KR20060061384A - Floor mounted air conditioner - Google Patents

Abstract

A floor mounted air conditioner (1) capable of selecting a variety of air flows, comprising a casing (4), a plurality of first horizontal flaps (80), a first flap control mechanism (21), and a second flap control mechanism (22). A first outlet (12) blowing out a conditioned air is formed in the casing (4). The plurality of first horizontal flaps (80) are installed at the first outlet (12) parallel with each other in the vertical direction (D2) and guide the air blowing out from the first outlet (12). The first flap control mechanism (21) can control the direction of the plurality of first horizontal flaps (80) belonging to the first horizontal flap group (G1) among the plurality of first horizontal flaps (80). The second flap control mechanism (22) can control the direction of the plurality of first horizontal flaps (80) belonging to the second horizontal flap group (G2) among the plurality of first horizontal flaps (80) independently of the first horizontal flap group (G1).

Description

Upper teeth type air conditioner {FLOOR MOUNTED AIR CONDITIONER}

The present invention relates to a phased air conditioner.

One of the air conditioners that blows the harmonized air into the room to perform air conditioning in the room is a so-called moist air conditioner. This air conditioner type air conditioner is an air conditioner of the type provided in the floor of an interior, and is equipped with the casing in which the blowout port was provided. A plurality of flaps are arranged at the blowout outlets arranged side by side in the vertical direction, and these flaps guide the air blown out of the blowout outlets. In such a phased air conditioner, the direction of the air blown out from the blowout port can be changed by changing the direction of the plurality of flaps. The structure which links and moves all is provided, and when the direction of a flap is changed manually or automatically, the direction of all flaps is changed to the same direction uniformly (refer patent document 1).

Patent Document 1: Japanese Unexamined Patent Publication No. 2003-343871

In the above-described standing type air conditioner, when the wind direction of the air from the blowout port is changed, the degree of freedom of selection of the wind direction is low. In order to create a comfortable air-conditioning environment, it is desirable to be able to select various air flows, but it is difficult to realize various air flows when the degree of freedom in selecting the wind direction is low.

An object of the present invention is to provide an air conditioner type air conditioner capable of selecting various air flows.

The phase-mounted air conditioner of the first invention includes a casing, a plurality of first flaps, a first flap adjusting mechanism, and a second flap adjusting mechanism. The casing is provided with a first blow-out port through which the harmonized air blows out. The plurality of first flaps are provided side by side in the vertical direction at the first outlet, and guide the air blown out from the first outlet. The 1st flap adjustment mechanism is a mechanism which can adjust the direction of the some 1st flap which belongs to a 1st flap group among a some 1st flap. The 2nd flap adjustment mechanism is a mechanism which can adjust the direction of the some 1st flap which belongs to a 2nd flap group among a some 1st flap independently from a 1st flap group.

In this phase-mounted air conditioner, a plurality of first flaps are divided into at least two groups of the first flap group and the second flap group, and the first flap adjustment mechanism and the second flap adjustment mechanism are used for each group. Adjustment is possible. For this reason, the flow of the air enclosed in the up-down direction can be realized by, for example, raising the group located on the upper side and lowering the group located on the lower side. In addition, by directing both the first flap group and the second flap group in the same direction, or by moving the upper group downward and the lower group upward, the air flow is concentrated to the far air. It is also possible to reach the flow of. As described above, in this phase air conditioner, various air flows can be selected.

The phase-mounted air conditioner of the second invention is the phase-mounted air conditioner of the first invention, wherein the first blowout port has a shape long in the vertical direction.

In this phase-mounted air conditioner, since the first blow-out port has a shape long in the vertical direction, a wider flow of air can be generated in the vertical direction.

The phase-mounted air conditioner of the third invention is the phase-type air conditioner of the first invention or the second invention, wherein the first flap adjustment mechanism has a first link member. The first link member is a member connected to a plurality of first flaps belonging to the first flap group and movable in the vertical direction. In addition, the second flap adjusting mechanism has a second link member. The second link member is a member connected to a plurality of first flaps belonging to the second flap group and movable in the vertical direction independently of the first link member.

In this phased air conditioner, the force which changes the direction of the 1st flap of a 1st flap group is transmitted by a 1st link member. Moreover, the force which changes the direction of the 2nd flap of a 2nd flap group by a 2nd link member is transmitted independently from a 1st link member. For this reason, the direction of the 1st flap of a 1st flap group, and the direction of the 1st flap of a 2nd flap group can be changed separately. Thereby, in this phase-mounted air conditioner, the direction of a 1st flap can be adjusted for every group of a 1st flap group and a 2nd flap group.

In the lettuce type air conditioner of 4th invention, the 1st link member and the 2nd link member are respectively provided so that a movement is possible manually.

In this phase-mounted air conditioner, the plurality of first flaps can be manually changed in direction. In the case where the direction of the first flap can be changed manually in this manner, if all the first flaps are linked, the influence of the gravity direction is also applied, and a relatively large force is required for the movement of the first flap. However, in this phased air conditioner, since the first flap is linked to each of the groups of the first flap group and the second flap group, compared to the case where all the first flaps are linked, 1 You can change the direction of the flap. Thereby, the operability for changing the direction of a 1st flap can be improved.

The phase difference type air conditioner of 5th invention is further equipped with the 3rd flap adjustment mechanism in the phase type air conditioner of any one of 1st invention-4th invention. The 3rd flap adjustment mechanism is a mechanism which can adjust the direction of the some 1st flap which belongs to a 3rd flap group among a some 1st flap independently from a 1st flap group and a 2nd flap group. And a 1st flap group, a 2nd flap group, and a 3rd flap group are arrange | positioned side by side in a perpendicular direction.

In this phase-mounted air conditioner, the direction of a 1st flap can be adjusted for every group of 1st flap group, 2nd flap group, and 3rd flap group arrange | positioned side by side in a perpendicular direction. For this reason, in this phase air conditioner, more various air flows can be selected.

The air conditioner of the sixth aspect of the invention is the air conditioner of any one of the first to fifth aspects of the invention, wherein the casing includes air in which the air is disposed in parallel with the first outlet in the transverse direction when viewed from the front. A second blowout outlet is further provided. This phase-mounted air conditioner further includes a plurality of second flaps, a fourth flap adjusting mechanism, and a fifth flap adjusting mechanism. The plurality of second flaps are provided side by side in the vertical direction at the second outlet, and guide the air blown out from the second outlet. The fourth flap adjustment mechanism is a mechanism capable of adjusting the directions of the plurality of second flaps belonging to the fourth flap group among the plurality of second flaps. The 5th flap adjustment mechanism is a mechanism which can adjust the direction of the some 2nd flap which belongs to a 5th flap group among a some 2nd flap independently from a 4th flap group.

