[아두이노 부품사용법] MQ-135 아두이노 유해가스/공기질 센서 모듈

• 이산화탄소, 암모니아, 질소산화물, 알콜류, 벤젠 감지 센서

• For Air Quality

  Sensitive for Benzene, Alcohol, smoke.

  The heater uses 5V.

  An example how to use it: http://wiring.org.co/learning/basics/airqualitymq135.html

  
  

  An example with calculation of the CO2 value: http://davidegironi.blogspot.it/2014/01/cheap-co2-meter-using-mq135-sensor-with.html

  
  

  Search for datasheet: http://duckduckgo.com/?q=%22mq135%22+gas+sensor+filetype%3Apdf

/*******************Demo for MQ-2 Gas Sensor Module V1.0*****************************

Support: Tiequan Shao: support[at]sandboxelectronics.com

Lisence: Attribution-NonCommercial-ShareAlike 3.0 Unported (CC BY-NC-SA 3.0)

Note: This piece of source code is supposed to be used as a demostration ONLY. More

sophisticated calibration is required for industrial field application.

Sandbox Electronics 2011-04-25

************************************************************************************/

/************************Hardware Related Macros************************************/

#define MQ_PIN (0) //define which analog input channel you are going to use

#define RL_VALUE (5) //define the load resistance on the board, in kilo ohms

#define RO_CLEAN_AIR_FACTOR (9.83) //RO_CLEAR_AIR_FACTOR=(Sensor resistance in clean air)/RO,

//which is derived from the chart in datasheet

/***********************Software Related Macros************************************/

#define CALIBARAION_SAMPLE_TIMES (50) //define how many samples you are going to take in the calibration phase

#define CALIBRATION_SAMPLE_INTERVAL (500) //define the time interal(in milisecond) between each samples in the

//cablibration phase

#define READ_SAMPLE_INTERVAL (50) //define how many samples you are going to take in normal operation

#define READ_SAMPLE_TIMES (5) //define the time interal(in milisecond) between each samples in

//normal operation

/**********************Application Related Macros**********************************/

#define GAS_LPG (0)

#define GAS_CO (1)

#define GAS_SMOKE (2)

/*****************************Globals***********************************************/

float LPGCurve[3] = {2.3,0.21,-0.47}; //two points are taken from the curve.

//with these two points, a line is formed which is "approximately equivalent"

//to the original curve.

//data format:{ x, y, slope}; point1: (lg200, 0.21), point2: (lg10000, -0.59)

float COCurve[3] = {2.3,0.72,-0.34}; //two points are taken from the curve.

//with these two points, a line is formed which is "approximately equivalent"

//to the original curve.

//data format:{ x, y, slope}; point1: (lg200, 0.72), point2: (lg10000, 0.15)

float SmokeCurve[3] ={2.3,0.53,-0.44}; //two points are taken from the curve.

//with these two points, a line is formed which is "approximately equivalent"

//to the original curve.

//data format:{ x, y, slope}; point1: (lg200, 0.53), point2: (lg10000, -0.22)

float Ro = 10; //Ro is initialized to 10 kilo ohms

void setup()

{

Serial.begin(9600); //UART setup, baudrate = 9600bps

Serial.print("Calibrating...\n");

Ro = MQCalibration(MQ_PIN); //Calibrating the sensor. Please make sure the sensor is in clean air

//when you perform the calibration

Serial.print("Calibration is done...\n");

Serial.print("Ro=");

Serial.print(Ro);

Serial.print("kohm");

Serial.print("\n");

}

void loop()

{

Serial.print("LPG:");

Serial.print(MQGetGasPercentage(MQRead(MQ_PIN)/Ro,GAS_LPG) );

Serial.print( "ppm" );

Serial.print(" ");

Serial.print("CO:");

Serial.print(MQGetGasPercentage(MQRead(MQ_PIN)/Ro,GAS_CO) );

Serial.print( "ppm" );

Serial.print(" ");

Serial.print("SMOKE:");

Serial.print(MQGetGasPercentage(MQRead(MQ_PIN)/Ro,GAS_SMOKE) );

Serial.print( "ppm" );

Serial.print("\n");

delay(200);

}

/****************** MQResistanceCalculation ****************************************

Input: raw_adc - raw value read from adc, which represents the voltage

Output: the calculated sensor resistance

Remarks: The sensor and the load resistor forms a voltage divider. Given the voltage

across the load resistor and its resistance, the resistance of the sensor

could be derived.

************************************************************************************/

float MQResistanceCalculation(int raw_adc)

{

return ( ((float)RL_VALUE*(1023-raw_adc)/raw_adc));

}

/***************************** MQCalibration ****************************************

Input: mq_pin - analog channel

Output: Ro of the sensor

Remarks: This function assumes that the sensor is in clean air. It use

MQResistanceCalculation to calculates the sensor resistance in clean air

and then divides it with RO_CLEAN_AIR_FACTOR. RO_CLEAN_AIR_FACTOR is about

10, which differs slightly between different sensors.

************************************************************************************/

float MQCalibration(int mq_pin)

{

int i;

float val=0;

for (i=0;i<CALIBARAION_SAMPLE_TIMES;i++) { //take multiple samples

val += MQResistanceCalculation(analogRead(mq_pin));

delay(CALIBRATION_SAMPLE_INTERVAL);

}

val = val/CALIBARAION_SAMPLE_TIMES; //calculate the average value

val = val/RO_CLEAN_AIR_FACTOR; //divided by RO_CLEAN_AIR_FACTOR yields the Ro

//according to the chart in the datasheet

return val;

}

/***************************** MQRead *********************************************

Input: mq_pin - analog channel

Output: Rs of the sensor

Remarks: This function use MQResistanceCalculation to caculate the sensor resistenc (Rs).

The Rs changes as the sensor is in the different consentration of the target

gas. The sample times and the time interval between samples could be configured

by changing the definition of the macros.

************************************************************************************/

float MQRead(int mq_pin)

{

int i;

float rs=0;

for (i=0;i<READ_SAMPLE_TIMES;i++) {

rs += MQResistanceCalculation(analogRead(mq_pin));

delay(READ_SAMPLE_INTERVAL);

}

rs = rs/READ_SAMPLE_TIMES;

return rs;

}

/***************************** MQGetGasPercentage **********************************

Input: rs_ro_ratio - Rs divided by Ro

gas_id - target gas type

Output: ppm of the target gas

Remarks: This function passes different curves to the MQGetPercentage function which

calculates the ppm (parts per million) of the target gas.

************************************************************************************/

int MQGetGasPercentage(float rs_ro_ratio, int gas_id)

{

if ( gas_id == GAS_LPG ) {

return MQGetPercentage(rs_ro_ratio,LPGCurve);

} else if ( gas_id == GAS_CO ) {

return MQGetPercentage(rs_ro_ratio,COCurve);

} else if ( gas_id == GAS_SMOKE ) {

return MQGetPercentage(rs_ro_ratio,SmokeCurve);

}

return 0;

}

/***************************** MQGetPercentage **********************************

Input: rs_ro_ratio - Rs divided by Ro

pcurve - pointer to the curve of the target gas

Output: ppm of the target gas

Remarks: By using the slope and a point of the line. The x(logarithmic value of ppm)

of the line could be derived if y(rs_ro_ratio) is provided. As it is a

logarithmic coordinate, power of 10 is used to convert the result to non-logarithmic

value.

************************************************************************************/

int MQGetPercentage(float rs_ro_ratio, float *pcurve)

{

return (pow(10,( ((log(rs_ro_ratio)-pcurve[1])/pcurve[2]) + pcurve[0])));

}

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