KR102292066B1 - Earthquake-proof generator capable of conotrolling vibration - Google Patents

Abstract

The present invention provides an earthquake-proof generator for controlling vibration, which comprises: a bed frame where a driving body or a driven body of a machine system is seated on an upper surface; a plurality of reduction devices coupled to a lower surface of the bed frame to reduce transmission of vibration generated by the driving body or the driven body to a floor surface where the driving body or the driven body is installed; a plurality of stoppers installed on one side or the opposite side of the bed frame for restraining vertical and horizontal displacement of the bed frame by the vibration of the driving body or the driven body; a base member fixated and installed on the floor surface where the machine system is installed to support the plurality of reduction devices; and a support rail supporting the plurality of stoppers.

Description

Vibration-controlled seismic generator

The present invention relates to a vibration-controlling seismic generator of a mechanical system, and more particularly, it can prevent damage to the mechanical system and the floor by damping vibrations generated during operation of various mechanical systems transmitted to the floor on which the mechanical system is installed. It relates to a vibration control seismic generator of a mechanical system.

In general, mechanical systems such as commercial generators, emergency generators that can be used in vehicles or marine vessels, machine tools or industrial machines that can process and manufacture various products, and power devices that provide driving power to operate other mechanical devices are , it can be driven by directly applying electricity or driven by a driven body that is driven by receiving power from the driving body.

In such a mechanical system, vibration due to rotation occurs when a driven body or a driving body that transmits power to the driven body is driven, and a reducer, a shaft, a coupling, a bearing, and a crankshaft connected to the driven body or the rotating shaft of the driven body, etc. Not only is it frequently damaged, but there is a problem in that cracks and breakages occur in the ground surface where the mechanical system is fixed, such as the ground, the floor of a building, and the floor of a vehicle or ship. It dampens vibrations that occur during operation.

In general, mechanical systems such as commercial generators, emergency generators that can be used in vehicles or marine vessels, machine tools or industrial machines that can process and manufacture various products, and power devices that provide driving power to operate other mechanical devices are , it can be driven by directly applying electricity or driven by a driven body that is driven by receiving power from the driving body.

In such a mechanical system, vibration due to rotation occurs when a driven body or a driving body that transmits power to the driven body is driven, and a reducer, a shaft, a coupling, a bearing, and a crankshaft connected to the driven body or the rotating shaft of the driven body, etc. Not only is it frequently damaged, but there is a problem in that cracks and breakages occur in the ground surface where the mechanical system is fixed, such as the ground, the floor of a building, and the floor of a vehicle or ship. It dampens vibrations that occur during operation.

According to one aspect of the present invention, a vibration-controlled seismic generator is provided. The vibration-controlled seismic generator is a bed frame on which a driving body or a driven body of a mechanical system is seated on an upper surface, and vibration generated in the driving body or driven body is transmitted to the bottom surface on which the driving body or driven body is installed. A plurality of damping devices coupled to the lower surface of the bed frame, installed on one side or the opposite side of the bed frame to limit the vertical and front-rear displacement of the bed frame due to vibration of the driving body or driven body It may include a plurality of stoppers, a base member that is fixedly installed on a floor surface on which the mechanical system is installed to support the plurality of damping devices, and a support rail for supporting the plurality of stoppers.

The plurality of damping devices includes a first damping device supported by a first base member and a second damping device supported by a second base member, the plurality of stoppers comprising a first stopper and a second stopper; , a first supporting member supporting the first stopper, a second supporting member supporting the second stopper, and a first supporting rail to which the first supporting member and the second supporting member are fixed.

The plurality of damping devices further include a third damping device supported by a third base member, the plurality of stoppers further comprising a third stopper, a third support member supporting the third stopper, and the third A second support rail to which the second support member and the third support member are fixed, and a second support rail having a length different from that of the first support rail may be included.

The plurality of damping devices further include a fourth damping device supported by a fourth base member, the plurality of stoppers further comprising a fourth stopper, and a fourth support member supporting the fourth stopper, the fourth stopper It may include a second support rail to which the third support member and the fourth support member are fixed, and a reinforcing member connecting the first support rail and the second support rail in a lateral direction.