In this phase-mounted air conditioner, a 1st blowout port and a 2nd blowout port are arrange | positioned side by side in the horizontal direction, and the some 1st flap and the some 2nd flap are provided, respectively. In addition to the plurality of first flaps, the plurality of second flaps can be adjusted in directions for each group of the fourth flap group and the fifth flap group. For this reason, not only the vertical direction but also the freedom degree of the flow of air of a horizontal direction, ie, a horizontal direction, can be improved. As a result, in this phased air conditioner, more various air flows can be selected.

Effect of the Invention

In the step-type air conditioner of the first aspect of the invention, since the direction can be adjusted for each group by the first flap adjusting mechanism and the second flap adjusting mechanism, various air flows can be selected.

In the phase-mounted air conditioner of the second invention, since the first blowout port has a shape long in the vertical direction, a wider flow of air can be generated in the vertical direction.

In the step-type air conditioner of 3rd invention, the direction of the 1st flap of a 1st flap group and the direction of the 1st flap of a 2nd flap group are changed separately by a 1st link member and a 2nd link member. It is possible. Thereby, in this phase-mounted air conditioner, the direction of a 1st flap can be adjusted for every group of a 1st flap group and a 2nd flap group.

In the phase-in-type air conditioner of 4th invention, compared with the case where all the 1st flaps are linked, the direction of the 1st flap of each group can be changed with a small force. Thereby, the operability for changing the direction of a 1st flap can be improved.

In the step-type air conditioner of the fifth invention, the direction of the first flap can be adjusted for each group of the first flap group, the second flap group, and the third flap group, which are arranged side by side in the vertical direction. The choice of flow is possible.

In the phase-mounted air conditioner of the sixth invention, not only the vertical direction but also the degree of freedom of the flow of the air in the lateral direction, that is, the horizontal direction can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a front view of an appearance of an air conditioner.

Fig. 2 is a front view showing the configuration of the lettuce air conditioner.

3 is a top cross-sectional view illustrating a configuration of a phase-mounted air conditioner.

4 is a side sectional view showing a configuration of an upset type air conditioner.

5 is a front view showing the configuration of the first horizontal flap portion and the second horizontal flap portion;

6 is a perspective view showing details of a configuration of a first horizontal flap portion;

The perspective view which shows the detail of the structure of a 1st horizontal flap part.

Fig. 8 is a control block diagram of a phase air conditioner according to the first embodiment.

9 illustrates the operation of the first vertical flap and the second vertical flap.

10 illustrates the operation of the first vertical flap and the second vertical flap.

11 illustrates the operation of a first horizontal flap and a second horizontal flap.

12 illustrates the operation of a first horizontal flap and a second horizontal flap.

It is a schematic diagram which shows the effect concerning the extraction of this invention.

It is a schematic diagram which shows the effect concerning the extraction of this invention.

Fig. 15 is a control block diagram of a phase air conditioner according to a second embodiment.

Fig. 16 is a schematic diagram showing the effect of taking out the present invention.

<Explanation of symbols for the main parts of the drawings>

1: normal type air conditioner 4: casing

12: first outlet 13: second outlet

21: first flap adjusting mechanism 22: second flap adjusting mechanism

23: third flap adjusting mechanism 24: fourth flap adjusting mechanism

25: 5th flap adjustment mechanism 80: 1st horizontal flap (1st flap)

81: first link member 82: second link member

90: 2nd horizontal flap (2nd flap) G1: 1st horizontal flap group (1st flap group)

G2: 2nd horizontal flap group (2nd flap group) G3: 3rd horizontal flap group (3rd flap group)

G4: 4th horizontal flap group (4th flap group) G5: 5th horizontal flap group (5th flap group)

D1: transverse direction D2: vertical direction

[First Example]

<Configuration>

[Overall structure]

The front view of the external appearance of the upper tooth type air conditioner 1 which employ | adopted 1st Example of this invention is shown in FIG. In addition, in a present Example, when it says "a horizontal direction" or "left and right", suppose the left-right direction when it sees from the front of FIG. 1 among horizontal directions (refer solid line arrow D1). In addition, when it is called "vertical direction" or "up-down," it shall say the up-down direction when seen from the front shown in FIG. 1 (refer to solid arrow D2).

This air conditioner 1 is an air conditioner installed on the floor F of a home interior, and performs air conditioning of indoors, such as air-conditioning. The phase-mounted air conditioner 1 is connected to an outdoor unit (not shown) arranged outdoors, and constitutes a refrigerant circuit between a compressor or an outdoor heat exchanger (not shown) accommodated in the outdoor unit. The phase-mounted air conditioner 1 mainly includes a heat exchanger 2, a fan 3, a casing 4, a control unit 10, and a remote controller 11.

〔heat transmitter〕

As shown in FIG. 2 and FIG. 3, the heat exchanger 2 is housed inside the casing 4 and performs heat exchange with air received in the casing 4. As shown in FIG. 2, the heat exchanger 2 occupies the position of the upper half of the upper tooth type air conditioner 1, and the 1st blowout opening 12 and the 2nd blowout opening 13 which are mentioned later are mentioned. It is placed at the same height as Moreover, as shown in FIG. 4, the heat exchanger 2 is provided so that the upper part may incline to the rear side of the upper air conditioner 1. As shown in FIG. In addition, FIG. 2 is a front view of the upset type air conditioner 1 from which the front panel 43 was removed, FIG. 3 is sectional drawing III-III in FIG. 1, and FIG. 4 is FIG. IV-IV cross section.

〔Pan〕

The fan 3 is housed inside the casing 4. The fan 3 sucks the indoor air into the casing 4 from the suction part 6 (refer to FIG. 1) which will be described later, and then, through the heat exchanger 2, the first blowout outlet 12 and the second blowout outlet ( 13) to send. The fan 3 is one sirocco fan which is arrange | positioned so that it may rotate in the surface parallel to the front of the upset type air conditioner 1, As shown in FIG. It is installed below. Moreover, the fan 3 is arrange | positioned in the vicinity of the suction part 6 mentioned later as shown in FIG. The fan 3 is accommodated in the fan casing 30 as shown in FIG. The fan casing 30 has an arcuate side surface 32 which surrounds about three quarters of the circumference of the fan 3 along the side of the fan 3, and the fan 3 has a fan 3. It is arranged to face the side of. The fan casing 30 surrounds the left half part of the side surface of the fan 3, and the lower half part of the right side. In addition, a fan casing outlet 31 is provided in the fan casing 30. The fan casing outlet 31 is a portion in which air flows out from the fan 3 toward the upper heat exchanger 2 and is located at the upper half of the right side of the fan 3 which is not surrounded by the fan casing 30. It is arrange | positioned in the facing position. The casing outlet 31 is provided eccentrically from the rotation center of the fan 3 to the right direction. In addition, the fan 3 rotates counterclockwise in FIG. 2 and sends air to the heat exchanger 2 (refer to the white arrow A1 and the solid arrow A2 of FIG. 2).

