GB2108263A - Wind-shifting apparatus for an air conditioner - Google Patents

Abstract

A wind-shifting apparatus for an air conditioner has a plurality of pivotably supported wind-shifting plates 1A, 1B disposed in front of a main body of the air conditioner for changing a direction and blow angle of wind emitted from the air conditioner main body, the apparatus including a drive source 6 coupled to a movable plate 4 so that rotary motion of the motor is converted into pivoting motion of the plate 4 about a support 10. An arm 3 connected to the plate 1A has a shaft 17 inserted into a selected one of the holes 7 in the plate 4 to vary the range of movement of the wind-shifting plates corresponding to the pivoting of the plate 4. The pivot mounting 9 for the plates 1A, 1B may be provided between elastic supporting arms to absorb variations. <IMAGE>

Description

SPECIFICATION Wind-shifting apparatus for an air conditioner The present invention relates to a wind-shifting apparatus for changing the direction and blow angle of wind emitted from an air conditioner.

The location at which an air conditioner can be installed in a room is often restricted by the purposes for which the room is used, the arrangement of furniture, and so forth. In order to operate the air conditioner most efficiently, it is necessary to design it so that the direction and blow angle of wind emitted from the air conditioner can be changed and varied as desired.

It is an object of the present invention to provide an improved wind-shifting apparatus which is capable of selectively varying a direction and blow angle of wind emitted from an air conditioner easily and inexpensively.

The wind-shifting apparatus of the present invention comprises a plurality of wind-shifting plates which are all integrally movable, an arm which is rotatably connected to one end of one of the wind-shifting plates, the other end of the arm being provided with a connecting shaft; a driving means which provides rotary motion; and a movable plate connected to said rotary shaft, a support for pivotably securing said movable plate at a point between opposite ends thereof, said movable plate having converting means at one end thereof connected to said rotary shaft for converting said rotary motion of said rotary shaft into pivotable motion of said movable plate about said support, an opposite end of said movable plate having a plurality of holes therein, an arm having a shaft engaged with one of said plurality of holes in said opposite end of said movable plate; and means for connecting said arm to one of said plurality of wind-shifting plates so that said rotational motion of said drive shaft pivotably rotates said one of said plurality of wind-shifting plates to change a direction of wind being blown from said air conditioner main body.

The movable plate may be provided with a plurality of holes on one end portion of the movable plate, said holes being chosen appropriately to receive the connecting shaft of the arm, and an opposite end of the movable plate having an elongated hole within it so that the rotary motion of a driving means can be converted into reciprocating motion by connecting the movable plate to the driving means through a crank, with one end of the crank inserted into the elongated hole of the movable plate.

The invention will now be described by way of example with reference to the accompanying drawings in which; Figure 1 is a perspective view of a first embodiment of a wind-shifting apparatus constructed in accordance with the present invention; Figures 2 to 4 each illustrate the action of the wind-shifting apparatus and the direction and blow angle of wind for the apparatus of Figure 1; Figure 5 is a partial perspective view illustrating a second embodiment of a wind-shifting apparatus constructed in accordance with the present invention; Figure 6 is a cross-sectional view illustrating the connecting portion between an arm and a movable plate in the apparatus of Figure 5; Figure 7is an enlarged perspective view showing the movable plate and the arm of Figures 5 and 6; Figures 8 and 9 each illustrate the action of the wind-shifting apparatus of Figures 5-7;; Figure 10 is a schematic, perspective view of a third embodiment of a wind-shifting apparatus constructed in accordance with the present invention; Figure 7 1 is an enlarged perspective view of a part of Figure 10, and Figure 12 is a dismantled, perspective view of a modification of the wind-shifting apparatus of Figure 10 and 11.

