JP2022034203A - Damper - Google Patents

Abstract

To provide a novel damper capable of mechanically restricting the rotation speed of a rotary body without using the viscous resistance of fluid.SOLUTION: A rotary body 4, on the outer peripheral face of which a spring member 6 wound as required is formed, is molded with a synthetic resin material having such characteristics that frictional force between the spring member 6 and itself is increased with an increase in the rotation speed with respect to the spring member 6. The spring member 6 is provided with positive wound parts each having a wire wound one to three turns in a positive direction and reverse wound parts each having the wire wound one to three turns in the reverse direction, and the positive wound parts and the reverse wound parts are arranged alternately in the axial direction. To both ends in the axial direction of the positive wound parts and the reverse wound parts, extension parts are attached where the wires extend in the tangential direction, respectively. The front ends of the two extension parts adjacent to each other in the axial direction are connected via a bridge part 24 where the wires extend in the axial direction.SELECTED DRAWING: Figure 1

Description

The present invention relates to a damper that suppresses an increase in the rotational speed of a rotating body by a spring member mounted on the outer peripheral surface of the rotating body.

Some blinds arranged in a room or the like are of a type in which a plurality of slats extending in the horizontal direction are arranged in the vertical direction and can be moved in the vertical direction. In such a type of blind, multiple slats are connected via an elevating cord that extends vertically, and one end of the elevating cord is attached to a bottom rail that extends horizontally in parallel with the slats, and the other end. Are each connected to the output rotating member of the take-up mechanism in the headbox. An operation code is connected to the input rotating member of the take-up mechanism, and by operating the operation code to rotate the input rotating member in the forward and reverse directions, the bottom rail connected to the output rotating member via the elevating cord is It moves up and down, which allows multiple slats to move up and down. The take-up mechanism is usually provided with a stopper (sometimes called a cord lock) that holds the operation code, and the operation code is forced to one side (usually outside) in the left-right direction. It is held at any position, and the bottom rail can be fixed at any height position (vertical position). The holding is released by forcing the operation code to the other side in the left-right direction while the operation code is held by the stopper.

As described above, since the input rotating member and the output rotating member rotate in conjunction with each other, for example, in a state where the operation code is pulled and the bottom rail is raised, if the operation code is not held by the stopper, the operation code is manually operated. When released, the bottom rail will fall freely and collide with the floor or the elevating cord will be pulled out to the maximum and an impact will be applied to the take-up mechanism. This is also the case when the holding of the operation code by the stopper is released and the holding is released so that the bottom rail freely falls. In order to prevent such a free fall of the bottom rail, a damper may be provided in the winding mechanism to limit the descent speed of the bottom rail.

As the damper, a rotary damper including a housing in which a relatively highly viscous fluid such as silicone oil is sealed inside and a rotating member rotatably mounted on the housing is put into practical use. In this rotary damper, the rotational speed of the input rotating member or the output rotating member is limited by applying a torque opposite to the rotation of the rotating member to the rotating member due to the viscous resistance of the fluid. The following Patent Document 1 discloses an example of the rotary damper described above.

By the way, there is a torque limiter as a mechanical component that connects and disconnects rotation between two different members. The following Patent Document 2 discloses a torque limiter that has been filed and already patented by the applicant of the present application prior to the present application. This torque limiter is mounted by contacting a shaft-shaped inner ring member having a mounting portion having a circular cross section and the outer peripheral surface of the mounting portion of the inner ring member, and is formed by winding a single wire rod many times in the same direction. It includes a spring member to be formed and a tubular outer ring member into which a rotating body to which the spring member is mounted is inserted. The spring member is provided with two hooks formed by bending a part of the wire rod when viewed in the axial direction, and when these hooks engage with the outer ring member, the spring member cannot rotate with respect to the outer ring member. It has become. From this, when the inner ring member and the outer ring member rotate relative to each other, the hook is pushed by the outer ring member in the direction in which the spring member is loosened, and the rotational torque applied between the inner ring member and the outer ring member is equal to or less than a predetermined value. The inner ring member rotates integrally with the outer ring member, but when the rotational torque is larger than a predetermined value, the inner ring member rotates with respect to the outer ring member. On the other hand, Patent Document 3 further discloses that the inner ring member is molded of PPS resin in a torque limiter using a spring member. Although not always clearly shown in Patent Document 3, when the inner ring member is formed of PPS resin, the frictional force between the inner ring members increases as the rotational speed of the inner ring member with respect to the spring member increases.