[Casing]

The casing 4 is a box-shaped member long in the vertical direction D2 for accommodating the heat exchanger 2, the fan 3, and the like. In the casing 4, as illustrated in FIG. 3, the angle 42 of the back surface 40 is chamfered. As shown in FIG. 1, the front surface 41 of the casing 4 has a shape having a front panel 43, a groove 44, and an inclined surface 45. Moreover, the casing 4 has the 1st blowout opening 12, the 2nd blowout opening 13, the suction part 6, the 1st vertical flap part 5, the 2nd vertical flap part 7, and the 1st horizontal flap. The part 8 and the 2nd horizontal flap part 9 are provided.

The front panel 43 is a flat portion provided on the front of the casing 4 over the entirety of the casing 4 in the vertical direction D2. In addition, a display unit 46 is provided above the front panel 43, and the display unit 46 displays information such as an indoor temperature, an outdoor temperature, a setting of an operation, and the like.

The groove part 44 is a groove long in the vertical direction D2 provided along the side end of the front panel 43, and is provided in both sides of the front panel 43, respectively. The groove part 44 is comprised by the side surface 440 and the curved surface 441, as shown in FIG. The side surface 440 is continuous with the front panel 43 and is provided perpendicular to the front panel 43. The curved surface 441 is continuous with the side surface 440 and further continues with the inclined surface 45.

The inclined surface 45 is an inclined surface adjacent to the side of the groove portion 44 and provided over the entire vertical direction D2 of the front surface 41. The inclined surface 45 is provided at both side ends of the front surface 41, respectively.

<The first outlet and the second outlet>

The 1st blowout outlet 12 and the 2nd blowout outlet 13 are provided in the upper half of the front surface 41 of the casing 4, and the air adjusted by the heat exchanger 2 blows out. In addition, the air which is not temperature-adjusted may blow out from the 1st blowout outlet 12 and the 2nd blowout outlet 13 at the time of a blowing operation.

The first ejection opening 12 and the second ejection opening 13 are rectangular openings having an elongated shape in the vertical direction D2 provided along both side ends of the front surface 41. The 1st blowout outlet 12 and the 2nd blowout outlet 13 are provided in the upper half of the inclined surface 45, and the 1st blowout outlet 12 is located on the left side through the front panel 43 and the groove part 44 between them. Is provided, and the 2nd blowout port 13 is provided in the right side. Therefore, the 1st blowout outlet 12 and the 2nd blowout outlet 13 are arrange | positioned side by side at a distance in the horizontal direction D1 from the front view. As shown in FIG. 5, the 1st blowout outlet 12 and the 2nd blowout outlet 13 are respectively divided into three of the upper part S1, the middle part S2, and the lower part S3 by the partition plate 49. As shown in FIG. have. Moreover, the projection part 14a-14c, 15a-15c which protrudes in a perpendicular direction is provided in the upper end part and the partition plate 49 of the 1st blowout outlet 12 and the 2nd blowout outlet 13, respectively. The upper end of the first ejection opening 12 is provided with a projection 14a projecting downward in the vertical direction, and the partition plate 49 of the first ejection opening 12 is a projection 14b, 14c projecting upward in the vertical direction. ) Is installed. The 1st flap motor 50 is being fixed so that the front-end | tip of the drive shaft may face upward in the vicinity of the lower end part of the 1st blow-out port 12. As shown in FIG. The drive shafts of the protrusions 14a-14c and the first flap motor 50 are arranged in a straight line at a distance in the vertical direction, and to the second rotation shaft AX1 of the first vertical flap 51 described later. It corresponds. Similarly, the projection part 15a which protrudes perpendicularly downward is provided in the upper end part of the 2nd ejection opening 13, The projection part 15b which protrudes perpendicularly upward in the partition plate 49 of the 2nd ejection opening 13 is similar. , 15c) is installed. In the vicinity of the lower end part of the 2nd blowout port 13, the 2nd flap motor 70 is being fixed so that the front-end | tip of the drive shaft may face upward. The drive shafts of the projections 15a-15c and the second flap motor 70 are arranged in a straight line at a distance in the vertical direction, and correspond to the second rotation shaft AX2 of the second vertical flap 71 described later. have. In addition, the drive shafts of the projections 14a-14c and the first flap motor 50 provided in the first outlet 12 are located outside the center of the first outlet 12, that is, on the left side. It is located between the center of 12 and the outer edge part of the 1st blowout port 12. As shown in FIG. In addition, the "center" here means the center in the horizontal direction D1, and it is the same below. The drive shafts of the protrusions 15a-15c and the second flap motor 70 provided in the second outlet 13 are located outside the center of the second outlet 13, that is, on the right side, and are centered on the second outlet 13. It is located between and the outer edge part of the 2nd blowout port 13. In addition, each of the protrusions 14a-14c and 15a-15c is rotatably fitted with a first vertical flap 51 and a second vertical flap 71 to be described later, and each of the flap motors 50 and 70. The lower end of the 1st vertical flap 51 and the lower end of the 2nd vertical flap 71 are respectively fixed to the drive shaft of.

<Suction part>

The suction part 6 is a part which sucks indoor air in the casing 4, and is shown in the lower half of the front surface 41 of the casing 4, as shown in FIG. The suction part 6 is comprised by the 1st suction port 61, the 2nd suction port 62, and the side suction ports 66 and 67. As shown in FIG.

The first suction port 61 and the second suction port 62 are openings provided in the side surface 440 of the groove part 44, and the first suction port 61 is provided in the groove part 44 on the left side, and the groove part 44 on the right side is provided. The second suction port 62 is provided. As shown in FIG. 4, the first suction port 61 is configured by three openings 63, 64, and 65, and is arranged side by side in the vertical direction D2. The uppermost opening 63 is disposed at a position higher than the fan 3, and the other two openings 64, 65 are disposed at a lower position than the fan 3. That is, the 1st suction port 61 is arrange | positioned in the position which does not oppose the fan 3. The same applies to the second suction port 62. In addition, the position where each inlet port 61, 62 is arrange | positioned is not limited to the position which does not strictly face the fan 3, The position of the extent to which a part of each inlet port 61, 62 is caught by the fan 3, It may be arranged in. Furthermore, each suction port 61 and 62 is not limited to the case where it is divided | segmented up and down of the fan 3, and may be arrange | positioned only to an upper direction or a lower direction.

The side suction ports 66 and 67 are openings long in the vertical direction D2 as shown in FIG. 4, respectively provided below the side surface 47 of the upper air conditioner 1. The side suction ports 66 and 67 are located between the fan 3 and the front surface 41 in the width direction D3. In addition, in FIG. 4, although the side suction port 66 provided in the side surface 47 of the left side is seen from the front, the same also applies to the side suction port 67 provided in the side surface 47 of the right side.

In addition, a filter (not shown) covering the lower side of the casing 4 is provided to face the first suction port 61, the second suction port 62, and the side suction ports 66 and 67.

