KR20190007994A - apparatus for rotating damper - Google Patents

Abstract

According to the present invention, provided is a rotary damper device comprising: a shaft part having a rotary shaft support part connected to the rotary shaft of a hinge connection part between a rotation support body and the rotation support body on which a rotation target body is supported; a housing part coupled to a rotary base part such that the shaft part is rotatably supported and has a friction base surface spaced apart from the outer surface of the rotary base part along an inner surface part; and an elastic rubber friction part coupled to the rotary base part and rubbing against the friction base surface to provide a damping force during rotation of the shaft part, and rotational energy is absorbed such that an impact is relieved at the hinge connection part which is a central axis of a rotation motion, thereby improving productivity.

Description

[0001] Apparatus for rotating damper [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotary damper device, and more particularly, to a rotary damper device that absorbs rotational energy to mitigate an impact at a hinge connection part serving as a central axis of rotary motion, and productivity is improved.

Generally, the door device of the hinged type comprises a door body and a door frame to which the door body is fixed. At this time, the door body is opened and closed by an artificial force, and includes a hinge connection part for smoothly opening and closing the door body.

On the other hand, when a door of a refrigerator, a door of a high-rise apartment or an office is suddenly opened or closed, a severe shock is applied to the door body and the door frame. Especially, since the atmospheric circulation of the high-rise building is blocked, the door body that is opened due to the air pressure difference is strongly closed, and the window that was opened by the external wind pressure is quickly closed.

In this way, the closing of the sudden and strong door device not only generates quiet noise, but also the door body and the door frame are broken, and if the user's hands are caught by the door frame, serious injury may occur. Accordingly, a damper device for cushioning shocks has been used so as to prevent various safety accidents and product damage.

Of course, such a damper device is applicable not only to the hinge connection portion of the door device but also to various hinge connection portions such as folding chairs and furniture.

At this time, the damper device is known as a friction damper using sliding friction, a fluid damper using fluid, a viscous damper using viscous body, and a lead damper using lead.

However, the frictional dampers are accompanied by abrasion due to abrasion, and the damping performance of the fluid dampers and the viscous dampers has been greatly reduced for a long period of use. The fluid dampers and the viscous dampers are required to be large in order to achieve high buffering performance, and an additional sealing structure There is a problem that the structure is complicated.

In addition, the lead damper has a problem in that it is difficult to reduce the weight due to weight due to lead, and there is a risk of leakage of lead which is a toxic substance.

Korean Registration Practice No. 20-0354593

In order to solve the above-mentioned problems, the present invention provides a rotary damper device in which rotational energy is absorbed so as to mitigate an impact at a hinge connection part serving as a central axis of rotary motion, and productivity is improved.

According to an aspect of the present invention, there is provided a hinge apparatus comprising: a shaft having a rotary shaft support portion connected to a rotary shaft of a hinge connection portion between a rotary support body and a rotary support body, the rotary support body having a rotary base at one end; A housing part which is coupled to the rotation base part so that the shaft part is rotatably supported and has a friction base surface spaced apart from the outer surface of the rotation base part along the inner surface part; And a rubber elastic friction portion coupled to the rotation base portion and rubbing against the friction base surface to provide damping force during rotation of the shaft portion.

The elastic frictional portion includes a ring-shaped engagement portion having a circular cross section and coupled to the rotation base portion. The elastic friction portion is protruded radially outward from the outer peripheral surface of the ring engagement portion so as to be pressed onto the friction base surface, And a plurality of friction protrusions formed to be spaced apart from each other in a rotating direction of the shaft portion to reduce and slide along the base surface.

Preferably, the friction protrusions are inclined radially outwardly in one direction so that the damping force is increased in one direction of rotation of the shaft but decreased in damping force in the other direction of rotation.

At this time, the one end of the friction protrusion is formed with a long width stepped surface exceeding a distance between the outer circumferential surface of the ring engagement portion and the friction base surface, and the other end of the friction protrusion is less than the interval between the outer circumferential surface of the ring- And the friction base surface is provided with a friction surface which is radially inwardly radially inwardly opposed to an inclined surface connecting between a radially outer end of the long width step surface and a radially outer end of the short- It is preferable that a projection is formed.

A locking recess is formed in the outer periphery of the rotation base portion in a radially outward direction, and the elastic friction portion is provided with a recessed groove portion for inserting the locking projection into the inner periphery of a coupling hole to which the rotation base portion is coupled, The stepped portion is formed to extend in the circumferential direction along the clearance angle so as to be integrally rotated with the elastic frictional portion at a gap angle equal to or greater than the clearance angle, and the engaging protrusions are constrained at both ends in the circumferential direction.

