KR102145301B1 - Mount assembly for vibration isolation - Google Patents

Abstract

The present invention relates to a vibro-isolating mount assembly. The vibro-isolating mount assembly includes: a buffer unit offsetting forward/backward/left/right vibration displacement in four directions as connection bars branched in a cross-shaped structure are placed above and below and a wire coil of a concentric circle structure is mutually fixed to each of the connection bars by being integrated therewith; a base plate mutually fixed to the connection bar placed in a lower part of the buffer unit to be attached to the ground; a support plate mutually fixed to the connection bar placed in an upper part of the buffer unit to support a heavy facility; a rubber rod fixed closely to each of four corners between the base plate and the support plate through a combination piece to absorb micro vibration displacement; and an elastic coil placed in the center between the base plate and the support plate to support the load as well as offset vertical vibration placement. On the base plate and the support plate, a first groove part for inserting the connection bars and a second groove part for guiding the insertion of the wire coil are formed alternately. As the connection bars and the wire coil are inserted into the first and second groove parts, the elastic coil is attached to the surfaces of the base plate and the support plate without the interference of the connection bars and the wire coil. Thus, the responsiveness of load and vertical vibration displacement can be secured.

Description

Anti-vibration mount assembly {MOUNT ASSEMBLY FOR VIBRATION ISOLATION}

The present invention relates to a vibration-proof mount assembly that is installed under a plurality of heavy equipment such as a switchboard to effectively vibration-proof vibrations and shocks caused by external forces or earthquakes, and more particularly, through an elastic coil disposed in the center. In addition to canceling the lower vibration displacement, the front/rear/left/right vibration displacement can be effectively canceled through the wire coils arranged in each of the four directions, and the vibration displacement due to the low vibration can be absorbed and canceled through the rubber rod. It relates to the assembly of the anti-vibration mount so that it is possible.

In general, dustproofing the entire building is the best means to secure the seismic performance of the entire building, but there is a problem of low economic efficiency to be applied to protect small-scale telecommunication facilities in the building.

Therefore, there is no need to make the entire building dust-proof, and dust-proof devices are applied to important electrical and communication facilities installed on some floors or in limited spaces.

The vibration isolator serves to reduce the seismic load transmitted to the upper structure by smoothly moving horizontally when the earthquake load is applied, and has a mechanism similar to the vibration isolator used in buildings.

Currently, the vibration isolator produced at home and abroad is a very expensive product, and the product cost is a problem when it is actually applied from the user's point of view. The performance of the anti-vibration device is adopted for the purpose of preventing the normal operation and overturning of the upper telecommunication equipment in the event of an earthquake.To meet this vibration-proof performance, low-friction bearing products used in precision machinery and products with expensive manufacturing processes are applied. Actually.

Considering the importance of recent telecommunication facilities and information data and the risk of earthquake disasters that are constantly increasing around the Korean Peninsula, the demand for vibration isolators is gradually increasing. The development of low-cost products is urgent.

In recent years, large-scale earthquakes in Japan, Taiwan, and China, which are the neighboring countries of the Korean peninsula, caused great damage to electricity, communication facilities, and electronic facilities. It is on an increasing trend.

As industrialization accelerates and develops, devices that are sensitive to vibrations related to electronics and communications have been developed and used, and when electronic and communications-related equipment are damaged, the resulting economic loss and social damage are enormous. Therefore, there is an increasing need for development to prevent earthquake damage to major electronics, information, communication facilities, and expensive cultural properties, exhibits, and medical equipment.

In the case of the currently developed and commercialized product, it is an expensive product, and there is a problem that the initial investment cost is enormous to prepare for earthquakes.

As a background technology of the present invention, there is a three-way seismic stopper for a vibration isolating device as Korean Patent No. 1671717.

However, the conventional background technology has a large vibration-proof effect in the vertical displacement, but it is difficult to expect effective vibration-proofing in the radial direction, and there is a problem of the risk of damage to the bearing due to left-right vibration.

Republic of Korea Patent Registration No. 1671717

The present invention was conceived in consideration of the above problems, and the first object of the present invention is to be installed in the lower part of a heavy equipment such as a switchboard to prevent external forces or earthquakes in the front/rear/left/right directions as well as vertical directions. It is to provide a vibration-proof mount assembly that can effectively vibration-proof the vibration and shock caused by.

