JP4175684B2 - Rotation support mechanism - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a rotational motion support mechanism, and more particularly to a rotational motion support mechanism having an improved click mechanism that holds a rotational shaft at a predetermined rotational angle.
[0002]
[Prior art]
Conventionally, control objects connected to a rotating shaft, for example, doors, piano keyboard lids, laptop computer lids, toilet seats and toilet lids of Western-style toilets, etc., the rotating shaft has reached a predetermined rotation angle. At that time, a rotation support mechanism with a built-in click mechanism is used to hold the controlled object in the open state at that position. As such a click mechanism portion, for example, a concave portion is provided on the inner surface of the main body case fixed to the main body portion that supports the control object, and a convex portion that engages with the concave portion is provided at an appropriate position on the rotation shaft. Or a mechanical structure using a cam system in which a steel ball or the like urged by a spring is disposed at a predetermined position and the rotating shaft is held at a predetermined rotation angle when both are engaged. ing.
[0003]
[Problems to be solved by the invention]
However, since the click mechanism portion described above is only mechanically engaged in any case, there is a problem in terms of durability because the engaging concave portion and convex portion wear with use. Further, when maintaining a high holding force at the time of clicking, it is necessary to employ a cam having a deeper concave portion, a higher convex portion or the like, and there is a problem that a sound generated at the time of clicking increases. Further, when the cam is deformed due to wear or the like, abnormal noise may be generated when the cam is engaged. There is also a structure that uses the reaction force of the leaf spring to click the leaf spring when it reaches a predetermined angle, but in this case, try to increase the holding force at the time of clicking. In this case, a leaf spring having a larger reaction force must be used, and in that case, there is a problem that workability at the time of assembly is inferior.
[0004]
The present invention has been made in view of the above, has excellent durability, can reduce the sound generated at the time of clicking, and can easily adjust the holding force at the time of clicking and has a large holding force. It is an object of the present invention to provide a rotational motion support mechanism provided with a click mechanism that does not adversely affect the workability during assembly even if is adopted.
[0005]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the rotational motion support mechanism according to the present invention is supported by a cylindrical main body case, at least a part of which is inserted into the main body case, and a control object is connected. A rotation operation support mechanism that rotatably supports a controlled object, wherein the click mechanism portion includes a main body case. A magnet portion that is disposed within and movable in the axial direction by rotation of the rotating shaft, and a normal position is provided in the main body case so as to be separated from the normal position of the magnet portion in the axial direction. A magnetic body portion that adsorbs when the rotation shaft rotates by a predetermined angle and the magnet portion moves a predetermined distance in the axial direction, and the magnet portion has an axis longer than the length along the axial direction of the permanent magnet. direction Includes a peripheral wall having a length along the a yoke which is fixed to the permanent magnet, outer diameter and the inner diameter of the main body case inner surface corresponding to that of the predetermined portion of the portion inserted into the body case of said rotary shaft Are formed so that a space portion can be formed between them, a screw portion is formed in a predetermined portion of the portion inserted into the main body case of the rotating shaft, and the click mechanism portion is The constituting magnet part has a non-magnetic nut that is screwed into the threaded part of the rotating shaft, the permanent magnet is fixed to the outside of the nut, and the yoke is on the outer surface and in the main body case. It has the to- be- engaged part engaged with the engaging part formed along the axial direction, It is characterized by the above-mentioned.
A rotational motion support mechanism according to a second aspect of the present invention is the rotational motion support mechanism according to the first aspect , further comprising a damper portion that delays the rotational motion in at least one direction of the rotational shaft. And
Rotation support mechanism of the present invention according to claim 3, a rotational movement support mechanism according to claim 2, wherein the damper unit is in one end the main body case, with a spring the other end is connected to the rotary shaft It is characterized by being configured.
Rotation support mechanism of the present invention according to claim 4, a rotational movement support mechanism according to claim 2, constituted the damper portion, provided with a viscous liquid to be filled between the rotating shaft and the body case It is characterized by being.
