JP2011185579A - Blower - Google Patents

Abstract

A blower that eliminates the need for a separate suction device, reduces product cost, and reduces the size of the product.
A blower fan, a heat exchanger, and an air filter are attached to a casing. The first opening 31 of the bypass passage 30 opens between the blower fan 13 and the heat exchanger 12, and the second opening 32 of the bypass passage 30 is provided in the temporary storage portion 70 that stores the dust of the air filter 21. Open.
[Selection] Figure 2

Description

  The present invention relates to an air conditioner such as a wall-mounted type, a floor-standing type, and a ceiling-mounted type, and an air blower such as an air purifier.

  Conventionally, as an air conditioner as an example of a blower, an air filter that removes dust of air passing through a heat exchanger, a suction nozzle that can be driven along the air filter, and a suction connected to the suction nozzle There is a device provided with the device (see WO 2006/046409: Patent Document 1).

  However, in the conventional air conditioner, in order to suck dust adhering to the air filter from the suction nozzle, a suction device separate from the blower fan in the air conditioner is required. For this reason, there has been a problem that the product cost increases and the size of the product increases.

WO 2006/046409

  Accordingly, an object of the present invention is to provide a blower that eliminates the need for a separate suction device, reduces the product cost, and reduces the size of the product.

In order to solve the above problems, the blower of the present invention is
A casing,
A blower fan provided in the casing;
A pressure loss member provided in the casing so as to be positioned upstream of the blower fan;
An air filter provided in the casing so as to be located upstream of the pressure loss member;
One end is opened between the blower fan and the pressure loss member, and the other end is provided with a bypass passage that opens to a dust existing area in the casing.

  According to the blower device of the present invention, one end of the bypass passage opens between the blower fan and the pressure loss member, and the other end of the bypass passage opens into a dust existing area in the casing. By rotating the blower fan, a negative pressure is generated between the blower fan and the pressure loss member to make the inside of the bypass passage a negative pressure. And by this negative pressure, the dust of the dust presence area | region in a casing is conveyed in a bypass channel from the other end opening part of a bypass channel.

  Therefore, since dust is sucked using the blower fan, a separate suction device is not required, reducing the product cost and reducing the size of the product. In addition, since dust is carried by negative pressure, it is less likely to cause dust diffusion and leakage from the gap between dusts than to blow away by positive pressure, and can be collected by suction at one place.

  Moreover, in the air blower of one Embodiment, the dust collection part which collects dust is provided in the middle of the said bypass channel.

  According to the air blower of this embodiment, since the dust collecting part is provided in the middle of the bypass passage, dust can be collected in the dust collecting part and the dust can be easily collected.

  In one embodiment, a bypass filter is provided in the middle of the bypass passage.

  According to the air blower of this embodiment, since the bypass filter is provided in the middle of the bypass passage, dust in the bypass passage is prevented from leaking outside the bypass passage.

  Moreover, in the air blower of one Embodiment, the opening / closing mechanism which opens and closes this bypass channel is provided in the middle of the said bypass channel.

  According to the blower of this embodiment, since the opening / closing mechanism is provided in the middle of the bypass passage, the bypass passage is closed by the opening / closing mechanism when it is not necessary to remove the dust in the dust existing area. Air is prevented from flowing through the inside, and a decrease in the amount of air passing through the pressure loss member is prevented. Further, when the air blower is an air conditioner, during the cooling operation, the bypass passage is closed by the opening / closing mechanism, thereby preventing condensation on one end side of the bypass passage.

  Moreover, in the air blower of one Embodiment, the dust scattering prevention mechanism which prevents scattering of the dust collected in this bypass channel is provided in the middle of the said bypass channel.

  According to the air blower of this embodiment, since the dust scattering prevention mechanism is provided in the middle of the bypass passage, dust scattering in the bypass passage is prevented.

  Moreover, in the air blower of one Embodiment, the said bypass channel is located inside the side part of the said casing, or the vicinity of the side part of the said casing.

  According to the blower of this embodiment, since the bypass passage is located inside the side of the casing or in the vicinity of the side of the casing, the occupied area of the suction port on the front surface of the blower can be increased, A reduction in the intake air volume of the blower is prevented, and a reduction in the capacity of the blower is prevented.

  Moreover, in the air blower of one Embodiment, it has the space enclosed by the said pressure loss member and the said air blower fan, and the said one end of the said bypass channel opens in this space.

  According to the blower device of this embodiment, since the one end of the bypass passage is opened in a space surrounded by the pressure loss member and the blower fan, this space is a space that can secure the opening of one end of the bypass passage. Become. Moreover, in the said space, a negative pressure can be generate | occur | produced reliably.

