KR101044730B1 - Beam having steel bar structure for reinforcing shearing force and upper tensile force, and providing space for passing through of plumbing, electric wire or communication wire etc - Google Patents

Abstract

PURPOSE: A girder including a reinforcement structure for reinforcing upper tensile force and shear force and providing a space for passing a pipeline, an electric wire, a communications line, etc. is provided to prevent cracks in the upper part of a concrete body and to control camber when prestressing, and to secure safety at work and to prevent tetanus, an accidental fall, etc. CONSTITUTION: A girder(100) including a reinforcement structure for reinforcing upper tensile force and shear force and providing a space for passing a pipeline, an electric wire, a communications line, etc. contains a concrete body(20), a connection(70) installed to two ends of the concrete body to connect the concrete body and a column(2), a main reinforcing bar arranged on the lower part of the concrete body, and a reinforcement structure(30) installed to the concrete body and provided with an upper reinforcing bar(31), a lower reinforcing bar and a lattice bar(33) connecting the upper reinforcing bar and the lower reinforcing bar.

Description

Beam having steel bar structure for reinforcing shearing force and upper tensile force, and providing space for passing through of plumbing, electric wire or communication wire etc}

The present invention relates to a beam, and more particularly, includes a lattice reinforcing bar and an upper reinforcing bar and a lower reinforcing bar installed along a longitudinal direction of the beam to resist shear and tensile stresses of a prestressed beam. It relates to beams that provide space for passing wires, wires, communication lines, etc.

In general, the structure is installed to connect the column and the pillar to support the load, the support for the load transmitted from the slab.

As shown in FIG. 1, the beam 10 includes a concrete body 12, a host reinforcing bar 14 installed below the concrete body 12, and a stirrup reinforcing bar 16 installed to surround the host reinforcing bar 14. Include.

The stirrup reinforcement 16 is installed at a predetermined interval along the longitudinal direction of the beam 10, serves to resist the shear stress generated in the beam (10). Stirrup reinforcement 16 serves to prevent brittle fracture by preventing the sinusoidal crack generated in the concrete body 12 due to the shear stress and to integrate the beam 10 and the slab (not shown in the figure).

The stirrup reinforcement 16 is installed to protrude upward than the concrete body 12, both ends of the stirrup reinforcement 16 is bent inward 135 degrees or 90 degrees. Due to the bent portion, the worker lacks a space for stepping on the foot during work, and thus, the safety accident of the worker is frequently caused by being caught at both ends of the stirrup reinforcement 16.

In addition, since the reinforcing bar 16 is usually used for the production of the reinforcing bar, such as a diameter of 10mm to 16mm, the amount of reinforcing bar is increased and the diameter is large, resulting in poor workability. In addition, there is also a problem that the step of installing the reinforcing bar on the upper side of the beam 10 after installing the beam (10). Furthermore, the manufacturing process of the stirrup reinforcement 16 and the process of installing the stirrup reinforcement 16 to the host reinforcing bar 14 is added, there is a problem that takes a lot of time and expensive manufacturing costs.

In addition, when the pre-stress is introduced to the beam 10, a tensile force is applied to the upper portion of the concrete body 12 and a compressive force is applied to the lower portion of the concrete body 12, the cracks on the upper surface of the concrete body 12 due to the tensile force There is a problem that it is easy to occur and difficult to control the amount of rise.

In addition, under the beam 10, various installations such as pipes, electric wires, communication lines, and the like are installed, and since the facility passes under the beam 10, there is a problem in that it takes up an indoor space. When the facility occupies an indoor space, the space available to residents can be reduced by that much.

 On the other hand, the host reinforcing bars 14 and the stub steel reinforcement 16 has a large specific gravity, but because the volume occupied by the beam 10 is small, the load generated by the host reinforcing bars 14 and the stub steel reinforcement 16 is small. Most of the load of the beam 10 is taken up by the concrete body 12. Therefore, reducing the amount of concrete used in the beam 10 can reduce the weight of the beam 10, thereby increasing the safety of the building. In particular, recently, many high-rise buildings are being constructed, and tower cranes are used for the construction of high-rise buildings, and if the beam's own weight can be reduced, the constructability (heavyness) of the high-rise building can be improved.

Also, as is known, a lot of energy is used with sand, gravel, water and cement to produce concrete. Therefore, to produce concrete will inevitably generate CO ₂ , if it can reduce the amount of concrete used in the beam 10 will also help to reduce the generation of CO ₂ .

