CN112858394B - Temperature and humidity compensation method and detection device of detection system - Google Patents

Abstract

A temperature and humidity compensation method of an air quality detection system relates to the field of gas detection. The single chip microcomputer is connected with the temperature and humidity sensor and the gas sensor, the temperature and humidity sensor is used for acquiring temperature and humidity information, the gas sensor is used for acquiring VOC concentration of air, and after the temperature and humidity information and the VOC concentration are acquired by the single chip microcomputer, the VOC concentration of the air is compensated and calibrated according to the temperature and humidity information; on the basis that the single chip microcomputer obtains the temperature and humidity information and the gas VOC concentration, the single chip microcomputer further performs compensation operation on the gas VOC concentration based on the temperature and humidity information, so that the single chip microcomputer obtains a more accurate gas VOC concentration value after operation, and the accuracy of a system result is improved; the invention also discloses a detection device.

Description

Temperature and humidity compensation method and detection device of detection system

Technical Field

The present invention relates to the field of gas detection, and more particularly, to a temperature and humidity compensation method and a detection apparatus for a detection system.

Background

The resistance value of the gas sensitive material in the gas sensor changes along with the change of the VOC content (concentration) in the mixed gas at high temperature, and the VOC content (concentration) is indirectly obtained by measuring the resistance value (gas sensitive resistor) of the gas sensitive material, but in practical application, the gas sensitive resistor is also influenced by the moisture content in the mixed gas.

Disclosure of Invention

The invention aims to overcome at least one defect (deficiency) of the prior art and provides a temperature and humidity compensation method and a detection device of a detection system, so that a singlechip obtains more accurate gas VOC concentration.

The technical scheme adopted by the invention is that,

a temperature and humidity compensation method of an air quality detection system comprises a single chip microcomputer, a temperature and humidity sensor and a gas sensor, wherein the single chip microcomputer is connected with the temperature and humidity sensor and the gas sensor, the temperature and humidity sensor is used for acquiring temperature and humidity information, the gas sensor is used for acquiring the VOC concentration of air, after the temperature and humidity information and the VOC concentration are acquired by the single chip microcomputer, the VOC concentration of the air is compensated and calibrated according to the temperature and humidity information, and the gas sensor comprises a gas-sensitive resistor Rs and a heating resistor REAT;

the compensation measurement device is used for compensating and measuring the gas-sensitive resistor Rs, comprises a singlechip, realizes temperature and humidity compensation by adopting the following algorithm,

in the formula, TVOC is the raw data VOC concentration without compensating for its humiture, TVOCx is the VOC concentration after the humiture compensation, RH is the relative humidity, and T is the temperature.

On the basis that the single chip microcomputer obtains temperature and humidity information and gas VOC concentration, the invention further has the following advantages that: in the aspect of measuring the VOC concentration influenced by the moisture content, the single chip microcomputer further performs compensation operation on the gas VOC concentration based on the temperature and humidity information, so that the single chip microcomputer obtains a more accurate gas VOC concentration value after operation, and the accuracy of a system result is improved.

As an optional implementation manner, the single chip microcomputer of the heating resistor RHEAT includes an IO interface, and the IO interface is connected to the heating resistor RHEAT and is used for adjusting the current of the heating resistor RHEAT; the single chip microcomputer comprises an ADC interface, the ADC interface is connected with the gas-sensitive resistor Rs, and the single chip microcomputer acquires the resistance value change of the gas-sensitive resistor Rs through the ADC interface.

As an optional implementation manner, the system further includes a resistor R3, one end of the resistor R3 is connected to the IO interface, and the other end of the resistor R3 is connected in series with the heating resistor RHEAT, and the single chip microcomputer controls the current of the heating resistor RHEAT by controlling the IO interface; or the resistance value of the resistor R3 is 200 to 500 omega, and preferably, the resistance value of the resistor R3 is 300 omega.

According to the invention, the IO port of the single chip microcomputer is arranged, the current of the heating resistor REAT is changed by controlling the high and low levels of the IO port, so that the sensor is accelerated to preheat, a proper high-temperature environment is provided for the operation environment of the gas sensitive resistor Rs, meanwhile, the effect of rapid preheating is realized by controlling the level of the IO port end, and the operation efficiency of the system is improved; meanwhile, the current in the circuit is limited to a certain extent due to the device operation requirement of the single chip microcomputer, so that the resistor R3 is added, the current of the heating resistor REAT is adjusted through the resistor R3, and the preheating process is accelerated.

