JP2021042864A - Blower - Google Patents

Abstract

To provide a blower capable of adjusting a blowing direction of an air flow without using a movable louver.SOLUTION: In a blower 10, a first air outlet 12 is formed on a front surface 11a of a housing 11 in a slit shape, and a first air flow 21 is blown toward a first side 11a along the front surface 11a. A second air outlet 13 is formed on a bottom surface 11b of the housing 11 in a slit-shape, and a second air flow 22 is blown toward the first side 11c along the bottom surface 11b. The volume of air blown from the first air outlet 12 is adjusted by a first damper 19, and the volume of air blown from the second air outlet 13 is adjusted by a second damper 20. The first air flow 21 and the second air flow 22 whose volumes of air are adjusted, collide with each other near the first side 11c, thereby sending a third air flow 23 toward a direction separating from the first side 11c.SELECTED DRAWING: Figure 2

Description

The present invention relates to a blower device, and more particularly to a blower device capable of adjusting the blowing direction of an air flow.

A conventional air conditioner has a movable louver at the airflow outlet, and the direction of the airflow blown from the airflow is changed by changing the angle of the louver (for example, Patent Document 1). ..

Japanese Unexamined Patent Publication No. 6-193900

However, the movable louver cannot be moved vertically downward or horizontally, and has a problem that the blowing range of the airflow blown out from the outlet is limited to less than 90 degrees.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a blower device capable of adjusting the blowing direction of an air flow without using a movable louver.

In order to achieve this object, the blower device of the present invention includes a housing, a first air outlet, a second air outlet, a first air volume adjusting unit, and a second air volume adjusting unit. The first air outlet is formed on the first surface of the housing, and blows the first airflow toward the first side of the housing along the first surface. The second air outlet is formed on the second surface of the housing which is in contact with the first surface on the first side, and blows the second airflow toward the first side along the second surface. The first air volume adjusting unit adjusts the air volume of the first air flow blown out from the first air outlet. The second air volume adjusting unit adjusts the air volume of the second airflow blown out from the second air outlet. The direction in which the first airflow whose airflow is adjusted by the first airflow adjusting unit and the second airflow whose airflow is adjusted by the second airflow adjusting unit collide with each other in the vicinity of the first side and are separated from the first side. A third airflow is sent toward.

According to the blower device of the present invention, the blowing direction of the airflow can be adjusted without using a movable louver.

FIG. 1 is a schematic configuration diagram of a blower device according to an embodiment of the present invention. FIG. 2 is a schematic cross-sectional view of the cross section of the blower as viewed from the left side. FIG. 3 is a control block diagram of the blower. FIG. 4A is a schematic view schematically showing the opening degrees of the first damper and the second damper when the airflow is sent out from the first side of the blower in the vertical direction, and is FIG. 4B. ) Is a schematic view schematically showing the opening degrees of the first damper and the second damper when the airflow is sent out from the first side of the blower in the horizontal direction.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the accompanying drawings. It should be noted that all of the embodiments described below show a preferred specific example of the present invention. Therefore, the numerical values, shapes, materials, components, arrangement positions of the components, connection forms, and the like shown in the following embodiments are examples and are not intended to limit the present invention. Therefore, among the components in the following embodiments, the components not described in the independent claims indicating the highest level concept of the present invention will be described as arbitrary components. Further, in each figure, substantially the same configuration is designated by the same reference numerals, and duplicate description will be omitted or simplified.

First, the schematic configuration of the blower 10 according to the embodiment of the present invention will be described with reference to FIGS. 1 to 3. FIG. 1 is a schematic perspective view of the blower device 10. FIG. 2 is a schematic cross-sectional view of the blower device 10 as viewed from the left side. FIG. 3 is a control block diagram of the blower device 10. In the following description, the surface of the blower 10 as seen from the arrow F shown in FIG. 1, that is, the surface on which the first outlet 12 described later is provided will be described as the front surface 11a.

The blower device 10 is a device having a rectangular housing 11 and sending out a third air flow 23 in a direction away from the first side 11c of the housing 11. Specifically, it is as follows.

The housing 11 of the blower 10 is provided with a first outlet 12 formed in a slit shape on the front surface 11a side, and is formed in a slit shape on the bottom surface 11b side in contact with the front surface 11a at the first side 11c. Two outlets 13 are provided. In the first outlet 12 and the second outlet 13, the long side of the slit is formed along the first side 11c, respectively. Further, the front surface 11a and the bottom surface 11b are substantially orthogonal to each other on the first side 11c. The front surface 11a corresponds to the first surface of the present invention, and the bottom surface 11b corresponds to the second surface of the present invention.

