KR102428380B1 - Method for testing loading for loading structure using movable and variable loading apparatus - Google Patents

Abstract

The present invention is a load structure using an improved movable variable load-bearing device that can be assembled and installed on-site to evaluate the structural performance of a load-bearing structure and can easily load a load required for a load test to the load structure. of the load test method.

Description

Load test method of load structure using movable variable load-bearing device

The present invention relates to a load test method of a load structure using a movable variable load-bearing device, and more particularly, to evaluate the structural performance of a load-bearing structure supporting a load, which can be assembled and installed in the field, and the load required for the load test It relates to a load test method of a load structure using an improved movable variable load-bearing device to easily load a load structure to the load structure.

A preflex composite girder is a process in which a number of steel girders having an I-type or H-shaped cross section are connected, and concrete is formed around the lower flange while a load causing bending deformation is applied to the girder. Then, by releasing the load, it refers to a form in which prestress is applied to the concrete.

That is, the preflex composite girder compensates for the weakness of concrete, which is weak in tensile force, by using a steel girder.

And in the case of a newly manufactured prestressed concrete girder bridge, it is possible to apply it to construction through verification of actual performance by conducting actual tests according to new construction methods and new shapes and materials.

However, in the case of products directly produced in the field (eg, prestressed concrete girder), the performance cannot be verified.

Accordingly, there is a problem in that it is difficult to confirm reliable structural performance because the quality conditions of on-site production and laboratory production are inevitably different.

On the other hand, as a prior patent document related to the present invention to be described later, Patent Publication No. 10-0890455 (Mar. 18, 2009, registered) discloses a gravity-type load-bearing device using the weight of a temporary facility, and a method for manufacturing a preflex composite girder using the same and apparatus are disclosed.

Gravity-type load-bearing apparatus using the weight of the temporary facility of the above-mentioned prior patent, the method and apparatus for manufacturing a preflex composite girder using the same, by elevating the temporary facility combined with the girder, directly transmits the load on the girder using a jacking means Instead, by adopting a new method of transferring the weight of the temporary facility as a load, the weight of the concrete formed under the girder is reflected in the reflection load in advance, thereby substantially suppressing the loss of compressive stress, resulting in mechanically excellent and efficient This improved preflex composite girder can be easily fabricated.

Therefore, it is possible to greatly reduce the construction cost, and there is an advantage in that it is possible to prevent problems due to waste concrete treatment and soil contamination in advance.

However, the gravity-type load-bearing device using the temporary weight of the above-mentioned prior patent has a complicated configuration, and it is difficult to install in the field for structural performance evaluation of the structure, and it is difficult to easily load the load required for the test on the structure. .

The present invention was created to solve the above problems, and it is movable, can be assembled and manufactured, so it can be easily installed in the field, and the load required for the test is applied to the load structure by evaluating the structural performance of the load structure. The purpose is to provide a load test method of a load structure using a movable variable load-bearing device that can be loaded on the

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The load test method of a load structure using the movable variable load-bearing device of the present invention for achieving the above object,
In the load test method of a load structure that applies a vertical load to a load structure using a load-bearing device, (a) assemble the truss structure by moving several unassembled parts to the site where the bridge is to be constructed using a vehicle, installing a truss structure side by side in the longitudinal direction of the load structure using spacers (A) installed on both ends of the load structure so that the truss structure is loaded with a load on the load structure; (b) installing end supports at both ends of the truss structure and the load structure to support the truss structure and the load structure, and installing a plurality of auxiliary supports at regular intervals between the end supports; (c) applying a load to the load structure through a telescopic jack device installed in the center of the lower portion of the truss structure; (d) testing the deflection and deformation of the load structure step by step by applying a constant load until the crack moment of the load structure step by step through a hydraulic device that provides hydraulic force to the telescopic jack device, and the load structure and and verifying the actual load-bearing capacity and stability of the load structure by measuring the relative displacement with the load-bearing device, wherein the end support and the auxiliary support are assembled and installed, and the truss structure comprises:
A central frame is assembled vertically upwardly to the center of the main frame installed in parallel with the load structure in the longitudinal direction, and one end is assembled and installed symmetrically to the upper left and right sides of the central frame, and the other end is the main frame. A plurality of reinforcing frames installed at both ends to be slanted in the form of a truss and assembled so as to be assembled can be assembledly connected to the main frame, the central frame and the inclined frame to structurally reinforce the truss structure. assembled to make it work.

