KR20210025976A - Apparatus for testing seismic isolation devices with specimen protection function - Google Patents

Abstract

The present invention relates to a tester for a seismic isolation device having a sample protection function, which can test performance of a seismic isolation device and prevent a sample from being broken by preventing high pressure from being applied to a pressurization device even though an emergency such as a blackout or a system error occurs during a test.

Description

Apparatus for testing seismic isolation devices with specimen protection function

The present invention relates to a seismic isolator tester, and more particularly, to a seismic isolator tester having a specimen protection function capable of preventing the specimen from being damaged even if an emergency situation occurs during the test of the seismic isolation performance of the seismic isolator.

Earthquake is when a sudden change in the earth's crust occurs at a certain point inside the earth, and the wave generated by the impact, that is, a seismic wave, is transmitted to the surface and vibrates the ground.

In order to minimize the damage caused by such an earthquake, structures and buildings in industrial sites, architecture, and civil engineering are designed in consideration of seismic, seismic, or vibration isolation. In particular, in order to reinforce the seismic performance of a structure or building, a seismic isolator that attenuates or blocks vibrations from outside is adopted and installed.

The seismic isolator must meet certain standards and performance required by the consumer. For this reason, a device capable of testing whether a certain standard and performance required by a consumer is satisfied is being developed. The prior art related to a device capable of testing such a seismic isolating device has been disclosed in Korean Patent Publication No. 10-1835811.

However, the conventional seismic isolator tester is operated by electronic devices and computer software.If control becomes impossible due to failure of electrical equipment such as power failure or surge, or program error, the actuator is subjected to maximum load due to malfunction of hydraulic valves, etc. As the specimen is pressurized, the specimen is damaged and the loss is enormous.

Republic of Korea Patent Registration No. 10-1835811 (February 28, 2018, registration)

The present invention has been proposed to solve the problems occurring in the prior art as described above, and has a specimen protection function capable of preventing the specimen from being damaged even if an emergency situation occurs during the test of the seismic isolation performance of the seismic isolation device. It is to provide a device tester.

In order to achieve the above object, the seismic isolator tester having a specimen protection function according to the present invention includes a test bed on which the specimen is seated; A lower frame having the test bed disposed on an upper portion and having a roller movable in a horizontal direction thereon; An upper frame disposed to be spaced apart from the lower frame; A pressing block disposed between the lower frame and the upper frame and pressing the specimen by an external pressing force; A pressurizing device provided under the upper frame and expanding and contracting in a vertical direction to press the upper portion of the pressurizing block; And a weight detection sensor provided on the upper part of the pressing block and measuring a vertical load generated as the pressing device presses the pressing block to create a measurement value.

In addition, a first valve provided on one side of the upper frame and controlling hydraulic pressure supplied from a hydraulic supply unit through a hydraulic supply line and applying it to the pressurizing device; A second valve provided on the hydraulic supply line to reduce a pressure of hydraulic oil supplied to the first valve; A third valve provided on the hydraulic supply line and opened when the hydraulic oil depressurized through the second valve is supplied above a preset hydraulic pressure to discharge a part of the hydraulic pressure; A fourth valve provided on the hydraulic supply line, opened and closed, and operates the hydraulic supply unit under load when opened, and operates the hydraulic supply unit without load when closed; And a control unit for controlling the operation of each of the first to fourth valves according to the pressure value input from an input unit to which a preset pressure value is input for testing of the pressurization device and a measurement value measured by the weight sensor. It further comprises, wherein the hydraulic supply line is provided with a pressure sensor for measuring the pressure of the hydraulic oil supplied from the hydraulic supply unit, the control unit generates a monitoring signal for monitoring the pressure value measured by the pressure sensor, and the It characterized in that it further comprises a display for visually displaying the monitoring signal generated by the control unit.

In addition, the hydraulic supply line is characterized in that a fifth valve is provided on one side of the hydraulic supply line is closed when the power is cut off when an emergency situation occurs to block the flow of the hydraulic oil.

As another example, the hydraulic supply line may be provided with a sixth valve on one side of the hydraulic supply line that is closed as power is supplied by the uninterruptible power supply and blocks the flow of hydraulic oil when power is cut off during an emergency situation.