The first air outlet 12 is an air outlet that blows out the first airflow 21 toward the first side 11c of the housing 11 along the front surface 11a. The second air outlet 13 is an air outlet that blows out the second airflow 22 toward the first side 11c of the housing 11 along the bottom surface 11b.

Here, the first outlet 12 and the second outlet so that the distance from the first outlet 12 to the first side 11c and the distance from the second outlet 13 to the first side 11c are substantially the same. The outlet 13 is formed. Here, substantially the same distance means that the strength of the first airflow 21 on the first side 11c and the strength of the second airflow 22 when the same amount of airflow is blown out from the first outlet 12 and the second outlet 13. It is a distance that is about the same as strength.

Suction ports 14 are provided on the upper surface (flat surface), the right side surface, the left side surface, and the back surface of the housing 11, respectively. Further, a scroll casing 16 is provided inside the housing 11, and a blower fan 15 is provided inside the scroll casing 16. The blower fan 15 is composed of, for example, a sirocco fan.

The air sucked from the suction port 14 is supplied to the inside of the blower fan 15. Further, a motor (not shown) for rotating the blower fan 15 is connected to the blower fan 15, and by rotating the motor, the blower fan 15 rotates clockwise in FIG. 2. As a result, the air supplied to the inside of the blower fan 15 is blown out from the inside of the blower fan 15 to the outside, and in FIG. 2, the air around the right in the space formed between the scroll casing 16 and the blower fan 15. Flow occurs.

Inside the housing 11, a first air guide path 17 communicating with the first air outlet 12 is connected to the outer periphery of the scroll casing 16. The first air guide path 17 guides air from the scroll casing 16 to the first air outlet 12. The first air guide path 17 is provided parallel to the bottom surface 11b from the scroll casing 16 to the middle of the first air outlet 12. Then, the first air guide path 17 is located on the first side in the vicinity of the first air outlet 12 so that the first airflow 21 from the first air outlet 12 is blown toward the first side 11c along the front surface 11a. It is bent toward the 11c side.

Further, inside the housing 11, a second air guide path 18 communicating with the second air outlet 13 is connected to the outer periphery of the scroll casing 16. The second air guide path 18 guides air from the scroll casing 16 to the second air outlet 13. The second air guide path 18 is provided parallel to the front surface 11a from the scroll casing 16 to the middle of the second air outlet 13. Then, the second air guide path 18 is located near the second outlet 13 on the first side so that the second airflow 22 from the second outlet 13 is blown out toward the first side 11c along the bottom surface 11b. It is bent toward the 11c side.

A first damper 19 is provided at the connection point between the scroll casing 16 and the first air guide path 17, and a second damper 20 is provided at the connection point between the scroll casing 16 and the second air guide path 18. There is.

The first damper 19 adjusts the air volume of the air guided from the scroll casing 16 to the first air guide path 17, and corresponds to the first air volume adjusting unit of the present invention. That is, when the opening degree of the first damper 19 is increased, the air volume of air guided from the scroll casing 16 to the first air guide path 17 increases, and when the opening degree of the first damper 19 is decreased, the scroll casing 16 to the first (1) The air volume of the air guided to the air guide path 17 is reduced.

Since the first air guide path 17 communicates with the first air outlet 12 as described above, the air volume guided to the first air guide 17 is adjusted to blow out from the first air outlet 12. The air volume of the first airflow 21 is adjusted. That is, it can be said that the first damper 19 adjusts the air volume of the first airflow 21 blown out from the first outlet 12.

The second damper 20 adjusts the air volume of the air guided from the scroll casing 16 to the second air guide path 18, and corresponds to the second air volume adjusting unit of the present invention. That is, when the opening degree of the second damper 20 is increased, the air volume of air guided from the scroll casing 16 to the second air guide path 18 increases, and when the opening degree of the second damper 20 is decreased, the scroll casing 16 to the second (Ii) The air volume of the air guided to the air guide path 18 is reduced.

Since the second air guide passage 18 communicates with the second outlet 13 as described above, the air volume guided to the second air guide passage 18 is adjusted to blow out from the second outlet 13. The air volume of the second airflow 22 to be generated will be adjusted. That is, it can be said that the second damper 20 adjusts the air volume of the second airflow 22 blown out from the second outlet 13.