Through the above-mentioned solution, the rotary damper device of the present invention provides the following effects.

First, since the shaft portion is rotated at a reduced speed through frictional resistance between a solid-based elastic frictional portion and a housing portion unlike the prior art using a fluid, the productivity is improved by a simple structure in which a sealing structure for preventing fluid leakage is eliminated, The elastic friction portion disposed between the portions further absorbs the radial flow and vibration, thereby improving the efficiency of the product, and the buffer sensitivity can be easily adjusted according to the strength and friction area of the elastic friction portion.

Second, a plurality of friction protrusions spaced apart from each other in the circumferential direction are projected on the ring-coupled portion coupled to the outer periphery of the rotation base portion so as to be pressed against the friction base surface, so that rapid rotation of the shaft portion is prevented, So that the shaft can be smoothly rotated at a low speed, so that the operation quality of the product can be improved.

Thirdly, since the frictional protrusions are inclined radially outwardly in one direction, a frictional force is formed during one-directional rotation, frictional force is reduced during rotation in the other direction, and damping is selectively performed in one opening / The usability of the product can be improved.

Fourthly, a corresponding friction protrusion is provided on the friction base surface so as to be opposed to the inclined surface of the friction protrusion so that a selective damping force can be applied according to the rotation direction. In addition, while the soft rotation in the unselected rotation direction is maintained, / Deceleration capability can be further increased, so that the operational reliability of the product can be remarkably improved.

1 is a perspective view of a rotary damper device according to an embodiment of the present invention;
2 is a perspective view showing the internal structure of a rotary damper device according to an embodiment of the present invention;
3 is a longitudinal sectional view of a rotary damper device according to an embodiment of the present invention.
4 is a cross-sectional view of a rotary damper device according to an embodiment of the present invention.
5 is a cross-sectional view showing a first modification of the rotary damper device according to the embodiment of the present invention.
6 is a cross-sectional view showing a second modification of the rotary damper device according to the embodiment of the present invention.

Hereinafter, a rotary damper device according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Here, the rotary damper device is provided in a hinge connection part serving as a central axis of rotary motion, and functions to prevent various safety accidents and damage to the product due to shocks during a rapid rotation of a rotating object such as a door. At this time, the hinge connection part includes not only a hinge connection part that is pivotally moved in the right and left direction such as an entrance and exit of a general building, a window, a door of a refrigerator or furniture, but also a hinge connection part that rotates back and forth / up and down like a folding chair of a vehicle, It is desirable to understand the meaning.

FIG. 1 is a perspective view of a rotary damper device according to an embodiment of the present invention. FIG. 2 is a perspective view illustrating an internal structure of a rotary damper device according to an embodiment of the present invention. FIG. 4 is a cross-sectional view of a rotary damper device according to an embodiment of the present invention. FIG.

1 to 4, the rotary damper device 100 includes a shaft portion 10, a housing portion 20, and an elastic frictional portion 30. As shown in FIGS.

1 to 3, the shaft portion 10 is provided at one end thereof with a rotation axis support portion 11 connected to a rotation axis of a hinge connection portion between the rotation support body and the rotation support body in which the rotation target body is supported, And a rotation base portion 13 is provided at an end thereof.

In this case, the pivotal object refers to a portion that is substantially pivoted, such as a door of a building, and the pivotal support member is a portion such as a door frame that is supported to pivot the door.

In detail, the shaft portion 10 is a bar member having a circular cross section and made of a metal material or reinforced plastic having high strength, and is arranged and coupled along the axial direction of the rotary shaft and rotated integrally with the rotary shaft And is provided with a rotary shaft support portion 11 formed at one end thereof to be engaged.

The other end of the shaft portion 10 is provided with a rotation base portion 13 having a cross-sectional area extending from the cross-sectional area of the rotation axis support portion 11, to which the elastic friction portion 30 is coupled.

At this time, the elastic frictional portion 30 is formed in a ring shape and is engaged and coupled from the other end of the rotary base portion 13 toward one end. At one end of the outer circumference of the rotary base portion 13, 30 extending radially outward so as to support one end edge of the supporting wing portion 12.

Since the shaft portion 10 is engaged with the elastic friction portion 30 through the rotation base portion 13 extended from the cross sectional area of the rotation axis supporting portion 11, the elastic friction portion 30 and the wide engagement / And it is possible to prevent the elastic frictional portion 30 from rotating / separating toward the one end of the shaft portion 10 through the support vane portion 12, so that the assembling stability of the product can be improved have.

