JP2021188819A - Heat exchange type ventilation device with air purification function - Google Patents

Abstract

To provide a heat exchange type ventilation device with air purification function capable of suppressing increase in humidity according to the exhaust of hypochlorous acid.SOLUTION: A heat exchange type ventilation device 50 with air purification function includes: a heat exchange type ventilation device 10 which exchanges heat between an exhaust flow 2 circulating in an exhaust air passage 4 and a supply air flow 3 circulating in a supply air passage 5; an air purification device 30 constituted so that the supply air flow 3 is introduced from the supply air passage 5, and for adding the component for performing air purification with respect to the introduced supply air flow 3; and an air passage switching part (first switching damper 20a to sixth switching damper 20f) installed at the supply air passage 5. The air passage switching part can switch between: a first state where the supply air flow 3 after heat exchange is introduced from the supply air passage 5, and after it has circulated the air purification device 30, it is led-out to the supply air passage 5 on the subsequent stage of the heat exchange type ventilation device 10; and a second state where the supply air flow 3 before heat exchange is introduced from the supply air passage 5, and after it has circulated the air purification device 30, it is led-out to the supply air passage 5 on the front stage of the heat exchange type ventilation device 10.SELECTED DRAWING: Figure 3

Description

The present invention relates to a heat exchange type ventilation device with an air purification function that disinfects a target space represented indoors while performing heat exchange ventilation.

Conventionally, as a heat exchange type ventilator with this kind of air purification function, air conditioning that disinfects the space by contacting the air supplied indoors with the gas-liquid contact member containing hypochlorous acid and releasing it. The system is known (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2009-133521

However, in the conventional air conditioning system, in order to release hypochlorous acid, a humidifier or a two-fluid nozzle is used to release hypochlorous acid together with moisture, so that the target space where hypochlorous acid is released is released. Humidity inside increased, and comfort was likely to be compromised, especially in summer when relative humidity was high.

Therefore, the present invention solves the above-mentioned conventional problems, and an object of the present invention is to provide a heat exchange type ventilation device with an air purification function capable of suppressing an increase in humidity due to the release of hypochlorous acid. ..

In order to achieve this object, the heat exchange type ventilator with an air purification function according to the present invention has an exhaust flow flowing through an exhaust air passage for discharging indoor air to the outside and outdoor air to be discharged indoors. A heat exchange type ventilator that exchanges heat with the air supply air flowing through the air supply air passage for supplying air to the air supply air passage, and the air supply air supply that is configured to be introduced from the air supply air passage and introduced. It also includes an air purification device that adds a component that purifies the air, and an air passage switching unit installed in the air supply air passage. Then, in the air passage switching unit, the air supply air after heat exchange is introduced from the air supply air passage, and after the air purification device is circulated, the first state and the supply air are led out to the air supply air passage in the subsequent stage of the heat exchange type ventilation device. The air supply air before heat exchange is introduced from the air passage, and after the air purification device is circulated, the second state of leading to the air supply air passage in the previous stage of the heat exchange type ventilation device can be switched. This will achieve the intended purpose.

According to the present invention, it is possible to provide an air purification device capable of suppressing an increase in humidity due to the release of hypochlorous acid.

FIG. 1 is a schematic view showing an installation state of a heat exchange type ventilation device according to a premise example of the present invention in a house. FIG. 2 is a schematic diagram showing the configuration of the heat exchange type ventilation device according to the premise example of the present invention. FIG. 3 is a schematic view showing the configuration of a heat exchange type ventilation device with an air purification function according to the first embodiment of the present invention. FIG. 4 is a schematic diagram showing the configuration of an air purification device in a heat exchange type ventilation device with an air purification function. FIG. 5 is a schematic view showing the flow path of the air supply when the air passage switching portion in the heat exchange type ventilator with an air purification function is in the first state. FIG. 6 is a schematic view showing the flow path of the air supply when the air passage switching portion in the heat exchange type ventilator with an air purification function is in the second state. FIG. 7 is a schematic block diagram showing a configuration of a control unit in a heat exchange type ventilator with an air purification function. FIG. 8 is a flowchart showing a process performed by the control unit in the heat exchange type ventilator with an air purification function.

The heat exchange type ventilator with an air purification function according to the present invention has an exhaust flow flowing through an exhaust air passage for exhausting indoor air to the outside and an air supply air passage for supplying outdoor air indoors. A heat exchange type ventilator that exchanges heat with the circulating air supply, and a component that purifies the air is added to the introduced air supply, which is configured so that the air supply is introduced from the air supply air passage. It is equipped with an air purification device and an air passage switching unit installed in the air supply air passage. Then, in the air passage switching unit, the air supply air after heat exchange is introduced from the air supply air passage, and after the air purification device is circulated, the first state and the supply air are led out to the air supply air passage in the subsequent stage of the heat exchange type ventilation device. The air supply air before heat exchange is introduced from the air passage, and after the air purification device is circulated, the second state of leading to the air supply air passage in the previous stage of the heat exchange type ventilation device can be switched.