As described above, according to the seismic isolating device tester having a specimen protection function according to the present invention, the performance of the seismic isolating device can be tested, and high pressure is applied to the pressurizing device even if an emergency situation such as power failure or system error occurs during the test. By preventing the specimen from being damaged, it is possible to prevent the specimen from being damaged.

In addition, according to the seismic isolator tester having a specimen protection function according to the present invention, even if an emergency situation occurs, power is resupplied through the emergency generator and the seismic isolation performance can be retested within a short time.

In addition, according to the seismic isolator tester having a specimen protection function according to the present invention, even if an emergency situation occurs, it is possible to prevent data loss by backing up the previously tested data.

1 is a schematic view showing a seismic isolator tester having a specimen protection function according to a first embodiment of the present invention.
2 is a block diagram of a seismic isolator tester having a specimen protection function according to a first embodiment of the present invention.
3 is a schematic view showing a seismic isolator tester having a specimen protection function according to a second embodiment of the present invention.
4 is a schematic view showing a tester for a seismic isolator having a specimen protection function according to a third embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement them.

It should be noted that, in the accompanying drawings, the same reference number is used as much as possible when indicating the same configuration in other drawings. In addition, in describing the present invention, when it is determined that a detailed description of a related known function or a known configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, certain features presented in the drawings are enlarged or reduced or simplified for ease of description, and the drawings and their components are not necessarily drawn to scale.

However, those skilled in the art will readily understand these details.

1 is a schematic view showing a seismic isolator tester having a specimen protection function according to a first embodiment of the present invention, and FIG. 2 is a block configuration of a seismic isolator tester having a specimen protection function according to a first embodiment of the present invention It is a degree.

The seismic isolator tester having a specimen protection function according to the present invention is designed to prevent the specimen from being damaged even if an emergency situation occurs during the test of the seismic isolation performance. Frame 20, pressure block 30, pressure device 40, weight sensor 50, first valve 60, second valve 70, third valve 80, fourth valve 90 ), a hydraulic supply unit 100, a pressure sensor 110, a control unit 120, an input unit 130, a display unit 140, a pump driving unit 150, a storage unit 160, and a backup storage unit 170. It is composed of.

The lower frame 10 is rigidly fixed and installed to an outer frame (not shown) by a fixing method such as bolting or welding so that it does not move or rotate even if it receives a vertical load generated by the pressing device 40.

It is preferable that the lower frame 10 is formed in a shape having a length and width of a predetermined shape, and has a flat upper portion so that the roller 12 can move smoothly in the horizontal direction. In addition, the lower frame 10 is preferably made of a material having sufficient durability and rigidity to withstand the vertical load generated by the pressing device 40.

Such a lower frame 10 includes a test bed 11 on which the specimen T is seated, and a roller 12 having the test bed 11 disposed thereon and movable in a horizontal direction.

Here, the test bed 11 is formed to have a larger area than the specimen T in order to test the specimen (T) as the specimen (T) is seated on the top. It is preferable that the upper surface of the test bed 11 is formed flat, and it is movable in the horizontal direction by the roller 12.

On the other hand, although not shown in the drawing, a pressing part that provides a horizontal force from the side to move the test bed 11 and the specimen T located on the upper part of the test bed 11 in the horizontal direction is It can be provided on the side. Here, the pressing unit (not shown) may be made of an actuator in which the rod is expanded or contracted by hydraulic or electric or pneumatic pressure.

The roller 12 is disposed on the upper part of the lower frame 10, the test bed 11 is disposed on the upper part, and is configured to be movable in the horizontal direction.

Specifically, the roller 12 is formed in a cylindrical shape to allow the test bed 11 disposed on the upper part to slide in a horizontal direction as it rolls. That is, when the pressing part (not shown) pushes the test bed 11 by applying a lateral force in the lateral direction, the test bed 11 is moved horizontally by the roller 12. This roller 12 is preferably configured to have sufficient durability and rigidity so as to support the vertical load applied to the test bed 11 and the specimen (T) disposed on the upper portion.

