KR102137017B1 - Module and module assembly for Anti-vibration module and Removable Special Floor Plate Structure comprising the same - Google Patents

Abstract

The present invention relates to a highly useful module which is a device for protecting a facility from vibration when installing a facility in a place where vibration occurs periodically or continuously, such as a construction site, a laboratory, or a place near a train station. The module can be easily assembled and manufactured due to having a simple structure, can effectively absorb vibration by absorbing the vibration while distributing the vibration over the entire module, can expand a length and an area by connecting modules to each other, and can be used by changing the shape according to a required shape.

Description

Vibration and vibration prevention module and module assembly and movable special floor plate structure comprising the same}

The present invention absorbs vibrations and vibrations generated when a facility is installed in a place where vibrations and vibrations are caused by the surrounding environment, and absorbs vibrations and vibrations received by the facility, thereby damping vibrations received by the facilities, and providing a plurality of modules connected to each other as an assembly Therefore, the present invention relates to a vibration and anti-vibration module and a module assembly and a movable special bottom plate structure, which can be provided by changing the size according to the installation location.

In general, in order to fix the facility, it can be attached and fixed using an adhesive member such as silicone or a fixing means such as welding. However, when the facility is installed using the above-mentioned adhesive member or fixing means where the surrounding environment is periodically or continuously vibrated, damage due to thermal expansion, vibration, etc. at the fixed part, and dropping of the facility due to aging may occur. Can.

In general, a device that absorbs vibrational energy is called a vibration damper or a reducer, and is intended to absorb some or all of the energy of an object in order to stop a moving object or a vibrating object.

Most of these reducers are devices that remove vibration by using air pressure or by using an actuator of an electronic device, which is difficult to manufacture due to its complex structure and high cost. However, there is also a device for removing vibration with a simple structure using a spring, but it is not effective for exhaustion because the buckling phenomenon of the spring occurs or the transmission direction of the vibration is not constant.

In addition, when a place to be installed is a non-reputable place, a place to be installed is narrow, or when it needs to be installed in a situation such as when it needs to be provided in an electric device or an electrical facility, the conventional reducer has a weak fixing force, so in a place where it is not reputed Since there is a high probability of dropping out, and it must be reproduced according to the size, it takes a lot of cost and time to install, and there is a problem that a fire or electric shock may occur when installed in a place where electricity is passed.

In order to provide the solar panel on a non-planar roof such as a home roof of a railway station where vibration and tremor are continuously generated, after attaching the solar panel to a structure support on the ground, the structure support is attached to a rail formed on the roof. After fitting, the solar panel is positioned while moving. Therefore, when the solar panel completely absorbs vibrations and tremors generated by the movement of the structure base, the solar panel may break and break or become unusable, resulting in secondary damage in the vicinity of the structure. Because it can, it needs an assistive device that can absorb or attenuate the vibrations and shocks the solar panel receives.

Korean Patent Registration No. 1757278 ("Easy to install and move copper reducer")

The present invention has been devised to solve the above problems, and reduces the effect of vibration generated by the train on the structure installed in the structure installed in the facility built around the rail where the train passes, thereby improving durability in the structure for a long time. It is to provide a vibration and anti-vibration module and a module assembly that can be made.

In addition, it is intended to provide a movable special bottom plate structure including a vibration and anti-vibration module and a module assembly that absorbs vibrations caused by shaking caused during high-altitude transportation of structures previously installed on the ground to protect the facility from vibrations. .

In the vibration and anti-vibration module interposed between the upper surface of the structure support and the support leg of the structure fixedly installed above the structure support, the base plate fixedly installed on the upper surface of the structure support; A pair of side plates extending upwardly from one side end portion of the base plate; A support portion disposed to be spaced a predetermined distance above the base plate and fixed to be supported between the pair of side plates, wherein a support leg of the structure is installed on an upper surface; And an elastic member interposed between the base plate and the base portion to reduce vibration in the vertical direction of the base portion, wherein the inner surface of the pair of side plates is recessed such that both sides of the base portion are recessed. Further comprising a groove, the movement limiting groove is formed to achieve a predetermined height in the vertical direction, it characterized in that to restrict the movement in the vertical direction of the support portion within a predetermined height.

At this time, the elastic member is formed extending upward from the center of the bottom plate; further comprising, the elastic member is characterized in that fitted to the elastic member fixing.

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In addition, when the plurality of vibration and anti-vibration modules are positioned adjacent to each other, they are formed in a shape corresponding to parts adjacent to each other so as to extend and join in one or more of the front-rear and left-right directions of the pair of side plates. It characterized in that it further comprises a connection portion.