Japanese Unexamined Patent Publication No. 7-12166 Japanese Patent No. 3344905 Japanese Patent No. 5972483

Therefore, in the rotary damper disclosed in Patent Document 1, the fluid enclosed in the housing may leak to the outside. In addition, since the viscous resistance of a fluid generally changes depending on the temperature, the torque applied by the rotary damper in the opposite direction changes between the summer when the temperature is high and the winter when the temperature is low, and the input is limited by this. The rotation speed of the member or the output member is also different.

In the torque limiter disclosed in Patent Document 3, the inner ring member is formed of a synthetic resin material (PPS resin) having a property that the frictional force with the spring member increases as the rotation speed with respect to the spring member increases. Therefore, since the increase in the rotation speed of the inner ring member with respect to the spring member is effectively suppressed, it seems that if the outer ring member is fixed, the rotation of the inner ring member is suppressed to a necessary degree by the tightening force of the spring member. .. However, the torque limiter disclosed in Patent Document 3 (and 2) cannot be used as a damper because the wire rod of the spring member is continuously wound many times in the same direction. This is due to the following reasons. According to the experience of the present inventors, the mechanism is not necessarily elucidated, but when the wire rod of the spring member is continuously wound many times in the same direction, the inner ring member rotates with respect to the spring member. It was found that the change in the frictional force between the inner ring member and the spring member with respect to the rotation speed of the inner ring member becomes small, and the above change becomes sufficiently small when the number of windings of the wire rod of the spring member is 4 or more. ing. In order to use the torque limiter disclosed in Patent Documents 2 and 3 as a damper, it is desirable that the frictional force between the two increases as the rotational speed of the inner ring member with respect to the spring member increases (characteristic), but Patent Document 2 In the torque limiter disclosed in (1) and (3), the wire rod of the spring member is continuously wound many times in the same direction, which hinders the above characteristics.

Further, in the torque limiter disclosed in Patent Documents 2 and 3, it is conceivable to arrange a plurality of spring members in which the wire rod is wound 1 to 3 times in series in the axial direction. Problems arise. That is, when the inner ring member rotates, all the spring members act in the loosening direction at the same time, so that (1) the spring member falls in the axial direction and the inner ring member cannot obtain a stable frictional force, and (2) the spring. If the member is coated with a lubricant, the lubricant may move axially on the outer peripheral surface of the inner ring member and separate from the spring member, resulting in seizure between the inner ring member and the spring member. There is.

The present invention has been made in view of the above facts, and its main technical problem is to improve a known torque limiter using a spring member and mechanically rotate a rotating body without utilizing the viscous resistance of a fluid. It is to provide a new damper that can limit the speed.

As a result of diligent studies, the present inventor has found that a spring member whose winding direction is reversed every time the wire is wound 1 to 3 times can be incorporated into the above-mentioned known torque limiter to function as a damper. I found it.

