KR101170463B1 - The structure for load-carrying capacity improvementmethod of construction having load measuring - Google Patents

Abstract

PURPOSE: A structure for improving bearing capacity of a construction structure with a load measuring function is provided to confirm the state of a construction structure in real-time by checking the load of the construction structure in consideration of the upward and downward force of an elastic beam. CONSTITUTION: A structure for improving bearing capacity of a construction structure with a load measuring function comprises elastic beams(100), first load measuring devices(200), second load measuring devices(300), and brackets(400). The elastic beams are fixed to a construction structure to apply upward force to the construction structure. Each first load measuring device is installed on the top center of each elastic beam and measures the load of the construction structure in consideration of the upward force of the elastic beam. The second load measuring devices are installed on the bottom surfaces of both sides of each elastic beam and measure the load of the construction structure in consideration of the downward force of the elastic beam. The brackets support the second load measuring devices.

Description

The Structure for Load-Carrying Capacity Improvement method of Construction Having Load Measuring}

The present invention relates to a structural load-bearing reinforcement structure having a load measuring function, and more particularly, has a load measuring function to enhance the load-bearing capacity of the structure and to check the load of the structure for stable and effective maintenance. An elastic beam reinforcing structure.

In general, concrete structures may crack due to various causes. If the microcracks caused by the dry shrinkage and environmental factors of the concrete progress due to the repeated action of the external load or excessive bending stress, the load capacity of the structure is reduced, which adversely affects the function of the structure.

In addition, the concrete structure has a large bending stress caused by the fixed load due to the characteristics of the material, so when the load capacity of the structure is lowered, the resistance to live load is reduced. Therefore, if the reinforcement shares a part of the bending moment due to the design load of the existing structure after reinforcement, the load carrying capacity of the original structure can be improved.

Accordingly, the present applicant reinforces beams and slabs so that tension bars and reinforcement plates can be shared so that the deflection stress of design loads due to the aging of bridges and buildings and the bending stress due to dead loads and live loads can be shared through Korean Patent Registration No. 10-0462311. By suggesting 'strength load-bearing reinforcement structure using steel beams and brackets' to maximize the resistance against live loads by reinforcement of dead loads.

However, in the reinforcing structure described above, as shown in FIG. 1, the shape of the steel beam 10 is H-beam, and the abdominal plate is not relatively firm, and in the case of the long beam, the torsion occurs in the steel beam 10. There is a difficulty, in order to obtain the required reinforcing effect, there was a problem that the cross section of the steel beam 10 should be large.

In addition, whether the load capacity of the structure is increased through the reinforcement of the structure or whether the reinforcement structure increases the weight of the structure alone, reinforcement is performed without accurate data analysis. Therefore, appropriate measures are required.

Korea Patent Registration No. 10-0462311 (Notice date 2004.12.17) Korean Utility Model Registration No. 20-0202345 (Notice date 2000.11.15) Korea Patent Registration No. 10-0462312 (Notice date 2004.12.17) Korean Patent Registration No. 10-0794674 (Announcement date 2008.01.14)

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems,

The purpose of the present invention is to maximize the load capacity of the structure by installing the elastic beam consisting of a cross-section 't' shape so that the upward force is generated, by installing a load measuring device at the load concentration point of the structure upward and downward force of the elastic beam It is to provide a structural load-bearing reinforcement structure having a load measurement function that can determine the state of the structure in real time by checking the load of the structure in consideration of this.

Structure load-bearing enhancement reinforcing structure having a load measuring function of the present invention according to one aspect provided to achieve the above object is a structure load-bearing enhancement reinforcing structure comprising a beam installed in the beam, the reinforcing structure is a cross-section The elastic beam is formed in a 't' shape, bent to have a camber set according to the area to be reinforced, and an elastic beam fixed at the center part to be in close contact with the bottom part of the structure and both ends are pressed upward to impart upward force to the structure. ; And a first load measuring device installed at a central portion of the upper surface of the elastic beam to display the load of the structure in numerical value in consideration of the upward force of the elastic beam.