At this time, the connecting portion, the body connecting portion is formed on the front and rear of the pair of side plates to be engaged with each other, so as to engage with the vibration and anti-vibration module adjacent to the front and rear direction of the pair of side plates; A support connection part formed on front and rear surfaces of the support part and engaged with each other so as to be engaged with each other so as to engage the vibration and anti-vibration module adjacent to the support part in the front-rear direction; And a side plate connecting portion formed on each outer side of the pair of side plates and engaged with each other so as to be engaged with the vibration and anti-shake module adjacent to the outer side in the left and right directions of the pair of side plates; Characterized in that it comprises any one or more of.

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In the module assembly in which the vibration and anti-vibration module is connected to a plurality of vibration and anti-vibration modules, the plurality of vibration and anti-vibration modules are respectively provided on a plurality of support legs of the structure, and a plurality of support legs of the structure Depending on the number and arrangement, the coupling portions formed in one or more directions selected from the front-rear direction and the left-right direction extend and engage with each other, and the vibrations generated by each of the plurality of support legs according to the movement of the structure are adjacent to each other. It is characterized by converging the vibration frequency generated in each of the plurality of support legs, by absorbing in a plurality of connected modules.

In addition, the elastic member is a spring, and the elastic member fixing portion is characterized in that it is formed in a nut-type tightening wrinkle shape.

In addition, the body connection portion is characterized in that formed on the front and rear of the side plate is engaged with each other to fit.

In addition, the support connection portion is characterized in that formed on the front and rear of the support portion is engaged with each other to fit.

In addition, the left and right outer surfaces of the pair of side plates, the side plate connecting portion is formed so that the main body portion is connected to each other.

At this time, the side plate connecting portion is characterized in that the adjacent side plates are formed to be engaged with each other to fit.

In the assembly in which a plurality of vibration and anti-vibration modules are connected, the body connection portion is formed on the front and rear of the body portion, and the plurality of body connections are combined to form a module assembly that forms a module extending in one direction. Is done.

In the assembly in which a plurality of vibration and anti-vibration modules are connected, the support connection portion is formed on the front and rear of the support portion, and the plurality of support connection portions are combined to form a module assembly that forms a module extending in one direction. Is done.

In an assembly in which a plurality of vibration and anti-vibration modules are connected, the side plate connecting portion is formed on an outer surface of the side plate on one side, and a plurality of the side plate connecting portions are combined to form a module that extends and extends in the side plate direction. It is characterized in that the assembly.

In addition, the present invention is characterized in that the vibration and anti-vibration module according to the above-described configuration forms a special bottom plate structure mounted on the top.

The vibration and anti-vibration module of the present invention according to the above configuration is simple in structure and easy to assemble and manufacture, and can be effectively exhausted because it is distributed over the entire module and absorbs vibration. The module can be expanded and can be used by changing the shape according to the required shape.

In addition, the movable special bottom plate structure including the vibration and anti-vibration module assembly of the present invention is installed on the ground to absorb the vibration applied between the supporting legs of the structure generated when being transported from the roof of the facility to prevent the structure from being damaged. It has the effect of preventing.

1 is a perspective view showing a movable special bottom plate structure according to an embodiment of the present invention.
Figure 2 is a side cross-sectional view according to Figure 1;
Figure 3 is a partial exploded view showing a fixing clip member according to an embodiment of the present invention.
Figure 4 is an enlarged main portion showing a fixing clip member according to an embodiment of the present invention.
Figure 5 is a cross-sectional view showing a special bottom plate structure according to another embodiment of the present invention.
Figure 6 is an exemplary view showing a special bottom plate structure according to a variation of the present invention.
Figure 7 is a flow chart showing the installation method of the movable special bottom plate structure of the present invention.
8 to 10 is an exemplary view showing a special bottom plate structure according to the installation procedure of the movable special bottom plate structure of the present invention.
11 is an example of use of the present invention
12 is a perspective view of the present invention
13 is a plan view of the present invention
14 is a perspective view of the elastic member fixing part of the present invention
15 is a partial perspective view of the present invention
16 is a front view of the present invention
17 is a schematic diagram of vibration absorption in the present invention
18 is a perspective view of a connection part Example 1 of the present invention
19 is a front view of the first embodiment of the connecting portion of the present invention
20 is a perspective view of a second embodiment of the present invention.
21 is a front view of a second embodiment of the present invention
22 is a plan view of one embodiment of the module assembly

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings. Prior to this, the terms or words used in the present specification and claims should not be construed as being limited to ordinary or lexical meanings, and the inventor appropriately explains the concept of terms in order to explain his or her invention in the best way. Based on the principle that it can be defined, it should be interpreted as meanings and concepts consistent with the technical spirit of the present invention.

Therefore, the embodiments shown in the embodiments and the drawings described in this specification are only the most preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, and thus can replace them at the time of application. It should be understood that there may be variations.

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings. The accompanying drawings are only examples shown in order to describe the technical spirit of the present invention in more detail, so the technical spirit of the present invention is not limited to the form of the accompanying drawings.

