JP7183417B2 - Air cleaning device and air cleaning method - Google Patents

Description

The present invention relates to an air cleaning device and an air cleaning method.

Odor components such as malodorous substances and volatile organic compounds (VOCs) contained in the air inside vehicles and indoors of buildings are removed (deodorized) and There are air purifiers that clean air containing odorous components by sterilizing them.

As such an air cleaning device, for example, there is a vehicle ventilation/deodorizing device provided with a fan, an ozone generator, a switching damper, a control unit, and an odor sensor (see, for example, Patent Document 1). In a conventional vehicle ventilation/deodorization device, a control unit controls a fan, an ozone generator, and a switching damper according to the concentration of odor inside the vehicle detected by an odor sensor, and the ventilation mode, the ozone normal mode, and the ozone Three modes of fumigation mode are switched. When removing strong odors that have permeated the interior of the vehicle, select the ozone fumigation mode to generate high-concentration ozone exceeding the standard value for a predetermined period of time, effectively deodorizing the strong odors that have permeated the interior of the vehicle. ing.

An odor sensor is generally a semiconductor type sensor formed using a semiconductor element formed of an oxide semiconductor or an organic semiconductor in many cases. In the semiconductor sensor, the oxygen adsorbed to the surface of the semiconductor element with a negative charge reacts with the odor component (surface reaction). value changes. A semiconductor sensor uses this property to measure the concentration of odorous components in the air.

Japanese Patent Laid-Open No. 10-151941

However, in the vehicle ventilation/deodorizing device of Patent Document 1, ozone is uniformly generated in the vehicle for a predetermined period of time by a timer regardless of the strength of the offensive odor. There was a high possibility of overdoing deodorization. If the deodorization is not sufficient, the offensive odor inside the vehicle will not be sufficiently removed and will remain, giving discomfort to the vehicle user. On the other hand, if deodorization is carried out excessively, ozone is excessively generated, resulting in wasted power consumption and an unnecessarily long deodorizing operation.

Therefore, it is necessary to appropriately suppress the generation of purifying substances such as ozone and hypochlorous acid that remove odorous components in the air.

An object of one aspect of the present invention is to provide an air cleaner capable of stopping the generation of purification substances at the optimum timing when deodorization is finished.

One aspect of the air purifier according to the present invention includes a cleaning unit that removes odorous components contained in the air in a space, and the air in the space that is supplied to the cleaning unit and cleaned in the cleaning unit. a circulation section for discharging clean air into the space, wherein the cleaning section includes a purification substance generating section for generating a purification substance that decomposes the odorous component, wherein the odorous component is removed. a reaction product concentration measuring unit for measuring the concentration of the reaction product generated when the purification substance is decomposed; a control unit that controls the purification substance generating unit to control the amount of the purification substance generated.

One aspect of the air purifier according to the present invention can stop the generation of purification substances at the optimum timing when deodorization is finished.

It is a figure which shows the state which applied the air cleaning apparatus which concerns on one Embodiment to the vehicle. It is a figure explaining an example of a control apparatus. It is a flow chart explaining an air cleaning method. FIG. 4 is a diagram showing an example of the relationship between time and concentration of reaction products; FIG. 4 is an explanatory diagram showing an example of the relationship between the unit time and the amount of increase in the concentration of the reaction product;

Hereinafter, embodiments of the present invention will be described in detail. In addition, in order to facilitate understanding of the description, the same components are denoted by the same reference numerals in each drawing, and overlapping descriptions are omitted. Also, the scale of each member in the drawings may differ from the actual scale.

<Air purifier>
An air cleaner according to one embodiment will be described. In this embodiment, as an example, a case where an air purifying device is used to clean odorous components contained in the air in the interior space (space) of a vehicle will be described. The term "odor component" refers to malodorous substances, volatile organic compounds (VOC), and the like, such as tobacco odor, pet odor, body odor from the human body, aging odor, and the like. Specifically, malodorous substances include methyl mercaptan, trimethylamine, isobutanol, and the like, and volatile organic compounds include toluene, xylene, and the like. In addition, ozone, hypochlorous acid, hydrogen peroxide, and the like are listed as purifying substances used for purifying odorous components. A case where the odor component is toluene and the purifying substance is ozone will be described below.

FIG. 1 is a diagram showing a state in which an air cleaner according to one embodiment is installed in a vehicle. In FIG. 1, the vehicle is stopped, people, pets (animals), etc. are out of the vehicle, and there are no people, pets (animals), etc. in the vehicle.

As shown in FIG. 1, the air purifying device 10 has a purifying section 20, a circulation section 30, a detecting section 40 and a control device 50. As shown in FIG. The cleaning unit 20, the circulation unit 30, and the detection unit 40 are installed in an indoor space (indoor space) S of the vehicle 12, and the main body of the control device 50 is outside the space S and inside the vehicle 12. is provided. The cleaning unit 20 and the circulation unit 30 are provided inside the device main body 11 of the air cleaning device 10 .

The device main body 11 has a casing having an internal space that accommodates the cleaning section 20 and the circulation section 30 . The internal space constitutes an air passage for circulating the inhaled air in a predetermined direction. As the casing of the device main body 11, for example, one formed in a cylindrical shape, a rectangular parallelepiped shape, or the like can be used.

