KR101829767B1 - Variable Shear type Viscous Damper - Google Patents

Abstract

The present invention relates to a variable shear type viscous damper for vibration control of a structure or an apparatus, which comprises: an upper bracket and a lower bracket; a lower fixing plate; a ball screw support block; a ball screw; an upper moving plate; an upper fixing plate; and viscous oil filling the inside of the lower fixing plate. According to the present invention, by controlling the change in the cross-section of the inside of the damper filled with the viscous oil, the shear force against vibration can be adjusted and improved, so the damping force against vibration can be tuned and set to an optimal state. The variable configuration of the present invention allows the vibration damping conditions to be optimally and simply controlled according to a structure or an apparatus of an installation site, as well as improving the installation space and installation efficiency.

Description

[0001] The present invention relates to a variable shear type viscous damper,

The present invention relates to a variable shear type viscous damper, and more particularly, to a variable shear type viscous damper capable of tuning and setting a damping force for vibration by adjusting a shear force by controlling changes in a cross section of a damper filled with viscous oil, To a variable shear type viscous damper capable of optimizing and simply controlling the vibration damping condition according to the structure or device of the installation site and improving installation space and installation efficiency.

In general, since vibration has a bad influence on a structure or a device, various types of vibration dampers for attenuating the damper are used.

Such a vibration damper has various structures and members including a method using an elastic member such as a spring, a method using a viscous fluid, a method using a magnetic force, a method using a frictional force, and the like.

However, the conventional techniques have limitations in increasing the efficiency of vibration damping, and there is a difficulty in controlling or controlling vibration damping force.

In addition, conventionally, the damping condition for the vibration in the structure or the apparatus is different according to the environment and the environment of the site, and in particular, the damper damper is installed without knowing the optimum damping condition in the field.

However, once the vibration damper is once installed in the field, it is necessary to additionally install a damper or to remove a damper already installed in order to meet the optimum attenuation condition in the field for vibration, which is considerably difficult to add or remove the damper And there is a difficulty in the operation such as securing a space for installation when a damper is additionally installed.

Korean Patent Registration No. 10-1480350 Korean Patent Registration No. 10-0935179

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to adjust the shear force by controlling a change in the cross section of a damper filled with viscous oil, It is an object of the present invention to provide a variable shear type viscous damper capable of optimizing and simply controlling the vibration damping condition in accordance with the structure or apparatus of the installation site through a variable configuration and improving installation space and installation efficiency.

The present invention makes it possible to tune the vibration damping condition by variable according to the structure or device installed on the site, thereby making it possible to improve the difficulty of adding or removing the number of vibration dampers in the field, And to provide a variable shear type viscous damper capable of increasing efficiency.

According to an aspect of the present invention, there is provided a variable shear type viscous damper comprising: an upper bracket and a lower bracket disposed on upper and lower sides, respectively; A lower fixing plate fixedly coupled to the upper surface of the lower bracket and having inner walls spaced from each other between both outer walls; A ball screw support block fixedly coupled to a lower surface of the upper bracket; A ball screw rotatably supported on the ballscrew support block and having a moving body coupled to the ballscrew by a ball driving force so as to move back and forth along a screw shaft; An upper moving plate coupled to the moving body of the ball screw to move in a forward and backward direction of the moving body and having a first downwardly projecting wall spaced apart from the inner walls of the lower fixed plate; An upper fixing plate disposed on the lower surface of the upper moving plate in a state of being fixedly coupled to the upper bracket and having a straight slit hole and a second downward protruding wall disposed between the first downward protruding walls of the upper moving plate; And a viscous oil filled in the lower fixed plate, wherein the first downward protruding wall of the upper movable plate is inserted into a straight slit hole side of the upper fixed plate and is disposed to protrude downward, And adjusting the degree of opening through the matching of the second downwardly projecting wall to adjust the vibration damping force due to the section change.

Here, the upper moving plate is formed with a straight guide hole, and the upper fixing plate has a connecting portion for fixing to the upper bracket protruding, and the connecting portion is fixedly coupled to the upper bracket through the linear guide hole, It is possible to configure the upper moving plate to move back and forth when the movable body is moved back and forth by rotating the screw.