Of course, the support vane 12 may be separately provided as a separate component, such as a washer member that is seated and supported at one end of the rotation base 13.

In addition to this, the structural coupling force to the elastic friction portion 30 is improved through the rotation base portion 13 extended from the rotation axis support portion 11, and the elastic friction portion 30, which is coupled to the rotation base portion 13, And the housing portion 20 surrounding the rotation base portion 13 can be increased, so that the buffering performance of the product can be improved.

Meanwhile, the housing part 20 is engaged with the rotation base part 13 so that the shaft part 10 is rotatably supported. The housing part 20 includes a housing cover 20a having a support hole 21 through which the rotation axis support part 11 is inserted at one end thereof and having an inverted container shape surrounding the outer periphery of the rotation base part 13, And a housing base 20b coupled to cover the opening at the other end of the housing cover 20a.

At this time, the housing cover 20a may fix and support the housing cover 20a in a state of being coupled to the pivot support to provide a frictional resistance against the rotation of the shaft portion 10. [

The shaft portion 10 is coupled from the other end opening of the housing cover 20a to one end so that the rotation shaft support portion 11 passes through the support hole 21, And the outer peripheral surface is supported on the inner periphery of the support hole 21. [

In addition, a coupling shaft portion 14 and an engagement shaft support portion 22 having a groove / projection shape are formed on the other surface portion of the rotation base portion 13 and the one surface portion of the housing base 20b, and the housing cover 20a Is coupled to one surface of the housing base 20b, the coupling shaft portion 14 is supported by the coupling shaft support portion 22.

Since the rotation shaft support portion 11 and the engagement shaft portion 14 are supported by the support hole 21 and the engagement shaft support portion 22 of the housing portion 20, the shaft portion 10 is supported by the housing portion 20 can be stably rotated without radial flow or twisting.

The housing cover 20a is provided to have an internal space of a cross-sectional area exceeding the cross-sectional area of the rotation base portion 13, and a gap between the inner circumferential surface of the housing cover 20a and the outer circumferential surface of the rotation base portion 13 is predetermined Respectively. That is, a friction base surface 23 may be formed along the inner surface of the housing cover 20a and spaced from the outer surface of the rotary base 13.

Meanwhile, the elastic friction portion 30 is coupled to surround the outer surface of the rotation base portion 13. At this time, when the shaft portion 10 is coupled to the housing portion 20, the elastic friction portion 30 is disposed inside the housing cover 20a.

Here, the elastic friction portion 30 is made of a rubber material and can provide a damping force when the shaft portion 10 is rotated by rubbing against the friction base surface 23.

The elastic friction portion 30 and the rotation base portion 13 are coupled to rotate integrally without slippage or diaphragm through key engagement or gear engagement, The rotational speed of the shaft portion 10 can be attenuated through the frictional resistance force between the friction base surface 23.

The elastic friction portion 30 may be formed of various materials such as butadiene rubber, acryonitrile butadiene rubber, polyacrylate rubber, silicone rubber, and urethane. And the damping force can be freely adjusted according to the strength of the material.

As described above, since the shaft portion 10 is rotated at a reduced speed through the frictional resistance between the solid-based elastic friction portion 30 and the housing portion 20, the sealing structure for preventing fluid leakage is removed Product structure can be improved with a simple structure. In addition, an elastic friction portion 30 of an elastic material is disposed between the shaft portion 10 connected to the rotation shaft of the hinge connection portion and the housing portion 20 fixed to the rotation support body, and the shaft portion 10 and the housing It is possible to improve the efficiency and durability of the product since it is possible to provide an auxiliary buffer for the radial flow and vibration as well as the relative rotation between the portions 20.

Since the damping force can be easily adjusted according to the material strength and the friction area of the elastic friction portion 30, the size of the base portion 13, the housing portion 20, the elastic friction portion 30, By adjusting the strength of the elastic frictional portion 30 and the like, it is possible to improve the compatibility and the design convenience of the product by the ease of deformation design applicable to the rotating object such as small / medium / large size.

2 to 4, the elastic frictional portion 30 includes a ring-shaped coupling portion 30a having a circular cross section and coupled to the rotation base portion 13, And a friction protrusion 30b protruded from the friction surface 30 and pressed against the friction base surface 23.

In this case, it is preferable that the ring coupling portion 30a is formed such that the outer surface thereof is spaced apart from the friction base surface 23 in a state where the ring coupling portion 30a is coupled to surround the outer surface of the rotation base portion 13, 30b may protrude from the outer surface of the ring-engaging portion 30a so as to have a radial size larger than a distance between the friction base surfaces 23 so as to provide a substantial frictional force.