  Moreover, in the air blower of one Embodiment, it has the cleaning member which removes the dust adhering to the said air filter, and the dust removed by this cleaning member is guide | induced to the said dust presence area | region.

  According to the blower of this embodiment, it has a cleaning member that removes dust adhering to the air filter, and the dust removed by the cleaning member is guided to the dust existing area, and thus removed by the cleaning member. The dust can be conveyed to the bypass passage by negative pressure, and the dust is prevented from staying in the dust existing area.

Moreover, in the air blower of one embodiment,
It temporarily stores the dust removed by the cleaning member and has a temporary storage unit corresponding to the dust existing area,
The other end of the bypass passage opens into the temporary storage unit.

  According to the blower of this embodiment, the dust removed by the cleaning member is temporarily stored and the temporary storage unit corresponding to the dust existing area is provided, and the other end of the bypass passage is the temporary storage unit. Therefore, the dust removed by the cleaning member is stored in the temporary storage unit and then sucked into the bypass passage. Therefore, almost all of the dust removed by the cleaning member can be sucked into the bypass passage.

  In addition, the temporary storage unit does not need to be configured to be removable as in the prior art to collect dust, and the temporary storage unit can be reduced in size. As a result, the occupation area of the temporary storage unit on the front surface of the blower can be reduced, and the occupation area of the suction port on the front surface of the blower can be increased. Accordingly, it is possible to prevent a reduction in the suction air volume of the blower and prevent a decrease in the capacity of the blower.

  Moreover, in the air blower of one Embodiment, the said cleaning member exists in the said dust presence area | region, and the said other end of the said bypass channel opens in the vicinity of the said cleaning member.

  According to the blower of this embodiment, the other end of the bypass passage opens in the vicinity of the cleaning member, so that the dust removed by the cleaning member is directly sucked into the bypass passage. Therefore, it is not necessary to provide a separate passage between the other end of the bypass passage and the cleaning member, and the apparatus can be downsized.

  In one embodiment, the other end of the bypass passage opens in the vicinity of the air filter corresponding to the dust existing area.

  According to the air blower of this embodiment, since the other end of the bypass passage opens in the vicinity of the air filter, dust of the air filter can be directly removed to the bypass passage by the action of negative pressure.

  According to the blower device of the present invention, one end of the bypass passage opens between the blower fan and the pressure loss member, and the other end of the bypass passage opens into a dust existing area in the casing. This eliminates the need for a separate suction device, reduces product costs, and reduces product size.

It is a disassembled perspective view of the air conditioner as 1st Embodiment of the air blower of this invention. It is a simplified sectional view of the air conditioner of FIG. It is explanatory drawing of an air conditioner. It is a simplified sectional view of the air harmony machine as a 2nd embodiment of the air blower of the present invention. It is a simplified sectional view of an air harmony machine as a 3rd embodiment of an air blower of the present invention. It is a simple perspective view of the air conditioner as 5th Embodiment of the air blower of this invention. It is a simplified sectional view of the air conditioner of FIG. It is a simplified sectional view of an air harmony machine as a 6th embodiment of an air blower of the present invention. It is a simplified sectional view of an air harmony machine as a 7th embodiment of an air blower of the present invention. It is a simplified sectional view of an air harmony machine as an 8th embodiment of an air blower of the present invention.

  Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments.

(First embodiment)
FIG. 1: has shown the disassembled perspective view of the air conditioner as 1st Embodiment of the air blower of this invention. FIG. 2 shows a simplified cross-sectional view of the air conditioner. In FIG. 2, for the sake of clarity, the cross section of the duct 3 is shown superimposed on the cross section of the casing 1 of the air conditioner.

  As shown in FIGS. 1 and 2, this air conditioner is a wall-hanging type air conditioner, and includes a main unit 10, a filter unit 20, a front grill 50, and a front panel 60.

  This air conditioner sucks indoor air from the openings on the front panel 60 and the front grill 50 and guides the sucked air to the main unit 10 through the front grill 50 and the filter unit 20 in this order. Then, air conditioning such as cooling, heating, and humidity control is performed in the main unit 10, and air is blown out from the air outlet 15 at the lower part of the main unit 10.

  The main body unit 10 includes a bottom frame 11, a heat exchanger 12 (as a pressure loss member), a blower fan 13, an electrical component box 14, and a duct 3 attached to the bottom frame 11.

  The blower fan 13 is, for example, a cross flow fan, and the heat exchanger 12 is located upstream of the air flow of the blower fan 13. The electrical component box 14 is located on the left and right sides of the bottom frame 11, and the duct 3 is located on the left and right sides of the bottom frame 11. Note that the duct 3 may be positioned in the vicinity of the side portion of the bottom frame 11. For example, when the duct 3 is provided on the electrical component box 14 side, the duct 3 is connected to the electrical component box 14 and the heat exchanger 12. Located between and.