1 is a perspective view showing a movable special bottom plate structure according to an embodiment of the present invention, FIG. 2 is a side sectional view according to FIG. 1, and FIG. 3 is a fixed clip member according to an embodiment of the present invention Partial exploded view, Figure 4 is an enlarged main portion showing a fixing clip member according to an embodiment of the present invention. Referring to FIGS. 1 to 4, a movable special bottom plate structure 2000 according to an embodiment of the present invention The non-planar roof 10, the base plate 2110, the structure support 2120, a linear moving means 2130, a fixed clip member 2140 and may be configured to include an uneven relief member 2150.

The non-flat roof 10 is installed on the railroad station, the home roof and other facilities, to prevent leakage, induce falling water and insulate, the insulation is filled inside and the upper surface is formed with a wavy irregularity 11 It is formed into a shape. At this time, the base plate 2110 is fixed to the upper side of the non-flat plate roof 10, and is configured to flatten the top surface of the roof 10, the fixing clip member on the top surface of the roof 10 ( 2140) and being fixed through welding (B), it is possible to prevent leakage into the interior by not piercing the roof 10.

The structure support 2120 is provided with a structure 20 to be installed on an upper surface, is coupled upwardly of the base plate 2110, and is linearly moved between the base plate 2110 and the structure support 2120. By being linearly moved through the means 2130, the structure 20 can be easily moved by a worker to a desired location.

At this time, the structure support 2120 further includes a clasp hole 2123 formed to easily move the structure support 2120 by using a tool such as a hook or wire W on at least a portion of the outer end. . At this time, the clasp hole 2123 is preferably formed at both ends of the outer end in the linear movement direction of the structure support 2120.

The fixing clip member 2140 is a configuration for fixing the base plate 2110 to the upper surface of the roof 10, corresponding to the area of the base plate 2110 installed on the upper surface of the roof 10 , By pressing the outer end of the base plate 2110 downward, the roof 10 and the base plate 2110 vibrate with different vibration frequencies due to disturbances such as vibration transmitted when the train passes. Can be prevented. That is, the fixing clip member 2140 presses the base plate 2110 in the direction of the roof 10, and serves to damp vibrations to the base plate 2110 and the roof 10.

3 and 4, the fixing clip member 2140 is a clip hanger 2141 fixed to the upper surface of the roof 10, and one side is fixed to the clip hanger 2141 and the other side is the The clip 2142 is fastened to press the side end portion 130 of the base plate 2110 downward, and is interposed between the clip 2142 and the side end portion 130 of the base plate 2110 to damp vibration caused by disturbance. By comprising the insulating block (2143), it is possible to attenuate the vibration due to disturbance while simultaneously pressing the base plate (2110) downward.

Thereafter, by welding (B) the top surface of the roof 10 with an edge on the side end portion 130 of the base plate 2110 to which the fixing clip member 2140 is not fastened, the base plate 2110 and the It is preferred to join the roof 10. At this time, before fixing the base plate 2110 with the fixing clip member 2140, when welding of the base plate 2110 is performed, the base plate (at the time of fixing of the fixing clip member 2140) 2110) is pressed downward, cracks may occur in the welding part, and even after installation, a gap between the base plate 2110 and the upper surface of the roof 10 may occur, which is vulnerable to disturbance vibration due to disturbance. . That is, when fixing the base plate 2110 to the roof 10, pressing the base plate 2110 using the fixing clip member 2140 prior to welding of the base plate 2110 desirable.

In addition, the concave-convex member 2150 provided to correspond to the height of the concave-convex portion 11 is additionally installed on the concave-convex portion 12 formed between the concave-convex portions 11 of the roof 10, and the base plate is provided. By dispersing the load applied from 2110, a more robust special bottom plate structure 2000 can be formed. At this time, when the gap between the uneven portions 11 of the roof 10 (that is, the distance between adjacent uneven portions 11) is narrow, the base plate 2110 is excluding the uneven relief member 2150 It may be secured by using the fixing clip member 2140. However, if the installation of the fixing clip member 2140 on the upper surface of the roof 10 is not easy because the gap between the uneven parts 11 is far, the uneven relief member having a flat upper surface inside the recessed part 12 It is preferable to be provided with (2150), at this time, by installing the fixing clip member (2140) to the uneven relief member (2150), the perforation of the roof (10) for fixing the fixing clip member (2140) There is no need to perform it, and in addition, there is an advantage that the height of the base plate 2110 and the fixing clip member 2140 seated upward on the uneven portion 11 of the roof 10 can be matched. That is, when the uneven relief member 2150 has a wide gap between the uneven portions 11 and it is difficult to match the heights of the fixing clip member 2140 and the base plate 2110, the indentations of the roof 10 ( It is preferable to planarize the roof 10 by interposing in 12).

