KR20210135919A - A seismic isolator of power supply - Google Patents

Abstract

The present invention relates to a seismic isolator of power source equipment. In order for the seismic isolator of the power source equipment to absorb vibrations in a wide range of vibration frequency bands when the vibrations from unspecified causes in an area where an uninterruptible power supply (UPS) is installed are applied to the UPS, an objective of the present invention is to provide the seismic isolator of power source equipment which improves vibration characteristics of the seismic isolator and movement of resonance frequencies. According to the present invention, by improving the vibration characteristics of the seismic isolator and the movement of the resonance frequencies, it is possible to absorb the vibrations in a wide range of vibration frequency bands, and provide an effect of absorbing the vibrations other than the resonance frequencies well. The seismic isolator of power source equipment of the present invention comprises: a base unit (10); and a buffer unit (30).

Description

A SEISMIC ISOLATOR OF POWER SUPPLY

The present invention relates to a seismic isolator for a power supply equipment, and more particularly, to a seismic isolator for a power supply equipment that attenuates external vibration applied to an uninterruptible power supply device in order to reduce a malfunction of the uninterruptible power supply device due to vibration.

Switchgear is a power supply facility that supplies power to general households or industrial facilities. It is installed in a specific area of a building and may be vulnerable to external vibration due to the characteristics of precision electronic devices. A seismic isolator is configured at the base of the switchboard so that external vibrations do not affect the switchboard.

The uninterruptible power supply unit, which can be included in the switchgear, supplies power to the internal electric device without power outage when commercial power is not supplied to home or industrial facilities, and is a precision electronic device located at the corner of the base to prevent external vibration from affecting the uninterruptible power supply unit. A vibration isolator is configured.

Taking the prior art related to the seismic isolator of the power equipment of the present invention as an example, as shown in FIG. 1 , the seismic device of the power equipment in Patent Document 1 is a vibration or impact force generated by not only the vibration of the power equipment itself but also an earthquake. It absorbs and safely protects power equipment such as uninterruptible power supply.

In the related art Patent Document 1, although the vibration isolator absorbs the vibration applied from the outside to the uninterruptible power supply, there is a problem in that it does not provide the seismic isolating performance to meet the industrial standards for the entire vibration in a wide vibration frequency band.

Registered Patent Publication No. 10-1835567 Seismic device of power equipment

The present invention relates to the vibration characteristics and movement of the resonance frequency of the seismic isolator so that the vibration isolator of the power equipment can isolate the vibration of a wide range of vibration frequency bands when the vibration generated from unspecified causes in the area where the uninterruptible power supply device is installed is applied to the uninterruptible power supply device. An object of the present invention is to provide a seismic isolator for power equipment that improves the

Another object of the present invention is to provide a seismic isolator for power equipment that controls the seismic isolation characteristics of the seismic isolator according to various weights or weight distributions of the uninterruptible power supply device.

Another object of the present invention is to provide a seismic isolator for power equipment that can easily adjust the seismic isolation characteristics of the seismic isolator even when the seismic isolation characteristics change due to long-term use of the seismic isolator.

a base portion 10 including a damping portion 20 for absorbing vibrations of the present invention; and a buffer part 30 supported by the base part 10 and buffering the support plate 40, wherein the base part 10 includes: a base lower plate 11; Damping rubber support 21 coupled to one side of the base lower plate 11 using a lower plate fixing member 12 for fixing the base lower plate 11 to the damping rubber support 21; a base upper plate 13 fixed to the damping rubber support 21 by an upper plate fixing member 14; and a tension wire 51 that pulls the base lower plate 11 and the base upper plate 13 to provide a surface pressure to the damping rubber support 21 to increase the seismic isolation characteristics by the damping rubber support 21 . It is characterized in that it contains;

In addition, the buffer unit 30 includes a spring 31 for supporting the base upper plate 13; and a support plate 40 supported by the spring 31 .

In addition, the buffer unit 30 includes a wire rod 32 for supporting the base upper plate 13; and a support plate 40 supported by the wire rod 32 .

In addition, the base part 10 is characterized in that the base lower plate 11, the rubber support for damping 21 and the base upper plate 13 form a plurality of layers.

In addition, the seismic isolator (1) includes a base rail (2) laid on the floor, and the seismic isolator (1) is positioned at a preset position of the base rail (2).