The friction protrusions 30b may be elastically deformed in the circumferential direction and may be spaced apart from each other in the rotation direction of the shaft portion 10 so as to be slid down along the friction base surface 23. [

That is, the frictional protrusions 30b are pressed on the frictional base surface 23 at the radially outer end thereof, and a predetermined clearance space is formed in the circumferential direction and the other direction of the frictional protrusions 30b. Thus, the friction protrusion 30b is prevented from rotating rapidly in the circumferential direction along the clearance space while preventing the rapid rotation of the shaft portion 10 in a state where the friction protrusion 30b is pressed on the friction base surface 23. [ The shaft portion 10 can be smoothly rotated at a low speed, so that the operation quality of the product can be improved.

Each of the friction protrusions 30b is formed to be inclined radially outward toward the one direction R so that the damping force is increased in one direction (R) of rotation of the shaft portion 10, . That is, the radial dimension of the other end of the rubbing protrusion 30b is small and the radial size of the unidirectional end portion is large.

At this time, a long width stepped surface 31 exceeding a distance between the outer circumferential surface of the ring coupling portion 30a and the friction base surface 23 is formed at one end (R) end of the friction protrusion 30b, At the other end of the projection 30b, a short-side difference surface 32 is formed at a distance from the outer peripheral surface of the ring engagement portion 30a to the friction base surface 23 or less.

The friction protrusions 30b are formed such that one end R thereof forms a high frictional force with the friction base surface 23 and the other end thereof forms a low frictional force or a predetermined clearance with the friction base surface 23. [ can do.

That is, the cross-section of the one-direction (R) end of the friction protrusion 30b as viewed in the up-down direction is such that the other-direction side slope 33 is inclined with respect to the friction base surface 23, And may be formed in a right triangle shape.

At this time, when the elastic friction portion 30 is rotated in the one direction R, the one end R of the friction protrusion 30b is supported by the inclined surface 33 so that the deformation amount toward the other direction is reduced, A high frictional force with respect to the surface 23 can be maintained.

Since the one end R of the friction protrusion 30b is deformed toward the clearance space when the elastic friction portion 30 is rotated in the other direction, the amount of deformation can be increased without a separate supporting force, Can be reduced.

As a result, the hinge connection portion can be smoothly rotated in the opposite direction while the one-way rotation of the hinge connection portion is effectively decelerated, and the damping force can be selectively given in one opening / closing direction such as opening or closing of the door, .

5 is a cross-sectional view showing a first modification of the rotary damper device according to the embodiment of the present invention. In the first modification example, the basic configuration except for the inner surface side corresponding friction protrusion 123a of the friction base surface 123 is the same as that of the above-described embodiment, so a detailed description of the same configuration will be omitted, Respectively.

5, the friction protrusion 30b has a long-width stepped surface 31 at an end of the one-way end R that exceeds the interval between the outer circumferential surface of the ring engagement portion 30a and the friction base surface 123 And an end face 32 is formed at an end portion of the other direction less than a distance between the outer peripheral face of the ring engagement portion 30a and the friction base face 123. [

At this time, on the friction base surface 123, a radially outer end of the long width stepped surface 31 and a radially outward end of the shortened end surface 32 are radially inwardly opposed to the inclined surface 33, A corresponding rubbing protrusion 123a is formed so as to be rounded.

That is, the corresponding friction protrusion 123a is disposed on the rotation locus of the slope surface 33 so as to have no substantial contact with the short-edge difference surface 32, (Not shown).

When the friction protrusion 30b is rotated in the other direction, the inclined surface 33 is slid along the corresponding friction protrusion 123a and the elastic friction portion 30 can be smoothly rotated.

When the friction protrusion 30b is rotated in the one direction R, the radially outer end of the long width step surface 31 is engaged with the corresponding friction protrusion 123a, but is elastically deformed in the other direction, (123a). Accordingly, the one-way rotational friction force of the elastic friction portion 30 can be further increased.

That is, through the engagement of the corresponding friction protrusion 123a and the narrow width stepped surface 31, the corresponding friction protrusion 123a, and the slip of the end surface 32 / sloped surface 33, a damping force While the smooth rotation about the unselected rotation direction is maintained, the buffering / decelerating ability of the selected rotation direction can be further increased, and the operational reliability of the product can be remarkably improved.

6 is a cross-sectional view showing a second modification of the rotary damper device according to the embodiment of the present invention. In the second modification, the basic configuration except for the outer surface side locking projection 113a of the rotation base portion 113 and the inner circumferential side constraint groove portion 134a of the ring engagement portion 130a is the same as that in the above embodiment, A detailed description of the configuration is omitted, and the same reference numerals are used for the same components.