The linear moving means 2130 of the present invention is configured to facilitate the movement of the structure support 2120 to the upper side of the base plate 2110 installed on the roof 10, and is separate from a cylinder, conveyor or rail. Although it may be configured to include a driving device, if the configuration is for the operator to easily move the structure 20 installed on the structure pedestal 2120 with only a simple installation, modification is performed using various means without departing from the gist of the present invention. It will be possible.

Hereinafter, a preferred embodiment of the linear moving means 2130 of the present invention will be described with reference to the drawings.

<First Embodiment>

Referring to FIG. 2, the linear moving means 2130 according to an embodiment of the present invention includes at least one rail 2131 and the structure support 2120 provided on the upper surface 2111 of the base plate 2110. It is provided on the lower surface 320, is configured to include a roller portion (2132a) coupled to the rail (2131) and moved along the rail (2131), the operator can easily move the structure support (2120) have. Accordingly, since the installation of the structure 20 installed on the upper portion of the structure support 2120 can be performed on the ground, there is an advantage of shortening the time for installing the structure 20.

At this time, the rail 2131 is preferably made of a box shape with one side open in the longitudinal direction, and also, the roller portion 2132a extends downward from the lower surface of the structure support 2120. (2132a), and the horizontal fixing (2132b) extending in the horizontal direction from the ends of the vertical fixing (2132a), and formed at the ends of the horizontal fixing (2132b) in the open interior of the rail (2131) It may be configured to include a wheel 333 that is moved in the longitudinal direction. Here, the open side surface 311 of the rail 2131 is preferably disposed to be easy to install the structure support 2120 corresponding to the roller portion 2132a, the length of the rail 2131 Various modifications may be made to either side of both sides facing the direction.

<Example 2>

5 is a cross-sectional view showing a special bottom plate structure according to another embodiment of the present invention. Referring to FIG. 5, the linear moving means 2130 has a rail 2131 with an upper surface 311 in the longitudinal direction. This is made of an open box shape, the roller portion 2132a is formed at the ends of the vertical fixing portion 2132a and the vertical fixing portion 2132a extending downward from the lower surface 2122 of the structure support 2120. By being configured to include a wheel (2132c) that is moved in the longitudinal direction from the open inside of the rail (2131), after the structural support (2120) is seated on the upper portion of the base plate (2110), the rail (2131) ).

6 is an exemplary view showing a special bottom plate structure according to a modification of the present invention. Referring to FIG. 6, the special bottom plate structure 2000 according to an embodiment of the present invention includes the roof 10. A plurality of the base plate 2110 and the structure support 2120 may be installed on the upper portion, wherein a plurality of the base plates 2110 are disposed adjacent to each other in a direction orthogonal to the longitudinal direction of the rail 2131, The rails 2131 of the base plate 2110 form a pair that are arranged such that the open side faces opposite directions adjacent to each other, and a plurality of structure supports 2120 coupled to the upper side of the plurality of base plates 100 ) Of the roller portion 2132a is coupled to any one of the pair of adjacent rails 310a and 310b, and is coupled to alternate with each other in a direction orthogonal to the longitudinal direction of the rail 2131. A plurality of structure supports (200a, 200b) may be made to be coupled to the base plate (2110).

7 is a flow chart showing a method of installing the movable special bottom plate structure of the present invention, FIGS. 8 to 10 are exemplary views showing a special bottom plate structure according to the installation procedure of the movable special bottom plate structure of the present invention, 7 to 10, the installation method for installing the movable special bottom plate structure 2000 according to an embodiment of the present invention on a non-planar roof is an uneven relief step (S100), a clip hanger installation step (S200). , Base plate fixing step (S300), base plate welding step (S400) and structure support installation step (S500).

At this time, as shown in Figure 1, the uneven relief step (S100) includes a plurality of uneven parts 11 projecting upward and the recesses 12 formed between the plurality of uneven parts 11 The step of installing the uneven relief member 2150 which is interposed in the recessed portion 12 of the non-flat roof 10 forming a wave shape, and flattens the upper surface of the non-flat roof 10, and the clip hanger installation step ( S200) is a step of installing the clip hanger of the fixing clip member 2140 on the top surface of the non-flat plate roof 10, before the base plate fixing step (S300) of the uneven relief step (S100)-clip hanger It is preferable to be performed in the order of the installation step (S200).

Subsequently, as shown in FIG. 9, the base plate 2110 is seated on the top of the non-flat plate roof 10, and the fixing clip member 2140 is used at an outer edge of the base plate 2110. After fixing the base plate fixing step (S300) and the base plate fixing step (S300), a base plate welding step (S400) of welding between the fixing clip members 2140 is performed, so that the base plate 2110 is It is securely fixed on the roof 10.