In addition, the vibration isolator may include a piezoelectric sensor for measuring vibration applied to the vibration isolator; and calculating a vibration value by processing the electrical signal of the piezoelectric sensor, and using the calculated vibration value to control the tension of the tension wire.

In addition, the vibration isolator may include a control unit that controls a driving unit that adjusts the tensile force of the tensile wire using the calculated vibration value.

In addition, the power supply equipment is characterized in that it includes any one or more of a switchgear, an uninterruptible power supply device, a PCS, an ESS device, a battery panel, a rectifier device, and a voltage regulation device as an electricity supply device.

The present invention can have the effect of damping vibration by shifting the resonant frequency band with respect to a wide range of external vibration bands by adjusting the seismic isolating characteristics of the vibration isolator by adjusting the surface pressure applied to the vibration isolator by adjusting the tensile force of the tension wire.

In addition, the present invention provides a seismic isolator of a seismic isolator according to various weights or weight distributions of the uninterruptible power supply by adjusting the vibration characteristics of the seismic isolator using a tension wire that provides a tensile force to apply pressure to a high damping rubber bearing or a seismic isolator disk bearing. By adjusting the characteristics, it may have an effect of damping external vibration applied to the uninterruptible power supply.

In addition, the present invention controls the seismic isolating characteristics of the seismic isolator by adjusting the tensile force of the tensile wire, so that even if the seismic isolating characteristics change due to the long use of the seismic isolator, it can have the effect of simply maintaining the optimal seismic isolating characteristics against external vibration. .

1 is an exemplary view of a seismic device of a conventional power facility.
2 is an exemplary view showing a seismic isolator of a power supply facility according to a first embodiment of the present invention.
3 is an exemplary view showing a seismic isolator of a power facility according to a second embodiment of the present invention.
4 is an exemplary view showing a seismic isolator of a power supply facility according to a third embodiment of the present invention.
5 shows the shear characteristics according to the surface pressure.
6 is an exemplary view showing a seismic isolator of a power facility according to a fourth embodiment of the present invention.
7 is an exemplary view showing a seismic isolator of a power facility according to a fifth embodiment of the present invention.
8 is an exemplary view showing a seismic isolator of a power supply facility according to a sixth embodiment of the present invention.
9 is an exemplary view showing a seismic isolator of a power supply facility according to a seventh embodiment of the present invention.
10 is an experimental comparative example of the prior art and the present invention, showing acceleration comparison data in the Top of UPS and Control switch.
11 is an experimental comparative example of the prior art and the present invention, and shows acceleration comparison data in a cooling plate and a transformer.
12 is an experimental comparative example between the prior art and the present invention, and shows frequency and displacement data of the prior art and the present invention.
13 is an exemplary view showing a seismic isolator of a power supply facility according to an eighth embodiment of the present invention.

Hereinafter, a seismic isolator of a power supply facility according to a preferred embodiment of the present invention will be described in detail with reference to the drawings. Hereinafter, descriptions of previously known matters will be omitted or simplified in order to clarify the gist of the present invention. The components included in the description of the present invention operate individually or in combination in combination.

In the first embodiment, as shown in FIG. 2 , the damping rubber bearing 21 is applied to the damping unit 20 , and the spring 31 is configured in the damping unit 30 .

The seismic isolator includes a base part 10 including a damping part 20 for absorbing vibrations, and a buffer part 30 supported by the base part 10 and buffering the support plate 40 . The base part 10 is a base lower plate 11; a lower plate fixing member 12 for fixing the base lower plate 11 to the damping rubber support 21; The base lower plate 11 is coupled to one side of the rubber bearing 21 for damping; and a base upper plate 13 fixed to the damping rubber support 21 by the upper plate fixing member 14; and a damping rubber support 21 having excellent seismic isolation properties is used for the damping unit 20. The buffer unit 30 includes a spring 31 for supporting the base upper plate 13; and a support plate 40 supported by a spring 31 .

The high-damping rubber bearing (HDRB) 21 can absorb energy by adding a viscous material when mixing rubber to reduce friction between polymers and a viscous damping element caused by a viscous substance present between molecules.

The seismic isolator supports a vertical load using a rubber bearing 21 and a spring 31 for damping, accommodates horizontal displacement and rotation, has excellent restoring force against vertical load and displacement, and reduces seismic force.

