JP6982309B2 - Blower - Google Patents

Description

In the present invention, as people and vehicles enter and exit, the movement (blocking) of air inside and outside, and foreign substances such as dust, dust, dead leaves, plants such as fresh leaves, and other harmful substances are built from outside the building such as a factory. The present invention relates to a blower for a building entrance / exit that blows air from the floor surface of the building entrance / exit to a predetermined height to prevent intrusion into the room.

An air curtain is known as a means for avoiding the movement of air inside and outside a building such as a factory, a site, or a store. In this regard, there is an "air flow cutoff system" described in Patent Document 1, which creates a first air curtain and a second air curtain, and creates a windbreak space between the first air curtain and the second air curtain. It is a structure that forms.

Patent Document 2 is a partition member that abuts on both sides, the floor, and the ceiling of a room in order to prevent dust and dirt generated in the work place from spreading to other places during the construction of indoor extension and renovation. It is stated that the room is divided into two. The partition member includes a plurality of tubular air chambers formed of a synthetic resin or rubber sheet in a cylindrical shape, and air is continuously supplied from the blower to the tubular air chamber to stand the partition member on the floor surface. Set up. Noise is generated because the partition member is erected using a blower.

On the other hand, as an example of the technique for preventing noise, in the car wash machine of Patent Document 3, it is described that high-pressure air is blown from a blower to the vehicle in order to remove water droplets remaining on the washed vehicle. In order to reduce the noise from the blower, a sound absorbing material is attached to the inside of the casing in which the flow path of the air flow discharged from the blower is formed.

Japanese Unexamined Patent Publication No. 2016-114255 Japanese Unexamined Patent Publication No. 2006-63589 Japanese Unexamined Patent Publication No. 2008-13003

In Patent Document 1, by forming a windbreak space, as a result, the area of the wind area may be widened and the utilization area indoors may be narrowed. In addition, it is conceivable that the outside air accumulated in the windbreak space will be mixed into the room (wind flow that is not attractive). Further, in the invention using the partition member as in Patent Document 2, it is necessary to continue to supply air to the partition member by the blower. Therefore, noise due to the operation of the blower is constantly generated. Also, no means for preventing noise are disclosed. Further, in Patent Document 3, since it is necessary to generate high-pressure air in order to dry the vehicle, for example, a large blower is adopted. Therefore, along with the increase in size of the device and / or the casing and the generation of noise, the amount of the sound absorbing member may increase and the construction cost may increase.

The present invention has been made in view of the above circumstances, and an object of the present invention is to reduce the noise of a blower and provide a compact blower.

The present invention is for an entrance / exit of a building in which air is blown toward the entrance / exit of the building to prevent movement of inside / outside air (change in temperature and humidity of indoor air due to exhaust or intrusion) or prevention of foreign matter from entering the inside of the building. It is a blower of
The air blower for the entrance / exit of the building, which is installed at the entrance / exit of the building and blows air from the inside of this building to this entrance / exit, is
The first housing, which has a chamber inside and a sound absorbing member inside,
The air outlet provided in the first housing and
A second housing, which is connected to the first housing through a first opening and has a chamber inside and a sound absorbing member inside, respectively.
A third housing, which is connected to the second housing through a fourth opening and has a chamber inside and a sound absorbing member inside, respectively.
A first introduction port for air intake provided on the first side surface of the third housing, and
The blower housed in the second housing and
Consists of
A leg portion for supporting the first housing is provided.
The lower end of the air outlet has a configuration lower than the lower end of the first housing.
By the action of the blower, the air that has reached the chamber of the second housing from the first introduction port of the third housing via the fourth opening is passed through the first opening. It was characterized in that it was guided to the chamber of the first housing and sent out from the outlet to the outside of the device.

In the present invention, the second housing for accommodating the blower is attached to the upper part of the first housing, and the third housing is attached to the upper part of the second housing. Therefore, since the housings are mounted so as to be stacked in the height direction, it is not necessary to secure a large floor area for installing the blower. Further, a sound absorbing member is attached to the inner surface of each housing. This sound absorbing member can absorb the sound (noise) generated by the air flow such as the suction air of the blower and the blower. Thereby, the blower according to the present invention can provide a compact blower having a structure capable of reducing the noise of the blower, preventing foreign matter from entering from the entrance and exit, and exhibiting the outside air blocking effect.