According to this configuration, by switching to the first state in winter and operating, the component that purifies the air while humidifying the air supply after heat exchange (the relative humidity is lower than the indoor relative humidity). Since the purification component) can be supplied, the relative humidity (absolute humidity) of the indoor air can be increased. On the other hand, by switching to the second state and operating in the summer, heat exchange type ventilation is supplied while supplying a component that purifies the air supply before heat exchange (the relative humidity is higher than the indoor relative humidity). Since heat is exchanged by the device, the absolute humidity of the air supply after heat exchange is lower than when the component that purifies the air is supplied to the air supply in the first state, and the relative humidity (absolute humidity) of the indoor air is reduced. ) Can be suppressed.

Further, the heat exchange type ventilator with an air purification function according to the present invention has a switching operation between a temperature detection unit that detects the temperature of indoor air, a humidity detection unit that detects the humidity of indoor air, and an air passage switching unit. Further includes a control unit for controlling the temperature. Then, the control unit switches the air passage switching unit to the first state when the relative humidity of the indoor air is equal to or less than the reference value based on the temperature information from the temperature detection unit and the humidity information from the humidity detection unit. , It is preferable to switch the air passage switching unit to the second state when the relative humidity of the indoor air exceeds the reference value. By doing so, the control unit can reliably switch between the first state and the second state of the air passage switching unit according to the indoor environment.

Further, in the heat exchange type ventilator with an air purification function according to the present invention, the air purification device centrifuges the water containing the component for purifying the air, so that the air is brought into the apparatus with respect to the air supply. It is preferable to add a component for purifying. By doing so, it is possible to control the particle size or amount of water to be crushed by changing the rotation speed at the time of centrifugal crushing, and by extension, the amount of the component that purifies the air added to the air supply. You can control it.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the accompanying drawings. The following embodiments are examples that embody the present invention, and do not limit the technical scope of the present invention. Further, throughout the drawings, the same parts are designated by the same reference numerals and explanations are omitted. Further, in order to avoid duplication of details of each part not directly related to the present invention, the description of each drawing is omitted.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Premise example)
First, a heat exchange type ventilator which is a premise example of the embodiment of the present invention will be described with reference to FIGS. 1 and 2. FIG. 1 is a schematic view showing an installation state of a heat exchange type ventilation device according to a premise example of the present invention in a house. FIG. 2 is a schematic diagram showing the configuration of the heat exchange type ventilation device according to the premise example of the present invention.

In FIG. 1, a heat exchange type ventilation device 10 is installed indoors (behind the ceiling, etc.) of the house 1. The heat exchange type ventilator 10 is a device (type 2 ventilator) that ventilates while exchanging heat between indoor air and outdoor air.

As shown in FIG. 1, the exhaust flow 2 is discharged to the outside from an indoor space 8 such as a living room through an indoor exhaust port 6a, a heat exchange type ventilation device 10, and an outdoor exhaust port 6b as shown by a black arrow. The exhaust flow 2 is a flow of air discharged from indoors to outdoors. Further, the air supply airflow 3 is taken into the indoor space 8 from the outside through the outdoor air supply port 7b, the heat exchange type ventilation device 10, and the indoor air supply port 7a as shown by the white arrow. The air supply 3 is a flow of air taken in from the outside to the inside. For example, in winter in Japan, the exhaust flow 2 is 20 ° C to 25 ° C, while the air flow 3 may reach below freezing. The heat exchange type ventilation device 10 ventilates and transfers the heat of the exhaust flow 2 to the supply airflow 3 at the time of this ventilation to suppress the release of unnecessary heat.

As shown in FIG. 2, the heat exchange type ventilation device 10 includes a main body case 11, a heat exchange element 12, an exhaust fan 13, an inside air port 14, an exhaust port 15, an air supply fan 16, an outside air port 17, an air supply port 18, and an exhaust. It is provided with an air passage 4 and an air supply air passage 5. The main body case 11 is an outer frame of the heat exchange type ventilator 10. An inside air port 14, an exhaust port 15, an outside air port 17, and an air supply port 18 are formed on the outer periphery of the main body case 11. The inside air port 14 is a suction port for sucking the exhaust flow 2 into the heat exchange type ventilation device 10, and communicates with the indoor exhaust port 6a (see FIG. 1) via a duct or the like. The exhaust port 15 is a discharge port for discharging the exhaust flow 2 from the heat exchange type ventilation device 10 to the outside, and communicates with the outdoor exhaust port 6b (see FIG. 1) via a duct or the like. The outside air port 17 is a suction port for sucking the air supply air flow 3 into the heat exchange type ventilation device 10, and communicates with the outdoor air supply port 7b (see FIG. 1) via a duct or the like. The air supply port 18 is a discharge port for discharging the air supply air 3 indoors from the heat exchange type ventilation device 10, and communicates with the indoor air supply port 7a via a duct or the like.

