KR20040034881A - Apparatus and method for reinforcing sagging beam - Google Patents

Abstract

PURPOSE: A reinforcement device for a deflected beam is provided to execute a remodeling work easily by removing a column to support a beam, to heighten space utilization such as parking space, and to improve the durability or earthquake resistance of a building. CONSTITUTION: The reinforcement device for a deflected beam contains: a fixture(10) fixed to the upper ends of many columns(C) or both sides of a beam(G) between columns(C); a support(20) supporting the beam(G) between fixtures(10); a primary tension bar(30) fixed to the fixture(10) and provided with a primary bolt unit; a secondary tension bar(40) fixed to the support(20) and provided with a secondary bolt unit; and a turn buckle(50) fastening the primary bolt unit and the secondary bolt unit and tensioning the primary tension bar(30) and the secondary tension bar(40) according to the rotary direction.

Description

Sag beam reinforcement device and reinforcement method using the same {Apparatus and method for reinforcing sagging beam}

The present invention relates to a deflection beam reinforcement device and a reinforcement method for reinforcing a deflection of a beam.

It is an architectural structure supported by beams (not shown) that make up buildings such as various buildings, factories, and piers, and supports the lower surface of the roof or floor to support the vertical load of the roof or floor.

However, in order to increase the space utilization, it is often required that the spacing between the pillars be wide in the building. In this case, the vertical loads supported by the beams installed between the pillars of the wide spacing are very large and thus the deflection may occur. have. In addition, even when a heavy object is placed on the floor supported by the beam or many people work, deflection of the beam may occur due to these loads. This deflection of beams adversely affects the durability of the entire building and causes weakness in the seismic surface.

The present invention has been made to solve the above problems, not only to prevent the deflection of the beam, but also can further reinforce the already deflected beam, and the deflection beam reinforcement device that can enhance not only the durability of the building but also the shock resistance An object of the present invention is to provide a reinforcement method.

It is still another object of the present invention to provide a deflection reinforcement device capable of removing a pillar to enable remodeling and to increase utilization space, and a reinforcement method using the same.

1 is a view showing a first embodiment of a sag reinforcement device according to the present invention,

2 is an excerpt perspective view of a fixing part employed in FIG. 1;

3 is an excerpt perspective view of a support unit employed in FIG. 1;

Figure 4 is a view showing an extract of the crevis end coupled to one end of the first and second tensile rods of Figure 1,

5 is a view showing an extract of the turnbuckle and the first and second tensile rods of FIG.

Figure 6 is a view showing a second embodiment of the deflection beam reinforcement device according to the invention,

7 is a view showing a third embodiment of the deflection beam reinforcement device according to the present invention.

<Description of the symbols for the main parts of the drawings>

10, 110 ... fixing 11 ... coupling blade

11a ... through-hole 12 ... flange

12a ... through-hole 20, 120 ... support

21 ... Combination wing 21a ... Through hole

22 ... side walls 23 ... floor

30 ... First tensile rod 31 ... First bolt part

32 ... Crevis End 33 ... Crevis Wings

33a ... Through hole

40 ... second tensile rod

41 ... 2nd bolt part 42 ... Crevis end

43 ... Crevis Wings 43a ... Through-holes

50 ... turnbuckle 50a ... nut part

120 ... support 121 ... first support

122 ... 2nd support 123 ... Combination wing

In order to achieve the above object, the sag reinforcement device according to the present invention,

Reinforcing the deflection phenomenon of the beam (G) supported by a plurality of pillars (C), respectively fixed to both sides of the beam (G) between the top of the plurality of pillars (C) or the pillars (C) Fixing part 10; A support part 20 for supporting the beam G between the fixing parts 10; A first tension rod 30 having one side fixed to each of the fixing portions 10 and a first bolt portion 31 formed at the other side; A second tension rod 40 having one side fixed to the support portion 20 and a second bolt portion 41 formed at the other side; A turnbuckle 50 fastening the first bolt portion 31 and the second bolt portion 41 to tension the first tension rod 30 and the second tension rod 40 in a rotational direction; It is characterized by doing.

