JP6950378B2 - Ventilation system - Google Patents

Description

The present invention relates to a ventilation system having a dust collector and a ventilation device and performing interlocking operation, a dust collector, and a dust collection method.

Conventionally, an air supply air passage that leads from the outside to the room, an exhaust air passage that leads from the room to the outside, an air supply blower provided in the air supply air passage, and an exhaust air blower provided in the exhaust air passage are supplied. It is equipped with a heat exchanger provided at the intersection of the air passage and the exhaust air passage, and the heat exchange ventilation device that ventilates the room while exchanging heat between the supply air and the exhaust by the heat exchanger is known. Has been done.
As such a heat exchange ventilation device, one provided with an electrostatic precipitator in the air supply air passage on the upstream side of the heat exchanger (for example, Patent Document 1) is disclosed.

The heat exchange ventilation device described in Patent Document 1 removes dirt such as dust contained in the outdoor air by an electrostatic precipitator provided upstream of the air supply air passage, and exhaust air from the air supply air passage side inside the heat exchanger. By applying pressure to the road side, the pressure difference between the air passages allows ozone and hydrogen peroxide generated by the electrostatic precipitator installed in the air supply air passage to permeate from the air supply air passage side to the exhaust air passage side for heat exchange. The purpose is to control the growth of mold and bacteria in both air passages of the vessel, that is, to keep the heat exchanger, air supply air passage and exhaust air passage clean by the electrostatic precipitator.

JP-A-2016-169920

However, the heat exchange ventilator disclosed in Patent Document 1 aims to remove dirt such as dust contained in the outdoor air and suppress the growth of mold and bacteria in both air passages of the heat exchanger. Whenever a heat exchange ventilator is used, it is necessary to operate the electrostatic precipitator. In recent years, 24-hour ventilation is recommended for residential ventilation, and the ventilation device is often operated at all times.
That is, there is a problem that the electric dust collector is often operated even when dust collection is unnecessary, and the power consumption increases as the operating time of the electric dust collector increases.

The present invention has been made to solve the above-mentioned problems, and provides a ventilation system that performs effective dust collection operation while suppressing power consumption.

The ventilation system according to the present invention includes a dust collecting means, a control means for controlling the dust collecting means, a ventilation device for ventilating the target space, and an air inflow determining means for determining the inflow of outside air into the target space. Therefore, the control means is configured to operate the dust collecting means in conjunction with the determination result of the air inflow determining means.

Since the ventilation system of the present invention is configured as described above, it is possible to obtain an effect that effective dust collection operation can be performed while suppressing power consumption.

It is a block block diagram which shows the ventilation system which concerns on Embodiment 1 of this invention. It is a block block diagram which shows the modification of the ventilation system which concerns on Embodiment 1 of this invention. It is a block block diagram which shows the ventilation system which concerns on Embodiment 2 of this invention. It is a block block diagram which shows the ventilation system which concerns on Embodiment 3 of this invention. It is a block block diagram which shows the dust collector which concerns on Embodiment 4 of this invention. It is a flowchart which shows the dust collection method which concerns on Embodiment 4 of this invention.

Hereinafter, embodiments of a ventilation system, a dust collector, and a dust collecting method according to the present invention will be described in detail with reference to the drawings.

Embodiment 1.
FIG. 1 is a block configuration diagram showing a ventilation system according to a first embodiment of the present invention. Further, FIG. 2 is a block configuration diagram showing a modified example of the ventilation system according to the first embodiment of the present invention.

First, the configuration of the ventilation system 100 according to the first embodiment will be described with reference to FIG. In FIG. 1, the heat exchange ventilation device 1 as a ventilation device has a configuration in which a heat exchanger 2, an air supply blower 3, an exhaust blower 4, and a ventilation control circuit 5 are housed inside a housing 6. The outer shell of the housing 6 is provided with an air supply inlet / outlet 6a, an air supply outlet 6b, an exhaust suction port 6c, and an exhaust air outlet 6d as air inlets / outlets. An air supply air passage 7 is formed from the port 6a via the heat exchanger 2 to the air supply air outlet 6b, and the exhaust air from the exhaust suction port 6c via the heat exchanger 2 to the exhaust air outlet 6d. Road 8 is formed.
The heat exchanger 2 exchanges heat between the air supply airflow flowing through the air supply air passage 7 and the exhaust flow flowing through the exhaust air passage 8. Inside the heat exchanger 2, the primary side air passage through which the air supply air flow flows through the air supply air passage 7 and the secondary side air passage through which the exhaust air flow flows through the exhaust air passage 8 are separated from each other and intersect with each other. It has a structure, and there is no air in or out between the primary side air passage and the secondary side air passage, but heat exchange, that is, heat exchange is possible.