The rotational motion support mechanism of the present invention according to claim 5 is the rotational motion support mechanism according to claim 2 , wherein the damper portion includes a spring whose one end is connected to the main body case and the other end is connected to the rotation shaft, and In addition, the liquid crystal display device is characterized by comprising both viscous liquid filled between the main body case and the rotating shaft.
[0006]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. 1 and 2 are cross-sectional views showing a rotational motion support mechanism 1 according to one embodiment of the present invention. The rotation operation support mechanism 1 includes a cylindrical main body case 2, a rotation shaft 3 that is inserted and disposed in at least a part of the main body case 2, and a click mechanism portion 4. .
[0007]
The main body case 2 is a main body that supports the object to be controlled. For example, if the object to be controlled is an entrance door, it is attached to the entrance frame, and if it is a toilet seat or toilet lid of a Western-style toilet, a screw (not shown), etc. It is fixedly arranged using. The main body case 2 has a small diameter portion 21 having a small inner diameter and a large diameter portion 22 having a large inner diameter. Near the end of the small-diameter portion 21, a step portion 21a that protrudes inward as viewed from the small-diameter portion 21 side is formed, and a shaft insertion portion 21c having a smaller inner diameter is formed by this step portion 21a. You may comprise using the cover body (not shown) which consists of another member which has a shaft insertion part, without forming 21a. Further, a stepped portion 22a is formed in the vicinity of the end of the large-diameter portion 22 so as to spread outward when viewed from the large-diameter portion 22 side, and the inner diameter between the stepped portion 22a and the end portion 22b is larger. ing. Between the step portion 22a and the end portion 22b, a magnetic body portion 6 constituting one member of the click mechanism portion 4 described later is disposed. A lid member 23 for holding the rotary shaft 3 and the click mechanism portion 4 in the main body case 2 after the rotary shaft 3 and the click mechanism portion 4 are accommodated is attached to the end portion 22 b on the large diameter portion 22 side of the main body case 2.
[0008]
At least a part of the rotating shaft 3 is inserted into the main body case 2, and the outer diameter of the portion corresponding to the inner surface of the large diameter portion 22 of the main body case 2 is the outer surface and the inner surface of the large diameter portion 22. It is formed in a shape that can form the space portion 24 therebetween. Specifically, it is formed with an outer diameter substantially the same as the inner diameter of the shaft insertion portion 21c of the main body case 2 described above, passes through the shaft insertion portion 21c, protrudes out of the main body case 2, and is controlled (not shown). A projecting portion 31 connected to the intermediate portion 32, an outer diameter that is substantially the same as the inner diameter of the small diameter portion 21 of the main body case 2, and a rear end portion from a boundary portion between the intermediate portion 32 33b, which corresponds to the above-described predetermined portion of the portion inserted into the main body case 2, and includes a small outer diameter portion 33 having an outer diameter smaller than the outer diameter of the intermediate portion 32. Is done. Thereby, the space part 24 is formed between this small outer diameter part 33 and the large diameter part inner surface of the main body case 2 corresponding to this. In the present embodiment, a screw portion 33 a is formed on the outer surface of the small outer diameter portion 33. This threaded portion 33a is preferably formed as a multi-threaded screw in order to enlarge the lead. The rear end portion 33 b is pivotally supported on the lid member 23 of the main body case 2.
