JP7291042B2 - Air cleaner - Google Patents

Description

The present invention relates to air cleaners.

For example, Patent Literature 1 discloses an air purifier that can change the direction of the air blown out from the outlet provided on the upper surface to be backward from the vertical direction along the wall surface of the surrounding room. The blow-out port is provided with a louver including a partition blade that divides the region into a region through which the first blown air passes and a region through which the second blown air passes. The partition blades of the louver are inclined with respect to the vertical direction to change the direction of the air blown out from the outlet.

JP 2015-59707 A

However, in the air purifier described in Patent Literature 1, the air could not be sent forward or forward and downward in the room.

SUMMARY OF THE INVENTION In view of the above problems, an object of the present invention is to provide, as an example, an air purifier capable of blowing air forward or forward and downward from an air outlet formed on the upper surface.

An air purifier according to an aspect of the present invention comprises a housing, an air outlet formed on an upper surface of the housing for blowing air, and an air passage provided in the housing and communicating with the air outlet. A wall portion and a louver that rotates to change the direction of the air are provided, and the louver extends from the air passage toward the air outlet and curves toward the front side of the housing. It has a curved surface.

1 is a perspective view of an air cleaner according to Embodiment 1 of the present invention; FIG. FIG. 2 is a front view of the air cleaner shown in FIG. 1; FIG. 2 is a right side view of the air cleaner shown in FIG. 1; FIG. 2 is a plan view of the air cleaner shown in FIG. 1; FIG. 3 is a cross-sectional view of the air purifier shown in FIG. 2 taken along line VV; 6 is a partially enlarged cross-sectional view showing an air outlet of the air cleaner shown in FIG. 5; FIG. (a) It is a perspective view showing the rotation mechanism of the air cleaner shown in FIG. 1. (b) It is an exploded perspective view showing the rotation mechanism of the air cleaner shown in FIG. 1. (c) It is shown in FIG. FIG. 10 is a partially enlarged cross-sectional view showing a rotation mechanism of the air purifier. (a) It is a side cross-sectional view showing a first posture of the operation unit of the air cleaner shown in FIG. 1. (b) It is a side cross-sectional view showing a second posture of the operation unit of the air cleaner shown in FIG. .

Hereinafter, each embodiment of the present invention will be described with reference to the drawings. In the present specification and drawings, the same or equivalent elements are denoted by the same reference numerals to omit redundant description, and elements that are not directly related to the present invention may be omitted from the drawings. Furthermore, the forms of the components shown in these embodiments are merely examples, and the present invention is not limited to these forms.

(First embodiment)
The overall structure of an air cleaner 100 according to Embodiment 1 of the present invention will be described with reference to FIGS. 1 to 5. FIG. In the following description, the side of the air purifier 100 where the suction port 120 is provided is referred to as the rear side or rear side, and the side of the air purifier 100 facing the rear side is referred to as the front side or front side. The right side of the air cleaner 100 means the right side when the air cleaner 100 is viewed from the front, and the left side of the air cleaner 100 means the left side when the air cleaner 100 is viewed from the front. do. FIG. 1 is a perspective view of the air cleaner 100. FIG. FIG. 2 is a front view of the air cleaner 100. FIG. 3 is a right side view of air cleaner 100. FIG. FIG. 4 is a plan view of the air cleaner 100. FIG. FIG. 5 is a cross-sectional view of the air cleaner 100 shown in FIG. 2 taken along line VV.

The appearance of the air cleaner 100 will be described with reference to FIGS. 1 to 4. FIG. Air purifier 100 includes housing 110 . The housing 110 includes a front surface 110a, a rear surface 110b, a left side 110c, a right side 110d, a top surface 110e, and a bottom surface 110f, and is formed in a substantially frustum shape with an opening in the top surface 110e. The housing 110 is formed to expand outward from the top to the bottom. Specifically, the front surface 110a and the rear surface 110b are slanted outward so that the distance between them increases toward the bottom. Similarly, the left side 110c and the right side 110d are slanted outward so that the distance between them increases toward the bottom. The front surface 110a is connected to the left side surface 110c and the right side surface 110d by smooth curved surfaces. Similarly, the rear surface 110b is connected to the left side 110c and the right side 110d by smooth curved surfaces. As described above, the outer peripheral surface surrounding the housing 110 is formed in a substantially rectangular shape in plan view.