The air supply blower 3 is installed on the air supply outlet 6b side (downstream side with respect to the heat exchanger 2) on the air supply air passage 7, and the exhaust blower 4 is on the exhaust air outlet 6d side (heat) on the exhaust air passage 8. It is installed on the downstream side of the exchanger 2).
The ventilation control circuit 5 controls the operation / stop of the air supply blower 3 and the exhaust blower 4.
The air supply filter 9 is installed in the air supply air passage 7 and collects dust and the like contained in the air supply airflow. Further, the exhaust filter 10 is installed in the exhaust air passage 8 and collects dust and the like contained in the exhaust flow.

An outdoor side air supply duct 14a is connected to the air supply suction port 6a of the heat exchange ventilation device 1, and the outdoor suction port 15a communicates with the outside. Further, an indoor air supply duct 14b is connected to the air supply outlet 6b, and the indoor air outlet 15b communicates with the room. Further, an indoor exhaust duct 14c is connected to the exhaust suction port 6c, and the indoor suction port 15c communicates with the room. Further, an outdoor side exhaust duct 14d is connected to the exhaust air outlet 6d, and the outdoor air outlet 15d communicates with the outside.

An electric dust collector 11 is installed in the middle of the outdoor side air supply duct 14a as a dust collecting means. The electrostatic precipitator 11 is connected to a control device 12 as a control means by a signal line 16. Further, the control device 12 is connected to the air inflow determining device 13 as an air inflow determining means by a signal line 16. Further, the air inflow determining device 13 is connected to the air supply blower 3 of the heat exchange ventilation device 1 by a signal line 16.
Although not shown in the figure, the electrostatic precipitator 11 is composed of a metal positive electrode and a ground electrode that face each other across the ventilation path, and a dust collector filter that is arranged after the ventilation path and has the same potential as the ground electrode. It is configured.

Next, the operation of the ventilation system 100 according to the first embodiment will be described.
When an operation operation signal is sent to the heat exchange ventilation device 1 by the user operating a remote controller device (not shown), the ventilation control circuit 5 receives the operation operation signal and causes the ventilation control circuit 5 to supply the air supply blower 3 and exhaust air. An operation command is sent to the blower 4. As a result, the air supply blower 3 and the exhaust blower 4 start operation. As shown in FIG. 1, the air supply A is generated by the operation of the air supply blower 3. That is, the outdoor air enters the room from the outdoor suction port 15a via the outdoor air supply duct 14a, through the air supply air passage 7 and the heat exchanger 2, and through the indoor air supply duct 14b from the indoor air outlet 15b. Be supplied. Further, the operation of the exhaust blower 4 generates an exhaust flow B as shown in FIG. That is, the indoor air is discharged from the indoor suction port 15c to the outside through the indoor side exhaust duct 14c, through the exhaust air passage 8 and the heat exchanger 2, and through the outdoor side exhaust duct 14d from the outdoor air outlet 15d. NS.

The electrostatic precipitator 11 collects dust and fine particulate matter such as PM2.5 contained in the air taken in from the outdoor side through the outdoor side air supply duct 14a. That is, clean air from which dust and the like have been removed by the operation of the electrostatic precipitator 11 is supplied into the room. Since the electrostatic precipitator 11 can also collect fine particulate matter that cannot be collected by the air supply filter 9, it is possible to omit the air supply filter 9 in the heat exchange ventilation device 1 by installing the electrostatic precipitator 11.
The operation of the electrostatic precipitator 11 is to charge the dust or the like passing through the discharge space by applying a high voltage of about 10 kV between the positive electrode and the ground electrode of the electrostatic precipitator 11 to form a discharge space. The dust is collected by adsorbing the collected dust or the like on a dust collecting filter having the same potential as the ground electrode by a Coulomb force.

By the way, in winter, when cold outdoor air enters the inside of the heat exchange ventilation device 1 from the air supply suction port 6a, there arises a problem that the heat exchanger 2 freezes or the heat exchange ventilation device 1 itself condenses. Sometimes. In order to prevent freezing of the heat exchanger 2 and dew condensation of the heat exchange ventilation device 1, the ventilation control circuit 5 operates the air supply blower 3 based on the temperature of the outdoor air detected by a temperature sensor (not shown). It may stop and stop taking in cold air from the outside.
Further, the air from the outside is supplied to the room after the heat is exchanged by the heat exchanger 2, but since it is colder than the indoor air, the user who dislikes the feeling of cold air can operate it by himself / herself with a remote controller or the like. The air supply may be stopped.