At this time, the uneven relief step (S100) to the base plate welding step (S400), the worker can work on the roof 10, by installing a bulky structure on the ground, the uneven relief step (S100) to the base In the plate welding step (S400), the work can be performed without blocking the current of the high-voltage line located above.

Thereafter, the method for installing the movable special floor plate structure of the present invention, as shown in FIG. 10, using the linear moving means 2130 provided on the base plate 2110, the structure 20 is pre-installed structure It is performed by further comprising a step (S500) of installing the structure pedestal to install by moving the pedestal 2120 in a straight line.

At this time, by blocking the current of the high-voltage line during the structure support installation step (S500), the bulky structure 20 is short-circuited to the high-voltage line to prevent electric shock, and at this time, the strong structure support 2120 By moving and fixing the base plate 2110 from one side of the base plate to a location to be installed, it is possible to significantly reduce the working time of blocking the current flowing through the high-voltage wire provided above the roof.

As shown in FIG. 11, as an embodiment in which the present invention is provided, when a solar panel is to be provided on a non-flat roof such as a home roof of a railway station in which vibration and shaking are continuously generated, the module 1000 Is supported to support the photovoltaic panel and is positioned to absorb vibration, and may be provided to prevent damage to the photovoltaic panel. The accompanying drawings are only examples shown in order to explain the technical spirit of the present invention in more detail, and are not limited, and the scope of the present invention claimed in the claims is various, and is not limited. It will be described based on the fact that it is possible to perform the modification.

The present invention is provided to install a facility more stably in a place where a periodic or continuous vibration is generated, an uneven place, or a structurally unstable place, and is provided by fixing and supporting a facility, thereby replacing vibration and vibration that the facility may receive. It is a device that absorbs and reduces the impact and prevents damage.

For example, when a facility is installed in a place where periodic or continuous vibration occurs, such as railway history, it can be attached to the facility to attenuate vibration and prevent damage to the facility. It is installed when installing a solar panel on the home roof of the history to reduce the vibration received by the solar panel to prevent damage, and by using a material that does not flow current, it can prevent accidents caused by high-voltage wires. have.

Referring to FIG. 12, the module 1000 of the present invention includes a body portion including a base plate 110 and a pair of side plates 120 extending vertically upward from both ends of the base plate 110 in the left and right directions. (100), the elastic member fixing portion 210 extending upward from the center of the base plate 110, the elastic member 200 fitted to the elastic member fixing portion 210, the top of the elastic member 200 Is coupled to, it is formed recessed in the support portion 300 and a pair of the side plate 120 for supporting the external structure, the movement limiting groove 130 to regulate the vertical movement of the support portion 300 within a predetermined range ).

13 is a plan view of the main body 100, the main body 100 is preferably formed of the base plate 110 and the side plate 120 of a certain thickness or more, the main body 100 is U-shaped It is characterized in that it is formed integrally and is formed to be easy to manufacture the main body 100 using a molding frame. When the vibration transmitted to the facility occurs, the main body portion 100 has an effect of dispersing and absorbing vibration using the front surface of the main body portion 100, and the main body portion 100 is rubber, urethane It has high impact resistance, abrasion resistance, elasticity and tensile strength, and is formed of a shock-reducing material that does not flow electricity, absorbs vibration transmitted to the body portion 100, and can be installed in a place where high-pressure electricity flows. It is characterized by being formed.

As illustrated in FIG. 14, the elastic member fixing part 210 refers to a vertical extension extending from the base plate 110 of the main body portion 100, and may be formed by a plurality of one or more, and the base plate. It is appropriate to be formed at the center of (110) so that the facility can be centered. In addition, the circumference of the elastic member fixing part 210 may be formed according to the width of the base plate 110 or according to a user's setting, and is formed of an integral body formed of a shock-reducing material such as the body part 100. Can be. The elastic member fixing part 210 is formed to mount the elastic member 200, and the elastic member fixing part 210 may be formed according to the shape of the elastic member 200, and the elastic member The fixing part 210 is provided with one or more protrusions and depressions, and the protrusions and depressions may be formed in a form in which layers are intersected, and may be formed in a shape where screws are spirally intersected and the protrusions are crossed. Can. The number of protrusions and depressions may be selected by the user depending on the length of the spring or the frequency that the module 1000 wants to absorb.

15, the elastic member 200 has elasticity and is provided to absorb vibration transmitted up and down to the module 1000, and can be used irrespective of elasticity capable of absorbing vibration. . In one embodiment of the present invention, the elastic member 200 is a high-tensile spring, and may be a spring formed in the form of a circular or elliptical shape, but a spring reinforced in tension may be used by using a spring bent in a polygonal shape. The length of the spring is determined according to the height of the main body 100 (the length of the top end of the side plate 120 from the bottom plate 110), or the length is formed according to the frequency that the module 1000 wants to absorb. It may be, the diameter of the elastic member 200 is formed according to the distance between the pair of side plates 120 (the left and right length of the side plate 120), or the diameter of the elastic member fixing portion 210 It can be formed accordingly.