(A) is a diagram showing a perspective view and a partially enlarged view according to an embodiment of the present invention, and (b) is a perspective view and a partially enlarged view of FIG. 1 (a) seen from the direction A. It is a figure which shows the figure. (A) is a side view of the blower device according to the embodiment of the present invention, and (b) is a front view of FIG. 2 (a). 2 is a cross-sectional view of the blower cut along the cross-sectional line AA of FIG. 2A. 2 is a cross-sectional view of the blower cut along the cross-sectional line BB of FIG. 2B. (A) is a diagram showing the positional relationship between the third opening and the fourth opening when the main body housing portion is viewed from above, and (b) is a diagram showing the positional relationship between the first opening and the blowout portion. FIG. 2 is an enlarged cross-sectional view of a main part obtained by cutting the blowout portion of FIG. 2A along the cross-sectional line C—C ′. It is a figure which shows an example which looked at the state which used the blower which concerns on embodiment in a building from above. It is a figure which shows the other example which looked at the state which used the blower which concerns on embodiment in a building from above.

(Embodiment)
Hereinafter, embodiments of the present invention will be described with reference to the drawings. XYZ coordinates are set in the drawings and referred to as appropriate. When the side on which the air outlet for blowing air is formed is the side surface, the X-axis is the width direction, the Y-axis is the height direction, and the Z-axis is the depth direction.

The blower according to the embodiment is installed at the entrance / exit of a building such as a factory or a workshop, blows wind toward the entrance / exit (outside the venue), and foreign matter invades the inside of the building as people or vehicles enter. It is a device to prevent. Here, the foreign substance means a foreign substance that enters the building such as garbage, dust, dead leaves, plants such as fresh leaves, insects, and other harmful substances.

As shown in FIGS. 1A and 1B, the blower device 1 includes a first housing 100 having an air outlet 122a for blowing air, and a second housing 200 attached to the upper part of the first housing 100. The third housing 300, which is attached to the upper part of the second housing 200 and has a first introduction port 301a for taking in air, and legs 102 are provided. In this way, the blower device 1 is configured by stacking the first housing 100, the second housing 200, and the third housing 300 in this order in the height direction from the bottom. The blower device 1 takes in air from the first introduction port 301a of the third housing 300 by the blower 220 described later housed in the second housing 200, and blows air from the air outlet 122a of the first housing 100. A wind barrier is formed at the air outlet and the doorway 3. This reduces, for example, the intrusion of foreign matter.

The first housing 100 is a housing having an outlet 122a that blows air taken in from the second housing 200 to the entrance / exit of the building. The first housing 100 is formed of a plate-shaped member such as metal or resin. As shown in FIG. 2, an outlet portion 120 having an outlet 122a for blowing air is formed on the side surface of the first housing 100 on the −Z side. The first housing 100 is supported by the legs 102.

The first housing 100 is a rectangular parallelepiped housing, and constitutes a chamber having a hollow inside. When viewed from the −Y direction of FIGS. 2A and 2B, the first housing 100 has a rectangular upper plate 111 and each side of the upper plate 111 as shown in FIGS. 1, 3 and 4. Four square-shaped side plates 112a, 112b, 112c, 112d (generally referred to as side plates 112) extending downward from the top plate 111, and four side plates 112 facing the upper plate 111. It is formed by a rectangular bottom plate 113 that closes the formed opening.

A first opening 111a is formed in the upper plate 111, which is aligned with the third opening 213a of the second housing 200, which will be described later, and takes in air from the second housing 200. The side plate 112c is formed with a second opening 112cc for sending air to the blowing portion 120. The second opening 112cc is formed by a rectangular hole extending in the vertical direction of the side plate 112c.

A sound absorbing member 119 is attached to the inner surfaces of the upper plate 111, the four side plates 112, and the bottom plate 113 of the first housing 100. As the sound absorbing member 119, for example, a plate made of a porous sound absorbing material made of aluminum fiber or a plate made of a sound absorbing material such as urethane foam is used.

The blowing portion 120 is a member attached to the side plate 112c of the first housing 100 and covers the second opening 112cc opened in the first housing 100, and has a role of blowing out the air inside (chamber) of the first housing 100. There is. FIG. 6 is a cross-sectional view of the blowout portion 120 of FIG. 2A cut along the CC'line. The blowout portion 120 includes a first inclined plate 120a along the longitudinal direction (Y-axis direction) of the first housing 100, a second inclined plate 120b, the first inclined plate 120a, and the upper and lower parts of the second inclined plate 120b. It consists of a top plate 120c and a bottom plate 120d deployed in. Then, an outlet 122a that functions as a nozzle is formed in the converging portion 120e of the room formed by the first inclined plate 120a and the second inclined plate 120b, the top plate 120c, and the bottom plate 120d. Further, the first inclined plate 120a and the second inclined plate 120b are inclined in the astringent direction as shown in FIG.

