JP2021173462A - Dust collector - Google Patents

Abstract

To provide a dust collector capable of improving cleaning maintenance performance inside the device in the dust collector removing dust included in air.SOLUTION: A dust collector 2 removes dust included in outdoor air sucked from a suction port 7 and then, sends out the air from a blowout port 8. The dust collector 2 includes: a dust collecting part 9 collecting dust included in the outdoor air; a first injection part 10 disposed between the dust collecting part 9 and the blowout port 8 and blowing out compressed air toward the dust collecting part 9; a second injection part 11 disposed between the suction port 7 and a first duct 5A communicated with an outdoor side and blowing out compressed air flowing toward the outdoor side into the first duct 5A; and a control part controlling operations of the first injection part 10 and the second injection part 11. When the dust collecting part 9 is cleaned, the control part performs control to operate the first injection part 10 and the second injection part 11 and discharge the dust collected by the dust collecting part 9 from the suction port 7 to the outdoor side.SELECTED DRAWING: Figure 2

Description

The present invention relates to a dust collector that removes dust contained in air introduced from outdoors to indoors.

Conventionally, a dust collector for removing dust contained in air introduced from outdoors to indoors is known (see, for example, Patent Document 1). Such conventional dust collectors are often used in connection with a ventilation device that supplies outdoor air indoors via a duct, and are generally used in the attic in order to secure an indoor space. Will be installed in.

JP-A-2019-173985

However, in such a conventional dust collector, dust adheres to the inside of the device, causing problems such as a decrease in the dust collection ability or a decrease in the ventilation capacity due to clogging. It was necessary to clean and remove the adhering dust. Specifically, users of conventional dust collectors go up to the platform so that they can reach the ceiling, open the inspection door, take out the dust collector installed behind the ceiling, and wash it with water or the like. By doing so, the adhering dust is removed. Then, the users and the like had to return the dust collector to the ceiling after it was sufficiently dried.

Therefore, the present invention solves the above-mentioned conventional problems, and an object of the present invention is to provide a dust collector capable of improving cleaning maintainability inside the device.

Then, in order to achieve this object, the dust collector according to the present invention removes the dust contained in the outdoor air sucked from the suction port and sends it out from the air outlet. The dust collector is arranged between a dust collecting unit that collects dust contained in outdoor air and a dust collecting unit and an outlet, and a first injection unit that blows compressed air toward the dust collecting unit. A second injection unit that is arranged between the suction port and a duct that communicates with the outside and blows out compressed air that flows toward the outside into the duct, and a control unit that controls the operation of the first injection unit and the second injection unit. To be equipped. Then, when cleaning the dust collecting unit, the control unit operates the first injection unit and the second injection unit to control the dust collected in the dust collecting unit to be discharged to the outside from the suction port. It is characterized by the fact that it achieves its initial purpose.

According to the present invention, it is possible to provide a dust collector capable of improving the cleaning maintainability inside the device.

A side view showing a ventilation system having a dust collector according to the first embodiment of the present invention. Side sectional view showing the configuration of the dust collector used in the ventilation system Plane cross-sectional view showing the internal structure of the dust collector Perspective view of the first injection part constituting the dust collector Side sectional view of the second injection part constituting the dust collector Diagram showing the connection between the control unit of the dust collector and each device Flow chart of ventilation mode and cleaning mode in the ventilation system (A) A plan view showing a state in which the third airflow from the first injection section is closer to the center, (b) a plan view showing a state in which the third airflow from the first injection section is closer to the right, and (c) a first injection section. Plan view showing the state where the third airflow from

The dust collector according to the present invention removes dust contained in the outdoor air sucked from the suction port and sends it out from the air outlet. The dust collector is arranged between a dust collecting unit that collects dust contained in outdoor air and a dust collecting unit and an outlet, and a first injection unit that blows compressed air toward the dust collecting unit. A second injection unit that is arranged between the suction port and a duct that communicates with the outside and blows out compressed air that flows toward the outside into the duct, and a control unit that controls the operation of the first injection unit and the second injection unit. To be equipped. Then, when cleaning the dust collecting unit, the control unit operates the first injection unit and the second injection unit to control the dust collected in the dust collecting unit to be discharged to the outside from the suction port.

According to such a configuration, the dust adhering to the dust collecting portion can be removed by the compressed air injected from the first injection unit, and the removed dust is generated by the compressed air injected from the second injection unit. It can be discharged to the outdoors by riding the flow toward the outdoors. That is, it can be a dust collector capable of improving the cleaning maintainability inside the device.

Further, in the dust collector according to the present invention, the second injection unit has a configuration in which the compressed air flowing toward the outside is blown into the duct to generate an attracting airflow from the suction port toward the outside.