Referring to Figure 1, upper and lower frames 8a, 8b are provided at a blow outlet of an air conditioner (not shown). The frames 8a, 8b comprise a pair of supporting members which pivotally support a plurality of wind-shifting plates 1,two of which are identified as 1A and 1 B in Figure 1. The plates are rotatably secured to the frames 8a and 8b by supporting shafts 9, and the plates 1 are connected to each other by means of a connecting bar 2 so that all the wind-shifting plates are movable together. A driving shaft 11 extends from the bottom of a driving wind-shifting plate 1A, and the driving shaft 11 extends through a hole bored in one end of an arm 3 so that it is rotatably connected to the arm 3.A shaft 17 extends from the other end of the arm 3, and the shaft 17 is rotatably connected to a movable plate 4 by inserting the shaft 17 in one of a plurality of holes 7 in the movable plate 4. The positions of the holes 7 are determined by the length of the arm 3, the necessary angle of rotation of the wind-shifting plate 1, and so forth. The movable plate 4 is rotatably fixed to the frame 8b by means of a support 10, and an elongated hole 12 is bored through the opposite side of the movable plate 4. A pin 5 of a crank 13, which is attached to a low-speed rotary motor 6, is fitted through and slide within the elongated hole 12 so that it converts the rotary motion of the motor into the pivoting motion of the movable plate 4.

The function of the wind-shifting apparatus is explained below.

When the low-speed rotary motor 6 rotates, the crank 13 also rotates so that the pin 5 of the crank 13 slides in the elongated hole 12 of the movable plate 4, thus causing the movable plate 4 to pivot about the support 10. Since the arm 3 is connected through one of the holes 4 to the opposite side of the movable plate 4, the pivoting motion is transmitted as reciprocating motion to the arm 3, which causes the wind-shifting plate 1Ato pivot about its support shafts 9. Accordingly, the direction of wind is automatically changed according to the rotation of the motor 6.

When the arm 3 is connected to a hole 14 which is bored into the top end of the movable plate 4, as illustrated in Figure 2, the wind-shifting plate 1A moves within the a-b range, thus changing the direction mode of wind. Similarly, when the arm 3 is connected to a hole 15 which is bored near the support 10 of the movable plate 4, as illustrated in Figure 3, the wind-shifting plate 1A moves within the b-c range, thus also chaning the direction of wind.

When the arm 3 is connected to a hole 16 which is bored into the left end of the movable plate 4, as illustrated in Figure 4, the wind-shifting plate 1A moves within the a-c range, thus, again changing the direction of wind.

If it is desired to moe the wind-shifting plate within the a-b range, such movement can be accomplished by boring a hole at a point within the triangle formed by the holes 14, 15 and 16 and connecting the arm 3 to the hole.

Since the wind-shifting apparatus comprises a crank device which is used to convert rotary motion into reciprocating motion, a movable plate with a plurality of holes bored within it, and an arm connected to a wind-shifting plate, the wind-shifting apparatus is inexpensive. Furthermore, the direction and blow angle of wind can be easily varied by using the wind-shifting apparatus.

Another embodiment is shown in Figures 5-9.

According to the embodiment shown in these Figures, the frames 8a and 8b, which are placed at the blow outlet of an air conditioner; a wind-shifting plate 1; a connecting bar 2; an arm 3; a movable plate 4; a low-speed rotary motor 6; etc., have the same construction as those shown in Figure 1. A shaft 17 of the arm 3 comprises a small diameter portion 21 and a large diameter portion 22. A plurality of small holes 18 are bored in the movable plate 4 and are connected to a large hole 19 which is bored in the central portion of the movable plate 4 through groove or slit 20. The large hole 19, which is bored at the central portion, is designed so that the large diameter portion 22 of the shaft 17 can pass therethrough. The diameter of the small holes 18 is determined so that the small hole 18 comes into engagement with the small diameter portion 21 of the shaft 17.The diameter of the small holes 18 permits the small diameter portion 21 of the shaft 17 to be smoothly rotatable without rattling. The small diameter portion 21 of the shaft 17 is urged to fit with the small hole 18 through the groove 20. The width of the grooves or slits 20 which connect the small holes 18 to the large hole 19 is made smaller than the small diameter portion 21 of the shaft 17 to thus prevent the shaft 17 from release. In bringing the arm 3 into engagement with the movable plate 4, the shaft 17 of the arm 3 is inserted into the large hole 19, which is bored at the central portion, and moved toward the small hole 18, which lies in approximately the same plane as the large hole 19. At this time, since the movable plate 4 is made of resilient plastic material, the groove 20 is deformed and broadened when the shaft 17 is pushed into it.When the shaft 17 is completely fitted through the small hole 18, the groove 20 returns to its original form. Accordingly, the shaft 17 of the arm 3 cannot be released from the hole 18, in spite of the frictional forces which are generated and transmitted to the shaft 17 by the pivoting of the wind-shifting plates 1 and the forces created by wind resistance.

