JP2967431B2 - Air cleaner - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air purifier that detects air contamination using a sensor and purifies the air in accordance with the contamination.

2. Description of the Related Art Conventionally, this type of air purifier uses a gas sensor that undergoes a chemical reaction with a certain gas component and changes its resistance value in accordance with the gas concentration. , And purifying the air according to the detection level. Further, in order for a gas sensor to actively perform a chemical reaction with a certain kind of gas, it is necessary to set the sensor temperature to about 300 ° C. to 400 ° C. Therefore, the sensor was heated with a heater to maintain the sensor temperature at about 300 ° C. to 400 ° C. In addition, in order to always operate the gas sensor stably, the power supply of the heater power supply is linked with the power supply of the air purifier, and the power supply of the heater is also supplied while the power supply is turned on.

Problems to be Solved by the Invention In such a conventional air purifier, the gas sensor performs a stable chemical reaction while the gas sensor is kept warm. However, once the gas sensor is cooled, the chemical reaction becomes unstable. It took several tens seconds to several minutes to reheat the gas sensor and bring the chemical reaction to a stable state again. The time variation of several tens of seconds to several minutes is caused by the variation of the inactive state of the gas sensor caused by the cooling time. If the non-energizing time of the heater is short, the gas sensor becomes stable in a few seconds after the start of energizing. However, if the non-energization time is long, it takes several minutes for the gas sensor to stably perform a chemical reaction. Then, assuming the worst case in the conventional air purifier, the output value of the gas sensor is determined to be not normal for several minutes from the start of energization of the heater.

By the way, home-installed air cleaners, once installed, are usually powered on and off, so it was not a major problem that the gas concentration could not be determined by the gas sensor for several minutes after the power was turned on. . But,
In the case of a portable type for home use, when the user wants to use it, he / she carries it to the place where it is used, and turns on the power at the place. Then, despite the desire to operate the air purifier immediately, there is a problem that the air cannot be purified according to the output value of the gas sensor for a few minutes after the power is turned on. In addition, the car air purifier also has a problem that the same operation as a home portable type is performed every time the engine is turned on and off.

The present invention has been made in order to solve the above-described problem, and is characterized in that the time from power-on until the gas sensor stably performs a chemical reaction can be determined by the non-energizing period of the heater and the amount of change in the gas sensor resistance. It is an object of the present invention to provide an air purifier in which a period in which the degree of contamination of a gas cannot be determined based on an output value of a gas sensor after turning on a power supply is set to a minimum time.

Means for Solving the Problems A first object of the present invention for achieving the above object is to provide a gas sensor comprising a sensor, a heater for heating the sensor, and a detecting means for detecting an output level of the gas sensor. A switch for inputting an output signal of the detecting means, and a period during which the heater is not generating heat (non-conduction time).
Timer, a switch control means for controlling the opening and closing of the switch by a signal output from the off timer, a processing means to which the switch is output, and an output corresponding to the processing result of the processing means The second problem solving means is a gas sensor comprising a sensor, a heater for heating the sensor, a detecting means for detecting an output level of the gas sensor, A changeover switch for inputting an output signal of the detection means, a change amount detection means which is one output destination of the changeover switch, and an output destination of the changeover switch is switched according to a signal output from the change amount detection means. A switching unit, a processing unit that is the other output destination of the changeover switch, and a processing result of the processing unit. An air purifier comprising output means for performing the same output is provided. Further, the third object of the present invention is to provide a gas sensor comprising a sensor, a heater for heating the sensor, and an output of the gas sensor. Detection means for detecting a level, an off timer for detecting a period during which the heater is not generating heat, storage means for storing an output value of a gas sensor on clean air in accordance with the value of the off timer, and the detection means A signal output from the storage unit is input, and the air purifier includes a determination unit that determines the degree of contamination of air based on these signals, and an output unit that outputs according to a result of processing by the determination unit. Things.

Operation With the above-described configuration, the operation of the first problem solving is that the control means controls the switch by the signal output from the off timer, so that the sensor can stably perform a chemical reaction from the non-energization time of the heater. The operation of the second object of the present invention is to control the switch by the switching means for switching the output destination of the changeover switch in accordance with the signal output from the change amount detecting means. The amount of change in the sensor output value after the detection is detected, and the stable state of the chemical reaction can be determined from this value,
Further, the operation of the third problem solving is that the output from the storage means processes the determination means according to the value of the off timer,
From the non-energizing time of the heater, the time until the sensor can perform a stable chemical reaction, and the reference output value that would be indicated by the sensor output value are set. The gas concentration from the start of energization until the chemical reaction of the sensor is stabilized is determined.

