JP6284338B2 - Blower - Google Patents

Description

  The present invention relates to a blower device including a plurality of air outlets.

  Many air conditioners having a purification action have been put into practical use. Examples of documents disclosing this type of air conditioner include Japanese Patent Application Laid-Open No. 2011-33305 (Patent Document 1) and Japanese Patent Application Laid-Open No. 2011-237139 (Patent Document 2).

  Patent Document 1 discloses an electrostatic atomizer including an electrostatic atomizer that generates electrostatic fine particle water having an air purification action, and a blower that conveys the electrostatic fine particle water toward a room. ing. The blower device includes an air outlet and a suction port provided in the main body case, a blower for blowing air from the suction port to the air outlet, and an openable / closable wind direction louver provided at the air outlet. By setting it as such a structure, electrostatic fine particle water can be discharge | released toward a predetermined direction by a wind direction louver.

  Patent Document 2 discloses a blower that conveys ions having an air purification action toward a room. The blower includes a suction port, a first blower outlet with the front as the main blow direction, a second blower outlet with the upper portion as the main blow direction, and a blower that blows air from the suction port to the first blower outlet and the second blower outlet. With.

  A louver having a variable elevation angle is provided at the first air outlet, and an air guide plate that interferes with air blown from the blower toward the first air outlet and the second air outlet protrudes from the louver. By moving the air guide plate in conjunction with the rotation of the louver, the amount of air blown from each of the first air outlet and the second air outlet is distributed.

JP 2011-33305 A JP 2011-237139 A

  Purifying substances such as electrostatic fine particle water and ions having an air purification action are required to be delivered to the entire room. Generally, the blower is installed near one wall in the room, and the wind containing the purification substance is discharged toward the center of the room by the action of the blower.

  However, in the electrostatic atomizer disclosed in Patent Document 1, since only one outlet is provided, the wind direction of the air blown out from the outlet is adjusted to a predetermined direction by the wind direction louver. Even in this case, the wind direction is concentrated in a predetermined blowing direction. For this reason, the direction in which electrostatic fine particle water is discharged is limited.

  On the other hand, in the air blower disclosed in Patent Document 2, although two air outlets are provided, the louver provided in the first air outlet determines the air direction of the air blown out from the first air outlet. It is variable so that it goes to the surface side. For this reason, when the louver is varied, air is blown out from the first air outlet in a direction away from the air blown out from the second air outlet. As a result, in the blower disclosed in Patent Document 2, the wind direction is concentrated in the two blowing directions, and it is difficult to diffuse the air well in other directions.

  This invention is made | formed in view of the above problems, and the objective of this invention aims at providing the air blower which can spread the air which blows off from a blower outlet over a wide range.

The blower based on this invention is the 1st blower outlet and 2nd blower which blow off air toward the exterior, the 1st wind direction adjustment part located in the ventilation downstream of the said 1st blower outlet, and the said 2nd blower outlet The 2nd wind direction adjustment part located in the ventilation downstream side of this, and the air blower which ventilates air to the said 1st blower outlet and the said 2nd blower outlet. The first wind direction adjusting unit and the second wind direction adjusting unit are a first air flow blowing range blown through the first wind direction adjusting unit and a second blown out through the second wind direction adjusting unit. It is comprised so that the ventilation range of an airflow can overlap in an open space. Each of the first wind direction adjusting unit and the second wind direction adjusting unit includes a first wind direction adjusting plate and a second wind direction adjusting plate that are spaced apart from each other. The first wind direction adjusting plate and the second wind direction adjusting plate are arranged so as to be inclined so that a distance between the first wind direction adjusting plate and the second wind direction adjusting plate becomes narrower toward the air blowing downstream side. Yes. The widths of the first air direction adjusting plate and the second air direction adjusting plate are narrower toward the air blowing downstream side than the width of the base end portion located on the air blowing upstream side.

  In the air blower according to the present invention, the first wind direction adjusting unit in the first wind direction adjusting unit and the first wind direction adjusting plate are arranged in the direction in which the first wind direction adjusting plate and the second wind direction adjusting plate are arranged. It is preferable that the direction in which the wind direction adjusting plate and the second wind direction adjusting plate are arranged intersect.

  It is preferable that the air blower according to the present invention further includes an ion generator that emits ions to the air blown by the blower. In this case, it is preferable that air containing ions is blown out from at least one of the first air outlet and the second air outlet.

  In the air blower according to the present invention, it is preferable that the first wind direction adjusting unit and the second wind direction adjusting unit are configured to be rotatable so that the blowing direction changes.

  ADVANTAGE OF THE INVENTION According to this invention, the air blower which can spread the air blown off from a blower outlet over a wide range can be provided.

It is a perspective view of the air blower concerning this Embodiment 1. FIG. It is a front view of the air blower shown in FIG. It is a right view of the air blower shown in FIG. It is a schematic cross section along the IV-IV line shown in FIG. It is an external view which shows an example of the ventilation unit shown in FIG. It is a top view of the ion generator shown in FIG. It is a front view of the ion generator seen from the direction shown by arrow VII shown in FIG. It is a front view of the ion generator seen from the direction shown by arrow VIII shown in FIG. It is a schematic diagram which shows the 1st airflow which blows off through the 1st wind direction adjustment part at the time of seeing from the side surface side of an air blower. It is a schematic diagram which shows the 2nd airflow which blows off through the 2nd wind direction adjustment part at the time of seeing from the upper surface side of an air blower. It is a figure which shows the centerline of the air blower shown in FIG. 1, and the 1st airflow and 2nd airflow which are blown out from this. It is a figure which shows the simulation result regarding the density | concentration distribution of the ion diffused indoors by the air blower shown in FIG. It is a figure which shows the centerline of the air blower which concerns on Embodiment 2, and the 1st airflow and 2nd airflow which blow off from this. It is a figure which shows the center line of the air blower which concerns on Embodiment 3, and the 1st airflow and 2nd airflow which are blown out from this. It is a figure which shows the observation position of the verification experiment performed in order to verify the effect of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following embodiments, the same or common parts are denoted by the same reference numerals in the drawings, and description thereof will not be repeated.