Further comprising a vertical member spaced apart from the side of each of the support rails, each of the stoppers, one end passing through the coupling hole of the vertical member to form a gap with the side surface of the support rail, the other end of the Including a bolt fixed to the support member, the inner diameter of the coupling hole may be formed larger than the outer diameter of the bolt.

The plurality of damping devices may include at least one of a spring and a damper.

The vibration control device is a bed frame on which the driven body and the driving body of the mechanical system are seated on the upper surface, and the vibration generated from the driven body and the driving body is transmitted to the bottom surface where the driven body and the driving body are installed. A plurality of damping devices disposed on the lower surface of the bed frame, and installed on one side or the opposite side of the bed frame to limit the horizontal displacement of the bed frame due to vibration of the driven body and the driving body It may include a plurality of stoppers, a first support rail supporting at least one of the plurality of stoppers, and a second support rail supporting at least another one of the plurality of stoppers.

The plurality of damping devices comprises a first damping device and a second damping device supported by the first base member, a third damping device supported by the second base member, a fourth damping device, and a fifth damping device; a first distance between the first attenuation device and the second attenuation device, a second distance between the second attenuation device and the third attenuation device, and a distance between the third attenuation device and the fourth attenuation device. The third distance and the fourth distance between the fourth damping device and the fifth damping device may have different lengths, respectively.

The mechanical system includes a generator, the driven body includes an alternator and a radiator, the driving body includes an engine, and the first damping device and the second damping device are the lower and right sides of the left end of the alternator. The third damping device and the fourth damping device are disposed under the lower left end cylinder and the right end cylinder of the engine, and the fifth damping device is disposed under the radiator. can

According to an embodiment of the present invention made as described above, there is no need for a separate construction for fixing the mechanical system to the floor surface by modularizing the damping device and the frame for damping the vibration of the mechanical system, and also, the weight of the mechanical system The number and spacing of the springs or dampers constituting the damping device may be set according to the distribution and the intensity distribution of the generated vibration.

Accordingly, it is possible to implement a vibration-controlled seismic generator having the effect of efficiently distributing the overall weight of the mechanical system and the intensity of vibration to increase the efficiency and performance of the mechanical system and reduce the installation cost. In addition, it is possible to implement a vibration-controlled seismic generator capable of preventing damage to the mechanical system and the floor by damping the vibration generated during operation of the mechanical system from being transmitted to the floor where the mechanical system is installed.

In addition, it is possible to attenuate vibrations in various directions, such as the left-right direction, the front-rear direction, and the vertical direction of the mechanical system.

In addition, when an earthquake occurs, even if vibration is generated from the base member via the support rail and the support member, the bolt damps the vibration with a gap in the gap of the coupling hole, so that an earthquake-resistant design is possible.

1 is a side view schematically showing a mechanical system and a vibration-controlled seismic generator according to an embodiment of the present invention.
Figure 2 is a perspective view showing a vibration-controlled seismic generator according to an embodiment of the present invention and the bed frame of the mechanical system.
3 is a perspective view illustrating the bed frame in FIG. 2 removed.
4 and 5 are enlarged perspective and cross-sectional views of a support member, a stopper, and a damping device of the vibration control device of FIG. 2 .
6 is an enlarged view of a state in which the bolt of the stopper of the vibration-controlled seismic generator according to an embodiment of the present invention is penetrated and coupled to the coupling hole.

Hereinafter, several preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Examples of the present invention are provided to more completely explain the present invention to those of ordinary skill in the art, and the following examples may be modified in various other forms, and the scope of the present invention is as follows It is not limited to an Example. Rather, these embodiments are provided so as to more fully and complete the present disclosure, and to fully convey the spirit of the present invention to those skilled in the art. In addition, in the drawings, the thickness or size of each layer is exaggerated for convenience and clarity of description.