[0009]
The click mechanism unit 4 includes a magnet unit 5 and a magnetic body unit 6 that are accommodated in the space 24 described above. Specifically, the magnet portion 5 has a screw portion (not shown) that is screwed into the screw portion 33a of the small outer diameter portion 33 of the rotating shaft 3 on the inner surface, and a nut 51 made of a nonmagnetic material such as plastic. And an annular permanent magnet 52 fixed to the outer surface of the nut 51 using an adhesive or the like, and an outer surface of the permanent magnet 52 also fixed to the outer surface of the permanent magnet 52 using an adhesive or the like, and has a bottom wall 53a and a peripheral wall 53b. The cut end face is substantially L-shaped and is composed of a planar annular yoke 53. More specifically, the yoke 53 is disposed so that the bottom wall 53a is positioned on the small diameter portion 21 of the main body case 2 and the intermediate portion 32 side of the rotary shaft 3, and the permanent magnet 52 includes a peripheral wall 53b, a nut 51, and the like. Between the two. Further, in order to prevent the permanent magnet 52 from coming into direct contact with the magnetic part 6 described below and being damaged, the height of the peripheral wall 53b of the yoke 53 (the length along the axial direction) is the axial direction of the permanent magnet 52. It is preferable that the length is longer than the length along. Further, as shown in FIG. 2, a groove 53c as an engaged portion is formed on the outer surface of the peripheral wall 53b of the yoke 53 along the axial direction. The inner surface of the diameter portion 22 is engaged with a protrusion 22c which is an engagement portion formed along the axial direction.
[0010]
In this embodiment, the magnetic body portion 6 has an insertion hole 61 having an inner diameter larger than the outer diameter of the small outer diameter portion 33 of the rotating shaft 3 in the vicinity of the center portion, and the outer diameter is larger than that of the main body case 2 described above. It consists of a disk-shaped iron plate formed so that it may become substantially the same as the internal diameter from the level | step-difference part 22a by the side of the diameter part 22 to the edge part 22b. As long as the magnetic part 6 is a magnetic material, it is not limited to iron.
[0011]
For example, if the rotational motion support mechanism 1 according to the present embodiment is a Western-style toilet, the main body case 2 is fixed to the upper part of the toilet body, and the protruding portion 31 of the rotary shaft 3 is attached to the toilet seat or toilet lid that is a control object. Are used concatenated. Specifically, in the closed state of the toilet seat or the toilet lid, the bottom wall 53a of the yoke 53 of the magnet portion 5 is in contact with the boundary portion of the small diameter portion 21 of the main body case 2 and the intermediate portion 32 of the rotating shaft 3. The normal position is set (the state shown in FIG. 1). At this time, the magnetic body portion 6 is located between the step portion 22 a on the large diameter portion 22 side of the main body case 2 and the end portion 22 b and is separated from the magnet portion 5.
[0012]
When the toilet seat or toilet lid is opened from this state, the rotary shaft 3 rotates in one direction accordingly. Even if the rotation shaft 3 rotates in one direction, the groove 53c of the yoke 53 is engaged with the protrusion 22c of the main body case 2, and therefore the rotation of the magnet portion 5 in the same direction as the rotation shaft 3 is prevented. The nut 51 is screwed into the small outer diameter portion 33 of the rotary shaft 3 while rotating in the opposite direction relatively, and eventually moves along the axial direction in a direction approaching the magnetic body portion 6.
[0013]
When the toilet seat or toilet lid is further opened and opened at a predetermined angle, for example, 100 degrees, the magnetic body 6 is attracted to the magnet 5 by the magnetic force of the permanent magnet 52. In this state, when the toilet seat or toilet lid is further opened, until the magnetic body portion 6 comes into contact with the lid member 23 of the main body case 2, the rotation angle of the toilet seat or toilet lid is, for example, up to 120 degrees. The magnet part 5 and the magnetic body part 6 move in the axial direction together.
[0014]
In this state, when the hand attached to lift the toilet seat or toilet lid is released, the toilet seat or toilet lid tends to fall forward due to its own weight, but the magnetic body portion 6 is the large diameter portion 22 of the main body case 2. It stops at the point of contact with the side step portion 22a, that is, in this case, the opening angle is 100 degrees. Thereby, a toilet seat or a toilet lid can be made independent at a desired angle.
[0015]
When closing the toilet seat or the toilet lid, an external force is applied to such an extent that the magnet portion 5 is separated from the magnetic body portion 6 in the closing direction. After that, the toilet seat or the toilet lid is closed by its own weight, and the rotating shaft 3 rotates in the opposite direction to that when the toilet shaft is opened, so that the magnet portion 5 extends along the axial direction of the main body case 2 in the main body case 2. When it moves in the direction approaching the small diameter portion 21 of the main body case 2 and the intermediate portion 32 of the rotating shaft 3 and completely closes, it returns to the normal position shown in FIG.