As a result, a flow rate larger than the flow rate of the compressed air injected from the second injection unit can be generated, so that the dust removed by the compressed air injected from the first injection unit can be more reliably discharged to the outside. Can be done.

Further, in the dust collector according to the present invention, the second injection unit is configured to have a ring-shaped injection port arranged so as to surround the suction port 7. As a result, the second injection unit can blow out compressed air into the duct without bias.

Further, in the dust collector according to the present invention, the second injection unit is configured to be installed adjacent to the suction port. As a result, the dust collector can be integrated with the dust collector, so that the device can be miniaturized.

Further, in the dust collector according to the present invention, the air outlet has a configuration in which it communicates with a blower for taking in outdoor air indoors or a ventilation device having a blower. This makes it possible to create a ventilation system that purifies the outdoor air and supplies it indoors.

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

(Embodiment 1)
First, the outline of the ventilation system 40 according to the first embodiment of the present invention will be described with reference to FIGS. 1, 2, and 3. FIG. 1 is a diagram showing a configuration of a ventilation system 40. FIG. 2 is a diagram showing the configuration of the dust collector 2. FIG. 3 is a plan sectional view showing the internal structure of the dust collector 2.

The ventilation system 40 according to the present embodiment has a configuration in which the dust collector 2 is incorporated in the ventilation device that sends the air of the outdoor 42 to the indoor 41 in a general house, and as shown in FIG. 1, the ceiling of the house. The equipment is installed on the back. In the ventilation system 40, the equipment is arranged in the order of the outdoor hood 1, the dust collector 2, the blower 3, and the blowout grill 4 from the outdoor 42 side. The outdoor hood 1 and the dust collector 2 are communicated with each other by the first duct 5A, the dust collector 2 and the blower 3 are communicated with each other by the second duct 5B, and the blower 3 and the blowout grill 4 are communicated with each other by the third duct 5C. Communicated by.

In the ventilation system 40, by operating the blower 3, the air of the outdoor 42 flows in from the outdoor hood 1 as shown by the white arrow in FIG. 1, passes through the dust collector 2, passes through the blower 3, and is indoor 41. Air is supplied to.

Specifically, as shown in FIG. 1, the ventilation system 40 includes an outdoor hood 1, a first duct 5A, a dust collector 2, a second duct 5B, a blower 3, and a third duct 5C. It is configured to have a blowout grill 4.

The outdoor hood 1 is provided on the wall surface or under the eaves of the house, and prevents rain or wind from entering the opening (not shown) for taking in the air of the outdoor 42. Hereinafter, the outdoor hood 1 will be described as including an opening for taking in the air of the outdoor 42. The opening here also has a role of discharging dust from the dust collecting unit 9 (see FIG. 2) when cleaning the dust collecting device 2.

The first duct 5A is a duct that communicates the outdoor hood 1 and the dust collector 2.

The dust collector 2 is a device that removes dust contained in the air of the outdoor 42 introduced from the outdoor hood 1. Details of the dust collector 2 will be described later.

The second duct 5B is a duct that communicates the dust collector 2 and the blower 3.

The blower 3 is connected to a second duct 5B that communicates with the dust collector 2, and the blades are rotated by a motor to generate wind (air flow). The wind (air flow) generated by the blower 3 is sent from the blow-out grill 4 to the indoor 41 via the third duct 5C.

The third duct 5C is a duct that communicates the blower 3 and the blowout grill 4.

The blowout grill 4 is a grill provided on the ceiling or wall surface of the living room or the like of the indoor 41 so as to cover the opening for blowing the air treated by the ventilation system 40 into the indoor 41. Hereinafter, the blowing grill 4 will be described as including an opening for blowing the air treated by the ventilation system 40 into the indoor 41.

Next, the configuration of the dust collector 2 will be described with reference to FIG.

The dust collector 2 is a device having a function of removing dust from the air introduced into the device to purify the air and a function of discharging the collected dust to the outdoors 42. Specifically, the dust collector 2 includes a housing 6, a suction port 7, an outlet 8, a dust collector 9, a first injection unit 10, a second injection unit 11, and a control unit 29. , And are configured.

The housing 6 constitutes the outer frame of the dust collector 2. The suction port 7 and the air outlet 8 are formed on the outer peripheral side surface of the housing 6 at positions facing each other. Further, a dust collecting portion 9 and a first injection portion 10 are formed inside the housing 6.

The suction port 7 is provided on the side surface of the housing 6 and is an opening through which the air of the outdoor 42 introduced from the outdoor hood 1 flows. A second injection unit 11 is installed on the outside of the suction port 7 (on the outdoor hood 1 side).