For this reason, when the air supply of the heat exchange ventilator 1 is stopped, that is, the air supply blower 3 is stopped, the air inflow determination device 13 acquires the stop information of the air supply blower 3, and the air supply air passage is taken from the outside. It is determined that there is no air supply to the room through No. 7, that is, there is no air inflow from the outside, and the information is sent to the control device 12. Since there is no air inflow from the outside, the control device 12 determines that dust collection is not necessary, and stops the operation of the electrostatic precipitator 11.

When the ventilation control circuit 5 resumes the operation of the air supply blower 3 when the outdoor air returns to a temperature at which freezing of the heat exchanger 2 and dew condensation of the heat exchange ventilation device 1 do not occur, or the user himself / herself When the operation of the air supply blower 3 is restarted by operating the remote control device or the like, the air inflow determination device 13 acquires the information on the restart of the operation of the air supply blower 3, and sends the information to the control device 12. Since the control device 12 has an inflow of air from the outside, it determines that it is necessary to collect dust, and operates the electrostatic precipitator 11.

In this way, by operating or stopping the electrostatic precipitator 11 in conjunction with the operation or stop of the air supply blower 3, unnecessary operation of the electrostatic precipitator 11 can be avoided and wasteful power consumption can be reduced. ..
Further, if the unnecessary operation of the electrostatic precipitator 11 is reduced, the number of maintenance of the electrostatic precipitator 11 can be reduced. Further, if the unnecessary operation of the electrostatic precipitator 11 is reduced, excessive ozone generation is suppressed, and there is also an effect of reducing the peculiar odor of ozone and reducing discomfort.

In FIG. 1, a ventilation system using a heat exchange ventilation device 1 as a ventilation device has been described as an example, but for example, it is a ventilation system using an air supply ventilation device instead of the heat exchange ventilation device 1. However, by operating or stopping the electric dust collector 11 in conjunction with the operation or stop of the air supply blower of the air supply ventilation device, unnecessary operation of the electric dust collector 11 is avoided and wasteful power consumption is reduced. And the same effect can be obtained.

Further, in FIG. 1, an example in which the operation / stop of the electrostatic precipitator 11 is linked to the operation / stop of the air supply blower 3 is shown, but the operation / stop is linked to the air volume (fan rotation speed) of the air supply blower 3. You may. For example, in the case of a ventilation device that can switch and change the fan rotation speed of the air supply blower 3 with five notches, the electrostatic precipitator 11 is operated in conjunction with the three notches or more where the rotation speed is large, and the rotation speed is small 2. In the case of notch or less, since the air volume is small, the absolute amount of air taken in from the outside is small, and it is determined that the indoor air is not polluted enough to require dust collection, and the electrostatic precipitator 11 is stopped. In this case as well, unnecessary operation of the electrostatic precipitator 11 is avoided and wasteful power consumption is reduced. The stage of the notch for switching the operation / stop of the electrostatic precipitator 11 may be arbitrarily changed by means such as a switch provided in the control device 12.

Further, in FIG. 1, an air inflow determination device 13 as an air inflow determination means and a control device 12 as a control means are installed outside the heat exchange ventilation device 1, and the air supply blower 3 of the heat exchange ventilation device 1 is operated. The air inflow determination device 13 detects the inflow of air by / stopping and notifies the control device 12, so that the control device 12 controls the operation / stop of the electrostatic collector 11. However, the ventilation in the heat exchange ventilation device 1 The control circuit 5 may have the functions of the air inflow determination means and the control means, and may directly control the operation / stop of the electrostatic collector 11 in response to the operation / stop of the air supply blower 3.

Next, a modified example of the ventilation system according to the first embodiment will be described with reference to FIG.
In the ventilation system 200 of FIG. 2, a wind speed sensor 17 as a wind detection sensor is provided in the outdoor side air supply duct 14a, and is connected to the air inflow determination device 13 by a signal line 16. Since other configurations are the same as those in FIG. 1, the description thereof will be omitted.