The terminology used herein is used to describe the embodiments, and is not intended to limit and/or limit the disclosed invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In this specification, terms such as "comprises" or "have" are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist, but one or more other features It does not preclude the possibility of the presence or addition of figures, numbers, steps, operations, components, parts, or combinations thereof.

As used herein, terms including ordinal numbers such as “first”, “second”, etc. may be used to describe various components, but the components are not limited by the terms, and the terms are It is used only for the purpose of distinguishing a component from other components. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the drawings schematically illustrating ideal embodiments of the present invention. In the drawings, variations of the illustrated shape can be expected, for example depending on manufacturing technology and/or tolerances. Accordingly, embodiments of the inventive concept should not be construed as limited to the specific shape of the region shown in the present specification, but should include, for example, changes in shape caused by manufacturing.

1 is a side view schematically showing a mechanical system and a vibration-controlled seismic generator according to an embodiment of the present invention, and Figure 2 is a perspective view showing a vibration-controlled seismic generator according to an embodiment of the present invention and a bed frame of the mechanical system 3 is a perspective view illustrating the removal of the bed frame in FIG. 2, and FIGS. 4 and 5 are perspective and cross-sectional views showing enlarged support members, stoppers, and damping devices of the vibration control seismic generator of FIG. 2, FIG. 6 is an enlarged view of a state in which the bolt of the stopper of the vibration control earthquake-resistant generator according to an embodiment of the present invention is penetrated through the coupling hole.

1 to 6 , the vibration-controlled seismic generator according to an embodiment of the present invention may include a bed frame 10 , a damping device 20 , a stopper 40 , and a support rail 11 .

The bed frame 10 provides power so that the driven objects A and F can be driven by using power transmission members such as the driven objects A and F of the mechanical system and the couplings C1 and C2 on the upper surface. It may be a structure on which one or more of the actuators E are seated. In addition, the support rail 11 is a plurality of base members (50a, 50b, 50c, 50d, 50e, 50f, 50g, 50h, 50i, 50j) may be fixedly installed to support the plurality of damping devices 20 and the support rail 11 .

Here, for example, when the mechanical system is a commercial generator or an emergency generator, the driving body E may include an engine, and the driven bodies A and F are rotationally driven by the engine to generate electricity. Alternator) and radiators.

In addition, when the driven body (A) is directly driven by receiving electricity from the outside, only the driven body (A) may be installed on the upper surface of the bed frame (10).

The bed frame 10 supports the driven body A, F and the driving body E of the above-described mechanical system, and the supporting rail 11 may include a plurality of supporting rails 11a, 11b, 11c, 11d. The bed frame 10 and the plurality of support rails 11a, 11b, 11c, 11d may be a kind of frame structure having adequate strength and durability to sufficiently support the damping device 20 and the stopper 40. have.

For example, the bed frame 10 and the support rail 11 are an integral injection structure, a casting, or a frame formed by welding or connecting plates, wires, pipes, vertical members, horizontal members, and inclined members of various shapes to each other. It can be a structure. However, the bed frame 10 and the support rail 11 are not necessarily limited to FIG. 1 , and structures having a wide variety of shapes, such as a pad shape capable of supporting the above-described components, may be applied.

The damping device 20 attenuates vibrations generated in the driven body (A, F) or the driving body (E) during operation of the mechanical system, and the driven body (A, F) or the driving body (E) is installed. In order to prevent the vibration from being transmitted to the floor surface, it may be installed on the lower surface of the bed frame 10 to correspond to the seating positions of the driven bodies A and F and the driving body E.

The vibration control device may include a plurality of damping devices 20 . That is, the damping device 20 includes a first damping device 20a, a second damping device 20b, a third damping device 20c, a fourth damping device 20d, a fifth damping device 20e, and a sixth It may include an attenuation device 20f, a seventh attenuation device 20g, an eighth attenuation device 20h, a ninth attenuation device 20i, and a tenth attenuation device 20j.

The plurality of damping devices 20 are arranged in two rows at intervals along the longitudinal direction of the bed frame 10 and the support rail 11 at positions corresponding to the seating positions of the driven bodies A, F and the driving body E. can be placed. The damping device 20 may include at least one of a spring and a damper.