The function of the wind-shifting apparatus shown in Figure 5 is almost the same as that of the apparatus shown in Figure 1 except that, when it is desired to change the direction of wind in the apparatus of Figure 5, it is sufficient to remove the shaft 17 from one small hole 18 and place it into another small hole 18, as is apparent from Figure 7.

Therefore, linkage between the arm and the shaft is easily carried out, and the linking position therebetween is easily changeable in accordance with the installing condition of the air conditioner to obtain optimum wind direction, and that the simple construction results, so that optimum wind direction and blowing angle is obtainable at low cost. Since the driving force can be reliably transmitted from the motor to the wind-shifting plate in the apparatus shown in Figure 5 without disengagement between the arm and shaft, the effect is further improved.

Next, the structure for supporting the reciprocating, pivotal wind-shifting plate will be described with reference to Figures 10 and 12 according to another preferred embodiment.

As illustrated in Figure 10 and 11, a plurality of bearing holes 33 are bored at predetermined intervals in the upper and lower bearing plates 8a and 8b.

These bearing plates are to be placed at the blow outlet of the air conditioner (not shown), and a plurality of wind-shifting plates 1A, 1 B, each being provided with supporting shafts 9 at their upper and lower ends, are rotatably supported on the bearing plates 8a and 8b by engagement of the supporting shafts in the bearing the holes 33. The bearing holes 33 are made slightly smaller than the diameter of the supporting shafts 9. These wind-shifting plates are connected to each other by a connecting bar 2 which is mounted on the top of the plates. At least one of the wind-shifting plates 1A is connected to a lowspeed rotary motor 6 through an arm 3 and a movable plate 4, with a support 10 provided thereto.

The movable plate 4 is connected to the arm 3.

As in the other embodiment, an elongated hole 12 is provided in the movable plate 4, and a crank pin 5 is engaged with the elongated hole 12. The crank pin 5 is connected to the low-speed rotary motor 6. A pin 17 is provided on the arm 4 and is brought into engagement with a plurality of pin holes 7, which are bored into the movable plate 4 so that the arm 3 and the movable plate 4 are connected to each other.

A plurality of U-shaped grooves 46 are bored in the upper and lower bearing plates 8a and 8b. The U-shaped grooves surround and are spaced apart from bearing holes 33. The diameter of the bearing holes 33 is less than the diameter of the supporting shafts. A plurality of notched grooves 47 (Figure 11) connect the bearing holes 33 to the bottom portions 48 of the U-shaped grooves 46, and a slit 49 extends from each of the bearing holes 33 in the opposite direction of the corresponding notched grooves 47.

The slit 49 is parallel with a straight portion 50 of the U-shaped groove 46, and, accordingly, an elastic supporting arm 51 is formed.

Since the diameter of the bearing holes 33 is made smaller than the diameter of the supporting shafts 9, the supporting arms 51 are urged apart when the supporting shaft 9 is inserted into the hole 33 to securely hold the supporting shaft 9. When the low-speed rotary motor 6 is operated, the arms 3 moved back and forth in the same manner as in the other embodiments, and this motion is transmitter to the wind-shifting plate 1A. In this way, the wind from a blower (not shown) is automatically shifted according to the rotation of the low-speed rotary motor 6. In this embodiment, if the wind-shifting plates 1A, 1B begin to vibrate from the wind pressure of the blower, the vibration are absorbed by the supporting arms 51 which form the bearing holes 33, and no unpleasant noise develops. Furthermore, no excess friction develops between the supporting shaft and the bearing hole due to the resiliency of the supporting arms 51.

Figure 12 shows a modification of the embodiment of Figures 10 and 11. In Figure 12, half of the U-shaped groove 46 has been eliminated so that only one resilient supporting arm 52 is formed adjacent to the bearing hole 33. Again, the diameter of the bearing hole 33 is smaller than the diameter of the supporting shaft 9 so that the supporting arm 52 can resiliently hold the supporting shaft 9 and dampen vibrations.

Claims (22)

1. Awind-shifting apparatusforan air conditioner, comprising, a plurality of wind-shifting plates; means for pivotally supporting said wind-shifting plates in front of a main body of said air conditioner, a drive source having a rotary shaft which provides rotary motion, a movable plate connected to said rotary shaft, a support for pivotably securing said movable plate at a point between opposite ends thereof, said movable plate having converting means at one end thereof connected to said rotary shaft for converting said rotary motion of said rotary shaft into pivotable motion of said movable plate about said support, an opposite end of said movable plate having a plurality of holes therein, an arm having a shaft engaged with one of said plurality of holes in said opposite end of said movable plate; and means for connecting said arm to one of said plurality of wind-shifting plates so that said rotational motion of said drive shaft pivotably rotates said one of said plurality of wind-shifting plates to change a direction of wind being blown from said air conditioner main body.