A rear surface 110b of the housing 110 is formed with a suction port 120 for taking in air (wind). The suction port 120 consists of a plurality of holes formed in a rear panel detachably provided on the housing 110 . An upper surface 110e of the housing 110 is formed with an air outlet 130 for blowing out air (wind). A water supply tank 140 is detachably provided on the right side surface 110d of the housing 110 . Grips 150 are formed on the upper portions of the left side 110c and the right side 110d of the housing 110, respectively, so that the housing 110 can be easily carried. A plurality of wheels 160 are attached to the bottom surface 110f of the housing 110 so that the air cleaner 100 can be smoothly moved along the floor surface S. The air outlet 130 is provided with a louver 300 described later for switching the direction of air (wind) blown from the air outlet 130 .

A display unit 170 that indicates the operating state of the air cleaner 100 may be provided on the front surface 110 a of the housing 110 . As an example, the display unit 170 includes a substrate on which an LED light source is arranged, and irradiates light from the inside of the housing 110 toward the front surface 110a of the housing 110 having translucency, so that the user can see The operating state of the air purifier 100 and the like are displayed.

The internal structure of air cleaner 100 will be described with reference to FIG. The inside of housing 110 is configured such that air flows from inlet 120 toward outlet 130 . A pre-filter 210 , a deodorizing filter 220 , a dust collection filter 230 , a humidification unit 240 , a blower 250 , and a discharge device 260 are provided in this order from the suction port 120 toward the blowout port 130 inside the housing 110 .

The pre-filter 210 is for collecting dust (coarse dust) in the passing air. The pre-filter 210 is formed of sheet-like mesh such as polypropylene, for example. The pre-filter 210 is attached inside the rear surface 110 b of the housing 110 so as to face the suction port 120 .

Inside the housing 110, a housing portion 110g for housing the deodorizing filter 220 and the dust collecting filter 230 is formed. The housing portion 110g is a substantially rectangular parallelepiped recessed space formed at a position facing the suction port 120 of the housing 110 on the rear side of the housing 110 . The deodorizing filter 220 and the dust collection filter 230 are accommodated in order from the upstream side in the air flow direction in the accommodation portion 110g.

The deodorizing filter 220 is for deodorizing the air by adsorbing odorous components (for example, acetaldehyde, ammonia, acetic acid, etc.) in the passing air. As an example, the deodorizing filter 220 has a structure in which a polyester nonwoven fabric is attached to a rectangular frame, activated carbon is evenly distributed thereon, and the polyester nonwoven fabric is covered thereon.

The dust collection filter 230 is for collecting dust in the passing air, specifically fine dust and fine particles such as PM2.5 having a particle size smaller than a predetermined particle size (for example, 3 μm). is. The dust collection filter 230 is, for example, a HEPA (High Efficiency Particulate Air) filter, and has a structure in which a frame material is welded by hot melt so as to cover the filter material.

The humidification unit 240 is for humidifying the passing air. The humidification unit 240 is arranged in front of the housing portion 110g, more specifically in front of the dust collection filter 230. As shown in FIG. The humidification unit 240 includes a tray 240a for storing water, and a humidification filter 240b arranged with its lower part immersed in the water in the tray 240a. The tray 240 a is configured to be able to supply water from the water supply tank 140 . The humidification unit 240 humidifies the air by vaporizing the water contained in the humidification filter 240b by blowing air onto the humidification filter 240b.

A fan 250 is arranged in front of the humidifying unit 240 , that is, on the front bottom side of the housing 110 . The blower 250 has a fan 250a and a fan motor (not shown) that drives the fan 250a. The fan 250a is formed by a centrifugal fan such as a sirocco fan, and is configured to take in air in the axial direction (front-rear direction) and send out air in the circumferential direction (upward).

A partition wall 110 h is arranged between the humidifying unit 240 and the blower 250 . 110 h of partitions are arrange|positioned so that the internal space of the housing|casing 110 may be divided into front and back, and the upper part is extended so that it may incline to back. A humidifying unit 240, a dust collection filter 230, a deodorizing filter 220 and a pre-filter 210 are arranged behind the partition wall 110h. A blower 250 is arranged in front of the partition wall 110h. A plurality of air holes 110i communicating with the blower 250 are formed in the partition wall 110h. As a result, the air taken into the housing 110 through the suction port 120 is sucked into the blower 250 through the ventilation holes 110i.

Inside the housing 110, an air passage 200 that communicates from the fan 250a to the outlet 130 is formed. The air passage 200 consists of a first air passage 200a on the upstream side and a second air passage 200b on the downstream side. The first air passage 200a is a duct having a substantially rectangular cross-section, which is composed of a partition wall 110h and a fan case 250b that houses the fan 250a. The upper portion of the fan case 250b (the portion positioned above the fan 250a) is formed to extend upward while being inclined from the front to the rear, similarly to the partition wall 110h, and is attached so as to surround the front surface of the partition wall 110h. It is As described above, the first air passage 200a is configured, for example, so that the direction of inclination is rearward and obliquely upward. Although the first air passage 200a is configured to extend rearward and obliquely upward, it is not limited to this, and may be configured to extend at least upward.