The operation of the modified example shown in FIG. 2 will be described. When the air supply blower 3 of the heat exchange ventilation device 1 is operated to start taking in the outdoor air, the air supply A leading from the outdoor side air supply duct 14a to the air supply air passage 7 and the indoor side air supply duct 14b is generated. The wind speed sensor 17 detects the air supply airflow and transmits it to the air inflow determination device 13. The air inflow determination device 13 compares the detection signal by the wind speed sensor 17 with a preset threshold value, and informs the control device 12 whether or not the threshold value is equal to or higher than the threshold value. The control device 12 operates the electrostatic precipitator 11 when the detection signal is equal to or higher than the threshold value, and stops the electrostatic precipitator 11 when the detection signal is less than the threshold value. That is, if the wind speed of the air supply is equal to or higher than a certain level, it is determined that the pollution of the indoor air due to the intake of outside air is also higher than a certain level, and the electrostatic precipitator 11 is operated.
As the wind detection sensor, a wind volume sensor or a wind pressure sensor may be used instead of the wind speed sensor 17 described above. Further, the wind detection sensor is not limited to the installation in the outdoor side air supply duct 14a, but is either in the air supply air passage 7 of the ventilation device 1 or in the indoor air supply duct 14b or on the air supply path of the ventilation system 200. It may be installed in.

As described above, in the modified example of the first embodiment, the electrostatic precipitator 11 is operated or stopped in conjunction with the output of the wind detection sensor on the air supply path to avoid unnecessary operation of the electrostatic precipitator 11. Wasted power consumption can be reduced.

In FIG. 2, an air inflow determination device 13 as an air inflow determination means and a control device 12 as a control means are installed outside the heat exchange ventilation device 1, and air is generated by a detection signal of a wind speed sensor 17 as a wind detection sensor. The inflow determination device 13 detects the inflow of air and transmits it to the control device 12, and the control device 12 controls the operation / stop of the electrostatic precipitator 11, but the ventilation control circuit 5 in the heat exchange ventilation device 1 is configured. It may have the functions of an air inflow determination means and a control means, and may be configured to control the operation / stop of the electrostatic precipitator 11 by receiving the detection signal of the wind speed sensor 17.

Since the first embodiment is configured as described above, the dust collecting means is operated when it is determined that there is an inflow of air from the outside into the room, and the dust collecting means is operated when it is determined that there is no inflow of air. Since the dust means is stopped, unnecessary operation of the dust collecting means can be avoided and wasteful power consumption can be reduced.
Further, since unnecessary operations of the dust collecting means are reduced, the number of maintenances of the dust collecting means can be reduced. Further, when the dust collecting means is an electrostatic precipitator, excessive ozone generation can be suppressed by reducing unnecessary operations, and discomfort due to a peculiar odor can be reduced.

Embodiment 2.
In the ventilation system according to the first embodiment, the dust collecting means is installed in the air supply duct connecting the ventilation device and the outside. In the ventilation system according to the second embodiment, the dust collecting means is installed in the ventilation device.
FIG. 3 is a block configuration diagram of the ventilation system according to the second embodiment of the present invention.

First, the configuration of the ventilation system 300 according to the second embodiment will be described.
In FIG. 3, an electric dust collector 11 as a dust collecting means is installed in an air supply air passage 7 between the air supply suction port 6a of the ventilation device 1 and the heat exchanger 2 in the ventilation system 300. Further, a wind speed sensor 17 as a wind detection sensor is installed in the same air supply air passage 7, and an air inflow determination device 13 as an air inflow determination means and a control device 12 as a control means are installed in the ventilation device 1. .. The wind speed sensor 17 and the air inflow determination device 13, the air inflow determination device 13 and the control device 12, and the control device 12 and the electrostatic precipitator 11 are connected by signal lines, respectively. Further, it is assumed that the air supply filter 9 is installed on the upstream side of the electrostatic precipitator 11 in the air supply air passage 7.
Since the configurations of the other air supply ducts, exhaust ducts, etc. are the same as those of the first embodiment (FIGS. 1 and 2), illustration and description thereof will be omitted.

Next, the operation of the ventilation system 300 according to the second embodiment will be described with reference to FIG.
When the air supply blower 3 of the ventilation device 1 starts operation, outdoor air is taken into the air supply air passage 7 from the air supply suction port 6a, and the wind speed sensor 17 installation part, the air supply filter 9 part, and the electrostatic precipitator 11 It is supplied to the room through the heat exchanger 2, the air supply outlet 6b, and the air supply outlet 6b. The wind speed sensor 17 detects the wind speed by the air flow, that is, the air supply airflow, and transmits the wind speed to the air inflow determination device 13. When the wind speed exceeds a certain threshold value, the air inflow determining device 13 determines that air inflow from the outside to the room is occurring, and informs the control device 12. The control device 12 causes the electrostatic precipitator 11 to start the operation based on the information.
Further, when the air supply blower 3 of the ventilation device 1 stops operating, the air supply is lost, so that the wind speed sensor 17 does not detect the wind speed. In response to this, the air inflow determining device 13 determines that there is no air inflow into the room, and the control device 12 stops the operation of the electrostatic precipitator 11.

