KR100450304B1 - Rotary angle control apparatus for electric fan - Google Patents

Abstract

It provides a fan rotation angle adjustment device that can smoothly operate the lever rotation without using a large operating force.

The rotation angle adjusting device D 'includes a substantially double-shaped neckpiece upper 4 having a sidewall formed in a periphery of a bottom wall of a predetermined shape, and a support shaft placed in the bottom wall 15 of the neckpiece upper 4. Between the rotation angle adjustment lever 6 supported by the shaft 5 and the support shaft 5 and the bottom wall 15 of the neckpiece upper 4 while closing and covering the upper opening of the neckpiece upper 4. A plate 8 for rotatably inserting the lever 6 and one end is mounted to the head of the fan, and the other end is provided with a rotary link mounted to the lever 6.

Description

Rotary angle control apparatus for electric fan

The present invention relates to a rotation angle adjusting device of the fan.

As shown in Figs. 13 to 17, the rotation angle adjusting device of the conventional fan is axially supported by the support shaft 104, which is placed inside the neckpiece 102, with the rotation angle adjusting lever 105 being When the user rotates the lever 105 by hand, and puts it in the selected position, it is comprised so that the rotation angle of the fan 100 may be switched in multiple steps.

This will be described in more detail. The neckpiece 102 is mounted on the upper end of the support 115 and a neckpiece lower 116 for axially supporting the head 101 of the fan 100 so as to be able to pivot up and down. It consists mainly of the neckpiece upper 103 opened in the substantially double shape arrange | positioned on the neckpiece lower 116 (refer FIG. 13).

The rotation angle adjusting device includes a neckpiece upper 103 (see FIG. 14), a support shaft 104 (see FIG. 14) mounted on the bottom wall 103g of the neckpiece upper 103, and a support shaft 104. The lever 105 for rotation angle adjustment (refer FIG. 15) and the upper opening of the neckpiece upper 103 which are axially supported by the cover is closed, and the lever 105 is inserted rotatably between the bottom wall 103g, and is inserted. The plate 106 (refer FIG. 17) attached so that it may be equipped, and the rotating link (not shown) in which one end part is attached to the head part 101 and the other end part is attached to the lever 105 are provided.

The lever 105 is as shown in Figs. 15 and 16 in its overall shape, and the shaft support portion 120, which is inserted into the support shaft 104 having the screw hole 104a and is axially supported, is approximately in the middle of its length. 121 is a lever body portion extending from the shaft support portion 120 to a predetermined width, and a substantially hemispherical groove 105a opened upward in the middle portion of the length of the upper surface of the lever body portion 121 is provided. It is installed. A steel ball 107 is fitted into the groove 105a in a state where the upper half protrudes. The projection 105b is provided in the lower surface of the lever main body 121 just below the groove 105a. The projection 105b has a bottom wall 103g of the neckpiece upper 103 when the lever 105 is rotated. It is a support part of the lever 105 which slides in contact with ().

As shown in Fig. 17, the plate 106 is provided with three holes 108, 109, and 110 through which the steel ball 107 is engaged with the rotation operation of the lever 105. The steel ball 107 inserted into the groove 105a of the 105 is engaged with any one of the three holes 108, 109, and 110 in the plate 106, so that the rotation angle of the fan 100 is desired (for example, 40). And one of 60 degrees and 80 degrees. The fixing portion 111 having a screw hole is formed on the plate 106 at a position corresponding to the support shaft 104.

The plate 106 is mounted as follows. First, the lever 105 is inserted from the shaft support portion 120 to the support shaft 104 of the neckpiece upper 103. Thereafter, one side edge of the plate 106 (side edge close to the fixing portion 111). ), A part of the bottom surface of the bottom surface of the neckpiece upper 103 is placed on the first mounting portion 103a and the second mounting portion 103b, which are integrally formed in one side wall of the neckpiece upper 103 in an inwardly protruding shape, and the side edges of the plate 106 in the other direction. A portion of the lower surface of the bottom surface is placed on the third placing portion 103c and the fourth placing portion 103d which are integrally formed in the inner side protruding shape on the side wall of the neckpiece upper 103. Next, as shown in Figs. Similarly, most of one side edge of the plate 106 is put under the engagement hook portion 103e integrally formed in the inner protrusion shape at the upper edge of one side wall of the neckpiece upper 103 to the hook portion 103e. Godfather of other side edge of plate 106 A, put into the lower side of the upper neck piece 103, the other walking integrally formed inwardly protruding on the upper edge of the side wall hanging loop alignment portion (103f) for a walk align the hanging loop portion (103f). Finally, the screw hole of the fixing part 111 of the plate 106 coincides with the screw hole 104a of the support shaft 104, and is attached to the support shaft 104 by the screw member 112. As described above. 17, the rotation angle adjusting device is obtained.