The air blown out from the outlet 122a is blown out at an angle of θ1 in the blowing direction (indicated by the alternate long and short dash line in FIG. 6).

One of the second inclined plates 120b of the pair of second inclined plates 120b is a long plate extended in the one first inclined plate 120a and extending in the Y-axis direction, and is in the blowing direction of the air blown out from the outlet 122a. It is an inclined plate that inclines with an angle of θ2, which is an angle larger than θ1. The other second inclined plate 120b is a long plate extending in the other first inclined plate 120a and extending in the Y-axis direction, and is inclined with an angle of θ2 in the blowing direction of the air blown out from the outlet 122a. It is a sloping plate. In the present embodiment, θ1 is in the range of 6 ° or more and 8 ° or less, preferably 7 °. θ2 is in the range of 35 ° or more and 37 ° or less, preferably 36 °. Noise can be reduced by forming the outlet 122a by combining the inclined plates 120a and 120b having the above angles θ1 and θ2. The ends of the pair of second inclined plates 120b are bent outward, and the bent portions are attached to the side plates 112c. Further, as shown in FIGS. 1, 2 and 4, a protruding portion 122b is formed at the lower end portion of the first inclined plate 120a so as to project downward from the lower end of the second inclined plate 120b.

As shown in FIGS. 1 (a) and 1 (b), the blowout portion 120 has a pair of first inclined plates 120a and a pair of second inclined plates 120b extending in the Y-axis direction in the front-rear direction of the paper surface of FIG. A top plate 120c that closes the upper part of the above plate and a bottom plate 120d that closes the lower part of the top plate 120c are provided.

The air that has entered the blowout portion 120 from the second opening 112cc is discharged from the room surrounded by the second inclined plate 120b, the top plate 120c, and the bottom plate 120d (hereinafter referred to as the second chamber) from the first inclined plate 120a. It flows into the space surrounded by the top plate 120c and the bottom plate 120d (hereinafter referred to as the first chamber). The volume of the second chamber is larger than the volume of the first chamber, from the second chamber including the second inclined plate 120b having a large inclination angle θ2 to the first chamber including the first inclined plate 120a having a small inclination angle θ1. In the process of flowing air from the second chamber to the first chamber, the air is blown out from the outlet 122a while increasing the flow velocity. By blowing out a high-speed air flow from the outlet 122a, the effect of removing foreign substances invading the building is enhanced.

The outlet 122a is an opening in which the gap between the pair of first inclined plates 120a is closed by the top plate 120c and the bottom plate 120d, and is a slit nozzle extending in the Y-axis direction. An inclined surface 120aa that inclines at an angle of θ3 in the blowing direction is formed on the side surface of one of the first inclined plates 120a on the outlet 122a side, and on the side surface of the other first inclined plate 120a on the outlet 122a side. Also, an inclined surface 120aa that inclines at an angle of θ3 in the blowing direction is formed. θ3 is, for example, 15 °. The inclined surface 120aa functions to make the air outside the inclined surface 120aa into an air flow directed toward the outlet 122a. Therefore, when the air is blown out from the outlet 122a, the air outside the inclined surface 120aa can be taken in and merged with the air blown out from the outlet 122a to increase the air volume of the air flowing in the blowing direction. By increasing the amount of air flowing in the blowing direction, the effect of removing foreign substances entering the building is enhanced.

The air outlet 122a blows out air in a direction intersecting the plate surface of the side plate 112c. For example, air is blown out at an angle of 90 degrees with respect to the plate surface of the side plate 112c. The direction of the air blown out from the outlet 122a is set to an appropriate angle according to the structure of the building in which the blower 1 is installed. A blower device 1 is installed so that the air outlet 122a faces the entrance / exit of the building, and an air flow is blown to the entrance / exit to prevent foreign matter from entering the building from the outside of the building.

As shown in FIG. 5B, the first opening 111a passes through the center of the upper plate 111 in the X-axis direction, is in the vicinity of the side plate 112a on the −X side of the center line 103 parallel to the Z-axis direction, and It is arranged near the center in the Z-axis direction. The blowout portion 120 is attached to the side plate 112c, which is a side plate perpendicular to the side plate 112a, on the right side of the center line 103. By arranging the first opening 111a and the blowing portion 120 in such a positional relationship, the air discharged from the first opening 111a flows toward the blowing portion 120 as shown by the arrow 101. At this time, air flows to the air outlet 122a while contacting the sound absorbing member 119 attached to the inner surface of each of the upper plate 111, the four side plates 112, and the bottom plate 113.