Therefore, also in the configuration of the second embodiment, by operating or stopping the electrostatic precipitator 11 based on the presence or absence of air inflow into the room, unnecessary operation of the electrostatic precipitator 11 is avoided and wasteful power consumption is reduced. Can be made to.
Further, if the unnecessary operation of the electrostatic precipitator 11 is reduced, the number of maintenance of the electrostatic precipitator 11 can be reduced. Further, if the unnecessary operation of the electrostatic precipitator 11 is reduced, excessive ozone generation can be suppressed, and the peculiar odor of ozone can be reduced to reduce discomfort.

In the second embodiment, the electrostatic precipitator 11, the wind speed sensor 17, the air inflow determination device 13, and the control device 12 are built in the ventilation device 1, so that the electrostatic precipitator 11 and the wind speed are as in the first embodiment. The work of installing the sensor 17 in the duct pipe and the work of installing the air inflow determination device 13 and the control device 12 and wiring each of them become unnecessary. Further, it is not necessary to secure the installation space of the electrostatic precipitator 11 and the wind speed sensor 17 in the duct pipe, and to secure the installation space of the air inflow determination device 13 and the control device 12. That is, the configuration in which the electrostatic precipitator 11 or the like is built in the ventilation device has the effect of improving the workability of the installation work of the ventilation system of the present application.

Further, in the second embodiment, the air supply filter 9 is installed on the upstream side of the electrostatic precipitator 11. The air supply filter 9 may be on the downstream side of the electrostatic precipitator 11, but if it is installed on the upstream side, the air supply filter 9 in the previous stage first collects large dust such as dust contained in the outdoor air. Next, the electrostatic precipitator 11 collects dust and fine particulate matter such as PM2.5 that cannot be collected by the air supply filter 9. That is, since the electrostatic precipitator 11 performs the dust collecting operation on the air that has been cleaned to some extent, it is possible to further reduce the number of maintenances of the electrostatic precipitator.

Further, in the second embodiment, the air inflow determining device 13 is configured to determine the inflow of air based on the wind speed detected by the wind speed sensor 17, but as shown in the first embodiment, the operating state of the air supply blower 3 The inflow of air may be determined based on the above.

Further, in the second embodiment, the air inflow determination device 13 as the air inflow determination means and the control device 12 as the control means are installed in the heat exchange ventilation device 1, and the detection signal of the wind speed sensor 17 as the wind detection sensor is installed. The air inflow determination device 13 detects the inflow of air and transmits it to the control device 12, and the control device 12 controls the operation / stop of the electrostatic precipitator 11. However, the ventilation control circuit in the heat exchange ventilation device 1 5 may have the functions of an air inflow determination means and a control means, and may be configured to control the operation / stop of the electrostatic precipitator 11 by receiving the detection signal of the wind speed sensor 17.

Since the second embodiment is configured as described above, it is possible to avoid unnecessary operation of the dust collecting means and reduce wasteful power consumption as in the first embodiment. Further, it is possible to reduce the number of maintenances of the dust collecting means, and when the dust collecting means is an electric dust collector, it is possible to reduce the peculiar odor associated with the generation of ozone and reduce the discomfort.
In addition, by incorporating dust collecting means, wind detection sensor, air inflow judgment means, and control means in the ventilation device, it is possible to secure space for installing them in duct piping, installation work, and wiring work. Since it is no longer necessary, the workability of installation work is greatly improved.

Embodiment 3.
The ventilation system according to the first and second embodiments has a configuration including a ventilation device in which an air supply function and an exhaust function are integrated, and a dust collecting means. In the ventilation system according to the third embodiment, the air supply ventilation device and the exhaust ventilation device are installed independently, and a dust collecting means is further installed.
FIG. 4 is a block configuration diagram of the ventilation system according to the third embodiment of the present invention.

First, the configuration of the ventilation system 400 according to the third embodiment will be described.
In FIG. 4, the air supply device 18 is installed between the room, which is the target space for ventilation, and the outside. The outdoor and the air supply device 18 are connected from the outdoor suction port 15a facing the outside via the outdoor side air supply duct 14a. The air outlet of the air supply device 18 faces the room. The air supply device 18 includes an air supply filter 9, an air supply blower 3, and an air supply control circuit 5a, and the operation / stop of the air supply blower 3 is controlled by the air supply control circuit 5a. Further, an electric dust collector 11 is installed as a dust collecting means in the outdoor side air supply duct 14a, and is connected to a control device 12 as a control means by a signal line 16. Further, the control device 12 is connected to the receiving unit 21 installed in the room by a signal line.