Here, the front support block and the rear support block, which are fixedly coupled to the upper bracket and are respectively disposed at the front and rear sides, And a rotation preventing guide rod connected to the front support block and the rear support block to prevent rotation of the upper moving plate when the ball screw rotates.

Wherein each of the first downwardly projecting wall and the second downwardly projecting wall has an opening formed between the first downwardly projecting wall and the second downwardly projecting wall by spacing the first downwardly projecting wall and the second downwardly projecting wall in the longitudinal direction so as to tune the vibration damping force by a change in cross section, So that the opening degree of the opening can be adjusted by matching with the second downwardly projecting wall.

According to another aspect of the present invention, there is provided a variable shear type viscous damper comprising: an upper bracket and a lower bracket disposed on upper and lower sides, respectively; A lower circular fixing plate fixedly coupled to the upper surface of the lower bracket and having an inner wall spaced apart from the outer walls; A support block fixedly coupled to a lower surface of the upper bracket; A rotation regulating member rotatably supported on the support block and having a worm gear portion; A wormhole portion provided on an upper surface of the worm gear portion of the rotation adjusting rod to be engaged with the worm wheel portion and rotatably moved in accordance with normal and reverse rotation of the rotation adjusting rod, An upper rotation movable plate on which a wall is formed; And a second downwardly protruding wall disposed between the first downward protruding walls of the upper rotating plate, wherein the upper rotating plate is disposed on the lower surface of the upper rotating plate while being fixedly coupled to the upper bracket, An upper fixing plate on which protruding walls are formed; Wherein the first downward protruding wall of the upper rotating plate is inserted into the arcuate slit hole side of the upper fixed plate and is disposed to protrude downward, And adjusting the degree of opening through matching of the second downwardly projecting wall on the side of the upper fixed plate in accordance with the moving state, thereby tuning the vibration damping force due to the section change.

Here, the upper rotation movable plate is formed with an arcuate guide hole, and the upper fixed plate has a connecting portion protruded from its upper surface. The connecting portion is arranged through the circular arc guide hole and the upper end is fixedly coupled to the upper bracket It is possible to rotate the upper rotation plate while rotating the rotation control rod to provide a rotational force by engaging the teeth of the worm gear and the wormhole.

Here, the first downwardly projecting wall and the second downwardly projecting wall each have an arc-shaped wall structure for tuning a vibration damping force due to a change in cross section, and an opening is formed between the first downwardly projecting wall and the second downwardly projecting wall, And the opening degree of the opening can be adjusted by matching with the second downwardly projecting wall according to the rotational movement of the first downwardly projecting wall.

According to the present invention, there is provided a variable structure having a structure using forward and backward movement or rotational movement of a front end plate (upper moving plate or upper rotating plate) for adjusting a shearing force, wherein the damper The shear force can be easily improved by controlling the change in the internal section, and the damping force for vibration can be tuned and set to the optimal state. Since tuning can be performed, vibration damping It is possible to optimize the conditions and to control them easily and achieve the usefulness of improving the installation space and installation efficiency compared to the existing ones.

Since the present invention can tune the vibration attenuation condition by variable according to the structure or device installed on the field, it is not necessary to add or remove the number of the damper installed in the field in order to meet the dustproof condition in the past There is a difficulty in such a work, but it can be improved and the usefulness of increasing the efficiency of vibration damping by shear force tuning can be achieved.

1 is a sectional view showing a variable shear type viscous damper according to an embodiment of the present invention.
FIG. 2 is a block diagram showing an upper moving plate in a variable shear type viscous damper according to an embodiment of the present invention.
3 is a block diagram showing an upper fixing plate of a variable shear type viscous damper according to an embodiment of the present invention.
4 is a view showing a configuration including a rotation preventing guide rod in the variable shear type viscous damper according to the embodiment of the present invention.
FIG. 5 is a view showing the open state of the opening portion of the variable shear type viscous damper according to the embodiment of the present invention.
FIG. 6 is a view illustrating a use state of the variable shear type viscous damper according to the embodiment of the present invention, in which the upper moving plate is adjusted by adjusting the rotation of the ball screw to adjust the opening degree with respect to the opening.
7 is a sectional view showing a variable shear type viscous damper according to another embodiment of the present invention.
8 is a cross-sectional view of a variable shear type viscous damper according to another embodiment of the present invention in another direction.
FIG. 9 is a view showing an upper rotating plate in a variable shear type viscous damper according to another embodiment of the present invention.
FIG. 10 is a block diagram showing an upper fixing plate in a variable shear type viscous damper according to another embodiment of the present invention.
FIG. 11 is a view showing an open state of an opening in a variable shear type viscous damper according to another embodiment of the present invention.
FIG. 12 is a view illustrating a use state of the variable shear type viscous damper according to the embodiment of the present invention, in which the opening degree of the opening is adjusted by rotating the upper rotary plate through rotation adjustment of the rotary guide.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The present invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.