A discharge device 260 is provided on the upper wall surface of the fan case 250b. As an example, the discharge device 260 is arranged such that a needle-shaped discharge electrode is exposed in the air passage 200, and generates ions by applying a high voltage. The ions generated by the discharge device 260 are blown out from the outlet 130 along with the air flow by the blower 250 .

The second airflow passage 200b is connected to the upper end portions (end portions in the airflow direction) of the fan case 250b and the partition wall 110h. The second air passage 200b connects the first air passage 200a and the outlet 130 . The housing 110 has an upper cover (not shown) in which the outlet 130, the second air passage 200b, and the outer peripheral surface of the upper portion of the housing 110 are integrally formed. Configured as part of the top cover.

In the above configuration, by rotating the fan 250a, the air sucked from the suction port 120 moves forward inside the housing 110 and passes through the pre-filter 210, the deodorizing filter 220, and the dust collecting filter 230. , the air is purified into odor and dust-free air and humidified by the humidification unit 240 . Ions generated by the discharge device 260 are added to the air blower 250 while proceeding obliquely upward from the blower 250 . More specifically, air containing ions is blown forward or forward and downward from a first blower port 130a, which will be described later, and is blown rearward and obliquely upward from a second blower port 130b, which will be described later.

In addition, the air cleaner 100 does not have a function of cleaning the pre-filter 210, but is not limited to this. It may be configured to In addition, the air cleaner 100 has a structure for humidifying air and a structure for generating ions, but is not limited to this. It may have a function of dehumidifying the air.

The outlet 130 and the second air passage 200b will be described with reference to FIG. FIG. 6 is a partially enlarged cross-sectional view showing the outlet 130 of the air cleaner 100. As shown in FIG.

An air outlet 130 is formed in the upper surface 110 e of the housing 110 . As an example, the air outlet 130 is formed over the entire upper surface 110e, and is formed in a substantially rectangular shape elongated in the left-right direction. Therefore, the upper surface 110 e is composed of the edges that form the outlet 130 . In addition, although the outlet 130 is formed over the entire upper surface 110e, it is not limited to this, and may be formed in a part of the upper surface 110e.

The second air passage 200b has a curved surface or an inclined surface that is inclined with respect to the first air passage 200a. The wall portion 201 forming the second air passage 200b is, for example, curved so as to widen toward the outlet 130 . That is, the second air passage 200b has a wall portion 201 configured as a curved surface. The wall portion 201 is formed so that the opening becomes wider as it approaches the outlet 130 . The widening of the opening means that the cross-sectional area of the second air passage 200b is increased in the direction orthogonal to the direction in which the air flows (inclination direction of the first air passage 200a). The wall portion 201 is curved to protrude upward inside the housing 110 . In other words, the wall portion 201 is formed in a substantially funnel shape that inclines (curves) downward from the outlet 130 .

As described above, the second air passage 200b has the wall portion 201 configured as a curved surface. may In this case, the wall portion 201 is formed so as to widen toward the outlet 130 . Also, the second air passage 200b may have an inclined surface that is inclined with respect to the vertical direction.

The louver 300 is for switching the direction of the air (wind) blown out from the outlet 130 . The louver 300 is configured to be able to change the direction of the air (wind) blown out from the outlet 130 by being rotated by a rotation mechanism 400 (see FIG. 7), which will be described later. The louver 300 is provided with an operation unit 350 for setting various operations of the air cleaner 100 . The setting of various operations of the air purifier 100 means, for example, the setting of operation start, operation stop, operation mode selection, air volume, air direction, etc. of the air purifier 100 . That is, the louver 300 also has a function as the operation section 350 . The operation unit 350 includes, for example, a touch panel. As described above, the louver 300 has both the function of changing the direction of the wind as described above and the function of setting various operations of the air purifier 100, thereby reducing the number of design elements. It can be a more stylish design. Various operations are set by the operation unit 350 in the louver 300, but the setting is not limited to this, and may be performed in a setting unit other than the louver 300. FIG.

A louver 300 is provided from the air passage 200 to the outlet 130 . More specifically, louver 300 is provided so as to protrude from second air passage 200b to the outside of housing 110 .