The upper frame 20 is disposed to be spaced apart from the lower frame 10. The upper frame 20 is rigidly fixed to an outer frame (not shown) by a fixing method such as bolting or welding so that the pressurizing device 40 can expand and contract to press the pressurizing block 30.

In more detail, the upper frame 20 serves to act as a reaction force toward the pressing device 40 when the vertical load is applied toward the pressing block 30 as the pressing device 40 is elongated. This upper frame 20, like the lower frame 10, has a shape having a length and width of a certain shape, and is made of a material having sufficient durability and rigidity to withstand the reaction force generated from the pressurizing device 40. It is desirable to be.

The pressing block 30 is disposed between the lower frame 10 and the upper frame 20, and presses the specimen T by an external pressing force. Here, the external pressing force may mean a force generated as a vertical load is applied by the pressing device 40. The pressure block 30 is not newly devised for the implementation of the present invention, and since it is possible to use a pressure block used in an existing seismic isolator test device, it will not be described in detail here.

The pressurizing device 40 is provided under the upper frame 20 and expands and contracts in a vertical direction to press the upper portion of the pressurizing block 30. That is, the pressurization device 40 presses the upper portion of the pressurization block 30 so that the pressurization block 30 presses the upper portion of the specimen T.

More specifically, the pressurization device 40 is applied to the pressure block 30 by receiving the hydraulic pressure supplied from the hydraulic pressure supply unit 100 according to the preset pressure in the input unit 130 through the first valve 60. Apply a test load of the size to be measured. This pressurizing device 40 may be made of a double-rod hydraulic cylinder provided on both sides of rods capable of forward and backward withdrawal operations using hydraulic pressure. The pressurizing device 40 is preferably connected to the first valve 60 through a hydraulic pilot line (not shown) in order to receive pressure from the first valve 60.

At this time, it has been described that the pressurizing device 40 is provided under the upper frame 20, but this is only an example for convenience of description, and a chamber (not shown) that receives pressure from the first valve 60 is the upper frame It is mounted inside of the 20, is connected to the first valve 60 and the hydraulic pilot line, the rod may be configured to pressurize the pressure block 30 from the outside of the upper frame (20).

In addition, the pressing device 40 is divided into at least one or more and provided under the upper frame 20. The reason why the pressurization device 40 is configured by dividing it into at least one or more is for facilitating manufacturing and for precise measurement in a high load area.

Of course, the pressurizing device 40 is not divided into at least one or more, but may be formed as a single unit.

On the other hand, when the pressurizing device 40 is divided into at least one or more, it is preferable that a hydraulic circuit is configured to prevent an unbalanced load from being applied to each pressurizing device 40.

The weight detection sensor 50 is provided on the upper part of the pressing block 30, and measures the vertical load generated as the pressing device 40 presses the pressing block 30 to create a measurement value. The weight detection sensor 50 may apply a load cell capable of measuring a weight ranging from a small amount to several thousand tons. Here, since the load cell is a known technology, a detailed description will be omitted.

On the other hand, the weight sensing sensor 50 may use not only a load cell, but also various known weight sensing measuring means.

However, it is preferable to apply a load cell to the weight sensing sensor 50 in order to directly and highly responsively measure the tensile and compressive load applied to the specimen. In addition, as the weight detection sensor 50 is made of a load cell, it is possible to easily measure the vertical load generated by the pressurizing device 40, and in particular, for controlling the first valve 60 according to the measured value. The tearing phenomenon of the control value can be prevented.

The weight detection sensor 50 is provided on the upper portion of the pressure block 30 corresponding to the number of pressurization devices 40. Of course, when the pressurizing device 40 is provided as a single unit, the weight sensing sensor 50 must also be provided in a single unit.

However, it is preferable that the weight sensing sensor 50 used in the present invention is configured corresponding to the number of pressurizing devices 40. This is because it is easier to manufacture than the case where the weight sensing sensor 50 is provided as a single unit. It is also advantageous in terms of calibration and maintenance.

The first valve 60 is provided on one side of the upper frame 20 and serves to adjust the hydraulic pressure supplied from the hydraulic supply unit 100 through the hydraulic supply line L and apply it to the pressurizing device 40.