Embodiments Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows an embodiment according to a first means for solving the problem of the present invention. A gas sensor 1 comprises a sensor 2 and a heater 3 for heating the sensor 2, and a detecting means 4 comprises The output level is detected, the switch 5 receives the output signal of the detection means, the power supply 6 applies a voltage to the heater 3, and the off timer 7 detects the non-energized time of the power supply 6 (a period during which the heater is not generating heat). Switch control means 8
Controls the opening and closing of the switch 5 by a signal output from the off timer 7, the processing means 9 is an output destination of the switch 5, and 10 is a fan motor or an LED which outputs according to the processing result of the processing means 9. Output means such as display.

The operation of the above configuration will be described. A signal output from the gas sensor 1 is converted into an electric signal by the detection unit 4. Then, this electric signal is input to the processing means 9. The processing means 9 which has received the electric signal changes and outputs the air volume of the fan 10 and the display content of the LED 10 according to the signal level. Thus, the output is controlled according to the output level of the gas sensor 1. The gas sensor 1 detects the degree of air contamination by utilizing the fact that the resistance value of the sensor 2 changes due to a chemical reaction between the surrounding gas components and the sensor 2. In addition, the heater 2 is used to move the sensor 2 by 300 so that the sensor 2 can perform a chemical reaction stably.
Warm to 400 ° C. However, the state of the sensor 2 differs depending on the time before the power is turned on, and the time from when the power is turned on to when the sensor output is stabilized becomes longer as shown in FIG. It is long and short when the non-energization time is short, and takes several tens of seconds to several minutes depending on the non-energization time.
The user wants to use immediately after turning on the power. Therefore, focusing on the point that the time from when the power is turned on until the sensor output value stably outputs is correlated with the non-energization time of the heater, as shown in FIG.
, The time until the gas sensor 1 operates stably is calculated. This will be described below.

First, when the power supply 6 is turned off, the off-timer 7 detects that the heater 3 is off, and starts counting off time. The switch control means 8 having received the signal output from the off timer 7 sends a signal to the switch 5 to open the switch 5 so that the output signal from the detection means 4 is not sent to the processing means 9. Then, when the power supply 6 is turned on, the off timer 7 detects the power supply start time of the power supply 6. Next, based on the timer count time, the time from when the heater 3 starts to be energized to when the sensor 2 stably performs a chemical reaction is calculated. After passing the calculated time from the start of the heater 3 energizing time, the switch 5
Signal from the switch control means 8 so that the switch 5 is closed.
Sent to When the switch 5 is closed, the sensor 2
Is received by the detection means 4, and the processing means 9 receives this signal via the switch 5. Upon receiving this signal, the processing means 9 outputs the fan airflow and the LED display content according to the sensor output level.

FIG. 3 shows an embodiment according to the second means for solving the problem of the present invention. In the above-mentioned first embodiment, by detecting the non-energization time of the heater 3, the gas sensor 1 is turned on after the power is turned on. Although the time until the operation is stably calculated is calculated, in the present embodiment, the stable state of the output value of the gas sensor 1 is detected from the amount of change in the output value of the sensor 2 detected by the detection means 4. The same components as those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

In the figure, reference numeral 11 denotes a changeover switch for inputting an output signal of the detection means 4, 12 denotes a change amount detection means which is one output destination of the changeover switch 11, and 13 denotes a change amount detection means.
The changeover switch 11 according to the signal output from 12
Is a switching means for switching the output destination.

Explaining the mutual relationship and operation of the above components, when the power supply 6 is turned on, first, the changeover switch 11 is switched to the change amount detecting means 12 side. The output value of the gas sensor 1 detected by the detecting means 4 is input to the change amount detecting means 12. At this time, the output value from the detecting means 4 increases in a certain curve with respect to the time after the power supply 6 is turned on as shown in FIG. The increase amount (change amount) Δt of this gas sensor output value with respect to a minute time is Δt ₀ after the power supply 6 is turned on, and thereafter decreases gradually.
Finally, it becomes 0. Becomes smaller when below a certain value Delta] t ₁ with this Delta] t, the output value from the sensor 2 determines that outputting the dirt of the surrounding gas accurately. The switching means 13 transmits this to the changeover switch 11, and upon receiving this signal, the changeover switch 6 is switched to the processing means 9 side, and the processing means 9 determines the output content of the output means according to the sensor output value, and doing.

As is apparent from the above description, the time from when the power is turned on until the output value of the gas sensor becomes stable, or by detecting the stable state of the output value of the gas sensor, from the time when the power is turned on to when the output value of the gas sensor is determined by the gas sensor output value. Any configuration that minimizes the time may be used.

FIG. 5 shows an embodiment according to the third means for solving the problem of the present invention.
The same reference numerals are given to the same components as in the embodiment, and the description is omitted.

As shown in the figure, the storage means 21 stores the output state of the gas sensor in clean air from the time the power is turned on until the gas sensor output value is settled in accordance with the length of the non-energization time. Inputs the output signal from the storage means and the detection means 4 and judges the degree of air contamination. Then, the output means 23 outputs according to the output content from the determination means.

