JPH0653836U - Rotary oil damper - Google Patents

Abstract

(57) [Abstract] [Purpose] The present invention provides a rotary oil damper capable of providing different braking characteristics in forward and reverse directions. A housing 11, a first rotor 20 housed in the housing 11, and a driving shaft 25 fixed to the first rotor 20 at one end side and provided liquid-tightly through a wall of the housing 11. An elastic body 30 disposed in the housing 11, and an elastic body 30 rotatably disposed in the housing 11 around the axis of the first rotor 20. When the first rotor 20 rotates in one direction, the elastic body 30 is elastic. The first rotor 2 through the body 30
When the first rotor 20 rotates in the same direction as the first rotor 20 by receiving the rotational force from 0, and the first rotor 20 rotates in the other direction, the first rotor 20 directly receives the rotational force and receives the first rotation. Child 2
It includes a second rotor 40 that rotates in the same direction as 0 and oil contained in the housing 11.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a rotary oil damper that absorbs kinetic energy by utilizing the viscous resistance of oil.

[0002]

[Prior art]

 Conventionally, in the field of AV equipment, OA equipment, etc., a small damper is often incorporated in order to quietly operate an opening / closing door that is opened and closed by a spring force. As a damper used for such a purpose, a friction damper or a fluid viscosity damper is suitable in terms of size and manufacturing cost.

However, although the friction damper has a simple structure, it uses solid friction, so that stable damping force cannot be obtained for a long period of time due to deterioration of the friction plate or the like. Moreover, since there is a difference between the coefficient of static friction and the coefficient of dynamic friction, the damping force is not proportional to the speed, and smooth control and good feel cannot be obtained. On the other hand, the fluid viscosity damper utilizes the viscosity of oil or air and does not have the drawbacks described above. Therefore, the fluid viscosity damper is used in AV equipment, OA equipment and the like.

Fluid viscous dampers used in AV equipment and the like are roughly classified into a linear type and a rotary type, but recently, a rotary type is widely used from the viewpoint of installation space. Among these, a rotary oil damper using oil as a viscous fluid is usually a housing, a rotor rotatably accommodated in the housing, and a wall of the housing so that one end side is connected to the rotor. It is composed of a drive shaft that is rotatably and rotatably penetrated through and a oil such as silicone grease contained in the housing.

In such a rotary oil damper, the braking force applied to the rotor is set to an appropriate value in order to obtain smooth braking and a good feel. Generally, the desired braking characteristics are obtained by selecting the oil to be used, the contact area between the rotor and the oil, and the gap between the rotor and the housing.

[0006]

[Problems to be solved by the device]

 The conventional rotary oil damper configured as described above has a constant braking characteristic regardless of the rotation direction of the driving shaft. Therefore, for example, when the door is opened by borrowing the force of the spring, the braking force can be applied over the entire process from the fully closed state to the fully opened state when the door is opened. It can absorb the impact of force.

However, taking the case of closing the door as an example, in this case, since the door is operated by hand, the braking force is generated only to absorb the impact just before the door is fully closed. It is enough to use. However, even when the door is closed, the braking force acts over the entire process from the fully open state to the fully closed state, which causes a problem of discomfort when closing the door.

Therefore, the present invention has an object to provide a rotary oil damper that can make the braking characteristic pattern different depending on the rotation direction, thereby contributing to alleviation of the above-mentioned problems.

[0009]

[Means for Solving the Problems]

 To achieve the above object, a rotary oil damper according to the present invention comprises a housing, a first rotor housed in the housing, and a wall of the housing having one end fixed to the first rotor. A driving shaft provided in a liquid-tight manner through the housing, an elastic body arranged in the housing, and rotatably arranged around the axis of the first rotor in the housing. When the first rotor rotates in one direction, it receives a rotational force from the first rotor via the elastic body and rotates in the same direction as the first rotor, and the first rotor is rotated. A second rotor which rotates in the same direction as the first rotor when directly rotated by the first rotor when rotated in the other direction; and an oil contained in the housing. ing.

[0010]

[Action]

 Viscous resistance acts on the first rotor and the second rotor housed in the housing according to the rotation speed by the oil housed in the housing.