When the blower device 1 is installed on the left and right sides of the doorway, the blowout portion 120 of one first housing 100 is attached to the side plate facing the side plate to which the blowout portion 120 of the other first housing 100 is attached. .. For example, in FIGS. 2A and 3, the blowout portion 120 is attached to the side plate 112c on the left side of the drawing. When such a blower device 1 is installed on the right side toward the doorway, the blowout unit 120 of the blower device 1 installed on the left side toward the doorway is on the right side of the blower device 1 shown in FIGS. 2A and 3. It is attached to the side plate 112d of.

The legs 102 are attached to the four corners of the bottom plate 113 of the first housing 100. At least a part of the leg 102 is formed from an elastic member such as rubber. The leg 102 absorbs the vibration generated by the blower 220.

Although not limited, the protruding portion 122b of the first inclined plate 120a protrudes downward from the lower end of the first housing 100 supported by the leg portion 102, that is, the bottom plate 113, and the tip thereof is the first with respect to the floor surface. 1 The outlet 122a is arranged close to the floor surface, which is substantially the same as the bottom plate 113 of the housing 100 or extends to a position lower than the bottom plate 113. This makes it possible to blow air from the outlet 122a to near the floor surface. Alternatively, foreign matter remaining on the floor surface or invading from the floor surface can be eliminated (prevented).

As shown in FIGS. 3 and 4, the second housing 200 is attached to the upper part of the first housing 100 and houses the blower 220 inside. The second housing 200 is a housing in which air is taken in from the third housing 300 by driving the blower 220, and the taken-in air is sent to the first housing 100. Then, an outer body that matches the shape of the blower 220 is provided. Secure the air passage space of the second chamber.

The second housing 200 is, for example, a rectangular parallelepiped housing made of a plate-shaped member such as metal or resin, and constitutes a chamber having a hollow inside. When viewed from the −Y direction of FIGS. 2A and 2B, the second housing 200 has a rectangular upper plate 211 and each side of the upper plate 211 as shown in FIGS. 1, 3 and 4. Four square-shaped side plates 212a, 212b, 212c, 212d (generally referred to as side plates 212) extending downward from the upper plate 211 and four side plates 212 facing the upper plate 211. It is formed by a rectangular bottom plate 213 that closes the formed opening. The side plate 212c has a shape in which the lower portion is bent inward to match the shape of the casing 211 of the blower 220 housed inside the housing 210.

The upper plate 211 is formed with a fourth opening 211a that takes in the air of the third housing 300 inside the second housing 200, and the bottom plate 213 is formed with the air inside the second housing 200 in the first housing. A third opening 213a is formed to drain into the body 100. As shown in FIG. 3, the fourth opening 211a is located on the right side of the upper plate 211 of the second housing 200. The third opening 213a is formed on the left side of the bottom plate 213. The fourth opening 211a and the third opening 213a have the fourth opening 211a as shown in FIG. 5A when the upper plate 211 is viewed from above (-Y direction) of FIGS. 2B and 3. The opening 211a is located on the right side and the third opening 213a is located on the left side.

The blower 220 includes a casing 221, an impeller 222 housed inside the casing 22, a motor 223 for driving the impeller 222, and a base 224 to which the motor 223 is fixed. The blower 220 is arranged so that the rotation axis 223a of the motor 223 is orthogonal to the plate surface of the side plate 212d. Further, the blower 220 is housed inside the second housing 200 so that the motor 223 is arranged on the side of the fourth opening 211a and the casing 221 is arranged on the side of the third opening 213a.

The casing 221 is a case made of metal or the like that houses the impeller 222 inside. The casing 221 is formed with a suction port 221a and a discharge port 221b. The suction port 221a opens in the axial direction of the rotation shaft 223a, and the discharge port 221b is arranged at a position perpendicular to the direction of the suction port 221a. A wire mesh is attached to both the suction port 221a and the discharge port 221b. The discharge port 221b has a diameter whose end end fits in the third opening 213a formed in the bottom plate 213, and by fitting the discharge port 221b into the third opening 213b, the blower 220 is the second housing 200. Is fixed to.

The impeller 222 comprises, for example, a metal sirocco fan or turbofan. The impeller 222 is rotatably supported in the casing 221 by the rotating shaft 223a of the motor 223. The impeller 222 is rotated in synchronization with the rotation of the rotation shaft 223a of the motor 223. The motor 223 is connected to an external commercial power source for power supply by a cable (not shown).

The base 224 is a member that supports the motor 223, and the motor 223 is placed on the upper surface thereof, and one side surface thereof is fixed to the side surface of the casing 221. The base 224 and the motor 223, and the base 224 and the casing 221 are fixed to the second housing 200 by screwing or welding, respectively.