In the conventional rotation angle adjusting device, when the steel ball 107 moves between the three holes 108, 109, 110 of the plate 106, the top of the steel ball 107 moves while contacting the bottom surface of the plate 106, As shown in FIG. 18, when the steel ball 107 comes to either position of the holes 108, 109, 110, the top of the steel ball 107 is set to a desired rotational angle by engaging the one of the holes 108, 109, 110. will be. Thus, the dimensions between the lever 105 and the plate 106 need to be changed when the steel ball 107 is between the holes 108, 109, 110 and when the steel ball 107 is in either position of the hole 108, 109, 110. There is. In the conventional rotation angle adjusting device, the plate 106 is bent upward to adjust the dimension between the lever 105 and the plate 106 and selectively rotate the lever 105 at a predetermined angle position. In addition, the lever 105 can be selectively held at a predetermined angle position.

In addition, the conventional rotation angle adjusting device has a structure employed in the previous rotation angle adjusting device, that is, a structure in which a compression coil spring for inserting the steel ball 107 upward into the groove 105a of the lever 105 is inserted. The cost reduction is achieved by eliminating the need for a compression coil spring.

However, this conventional rotation angle adjusting device has a drawback in that a large resistance is generated between the steel ball 107 and the plate 106, and the operating force for rotating the lever 105 becomes large. 105b is provided directly under the groove 105a because it directly receives the moving force on the steel ball 107 (see FIGS. 15 and 16), and the rotation of the lever 105 to a predetermined position causes the plate 106 to move. Although it is performed by bending, the plate 106 has a structure in which the plate 106 is hard to bend or move upward especially since both edges are restricted from moving upwards almost throughout. As a result, the friction force between the lever 105 and the plate 106 is larger than the previous rotation angle adjusting device, and the lever operating force is increased, so that the lever 105 cannot be moved smoothly. It was slightly difficult to stop the rotation of the lever 105 in the position where the intermediate hole 109 among the 108,109, 110 is.

This invention is made | formed in view of such a situation, The subject is providing the rotation angle adjustment apparatus of the fan which can perform smoothly the rotation operation of a lever, without resorting to a large operation force.

According to the present invention, a neckpiece upper is formed by opening a sidewall at a circumferential edge of a predetermined bottom wall, and a support shaft placed on the bottom wall of the neckpiece upper, a lever for rotation angle adjustment axially supported on the support shaft, Rotating plate that closes and covers the upper opening of the neckpiece upper and inserts the lever pivotally between the bottom wall of the neckpiece upper and one end is mounted to the head of the fan and the other end is mounted to the lever. It is provided with a link, a substantially hemispherical groove is provided on the upper surface of the lever, a plurality of engaging holes are provided in the plate, and the groove is inserted with the steel ball protruding the upper half thereof. When the lever is rotated, the top of the steel ball slides the lower surface of the steel plate and engages with the engagement hole so that the lever is positioned in a plurality of predetermined positions. And support the lever by the bottom wall of the neckpiece upper at a position biased from the groove to the support shaft side, and at the lever operating end side of this support point, the bottom surface of the lever and the bottom wall of the neckpiece upper A rotation angle adjusting device for a fan is provided, characterized in that a support portion is formed in between.

Since the rotation angle adjustment device of the fan according to the present invention is configured in this manner, the plate is bent upwards in the same way as the conventional one for adjusting the dimension between the lever and the plate, and the distance between the groove of the lever and the protrusion By making the levers both bent downward, the larger dimension adjustment range can be ensured, and the rotation operation of the lever can be performed smoothly without a large operating force.

The plate of the rotation angle adjusting device of the fan according to the present invention can be configured to fix only the support shaft side portion in the up and down direction without fixing the lever operating end side portion of both side edges in the up and down direction.

In this way, both edges of the plate are more likely to be bent upward on their side of the lever operation end (the front part), that is, the part with the locking hole, and the size adjustment range between the plate and the lever can be increased. have.