In an optional embodiment, the heating resistor RHEAT of the gas sensor is further connected with a resistor R4, and one end of the resistor R4 is grounded; or, the gas sensor has one end connected to ground; or the resistance value of the resistor R4 is 50-100 omega, preferably, the resistance value of the resistor R4 is 68 omega, and the resistor R4 is used as the main fixed current of the heating resistor REAT.

The resistor R4 and the resistor R3 are both connected with the heating resistor REAT in series, wherein the resistor R4 is a part of the heating circuit and is matched with the heating resistor REAT.

As an alternative embodiment, the gas sensing resistor Rs is connected in series with a voltage dividing resistor R1.

As an optional embodiment, the resistance value of the voltage dividing resistor R1 is 50K Ω to 150K Ω, and preferably, the resistance value of R1 is 100K Ω.

In the invention, the voltage dividing resistor R1 and the gas sensitive resistor Rs form a voltage dividing circuit, an ADC interface is connected to the voltage dividing circuit to divide the voltage of the ADC sampling gas sensitive resistor Rs, so that a voltage signal and resistance value change of the gas sensitive resistor Rs are obtained, and the VOC concentration can be measured through the relation between the gas sensitive resistor Rs and the VOC concentration.

As an optional implementation manner, a power supply data interface is provided, and the power supply data interface is used for inputting a 5V power supply to the single chip microcomputer.

As an optional implementation manner, the power supply data interface is connected in parallel with a resistor R5 and a resistor R6, and the resistance values of the resistor R5 and the resistor R6 range from 5k Ω to 15k Ω; preferably, the resistors R5 and R6 are selected to have a resistance of 10k Ω.

The two resistors are arranged in the invention, so that the IIC has a certain high and low level during the communication, the communication is more stable, and the bus requirements of the IIC protocol are matched.

As an optional implementation manner, the power supply data interface is connected with an IIC bus, the IIC bus uses a standard IIC protocol for communication, the IIC bus is used for connecting an external device, and the external device reads the data of the single chip microcomputer through the IIC bus and the standard IIC protocol.

As an optional implementation manner, the power supply data interface includes an LDO linear regulator, a power supply voltage passing through the LDO linear regulator is 3.0V, and the power supply is input to the temperature and humidity sensor and the gas sensor.

In an alternative embodiment, the LDO linear regulator is connected in parallel with a filter capacitor for providing a smoother voltage.

In an optional implementation manner, one end of the filter capacitor is connected in parallel with the LDO linear regulator, and the other end is grounded.

As an optional implementation manner, the filter capacitor includes a first capacitor, a second capacitor, and a third capacitor.

As an optional implementation manner, the single chip microcomputer includes an IIC interface, the IIC interface is connected to the temperature and humidity sensor, and the single chip microcomputer obtains temperature and humidity data measured by the temperature and humidity sensor through the IIC interface.

As an optional implementation manner, the temperature and humidity sensor and the single chip microcomputer communicate with each other by using an IIC communication protocol, or pull-up resistors R8 and R9 are arranged between the temperature and humidity sensor and the IIC interface.

In an optional embodiment, the resistance values of the pull-up resistors R8 and R9 are 1k Ω to 15k Ω; preferably, the resistance values of R8 and R9 are 10k Ω.

In the invention, the addition of the pull-up resistor enables the IIC bus to have a determined level state during communication, and the singlechip is connected with the temperature and humidity sensor or the IIC communication is stable during data reading.

As an optional implementation manner, the temperature and humidity sensor integrated circuit comprises a PCB, wherein the gas sensor, the temperature and humidity sensor and the single chip are integrated on the PCB, the PCB comprises at least one isolation island, through holes are formed around the isolation island, and the gas sensor or the temperature and humidity sensor is arranged on the isolation island.

As an optional implementation manner, the through hole is of a C-shaped structure, and an opening of the through hole is communicated with the PCB to form the isolation island.

As an optional implementation manner, the PCB board is provided with two isolation islands, and the opening directions of the two isolation islands are opposite to each other and are disposed at two ends of the PCB board.