As shown in FIG. 3, a second introduction port 214 is formed on the side plate 212d of the second housing 200 so as to face the motor 223, and external air is taken in from the second introduction port 214. Further, as shown in FIGS. 1 to 3, a cover member 215 that covers the second introduction port 214 is attached to the outer surface of the side plate 212d. The cover member 215 has an XY cross section formed in a U-shape, and the space inside the U-shape leads to the inside of the second housing 200 via the second introduction port 214. When the motor 223 is driven and the impeller 222 is rotated, external air is taken in from the second introduction port 214 through the space of the cover member 215, and the motor 223 is cooled by this air. Further, by attaching the cover member 215 so as to cover the second introduction port 214, the cover member 215 prevents dust and dirt contained in the outside air from being taken into the second housing 200.

As shown in FIGS. 2 to 4, a sound absorbing member 119 is attached to the inner surface of the second housing 200. Specifically, the sound absorbing member 119 is attached to the inner surface of each of the upper plate 211, the four side plates 212, and the bottom plate 213. As the sound absorbing member 119, for example, a plate made of a porous sound absorbing material made of aluminum fiber or a plate made of a sound absorbing material such as urethane foam is used. The noise generated by the blower 220 is absorbed when the taken-in air comes into contact with the sound absorbing member 119.

With the above configuration, the blower 220 sucks air from the fourth opening 211a formed in the upper plate 211 of the second housing 200 by rotating the impeller 222. The air sucked in from the fourth opening 211a flows along the arrow 201. In addition, air is also taken in from the second introduction port 214 and flows along the arrow 201. The air sucked from the fourth opening 211a is a sound absorbing member attached to the upper plate 211, the side plate 212d, the bottom plate 213 of the second housing 200, and the side plates 212b and 212c arranged in the front-rear direction of the paper surface of FIG. It flows while contacting 119. After that, the air flows along the arrow 202 and is sucked into the casing 221 from the suction port 221a of the casing 211. The air flowing along the arrow 202 flows while contacting the upper plate 211, the side plate 212a, the bottom plate 213, and the sound absorbing members 119 attached to the side plates 212b and 212c arranged in the front-rear direction of the paper surface of FIG. The air sucked from the suction port 221a passes through the discharge port 221b and the third opening 213a in the radial direction of the impeller 222 (-Y direction shown in FIG. 2), which is the direction perpendicular to the rotation shaft 223a. It is discharged to the first housing 100. The configuration of the blower 220 described above is an example, and the configuration of the blower 220 can be changed as appropriate.

The third housing 300 is a housing that takes in air from the outside, and is attached to the upper part of the second housing 200. As shown in FIGS. 1 to 3, the third housing 300 is a rectangular parallelepiped housing formed of metal, resin, or the like, and constitutes a chamber having a hollow inside. The third housing 300 includes a first side surface 301 and a second side surface 305 facing the rectangular parallelepiped in the longitudinal direction (X-axis direction). A first introduction port 301a for taking in external air is formed on the first side surface 301, and inside the third housing 300, the first introduction port 301a to the second introduction port 301a indicated by the flow path 306 indicated by an arrow are formed. A flow path to the side surface 305 is formed. By providing the wire mesh 300b in the first introduction port 301a, it is considered to be useful for preventing danger,, in some cases, preventing foreign matter from entering from outside the device, and for sucking in air and rectifying air.

The third housing 300 is, for example, rectangular, and has an upper and lower plates 302, 303, a third side plate 304a, a fourth side plate 304b, and a second side plate 305 forming a second side surface 305 (otherwise, in a tubular shape). , And a space (chamber) surrounded by the upper and lower plates 302, 303, the third side plate 304a, the fourth side plate 304b, and the second side plate 305. Then, air flows in the chamber through the flow path 306 indicated by the arrow. In the example in which the third housing 300 is formed by welding, the surface in the longitudinal direction is joined to the second housing 200, so that the height of the blower device 1 can be lowered and the device becomes compact. In addition, the position of the center of gravity can be lowered, and the stability of the device can be ensured. Further, as shown in FIG. 2B, the inner width m in the X-axis direction of the third housing 300 (the inner width excluding the thickness of the sound absorbing member 119; the same applies hereinafter) is the second in the figure. The housing 200 is formed to have a width equal to or slightly smaller than the inner width n in the X-axis direction. Since the flow path 306 is formed in the X-axis direction, it can have a maximum length equal to the inner width n of the second housing 200.

A fifth opening 300a consistent with the fourth opening 211a is formed in the vicinity of the second side plate 305 of the lower plate 303. By driving the blower 220, air is taken in from the first introduction port 301a, and the taken-in air flows in the third housing 300 to the fifth opening 300a, and the fifth opening 300a and the fourth opening 300a. It is sent to the second housing 200 through the opening 211a of.