The rotation angle adjusting device of the fan according to the present invention can be formed by a protrusion projecting from the lower surface of the lever. By forming the support part in this way, the shape of the support part can be made simple, and the manufacturing becomes easy, and even if the lever is in any rotational position, the degree of bending of the lever is constant and a stable lever rotation operation is secured. Moreover, this protrusion can be made into the shape suitable for support.

The rotation angle adjustment device of the fan according to the present invention can be formed by a protrusion projecting from the bottom wall of the neckpiece upper. When the support portion is formed in this way, the lower surface of the lever can be flattened, so that the lever life is not stressed by the bending force and the life of the lever is extended.

The rotation angle adjusting device of the fan according to the present invention sets the protruding portion to have a flat shape and sets the protruding height to be lower at a position where the distance between the support point and the steel ball becomes smaller by the rotation of the lever. It may be set higher at a larger position.

By setting the protruding height of the protruding portion in this manner, it is possible to reduce the difference between the operating force (bending) at the lever rotational position where the distance is smaller and the operating force (bending stress) at the lever rotational position larger than the distance. Therefore, when the support part is provided on the neckpiece upper side, the lever can be rotated with almost no change in the operating force regardless of the lever rotation position. For example, it becomes possible to set to a rectangle extending between one sidewall bias position and the other sidewall bias position of the bottom wall of the neckpiece.

In addition, the position of attaching the height difference of the protrusion and the degree of height difference can be appropriately changed depending on the material and strength of the lever or plate, the number and position of the engagement holes of the plate.

In the rotation angle adjusting device of the fan according to the present invention, the lever and the neckpiece upper may be formed by plastic integral molding, and the plate may be made of a metal plate. In this way, a complicated shape of the lever and neckpiece upper can be easily obtained, and the necessary elastic deflection can be secured by adjusting the plate thickness of the plate.

BRIEF DESCRIPTION OF THE DRAWINGS It is a principal part enlarged side view of the fan with which the rotation angle adjustment apparatus concerning Embodiment 1 of this invention was assembled.

FIG. 2 is a perspective view of a neck piece upper constituting part of the rotation angle adjusting device of FIG. 1. FIG.

3A is a perspective view of a rotation angle adjusting lever constituting a part of the rotation angle adjusting device of FIG. 1. FIG. 3B is a front view of the lever of FIG. 3A.

4 is a perspective view of a plate that forms part of the rotation angle adjusting device of FIG. 1.

5 is a cross-sectional view showing a part of the mounting method of the plate of the neckpiece upper of FIG. 2.

6 is a perspective view of the rotation angle adjusting device of FIG. 1.

7 is a cross-sectional view illustrating the function of the rotation angle adjusting device of FIG. 1.

8 is a cross-sectional view illustrating the function of the rotation angle adjusting device of FIG. 1.

It is a perspective view of the neckpiece upper which comprises a part of rotation angle adjusting device concerning Embodiment 2 of this invention.

10A is a perspective view of a lever constituting a part of the rotation angle adjusting device of FIG. 9.

FIG. 10B is a front view of the lever of FIG. 10A.

FIG. 11 is a cross-sectional view illustrating the function of the rotation angle adjusting device of FIG. 8.

12 is a cross-sectional view illustrating the function of the rotation angle adjusting device of FIG. 8.

13 is an enlarged side view of main parts of a fan to which a conventional rotation angle adjusting device is assembled.

14 is a perspective view of a neckpiece upper constituting a part of the rotation angle adjusting device of FIG. 13.

FIG. 15 is a perspective view of a rotation angle adjusting lever constituting a part of the rotation angle adjusting device of FIG. 13.

16 is a front view of the lever of FIG.

17 is a perspective view of the rotation angle adjusting device of FIG. 13.

18 is a cross-sectional view illustrating the function of the rotation angle adjusting device of FIG. 13.

* Description of Reference Symbols Representing Major Parts

1: electric fan 2: head

4: neckpiece upper 4A: neckpiece upper

5: support shaft

6: lever for adjusting the rotation angle

6A: rotation angle adjustment lever 8: plate

9: one side wall 10: other side wall

11: first placing unit 12: second placing unit

13: 3rd placing part 14: 4th placing part

15: bottom wall 16: fixed part

17: engagement hole 18: engagement hole

19: engaging hole 20: shaft portion

21: lever body 22: groove

23: steel ball 24: protrusion

60: protrusion

EMBODIMENT OF THE INVENTION Hereinafter, two embodiment which concerns on this invention is described based on drawing. In addition, this invention is not limited by this.