The air outlet 8 is provided on a side surface facing the side surface of the housing 6 provided with the suction port 7, and is an opening through which the air cleaned by the dust collecting portion 9 flows out. An adapter 12 is installed on the outside of the outlet 8 (on the side of the outlet grill 4).

The dust collecting unit 9 is a unit that purifies the air by removing the dust from the air introduced into the dust collecting device 2. In the present embodiment, the dust collecting unit 9 collects dust by an electric dust collecting method. In the electrostatic precipitator method, dust in the air is charged by corona discharge, and the charged dust is attracted to the electrode plate 13 by receiving a Coulomb force when passing through the space where an electric field is generated, and the dust adheres to the electrode plate 13. It collects dust. Therefore, the dust collecting unit 9 is configured by laminating a plurality of electrode plates 13 in the vertical direction with a predetermined interval.

As shown in FIG. 3, the first injection units 10 are arranged in pairs (two sets) facing each other with the airflow passing region of the dust collecting unit 9 interposed therebetween. That is, the first injection unit 10 includes a first injection unit 10R and a first injection unit 10L. Here, the "R" and "L" attached to the reference numerals of the first injection unit 10 are those arranged on the right side when the first injection unit 10 is viewed from the suction port 7 side as "R". The one arranged on the left side is designated as "L". When cleaning the dust collecting unit 9, the first injection unit 10 blows compressed air toward the dust collecting unit 9. At this time, the first injection unit 10 blows out so that the flow rate of the compressed air gradually increases.

The second injection unit 11 is connected to the first duct 5A communicating with the outdoor hood 1 and is installed adjacent to the suction port 7. When cleaning the dust collecting unit 9, the second injection unit 11 blows compressed air flowing toward the outdoor 42 to the first duct 5A at a constant flow rate to attract the compressed air from the suction port 7 toward the outdoor 42. Create an air flow.

The adapter 12 is provided adjacent to the air outlet 8 and is connected to a second duct 5B that communicates with the blower 3.

The control unit 29 has a function of controlling the supply of compressed air to the first injection unit 10 and the second injection unit 11. It also controls the operation of the blower 3. The details of the control unit 29 will be described later. Regarding the blower 3, a control unit may be separately prepared as the ventilation system 40.

Next, the arrangement of the first injection unit 10 will be described with reference to FIG. In addition, in FIG. 3, the state where the dust collector 2 is operating (the state where the air of the outdoor 42 is taken in, the dust is removed by the dust collecting unit 9 and the cleaned air is sent to the indoor 41, the ventilation described later). In mode).

As shown in FIG. 3, the dust collecting unit 9 is provided with supports 14 on both the left and right sides in order to support the electrode plate 13 that generates an electric field. The space through which the air flows becomes the space where the electrode plate 13 is located, and the air does not flow in the region of the support 14. The first injection unit 10 is arranged so as to be paired on the left and right outside thereof so as to sandwich the air (air flow passage region) through which the air (processed air) passes through the electrode plate 13. The dust collection rate of the dust collecting unit 9 is often not 100%, and the dust that could not be removed scatters downstream. However, since the treated air does not directly hit the first injection unit 10 arranged so as to face the first injection unit 10 with the air flow passage region of the dust collecting unit 9 interposed therebetween, the adhesion of dirt to the first injection unit 10 is suppressed. NS.

Next, the detailed configuration of the first injection unit 10 will be described with reference to FIG. FIG. 4 is a perspective view of the first injection unit 10L constituting the dust collector 2.

As shown in FIG. 4, the first injection portion 10L includes a first joint portion 15, a pipe 16, a nozzle 17, and a rotary motor 18. In the first injection portion 10L, the first joint portion 15 is connected to one end of the pipe 16, the other end of the pipe 16 is sealed so that air does not leak, and the rotary motor 18 is connected, and three are connected to the side surface of the pipe 16. Nozzle 17 is connected. Then, the first injection unit 10L blows compressed air from the nozzle 17 toward the dust collecting unit 9.

The first joint portion 15 connects a tube or the like for supplying compressed air to the pipe 16.

The pipe 16 has a hollow structure, and one end communicates with the first joint portion 15. Then, compressed air is introduced into the pipe 16 from the outside via the first joint portion 15.

Three nozzles 17 are connected along the vertical direction (vertical direction) on the side surface of the pipe 16. The nozzle 17 includes a first injection port 19 which is a circular hole for injecting compressed air at the tip. The first injection ports 19 are arranged side by side in a two-row configuration, and three nozzles 17 are arranged so that the first injection ports 19 are arranged long in the vertical direction (vertical direction). As a result, the first injection port 19 is provided with two rows in the vertical vertical direction. A hole may be made directly in the pipe 16 without using the nozzle 17, and a plurality of holes may be provided so that the holes are arranged in the vertical vertical direction.