[0016]
If it is desired to change the holding force at the time of clicking (at the time of attracting the magnet part 5 and the magnetic body part 6) according to the control object, it is only necessary to use a permanent magnet 52 having a different magnetic force. The adjustment of the force is easy and the holding force is increased so that the assembly is not difficult.
[0017]
FIG. 3 shows a rotational motion support mechanism 1 according to another embodiment of the present invention. The rotational motion support mechanism 1 has a coil spring 7 that has one end 7 a fixed to the projecting portion 31 of the rotating shaft 3 and the other end 7 b fixed to the main body case 2 and that constitutes a damper portion. The coil spring 7 is set so as to be wound when the rotating shaft 3 rotates in one direction, for example, the closing direction of the object to be controlled, and to exert its resistance. Other structures are the same as those of the above-described embodiment.
[0018]
Therefore, according to the rotational motion support mechanism 1 of the present embodiment, when an external force of a predetermined level or more is applied in a direction in which the click due to the magnet portion 5 attracted to the magnetic body portion 6 is released, the control object is self-weighted. The control object is slowly closed by the resistance force of the coil spring 7.
[0019]
4 and 5 show a rotational motion support mechanism 1 according to still another embodiment of the present invention. In the present embodiment, as the main body case 2 ′, a main body case 2 ′ having a large diameter portion 22 ′, 23 ′ on both sides of a partition wall portion 21 ′ formed in a substantially central portion is used. In the space portion 24 ′ formed in 22 ′, a click mechanism portion 4 including a magnet portion 5 and a magnetic body portion 6 that are exactly the same as those described above is disposed. In the other large-diameter portion 23 ′, partition walls 23′a and 23′b whose tip surface abuts on the outer surface of the rotating shaft 3 ′ and partitions the inside in the circumferential direction are provided (see FIG. 5). ). And the part which has vane part 34 ', 35' protruding along the axial direction among rotating shaft 3 'is located in this other large diameter part 23', and the outer surface of this rotating shaft 3 'and this other The large diameter portion 23 'is filled with a viscous liquid. That is, in the other large-diameter portion 23 ′, a damper portion including a viscous liquid, partition walls 23′a and 23′b, and vane portions 34 ′ and 35 ′ is provided.
[0020]
As a result, when the rotary shaft 3 ′ rotates together with the object to be controlled, the vane portion 34′35 ′ presses the viscous liquid, and the partition walls 23′a, 23′b and the outer surface of the rotary shaft 3 ′ slightly change. The rotational movement of the rotary shaft 3 ′ becomes slow due to the dynamic pressure resistance exerted by passing through the gap. Therefore, also in the present embodiment, when an external force of a predetermined level or more is applied in the direction in which the click caused by the magnet unit 5 attracting the magnetic body unit 6 is released, the controlled object slowly closes or opens. .
[0021]
In addition, as a damper part using a viscous liquid, it is not limited to what was shown in FIG.4 and FIG.5. Further, an orifice (not shown) may be formed in the vane portions 34 ′ and 35 ′ so that the dynamic pressure resistance of the viscous liquid works only when the rotating shaft 3 ′ rotates in one direction. Further, without providing the vane portions 34 'and 35', the outer diameter of the rotating shaft 3 'is made slightly smaller than the inner diameter of the other large diameter portion 23', and the gap is filled with a viscous liquid such as grease. And it can also be set as the structure which delays operation | movement of rotating shaft 3 'using the viscous resistance. Furthermore, the damper part using viscous liquid and the coil spring 7 shown in FIG. 3 can also be used together.