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According to an embodiment of the present invention, by using a prefabricated structure in the form of a triangular truss, sufficient structural strength and stability are secured compared to the conventional load test method, thereby reducing the risk of safety accidents during the load test, and improving the utility and reliability of the load test can be raised

In addition, it is movable, it is made in a prefabricated type, and it is possible to test the structural performance according to the load test of a load structure directly produced in the field in a variable type, so that it can be universally verified for various load structures.

1a is a front view of a movable variable load-bearing device according to the present invention;
FIG. 1B is a detailed view showing part “B” in FIG. 1A in more detail;
FIG. 1C is a detailed view showing part “C” in FIG. 1A in more detail;
1D is a detailed view showing the part "D" in FIG. 1A in more detail;
Fig. 2 is a plan view of Fig. 1A;
Fig. 3A is a side view viewed from "A" in Fig. 1A;
FIG. 3B is a detailed view showing the part “E” in FIG. 3A in more detail;
FIG. 3C is a detailed view showing the part “F” in FIG. 3A in more detail;
Fig. 3D is a side view of Fig. 3A;
4 is a perspective view showing a state in which a load test is performed in the field using the movable variable load load device according to the present invention.

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

Figure 1a is a front view of the movable variable load-bearing device according to the present invention is shown.

In addition, FIG. 1b is a detailed view showing part "B" in FIG. 1a in more detail, FIG. 1c is a detailed view showing part "C" in FIG. 1a in more detail, and FIG. 1d is FIG. 1a A detailed view showing the “D” part in more detail is shown.

Also, a plan view of FIG. 1A is shown in FIG. 2 .

And FIG. 3A is a side view viewed from "A" in FIG. 1A .

In addition, FIG. 3B is a detailed view showing part "E" in FIG. 3A in more detail, and FIG. 3C is a detailed view showing part "F" in FIG. 3A in more detail.

And Fig. 3d shows a side view of Fig. 3a.

In addition, FIG. 4 is a perspective view showing a state in which a load test is performed in the field using the movable variable load load device according to the present invention.

1A to 4, the movable variable load-bearing apparatus according to the present invention applies a vertical load to the load structure 100 for the load-bearing test of the load structure 100 such as a beam or a girder of a bridge. , The truss structure 200 installed on the upper part of the load structure 100 in the longitudinal direction of the load structure 100 , and installed so as to be assembled so that a load is loaded by the weight of the load structure 100 , and the truss structure (200) Expansion jack devices 500 and 700 that are installed at both ends and the center of the lower part and apply a vertical load to the load structure 100 disposed on the ground 101 by applying a load of a predetermined size to the load structure 100, and the load structure 100 ) and an end support 300 installed so as to be assembled at the front and rear ends of the truss structure 200 to support the load structure 100 and the truss structure 200 to promote the conduction stability and structural stability of the load-bearing device. ) and the end support 300, a plurality of pieces are installed so that they can be assembled at regular intervals to support the load structure 100 and the truss structure 200 together with the end support 300, so that the conduction stability and structure of the load-bearing device It is configured to include an auxiliary support 400 that promotes stability.

And the truss structure 200 is installed in parallel with the load structure 100 in the longitudinal direction, is installed so that it can be assembled by bolting, and the main frame 210 in which the telescopic jack devices 500 and 700 are installed at the lower part; The central frame 220 is installed vertically above the center of the main frame 210 and installed so as to be assembled by bolting, and one end is symmetrically installed on the upper left and right sides of the central frame 220 and the other end is the main frame 210 . ) installed at both ends of a truss-shaped inclined frame 230 and installed so that it can be assembled, and the main frame 210, the central frame 220 and the inclined frame 230 are connected and installed, and assembled by bolting It is configured to include a plurality of reinforcing frames 240 that are installed to structurally reinforce the truss structure 200 .

In addition, in the case of the reinforcing frame 240 in the truss structure 200, the reinforcing structure may be changed according to the degree or size of the load.

In the truss structure 200 as described above, the main frame 210 is formed by assembling at least two or more H-shaped steel materials by bolting.

In the embodiment of the present invention, as shown in FIGS. 1A and 2 , the main frame 210 is formed by assembling three H-shaped steel materials by bolting.

And the telescopic jack devices 500 and 700 are made of a jack device capable of loading a load of up to 300 tons (ton).