A measurement method, for measurement of the gas resistance Rs in the detection system, based on a characteristic curve of the gas resistance Rs:

RX = R0 EXP (-K CX), wherein K is a sensitivity coefficient, CX is a gas concentration, R0 is a gas-sensitive resistance Rs of clean air, and RX is a gas-sensitive resistance Rs value under the concentration of CX;

the following measurement formula is obtained for obtaining the resistance value of the gas sensitive resistor Rs:

cx is fitted within 1ppm using y = 1/(Ax × Kx), where Kx = Rx/R1, when 0.1ppm =1/10, i.e. a0.1= (R0.1/R1) =10; then a0.1=10/K0.1;

when RX > R0.1, i.e. the range y at which the gas concentration is below 0.1ppm, is calculated as follows:

y=1/（A0.1*Kx)；

when R1 < RX < R0.1, i.e. the gas concentration is in the range y of 0.1ppm to 1ppm, the calculation is as follows:

y = 1/(Ax × Kx); wherein Ax =1+ (a 0.1-1) (Rx-R1)/(R0.1-R1).

When RX < R1, i.e. the gas concentration, is in the range y of 1ppm to 10ppm, the calculation is as follows:

y=1+9*(R1-Rx)/(R1-R10)；

wherein, R0.1 is the resistance at the concentration C0.1=0.1ppm, R1 is the resistance at the concentration C1=1ppm, R10 is the resistance at the concentration C10=10ppm, and a is the adjustment factor coefficient.

According to the invention, the characteristic curve of the gas-sensitive resistor Rs is simplified, and R0.1 can be calculated only by calibrating R1 and R10 (namely 1ppm and 10 ppm), so that the VOC concentration in the range of 0-10 ppm can be calculated; by adopting the algorithm, the production efficiency of the sensor can be greatly improved, and meanwhile, good support is provided for zero point self-calibration of a user.

A detection device utilizes the measurement method and/or the temperature and humidity compensation method to detect air quality.

Compared with the prior art, the invention has the following beneficial effects:

in the invention, the VOC gas sensor needs to be heated, heat can be generated, and the measurement of the temperature and humidity sensor is seriously influenced, so the PCB layout design needs to be considered, and the heat source conduction path is changed by the PCB layout in an isolation island mode; therefore, in a limited size, the influence of a heating source on the temperature and humidity sensor is greatly reduced, preferably, a mode of reducing the influence as much as possible is to arrange two isolation island structures which are provided with an annular C-shaped through hole structure, so that the contact area with a PCB (printed circuit board) can be reduced to the greatest extent, and the influence of heat transmitted by a heating resistor RHAET in the gas sensor on the board is minimized; meanwhile, a better scheme is that two isolation island structures are arranged, and a gas sensor and a temperature and humidity sensor are respectively arranged, so that the influence of the sensors on the PCB during measurement is further reduced, and the mutual measurement is not influenced; it may also be a inferior solution, where only one isolated island is provided for placing the gas sensor.

Drawings

Fig. 1 is an overall structural view of the present invention.

FIG. 2 is a schematic diagram of a PCB board of the present invention.

In the figure, a temperature and humidity sensor 100, a gas sensor 200 and a power supply data interface 300 are shown.

Detailed Description

The drawings are only for purposes of illustration and are not to be construed as limiting the invention. For a better understanding of the following embodiments, certain features of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

Example 1

As shown in fig. 1, an air quality detection system includes a single chip microcomputer, a temperature and humidity sensor 100 and a gas sensor 200, the single chip microcomputer is connected with the temperature and humidity sensor 100 and the gas sensor 200, the temperature and humidity sensor 100 is used for acquiring temperature and humidity information, the gas sensor 200 is used for acquiring a VOC concentration of air, after acquiring the temperature and humidity information and the VOC concentration, the single chip microcomputer compensates and calibrates the VOC concentration of air according to the temperature and humidity information, and the gas sensor 200 includes a gas sensitive resistor Rs and a heating resistor R _HEAT 。

On the basis that the temperature and humidity information and the gas VOC concentration are obtained by the single chip microcomputer, the invention further has the following advantages that: in the aspect of measuring the VOC concentration influenced by the moisture content, the single chip microcomputer further performs compensation operation on the gas VOC concentration based on the temperature and humidity information, so that the single chip microcomputer obtains a more accurate gas VOC concentration value after operation, and the accuracy of a system result is improved.

As an optional implementation manner, the single chip microcomputer includes an IO interface, and the IO interface is connected to the heating resistor RHEAT and is used for adjusting the current of the heating resistor RHEAT; the single chip microcomputer comprises an ADC interface, the ADC interface is connected with the gas-sensitive resistor Rs, and the single chip microcomputer acquires the resistance value change of the gas-sensitive resistor Rs through the ADC interface.