In addition, an exhaust device 19 is installed between the room, which is the target space for ventilation, and the outside. The exhaust device 19 and the outside are connected by an outdoor air outlet 15d facing the outside via an outdoor side exhaust duct 14d. The suction port of the exhaust device 19 faces the room. The exhaust device 19 includes an exhaust filter 10, an exhaust blower 4, and an exhaust control circuit 5b, and the exhaust blower 4 is controlled to start / stop by the exhaust control circuit 5b. Further, an air inflow determining device 13 is installed as an air inflow determining means, and is connected to the exhaust blower 4 by a signal line. Further, the air inflow determining device 13 is connected to the transmitting unit 20 installed in the room by a signal line.

Next, the operation of the ventilation system 400 in the third embodiment will be described with reference to FIG.
When the air supply device 18 performs the air supply operation, the air supply blower 3 operates, and the control device 12 issues an operation command to the electrostatic precipitator 11 in response to the operating state. That is, the air taken in from the outside by the air supply operation of the air supply device 18 is cleaned by the operation of the electrostatic precipitator 11 and then supplied to the room. When the air supply device 18 stops the air supply operation, the air supply blower 3 is stopped, and the control device 12 issues a stop command to the electrostatic precipitator 11 in response to the stopped state.
Therefore, since the electrostatic precipitator 11 operates in conjunction with the operation / stop of the air supply device 18, unnecessary operation of the electrostatic precipitator 11 can be avoided and wasteful power consumption can be reduced.

Here, consider a case where the user operates the remote controller or the like to start the operation of the exhaust device 19 while the air supply device 18 is stopped. When the exhaust blower 4 in the exhaust device 19 operates and starts exhausting the air in the room to the outside, the air pressure in the room becomes negative because the air supply device 18 is not operating, so that air is supplied from the outside. It is desirable to do so. The air inflow determination device 13 recognizes the negative pressure in the room in response to the fact that the exhaust blower 4 in the exhaust device 19 is in the operating state, determines that air supply from the outside is necessary, and determines that the air supply unit from the outside is necessary. The air supply device 18 is instructed to start operation via the 20th. Specifically, an infrared command signal is transmitted from the transmitting unit 20 to the receiving unit 21. The receiving unit 21 transmits the received command signal to the control device 12, and the control device 12 receives the signal and sends an operation command to the air supply blower 3 of the air supply device 18 and operates the electrostatic precipitator 11. By operating the air supply blower 3, air is supplied from the outside to the room, and the negative pressure in the room is eliminated. At this time, the air taken in from the outside is cleaned by the operation of the electrostatic precipitator 11 and then supplied to the room.
The control device 12 may not directly send an operation command to the air supply blower 3, but may operate the air supply blower 3 via the air supply control circuit 5a of the air supply device 18.

Further, when the operation of the exhaust device 19 is stopped, if the air supply device 18 continues to operate, the pressure in the room becomes positive. Therefore, it is desirable to stop the supply of air. 20 → A signal is sent from the receiving unit 21 to the control device 12, and the operation of the air supply blower 3 and the operation of the electrostatic precipitator 11 are stopped.
That is, in conjunction with the operation / stop of the exhaust device 19, the air supply blower 3 is automatically operated / stopped, and the operation / stop of the electrostatic precipitator 11 is also interlocked. Therefore, since the electrostatic precipitator 11 operates only when air is supplied from the outside to the room, unnecessary operation of the electrostatic precipitator 11 can be avoided and wasteful power consumption can be reduced.

In the third embodiment, infrared communication has been described as an example of the means of communication by the transmitting unit 20 and the receiving unit 21, but short-range wireless communication such as a wireless LAN may be used. Further, the air inflow determination device 13 and the control device 12 may be directly connected by a signal line and communicated by wire communication. Further, an example of controlling the operation / stop of the air supply blower 3 and the electrostatic precipitator 11 of the air supply device 18 in conjunction with the operation / stop of the exhaust blower 4 of the exhaust device 19 has been described. Exhaust air volume In other words, the operation / stop of the air supply blower 3 and the electrostatic precipitator 11 of the air supply device 18 may be controlled corresponding to the operation notch of the exhaust blower 4.