The rotary motor 18 is a stepping motor. The alternate long and short dash line shown in FIG. 4 is the central axis 20 of the pipe 16 and indicates the axis along the vertical vertical direction. The rotary motor 18 can rotate the pipe 16 around the central shaft 20, and can change the injection direction of the jet flow (first air flow 30 described later) injected from the first injection port 19.

In the first injection unit 10L, as shown by the white arrow in FIG. 4, when the compressed air is supplied from the first joint portion 15, the compressed air passes through the pipe 16 and is injected from the first injection port 19. The compressed air is obtained by compressing the air using a compressor, and the pressure is about 0.1 MPa to 0.7 MPa.

Here, the first injection unit 10L has been described, but the first injection unit 10R is the same as the first injection unit 10L except that it has a symmetrical configuration, and thus the description thereof will be omitted.

Next, the detailed configuration of the second injection unit 11 will be described with reference to FIG. FIG. 5 is a side sectional view of the second injection unit 11 constituting the dust collector 2.

As shown in FIG. 5, the second injection portion 11 includes a second joint portion 21, an outer cylindrical portion 22, an inner cylindrical portion 23, and a second injection port 24. The second injection portion 11 includes an outer cylindrical portion 22 to which the second joint portion 21 is connected, and an inner cylindrical portion 23 inside the outer cylindrical portion 22.

The second joint portion 21 is a portion for connecting a tube or the like for supplying compressed air to the outer cylindrical portion 22.

The outer cylindrical portion 22 is provided on the side surface of the housing 6 provided with the suction port 7. Further, a second joint portion 21 is connected to the outer cylindrical portion 22, and compressed air is introduced from the outside via the second joint portion 21.

The inner cylindrical portion 23 has a penetrating cylindrical shape, one end communicating with the first duct 5A and the other end communicating with the suction port 7 on the side surface of the housing 6. Then, the inner cylindrical portion 23 can pass the air taken in from the outdoor 42 by the operation of the blower 3. On the other hand, the inner cylindrical portion 23 can allow air to pass from the suction port 7 side to the outdoor hood 1 side when cleaning the dust collecting portion 9.

The second injection portion 11 is installed adjacent to the suction port 7, and a slight gap is provided between the outer cylindrical portion 22 and the inner cylindrical portion 23 on the suction port 7 side of the second injection portion 11. Two injection ports 24 are provided. The second injection unit 11 injects compressed air from the second injection port 24 into the first duct 5A.

The second injection port 24 is arranged so as to surround the suction port 7 and is a ring-shaped slit. The end shape of the inner cylindrical portion 23 has a shape in which the mouth expands like a trumpet toward the suction port 7 side.

In the second injection unit 11, as shown by the white arrow in FIG. 5, when the compressed air is supplied from the second joint portion 21, the compressed air is injected from the second injection port 24, and the jet flow is FIG. As shown by the black arrow of, the air is bent along the trumpet-like shape by the Coanda effect, and is jetted into the first duct 5A toward the outdoor hood 1 (outdoor 42). At this time, the surrounding air is attracted, and a flow rate larger than the flow rate of the compressed air supplied from the second joint portion 21 flows back in the first duct 5A, and is sent from the outdoor hood 1 to the outdoor 42.

Next, the configuration of the control unit 29 will be described with reference to FIG. FIG. 6 is a diagram showing a connection between the control unit 29 of the dust collector 2 and each device. In FIG. 6, the connection between the control unit 29 and each device is shown by a dotted line, and the flow of compressed air is shown by a solid line.

As shown in FIG. 6, in the dust collector 2, the compressed air supplied from the compressor 25 circulates in the order of the sluice valve 26, the pressure reducing valve 27, and the flow rate adjusting valve 28, and the pair of first injection units 10 (third). It is sent to one injection unit 10R and a first injection unit 10L), respectively. Further, in the dust collector 2, the compressed air supplied from the compressor 25 circulates in the order of the sluice valve 26 and the pressure reducing valve 27, and is sent to the second injection unit 11.

Here, the sluice valve 26 is a valve that supplies or stops compressed air from the compressor 25 by an opening / closing operation. The pressure reducing valve 27 is a valve that reduces the pressure of compressed air that has passed through the sluice valve 26 to a predetermined pressure. Further, the flow rate adjusting valve 28 is a valve that adjusts the flow rate of the air passing through the compressed air passing through the pressure reducing valve 27 depending on the degree of opening of the valve.

The control unit 29 is connected by wire or wirelessly between the blower 3, the rotary motor 18, the sluice valve 26, and the flow rate adjusting valve 28, respectively. Then, the control unit 29 issues a command for starting and stopping the operation to the blower 3. Further, the control unit 29 issues a command for rotational operation to the rotary motor 18. Then, the control unit 29 issues a command for opening / closing operation to the sluice valve 26 to control the supply or stop of the compressed air. Further, the control unit 29 issues an opening / closing command including an opening degree to the flow rate adjusting valve 28.