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a beam capable of preventing cracks from occurring at the top of the concrete body and controlling the amount of rise when the prestress is introduced.

Still another object of the present invention is to provide a beam having a space through which various pipes, wires, communication lines, etc. can pass under the beam.

Another object of the present invention is to provide a sufficient space for the operator's foot to prevent the worker's foot from being interfered by the reinforcing bars to ensure the safety of work and to prevent tetanus, fall accidents, etc. The purpose is to provide.

Still another object of the present invention is to provide a beam that can reduce the amount of stirrup rebar, reduce the amount of rebar work in the field, and increase the production speed because the rebar assembly process can be simplified.

Another object of the present invention to provide a beam that can reduce the processing cost and manufacturing cost through production automation.

To achieve the above object, the beam according to the present invention, the concrete body is formed long in the longitudinal direction and formed on the lower surface of at least one end of both ends above the lower surface of the central portion; A cast iron bar disposed below the concrete body along the length direction; And rebar structures installed on both sides of the main reinforcing bars along the longitudinal direction to reinforce the shear force. The reinforcing bar structure, the upper reinforcement is installed to protrude above the concrete body; A lower reinforcing bar positioned under the upper reinforcing bar and embedded in the concrete body; And a lattice reinforcing bar installed to connect the upper reinforcing bar and the lower reinforcing bar. At this time, the upper reinforcement and the lower reinforcement is extended together in the longitudinal direction, the lattice reinforcement is coupled with the upper reinforcement and the lower reinforcement at predetermined intervals along the longitudinal direction to connect the upper and lower reinforcement.

It is preferable that the compressive force acts on the lower part of the concrete body by prestressing and the tensile force acts on the upper part and the upper reinforcing bar of the concrete body by pre-stressing the concrete constituting the concrete body in the tensioned state of the reinforcing bar. The tension applied to the upper surface of the concrete body is reduced by the upper bar receiving the tension.

The lower reinforcing bar may include end lower reinforcing bars installed at both ends, and a central lower bar reinforcing parts installed at the central part. At this time, the center lower reinforcing bar is located below the at least one end lower reinforcing bar.

On the other hand, it is preferable that both ends of the concrete body is provided with a connection for connecting the concrete body and the pillar.

The connecting portion may include: a first plate installed to cover at least a portion of the lower surfaces of the both ends; A second plate coupled with the first plate and installed to at least partially cover both sides 26 and 27 of the concrete body; And a third plate installed to be perpendicular to the second plate, coupled to the second plate, and having a perforation hole into which the fastening member is inserted.

The connection part may include a fourth flat plate in addition to the first, second and third flat plates. The fourth plate is installed on the opposite side of the surface on which the third plate is installed, on both sides of the second plate, and is embedded in the concrete body.

The lattice reinforcing bar may be bent in a zigzag shape and alternately coupled to the upper and lower bars. At this time, the lattice reinforcing bar may include a first lattice reinforcing bar and a second lattice reinforcing bar. The first lattice reinforcing bar is coupled to one side of the upper reinforcing bar and one side of the lower reinforcing bar, and the second lattice reinforcing bar is coupled to the other side of the upper bar and the other side of the lower bar.

In addition, a plurality of lattice reinforcing bars may be vertically coupled to the upper and lower bars at predetermined intervals.

In addition, it is desirable that the portion of the shear stress acting largely has a narrow spacing of the lattice rebars than the portion of the shear stress acting small.

Furthermore, the lattice reinforcing bar connecting the upper reinforcing bar and the lower reinforcing bar is preferably not bent toward the upper or facing lower reinforcing bar from the upper side of the concrete body.

On the other hand, the beam according to the present invention may include a strand wire embedded in the upper portion of the concrete body. The strand is arranged along the length of the concrete body, the strand is prestressed to provide a compressive force to the concrete body.

In addition, the beam according to the present invention may include a light weight body, which is embedded along the longitudinal direction of the concrete body in order to reduce the weight of the concrete body has a specific gravity less than concrete.

In addition, the beam may include a fixing means for fixing the light body at a predetermined position inside the formwork or for fixing the light body to the main reinforcing bar or reinforcing structure.

Further, the light weight body is preferably installed to be spaced apart at a predetermined interval along the longitudinal direction. The fixing means may include a bar assembly surrounding each lightweight body spaced at a predetermined interval.

Preferably, the fixing means fixes the lightweight body to be located on the neutral axis of the beam before the slab is formed.