That is, according to the present invention, as a damper capable of solving the above-mentioned main technical problem, a shaft-shaped rotating body having a mounting portion having a circular cross section and the outer peripheral surface of the mounting portion of the rotating body are in contact with each other. It is equipped with a spring member that is mounted and formed by winding a single wire as required.
The spring member is provided with two hooks formed by bending a part of the wire rod when viewed in the axial direction, and when the hook engages with the fixing member, the spring member is attached to the fixing member. On the other hand, it cannot rotate,
When the rotating body rotates, the hook is pushed by the fixing member in a direction in which the tightening of the spring member is loosened, and the rotating body rotates with respect to the spring member.
The rotating body is a damper formed of a synthetic resin material having a property that the frictional force with the spring member increases as the rotation speed with respect to the spring member increases.
The spring member includes a forward winding portion in which the wire is wound 1 to 3 times in the forward direction and a reverse winding portion in which the wire is wound 1 to 3 times in the reverse direction. The reverse winding portion and the reverse winding portion are alternately arranged in the axial direction, and the wire rod extends linearly at both ends of the normal winding portion and the reverse winding portion in the axial direction, respectively, as a part of the hook. A damper is provided characterized in that an extension is provided and the tips of two axially adjacent extensions are connected by a bridge in which the wire extends axially.

Preferably, the number of turns of the wire rod in the forward winding portion and the reverse winding portion of the spring member is 1. It is preferable that the mounting portion of the rotating body has a cylindrical shape, and the inner diameters of the forward winding portion and the reverse winding portion of the spring member are the same. The fixing member is preferably a cylindrical housing into which the rotating body to which the spring member is mounted is inserted. The synthetic resin material is preferably PPS or PA. Preferably, carbon filler or carbon black is added to the synthetic resin material. It is preferable that the spring member is coated with a lubricant.

In a damper configured in accordance with the present invention, the spring member comprises a forward and reverse winding portion in which the wire is wound one to three times in each of the forward and reverse directions, and thus the spring. The number of windings of the wire rod in each winding portion of the member is sufficiently small, and therefore, when the rotating body rotates with respect to the spring member, the frictional force with the spring member increases as the rotation speed of the rotating body increases. The characteristics of the spring are not impaired. Further, the forward winding part and the reverse winding part are arranged alternately in the axial direction, respectively, and the wire rod is linear at both ends of the forward winding part and the reverse winding part in the axial direction, respectively, as a part of the hook. An extending extension portion is attached, and the tips of the two extending portions adjacent to each other in the axial direction are connected by a bridge portion in which the wire rod extends in the axial direction. As a result, when the rotating body rotates with respect to the spring member and the hook is pushed by the fixing member, the vector component of the axial force applied to the forward winding portion and the reverse winding portion is canceled out, and the spring member. Is prevented from falling in the axial direction. Therefore, the rotating body can stably obtain a frictional force from the spring member. Further, when the lubricant is applied to the spring member, the lubricant moves axially on the outer peripheral surface of the rotating body and separates from the spring member, causing seizure between the rotating body and the spring member. It is prevented from being lost. Thus, a damper is provided that can mechanically limit the rotational speed of a rotating body without utilizing the viscous resistance of the fluid.

The figure which shows the whole structure of the damper configured according to this invention. An exploded perspective view of the damper shown in FIG. The figure which shows the rotating body of the damper shown in FIG. 1 by itself. The figure which shows the spring member of the damper shown in FIG. 1 by itself. The figure which shows the housing of the damper shown in FIG. 1 by itself.

Hereinafter, description will be made in more detail with reference to the accompanying drawings illustrating preferred embodiments of dampers configured in accordance with the present invention. Unless otherwise specified, "one side in the axial direction" and "the other side in the axial direction" in the following description are referred to in the same figure as "one side in the axial direction" with reference to the state shown in the AA cross section of FIG. The right side, "the other side in the axial direction" means the left side in the figure.

Explaining with reference to FIGS. 1 and 2, the damper, which is entirely configured according to the present invention and is indicated by the number 2, includes a rotating body 4 and a spring member 6. For easy understanding, in the cross section AA of FIG. 1, the cross section of the spring member 6 is shown in light ink.