2. The apparatus as claimed in claim 1 further comprising means for interconnecting said plurality of wind-shifting plates so that said plurality of wind-shifting plates pivotably rotate together.

3. The apparatus as claimed in claim 2 wherein said interconnecting means comprises a connecting bar.

4. The apparatus as claimed in claim 2 wherein said pivoting supporting means comprises upper and lower frame members and a plurality of supporting shafts which extend from upper and lower ends of said plurality of plates, said plurality of supporting shafts being pivotably coupled to said upper and lower frame members.

5. The apparatus as claimed in claim 1 wherein said plurality of holes in said opposite end of said movable plate are positioned to provide varying angles of rotation of said one of said plurality of wind-shifting plates, said plurality of holes being in substantially a common plane.

6. The apparatus as claimed in claim 4wherein said support is connected to said lower frame member.

7. The apparatus as claimed in claim 1 wherein said drive source comprises a low-speed electric motor.

8. The apparatus as claimed in claim 1 wherein said converting means comprises an elongated slot formed in said movable plate, and a crank having a pin engagable with said elongated slot, said crank having one end coupled to said rotary shaft.

9. The apparatus as claimed in claim 5 wherein said plurality of holes in said opposite end of said movable plate are each connected to a large connecting hole by a plurality of slits having a width slightly smaller than a diameter of said shaft of said arm.

10. The apparatus as claimed in claim 9 wherein said plurality of holes in said movable plate are formed around said large connecting hole.

11. The apparatus as claimed in claim 10 wherein said shaft of said arm has a small diameter portion and a large diameter portion, a diameter of said small diameter portion being slightly greater than said width of said plurality of slits, a diameter of said large diameter portion being larger than a diameter of said plurality of holes in said movable plate.

12. The apparatus as claimed in claim 11 wherein said diameter of said large diameter portion is less than a diameter of said large connecting hole.

13. The apparatus as claimed in claim 1 wherein said pivoting supporting means comprises upper and lowerframe members and a plurality of supporting shafts which extend from upper and lower ends of said plurality of plates, said upper and lower frame members having bearing holes through which said supporting shafts extend, at least one bearing hole being formed by at least one resilient supporting arm, one of said supporting shafts having a diameter larger than said one bearing hole so that when said one supporting shaft is inserted into said one bearing hole, said resilient supporting arm of said one bearing hole is resiliently urged outward to enlarge a size of said one bearing hole to accommodate said one supporting shaft.

14. The apparatus as claimed in claim 13 further comprising means for interconnecting said plurality of wind-shifting plates to one another so that said plurality of wind-shifting plates pivotably rotates together.

15. The apparatus as claimed in claim 14 wherein said interconnecting means comprises a connecting bar.

16. The apparatus as claimed in claim 14 wherein said one bearing hole is formed by two resilient supporting arms which are urged away from each other to enlarge said size of said one bearing hole when said one supporting shaft is inserted into said one bearing hole.

17. The apparatus as claimed in claim 16 wherein said two resilient supporting arms define a U-shaped groove in addition to said one bearing hole as well as a longitudinal slit which passes through sid one bearing hole, one end of said longitudinal slit terminating art a U part of said U-shaped groove, an opposite end of said longitudinal slit extending between leg portions of said U-shaped groove.

18. The apparatus as claimed in claim 13 wherein said drive source is an electric motor which is rotated at a low speed.

19. The apparatus as claimed in claim 13 wherein said converting means comprises an elongated slot formed in said movable plate, and a crank having a pin engageable with said longitudinal slot, said crank having one end coupled to said rotary shaft.

20. Wind-shifting apparatus for an air conditioner substantially as hereinbefore described with reference to and as shown in Figures 1 to 4.

21. Wind-shifting apparatus for an air conditioner substantially as hereinbefore described with reference to and as shown in Figures 5 to 9.

22. Wind-shifting apparatus for an air conditioner substantially as hereinbefore described with reference to and as shown in Figures 10 to 12.