Here, the first load measuring device includes a load gauge for measuring the load of the structure in consideration of the upward force of the elastic beam, a power supply for supplying power to the load gauge, and a display unit for numerically displaying the load measured on the load gauge. It is characterized by.

In addition, the first load measuring device is further provided with an impact canceling device for canceling the impact applied to the structure.

In addition, a seating portion for seating a load meter is provided at the central portion of the upper surface of the elastic beam, a support member for supporting the seating portion is installed at a bottom of the seating portion, and a first space portion at which one side of the support member is provided with a power supply unit is provided. The other side of the support member is characterized in that the second space is provided with a display unit is provided.

In addition, the bottom of both sides of the elastic beam is further provided with a second load measuring instrument for numerically indicating the load of the structure in consideration of the downward force of the elastic beam, and a bracket for supporting the second load measuring instrument and fixed to the side of the beam It features.

The second load measuring device includes a load gauge for measuring the load of the structure in consideration of the downward force of the elastic beam, an impact canceling device provided at a lower portion of the load gauge to cancel the impact applied to the structure, and a load gauge provided at the upper portion of the load gauge. The upper pressure plate to protect the, the lower pressure plate provided on the lower portion of the impact canceller to protect the load gauge and the impact canceller, the power supply for supplying power to the load gauge, and displays the load measured by the load gauge in numerical values Characterized in that the display portion.

Structure load-bearing reinforcement structure having a load measuring function of the present invention according to another aspect in the structure load-bearing reinforcement structure including a beam installed in the beam, the reinforcement structure is made of a cross-section 't' shape, the structure An elastic beam which is bent to have a camber set according to an area to be reinforcement of the elastic beam, the center portion of which is in close contact with the bottom of the structure and both ends thereof are pressed upwards to impart an upward force to the structure; A display installed in the center of the upper surface of the elastic beam, a load meter for measuring the load of the structure in consideration of the upward force of the elastic beam, a power supply for supplying power to the load meter, and a display for displaying the upward force checked in the load meter numerically A first load measuring device comprising a portion; It is provided on both bottom surfaces of the elastic beam, the load gauge for measuring the load of the structure in consideration of the downward force of the elastic beam, an impact canceling device provided in the lower portion of the load gauge to offset the impact of the structure, and provided in the upper portion of the load gauge The upper pressure plate to protect the load gauge, the lower pressure plate provided at the lower portion of the impact canceller to protect the load gauge and the impact canceller, a power supply for supplying power to the load gauge, and the load measured by the load gauge as a numerical value. A second load measuring device configured to display; And a bracket provided on the bottom of the second load gauge to support the second load gauge and to be fixed to the beam.

According to the structural load-bearing reinforcement structure having a load measuring function of the present invention, by installing an elastic beam having a cross-sectional shape 'p' shaped so that upward force is generated, the reinforcing effect is improved by maximizing the load capacity of the structure, and also the elastic beam A first load measuring device is installed at the center of the upper surface of the elastic beam in consideration of the upward force of the elastic beam, and a second load measuring device considering the downward force of the elastic beam is installed at the bottom of both ends of the elastic beam. By measuring the data in real time, not only can the safety evaluation of the structure be accurate, but the structure can be easily and efficiently managed.

1 is a view showing the shape of the beam used in the conventional structure load-bearing enhancement structure.
Figure 2 is a view showing a structure load-bearing reinforcement structure having a load measuring function according to the present invention.
Figure 3 is a view showing the elastic beam in the structure load-bearing enhanced reinforcement structure having a load measuring function according to the present invention.
Figure 4 is a view showing the manufacturing process of the elastic beam in the structure load-bearing reinforcement structure having a load measurement function according to the present invention.
5 is a view for explaining the upward force of the elastic beam in the structure load-bearing enhanced reinforcement structure having a load measuring function according to the present invention.
6 is a view for explaining the coupling relationship between the elastic beam and the first load measuring device in the structure load-bearing reinforcement structure having a load measuring function according to the present invention.
Figure 7 is a view for explaining the coupling relationship between the elastic beam and the second load measuring device in the structure load-bearing reinforcement structure having a load measuring function according to the present invention.
8 is a view for explaining the coupling process of the elastic beam in the structure load-bearing reinforcement structure having a load measuring function according to the present invention.