The beam according to the present invention has the following effects.

First, when the prestress is introduced, since the upper reinforcing bar can be subjected to a tensile force, it is possible to prevent the occurrence of cracks on the upper surface of the concrete body and to control the amount of rise.

Second, it provides a space through which various pipes, wires, communication lines, etc. can pass under the beam.

Third, since the worker's foot can provide enough space to step, it is possible to prevent the worker's foot from being interfered with by the reinforcing bar to secure the safety of the work and to prevent tetanus and the fall accident.

Fourth, it is possible to reduce the amount of stirrup rebar, to reduce the amount of work on the site reinforcement, and to simplify the rebar assembly process to increase the production speed of the beam.

Fifth, processing costs and manufacturing costs can be reduced through production automation.

1 is a cross-sectional view showing a beam according to the prior art.
Figure 2 is an exploded perspective view showing that the beam according to the first embodiment of the present invention is coupled to the pillar.
3 is a front view showing the beam of FIG.
4 is a front view showing a cast iron and reinforcing bar structure provided in the beam of FIG.
5 is a cross-sectional view taken along line VV 'of FIG. 3.
6 is an enlarged view of a portion A of FIG. 4.
Figure 7 (a) is a front view showing a modification of the reinforcing structure provided in the beam according to the first embodiment of the present invention, Figure 7 (b) is a side view of Figure 7 (a).
8 is a front view showing another modified example of the reinforcing bar structure provided in the beam according to the first embodiment of the present invention.
9 is a front view showing another modified example of the reinforcing bar structure provided in the beam according to the first embodiment of the present invention.
Figure 10 (a) is a front view showing another modified example of the reinforcing structure provided in the beam according to the first embodiment of the present invention, Figure 10 (b) is a side view of Figure 10 (a).
11 is a sectional view showing a beam according to a second embodiment of the present invention.
12 is a perspective view showing a weight reduction unit provided in the beam of FIG.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely examples of the present invention and are not intended to represent all of the technical ideas of the present invention, so that various equivalents And variations are possible.

2 is an exploded perspective view showing the beam is coupled to the pillar according to the first embodiment of the present invention, Figure 3 is a front view showing the beam, Figure 4 is a front view showing a cast iron and reinforcing bar structure provided in the beam.

The beam 100 according to the embodiment uses a reinforcing bar structure that is continuously installed along the longitudinal direction of the beam in place of the existing stirrup reinforcement 16, and various pipes, electric lines, communication lines, etc. under the beam. It is characterized by providing a space for passing (hereinafter referred to as 'various piping and wiring'). The reinforcing structures can effectively resist shear and tensile stresses (tensile stresses occurring at the top of the prestressed beams) acting on the beams, in particular the prestressed beams, and provide sufficient space for the operator to step on the feet. Make sure In addition, providing a space through which various pipes and wires can pass allows efficient use of the indoor space.

Referring to the drawings, the beam 100 is a concrete body 20, the connection portion 70 for connecting the concrete body 20 and the pillar (2), and the main reinforcing bar disposed under the concrete body (20) 21) and the reinforcing bar structure 30 installed in the concrete body 20.

The concrete body 20 is made of concrete and is formed long along its longitudinal direction (x direction). The lower surface of both ends in the concrete body 20 is formed above the lower surface of the central portion. The lower surfaces of both ends form a space S through which the various pipes, electric lines, communication lines, and the like (hereinafter, referred to as various pipes and wirings) pass along the pillars 2.

Meanwhile, the space S may be formed at both ends of the concrete body 20, but may be formed at only one end of both ends. That is, only the bottom surface of one of the lower surfaces of both ends is formed above the bottom surface of the central portion, and thus the space S may be formed only at the one end portion. This will be readily apparent to those skilled in the art with reference to the present specification. However, hereinafter, a case in which both the spaces S are formed at both ends will be described for convenience of description.