Then, each device (blower 3, rotary motor 18, sluice valve 26, flow rate adjusting valve 28) executes each operation based on a command (control signal) from the control unit 29.

The ventilation system 40 as described above includes a ventilation mode and a cleaning mode. The ventilation mode is a state in which the blower 3 is operated to purify the air in the outdoor 42 and supply it to the indoor 41. The cleaning mode is a state in which the operation of the blower 3 is stopped, the dust adhering to the dust collecting unit 9 is removed, and the dust is discharged to the outdoors 42.

In the dust collecting device 2, when the operation in the ventilation mode is continued, dust is gradually accumulated in the dust collecting portion 9, and the dust collecting performance is lowered or the air volume is lowered due to the clogging of the dust. Therefore, the operation of the control unit 29 periodically stops the blower 3 and shifts to a cleaning mode in which compressed air is supplied to the first injection unit 10 and the second injection unit 11. ..

Next, the operation of the ventilation mode and the cleaning mode in the dust collector 2 will be described with reference to FIG. 7. FIG. 7 is a flowchart of a ventilation mode and a cleaning mode in the ventilation system 40.

In the ventilation system 40, when the ventilation system 40 is operated, the ventilation mode is set, the blower 3 is operated, and the air of the outdoor 42 is continuously supplied to the indoor 41.

Then, the ventilation system 40 shifts to the cleaning mode when the preset time elapses.

In the ventilation system 40, when the cleaning mode is entered, the control unit 29 stops the blower 3 and opens the sluice valve 26. As a result, the compressed air flowing from the second injection unit 11 toward the outdoor 42 is injected into the first duct 5A, and an induced air flow is generated from the suction port 7 toward the outdoor 42. As a result, a backflow airflow from the indoor 41 to the outdoor 42 is generated in the first duct 5A.

Next, the control unit 29 turns on the rotary motor 18 and adjusts the flow rate by using the flow rate adjusting valve 28 according to the angle of the nozzle 17. This control will be described with reference to FIG. FIG. 8A is a plan view showing a state in which the third airflow 32 from the first injection unit 10 is closer to the center. FIG. 8B is a plan view showing a state in which the third airflow 32 from the first injection unit 10 is to the right. FIG. 8C is a plan view showing a state in which the third airflow 32 from the first injection unit 10 is to the left. Here, in FIG. 8, the jet flow injected from the first injection port 19 of the first injection unit 10R is referred to as the first air flow 30, and the jet flow injected from the first injection port 19 of the first injection unit 10L is referred to as the second air flow 31. do. Then, the airflow in which the first airflow 30 and the second airflow 31 merge is referred to as the third airflow 32. The third airflow 32 is the same as the first airflow 30 and the second airflow 31 considered by combining vectors.

In the case of FIG. 8A, the control unit 29 of the first injection unit 10R and the first injection unit 10L so that the first air flow 30 and the second air flow 31 collide with each other near the center in the left-right direction of the dust collecting unit 9. Adjust the angle. When the same amount of compressed air is injected from both, the third airflow 32 is located near the center between the first injection unit 10R and the first injection unit 10L, and the airflow passage surface 9a of the dust collection unit 9 (dust collection unit 9). Is an air flow in the direction perpendicular to the side surface facing the air outlet 8) and flows toward the suction port 7 (second injection unit 11) side.

In the case of FIG. 8B, the control unit 29 has an angle between the first injection unit 10R and the first injection unit 10L so that the position where the first air flow 30 and the second air flow 31 collide is on the first injection unit 10R side. To adjust. In this case, by increasing the flow rate of the second airflow 31 more than the first airflow 30, the third airflow 32 has the dust collecting portion 9 on the right side when the dust collecting portion 9 is viewed from the suction port 7 side. The airflow is perpendicular to the airflow passing surface 9a and flows toward the second injection unit 11.

In the case of FIG. 8C, the control unit 29 has an angle between the first injection unit 10R and the first injection unit 10L so that the position where the first air flow 30 and the second air flow 31 collide is on the first injection unit 10L side. To adjust. In this case, by increasing the flow rate of the first airflow 30 more than the second airflow 31, the third airflow 32 has the dust collecting portion 9 on the left side when the dust collecting portion 9 is viewed from the suction port 7 side. The airflow is perpendicular to the airflow passing surface 9a and flows toward the second injection unit 11.