A sound absorbing member 119 is attached to the inner surface of the third housing 300. The sound absorbing member 119 is a plate made of a sound absorbing material such as urethane foam. Specifically, the sound absorbing member 119 is attached to the inner surfaces of the upper plate 302, the lower plate 303, the third side plate 304a, the fourth side plate 304b, and the second side plate 305 of the third housing 300. The noise generated by the blower 220, for example, the noise caused by the suction of the blower 220 and the noise caused by the vibration, is generated on the third housing 300 in the process in which the air taken in from the first introduction port 301a passes through the flow path 306. Sound is absorbed by contacting the sound absorbing member 119 attached to the inner surface of each of the plate 302, the lower plate 303, the third side plate 304a, the fourth side plate 304b, and the second side plate 305.

Further, the first side surface 301 on which the first introduction port 301a of the third housing 300 is formed and the side plate 112c on the side surface on which the air outlet 122a of the first housing 100 is formed are arranged at orthogonal positions. Will be done. Since the third housing 300 and the first housing 100 have such an arrangement relationship, the side plate 112c having the outlet 122a is arranged toward the entrance / exit of the building, and the first introduction port 301a is inside the building. Can be placed towards. Since the first introduction port 301a is arranged toward the inside of the building, the blower 1 does not take in air containing foreign matter such as dust outside the building.

An example in which the blower device according to the present embodiment is installed in a building such as a factory will be described with reference to the bird's-eye view of FIG. 7. One blower 1-1 and the other blower 1-2 (not limited to a pair, and although not shown, a stacking type is also possible) are installed on the left and right near the doorway 3 inside the building 2. Therefore, the first introduction port 301a-1 of the blower device 1-1 and the first introduction port 301a-2 of the blower device 1-2 are arranged so as to face the inside of the building 2. This arrangement is, for example, the first introduction port 301a (301a-1, 301a-2) of the third housing 300 (one of the blower devices 1-1 and the other blower device 1-2) and the blowout port. This can be achieved by a structure in which the portion 120 is provided at orthogonal positions in a plan view.

The blowout portion 120 of the blower device 1-1 and the blowout portion 120 of the blower device 1-2 are attached to the side plates 112 so that the blowout portions 120 face each other. The outlet portion 120 is attached so that the outlet 122a faces an angle of 90 degrees with respect to the side plate 112. By installing the air blower 1-1 and the air blower 1-2 on the left and right sides of the doorway 3 of the building 2, the air outlets 122a facing each other are indicated by arrows toward the vehicle or the like entering from the doorway 3. Can be blown with airflows facing each other. Therefore, a barrier that covers the doorway 3 is formed in the vicinity of the doorway 3 inside the building 2, and foreign matter such as external dust and dust can be prevented from entering.

For example, it is possible to prevent the inflow of foreign matter such as dust due to the inflow of air from the outside to the inside of the building 2 or the inflow of air due to the wind from the outside, which is caused by the temperature difference between the inside and the outside of the building 2. Further, it is possible to prevent foreign substances such as dust and dirt that accompany the vehicle when it enters the doorway 3 from entering the inside of the building 2.

Further, the mounting angle of the outlet 122a with respect to the side plate 112 is not limited to 90 degrees, and for example, the outlet 120 may be formed so as to be 45 degrees. FIG. 8 shows an example in which the blower 1-1 and the blower 1-2 are installed on the left and right sides of the doorway 3 of the building 2. The blower device 1-1 and the blower device 1-2 are arranged so as to face each other so that the outlet 122a of each other faces the inlet / outlet 3. By blowing air from the pair of outlets 122a, the air flow flows in the direction from the inside to the outside of the building 2, as indicated by the arrows. Therefore, it is possible to prevent the intrusion of foreign matter such as external dust and dust. It is also possible to discharge foreign matter in the vicinity of the doorway 3 inside the building 2.

Further, by providing the air outlet 122a that blows air from the inside to the outside of the building 2, it is not necessary to form a windbreak space, and the utilization area in the building 2 is not narrowed. In addition, the inflow of air from the outside to the inside of the building 2 caused by the temperature difference between the inside and the outside of the building 2, the intrusion of dust due to the inflow of air due to the wind from the outside, and further, the vehicle or the like enters the entrance / exit 3. It is also possible to prevent the intrusion of foreign matter such as dust and dirt that accompanies the intrusion.