14 and 15, in one embodiment of the present invention, the elastic member 200 is a high-tensile spring formed by bending in a polygon, and the elastic member fixing part 210 is fitted with the elastic member 200 It is characterized in that it is formed of a nut-type tightening wrinkle so as to be coupled, and the spacing of the elastic member 200 can be formed according to the spacing and tension of the spring which is the elastic member 200. The circumference of the elastic member fixing part 210 may be used regardless of the shape, so that it may be formed in a polygonal bending shape of the same shape as the elastic member 200, but is formed in a circle as shown, so that the elastic member 200 ) Is appropriately fitted between the wrinkles formed in the elastic member fixing part 210.

The support part 300 is characterized in that it is formed by being coupled to the top of the elastic member 200 so as to move together according to the movement of the elastic member 200, the shape of the plate to support and support the external structure It may be formed to a predetermined thickness or more, and may be formed of an impact-reducing material such as the main body portion 100 to further distribute and absorb vibrations received by the module 1000. The support portion 300 is formed as a distance between the pair of side plates 120 (the left and right lengths of the side plate 120), the left and right cross-sections of the support portion 300 inscribe to the side plate 120 and move up and down. It can be made, it is formed to be more than the distance between the pair of the side plate 120 may be formed to limit the vertical movement of the support portion 300.

As shown in Figure 16, in one embodiment of the present invention, the base 300 is formed over a distance between the pair of the side plate 120, at this time, the smooth movement of the base 300 and up and down At the same time, so as to limit the vertical movement distance of the support portion 300, the main body portion 100 includes the movement limiting groove 130, which is formed by being recessed over a certain interval inside the inner surface of the side plate 120, respectively. Can be formed. The degree of depression of the movement limiting groove 130 may be formed along the left and right lengths of the supporting portion 300, and the supporting portion 300 is equal to or greater than the distance between the pair of side plates 120, the pair of the It may be formed to be left and right lengths equal to or less than the distance between the inner surfaces of the movement limiting grooves 130, and may be formed to be restricted by vertical movements by the jaws formed on the main body 100 side. The upper and lower heights of the movement limiting grooves 130 are suitably formed to be greater than or equal to the thickness of the support portion 300, and may be formed to a predetermined height according to the elastic force of the elastic member 200 or according to a user's use. The movement limiting groove 130 has an effect of limiting the vertical movement of the facility mounted on the support unit 300 due to an external impact so as not to be overextended or overconstricted so that the facility can be safely provided.

Therefore, as illustrated in FIG. 17, when the shock absorption of the module 1000 is described as an example of the present invention, when the facility is mounted on the base 300 and vibration is generated by the surrounding environment, The support portion 300 is moved in the vertical direction within the height of the movement limiting groove 130 by the elastic member 200, the elastic member 200 moves the vibration transmitted to the facility in the vertical direction Absorb. In addition, since the vibration is transmitted to the body portion 100 by the support portion 300, the vibration is distributed and relaxed along the shape (U-shape) of the body portion 100 formed of a shock-reducing material, It is possible to provide a device having an effect of alleviating vibration absorption more improved than a conventional device for absorbing vibration while moving up and down.

The module 1000 may be configured in plural, and modules adjacent to each other among the plurality of modules 1000 are referred to as a first module 1000a and a second module 1000b, respectively, and before and after the pair of side plates. In at least one of the direction and the left and right directions, it is characterized in that it forms a shape corresponding to each other to combine the adjacent first module (1000a) and the second module (1000b). The connecting parts 410, 420, and 430 are connected to the module 1000 back and forth, left and right, respectively, depending on the shape and size of the facility, or regardless of the shape of the place where the facility is installed, the module 1000 It is formed so as to be provided, the connection portion (410, 420, 430) may be formed by including a magnet or an adhesive, the following description of the connection portion (410, 420, 430) according to the direction and position to be extended Do it.

Referring to Figures 18 and 19, the connecting portion 410, 420, 430 may be formed of a body connecting portion 410 formed on the front and rear of the side plate 120, the front-rear direction of the pair of side plates On the outer surface of the furnace, adjacent first modules 1000a and second modules 1000b may be formed to be connected to each other. In addition, the connection part 400 may be formed of a support connection part 420 formed on the front and rear surfaces of the support part 300, and at both side ends in the front-rear direction of the support part 410, 420, 430. It may be formed in a shape corresponding to each other so as to combine the adjacent first module (1000a) and the second module (1000b), and includes the body connection portion 410 and / or the side plate connection portion 420, the connection portion 410 , 420, 430 ).