Here, when the driving shaft rotates so that the first rotor rotates in one direction, the rotational force of the first rotor is transmitted to the second rotating body via the elastic body. To be done. At this time, a static friction force acts on the second rotor with the housing. Therefore, the elastic body is compressed to a predetermined length by the rotational force of the first rotor, and when the restoring force exceeds the above static friction force, the second rotor moves in the same direction as the first rotor. To start rotating.

Therefore, only the braking force due to the viscous resistance acting on the first rotor acts on the drive shaft up to a predetermined angle, and the braking force of the first rotor and the second rotor starts from the predetermined angle. The braking force due to the viscous resistance of the oil acting on both acts.

On the other hand, when the drive shaft rotates so that the first rotor rotates in the other direction, the rotational force of the first rotor is directly transmitted to the second rotor. Therefore, a constant braking force from the start of rotation to the end of rotation, that is, the braking force due to the viscous resistance of the oil acting on the first rotor and the second rotor acts on the drive shaft.

As described above, when the drive shaft rotates in one direction, the braking force that acts on the drive shaft is small from the start of rotation to a predetermined angle and becomes large thereafter. Also, when the drive shaft rotates in the other direction, the braking force that acts on the drive shaft has a large constant value from the start of rotation to the end of rotation, and eventually it is possible to obtain different braking pattern characteristics depending on the rotation direction. Become.

[0015]

EXAMPLES Examples will be described below with reference to the drawings.

FIG. 1 is a top view of a rotary oil damper according to an embodiment of the present invention with a gear and a lid removed. FIG. 2 shows a sectional view of the rotary oil damper taken along line X-X in FIG. 1 and viewed in the direction of the arrow. Further, FIG. 3 shows an exploded perspective view of the rotary oil damper.

In these figures, 11 indicates a housing made of plastic or the like. The housing 11 includes a case 12 having a cylindrical shape with a bottom, a disk-shaped lid 13 fitted and adhered to the case 12 so as to close an opening of the case 12, and integrally provided outside the case 12. And a mounting portion 14 that extends toward one side and is used for mounting on a device to be used.

A bearing projection 15 is provided on the inner surface of the bottom wall of the case 12 and at the center of the case 12. Further, at a position on the inner surface of the bottom wall that is separated from the center of the case 12 by a predetermined amount, the coil spring 30 to be described later is held and the rotatable range of the first rotor 20 and the second rotor 40 is regulated by 90 degrees An arcuate stopper 16 is provided so as to project.

The lid 13 is formed to have a thickness that allows the open end of the case 12 to be liquid-tightly closed under the condition that the outer peripheral edge of the lid 13 is fitted into the case 12, and has a hole in the center. 13a is provided.

Inside the case 12, a first rotor 20 made of plastic or the like is arranged with a slight gap between the inner surface of the case 12 and the inner surface of the lid 13. The first rotor 20 has a concave portion 21 formed so as to be fitted to the protrusion 15, a rotation support portion 22 rotatably mounted by being supported by a bearing by this fitting, and this rotation support. The sliding portion 24 is connected to the portion 22 via a fan-shaped portion 23 and is formed so as to extend in an arc shape of approximately 180 degrees with a slight gap between the portion 22 and the inner surface of the case 12. . A driving shaft 25 is coaxially integrally formed with the rotation support portion 22. The driving shaft 25 is liquid-tightly penetrated through a hole 13a provided in the lid 13 and guided to the outside. A gear 26 is fixed to the outer periphery of the portion of the driving shaft 25 protruding outside by means such as press fitting.

A coil spring 30 is arranged between the outer peripheral surface of the stopper 16 and the inner peripheral surface of the case 12, one end of which is in contact with the tip of the sliding portion 24 of the first rotor 20, The other end is in contact with one end face in the circumferential direction of the second rotor 40 described later.

The second rotor 40 is formed of plastic or the like in a 90-degree arc shape. The outer peripheral surface of the second rotor 40 is slidable with a slight gap provided on the inner peripheral surface of the case 12, and the inner peripheral surface is slightly different from the outer peripheral surface of the rotation support portion 22 of the first rotor 20. It is possible to slide with a gap. That is, the second rotor 40 is mounted so as to be slidably rotatable around the axis of the first rotor 20. The other end face of the second rotor 40 in the circumferential direction is in contact with the end face 23a of the portion 23 described above.