<1st horizontal flap part and 2nd horizontal flap part>

The 1st horizontal flap part 8 is a part for guiding the air blown out from the 1st blowout port 12, and separating in the perpendicular direction D2. As shown in FIG. 5, the first horizontal flap portion 8 includes a plurality of first horizontal flaps 80 (first flaps), a first flap adjusting mechanism 21, a second flap adjusting mechanism 22, and It has the 3rd flap adjustment mechanism 23.

The plurality of first horizontal flaps 80 are arranged side by side in the vertical direction D2 at the first outlet 12, and guide the air blown out from the first outlet 12 to be separated in the vertical direction D2. In the present embodiment, the plurality of first horizontal flaps 80 includes a first horizontal flap group G1 and a first flap group, a second horizontal flap group G2 and a second flap group, and a third horizontal flap group ( G3, 3rd flap group), It is divided into three groups, and one group has five 1st horizontal flaps 80. As shown in FIG. The first horizontal flap group G1, the second horizontal flap group G2, and the third horizontal flap group G3 are respectively an upper portion S1, a middle portion S2, and a lower portion S3 of the first outlet 12. It is arrange | positioned at and arrange | positioned in the vertical direction D2. The 1st horizontal flap 80 showed the shape of the thin plate shape formed with the elastic material, and is arrange | positioned substantially horizontally.

In addition, the first horizontal flap 80 is not limited to the case where the whole is formed of an elastic material, and a part of the first horizontal flap 80 such as a center portion may be formed of the elastic material. Moreover, even if it is not formed with an elastic material, the 1st horizontal flap 80 may be made to have elasticity, such as forming the 1st horizontal flap 80 in thin shape.

The 1st flap adjustment mechanism 21 is a mechanism which can adjust the direction of the some 1st horizontal flap 80 which belongs to the 1st horizontal flap group G1, and is the 1st link member 81 and the 1st fixing member ( 84). As shown in FIG. 6, the 1st link member 81 is a plate-shaped member long in the perpendicular direction D2 which connects the front vicinity of the outer edge part of the 1st horizontal flap group G1. The first link member 81 moves the tip of the first horizontal flap group G1 integrally in the vertical direction D2 by moving in the vertical direction D2. Moreover, the 1st slit 801 and the 2nd slit 802 which penetrate in the horizontal direction D1 are provided in the 1st link member 81. As shown in FIG. The 1st slit 801 has shown the shape which curved convexly to the rear side, and is provided in the upper part of the 1st link member 81. As shown in FIG. The second slit 802 also has the same shape as the first slit 801, and is provided below the first link member 81. In the first slit 801 and the second slit 802, two locking clips 121 and 122 provided at the edge of the first outlet 12 are inserted, respectively, and the locking clips 121 and 122 are firstly inserted into the first slit 801 and the second slit 802. The slit 801 and the second slit 802 are locked so as to be slidably in contact with each other. Moreover, the operation part 803 which protrudes inward is provided between the 1st slit 801 and the 2nd slit 802 in the center vicinity of the inner surface of the 1st link member 81, and The user can easily move the first link member 81 in the vertical direction D2 by holding the operation portion 803. In addition, as shown in FIG. 7, the outer surface of the first link member 81 is provided with a plurality of recesses 804 recessed in the inward direction (in addition, in FIG. Only the recessed part 804 is attached | subjected and others are abbreviate | omitted). The plurality of recesses 804 are arranged side by side in the vertical direction D2, and the protrusions 123 (see FIG. 6) provided in the edge portion of the first ejection opening 12 are inserted. When the protrusion 123 is inserted into the recess 804, the protrusion 123 is engaged with the recess 804 to regulate the movement of the first link member 81 in the vertical direction D2. When a user grasps the operation part 803 and applies a force to the 1st link member 81, the 1st link member 81 moves, and the protrusion 123 will be locked to the other recessed part 804. FIG. As a result, the first link member 81 is positioned at a desired position. In addition, since the recessed part 804 is arranged in multiple numbers in the perpendicular direction D2, the 1st link member 81 can be positioned in multiple steps in the perpendicular direction D2. As shown in FIG. 6, the first fixing member 84 is fixed to the rear side of the outer end of the first horizontal flap group G1. In addition, as shown in FIG. 7, the first fixing member 84 includes a plurality of fixing clips 805 provided corresponding to the plurality of first horizontal flaps 80 of the first horizontal flap group G1, and It has the wall part 806 arrange | positioned with the clearance gap with respect to the fixing clip 805. The fixing clip 805 is provided with a locking hole. When the edge portion of the first outlet 12 is inserted into the gap between the fixing clip 805 and the wall 806, the locking hole of the fixing clip 805 is provided at the edge portion. The first fixing member 84 is fixed to the casing 4 by engaging the provided hole 124.

The 2nd flap adjustment mechanism 22 is a mechanism which can adjust the direction of the some 1st horizontal flap 80 which belongs to 2nd horizontal flap group G2, and the 2nd link member 82 and the 2nd fixing member ( 85). Moreover, the 3rd flap adjustment mechanism 23 is a mechanism which can adjust the direction of the some 1st horizontal flap 80 which belongs to 3rd horizontal flap group G3, and is the 3rd link member 83 and 3rd fixed Has a member 86. Although the 2nd link member 82 and the 3rd link member 83 are the same structure as the 1st link member 81, each link member 81-83 is a separate body, and can move independently independently. In addition, the second link member 82 connects the second horizontal flap group G2, and the third link member 83 connects the third horizontal flap group G3. The second fixing member 85 is fixed to the second horizontal flap group G2, and the third fixing member 86 is fixed to the third horizontal flap group G3.

The 2nd horizontal flap part 9 is a part which guides the air blown out from the 2nd blowout port 13 to a perpendicular direction D2. The second horizontal flap portion 9 includes a plurality of second horizontal flaps 90 and second flaps, a fourth flap adjusting mechanism 24, a fifth flap adjusting mechanism 25, and a sixth flap adjusting mechanism 26. Have

The plurality of second horizontal flaps 90 are arranged side by side in the vertical direction D2 at the second outlet port 13, and guide the air blown out from the second outlet port 13 in the vertical direction D2. Similar to the first horizontal flap 80, the second horizontal flap 90 includes the fourth horizontal flap group G4 and the fourth flap group, the fifth horizontal flap group G5 and the fifth flap group, and the sixth horizontal flap 90. The flap group G6 is divided into three groups. The 4th flap adjustment mechanism 24 is a mechanism which can adjust the direction of the some 2nd horizontal flap 90 which belongs to 4th horizontal flap group G4, and the 4th link member 91 and the 4th fixing member ( 94). The 5th flap adjustment mechanism 25 is a mechanism which can adjust the direction of the some 2nd horizontal flap 90 which belongs to the 5th horizontal flap group G5, and the 5th link member 92 and the 4th fixing member ( 95). In addition, the 6th flap adjustment mechanism 26 is a mechanism which can adjust the direction of the some 2nd horizontal flap 90 which belongs to the 6th horizontal flap group G6, and the 6th link member 93 and 6th fixed It has a member 96.