As an optional implementation manner, the system further includes a resistor R3, one end of the resistor R3 is connected to the IO interface, and the other end of the resistor R3 is connected in series with the heating resistor RHEAT, and the single chip microcomputer controls the current of the heating resistor RHEAT by controlling the IO interface; or the resistance value of the resistor R3 is 200 to 500 omega, and preferably, the resistance value of the resistor R3 is 300 omega.

According to the invention, the IO port of the single chip microcomputer is arranged, and the current of the heating resistor REAT is changed by controlling the high and low levels of the IO port, so that the sensor is accelerated to preheat, a proper high-temperature environment is provided for the operating environment of the gas sensitive resistor Rs, meanwhile, the effect of rapid preheating is realized by controlling the level of the IO interface end, and the operating efficiency of the system is improved; meanwhile, the current in the circuit is limited to a certain extent due to the operation requirement of the device of the single chip microcomputer, so that the resistor R3 is added, the current of the heating resistor REAT is adjusted through the resistor R3, and the preheating process is accelerated.

As an alternative embodiment, the gas sensor 200 is further connected with a resistor R4, and one end of the resistor R4 is grounded; alternatively, the gas sensor 200 has one end grounded; or the resistance value of the resistor R4 is 50-100 omega, preferably, the resistance value of the resistor R4 is 68 omega, and the resistor R4 is used as the main fixed current of the heating resistor REAT.

The resistor R4 and the resistor R3 are both connected with the heating resistor REAT in series, wherein the resistor R4 is a part of the heating circuit and is matched with the heating resistor REAT.

As an alternative embodiment, the gas sensing resistor Rs is connected in series with a voltage dividing resistor R1.

As an optional embodiment, the resistance value of the voltage dividing resistor R1 is 10K Ω to 150K Ω, and preferably, the resistance value of R1 is 100K Ω.

In the invention, the voltage dividing resistor R1 and the gas sensitive resistor Rs form a voltage dividing circuit, an ADC interface is connected to the voltage dividing circuit to divide the voltage of the ADC sampling gas sensitive resistor Rs, so that a voltage signal and resistance value change of the gas sensitive resistor Rs are obtained, and the VOC concentration can be measured through the relation between the gas sensitive resistor Rs and the VOC concentration.

As an optional implementation manner, a power supply data interface 300 is provided, and the power supply data interface 300 is used for inputting a 5V power supply to the single chip microcomputer.

As an optional implementation manner, the power supply data interface 300 is connected in parallel with a resistor R5 and a resistor R6, and the resistance ranges of the resistor R5 and the resistor R6 are 1k Ω to 15k Ω; preferably, the resistors R5 and R6 are selected to have a resistance of 10k Ω.

The two resistors are arranged in the invention, so that the IIC has a determined high and low level during communication, the communication is more stable, and the bus requirements of the IIC protocol are matched.

As an optional implementation manner, the power supply data interface 300 is connected to an IIC bus, the IIC bus uses a standard IIC protocol for communication, the IIC bus is used for connecting an external device, and the external device reads the data of the single chip microcomputer through the IIC bus and the standard IIC protocol.

As an optional implementation manner, the power supply data interface 300 is provided with an LDO linear regulator, the power supply voltage passing through the LDO linear regulator is 3.0V, and the power supply is input to the temperature and humidity sensor 100 and the gas sensor 200.

In an alternative embodiment, the LDO linear regulator is connected in parallel with a filter capacitor to provide a smoother voltage.

In an optional implementation manner, one end of the filter capacitor is connected in parallel with the LDO linear regulator, and the other end is grounded.

As an optional implementation manner, the filter capacitor includes a first capacitor, a second capacitor, and a third capacitor.

As an optional implementation manner, the single chip microcomputer includes an IIC interface, the IIC interface is connected to the temperature and humidity sensor 100, and the single chip microcomputer obtains temperature and humidity data measured by the temperature and humidity sensor 100 through the IIC interface.

As an optional implementation manner, the temperature and humidity sensor 100 and the single chip microcomputer communicate with each other by using an IIC communication protocol, or pull-up resistors R8 and R9 are provided between the temperature and humidity sensor 100 and the IIC interface.

As an optional implementation manner, the resistance values of the pull-up resistors R8 and R9 are 1k Ω to 15k Ω; preferably, the resistance values of R8 and R9 are 10k Ω.

In the invention, the addition of the pull-up resistor enables the IIC bus to have a determined level state during communication, and the single chip microcomputer is connected with the temperature and humidity sensor 100 or the IIC communication is stable during data reading.