(Clean part)
The cleaning section 20 cleans the air in the space S and has a purification substance generating section 21 and a dust collection filter 22 . The cleaning unit 20 includes a purification substance generating unit 21 and a dust collection filter 22 in this order along the air blowing direction.

The purifying substance generator 21 generates ozone in the air using oxygen in the air taken in by the blower 32, which will be described later, as a raw material, and functions as an ozone generator. The purification substance generating unit 21 is electrically connected to a later-described control unit 51 (see FIG. 2) of the control device 50 and controlled by the control unit 51 (see FIG. 2). Any type of purification substance generator 21 can be used as long as it can generate ozone. For example, as the purifying substance generating unit 21, a discharge type device in which discharge electrodes and counter electrodes are alternately arranged so as to face each other can be used. In this discharge type, when a voltage is applied to both electrodes, a discharge occurs between both electrodes. Oxygen contained in the air is activated by passing air between the electrodes generating the discharge, and part of the dissociated or excited oxygen changes to ozone (O ₃ ). This creates ozone in the air. The generated ozone is transported in a state of being contained in the air. Ozone undergoes an oxidation reaction with odorous components contained in the air to decompose and remove the odorous components.

When the odorous component is, for example, toluene, the odorous component reacts with ozone and is decomposed into reaction products, carbon dioxide (CO ₂ ) and water (H ₂ O), as shown in the following formula (1). be.
_C7H8 + _6O3- > _7CO2 + _{4H2O (} 1)

The amount of ozone generated in the purification substance generator 21 (ozone generation amount) can be controlled (increased or decreased, activated, stopped, etc.) by adjusting the amount of discharge by a controller 51 (see FIG. 2) described later.

The dust collection filter 22 is provided on the downstream side of the purification substance generating section 21 in the air flow direction. The dust collection filter 22 collects solid matter such as dust in the air. The dust collection filter 22 may be any filter as long as it can collect dust in the air. For example, a pleated nonwoven fabric made of fine metal wires, natural fibers, or synthetic fibers can be used.

(Circulation part)
The circulation section 30 has an intake port 31 , a blower 32 and an exhaust port 33 .

The intake port 31 is for drawing the air in the space S into the apparatus body 11 . The intake port 31 is formed in a slit shape on the side surface of the device main body 11 . Incidentally, the intake port 31 may be formed on the upper surface or the lower surface of the apparatus main body 11 .

The blower 32 is provided in the vicinity of the intake port 31 on the upstream side in the air flow direction of the purification substance generating section 21 in the device main body 11 . The blower 32 is electrically connected to the control section 51 (see FIG. 2) of the control device 50 and controlled by the control section 51 (see FIG. 2). The blower 32 can be, for example, an axial fan that blows air in the rotation axis direction with propeller blades. The blower 32 is composed of a motor (not shown) and a plurality of blades fixed to the rotating shaft of the motor. The blower 32 is powered by an external power supply, and is driven by the motor to rotate the blades, thereby sucking air into the internal space of the apparatus main body 11, and the sucked air is sent to the purification substance generating section 21 and the dust collection filter. 22 and discharged into the space S from the exhaust port 33 . Note that the rotation speed of the blower 32 is controlled by a controller 51 (see FIG. 2), which will be described later.

The exhaust port 33 is for discharging the air (clean air) cleaned by the cleaning section 20 in the apparatus main body 11 to the space S inside the vehicle. The exhaust port 33 is formed in a slit shape on the side surface of the apparatus main body 11 . Note that the intake port 31 may be formed on the upper surface of the apparatus main body 11 .

(detector)
The detection unit 40 includes a purification substance concentration sensor 41 that is a purification substance concentration measurement unit, a reaction product concentration sensor 42 that is a reaction product concentration measurement unit, an odor sensor 43 that is an odor measurement unit, and a human detection sensor that is a human detection unit. 44. These sensors are provided in the space S, respectively. Moreover, the detection unit 40 is electrically connected to the control unit 51 (see FIG. 2) of the control device 50, and transmits each detection signal to the control unit 51 (see FIG. 2).

The purification substance concentration sensor 41 measures the ozone concentration of the air in the space S, and functions as an ozone concentration sensor. As the purification substance concentration sensor 41, a semiconductor type sensor or the like having a semiconductor element can be used. In the semiconductor sensor, ozone is adsorbed on the surface of the semiconductor element to change the resistance value of the semiconductor element, thereby measuring the ozone concentration.

The purification substance concentration sensor 41 is preferably provided in the space S at a position close to the intake port 31 . At a position closer to the intake port 31 than at a position closer to the exhaust port 33, it is easier to measure the ozone concentration after the ozone released into the space S has reacted with the odor component. Therefore, the concentration of ozone contained in the air in the space S can be stably measured. Note that the purification substance concentration sensor 41 may be installed in the space S at a position far from the device main body 11 .

The reaction product concentration sensor 42 measures the concentration of water (water concentration (humidity)), which is one of reaction products generated when odorous components are decomposed by ozone. A known moisture concentration meter (moisture meter) or the like can be used as the reaction product concentration sensor 42 . The type of moisture concentration meter is not limited, and for example, a polymer capacitance humidity sensor or the like can be used as the moisture concentration meter. The reaction product concentration sensor 42 may be provided at a position where the water concentration in the space S can be measured.