In the present invention, the fixing part 10 is a border formed with a coupling wing 11 is coupled to one side of the first tensile rod 30 surrounding the pillar (C).

In the present invention, the fixing portion 10 further includes a flange 12 which is formed on the upper end of the rim to be installed in the beam (G).

In this invention, the said support part 20 supports the edge part G 'which supported the said beam G.

In the present invention, the support 20, four sidewalls 22 formed with a coupling blade 21 is formed to surround the end edge of the pillar (G ') and the one side of the second tension rod 40 is coupled; It has a box shape consisting of a bottom 23 for supporting the end of the pillar (G ').

In the present invention, the support part 120 supports the bottom of the first support piece 121 and the first support piece 121 installed on the beam G, and one side of the second tensile rod 40. It consists of a second support piece 122 is formed with a coupling blade 123 is coupled.

In order to achieve the above object, the sag reinforcement method according to the present invention,

In order to prevent sagging of the beam G supported by the plurality of pillars C,

Fixing the fixing parts 10 and 110 to both sides of the beams G between the upper ends of the plurality of pillars C or the pillars C; Installing support portions (20) (120) on beams (G) between the respective fixing portions (10) (110); Coupling one side of the first tension rod (30) having the first bolt portion (31) to the other side to each of the fixing portions (10) (110); Coupling one side of the second tension bar (40) having the second bolt portion (41) to the support portion (20) (120); Coupling the first bolt part 31 and the second bolt part 41 to both sides of the turnbuckle 50; and rotating the turnbuckle 50 to the first and second tension rods 30 ( 40) to reinforce the deflection of the beam (G).

Hereinafter, the sag reinforcement device and a reinforcement method using the same according to the present invention with reference to the accompanying drawings will be described in detail with reference to the accompanying drawings.

1 is a view showing a first embodiment of a sag reinforcement device according to the present invention, Figure 2 is an excerpt perspective view of the fixing portion employed in Figure 1, Figure 3 is an excerpt perspective view of the support portion employed in Figure 1 4 is a view showing an extract of a crevis end coupled to one end of the first and second tensile rods of FIG. 1, and FIG. 5 is a view showing an extract of the turnbuckle and the first and second tensile rods of FIG.

As shown, the deflection beam reinforcement device is for reinforcing the deflection phenomenon of the beam (G) supported by a plurality of pillars (C). This reinforcement device, the fixing portion 10 is fixed to the top of the plurality of pillars (C), respectively, and the support portion for supporting the beam between the fixing portion 10, preferably between the center portion between the fixing portion ( 20) and a first tension rod 30 having one side fixed to each of the fixing portions 10 and a first bolt portion 31 formed on the other side, and one side fixed to the support portion 20 and a second bolt portion on the other side The first tension rods 30 and the second tension rods 40 are formed by fastening the second tension rods 40 and the first bolt portion 31 and the second bolt portions 41 having the 41 formed therein. It comprises a turnbuckle 50 to tension the).

As shown in FIG. 2, the fixing part 10 is an edge having four side walls to be fitted to the pillar C, and one side of the first tension rod 30 is coupled to at least one side wall. Wings 11 are formed. The coupling blade 11 is formed with a through hole 11a through which the bolt 34 penetrates. At this time, the flange 12 is preferably formed on the lower end of the beam (G) at the upper end of the fixing portion (10). A plurality of through holes 12a are formed in the flange 12. In the present embodiment, the fixing portion 10 is fitted to the column (C), the anchor bolt 12b penetrating through the flange 12 is coupled to the beam (G), thereby firmly on the top of the column (C) It is fixed. However, this is only an embodiment, and of course, the fixing part may be implemented in various structures in which the top of the column is fixed.

As shown in FIG. 3, the support portion 20 removes the pillar that supported the beam G, and then has four side walls 22 and the bottom 23 so as to be supported by the removed pillar end G '. It has a box shape consisting of). Each of the four side walls 22 is formed with a coupling blade 21 to which one side of the second tensile rod 40 is coupled. Each coupling blade 21 is formed with a through hole 21a through which the bolt 35 penetrates.