The louver 300 has a base body 310 formed in a substantially crescent shape in a side view by combining two bow-shaped plate-like members in the front-back direction. The front plate-shaped member is formed of a curved surface portion 310 a that extends from the air passage 200 toward the outlet 130 and curves toward the front side of the housing 110 . The rear plate-shaped member includes a rear surface portion 310b extending from the air passage 200 toward the blower outlet 130, and an upper surface portion 310c curved from the rear surface portion 310b and extending toward the front side. The base 310 is formed in a hollow shape, and a substrate, a touch panel, and the like constituting the operation unit 350 are accommodated in the hollow portion. More specifically, a substrate and a touch panel that constitute the operation unit 350 are superimposed on the upper surface portion 310c, and various operations of the air purifier 100 can be performed by the user operating the upper surface portion 310c. can.

The base 311 side of the base body 310, that is, the portion positioned inside the air duct 200 is arranged so as to traverse the inside of the second air duct 200b in the left-right direction, partitioning it into the front and rear. In addition, the base 311 side of the base 310 is arranged closer to the front in the second air passage 200b. Further, the lateral width of the base 310 on the side of the base 311 is formed so as to increase in accordance with the lateral width in the second air passage 200b from the lower portion toward the upper portion.

As described above, the base 310 divides the second air passage 200b into the front and rear. Below, the air passage located in the front portion with the substrate 310 interposed therebetween is referred to as a first branch flow passage 200c. The first branch channel 200c mainly refers to a space surrounded by a portion of the wall portion 201 extending from the front surface to the side surface and the curved surface portion 310a. That is, a portion of the louver 300 (the curved surface portion 310a) constitutes the first branch channel 200c. Below, the outlet of the first branch channel 200c is referred to as a first outlet 130a. Further, the air passage located in the rear portion with the base 310 interposed therebetween is referred to as a second branch flow passage 200d. 200 d of 2nd branch flow paths refer to the space mainly surrounded by the back surface part 310b and the part which reaches the back surface from the side surface among the wall parts 201. As shown in FIG. Below, the outlet of the second branch flow path 200d is referred to as a second outlet 130b. By rotating the louver 300 with a rotating mechanism 400 (see FIG. 7), which will be described later, the opening areas of the first outlet 130a and the second outlet 130b are changed. More specifically, as the louver 300 rotates, the opening area of one outlet (eg, the first outlet 130a) increases, and the opening of the other outlet (eg, the second outlet 130b) increases. It is designed to have a small area.

The front end portion 312 side of the base 310 , that is, the portion positioned outside (above) the outlet 130 is formed to face the front (forward) side of the housing 110 . Further, the substrate 310 is formed such that the distance (thickness) between the curved surface portion 310a and the upper surface portion 310c facing each other decreases toward the tip portion 312 side.

The base body 310 extends from the air passage 200 toward the air outlet 130 and is curved toward the front side of the housing 110 , so that the front end portion 312 of the base body 310 extends toward the front side of the air outlet 130 . It is configured to be positioned substantially above the edge 130c. In the above configuration, the first outlet 130a can blow forward the air flowing through the first branch flow path 200c by forming an opening on the front side. Further, the base body 310 extends from the air passage 200 toward the air outlet 130 and has a curved surface portion 310a that curves toward the front side of the housing 110, thereby efficiently sending air to the first air outlet 130a. can be done. That is, the curved surface portion 310a functions as a guide surface that guides the air flowing through the first branch flow path 200c to the first blowout port 130a.

In addition, the air flowing through the second branch flow path 200d is mainly blown rearward and obliquely upward from the second outlet 130b along substantially the same direction as the inclination direction of the first air blowing path 200a. At this time, the base 310 is arranged near the front portion in the second air passage 200b, and the back portion 310b is formed so as to extend upward (substantially directly above) from the base portion 311 side. It is less likely to obstruct the air flowing through the flow path 200d. As described above, the air purifier 100 can blow air forward as well as upward from one air outlet 130 formed in the upper surface 110e.

Hereinafter, the wall portion 201 facing the curved surface portion 310a is also referred to as a first wall portion 201a, and the wall portion 201 facing the back surface portion 310b is also referred to as a second wall portion 201b. The first wall portion 201a refers to a portion that curves downward from the front side edge portion 130c of the outlet 130 toward the inside. The second wall portion 201b refers to a portion that curves downward and inward from the rear side edge portion 130d of the outlet 130 .

The first wall portion 201a is formed so that the distance between the first wall portion 201a and the curved surface portion 310a is substantially the same. That is, the first wall portion 201a has substantially the same curved surface as the curved surface portion 310a. As a result, the air flowing through the first branch flow path 200c can be smoothly guided to the first outlet 130a by the first wall portion 201a and the curved surface portion 310a, thereby improving the blowing efficiency. Furthermore, since a portion of the louver 300 (the curved surface portion 310a) constitutes the first branch flow path 200c, the direction of the wind can be easily switched simply by rotating the louver 300. FIG.