The odor sensor 43 measures the concentration of odor components in the space S. As the odor sensor 43, a semiconductor type sensor or the like using a metal oxide semiconductor such as tin oxide or zinc oxide can be used. In the semiconductor sensor, the oxygen adsorbed on the surface of the semiconductor element reacts with the odor component (surface reaction), and the oxygen is released, thereby changing the resistance value of the semiconductor element. The concentration of odorous components in the air is measured from the change in this resistance value. Note that the odor sensor 43 may be of a type other than the semiconductor type.

The human detection sensor 44 detects the presence or absence of a person in the space S. For the human sensor 44, for example, an infrared sensor or the like that senses the heat of a person or an animal such as a pet can be used. In this embodiment, the human detection sensor 44 is preferably used as the human detection unit, but any sensor that can detect the presence or absence of a person or an animal may be used. may be

(Control device)
As shown in FIG. 2 , the control device 50 has a control section 51 as a main body, an operation section 52 connected to the control section 51 , and a display section 53 . In this embodiment, the control unit 51 is provided inside the vehicle 12 outside the space S, and the operation unit 52 and the display unit 53 are provided inside the space S.

The control unit 51 is connected to each member constituting the air cleaning device 10 such as the purification substance generating unit 21 and the blower 32 and the display unit 53 so as to be controllable. The control unit 51 has storage means for storing control programs and various types of storage information, and calculation means for operating based on the control programs. The control unit 51 is implemented by reading and executing a control program or the like stored in the storage means by the calculation means.

The control unit 51 receives measurement results from the detection unit 40 . The control unit 51 controls the amount of ozone generated by the purification substance generating unit 21 and the rotation speed of the blower 32 based on the measurement result of the detection unit 40 . Specifically, the control unit 51 controls the ozone concentration measured by the purification substance concentration sensor 41, the water concentration measured by the reaction product concentration sensor 42, and the concentration of odorous components in the space S measured by the odor sensor 43. and a signal indicating the presence or absence of a person detected by the human sensor 44 is received. Based on the signals received from these sensors, the control unit 51 calculates the ozone concentration, moisture concentration, or concentration of odorous components in the air, judges the presence or absence of people, and supplies ozone to the purification substance generating unit 21. It outputs a signal to generate or a signal to rotate the fan 32 to the fan 32 . Based on the output signal, the discharge amount of the purification substance generator 21 or the rotation speed of the blower 32 is controlled, thereby adjusting the amount of generated ozone or the amount of blown air.

The control unit 51 controls the purification substance generating unit 21 to control the amount of ozone generated when the amount of increase in water concentration per unit time is equal to or less than a predetermined value.

The control unit 51 determines the relationship between the amount of ozone generated by the purification substance generating unit 21, the volume of the space S, and the amount of increase in the concentration of the reaction product (for example, water, CO _{2 ,} etc.) per unit time. You may make it memorize|store in a memory|storage means beforehand. In this embodiment, the storage means preferably stores the relationship between the amount of ozone generated by the purification substance generating section 21, the volume of the space S, and the amount of increase in water concentration per unit time. In this case, the control unit 51 compares the stored value stored in the storage means with the actual measurement value measured by the purification substance concentration sensor 41, and determines the amount of increase in the moisture concentration in the space S per unit time. is equal to or less than a predetermined value.

The control unit 51 controls the purification substance generating unit 21 and the blower 32 to change the operating state of the air purifying device 10 into a ventilation mode, a purification substance regular use mode (hereinafter referred to as an ozone regular use mode), and a purification substance The fumigation mode (hereinafter referred to as ozone fumigation mode in this embodiment) can be controlled in any one of three operation modes.

The ventilation mode is an operation mode in which the air sucked into the device main body 11 is discharged from the device main body 11 to the space S without the purification substance generating section 21 generating ozone. In the ventilation mode, the control section 51 stops the operation of the purification substance generating section 21 and controls to operate only the blower 32 .

In the normal ozone mode, the purification substance generator 21 generates low-concentration ozone, and the cleaning unit 20 cleans the air with the low-concentration ozone, and the clean air, together with the low-concentration ozone, is delivered from the device main body 11 to the space S. It is an operation mode for discharging. In the ozone regular mode, the controller 51 operates the air blower 32 and controls the purification substance generator 21 to generate low-concentration ozone.

In the ozone fumigation mode, the purification substance generator 21 generates high-concentration ozone, and the cleaning unit 20 cleans the air with high-concentration ozone together with the high-concentration ozone. It is an operation mode for discharging. In the ozone fumigation mode, the controller 51 operates the air blower 32 and controls the purification substance generator 21 to generate high-concentration ozone.

The concentration of ozone generated by the purification substance generator 21 is the ratio of the amount of ozone generated by the purification substance generator 21 to the amount of air passing through the purification substance generator 21 (ozone concentration=amount of ozone generated/purification substance generator 21).

Even if the amount of generated ozone is constant, the concentration of ozone discharged into the space S from the inside of the device body 11 fluctuates when the amount of air fluctuates. Therefore, any one of the following three methods can be used when adjusting the ozone concentration to a high concentration or a low concentration. The first method is to vary the amount of ozone generated by the purification substance generator 21 and keep the amount of air blown by the blower 32 constant. The second method is to keep the amount of ozone generated by the purification substance generator 21 constant and vary the amount of air blown by the blower 32 . A third method is to vary both the amount of ozone generated by the purification substance generator 21 and the amount of air blown by the blower 32 . In the present embodiment, it is preferable to use the first method described above in terms of stably circulating the air in the space S in the vehicle and facilitating control.

