOAKING temperature upkeep time in cycles #define MAX_CONTINUE_OPR_TIME 3000 //MAX_CONTINUE_OPR automatic shutdown desolder heatbed if continue operate for ~5 minutes for safty reasons /* Temperature Settings The ADC value can be calculated using the following line equation t=-0.7x+250 where X is ADC reading and t is target temp in degree C Note that different setup (e.g. ref resistor value / NTC resistor value) might have different equations You can experiment with yours and get a few data point to plot your own line */ #define COOLDOWN_TEMP_ADC 255 //Room temperature //Preheat temp & power #define PREHEAT_START_ADC 143 //150 degree C #define PREHEAT_TEMP_ADC 122 //160 degree C #define PREHEAT_PWR_PWM 155 //60% power output //Reflow temp & power #define REFLOW_TEMP_ADC 58 //220 degree C #define REFLOW_PWR_PWM 255 //100% power output //Overheat cutoff temp #define CUTOFF_TEMP_ADC 53 //250 degree C /* Function Prototypes */ bool updateHeaterPowerState(); void updateKeyStates(); void handleLEDBlinking(); void handleReflowProcedures(); void handleDesolderProcedures(); void enterStandbyMode(); int readTemp(); /* Runtime Variables */ bool reflowing = false; //Reflow has started bool reflowComplete = false; //Indicate if the stopping is done because of reflow complete bool startPressed = false; //Start button is pressed down bool stopPressed = false; //Stop button is pressed down /* Reflow Stages define what is the next state the hotplate should reach 0: Standby 1: Preheating 2: Preheat Holding / Soaking 3: Reflowing 4: Cooling down 10: Preheating to reflow temp for desoldering 11: Desolder Mode (Keep at REFLOW_TEMP_ADC) */ int reflowStages = 0; int startCountdown = HOLDSTART_TIME; //Hold for HOLDSTART_TIME to start to prevent accidental touches int stopcountdown = HOLDSTOP_TIME; //Hold for HOLDSTOP_TIME to stop reflowing int cycleCounter = 0; //Record cycle time up to 10 seconds int soakingCountdown = SOAKING_TIME; int desolderCountdown = MAX_CONTINUE_OPR_TIME; //Prevent overheat //Blink state controls bool blinkState = false; //If blinking this will be switching between true and false bool blinkYellow = true; //Slow blink yellow if enabled (Standby). Do not enable both yellow and red at the same time bool blinkRed = false; //Slow blink red if enable (End of Reflow). Do not enable both yellow and red at the same time bool fastBlinkState = false; bool fastblinkRed = false; //Real-time temperature control targets int targetTempADC = 255; //Target ADC reading to reach, 255 = room temperature int targetPwrPWM = 0; //Target PWM cycle for heater, 255 = full power, 0 = off int offset = 0; //Allow +-offset for the ADC reading before reheating / cooling void setup() { //Set button pins to input pinMode(START_BTN, INPUT); pinMode(STOP_BTN, INPUT); //Set LED pins to output pinMode(LED_PREHEAT, OUTPUT); pinMode(LED_REFLOW, OUTPUT); digitalWrite(LED_PREHEAT, LOW); digitalWrite(LED_REFLOW, LOW); //Set temp sense pin to input pinMode(TEMP_PIN, INPUT); //Set mosfet control pins to output and disable it pinMode(HEATER_PIN, OUTPUT); digitalWrite(HEATER_PIN, LOW); USBSerial_println("Reflow Hotplate Ready!"); } void loop() { /* State Check */ updateKeyStates(); /* Main reflowing logics */ //Add delay to the end of each conditions so each loop cycle is approximate 100ms if (reflowing && reflowStages < 10) { //Automatic Reflow handleReflowProcedures(); } else if (reflowing && reflowStages >= 10) { //Desolder hotplate handleDesolderProcedures(); } else { /* Standby Mode */ digitalWrite(HEATER_PIN, LOW); blinkYellow = true; delay(100); //adjust this if needed to make sure reflow cycles use the same time as standby cycles } /* Blink Signal Handlers */ handleLEDBlinking(); /* Cycle Counter Counter are limited to 600 to prevent overflow. */ cycleCounter++; if (cycleCounter > 600) { cycleCounter = 0; } }