  A flap 16 is swingably attached to the bottom frame 11, and the flap 16 opens and closes the air outlet 15 and adjusts the wind direction.

  The filter unit 20 includes an air filter 21, a brush 71 as a cleaning member, a temporary storage unit 70, and a pinion 23 as a transfer means.

  The air filter 21 is located on the upstream side (front side) of the air flow of the heat exchanger 12. The air filter 21 prevents dust (dust) floating in the air from contaminating the heat exchanger 12.

  The brush 71 scrapes and removes dust adhering to the air filter 21. The brush 71 is rotatably disposed in the temporary storage unit 70.

  The temporary storage unit 70 temporarily stores the dust removed by the brush 71. The temporary storage unit 70 corresponds to a dust presence area Z that is an area where dust exists. The temporary storage unit 70 may not be configured to be removable from the filter unit 20. For this reason, it is not necessary to collect the dust in a detachable configuration as in the prior art, and not only the structure of the temporary storage unit 70 can be simplified but also the size can be reduced. As a result, the occupation area of the temporary storage unit 70 on the front surface of the air conditioner can be reduced, and the occupation area of the suction port on the front surface of the air conditioner can be increased. Therefore, it is possible to prevent a reduction in the intake air volume of the air conditioner and to prevent a decrease in the capacity of the air conditioner.

  The pinion 23 moves the air filter 21 in order to perform cleaning to remove dust attached to the air filter 21. The pinion 23 meshes with a rack portion (not shown) provided in the air filter 21. Then, the air filter 21 is cleaned by bringing the air filter 21 into contact with the rotating brush 71 while traveling by the rotation of the pinion 23. Note that the detailed configuration is the same as that of JP-A-2008-57883, and is omitted.

  The front grill 50 is attached so as to cover the filter unit 20. The front panel 60 is attached so as to cover the front surface of the front grill 50 so as to be freely opened and closed. The bottom frame 11, the front grill 50 and the front panel 60 of the main unit 10 constitute a casing 1 of an air conditioner. In the casing 1, the heat exchanger 12, the blower fan 13, the air filter 21, the electrical component box 14, and the duct 3 are provided.

  The inside of the duct 3 constitutes a part of the bypass passage 30. The first opening 31 on one end side of the bypass passage 30 opens between the blower fan 13 and the heat exchanger 12. The second opening 32 on the other end side of the bypass passage 30 opens into the temporary storage part 70 (dust existing area Z). The first opening 31 is located above the second opening 32. The first opening 31 may be positioned below the second opening 32 or may be positioned at the same height as the second opening 32.

  As described above, the first opening 31 of the bypass passage 30 opens on the upstream side of the blower fan 13 and on the downstream side of the heat exchanger 12, so that the blower fan can be used during normal operation of the air conditioner. By the rotation of 13, a negative pressure is generated between the blower fan 13 and the heat exchanger 12, and the inside of the bypass passage 30 becomes a negative pressure. This negative pressure means that the air pressure in the space between the blower fan 13 and the heat exchanger 12 is lower than the air pressure in the space upstream of the heat exchanger 12.

  And the dust in the temporary storage part 70 is conveyed in the bypass channel 30 from the 2nd opening part 32 of the bypass channel 30 by this negative pressure. That is, in a normal air conditioning operation in which the flap 16 is opened and the blower fan 13 is rotated, air flows in the bypass passage 30 from the second opening 32 toward the first opening 31.

  In the middle of the bypass passage 30, a dust collecting unit 35 that collects dust is provided in the duct 3. The dust collection unit 35 is a resin case, for example, and is attached to the duct 3 so as to be detachable in the vertical direction. Therefore, dust is collected in the dust collecting unit 35, and the dust can be easily collected. A sealing material 41 that prevents air leakage is provided between the outer surface of the dust collecting unit 35 and the inner surface of the duct 3. For this reason, dust does not spill from between the outside of the dust collecting unit 35 and the inside of the duct 3. The dust collecting unit 35 may be fixed to the duct 3 with a screw or a claw. However, if the dust collecting unit 35 is fixed with a push-pull or slide-type attachment / detachment mechanism, the attachment / detachment becomes easy.

  The upper and lower portions of the dust collecting unit 35 are open, and the lower opening corresponds to the second opening 32. The upper opening communicates with the duct 3 (first opening 31). Therefore, the air flows in the dust collecting unit 35 from the lower opening to the upper opening. The interior of the dust collection unit 35 constitutes a part of the bypass passage 30.

  In the middle of the bypass passage 30, a bypass filter 36 is provided in the upper opening of the dust collecting unit 35. Therefore, the dust in the bypass passage 30 is prevented from leaking outside the bypass passage 30 by the bypass filter 36.

