KR102291642B1 - Optimization device and optimization method of specimen test equipment for seismic countertop - Google Patents

Abstract

The present invention provides a test by maintaining an optimal state in the process of testing a seismic isolation bearing specimen, that is, preventing high-temperature heat from being transferred to a load sensor according to pressure and optimizing the temperature condition of the specimen to be tested. a cooling means provided on the upper portion of the pressure plate provided in the test equipment for testing the specimen for seismic isolation support to block the transfer of high-temperature heat generated from the pressure plate according to the pressure for testing the specimen to the load sensor; and a cooling/heating chamber provided outside the specimen to satisfy the temperature condition of the specimen while not being exposed to the test environmental conditions.
Accordingly, it has the effect of providing accurate measurement values for the seismic isolation bearing, and also has the effect of securing high safety in the installation target.

Description

Optimization device and optimization method of specimen test equipment for seismic countertop

The present invention relates to being applied to testing equipment for testing seismic support specimens, and more particularly, to maintain an optimal state in the process of testing seismic support specimens, that is, use a load sensor according to pressure to It relates to an optimization device and optimization method for specimen testing equipment for seismic isolation bearings that prevents heat transfer and optimizes the temperature condition of the specimen to be tested.

In general, lead seismic bearings (LRBs, hereinafter referred to as 'seismic bearings') solve safety problems with respect to temperature dependence, durability, and repeated loads by inserting a lead core into an elastic bearing made of a laminate of rubber and steel plates, while at the same time solving an earthquake. It absorbs and dissipates horizontal energy.

These seismic isolation bearings are mainly applied and used in bridge structures. They resist short-term loads acting at high speeds such as wind loads and braking loads with lead elastic stiffness, and thus have stability against regular loads, such as temperature changes. It deforms easily against displacement and does not transmit a large load to the substructure.

In addition, for seismic loads, it absorbs and dissipates seismic energy through plastic deformation of lead, and it has a restoration performance that returns to the original position after the earthquake has ended, so there is no need for separate maintenance.

In this way, the bridge bearing, which plays an important role by being applied to the bridge structure, is tested whether the specimen of the manufactured bridge bearing is suitable for each condition through the test equipment after manufacturing.

Conventional test equipment for testing the specimen of the seismic isolation bearing includes a pressing means such as a cylinder that applies a load from the top, a load sensor such as a load cell that measures the pressing force on the lower part of the pressing means, and a pressurized object directly below the load sensor. It has a technical configuration including a pressure plate for pressing with a pressure plate, a test target specimen positioned under the pressure plate, and a supporting means for supporting and supporting the specimen on the lower portion of the specimen. The support means may include a horizontal sliding means for measuring horizontal displacement.

However, in such a conventional test equipment, the high-temperature heat generated from the pressure plate according to the load pressure is transferred to the load sensor as it is, so as the load value of the load sensor changes, accurate measurement is not performed.

In addition, the specimen to be tested also has a disadvantage in that an accurate test is not performed due to a change in the characteristics of the specimen itself due to temperature change, etc.

As described above, in the prior art related to the performance or testing of the seismic isolator bearing, the pendulum of a pendulum in a pendulum type seismic isolation device as disclosed in Korean Patent Publication No. 10-1284887 (hereinafter referred to as 'prior art document 1'). Techniques such as an improved pendulum type seismic isolator test device that can load hydrostatic force while maintaining homeostasis in the hydrostatic direction against continuous height deviations (changes) that occur during motion have been proposed.

In addition, as posted in Korean Patent Publication No. 10-1443811(), it detects whether displacement of the bridge occurs in real time and wirelessly notifies the administrator when an abnormality occurs, thereby safely managing the bridge and preventing safety accidents in advance. At the same time, techniques such as a bridge displacement measurement system and a displacement measurement method using the same have been proposed, which can reduce the time and cost required for bridge management.

In addition, as published in Korean Patent Publication No. 10-1547156 (hereinafter referred to as 'Prior Art Document 3'), the seismic response of a structure to which the seismic isolation system is applied is predicted in a simplified way, and the cost of Mont-Carlo simulation is reduced and seismic isolation A technique such as a method for estimating the support response distribution of seismic isolating structures that can efficiently evaluate the seismic performance of structures to which the system is applied has been proposed.

