KR200239375Y1 - Measurable bridge bearing - Google Patents

Abstract

The present invention adds a load cell to a spherical bridge device having an upper plate, a lower plate, a rubber plate, a piston, a sliding plate, and a stainless plate to enable measurement of the bridge at normal times. The present invention has an upper plate fixed to an upper structure of a bridge, a lower plate fixed to a lower structure of a bridge, a rubber plate inserted into a recess of the lower plate, a piston located on an upper portion of the rubber plate, and a piston at the top of the piston. In the load cell and the load cell having a sliding plate adhered to a spherical surface and a stainless plate attached to the upper plate at the upper part of the sliding plate, the lower plate is contacted with a portion of the lower surface of the rubber plate to measure the partial load applied to the rubber plate. It is possible to measure at any time by providing a connection path to connect the generated signal to the outside.

Description

Measuring instrument for measuring device {MEASURABLE BRIDGE BEARING}

The present invention relates to a measuring bridge device, and more specifically, to the spherical bridge device that is installed on the upper part of the bridge supporting the upper plate of the bridge and receives the load and deformation of the upper plate, The present invention relates to an instrument for measuring measurement, in which a measurement device is installed to enable measurement at all times.

Spherical chair devices are used in various forms, and Korean Utility Model Publication No. 1999-001241 discloses an example of such a spherical chair device. The spherical stabilizing device according to the present disclosure is expected to relieve shock and vibration by inserting a rubber plate on the lower surface of the piston.

In general, five years after the completion of a bridge or the like, the structure safety diagnosis is carried out to evaluate the safety of the bridge structure, and if there is no problem, the management work is transferred to the competent supervisory authority. To this end, it is necessary to evaluate the safety of bridge structures, and bridge management is required to prevent large-scale accidents in advance for bridges that have passed a certain period after completion. To this end, in order to check the safety of the bridge structure, a separate measurement equipment is installed at the middle of the upper plate of the bridge, and the test vehicle is operated to measure the load and various displacements acting on the bridge and analyze the data to analyze the state of the bridge. Measured.

The bridge using the spherical bridge device according to the above-described open design should proceed in the conventional method described above at the time of measurement. Therefore, it is difficult to determine the durability life of the structure only by the data at the time of measurement, because only the characteristics of the structure at the time of measurement can not be checked and continuous changes of the structure cannot be checked. In addition, by installing a separate measuring device for the measurement and running a test vehicle, there is a problem in that it takes a lot of time and manpower and costs, such as restrictions on vehicle traffic, and takes a long time to measure and analyze.

On the other hand, the precise safety diagnosis of the spherical cross-section device by the open design is carried out by a method of measuring the variation stress using the visual inspection or the attached strain gauge. Can be measured, but there is a problem in that it is not possible to determine critical factors such as deformation of the bridge deck and settlement of the bridge.

The present invention is to solve this problem, and its purpose is to provide a new type of measuring instrument that can check the continuous changes of the structure and reduce the cost, manpower and time required to measure the bridge. have.

1 is a cross-sectional view for explaining the measuring device for measuring according to the present invention;

Figure 2 is a graph showing the relationship between the load applied to the instrument and the load measured in the instrument using the measuring instrument for 130 tons according to the present invention;

3 is a graph showing the relationship between the load applied to the instrument and the load measured in the instrument using the measuring instrument for 600 tons according to the present invention;

4 is a view showing an example of the bridge measuring system configured by using the measuring bridge device according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: measuring instrument 20: top plate

22,32: anchor bolt 24: stainless steel plate

30: lower plate 34: guide angle

36: packing 40: sliding plate

42: piston 44: rubber plate

50: load cell 52: connection passage

54: temperature measuring device 56: X, Y axis displacement measuring device

58: Z-axis displacement measuring device 12: data storage device

13: transceiver 13 ': transmitter

13 ': receiver 14: data comparison and analysis device

15 monitor 16 alarm device

A: Measuring instrument B: Upper plate

C: Pier

According to a feature of the present invention for achieving the above object, the present invention is the upper plate fixed to the upper structure of the bridge, the lower plate fixed to the lower structure of the bridge, and the rubber plate inserted into the recess of the lower plate and A spherical shape that can be measured at any time, including a piston located on the upper portion of the rubber plate, a sliding plate in close contact with the piston and the spherical surface on the upper portion of the piston and a stainless plate attached to the upper plate on the upper portion of the sliding plate Provides a measuring instrument for measuring. Such a measuring instrument is provided with a load cell inserted and fixed to the lower plate in contact with a portion of the lower surface of the rubber plate to measure the partial load applied to the rubber plate and a connection passage for connecting the signal generated from the load cell to the outside. .