The fourth link member 91 connects the fourth horizontal flap group G4, the fifth link member 92 connects the fifth horizontal flap group G5, and the sixth link member 93 connects the sixth The horizontal flap group G6 is connected. The 2nd horizontal flap 90 is arrange | positioned symmetrically with the 1st horizontal flap 80, 4th horizontal flap group G4 corresponds to 1st horizontal flap group G1, and 5th horizontal flap group G5 corresponds to the second horizontal flap group G2, and the sixth horizontal flap group G6 corresponds to the third horizontal flap group G3. Moreover, each link member 91-93 of the 2nd horizontal flap part 9 is also the same structure as each link member 81-83 of the 1st horizontal flap part 8, and is symmetrical. The same applies to the fixing members 94 to 96.

As mentioned above, the 1st horizontal flap 80 and the 2nd horizontal flap 90 are fixed to the back side by the fixing member 84-86, 94-96, and the front side is the link member 81-83, 91-. 93 is movably connected. For this reason, the flexible 1st horizontal flap 80 and the 2nd horizontal flap 90 deform | transform by the movement of the link members 81-83, 91-93. For example, when the link members 81-83, 91-93 move upward, the first horizontal flap 80 so that the front ends of the first horizontal flap 80 and the second horizontal flap 90 face upwards. And the second horizontal flap 90 is curved (see FIG. 11 (a)). In addition, when the link members 81-83, 91-93 are moved downward, the first horizontal flap 80 and the first horizontal flap 80 and the second horizontal flap 90 are directed downward. 2 horizontal flap 90 is curved (see FIG. 11 (b)). In this way, the guide direction of the air by the 1st horizontal flap 80 and the 2nd horizontal flap 90 can be changed by the movement of the link members 81-83, 91-93.

<1st vertical flap part and 2nd vertical flap part>

As shown in FIG. 3, the 1st vertical flap part 5 and the 2nd vertical flap part 7 blow air which blows from the 1st blowout outlet 12 and the 2nd blowout outlet 13 in the horizontal direction D1. It is a part which guides so that it may isolate | separate, and is provided in the 1st blowout outlet 12 and the 2nd blowout outlet 13, respectively.

The 1st vertical flap part 5 is a part which adjusts the wind direction of the air blown out from the 1st blowout outlet 12, and has the 1st vertical flap 51 and the 1st flap motor 50. As shown in FIG.

The 1st vertical flap 51 is arrange | positioned at the left side by the front view, and opens and closes the 1st blowout opening 12. As shown in FIG. The 1st board | substrate flap 51 is a 1st board part 52 and the 1st board part 52 which are substantially the same shape as the outer edge of the 1st blowout opening 12, and show a long plate shape in the perpendicular direction D2. It has a some 1st rib 53 provided in the perpendicular | vertical direction D2 side by side on the back surface of the side. The 1st board part 52 is a member which guides the air blown out from the 1st blowout port 12 in an open state. The 1st rib 53 protrudes substantially perpendicularly from the back surface of the 1st board part 52, and the circular hole which penetrates in the perpendicular direction D2 is provided. The drive shaft of the 1st flap motor 50 provided in the casing 4 is inserted and fixed to the hole of the 1st rib 53 located in the lower end vicinity of the 1st board part 52 (refer FIG. 5). Moreover, the some protrusion part 14a-14c provided in the inside of the 1st blowout opening 12 fits into the other hole of the 1st rib 53, respectively. The 1st vertical flap 51 is provided so that rotation is possible about the 1st rotation axis AX1 extended in the perpendicular direction D2 through the hole provided in the 1st rib 53. As shown in FIG. In addition, the hole provided in the 1st rib 53 is provided eccentrically to the outer side, the left side, rather than the center of the 1st board part 52, and is eccentrically outward from the center of the 1st blow-out port 12, too. For this reason, the 1st rotation shaft AX1 is also located outside the center of the 1st blowout opening 12, and is located between the center of the 1st blowout opening 12 and the outer end of the 1st blowout opening 12, ie, the left end. have.

The 1st flap motor 50 rotates the 1st vertical flap 51 about the 1st rotation axis AX1 parallel in a perpendicular direction D2. The first flap motor 50 changes the arrangement angle of the first vertical flap 51 to change the direction of the first vertical flap 51. As a result, the wind direction of the air blown out from the first blowout port 12 is changed. The operation of the first vertical flap 51 at this time will be described later in detail.

The 2nd vertical flap part 7 is a part which adjusts the wind direction of the air blown out from the 2nd blower outlet 13, and has the 2nd vertical flap 71 and the 2nd flap motor 70. As shown in FIG. The 2nd vertical flap 71 is arrange | positioned at the right side when viewed from the front, and opens and closes the 2nd blowout opening 13.

The second vertical flap 71 has a shape substantially the same as the outer periphery of the second outlet port 13, and exhibits a plate shape that is elongated in the vertical direction D2, and on the back surface of the second plate part 72. It has a some 2nd rib 73 provided side by side in the perpendicular direction D2. The 2nd board part 72 is a member which guides the air blown out from the 2nd blowout port 13 in an open state. The 2nd rib 73 protrudes substantially perpendicularly from the back surface of the 2nd board part 72, and the circular hole which penetrates in the perpendicular direction D2 is provided. The drive shaft of the 2nd flap motor 70 provided in the casing 4 is inserted and fixed to the hole of the 2nd rib 73 located in the vicinity of the lower end part of the 2nd board part 72. As shown in FIG. Moreover, the some protrusion part 15a-15c provided in the inside of the 2nd ejection opening 13 fits into the other hole of the 2nd rib 73, respectively. The second vertical flap 71 is rotatably provided around the second rotation axis AX2 extending in the vertical direction D2 through the hole provided in the second rib 73. In addition, the hole provided in the 2nd rib 73 is provided eccentrically to the outer side, or right side, rather than the center of the 2nd board part 72, and is eccentrically outward from the center of the 2nd ejection opening 13, too. For this reason, the 2nd rotating shaft AX2 is also located outside the center of the 2nd blowout opening 13, and is located between the center of the 1st blowout opening 12 and the outer edge part of the 1st blowout opening 12, ie, the right end. .

The 2nd flap motor 70 can drive independently of the 1st flap motor 50, and rotates the 2nd vertical flap 71 about the 2nd rotation axis AX2 parallel in the perpendicular direction D2. Let's do it. The second flap motor 70 changes the arrangement angle of the second vertical flap 71 to change the direction of the second vertical flap 71. As a result, the wind direction of the air blown out from the second blowout port 13 is changed.

1 and 3 show the fully closed state in which the first vertical flaps 51 and the second vertical flaps 71 close the respective ejection openings 12 and 13.