The vibration isolator uses a rubber bearing 21 for damping composed of laminated rubber using rubber with high damping properties, and generally does not require a separate damper, so it is easy to install. The seismic isolation effect is exhibited, and vertical vibration is controlled by the use of the seismic spring (31).

In the second embodiment, as shown in FIG. 3 , the seismic isolation disk support 22 is applied to the damping unit 20 , and the spring 31 is configured to the buffer unit 30 .

The seismic isolator includes a base part 10 including a damping part 20 for absorbing vibrations, and a buffer part 30 supported by the base part 10 and buffering the support plate 40 . The base part 10 is a base lower plate 11; a lower plate fixing member 12 for fixing the base lower plate 11 to the seismic isolation disk support 22; The base lower plate 11 is coupled to one side of the rubber bearing 21 for damping; and a base upper plate 13 fixed to the seismic isolating disk support 22 by means of the upper plate fixing member 14 , and the damping unit 20 uses a seismic isolating disk support 22 having excellent seismic isolation properties. The buffer unit 30 includes a spring 31 for supporting the base upper plate 13; and a support plate 40 supported by a spring 31 .

The seismic isolating disk bearing (MNDB) 22 supports the load of power equipment and applies polyurethane that accommodates rotational deformation, thereby solving problems such as deterioration of durability due to leakage and damage of the rubber plate, which has been pointed out as a disadvantage of the port bearing so far. improve with

The seismic isolator can be manufactured in various sizes and hardness using the seismic isolator disk support 22 and the spring 31, reduces vertical vibration, has high fatigue stability due to repeated loads, and has a low rubber height.

In the third embodiment, as shown in FIG. 4 , the damping rubber bearing 21 is applied to the damping unit 20 , and the wire rod 32 is configured in the damping unit 30 .

The seismic isolator includes a base part 10 including a damping part 20 for absorbing vibrations, and a buffer part 30 supported by the base part 10 and buffering the support plate 40 . The base part 10 is a base lower plate 11; a lower plate fixing member 12 for fixing the base lower plate 11 to the damping rubber support 21; The base lower plate 11 is coupled to one side of the rubber bearing 21 for damping; and a base upper plate 13 fixed to the damping rubber support 21 by the upper plate fixing member 14; and a damping rubber support 21 having excellent seismic isolation properties is used for the damping unit 20. The buffer unit 30 includes a wire rod 32 for supporting the base upper plate 13; and a support plate 40 supported by the wire rod 32 .

The vibration isolator reduces the height due to the lateral arrangement of the wire rod 32 by using the damping rubber bearing 21 and the wire rod 32, and reduces the risk of overturning by limiting horizontal and vertical displacement.

The vibration isolator uses the wire rod 32 instead of the spring 31, and reduces the risk of overturning, which can be a disadvantage when the rigidity of the spring 31 is used small, and the rubber for damping and damping of the wire rod 32 The damping of the bearing 21 dissipates energy.

The seismic isolator 10 applies a surface pressure to the damping rubber bearing 21 with a tension wire 51 to change the vibration damping characteristics of the damping rubber bearing 21, and the non-interruptible damping rubber bearing 21 supports Do not apply external vibration to the power supply. The damping rubber bearing 21 is installed where a high load is applied, such as a bridge, and significantly dampens external vibrations applied to the bridge. In the case of an uninterruptible power supply, since the load is small, the rubber bearing 21 for damping does not exhibit a smooth vibration damping performance. to improve the seismic isolation characteristics of the rubber bearing 21 for damping.

5 is an exemplary view showing the rate of change of shear characteristics according to the surface pressure.

Most of the seismic isolators used in the existing small mechanical and electrical non-structural elements have disadvantages in that the details are complicated and the unit price is high. In order to overcome this, a simple and economical damping rubber bearing 21 and a wire rod 32 are used to propose a seismic isolator.

In the case of the rubber bearing 21 for damping used for large buildings or bridges, the greater the surface pressure, the better the damping performance, so it is difficult to use it for small or light objects.

In order to solve the above problem, a tension wire 51 is proposed so that it can be applied to various small devices and machines by applying a tensile force to the existing vibration isolator and adjusting the surface pressure received by the damping rubber bearing 21 .