  The bypass filter 36 constitutes a part of the ceiling surface of the dust collecting unit 35. Therefore, dust adhering to the filter 36 can be easily removed, and the filter 36 can be prevented from being clogged. In addition, since the bottom of the dust collecting unit 35 where the dust accumulates and the filter 36 are separated from each other, the reattachment of the dust to the filter 36 can be prevented. Further, a vibrator 42 is provided in the vicinity of the bypass filter 36, and dust attached to the filter 36 is dropped by vibration of the vibrator 42.

  A shutter 37 serving as an opening / closing mechanism for opening and closing the bypass passage 30 is provided in the duct 3 in the middle of the bypass passage 30. The shutter 37 is located between the first opening 31 of the bypass passage 30 and the bypass filter 36. Therefore, when it is not necessary to remove the dust in the temporary storage unit 70, the shutter 37 closes the bypass passage 30 to prevent the air from flowing through the bypass passage 30 and the air volume passing through the heat exchanger 12 To prevent the loss of Further, during the cooling operation of the air conditioner, the bypass passage 30 is closed by the shutter 37, thereby preventing condensation on the first opening 31 side of the bypass passage 30.

  In the middle of the bypass passage 30, a wall 38 is provided in the dust collection unit 35 as a dust scattering prevention mechanism that prevents the dust collected in the dust collection unit 35 from scattering. The wall 38 is erected on the bottom of the dust collecting unit 35. The wall 38 partitions the inside of the dust collecting unit 35 into a dust storage space for storing dust and a suction passage including the second opening 32. The dust storage space and the suction passage communicate with each other at the upper portion, and the air flowing into the suction passage from the second opening 32 passes through the bypass filter 36 without passing through the dust storage space. Therefore, it becomes difficult for air to flow directly into the dust storage space, and scattering of dust accumulated in the dust storage space is prevented.

  The bypass passage 30 (the duct 3 and the dust collecting portion 35) is located inside the side portion of the casing 1. Therefore, the occupation area of the suction port on the front surface of the air conditioner can be increased, and the reduction of the intake air volume of the air conditioner can be prevented, and the deterioration of the performance of the air conditioner can be prevented. The bypass passage 30 may be positioned in the vicinity of the side portion of the casing 1. For example, when the bypass passage 30 is provided on the electrical component box 14 side, the bypass passage 30 is connected to the electrical component box 14 and heat. It is located between the exchanger 12.

  A space surrounded by the heat exchanger 12 and the blower fan 13 is provided, and the first opening 31 of the bypass passage 30 opens in this space. That is, the heat exchanger 12 is formed in an inverted V shape, and the space is formed between the V-shaped heat exchanger 12 and the blower fan 13 located on the downstream side of the heat exchanger 12. . Therefore, this space is a space in which the first opening 31 of the bypass passage 30 can be secured. Moreover, in the said space, a negative pressure can be generate | occur | produced reliably.

  Here, as shown in FIG. 3, the space A <b> 1 surrounded by the heat exchanger 12 and the blower fan 13 on the upper side of the blower fan 13, and the heat exchanger 12 and the blower on the lateral side (front side) of the blower fan 13. A case where the first opening 31 is provided in the reference space A2 between the fan 13 and the fan 13 will be compared. In FIG. 3, the space A1 and the reference space A2 are indicated by hatching.

  Since the space between the heat exchanger 12 and the blower fan 13 is small in the reference space A2, when the blower fan 13 is operated, the pressure in the reference space A2 is lower than the pressure in the space A1. For this reason, the amount of dust sucked by the bypass passage 30 increases when the first opening 31 is provided in the reference space A2.

  However, since the reference space A2 is small, the first opening 31 is provided in the immediate vicinity of the blower fan 13, and there is a problem that airflow is disturbed and noise is easily generated. Further, since the reference space A2 is small, there is a problem that it is difficult to provide the large first opening 31.

  Therefore, although the amount of suction is slightly less when the first opening 31 is provided in the space A1 than when the first opening 31 is provided in the reference space A2, the first opening 31 can be separated from the blower fan 13 to reduce noise. This is desirable because it is less likely to occur and a large space can be secured.

  According to the air conditioner having the above configuration, dust is sucked using the blower fan 13, so that a separate suction device is not required, and the product cost is reduced and the product is downsized. In addition, since dust is carried by negative pressure, it is less likely to cause dust diffusion and leakage from the gap between dusts than to blow away by positive pressure, and can be collected by suction at one place. On the other hand, since the blow-off by the positive pressure is configured to blow off dust attached to the filter, a mechanism for preventing the blown-off dust from being scattered is necessary, and the mechanism becomes complicated.