The first tension rod 30 has one side coupled to the fixed portion 10 and the other side on which the first bolt portion 31 is formed. At this time, one side of the first tensile rod 30 is preferably provided with a crevis end 32 is fastened to the coupling blade 11 of the fixing portion. As shown in FIG. 4, the crevis end 32 has a crevis wing 33 formed so that the coupling blade 11 can be fitted therein, and the through hole 33a is formed in the crevis wing 33. Therefore, the bolt 34 passes through the through holes 11a and 33a in the state in which the coupling blade 11 is fitted to the crevis blade 33 to thereby be fastened to the nut (not shown), thereby eventually forming the first tensile rod 30. ) Is firmly coupled to the fixing part (10).

The second tension rod 40 has one side coupled to the support 20 and the other side on which the second bolt portion 41 is formed. At this time, it is preferable that one side of the second tensile rod 40 is provided with a crevis end 42 that is engaged with the coupling blade 21 of the support. As shown in FIG. 4, the crevis end 42 has a crevis wing 43 into which the coupling blade 21 is fitted, and a through hole 43a is formed in the crevis wing 43. Therefore, the bolt 35 passes through the through-holes 21a and 43a in the state where the coupling blade 21 is fitted to the crevis blade 43 to thereby be fastened to the nut (not shown), thereby eventually pulling the second tensile rod 40. ) Is firmly coupled to the support 20.

As shown in FIG. 5, the turnbuckle 50 has a nut part 50a at which both the first and second bolt parts 31 and 41 of the first and second tensile rods 30 and 40 are respectively screwed together. Is formed. Since each of the nut parts 50a is formed in the opposite direction, the first and second tensile rods 30 and 40 are tensioned by rotating or reversely rotating the first and second turnbuckles 50. By employing the turnbuckle 50, the rotational torque can be accurately measured using a measuring tool (not shown) when the turnbuckle 50 is rotated, so that the tensile force of the first and second tensile rods 30 and 40 can be measured. Can be set correctly.

Next, a second embodiment of the deflection reinforcement device according to the present invention will be described.

Figure 6 is a view showing a second embodiment of the deflection beam reinforcement device according to the present invention. Here, the same reference numerals as in FIG. 1 are the same members having the same function.

The second embodiment of the deflection beam reinforcement device differs from the first embodiment in that the structure of the support part 120 for supporting the beam G between the pillars C is different from that of the support part 20 in the first embodiment. It is different. That is, as shown in the second embodiment, the support part 120 supports a metal first support piece 121 directly installed on the beam G and a bottom of the first support piece 121. It consists of the 2nd support piece 122. As shown in FIG. At this time, at the lower end of the second support piece 122, the coupling blade 123 is formed to be coupled to the crevis end 42 installed on the second tensile rod 40, the through blade is formed in the coupling blade 123 have. Therefore, in the state in which the coupling blade 123 is fitted to the crevis blade 43, the bolt 35 passes through the through hole 34a of the coupling blade 123 and the through hole 34 of the coupling blade 123, and a nut (not shown). By being fastened to, the second tensile rod 40 is to be firmly coupled to the support 120.

7 is a view showing a third embodiment of the deflection beam reinforcement device according to the present invention. Here, the same reference numerals as in FIGS. 1 and 6 are the same members having the same function.

The third embodiment of the deflection beam reinforcement device differs from the first embodiment in that the fixing part 110 is fixed to both sides of the beam G between the pillars C, respectively. The structure is different from the government (10). That is, the fixing part 110 in the third embodiment is a crevis end coupled to both sides of the beam G between both pillars C by bolts (not shown) and nuts (not shown). The end has a single crevis wing. Through holes are also formed in a single crevis blade, and thus the single crevis blade 33 of the first tensile rod 30 and the single crevis blade of the fixing part 110 are fastened by a bolt 34 and a nut (not shown), As a result, the first tensile rod 30 is firmly coupled to the fixing part 110.

Next, the reinforcement method using the first, second, third embodiments of the sag reinforcement device according to the present invention.

First, fixing the fixing parts 10 and 110 to both sides of the beams G between the tops of the plurality of pillars C or the pillars C are performed.

Next, performing the step of installing the support 20, 120 in the beam (G) between each of the fixing portion (10) (110).