The connection part 70 is installed at both ends of the concrete body 20 to connect the concrete body 20 and the pillar 2. The connection part 70 includes a first flat plate 71 installed to cover at least a portion of the lower surface of the end portion, and a first plate 71 coupled to the first flat plate 71 and at least partially covering both side surfaces 26 and 27 of the concrete body. 2 Drilling hole which is installed perpendicular to either side (column side) of the flat plate 72 and both surfaces of the second flat plate 72 to be coupled to the second flat plate 72 and the fastening member 79 is inserted The 3rd flat plate 73 in which 76 was formed, and the 4th flat plate 74 provided in the other surface of the both surfaces of the 2nd flat plate 72, and embedded in the concrete body 20 are provided. The first, second, third and fourth flat plates 71, 72, 73 and 74 are preferably metal flat plates having a predetermined thickness, rigidity and strength. Among the plates, the first, second and fourth plates 71, 72, and 74 are integrally combined with the concrete of the concrete body 20, and the third plate 73 is connected to the pillar by the fastening member 79. 2) is coupled to the coupling plate (3). The fastening member 79 is inserted into the drilling hole 76 and the coupling hole 4 to couple the coupling plate 3 and the third flat plate 73.

On the other hand, the connection portion 70 may be provided with a fifth flat plate 77 which is respectively coupled to the front and rear of the both ends. The fifth plate 77 is coupled to the first plate 71, the second plate 72, and the concrete body 20.

In addition, the connection part 70 may include a support plate 78 coupled to the first plate 71 and the second plate 72 in the space S. The support flat plate 78 serves to support the first flat plate 71.

As such, the beam 100 according to the present invention is preferably coupled to the pillar 2 in the field after the pre-fabricated in the factory because the coupling with the pillar 2 can be made by the connection portion 70. However, it is not necessarily limited thereto.

In addition, the present invention may be preferably applied to prestressed beams, but is not limited thereto and may be applied to general beams without prestressed beams.

Reinforcement may be reinforced in the concrete body 20, the lower portion of the concrete body 20 is disposed a cast iron 21 for resisting the tensile stress and bending stress. In the case of manufacturing the PC beam (prestressed concrete beam) by applying prestress to the beam 100, the compressive force is applied to the lower part of the concrete body 20 by placing concrete in the state in which the cast steel 21 is tensioned (prestressed) and the concrete body Tensile force is applied to the upper portion of the (20). As described above, in the present embodiment (first embodiment) and the second embodiment below, it is preferable that the concrete forming the concrete body 20 is cast in the state in which the main reinforcing bar 21 is prestressed, thereby becoming a PC beam. In addition, it is preferable to be manufactured by precast in the factory according to the present invention than to be produced by in-situ casting. On the other hand, as the main reinforcing bar 21 may be used a general rebar, but the stranded wire may be used. In the present specification, the main reinforcing bar should be understood to include both the general reinforcing bar and the strand.

On the other hand, as described above, the lower surface of both ends is formed above the lower surface of the central portion, it is preferable that the main reinforcing bar 21 is provided only in the center portion without extending the main reinforcing bar 21 toward both ends. Since the main reinforcing bar 21 serves to resist tensile and bending stresses, the bending stress is generated at the center of the beam 100 and relatively small at both ends, so that the bending reinforcement 21 is disposed only at the center. Can resist effectively.

On the other hand, the strands 25 may be installed on the upper portion of the concrete body 20. The strand 25 is prestressed together with the cast reinforcing bar 21, in which the concrete forming the concrete body 20 is poured. Therefore, the strand 25 applies a compressive force to the concrete body 20 when the curing of the concrete is completed.

In the PC beam without the strands 25, tensile stress may be applied to the upper portion of the concrete body 20 and compressive stress may be applied to the lower portion thereof, thereby causing tensile cracks to occur at the upper portion of the concrete body 20. The compressive stress acts on the upper portion of the concrete body 20 by the prestress. Thus, the strand 25 prevents the occurrence of tensile cracks in the upper portion of the concrete body 20 together with the upper reinforcement 31 and controls the amount of rise. On the other hand, although the reinforcing bar may be used instead of the barbed wire 25, the barbed wire 25 is more advantageous when a tensile force is applied (prestressed).

The reinforcing structure 30 is installed along the longitudinal direction (x direction) of the beam 100 in order to resist shear stress and tensile stress acting on the upper part of the PC beam. Preferably, two reinforcing bar structures 30 are installed at both sides of the main bar 21 with the main bar 21 therebetween. As described above, the rebar structure 30 is used in place of the stirrup reinforcement 16 used in the conventional beam 10, but the stirrup reinforcement 16 may be installed in the reinforcement structure 30 at predetermined intervals. .

The reinforcing structure 30 is a lattice reinforcing bar installed to connect the upper reinforcing bar 31, the lower reinforcing bars 32, 36 and 37, and the upper reinforcing bar 31 and the lower reinforcing bars 32, 36 and 37. 33).