The housing 11 is provided with a control unit 30. As shown in FIG. 3, the control unit 30 is connected to the blower fan 15 and controls the rotational operation of the blower fan 15. Further, the control unit 30 is connected to the first damper 19 and the second damper 20, and controls the opening degree of the first damper 19 and the opening degree of the second damper 20. The control unit 30 controls the rotational operation of the blower fan 15, the opening degree of the first damper 19, and the opening degree of the second damper 20, so that the air volume of the first airflow 21 blown out from the first air outlet 12 And the air volume of the second airflow 22 blown out from the second outlet 13, and as described later, the direction in which the third airflow 23 separates from the first side 11c is controlled.

Subsequently, the operation of the blower device 10 configured as described above will be described with reference to FIGS. 2 to 4. FIG. 4A is a schematic view schematically showing the opening degrees of the first damper 19 and the second damper 20 when the third airflow 23 is sent out from the first side 11c of the blower device 10 in the vertical direction. Is. FIG. 4B is a schematic view schematically showing the opening degrees of the first damper 19 and the second damper 20 when the third airflow 23 is sent out from the first side 11c of the blower device 10 in the horizontal direction. Is.

In the blower device 10, in FIG. 2, when the motor connected to the blower fan 15 is driven, the blower fan 15 rotates clockwise. As a result, air is supplied from the suction port 14 to the inside of the blower fan 15, and the air supplied to the inside of the blower fan 15 is blown out from the inside to the outside of the blower fan 15. Then, the air blown out from the blower fan 15 generates a right-handed air flow in the space formed between the scroll casing 16 and the blower fan 15.

A part of the air flow generated as described above is guided to the first air guide path 17 via the first damper 19, and is guided to the second air guide path 18 via the second damper 20. Then, the air guided to the first air guide path 17 is blown out from the first air outlet 12 as the first air flow 21 and from the second air outlet 13 as the second air flow 22.

Here, as described above, the first air guide path 17 is bent from the state parallel to the bottom surface 11b toward the first side 11c near the first outlet 12, so that the first air guide 12 is bent from the first outlet 12. The first airflow 21 is blown out toward the first side 11c along the front surface 11a. The first airflow 21 blown out from the first air outlet 12 is attracted by the Coanda effect (a negative pressure region is generated between the first airflow 21 and the front surface 11a, and the first airflow 21 is attracted to the negative pressure region side. It flows along the front surface 11a due to the phenomenon).

Further, since the second air guide path 18 is bent toward the first side 11c side near the second outlet 13 from a state parallel to the front surface 11a, the second air guide path 18 is bent from the second outlet 13 along the bottom surface 11b. The second airflow 22 is blown toward the first side 11c. The second airflow 22 blown out from the second outlet 13 flows along the bottom surface 11b due to the attraction phenomenon due to the Coanda effect.

The first airflow 21 blown out from the first outlet 12 and the second airflow 22 blown out from the second outlet 13 collide with each other in the vicinity of the first side 11c and move away from the first side 11c. The three airflows 23 are formed. At this time, the third airflow 23 is sent out in a direction away from the first side 11c at an elevation angle (an angle formed with the bottom surface 11b) according to the airflow of the first airflow 21 and the airflow of the second airflow 22.

For example, as shown in FIG. 2, when the opening degree of the first damper 19 is set to “medium” and the opening degree of the second damper 20 is set to “medium” under the control of the control unit 30, the first air guide path 17 Air is guided to the second air guide passage 18 and the second air guide passage 18 with the same air volume. That is, the air volume of the first air flow 21 blown out from the first air outlet 12 and the air volume of the second air flow 22 blown out from the second air outlet 13 are about the same.

Since the distance from the first outlet 12 to the first side 11c and the distance from the second outlet 13 to the first side 11c are substantially the same, the strength of the first airflow 21 at the first side 11c ( The air volume) and the strength (air volume) of the second air flow 22 are about the same. Therefore, in the blower device 10, the first airflow 21 and the second airflow 22 having the same strength collide with each other in the vicinity of the first side 11c, so that the third airflow 23 is in the direction of an elevation angle of 45 degrees from the first side 11c. Is sent.