Explaining with reference to FIG. 3 together with FIGS. 1 and 2, the rotating body 4 is a hollow shaft-shaped member formed by compression molding or injection molding of a synthetic resin material having predetermined characteristics described later and rotates. It has an axis o. A mounting portion 8 having a circular cross section is provided at an axial intermediate portion of the rotating body 4. The mounting portion 8 has a cylindrical shape extending in the axial direction along the axis of rotation o, and has a constant outer diameter and inner diameter in the axial direction. At one end of the mounting portion 8 in the axial direction, the inner diameter is the same as that of the mounting portion 8, but the outer diameter is gradually reduced from that of the mounting portion 8 toward one side in the axial direction. Is connected. A cylindrical other end 12 having the same inner diameter as that of the mounting 8 but having a slightly smaller outer diameter than that of the mounting 8 is connected to the other end in the axial direction of the mounting portion 8. Has been done. A pair of rectangular notches 14 open toward the other side in the axial direction are formed on the other end portion 12 so as to face each other in the radial direction. The rotating body 4 is connected to, for example, an input rotating member or an output rotating member of a blind winding mechanism via a pair of notches 14.

As shown in FIG. 1, the spring member 6 is mounted in contact with the outer peripheral surface of the mounting portion 8 of the rotating body 4. Explaining with reference to FIGS. 2 and 4 together with FIG. 1, the spring member 6 is formed by winding a single metal wire rod as required. That is, the spring member 6 includes a forward winding portion 16 in which the wire rod is wound 1 to 3 times in the forward direction and a reverse winding portion 18 in which the wire rod is wound 1 to 3 times in the reverse direction. The winding portion 16 and the reverse winding portion 18 are arranged alternately in the axial direction, respectively. In the illustrated embodiment, from one side in the axial direction to the other side, a wire rod having a circular cross section is clockwise in the forward winding portion 16 and counterclockwise in the reverse winding portion 18, respectively. It is wound one by one, and two forward winding portions 16 and one reverse winding portion 18 are provided. The inner diameters of the forward winding portion 16 and the reverse winding portion 18 are the same. The spring member 6 is provided with two hooks 20 formed by bending a part of the wire rod when viewed in the axial direction. Explaining the hook 20, all the winding portions (normal winding portion 16 and reverse winding portion 18) have the same circumferential position at the axial end (this position is indicated by X), and the normal winding portion 16 At both ends of the reverse winding portion 18 in the axial direction, extension portions 22 are attached to each of the above-mentioned wire rods so as to extend linearly in the tangential direction. From this, when the spring member 6 is viewed in the axial direction, the extending portion 22 is classified into one extending from the position X to one side in the tangential direction and one extending to the other side in the tangential direction, and the extending portion 22 belonging to the former is 2. One of the two hooks 20 (indicated by 20a) is configured, and the extension 22 belonging to the latter constitutes the other of the two hooks 20 (indicated by 20b). The two extending portions 22 adjacent to each other in the axial direction are connected by a bridge portion 24 in which the wire rod extends in the axial direction. The above-mentioned spring member 6 is coated with a linear or linear and side chain fluorine oil-based lubricant such as grease.