By installing the tension wire 51 for adjusting the surface pressure received by the rubber bearing 21 for damping, it can be applied to various weights, and the risk of overturning due to the installation of the wire rod 32 can be prevented.

In the fourth embodiment, as shown in FIG. 6 , the damping rubber bearing 21 is applied to the damping unit 20 , and the tension wire 51 is configured to provide a surface pressure to the damping rubber bearing 21 .

The vibration isolator has a base portion (10) including a damping portion (20) for absorbing vibrations. The base part 10 is a base lower plate 11; a lower plate fixing member 12 for fixing the base lower plate 11 to the damping rubber support 21; The base lower plate 11 is coupled to one side of the rubber bearing 21 for damping; The base upper plate 13 fixed to the rubber support 21 for damping by the upper plate fixing member 14; and a tension wire 51 that provides a surface pressure to the damping rubber support 21 by pulling the base lower plate 11 and the base upper plate 13 to increase the seismic isolation characteristics by the damping rubber support 21; . The wire fixing member 52 pulls the tension wire 51 in order to provide surface pressure to the rubber bearing 21 for damping whose one side and the other side are finished with the base lower plate 11 and the base upper plate 13, and the base lower plate ( 11) and the base top plate 13 are fixed to the rubber support 21 for damping. The seismic isolator for damping the vibration of the power equipment adjusts the tensile force of the tension wire 51 in consideration of the weight applied according to the position of the seismic isolator supporting the power equipment. When the weight of the power equipment varies depending on the location, the tensile force of the tensile wire 51 is adjusted in consideration of the weight. The seismic isolator configures a load cell at each position (four corners), and controls the degree of rotation of the wire fixing member 52 to adjust the tensile force of the tensile wire 51 according to the weight level measured by the load cell.

Considering the size of the seismic isolator as a round rubber bearing 21 for damping of about 100 millimeters, a surface pressure of about 7.5 MPa is required for damping ratio efficiency. Considering this, a pressure of about 58900N is required.

Considering that the elongation of one wire is around 1.5%, the maximum change length of a wire of about 100 millimeters in length is 1.5 millimeters. The rigidity (k = EA/L) of a 4mm diameter wire is about 25132N/mm, and a tensile force of about 25132N occurs when 1mm changes.

In consideration of this, using two tensile wires 51 with a length of 99 mm and a diameter of 4 mm, a change of 1 mm is given to apply a surface pressure to the rubber bearing 21 for damping.

In the fifth embodiment, as shown in FIG. 7 , the damping rubber bearing 21 is applied to the damping unit 20 , and the tension wire 51 is configured to provide a surface pressure to the damping rubber bearing 21 , and the buffer A spring 31 is configured in the portion 30 .

The vibration isolator includes a base portion 10 including a damping portion 20 for absorbing vibration; and a buffer part 30 supported by the base part 10 to buffer the support plate 40 . The base part 10 is a base lower plate 11; a lower plate fixing member 12 for fixing the base lower plate 11 to the damping rubber support 21; The base lower plate 11 is coupled to one side of the rubber bearing 21 for damping; The base upper plate 13 fixed to the rubber support 21 for damping by the upper plate fixing member 14; and a tension wire 51 that provides a surface pressure to the damping rubber support 21 by pulling the base lower plate 11 and the base upper plate 13 to increase the seismic isolation characteristics by the damping rubber support 21; . The buffer unit 30 includes a spring 31 for supporting the base upper plate 13; and a support plate 40 supported by a spring 31 . The wire fixing member 52 pulls the tension wire 51 in order to provide surface pressure to the rubber bearing 21 for damping whose one side and the other side are finished with the base lower plate 11 and the base upper plate 13, and the base lower plate ( 11) and the base top plate 13 are fixed to the rubber support 21 for damping.

In the sixth embodiment, as shown in FIG. 8 , the damping rubber bearing 21 is applied to the damping part 20 , and the tension wire 51 is configured to provide a surface pressure to the damping rubber bearing 21 , and the buffer A wire rod 32 is configured in the portion 30 .