  Further, according to the air conditioner having the above configuration, the dust removed by the brush 71 is stored in the temporary storage unit 70 and then sucked into the bypass passage 30. Therefore, almost all of the dust removed by the brush 71 can be sucked into the bypass passage 30.

(Second Embodiment)
FIG. 4 shows an air conditioner as a second embodiment of the blower of the present invention. The difference from the first embodiment will be described. In the second embodiment, the configurations of the duct and the dust collecting unit are different. In the second embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 4, the lower portion of the duct 203 opens to the temporary storage portion 70, and this lower opening corresponds to the second opening 32. The dust collector 235 is open only at the top. The bypass filter 36 is attached to the upstream side of the shutter 37 in the duct 203, not the upper opening of the dust collection unit 235.

  The wall 238 as a dust scattering prevention mechanism is not provided at the bottom of the dust collection unit 235 but constitutes a part of the duct 203. The dust collecting unit 235 is detachably attached to the inside of the wall 238.

  The duct 203 has a suction passage including the second opening 32, and the air flowing into the suction passage from the second opening 32 passes through the bypass filter 36 without passing through the dust collection portion 235. .

  According to the air conditioner having the above configuration, the dust collecting unit 235 is not provided with the bypass filter 36 and the wall 238, so that the dust collecting unit 235 can be made compact and easy to handle.

(Third embodiment)
FIG. 5 shows an air conditioner as a third embodiment of the blower of the present invention. The difference from the first embodiment will be described. In the third embodiment, the configurations of the duct and the dust collecting unit are different. In the third embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 5, the dust collection part 335 is detachably attached to the lower part of the duct 303. The front and rear of the dust collection part 335 are opened, the front opening corresponds to the second opening 32, and the rear opening communicates with the duct 303 (first opening 31).

  A bypass filter 36 is attached to the rear opening of the dust collector 335, and a damper 338 as a scattering prevention mechanism is attached to the front opening of the dust collector 335. The damper 338 allows the front opening to be opened and closed. The damper 338 is set so as to be opened only when the dust in the temporary storage unit 70 is sucked into the bypass passage 30. When the dust is not sucked, the damper 338 is closed, and the dust in the dust collecting unit 335 is removed. The return to the temporary storage unit 70 is prevented again. That is, the damper 338 also plays a role of an opening / closing mechanism in addition to the dust scattering prevention mechanism. In this air conditioner, the vibrator 42 and the shutter 37 of the first embodiment are omitted.

  According to the air conditioner having the above configuration, the damper 338 also serves as an opening / closing mechanism in addition to the dust scattering prevention mechanism, so that the number of parts can be reduced and the size can be reduced.

(Fourth embodiment)
In the air conditioner as the fourth embodiment of the blower of the present invention, referring to FIG. 2, the temporary storage unit 70 is omitted, and the second opening 32 of the bypass passage 30 opens in the vicinity of the brush 71. Since other structures are the same as those of the first embodiment, description thereof is omitted.

  The second opening 32 is located directly below the brush 71 and sucks the dust removed by the brush 71 directly from the second opening 32 to the bypass passage 30. It can be said that the brush 71 is in the dust presence area Z.

  According to the air conditioner having the above configuration, it is not necessary to provide a separate passage between the second opening 32 of the bypass passage 30 and the brush 71, and the apparatus can be downsized.

(Fifth embodiment)
6 and 7 show an air conditioner as a fifth embodiment of the blower of the present invention. The difference from the first embodiment will be described. In the fifth embodiment, the configuration of the bypass passage is different. Since the other structure is the same as that of the first embodiment, the description thereof is omitted, and the same reference numerals as those of the first embodiment are the same as those of the first embodiment. The description is omitted.

  As shown in FIGS. 6 and 7, the second opening 32 of the bypass passage 30 is open in the vicinity of the air filter 21 corresponding to the dust existing area Z. More specifically, a suction nozzle 103 is connected to the duct 3 and the dust collecting unit 35 shown in FIG. The suction nozzle 103 is disposed on the upstream side of the front surface of the air filter 21 and moves to the left and right along the air filter 21. The suction nozzle 103 has a slit-like opening extending in the vertical direction on the surface facing the air filter 21, and the slit-like opening corresponds to the second opening 32.

  The blade 5 is attached to the suction nozzle 103, and when the suction nozzle 103 moves, the blade 5 comes into contact with the front surface of the air filter 21 and scrapes off the dust 4 adhering to the air filter 21. The dust 4 scraped off by the blade 5 is sucked into the bypass passage 30 inside the suction nozzle 103 from the second opening 32. In addition, since the detailed structure of this air conditioner is the same as that of Unexamined-Japanese-Patent No. 2008-14559, it abbreviate | omits.