A heat exchange element 12, an exhaust fan 13, and an air supply fan 16 are mounted inside the main body case 11. Further, an exhaust air passage 4 and an air supply air passage 5 are configured inside the main body case 11. The heat exchange element 12 is a member for performing heat exchange (sensible heat and latent heat) between the exhaust flow 2 flowing through the exhaust air passage 4 and the supply airflow 3 flowing through the supply air passage 5. The exhaust fan 13 is installed in the vicinity of the exhaust port 15 and is a blower for sucking the exhaust flow 2 from the inside air port 14 and discharging it from the exhaust port 15. The air supply fan 16 is installed in the vicinity of the air supply port 18, and is a blower for sucking the air supply airflow 3 from the outside air port 17 and discharging the air supply port 18 from the air supply port 18. The exhaust air passage 4 is an air passage that communicates the inside air port 14 and the exhaust port 15. The air supply air passage 5 is an air passage that communicates the outside air port 17 and the air supply port 18. The exhaust flow 2 sucked by the exhaust fan 13 is discharged to the outside from the exhaust port 15 via the heat exchange element 12 in the exhaust air passage 4 and the exhaust fan 13. Further, the air supply airflow 3 sucked by the air supply fan 16 is supplied indoors from the air supply port 18 via the heat exchange element 12 and the air supply fan 16 in the air supply air passage 5.

When heat exchange ventilation is performed, the heat exchange type ventilation device 10 operates the exhaust fan 13 and the air supply fan 16 of the heat exchange element 12 with the exhaust flow 2 flowing through the exhaust air passage 4 in the heat exchange element 12. , Heat exchange is performed with the air supply airflow 3 flowing through the air supply air passage 5. As a result, the heat exchange type ventilator 10 transfers the heat of the exhaust flow 2 released to the outside to the air supply air 3 which takes in indoors when ventilating, suppresses the release of unnecessary heat, and heats indoors. To collect. As a result, in winter, when ventilating, the indoor temperature drop can be suppressed by the air having a low outdoor temperature. On the other hand, in the summer, when ventilating, the indoor temperature rise can be suppressed by the air having a high outdoor temperature.

(Embodiment 1)
Next, the heat exchange type ventilation device 50 with an air purification function according to the first embodiment will be described with reference to FIGS. 3 and 4. FIG. 3 is a schematic view showing the configuration of the heat exchange type ventilation device 50 with an air purification function according to the first embodiment of the present invention. FIG. 4 is a schematic diagram showing the configuration of the air purification device 30 in the heat exchange type ventilation device 50 with an air purification function. In the following description, the airflow (exhaust flow 2, supply airflow 3) or air passage (exhaust air passage 4, supply air air passage 5) after heat exchange passes through the heat exchange element 12 in the heat exchange type ventilation device 10. The airflow or air passage before heat exchange indicates the airflow or air passage after the heat exchange, and the airflow or air passage before heat exchange indicates the airflow or air passage before passing through the heat exchange element 12.

As shown in FIG. 3, the heat exchange type ventilation device 50 with an air purification function according to the first embodiment imparts an air purification function to the air supply air passage 5 of the heat exchange type ventilation device 10 according to the premise example. It has a configuration in which an air purification device 30 is connected via a branch air supply air passage (first branch air supply air passage 5a to sixth branch air supply air passage 5f). The branched air supply air passage is a component that purifies the air supply air flow 3 after heat exchange by switching the switching dampers (first switching damper 20a to sixth switching damper 20f) installed in the branched air supply air passage. Between the heat exchange type ventilation device 10 and the air purification device 30 so as to be in the first state in which the heat exchange is added or in the second state in which the component that purifies the air is added to the supply airflow 3 before the heat exchange. The distribution channels of the air supply air 3 are connected.

In the first state, the air supply air force 3 after heat exchange is introduced from the air supply air passage 5, a component for purifying air is added to the introduced air supply air flow 3, and then a component for purifying air is added. The flow path of the air supply 3 is connected so that the air supply 3 is led out to the air supply air passage 5 after the heat exchange of the heat exchange type ventilation device 10 (the air supply air passage 5 in the subsequent stage of the heat exchange type ventilation device 10). It is in a state. On the other hand, in the second state, the air supply airflow 3 after heat exchange is introduced from the air supply air passage 5, a component for purifying air is added to the introduced air supply airflow 3, and then a component for purifying air is added. The flow path of the air supply air 3 is provided so that the supplied air supply air 3 is led out to the air supply air passage 5 after heat exchange of the heat exchange type ventilation device 10 (the air supply air passage 5 in the subsequent stage of the heat exchange type ventilation device 10). It is in a connected state. The details of the branched air supply air passage will be described later.

The air purification device 30 is a device that includes a finely divided purification component (a component that purifies the air) in the air flowing through the device, and sucks in the airflow 3 flowing through the branched air supply air passage 31. After adding a finely divided purification component to the sucked air flow 3 from the air outlet 32, the air is discharged from the outlet 32 to the branched air supply air passage. Here, as the purifying component, for example, hypochlorous acid having bactericidal or deodorant properties is used. As a result, the hypochlorite water is included in the air flow 3 and supplied indoors, so that indoor sterilization or deodorization can be performed.

Specifically, as shown in FIG. 4, the air purification device 30 includes an intake 31a, an discharge port 32a, a liquid miniaturization chamber 33, a rotary plate 34, a collision wall 35, a rotary motor 36, a rotary shaft 37, and a pumping pipe. It includes 38, a purification component supply unit 39, a blower fan 40, and a control unit 41.

