franz-josef-kaiser/FlowMeterDIY.ino

## FlowMeterDIY.ino
/*
Liquid flow rate sensor -DIYhacking.com Arvind Sanjeev

Measure the liquid/water flow rate using this code.
Connect Vcc and Gnd of sensor to arduino, and the
signal line to arduino digital pin 2.

Source: @link https://diyhacking.com/projects/FlowMeterDIY.ino
 */

byte statusLed    = 13;

byte sensorInterrupt = 0;  // 0 = digital pin 2
byte sensorPin       = 2;

// The hall-effect flow sensor outputs approximately 4.5 pulses per second per
// litre/minute of flow.
float calibrationFactor = 4.5;

volatile byte pulseCount;

float flowRate;
unsigned int flowMilliLitres;
unsigned long totalMilliLitres;

unsigned long oldTime;

void setup()
{

  // Initialize a serial connection for reporting values to the host
  Serial.begin(38400);

  // Set up the status LED line as an output
  pinMode(statusLed, OUTPUT);
  digitalWrite(statusLed, HIGH);  // We have an active-low LED attached

  pinMode(sensorPin, INPUT);
  digitalWrite(sensorPin, HIGH);

  pulseCount        = 0;
  flowRate          = 0.0;
  flowMilliLitres   = 0;
  totalMilliLitres  = 0;
  oldTime           = 0;

  // The Hall-effect sensor is connected to pin 2 which uses interrupt 0.
  // Configured to trigger on a FALLING state change (transition from HIGH
  // state to LOW state)
  attachInterrupt(sensorInterrupt, pulseCounter, FALLING);
}

/**
 * Main program loop
 */
void loop()
{

   if((millis() - oldTime) > 1000)    // Only process counters once per second
  {
    // Disable the interrupt while calculating flow rate and sending the value to
    // the host
    detachInterrupt(sensorInterrupt);

    // Because this loop may not complete in exactly 1 second intervals we calculate
    // the number of milliseconds that have passed since the last execution and use
    // that to scale the output. We also apply the calibrationFactor to scale the output
    // based on the number of pulses per second per units of measure (litres/minute in
    // this case) coming from the sensor.
    flowRate = ((1000.0 / (millis() - oldTime)) * pulseCount) / calibrationFactor;

    // Note the time this processing pass was executed. Note that because we've
    // disabled interrupts the millis() function won't actually be incrementing right
    // at this point, but it will still return the value it was set to just before
    // interrupts went away.
    oldTime = millis();

    // Divide the flow rate in litres/minute by 60 to determine how many litres have
    // passed through the sensor in this 1 second interval, then multiply by 1000 to
    // convert to millilitres.
    flowMilliLitres = (flowRate / 60) * 1000;

    // Add the millilitres passed in this second to the cumulative total
    totalMilliLitres += flowMilliLitres;

    unsigned int frac;

    // Print the flow rate for this second in litres / minute
    Serial.print("Flow rate: ");
    Serial.print(int(flowRate));  // Print the integer part of the variable
    Serial.print(".");             // Print the decimal point
    // Determine the fractional part. The 10 multiplier gives us 1 decimal place.
    frac = (flowRate - int(flowRate)) * 10;
    Serial.print(frac, DEC) ;      // Print the fractional part of the variable
    Serial.print("L/min");
    // Print the number of litres flowed in this second
    Serial.print("  Current Liquid Flowing: ");             // Output separator
    Serial.print(flowMilliLitres);
    Serial.print("mL/Sec");

    // Print the cumulative total of litres flowed since starting
    Serial.print("  Output Liquid Quantity: ");             // Output separator
    Serial.print(totalMilliLitres);
    Serial.println("mL");

    // Reset the pulse counter so we can start incrementing again
    pulseCount = 0;

    // Enable the interrupt again now that we've finished sending output
    attachInterrupt(sensorInterrupt, pulseCounter, FALLING);
  }
}

/*
Insterrupt Service Routine
 */
void pulseCounter()
{
  // Increment the pulse counter
  pulseCount++;
}
	/*
	Liquid flow rate sensor -DIYhacking.com Arvind Sanjeev

	Measure the liquid/water flow rate using this code.
	Connect Vcc and Gnd of sensor to arduino, and the
	signal line to arduino digital pin 2.