The second object of the present invention is to effectively composite offset the front/rear/left/right vibration displacement through the wire coils arranged in four directions, as well as offset the upper/lower vibration displacement through an elastic coil disposed in the center. In addition, it is to provide a vibration-proof mount assembly that can eliminate the resonance phenomenon by absorbing the vibration displacement by the micro-vibration through the rubber rod.

According to the features for achieving the above object, the first invention relates to a vibration-proof mount assembly, and for this purpose, a connecting rod branching in a cross-shaped structure is placed up and down, and a wire coil of a concentric circle structure is integrated with each other on each branched connection rod A buffer unit that is fixed to the front/rear/left/right vibration displacement in four directions; and a base plate that is fixed to each other with a connecting rod disposed under the buffer unit to be in close contact with the ground; and, of the buffer unit A support plate that is fixed to each other with a connecting rod disposed at the top to support heavy equipment; and a rubber rod that is fixed with a coupling piece in proximity to four corners between the base plate and the support plate to absorb microscopic vibrational displacement; And , An elastic coil disposed in the center between the base plate and the support plate to support a load and to offset the vertical vibration displacement; wherein the base plate and the support plate include a first groove portion into which a connecting rod can be inserted; , The second groove that can guide the insertion of the wire coil is formed to cross, and the elastic coil is the support plate without interference between the connecting rod and the wire coil as the connecting rod and the wire coil are inserted into the first groove and the second groove. And the base plate are in close contact with the surface to secure the response of load and vertical vibration displacement, and the elastic coil is composed of a barrel type spring to minimize buckling, but in the axial direction of the barrel type spring It is characterized in that a helper spring to supplement the barrel-type spring is further disposed.

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In the third invention, in the first invention, the wire coil is configured to be fixed to at least two of each connecting rod divided in four directions according to the weight of the heavy equipment.

In the fourth invention, in the first or third invention, each wire coil is plasticized by a critical load by inserting a polyurethane block along the axial direction to buffer the vertically applied load and impact. It characterized in that it is configured to prevent.

In the fifth invention, in the first invention, an insertion hole for mounting a pad is further formed on the upper surface of the base plate and the bottom surface of the support plate, wherein each of the pads further comprises an insertion tube inserted into the insertion hole. It is characterized.

According to the anti-vibration mount assembly according to the present invention, as well as offsetting the upper/lower vibration displacement through the elastic coil disposed in the center, the front/rear/left/right vibration displacement is effectively prevented through the wire coils respectively disposed toward four directions. There is an effect that can be complex offset.

In addition, vibration displacement due to micro-vibration is absorbed through the rubber rod, thereby eliminating the resonance phenomenon.

In addition, it is possible to prevent slipping through a pad coupled to the base plate and the support plate, and there is an effect that it can be easily leveled through the pad overlapping the support plate even on the ground with different heights.

1 is a configuration diagram showing a switchboard to which the anti-vibration mount assembly according to the present invention is applied,
2 is a front view of the anti-vibration mount assembly according to the present invention,
3 is a plan view showing a buffer unit installed on the base plate in FIG. 2, an elastic coil and a rubber rod;
Figure 4 is a front view and a plan view showing the buffer unit in Figure 2,
5 is a plan view showing first and second grooves formed in the base plate and the support plate;
6 is a front view showing an elastic coil installed between the base plate and the support plate.

The following objects, other objects, features, and advantages of the present invention will be easily understood through the following preferred embodiments related to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms.

Rather, the embodiments introduced herein are provided so that the disclosed content may be thorough and complete, and the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

The embodiments described and illustrated herein also include complementary embodiments thereof.

In this specification, the singular form also includes the plural form unless otherwise specified in the phrase. As used in the specification, "comprise" and/or "comprising" does not exclude the presence or addition of one or more other components.

Hereinafter, the present invention will be described in detail with reference to the drawings. In describing the specific embodiments below, various specific contents have been prepared to more specifically describe the invention and to aid in understanding. However, a reader who has knowledge in this field enough to understand the present invention can recognize that it can be used without these various specific contents. In some cases, it should be noted in advance that parts that are commonly known in describing the invention and are not significantly related to the invention are not described in order to avoid confusion in describing the invention.

Hereinafter, the vibration-proof mount assembly according to the present invention will be described in detail together with the accompanying drawings.