(Embodiment 1)
FIG. 1 is a perspective view showing a blower according to the present embodiment. FIG. 2 is a front view of the blower shown in FIG. FIG. 3 is a right side view of the air blower shown in FIG. FIG. 4 is a schematic cross-sectional view taken along line IV-IV shown in FIG. With reference to FIGS. 1-4, the air blower 1 which concerns on this Embodiment is demonstrated.

  As shown in FIGS. 1 to 4, the blower device 1 according to the present embodiment includes blower units 2A and 2B (see FIG. 4) and a housing 10 that houses the blower units 2A and 2B.

  The housing 10 accommodates a part of the blower unit 2A arranged on the upper side among the blower units 2A and 2B (see FIG. 4) arranged side by side in the vertical direction (Z-axis direction in the drawing). The part 12 and the suction inlet 11 provided in the one side (right side) of the side surface are included.

  Openings 14 and 15 are provided on the front side of the housing 10. The opening 14 is located on the front side of the housing part 12, and the opening 15 is located at the approximate center on the front side of the housing 10. The opening 14 has a long side extending in a substantially vertical direction (Z-axis direction) and a short side extending in a substantially horizontal direction (X-axis direction in the drawing) when viewed from the front side. The opening 15 has a short side extending substantially in the vertical direction and a long side extending in the left-right direction when viewed from the front.

  From the long sides of the openings 14 and 15, wind direction adjusting units 3 </ b> A and 3 </ b> B to be described later protrude toward the blower downstream side (Y-axis negative direction in the drawing).

  As shown in FIG. 4, the blower unit 2A includes a blower 51A, a blower duct 53A, an ion generator 60A, a blowout duct 100A, a first blower outlet 100A1, and a wind direction adjusting unit 3A. The blower unit 2B includes a blower 51B, a blower duct 53B, an ion generator 60B, a blowout duct 100B, a second blower outlet 100B1, and a wind direction adjusting unit 3B.

  Hereinafter, when the air duct 53A and the air duct 53B are not particularly distinguished, they are referred to as the air duct 53, and when the air duct 100A and the air duct 100B are not particularly distinguished, they are referred to as the air duct 100.

  Further, when the ion generator 60A and the ion generator 60B are not particularly distinguished from each other, they are referred to as the ion generator 60, and when the wind direction adjusting unit 3A and the wind direction adjusting unit 3B are not particularly distinguished from each other, they are referred to as the wind direction adjusting unit 3. Called.

  The blowers 51A and 51B take in air outside the blower 1 from the suction port 11, and send the taken air toward the blower ducts 53A and 53B. The blower 51A and the blower 51B are provided so that the rotation axes of the blowers are parallel to each other. As the blower 51A and the blower 51B, a sirocco fan, a propeller fan, or a turbofan blower may be employed.

  The blowout duct 100 is connected to the blower duct 53 via the ion generator 60. Blowing spaces 64a and 64b (see FIG. 5), which will be described later, are formed in the ion generator 60, and the blowing duct 100 and the blowing duct 53 communicate with each other by the blowing spaces 64a and 64b.

  In this way, the ducts 4A and 4B that define the blowing paths 52A and 52B are configured by connecting the blowing ducts 100A and 100B and the blowing ducts 53A and 53B. Here, when the duct 4A and the duct 4B are not particularly distinguished, they are referred to as a duct 4. In addition, the duct 4 may be comprised by integrally forming the blowing duct 100 and the ventilation duct 53. FIG.

  1st blower outlet 100A1 is prescribed | regulated by the opening end of 100 A of blower ducts in the ventilation downstream. The first air outlet 100A1 blows out the air blown from the blower 51A toward the outside. A wind direction adjusting unit 3A is provided on the air blowing downstream side of the first air outlet 100A1. The wind direction adjusting unit 3A is connected to the vicinity of the opening end of the blowing duct 100A.

  The second outlet 100B1 is defined by the open end of the outlet duct 100B on the air blowing downstream side. The second outlet 100B1 blows out the air blown from the blower 51B to the outside. An airflow direction adjustment unit 3B is provided on the downstream side of the second air outlet 100B1. The wind direction adjusting unit 3B is connected to the vicinity of the opening end of the blowing duct 100B.

  In the blower unit 2A, the opening of the blower duct 53A located on the ion generator 60A side is formed such that the DR1 direction in the figure is the longitudinal direction and the X-axis direction in the figure is the short direction. Correspondingly, the first outlet 100A1 is also formed such that the DR1 direction in the drawing is the longitudinal direction and the X-axis direction in the drawing is the short direction. That is, the outlet 100A1 has a substantially rectangular shape when viewed from the normal direction.

  In the blower unit 2B, the opening of the blower duct 53B located on the ion generator 60B side is formed such that the DR2 direction in the figure is the short direction and the substantially X-axis direction in the figure is the long direction. Correspondingly, the air outlet 100B1 is also formed such that the X-axis direction in the drawing is the longitudinal direction and the DR2 direction in the drawing is the short direction. That is, the blower outlet 100B1 has a substantially rectangular shape when viewed from the normal direction.