More specifically, the first valve 60 receives power from the outside, receives feedback from the control unit 120, and finely adjusts the hydraulic pressure supplied through the hydraulic supply line (L) to the pressurizing device (40). Approved. Here, the feedback may be defined as a data value for controlling the opening/closing operation of the first valve 60 through a vertical load value measured by the weight sensor 50.

The first valve 60 may be formed of a servo valve suitable for a large flow rate. In particular, the first valve 60 may be applied to a three-stage servo valve. The first valve 60 is connected to the pressurizing device 40 through a hydraulic pilot line, and performs an opening/closing operation under the control of the controller 120. To this end, the first valve 60 is dualized, and a shutoff valve may be provided for each valve. In addition, it is preferable that the first valve 60 is installed as close as possible to the pressurizing device 40 so that a response delay phenomenon does not occur from the control unit 120.

The second valve 70 is provided on the hydraulic supply line L and serves to reduce the pressure of the hydraulic oil supplied to the first valve 60.

More specifically, the second valve 70 reduces the pressure of the hydraulic oil supplied from the hydraulic supply unit 100 to the pressurizing device 40 through the hydraulic supply line L and prevents high pressure from being transmitted. Plays a role. This second valve 70 may be formed as a pressure reducing valve. Here, the pressure reducing valve blocks the flow path from the hydraulic supply unit 100 to the pressurizing device 40 when the pressure reaches a preset pressure to prevent the pressure from rising to the pressurizing device 40 side.

Meanwhile, the second valve 70 may be used together when the third valve 80 operates the pressurizing device 40 below a preset pressure. In addition, the second valve 70 may perform an opening/closing operation under the control of the controller 120.

The third valve 80 is provided on the hydraulic supply line L, and when the hydraulic oil depressurized through the second valve 70 is supplied above a preset hydraulic pressure, it is opened and serves to discharge a part of the hydraulic pressure. The third valve 80 may be configured as a general relief valve that sets the maximum pressure in the circuit and discharges the hydraulic oil to the oil tank (not shown) when the pressure is reached. That is, the operator can test the performance of the seismic isolator by setting the pressure to the third valve 80 in advance and applying hydraulic pressure only within the pressure. For this reason, even if an emergency situation such as a power failure or system error occurs, it is possible to prevent a phenomenon in which a high load is applied to the specimen T, thereby protecting the specimen.

The fourth valve 90 is provided on the hydraulic supply line L, opens and closes, and when opened, drives the hydraulic supply unit 100 under load, and when closed, operates the hydraulic supply unit 100 without load. do. This fourth valve 90 may be formed of a conventional solenoid valve. In other words, the hydraulic pressure supplied from the hydraulic supply unit 100 is controlled to a desired force according to the control of the controller 120 and then sent in the direction to be used.

Meanwhile, although the third valve 80 and the fourth valve 90 have been separately described, the present invention is not limited thereto. That is, the third valve 80 and the fourth valve 90 are not distinguished, and a single solenoid valve may be used. Here, when the pressure of the hydraulic oil supplied from the hydraulic supply unit 100 does not reach a preset pressure value, the sole relief valve returns the hydraulic oil to the oil tank (not shown) in a no-load state, and the pressure of the hydraulic oil reaches a preset pressure value. When it reaches, it leaves only the hydraulic oil enough to maintain the set pressure and sends the rest back to the oil tank (not shown). Accordingly, if the sole relief valve is used without separating the third valve 80 and the fourth valve 90 separately, the amount of heat generated in the hydraulic circuit can be minimized.

On the other hand, the second to fourth valves (70, 80, 90) are shown in a box shape in the drawing, but this is only an example for convenience of description, and each of the valves (70, 80, 90) is the pressurizing device 40 Any configuration is not a problem as long as it is a configuration that efficiently applies hydraulic pressure to the device. That is, the hydraulic circuits of the second to fourth valves 70, 80, and 90 are organically coupled to each other to smoothly depressurize the hydraulic oil supplied from the hydraulic supply unit 100 and send it to the first valve 60. I can.

Meanwhile, the hydraulic supply unit 100 serves to supply hydraulic pressure to the pressurizing device 40, and may be formed of a general hydraulic pump including a pump driving unit 150 such as an electric motor. Such a hydraulic pump is a known technology and is not intended to be described in the present invention, so a detailed description thereof will be omitted.