As shown in FIGS. 1 to 6, the variable shear type viscous damper 100 according to the embodiment of the present invention induces a change in the internal surface of the damper 100 through a structure using forward and backward movement, The upper bracket 110, the lower bracket 120, the lower fixing plate 130, the ball screw supporting block 140, the ball screw 150, the upper bracket 120, A moving plate 160, and an upper fixing plate 170.

The lower fixing plate 130 is filled with viscous oil 180 so as to utilize a resistance force due to oil shear force.

The upper bracket 110 is used to fix or support the ball screw support block 140 and the upper fixing plate 170. The upper bracket 110 is used to fix or support the ball screw supporting block 140 and the upper fixing plate 170, do.

The lower bracket 120 is used for fixing the bottom fixing plate 130 to the bottom surface of the building or the like of the variable shear type viscous damper 100 of the present invention.

The upper bracket 110 and the lower bracket 120 are disposed on the upper side and the lower side, respectively, and a restoring spring (not shown) is provided on both sides of the damper 100 including such a structure. It is preferable that the damper 100 is restored to its original state after the damper 100 is contracted and the external force is removed upon receiving an external force.

The lower fixing plate 130 is fixedly coupled to the upper surface of the lower bracket 120 by fastening. The lower fixing plate 130 is provided with an inner wall 132 disposed between the outer walls 131 protruding upward.

The ball screw support block 140 is fixedly coupled to the center of the lower surface of the upper bracket 110 and is used to support and support the ball screw 150 on the lower side of the upper bracket 110.

The ball screw 150 is rotatably supported on the ball screw support block 140 and includes a moving body 152 coupled to move forward and backward along a screw shaft 151 by a ball driving force.

The ball screw 150 moves the upper moving plate 160 in the forward and backward directions according to the direction of the forward and reverse rotations to adjust the change in the cross section inside the damper 100 filled with the oil 180, It is used to tune the damping force to the optimal state.

The upper moving plate 160 is coupled to the moving body 152 of the ball screw 150 to move in the forward and backward directions of the moving body 152 and is disposed between the inner walls 132 of the lower fixing plate 130. [ A first downwardly projecting wall 161 is formed.

At this time, a straight guide hole 162 is formed in the upper moving plate 160.

The upper fixing plate 170 is disposed on the lower surface of the upper moving plate 160 in a state of being fixedly coupled to the upper bracket 110 and is provided with a straight slit hole 162 for positioning the first downward protruding wall 161. [ And a second downwardly projecting wall 172 disposed between the first downwardly projecting walls 161 of the upper moving plate 160 is formed.

The upper fixing plate 170 is formed integrally with the upper bracket 110 by extending a connecting portion 173 for fixing the upper bracket 110 to the upper bracket 110. The connecting portion 173 passes through the straight guide hole 162 And fastened to the upper bracket 110 by fastening the end thereof.

The first downward protrusion wall 161 of the upper moving plate 160 is inserted into the linear slit hole 171 of the upper fixed plate 170 and is disposed to protrude downward. And is formed between the first downward protruding wall 161 and the second downward protruding wall 172 through matching with the second downward protruding wall 172 of the upper fixed plate 170 according to the moving state of the forward / So that the vibration damping force due to a change in cross section can be tuned.