Further, in the third embodiment, apart from the exhaust device 19 and the air supply device 18, an air inflow determination device 13 as an air inflow determination means and a control device 12 as a control means are installed, and the air inflow determination device 13 exhausts. The necessity of inflow of air was determined by the operation / stop of the blower 4, and the control device 12 was configured to control the operation / stop of the electrostatic precipitator 11, but the exhaust in the exhaust device 19 was exhausted. The control circuit 5b also has the function of the air inflow determination means, and the air supply control circuit 5a in the air supply device 18 also has the function of the control means, so that the exhaust control circuit 5b starts / stops the exhaust blower 4. The information may be transmitted to the air supply control circuit 5a via the receiving and transmitting units 20 and the receiving unit 21, and the air supply control circuit 5a may control the operation / stop of the air supply blower 3 and the electrostatic precipitator 11. ..

Further, in the third embodiment, the example in which the electrostatic precipitator 11 is installed in the outdoor side air supply duct 14a connected to the air supply device 18 has been described, but the electrostatic precipitator 11 is built in the air supply device 18. But it may be. That is, it suffices if it is installed on the air supply path from the outside.

Further, in the third embodiment, the ventilation system having one each of the air supply device 18 and the exhaust device 19 has been described, but the ventilation system may have a plurality of exhaust devices 19.
For example, the air supply device 18 and the electrostatic precipitator 11 may be operated according to the number of the exhaust devices 19 in the operating state among the plurality of exhaust devices 19. If the number of exhaust devices 19 in operation is large, the degree of negative pressure in the room increases. Therefore, it is determined that the air supply device 18 needs to be operated, and the electrostatic precipitator 11 is used to purify the inflowing air. Let it drive. If the number of exhaust devices 19 in operation is small, the degree of negative pressure in the room is small, so it is determined that the operation of the air supply device 18 is unnecessary, and no inflow of air is generated, so that the electrostatic precipitator 11 is stopped. That is, since the electrostatic precipitator 11 is operated as needed, wasteful power consumption can be suppressed.

Since the third embodiment is configured as described above, it is possible to avoid unnecessary operation of the dust collecting means and reduce wasteful power consumption as in the first and second embodiments. Further, it is possible to reduce the number of maintenances of the dust collecting means, and when the dust collecting means is an electric dust collector, it is possible to reduce the peculiar odor associated with the generation of ozone and reduce the discomfort.
In addition, in a ventilation system in which an air supply device and an exhaust device are installed independently, it is possible to perform an air supply operation and a dust collection operation in conjunction with the operation operation of the exhaust device, so that indoor and outdoor operations can be performed. It is possible to realize operation control to make the air condition more comfortable, including the difference in air pressure.

Embodiment 4.
In the first to third embodiments, a ventilation system having a configuration in which the dust collecting means is installed in the air supply duct or in the air supply air passage of the ventilation device is shown. In the fourth embodiment, an example of a dust collector independent of the ventilation device is shown.
FIG. 5 is a block configuration diagram of the dust collector according to the fourth embodiment of the present invention.

First, the configuration of the dust collector 500 according to the fourth embodiment will be described.
In FIG. 5, the dust collector 500 is provided by an air inflow determining means 13 for determining the inflow of air into an indoor space to be collected, a control means 12, and a dust collecting means 11 for collecting dust in the indoor space. It is configured. The air inflow determining means 13, the controlling means 12, and the dust collecting means 11 are each connected by a signal line, and signals can be exchanged with each other. Further, the air inflow determination means 13, the control means 12, and the dust collecting means 11 do not necessarily have to be installed in one housing, and may be installed in a dispersed manner. In that case, a configuration may be used in which signals are exchanged by infrared rays or wirelessly, regardless of the signal line.

Next, the operation of the dust collector 500 according to the fourth embodiment will be described with reference to FIG.
When the air inflow determining means 13 determines that there is an inflow of air (for example, from the outdoors or from another room) into the indoor space where the dust collector 500 is installed, the air inflow determining means 13 controls the information. Send to means 12. The control means 12 determines that the inflowing air may be contaminated with dust or the like, and sends a command to start the operation to the dust collecting means 11. As a result, the dust collecting means 11 starts the operation operation, takes in the air 23 before the dust collection in the target room space, collects the dust contained therein, and then serves as the cleaned air 24 after the dust collection. Supply indoors.

As described above, even if the dust collector is independent of the ventilation device, it is possible to determine the presence or absence of air inflow into the room and perform the dust collection operation based on the determination. Since the dust collection operation is performed when there is an air inflow from the outside and the dust collection operation is stopped when there is no air inflow from the outside, it is possible to carry out effective dust collection without wasting power. can.