The plurality of damping devices 20 may all be configured as springs, or may all be configured as dampers. The plurality of damping devices 20 may be formed by a combination of a spring and a damper. In addition, the driven bodies A and F and the driving body E of the mechanical system such as rubber, cork, wood and synthetic resin having elasticity. ), a vibration-proof pad to which members of a wide variety of materials are applied can be applied to damp the vibrations generated in the .

In addition, a plurality of damping devices 20 composed of springs having the same elastic modulus or all dampers having the same damping coefficient are provided to effectively dampen vibrations generated according to the distribution of the weight and vibration intensity of the mechanical system, each The spacing between the damping devices 20 may be different from each other.

For example, the first damping device 20a and the second damping device 20b may be installed at a position corresponding to the lower portion of the driven body A, F of the bed frame 10 with a gap D1. At this time, the third damping device 20c, the fourth damping device 20d, and the fifth damping device 20e have a heavier weight than the driven objects A and F and a driving body E that can generate a greater vibration. In order to support the first damping device 20a and the second damping device 20b between the gap (D1) smaller than the spacing (D3, D4) more densely of the driving body (E) of the bed frame (10) It may be installed at a position corresponding to the lower side.

Therefore, in order to effectively support the driven bodies (A, F) and the driving body (E) of the mechanical system with different weights and different strengths of vibrations, respectively, the vibrations can be attenuated by adjusting the spacing of the installed springs. The damping force of the device 20 can be adjusted to be different from each other.

For example, when the mechanical system is a generator, the driven bodies A and F are an alternator A and a radiator F, and the driving body E is an engine, the first damping device 20a and the second damping device ( 20b) may be disposed in the lower part of the left end and the lower right end of the alternator A in the drawing, and the third damping device 20c and the fourth damping device 20d are the left end cylinders inside the engine E It may be disposed under the lower portion and the right end cylinder (V2) of (V1), the fifth damping device (20e) may be disposed under the radiator (F).

Here, the distance between the first damping device 20a and the second damping device 20b is the first distance D1, and the distance between the second damping device 20b and the third damping device 20c is the second distance (D2), the distance between the third damping device 20c and the fourth damping device 20d is subtracted from the third distance D3, and the distance between the fourth damping device 20d and the fifth damping device 20e is subtracted If the fourth distance D4 is defined, the first distance D1 , the second distance D2 , the third distance D3 , and the fourth distance D4 may have different lengths, for example, each The ratio (D1:D2:D3:D4) of the distances may be 100:36:79:83.

The stopper 40 causes the bed frame 10 to vibrate in up, down, left and right directions by vibration generated in the driven body (A, F) or the driving body (E) during operation of the mechanical system or the bolt of the stopper 40 . In order to limit the displacement in which the 401 moves radially around the coupling hole 12a, the seating positions of the driven bodies A, F and the driving body E on one side or the opposite side of the bed frame 10 can be installed correspondingly to

The vibration-controlled seismic generator may include a plurality of stoppers 40, and each stopper 40 is a bed frame 10 at a position corresponding to the seating position of the driven body A, F and the driving body E. Doedoe arranged at intervals on one side and the other side of the stopper 40, the bolt 401 of the stopper 40 penetrates through the coupling hole 12a of the vertical member 12 formed vertically along the longitudinal direction of the bed frame (10) can be arranged as much as possible. At least two stoppers 40 may be installed for each support member 55 so as to be supported by the support members 55 spaced apart from each other on the side of the bed frame 10 .

The stopper 40 may include at least one of a spring and a damper. The plurality of stoppers 40 may all be configured as springs, or may all be configured as dampers. The plurality of stoppers 40 may be formed by a combination of a spring and a damper. In addition, the driven bodies A and F and the driving body E of the mechanical system such as rubber, cork, wood and synthetic resin having elasticity. A vibration-proof pad to which members of a wide variety of materials are applied can be applied to damp the vibrations generated in the .