  In addition, although the case where DR1 direction and DR2 direction incline with respect to XZ plane is illustrated, it is not limited to this, You may be parallel to XZ plane. Further, the DR1 direction and the DR2 direction may be set so that the inclination angles with respect to the XZ plane are different or may be set to be the same.

  The blowout duct 100B is connected to the blower duct 53B so that its longitudinal direction intersects the longitudinal direction of the blowout duct 100A when viewed from the front. Thereby, also in the wind direction adjustment unit 3B, when it sees from the front, it is attached to the blowing duct 100B so that the longitudinal direction may cross the longitudinal direction of the wind direction adjustment unit 3A.

  For example, when viewed from the front, the longitudinal direction of the blowing duct 100B and the longitudinal direction of the blowing duct 100A are substantially orthogonal, and the longitudinal direction of the wind direction adjusting unit 3B and the longitudinal direction of the wind direction adjusting unit 3A are approximately orthogonal.

  As shown in FIGS. 1, 2, and 4, protective nets 18 </ b> A and 18 </ b> B are arranged in the blowing ducts 100 </ b> A and 100 </ b> B. The protective nets 18A and 18B are arranged on the air blowing upstream side of the first air outlet 100A1 and the second air outlet 100B1. The protective nets 18A and 18B are provided to prevent foreign objects such as fingers from entering from the outside.

  As shown in FIG. 4, the ion generator 60 generates ions and releases the ions to the air blown by the blower. The discharged ions pass through the duct 4 and are blown out from the first outlet 100A1 and the second outlet 100B1. The ion generator 60 is detachably attached to the duct 4. The ion generator 60A is assembled to the duct 4A so that the longitudinal direction is along the DR1 direction, and the ion generator 60B is assembled to the duct 4B so that the longitudinal direction is along the X axis.

  FIG. 5 is an external view showing an example of the air blowing unit shown in FIG. Specifically, FIG. 5 is an external view showing the blower unit 2A shown in FIG. With reference to FIG. 5, the detail of the air direction adjustment unit 3A in the ventilation unit 2A is demonstrated.

  As shown in FIG. 5, the air direction adjusting unit 3A includes a first air direction adjusting unit 20A, a first air leakage preventing unit 81A, a second air leakage preventing unit 82A, and a driving unit 70. The wind direction adjusting unit 3A is rotatably attached to the blowing duct 100A.

  20 A of 1st wind direction adjustment parts are the 1st wind direction adjustment board 21A and 2nd wind direction adjustment board 22A which are mutually opposingly arranged, and one end side and other end side of these base end parts 21a and 22a are 1st. And a connecting portion 23A that is connected in the direction in which the first air direction adjusting plate 21A and the second air direction adjusting plate 22A are arranged.

  The first air direction adjusting plate 21A and the second air direction adjusting plate 22A are arranged so as to be inclined so that the distance between the first air direction adjusting plate 21A and the second air direction adjusting plate 22A becomes narrower toward the air blowing downstream side. Yes. The first air direction adjusting plate 21A and the second air direction adjusting plate 22A are narrower in width (W1 in the figure) as it goes toward the air blowing downstream side than the width of the base end portions 21a, 22a located on the air blowing upstream side.

  The first air direction adjusting plate 21A and the second air direction adjusting plate 22A are preferably formed in, for example, a semicircular shape, a semi-elliptical shape, and a semi-polygonal shape, and are mirror-symmetric with each other. The first air direction adjusting plate 21A and the second air direction adjusting plate 22A may be arranged to be inclined so as to have a certain angle, or may be bent and bent in order to further reduce the air resistance. It may be configured to be bent.

  On the short side of the opening end portion 100A2 of the blowout duct 100A, a support portion 101 that extends toward the blower downstream side is provided. The connecting portion 23 of the first wind direction adjusting portion 20A is rotatably supported by the support portion 101.

  The first air leakage prevention unit 81A is configured to be able to follow the rotation of the first air direction adjusting plate 21A while covering the gap between the first air direction adjusting plate 21A and the blowout duct 100A. 81 A of 1st air leak prevention parts can suppress the leakage of the air which blows off from 100 A of blower ducts by covering the clearance gap between 21 A of 1st wind direction adjustment plates, and the blower duct 100A, and the said 1st wind direction It can guide toward the space between the adjusting plate 21A and the second air direction adjusting plate 22A.

  The second air leakage prevention part 82A is configured to follow the rotation of the second air direction adjusting plate 22A while covering the gap between the second air direction adjusting plate 22A and the blowout duct 100A. The second air leakage prevention unit 82A covers the gap between the second air direction adjusting plate 22A and the blowout duct 100A, thereby suppressing leakage of air blown out from the blowout duct 100A and making the air flow in the first wind direction. It can guide toward the space between the adjusting plate 21A and the second air direction adjusting plate 22A.

  The drive part 70 is provided in the side surface of the blower duct 100 which prescribes | regulates the short side of 1st blower outlet 100A1. The drive unit 70 rotates the first air direction adjusting unit 20A around an axis extending in a direction parallel to the width direction of the first air direction adjusting plate 21A and the second air direction adjusting plate 22A as a central axis.

  The detailed configuration of the wind direction adjusting unit 3B is substantially the same as the configuration of the wind direction adjusting unit 3A. As shown in FIG. 4, the wind direction adjusting unit 3B includes a second wind direction adjusting unit 20B, a first air leakage preventing unit 81B, a second air leakage preventing unit 82B, and a drive unit (not shown). The 2nd wind direction adjustment part 20B contains the 1st wind direction adjustment board 21B, the 2nd wind direction adjustment part 22B, and a connection part (not shown).