[0022]
6 to 11 show a rotational motion support mechanism 10 according to still another embodiment of the present invention. The rotating motion support mechanism 10 is fixedly provided with a magnetic body portion 12 made of an annular iron plate in the middle so as to divide the inside of the bottomed cylindrical main body case 11 into two chambers in the axial direction. A cap member 11a is disposed in the opening.
[0023]
The rotary shaft 13 passes through the cap member 11 a and has one end 13 a protruding outward, and the other end side is accommodated in one chamber 11 c in the main body case 11 partitioned by the magnetic body portion 12. And as shown in FIG.8 and FIG.9, the 1st recessed part 13c and the 1st convex part 13d are formed in the end surface 13b located in this main body case 11. As shown in FIG. The first concave portion 13c is formed by forming the end surface 13b with a predetermined width along the diameter direction, and the first convex portion 13d that relatively protrudes by forming the first concave portion 13c is It corresponds to all parts other than the first recess 13c in the end face 13b. Further, the boundary portion 13e between the first concave portion 13c and the first convex portion 13d is formed in a tapered shape.
[0024]
As shown in FIGS. 10 and 11, the cam member 14 is formed in a disk shape, and has a second protrusion with a predetermined width along the diameter direction on one end surface 14 a facing the rotation shaft 13. 14b is formed. The width of the second convex portion 14b is set to be equal to or smaller than the width of the first concave portion 13c of the rotating shaft 13 described above. Moreover, in this one end surface 14a, the 2nd convex part 14b protrudes relatively, and the other part becomes concave (2nd recessed part 14c). Further, guide grooves 14d are formed at appropriate positions on the outer peripheral surface of the cam member 14, that is, at positions facing substantially 180 degrees in the present embodiment. As shown in FIG. 7, the guide groove 14 d engages with a guide protrusion 11 b that protrudes in the main body case 11 along the axial direction. Further, a projection 14e is projected at a substantially central portion of the other end surface 14f of the cam member 14, and the projection 14e can be inserted into the central hole portion 12a of the magnetic body portion 12.
[0025]
In the main body case 11, a magnet portion 15 that constitutes a click mechanism portion together with the magnetic body portion 12 is disposed in the other chamber 11 d separated by the magnetic body portion 12. The magnet unit 15 includes a disk-shaped permanent magnet 15a and a concave yoke 15b that holds the magnet. In addition, the axial length of the magnet portion 15 is shorter than the axial length of the other chamber 11d of the main body case 11. Thereby, the magnet part 15 can be moved in the axial direction in the other chamber 11 d of the main body case 11.
[0026]
According to the present embodiment, similarly to the above, the main body case 11 is fixed to, for example, the upper part of a toilet body of a Western-style toilet, and one end 13a of the rotary shaft 13 is connected to a toilet seat or toilet lid that is a control object. .
[0027]
In the state where the toilet seat or the toilet lid is closed, the first convex portion 13d of the rotating shaft 13 and the second convex portion 14b of the cam member 14 are set in contact with each other, and this is set as the normal position. In this normal position, the convex portions of the rotary shaft 13 and the cam member 14 are in contact with each other, and therefore the first concave portion 13c of the rotary shaft 13 and the second concave portion 14c of the cam member 14 are separated from each other. That is, the cam member 14 is positioned below the state shown in FIG. 6, and as a result, the projection 14 e of the cam member 14 presses the magnet portion 15 and is separated from the magnetic body portion 12. Therefore, in this state, the attractive force of the magnet unit 15 does not act.
[0028]
When the toilet seat or toilet lid is opened, the rotating shaft 13 rotates in one direction. The first convex portion 13d of the rotating shaft 13 is formed in a fan shape when viewed from the end face 13b side because the first concave portion 13c is only formed with a predetermined width along the diameter direction. Further, since the guide groove 14 d is engaged with the guide protrusion 11 b of the main body case 11, the cam member 14 does not rotate following the rotation shaft 13. Accordingly, the second convex portion 14b of the cam member 14 keeps in contact with the first convex portion 13d of the rotating shaft 13 within a predetermined angle range, and during that time, the position of the magnet portion 15 does not change, and the magnetic body portion 12 Maintaining a separated state.