When the hooks 20a and 20b engage with the fixing member, the spring member 6 cannot rotate with respect to the fixing member. In the illustrated embodiment, the fixing member is a cylindrical housing 26 into which the rotating body 4 to which the spring member 6 is mounted is inserted. Explaining with reference to FIG. 5 together with FIGS. 1 and 2, the outer peripheral shape of the cross section of the housing 26 is circular and extends linearly in the axial direction, and has a central axis concentric with the rotation axis o. The inner space 28 of the housing 26 is provided with an intermediate portion 30 in which the spring member 6 mounted on the outer peripheral surface of the mounting portion 8 of the rotating body 4 is located. The intermediate portion 30 is divided into a main portion 32 in which a part of the cylindrical shape concentric with the rotation axis o is cut out in the axial direction, and a substantially D-shaped expansion portion 34 connected to the main portion 32 (FIG. 5). (Refer to the BB cross section), the forward winding portion 16 and the reverse winding portion 18 of the spring member 6 are arranged in the main portion 32, and the hook 20 is arranged in the extended portion 34, respectively. An engaging portion 36a and an engaging portion 36b with which the hook 20a and the hook 20b of the spring member 6 are engaged with each other are formed at a required portion of the inner peripheral surface of the housing 26 that defines the expansion portion 34. .. On one side in the axial direction of the intermediate portion 30, a cylindrical one-sided portion 38 into which the one-sided end portion 10 of the rotating body 4 enters is provided. The diameter of the one-sided portion 38 is slightly larger than the outer diameter of the base end of the one-sided end portion 10 of the rotating body 4, and the one-sided end portion 10 of the rotating body 4 is the inner circumference of the housing 26 defining the one-sided portion 38 of the inner space 28. Rotatably supported by a surface. An annular shape restricting piece 40 protruding inward in the radial direction is formed on the inner peripheral surface of one end portion in the axial direction of the housing 26, and the restricting piece 40 supports one side end in the axial direction of the rotating body 4. A cylindrical other side portion 42 is provided on the other side in the axial direction of the intermediate portion 30. The diameter of the other side portion 42 is larger than the diameter of the main portion 32 of the intermediate portion 30, and a disk-shaped shield plate 46 is press-fitted into the other side portion 42 (see FIGS. 1 and 2). The shield plate 46 is made of synthetic resin, and a shaft hole 48 is formed in the center of which the other side end portion 12 of the rotating body 4 is inserted to rotatably support the shield plate 46. The outer peripheral surface of the shield plate 46 bulges outward in the radial direction, and this is fitted into the annular groove 50 (see FIG. 2) formed at the other end in the axial direction of the inner peripheral surface of the housing 26. Then, the shield plate 46 is attached to the housing 26. A pair of projecting pieces 52 projecting to one side in the axial direction is provided on one end surface of the housing 26 in the axial direction, and the housing 26 is fixed to a wall (not shown) by the pair of projecting pieces 52.

Subsequently, the operation of the damper configured according to the present invention will be described with reference to FIG.
In the damper 2 shown in FIG. 1, the housing 26 is fixed to a wall (not shown) as described above. Further, the spring member 6 cannot rotate with respect to the housing 26 because the hooks 20a and 20b engage with the engaging portions 36a and 36b of the housing 26, respectively. From this, when the rotating body 4 rotates, either the hooks 20a and 20b are pushed by either of the engaging portions 36a and 36b of the housing 26 in the direction in which the tightening of the spring member 6 is loosened according to the rotation direction. The rotating body 4 rotates with respect to the housing 26 and the spring member 6. More specifically, when the rotating body 4 is rotated clockwise (viewed from the left side of the AA cross section of FIG. 1), the hook 20a is rotated by the engaging portion 36a, and when the rotating body 4 is rotated counterclockwise, the hook 20b is rotated. Pushed by the engaging portions 36b, the rotating body 4 slides with respect to the spring member 6.

Here, the rotating body 4 is formed of a synthetic resin material having a property that the frictional force with the spring member 6 increases as the rotation speed with respect to the spring member 6 increases. Therefore, for example, when the rotating body 4 is connected to the input rotating member or the output rotating member of the blind winding mechanism and the bottom rail freely falls, the falling speed will increase as the bottom rail freely falls. Even so, when the speed of the rotating body 4 increases, the frictional force received from the spring member 6 increases by that amount, so that the increase in the rotating speed of the rotating body 4 is suppressed, and thus the bottom rail is prevented from dropping suddenly. Examples of the synthetic resin material having the above characteristics include PPS (polyphenylene sulfide) and PA (polyamide), and carbon filler or carbon is used in these synthetic resin materials from the viewpoint of improving the wear resistance of the rotating body 4. It is preferable to add black.