A low ozone concentration means that the ozone concentration is in the range of a safe standard value or less for the human body, and is 0.1 ppm or less, preferably 0.05 ppm or less.

In addition, the high ozone concentration means that the ozone concentration is higher than the standard value safe for the human body, and although a higher concentration is preferable in order to efficiently decompose odorous components, it does not affect the human body. Concerned. Therefore, it is preferable to perform the ozone fumigation mode using high-concentration ozone after confirming with the human detection sensor 44 that there are no people, pets, or the like in the space S inside the vehicle.

The operation unit 52 is arranged in the space S, and is operated from the outside to control the presence or absence of ozone generation in the purification substance generation unit 21, the amount of ozone generation, the presence or absence of operation of the blower 32, its rotation speed, etc. to the control unit 51.

The display unit 53 is arranged in the space S, and indicates whether or not ozone is generated in the purification substance generating unit 21 and the amount of ozone generated, whether or not the blower 32 is in operation and its rotation speed, and the ozone concentration measured by the purification substance concentration sensor 41. , the moisture concentration measured by the reaction product concentration sensor 42, the concentration of odorous components in the space S measured by the odor sensor 43, the presence or absence of a person detected by the human sensor 44, and the like. The display unit 53 also displays the end of the air cleaning method, which will be described later.

(driving motion)
The operation of the air cleaner 10 having the above configuration will be described. In the air purifier 10, when an operator turns on the power (not shown) of the controller 50, the controller 51 is energized and the air purifier 10 starts operating. The operator selects the operation mode from the ventilation mode, the ozone regular mode, or the ozone fumigation mode using the operation unit 52 . First, the case where ventilation mode is performed is demonstrated.

(1. Ventilation mode)
When the operator operates the operation unit 52 to set the operation mode to the ventilation mode, the operation unit 52 transmits a signal to set the operation mode to the ventilation mode to the control unit 51 . The control unit 51 receives a signal from the operation unit 52 and outputs to the blower 32 a signal for driving the blower 32 , thereby rotating the blades of the blower 32 . As a result, the air in the space S is sucked into the apparatus main body 11 through the intake port 31 . The air sucked into the apparatus main body 11 passes through the purification substance generating portion 21, and solid matter such as dust in the air is removed by the dust collection filter 22. FIG. Air from which solids have been removed is also referred to as clean air. The clean air that has passed through the dust collection filter 22 is pressure-fed by the blower 32 and discharged into the space S through the exhaust port 33 . The clean air discharged from the exhaust port 33 into the space S diffuses in the space S and is mixed with the air containing the odorous component to become the air containing the odorous component. The air circulates by natural convection in the space S. A part of the air circulating in the space S is sucked into the device main body 11 through the intake port 31 and cleaned again by the air cleaning device 10 . By repeatedly cleaning the air in the space S with the air cleaner 10, the air in the space S becomes air with a low concentration of solids such as dust.

(2. Ozone regular mode)
Next, a case where the operation mode is set to the normal ozone mode will be described. When the operator operates the operation unit 52 to set the operation mode to the ozone regular mode, the operation unit 52 sends a signal to the control unit 51 to switch the operation mode to the ozone regular mode. The control unit 51 receives a signal from the operation unit 52 and outputs a signal for driving the blower 32 to the blower 32, thereby rotating the blades of the blower 32 and generating a signal for generating low-concentration ozone. By outputting to the unit 21, the purification substance generating unit 21 is operated. When the air sucked into the apparatus main body 11 from the intake port 31 reaches the purifying substance generating portion 21, the air passes through the purifying substance generating portion 21 and is mixed with low-concentration ozone. The air containing low-concentration ozone that has passed through the purification substance generating unit 21 has solids such as dust in the air removed by the dust collection filter 22, and then is pressure-fed by the blower 32 into the space S through the exhaust port 33. and diffuses in the space S.

While the air containing ozone is diffusing in the space S from the purification substance generating part 21, the odorous components and the like contained in the air are decomposed and removed by an oxidation reaction with the ozone. The air is thereby deodorized and sterilized. Moreover, not only the odorous components contained in the air but also the odorous components adhering to the seats, walls, etc. inside the vehicle come into contact with ozone and are deodorized and sterilized by an oxidation reaction with the ozone. On the other hand, the ozone mixed in the air in the purification substance generator 21 disappears by reacting with odorous components in the air.

When ozone is generated by the purifying substance generator 21, the air deodorized and sterilized by ozone as well as the removal of solid matter is also called clean air. Clean air includes not only air completely free of odorous components but also air containing a very small amount of odorous components.

The clean air discharged from the exhaust port 33 into the space S diffuses in the space S and is mixed with the air containing the odor component, thereby becoming the air containing the odor component. Air circulates in the space S. A part of the circulating air is sucked into the device main body 11 and cleaned again by the air cleaning device 10 . By repeatedly cleaning the air in the space S with the air purifying device 10, the air in the space S has a low concentration of solids and is deodorized and sterilized.

The ozone concentration, moisture concentration and odor component concentration in the air in the space S are measured by a purification substance concentration sensor 41 , a reaction product concentration sensor 42 and an odor sensor 43 . These measurement results are sent to the control unit 51 .