By adjusting the injection angle and the injection flow rate of the first injection unit 10R and the first injection unit 10L in this way, the third air flow 32 in which the first air flow 30 and the second air flow 31 collide is always the dust collecting unit 9. The flow is perpendicular to the airflow passing surface 9a and toward the suction port 7 (second injection portion 11). Then, by moving the position where the first air flow 30 and the second air flow 31 collide with each other between the side of the first injection unit 10R and the side of the first injection unit 10L, the position where the third air flow 32 is generated is left and right. Since it can be moved in the direction, the dust adhering to the dust collecting portion 9 can be completely removed. At this time, the jet flow injected by the second injection section 11 creates a flow from the indoor 41 side through the dust collecting section 9 to the outdoor 42 side, so that the removed dust rides on the flow and is carried on the outdoor 42. Is discharged to. The third airflow 32 does not necessarily have to be blown in the direction perpendicular to the dust collecting portion 9. That is, even if the injection flow rates of the compressed air of the first injection unit 10R and the first injection unit 10L are always the same and only the angle is adjusted, the third air flow 32 will be directed to the second injection unit 11 side. no problem.

Further, when the control unit 29 adjusts the injection flow rates of the first injection unit 10R and the first injection unit 10, the flow rate of the third air flow 32 in which the first air flow 30 and the second air flow 31 collide gradually increases. It is controlled to do. Specifically, when the maximum flow rate of the third airflow 32 is "100%", the control unit 29 sets the flow rate of the third airflow 32 to "20%", "40%", "60%", and "80". It is controlled to increase by 20% at regular intervals such as "%" and "100%". As a result, in the dust collector 2, as compared with the case where the third airflow 32 is blown to the dust collecting unit 9 at a constant flow rate (maximum flow rate) immediately after the start of cleaning, the dust collecting device 2 suppresses the rising of dust in the device and collects dust. Dust adhering to the portion 9 can be removed.

Then, in the ventilation system 40, when the preset time elapses, the control unit 29 turns off the rotary motor 18, closes the sluice valve 26 and the flow rate adjusting valve 28, and shifts to the ventilation mode.

As described above, in the dust collector 2 constituting the ventilation system 40, the ventilation mode and the cleaning mode are periodically switched, so that it is possible to prevent the dust from continuing to accumulate on the dust collecting portion 9, and the dust collecting performance is improved. It is possible to prevent lowering or clogging. Further, the backflow airflow generated by the second injection unit 11 can discharge the dust removed from the dust collecting unit 9 to the outdoor 42. This cleaning mode eliminates the need for the user or the like to take out the dust collecting unit 9 and manually clean it, so that the cleaning maintainability inside the device can be improved.

Further, the same first duct 5A can be used in both the ventilation mode and the cleaning mode. Since it is not necessary to install a separate duct in each mode, it can be a space-saving automatic cleaning mechanism.

As described above, according to the dust collecting device 2 and the ventilation system 40 using the dust collecting device 2 according to the first embodiment, the following effects can be enjoyed.

(1-1) The dust collector 2 is arranged between the dust collecting unit 9 that collects the dust contained in the air of the outdoor 42, the dust collecting unit 9, and the air outlet 8, and is directed toward the dust collecting unit 9. Second, which is arranged between the first injection unit 10 for blowing out compressed air and the first duct 5A communicating with the suction port 7 and the outdoor 42, and blows out the compressed air flowing toward the outdoor 42 in the first duct 5A. It is configured to include an injection unit 11 and a control unit 29 that controls the operations of the first injection unit 10 and the second injection unit 11. Then, when cleaning the dust collecting unit 9, the control unit 29 operates the first injection unit 10 and the second injection unit 11 to transfer the dust collected in the dust collecting unit 9 from the suction port 7 to the outdoor 42. It was controlled to discharge. As a result, the dust adhering to the dust collecting unit 9 can be removed by the compressed air injected from the first injection unit 10, and the removed dust is generated by the compressed air injected from the second injection unit 11. It is possible to discharge to the outdoor 42 by riding the flow toward the outdoor 42. That is, the dust collector 2 can be used to improve the cleaning maintainability inside the device.

(1-2) In the dust collector 2, the second injection unit 11 blows compressed air flowing toward the outdoor 42 into the first duct 5A to generate an attracting air flow from the suction port 7 toward the outdoor 42. I tried to make it. As a result, a flow rate larger than the flow rate of the compressed air injected from the second injection unit 11 can be generated, so that the dust removed by the compressed air injected from the first injection unit 10 can be more reliably sent to the outdoor 42. Can be discharged.

(1-3) In the dust collector 2, the second injection portion 11 is configured to have a ring-shaped second injection port 24 arranged so as to surround the suction port 7. As a result, the second injection unit 11 can blow compressed air into the first duct 5A without bias.

(1-4) In the dust collector 2, the second injection unit 11 is installed adjacent to the suction port 7. As a result, the dust collector 2 can be integrated with the dust collector 2, so that the device can be miniaturized.