In addition, the first downward projecting wall 161 of the upper moving plate 160 and the second downward projecting wall 172 of the upper fixed plate 170 have a vibration damping force The damper 100 is provided so as to be spaced apart from the damper 100 in the longitudinal direction to form an opening O between the damper 100 and the first downwardly projecting wall 161 to match the second downwardly projecting wall 172 to adjust the degree of opening of the opening O. [

With such a configuration, when the moving body 152 is moved forward and backward by rotating and adjusting the ball screw 150, it is possible to perform forward and backward movement with respect to the upper moving plate 160, It is possible to tune and set the vibration damping force through a change in the cross section of the inside of the housing 100 to an optimum state.

In the present invention, the front support block 101 and the rear support block 102 are fixedly coupled to the upper bracket 110 by fastening, respectively, and are disposed at the front and rear, respectively. And a rotation preventing guide rod 190 fixedly coupled to the front support block 101 and the rear support block 102 by fastening.

The front support block 101 and the rear support block 102 may be disposed outside the upper bracket 110. However, the front support block 101 and the rear support block 102 may be disposed inside the upper bracket 110 in consideration of aesthetic and installation space.

According to this configuration, it is possible to prevent the ball screw 150 from being rotated with respect to the upper moving plate 160, which moves back and forth in accordance with the movement of the moving body 152 during the rotation adjustment.

5, the first downward protruding wall 161 and the upper fixed plate 170 of the upper moving plate 160 have the same shape as that of the upper fixed plate 170. In the variable shearing type viscous damper 100 of the present invention having the above- When the second downwardly projecting wall 172 having the first downward protruding wall 172 overlaps with the first downward protruding wall 172, the first downward protruding wall 172 has an opening O in which one side is opened inside the damper 100 having the viscous oil 180.

In this initial arrangement state, when the ball screw 150 coupled to the upper moving plate 160 is rotationally adjusted, the moving body 152 moves forward and backward along the screw shaft 151 in accordance with the forward and reverse rotational directions of the ball screw 150 At the same time, as shown in FIG. 6, as the upper moving plate 160 is moved forward or backward, the first downward protruding wall 161 is initially formed while being offset from the second downward protruding wall 172 It is possible to adjust the opening degree of the opening (O).

Accordingly, by changing the position of the first downward projecting wall 161 by moving the upper moving plate 160 by adjusting the rotation of the ball screw 150 in accordance with the installation site, a change in section within the damper 100 can be prevented And adjust the position of the first downward projecting wall 161 by adjusting the position of the upper moving plate 160 to adjust the damping force for the vibration to the optimum condition It can be set by tuning.

7 to 12, the variable shear type viscous damper 200 according to another exemplary embodiment of the present invention adjusts the shear force by inducing a change in the internal surface of the damper 200 through the structure using rotational movement, The upper bracket 210, the lower bracket 220, the lower circular fixing plate 230, the support block 240, the rotation guide 250, and the lower bracket 220. [ An upper rotating plate 260, and an upper fixing plate 270. [

The lower circular fixing plate 230 is filled with a viscous oil 280 so that a resistive force due to oil shear force can be utilized.

The upper bracket 210 is used to fix or support the support block 240 and the upper fixing plate 270. The upper bracket 210 is used to fix or support the supporting block 240 and the upper fixing plate 270. [

The lower bracket 220 is used for fixing the bottom circular fixing plate 230 to the bottom surface or the structure of the building to which the variable shearing type viscous damper 200 of the present invention is to be installed.

The upper bracket 210 and the lower bracket 220 are disposed on the upper side and the lower side, respectively, and a restoring spring (not shown) is provided on both sides of the damper 100 including such a structure. It is preferable that the damper 200 is restored to its original state after the damper 200 is contracted and its external force is removed upon receiving an external force.

The lower circular fixing plate 230 is fixedly coupled to the upper surface of the lower bracket 220 by means of fastening. An inner wall 232 is interposed between the circular outer walls 231 protruding upward.

The support block 240 is fixedly coupled to the lower surface of the upper bracket 210 by fastening and is used to support and support the rotation guide 250 on the lower side of the upper bracket 210.

It is preferable that the support block 240 is disposed at the front and rear in the longitudinal direction of the upper bracket 210.

The rotation regulating unit 250 includes a worm gear unit 251 rotatably supported on the support block 240 and coupled to transmit rotational force.