In the above configuration, the wall portion 201 is curved so as to widen toward the blowout port 130 along the circumferential direction of the blowout port 130 . It may be configured to be curved so as to widen toward.

Also, the wall portion 201 is formed so that, for example, the tangential direction approaches the horizontal direction as it approaches the outlet 130 . As a result, the air flowing along the wall portion 201 can be smoothly guided forward. Although the wall portion 201 is configured so that the tangential direction approaches the horizontal direction over the circumferential direction, the tangential direction of the first wall portion 201a is not limited to this, and as it approaches the outlet 130, the tangential direction becomes You may form so that it may approach a horizontal direction.

Further, the outlet 130 is configured, for example, such that the rear side edge 130d is higher than the front side edge 130c. As a result, the air flowing through the second branch flow path 200d can be stably sent out rearward and obliquely upward.

As shown in FIGS. 6 and 7A, the base 310 has a pair of projections formed so as to protrude from the curved surface portion 310a toward the wall portion 201 (first wall portion 201a) (front and lower). A sidewall 320 is provided. The pair of side walls 320 are provided at both ends of the base 310 in the left-right direction, and are connected to the curved surface portion 310a by a smooth curved surface.

The pair of side walls 320 can prevent the air that has flowed into the first branch flow path 200c from flowing sideways. Further, in the second posture of the louver 300, which will be described later, when the distance between the front end portion 312 of the base 310 and the front side edge portion 130c of the outlet 130 becomes narrower and the flow velocity of the blown air increases, It is possible to suppress the air from flowing sideways (for example, leftward or rightward) from the first outlet 130a.

A damper 330 that changes the flow rate balance of the air flowing through the first branched flow path 200c and the second branched flow path 200d is provided in the blowing path 200, for example. The damper 330 is formed in the shape of a thin plate, and supports the lower portion so as to be rotatable in the front-rear direction about a pivot shaft 330a provided on the upper portion. By rotating the damper 330, the air flow balance between the first branch flow path 200c and the second branch flow path 200d is changed.

The damper 330 is provided, for example, around the upper end of the first air passage 200a. The rotating shaft 330a is arranged below the base 311 of the base 310, and the damper 330 is configured to be changeable between three positions. More specifically, the inclination direction of the damper 330 is the same as the inclination direction of the first air passage 200a (rear diagonally upward), and as it progresses from the first position P1 to the upstream side (downward) of the air passage 200, , a second position P2 in which the damper 330 is inclined rearward, and a third position P3 in which the damper 330 abuts against and is locked to the front wall surface forming the first air passage 200a. Configured. At the third position P3, the damper 330 is configured to contact and be locked to the locking portion 330b formed on the front wall surface of the first air passage 200a.

The damper 330 is configured to send a predetermined amount of air into each of the first branched flow path 200c and the second branched flow path 200d at the first position P1. The damper 330 increases the flow rate of air flowing through the first branch flow path 200c at the second position P2 compared to the first position P1. The damper 330 is configured so as not to substantially flow air into the first branch flow path 200c at the third position P3. That is, it is configured to flow most of the air through the second branch flow path 200d. As described above, by arranging the damper 330 inside the blowing passage 200 and configuring the damper 330 so that it can be changed to three positions (three postures), the first branch flow passage 200c and the second branch flow passage 200d It changes the flow rate balance of the flowing air.

The airflow path 200 is provided with, for example, a first straightening member 340a that straightens the air entering the first branched flow path 200c and a second straightening member 340b that straightens the air entering the second branched flow path 200d. The first rectifying member 340a is attached to the first wall portion 201a side. The first rectifying member 340a is a lattice-shaped member formed by combining a plurality of rectifying plates so that air can be sent upward (substantially directly above). The second straightening member 340b is attached to the second wall portion 201b side. The second rectifying member 340b is a lattice-shaped member formed by combining a plurality of rectifying plates so that air can be sent out obliquely backward and upward. The first straightening member 340 a and the second straightening member 340 b are connected at the base 311 of the base 310 .

A rotating mechanism 400 for the louver 300 will be described with reference to FIG. FIG. 7A is a perspective view showing the rotating mechanism 400 of the air cleaner 100. FIG. FIG. 7B is an exploded perspective view showing the rotation mechanism 400 of the air cleaner 100. FIG. FIG. 7C is a partially enlarged sectional view showing the rotation mechanism 400 of the air cleaner 100. FIG. The louver 300 is rotated by the rotating mechanism 400 to change the direction of air (wind) blown mainly from the first outlet 130a. The rotating mechanism 400 includes a rotating arm 410 , a mounting plate 420 , a spring 430 , a spring cover 440 and an arm retainer 450 .