The operation will be described in the above configuration. First, when the power supply 6 is turned off, the off timer 7 detects that the heater 3 is off, and starts counting off time. Thereafter, when the power supply 6 is turned on, the off timer 7
Of the power supply is detected. Next, based on the timer count time, the time from when the heater 3 starts to be energized to when the sensor 2 stably performs a chemical reaction is calculated. From the calculated time, the contents that the gas sensor 1 will output in the clean air are output from the storage unit 21 to the determination unit 22.
The judgment means 22 receives the gas sensor signal from the detection means 4 at the same time as receiving the signal from the storage means 21. From these two signals, the current degree of air contamination is determined.

The details will be described with reference to FIG. 6. First, FIG. 6A shows the output value (ideal curve) of the detection means in clean air, FIG. 6B shows the case where the air becomes dirty after the gas sensor value is stabilized, and FIG. FIG. 4 shows a diagram in which air becomes dirty before the gas sensor value is stabilized.
The curve in FIG. 7A is sent from the storage unit to the determination unit. On the other hand, actual detection values are as shown in (b) and (c). As shown in (b), when the air starts to become dirty after the output value of the gas sensor is stabilized t ₀ , the reference value R ₀ after the output value of the gas sensor is stabilized is the same as in the conventional case.
Dirt degree can be determined by the current difference or ratio value R ₁ for. In the example of (c), if R ₀ is determined at t ₀ ,
Even if air contamination, the amount of change in R ₁ for R ₀ is made to the fact that 0, the output means 10 outputs the clean. Thus, by determining the degree of air contamination from the difference or ratio between the ideal curve sent from the storage means 21 and the current curve, the degree of air contamination can be determined at any time after the power is turned on. I can judge.

Advantageous Effects of the Invention As is clear from the above description of the embodiment, according to the air purifier of the present invention, by detecting the point in time when the chemical reaction of the gas sensor is in a stable state, the air purifier according to the output value of the gas sensor is detected. It is possible to minimize the time until it is possible to judge dirt. Further, the output state of the gas sensor after turning on the power in the clean air is stored in the storage means, and the value is compared with the current gas sensor value, so that the degree of contamination of the air is always determined according to the output value of the gas sensor. You can judge.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a first embodiment of the present invention,
FIG. 2 is a diagram showing a transient response time from the power-on of the gas sensor output value according to the first embodiment of the present invention, FIG. 3 is a block diagram showing a second embodiment of the present invention, and FIG. FIG. 5 is a diagram of a transient response time from the power-on of the gas sensor output value of the second embodiment, FIG. 5 is a block diagram showing a third embodiment of the present invention, and FIG. 6 is a diagram of a third embodiment of the present invention. FIG. 6 is a diagram illustrating a transient response time from a power-on of a gas sensor output value. 1 ... gas sensor, 2 ... sensor, 3 ... heater, 4 ...
... Detecting means, 5 ... Switch, 7 ... Off timer, 8 ...
... switch control means, 9 ... processing means, 10 ... output means.

Continuation of the front page (72) Inventor Shunichiro Tanaka 1006 Kazuma Kadoma, Kadoma City, Osaka Prefecture Matsushita Electric Industrial Co., Ltd. (56) References JP-A-3-296414 (JP, A) (58) Fields surveyed (Int .Cl. ⁶ , DB name) G01N 27/12 B01D 53/30

Claims (3)

(57) [Claims] 1. A gas sensor comprising a sensor, a heater for heating the sensor, detecting means for detecting an output level of the gas sensor, a switch for inputting an output signal of the detecting means, and the heater not generating heat. An off timer for detecting a period (non-energized time); a switch control means for controlling the opening and closing of the switch by a signal output from the off timer; a processing means as an output destination of the switch; and a processing result of the processing means An air purifier comprising output means for performing an output according to the condition. 2. A gas sensor comprising a sensor, a heater for heating the sensor, detection means for detecting an output level of the gas sensor, a changeover switch for inputting an output signal of the detection means, and one of the changeover switches. A change amount detection unit that is an output destination, a switching unit that switches an output destination of the changeover switch in accordance with a signal output from the change amount detection unit, a processing unit that is the other output destination of the changeover switch, An air purifier comprising output means for performing an output in accordance with a result processed by the processing means. 3. A gas sensor comprising a sensor, a heater for heating the sensor, detection means for detecting an output level of the gas sensor, an off timer for detecting a period during which the heater is not generating heat, and Storage means for storing the output value of the gas sensor in accordance with the value of the off-timer; inputting signals output from the detection means and the storage means; determining means for determining the degree of air contamination based on these signals; An air purifier comprising an output unit that outputs according to a result processed by the determination unit.