The rotation regulating unit 250 regulates a sectional change in the damper 200 filled with the oil 280 by rotationally moving the upper rotating plate 260 according to the direction of the forward and reverse rotation, It is used for tuning to the optimum state.

The upper rotating plate 260 is provided on the upper surface thereof with a wormhole portion 261 which is engaged with the worm gear portion 251 of the rotation adjusting table 250 so as to rotate in accordance with normal and reverse rotation of the rotation adjusting table 250 And a first downward protruding wall 262 spaced apart from the inner wall 232 of the lower circular fixing plate 230 is formed.

At this time, the upper rotation plate 260 is formed with an arcuate guide hole 263.

The upper fixing plate 270 is disposed on the lower surface of the upper rotating plate 260 in a state of being fixedly coupled to the upper bracket 110 and has an arcuate shape for arranging the first downward projecting wall 262 And a second downward projecting wall 272 formed between the first downward projecting walls 262 of the upper rotary movement plate 260 is formed.

The upper fixing plate 270 has a connecting portion 273 for fixing the upper bracket 210 to the upper bracket 210. The connecting portion 273 protrudes from the upper bracket 210 in an integral structure. So as to be fixedly coupled to the upper bracket 210 by fastening the ends thereof.

The first downward projecting wall 262 of the upper rotary movement plate 260 is inserted into the arc-shaped slit hole 271 of the upper fixed plate 270 to be projected downward, (Not shown) formed between the first downward protruding wall 262 and the second downward protruding wall 272 through matching with the second downward protruding wall 272 on the side of the upper fixed plate 270 O to adjust the vibration damping force due to a change in cross section.

The first downward protruding wall 262 of the upper rotating plate 260 and the second downward protruding wall 272 of the upper fixed plate 270 have a vibration damping force The first rotating plate 260 is provided so as to form an opening O therebetween by correspondingly arranging the first rotating plate 260 and the second rotating plate 260 in an arcuate wall structure, And is provided to adjust the opening degree of the opening O by matching with the second downward projecting wall 272 in accordance with the rotation movement of the projecting wall 262.

According to such a configuration, the rotation regulating unit 250 is rotated to transmit the rotational force to the wormhole unit 261 which is engaged with the worm gear unit 251 by the movement of the worm gear unit 251, and the rotational movement of the upper rotating plate 260 is performed So that the vibration damping force due to the change in the cross section of the damper 100 can be tuned and set to an optimal state according to the installation site.

11, the variable shear-type viscous damper 200 according to the present invention having the above-described structure has the first downward protrusion wall 262 of the upper rotating plate 260 and the upper fixed plate 270 The second downward projecting wall 272 has an initial arrangement in which one side of the damper 200 having the viscous oil 280 is opened to form an opening O when the second downward projecting walls 272 are superimposed on each other.

The worm gear unit 251 rotates in accordance with the forward / reverse rotation direction to transmit the rotational force to the wormhole unit 261 coupled to the worm gear unit 251 so that the upper rotation plate 260 is rotated clockwise The first downward protruding wall 262 is shifted from the second downward protruding wall 272 in accordance with the rotational movement of the upper rotating plate 260 as shown in FIG. 12, The degree of opening of the opening portion O can be adjusted.

Accordingly, by rotating the upper rotation plate 260 by adjusting the rotation of the rotation control table 250 in accordance with the installation site, the position of the first downward projecting wall 262 is moved and adjusted to induce a change in the section inside the damper 200 The damping force against vibration can be tuned to an optimum condition according to the installation site by adjusting the position of the first downward projecting wall 262 by adjusting the rotation of the upper rotating plate 260 Can be set.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. May be made, which will be within the technical scope of the present invention.