The blower devices 1-1 and 1-2 shown in FIG. 8 are formed so that the angle of the outlet 122a is 45 degrees, but the devices of the blower devices 1-1 and 1-2 shown in FIG. 7 are formed. The installation angle of the air outlet 122a may be changed so that the outlet 122a faces the outside of the device.

Next, with reference to FIGS. 3 to 5, the flow of air flowing inside the blower 1 and the sound absorbing effect will be described.

When power is supplied to the motor 223, the motor 223 rotates about the rotating shaft 223a, and the impeller 222 connected to the rotating shaft 223a rotates about the rotating shaft 223a. When the impeller 222 rotates, the air inside the building 2 is sucked in from the first introduction port 301a of the third housing 300. The sucked air flows from the first side surface 301 to the second side surface (second side plate) 305 along the flow path 306 indicated by the arrow shown in FIG. When the sucked air passes through the inside of the third housing 300, the sound absorbing member attached to the inner surface of the upper plate 302, the lower plate 303, the third side plate 304a, the fourth side plate 304b, and the second side plate 305. Since the air flows while in contact with the 119, the suction sound at the time of suction and other noises related to the suction are absorbed. Since the inner width m in the X-axis direction of the third housing 300 is substantially the same as the inner width n of the second housing 200, a sufficient flow path length can be secured, and the third housing 300 can be secured. The residence time of air inside can be maintained for a long time, and the sound absorption effect can be enhanced.

Then, the air taken into the third housing 300 reaches the fifth opening 300a and is taken into the inside of the second housing 200 through the fifth opening 300a and the fourth opening 211a. In addition, air is taken into the second housing 200 from the second introduction port 214 as well. The air taken into the inside of the second housing 200 flows along the arrows 201 and 202, is sucked into the casing 221 from the suction port 221a of the casing 221 along the rotation shaft 223a, and is sucked into the casing 221 in the radial direction of the impeller 222. It flows and is discharged from the discharge port 221b. The air taken into the second housing 200 comes into contact with the sound absorbing member attached to the inner surface of the upper plate 211, the four side plates 212, and the bottom plate 213 of the second housing 200, and the impeller 222 of the blower 220 Noise, noise caused by vibration caused by the motor 223, and the like are absorbed. Further, as shown in FIG. 5A, the fourth opening 211a and the third opening 213a are located apart from each other on the left and right when viewed from above. Therefore, the air entering from the fourth opening 211a reaches the third opening 213a while maintaining a sufficient residence time inside the second housing 200, so that the sound absorption effect can be enhanced. Further, the motor 223 can be cooled by the air taken in from the second introduction port 214.

The air discharged from the second housing 200 flows into the first housing 100 through the third opening 213a and the first opening 111a. As shown in FIG. 5B, the air flowing into the first housing 100 flows from the first opening 111a to the blowout portion 120 in the direction indicated by the arrow 101, and in the meantime, the upper plates 111 and four sheets. Since it comes into contact with the sound absorbing member 119 attached to the inner surface of the side plate 112 and the bottom plate 113, the noise, impact sound, etc. of the blower 220 are absorbed. As shown in FIG. 5B, the first opening 111a is arranged on the left side of the center line 103, and the blowout portion 120 attached to the side plate 112c is arranged on the right side of the center line 130. Since the air that has entered the body 100 reaches the blowout portion 120 while maintaining a sufficient residence time inside the first housing 100, the sound absorption effect can be enhanced.

Further, since air is introduced from the first introduction port 301a and the second introduction port 214, it is possible to blow out air having a larger air volume than the blower device 1 provided with only the first introduction port 301a from the outlet 122a. can. By increasing the air volume, it is possible to prevent foreign matter entering the inside of the building or improve the effect of removing foreign matter inside the building to the outside.

As described above, according to the present embodiment, the blower device 1 includes the first housing 100, the second housing 200, and the third housing 300 in this order from the bottom to the height. It was laminated and joined. Therefore, the occupied area of the floor surface on which the blower device 1 is installed can be reduced, and a compact blower device 1 can be provided.

According to the present embodiment, a flow path from the first side surface 301 of the rectangular parallelepiped third housing 300 to the second side surface 305 facing the first side surface is formed, and a sound absorbing member is formed on the inner surface of the third housing 300. Since the 119 is attached, a long flow path can be secured and the sound absorption effect can be enhanced.

According to the present embodiment, since the sound absorbing member is attached to the compact blower 1, the area for attaching the sound absorbing member is reduced, and the material cost is reduced.

In the embodiment, it has been described that the third housing 300 has a rectangular parallelepiped shape, but it may be a pillar shape. Therefore, any shape may be applied as long as it is a pillar shape such as a cylinder or a triangular prism.