  When compared with the blower duct 53A, the blower duct 53B in the blower unit 2B has a configuration in which a portion on the downstream side of the blower is rotated approximately 90 degrees in the circumferential direction around the central axis of the blower duct 53A. For this reason, the 2nd wind direction adjustment part 20B in the ventilation unit 2B, the 1st air leak prevention part 81B, the 2nd air leak prevention part 82B, and the drive part are the 1st air direction adjustment part 20A in the air blow unit 2A, the 1st air leak prevention. The part 81A, the second air leakage prevention part 82A, and the drive part 70 are configured to rotate approximately 90 degrees as described above.

  FIG. 6 is a plan view of the ion generator shown in FIG. FIG. 7 is a front view of the ion generator viewed from the direction indicated by the arrow VII shown in FIG. FIG. 8 is a front view of the ion generator as seen from the direction indicated by the arrow VIII shown in FIG. The ion generator will be described with reference to FIGS.

  As shown in FIGS. 6 to 8, the ion generator 60 includes a case 61, discharge electrodes 65a to 65d, an induction electrode (counter electrode) 65e, a high voltage generation circuit unit 66, a substrate 69a, and a substrate 69b. Including.

  The case 61 is composed of an upper case 62 and a lower case 63. The upper case 62 has accommodating portions 62a and 62b. In the accommodating space between the accommodating part 62a and the lower case 63, a substrate 69a for fixing the discharge electrodes 65a and 65b and the induction electrode 65e and the high voltage generating circuit part 66 are accommodated. A substrate 69b that fixes the discharge electrodes 65c and 65d is accommodated in the accommodation space between the accommodation portion 62b and the lower case 63.

  The ventilation space is formed by the inner peripheral surface of the case 61 with the communication portion 68 connecting the accommodation space between the accommodation portion 62a and the lower case 63 and the accommodation space between the accommodation portion 62b and the lower case 63 interposed therebetween. 64a and 64b are formed.

  The discharge electrode 65a and the discharge electrode 65c are accommodated in the case 61 so that the tips thereof are located in the blower space 64a. Further, the discharge electrode 65a and the discharge electrode 65c are arranged to face each other so that the central axes of the electrodes are located on the same straight line.

  The discharge electrode 65b and the discharge electrode 65d are accommodated in the case 61 so that the tips thereof are located in the air blowing space 64b. Further, the discharge electrode 65b and the discharge electrode 65d are arranged to face each other so that the central axes of the electrodes are located on the same straight line.

  These discharge electrodes 65a to 65d have a needle shape with a sharpened tip. The discharge electrodes 65a to 65d are provided in the same plane. The discharge electrodes 65a to 65d are arranged so that the central axes of the electrodes are parallel to each other.

  The discharge electrode 65a and the discharge electrode 65b are separated from each other in a direction orthogonal to the central axis of the electrode. The discharge electrode 65c and the discharge electrode 65d are arranged apart from each other in a direction orthogonal to the central axis of the electrode.

  The induction electrode 65e is disposed between the discharge electrode 65a and the discharge electrode 65b. The induction electrode 65e is provided at a position that is the same distance from the discharge electrode 65a and the discharge electrode 65b, and is provided at a position that is the same distance from the discharge electrode 65c and the discharge electrode 65d.

  The discharge electrode 65a and the discharge electrode 65c generate ions with different polarities, and the discharge electrode 65b and the discharge electrode 65d generate ions with different polarities. The discharge electrode 65a and the discharge electrode 65b generate ions having different polarities, and the discharge electrode 65c and the discharge electrode 65d generate ions having different polarities.

  When a positive or negative high voltage is applied to the discharge electrode 65a and a negative or positive high voltage is applied to the discharge electrode 65b, a corona discharge is generated between the discharge electrode and the induction electrode 65e, and positive ions and Negative ions are generated. Similarly, when a negative or positive high voltage is applied to the discharge electrode 65c and a positive or negative high voltage is applied to the discharge electrode 65d, a corona discharge is generated between the discharge electrode and the induction electrode 65e, Negative ions and positive ions are generated.

  Each of the discharge electrodes 65a to 65d is electrically connected to the high voltage generation circuit unit 66, and the high voltage generated by the high voltage generation circuit unit 66 is applied to the discharge electrodes 65a to 65d.

The positive ions are mainly composed of H ⁺ (H ₂ O) _n and the negative ions are mainly composed of O ₂ ⁻ (H ₂ O) m. n and m are integers. When positive ions and negative ions aggregate on the surface of airborne bacteria and odor components, a hydrogen peroxide solution H ₂ O ₂ or a hydroxyl radical [.OH], which is an active species, is generated by a chemical reaction. Since hydrogen peroxide and hydroxyl radicals have extremely strong activity, suspended bacteria and odor components are destroyed.

  FIG. 9 is a schematic diagram illustrating a first air flow blown out through the first air direction adjusting unit when viewed from the side surface side of the blower. FIG. 10 is a schematic diagram illustrating a second air flow blown out through the second air direction adjusting unit when viewed from the upper surface side of the blower. With reference to FIG. 9 and FIG. 10, the 1st air flow 5 and the 2nd air flow 6 which are blown off via 20 A of 1st wind direction adjustment parts and the 2nd wind direction adjustment part 20B are demonstrated.

  As shown in FIG. 9, the air blown out from the first outlet 100 </ b> A <b> 1 passes through the first wind direction adjusting unit 20 </ b> A in the wind direction adjusting unit 3 </ b> A so as to draw an arc that is convex with respect to the blowing direction. Spreads radially. In this manner, the fan-shaped first air flow 5 is blown out through the first air direction adjusting unit 20A. The first air flow 5 has a predetermined thickness with respect to the horizontal direction (perpendicular to the paper surface), and has a band shape when viewed from the front. By constricting the air into such a shape, the first air flow 5 can be blown far away along a predetermined direction.