Also, the presence or absence of a person in the vehicle 12 is detected by the human detection sensor 44 and the detection result is sent to the control section 51 .

The control unit 51 outputs signals for controlling the purification substance generating unit 21 and the blower 32 based on the detection results of these sensors.

(3. Ozone fumigation mode)
Next, a case where the operation mode is the ozone fumigation mode will be described. The ozone fumigation mode is the same as the regular ozone mode, except that the control unit 51 outputs a signal for generating high-concentration ozone to the purification substance generator 21 to cause the purification substance generator 21 to generate high-concentration ozone. Show action.

In the ozone fumigation mode, while odorous components are present in the air, ozone reacts with the odorous components and is consumed. Concentrated ozone is supplied. Therefore, when the odor component that reacts with ozone in the air disappears, the concentration of ozone in the air rises at a constant rate. Ozone naturally decomposes and disappears in the process in which the air is released into the space S from the purification substance generating unit 21. It is much lower than the supply speed of ozone supplied into the air from the purification substance generator 21 . Therefore, the rate of decomposition of ozone need not be considered when determining whether the ozone concentration has increased or decreased.

In addition, in the ozone fumigation mode, since high-concentration ozone that may affect the human body is used, it is desirable to start the operation after confirming that there are no people or pets in the space S with the human detection sensor 44. . In addition, even after stopping ozone generation, it is possible to inform the user whether or not to board the vehicle after the ozone concentration has fallen below a safe concentration, or to unlock the door after the ozone concentration has fallen below a safe concentration. desirable.

<Air cleaning method>
Next, an example of an air cleaning method for cleaning air using the air cleaner 10 having the above configuration will be described with reference to FIGS. 3 and 4. FIG. Here, the case where the odor component is toluene will be described.

FIG. 3 is a flowchart for explaining the air cleaning method, and FIG. 4 is a diagram showing an example of the relationship between time, water concentration, and toluene concentration. As shown in FIG. 3, the control unit 51 selects the ozone fumigation mode as the operation mode, operates the purification substance generating unit 21 and the blower 32, sucks the air in the space S, and to generate high-concentration ozone (step S11).

When high-concentration ozone is generated, solid matter is removed, and deodorized and sterilized clean air is discharged from the exhaust port 33 of the air cleaner 10 and spreads in the space S. The concentration of ozone in the air in the space S of the vehicle 12 increases, and the toluene in the space S reacts with the ozone and is decomposed to produce water and CO ₂ as reaction products, as shown in the following formula (1). occurs.
_C7H8 + _6O3- > _{7CO2 + 4H2O} (1)

Therefore, as shown in FIG. 4, after the point P1 at which high-concentration ozone is generated in the space S, toluene continues to be decomposed by ozone, and these concentrations increase. M1 is the water concentration before the generation of high-concentration ozone, that is, before toluene is decomposed, and M2 is the water concentration after most or all of the toluene has been decomposed. increasing trend. On the other hand, when the toluene concentration before generation of high-concentration ozone is M11 and the toluene concentration after most or all of the toluene is decomposed is M12, the toluene concentration tends to decrease from M11 to M12. Become.

Subsequently, as shown in FIG. 3, the concentration of water in the space S is measured by the reaction product concentration sensor 42 (concentration measurement step: step S12).

The measurement result of the moisture concentration is sent to the controller 51 .

Next, the controller 51 calculates whether or not the amount of increase in water concentration per unit time measured by the reaction product concentration sensor 42 is equal to or less than a predetermined value (step S13).

In this embodiment, the predetermined value means that the amount of increase in water concentration per unit time is, for example, 3.0% or less, and is preferably the same or substantially the same. Equivalent means a range in which an error of ±1.0% is allowed.

As a method for calculating the amount of increase in the moisture concentration per unit time, for example, the moisture concentration value at the start of the unit time ΔT is changed from the moisture concentration value at the end of the unit time ΔT, as in the following formula (I). and the value of the moisture concentration at the beginning of the unit time ΔT.
((value of moisture concentration at the end of unit time ΔT)−(value of moisture concentration at the start of unit time ΔT))/(value of moisture concentration at the start of unit time ΔT) (I)

Also, instead of the value of the moisture concentration in the unit time ΔT, the average value of the sum of the moisture concentrations in the unit time ΔT, the value of the moisture concentration in the middle of the unit time ΔT, or the like can be used.

In step S13, when the amount of increase in water concentration per unit time exceeds the predetermined value (step S13: No), the control section 51 keeps the purification substance generating section 21 in operation. Then, the controller 51 measures the water concentration in the space S with the reaction product concentration sensor 42 (step S12), and calculates whether or not the amount of increase in the water concentration per unit time is equal to or less than a predetermined value (step S13). . For a predetermined time after the operation of the purification substance generating unit 21 is started, ozone reacts with the odor component (here, toluene) to produce reaction products (water and CO ₂ ). Concentration continues to increase.

For example, as shown in FIG. 4, at time T1, high-concentration ozone is newly supplied to the air from the purification substance generator 21 . Therefore, ozone reacts with toluene to produce reaction products ( _CO2 and water) and the water concentration increases from M1 to M2. It should be noted that the length of the times T1 and T2, the degree of change in the concentration of toluene, and the degree of change in the concentration of water depend on the concentration of toluene in the space S of the vehicle.