The vibration isolator includes a base portion 10 including a damping portion 20 for absorbing vibration; and a buffer part 30 supported by the base part 10 to buffer the support plate 40 . The base part 10 is a base lower plate 11; a lower plate fixing member 12 for fixing the base lower plate 11 to the damping rubber support 21; The base lower plate 11 is coupled to one side of the rubber bearing 21 for damping; The base upper plate 13 fixed to the rubber support 21 for damping by the upper plate fixing member 14; and a tension wire 51 that provides a surface pressure to the damping rubber support 21 by pulling the base lower plate 11 and the base upper plate 13 to increase the seismic isolation characteristics by the damping rubber support 21; . The buffer unit 30 includes a wire rod 32 for supporting the base upper plate 13; and a support plate 40 supported by the wire rod 32 . The wire fixing member 52 pulls the tension wire 51 in order to provide surface pressure to the rubber bearing 21 for damping whose one side and the other side are finished with the base lower plate 11 and the base upper plate 13, and the base lower plate ( 11) and the base top plate 13 are fixed to the rubber support 21 for damping.

In the seventh embodiment, as shown in FIG. 9 , a lower base rail 2 is installed on the floor on which the uninterruptible power supply device is placed, the seismic isolator 1 is installed on the lower base rail 2 , and the upper part is installed on the seismic isolator 1 . A base rail 3 is installed, and a power supply is installed on the upper base rail 3 .

In the seventh embodiment, the vibration isolator 1 may use a general vibration isolator that absorbs vibration using rubber, a spring, etc., or a base in which the vibration isolator 1 includes a damping unit 20 that absorbs vibration. part (10); and a buffer part 30 supported by the base part 10 to buffer the support plate 40 .

Alternatively, in the seventh embodiment, the seismic isolator 1 includes: a base part 10 including a damping part 20 for absorbing vibrations like the seismic isolators of the previous embodiments; and a buffer part 30 supported by the base part 10 and buffering the support plate 40, wherein the base part 10 includes a lower base plate 11; a rubber support 21 for damping installed on the upper surface of the base lower plate 11; a base top plate 13 installed on the upper surface of the rubber bearing 21 for damping; and a tension wire 51 that pulls the base lower plate 11 and the base upper plate 13 to provide a surface pressure to the damping rubber support 21 to adjust the seismic isolation characteristics by the damping rubber support 21 . ); may be included.

In addition, in the seventh embodiment, the seismic isolator 1 includes: a rubber support 21 for damping forming a multi-layer; Tensile wire 51 for providing a surface pressure to the multi-layer damping rubber bearing 21; and a wire rod 32 configured on the multi-layered rubber bearing 21 for damping.

In the seventh embodiment, the rubber bearing 21 for damping may be fastened and fixed to the base upper plate 13 and the base lower plate 11 by a fastening device.

The lower base rail 2 serves to fix the seismic isolator 1 on the floor, and the damping rubber bearing 21 forming a multi-layered damping rubber bearing 21 having a plurality of different elastic modulus is laminated. .

When the installation process of the power supply facility is described in detail with respect to the seventh embodiment, first, the lower base rail 2 is fixedly installed on the floor by a fastening device such as bolts, and the seismic isolator 1 is installed in the lower base rail 2 . A plurality of installation holes (not shown) to be installed are formed, so that the installation position of the seismic isolator 1 on the lower base end rail 2 can be freely changed.

In addition, a plurality of installation holes (not shown) for installing the seismic isolator 1 are also formed on the upper base rail 3, so that the installation position of the seismic isolator 1 can be freely changed, and furthermore, the upper base rail 3 A plurality of power equipment installers (not shown) for fixing and installing the power equipment are formed there, so that the position of the power equipment can be freely changed on the upper base rail 3 .

As in the seventh embodiment, when the lower base rail 2 or the upper base rail 3 is not used, the seismic isolator 1 is directly fixed to the floor and the power equipment must be fixedly installed on it, so the position of the power equipment is changed However, whenever replacement of power facilities is required, it is inconvenient to separately perform floor work or fixing work of power facilities. In addition, when the seismic isolator 1 is reinstalled on the floor and the power equipment is installed thereon, the characteristics of the originally set seismic isolator are changed, so that there is a problem in that the characteristics of the seismic isolator are newly adjusted whenever the power equipment is moved.

However, as shown in FIG. 9, if the lower base rail 2 having a plurality of installation holes is first installed on the floor and then the seismic isolator is installed, the seismic isolator is installed on the lower base rail 2 instead of directly on the floor. When it is necessary to change the position of the seismic isolator, it is not necessary to separate the seismic isolator and the floor and perform a separate floor construction for reinstallation. Since it is only necessary to fix the lower proximal rail and the floor to the new position again with the later fastening device, there is an effect that the position of the seismic isolator is easily changed.