Therefore, the vibration control seismic generator of the mechanical system according to an embodiment of the present invention, the damping device 20, the stopper 40 and the support member 55 for damping the vibration of the mechanical system bed frame 10, By modularizing with the support rails 11a, 11b, 11c, 11d and the base member 50, there is no need for a separate ground construction for fixing the mechanical system to the floor surface T, thereby reducing the installation cost of the mechanical system have.

In addition, the damping device 20 or the stopper 40 according to the non-uniform weight distribution and the distribution of the vibration intensity generated according to the different weights and vibrations of the driven objects A and F and the driven body E of the mechanical system. ), by setting the spacing of the springs or dampers in various ways, it is possible to efficiently distribute the total weight of the mechanical system and the intensity of vibration to increase the efficiency and performance of the mechanical system.

The vibration control seismic generator of the mechanical system is installed at a position corresponding to the seating position of the driven objects A and F on the floor surface T, and a base member 50 and a stopper 40 for supporting the damping device 20 . It may include a support member 40 for supporting the and two pairs of support rails (11a, 11b, 11c, 11d) for supporting the stopper (40). The support rails 11a, 11b, 11c, and 11d are an example, and the support rails 11a and 11b in any one row are formed by being separated into the first support rail 11a and the second support rail 11b, so that the first support rails 11a and 11b are formed separately. The different damping forces of the supporting members 55a, 55b supported by the rail 11a and the supporting members 55c, 55d supported by the second supporting rail 11b do not affect each other and respectively dodge the mechanical system It can be effectively induced so that it can be applied independently to the fuselage (A, F) and the driving body (E).

In addition, the plurality of damping devices 20 may include springs having different elastic modulus, dampers having the same damping coefficient, or the same A damper having a damping coefficient may be included.

Accordingly, the spring or the damping device 20 according to the non-uniform distribution of weight and vibration intensity generated according to different weights and vibrations of the driven bodies A and F and the driving body E of the mechanical system or By variously setting the modulus of elasticity or damping modulus of the damper, it is possible to efficiently distribute the total weight and intensity of vibration of the mechanical system to increase the efficiency and performance of the mechanical system.

A plurality of support members 50a, 50b, 50c, 50d, 50e, 50f, 50g, 50h, 50i, 50j for supporting the stopper 40, and a reinforcing member 70 for connecting the support rail 50 in the transverse direction can be provided. The support member 50 is fixed to the support rail 11 , and the reinforcing member 70 may reinforce rigidity in the transverse direction of the support rail 11 .

A plurality of damping devices 20 supported by the base member 50 are arranged at predetermined intervals along the length of the support rail 11 to have a uniform damping force distribution in the area along the length direction of the support rail 11 . The driven body A, F or the driving body E can be supported.

3, the vibration control seismic generator according to an embodiment of the present invention, a first damping device (20a), a second damping device (20b), a first stopper (40a), a second stopper (40b), It may include a first support member 55a, a second support member 55b, and a first support rail 11a. In this case, the first damping device 20a and the second damping device 20b may be disposed to be spaced apart from each other in the longitudinal direction of the first support rail 11a.

The vibration control seismic generator may include a third damping device 20c, a third stopper 40c, a third base member 50c, and a second support rail 11b. At this time, the second damping device 20b and the third damping device 20c may be disposed to be spaced apart along the longitudinal direction of the second support rail (11b). The first support rail 11a and the second support rail 11b may have different lengths, and the first damping device 20a, the second damping device 20b and the third damping device 20c are different from each other. They may be spaced apart.

The vibration control earthquake-resistant generator includes a fourth damping device 20d, a fifth damping device 20e, a fourth stopper 40d, a fifth stopper 40e, a fourth support member 55d, and a fifth support member ( 55e), a third support rail 11c, and a reinforcing member 70 may be further included. At this time, the fourth damping device 20d and the fifth damping device 20e may be disposed to be spaced apart from each other at a predetermined distance along the longitudinal direction of the third support rail 11c, and the first damping device 20a and the first damping device 20a 4 damping device (20d) may be disposed spaced apart a predetermined distance along the longitudinal direction of the first and second support rails (11a, 11b), the second damping device (20b) and the fifth damping device (20e) is the first The 1 and 2 support rails 11a and 11b may be disposed to be spaced apart from each other by a predetermined distance along the longitudinal direction. The first support rail 11a and the third support rail 11c may have the same length.