Further, as shown in FIG. 4A, when the opening degree of the first damper 19 is set to "large" and the opening degree of the second damper 20 is set to "small" by the control of the control unit 30, the first air Air is guided to the guide path 17 with a large air volume, and air is guided to the second air guide path 18 with a small air volume. That is, the air volume of the first airflow 21 blown out from the first outlet 12 becomes large, and the airflow of the second airflow 22 blown out from the second airflow port 13 becomes small. As a result, the strength (air volume) of the first airflow 21 increases and the strength (air volume) of the second airflow 22 decreases even on the first side 11c. Therefore, in the blower device 10, the strong first airflow 21 and the weak second airflow 22 collide with each other in the vicinity of the first side 11c, so that the third side is in the direction of an elevation angle of 90 degrees from the first side 11c, that is, in the substantially vertical direction. The air flow 23 is sent out.

When the second damper 20 is completely closed and the air volume of the second airflow 22 blown out from the second outlet 13 is set to 0, the first airflow 21 blown out from the first outlet 12 has a first side 11c. The elevation angle of the third airflow 23, which is caught in the bottom surface 11b side in the vicinity and is sent from the first side 11c, exceeds 90 degrees. Therefore, when the third airflow 23 is sent out in the vertical direction from the first side 11c, it is preferable to blow out the second airflow 22 having a weak air volume from the second outlet 13.

Further, as shown in FIG. 4B, when the opening degree of the first damper 19 is set to "small" and the opening degree of the second damper 20 is set to "large" by the control of the control unit 30, the first air Air is guided to the guide path 17 with a small air volume, and air is guided to the second air guide path 18 with a large air volume. That is, the air volume of the first airflow 21 blown out from the first outlet 12 becomes small, and the airflow of the second airflow 22 blown out from the second airflow port 13 becomes large. As a result, the strength (air volume) of the first airflow 21 is reduced and the strength (air volume) of the second airflow 22 is increased even on the first side 11c. Therefore, in the blower device 10, the weak first airflow 21 and the strong second airflow 22 collide with each other in the vicinity of the first side 11c, so that the third side is in the direction of 0 degree elevation angle from the first side 11c, that is, in the substantially horizontal direction. The air flow 23 is sent out.

When the first damper 19 is completely closed and the air volume of the first airflow 21 blown out from the first outlet 12 is set to 0, the second airflow 22 blown out from the second outlet 13 has a first side 11c. The elevation angle of the third airflow 23, which is caught in the front 11a side in the vicinity and is sent from the first side 11c, is lower than 0 degrees (upward). Therefore, when the third airflow 23 is sent out in the horizontal direction from the first side 11c, it is preferable to blow out the first airflow 21 having a weak air volume from the first outlet 12.

In this way, in the blower device 10, the first airflow 21 whose air volume is adjusted by the first damper 19 and the second airflow 22 whose air volume is adjusted by the second damper 20 collide with each other in the vicinity of the first side 11c. As a result, the third airflow 23 is sent out in a direction away from the first side 11c. At this time, the control unit 30 of the blower device 10 controls the adjustment of the air volume of the first air flow 21 by the first damper 19 and the adjustment of the air volume of the second air flow 22 by the second damper 20, and the third air flow 23. Controls the direction away from the first side 11c within a predetermined air flow range.

As described above, according to the blower device 10 of the present invention, the first air outlet 12 is formed on the front surface 11a of the housing 11, and the first airflow 21 is blown out toward the first side 11c along the front surface 11a. Further, a second air outlet 13 is formed on the bottom surface 11b of the housing 11, and the second airflow 22 is blown out along the bottom surface 11b toward the first side 11c. Then, the blower device 10 adjusts the air volume of the first airflow 21 blown out from the first air outlet 12 and the air volume of the second airflow 22 blown out from the second air outlet 13, so that the first side 11c The third airflow 23 can be sent out within a predetermined blowing range in a direction away from the airflow. That is, the blower device 10 can adjust the blowing direction of the third airflow 23 without using the movable louver required in the conventional sending device.

Further, the blower device 10 adjusts the air volume of the first air flow 21 blown from the first air outlet 12 and the air volume of the second air flow 22 blown from the second air outlet 13 to obtain an elevation angle (bottom surface 11b). The third airflow 23 can be sent out in a direction away from the first side 11c within a blowing range of at least 90 degrees. That is, it is possible to realize the blower device 10 in which the blower range of the airflow to be blown out is wider than that of the conventional blower device using the movable louver.