Embodiment 1

As shown in FIGS. 1-5, the rotation angle adjustment apparatus D 'of the fan which concerns on Embodiment 1 of this invention has the rotation angle adjustment lever 6 installed in the inside of the neck piece 3, and the support shaft ( 5), the rotation angle of the fan 1 is switched to a plurality of stages by rotating the lever 6 by the user by rotating the lever 6 by hand.

This will be described in more detail below. The neck piece 3 is attached to the upper end of the strut 31, and a neck piece lower 7 for axially supporting the head 2 of the fan 1 so as to be able to pivot up and down, It consists mainly of the neckpiece upper 4 opened in the substantially double shape mounted on the neckpiece lower 7 (refer FIG. 1).

The rotation angle adjusting device D 'includes a support shaft 5 having a screw hole 5a at the center of the neckpiece upper 4 (see FIG. 2) and the neckpiece upper 4. The same), the rotation angle adjustment lever 6 (see FIGS. 3A and 3B) and the upper portion of the neckpiece upper 4 which are axially supported on the support shaft 5 so as to be substantially horizontally rotated. A plate 8 (see FIG. 4) and one end of which the lever 6 is rotatably inserted between the bottom wall 15 of the upper 4 and one end thereof are mounted to the head 2 of the fan 1. The other end is comprised with the rotary link (not shown) attached to the lever 6.

The lever 6 is a plastic integrally molded article, and in particular, as shown in Figs. 3A and 3B, a shaft support portion 20, which is inserted into the support shaft 5 and supported by the shaft, is provided at almost the middle portion of the length thereof. Is a lever body portion integrally formed from the shaft support portion 20 in an extended shape, and an approximately half-spherical groove 22 opened upward as an engaging portion in the middle of the length of the upper surface of the lever body portion 21 is formed. The stainless steel ball 23 arrange | positioned so that the groove | channel 22 may slide on the lower surface of the plate 8 is inserted in the state which sank about half.

On the lower surface of the lever body portion 21, a portion separated from the bottom of the groove 22 toward the support shaft 5 by a predetermined distance is supported on the upper surface of the bottom wall 15 of the neckpiece upper 4 and at the same time, the lever body portion is lower than the support point. A projection 24 serving as a lever support portion that forms a space between the operation end side portion of the lever body portion 21 biased toward the operation end side of the 21 and the bottom wall 15 of the neckpiece upper 4 is provided. have. That is, the projection part 24 is a support part of the lever 6 which slides in contact with the bottom wall 15 of the neckpiece upper 4 at the time of the rotation operation of the lever 6. By configuring the lever main body 21 as described above, a predetermined distance is secured between the groove 22 and the protrusion 24 (supporting point) unlike the prior art.

The neckpiece upper 4 is a plastic integrally molded article, and as shown in FIG. 2, two slits 30 in which the middle portion of one side wall 9, which is a side wall close to the support shaft 5, extends vertically, At the same time as the intermediate wall 31, the hook portion 31a for engagement with the upper edge of the intermediate wall 31 is integrally formed in the inner protrusion shape. The hook portion 31a is formed in FIG. As shown by the solid line, the inclined portion 31a-1 and the vertical portion 31a-2 connected to the inclined portion 31a-1 are formed. Moreover, the 1st mounting part 11 and the 2nd mounting part 12 are integrally formed in the inner side protruding shape in the both side surfaces of the intermediate | middle wall 31 in one side wall 9, respectively. The third mounting portion 13 and the fourth placing portion 14 are integrally formed in the inner protruding shape on the other side wall 10. At the upper edge of the other side wall 10, the support shaft side of the side wall 10 is formed. An engaging hook portion 10a extending almost half is integrally formed in the inner protrusion shape. The hook portion 31a of one side wall 9 and the hook portion 10a of the other side wall 10 are plated. It acts to regulate upward movement in the corresponding positions of one side edge and the other side edge of (8).

Further, a first stopper portion 25 integrally formed in the inner protruding shape is provided at the front end of one side wall. The second stopper portion integrally formed in the inner protruding shape is provided at the front end of the other side wall 10. 26. The first stopper portion 25 and the second stopper portion 26 have the side surfaces of the lever body portion 21 abutting against the lever body portion 21 when the lever 6 is rotated. It acts to prevent rotation beyond a certain range.