The pressure sensor 110 is provided on the hydraulic supply line L and serves to measure the pressure of hydraulic oil supplied from the hydraulic supply unit 100. The pressure sensor 110 may use a known pressure sensor capable of measuring the pressure of the flow rate. At this time, the pressure sensor 110 is shown to be provided on the side of the fourth valve 90 in the drawing, but this is only an example for convenience of description, and between the second valve 70 and the third valve 80 It is preferable to measure the pressure of the hydraulic oil that is provided and depressurized through the second valve 70.

The control unit 120 includes first to fourth valves according to the pressure value input from the input unit 130 to which a preset pressure value is input for the test of the pressurization device 40 and the measured value measured by the weight sensor 50. (60,70,80,90) It plays a role of controlling the opening and closing operation of each. Here, the preset pressure value may be defined as a test pressure value previously designated by the operator to test the performance of the seismic isolator tester. The preset pressure value may be stored in the storage unit 160. In addition, the storage unit 160 may include an algorithm and a control program for controlling each of the valves 60, 70, 80, and 90.

Accordingly, when a preset pressure value is input to the input unit 130, the control unit 120 stores the input pressure value in the storage unit 160 and stores the first to fourth valves through the preset input pressure value. It controls the opening and closing operation of (60,70,80,90).

In addition, the control unit 120 controls the pump driving unit 150 to drive the hydraulic pressure supply unit 100 according to a preset pressure value.

In addition, the control unit 120 may generate a monitoring signal for monitoring the pressure value measured by the pressure sensor 110. Such a monitoring signal may include the pressure of the hydraulic oil flowing in the hydraulic supply line L or the state of the valves 60, 70, 80, and 90 and the pressurizing device 40. It is preferable that the control unit 120 includes a communication unit (not shown) to transmit the generated monitoring signal to the display unit 140. Here, the communication unit (not shown) transmits the monitoring signal generated by the control unit 120 to the display unit 140 using either a long-distance communication module or a short-range communication module.

The display unit 140 receives the monitoring signal generated by the control unit 120 through the communication unit (not shown) and displays it in time. That is, the display unit 140 may output a monitoring signal in various ways, such as outputting an image, a graph, or an image.

Meanwhile, the control unit 120, the input unit 130, the display unit 140, the pump driving unit 150, and the storage unit 160 have been separately described, but this is only an example for convenience of description, It is desirable to be integrated and provided.

Accordingly, the present invention is configured as described above to test the performance of the seismic isolator, and even if an emergency situation such as a power failure or system error occurs, the pressurizing device through the second to fourth valves 70, 80, and 90 It is possible to prevent high pressure from being applied to (40). Due to this, it is possible to prevent the specimen from being damaged.

However, at this time, if an emergency situation such as a power outage or system error occurs, the power supply is cut off and the setting values and test data for testing the performance of the seismic isolator are lost, and the performance test of the seismic isolator is performed again from the beginning. In order to solve this problem, the present invention further includes a backup storage unit 170.

The backup storage unit 170 is provided separately from the storage unit 160 to test the performance of the seismic isolator, that is, the measurement value measured by the weight sensor 50 and the result of the test data of the specimen (T). The last data is configured to be saved automatically. For this reason, even if the seismic isolator tester is restarted after various components are forcibly terminated in an emergency situation, the backup storage unit 170 reloads the stored data and automatically sets it. As a method for reloading the backup data, when a user presses a reset button (not shown) or a power button (not shown), a method of automatically reloading can be applied.

3 is a schematic view showing a seismic isolator tester having a specimen protection function according to a second embodiment of the present invention.

In describing FIG. 3, a detailed description of the same part as the above-described first embodiment or parts that can be easily understood with reference to the first embodiment will be omitted.

Referring to FIG. 3, in the case of a seismic isolator tester having a specimen protection function according to a second embodiment of the present invention, when the power supply is cut off due to an emergency situation such as a power failure or system error, the pressurizing device 40 ), and to re-operate the seismic isolation system tester within a short time by connecting the emergency generator (E) to the hydraulic supply unit 100, and to perform the seismic isolation performance test again, on the hydraulic supply line (L). It is configured to include a fifth valve 200 provided in the emergency generator (E) connected to the hydraulic supply unit 100.