Next, the other side of the fixing portion 10, 110 performs a step of coupling one side of the first tension rod 30 having the first bolt portion 31.

Next, the other side of the support portion 20, 120 performs a step of coupling one side of the second tension rod 40 having the second bolt portion (41).

Next, the first bolt part 31 and the second bolt part 41 are coupled to both sides of the turnbuckle 50.

Next, the deflection of the beam G is reinforced by rotating the turnbuckles 50 to tension the first and second tensile rods 30 and 40. As the turnbuckle 50 is rotated, a tensile force is applied to the first and second tensile rods 30 and 40, and the tensile force acts in the direction in which the support portions 20 and 120 are raised to reinforce the sagging beam.

By employing the above-described turnbuckle 50, the rotational torque can be accurately measured by using a measuring tool when the turnbuckle 50 is rotated, so that the tensile force of the first and second tensile rods 30 and 40 can be set accurately. Can be. Furthermore, even when a larger load is applied to the beam G, even if additional tensile force of a certain value is required for the first and second tensile rods 30 and 40, the measuring tool and the turnbuckle 50 can be easily added. Tension can be performed.

The preferred embodiment of the present invention described by the accompanying reference drawings is only one embodiment. Therefore, those skilled in the art will fully understand the preferred embodiment of the present invention will be able to implement a similar type of sag reinforcement device and a reinforcement method using the same.

As described above, according to the deflection beam reinforcement device and the reinforcement method using the same, by removing the pillar supporting the beam, not only can the remodeling be easier, but also can increase the space utilization, such as to increase the parking space.

In addition, when the beam is struck, the beam can be reinforced, thereby improving the durability as well as the durability of the building.

Claims (7)

As to reinforce the deflection phenomenon of the beam G supported by the plurality of pillars C, Fixing parts 10 are respectively fixed to the upper side of the plurality of pillars (C) or both sides of the beam (G) between the pillars (C); A support part 20 for supporting the beam G between the fixing parts 10; A first tension rod 30 having one side fixed to each of the fixing portions 10 and a first bolt portion 31 formed at the other side; A second tension rod 40 having one side fixed to the support portion 20 and a second bolt portion 41 formed at the other side; A turnbuckle 50 fastening the first bolt portion 31 and the second bolt portion 41 to tension the first tension rod 30 and the second tension rod 40 in a rotational direction; Sag reinforcement device, characterized in that. The method of claim 1, The fixing part 10, the sag reinforcement device is characterized in that the edge surrounding the pillar (C) is formed with a coupling blade 11 is coupled to one side of the first tension rod (30). The method of claim 2, The fixing part 10 is formed on the upper end of the deflection beam reinforcement device, characterized in that it further comprises a flange (12) to be installed in the beam (G). The method of claim 1, The support portion 20, the deflection beam reinforcement device, characterized in that for supporting the end of the column (G ') that supported the beam (G). The method of claim 3, The support portion 20 is wrapped around the end edge of the pillar (G ') and the four side walls 22 formed with coupling wings 21 to which one side of the second tensile rod 40 is coupled, and the pillar (G) Deflection beam reinforcement device characterized in that it has a box shape consisting of a bottom (23) for supporting the end of '). The method of claim 1, The support portion 120, the first support piece 121 is installed on the beam (G) and the coupling wing that is coupled to one side of the second tension rod 40 while supporting the bottom of the first support piece 121. Sag reinforcement device, characterized in that consisting of a second support piece (122) formed (123). In order to prevent sagging of the beam G supported by the plurality of pillars C, Fixing the fixing parts 10 and 110 to both sides of the beams G between the upper ends of the plurality of pillars C or the pillars C; Installing support portions (20) (120) on beams (G) between the respective fixing portions (10) (110); Coupling one side of the first tension rod (30) having the first bolt portion (31) to the other side to each of the fixing portions (10) (110); Coupling one side of the second tension bar (40) having the second bolt portion (41) to the support portion (20) (120); And coupling the first bolt portion 31 and the second bolt portion 41 to both sides of the turnbuckle 50. Rotating the turnbuckle (50) to reinforce the deflection of the beam (G) by tensioning the first and second tensile rods (30) (40).