The upper reinforcement 31 is installed to extend along the longitudinal direction (x direction) of the beam 100. The upper reinforcement 31 is projected upwardly than the upper surface 22 of the concrete body 20, and thus a portion of the tensile force acting on the upper portion of the concrete body 20 in the PC (prestressed concrete) beams Because of this burden, it is possible to prevent cracks occurring in the upper portion of the concrete body 20 and to control the amount of rise of the concrete body 20. That is, the upper reinforcement 31 serves to reinforce the upper tensile force of the PC beam (100).

The lower reinforcing bars 32 and 36 and 37 are installed to extend along the longitudinal direction (x direction) of the beam 100 under the upper reinforcing bars 31. The lower reinforcing bars 32, 36 and 37 are installed to be buried under the concrete body 20.

Preferably, the lower reinforcing bars 32, 36 and 37 include a central lower reinforcing bar 32 installed at the center of the beam 100 and end lower reinforcing bars 36 and 37 provided at both ends. That is, three lower reinforcing bars 32, 36 and 37 may be separated and installed, and the central lower reinforcing bar 32 is installed below the lower end reinforcing bars 36 and 37.

The upper reinforcement 31 may be combined with the neighboring upper reinforcement 31 when the length of the beam 100 is long, and the joining is a conventional method, for example, a method of welding after overlapping reinforcing bars (overlap joints). It may be made, but may be made by gas pressure welding or using a coupler. The gas welding is advantageous in that the amount of rebars can be reduced because the rebars do not overlap each other and are coupled to each other by facing the ends of the rebars. In the figure w1 represents a gas-welded part. In addition, the coupler is a device that couples the reinforcing bars of both sides by a screw coupling method.

Meanwhile, the lower reinforcing bars 32, 36 and 37 may also be combined with neighboring lower reinforcing bars 32, 36 and 37, and the lower reinforcing bars 32, 36 and 37 may be combined with each other. The method is the same as the method for joining the upper bars 31 to each other.

The lattice reinforcement 33 is combined with the upper reinforcement 31 and the lower reinforcement 32, 36, 37 at a predetermined interval along the longitudinal direction (x direction) of the beam 100, the upper reinforcement 31 and the lower Reinforcing bars 32, 36 and 37 are connected.

The lattice reinforcement 33 is coupled to the upper reinforcement 31 and the lower reinforcement 32, 36, 37 by welding or the like. Conventional stirrup reinforcement (16) was used as a thick rebar, such as 10mm ~ 16mm in diameter, the lattice reinforcement (33) can be used as well as the reinforcing bar of the diameter 6mm ~ 10mm.

Like the upper and lower reinforcing bars 31, 32, 36 and 37, the lattice reinforcing bar 33 may be connected to each other by being coupled to the neighboring lattice reinforcing bars 33. The method for joining the lattice reinforcing bars 33 to each other is the same as the method for joining the upper bars 31 to each other and the method for joining the lower bars 32, 36 and 37 to each other. Indicates a portion of the

On the other hand, the upper reinforcement 31 is projected upward than the upper surface 22 of the concrete body 20 and the lattice reinforcement 33 is coupled to the upper reinforcement 31, the lattice reinforcement 33 is higher than the concrete body 20 It is not bent toward the upper reinforcing bar 31 or the lower lower bar 32, 36, 37 facing each other. If the lattice reinforcement 33 is bent toward the upper reinforcement 31 facing the upper reinforcement 31 or the lower lower reinforcement 32, 36, 37 facing up than the concrete body 20, the worker The upper surface 22 of the body 20 lacks a space to support the foot. Since the reinforcing structure 30 according to the present invention does not form the bent portion, the worker may provide a sufficient space for stepping on the upper surface 22 of the concrete body 20, whereby the worker's foot It is possible to prevent tetanus and fall accidents by preventing interference due to rebar.

In the present embodiment, the lattice reinforcing bar 33 may be disposed at a narrow interval at a portion where the shear stress is large and at a relatively wide interval at a portion where the shear stress is small. In general, since the shear stress is largely applied at both ends of the beam 2 and the adjacent beam 100, the lattice reinforcement 33 is disposed at both ends of the beam 100 at narrow intervals, and in the center portion of the beam 100, Since the shear stress acts relatively small, the lattice reinforcing bars 33 are arranged at wide intervals. Accordingly, as shown in the figure, the lattice reinforcement 33 is disposed at both ends of the reinforcing structure 30 corresponding to both ends of the beam 100 at narrow intervals and the reinforcing structure corresponding to the central portion of the beam 100 ( At the central portion of 30), a lattice rebar 33 is disposed at a wide interval.