The fifth valve 200 is provided on the hydraulic supply line L, and serves to automatically cut off the flow of hydraulic oil when an emergency situation occurs and power supply is cut off. The reason why the fifth valve 200 blocks the flow of hydraulic oil as described above is that when an emergency occurs, the operation of the hydraulic supply unit 100 is not stopped immediately, but gradually stops, so that the hydraulic oil is not operated. This is because it can be supplied to the pressurizing device 40 until it is completely stopped. That is, in order to prevent the high pressure from being applied to the pressurizing device 40, the flow of the hydraulic oil is blocked by using the fifth valve 200.

The fifth valve 200 is composed of a solenoid valve, and maintains an open state when power is supplied normally, and closes when power is cut off due to an emergency situation. The fifth valve 200 maintains the closing operation only until the emergency generator E operates normally or commercial power is normally supplied, and then emergency power is supplied from the emergency generator E or commercial power is normally supplied. Then it will remain open again.

On the other hand, when the fifth valve 200 is blocking the flow of hydraulic oil, it is configured to apply power to the seismic isolator tester using the emergency generator (E).

When the commercial power supplied to the seismic isolator tester is cut off, the emergency generator (E) generates emergency power and supplies it to the seismic isolator tester. At this time, the emergency generator may be configured to check whether an abnormality has occurred due to the commercial power being cut off or whether a problem has occurred in the system, and can be automatically operated accordingly.

Therefore, in the seismic isolator tester having a specimen protection function according to the second embodiment of the present invention, even if an emergency situation occurs through the fifth valve 200, high pressure is applied to the pressurizing device 40 to damage the specimen T. This can be prevented, and the seismic isolation performance test can be re-performed within a short time by resupplying power through the emergency generator (E).

However, the seismic isolator tester having a specimen protection function according to the second embodiment has a disadvantage in that electricity costs are high since power must be supplied to the fifth valve 200 throughout the performance test of the seismic isolator.

In order to solve this problem, a sixth valve 300 and an uninterruptible power supply U as shown in FIG. 4 were used.

4 is a schematic view showing a tester for a seismic isolator having a specimen protection function according to a third embodiment of the present invention.

In describing FIG. 4, detailed descriptions of parts that are the same as those of the first and second embodiments described above or parts that can be easily understood with reference to the first and second embodiments will be omitted.

Referring to FIG. 4, the seismic isolator tester having a specimen protection function according to the third embodiment of the present invention solves the problem of supplying power to the fifth valve 200 throughout the performance of the seismic isolator. It is configured to include the sixth valve 300 and the uninterruptible power supply (U).

The sixth valve 300 is provided on the hydraulic supply line (L), and when power is cut off due to an emergency situation, it is closed as power is supplied by the uninterruptible power supply unit (U) to block the flow of hydraulic oil. Plays a role. Unlike the fifth valve 200, the sixth valve 300 is composed of a solenoid valve in an open state and is configured to be closed only when power is supplied. Therefore, since the sixth valve 300 does not need to supply power throughout the performance test of the seismic isolating device, electricity cost can be saved. In addition, even if an emergency situation occurs, it is closed by receiving emergency power by the uninterruptible power supply U, thereby blocking the flow of hydraulic oil, so that high pressure is not applied to the pressurizing device 40, thereby preventing damage to the specimen.

On the other hand, the sixth valve 300, like the fifth valve 200, it is preferable to maintain the closing operation only until the emergency generator E is normally operated or commercial power is normally supplied.

Meanwhile, the uninterruptible power supply U stores and stores power, and supplies the stored power to the sixth valve 300 according to the system monitoring and control of the controller 120. The uninterruptible power supply U is not shown in detail in the drawings, but may include a battery, a charge/discharge control unit, and a battery monitoring unit.