As shown in FIG. 4 , any one of the supporting members 55 may include, for example, a base member 50 supporting the damping device 20 and a supporting member 55 supporting the stopper 40 . The base member 50 may be inserted into the fixing hole 90 by using a fixing member (not shown) such as an anchor bolt to be fixedly installed on the bottom surface T.

The damping device 20 may include a spring 201 or a damper, a housing 202 surrounding the spring 201 or the damper, and a fastening member 203 such as a bolt for installation in the bed frame 10 . The damping device 20 may be fixed by fastening a fixing member (not shown) to the fixing groove 80 so as not to be separated from the base member 50f.

The stopper 40 is supported by the support member 55 fixed to the support rail 11 , and the bolt 401 of the stopper 40 may be coupled to penetrate through the coupling hole 12a of the vertical member 12 . have.

The end of the bolt 401 is disposed to maintain the gap G on the side surface of the bed frame 10 as shown in FIG. 5 , thereby generating vibration along the width direction of the bed frame 10. It is possible to additionally perform a function of damping vibration by implementing a cushioning function for the .

The damping device 20 is installed on the base member 50 so that the damping device 20 and the stopper 40 do not affect each other, and the stopper 40 is a support member 55 positioned on the support rail 11 . By being installed in the, the installation and maintenance of the vibration control device can have the effect of easy.

Meanwhile, referring to FIG. 6 , the bolt 401 of each stopper 40 is penetrated through the coupling hole 12a of the vertical member 12 , and the inner diameter of the coupling hole 12a is larger than the outer diameter of the bolt 401 . By forming a gap (C) is formed, when the front-rear direction and vertical direction vibration is generated in the bed frame 10, the bolt 401 performs a function of damping the vibration based on the center of the coupling hole (12a). will do In other words, the bolt 401 may perform a function of damping vibration in any direction with respect to the radial direction outside the center of the coupling hole 12a.

That is, when an earthquake occurs, even if vibration is generated from the base member 50 via the support rail 11 and the support member 55 , the bolt 401 moves to a play state within the gap C of the coupling hole 12a. By damping vibration, seismic design becomes possible.

In the vibration control earthquake-resistant generator according to an embodiment of the present invention, a separate construction for fixing the mechanical system to the floor surface can be omitted by modularizing the damping device and the frame for damping the vibration of the mechanical system, and also The number and spacing of the springs or dampers constituting the damping device may be set according to the weight distribution and the intensity distribution of the generated vibration.

Accordingly, it is possible to implement a vibration control device of a mechanical system having the effect of efficiently distributing the overall weight and the intensity of vibration of the mechanical system to increase the efficiency and performance of the mechanical system and reduce the installation cost. In addition, it is possible to implement a vibration control device of the mechanical system capable of preventing damage to the mechanical system and the floor by damping the vibration generated during operation of the mechanical system from being transmitted to the floor where the mechanical system is installed.

In addition, it is possible to attenuate vibrations in various directions, such as the left-right direction, the front-rear direction, and the vertical direction of the mechanical system.

Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

10: bed frame
11: support rail
12: vertical member
20: damping device
40: stopper
50: base member
55: support member
70: reinforcing member
80: fixed groove
90: fixing hole
401: bolt
A: driven object
E: driving body
C: gap
F: radiator
G: Gap