1 is a configuration diagram showing a switchboard to which the anti-vibration mount assembly according to the present invention is applied, and FIG. 2 is a front view of the anti-vibration mount assembly according to the present invention, and FIG. 3 is a buffer unit installed on a base plate in FIG. 2, an elastic coil and a rubber rod 4 is a front view and a plan view showing the buffer unit in FIG. 2, FIG. 5 is a plan view showing first and second grooves formed in the base plate and the support plate, and FIG. 6 is a view of the base plate and the support plate. It is a front view showing an elastic coil installed between.

As shown in FIGS. 1 to 6, the present invention relates to a vibration-proof mount assembly that is installed under a heavy equipment such as a switchboard 200 to effectively vibration-proof vibrations and shocks caused by external forces or earthquakes.

Furthermore, the present invention can effectively composite offset the front/rear/left/right vibration displacement through the wire coils respectively disposed toward four directions as well as canceling the upper/lower vibration displacement through the elastic coil disposed in the center. In addition, it relates to a vibration-proof mount assembly that can eliminate the resonance phenomenon by absorbing the vibration displacement by the micro-vibration through the rubber rod.

The anti-vibration mount assembly 100 according to the present invention is largely composed of five parts, which are composed of a buffer unit 10, a base plate 20a, a support plate 20b, a rubber rod 30, and an elastic coil. do.

The buffer unit 10 functions to cancel up/down vibration displacement as well as front/rear/left/right vibration displacement.

As shown in FIG. 4, the buffer unit 10 is integrally fixed to each other to each of the branched connecting rods 11 with the connecting rods 11 branching in a cross-shaped structure up and down, It is configured to offset rear/left/right vibration displacement in 4 directions.

Here, the connecting rod 11 is branched along the four-axis direction in a "+" shape, and the connecting rod 11 integrates the wire coils 12 arranged along the four directions with each other, and together with external force or earthquake It functions to disperse and transmit vibration and shock to each wire coil 12.

The wire coil 12 is for offsetting the vertical vibration displacement as well as the vibration displacement in the radial direction, and is connected through each connecting rod 11 branched in the four-axis direction.

The arrangement structure of the wire coil 12 is that the front/rear wire coils 12 or the left/right wire coils 12 arranged on the same horizontal plane are synchronized with each other while securing space in the center area. The pair of wire coils 12 is configured to compositely cancel the vibration displacement before/after/left/right.

These wire coils 12 are connected one by one to the branched connecting rods in an embodiment, but at least two or more can be configured to be fixed to each connecting rod 11 branched in four directions according to the weight of the heavy equipment. to be.

In addition, each wire coil 12 can prevent plasticity of the wire coil 12 due to a critical load by inserting a polyurethane block 121 along the axial direction to buffer the load and impact applied vertically. It can be configured to be.

Meanwhile, the base plate 20a is in close contact with the ground, and is piece-coupled with the connecting rod 11 disposed under the buffer unit 10.

In addition, the support plate 20b is piece-coupled with the connecting rod 11 disposed on the upper portion of the buffer unit 10 to support heavy equipment.

As shown in FIG. 2, an insertion hole 23 through which a pad 50 may be mounted may be further formed on the upper surface of the base plate 20a and the lower surface of the support plate 20b.

Each of the pads 50 is further formed with an insertion tube 51 inserted into the insertion hole 23, and when the insertion tube 51 is inserted into the insertion hole 23, the base plate 20a or the support plate ( Provide a structure that can be fixed on the plane of 20b) without being separated.

In addition, the pad 50 coupled to the upper surface of the base plate 20a functions to adjust the height, and the pad 50 has a function of leveling the heavy equipment by adjusting the height according to the number of stacked. do.

In addition, the pad 50 coupled to the bottom surface of the support plate 20b is for anti-slip, and a plurality of recessed hemispherical grooves (not shown) may be formed on the surface to increase the anti-slip effect.

In addition, each of the pads 50 described above may also function as an additional function of absorbing micro-vibration in addition to preventing slipping and adjusting height.

In addition, as shown in Figure 5, the base plate (20a) and the support plate (20b) is a first groove (21) through which the connecting rod (11) can be inserted, and a first through the wire coil (12) that can guide insertion. The two grooves 22 are formed to cross each other.

These first and second grooves 21 and 22 have a function to effectively transmit vibrations and shocks due to external forces or earthquakes transmitted to the support plate 20b by increasing the contact area to the buffer unit 10. When the elastic coil is installed, it may serve as an additional function of eliminating interference of the buffer unit 10.