  The first air flow 5 has a center line 5a. Here, the center line 5a refers to a line connecting the fastest wind speed portions along the blowing direction in each section when the first air flow 5 is divided and divided in a substantially arc shape along the blowing direction. . There is a tendency that the wind speed of the air passing between the front end portion of the first air direction adjusting plate 21 and the front end portion of the second air direction adjusting plate 22 is increased.

  As shown in FIG. 10, the air blown out from the second outlet 100B1 passes through the second wind direction adjusting unit 20B in the wind direction adjusting unit 3B, thereby drawing a circular arc that is convex with respect to the blowing direction. Spreads radially. In this way, the fan-shaped second air flow 6 is blown out through the second wind direction adjusting portion 20B. The second air flow 6 has a predetermined thickness with respect to the vertical direction (perpendicular to the paper surface), and has a band shape when viewed from the front. By constricting the air into such a shape, the second air flow 6 can be blown far away along a predetermined direction.

  The second air flow 6 has a center line 6a. Here, the center line 6a refers to a line connecting the sections with the highest wind speed along the blowing direction in each section when the second air flow 6 is divided and divided in a substantially arc shape along the blowing direction. . There is a tendency that the wind speed of the air passing between the front end portion of the first air direction adjusting plate 21 and the front end portion of the second air direction adjusting plate 22 is increased.

  FIG. 11 is a diagram showing the blower shown in FIG. 1 and the center lines of the first air flow and the second air flow blown out therefrom. FIG. 11 is a cross-sectional view of the center of the room 200 along the blowing direction. With reference to FIG. 11, a mode that the airflow which blows off from the air blower shown in FIG. 1 is spread | diffused indoors is shown.

  As shown in FIG. 11, the blower device 1 according to the present embodiment is installed at the center on the side wall 200 c side of the room 200. Moreover, the air blower 1 is installed on the floor surface 200b. The blower 1 has the first air flow 5 and the second air flow toward the other side wall 200d located on the side opposite to the installed side wall 200c side via the first wind direction adjusting unit 20A and the second wind direction adjusting unit 20B. Air stream 6 is blown out.

  The first wind direction adjusting unit 20A and the second wind direction are arranged so that the center line 5a of the first air flow 5 and the center line 6a of the second air flow 6 intersect in front of the blower 1 before reaching the other side wall 200d. An adjustment unit 20B is configured. At this time, the elevation angle of the center line 5a is smaller than the elevation angle of the center line 6a. Thereby, the ventilation range of the 1st airflow 5 and the ventilation range of the 2nd airflow 6 can be overlapped in a wider area.

  The first air flow 5 blown out through the first wind direction adjusting portion 20A located above moves toward the other side wall 200d while spreading radially in the vertical direction. The second air flow 6 blown out through the second wind direction adjusting portion 20B located below moves toward the other side wall 200d while spreading radially in the left-right direction (horizontal direction).

  At this time, the first air flow 5 collides with the second air flow 6 and thereby travels toward the side wall 200d while diffusing the second air flow 6 toward the floor surface 200b. Further, the second air flow 6 travels toward the side wall 200d while colliding with the first air flow 5 to diffuse the first air flow 5 in the horizontal direction.

  By using such an air blowing method, air that has been squeezed so as to spread radially in the vertical direction and the horizontal direction by the first air direction adjusting unit 20A and the second air direction adjusting unit 20B is directly collided with each other, thereby efficiently in the room. The air can be diffused.

  In the present embodiment, the case where the center line 5a of the first air flow 5 and the center line 6a of the second air flow 6 intersect in the room has been described as an example. However, the present invention is not limited to this. As long as the blowing range of the first air flow 5 and the blowing range of the second air flow 6 can overlap, the elevation angle and direction of the center line 5a and the center line 6a can be appropriately selected.

  For example, the first wind direction adjusting unit 20A and the second wind direction adjusting unit 20B may be configured such that the elevation angle of the center line 5a is larger than the elevation angle of the center line 6a. In such a case, the center line 5a and the center line 6b do not intersect in the room, but a part of the blowing range of the first air flow 5 and a part of the blowing range of the second air flow 6 overlap. As described above, the first air flow 5 and the second air flow 6 can be diffused horizontally and vertically. As a result, it is possible to efficiently diffuse the air blown out from the air outlet into the room.

  Moreover, although the elevation angle of the center line 5a is smaller than the elevation angle of the center line 6a, the first wind direction adjustment unit 20A and the second wind direction adjustment unit 20B so that the center line 5a and the center line 6a are in a twisted position. May be configured. Even in such a case, a part of the air blowing range of the first air flow 5 and a part of the air blowing range of the second air flow 6 overlap, so that the first air flow 5 and the second air flow 6 are changed. It can be diffused horizontally and vertically. As a result, it is possible to efficiently diffuse the air blown out from the air outlet into the room.

  FIG. 12 is a diagram showing a simulation result regarding the concentration distribution of ions diffused into the room by the blower shown in FIG. With reference to FIG. 12, the simulation result regarding the concentration distribution of ions diffused into the room by the blower 1 will be described.

  As shown in FIG. 12, in this simulation, the elevation angle of the center line 5a of the first air flow 5 is larger than the center line 6a of the second air flow 6, and the center line 5a and the center line 6a do not intersect. An example will be described. Specifically, the center of the first outlet 100A1 is located at 647.5 mm from the floor surface 200b, and the elevation angle of the center line 5a of the first air flow 5 is 20.8 degrees. Further, the center of the second outlet 100B1 was positioned 303.2 mm from the floor surface 200b, and the elevation angle of the center line 6a of the second air flow 6 was 11.9 degrees.