The intake port 31a is an opening for taking in the air flow 3 flowing through the branched air supply air passage into the apparatus, and is configured to communicate with the suction port 31 (see FIG. 3) via a member (not shown).

The discharge port 32a is an opening for discharging the air flow 3 to which the purification component is added from the inside of the device, and is configured to communicate with the outlet 32 (see FIG. 3) via a member (not shown).

The liquid miniaturization chamber 33 constitutes the housing of the entire device, and constitutes a space for adding a purification component to the air flow 3 taken in from the intake port 31a. Further, the bottom of the liquid miniaturization chamber 33 is shaped like a vessel so that water 42 containing a purification component can be stored. A blower fan 40 for adjusting the flow rate of the airflow 3 flowing in the apparatus is provided above the liquid miniaturization chamber 33.

The liquid miniaturization chamber 33 is provided with a cylindrical collision wall 35 having an opening above and below. The collision wall 35 is fixed in the liquid miniaturization chamber 33. Further, the liquid miniaturization chamber 33 is provided with a cylindrical pumping pipe 38 for pumping (pumping) water 42 containing a purifying component while rotating inside surrounded by a collision wall 35. The pumping pipe 38 has an inverted conical hollow structure, is provided with a circular pumping port 38a below in the vertical direction, and has a rotation axis above the vertical direction of the pumping pipe 38 and centered on the top surface of the inverted cone. 37 is fixed. By connecting the rotary shaft 37 to the rotary motor 36 provided in the liquid miniaturization chamber 33, the rotational motion of the rotary motor 36 is conducted to the pumping pipe 38 through the rotary shaft 37, and the pumping pipe 38 rotates. The rotary motor 36 is configured to execute a rotary motion based on a control signal from the control unit 41.

The pumping pipe 38 is provided with a rotating plate 34 formed so as to project outward from the outer surface of the pumping pipe 38 on the top surface side of the inverted cone. Since the rotary plate 34 rotates together with the pumping pipe 38, a horizontal disk shape coaxial with the rotary shaft 37 is preferable.

The water 42 containing the purification component is supplied to the liquid miniaturization chamber 33 by the purification component supply unit 39 installed outside the liquid miniaturization chamber 33. The purification component supply unit 39 has a generation means for generating water 42 containing the purification component, and the purification component is supplied from the supply port 39a to the liquid miniaturization chamber 33 based on the control signal from the control unit 41. Supply water 42 containing.

Then, in the liquid miniaturization chamber 33, the pumping pipe 38 is rotated by the rotary motor 36, so that the water stored in the bottom (water 42 containing the purification component) is pumped by the pumping pipe 38, and the pumped water is pumped. It is scattered and radiated in the centrifugal direction along the rotating plate 34. When the scattered / radiated water collides with the collision wall 35, the water is crushed and made finer. Then, the miniaturized water is taken into the air flow 3 flowing in the liquid miniaturization chamber 33 and discharged from the liquid miniaturization chamber 33.

The blower fan 40 circulates the air flow 3 inside the liquid miniaturization chamber 33 by blowing air. Examples of the blower fan 40 include a cross flow fan and a blower fan. The blower fan 40 is configured to execute the blower operation based on the control signal from the control unit 41.

The control unit 41 controls the operation operation of the air purification device 30 (the operation operation of the rotary motor 36, the purification component supply unit 39, and the blower fan 40) to purify the air flow 3 flowing through the liquid miniaturization chamber 33. The application operation of (water 42 containing a purifying component) is controlled. Details will be described later.

Next, with reference to FIGS. 3, 5, and 6, a branched air supply air passage connecting the heat exchange type ventilation device 10 and the air purification device 30 will be described. FIG. 5 is a schematic view showing a distribution path of the air flow 3 when the air passage switching portion in the heat exchange type ventilation device 50 with an air purification function is in the first state. FIG. 6 is a schematic view showing the distribution path of the air supply air 3 when the air passage switching portion in the heat exchange type ventilation device 50 with an air purification function is in the second state.

As shown in FIG. 3, the branched air supply air passage is configured by connecting the first branched air supply air passage 5a to the sixth branch air supply air passage 5f. Then, in the branched air supply air passage, the switching dampers (first switching damper 20a to sixth switching damper 20f) arranged at each branch point of the air passage are set to a predetermined switching state, so that the air supply airflow 3 after heat exchange is performed. The first state (see FIG. 5) in which a component for purifying air is added to the air supply airflow 3 before heat exchange, or the second state (see FIG. 6) in which a component for purifying air is added to the air supply 3 before heat exchange. .. Here, the switching damper corresponds to the "air passage switching portion" of the claim.

As the switching dampers, the first switching damper 20a and the second switching damper 20b are installed in the air supply air passage 5 before the heat exchange, and the third switching damper 20c and the fourth switching damper 20d are installed in the air supply air passage 5 after the heat exchange. is set up. Further, a fifth switching damper 20e and a sixth switching damper 20f are installed in the branched air supply air passage.