[Control part and remote control]

As shown in FIG. 8, the control unit 10 is connected to the fan 3, the first flap motor 50, the second flap motor 70, and the like, and the fan 3 and the first flap motor 50. ), The second flap motor 70 and the like. The control part 10 can control the 1st flap motor 50 and the 2nd flap motor 70 separately, respectively, and the 1st vertical flap part 5 and the 2nd vertical flap part 7 are the aspects, respectively. It is possible to control with. Therefore, the control part 10 can not only move the 1st vertical flap 51 and the 2nd vertical flap 71 from left to right, but can also move asymmetrically. Thereby, the wind direction of the air blown out from the 1st blowout outlet 12 and the wind direction of the air blown out from the 2nd blowout outlet 13 can be changed individually, respectively.

The remote controller 11 is an input device for the user to instruct the operation contents of the upset type air conditioner 1, and controls the power on / off, switching between heating and cooling, heating, temperature setting, air volume setting, wind direction setting, and the like. The input of the content is received, and a control signal corresponding to each input is transmitted to the control unit 10 by wireless communication means such as infrared rays. For example, the remote control 11 can accept the specification of the direction of the 1st vertical flap 51, and the specification of the direction of the 2nd vertical flap 71, respectively. In addition, a plurality of driving modes may be set in advance in the control unit 10, and a plurality of driving modes may include a driving mode in which the first vertical flaps 51 and the second vertical flaps 71 are asymmetrically moved. In this case, the remote controller 11 may accept the designation of any one driving mode.

<action>

The operation of the characteristic first vertical flap 51, the second vertical flap 71, the first horizontal flap 80 and the second horizontal flap 90 and the air flow in the present invention will be described in detail.

First, when the fan 3 rotates, indoor air is taken into the casing 4 from the first suction port 61, the second suction port 62, and the side suction ports 66 and 67 (see FIG. 1). The air received is sent from the casing outlet 31 to the upper side of the fan 3 by the rotation of the fan 3, and passes through the heat exchanger 2, so that the first blowout outlet 12 and the second blowout outlet 13 are provided. Blow out into the room. At this time, the wind direction of the air can be changed left and right by the first vertical flap portion 5 and the second vertical flap portion 7, and by the first horizontal flap portion 8 and the second horizontal flap portion 9. The wind direction can be changed up and down.

[Operation of the First Vertical Flap and the Second Vertical Flap]

At the time of stop of operation, the 1st blowout opening 12 and the 2nd blowout opening 13 are closed by the 1st vertical flap part 5 and the 2nd vertical flap part 7, as shown in FIG. Hereinafter, this state is called "fully closed state." When the phase-mounted air conditioner 1 starts operation, the 1st vertical flap 51 and the 2nd vertical flap 71 move, and the 1st blowout opening 12 and the 2nd blowout opening 13 open. At this time, the first flap motor 50 and the second flap motor 70 are driven to rotate the first vertical flap 51 about the first rotation axis AX1, and the second vertical flap 71 is formed by the first flap motor 50. 2 Rotate around the axis AX2. The 1st vertical flap 51 rotates clockwise as seen from an upper surface, and the right end part of the 1st board part 52 located inside in the fully closed state moves forward. Thus, the 1st vertical flap 51 rotates so that the inner edge part of the 1st board part 52 of a fully closed state may approach the outer edge side of the 1st blowout opening 12. As shown in FIG. Moreover, the 2nd vertical flap 71 rotates counterclockwise as seen from an upper surface, and the left end part of the 2nd board part 72 located inside in the fully closed state moves forward. Thus, the 2nd vertical flap 71 moves so that the inner edge part of the 2nd board part 72 of a fully closed state may approach the outer edge side of the 2nd blowout port 13. As shown in FIG. The control part 10 controls the 1st flap motor 50 and the 2nd flap motor 70, and the desired opening degree of the 1st vertical flap 51 and the 2nd vertical flap 71 is desired. Can be opened as For example, the first vertical flap 51 and the second vertical flap 71 can be opened in a first open state, a second open state, and a third open state as shown in FIG. 9. As shown to Fig.9 (a), the 1st open state is a state in which the front side edge part of the 1st board part 52 and the front side edge part of the 2nd board part 72 faced inward. At this time, the front end part of the 1st board part 52 is located inside or right side rather than the center of the 1st blowout port 12, and the rear end part is located outside or the left side than the center of the 1st blowout port 12. FIG. In this first open state, the air blown out from the first blowout outlet 12 and the second blowout outlet 13 is concentrated and blown out in the center direction of the uptake type air conditioner 1. As shown in FIG. 9 (b), the second open state is a state in which the front end portion of the first plate portion 52 and the front end portion of the second plate portion 72 face the front side. At this time, the 1st board part 52 and the 2nd board part 72 will be in substantially parallel state in the direction perpendicular | vertical to a front surface. In this state, the first plate part 52 is located outside the first rotation shaft AX1 and located outside the center of the first ejection opening 12. Moreover, the 2nd board part 72 is located in the outer side of the 2nd rotation axis AX2, and is located in the outer side from the center of the 2nd ejection port 13. As shown in FIG. In this 2nd state, the air blown out from the 1st blowout outlet 12 and the 2nd blowout outlet 13 blows straight in a front direction. As shown in FIG.9 (c), the 3rd open state is the state in which the 1st board part 52 and the 2nd board part 72 were fully opened, and the front end part and 2nd of the 1st board part 52 are opened. The front end part of the plate part 72 is facing outward. At this time, the front end part of the 1st board part 52 is located outside the outer edge part of the 1st blowout opening 12, and the rear end part is located inside the center of the 1st blowout outlet 12 inside. The front end part of the 2nd board part 72 is located outside the outer edge part of the 2nd blowout port 13, and the rear end part is located inside the center of the 1st blowout port 12 inside. In this third open state, the air blown out from the first blowout outlet 12 and the second blowout outlet 13 blows out to the outside.

In addition, the opening degree of the 1st vertical flap 51 and the 2nd vertical flap 71 may not only be opened in 3 steps of said 3rd open state from said 1st open state, but may be opened in the intermediate opening degree. In addition, the first vertical flap 51 and the second vertical flap 71 can be opened not only in stages of opening but also in any opening.

Moreover, in this phase-mounted air conditioner 1, not only the 1st vertical flap 51 and the 2nd vertical flap 71 move left and right symmetrically, but also the 1st vertical flap 51, as shown in FIG. ) And the second vertical flap 71 may move left and right asymmetrically to open the first outlet 12 and the second outlet 13. For example, as shown in Fig. 10A, the first vertical flap 51 is in a completely closed state, and the second vertical flap 71 can be opened in a third open state. In addition, as shown in Fig. 10B, the first vertical flap 51 is opened in the first open state, and the second vertical flap 71 can be opened in the third open state.

In addition, when the 1st vertical flap 51 and the 2nd vertical flap 71 close the 1st blowout opening 12 and the 2nd blowout opening 13, it moves to the opposite direction to the above.