At this time, in the damper configured according to the present invention, the spring member 6 has a forward winding portion 16 and a reverse winding portion 18 in which the wire rod is wound 1 to 3 times in each of the forward direction and the reverse direction. Therefore, the number of windings of the wire rod in each winding portion of the spring member 6 is sufficiently small, and therefore, as the rotating body 4 rotates with respect to the spring member 6, the rotational speed of the rotating body 4 increases. The property of increasing the frictional force with the spring member 6 is not impaired. Further, the forward winding portion 16 and the reverse winding portion 18 are arranged alternately in the axial direction, respectively, and both ends of the normal winding portion 16 and the reverse winding portion 18 in the axial direction are part of the hook 20 respectively. An extension portion 22 in which the wire rod extends linearly is attached, and the tips of the two extension portions 22 adjacent to each other in the axial direction are connected by a bridge portion 24 in which the wire rod extends in the axial direction. As a result, when the rotating body 4 rotates with respect to the spring member 6 and the hook 20 is pushed by the fixing member (housing 26), an axial force applied to the forward winding portion 16 and the reverse winding portion 18 is applied. The vector component of is canceled out, and the spring member 6 is prevented from tilting in the axial direction. Therefore, the rotating body 4 can stably obtain a frictional force from the spring member 6. Further, when the lubricant is applied to the spring member 6, the lubricant moves axially on the outer peripheral surface of the rotating body 4 and separates from the spring member 6, and the rotating body 4 and the spring member 6 are separated from each other. It is prevented that seizure occurs between them. Thus, a damper is provided that can mechanically limit the rotational speed of a rotating body without utilizing the viscous resistance of the fluid.

Although the damper configured according to the present invention has been described in detail with reference to the attached drawings, the present invention is not limited to the above-described embodiment, and appropriate modifications and modifications are made without departing from the present invention. Is possible. For example, in the illustrated embodiment, the extending portion of the spring member has the wire rod extending in the tangential direction of the normal winding portion and the reverse winding portion, but the wire rod may extend in the normal direction. Further, in the illustrated embodiment, the fixing member is a cylindrical housing, but since the fixing member only needs to regulate the rotation of the spring member, the fixing member is, for example, a shaft extending in the axial direction, and this shaft is used. May engage with the hook of the spring member.

2: Damper 4: Rotating body 6: Spring member 16: Forward winding part 18: Reverse winding part 20 (20a and 20b): Hook 22: Extension part 24: Bridge part 26: Housing (fixing member)

Claims (7)

A shaft-shaped rotating body having a mounting portion having a circular cross section and a spring member that is mounted in contact with the outer peripheral surface of the mounting portion of the rotating body and is formed by winding a single wire rod as required. Equipped with
The spring member is provided with two hooks formed by bending a part of the wire rod when viewed in the axial direction, and when the hook engages with the fixing member, the spring member is attached to the fixing member. On the other hand, it cannot rotate,
When the rotating body rotates, the hook is pushed by the fixing member in a direction in which the tightening of the spring member is loosened, and the rotating body rotates with respect to the spring member.
The rotating body is a damper formed of a synthetic resin material having a property that the frictional force with the spring member increases as the rotation speed with respect to the spring member increases.
The spring member includes a forward winding portion in which the wire is wound 1 to 3 times in the forward direction and a reverse winding portion in which the wire is wound 1 to 3 times in the reverse direction. The reverse winding portion and the reverse winding portion are alternately arranged in the axial direction, and the wire rod extends linearly at both ends of the normal winding portion and the reverse winding portion in the axial direction, respectively, as a part of the hook. A damper to which an extension portion is attached, and the tips of the two extension portions adjacent to each other in the axial direction are connected by a bridge portion in which the wire rod extends in the axial direction. The damper according to claim 1, wherein the number of times of winding the wire rod in the forward winding portion and the reverse winding portion of the spring member is 1. The damper according to claim 1 or 2, wherein the mounting portion of the rotating body has a cylindrical shape, and the inner diameters of the forward winding portion and the reverse winding portion of the spring member are the same. The damper according to any one of claims 1 to 3, wherein the fixing member is a cylindrical housing into which the rotating body to which the spring member is mounted is inserted. The damper according to any one of claims 1 to 4, wherein the synthetic resin material is PPS or PA. The damper according to claim 5, wherein carbon filler or carbon black is added to the synthetic resin material. The damper according to any one of claims 1 to 6, wherein the spring member is coated with a lubricant.

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