The battery is a component that stores power for use as emergency power, and may be configured to temporarily provide a predetermined amount of power for driving the sixth valve 300. For example, the battery capacity may be designed to have a capacity sufficient to supply the amount of power required to drive the sixth valve 300 for a predetermined period of time in case of an emergency situation such as a power failure. In particular, the battery capacity is determined by the operation of the sixth valve 300 for the time set to determine whether to drive the emergency generator E and the time required for the generator E to perform normal power output after driving the emergency generator E. It can be designed to have a capacity enough to supply the power required for it.

The battery monitoring unit calculates the charging and discharging state of the battery, and provides the setting time and the remaining amount of the battery information to the control unit 120. In this case, the control unit 120 may be configured to include the provided battery remaining amount information in the monitoring signal so that the display unit 140 displays the remaining battery amount of the uninterruptible power supply U.

The charge/discharge control unit supports charging of battery energy under the control of the control unit 120 and supports discharging control of the battery based on a command of the control unit 120.

Therefore, in the seismic isolator tester having a specimen protection function according to the third embodiment of the present invention, even if an emergency situation occurs through the sixth valve 300, a high pressure is applied to the pressurizing device 40 to damage the specimen T. This can be prevented, and the seismic isolation performance test can be re-performed within a short time by resupplying power through the emergency generator (E). In addition, unlike the second embodiment, since the sixth valve 300 is made in an open state, there is no need to supply power throughout the performance test of the seismic isolator, so that electricity costs can be saved.

Although the invention made by the present inventor has been described in detail according to the above embodiment, the invention is not limited to the above embodiment, and it goes without saying that various changes can be made without departing from the gist of the invention.

Lower frame: 10
Test bed: 11 Rollers: 12
Upper frame: 20 Pressurized block: 30
Pressurized device: 40 Weight sensor: 50
First valve: 60 Second valve: 70
3rd valve: 80 4th valve: 90
Hydraulic supply: 100 Pressure sensor: 110
Control unit: 120 Input unit: 130
Display unit: 140 Pump drive unit: 150
Storage unit: 160 Backup storage unit: 170
5th valve: 200 6th valve: 300

Claims (4)

A test bed on which the specimen is seated;
A lower frame having the test bed disposed thereon and having a roller movable in a horizontal direction thereon;
An upper frame disposed to be spaced apart from the lower frame;
A pressing block disposed between the lower frame and the upper frame and pressing the specimen by an external pressing force;
A pressurizing device provided under the upper frame and expanding and contracting in a vertical direction to press the upper portion of the pressurizing block; And
A seismic isolator tester having a specimen protection function, characterized in that it comprises a weight detection sensor provided on the upper part of the pressing block and measuring a vertical load generated when the pressing device presses the pressing block to create a measurement value. .
In claim 1,
A first valve provided on one side of the upper frame and controlling hydraulic pressure supplied from a hydraulic supply unit through a hydraulic supply line and applying it to the pressurizing device;
A second valve provided on the hydraulic supply line to reduce a pressure of hydraulic oil supplied to the first valve;
A third valve provided on the hydraulic pressure supply line and opened when the hydraulic oil depressurized through the second valve is supplied above a preset hydraulic pressure to discharge a part of the hydraulic pressure;
A fourth valve provided on the hydraulic supply line, opened and closed, and operates the hydraulic supply unit with a load when it is open and operates the hydraulic supply unit with no load when it is closed; And
A control unit for controlling the operation of each of the first to fourth valves according to the pressure value input from an input unit to which a preset pressure value is input for testing of the pressurization device and a measurement value measured by the weight sensor; Including more,
In the hydraulic supply line
A pressure sensor for measuring the pressure of the hydraulic oil supplied from the hydraulic supply unit is provided,
The control unit
Generate a monitoring signal for monitoring the pressure value measured by the pressure sensor,
And a display unit for visually displaying the monitoring signal generated by the control unit.
In claim 2, the hydraulic supply line
A seismic isolator tester having a specimen protection function, characterized in that a fifth valve is provided on one side that is closed and blocks the flow of hydraulic oil when power is cut off in case of an emergency.
In claim 2, the hydraulic supply line
A seismic isolator tester having a specimen protection function, characterized in that a sixth valve is provided on one side to block the flow of hydraulic oil by being closed as power is supplied by the uninterruptible power supply when power is cut off during an emergency situation.

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