  As a result of this simulation, the room 200 could be divided into five regions according to the ion concentration distribution. Specifically, a region 201 having a very high ion concentration, a region 202 having a high ion concentration next to the region 201, a region 203 having a high ion concentration next to the region 202, and a high ion concentration next to the region 203. The room 200 was divided into a region 204 and a region 205 having a low ion concentration.

  In the region 201, the ion concentration was 13 times or more the ion concentration of the region 205. In the region 202, the ion concentration is 10 times or more and smaller than 13 times the ion concentration of the region 205. In the region 203, the ion concentration is 6 times or more and less than 10 times the ion concentration of the region 205. In the region 204, the ion concentration is 3 times or more and smaller than 6 times that of the region 205.

  Further, by causing the first air flow 5 and the second air flow 6 to collide, each of the regions 201, 202, and 203 having a high ion concentration expanded along the direction in which the center line 6a extends. Further, in the region on the other side wall 200d side, ions were diffused from the top surface 200a side to the floor surface 200b side.

  Thus, it can be seen from the simulation results that ions can be diffused by the blower 1 while the ion concentration is kept high.

  By setting it as the above structures, in the air blower 1 and the air blowing method which concern on this Embodiment, a blowing air can be diffused efficiently indoors, and, thereby, ion is spread to every corner of the room. be able to. Furthermore, ions can be diffused indoors with the ion concentration kept high.

  When the center line 5a and the center line 5b are crossed, the overlapping area of the air blowing range of the first air flow 5 and the air blowing range of the second air flow 6 can be increased, so that the ion concentration is further increased. Ions can be diffused in a state kept at a low temperature.

  Further, when the first air direction adjusting unit 20A and the second air direction adjusting unit 20B are rotated, the overlapping area between the air blowing range of the first air flow 5 and the air blowing range of the second air flow 6 is increased. Since ions can be emitted from each of the first outlet and the second outlet in each direction, the ions can be diffused while the ion concentration is kept at a higher level.

  For example, when the first wind direction adjusting portion 20A is rotated in the vertical direction about the axis extending in the direction parallel to the width direction of the first wind direction adjusting plate 21A and the second wind direction adjusting plate 22A, the vertical direction Ions can be further diffused, and the second wind direction adjusting portion 20B is rotated in the left-right direction with an axis extending in a direction parallel to the width direction of the first wind direction adjusting plate 21B and the second wind direction adjusting plate 22B as the central axis. In some cases, ions can be further diffused in the left-right direction.

  Since ions can remove floating bacteria and odor components in the air, the ions are diffused in a state where the ion concentration is kept high, so that the blower 1 according to the present embodiment removes the ions. The bacteria deodorizing effect can be improved.

  In addition, in this Embodiment, although the case where air was ventilated from air blower 51A, 51B via the duct 4A, 4B separately provided in several 1st blower outlet 100A1 and 2nd blower outlet 100B1, was illustrated. However, the present invention is not limited to this. That is, the air blower is not limited to a configuration in which the same number of ducts and blowers are provided for a plurality of air outlets, and a plurality of ducts branched to the downstream side of the air flow communicate with the air outlets. The structure by which air is ventilated from a single air blower via the duct may be sufficient.

  Further, the wind speed of the first air flow and the wind speed of the second air flow may be the same or different. By adjusting the wind speed of the first air flow and the wind speed of the second air flow, the region in which the air is diffused can be expanded. For example, when the wind speed of the first air flow is made faster than that of the second air flow, the force of the first air flow to push the second air flow toward the floor surface 200b becomes stronger, and the air is drawn by the floor surface 200b side. Can be diffused.

  Moreover, in this Embodiment, although the air blower 1 illustrated and demonstrated the case where ion was discharge | released from all the some blower outlets, it is not limited to this, At least 1 blower is demonstrated. You may be comprised so that ion may be discharge | released from an exit.

(Embodiment 2)
FIG. 13 is a diagram showing the air blower according to the present embodiment and the center lines of the first air flow and the second air flow blown out therefrom. FIG. 13 is a view of the blower 1 </ b> C disposed in the room 200 as viewed from the top side. With reference to FIG. 13, a blower 1 </ b> C according to the present embodiment will be described.

  As shown in FIG. 13, the blower 1 </ b> C according to the present embodiment is arranged so that two blower units are aligned in the horizontal direction in the housing 10 when compared with the blower 1 according to the first embodiment. The other configurations are substantially the same. The configuration of the two blower units is the same as that of the blower unit 2A according to the first embodiment.

  In the blower 1C according to the present embodiment, the center line 5b of the first air flow 5 and the center line 6b of the second air flow 6 intersect before the blower 1C before reaching the other side wall 200d in the room. Thus, the first wind direction adjusting unit 20C and the second wind direction adjusting unit 20D are configured. The center line 5b is inclined so as to approach the second wind direction adjusting unit 20D with respect to the front direction of the blower 1, and the center line 6b is closer to the first wind direction adjusting unit 20C with respect to the front direction of the blower 1. It is inclined to. Thereby, the ventilation range of the 1st airflow 5 and the ventilation range of the 2nd airflow 6 can be overlapped.

  The first air flow 5 blown out through the first wind direction adjusting unit 20C moves radially toward the other side wall 200d along the extending direction of the center line 5b while spreading radially in the vertical direction (the direction perpendicular to the paper surface). . The second air flow 6 blown out through the second wind direction adjusting unit 20D spreads radially in the vertical direction (perpendicular to the paper surface) and moves toward the other side wall 200d along the direction in which the center line 6b extends. .