Claims (9)

a bed frame on which a driving body or a driven body of the mechanical system is seated on the upper surface;
a plurality of damping devices coupled to the lower surface of the bed frame so as to attenuate the vibration generated in the driving body or the driven body from being transmitted to the floor surface on which the driving body or the driven body is installed;
a plurality of stoppers installed on one side or opposite sides of the bed frame in order to limit vertical and front-rear displacement of the bed frame due to the vibration of the driving body or the driven body;
a base member that is fixedly installed on a floor surface on which the mechanical system is installed and supports the plurality of damping devices;
a support rail supporting the plurality of stoppers;
a plurality of support members disposed on the upper side in the longitudinal direction of the support rail; and
Doedoe formed on the side of the bed frame, comprising a vertical member formed to stand spaced apart along the longitudinal direction on the side of each support rail,
Each of the stoppers,
and a bolt having one end passing through the coupling hole of the vertical member to form a gap with the side surface of the bed frame, and the other end being fixed to the support member,
The inner diameter of the coupling hole is formed larger than the outer diameter of the bolt, including a gap formed between the inner diameter of the coupling hole and the outer circumferential surface of the bolt in a state in which the bolt penetrates the coupling hole, vibration-controlled seismic generator. According to claim 1,
the plurality of damping devices comprising a first damping device supported by a first base member and a second damping device supported by a second base member;
The plurality of stoppers include a first stopper and a second stopper,
a first support member supporting the first stopper;
a second support member supporting the second stopper; and
and a first support rail to which the first support member and the second support member are fixed. 3. The method of claim 2,
the plurality of damping devices further comprising a third damping device supported by a third base member;
The plurality of stoppers further include a third stopper and a fourth stopper,
A third support member supporting the third stopper
a fourth support member supporting the fourth stopper; and
and a second support rail to which the third support member and the fourth support member are fixed, and a second support rail having a length different from that of the first support rail. 4. The method of claim 3,
the plurality of damping devices further comprising a fourth damping device supported by a fourth base member;
a second support rail to which the third support member and the fourth support member are fixed;
a third support rail spaced apart from the first support rail;
a fourth support rail spaced apart from the second support rail; and
and a reinforcing member that transversely connects between the first support rail and the third support rail and between the second support rail and the fourth support rail, respectively. delete According to claim 1,
The plurality of damping devices comprising at least one of a spring and a damper, vibration-controlled seismic generator. a bed frame on which the driven body and the driving body of the mechanical system are seated on the upper surface;
a plurality of damping devices disposed on the lower surface of the bed frame to attenuate transmission of the driven body and the vibration generated by the driving body to the bottom surface on which the driven body and the driving body are installed;
a plurality of stoppers installed on one side or opposite sides of the bed frame to limit vertical and horizontal displacement of the bed frame due to vibration of the driven body and the driving body;
a first support rail supporting at least one of the plurality of stoppers;
a second support rail supporting at least another one of the plurality of stoppers;
a plurality of support members disposed above the first and second support rails in a longitudinal direction; and
Doedoe formed on the side of the bed frame, comprising a vertical member formed to stand spaced apart along the longitudinal direction on the side of each support rail,
Each of the stoppers,
and a bolt having one end passing through the coupling hole of the vertical member to form a gap with the side surface of the bed frame, and the other end being fixed to the support member,
The inner diameter of the coupling hole is formed larger than the outer diameter of the bolt, including a gap formed between the inner diameter of the coupling hole and the outer circumferential surface of the bolt in a state in which the bolt penetrates the coupling hole, vibration-controlled seismic generator. 8. The method of claim 7,
The plurality of attenuation devices,
first, second, third, fourth and fifth damping devices respectively supported by first, second, third, fourth, and fifth base members fixed to the ground;
a first distance between the first attenuation device and the second attenuation device, a second distance between the second attenuation device and the third attenuation device, a third distance between the third attenuation device and the fourth attenuation device and a fourth distance between the fourth damping device and the fifth damping device, respectively, having different lengths, vibration-controlled seismic generator. 9. The method of claim 8,
the mechanical system includes a generator, the driven body includes an alternator and a radiator, and the driven body includes an engine;
The first damping device and the second damping device are disposed below the left end and the right end of the alternator,
The third damping device and the fourth damping device are disposed below the left end cylinder and the right end cylinder of the engine,
The fifth damping device is disposed under the radiator, vibration-controlled seismic generator.

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