The plate 8 is formed of a stainless steel plate, and as shown in FIG. 4, the fixing portion 16 is integrally formed at a position corresponding to the support shaft 5 of the neckpiece upper 4. A screw hole 16a is provided in the fixing portion 16.

The plate 8 is mounted as follows. First, the lever 6 is fitted from the shaft support 20 to the shaft support 5 of the neckpiece upper 4. Next, the other side edges (side edges away from the fixing portion 16) of the plate 8 are placed on the third placing portion 13 and the fourth placing portion 14 of the neckpiece upper 4. . Thereafter, one side edge of the plate 8 is pushed from above to be placed on the first placing portion 11 and the second placing portion 12 of the neckpiece upper 4. Then, as shown by the broken line in FIG. 5, the inclined portion 31a-1 of the intermediate wall 31 of the neckpiece upper 4 is pressed downward from one side edge of the plate 8. When the plate 8 is pressed in this state, the part of the side edge of the plate 8 which is in contact with the inclined portion 31a-1 of the middle wall 31 slides down the inclined portion 31a-1. Therefore, the upper portion of the intermediate wall 31 elastically deforms in the outward direction. When the plate 8 is further pushed in, one side edge of the plate 8 which has been in contact with the inclined portion 31a-1 is lowered and passes through the vertical portion 31a-2. Then, since the upper part of the intermediate wall 31 elastically returns to a solid line position, it is preferable that the plate 8 occupies a predetermined position in a state where it is placed on the first placing unit 11 and the second placing unit 12. do. At this time, the support shaft part of the other side edge of the plate 8 is engaged with the hook part 10a in the state which dug into the lower part of the hook part 10a of the neckpiece upper 4. As shown in FIG. Finally, the screw hole 16a of the fixing portion 16 of the plate 8 coincides with the screw hole 5a of the support shaft 5 of the neckpiece upper 4 so as to match the screw member 28 (see FIG. 5). By the support shaft 5. As described above, the rotation angle adjusting device D ₁ as shown in FIG. 6 can be obtained.

Three engagement holes 17, 18, and 19 are provided in the plate 8 in a through type. (See FIG. 4). These holes 17, 18, 19 are provided on an arc centered around the center of the screw hole 16a of the fixing portion 16. As shown in FIG. As shown in FIG. 7, when the steel ball 23 moves between the three holes 17, 18, 19 of the plate 8, the top of the steel ball 23 moves while contacting the bottom surface of the plate 8. do. At this time, since the lever operating end side portion of both side edges of the plate 8 is not fixed in the up-down direction as described above, as shown by the upward arrow of FIG. 7, it is easily pressed by the top of the steel ball 23. Bend upwards to move. Moreover, since a predetermined distance is provided between the groove | channel 22 (part of the steel ball 23) of the lever 6, and the protrusion part 24 in the longitudinal direction of the lever 6, the lever 6 is a steel ball 23 ) Moves downward between the three holes 17, 18, 19 of the plate 8 as indicated by the downward arrow in FIG. 7 with the lower end of the protrusion 24 as a point. And when the steel ball 23 comes to either position of the hole 17, 18, 19, as shown in FIG. 8, the vertex part of the steel ball 23 engages with either one of the hole 17, 18, 19, and a lever. (6) returns to the natural shape.

As described above, when the steel ball 23 is engaged with the hole 17 close to one side edge of the plate 8, the rotation angle mounted on the lever 6 becomes the maximum (for example, 80 degrees) and the intermediate hole ( 18), the rotation angle becomes intermediate (for example, 60 degrees) and the rotation angle becomes minimum (for example, 40 degrees) when engaged in the hole 19 near the other side edge.

In this rotation angle adjusting device D ₁ , the plate 8 is bent upward and the grooves 22 of the lever 6 are bent in the same way as in the prior art to adjust the dimension between the lever 6 and the plate 8. ) And the protruding portion 24 in the longitudinal direction of the lever 6 are provided at a predetermined dimension apart from each other in which the lever 6 is easily bent downward. It is possible to secure a larger dimension adjustment range than this lever 6, and it is possible to smoothly execute the rotation operation of the lever 6 without depending on a large operating force.

In addition, since the protruding portion 24 provided on the lower surface of the lever 6 has a simple configuration, the shape of the lever 6 is simple, which facilitates the manufacture of the lever 6 and the lever 6 is in any rotational position. The degree of bending is constant and stable lever rotation operation is ensured.