In addition, if the upper base rail 3 having a plurality of power equipment installation holes and a plurality of installation holes for the seismic isolator is used, only the fastening device that fixes the power equipment and the upper base rail 3 on the upper base rail 3 is loosened. Not only can the position change or replacement of the power supply equipment be facilitated, but there is a remarkable effect of reducing the need to newly set the seismic isolation characteristics of the seismic isolator every time the power supply equipment is replaced or the position is changed.

In addition, according to the present invention, the power equipment and the seismic isolator can be moved at once by separating the lower base rail 2 from the floor in a state where the power equipment is installed on the upper base rail 3, so that the power equipment and the seismic isolator can be It is easy to move all at once, and there is a remarkable effect that it is not necessary to newly set the seismic isolating characteristics of the seismic isolator every time the positions of the power supply equipment and the seismic isolator are changed.

In the seventh embodiment, the rubber bearing 21 for damping forming a multi-layer; In the case of using the seismic isolator 1 including the tension wire 51 that provides the surface pressure to the multi-layered rubber bearing 21 for damping, the seismic isolator 1 includes the wire rod 32 and a plurality of different It is characterized in that the seismic isolation characteristic is controlled by two means of the rubber bearing 21 for damping having an elastic modulus.

In FIG. 9 , the surface pressure for pressing the damping rubber bearing 21 with the tension wire 51 of the vibration isolator 1 is adjusted to prevent external vibration from being transmitted to the uninterruptible power supply.

If the tension wire 51 of the seismic isolator 1 does not sufficiently dampen external vibration, one or more damping rubber bearings 21 in the multi-layered damping rubber bearing 21 are damped with different elastic modulus. Adjust the seismic isolation characteristics by changing to the rubber support (21) for use.

As described above, the seismic isolator 1 of FIG. 9 first adjusts the seismic isolation characteristics of the seismic isolator 1 with the tension wire 51, and if the external vibration cannot be sufficiently attenuated, the elastic modulus of the multi-layer damping rubber bearings 21 It is possible to adjust the seismic isolation characteristics of the seismic isolator 1 while changing

10 is an experimental comparative example of the prior art and the present invention, and shows acceleration comparison data in the Top of UPS and Control switch. As a result of applying the seismic isolator of the present invention, it can be confirmed that the magnitude of the acceleration is reduced in all of the x, y, and z directions, thereby increasing the seismic isolating effect.

11 is also an experimental comparative example of the prior art and the present invention, showing comparison data of acceleration in a cooling plate and a transformer. As a result of applying the seismic isolator of the present invention, it can be confirmed that the magnitude of the acceleration is reduced in all of the x, y, and z directions, thereby increasing the seismic isolating effect.

12 is an experimental comparative example of the prior art and the present invention. When the prior art and the present invention are compared, the resonant frequency moves from the frequency band to the low frequency band, and the displacement magnitude of the present invention is smaller than that of the prior art. This indicates that the resonant frequency shifts to a lower frequency band, and the frequency characteristics for external vibration frequencies are improved.

In the eighth embodiment, as shown in FIG. 13 , the distance sensor 60 is applied to the damping part 20 of the seismic isolator 10 , and the base upper plate 13 and the base lower plate of the damping part 20 are used as the distance sensor 60 . (11) Measure the distance between, and adjust the surface pressure by adjusting the tensile force of the tensile wire 51 with the tensile force driving unit 70 in order to predict the damping performance corresponding to the measured distance to exhibit the desired damping performance.

In the present invention, as the distance sensor 60 , any one of an ultrasonic sensor, a laser sensor, and an optical sensor may be selected and applied to the seismic isolator 1 .

Also, in the present invention, the seismic isolator 10 may include a separate tensile force sensor for measuring the tensile force of the tensile wire 51 .

First, the distance between the base upper plate 13 and the base lower plate 11 according to the elastic modulus of the damping rubber bearing 21 and the tensile force of the tensile wire 51 is measured, and at this time, the frequency range of external vibration is changed while damping The seismic isolation characteristics of the rubber bearing 21 are experimentally obtained and converted into a database.