As shown in FIG. 7( a ), the rotating mechanism 400 has a pair of rotating arms 410 for rotating the base 310 . The rotating arm 410 is made of a hollow cylindrical member and is curved so as to protrude downward. One end of the rotating arm 410 is rotatably supported in the space behind the first wall portion 201a. The space behind the first wall portion 201a refers to a space surrounded by the first wall portion 201a and the outer peripheral surface of the housing 110 (for example, the front surface 110a). The other end of the rotating arm 410 passes through the bottom of the base 310 and is fixed to an internal wall surface (not shown). As a result, the louver 300 is configured such that the other end side of the rotating arm 410 can rotate in the front-rear direction with one end of the rotating arm 410 serving as a fulcrum. The rotating arms 410 are attached to the left and right ends of the base 310 by the same mechanism.

As shown in FIGS. 7B and 7C, one end of the rotating arm 410 is rotatably supported by a mounting plate 420 provided on the back side of the first wall portion 201a. The mounting plate 420 is a plate-shaped member provided so as to protrude from the first wall portion 201a toward the back side (forward). The rotating mechanism 400 has a spring 430 that biases one end of the rotating arm 410 toward the mounting plate 420 from the side. A spring cover 440 is attached to one end of the spring 430 to contact the rotating arm 410 to lock the rotating arm 410 . The spring cover 440 is formed in a cylindrical shape and is rotatably supported relative to a recess 410 a provided at one end of the rotating arm 410 . An arm presser 450 fastened to the mounting plate 420 is attached to the other end of the spring 430 . That is, the rotating arm 410 is locked between the mounting plate 420 and the arm retainer 450 by being biased against the mounting plate 420 by the spring cover 440 to which the biasing force of the spring 430 is applied. The biasing force of the spring 430 refers to a biasing force capable of locking the louver 300 in a desired posture.

In the above configuration, when the user pushes in or pulls out the louver 300 (base body 310), the rotating arm 410 is rotated against the biasing force of the spring 430, and the louver 300 is held in a desired posture. can be rotated to Then, the biasing force of the spring 430 can lock the louver 300 in a desired posture. In addition, since the rotating arm 410 is configured in a hollow shape, the lead wires connected to the substrate constituting the operation unit 350 and the substrate of the irradiation unit 600 to be described later can be routed out of the airflow path 200 through the inside of the rotating arm 410. can guide you.

The rotation posture of the louver 300 will be described with reference to FIG. FIG. 8A is a side sectional view showing the first posture of the louver 300. FIG. FIG. 8B is a side sectional view showing the second posture of the louver 300. FIG.

As shown in FIGS. 6 and 8A, the first posture of the louver 300 refers to a posture in which the tip portion 312 of the base 310 is positioned substantially above the front edge portion 130c of the blower port 130. As shown in FIGS. The curved surface portion 310a of the louver 300 and the first wall portion 201a are arranged so that the distance therebetween is approximately the same. As a result, the air flowing through the first branch flow path 200c is efficiently blown forward from the first outlet 130a. Here, the tip portion 312 of the curved surface portion 310a is located inside the front side edge portion 130c (the housing 110) of the outlet 130. As shown in FIG.

As shown in FIG. 8B, the second posture of the louver 300 is a posture in which the louver 300 is rotated from the first posture so as to be drawn forward. More specifically, the second posture is a posture in which tip portion 312 of louver 300 (curved surface portion 310 a ) is positioned in the front direction (forward) relative to housing 110 . The second posture is a posture in which the tip portion 312 of the curved surface portion 310a faces obliquely downward. A tip portion 312 of the curved surface portion 310a is positioned (protrudes) outside a front side edge portion 130c (housing 110) of the outlet 130. As shown in FIG. As a result, the air flowing through the first branch flow path 200c is blown forward and downward from the first outlet 130a. Here, the interval between the curved surface portion 310a and the first wall portion 201a is configured to become narrower toward the distal end portion 312 .

As described above, the rotating mechanism 400 is configured to be able to rotate the louver 300 from the first posture to the second posture. As a result, in the room where the air purifier 100 is placed, the first posture is adopted when it is desired to send air forward, and the second posture is adopted when it is desired to discharge air toward the bottom of the room. wind direction can be changed according to Further, by constructing the rotating mechanism 400 so as to be accommodated in the space on the back side of the first wall portion 201a, the rotating mechanism 400 can be arranged without difficulty using the existing space. In addition, since the operation unit 350 is configured by a touch panel, it is possible to set various operations without pressing the operation unit 350 . Therefore, even if the louver 300 is configured to be rotatable, various operations can be set without carelessly rotating the louver 300 . Although the louver 300 is manually rotated, the configuration is not limited to this, and the louver 300 may be rotated using a motor or the like.