Republic of Korea Patent Publication No. 10-1284887 Republic of Korea Patent Publication No. 10-1443811 Republic of Korea Patent Publication No. 10-1547156

However, prior art documents 1 and 3 have disadvantages in that they are not suitable for testing the specimens of the actual seismic isolation bearing as described in the background technology of the invention, and lack the technical configuration for accurate testing.

Prior art document 2 will be said to be a technology that provides the safety of a structure to which the seismic isolation bearing is applied, rather than a test on the seismic isolation bearing.

The specific technical solution of the present invention for solving the problems of the prior art is to maintain the optimal state in the process of testing the specimen for seismic isolation bearing, that is, to generate high-temperature heat by the load sensor according to the pressure. It is to provide an optimization device and optimization method of specimen testing equipment for seismic isolation bearings that prevent transmission and optimize the temperature condition of the specimen to be tested.

The specific technical solution means of the present invention for solving the specific technical problems as described above is a pressing means for applying a load from the upper portion, a load sensor for measuring the pressing force on the lower portion of the pressing means, and directly applying a pressure object to the lower portion of the load sensor. Optimization device for optimization according to specimen testing in a test equipment for testing a specimen for seismic isolation bearing comprising a pressure plate to be pressed, a specimen to be tested located under the pressure plate, and a support means for supporting and supporting the specimen under the specimen As a result, the optimization device includes: a cooling means provided on the upper portion of the pressure plate to block the transfer of high-temperature heat generated from the pressure plate to the load sensor according to the pressure for testing the specimen; and a cooling/heating chamber provided on the outside of the specimen to satisfy the temperature condition of the specimen while not being exposed to the test environmental conditions.

The cooling means includes a circulation path formed in a zigzag shape to circulate the refrigerant on the upper portion of the pressure plate, a connection line connected to the circulation path and the refrigerant to circulate, a cooling device provided in the connection line, and a control provided in a recovery line of the connection line It includes a valve and a temperature sensor provided on the pressure plate.

The temperature sensor is connected to the control valve and further includes adjusting the circulation amount of the refrigerant by the control unit according to the temperature of the pressure plate.

The cooling chamber is a chamber that surrounds the outside of the specimen to be blocked from the outside, a temperature sensor provided inside the chamber, and a temperature sensor provided in the chamber to maintain a constant temperature so that the characteristics of the specimen do not change according to the temperature measured by the temperature sensor into the chamber. a heat exchanger connected thereto.

Pressing means for applying a load from an upper portion, a load sensor for measuring a pressing force on the lower portion of the pressing means, a pressure plate for directly pressing a pressure object under the load sensor, a test object located under the pressure plate, and a test piece of the specimen As an optimization method for optimization according to a specimen test in a test equipment for testing a specimen for seismic isolation bearing that includes a supporting means for supporting and supporting the specimen at the lower portion, the optimization method is the high temperature blocking heat from being transferred to the load sensor; and adjusting the internal temperature of the specimen so as not to be exposed to the test environment on the outside of the specimen and not changing the internal characteristics of the specimen to satisfy the temperature condition.

The present invention optimizes the temperature condition of the specimen to be tested so that it can be tested by maintaining the optimal state in the process of testing the specimen for seismic isolation bearing, that is, by preventing the transfer of high-temperature heat to the load sensor according to the pressure. By making it possible to test, it has the effect of providing accurate measurement values for the seismic isolation bearing, and also has the effect of securing high safety in the installation target.

1 is a schematic front view for explaining the concept of the present invention;
Figure 2 is a plan view for explaining the cooling means according to Figure 1;
3 is a block diagram for explaining the optimization method of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, and the present invention is not limited or limited by the embodiments.

1 is a schematic front view for explaining the concept of the present invention, and FIG. 2 is a plan view for explaining the cooling means according to FIG. 1 .

As shown, the test equipment 100 for testing a typical seismic isolation bearing specimen includes a pressing means 110 such as a conventional cylinder that applies a load from an upper portion, and a conventional measuring pressure on the lower portion of the pressing means 110 . A load sensor 120 such as an in-load cell, a pressure plate 130 that directly presses an object to be pressed under the load sensor 120 , and a specimen S as a test object located under the pressure plate 130 . And it has a technical configuration including a supporting means 140 for supporting the specimen (S) in the lower portion of the specimen (S).