On the other hand, the elastic coil is disposed in the center between the base plate 20a and the support plate 20b to support a load, and also functions to offset vertical vibration displacement.

As shown in FIG. 3, the elastic coil is interfering with the connecting rod 11 and the wire coil 12 as the connecting rod 11 and the wire coil 12 are inserted into the first groove 21 and the second groove 22. Without being in close contact with the support plate 20b and the base plate 20a on the surface, it is possible to secure the responsiveness of the load and vertical vibration displacement.

In addition, the elastic coil is preferably composed of a barrel-type spring (40a) to eliminate buckling, as shown in Figure 6, and also to supplement the barrel-type spring (40a) in the axial direction of the barrel-type spring (40a). The helper spring (40b) may be arranged to more effectively cancel the vertical vibration displacement along with the load bearing capacity.

The above-described helper spring 40b prevents sagging due to weakening of the elastic force and support force of the wire coil 12 and the barrel type spring 40a as time passes by the load of the heavy equipment, and as a result, the barrel type spring 40a And it can serve as an additional function to more effectively exert the load bearing capacity and vibration canceling function of the wire coil 12.

In addition, a rubber rod 30 is further installed between the base plate 20a and the support plate 20b and fixed with a coupling piece to be close to each of the four corners to absorb the microscopic vibrational displacement.

The rubber rod 30 is combined with the pad 50 coupled to the base plate 20a and the support plate 20b to effectively absorb the resonance of the amplitude and the vibration frequency as well as the fine vibration displacement.

Here, the rubber rod 30 and the pad 50 may be made of any one of rubber, synthetic rubber, polyurethane, acrylic rubber, urethane rubber, silicone rubber, fluorine rubber, and polybutatiene rubber.

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

10: buffer unit 11: connecting rod 12: wire coil
121: polyurethane block
20a: base plate 20b: support plate
21: first groove 22: second groove
23: insertion hole
30: rubber rod
40a: barrel spring 40b: helper spring
50: pad 51: insertion tube
100: anti-vibration mount assembly
200: switchboard

Claims (5)

With the connecting rod 11 branching in a cross-shaped structure up and down, the wire coil 12 of a concentric circle structure is integrally fixed to each branched connecting rod 11 to offset the front/rear/left/right vibration displacement in four directions. A buffer unit 10;
A base plate (20a) fixed to each other with the connecting rod (11) disposed below the buffer unit (10) and in close contact with the ground;
A support plate (20b) fixed to each other with the connecting rod (11) disposed on the upper portion of the buffer unit (10) to support heavy equipment;
A rubber rod 30 that is fixed with a coupling piece close to each of the four corners between the base plate 20a and the support plate 20b to absorb microscopic vibrational displacement;
Consisting to include; an elastic coil disposed in the center between the base plate 20a and the support plate 20b to support a load and offset vertical vibration displacement,
The base plate (20a) and the support plate (20b) have a first groove (21) into which the connecting rod (11) can be inserted, and a second groove (22) through which the wire coil (12) is inserted. Is formed to be intersecting,
The elastic coil is the support plate 20b without interference between the connecting rod 11 and the wire coil 12 as the connecting rod 11 and the wire coil 12 are inserted into the first groove 21 and the second groove 22. ) And the base plate (20a) in close contact on the surface to secure the response of the load and vertical vibration displacement,
The elastic coil is composed of a barrel-type spring (40a) to minimize buckling, but a helper spring (40b) to supplement the barrel-type spring (40a) is further disposed in the axial direction of the barrel-type spring (40a) Anti-vibration mount assembly, characterized in that the.
delete The method of claim 1,
The wire coil 12 is a vibration-proof mount assembly, characterized in that it is configured to be fixed at least two of each connecting rod (11) branched in four directions according to the weight of the heavy equipment.
The method according to claim 1 or 3,
Each of the wire coils 12 is configured to prevent plasticity of the wire coils due to critical loads by inserting a polyurethane block 121 along the axial direction to buffer the load and impact applied vertically. Anti-vibration mount assembly, characterized in that.
The method of claim 1,
In the upper surface of the base plate 20a and the lower surface of the support plate 20b, an insertion hole 23 for mounting the pad 50 is further formed,
Each of the pads (50) is a vibration-proof mount assembly, characterized in that it further comprises an insertion tube (51) inserted into the insertion hole (23).

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