In the embodiment, it has been described that the outlet 122a is the outlet of the slit nozzle extending in the vertical direction, but the outlet 122a does not have to be formed in such a shape. For example, slit-shaped outlets may be formed at intervals along the vertical direction. Further, circular holes may be formed at intervals along the vertical direction.

In the embodiment, it has been described that one rectangular parallelepiped third housing 300 is attached to the second housing 200, but the present invention is not limited to one third housing 300. For example, a plurality of units of the third housing 300 of the rectangular parallelepiped member may be arranged in the Z-axis direction, and the sound absorbing member may be attached to the inside of each unit. By adopting such a structure, it is possible to increase the area to which the suction member is attached and enhance the sound absorption effect.

Although it has been described that the third housing 300 includes the lower plate 303, the third housing 300 may be a third housing having a gate-shaped cross section without the lower plate 303. When such a third housing is applied, the end portion of the side plate 304 may be joined to the upper plate 211 of the second housing 200 by welding or the like.

In the embodiment, an example in which two blowers 1-1 and 1-2 are installed on the left and right sides of the doorway 3 of the building 2 has been described, but one blower device 1 may be installed in the vicinity of the doorway 3. ..

The present invention allows for various embodiments and variations without departing from the broad spirit and scope of the invention. Further, the above-described embodiments are for explaining the present invention, and do not limit the scope of the present invention. That is, the scope of the present invention is shown not by the embodiment but by the claims. Then, various modifications made within the scope of the claims and within the scope of the equivalent invention are considered to be within the scope of the present invention.

1,1-1,1-2 Blower 2 Building 3 Doorway 4 Vehicle 100 First casing 102 Leg 102a Support 102b Installation 103 Center line 111 Top plate 111a First opening 112 Side plates 112a, 112b, 112c, 112d Side plate 112cc Second opening 113 Bottom plate 119 Sound absorbing member 120 Blow-out part 120a First inclined plate 120aa Side surface 120b Second inclined plate 120c Top plate 120d Bottom plate 120e Convergence part 122a Outlet 122b Protruding part 200 Second casing 211 Top plate 211a 4th opening 212 Side plate 212a, 212b, 212c, 212d Side plate 213 Bottom plate 213a 3rd opening 214 2nd introduction port 215 Cover member 220 Blower 221 Casing 221a Suction port 221b Discharge port 222 Impeller 223 Motor 223a Rotating shaft 224 base 300 Third casing 300a Fifth opening 300b Wire mesh 301 First side surface 301a, 301a-1, 301a-2 First introduction port 302 Upper plate 303 Lower plate 304a Third side plate 304b Fourth side plate 305 Second side plate (first) 2 sides)

Claims (7)

The air blower for the entrance / exit of the building, which is installed at the entrance / exit of the building and blows air from the inside of this building to this entrance / exit, is
The first housing, which has a chamber inside and a sound absorbing member inside,
The air outlet provided in the first housing and
A second housing, which is connected to the first housing through a first opening and has a chamber inside and a sound absorbing member inside, respectively.
A third housing, which is connected to the second housing through a fourth opening and has a chamber inside and a sound absorbing member inside, respectively.
A first introduction port for air intake provided on the first side surface of the third housing, and
The blower housed in the second housing and
Consists of
A leg portion for supporting the first housing is provided.
The lower end of the air outlet has a configuration lower than the lower end of the first housing.
By the action of the blower, the air that has reached the chamber of the second housing from the first introduction port of the third housing via the fourth opening is passed through the first opening. A blower device characterized in that the air is guided to the chamber of the first housing and sent out from the air outlet to the outside of the device. The air outlet is formed on the side surface of the first housing, and the first side surface of the third housing in which the first introduction port is formed is orthogonal to the side surface of the first housing. Characterized by that
The blower according to claim 1. The outlet is characterized in that it is formed in a slit shape extending in the vertical direction.
The blower according to claim 1 or 2. The first housing is
A pair of first inclined plates that are inclined in the direction of blowing out the air blown out from the outlet and the gap at the tip constitutes the outlet.
It is characterized by having a pair of second inclined plates extending from the first inclined plate and inclined more than the inclination angle of the first inclined plate.
The blower according to claim 3. The end surface of the first inclined plate on the outlet side is characterized by being composed of an inclined surface inclined in the blowing direction.
The blower according to claim 4. The blower includes a rotary blade, a motor including a rotary shaft that rotates with the rotary blade, and a motor.
Have,
The second housing is characterized in that a second introduction port for taking in air for cooling the motor is formed.
The blower according to any one of claims 1 to 5. The second housing is characterized in that a portion covering the second introduction port is formed.
The blower according to claim 6.

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