Further, oil such as silicone grease is enclosed in a so-called room surrounded by the case 12 and the lid 13.

With such a configuration, when the rotational force for manually closing the door (not shown) is transmitted to the driving shaft 25 via the gear 26, the first rotor 20 is shown in FIG. The rotation starts in the direction of arrow A in the figure from that position. The tip of the sliding portion 24 of the first rotor 20 compresses the coil spring 30. When the coil spring 30 further rotates and reaches a predetermined position, the restoring force of the coil spring 30 exceeds the static friction force of the second rotor 40, the second rotor 40 starts rotating, and the viscous resistance of the enclosed oil limits the force. Receive power. Then, when the end face of the portion 23b of the first rotor 20 contacts the stopper 16, the rotation of the first rotor 20 and the second rotor 40 stops. At this time, the open / close door is fully closed.

On the other hand, when the opening / closing door is opened, when the rotational force given by the spring force or the like is transmitted to the driving shaft 25 via the gear 26, the first rotor 20 rotates in the direction of arrow B in the figure. To start. Since the end surface 23a of the portion 23 of the first rotor 20 is in contact with the end surface of the second rotor 40, the second rotor 40 also starts rotating. Then, when the end surface of the second rotor 40 contacts the stopper 16, the rotation of the first rotor 20 and the second rotor 40 is stopped. At this time, the open / close door is fully opened.

Therefore, in the rotary oil damper according to the present embodiment, the feeling when rotating in one direction, that is, when the opening / closing door is closed by hand is light to the extent that almost no braking force is felt at first. It closes, but becomes heavy just before it closes completely. Also, when rotating in the other direction, that is, when the opening / closing door is opened, it opens smoothly and quietly from the fully closed state to the fully opened state as in the conventional case.

Further, by changing the sizes and shapes of the stopper 16, the first rotor 20, and the second rotor 40 and the spring constant of the coil spring 30 to appropriate ones, a rotary oil damper having arbitrary braking characteristics. Is obtained.

The present invention is not limited to the above embodiment. That is, although the coil spring is used as the elastic body in the above-described embodiments, other spring members or rubber may be used. Although silicone grease is used as the enclosed oil, the oil is not limited to this.

Further, the above-described embodiment is an application of the present invention to a rotary oil damper for braking the opening / closing door of AV equipment and OA equipment. It can also be applied to rotary oil dampers for damping and damping shocks and vibrations of general machinery and structures.

Further, it is needless to say that the present invention can be variously modified and implemented without departing from the gist of the present invention.

[0031]

[Effect of device]

 As described in detail above, according to the present invention, in one direction of rotation, the braking force from the start of rotation to a predetermined angle can be made small, and the braking force from the predetermined angle to the end of rotation can be made large, and In the case of rotation in the other direction, it is possible to provide a rotary oil damper that can keep the braking force constant from the start of rotation to the end of rotation.

[Brief description of drawings]

FIG. 1 is a top view of a rotary oil damper according to an embodiment of the present invention with a gear and a lid removed.

FIG. 2 is a cross-sectional view of the rotary oil damper taken along line XX in FIG. 1 and viewed in the direction of the arrow.

FIG. 3 is an exploded perspective view of the rotary oil damper.

[Explanation of symbols]

 11 ... Housing 12 ... Case 16 ... Stopper 20 ... 1st rotor 22 ... Rotation support part 24 ... Sliding part 25 ... Driving shaft 30 ... Coil spring 40 ... 2nd rotor

Claims (1)

[Scope of utility model registration request] 1. A housing, a first rotor housed in the housing, and a drive shaft which is fixed to the first rotor at one end side and is provided to penetrate the wall of the housing in a liquid-tight manner. An elastic body arranged in the housing, and rotatably arranged in the housing around an axis of the first rotor, and the elastic body when the first rotor rotates in one direction. Receives a rotational force from the first rotor via the rotor and rotates in the same direction as the first rotor, and directly rotates from the first rotor when the first rotor rotates in the other direction. A rotary oil damper comprising: a second rotor which receives a force and rotates in the same direction as the first rotor; and an oil contained in the housing.