  According to the air conditioner having the above configuration, the second opening 32 of the bypass passage 30 opens in the vicinity of the air filter 21, so that dust on the air filter 21 is directly removed to the bypass passage 30 by the action of negative pressure. it can.

  Note that the suction nozzle 103 may be configured to move vertically and horizontally along the air filter 21. Further, the blade 5 may be omitted, and the dust 4 may be sucked only by the second opening 32.

(Sixth embodiment)
FIG. 8 shows an air conditioner as a sixth embodiment of the blower of the present invention. If the point which is different from the said 1st Embodiment is demonstrated, in this 6th Embodiment, an air conditioner is a floor-standing type air conditioner. Note that in the sixth embodiment, the same portions as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 8, the air conditioner includes a casing 601, a blower fan 613 provided in the casing 601, a heat exchanger 612 (as a pressure loss member), and an air filter 621. In addition, since the detailed structure of this air conditioner is the same as that of Unexamined-Japanese-Patent No. 2007-183011, it abbreviate | omits.

  The blower fan 613 is a turbo fan, for example, and the heat exchanger 612 is located upstream of the air flow of the blower fan 613, and the air filter 621 is located upstream of the heat exchanger 612. . And air flows as shown by the arrow in the figure by the rotation of the blower fan 613.

  A duct 603 is attached to the inside of the side portion of the casing 601. A dust collecting unit 635 is attached to the duct 603 so as to be detachable forward. The duct 603 is attached with a bypass filter 36, a shutter 37 as an opening / closing mechanism, and a vibrator 42 similar to those in the first embodiment. In FIG. 8, the sealing material between the duct 603 and the dust collecting unit 635 is omitted.

  The first opening 31 which is an opening at one end of the duct 603 opens between the blower fan 613 and the heat exchanger 612. The opening at the other end of the duct 603 is connected to the suction duct 624, and the suction duct 624 is connected to the suction nozzle 623.

  The suction nozzle 623 is disposed on the upstream side of the front surface of the air filter 621, and moves up, down, left, and right along the air filter 621. The suction nozzle 623 has an opening on the surface facing the air filter 21, and this opening corresponds to the second opening 32. The second opening 32 opens near the air filter 621. The inside of the duct 603, the inside of the dust collecting unit 635, the inside of the suction duct 624, and the inside of the suction nozzle 623 constitute the bypass passage 30.

  When the air filter 621 is cleaned by the suction nozzle 623, a negative pressure is generated between the blower fan 613 and the heat exchanger 612 by the rotation of the blower fan 613, and the inside of the bypass passage 30 is made a negative pressure. Thus, the suction nozzle 623 is moved vertically and horizontally along the air filter 621, and the dust adhering to the air filter 621 is sucked into the bypass passage 30 from the second opening 32. The dust sucked into the bypass passage 30 is collected in the dust collecting unit 635 and collected.

  According to the air conditioner having the above configuration, dust is sucked using the blower fan 613, so that a separate suction device is not required, reducing the product cost and reducing the size of the product. In addition, since dust is carried by negative pressure, it is less likely to cause dust diffusion and leakage from the gap between dusts than to blow away by positive pressure, and can be collected by suction at one place. On the other hand, since the blow-off by the positive pressure is configured to blow off dust attached to the filter, a mechanism for preventing the blown-off dust from being scattered is necessary, and the mechanism becomes complicated.

  Further, since the second opening 32 of the bypass passage 30 opens in the vicinity of the air filter 621, dust of the air filter 621 can be directly removed to the bypass passage 30 by the action of negative pressure.

(Seventh embodiment)
FIG. 9 shows an air conditioner as a seventh embodiment of the blower of the present invention. The difference from the first embodiment will be described. In the seventh embodiment, the air conditioner is a ceiling embedded type air conditioner. Note that in the seventh embodiment, the same portions as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 9, the air conditioner includes a casing 701, a blower fan 713 provided in the casing 701, a heat exchanger 712 (as a pressure loss member), and an air filter 721. The detailed configuration of the air conditioner is the same as that of JP-A-7-243661, and is therefore omitted.

  The blower fan 713 is, for example, a cross flow fan, and the heat exchanger 712 is located upstream of the air flow of the blower fan 713, and the air filter 721 is located upstream of the heat exchanger 712. To do. Then, the air flows as shown by the arrows in the figure by the rotation of the blower fan 713.

  A duct 703 is attached to the inside of the side portion of the casing 701. A dust collector 735 is attached to the duct 703 so as to be detachable downward. The duct 703 is provided with a bypass filter 36, a shutter 37 as an opening / closing mechanism, and a vibrator 42 similar to those in the first embodiment. In FIG. 9, the sealing material between the duct 703 and the dust collecting unit 735 is omitted.