The lattice reinforcement 33 provided in the present embodiment is bent in a zigzag shape while extending in the x direction and alternately coupled to the upper reinforcing bars 31 and the lower reinforcing bars 32 and 36 and 37. Lattice reinforcing bar 33 includes a first lattice rebar 34 and a second lattice rebar 35. As shown in FIG. 5, the first lattice reinforcement 34 is coupled to one side of the upper reinforcement 31 and one side of the lower reinforcement 32, 36 and 37, and the second lattice reinforcement 35 is the upper reinforcement. It is coupled to the other side of the 31 and the other side of the lower reinforcing bars 32, 36, 37.

On the other hand, the tie bar 38 for preventing the twist along the longitudinal direction of the beam 100 may be provided on the lower reinforcement 32, 36, 37 at a predetermined interval. For ease of understanding of the drawings, tie bars 38 are not shown in FIG. 4 and tie bars 38 are shown in FIG. 5 only.

Thus, the reinforcing structure 30 is the upper reinforcement 31, the lower reinforcing bars 32, 36, 37, and the upper and lower reinforcing bars 31, 32 (continuous in the longitudinal direction of the beam 100) ( 36) (37) consists of a simple configuration comprising a lattice rebar (33) installed to connect. Therefore, the manufacturing (assembly) process of the reinforcing structure 30 can be simplified, and the work of installing the reinforcing structure 30 in the formwork becomes simple and simple, thereby increasing the production speed of the beam 100. In addition, since the reinforcing bar of smaller diameter than the existing stirrup reinforcing bar 16 can be used, the amount of rebars can be reduced. In addition, since the reinforcing structure 30 is made integral, the amount of rebar work after installing the beam 100 can be reduced.

In particular, the existing stirrup reinforcement 16 is because the both ends are bent inwards because the worker lacks space for tread, because the reinforcing structure 30 according to the present invention does not bend the lattice reinforcement 33 The upper surface 22 of the concrete body 20 may provide a sufficient space for the worker to step on the foot, thereby preventing the worker's foot from being interfered by the rebar, it is possible to prevent tetanus, fall accidents and the like. .

On the other hand, Figure 7 (a) is a front view showing a modification of the reinforcing structure provided in the beam 100, Figure 7 (b) is a side view of Figure 7 (a). 7 (a) and 7 (b) show only the central portion of the reinforcing structure 30a.

Referring to the drawings, the reinforcing bar structure 30a includes an upper bar 31, a lower bar 32, 36 and 37, and an upper bar 31 and lower bar 32, 36 and 37. And a lattice rebar 33a installed to connect. The upper reinforcement 31 is the same as the upper reinforcement 31 described above, the lower reinforcement 32, 36, 37 is the same as the lower reinforcement 32, 36, 37 described above.

Whereas the above-described lattice reinforcing bar 33 is composed of two rebars 34 and 35, the lattice reinforcing bar 33a is formed of one reinforcing bar.

The lattice reinforcement 33a is bent in a zigzag shape while extending in the x direction and alternately coupled to the upper reinforcement 31 and the lower reinforcement 32 and 36 and 37. Preferably, the lattice reinforcement 33a is coupled to the lower portion of the upper reinforcement 31 and the upper portion of the lower reinforcement 32, 36, 37 by welding or the like.

8 is a front view illustrating another modified example of the reinforcing bar structure provided in the beam 100. 8 shows only the central portion of the rebar structure 30b.

The reinforcing structure 30b is a lattice reinforcing bar installed to connect the upper reinforcement 31, the lower reinforcement 32, 36, 37, and the upper reinforcement 31 and the lower reinforcement 31, 36, 37. (33b). The upper reinforcement 31 is the same as the upper reinforcement 31 described above, the lower reinforcement 32 is the same as the lower reinforcement 32, 36, 37 described above.

The lattice reinforcing bar 33b is bent in a zigzag shape while extending in the x direction and alternately coupled to the upper reinforcing bars 31 and the lower reinforcing bars 32 and 36 and 37. At this time, at a portion where the lattice reinforcing bar 33b is coupled to the upper reinforcing bar 31, a predetermined section of the lattice reinforcing bar 33b is bent to be parallel to the upper reinforcing bar 31. This is to increase the coupling force between the lattice reinforcing bar 33b and the upper reinforcing bar 31 so that the section in which the lattice reinforcing bar 33b and the upper reinforcing bar 31 are lengthened.