As an optional implementation manner, as shown in fig. 2, the temperature and humidity sensor device includes a PCB, the gas sensor 200, the temperature and humidity sensor 100, and the single chip are integrated on the PCB, the PCB includes at least one isolation island, through holes are provided around the isolation island, and the gas sensor 200 or the temperature and humidity sensor 100 is provided on the isolation island.

As an optional implementation manner, the through hole is a C-shaped structure, and an opening of the through hole is communicated with the PCB to form the isolation island.

As an optional implementation manner, the PCB board is provided with two isolation islands, and the opening directions of the two isolation islands are opposite to each other and are disposed at two ends of the PCB board.

A measurement method for measurement of the gas-sensitive resistor Rs in the detection system, based on a characteristic curve of the gas-sensitive resistor Rs:

RX = R0 EXP (-K CX), wherein K is a sensitivity coefficient, CX is a gas concentration, R0 is a gas-sensitive resistance Rs of clean air, and RX is a gas-sensitive resistance Rs value under the concentration of CX;

the following measurement formula is obtained for obtaining the resistance value of the gas sensitive resistor Rs:

cx is fitted within 1ppm using y = 1/(Ax x Kx), where Kx = Rx/R1, when 0.1ppm =1/10, i.e. a0.1 (R0.1/R1) =10; then a0.1=10/K0.1;

when RX > R0.1, i.e. the range y of the gas concentration below 0.1ppm, is calculated as follows:

y=1/（A0.1*Kx)；

when R1 < RX < R0.1, i.e. the gas concentration is in the range y of 0.1ppm to 1ppm, the calculation is as follows:

y = 1/(Ax × Kx); wherein Ax =1+ (a 0.1-1) × (Rx-R1)/(R0.1-R1).

When RX < R1, i.e. the gas concentration, is in the range y of 1ppm to 10ppm, the calculation is as follows:

y=1+9*(R1-Rx)/(R1-R10)；

wherein, R0.1 is a resistance value at a concentration C0.1=0.1ppm, R1 is a resistance value at a concentration C1=1ppm, R10 is a resistance value at a concentration C10=10ppm, and a is an adjustment factor coefficient.

According to the invention, the characteristic curve of the gas-sensitive resistor Rs is simplified, and R0.1 can be calculated only by calibrating R1 and R10 (namely 1ppm and 10 ppm), so that the VOC concentration in the range of 0-10 ppm can be calculated; by adopting the algorithm, the production efficiency of the sensor can be greatly improved, and meanwhile, good support is provided for zero-point self calibration of a user.

A temperature and humidity compensation method is used for compensation measurement of the gas-sensitive resistor Rs in the detection system, the singlechip realizes temperature and humidity compensation by adopting the following algorithm,

in the formula, TVOC is the raw data VOC concentration to its temperature and humidity compensation, TVOCx is the VOC concentration after temperature and humidity compensation, RH is relative humidity, and T is the temperature.

A detection device utilizes the measurement method and/or the temperature and humidity compensation method to detect air quality.

In particular, the method comprises the following steps of,

according to experiments and related theories, the gas-sensitive resistance Rs characteristic model accords with an exponential relationship, and fitting can be performed by applying NTC characteristics.

RX=R0*EXP(-K*CX)

Wherein K is the sensitivity coefficient, CX is gas concentration, R0 is clean air gas sensitive resistance Rs, RX is gas sensitive resistance Rs under VOC's CX concentration.

R0.1=R0*EXP(-K*C0.1)

R1=R0*EXP(-K*C1)

R10=R0*EXP(-K*C10)

Wherein R0.1 is the resistance at a concentration of C0.1=0.1ppm, R1 is the resistance at a concentration of C1=1ppm, and R10 is the resistance at a concentration of C10=10ppm

Can obtain

LOG(R0.1/ R0)/LOG(R1/R0)=C0.1/C1=LOG(R1/ R0)/LOG(R10/ R0)=C1/C10

Therefore it has the advantages of

（LOG(R1/ R0)）2=LOG(R0.1/ R0)* LOG(R10/ R0)

Under the condition of low precision requirement, the precision requirement can be simplified to

(R1/ R0.1）2= (R10/ R0.1)

Let K = R10/R1, and further simplify R1/R0.1= K, which is the key point,

cx is fitted within 1ppm using y = 1/(Ax × Kx), where Kx = Rx/R1, when 0.1ppm =1/10, i.e. a0.1= (R0.1/R1) =10; then a0.1=10/K0.1;

when RX > R0.1, i.e. the range y at which the gas concentration is below 0.1ppm, is calculated as follows:

y=1/（A0.1*Kx)；

when R1 < RX < R0.1, i.e. the gas concentration is in the range of 0.1ppm to 1ppm, y is calculated as follows:

y = 1/(Ax × Kx); wherein Ax =1+ (a 0.1-1) × (Rx-R1)/(R0.1-R1).