	Source: @link https://diyhacking.com/projects/FlowMeterDIY.ino
	*/

	byte statusLed = 13;

	byte sensorInterrupt = 0; // 0 = digital pin 2
	byte sensorPin = 2;

	// The hall-effect flow sensor outputs approximately 4.5 pulses per second per
	// litre/minute of flow.
	float calibrationFactor = 4.5;

	volatile byte pulseCount;

	float flowRate;
	unsigned int flowMilliLitres;
	unsigned long totalMilliLitres;

	unsigned long oldTime;

	void setup()
	{

	// Initialize a serial connection for reporting values to the host
	Serial.begin(38400);

	// Set up the status LED line as an output
	pinMode(statusLed, OUTPUT);
	digitalWrite(statusLed, HIGH); // We have an active-low LED attached

	pinMode(sensorPin, INPUT);
	digitalWrite(sensorPin, HIGH);

	pulseCount = 0;
	flowRate = 0.0;
	flowMilliLitres = 0;
	totalMilliLitres = 0;
	oldTime = 0;

	// The Hall-effect sensor is connected to pin 2 which uses interrupt 0.
	// Configured to trigger on a FALLING state change (transition from HIGH
	// state to LOW state)
	attachInterrupt(sensorInterrupt, pulseCounter, FALLING);
	}

	/**
	* Main program loop
	*/
	void loop()
	{

	if((millis() - oldTime) > 1000) // Only process counters once per second
	{
	// Disable the interrupt while calculating flow rate and sending the value to
	// the host
	detachInterrupt(sensorInterrupt);

	// Because this loop may not complete in exactly 1 second intervals we calculate
	// the number of milliseconds that have passed since the last execution and use
	// that to scale the output. We also apply the calibrationFactor to scale the output
	// based on the number of pulses per second per units of measure (litres/minute in
	// this case) coming from the sensor.
	flowRate = ((1000.0 / (millis() - oldTime)) * pulseCount) / calibrationFactor;

	// Note the time this processing pass was executed. Note that because we've
	// disabled interrupts the millis() function won't actually be incrementing right
	// at this point, but it will still return the value it was set to just before
	// interrupts went away.
	oldTime = millis();

	// Divide the flow rate in litres/minute by 60 to determine how many litres have
	// passed through the sensor in this 1 second interval, then multiply by 1000 to
	// convert to millilitres.
	flowMilliLitres = (flowRate / 60) * 1000;

	// Add the millilitres passed in this second to the cumulative total
	totalMilliLitres += flowMilliLitres;

	unsigned int frac;

	// Print the flow rate for this second in litres / minute
	Serial.print("Flow rate: ");
	Serial.print(int(flowRate)); // Print the integer part of the variable
	Serial.print("."); // Print the decimal point
	// Determine the fractional part. The 10 multiplier gives us 1 decimal place.
	frac = (flowRate - int(flowRate)) * 10;
	Serial.print(frac, DEC) ; // Print the fractional part of the variable
	Serial.print("L/min");
	// Print the number of litres flowed in this second
	Serial.print(" Current Liquid Flowing: "); // Output separator
	Serial.print(flowMilliLitres);
	Serial.print("mL/Sec");

	// Print the cumulative total of litres flowed since starting
	Serial.print(" Output Liquid Quantity: "); // Output separator
	Serial.print(totalMilliLitres);
	Serial.println("mL");

	// Reset the pulse counter so we can start incrementing again
	pulseCount = 0;

	// Enable the interrupt again now that we've finished sending output
	attachInterrupt(sensorInterrupt, pulseCounter, FALLING);
	}
	}

	/*
	Insterrupt Service Routine
	*/
	void pulseCounter()
	{
	// Increment the pulse counter
	pulseCount++;
	}