Later, when the weight or weight distribution of the uninterruptible power supply device changes or when the uninterruptible power supply device is newly installed, the tensile force driving unit 70 adjusts the tensile force of the tensile wire 51 based on the above data base to adjust the tensile force of the tensile wire 51 to the damping unit 20 ) to control the seismic isolation characteristics of the seismic isolator by controlling the surface pressure.

In addition, when the characteristics of the damping rubber bearing 21 are changed and compressed due to the long use of the seismic isolator, the distance between the base upper plate 13 and the base lower plate 11 and the tensile force of the tensile force wire are changed, so the distance sensor 60 ) and a tensile force sensor to detect such a distance change and a tensile force change, and notify the user thereof, and the tensile force driving unit 70 may tension the tensile force wire to obtain the originally set seismic isolation characteristics.

The present invention is not limited to the specific preferred embodiments described above, and without departing from the gist of the present invention as claimed in the claims, anyone with ordinary skill in the art to which the invention pertains can implement various modifications Of course, such modifications are intended to be within the scope of the claims.

1: seismic isolator
2: Lower proximal rail
3: Upper proximal rail
10: base part
11: Base lower plate
12: lower plate fixing member
13: base top
14: upper plate fixing member
20: damping unit
21: high damping rubber support
22: seismic isolation disk support
30: buffer
31: spring
32: wire rod
50: surface pressure part
51: tension wire
52: wire fixing member
60: distance sensor
70: tensile force driving unit

Claims (6)

seismic isolator of power equipment
a base unit 10 including a damping unit 20 for absorbing vibration; and
and a buffer part 30 supported by the base part 10 and buffering the support plate 40,
On the floor on which the uninterruptible power supply device is placed, the lower base rail 2 is fixedly installed by a fastening device, and a plurality of installation holes for installing the seismic isolator are formed in the lower base rail 2, so that the seismic isolator is formed on the lower base rail 2 A device is installed, and an upper base rail (3) formed with a plurality of installation holes for installing the seismic isolator and a plurality of power equipment installation holes for fixing and installing power equipment is installed on the seismic isolator, and the upper base rail (3) ), characterized in that the power equipment is installed on the, seismic isolator of the power equipment. According to claim 1, wherein the base portion (10)
Base lower plate 11;
a rubber support 21 for damping installed on the upper surface of the base lower plate 11;
a base top plate 13 installed on the upper surface of the rubber bearing 21 for damping; and
A tension wire 51 for controlling the seismic isolation characteristics by the damping rubber support 21 by pulling the base lower plate 11 and the base upper plate 13 to provide a surface pressure to the damping rubber support 21 . ; A seismic isolator of power equipment comprising: 3. The method of claim 2,
The buffer unit 30,
and a wire rod (32) or a spring (31) supported by the base upper plate (13). 4. The method of claim 3,
The vibration isolation device is
A distance sensor 60 for measuring the distance between the base upper plate 13 and the base lower plate 11 of the damping unit 20 and a separate tensile force sensor for measuring the tensile force of the tensile wire 51 are provided, and a tensile force driving unit ( Power supply, characterized in that 70) adjusts the tensile force of the tensile wire 51 based on the distance and tensile force measured by the distance sensor 60 and the tensile force sensor to adjust the surface pressure of the damping rubber bearing 21 seismic isolators of equipment. 5. The method of claim 4,
The damping rubber bearing 21 is a seismic isolator of a power facility, characterized in that the rubber bearing 21 for damping having a plurality of different elastic modulus constituting a multi-layer is stacked. a base unit 10 including a damping unit 20 for absorbing vibration; and
In the seismic isolator of power equipment including a buffer part (30) supported by the base part (10) and buffering the support plate (40),
The base portion 10 includes a lower base plate 11;
a rubber support 21 for damping installed on the upper surface of the base lower plate 11;
a base top plate 13 installed on the upper surface of the rubber bearing 21 for damping; and
A tension wire 51 for controlling the seismic isolation characteristics by the damping rubber support 21 by pulling the base lower plate 11 and the base upper plate 13 to provide a surface pressure to the damping rubber support 21 . including;
The damping rubber bearing 21 is a seismic isolator of a power facility, characterized in that the rubber bearing 21 for damping having a plurality of different elastic modulus constituting a multi-layer is stacked.

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