(1-5) In the dust collector 2, the air outlet 8 is configured to communicate with a blower 3 for taking in the air of the outdoor 42 into the indoor 41 or a ventilation device having a blower 3. As a result, the ventilation system 40 can be used to purify the air in the outdoor 42 and supply it indoors.

(2-1) In the dust collector 2, when cleaning the dust unit 9, the first injection unit 10 and the second injection unit 11 are operated to collect the dust collected in the dust collection unit 9 outdoors from the suction port 7. It was made to be discharged to 42. Then, in the dust collector 2, the first injection unit 10 has a pair of nozzles (first injection unit 10R, first injection unit 10L) arranged so as to face each other with the airflow passage region of the dust collection unit 9 interposed therebetween. The first airflow 30 blown out from one of the nozzles (first injection unit 10R) and the second airflow 31 blown out from the other nozzle (first injection part 10L) collide with each other to collect dust. The third airflow 32 toward 9 was created. As a result, when the dust contained in the air introduced from the outdoor 42 is removed by the dust collecting unit 9 and sent out from the outlet 8 to the indoor 41, the airflow passing through the dust collecting unit 9 is the first injection unit. Since it does not directly hit the 10, it is possible to prevent dust from adhering to the first injection unit 10. Further, when cleaning the dust collecting portion 9, the third airflow 32 in which the first airflow 30 and the second airflow 31 collide is an injection flow in the direction opposite to the direction of the airflow flowing from the suction port 7 to the outlet 8. Therefore, the injection flow can be applied from the dust collecting unit 9 toward the suction port 7, and the dust adhering to the dust collecting unit 9 can be reliably removed.

(2-2) In the dust collector 2, the first injection unit 10 is used to generate a third air flow 32 so as to blow the dust collecting unit 9 in the direction perpendicular to the air flow passing surface 9a. As a result, the dust adhering to the dust collecting portion 9 can be effectively removed. Further, since the third airflow 32 containing the removed dust becomes a flow toward the suction port 7 (second injection unit 11) side, the soaring is suppressed in the apparatus, and the airflow is efficiently discharged from the suction port 7 to the outdoor 42. be able to.

(2-3) In the dust collector 2, each of the pair of nozzles (first injection unit 10R, first injection unit 10L) is configured to have a plurality of first injection ports 19 along the vertical vertical direction. , It is made rotatable around the central axis 20 in the vertical vertical direction. Thereby, the position where the first injection unit 10 sprays on the airflow passing surface 9a of the dust collecting unit 9 can be easily adjusted in the entire vertical vertical direction (vertical direction) and the horizontal direction of the dust collecting unit 9.

(2-4) In the dust collector 2, the control unit 29 rotates the central axis 20 to set the position where the first airflow 30 and the second airflow 31 collide with the side of the first injection unit 10L. It was controlled to move to and from the side of the injection unit 10R. As a result, the position where the third airflow 32 is generated is moved in the left-right direction of the dust collecting portion, so that the dust adhering to the dust collecting portion 9 can be reliably removed.

(2-5) In the dust collector 2, the air outlet 8 is configured to communicate with a blower 3 for taking in the air of the outdoor 42 into the indoor 41 or a ventilation device having a blower 3. As a result, the ventilation system 40 can be used to purify the air in the outdoor 42 and supply it indoors.

(3-1) In the dust collector 2, the control unit 29 operates the first injection unit 10 and the second injection unit 11 to transfer the dust collected in the dust collection unit 9 from the suction port 7 to the outdoor 42. At the time of discharge, the flow rate of the compressed air blown out from the first injection unit 10 is controlled to be gradually increased. As a result, it is possible to remove the dust adhering to the dust collecting unit 9 while suppressing the dust from flying up in the device, so that it is possible to prevent the dust from scattering to the indoor 41 side of the dust collecting unit 9. can.

(3-2) In the dust collector 2, a pair of nozzles (first injection unit 10R, first injection unit 10R, first injection unit 10R) are arranged so that the first injection unit 10 faces each other with the airflow passage region of the dust collection unit 9 interposed therebetween. 10L), the first airflow 30 blown from one of the nozzles (first injection section 10R) and the second airflow 31 blown from the other nozzle (first injection section 10L) are made to collide with each other. It was configured to generate a third airflow 32 toward the dust collector 9. Then, the control unit 29 controlled so as to gradually increase the flow rate of the third air flow 32. As a result, a third airflow 32 that is blown perpendicularly to the airflow passage surface 9a of the dust collecting portion 9 is generated, and the third airflow 32 containing the removed dust is directed to the suction port 7 (second injection portion 11) side. Since the flow is directed, the soaring up in the device is further suppressed, and the air can be efficiently discharged from the suction port 7 to the outdoor 42.