6, a locking protrusion 113a protrudes radially outward from the outer surface of the rotation base portion 113, and on the inner circumference of the ring coupling portion 130a of the elastic friction portion 130, The engaging recess 134a into which the engaging protrusion 113a is inserted is formed in the inner periphery of the engaging hole 134 formed to engage with the engaging portion 113. [

At this time, the restraining groove portion 134a is slipwise rotated at a predetermined clearance angle, and is extended in the circumferential direction along the clearance angle so as to be integrally rotated with the elastic friction portion 130 at the clearance angle or more And stepped portions 134b and 134c are formed at both ends in the circumferential direction to arrest the locking protrusion 113a.

More specifically, the coupling hole 134 is formed in a cross-sectional area corresponding to the rotation base portion 113, and the constraining groove portion 134a is formed in the inner periphery of the coupling hole 134 opposed to the outer peripheral surface of the rotation base portion 113 In the radial direction.

The rotation base portion 113 is inserted into the coupling hole 134 and the shaft portion 110 and the elastic frictional portion 130a are inserted into the locking recess portion 134a, ) Can be combined.

Here, the constraining groove portion 134a is recessed to have a radial depth corresponding to the radial direction protrusion size of the engagement protrusion 113a, and the circumferential width of the engagement protrusion 113a is set to a circumferential width Direction.

At this time, both end portions in the circumferential direction of the engaging projection 113a and both end portions of the restricting groove portion 134a are formed to be stepped to be engaged with each other.

That is, within the clearance angle, the locking protrusion 113a is moved along the inside of the constraining groove portion 134a, and the rotation base portion 113 and the elastic friction portion 130 are rotated independently of each other, The shaft portion 110 can be rotated in a minimized state.

The rotation base portion 113 and the elastic friction portion 130 are integrally rotated when the locking projection 113a is in contact with the stepped portions 134b and 134c when the clearance angle is exceeded, The shaft portion 110 may be rotated at a reduced speed according to a frictional force between the housing 130 and the housing portion 20.

Accordingly, the hinge connection portion smoothly freely rotates freely within a predetermined opening / closing angle, and can be opened or closed quickly. However, since the hinge connection portion can be rotated at a reduced speed in the vicinity of the fully opened or fully closed position other than the set angle, .

As described above, the present invention is not limited to the above-described embodiments, and variations and modifications may be made by those skilled in the art without departing from the scope of the present invention. And such modifications are within the scope of the present invention.

100: rotary damper device 10: shaft portion
20: housing part 30: elastic friction part

Claims (5)

A shaft portion having a rotation axis support portion connected to a rotation axis of a hinge connection portion between the rotation support body and the rotation support body, the rotation base being provided at the other end portion;
A housing part which is coupled to the rotation base part so that the shaft part is rotatably supported and has a friction base surface spaced apart from the outer surface of the rotation base part along the inner surface part; And
And a rubber elastic friction portion coupled to the rotation base portion and rubbing against the friction base surface to provide a damping force during rotation of the shaft portion. The method according to claim 1,
The elastic friction portion
A ring coupling portion of a circular cross section coupled to the rotation base portion,
A plurality of frictional protrusions formed to be radially outwardly protruded from the outer circumferential surface of the ring engaging portion so as to be pressed on the friction base surface and spaced apart from each other in a rotating direction of the shaft portion so as to be elastically deformed in the circumferential direction, Wherein the rotation damper device comprises: 3. The method of claim 2,
Wherein each of the friction protrusions is formed to be inclined radially outwardly in one direction so that the damping force is increased in one direction of rotation of the shaft but decreased in damping force in the other direction. 3. The method of claim 2,
Wherein the friction protrusions are formed at one end with a long width stepped surface exceeding a distance between the outer circumferential surface of the ring engagement portion and the friction base surface, A far-end difference surface is formed,
Wherein the friction base surface is provided with a corresponding friction protrusion which is radially inwardly and radially inwardly opposed to an inclined surface connecting a radially outer end of the long width stepped surface and a radially outer end of the shortened step difference surface. Damper device. The method according to claim 1,
A locking projection is projected radially outward from the outer periphery of the rotation base portion,
Wherein the elastic frictional portion is formed with a restricting groove portion for inserting the engaging protrusion into the inner periphery of the engaging hole,
Wherein the restricting groove portion is formed by extending in the circumferential direction along the clearance angle so that the rotation base portion is slipingly rotated at a predetermined clearance angle and is integrally rotated with the elastic frictional portion at the clearance angle or more, Wherein the damper unit is formed with an opening.

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