In step S13, if the amount of increase in water concentration per unit time is equal to or less than the predetermined value (step S13: Yes), the control unit 51 stops generation of high-concentration ozone in the purification substance generation unit 21 (adjustment Process: step S14). Decomposition of toluene ends when almost all of the toluene present in the space S is decomposed after a predetermined time has elapsed since the start of ozone generation. As a result, since there is almost no substance that reacts with ozone in the space S, the concentration of the reaction products (CO ₂ and water) hardly increases and becomes below the predetermined value.

For example, as shown in FIG. 4, at time point P2, toluene that reacts with ozone is almost gone in the space S, so at time T2, the amount of increase in water concentration per unit time is below a predetermined value. , and becomes almost constant.

If the amount of increase in water concentration per unit time is less than or equal to the predetermined value even once, it can be determined that the amount of increase in water concentration per unit time is less than or equal to the predetermined value, but the present invention is not limited to this. As an index for determining that the amount of increase in moisture concentration per unit time is equal to or less than a predetermined value, for example, as shown in FIG. , three times or more), which are approximately the same, can be used. In this case, it can be determined that the amount of increase in water concentration per unit time is equal to or less than the predetermined value.

The amount of increase in water concentration per unit time is preferably constant. If the amount of increase in water concentration is constant, the control unit 51 can easily determine that the amount of increase in water concentration per unit time is equal to or less than the predetermined value. is easier to detect with certainty.

As shown in FIG. 3, when the control unit 51 determines that the amount of increase in water concentration per unit time measured by the reaction product concentration sensor 42 is equal to or less than a predetermined value, the purification substance generating unit 21 The generation of concentrated ozone is stopped (forcibly terminated) (see point P3 in FIG. 4). As a result, the amount of ozone excessively generated in the space S can be reduced.

It should be noted that since the ozone concentration in the space S only needs to be reduced, the generation of high-concentration ozone can be changed to low-concentration ozone without stopping the purification substance generation unit 21 other than stopping the purification substance generation unit 21. switch to gradually reduce the ozone concentration. Finally, the mode may be switched to the ventilation mode, or the purification substance generator 21 may be stopped to stop the generation of ozone.

When the operation of the purifying substance generator 21 stops, the supply of ozone from the purifying substance generator 21 to the space S stops, so that no ozone is newly generated in the space S, and almost no toluene remains to be decomposed. do not have. Therefore, the moisture concentration in the space S is constant. In addition, since the ozone in the space S decomposes naturally, the ozone concentration in the space S gradually decreases.

As described above, the air cleaner 10 includes the reaction product concentration sensor 42 and the controller 51 . The control unit 51 controls the purification substance generating unit 21 to control the amount of ozone generated when the amount of increase in water concentration per unit time is equal to or less than a predetermined value. When the ozone generated by the purification substance generator 21 is supplied into the space S, it decomposes odorous components (for example, toluene) present in the space S to produce water, which is one of the reaction products. When all the odorous components in the space S are decomposed by ozone, there are almost no substances that react with ozone, and no water is newly generated, so the moisture concentration in the space S does not increase. Therefore, when the amount of increase in moisture concentration per unit time is equal to or less than a predetermined value, it can be said that the odorous component present in the space S does not exist. Therefore, in the air purifying device 10, when the amount of increase in moisture concentration per unit time becomes equal to or less than a predetermined value, the controller 51 controls the purification substance generator 21 so that the air is supplied from the purification substance generator 21. control the amount of ozone generated. Therefore, the air cleaning device 10 can more accurately determine the end of deodorization in the space S, and can stop the generation of ozone at the optimum timing when the deodorization ends.

Since the air purifying device 10 can suppress unnecessary ozone generation in the purification substance generating section 21, it is possible to efficiently remove odorous components while reducing wasteful energy consumption. Therefore, according to the air purifying device 10, it is possible to reduce discomfort to the user of the next vehicle, and it is possible to reduce the time required for the deodorizing work more than necessary while suppressing wasteful power consumption. be able to.

In addition, the air purifier 10 can reduce excess ozone remaining in the space S by stopping the generation of ozone at the optimum timing, so even if the odor sensor 43 is a semiconductor sensor , the odor sensor 43 can stably measure the concentration of the odor component. For example, when the odor sensor 43 is a semiconductor type sensor, if ozone generated during deodorization exists in the space S of the vehicle, oxygen ions adsorbed to the surface of the semiconductor element increase. There is a possibility that the measurement performance of the odor component of 43 will be deteriorated. Therefore, even if odorous components remain in a space such as a vehicle or a building, the odor sensor 43 may measure the concentration of the odorous components at a low level and may not be able to accurately measure the concentration of the odorous components. As a result, the operation of the purification substance generator 21 may be stopped. In the present embodiment, it is possible to reduce excess ozone remaining in the space S. Therefore, even if the odor sensor 43 is a semiconductor type sensor, the oxygen ions that are excessively adsorbed on the surface of the semiconductor element of the odor sensor 43 are reduced. can reduce the amount of Therefore, even if a semiconductor sensor is used as the odor sensor 43, the air cleaning apparatus 10 can reduce excess adsorption of ozone on the semiconductor surface of the semiconductor element of the odor sensor 43, so that the odor sensor 43 detects odor components. It is possible to suppress the deterioration of the performance to perform. Therefore, the air purifier 10 can stably measure the concentration of the odor component with the odor sensor 43 with high accuracy.