In this rotation angle adjusting device D ₁ , the lever 6 and the neckpiece upper 4 are formed by integral plastic molding, and the plate 8 is made of a metal plate, so that the lever 6 and the complicated shape are formed. The neck piece upper 4 can be obtained simply, and the necessary elastic deflection can be secured by adjusting the plate thickness of the plate 6.

Embodiment 2

In Embodiment 2 of this invention, the protrusion part as a support part is provided in the neckpiece upper side. Hereinafter, this point is demonstrated in more detail with reference to FIGS. In addition, in these drawings, the same code | symbol is attached | subjected to the substantially same part as Embodiment 1, and the description is abbreviate | omitted.

In the bottom wall 15 of the neck piece upper 4A which is close to the support shaft 5, the protrusion part 60 as a support part which extends from the one side wall 30 to the other side wall 10 is provided. (See Figure 9). The protrusion 60 has a rectangular planar shape and has a constant width. Although the length of the protrusion part 60 should just have the length corresponding to the rotation angle of the lever main-body part 21 at least, the width of the bottom wall 15 of the neckpiece upper 4A may be full.

The lower surface of the lever main body 21 in the lever 6A is flat without the protrusion 24 or the like in the rotation angle adjusting device D ₁ . See Figure 10b)

The protruding portion 60 is a support portion of the lever 6A which slides in a state where a part of the lower surface of the lever body portion 21 abuts on the bottom wall 15 of the neckpiece upper 4A during the rotation operation of the lever 6A. The protrusion 60 is provided such that the lever main body 21 is fitted into the groove 22 and receives a force from the steel ball 23 sliding the lower surface of the plate 8 so as to contact the protrusion 60. By bending downward as a point, the gap adjustment with the plate 8 is performed and it moves smoothly. This will be described in more detail below.

The projection 60 has a portion (one end side portion) from one end close to one side wall 9 to a position of about 70% of its length set to the same protruding height, and the other side wall 10 at the same position. The part (other end side part) to the other end part near to it is set so that it may gradually descend from one end side part, and may become inclined, and gradually become low. This is for the following reason.

In the rotation angle adjusting device D ₁ according to the first embodiment, the distance between the groove 22 or the steel ball 23 and the protruding portion 24 is not changed by the rotation operation of the lever 6. In the rotation angle device according to the present invention, since the projection 60 is provided on the bottom wall 15 of the neckpiece upper 4A so as to have a flat shape, the groove 22 or the steel ball 23 and the projection ( Distance from the other end side of the projection 60 is shorter than one end side, and the deflection of the lever 6A is worse than that of the one end side at the other end side of the projection 60. Since there is a difference in the height of the protruding height of the protrusions 60 is to solve this problem.

In the rotation angle adjusting device in which the protruding height of the protruding portion 60 is set in this way, as shown in FIG. 11, when the steel ball 23 moves between the three holes 17, 18, and 19 of the plate 8, the steel balls are used. The top of the plate 23 moves while contacting the bottom surface of the plate 8. At this time, since the lever operating end side portions of both side edges of the plate 8 are not fixed in the up-down direction as described above, as shown by the upward arrow of FIG. 11, they are easily pressed by the tops of the steel balls 23. Bend upwards to move. Moreover, since the predetermined distance is provided between the groove | channel 22 (part of the steel ball 23) of the lever 6A, and the projection part 60 in the longitudinal direction of the lever 6A, the lever 6A is a steel ball 23 Is moved between the three holes 17, 18, 19 of the plate 8, as indicated by the downward arrow in Fig. 11, the lower part of the plate 8 is in contact with the protrusion 60 and the lever 6A as the point. I broke it. When the steel ball 23 comes to one of the holes 17, 18, and 19, as shown in Fig. 12, the top of the steel ball 23 is engaged with one of the holes 17, 18, and 19, and the lever 6 Returns to the shape of the natural body. In addition, when such a projection part 60 is not provided, it is preferable to set the planar shape of a projection part to the fan shape which has two parallel arcs extended to both sides of the arc of the predetermined center angle which is the rotational point of the said support point.

As described above, also in the rotation angle adjusting device according to the second embodiment, the plate 8 is bent upward and the groove of the lever 6A is adjusted in the same way as the conventional one for the dimension adjustment between the lever 6A and the plate 8. It is easy to bend the lever 6A downward with a predetermined distance between the 22 and the projection 60 of the neckpiece upper 4A, and by doing it on both sides, a larger dimensional adjustment range can be secured. The rotational operation of the lever 6A can be performed smoothly without depending on a large operating force.