  The first air flow 5 collides with the second air flow 6, so that the second air flow 6 on the side wall 200 f located on the second airflow direction adjustment unit 20 D side among the pair of side walls 200 e and 200 f substantially parallel to the blowing direction. Toward the wall 200d while diffusing. The second air flow 6 collides with the first air flow 5, and thus travels toward the other wall 200d while diffusing the first air flow toward the side wall 200e located on the first air direction adjusting portion 20C side.

  By using such a blowing method, air blown by the first wind direction adjusting unit 20C and the second wind direction adjusting unit 20D to collide with each other directly in a vertical direction is directly collided with each other, thereby efficiently blowing air into the room. Can be diffused.

  As a result, even in the air blowing device 1C and the air blowing method according to the present embodiment, the same effect as the air blowing device 1 and the air blowing method according to the first embodiment can be obtained.

  In the present embodiment, the case where the center line 5b of the first air flow 5 and the center line 6b of the second air flow 6 intersect each other has been described as an example. As long as it is possible to overlap the blowing range of the second air flow, it is not limited to this. For example, the center line 5b of the first air flow 5 and the center line 6b of the second air flow 6 may be in a twisted positional relationship.

  Further, the wind speed of the first air flow and the wind speed of the second air flow may be the same or different. By adjusting the wind speed of the first air flow and the wind speed of the second air flow, the region in which the air is diffused can be expanded. For example, when the wind speed of the first air flow is made faster than that of the second air flow, the force of the first air flow that pushes the second air flow toward the side wall 200f becomes stronger, and the air is diffused on the side wall 200f side. be able to.

(Embodiment 3)
FIG. 14 is a diagram showing the blower according to the present embodiment and the center lines of the first air flow and the second air flow blown from the blower. FIG. 14 is a cross-sectional view of the center of the room 200 along the blowing direction. With reference to FIG. 14, the air blower 1E which concerns on this Embodiment is demonstrated.

  As shown in FIG. 14, the blower 1 </ b> E according to the present embodiment is arranged so that two blower units are arranged in the vertical direction in the housing 10 when compared with the blower 1 according to the embodiment. However, the other configurations are almost the same. The configuration of the two blower units is the same as that of the blower unit 2B according to the first embodiment.

  In the blower 1E according to the present embodiment, the center line 5c of the first air flow 5 and the center line 6c of the second air flow 6 intersect before the blower 1E before reaching the other side wall 200d in the room. Thus, the first wind direction adjusting unit 20E and the second wind direction adjusting unit 20F are configured. The center line 5c has a predetermined depression angle so as to approach the second wind direction adjusting unit 20F. The center line 5d has a predetermined elevation angle so as to approach the first wind direction adjusting unit 20E. Thereby, the ventilation range of the 1st airflow 5 and the ventilation range of the 2nd airflow can be overlapped.

  The first air flow 5 blown out through the first air direction adjusting unit 20E moves radially toward the other side wall 200d along the direction in which the center line 5c extends while spreading radially in the horizontal direction (perpendicular to the paper surface). To do. The second air flow 6 blown out through the second wind direction adjusting unit 20F moves toward the other side wall 200d along the direction in which the center line 6c extends while spreading radially in the horizontal direction (the vertical direction on the paper surface). .

  The first air flow 5 collides with the second air flow 6 and thereby travels toward the other side wall 200d while diffusing the second air flow 6 toward the floor surface 200b. The second air flow 6 collides with the first air flow 5 and travels toward the other side wall 200d while diffusing the first air flow 5 toward the top surface 200a.

  By using such a blowing method, air that has been squeezed so as to spread radially in the horizontal direction by the first air direction adjusting unit 20E and the second air direction adjusting unit 20F is directly collided with each other, thereby efficiently blowing the air into the room. Can be diffused.

  As a result, even if it exists in the air blower 1E and air blowing method which concern on this Embodiment, the effect similar to the air blower 1 which concerns on Embodiment 1 is acquired.

  In the present embodiment, the case where the center line 5c of the first air flow 5 and the center line 6c of the second air flow 6 intersect each other has been described as an example. As long as it is possible to overlap the blowing range of the second air flow, it is not limited to this. For example, the center line 5c of the first air flow 5 and the center line 6c of the second air flow 6 may be in a twisted positional relationship.

  Further, the wind speed of the first air flow and the wind speed of the second air flow may be the same or different. By adjusting the wind speed of the first air flow and the wind speed of the second air flow, the region in which the air is diffused can be expanded. For example, when the wind speed of the second air flow is higher than that of the first air flow, the second air flow has a stronger force to push the first air flow toward the top surface 200a, and the air is absorbed by the top surface 200a. Can be diffused.

(Verification experiment)
FIG. 15 is a diagram showing an observation position of a verification experiment performed for verifying the effect of the present invention. With reference to FIG. 15, a verification experiment conducted to verify the effect of the present invention will be described.

  In this verification experiment, the air blower 1 which concerns on Embodiment 1 was used as Example 1,2. In the first embodiment, the first wind direction adjusting unit 20A and the second wind direction adjusting unit 20B are configured so that the center line 5a and the center line 6a intersect each other. In the second embodiment, the first wind direction adjusting unit 20A is configured so that the center line 5a has the same conditions as in the first embodiment, and the second wind direction adjusting unit is set so that the center line 6a and the floor surface 200b are parallel to each other. 20B was constructed.

  The air blower 1 was installed in a room 200 equivalent to 8 tatami mats (width 3.6 m × depth 3.6 m × height 2.4 m). The blower 1 was installed on the floor surface 200b located in the center of the room 200 on the one wall 200c side.