The first switching damper 20a is a state in which the supply airflow 3 introduced from the indoor air supply port 7a and flowing through the air supply air passage 5 flows to the second switching damper 20b side (heat exchange type ventilation device 10 side), and the indoor air supply. It is a damper that switches between a state in which the airflow 3 introduced from the port 7a and flowing through the air supply air passage 5 flows to the first branch air supply air passage 5a on the fifth switching damper 20e side.

The second switching damper 20b is a state in which the air supply 3 flowing through the first switching damper 20a flows to the heat exchange type ventilation device 10 side, and the heat exchange type ventilation device allows the air supply air 3 flowing through the fourth branch air supply air passage 5d to flow. It is a damper that switches between the state of flowing to the 10 side.

The third switching damper 20c has a state in which the supply airflow 3 after heat exchange through the heat exchange element 12 flows to the fourth switching damper 20d side (indoor air supply port 7a side) and the heat exchange through which the heat exchange element 12 has flowed. This is a damper that switches between a state in which the subsequent air supply air flow 3 is allowed to flow through the fifth branch air supply air passage 5e (fifth switching damper 20e side).

The fourth switching damper 20d has a state in which the airflow 3 flowing through the third switching damper 20c flows to the indoor air supply port 7a side, and the airflow 3 flowing through the sixth branch air supply air passage 5f is sent to the indoor air supply port 7a side. It is a damper that switches between the state of flowing to and the state of flowing to.

The fifth switching damper 20e circulates a state in which the airflow 3 flowing through the first branch air supply air passage 5a flows through the second branch air supply air passage 5b (air purification device 30 side) and the fifth branch air supply air passage 5e. It is a damper that switches between a state in which the air supply air flow 3 flows through the second branch air supply air passage 5b (air purification device 30 side).

The sixth switching damper 20f is a state in which the supply airflow 3 discharged from the air purification device 30 and flowing through the third branch air supply air passage 5c flows to the fourth branch air supply air passage 5d (fifth switching damper 20e side) and air. It is a damper that switches between a state in which a supply airflow 3 discharged from the purification device 30 and flowing through the third branch air supply air passage 5c flows to the sixth branch air supply air passage 5f (fourth switching damper 20d side).

As shown in FIG. 5, the branched air supply air passages configured in the first state include the third switching air passage 20c, the fifth branch air supply air passage 5e, the fifth switching air passage 20e, the second branch air supply air passage 5b, and air purification. It is composed of an apparatus 30, a third branch air supply air passage 5c, a sixth switching damper 20f, a sixth branch air supply air passage 5f, and a fourth switching damper 20d. The air flow 3 introduced from the indoor air supply port 7a and flowing through the air supply air passage 5 is the first switching damper 20a, the second switching damper 20b, the heat exchange element 12, and the branch air supply air passage in the first state. It is distributed in order and air is supplied from the indoor air supply port 7a.

On the other hand, as shown in FIG. 6, the branched air supply air passages configured in the second state include the first switching air passage 20a, the first branch air supply air passage 5a, the fifth switching air passage 20e, and the second branch air supply air passage 5b. It is composed of an air purification device 30, a third branch air supply air passage 5c, a sixth switching damper 20f, a fourth branch air supply air passage 5d, and a second switching damper 20b. The air flow 3 introduced from the indoor air supply port 7a and flowing through the air supply air passage 5 is the branch air supply air passage in the second state, the heat exchange element 12, the third switching damper 20c, and the fourth switching damper 20d. It is distributed in order and air is supplied from the indoor air supply port 7a.

Of the switching dampers, by setting the first switching damper 20a to the fourth switching damper 20d in a predetermined switching state, the air supply air 3 after heat exchange is supplied indoors without flowing through the air purification device 30. It is also possible. That is, when it is not necessary to add a purification component to the air supply air 3, the air supply air 3 heat-exchanged by the heat exchange type ventilation device 10 is supplied indoors as it is. As a result, the increase in pressure loss caused by the air purification device 30 is suppressed, and the heat exchange type ventilation device 50 with an air purification function can be operated with energy saving throughout the year.

As described above, the heat exchange type ventilator 50 with an air purification function switches the flow of the supply airflow 3 between the first state and the second state, so that the supply airflow 3 after heat exchange or the airflow before heat exchange is exchanged. It is configured to contain an air purifying component with respect to 3 so that air is supplied indoors.

Next, the control unit 41 of the air purification device 30 will be described with reference to FIG. 7. FIG. 7 is a schematic block diagram showing the configuration of the control unit 41 in the heat exchange type ventilation device 50 with an air purification function.

As shown in FIG. 7, the control unit 41 includes an input unit 41a, a storage unit 41b, a timing unit 41c, a processing unit 41d, and an output unit 41e.

The input unit 41a relates to the first information regarding the operation start instruction or the operation stop instruction from the operation panel 43, the second information regarding the temperature of the indoor air from the temperature detection unit 26a, and the humidity of the indoor air from the humidity detection unit 26b. Accepts third information. The input unit 41a outputs the received first information to the third information to the processing unit 41d.