  The first opening 31 that is an opening at one end of the duct 703 opens between the blower fan 713 and the heat exchanger 712. The opening at the other end of the duct 703 is connected to the suction duct 724, and the suction duct 724 is connected to the suction nozzle 723.

  The suction nozzle 723 is disposed on the lower surface upstream side of the air filter 721 and moves forward, backward, left and right along the air filter 721. The suction nozzle 723 has an opening on the surface facing the air filter 21, and this opening corresponds to the second opening 32. The second opening 32 opens near the air filter 721. The inside of the duct 703, the inside of the dust collecting unit 735, the inside of the suction duct 724, and the inside of the suction nozzle 723 constitute the bypass passage 30.

  When the air filter 721 is cleaned by the suction nozzle 723, a negative pressure is generated between the blower fan 713 and the heat exchanger 712 by the rotation of the blower fan 713, and the inside of the bypass passage 30 is made a negative pressure. Thus, the suction nozzle 723 is moved back and forth and right and left along the air filter 721, and the dust adhering to the air filter 721 is sucked into the bypass passage 30 from the second opening 32. The dust sucked into the bypass passage 30 is collected in the dust collection unit 735 and collected.

  According to the air conditioner having the above-described configuration, dust is sucked using the blower fan 713, so that a separate suction device is not required, reducing the product cost and reducing the size of the product. In addition, since dust is carried by negative pressure, it is less likely to cause dust diffusion and leakage from the gap between dusts than to blow away by positive pressure, and can be collected by suction at one place. On the other hand, since the blow-off by the positive pressure is configured to blow off dust attached to the filter, a mechanism for preventing the blown-off dust from being scattered is necessary, and the mechanism becomes complicated.

  Further, since the second opening 32 of the bypass passage 30 opens in the vicinity of the air filter 721, dust of the air filter 721 can be directly removed to the bypass passage 30 by the action of negative pressure.

(Eighth embodiment)
FIG. 10 shows an air cleaner as an eighth embodiment of the blower of the present invention. If the point which is different from the said 1st Embodiment is demonstrated, in this 8th Embodiment, an air cleaner is a floor-standing type air cleaner. In the eighth embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 10, the air cleaner includes a casing 801, a blower fan 813 provided in the casing 801, an air cleaning unit 812 (as a pressure loss member), and an air filter 821. In addition, since the detailed structure of this air cleaner is the same as that of Unexamined-Japanese-Patent No. 2009-248031, it abbreviate | omits.

  The air blowing fan 813 is, for example, a turbo fan, and the air cleaning unit 812 is located upstream of the air flow of the air blowing fan 813, and the air filter 821 is located upstream of the air cleaning unit 812. . Then, the air flows as shown by the arrows in the figure by the rotation of the blower fan 813.

  A duct 803 is attached to the inside of the side portion of the casing 801. A dust collecting unit 835 is attached to the duct 803 so as to be detachable forward. The duct 803 is attached with a bypass filter 36, a shutter 37 as an opening / closing mechanism, and a vibrator 42 similar to those in the first embodiment. In FIG. 10, the sealing material between the duct 803 and the dust collection unit 835 is omitted.

  The first opening 31 that is an opening at one end of the duct 803 opens between the blower fan 813 and the air cleaning unit 812. The opening at the other end of the duct 803 is connected to the suction duct 824, and the suction duct 824 is connected to the suction nozzle 823.

  The suction nozzle 823 is arranged on the upstream side of the front surface of the air filter 821 and moves up and down and left and right along the air filter 821. The suction nozzle 823 has an opening on the surface facing the air filter 21, and this opening corresponds to the second opening 32. The second opening 32 opens near the air filter 821. The inside of the duct 803, the inside of the dust collecting unit 835, the inside of the suction duct 824, and the inside of the suction nozzle 823 constitute the bypass passage 30.

  When the air filter 821 is cleaned by the suction nozzle 823, a negative pressure is generated between the blower fan 813 and the air cleaning unit 812 by the rotation of the blower fan 813, and the inside of the bypass passage 30 is set to a negative pressure. Thus, the suction nozzle 823 is moved vertically and horizontally along the air filter 821, and the dust adhering to the air filter 821 is sucked into the bypass passage 30 from the second opening 32. The dust sucked into the bypass passage 30 is collected in the dust collecting unit 835 and collected.

  According to the air cleaner having the above-described configuration, dust is sucked using the blower fan 813, so that a separate suction device is not required, reducing the product cost and reducing the size of the product. In addition, since dust is carried by negative pressure, it is less likely to cause dust diffusion and leakage from the gap between dusts than to blow away by positive pressure, and can be collected by suction at one place. On the other hand, since the blow-off by the positive pressure is configured to blow off dust attached to the filter, a mechanism for preventing the blown-off dust from being scattered is necessary, and the mechanism becomes complicated.