[Operation of the first horizontal flap and the second horizontal flap]

In the phase-mounted air conditioner 1, the first horizontal flap group G1 to the third horizontal flap group G3 and the fourth horizontal flap group G4 to the sixth horizontal flap group G6 are each individually. The angle of the horizontal flaps 80 and 90 can be changed. For this reason, the direction of each flap 80 and 90 can be set to the angle which a user desires. For example, as shown to Fig.11 (a), all the 1st horizontal flap group G1 to the 3rd horizontal flap group G3 are set upward, or as shown to FIG. 11 (b). The first horizontal flap group G1 to the third horizontal flap group G3 can all be set downward. When all of the first horizontal flap group G1 to the third horizontal flap group G3 are set upward, the air blown out from the first blowout port 12 blows upward. For this reason, it is effective when it is desired to blow cold air upward at the time of cooling. In addition, when all from the 1st horizontal flap group G1 to the 3rd horizontal flap group G3 are set downward, the air blown out from the 1st blowout outlet 12 will blow downward. This is effective when it is desired to blow warm air downward during heating. The same applies to the sixth horizontal flap group G6 in the fourth horizontal flap group G4.

Further, since the sixth horizontal flap groups G6 in the first horizontal flap group G1 can be changed independently of each other, even if the respective horizontal flaps 80 and 90 are set to face different directions as shown in FIG. 12. It's okay. For example, in FIG. 12A, the first horizontal flap group G1 is set upward, the second horizontal flap group G2 is set in the front direction, and the third horizontal flap group G3 is downward. Is set. For this reason, air blows upwards from the upper part S1 of the 1st blow-out port 12, air blows straight out from the middle part S2, and air blows downwards from the lower part S3. . Thereby, air can be blown widely in a vertical direction D2, and the flow of air which encloses an interior from the top and bottom can be implement | achieved. In addition, as shown in FIG. 12 (b), the first horizontal flap group G1 is set downward, the second horizontal flap group G2 is set in the front direction, and the third horizontal flap group G3. May be set upward. In this case, the air blows downward from the upper portion S1 of the first outlet 12, the air blows straight out from the central portion S2, and the air blows upward from the lower portion S3. . Thereby, air can be blown so that it may be concentrated in a front direction, and the flow of air can be reached to a distant place. The same applies to the fourth horizontal flap group G4, the fifth horizontal flap group G5, and the sixth horizontal flap group G6.

In addition, the 1st horizontal flap 80 is connected to the 1st link member 81, the 2nd link member 82, and the 3rd link member 83 by moving in the perpendicular direction D2, respectively. Although the horizontal flap 80 bends and changes its direction, the first link member 81, the second link member 82, and the third link member 83 not only change their positions stepwise, but also continuously It is also possible to change the position. In addition, the direction of the first horizontal flap 80 is not only manually changed, but also driven by each of the first horizontal flap group G1, the second horizontal flap group G2, and the third horizontal flap group G3. It is also possible to change automatically by installing a motor. The same applies to the second horizontal flap 90.

<Characteristic>

(One)

In this phase-mounted air conditioner 1, the 1st vertical flap 51 and the 2nd vertical flap 71 are opened so that it may be located outside the center of the 1st blowout outlet 12 and the 2nd blowout outlet 13, respectively. As in the conventional tooth type air conditioner, when the first vertical flap 51 and the second vertical flap 71 are disposed near the inner side, the first vertical flap 51 and the second vertical flap 71 are inward. When it becomes in the 1st open state which faces to this, as shown in FIG.13 (a), since the flow of air will disperse also to the outer side, it is difficult to aggregate the flow of air to a front direction. On the other hand, when the 1st vertical flap 51 and the 2nd vertical flap 71 open so that it may be located outside from the center of the 1st blowout opening 12 and the 2nd blowout opening 13, respectively, as shown to FIG. 13 (b). As described above, since dispersion to the outside of the flow of air is suppressed, the density of the flow of air in the front direction is improved. As a result, the straightness is improved by the concentration of air flow in the center direction. For this reason, it is possible to reach the flow of air to the distant.

In addition, in this phase-mounted air conditioner 1, since the 1st blowout outlet 12 and the 2nd blowout outlet 13 are arrange | positioned at the horizontal direction, the 3rd open state shown in FIG.9 (c) is arranged. As described above, by opening the first vertical flap 51 and the second vertical flap 71 largely from side to side, it is also possible to blow air to the left and right widely. For this reason, the flow of air enclosed from the left and right by separation in both the left and right directions is also possible.

As described above, in this phase-mounted air conditioner 1, the control range of the wind direction is expanded. Thereby, in this phase-mounted air conditioner 1, it is possible to respond to installation in various places and various usage methods.

(2)

In this phase-mounted air conditioner 1, the wind direction from the 1st blow-out port 12 and the wind direction from the 2nd blow-out port 13 can be controlled separately. For this reason, distribution of the flow of air according to a room, distribution of the flow of air according to a user's preference, etc. are possible. In addition, since the degree of freedom of distribution of the flow of air is improved, the distribution of air flow is changed in accordance with the shape of the room where the air conditioner 1 is disposed, or the airflow is applied only to a portion where air conditioning such as air conditioning and the like is particularly required. By dispensing, the air conditioning efficiency can be improved. For example, when the air conditioner 1 is arranged in a corner of a long room showing an elongated shape in one direction, when the air is blown in an even direction from side to side, the diagonal of the air conditioner 1 is provided. It is difficult to reach the flow of air to the corner portion located at (iii). In this case, as shown in FIG. 14, the part which was hard to reach | attained by making the wind direction from the 1st blowout opening 12 and the wind direction from the 2nd blowout opening 13 into the direction which deviated to the longitudinal direction of a room. Can reach the flow of air.

(3)

In the phase-mounted air conditioner 1, the horizontal flaps 80 and 90 are divided into a plurality of groups, and the directions of the horizontal flaps 80 and 90 can be freely changed for each group. For this reason, according to the shape of a room, a user's preference, etc., the aspect of extraction in the vertical direction D2 can be selected freely. For example, the flow of air surrounding the room from the top and the bottom can be realized, and conversely, it is also possible to enlarge the arrival area of the flow of air by condensing the flow of air.

In addition, instead of moving all the horizontal flaps 80 and 90 simultaneously, each horizontal flap group G1-G3, G4-G6 can be moved separately, and therefore, one horizontal flap group G1-G6 In the case of moving, the operation by light force becomes possible, and the operability is improved.

(4)

In this phase-mounted air conditioner 1, as mentioned above, by the 1st vertical flap 51, the 2nd vertical flap 71, the 1st horizontal flap 80, and the 2nd horizontal flap 90, it is various directions. Can blow air. For this reason, various air can be blown out even if a plurality of fans 3 are not provided but only one fan is provided.

Second Embodiment

<Configuration>

In the first embodiment described above, the adjustment of the left and right wind directions can be controlled individually, but the amount of air from the left and right blowout ports may be individually controlled. 15 is a control block diagram of the phase-mounted air conditioner 1 according to the second embodiment of the present invention.