The body connection portion 410 is formed on the front and rear of the side plate 120, the support connection portion 420 is formed on the front and rear of the support portion 300, the body connection portion 410 and the The side plate connecting portion 420 is formed to be engaged with each other and to be fitted, or to the front and rear surfaces of the main body portion 100 and the base portion 300, regardless of whether they are formed in the form of clips, hooks, bands, etc., which can be combined with each other. It may be provided in a predetermined recessed space inward to be coupled to each other.

The body connection portion 410 is characterized in that the body portion 100 is coupled in a direction extending in one direction, the body connection portion 410 may be formed as a protrusion and a depression, respectively, to be fitted to each other. . The support connection part 420 is characterized in that the support part 300 is coupled in a direction extending in one direction, and the support connection part 420 may be formed as a protruding part and a recessed part to be fitted to each other. .

The body connecting portion 410 is fixed to the neighboring body portion 100 in close contact with each other, so that vibrations transmitted to the body portion 100 through the elastic member 200 by the facility are connected to and coupled to each other. Since each can be widely distributed while absorbing vibrations to the body part 100 to absorb vibration, there is an advantage of obtaining an improved cushioning effect. The support connection part 420 is to connect the adjacent support parts 300 in close contact with each other, and the support part 300 directly supports facilities, and the adjacent support parts 300 are fixed to each other in close contact with each other. By having the effect of increasing the mass of the elastic modulus supporting one facility, the vibrations transmitted while transmitting the weights due to the facility can be widely distributed and absorbed, thereby improving the cushioning effect. have. Accordingly, the body connection portion 410 and/or the base connection portion 420 are in close contact with each other and are defective, thereby effectively absorbing and dispersing vibration absorbed by the module 1000.

20 and 21, as another embodiment of the connecting portions 410, 420, and 430, the pair of side plates 120 may be formed of side plate connecting portions 430 formed on left and right outer surfaces, respectively. In the left and right outer surfaces of the pair of side plates 120, adjacent first modules 1000a and second modules 1000b may be connected to each other. Each side plate connecting portion 430 formed on the outer surface of the side plate 120 is engaged with each other and is formed to be fitted. The side plate connecting portion 430 is characterized in that the side plates 120 are connected to each other and are extended to each other, and the side plate connecting portions 430 may be formed as protrusions and depressions, and may be formed to be fitted to each other. In the form of a coupleable clip, hook, band, etc., each side plate 120 is provided in a predetermined recessed space inside the outer outer surface to be coupled to each other, so that the areas except the side plate connecting portion 430 are in close contact with each other to be connected Can be provided. This is because the main body 100 is in close contact with each other and is fixed in close contact with each other, so that the main body 100 receiving the vibration of the facility by the base 300 is rapidly connected to the neighboring main body 100. Since vibrations can be absorbed by dispersing widely and far apart while transmitting vibrations to each other, there is an advantage of obtaining an improved cushioning effect.

Referring to FIG. 22, the present invention is an assembly in which the modules 1000 are connected in plurality after determining the shape of the modules 1000, and the plurality of vibration and anti-vibration modules 1000 include the structures 20. ) Is provided on each of the plurality of support legs 21, but connected to each other in at least one of the front and rear directions or the left and right directions according to the number and arrangement of the plurality of support legs 21 of the structure 20 , By absorbing the vibration generated in each of the plurality of support legs 21 according to the movement of the structure 20 in a plurality of modules connected to each other, converging the vibration frequency generated in each of the plurality of support legs 21 It is characterized by letting.

The module 1000 may be formed to have different widths or heights according to the purpose or the shape of the facility to be supported, and may also include a plurality of modules including the first module 1000a and the second module 1000b. By combining the modules using the connection parts 410, 420, and 430 in the direction of one or more of the front and rear and right and left in accordance with the use and shape, the vibration absorption effect is not limited to the place and environment where the facility is installed It is characterized in that it can be installed while raising the maximum.

Accordingly, the module 1000 may form an assembly according to size, use, and location, and the body connection part 410, the support connection part 420, and the side plate connection part, which are the connection parts 410, 420, and 430 430) by using any one or more of the first module (1000a) and the second module (1000a) can be combined, and the assembly using this effectively absorbs vibration to suit the purpose and shape and can be tightly coupled to each other Can be configured.

Since the module 1000 according to the present invention is formed as a U-shaped integral type including the elastic member connecting portion 140, the process of assembling the device is very small, thereby improving productivity, and the supporting portion 300 Since it is formed so that it can move along the side surface of the main body 100, there is no need for a separate member for fixing the movement of the elastic member 200, thereby simplifying the manufacturing process.