These and other objects, features and other advantages of the present invention will become more apparent by describing in detail preferred embodiments of the present invention with reference to the accompanying drawings. Hereinafter, with reference to the accompanying drawings will be described in detail the structure load-bearing enhancement reinforcing structure having a load measuring function of the present invention. For the purposes of this specification, like reference numerals in the drawings denote like parts unless otherwise indicated.

Figure 2 is a view showing a perspective view of the structure load-bearing reinforcement structure having a load measuring function according to the present invention, Figure 3 is a view showing an elastic beam in the structure load-bearing enhanced reinforcing structure having a load measuring function according to the present invention; 4 is a view illustrating a manufacturing process of an elastic beam in a structure load-bearing reinforcement structure having a load measurement function according to the present invention, Figure 5 is a elastic beam in a structure load-bearing enhancement structure with a load measurement function according to the present invention Figure 6 is a view for explaining the upward force of, Figure 6 is a view for explaining the coupling relationship between the elastic beam and the first load measuring device in the load-bearing structure reinforcement structure having a load measurement function according to the present invention, Figure 7 A diagram for explaining the coupling relationship between the elastic beam and the second load gauge in a load-bearing reinforcement structure having a load measurement function according to .

As shown in Figures 2 to 7 the structure load-bearing reinforcement structure having a load measuring function of the present invention is a structure load-bearing reinforcement structure including a beam installed on the beam, the cross-section is made of '?' The beam 100, the first load measuring device 200 provided in the center of the upper surface of the elastic beam 100, the second load measuring device 300 provided on both bottom surfaces of the elastic beam 100, and the second load measuring device It includes a bracket 400 for supporting (300).

The elastic beam 100 is made of a cross-section of the '’' shape to increase the reinforcement of the abdominal plate. The elastic beam 100 having a cross-section 't' shape has a stronger abdominal plate and no torsion than the beam having a cross-section 'H' shape, and also has a small volume, excellent aesthetics, workability and reinforcement. great.

To prove this, comparing the cross-sectional force of each cross-sectional shape of the elastic beam is as follows.

Load condition: 10kg / cm

Cross Section Second Moment Comparison

즉, 탄성빔(100)이‘ㅍ’자 형상의 단면으로 이루어짐으로써 보강재의 안정성을 높일 수 있으며, 보강효과를 극대화시킬 수 있음을 알 수 있다.

That is, it can be seen that the elastic beam 100 is made of a cross-section of the 'ㅍ' shape can increase the stability of the reinforcement, and can maximize the reinforcement effect.

Criteria of cross-sectional dimensions for local oysters of the abdomen

Therefore, it is possible to increase the safety against the buckling of the reinforcement by changing the shape of the elastic beam 100.

Then, the elastic beam 100 is manufactured by giving a curvature in advance to determine the degree of damage of the structure and then determine the amount of reinforcement of the structure, that is, the amount of reduction of the static moment due to the design load.

As shown in FIG. 4, the fabrication of the elastic beam 100 determines the load capacity of the target structure (S10), and if the load capacity is insufficient, calculates the reinforcement moment (S20), and assumes the reinforcement length (S30). Calculate (S40).

Next, when the upward force is calculated, the camber amount of the elastic beam 100 is designed (S50), and the cross section of the curved beam of the elastic beam 100 is examined (S60). At this time, if the cross section of the curved beam of the elastic beam 100 is incorrectly designed, the camber amount of the elastic beam 100 is redesigned (S50).

Subsequently, the load capacity of the structure is examined with the camber amount of the designed elastic beam 100 (S70), and as a result of the review, if the load capacity is weak, the recomputation is recalculated (S40), and if the load capacity is excellent, the fixing unit is designed (S80) to elasticity. Production of the beam 100 is made (S90). At this time, the elastic beam 100 is provided with a stiffener 101 of a predetermined interval in the longitudinal direction to catch the twisting phenomenon.