Such a measuring device may be configured to further include an X, Y-axis displacement measuring device and a Z-axis displacement measuring device, it may be configured to further include a temperature measuring device. X, Y axis displacement measuring device is installed in the outer center of the upper plate and the sliding plate to measure the X, Y axis displacement of the bridge top plate using the potential difference generated according to the relative displacement amount of the sliding plate. Z-axis displacement measuring device is installed on the upper edge of the lower plate to measure the Z-axis displacement with the upper plate. The temperature measuring device measures the change in the ambient temperature.

The measuring instrument according to the present invention is a small load cell (load cell) capable of measuring the load is attached to the inside of the bearing, by applying the principle of Pascal not only can measure the bridge load and variable load of high load, but also In order to measure the X and Y axis displacement between the plate and the sliding plate, an X, Y axis displacement measuring device is installed at the outer center of the upper plate and the sliding plate to measure the relative displacement between the upper plate and the lower plate, and the Z axis displacement. By measuring the displacement of the upper and lower sides by installing the Z-axis displacement measuring device at the upper edge of the lower plate to measure the pressure, all displacements (X, Y, Z-axis) generated in the chair can be measured. The temperature measurement was also enabled by installing This makes it possible to simultaneously measure all the operating behaviors of the bearings, so that the load and displacement history of the bridges, which were not possible with the conventional method, can be measured at the same time, so that the behavior of the bridges and the settlement of the bridges can be confirmed.

The configuration of the present invention will be described with reference to the drawings.

Figure 1 shows the measuring instrument of the present invention, having a top plate 20, a bottom plate 30, a rubber plate 44, a piston 42, a sliding plate 40 and a stainless plate 24 The load cell 50 is added to the spherical bridge device to allow measurement of the load applied to the bridge even in normal times. The upper plate 20 is fixed to the upper structure of the bridge, the lower plate 30 is fixed to the lower structure of the bridge. A rubber plate 44 is inserted into the recessed portion of the lower plate 30, the piston 42 is positioned above the rubber plate 44, and the sliding plate 40 is located above the piston 42. In close contact with the piston 42 and the spherical surface. The stainless plate 24 is attached to the upper plate 20 at the upper portion of the sliding plate 40. The packing 36 is installed to prevent foreign substances such as dust from flowing into the sliding plate 40.

As described above, the load cell 50 is installed in the measurement chair 10 according to the present invention. The load cell 50 is fixed to the lower plate 30 so as to be in contact with a portion of the lower surface of the rubber plate 44 to measure the partial load applied to the rubber plate 44. At this time, the lower plate 30 is formed with a connection passage 52 for connecting the signal generated from the load cell 50 to the outside.

As described above, the measuring device 10 according to the present invention has a relative displacement of the sliding plate 40 by installing an X, Y axis displacement measuring device 56 at the outer center of the upper plate 20 and the sliding plate 40. By using the potential difference generated according to the X, Y axis displacement of the bridge deck can be measured. In addition, the Z-axis displacement measuring device 58 is installed on the upper edge portion of the lower plate 30 so that the Z-axis displacement can also be measured by using a potential difference according to the displacement amount of the upper plate with respect to the load change acting on the bridge upper plate. . In addition, by installing a temperature measuring device 54 capable of measuring the temperature of the chair device to the lower plate 30 in contact with the lower surface of the rubber plate 44 it is also possible to measure the temperature of the chair device. The temperature measuring device 54 can measure the temperature of the rubber plate 44, which is sensitive to temperature, to correct the load and displacement measurement amount according to the temperature change, thereby improving accuracy.

When the load is applied to the bridge plate and the equal distribution load is applied to the circular rubber plate 44, the partial load is applied to the circular load cell 50 installed in a predetermined width at the center lower portion of the rubber plate 44. 50) to measure the load acting on the spherical bridge device by measuring the partial load acting on it. Herein, when the diameter of the rubber plate 44 is D and the diameter of the load cell 50 is d, the compressive stress σ acting on the rubber plate 44 when the load P acts on the stabilizing device is

σ = P / A = 4P / πD ²

(Where A is the cross section of the rubber plate and a is the cross section of the load cell)

The load p acting on the load cell is

p = σ × a = P / A × a

In the above formula, if p is measured using a load cell,

P = A / a × p

^{P = [(πD 2/4} ) / (πd 2/4)] × p

P = (D / d) ² × p

Knowing the diameter (D) of the rubber plate 44 and the diameter (d) of the load cell in the above equation it can be seen that the load P acting on the chair device.