Similarly, at the portion where the lattice reinforcing bar 33b is engaged with the lower reinforcing bars 32, 36 and 37, a predetermined section of the lattice reinforcing bar 33b is bent so as to be parallel to the lower reinforcing bars 32, 36 and 37. .

9 is a front view illustrating another modified example of the reinforcing bar structure provided in the beam 100. 9 shows only the central portion of the reinforcing structure 30c.

The reinforcing structure 30c is a lattice reinforcing bar installed to connect the upper reinforcement 31, the lower reinforcement 32, 36, 37, and the upper reinforcement 31 and the lower reinforcement 32, 36, 37. (33c). The upper reinforcement 31 is the same as the upper reinforcement 31 described above, the lower reinforcement 32, 36, 37 is the same as the lower reinforcement 32, 36, 37 described above.

The lattice reinforcing bars 33c are installed at predetermined intervals along the x direction, and are installed to be perpendicular or substantially perpendicular to the upper reinforcing bars 31 and the lower reinforcing bars 32 and 36 and 37. The lattice reinforcement 33c is coupled to the upper reinforcement 31 and the lower reinforcement 32 and 36 and 37 by welding or the like.

10 (a) is a front view showing another modified example of the reinforcing structure provided in the beam 100. 10 (a) and 10 (b) show only the center portion of the reinforcing structure 30d.

As shown in the figure, the reinforcing bar structure 30d includes upper bars 31, lower bars 32, 36, 37, and upper bars 31, lower bars 32, 36, 37. Lattice reinforcing bars (33d) (33d ') installed to connect the.

The upper reinforcement 31 is the same as the upper reinforcement 31 described above, the lower reinforcement 32, 36, 37 is the same as the lower reinforcement 32, 36, 37 described above.

Lattice reinforcing bars 33d and 33d 'are alternately coupled to the upper reinforcing bars 31 and the lower reinforcing bars 32 and 36 and 37 while extending in the x direction. At this time, the lattice reinforcement 33d is coupled to one side of the upper reinforcement 31 and one side of the lower reinforcement 32, 36 and 37, and the lattice reinforcement 33d 'is the other side and the lower of the upper reinforcement 31. It is coupled to the other side of the reinforcing bars 32, 36, 37. The lattice reinforcement 33d 'forms a goal where the lattice reinforcement 33d forms a mountain, and the lattice reinforcement 33d' forms a mountain where the lattice reinforcement 33d forms a goal.

On the other hand, Figure 11 is a cross-sectional view showing a beam according to a second embodiment of the present invention, Figure 12 is a perspective view showing a weight reduction unit provided in the beam. The same reference numerals of FIGS. 1 to 10 among the reference numerals of FIG. 11 denote the same components having the same function.

The beam 200 is to use a reinforcing structure that is continuously installed along the longitudinal direction of the beam in place of the existing stirrup reinforcement 16, and provides a space through which various pipes and wiring can pass under the beam And by reducing the amount of concrete used in the production of the beam, it is characterized by reducing the weight of the beam and the carbon dioxide emissions. The reinforcing structures can effectively resist shear and tensile stresses (tensile stresses occurring at the top of the prestressed beams) acting on the beams, in particular the prestressed beams, and provide sufficient space for the operator to step on the feet. Make sure In addition, providing a space through which various pipes and wires can pass allows efficient use of the indoor space. In addition, reducing the weight of the beam can increase the workability (gravity) when working on high-rise buildings using tower cranes and the like.

The beam 200 may be preferably used in the case of applying prestress, but is not limited thereto, and may be used in a general beam without prestressing.

Referring to the drawings, the beam 200 is embedded in the concrete body 20, the connection portion 70 (not shown in FIG. 11) for connecting the concrete body 20 and the pillar, and the inside of the concrete body 20 The weight reduction unit 80, the main reinforcing bar 21 and the reinforcing bar structure 30 for resisting tensile stress and shear stress acting on the concrete body 20.

The concrete body 20, the connection part 70, the main reinforcing bar 21 and the reinforcing bar structure 30 are the concrete body 20, the connecting part 70, the main reinforcing bar 21 and the reinforcing bar structure of the first embodiment. Since it is the same as each of (30), description thereof will be omitted here.