As shown in FIG. 8, at the top of the first rectifying member 340a, wind is directed to an air passage (first branch passage 200c) composed of a curved surface portion 310a and a wall portion 201 (first wall portion 201a). A guide portion 500 for guiding is provided in the air passage 200 . The guide portion 500 is attached to the first wall portion 201a, the first straightening member 340a, and the like. The guide part 500 is a hollow duct-like member that is fan-shaped when viewed from the side. The guide part 500 is configured to take in air from an opening (not shown) formed at the bottom and to let air out from an opening (not shown) formed at the front.

The guide portion 500 has a sliding surface 500a that slidably supports the base 310 as the louver 300 rotates. The sliding surface 500a is an outer peripheral surface of the guide portion 500, more specifically, a surface forming an arc portion in a side view. The sliding surface 500a and the lower portion of the curved surface portion 310a of the louver 300 are formed along the locus of rotation about the pivot point of the louver 300. As shown in FIG. In the first posture of the louver 300, the sliding surface 500a and the lower portion of the curved surface portion 310a of the louver 300 are in close contact with each other. When the louver 300 is rotated forward from the first posture, the curved surface portion 310a of the louver 300 slides along the sliding surface 500a and shifts to the second posture. In the second posture of the louver 300, the sliding surface 500a and the lower portion of the curved surface portion 310a of the louver 300 are in a state of being partially in contact with each other.

As shown in FIG. 8, the curved surface portion 310a of the louver 300 is provided with, for example, a locking portion 310d for restricting backward rotation. The locking portion 310d is formed in the middle of the curved surface portion 310a and is a stepped portion that locks the upper portion of the guide portion 500. As shown in FIG. As a result, the louver 300 is regulated so as not to rotate backward from the first posture. A support portion 500b that protrudes rearward is formed at the lower end portion of the sliding surface 500a so as to support the base portion 311 of the louver 300. As shown in FIG. Thereby, the louver 300 can be stably supported in the first posture.

As described above, the sliding surface 500a is formed along the locus of rotation of the louver 300, so that the louver 300 can be rotated while being stably supported. In addition, even if the louver 300 rotates forward, air can be reliably introduced into the first branch flow path 200c through the guide portion 500. As shown in FIG.

The irradiation unit 600 that irradiates the air passage 200 with light will be described with reference to FIG. 8 . In FIG. 8A, the irradiation area of the irradiation unit 600 in the first posture of the louver 300 is schematically represented as an area surrounded by straight lines indicated by reference characters L1 and L2 (the hatched area). In FIG. 8B, the irradiation area of the irradiation unit 600 in the second posture of the louver 300 is schematically represented as an area surrounded by straight lines indicated by reference characters L3 and L4 (the hatched area).

The air cleaner 100 has an irradiation unit 600 that irradiates a curved surface provided on the downstream side of the air duct 200 with light. That is, the irradiation section 600 is configured to irradiate the wall section 201 configured as the curved surface of the second airflow path 200b. In addition, as an example, the irradiation unit 600 irradiates light in the rearward direction (rear) of the housing 110 . Although the air cleaner 100 is configured to irradiate the wall 201 configured as a curved surface with light, the present invention is not limited to this, and for example, a configuration in which the wall 201 configured as an inclined surface is configured to irradiate light. good too.

The irradiation unit 600 is provided, for example, in a louver 300 that changes the wind direction. More specifically, the irradiation section 600 is provided on the back side of the louver 300 (back section 310b). In addition, the irradiation unit 600 is arranged below the outlet 130 .

The irradiation unit 600 includes, for example, an LED light source (not shown) and a lens (not shown) that bends light from the LED light source. An LED light source is positioned inside the substrate 310 . The lens is arranged inside the substrate 310 to face the light source on the illumination side of the light source. The lens has an optical characteristic of emitting light from the LED light source in a predetermined direction (for example, toward the back of the housing 110). A portion of the back surface portion 310b of the base 310 that intersects with the irradiation direction from the LED light source is formed as a translucent region 600a. The translucent region 600a is formed by molding translucent glass or resin. Although a lens is used to emit the light from the LED light source in a predetermined direction, the present invention is not limited to this. The light from the LED light source may be emitted in a predetermined direction by processing.