Figure 2 shows that the allowable load of the present inventors increased the test weight to the measuring instrument of 130 tons starting from 10 tons and continued to increase by 10 tons. The x-axis represents the actual applied load and the lower weight measured in the load cell according to the y-axis. It is shown. Here it can be seen that the graph is almost linear with the theoretical value.

Figure 3 is the allowable load of the present inventors in the 600 tons measuring instrument, the experimental weight was increased by 10 tons, starting from 10 tons, the x-axis represents the actual applied load and the load weight measured in the load cell according to the y-axis It is shown. Here too, the graph appears to be almost linear with the theoretical value.

Therefore, it can be seen from the above two experiment results that the large load acting on the actual measuring instrument can be measured by the load cell.

Figure 4 is installed for each measuring bridge (A) for each pier and connected by wire or wireless to the load (pressure), horizontal (X, Y) and vertical ( Z) After collecting and storing the electrical signals of the displacement and temperature change data in the data storage device 12, the transmission and reception device consisting of a transmitter 13 ', a transmission path (wired or wireless) and a receiver 13' ( 13) the data of the measuring bridge device of the entire bridge is transmitted to the data comparison analysis device 14, the data received from the data comparison analysis device 14 is stored and compared and analyzed, the comparison result Is displayed on the monitor 15 and the alarm device 16 generates an alarm sound for the numerical value of the comparative analysis result that is outside the normal value. Here, the data storage device 12 and the transmission device 13 ′ are installed in the bridge, and the power source for driving them is to use a solar cell and a storage battery so that no separate power source is required.

In this way, the amount of load or displacement applied to the bridge top plate B is measured on each measuring bridge device A installed on the top of the bridge C supporting the top plate B of the bridge and receiving the load and deformation of the top plate. It is possible to make a measurement at all times by installing a device that can measure the data such as load (pressure), displacement (X, Y, Z), temperature, etc. measured by each measuring instrument (A). ) Collects and stores the data in one place and transmits the data to the data comparison and analysis device 14 such as a bridge management control station that manages the bridge by wire or wirelessly through the transmission device 13 ', and transmits the reception device 13'. Data is analyzed by the data comparison and analysis device 14 for various data on the bridge device received through the bridge. At this time, the data comparison analysis device 14 stores and manages the data of the initial state (when the bridge is completed), and compares the data received by the receiving device through the data analysis device to check the change of the structure and there is a problem In this case, maintenance measures are taken and the cause is eliminated, and the bridge can be efficiently maintained.

The present invention attaches a load cell capable of measuring loads inside a spherical bridge device, which enables the measurement of large loads and fluctuating loads acting on the bridges, as well as simultaneous measurement of the bearing's operating behavior. And by measuring the displacement history at the same time there is an advantage that can confirm the behavior of the bridge and settlement of the bridge. In addition, through the spherical bridge device capable of measuring the change of the bridge structure at any time, it is possible to check the change of the structure from time to time, and after the initial installation, it is easy to analyze the data without additional equipment or installation cost, and thus it is possible to predict the durability life of the structure. In addition, since maintenance of the measuring device only needs to replace the spherical bridge device, there is an advantage in that it is simple and inexpensive.

Claims (3)

An upper plate 20 fixed to the upper structure of the bridge, a lower plate 30 fixed to the lower structure of the bridge, a rubber plate 44 inserted into the recessed portion of the lower plate 30, and the rubber plate 44 Piston 42 located in the upper portion of the upper surface of the sliding plate 40 and the sliding plate 40 in close contact with the piston 42 in the upper portion of the piston 42, the upper plate 20 In the teaching apparatus comprising a stainless steel plate 24 attached to), A load cell 50 inserted into and fixed to the lower plate 30 so as to be in contact with a portion of the lower surface of the rubber plate 44 to measure a partial load applied to the rubber plate 4 4; Measuring instrument device, characterized in that it comprises a connection passage 52 for connecting the signal generated in the load cell to the outside. The method of claim 1, X, Y, which is installed at the outer center of the upper plate 20 and the sliding plate 40 to measure the X, Y axis displacement of the bridge upper plate by using the potential difference generated according to the relative displacement of the sliding plate 40 An axial displacement measuring device 56; And a Z-axis displacement measuring device (58) installed at an upper edge portion of the lower plate (30) to enable measurement of Z-axis displacement with the upper plate (20). The method of claim 2, The measuring instrument device further comprises a temperature measuring device (54) capable of measuring a change in the ambient temperature.