According to the rotating angle adjusting device of the fan according to claim 1, the lever is supported by the bottom wall of the neckpiece upper at a position close to the support shaft side in the groove of the lever, and at the lever operating end side of the support point, the lever and the neckpiece upper Since a support portion is formed between the bottom wall of the valve, the plate is bent upwards in the same way as the conventional one for adjusting the dimension between the lever and the plate, and a predetermined distance between the groove of the lever and the protrusion is provided. It is possible to secure a larger dimensional adjustment range by performing both the lever and the lever to bend downward, and it is possible to smoothly perform the rotation operation of the lever without resorting to a large operating force.

According to the rotation angle adjusting device of the fan according to claim 2, since the plate fixes only the side of the support shaft in the vertical direction without fixing the lever operating end side of the two edges in the vertical direction, both edges of the plate are the semi-support shafts. The side part, that is, the part which is an engagement hole, becomes easy to bend upward, and the range of dimension adjustment between a plate and a lever can be enlarged further.

According to the rotating angle adjusting device of the fan according to claim 3, since the support portion is formed by a protrusion projecting from the lower surface of the lever, the shape of the lever is simple and the manufacture thereof is easy, and the lever is bent at any rotational position. The accuracy is constant and stable lever rotation operation is secured.

According to the rotation angle adjusting device of the fan according to claim 4, since the support portion is formed by a protrusion projecting from the bottom wall of the neckpiece upper, the lower surface of the lever can be flattened and the life of the lever can be caused without causing stress concentration to the bending force. This lengthens.

According to the rotating angle adjusting device of the fan according to claim 5, the protrusion has a flat shape and the protrusion height is set smaller at a position where the distance between the support point and the steel ball becomes smaller by the rotation of the lever. Since it is set higher at a larger position, it is possible to reduce the difference between the operation force at the lever rotational position where the distance is very small and the operation force at the lever rotational position where the distance is larger, and the support portion is the neckpiece upper side. In this case, the lever can be rotated without changing the operating force almost irrespective of the lever rotation position. Therefore, the planar shape of the protrusion can be set to a simple shape.

According to the rotating angle adjusting device of the fan according to claim 6, since the lever and the neckpiece upper are formed by plastic integral molding and the plate is made of a metal plate, a complicated shape of the lever and neckpiece upper can be easily obtained. By adjusting the plate thickness, it is possible to secure the required elastic deflection.

Claims (6)

A neckpiece upper having a side wall recessed at the circumferential edge of the bottom wall of a predetermined shape and opening upward, a support shaft mounted on the bottom wall of the neckpiece upper, a lever for rotation angle adjustment axially supported on the support shaft, and a neckpiece upper And a plate for closing and covering the upper opening of the upper part of the neckpiece and rotatably inserting the lever between the bottom wall of the neckpiece upper, and a rotating link having one end mounted to the head of the fan and the other end mounted to the lever. Done by A substantially hemispherical groove is provided on the upper surface of the lever, and a plurality of engaging holes are provided in the plate, and the groove is fitted in such a state that the steel balls protrude the upper half of the lever. The stem of the steel ball is configured to hold the lever in a plurality of predetermined positions by sliding the lower surface of the plate and engaging the engaging hole. Further, the lever is supported by the bottom wall of the neckpiece upper at a position close to the support shaft side from the groove, and at the lever operating end side portion of the support point, a space is formed between the bottom surface of the lever and the bottom wall of the neckpiece upper. Fan rotation angle adjustment device characterized in that the support is provided. The method of claim 1, The plate is a fan rotation angle control device, characterized in that the side of the support shaft fixed only the support shaft side portion in the vertical direction without fixing the side of the lever operating end side. The method according to claim 1 or 2, And the support portion is formed by a protrusion projecting from the lower surface of the lever. The method according to claim 1 or 2, And the support part is formed by a protrusion projecting from the bottom wall of the neckpiece upper. The method of claim 4, wherein The protruding portion has a planar shape, and the protruding height is set lower at a position where the distance between the support point and the steel ball becomes smaller by a rotational operation of the lever, and set higher at a larger position. Fan rotation angle adjuster. The method of claim 5, And said lever and said neckpiece upper are formed by plastic integral molding, and said plate is composed of a metal plate.