In addition, as shown in FIGS. 1a, 1c and 1d, one side of the telescopic jack device 700 installed at both ends of the main frame 210 of the truss structure 200 among the telescopic jack devices 500 and 700 At least one screw bar 600 is installed vertically to support the truss structure 200 and the load structure 100 .

A nut member 601 is installed at the upper end and lower end of the screw bar 600 , and a guide member 602 is installed at the lower end so that it can be rotated stably.

And the telescopic jack devices 500 and 700, the ram (ram) is provided at the front end to load the load by a hydraulic (pump) device, and the hydraulic jack device 500 installed in the lower center of the truss structure 200, and stops in the center A nut is provided and a load is loaded by elevating and lowering of the screw by a hydraulic device, and the truss structure 200 is configured to include a screw jack device 700 installed on one lower side of both ends, respectively.

Therefore, when a load is applied to the load structure 100 by the screw jack apparatus 700 of the telescopic jack apparatus 500 and 700, the screw bars 600 installed on one side of both ends of the load structure 100 rotate while the truss structure 200 is rotated. And the load structure 100 is stably supported, so that the movable variable load-bearing device according to the present invention does not fall during the test.

And the end support 300, as shown in Figs. 3a to 3d, is installed so as to be assembled, its length is variable and installed, and the vertical support members 302 and 303 installed opposite to each other at a predetermined distance, and The vertical support members 302 and 303 are integrally connected and installed at the upper end of the vertical support members 302 and 303, and the horizontal support member 305 installed while closely supporting the truss structure 200 to the upper end, and the vertical support member ( 302,303) is configured to include a height-variable member installed on one side of the vertical support member (302,303) so that the height is variable.

In addition, the height variable member, as shown in FIGS. 3A and 3D, the vertical support members 302 and 303 are divided into a lower vertical member 303 and an upper vertical member 302 made of a square pipe, and the It is fixed with two coupling pins 311 using a connection bracket 312 connecting the lower vertical member 303 and the upper vertical member 302, and the connection bracket 312 has a plurality of coupling holes 313. ) is formed, and when the coupling pin 311 is coupled while changing the position of the coupling hole 313, the height of the vertical support members 302 and 303 can be easily varied.

Accordingly, it is possible to actively respond to changes in the type and size of the load structure 100 .

And at the lower end of the vertical support members 302 and 303, a fall prevention member 301 for preventing the vertical support members 302 and 303 from falling is installed to protrude to the outside of the vertical support members 302 and 303.

In addition, the horizontal support member 305 and the fall prevention member 301 is made of an H-beam.

And in the case of the auxiliary support 400, as shown in FIGS. 1A and 2 , it is made in the form of a vertical support member and a horizontal support member like the end support 300 , and can be disassembled and assembled with a bolting structure 410 . is well equipped.

The operation of the movable variable load-bearing device according to the present invention having the configuration as described above and the load test method of the load structure using the same will be described as follows.

1A to 4 again, the movable variable load-bearing device and the load test method using the same according to the present invention are a load test method for loading a vertical load on the load structure 100. First, not assembled By using a vehicle to move several parts that are not in use to the site where the bridge is to be constructed, the truss structure 200 is assembled and installed on the load structure 100 , but the truss structure 200 is loaded with the load structure 100 . Install them side by side in the longitudinal direction. (Step 10)

Next, in order to support the load structure 100 of the truss structure 200, end supports 300 are installed at both ends of the truss structure 200 and the load structure 100, and a certain amount between the end supports 300 Install a plurality of auxiliary supports 400 at intervals. (Step 20)

Then, a load is applied to the load structure 100 through the telescopic jack devices 500 and 700 installed at both ends and at the center of the lower portion of the truss structure 200. (Step 30)

In addition, the deflection and deformation of the load structure 100 are tested step by step by applying a certain load until the crack moment of the load structure 100 step by step through a hydraulic device that provides hydraulic force to the telescopic jack devices 500 and 700 and measure the relative displacement between the load structure 100 and the load-bearing device to verify the actual load-bearing capacity and stability of the load structure 100 (step 40).