When RX < R1, i.e. the gas concentration is in the range y of 1ppm to 10ppm, the calculation is as follows:

y=1+9*(R1-Rx)/(R1-R10)；

wherein, R0.1 is the resistance at the concentration C0.1=0.1ppm, R1 is the resistance at the concentration C1=1ppm, R10 is the resistance at the concentration C10=10ppm, and a is the adjustment factor coefficient.

In the invention, the VOC gas sensor 200 needs to be heated, and can generate heat, which has serious influence on the measurement of the temperature and humidity sensor 100, so the PCB layout design needs to be considered, and the heat source conduction path is changed by the PCB layout in an isolation island mode; therefore, in a limited size, the influence of a heating source on the temperature and humidity sensor 100 is greatly reduced, preferably, a mode of reducing the influence as much as possible is to arrange two isolation island structures, and the structure has an annular C-shaped through hole structure, so that the contact area with a PCB (printed circuit board) can be reduced to the greatest extent, and the influence of heat transmitted by a heating resistor REAT in the gas sensor 200 on the board is minimized; meanwhile, a better scheme is that two isolation island structures are arranged, the gas sensor 200 and the temperature and humidity sensor 100 are respectively placed, so that the influence of the sensors on a PCB during measurement is further reduced, and the mutual measurement is not influenced; it may also be a less preferred solution to provide only one isolated island for placement of the gas sensor 200.

It should be understood that the above-mentioned embodiments of the present invention are only examples for clearly illustrating the technical solutions of the present invention, and are not intended to limit the specific embodiments of the present invention. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention claims should be included in the protection scope of the present invention claims.

Claims (8)

1. A temperature and humidity compensation method of an air quality detection system is characterized in that after the temperature and humidity information and the VOC concentration are obtained by the single chip microcomputer, the VOC concentration of air is compensated and calibrated according to the temperature and humidity information, and the gas sensor comprises a gas sensitive resistor Rs and a heating resistor R _HEAT ；

The single chip microcomputer adopts the following algorithm to realize temperature and humidity compensation,

in the formula, TVOC is the raw data VOC concentration without compensating for its humiture, TVOCx is the VOC concentration after the humiture compensation, RH is the relative humidity, and T is the temperature.

2. The temperature and humidity compensation method of the air quality detection system according to claim 1, comprising a PCB board, wherein the gas sensor, the temperature and humidity sensor, and the single chip are integrated on the PCB board, the PCB board comprises at least one isolation island, through holes are arranged around the isolation island, and the gas sensor or the temperature and humidity sensor is arranged on the isolation island.

3. The temperature and humidity compensation method of the air quality detection system according to claim 2, wherein the through hole is of a C-shaped structure, and an opening of the through hole is communicated with the PCB to form the isolation island.

4. The temperature and humidity compensation method of the air quality detection system according to claim 3, wherein the PCB is provided with two isolation islands, and the two isolation islands are provided at two ends of the PCB with opposite opening directions.

5. The temperature and humidity compensation method of the air quality detection system according to claim 1, wherein the single chip microcomputer comprises an IO interface, and the IO interface is connected with the heating resistor R _HEAT For the heating resistor R _HEAT Current regulation of (2); the single chip microcomputer further comprises an ADC interface, the ADC interface is connected with the gas sensitive resistor Rs, and the single chip microcomputer obtains resistance value changes of the gas sensitive resistor Rs through the ADC interface.

6. The temperature and humidity compensation method of the air quality detection system according to claim 5, further comprising a resistor R3, wherein one end of the resistor R3 is connected to the IO interface, and the other end of the resistor R3 is connected in series with the heating resistor R _HEAT The single chip microcomputer controls the heating resistor R by controlling the IO interface _HEAT The current of (2).

7. The temperature and humidity compensation method of the air quality detection system according to claim 2, wherein the gas sensitive resistor Rs is connected in series with a voltage dividing resistor R1.

8. A detection device, characterized in that the temperature and humidity compensation method according to any one of claims 1-7 is used for air quality detection.

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