In this conventional test equipment, accurate measurement is not made as the load value of the load sensor changes as the high-temperature heat generated from the pressure plate according to the load pressure as described in the background of the invention is transferred to the load sensor as it is. has the disadvantage of not

In addition, the specimen to be tested also has a disadvantage in that an accurate test is not performed due to the change in the characteristics of the specimen itself due to temperature change, etc.

The present invention optimizes the temperature condition of the specimen to be tested so that it can be tested by maintaining the optimal state in the process of testing the specimen for seismic isolation bearing, that is, by preventing the transfer of high-temperature heat to the load sensor according to the pressure. to be able to test it.

The optimization device 1 of the specimen testing equipment for seismic isolation bearing according to the present invention is a high-temperature heat generated from the pressing plate 130 according to the pressing for the specimen test on the upper portion of the pressing plate 130 that directly presses the test object. Cooling means (10) provided to block transmission to the load sensor (120); and a cooling/heating chamber 20 provided to satisfy the temperature condition of the specimen (S) while not being exposed to the test environmental conditions on the outside of the specimen (S).

In other words, the cooling means can prevent the load value of the load sensor from being changed as the high-temperature heat generated from the pressure plate according to the pressurization is not transferred to the load sensor, so that the correct load value can be measured. do

In addition, the cold-heat chamber can also be tested in a state with the characteristics of the specimen itself while not exposing the specimen for seismic isolation bearing, which is the test object, to the test environmental conditions, so that a more accurate test can be made.

As a result, the conditions of the seismic isolation bearing specimen to be tested can be accurately tested, and the appropriate seismic isolating bearing can be selected and installed on the installation target to be installed, thereby establishing safer conditions for use.

The cooling means 10 is connected to a circulation path 11 formed in a zigzag shape by a conventional processing method so that the refrigerant circulates in the upper part of the pressure plate 130, and the circulation path 11 and the refrigerant such as cooling water are circulated, That is, a conventional connection line 12 such as a supply line and a recovery line, a conventional chiller 14 provided to supply a refrigerant to the connection line 12 at an appropriate temperature, and the connection line 12 ) is provided in the recovery line and includes a conventional control valve 15 for controlling the circulation amount of the refrigerant and a temperature sensor 16 provided on the pressure plate 130 .

In other words, by lowering or increasing the temperature of the refrigerant in the cooling device according to the temperature of the pressure plate of the temperature sensor and controlling the amount of refrigerant circulated through the control valve, the high temperature heat generated in the pressure plate according to the pressurization of the specimen is blocked, That is, the high-temperature heat is not transferred to the load sensor as it is lowered.

As a result, the load value in the load sensor is not changed by high-temperature heat, so that an accurate load value can be calculated.

In addition, it is preferable that the control valve 15 adjusts the circulation amount of the refrigerant by a conventional controller (not shown) according to the temperature of the pressure plate 130 sensed by the temperature sensor 16 .

It is desirable to construct a technical configuration for appropriately cooling the pressure plate according to the temperature change as the temperature change is made in real time on the pressure plate.

Therefore, it has a condition that can fundamentally block the transfer of high-temperature heat generated during pressurization to the load sensor.

In addition, the above-described cooling means is only an example, and any known technical configuration may be applied so that the high-temperature heat generated from the pressure plate is not transferred to the load sensor.

The cooling chamber 20 includes a conventional chamber 22 that surrounds the outside of the specimen S to be blocked from the outside, a conventional temperature sensor 24 provided inside the chamber 22, and the chamber 22 ) into a conventional heat exchanger (not shown) connected by a conventional method to supply hot or cold air to maintain a constant temperature so that the properties of the specimen S do not change according to the temperature measured by the temperature sensor 24 into the ) is included.

As a result, as the specimen to be tested also has optimal conditions, the test can be made more accurately and precisely.

Accordingly, the present invention is to have the optimal conditions by a simple technical configuration rather than a complicated technical configuration when testing a specimen for seismic isolation bearing, so that it can be tested with an accurate measurement value for the specimen to be tested.

This, in turn, has the conditions for ensuring high safety from the installation target by having precise conditions for installing the seismic isolation bearing.