[0029]
When the opening angle of the toilet seat or toilet lid reaches a predetermined angle, for example, 100 degrees, the position of the first concave portion 13c of the rotating shaft 13 and the position of the second convex portion 14b of the cam member 14 coincide. At this time, the cam member 14 is free to move along the axial direction toward the rotary shaft 13 as the second convex portion 14b enters the first concave portion 13c. At the same time, the magnet unit 15 is attracted to the magnetic body unit 12 and attracted to the magnetic body unit 12. And unless this magnetic force gives the external force which exceeds this magnetic force, rotation operation of the rotating shaft 13 becomes impossible, and a toilet seat or a toilet lid can be made independent at a desired angle.
[0030]
When closing the toilet seat or toilet lid, an external force greater than a predetermined value is applied in the closing direction. As a result, the second convex portion 14b of the cam member 14 is detached from the first concave portion 13c of the rotating shaft 13, and again comes into contact with the first convex portion 13d of the rotating shaft 13. Further, since the guide groove 14d is engaged with the guide protrusion 11b of the main body case 11, the cam member 14 moves downward along the axial direction in FIG. 6, and the protrusion 14e of the cam member 14 is moved to the magnet portion 15. To separate the magnet portion 15 from the magnetic body portion 12. If the magnet portion 15 is slightly separated from the magnetic body portion 12, the click force does not work, and thereafter, the magnet portion 15 is closed by the weight of the toilet seat or the toilet lid.
[0031]
When the cam member 14 is used as in the present embodiment, if the rotating shaft 13 is slightly rotated after the magnet portion 15 is attracted to the magnetic body portion 12, the attracting force of the magnet portion 15 is ensured. Can be canceled.
[0032]
Also in the case of the rotational motion support mechanism 10 of the present embodiment, as shown in FIG. 12, as in the embodiment shown in FIG. 3, one end 17a is the protruding portion of the rotating shaft 13, and the other end 17b is the main body. A structure in which a coil spring 17 that constitutes a damper portion and is fixed to the case 11 is also provided. The coil spring 17 is set so as to be wound when the rotating shaft 13 rotates in one direction of the control target, for example, in the closing direction, and to exert its resistance. Therefore, when an external force of a predetermined level or more is applied in a direction in which the magnet unit 15 moves away from the magnetic body unit 12, the controlled object closes due to its own weight, but the controlled object is slowly closed by the resistance force of the coil spring 17. It works.
[0033]
As shown in FIGS. 13 and 14, as in the embodiment of FIGS. 4 and 5, the main body case 11 ′ is separated by a partition wall 11′a (corresponding to the cap member 11a of FIG. 6). A partition having a space portion 11′b is used, and in this space portion 11′b, the front end surface is in contact with the outer surface of the extension portion 13 ′ connected to the rotating shaft 13, and the inside is partitioned in the circumferential direction. Partition walls 11′c and 11′d are provided. And the part which has vane part 13'a and 13'b which protruded along the axial direction among extension part 13 'of the rotating shaft 13 is located in this space part 11'b, and extension of the rotating shaft 13 is carried out. The outer surface of the portion 13 ′ and the inner surface of the space portion 11′b are filled with a viscous liquid. That is, in the space portion 11′b, a damper portion including a viscous liquid, partition walls 11′c and 11′d, and vane portions 13′a and 13′b is provided. Thereby, when extension part 13 'of rotating shaft 13 rotates with a controlled object, vane parts 13'a and 13'b press viscous liquid, and partition walls 11'c and 11'd and a rotating shaft The rotational movement of the rotary shaft 13 becomes slow due to the dynamic pressure resistance exerted by passing through a slight gap with the outer surface of the extension portion 13 ′ of 13. Therefore, also in the present embodiment, when an external force of a predetermined level or more is applied in the direction in which the click caused by the magnet unit 15 adsorbing to the magnetic body unit 12 is released, the controlled object slowly closes or opens. . It should be noted that the type of the damper portion is not limited to these, as in the embodiment shown in FIGS.