The controller 51 of the air purifier 10 can predetermine, as a predetermined value, the amount of increase in moisture concentration per unit time calculated based on the amount of ozone generated and the volume of the space S. By comparing the measured value with a predetermined value, the controller 51 can easily determine whether or not the amount of increase in the moisture concentration in the space S per unit time has reached the predetermined value. This makes it easier for the controller 51 to make decisions for controlling the purification substance generator 21 .

In the present embodiment, it is preferable that the amount of increase in water concentration per unit time be constant. Note that constant means that the amount of increase in water concentration per unit time is almost zero. When all of the odorous components in the space S are decomposed by ozone and almost no substances that react with ozone are present, the moisture concentration in the space S does not increase. If the amount of increase in water concentration is constant, it can be determined more reliably that all the odorous components in the space S have been removed. Therefore, by stopping (forcibly stopping) the operation of the purification substance generating unit 21 at the timing when the amount of increase in the moisture concentration per unit time becomes constant, the amount of excess ozone generated in the space S can be reduced. Ozone generation can be stopped optimally. Therefore, according to the air purifier 10, it is possible to more efficiently remove odorous components while further reducing wasteful energy consumption.

The air purifying device 10 is controlled by the control unit 51 in one of three modes: a ventilation mode, an ozone regular mode, and an ozone fumigation mode. Thereby, the air cleaning device 10 can appropriately clean the air according to the concentration of the malodorous component in the space S.

The air cleaner 10 preferably has an odor sensor 43 . The air purifier 10 can detect odor components in the space S by including the odor sensor 43 .

The air cleaner 10 preferably has a human sensor 44 . The air purifying device 10 can confirm whether or not a person exists in the space S by including the human detection sensor 44 . Thereby, when the air cleaner 10 is operating in the ozone fumigation mode, the air cleaner 10 can stably perform the ozone fumigation mode in a state where no person exists in the space S.

The air cleaner 10 preferably includes a purification substance concentration sensor 41 . The air cleaner 10 can measure the ozone concentration in the space S by including the purification substance concentration sensor 41 .

As described above, the air cleaner 10 cleans the air in the space S inside the vehicle 12. As described above, the air cleaner 10 cleans the air in the space S at the optimum timing. can do. Therefore, the air purifying device 10 can be suitably used as an air purifying device for purifying the air in such spaces by installing it in, for example, the inside of a train, the inside of an airplane, the inside of a building, etc., in addition to the vehicle 12. can be done. In addition, the air purifier 10 deodorizes the kitchen of a shop, the partition space of a smoking room installed in a public facility, etc., the building space of a garbage collection site, the internal storage space of an air conditioner, a refrigerator, etc. It may be provided on a route or the like.

In this embodiment, the reaction product concentration sensor 42 provided in the space S measures the _water concentration as the concentration of the reaction _product . may As the CO ₂ concentration sensor, a known gas sensor such as a nondispersive infrared (NDIR) type sensor can be used.

In this embodiment, both a sensor for measuring the concentration of water and a sensor for measuring the concentration of CO ₂ may be provided as the reaction product concentration sensor 42 .

In this embodiment, the apparatus main body 11 having the cleaning section 20 and the circulation section 30 is installed in the space S inside the vehicle 12, but the present invention is not limited to this. For example, the device main body 11 may be provided inside the vehicle 12 but outside the space S, and the intake port 31 and the exhaust port 33 of the circulation unit 30 may open toward the space S.

In this embodiment, the purifying substance generator 21 generates ozone as a purifying substance for purifying odorous components, but any substance that can decompose odorous components contained in the air and generate reaction products may be used. For example, an oxidizing agent such as hypochlorous acid (HClO), hydrogen peroxide (H ₂ O ₂ ) may be generated.

When the purification substance generator 21 generates HClO as the purification substance, the reaction product concentration sensor 42 may be a hydrochloric acid concentration sensor capable of measuring the concentration of hydrochloric acid in the air within the space S. At this time, for example, when the odor component is expressed as RH as in the following formula (2), the odor component reacts with HClO to produce hydrochloric acid (HCl) as a reaction product. Therefore, the reaction product concentration sensor 42 can detect hydrochloric acid using a hydrochloric acid concentration sensor capable of measuring the concentration of hydrochloric acid in the air in the space S.
RH+HOCl+H ₂ O→R-OH+HCl+H ₂ O (2)

When the purification substance generator 21 generates hypochlorous acid as the purification substance, the purification substance concentration sensor 41 may be a hypochlorous acid concentration sensor capable of measuring the concentration of hypochlorous acid in the air in the space S. can. As the purification substance concentration sensor 41, for example, a measurement device provided with a fluorescent reagent that reacts with the hypochlorous acid generated by the purification substance generation unit 21 to emit light can be used. The fluorescent reagent provided in the purification substance concentration sensor 41 emits light upon contact with hypochlorous acid. The purification substance concentration sensor 41 can stably measure the presence or absence of hypochlorous acid contained in the air in the space S and the concentration of hypochlorous acid according to the presence or absence of light emission and the light emission intensity of the fluorescent reagent. As the purification substance concentration sensor 41, besides the measuring device described above, a hydrochloric acid gas sensor using a carbon nanotube is compact and highly sensitive and can be preferably used.