  Further, since the second opening 32 of the bypass passage 30 opens in the vicinity of the air filter 821, the dust of the air filter 821 can be directly removed to the bypass passage 30 by the action of negative pressure.

  In addition, this invention is not limited to the above-mentioned embodiment. For example, the feature points of the first to eighth embodiments may be variously combined.

  Moreover, the mechanism which moves an air filter and cleans an air filter is a mechanism currently disclosed by Unexamined-Japanese-Patent No. 2007-1000097, Unexamined-Japanese-Patent No. 2008-185331, Unexamined-Japanese-Patent No. 2008-057923, etc., for example. It may be. Further, a mechanism for moving the suction nozzle (second opening of the bypass passage) to clean the air filter is a mechanism disclosed in, for example, WO 2006/046409, JP 2008-057864 A, or the like. May be. Further, the air filter may be cleaned by moving both the air filter and the suction nozzle.

  In addition to the air filter, the dust suction area (dust-existing area) includes a heat exchanger, a desiccant rotor, a humidifying filter, an air cleaning unit, and a casing (such as a panel). Alternatively, dust adhering to these members may be sucked by the bypass passage.

  In addition to the space surrounded by the heat exchanger and the blower fan, the position of the first opening of the bypass passage is the downstream side of the heat exchanger and the upstream side of the blower fan. Any space between them may be used.

  The dust collecting unit may be fixed to the duct so as not to be detached. In addition, the dust collection unit may be a dust box, a disposable container or a bag, or a vacuum cleaner nozzle that can remove dust by suction.

  Further, the cleaning member may be a blade in addition to the brush. In addition to the shutter, a damper or the like may be used as the opening / closing mechanism. In addition to the wall, a damper or the like may be used as the dust scattering prevention mechanism. Further, the dust collecting unit, the bypass filter, the opening / closing mechanism (for example, a shutter) and the dust scattering prevention mechanism (for example, a wall) may be omitted.

1,601,701,801 Casing 3,203,303,603,703,803 Duct 12,612,712 Heat exchanger (pressure loss member)
812 Air purification unit (pressure loss member)
13, 613, 713, 813 Blower fan 21, 621, 721, 821 Air filter 30 Bypass passage 31 First opening 32 Second opening 35, 235, 335, 635, 735, 835 Dust collection part 36 Bypass filter 37 Shutter (open / close mechanism)
38,238 Wall (Dust scattering prevention mechanism)
338 Damper (Dust scattering prevention mechanism)
70 Temporary storage part 71 Brush (cleaning member)
103, 623, 723, 823 Suction nozzle Z Dust existing area

Claims (11)

A casing,
A blower fan provided in the casing;
A pressure loss member provided in the casing so as to be positioned upstream of the blower fan;
An air filter provided in the casing so as to be located upstream of the pressure loss member;
An air blower comprising: a bypass passage having one end opened between the blower fan and the pressure loss member and the other end opened to a dust existing area in the casing. The blower device according to claim 1,
A blower characterized in that a dust collecting part for collecting dust is provided in the middle of the bypass passage. In the air blower according to claim 1 or 2,
A blower characterized in that a bypass filter is provided in the middle of the bypass passage. In the air blower according to any one of claims 1 to 3,
An air blower characterized in that an opening / closing mechanism for opening and closing the bypass passage is provided in the middle of the bypass passage. In the air blower according to any one of claims 1 to 4,
An air blower characterized in that a dust scattering prevention mechanism for preventing scattering of dust accumulated in the bypass passage is provided in the middle of the bypass passage. In the air blower according to any one of claims 1 to 5,
The blower characterized in that the bypass passage is located inside a side portion of the casing or in the vicinity of the side portion of the casing. In the air blower according to any one of claims 1 to 6,
A blower comprising a space surrounded by the pressure loss member and the blower fan, wherein the one end of the bypass passage is opened in the space. In the air blower according to any one of claims 1 to 7,
An air blower comprising a cleaning member for removing dust adhering to the air filter, and the dust removed by the cleaning member is guided to the dust existing area. In the air blower according to claim 8,
It temporarily stores the dust removed by the cleaning member and has a temporary storage unit corresponding to the dust existing area,
The blower characterized in that the other end of the bypass passage opens into the temporary storage section. In the air blower according to claim 8,
The air blower characterized in that the cleaning member is in the dust existing area, and the other end of the bypass passage opens in the vicinity of the cleaning member. In the air blower according to any one of claims 1 to 7,
The blower characterized in that the other end of the bypass passage opens in the vicinity of the air filter corresponding to the dust existing area.

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