[0034]
【The invention's effect】
According to the rotational motion support mechanism of the present invention, since the attracting force of the magnet part is used as the click mechanism part, the click mechanism part is superior in durability compared with the conventional click mechanism part only by mechanical engagement, and the click mechanism part. The sound generated at the time can also be reduced. Further, when adjusting the holding force at the time of clicking, it is only necessary to change the permanent magnet constituting the magnet part to one having a different magnetic force, and the adjustment is easy. In addition, since only permanent magnets are exchanged, the adoption of one having a large holding force does not adversely affect the workability during assembly.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing an embodiment of a rotational motion support mechanism of the present invention.
FIG. 2 is a cross-sectional view taken along line AA in FIG.
FIG. 3 is a longitudinal sectional view showing another embodiment of the rotational motion support mechanism of the present invention.
FIG. 4 is a longitudinal sectional view showing still another embodiment of the rotational motion support mechanism of the present invention.
5 is a cross-sectional view taken along line BB in FIG.
FIG. 6 is a longitudinal sectional view showing still another embodiment of the rotational motion support mechanism of the present invention.
7 is a cross-sectional view taken along line CC in FIG.
FIG. 8 is an end view showing a rotating shaft used in the embodiment.
FIG. 9 is a side view showing a rotating shaft used in the embodiment.
FIG. 10 is an end view showing a cam member used in the embodiment.
FIG. 11 is a side view showing a cam member used in the embodiment.
FIG. 12 is a longitudinal sectional view showing still another embodiment of the rotational motion support mechanism of the present invention.
FIG. 13 is a longitudinal sectional view showing still another embodiment of the rotational motion support mechanism of the present invention.
14 is a sectional view taken along line DD of FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1,10 Rotation support mechanism 2,2 ', 11 Main body case 3,3', 13 Rotating shaft 4 Click mechanism part 5,15 Magnet part 6,12 Magnetic body part 7,17 Coil spring

Claims (5)

A cylindrical main body case, a rotation shaft to which at least a part is inserted and supported in the main body case, and a click shaft that stops rotation of the rotation shaft at a predetermined rotation angle. A rotational motion support mechanism that rotatably supports the control object,
The click mechanism is disposed in the main body case and is movable in the axial direction by rotation of the rotation shaft, and the normal position in the main body case is separated from the normal position of the magnet in the axial direction. And a magnetic body portion that is attracted when the rotation of the rotation shaft by a predetermined angle and the magnet portion moves by a predetermined distance in the axial direction,
The magnet portion includes a permanent magnet, and a yoke having a length along the axial direction longer than the length along the axial direction of the permanent magnet, and a yoke fixed to the permanent magnet ;
The outer diameter of a predetermined portion of the portion inserted into the main body case of the rotating shaft and the inner diameter of the inner surface of the main body case corresponding to the outer diameter are prepared so that a space portion can be formed between them. A screw part is formed in a predetermined part of the part inserted into the main body case, and the magnet part constituting the click mechanism part is made of a non-magnetic material that is screwed into the screw part of the rotating shaft. An engaged portion that has a nut, the permanent magnet is fixed to the outside of the nut, and the yoke engages with an engaging portion formed on the outer surface along the axial direction in the body case; A rotational motion support mechanism comprising: At least rotation support mechanism of claim 1, wherein is provided with a damper unit which lagged the rotation operation to one direction of the rotary shaft. The rotational motion support mechanism according to claim 2 , wherein the damper portion includes a spring having one end connected to the main body case and the other end connected to the rotation shaft. The rotation operation support mechanism according to claim 2 , wherein the damper portion is configured to include a viscous liquid filled between the main body case and the rotation shaft. The damper section, the one end the main body case, the spring other end of which is connected to the rotary shaft, and, according to claim 2 configured with both a viscous liquid which is filled between the shaft and the body case Rotational motion support mechanism.

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