Here, the operation panel 43 is a terminal for the user to input user input information regarding the air purification device 30 (for example, presence / absence of addition of purification component, amount of addition of purification component, amount of air blown, etc.), and is a terminal wirelessly or by wire. It is communicably connected to the control unit 41. The first information also includes user input information. Further, the temperature detection unit 26a is a sensor provided in the heat exchange type ventilation device 10 and senses the temperature of the indoor air RA (exhaust flow 2) taken in from the indoor exhaust port 6a. Further, the humidity detection unit 26b is a sensor provided in the heat exchange type ventilation device 10 and senses the humidity of the indoor air RA taken in from the indoor exhaust port 6a. The temperature detection unit 26a and the humidity detection unit 26b may be installed in an indoor target space. Further, the temperature detection unit 26a and the humidity detection unit 26b may be used as one temperature / humidity sensor.

The storage unit 41b is related to the fourth information regarding the addition processing setting in the application operation of the purification component (water 42 containing the purification component) to the supply airflow 3 flowing through the liquid miniaturization chamber 33, and the setting information corresponding to the user input information. Memorize the five information. The storage unit 41b outputs the stored fourth information and the fifth information to the processing unit 41d. It should be noted that the application processing setting in the purification component application operation can be said to be the humidification setting in the humidification operation of the air purification device 30.

The timekeeping unit 41c outputs the sixth information regarding the current time to the processing unit 41d.

The processing unit 41d receives the first information to the third information from the input unit 41a, the fourth information and the fifth information from the storage unit 41b, and the sixth information from the timekeeping unit 41c. The processing unit 41d uses the received first information to the sixth information to specify control information related to the grant operation based on the grant processing setting. The processing unit 41d outputs the specified control information to the output unit 41e.

The output unit 41e receives the control information from the processing unit 41d. The output unit 41e is electrically connected to a switching damper (first switching damper 20a to sixth switching damper 20f), a rotary motor 36, a purification component supply unit 39, and a blower fan 40. Then, the output unit 41e performs a switching operation of the switching damper (switching operation to the first state or the second state) and an operation of applying a purification component in the liquid miniaturization chamber 33 (rotary motor) based on the received control information. A signal (control signal) for controlling the rotation operation of 36, the ventilation operation of the blower fan 40) and the supply operation of the purification component in the purification component supply unit 39 is output.

Then, the switching damper receives the signal from the output unit 41e and executes the control of the switching damper based on the received signal. Further, the rotary motor 36, the blower fan 40, and the purification component supply unit 39 each receive signals from the output unit 41e and execute their respective controls based on the received signals.

As described above, the control unit 41 controls the operation of applying the purifying component (water 42 containing the purifying component) to the supply airflow 3 flowing through the liquid miniaturization chamber 33, respectively.

Next, with reference to FIG. 8, a processing procedure in the operation of applying the purifying component by the air purifying device 30 will be described. FIG. 8 is a flowchart showing a process performed by the control unit 41 in the heat exchange type ventilation device 50 with an air purification function.

When a control signal relating to the start of the operation of applying the purification component of the air purification device 30 is input to the control unit 41, first, as shown in FIG. 8, the control unit 41 is first subjected to the temperature detection unit 26a and the humidity detection unit 26b. The temperature / humidity information (second information, third information) of the indoor air RA is acquired (step S01). Then, the control unit 41 determines whether or not the relative humidity calculated based on the temperature / humidity information of the indoor air RA is equal to or less than a predetermined reference value H (step S02). Here, for example, 50% is set as the reference value H.

As a result, when the relative humidity of the indoor air RA is equal to or less than the reference value H (Yes in step S02), the control unit 41 adds a component for purifying the air to the supply airflow 3 after heat exchange. The operation in one state is carried out (step S03a). Specifically, the control unit 41 switches the communication state of the branch air supply air passage by the switching damper, and executes the operation of applying the purification component (rotational operation of the rotary motor 36, ventilation operation of the blower fan 40) in the first state. .. As a result, in the heat exchange type ventilation device 50 with an air purification function, after heat exchange ventilation is performed by the heat exchange type ventilation device 10 with respect to the air supply air 3 taken in from the outside, the purification component (air) by the air purification device 30 is performed. Since the purifying component) is added, the air supply air 3 is humidified and supplied indoors.

On the other hand, when the relative humidity of the indoor air RA exceeds the reference value H (No in step S02), the control unit 41 adds a component for purifying the air to the supply airflow 3 after heat exchange. The operation in two states is carried out (step S03b). Specifically, the control unit 41 switches the communication state of the branch air supply air passage by the switching damper, and executes the operation of applying the purification component (rotational operation of the rotary motor 36, ventilation operation of the blower fan 40) in the second state. .. As a result, in the heat exchange type ventilator 50 with an air purification function, after the purification component (component that purifies the air) is added to the air supply air 3 taken in from the outside by the air purification device 30, the heat exchange type is performed. Since the heat exchange ventilation is performed by the ventilation device 10, the air supply air 3 humidified by the air purification device 30 is dehumidified and supplied indoors at the time of the heat exchange ventilation by the heat exchange type ventilation device 10.