100: variable shear type viscous damper 110: upper bracket
120: lower bracket 130: lower fixing plate
131: outer wall 132: inner wall
140: Ball screw supporting block 150: Ball screw
160: upper moving plate 161: first downward projecting wall
162: guide ball 170: upper fixing plate
171: Slit hole 172: Second downward protruding wall
180: oil 190: anti-rotation guide rod

Claims (7)

An upper bracket and a lower bracket disposed on the upper side and the lower side, respectively;
A lower fixing plate fixedly coupled to the upper surface of the lower bracket and having inner walls spaced from each other between both outer walls;
A ball screw support block fixedly coupled to a lower surface of the upper bracket;
A ball screw rotatably supported on the ballscrew support block and having a moving body coupled to the ballscrew by a ball driving force so as to move back and forth along a screw shaft;
An upper moving plate coupled to the moving body of the ball screw to move in a forward and backward direction of the moving body and having a first downwardly projecting wall spaced apart from the inner walls of the lower fixed plate;
An upper fixing plate disposed on the lower surface of the upper moving plate in a state of being fixedly coupled to the upper bracket and having a straight slit hole and a second downward protruding wall disposed between the first downward protruding walls of the upper moving plate;
A viscous oil filled inside the lower fixing plate; / RTI >
The first downward projecting wall of the upper moving plate is inserted into the straight slit hole side of the upper fixed plate and is disposed to protrude downward, and the degree of opening is adjusted through matching with the second downward projecting wall according to the moving state by forward and backward movement Wherein the variable shear type viscous damper is configured to tune a vibration damping force due to a change in cross section. The method according to claim 1,
Wherein the upper moving plate is formed with a straight guide hole,
Wherein the upper fixing plate has a connection part for fixing to the upper bracket,
Wherein the connecting portion is fixedly coupled to the upper bracket through the straight guide hole to allow the upper moving plate to move back and forth when the moving member is moved back and forth by rotating the ball screw. The method according to claim 1,
A front support block and a rear support block fixedly coupled to the upper bracket,
Rotation preventing guide rods disposed on both left and right sides of the ball screw and coupled to the front support block and the rear support block to prevent rotation of the upper moving plate when the ball screw rotates; And a variable shear type viscous damper. The method according to claim 1,
Wherein the first downwardly projecting wall and the second downwardly projecting wall each have a substantially U-
And an opening is formed between them by spacing them in the longitudinal direction so as to tune the vibration damping force by the section change,
And the opening degree of the opening is adjusted by matching with the second downwardly projecting wall in accordance with the forward and backward movement of the first downwardly projecting wall. An upper bracket and a lower bracket disposed on the upper side and the lower side, respectively;
A lower circular fixing plate fixedly coupled to the upper surface of the lower bracket and having an inner wall spaced apart from the outer walls;
A support block fixedly coupled to a lower surface of the upper bracket;
A rotation regulating member rotatably supported on the support block and having a worm gear portion;
A wormhole portion provided on an upper surface of the worm gear portion of the rotation adjusting rod to be engaged with the worm wheel portion and rotatably moved in accordance with normal and reverse rotation of the rotation adjusting rod, An upper rotation movable plate on which a wall is formed;
And a second downwardly protruding wall disposed between the first downward protruding walls of the upper rotating plate, wherein the upper rotating plate is disposed on the lower surface of the upper rotating plate while being fixedly coupled to the upper bracket, An upper fixing plate on which protruding walls are formed;
A viscous oil filled inside the lower circular fixing plate; / RTI >
The first downwardly projecting wall of the upper rotary movement plate is inserted into the arc-shaped slit hole side of the upper fixed plate and is projected downwardly, and the first downwardly projecting wall is opened and closed by matching with the second downwardly projecting wall on the upper fixed plate, So as to adjust the vibration damping force due to a change in the cross section of the variable shear type viscous damper. 6. The method of claim 5,
Wherein the upper rotation movable plate is formed with an arcuate guide hole,
The upper fixing plate has a connecting portion protruding from an upper surface thereof,
The connecting portion is arranged to penetrate through the arcuate guide hole and the upper end is fixedly coupled to the upper bracket. When the rotational force is generated by the gear engagement between the worm gear portion and the wormhole portion by rotating the rotation adjusting rod, To the variable shear type viscous damper. 6. The method of claim 5,
Wherein the first downwardly projecting wall and the second downwardly projecting wall each have a substantially U-
An arc-shaped wall structure for tuning a vibration damping force due to a change in cross section,
Wherein the first downward protruding wall is configured to match the second downward protruding wall in accordance with the rotational movement of the first downward protruding wall so as to adjust the opening degree of the opening.

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