This phase-mounted air conditioner 1 is equipped with the 1st air volume adjusting part 58 and the 2nd air volume adjusting part 78. As shown in FIG. The 1st air volume adjusting part 58 has the 1st shutter mechanism which changes the opening area of the 1st air outlet 12, and can adjust the air volume of the air blown out from the 1st air outlet 12. FIG. The 2nd air volume adjusting part 78 has the 2nd shutter mechanism which changes the opening area of the 2nd air outlet 13, and can adjust the air volume of the air blown out from the 2nd air outlet 13. The control unit 10 can individually control the first air volume adjusting unit 58 and the second air volume adjusting unit 78, and the air volume of the air blown out from the first air outlet 12 and the second air outlet 13 can be controlled. The air volume of blown air can be changed individually. In addition, the user inputs the adjustment of the air volume of the air by the first air volume adjusting unit 58 and the second air volume adjusting unit 78 to the remote controller 11, whereby the air volume from the first air outlet 12 and the second air volume are adjusted. The amount of air from the blower outlet 13 can be adjusted to a desired quantity, respectively. In this case, similarly to the first embodiment, not only the change of the air volume can be input to each of the first air volume adjusting unit 58 and the second air volume adjusting unit 78, but also the first air volume by designation of the operation mode. It is also possible to operate the adjusting unit 58 and the second air volume adjusting unit 78 separately.

About another structure, it is the same as that of the phase difference type air conditioner 1 which concerns on 1st Example.

<Characteristic>

In this phase-mounted air conditioner 1, since the wind direction from the 1st blower outlet 12 and the air volume from the 2nd blower outlet 13 can be controlled separately, distribution of the flow of air according to the room, and Distribution of air flow according to preference is possible. In addition, since the degree of freedom of distribution of the flow of air is improved, the distribution of air flow is changed in accordance with the shape of the room where the air conditioner 1 is disposed, or the airflow is applied only to a portion where air conditioning such as air conditioning and the like is particularly required. By dispensing, the air conditioning efficiency can be improved. For example, when the air conditioner type | mold air conditioner 1 is arrange | positioned in the corner part of the elongate room which shows an elongate shape in one direction, as shown in FIG. What is necessary is just to increase and reduce the air volume from the other blower outlet. Thereby, it is possible to reach the flow of air to the part where the flow of air was difficult to reach.

<Other Examples>

(One)

In the standing type air conditioner 1 which concerns on said embodiment, the 1st vertical flap 51 and the 1st rotating shaft AX1 and the 2nd rotating shaft AX2 are arrange | positioned outwardly, respectively, Although the 2 vertical flaps 71 are opened eccentrically to the outside, the first rotary shaft AX1 and the second rotary shaft AX2 may be disposed at the center of the first outlet 12 and the center of the second outlet 13, respectively. Do. Also in such a case, the 1st vertical flap 51 is made, for example by making the shape of the 1st rib 53 and the position of the hole of the 1st rib 53 into the position away from the 1st board part 52. It is possible to open the first outlet 12 so as to eccentrically outward. However, in consideration of the limitations on the dimensions of the first ejection opening 12 and the first vertical flap 51, an arrangement in which the first rotation axis AX1 is eccentrically outward is more preferable. The same applies to the second vertical flaps 71.

(2)

In the upper-mounted type air conditioner 1 which concerns on said embodiment, although the 1st vertical flap 51 rotated clockwise from the upper surface, and opens the 1st blowout opening 12, in the counterclockwise direction The first blowout opening 12 may be opened by rotating. The same applies to the second vertical flaps 71.

(3)

In the standing type air conditioner 1 which concerns on said embodiment, the 1st blowout opening 12 and the 2nd blowout opening 13 are rotated by the 1st vertical flap 51 and the 2nd vertical flap 71 rotating. Although it is open, the 1st blowout outlet 12 and the 2nd blowout outlet 13 may be opened by moving to another aspect not only to rotational movement.

(4)

The phase-mounted air conditioner 1 according to the above embodiment includes the first vertical flap portion 5 and the second vertical flap portion 7 shown in the first embodiment, and the second embodiment. It is not limited to having only one of the 1st air volume adjustment part 58 and the 2nd air volume adjustment part shown in figure, and may be provided simultaneously.

(5)

In the positional air conditioner 1 which concerns on said embodiment, although the 1st horizontal flap 80 is divided into three groups in the perpendicular direction, what is necessary is just to be divided into two or more groups, for example, It may be divided into two or four groups. The same applies to the second horizontal flap 90.

This invention has the effect that selection of the various air flows is possible, and is useful as a lettuce air conditioner.

Claims (6)

A casing 4 provided with a first outlet 12 through which harmonized air is blown, and A plurality of first flaps 80 which are installed in the vertical direction at the first outlet 12 and guide the air blown out from the first outlet 12; First flap adjustment mechanism 21 which can adjust the direction of the said 1st flap 80 which belongs to 1st flap group G1 among the said 1st flap 80, and Second flap adjustment mechanism which can adjust the direction of the said 1st flap 80 which belongs to the 2nd flap group G2 among the said 1st flap 80 independently from the said 1st flap group G1 ( 22) An upper air conditioner (1) having a. The method of claim 1, The first outlet 12 has a long shape in the vertical direction Phase type air conditioner (1). The method according to claim 1 or 2, The first flap adjustment mechanism 21 has a first link member 81 connected to the plurality of first flaps 80 belonging to the first flap group G1 and movable in the vertical direction, The second flap adjustment mechanism 22 is connected to the plurality of first flaps 80 belonging to the second flap group G2 and is movable in the vertical direction independently of the first link member 81. With two link members 82 Phase type air conditioner (1). The method of claim 3, The first link member 81 and the second link member 82 are respectively installed to be movable manually. Phase type air conditioner (1). The method according to any one of claims 1 to 4, The direction of the said 1st flap 80 which belongs to 3rd flap group G3 among the said 1st flap 80 is independent from the said 1st flap group G1 and the 2nd flap group G2. Further comprising a third flap adjustment mechanism 23 that can be adjusted, The first flap group G1, the second flap group G2, and the third flap group G3 are arranged side by side in the vertical direction. Phase type air conditioner (1). The method according to any one of claims 1 to 5, The casing 4 is further provided with a second blowout opening 13 arranged side by side in the transverse direction D1 with the first blowout opening 12 and a harmonized air blown out from the front, A plurality of second flaps 90 which are installed side by side in the vertical direction at the second outlet 13 and guide the air blown out from the second outlet 13; Fourth flap adjustment mechanism 24 which can adjust the direction of the some 2nd flap 90 which belongs to the 4th flap group G4 among the said 2nd flap 90, The fifth flap adjustment mechanism which can adjust the direction of the some 2nd flap 90 which belongs to the 5th flap group G5 among the said 2nd flap 90 independently from the said 4th flap group G4 ( 25) An upright type air conditioner (1) further including.

Images