Then, it is determined whether or not the time measured with the operation execution time in step S03a or step S03b as the start time has elapsed the predetermined time T (step S04). As a result, when the predetermined time T has not elapsed (No in step S04), the control unit 41 continues the operation operation in each state as it is (returns to step S04). On the other hand, when the predetermined time T has elapsed (Yes in step S04), the control unit 41 proceeds to the next step (step S05) while continuing the operation operation in each state. Here, the predetermined time T is an interval time for feedback control of addition of the purifying component, and is set to, for example, 5 minutes.

Next, the control unit 41 determines whether or not a control signal for stopping the operation of the process of applying the purification component of the air purification device 30 is input (step S05). As a result, when the control signal regarding the stop of the operation of the purification component addition process is not input (No in step S05), the control unit 41 returns to step S01 and acquires the temperature / humidity information of the indoor air RA. , Repeat each step described above. On the other hand, when a control signal for stopping the operation of the purification component addition process is input (Yes in step S05), the control unit 41 is in charge of each device (rotary motor 36, blower fan 40, and purification component supply unit 39). ) Is stopped to stop the process of applying the purifying component. As a result, the air purification device 30 is in a state of waiting for an operation start instruction from the operation panel 43.

As described above, in the heat exchange type ventilation device 50 with an air purification function, each process in the additional operation of the purification component by the air purification device 30 is executed.

As described above, according to the heat exchange type ventilation device 50 with an air purification function according to the first embodiment, the following effects can be enjoyed.

(1) In the heat exchange type ventilation device 50 with an air purification function, a switching damper (first switching) provided at each branch point of the branch air supply air passage (first branch air supply air passage 5a to sixth branch air supply air passage 5f). The air supply air passage 3 after heat exchange is introduced from the air supply air passage 5 by the damper 20a to the sixth switching damper 20f), and after the air purification device 30 is circulated, the air supply air passage 5 in the subsequent stage of the heat exchange type ventilation device 10 is introduced. The first state to be derived and the second state to be derived to the air supply air passage 5 in the previous stage of the heat exchange type ventilation device 10 after the air supply airflow 3 before heat exchange is introduced from the air supply air passage 5 and circulated through the air purification device 30. The state and the state can be switched.

As a result, by switching to the first state in winter and operating, a component (purification component) that purifies the air while humidifying the supply airflow 3 after heat exchange (the relative humidity is lower than the indoor relative humidity). ) Can be supplied, so that the relative humidity (absolute humidity) of the indoor air RA can be increased. On the other hand, by switching to the second state in the summer and operating, the heat exchange type while supplying the component that purifies the air to the supply airflow 3 before heat exchange (which has a higher relative humidity than the indoor relative humidity). Since the heat is exchanged by the ventilation device 10, the absolute humidity of the air supply air 3 after heat exchange is lower than that in the case of supplying the component that purifies the air to the air supply air 3 in the first state, and the indoor air RA It is possible to suppress an increase in relative humidity (absolute humidity).

(2) In the heat exchange type ventilation device 50 with an air purification function, the operating state is automatically determined based on the humidity state of the indoor air RA every predetermined time T, and the purification component after passing through the air purification device 30 is determined. The provided air can be introduced into the front stage or the rear stage of the heat exchange type ventilation device 10. As a result, in winter, when it is easy to dry, by operating in the first state, it is possible to add humidity and purification components to the airflow 3 after heat exchange, making the indoor humidity comfortable. At the same time, it can be purified. On the other hand, in the summer when the humidity tends to be relatively high, a part of the water in the airflow 3 can be removed by exchanging heat with the airflow 3 after the purification component is applied, so that the purification component can be removed. It is possible to remove the water that is applied at the same time as the application of.

(3) In the heat exchange type ventilation device 50 with an air purification function, the control unit 41 uses the temperature information (second information) from the temperature detection unit 26a and the humidity information (third information) from the humidity detection unit 26b. Based on this, the switching damper is switched to the first state when the relative humidity of the indoor air RA is equal to or less than the reference value H, and the switching damper is switched to the second state when the relative humidity of the indoor air RA exceeds the reference value H. did. As a result, the control unit can reliably switch between the first state and the second state of the switching damper according to the indoor environment.

(4) In the heat exchange type ventilator 50 with an air purification function, the control unit 41 switches between the operation in the first state and the operation in the second state based on the temperature / humidity information of the indoor air RA. As a result, the humidity (40% to 60%) of the comfortable indoor air RA can be maintained without the user switching the operation.

(5) In the heat exchange type ventilation device with an air purification function, the air purification device 30 is introduced into the device by centrifugally crushing water containing a component for purifying air (water 42 containing a purification component). A component for purifying air was added to the air flow 3. As a result, the particle size or amount of water to be crushed can be controlled by changing the rotation speed at the time of centrifugal crushing, and by extension, the amount of the component for purifying air added to the supply airflow 3 can be controlled. Can be done.

Although the present invention has been described above based on the embodiments, the present invention is not limited to the above embodiments, and various improvements and modifications can be made without departing from the spirit of the present invention. It is easy to guess. For example, the numerical values given in the above embodiment are examples, and it is naturally possible to adopt other numerical values.