In addition, the movable louver required for the conventional blower requires a large opening as the outlet, so the presence of the outlet is conspicuous and the view of nature due to the blow is visually hindered. There was a problem. On the other hand, in the blower device 10, since the opening itself does not exist in the vicinity of the first side 11c to which the third airflow 23 is sent, it is possible to blow the air with a feeling of nature. Further, since the first outlet 12 and the second outlet 13 are also slit-shaped openings, the openings of the outlets can be further made inconspicuous, and the natural feeling of blowing air can be further enhanced.

The blower 10 can be installed on the ceiling surface of the room or turned upside down and installed on the floor surface. In this case, the suction port 14 provided on the upper surface (flat surface). Is blocked. Further, it is also possible to attach the back side of the blower 10 to the ceiling surface or the floor surface, and in this case, the suction port 14 provided on the back surface is closed. Further, in the blower device 10, the housing 11 is formed in a rectangular parallelepiped shape, and a plurality of blower devices 10 can be installed side by side in the left-right direction. In this case, the suction device 10 is provided on the right side surface or the left side surface. The mouth 14 may be blocked. However, since the air blower 10 is provided with the suction ports 14 on the upper surface (flat surface), the left side surface, the right side surface, and the back surface, it is possible to prevent at least one of the suction ports 14 from being blocked from the outside. Air can be reliably sucked into the blower 10.

Although the present invention has been described above based on the embodiments, the present invention is not limited to the above embodiments, and it is easy to make various improvements and modifications within a range that does not deviate from the gist of the present invention. It can be inferred. For example, each embodiment may be added by adding a part or a plurality of parts of the configuration of another embodiment to the embodiment or exchanging a part or a plurality of parts of the structure of the embodiment with each other. The embodiment may be modified to form the configuration. Further, the numerical values given in each of the above embodiments are examples, and it is naturally possible to adopt other numerical values.

In the above embodiment, the first air guide path 17 is located near the first outlet 12 so that the first airflow 21 from the first outlet 12 is blown toward the first side 11c along the front surface 11a. It is formed by being bent toward the first side 11c side. Further, the second air guide path 18 is provided on the first side near the second outlet 13 so that the second airflow 22 from the second outlet 13 is blown out toward the first side 11c along the bottom surface 11b. It is bent toward the 11c side. Instead of or in addition to this, the first airflow 21 from the first outlet 12 is fixed in the vicinity of the first outlet 12 so as to be blown toward the first side 11c along the front surface 11a. An expression louver may be provided. Further, a fixed louver may be provided near the second outlet 13 so that the second airflow 22 from the second outlet 13 is blown out toward the first side 11c along the bottom surface 11b. This also makes it possible to construct a blower device that can realize a wide blower range.

The blower according to the present invention is useful as a blower capable of adjusting the direction of the airflow to be sent without using a movable louver. For example, a blower with a scent function that adds an aromatic component to the airflow. Can be used for.

10 Blower 11 Housing 11a Front 11b Bottom 11c First side 12 First air outlet 13 Second air outlet 14 Suction port 15 Air fan 16 Scroll casing 17 First air guide path 18 Second air guide path 19 First damper 20 2nd damper 21 1st airflow 22 2nd airflow 23 3rd airflow 30 Control unit

Claims (4)

With the housing
A first air outlet formed on the first surface of the housing and blowing a first airflow toward the first side of the housing along the first surface.
A second air outlet formed on the second surface of the housing which is in contact with the first surface at the first side and blows out a second air flow toward the first side along the second surface.
A first air volume adjusting unit that adjusts the air volume of the first air flow blown out from the first air outlet, and
A second air volume adjusting unit for adjusting the air volume of the second air flow blown out from the second air outlet is provided.
The first airflow whose airflow is adjusted by the first airflow adjusting unit and the second airflow whose airflow is adjusted by the second airflow adjusting unit collide with each other in the vicinity of the first side. A blower that sends out a third airflow in a direction away from the first side. The blower according to claim 1, wherein the first outlet and the second outlet are formed in a slit shape along the first side. The direction in which the third airflow is separated from the first side by controlling the adjustment of the airflow of the first airflow by the first airflow adjusting unit and the adjustment of the airflow of the second airflow by the second airflow adjusting unit. The blower according to claim 1 or 2, further comprising a control unit for controlling the above. The first outlet and the second outlet are formed so that the distance from the first outlet to the first side and the distance from the second outlet to the first side are substantially the same. The blower according to any one of claims 1 to 3, wherein the blower is characterized by the above.

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