And in step 10, the truss structure 200, the load structure 100 and the central frame 220 vertically upward in the center of the main frame 210 installed in parallel in the longitudinal direction is assembled, one end The central frame 220 is symmetrically installed on the upper left and right sides, and the other end is installed at both ends of the main frame 210 so that the inclined frame 230 is assembled so as to be inclined in the form of a truss, and the main frame ( 210 ), a plurality of reinforcing frames 240 , which are installed to be assembledly connected to the central frame 220 and the inclined frame 230 to structurally reinforce the truss structure 200 are assembled.

In addition, in step 20, the end support 300 and the auxiliary support 400 are assembled and installed.

And in the steps 30 and 40, the telescopic jack devices 500 and 700 can load a maximum load of 300 tons (ton).

As described above, in the movable variable load-bearing device according to the present invention, since each member (or part) is configured to be disassembled and assembled, each part can be assembled by moving it to the field using a vehicle.

Accordingly, it can be easily assembled and installed at a construction site where a load structure 100 such as a beam or a girder of a bridge is installed.

In addition, the condition of the ground 101 acts in a manner of loading a load using the force of the truss structure 200 itself, rather than a method receiving a force from the fixed ground 101 in consideration of various field conditions.

And the load-bearing device according to the present invention is manufactured so that the load structure 100 can be tested in a variable type, and the ground 101 is a safety device that can prevent a fall risk regardless of whether the ground 101 is concrete or soft like soil. It is possible to carry out a load-bearing test in a state where it is easy and stability is secured.

Therefore, by evaluating the structural performance of the load structure 100, such as the beam or girder, it is possible to load the load required for the test to the structure.

In addition, since it is impossible to verify the performance of an aged bridge due to on-site conditions, it is possible to easily verify the structural performance of the aged bridge and the effect of repair and reinforcement by using the movable variable load-bearing device according to the present invention.

As described above, the present invention has been described with reference to one embodiment shown in the drawings, but this is merely exemplary, and various modifications and equivalent embodiments are possible therefrom by those skilled in the art. will understand Accordingly, the true protection scope of the present invention should be defined only by the appended claims.

100. Load structure
200. Truss structures
210. Mainframe
220. Center frame
230. Inclined frame
240. Reinforcement frame
300. End support
301. Fall prevention member
305. Horizontal support member
311. Binding Pin
312. Connection bracket
400. Auxiliary support
500,700. telescopic jack device
600. screw bar
302,303. vertical support member

Claims (13)

delete delete delete delete delete delete delete delete In the load test method of a load structure to apply a vertical load to the load structure 100 using a load-bearing device,
(a) Assembling the truss structure 200 by moving several unassembled parts to the site where the bridge is constructed using a vehicle, but using the spacer (A) installed on both ends of the load structure 100 Installing the truss structure 200 in parallel in the longitudinal direction of the load structure 100 so that the truss structure 200 is loaded with a load on the load structure;
(b) to support the truss structure 200 and the load structure 100, end supports 300 are installed at both ends of the truss structure and the load structure, and a plurality of Installing an auxiliary support 400;
(c) applying a load to the load structure 100 through the telescopic jack device 500 installed in the center of the lower portion of the truss structure;
(d) test the deflection and deformation of the load structure step by step by applying a constant load until the crack moment of the load structure step by step through a hydraulic device that provides hydraulic force to the telescopic jack device 500, measuring the relative displacement between the load structure and the load-bearing device to verify the actual load-bearing capacity and stability of the load structure 100,
The end support 300 and the auxiliary support 400 are assembled and installed,
The truss structure 200 is
A central frame 220 is assembled vertically upwardly at the center of the main frame 210 installed in parallel with the load structure 100 in the longitudinal direction,
One end is assembled and installed symmetrically on the upper left and right sides of the central frame 220, and the other end is installed at both ends of the main frame 210 so that the inclined frame 230 is assembled so as to be inclined in the form of a truss. ,
The main frame 210, the central frame 220, and a plurality of reinforcing frames 240 that are assembledly connected to and installed to structurally reinforce the truss structure 200 are assembled. A load test method of a load structure using a movable variable load-bearing device. delete delete delete 10. The method of claim 9,
The end support 300 is,
They face each other at a certain distance and the vertical support member is assembled and installed,
Both ends are assembled and installed on the upper end of the vertical support member, the truss structure is in close contact with the upper end, and the horizontal support member is assembled and installed,
At this time, the load test method of a load structure using a movable variable load-bearing device, characterized in that the height of the vertical support member is varied by the height-variable member installed on one side of the vertical support member.

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