The elastic beam 100 manufactured as described above is a high tensile steel of SWS-520 or more, the maximum limit of tensile strength is about 50% larger than that of ordinary steel, and has a high breaking point and elongation in the stress strain diagram. Thus, if the force applied after bending under a constant force within the elastic region is removed, it has a property of restoring to its original state. In other words, after fabricating with constant bending, close to the lower part of the place where there is severe sagging or cracking of the aging structure, and there is a risk of collapse. The restoring force to be shaped creates an upward force that keeps pushing the bottom of the structure.

Here, the upward force of the elastic beam 100 is the initial deflection and the slope according to the length of the beam beam given by the camber by Equation 1.1 and Equation 1.2 so as to act as an even distribution load when the structure is fixed to the structure as shown in FIG. It is calculated by calculating.

의 집중하향력이 작용하여 구조물의 전단력을 감소시킨다. 또한, 구조물의 사하중 및 활하중에 의한 휨응력을 감소시켜 사하중에 대한 보강으로 활하중의 저항능력을 극대화시킨다. When the reinforcement of the structure using the elastic beam 100, the upwardly distributed load acts over the entire length of the elastic beam 100 to reduce the moment of the structure, and also at both ends of the elastic beam 100

The concentrated downward force acts to reduce the shear force of the structure. In addition, by reducing the bending stress caused by the dead load and live load of the structure to maximize the resistance of the live load by reinforcement to the dead load.

2 and 6, the first load measuring device 200 is installed at the center of the upper surface of the elastic beam 100.

The first load measuring device 200 is installed at the center of the elastic beam 100, that is, the load concentration point that the structure is in contact with, the load gauge 210 for measuring the load of the structure in consideration of the upward force of the elastic beam 100, and the load meter ( It includes a power supply unit 220 for supplying power to the 210, and the display unit 230 to display the numerical value of the load measured on the load meter (210).

A seating part 110 on which the load meter 210 is mounted is provided at the center of the upper surface of the elastic beam 100 so that the first load measuring device 200 is installed, and the seating part 110 is supported on the bottom of the seating part 110. The support member 120 is installed, one side of the support member 120 is provided with a first space portion 130, the power supply unit 220 is provided, the other side of the support member 120, the display unit 230 The second space portion 140 is installed is provided.

Here, the load gauge 210 is contained in the load gauge case 211 and is seated on the seating portion 110 provided in the center of the upper surface of the elastic beam 100, the power supply 220 is the first space portion of the elastic beam 100 ( It is installed on the 130 is connected to the load meter 210 and the power line, the display unit 230 is installed in the second space portion 140 of the elastic beam 100 is connected to the load meter 210 by wire or wireless.

In addition, the screen of the display unit 230 may be exposed to the outside in consideration of aesthetics to the first space unit 130 in which the power supply unit 220 is installed and the second space unit 140 in which the display unit 230 is installed. The cover plate 150 covering the edges of the first space 130 and the second space 140 may be combined.

In addition, although not shown in the drawings, the lower part of the load gauge 210 may be further provided with an impact canceling device for canceling the impact applied to the structure.

On the other hand, as shown in Figures 2 and 7, the side of the bottom surface of both sides of the elastic beam 100 is provided with a cross section to provide an installation space 102, the second load measuring device 300 in the installation space 102 Is installed.

The second load measuring device 300 is installed on the bottom of both ends of the elastic beam 100, that is, the load concentration point of the structure, and the load gauge 310 for measuring the load of the structure in consideration of the downward force of the elastic beam 100, and the load meter ( An impact canceling device 320 provided at a lower portion of the 310 to cancel a shock applied to the structure, an upper pressure plate 330 provided at an upper portion of the load gauge 310 to protect the load gauge 310, and an impact canceling device ( The lower pressure plate 340 provided below the 320 to protect the load meter 310 and the impact canceling device 320, the power supply unit 350 for supplying power to the load meter 310, and the load meter 310 are measured. It is composed of a display unit 360 for displaying the loaded load numerically.