In this embodiment, the purification substance generator 21 and the blower 32 are incorporated together in the device main body 11, but they do not have to be incorporated together in the device main body 11. FIG.

In this embodiment, the blower 32 is provided on the upstream side of the purification substance generating section 21 in the device main body 11 in the air flow direction, but is provided on the downstream side of the purification substance generating section 21 in the air flow direction. may be provided.

In this embodiment, the cleaning unit 20 includes the dust collection filter 22, but the cleaning unit 20 does not include the dust collection filter 22 when it is not necessary to collect solid matter such as dust in the air. may

In this embodiment, the dust collection filter 22 is used to collect solid matter such as dust in the air, but it is sufficient to remove solid matter such as dust from the air. For example, an electric dust collector may be used instead of the dust collection filter 22 . An electric dust collector is a device that applies a high voltage to the air to electrify dust and the like contained in the air, and removes the dust and the like by attracting it to a dust collecting plate. By using the electric dust collector, the maintenance cycle becomes longer than when the dust collection filter 22 is used, and the frequency of maintenance can be reduced.

In the present embodiment, the control device 50 has the control unit 51 inside the vehicle 12 and outside the space S, and the operation unit 52 and the display unit 53 inside the space S, but the present invention is not limited to this. The control device 50 may be provided inside the apparatus main body 11 , or only the control section 51 may be provided inside the apparatus main body 11 . Further, the operation unit 52 and the display unit 53 of the control device 50 may be provided outside the vehicle 12 , or the control device 50 may be provided outside the vehicle 12 .

As described above, the embodiment has been described, but the above embodiment is presented as an example, and the present invention is not limited by the above embodiment. The above embodiments can be implemented in various other forms, and various combinations, omissions, replacements, changes, etc. can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and equivalents thereof.

This application claims priority based on Japanese Patent Application No. 2019-119788 filed with the Japan Patent Office on June 27, 2019, and the entire contents of Japanese Patent Application No. 2019-119788 are incorporated into this application. .

REFERENCE SIGNS LIST 10 air purifier 20 purifying unit 21 purification substance generating unit 30 circulation unit 32 blower 40 detection unit 41 purification substance concentration sensor (purification substance concentration measuring unit)
42 reaction product concentration sensor (reaction product concentration unit)
43 Odor sensor (odor measuring unit)
44 human detection sensor (human detection unit)
51 control unit S space

Claims (12)

a cleaning unit that removes odorous components contained in the air in the space;
a circulation unit that supplies the air in the space to the cleaning unit and discharges the clean air cleaned by the cleaning unit into the space;
The cleaning unit is an air cleaning device comprising a purification substance generating unit that generates a purification substance that decomposes the odorous component,
a reaction product concentration measuring unit that measures the concentration of a reaction product generated when the odorous component is decomposed by the purification substance;
a control unit for controlling the amount of the purification substance generated by controlling the purification substance generation unit when the amount of increase in the concentration of the reaction product per unit time becomes equal to or less than a predetermined value;
An air cleaning device comprising: The control unit sets the amount of increase in the concentration of the reaction product per unit time, which is calculated based on the amount of the purification substance generated in the purification substance generation unit and the volume of the space, to the predetermined value. The air cleaner according to claim 1, characterized in that: 3. The air purifier according to claim 2, wherein the amount of increase in the concentration of the reaction product per unit time is constant. The control unit
a ventilation mode for discharging the air in the space to the outside of the space;
The purification substance generating section generates the low-concentration purification substance, and the cleaning section discharges the air purified by using the low-concentration purification substance into the space together with the low-concentration purification substance. normal mode and
The purifying substance generating section generates the purifying substance at a high concentration, and the cleaning section discharges the air purified by using the high concentration purifying substance into the space together with the high concentration purifying substance. fumigation mode;
4. The air purifier according to any one of claims 1 to 3, wherein the control is performed in any one of modes. The air cleaner according to any one of claims 1 to 4, further comprising an odor detection unit that detects the odor component in the space. The air cleaner according to any one of claims 1 to 5, further comprising a human detection unit that detects the presence or absence of a person in the space. 7. The air purifier according to claim 1, further comprising a purification substance concentration measuring unit that detects the concentration of the purification substance in the air. The air purifier according to any one of claims 1 to 7, wherein the purifying substance is ozone or hypochlorous acid. The purification substance is hypochlorous acid,
8. The purification substance concentration measuring unit for measuring the concentration of the purification substance calculates the concentration of the hypochlorous acid using a fluorescent reagent that reacts with the hypochlorous acid and emits light. The air purifying device according to . The air cleaner according to any one of claims 1 to 9, wherein the reaction product is one or more of water, carbon dioxide and hydrochloric acid. An air cleaning method for generating a purification substance in a space and removing odorous components contained in the air in the space with the purification substance,
a concentration measuring step of measuring the concentration of a reaction product generated when the odor component is decomposed by the purification substance;
an adjusting step of adjusting the amount of the purification substance generated when the amount of increase in the concentration of the reaction product per unit time is equal to or less than a predetermined value;
A method for cleaning air, comprising: 12. The air cleaning method according to claim 11, wherein the reaction product is any one or more of water, carbon dioxide and hydrochloric acid.

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