In addition, the body portion 100 is formed of a shock-reducing material and the base portion 300 is formed to be in contact with the body portion 100, the facility of the facility by the vertical movement of the elastic member 200 Since vibration can be absorbed and absorbed at the same time, the entire body of the body 100 can be absorbed by dispersing and absorbing the vibration, so there is an advantage of providing a device with excellent vibration absorption, and the support is formed by forming the movement limiting groove 130. Since it is possible to limit the up and down movement of the facility mounted on the unit 300, it is possible to minimize damage to the facility and protect it from vibration.

In addition, the main body portion 100 is formed of a material that is not electrically conducting, so it can be installed in a place where high-voltage wires are constructed, and the module 1000 is extended in the longitudinal direction or the width direction by using the connecting portion. Since it is possible, regardless of the installation location or the size to be provided, it is possible to install by using a plurality of modules of a single size, so it has an advantage in production and installation.

As described above, in the present invention, it has been described by specific matters such as specific components, etc. and limited embodiment drawings, which are provided to help a more comprehensive understanding of the present invention, and the present invention is limited to the above-described one embodiment. No, those of ordinary skill in the art to which the present invention pertains are capable of various modifications and variations from these descriptions.

Accordingly, the spirit of the present invention should not be limited to the described embodiments, and should not be determined, and all claims that are equivalent or equivalent to the scope of the present invention as well as the scope of the claims described below will be said to belong to the scope of the spirit of the invention. .

10: non-flat roof 11: irregularities
12: recess 20: structure
21: support leg
2000: Special bottom plate structure
2100: base plate
2111: top 2112: bottom
2113: outer end 2113a: outer end edge
2120: structure support
2121: Top 2122: Bottom
2123: clasp hole
2130: linear moving means
2131: Rail 2131a: Open surface
2132: roller portion 2132a: vertical fixing
2132b: Level fixing 2132c: Wheel
2140: Fixed clip member
2141: clip hanger 2142: clip
2143: Insulation block
2150: Unevenness relief member
B: Welding bead W: Wire
1000: module
1000a: First module 1000b: Second module
100: body portion 110: base plate
120: side plate 130: movement restriction groove
200: elastic member 210: elastic member fixing portion
300: base
400: connecting portion 410: body connecting portion
420: support connection portion 430: side plate connection portion

Claims (7)

In the vibration and anti-vibration module interposed between the upper surface of the structure support and the support leg of the structure fixedly installed above the structure support,
A base plate fixedly installed on the upper surface of the structure support;
A pair of side plates extending upwardly from one side end portion of the base plate;
A support portion disposed to be spaced a predetermined distance above the base plate and fixed to be supported between the pair of side plates, wherein a support leg of the structure is installed on an upper surface; And
Includes; interposed between the base plate and the support portion, to reduce the vibration in the vertical direction of the support portion; includes,
The inner surface of the pair of side plates further includes a movement limiting groove recessed so that both side ends of the support portion are coupled,
The movement limiting groove is formed to achieve a predetermined height in the vertical direction, vibration and anti-vibration module, characterized in that to limit the movement in the vertical direction of the support portion within a predetermined height.
According to claim 1,
An elastic member fixing portion extending upward from the center of the base plate;
Including more,
The elastic member is vibration and vibration prevention module, characterized in that fitted to the elastic member fixing.
delete According to claim 1,
When a plurality of the vibration and anti-vibration modules are located adjacent to each other,
A connecting portion extending in at least one of the front-rear direction and the left-right direction of the pair of side plates and formed in a shape corresponding to portions adjacent to each other to be joined;
Vibration and anti-shake module, characterized in that it further comprises.
According to claim 4,
The connecting portion,
A body connection part formed on the front and rear surfaces of the pair of side plates and engaged with each other to be fitted to be coupled to the vibration and anti-vibration modules adjacent to the front and rear directions of the pair of side plates;
A support connection part formed on the front and rear surfaces of the support part and engaged with each other to be fitted so as to engage with the vibration and anti-vibration module adjacent in the front-rear direction of the support part; And
A side plate connecting portion formed on each outer side of the pair of side plates and engaged with each other to be fitted to be coupled to the vibration and anti-shake module adjacent to the outer side in the left and right directions of the pair of side plates;
Vibration and anti-vibration module, characterized in that it comprises any one or more of.
An assembly in which the plurality of vibration and anti-vibration modules of claim 4 are connected,
The plurality of vibration and anti-vibration modules,
Each of the plurality of support legs of the structure is provided,
Depending on the number and arrangement of the plurality of support legs of the structure, it is coupled to each other and extended by the connecting portions formed in at least one direction selected from the front-rear direction and the left-right direction,
Vibration and anti-vibration module characterized by converging the vibration frequencies generated in each of the plurality of support legs by absorbing the vibrations generated in each of the plurality of support legs due to the movement of the structure in a plurality of modules connected to each other. Assembly.
A special bottom plate structure with the vibration and anti-vibration module of claim 1 mounted on top.

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