In addition, a lower portion of the second load measuring unit 300 is provided with a bracket 400 for supporting the second load measuring unit 300 and being fixed to the side of the beam 2.

Here, the load gauge 310 and the impact canceller 320 is provided between the upper pressure plate 330 and the lower pressure plate 340 is mounted between the upper surface of the bracket 400 and the bottom surface of the elastic beam 100, the load gauge ( The power supply unit 350 for supplying power to the 310 and the display unit 360 for numerically displaying the load measured by the load gauge 310 are provided on one side of the load gauge or the bracket 400 may be easily identified. It is also preferably provided on one side of the front surface or the upper surface of the bracket 400.

8 is a view for explaining the coupling process of the elastic beam in the structure load-bearing reinforcement structure having a load measurement function according to the present invention.

As shown in FIG. 8 (a), when the structure to be reinforced, for example, the bridge 1 is to be reinforced, the state of the bridge 1 is examined to determine the range to be reinforced.

Subsequently, according to the reinforcement range of the bridge 1 to be reinforced, as shown in FIG. 8 (b), the 'p' shaped elastic beam 100 is manufactured with a camber, and the elastic beam 100 is The first load measuring unit 200 is installed at the center of the upper surface, and the second load measuring unit 300 and the bracket 400 are installed at both bottom surfaces of the elastic beam 100.

Subsequently, as shown in FIG. 8 (c), the elastic beam 100 provided with the first and second load measuring devices is moved to the lower part of the bridge 1 so that the first load measuring device 200 at the center part is connected to the bridge 1. Close contact with the bottom of the.

As shown in FIG. 8 (d), the both ends of the elastic beam 100 spaced apart from the lower surface of the bridge are pushed up by a constant force to integrate the bridge 1 with the elastic beam 100 flat. And also to securely support the bracket 400 on both sides of the elastic beam 100 on the side of the beam (2). At this time, both ends of the elastic beam 100, which is spaced apart from the lower surface of the bridge 1, by pushing a constant force, the elastic beam 100 is bent due to the cross-sectional force is relatively smaller than the bridge generates an upward force in the center.

At this time, it is preferable to attach a rubber material to a portion where the bottom surface of the elastic beam 100 and the bridge 1 abut so as to transmit even load by reducing the gap.

Then, when the elastic beam 100 is completely fixed to the lower side of the bridge (1) and both sides of the beam (2), power is supplied to the power supply unit 220 of the first load measuring device 200 installed in the center of the elastic beam 100 do.

Subsequently, the load gauge 210 supplied with power from the power supply unit 220 measures the load of the bridge 1 in consideration of the upward force of the elastic beam 100, and the load measured by the load meter 210 is measured by the display unit 230. ) As a number. At this time, by confirming the load value indicated by the numerical value, it is possible to confirm how much the upward force of the elastic beam 100 is acting, and it is possible to accurately evaluate the stability of the bridge (1).

In addition, when power is applied to the power supply unit 350 of the second load measuring unit 300 installed at both ends of the elastic beam 100, the load meter 310 receives power from the power supply unit 350 is the elastic beam 100 The load of the bridge 1 in consideration of the downward force of is measured, and the load measured by the load meter 310 is displayed numerically on the display unit 360. At this time, by confirming the load value indicated by the numerical value, it is possible to confirm how much the downward force of the elastic beam 100 acted, and also to determine how much weight is applied to the shift and the piers. In addition, the impact canceller 320 installed between the load gauge 310 and the bracket 400 eliminates a risk of cracking and breaking due to the vibration of the bridge.

As described above, the present invention reduces the static moment due to the fixed load of the existing concrete bridge by installing the elastic beam 100 having a cross-section of a 't' shape so that upward force is generated, and improves resistance to live loads. do.

In addition, the first load measuring device 200 for numerically displaying the load of the structure in consideration of the upward force of the elastic beam 100 is installed in the center of the upper surface of the elastic beam 100, and elasticity on the bottom of both ends of the elastic beam 100 By installing the second load measuring device 300 which displays the load of the structure in consideration of the downward force of the beam 100 by measuring the load of the structure in real time, it is possible not only to accurately evaluate the safety of the structure but also to facilitate the structure. It can be managed efficiently.