(3-3) In the dust collector 2, the second injection unit 11 blows compressed air flowing toward the outdoor 42 into the first duct 5A at a constant flow rate to attract the compressed air from the suction port 7 toward the outdoor 42. I tried to create an air flow. As a result, a flow rate larger than the flow rate of the compressed air injected from the second injection unit 11 can be generated, so that the dust removed by the compressed air injected from the first injection unit 10 can be more reliably sent to the outdoor 42. Can be discharged.

(3-4) In the dust collector 2, the air outlet 8 is configured to communicate with a blower 3 for taking in the air of the outdoor 42 into the indoor 41 or a ventilation device having a blower 3. As a result, the ventilation system 40 can be used to purify the air in the outdoor 42 and supply it indoors.

The present invention has been described above based on the embodiments. It will be appreciated by those skilled in the art that these embodiments are exemplary and that various variations of each of these components or combinations of processing processes are possible and that such modifications are also within the scope of the present invention. By the way.

In the dust collector 2 according to the present embodiment, the ventilation system 40 combined with the blower 3 is used, but the present invention is not limited to this. For example, the blower 3 may be a ventilation device equipped with a heat exchange element. As a result, air supply and exhaust can be performed at the same time, and when there is a temperature difference between the outdoor 42 and the indoor 41, the heat exchange element exchanges the heat contained in the air of the supply air and the exhaust, thereby the indoor 41. The temperature change can be minimized. At this time, the dust collector 2 is installed in the air passage on the air supply side.

Further, in the dust collector 2 according to the present embodiment, the second injection unit 11 is arranged adjacent to the suction port 7, but the present invention is not limited to this. For example, the second injection unit 11 may be arranged near the middle of the first duct 5A. Even with such an arrangement, the airflow from the indoor 41 to the outdoor 42 can be generated, so that the above-mentioned effect can be enjoyed. The position of the second injection portion 11 is not limited to the vicinity of the middle of the first duct 5A, and may be arranged anywhere between the suction port 7 and the outdoor hood 1.

Further, in the dust collector 2 according to the present embodiment, even if dust is accumulated on the bottom of the housing 6 near the air outlet 8, the first injection unit 10 is injected toward the air outlet 8. By making it possible to rotate the dust, the accumulated dust can be blown up. At this time, the dust that has been blown up can be discharged to the outdoor 42 by the backflow airflow toward the outdoor 42 side generated by the jet from the second injection unit 11.

Since the dust collector according to the present invention makes it possible to improve the cleaning maintainability inside the device, it is useful as an air purification device or the like used in a ventilation system.

1 Outdoor hood 2 Dust collector 3 Blower 4 Blow-off grill 5A 1st duct 5B 2nd duct 5C 3rd duct 6 Housing 7 Suction port 8 Blow-out 9 Dust collector 9a Air flow passage surface 10 1st injection part 10R 1st injection Part 10L 1st injection part 11 2nd injection part 12 Adapter 13 Electrode plate 14 Support 15 1st joint part 16 Pipe 17 Nozzle 18 Rotating motor 19 1st injection port 20 Central axis 21 2nd joint part 22 Outer cylindrical part 23 Cylindrical part 24 Second injection port 25 Compressor 26 Gate valve 27 Pressure reducing valve 28 Flow control valve 29 Control part 30 First airflow 31 Second airflow 32 Third airflow 40 Ventilation system 41 Indoor 42 Outdoor

Claims (5)

A dust collector that removes dust contained in the outdoor air sucked in from the suction port and sends it out from the air outlet.
A dust collecting unit that collects dust contained in the outdoor air,
A first injection section, which is arranged between the dust collecting section and the outlet and blows compressed air toward the dust collecting section,
A second injection unit that is arranged between the suction port and the duct that communicates with the outside and blows out compressed air that flows toward the outside into the duct.
A control unit that controls the operation of the first injection unit and the second injection unit,
With
When cleaning the dust collecting unit, the control unit operates the first injection unit and the second injection unit to discharge the dust collected in the dust collecting unit to the outside from the suction port. A dust collector characterized by being controlled to do so. The collection according to claim 1, wherein the second injection unit blows compressed air flowing toward the outside into the duct to generate an attracting air flow from the suction port toward the outside. Dust device. The dust collector according to claim 1 or 2, wherein the second injection unit is configured to have a ring-shaped injection port arranged so as to surround the suction port. The dust collector according to any one of claims 1 to 3, wherein the second injection unit is installed adjacent to the suction port. The dust collector according to any one of claims 1 to 5, wherein the air outlet communicates with a blower for taking in the outdoor air indoors or a ventilation device having the blower.

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