In the heat exchange type ventilator 50 with an air purification function according to the first embodiment, in the first state, the total air volume of the supply airflow 3 flowing through the air supply air passage 5 after heat exchange is branched and supplied by the third switching damper 20c. The supply airflow 3 that flows into the air passage and flows through the branch supply air passage is configured to return to the supply air passage 5 after heat exchange as it is by the fourth switching damper 20d, but the present invention is not limited to this. For example, a part of the air supply air 3 flowing through the air supply air passage 5 after heat exchange flows into the branch air supply air passage by the third switching damper 20c, and a part of the air supply air flow 3 circulating through the branch air supply air passage is switched to the fourth. The damper 20d may be configured to join the air supply airflow 3 flowing through the air supply air passage 5 after heat exchange. By doing so, in the first state, it is possible to control the amount of the component that purifies the air added to the air supply air 3 supplied indoors by the air volume of the air supply airflow 3 branched by the switching damper. ..

Further, in the heat exchange type ventilator 50 with an air purification function according to the first embodiment, in the second state, the total air volume of the air supply air 3 flowing through the air supply air passage 5 before the heat exchange is adjusted by the first switching damper 20a. The supply airflow 3 that flows into the branch air supply air passage and flows through the branch air supply air passage is configured to return to the air supply air passage 5 before heat exchange as it is by the second switching damper 20b, but the present invention is not limited to this. For example, a part of the supply airflow 3 flowing through the supply air passage 5 before heat exchange flows into the branch supply air passage by the first switching damper 20a, and a part of the supply airflow 3 circulating through the branch air supply air passage is switched to the second. The damper 20b may be configured to join the air supply airflow 3 flowing through the air supply air passage 5 before heat exchange. By doing so, in the second state, the amount of the component that purifies the air added to the air supply air 3 supplied indoors can be controlled by the air volume of the air supply airflow 3 branched by the switching damper. ..

It relates to an air purification system that sterilizes a target space represented indoors, and is useful because it can adjust the humidity of the target space to achieve both a sterilization effect and comfort.

1 House 2 Exhaust flow 3 Air supply air 4 Exhaust air passage 5 Air supply air passage 5a 1st branch air supply air passage 5b 2nd branch air supply air passage 5c 3rd branch air supply air passage 5d 4th branch air supply air passage 5e 5th branch air supply air passage Road 5f 6th branch air supply air passage 6a Indoor exhaust port 6b Outdoor exhaust port 7a Indoor air supply port 7b Outdoor air supply port 8 Indoor space 10 Heat exchange type ventilator 11 Main body case 12 Heat exchange element 13 Exhaust fan 14 Internal air port 15 Exhaust Port 16 Air supply fan 17 Outside air port 18 Air supply port 20a First switching damper 20b Second switching damper 20c Third switching damper 20d Fourth switching damper 20e Fifth switching damper 20f Sixth switching damper 30 Air purification device 31 Suction port 31a Intake 32 Outlet 32a Outlet 33 Liquid miniaturization chamber 34 Rotating plate 35 Collision wall 36 Rotating motor 37 Rotating shaft 38 Pumping pipe 38a Pumping port 39 Purifying component supply unit 39a Supply port 40 Blower fan 41 Control unit 41a Input unit 41b Storage Section 41c Measuring section 41d Processing section 41e Output section 42 Water containing purification components 43 Operation panel 50 Heat exchange type ventilation device with air purification function

Claims (3)

Heat exchange type ventilation that exchanges heat between the exhaust flow that flows through the exhaust air passage for exhausting indoor air to the outside and the air supply that flows through the air supply air passage for supplying outdoor air indoors. With the equipment
An air purification device configured to introduce the air supply from the air supply air passage and adding a component for purifying the air to the introduced air supply.
The air passage switching unit installed in the air supply air passage and
Equipped with
In the air passage switching unit, the air supply air after heat exchange is introduced from the air supply air passage, and after flowing through the air purification device, the first air passage is led to the air supply air passage after the heat exchange type ventilation device. A state and a second state in which the air supply air before heat exchange is introduced from the air supply air passage, and after flowing through the air purification device, is led out to the air supply air passage in the previous stage of the heat exchange type ventilation device. A heat exchange type ventilator with an air purification function, which is characterized by being configured to be switchable. A temperature detector that detects the temperature of indoor air,
Humidity detector that detects the humidity of indoor air,
A control unit that controls the switching operation of the air passage switching unit,
Further prepare
Based on the temperature information from the temperature detection unit and the humidity information from the humidity detection unit, the control unit sets the air passage switching unit to the first state when the relative humidity of the indoor air is equal to or less than the reference value. The heat exchange type ventilation device with an air purification function according to claim 1, wherein the air passage switching unit is switched to the second state when the relative humidity of the indoor air exceeds the reference value. The air purifying device is characterized in that a component for purifying air is added to the air supply air flow introduced into the device by centrifugally crushing water containing the component for purifying air. The heat exchange type ventilation device with an air purification function according to 1 or 2.

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