For example, in a room in which an air supply device is not installed, it is not possible to install a dust collecting means in the air supply device or in the air supply duct portion as in the first to third embodiments. However, if an exhaust system is installed and the room becomes negative pressure due to the operation of the exhaust system, it is considered that outside air will enter through the gaps in the doors unless the room has a high degree of airtightness. .. Therefore, it is conceivable that air containing dust and the like may enter from the outside due to the exhaust operation.
In such a case, if the dust collector shown in the fourth embodiment is installed in the room and the air inflow determination means is connected to the exhaust blower of the exhaust device, the exhaust operation is started, that is, the exhaust blower The dust collecting means operates in conjunction with the start of operation, and the dust collecting means also stops in conjunction with the stop of the exhaust operation.

In addition, a configuration that does not interlock with the exhaust device is also possible. Assuming a place where air is more likely to enter in the target room, a sensor that detects the wind as shown in the modified example of the first embodiment is installed at that place, so that the air inflow determination means is the air. It may be configured to determine the inflow.
Efficient dust collection is possible if dust collecting means can be installed in the air supply device or in the air supply duct portion as in the first to third embodiments, but the dust is collected at an arbitrary place in the room as in the fourth embodiment. By installing a dust device and operating it in conjunction with the inflow of air from the outside, effective dust collection operation without wasting power is possible.

The configuration of the dust collector having the air inflow means, the control means, and the dust collecting means as shown in the fourth embodiment shows the basic dust collecting method including the operations of the first to third embodiments. .. FIG. 6 shows the dust collecting method in a flowchart.
The basic dust collecting method of the present application will be described with reference to FIG.
First, in step S1, it is determined whether or not there is an inflow of air from the outside into the dust collection target space (air inflow determination step).
If there is an inflow of air (YES), the process proceeds to step S2, and the dust collection operation is started (ON) (dust collection step).
If there is no inflow of air (NO), the process proceeds to step S3, and the dust collecting operation is stopped (OFF).
As a result, the dust collecting operation is performed when necessary and the dust collecting operation is stopped when it is not needed, so that the dust collecting operation can be performed effectively and without consuming wasteful power.

Since the fourth embodiment is configured as described above, it is possible to avoid unnecessary operation of the dust collector and reduce wasteful power consumption as in the first to third embodiments.
In addition, effective dust collection with reduced power consumption can be achieved by a dust collection method in which the dust collection operation is performed when necessary and the dust collection operation is stopped when unnecessary.

1 Heat exchange ventilator 3 Air supply blower 4 Exhaust blower 7 Air supply air passage 11 Electrostatic precipitator 12 Control device 13 Air inflow judge 14a Outdoor side air supply duct 17 Wind speed sensor 18 Air supply device 19 Exhaust device 100, 200, 300 , 400 Ventilation system 500 Dust collector

Claims (3)

A dust collecting means that purifies the air in the target space,
A control means for controlling the dust collecting means and
A ventilation device that has a blower for air supply and ventilates the target space,
With an air inflow determining means for determining the inflow of outside air into the target space
With
The air inflow determining means determines the presence or absence of outside air inflow based on the operating state of the air supply blower.
The control means operates the dust collecting means in conjunction with the determination result of the air inflow determining means.
Ventilation system
The air inflow determining means determines that the outside air inflow is small when the air supply blower is operating at a predetermined rotation speed or less.
Wherein, ventilation system that is characterized in that stopping the dust collection unit by determining the outside air inflow is smaller by the air inlet determining means. A dust collecting means that purifies the air in the target space,
A control means for controlling the dust collecting means and
An air supply blower that supplies air to the target space,
An exhaust blower that exhausts air from the target space,
It is provided with an air inflow determining means for determining whether or not the outside air needs to flow into the target space.
The air inflow determining means determines whether or not outside air inflow is necessary based on the fan speed of the exhaust blower.
The ventilation system is characterized in that the control means operates the air supply blower and the dust collecting means in conjunction with the determination result of the air inflow determining means. A dust collecting means that purifies the air in the target space,
A control means for controlling the dust collecting means and
An air supply blower that supplies air to the target space,
A plurality of exhaust blowers that exhaust air from the target space,
It is provided with an air inflow determining means for determining whether or not the outside air needs to flow into the target space.
The air inflow determining means determines whether or not outside air inflow is necessary based on the number of operating exhaust blowers.
The ventilation system is characterized in that the control means operates the air supply blower and the dust collecting means in conjunction with the determination result of the air inflow determining means.

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