While preferred embodiments of the present invention have been described above, the present invention is not limited to the above-described specific embodiments. That is, those skilled in the art to which the present invention pertains can make many changes and modifications to the present invention without departing from the spirit and scope of the appended claims, and all such appropriate changes and modifications Equivalents should be considered to be within the scope of the present invention.

100: elastic beam 101: stiffener
110: seating portion 120: support member
130: first space portion 140: second space portion
150: cover plate 200: first load measuring instrument
210: load meter 220: power supply
230: display unit 300: second load measuring instrument
310: load gauge 320: impact offset device
330: upper pressure plate 340: lower pressure plate
350: power supply unit 360: display unit
400: bracket
1: bridge
2: see

Claims (7)

In the structure load-bearing reinforcement structure including a beam installed in the beam,
The reinforcing structure has a cross section having a 'p' shape, and is bent to have a camber set according to a region to be reinforced of the structure. An elastic beam fixed to impart; And,
A display installed in the center of the upper surface of the elastic beam, the load meter for measuring the load of the structure in consideration of the upward force of the elastic beam, the power supply for supplying power to the load meter, and the display to display the load measured in the load meter numerically A first load measuring device comprising a portion;
Structure load-bearing enhanced reinforcement structure having a load measurement function, characterized in that it comprises a. delete The method of claim 1,
The first load measuring device further includes a shock canceling device for canceling an impact applied to the structure. The method of claim 1,
In the center of the upper surface of the elastic beam, a seating portion for mounting a load meter is provided, a support member for supporting the seating portion is installed on the bottom of the seating portion, and a first space portion in which a power supply unit is installed is provided on one side of the support member, and a support member. The other side of the structure with a load-bearing function, characterized in that the second space is provided with a display unit is installed load-bearing reinforcement structure. The method of claim 1,
The bottom of both sides of the elastic beam is further provided with a second load measuring instrument for numerically indicating the load of the structure in consideration of the downward force of the elastic beam, and a bracket for supporting the second load measuring instrument and fixed to the side of the beam Load-bearing reinforcement structure with load measuring function. The method of claim 5, wherein
The second load measuring device includes a load gauge for measuring the load of the structure in consideration of the downward force of the elastic beam, an impact canceling device provided at a lower portion of the load gauge to cancel the impact applied to the structure, and a load gauge provided at the upper portion of the load gauge. The upper pressure plate to protect the, the lower pressure plate provided on the lower portion of the impact canceller to protect the load gauge and the impact canceller, the power supply for supplying power to the load gauge, and displays the load measured by the load gauge in numerical values Structure load-bearing reinforcement structure having a load measurement function, characterized in that the display unit. In the structure load-bearing reinforcement structure including a beam installed in the beam,
The reinforcing structure has a cross section having a 'p' shape, and is bent to have a camber set according to a region to be reinforced of the structure. An elastic beam fixed to impart;
A display installed in the center of the upper surface of the elastic beam, a load meter for measuring the load of the structure in consideration of the upward force of the elastic beam, a power supply for supplying power to the load meter, and a display for displaying the upward force checked in the load meter numerically A first load measuring device comprising a portion;
It is provided on both bottom surfaces of the elastic beam, the load gauge for measuring the load of the structure in consideration of the downward force of the elastic beam, an impact canceling device provided in the lower portion of the load gauge to offset the impact of the structure, and provided in the upper portion of the load gauge The upper pressure plate to protect the load gauge, the lower pressure plate provided at the lower portion of the impact canceller to protect the load gauge and the impact canceller, a power supply for supplying power to the load gauge, and the load measured by the load gauge as a numerical value. A second load measuring device configured to display; And
A bracket provided on the bottom of the second load gauge to support the second load gauge and to be fixed to the beam;
Structure load-bearing enhanced reinforcement structure having a load measurement function, characterized in that it comprises a.

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