In the above configuration, the light emitted from the irradiation unit 600 is emitted to the wall portion 201 configured as a curved surface, more specifically, to the second wall portion 201b through the translucent region 600a. In this manner, the irradiation surface of the light emitted from the irradiation unit 600 is a curved surface, and the light is reflected (scattered) on the curved surface, so that the vicinity of the air outlet 130 can be illuminated. Further, by curving the second wall portion 201b so as to widen toward the outlet 130, it becomes easier for the user to visually recognize the light reflected (scattered) by the second wall portion 201b. In addition, by curving the second wall portion 201b so that the tangential direction approaches the horizontal direction as it approaches the outlet 130, the light irradiated to the end of the outlet 130 is reflected (scattered) upward. easier to be Further, by forming the wall portion 201 in a curved shape when viewed from above, the light irradiated to the wall portion 201 can be easily reflected (scattered) in all directions (front, back, left, and right). This reduces the direct exposure of the user's eyes to the light emitted from the irradiation unit 600, that is, reduces the glare felt by the user, while reducing the amount of light reflected (scattered) by the second wall 201b. can be easily recognized. Therefore, it is possible to give a soft impression to the user, and to suppress spoiling the atmosphere of the room. Also, the irradiation unit 600 is provided below the outlet 130 . Also, an irradiation unit 600 is provided on the back side of the louver 300 . This makes it possible to reduce the direct exposure of the user's eyes to the light emitted from the irradiation unit 600 . In addition, since the outlet 130 is configured so that the back side edge 130d is higher than the front side edge 130c, the light distribution range on the back side can be widened, and the user's visibility is improved. be.

The irradiation area of the irradiation unit 600 in the first posture and the second posture of the louver 300 will be described with reference to FIGS. 8(a) and 8(b). The irradiation unit 600 is configured so that at least the second wall 201b is included in the irradiation area regardless of the posture of the louver 300 . As shown in FIG. 8A, in the first posture of the louver 300, the irradiation area of the irradiation section 600 is mainly configured to be the second wall section 201b. That is, in the first posture of the louver 300, the irradiation section 600 is configured to irradiate the second wall section 201b with light. As shown in FIG. 8B, in the second posture of the louver 300, the irradiation range of the irradiation section 600 includes at least the second wall section 201b. More specifically, the optical axis (not shown) of the irradiation unit 600 is positioned near the edge 130d of the outlet 130 on the side of the outlet 130 of the second wall 201b. It is configured. Thereby, the irradiation unit 600 can illuminate the outlet 130 side more. In addition, in the second posture of the louver 300 , the irradiation unit 600 irradiates the indoor wall surface W above the air outlet 130 , for example, behind the housing 110 , in addition to the second wall portion 201 b. can illuminate.

As described above, regardless of the direction in which the air is blown out (rotation posture of the louver 300), at least the second wall portion 201b is configured to be illuminated with light, thereby reducing glare to the user and can give the impression of soft light to In addition, by changing the irradiation location by the irradiation unit 600 according to the direction of blowing air (rotating posture of the louver 300), the user can intuitively grasp the blowing direction of the air (wind). Become. In addition, in the second posture of the louver 300 , the irradiation unit 600 is configured to illuminate the outlet 130 side more than in the first posture of the louver 300 . Instead, it may be configured to illuminate the same portion of the second wall portion 201b.

The present invention is not limited to the above embodiments, and various modifications are possible. For example, it can be replaced with a configuration that is substantially the same as the configuration shown in the above embodiment, a configuration that produces the same effects, or a configuration that can achieve the same purpose.

100 air cleaner, 110 housing, 110e upper surface, 130 outlet, 200 air passage, 200a first air passage, 200b second air passage, 201 wall, 201a first wall, 201b second wall, 300 louver 310a curved surface portion 320 pair of side walls 350 operation portion 500 guide portion 600 irradiation portion

Claims (5)

a housing;
an air outlet formed on the upper surface of the housing for blowing air;
a wall portion that is provided in the housing and that constitutes an air passage that communicates with the air outlet;
a louver that changes the direction of the wind by rotating,
The louver extends from the air passage toward the outlet and has a curved surface portion that curves toward the front side of the housing,
An air purifier , wherein the louver is rotated so that the tip of the louver is located in the front direction relative to the housing . 2. The air cleaner according to claim 1 , wherein said wall facing said curved surface is curved so as to widen toward said outlet. The air cleaner according to claim 1 or 2 , wherein said louver has a pair of side walls protruding from said curved surface portion toward said wall portion. The air purifier according to any one of claims 1 to 3 , wherein the air duct includes a guide portion that guides the air to an air duct composed of the curved surface portion and the wall portion. The air purifier according to any one of claims 1 to 4 , wherein the louver has an operation portion for operating the air purifier.

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