  The ion concentration of the ions released from the blower 1 was measured at a position Q that is a predetermined distance D1 mm away from the one side wall 200c where the blower 1 was installed. In a plane P parallel to one side wall 200c, a substantially rectangular region having a predetermined size surrounding the center was defined as an ion concentration measurement region. The ion concentration was measured at each of a plurality of lattice points formed when the measurement region was divided into a lattice shape. The ion concentrations in Example 1 and Example 2 were measured at the same lattice points, and the values were compared.

  Also in the air blower in the second embodiment, the first air flow 5 blown out from the first wind direction adjusting unit 20A located above moves toward the other side wall 200d while spreading radially in the vertical direction. Accordingly, the first air flow 5 and the second air flow 6 can be efficiently diffused indoors to a considerable extent by diffusing the second air flow 6 blown out from the second wind direction adjusting unit 20B located below. did it. On the other hand, in the air blower according to the first embodiment, the center line 5a of the first air flow 5 and the center line 6a of the second air flow 6 intersect each other in the room, so that the first air flow 5 and the second air flow 5 The air flow 6 could be diffused into the room more efficiently.

  When comparing the ion concentration of Example 1, the ion concentration of Example 1 slightly decreased at about 20% of the measurement points of ion concentration, but increased at the remaining 80% of measurement points. Was. Thus, the tendency for the ion concentration of Example 1 to increase as a whole was observed.

  Specifically, the decrease rate of the ion concentration was 5% to 40%, whereas the increase rate of the ion concentration was several percent to 400%. The ion concentration of Example 1 as a whole increased by about 47% compared to the ion concentration of Example 2.

  Further, even when the measurement area was divided into three in the horizontal direction, the ion concentration in Example 1 increased compared to the ion concentration in Example 2 in each of the divided areas.

  Furthermore, even when the measurement region was divided into three in the vertical direction, the ion concentration in Example 1 increased compared to the ion concentration in Example 2 in each of the divided regions.

  From the above results, in the air blower 1 and the air blowing method according to Embodiment 1, ions can be diffused in a state where the ion concentration is kept at a high concentration, and in particular, the center line 5a of the first air flow It can be said that it was confirmed experimentally that ions can be spread to every corner of the room by crossing the center line 6a of the second air flow.

  Moreover, in the air blower 1 and the air blowing method according to Embodiment 1, the first air flow and the second air flow can be efficiently diffused in the room so that the ions are spread to every corner of the room. It has been confirmed experimentally.

  Although the embodiments and examples of the present invention have been described above, the embodiments and examples disclosed this time are illustrative and not restrictive in all respects. The scope of the present invention is defined by the terms of the claims, and includes meanings equivalent to the terms of the claims and all modifications within the scope.

  1, 1C, 1E Blower, 2A, 2B Blower unit, 3, 3A, 3B Air direction adjusting unit, 4, 4A, 4B Duct, 5 First air flow, 5a, 5b, 5c, 5d, 6a, 6b, 6c Center Wire, 6 second air flow, 10 housing, 11 suction port, 12, 62a, 62b accommodating portion, 14, 15 opening, 18A, 18B protective net, 20A, 20C, 20E first wind direction adjusting portion, 20B, 20D , 20F 2nd wind direction adjustment part, 21A, 21B 1st wind direction adjustment board, 21a, 22a Base end part, 22A, 22B 2nd wind direction adjustment board, 23 connection part, 51A, 51B Blower, 52A, 52B Blower path, 53, 53A, 53B Air duct, 60, 60A, 60B Ion generator, 61 case, 62 Upper case, 63 Lower case, 64a, 64b Air space, 65a, 65b , 65c, 65d Discharge electrode, 65e induction electrode, 66 high voltage generation circuit part, 68 communication part, 69a, 69b substrate, 70 drive part, 81A, 81B first air leakage prevention part, 82A, 82B second air leakage prevention part , 100, 100A, 100B outlet duct, 100A1 first outlet, 100B1 second outlet, 101A support.

Claims (4)

A first air outlet and a second air outlet that blow air toward the outside;
A first air direction adjusting portion located on the air blowing downstream side of the first air outlet;
A second wind direction adjusting unit located on the air blowing downstream side of the second air outlet;
A blower for blowing air to the first air outlet and the second air outlet,
The first wind direction adjusting unit and the second wind direction adjusting unit are a first air flow blowing range blown through the first wind direction adjusting unit and a second blown out through the second wind direction adjusting unit. It is configured so that the air flow blowing range can overlap in the open space ,
Each of the first wind direction adjusting unit and the second wind direction adjusting unit includes a first wind direction adjusting plate and a second wind direction adjusting plate that are arranged to be spaced apart from each other.
The first air direction adjusting plate and the second air direction adjusting plate are disposed so as to be inclined so that a distance between the first air direction adjusting plate and the second air direction adjusting plate becomes narrower toward the air blowing downstream side. And
The first air direction adjusting plate and the second air direction adjusting plate have a width that is narrower toward the air blowing downstream side than the width of the base end portion located on the air blowing upstream side . A direction in which the first wind direction adjusting plate and the second wind direction adjusting plate are arranged in the first wind direction adjusting unit, and the first wind direction adjusting plate and the second wind direction adjusting plate in the second wind direction adjusting unit. a direction aligned intersect, blower according to claim 1. An ion generator that emits ions to the air blown by the blower;
The blower according to claim 1 or 2 , wherein air containing ions is blown out from at least one of the first air outlet and the second air outlet. The blower according to any one of claims 1 to 3 , wherein the first wind direction adjusting unit and the second wind direction adjusting unit are configured to be rotatable so that a blowing direction changes.

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