3 is a block diagram for explaining the optimization method of the present invention.

As shown, it also provides an optimization method for testing the specimen for seismic isolation bearings under the optimal conditions in the process of testing the specimens using conventional testing equipment.

First, a step (S1) of blocking the high-temperature heat generated by the pressure plate from being transferred to the load sensor during pressurization according to the specimen test is performed by a known method. This may be performed by an example cooling means as in the above-described optimization device.

In addition, it includes the step (S2) of meeting the temperature condition by adjusting the internal temperature so that the internal characteristics of the specimen are not changed while not being exposed to the test environment conditions on the outside of the specimen in a conventional manner. It will also be said that this can be performed by the cooling chamber in the above-described optimization device.

Accordingly, the optimization method of the present invention also allows testing under optimal conditions in the process of testing the specimen for seismic isolation bearing, so that accurate measurement values can be calculated through the test, providing high safety for the installation target to install the seismic support. conditions can be established.

1: Optimizer
10: cooling means 11: circulation path
12: connection line 14: cooling device
15: control valve 16, 24: temperature sensor
20: cooling chamber 22: chamber
100: test equipment
110: pressurizing means 120: load sensor
130: pressure plate 140: support means

Claims (5)

A pressing means for applying a load from an upper portion, a load sensor for measuring a pressing force on the lower portion of the pressing means, a pressing plate for directly pressing a pressing object under the load sensor, a test object located under the pressing plate, and the specimen of the specimen As an optimization device for optimizing the temperature condition of the specimen test in a test equipment for testing a specimen for seismic isolation bearing including a supporting means for supporting and supporting the specimen at the bottom,
The optimization device includes a cooling means provided on the top of the platen to block the transfer of high-temperature heat generated from the platen to the load sensor according to the pressurization for testing the specimen; and
It includes; a cooling and heating chamber provided to satisfy the temperature condition of the specimen while not being exposed to the test environmental conditions on the outside of the specimen.
The cooling means is a circulation path formed in a zigzag form so that the refrigerant circulates on the upper portion of the pressure plate,
a connection line connected so that the circulation path and the refrigerant are circulated;
a cooling device provided in the connection line;
a control valve provided in the return line of the connection line; and
Including a temperature sensor provided on the pressure plate,
The control valve controls the circulation amount of the refrigerant by the control unit according to the temperature of the pressure plate sensed by the temperature sensor,
The cooling chamber is a chamber that surrounds the outside of the specimen to block it from the outside;
a temperature sensor provided inside the chamber;
Specimen test for seismic isolation support, characterized in that it includes a heat exchanger that maintains a constant temperature so as not to change the characteristics of the specimen by supplying hot or cold air into the chamber according to the temperature measured by the temperature sensor provided in the chamber. equipment optimization device. delete delete delete A pressing means for applying a load from an upper portion, a load sensor for measuring a pressing force on the lower portion of the pressing means, a pressing plate for directly pressing a pressing object under the load sensor, a test object located under the pressing plate, and the specimen of the specimen An optimization method for optimizing the temperature conditions of a specimen test using the optimization device of the specimen testing equipment for seismic isolation support according to claim 1 in a test equipment for testing a specimen for seismic isolation support that includes a support means for supporting and supporting the specimen at the bottom As,
(a) blocking the high-temperature heat generated from the pressure plate from being transmitted to the load sensor during pressurization according to the specimen test; and
(b) satisfying the temperature condition by adjusting the internal temperature so that the characteristics of the specimen are not changed while not being exposed to the test environment on the outside of the specimen;
In the step (a), the refrigerant is supplied through a circuit formed in a zigzag shape on the upper portion of the pressure plate, and the circulation path and the refrigerant are circulated according to the temperature of the pressure plate detected by a temperature sensor installed on the pressure plate. Controls the circulation amount of refrigerant by driving the control valve provided in the recovery line of
In the step (b), the outer side of the specimen is surrounded by a chamber to block it from the outside, and the heat exchanger is driven according to the measured temperature of the temperature sensor provided inside the chamber to supply hot or cold air into the chamber, so that the characteristics of the specimen are Optimization method of specimen testing equipment for seismic isolation bearing, characterized in that it maintains a constant temperature so as not to change.

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