The weight reduction unit 80 includes a lightweight body 60, which is embedded in the concrete body 20 along the longitudinal direction (x direction) of the beam 200 and has a smaller specific gravity than concrete. .

The lightweight body 60 is preferably installed to be spaced apart at predetermined intervals along the longitudinal direction (x direction) of the beam 200. In addition, the light weight body 60 may have various shapes such as a sphere, a cube, an ellipse, a cylinder, and the like, and in order to reduce the weight of the light weight body 60, the inside thereof is preferably empty. On the other hand, the sphere, cube, ellipse, cylinder, etc. not only mean the exact sphere (cub), cube, ellipse, cylinder, etc. in the dictionary meaning, but also a sphere-like shape, a cube-like shape, oval It should be understood that the shape similar to the shape and the shape similar to the cylinder is included.

The lightweight body 60 is made of a material having a specific gravity smaller than concrete, preferably made of recycled plastic or styrofoam. The use of recycled plastics is environmentally beneficial.

The weight reduction unit 80 according to the present invention may include fixing means for fixing the light weight body 60 to the lattice reinforcement 33 or for fixing the light weight body 60 to a predetermined position inside the formwork (not shown). Can be.

The fastening means may consist of a bar assembly enclosing each lightweight body 60, the bar assembly comprising a transverse bar 62, a longitudinal bar 64, and a transverse bar 62. It is preferred to have a connecting bar 66 connecting the longitudinal bars 64. As the bars 62, 64, 66, wires or rebars having a diameter of about 4 mm to 6 mm may be used.

The horizontal bars 62 are members arranged in the y direction and are disposed at predetermined intervals along the x direction. The longitudinal bars 64 are members arranged in the x direction, and the four longitudinal bars 64 are arranged to be spaced apart at predetermined intervals in the y direction. The horizontal bar 62 and the vertical bar 64 cooperate with each other to form an inner space, and accommodate and fix the lightweight body 60 in the inner space. At this time, the connecting bar 66 is fixed to the horizontal bar 62 and the vertical bar 64 are connected to each other.

On the other hand, although the drawing shows a fixing means consisting of a horizontal bar 62 and the vertical bar 64, the fixing means may have a variety of structures as long as it can be fixed to the lightweight body (60).

At least one of the transverse bars 62 and the longitudinal bars 64 is engaged with the formwork to fix the position of the fastening means (bar assembly), for example, both ends of the longitudinal bars 64 may be wire or The position of the bar assembly is fixed by being connected to the formwork with a string or the like. Fixing the position of the bar assembly relative to the formwork can be made by the same principle that the cast iron 21 is fixed to the formwork, and this will be easily understood by those skilled in the art with reference to the present specification, which will not be elaborated herein. .

As an alternative to securing the bar assembly to the formwork, the bar assemblies may comprise the reinforcing bars 21, 31, 32, 33, 36, 37, for example the lattice bars 33. It can also be fixed at. At least a portion of the transverse bar 62 extends in the transverse direction (y direction) to weld or bind to the lattice rebar 33.

On the other hand, the lightweight body 60 is preferably installed on the neutral axis of the beam 200 (that is, the neutral axis of the precast PC beam 200) before forming the slab (not shown in the figure). As described above, in the PC beam (PC beam without the strand 25), the tensile stress acts on the neutral axis and the compressive stress acts on the lower part of the neutral axis about the neutral axis. In addition, when a slab (not shown in the drawing) is formed on the upper side of the PC beam, the tensile stress acts mainly on the PC beam and the compressive stress acts on the slab. The lower reinforcement 32, 36, 37 is received. When the lightweight body 60 is installed on the neutral shaft of the precast PC beam 200 (the beam before placing the slab), the compressive and tensile stress due to prestress is small in the vicinity of the neutral shaft and the neutral shaft. 60) is less likely to break, and after the slab is completed, the neutral axis moves toward the slab, thereby reducing the safety of the beam 200 because most of the tensile stress is received by the cast steel 21.

On the other hand, since the height of both ends is smaller than the center part, the beam 200 differs in the position of the said neutral shaft in a center part and both ends. Therefore, the weight reduction unit 80 is separated into three, it is preferable to be installed so as to correspond to the neutral axis of the central portion at the center portion and to correspond to the neutral axis of both ends at both ends.

20: concrete body 21: cast steel
25: stranded wire 31: upper bar
32, 36, 37: lower rebar
33, 33a, 33b, 33c, 33d, 33d ': Lattice rebar
60: light weight body 80: weight reduction unit
100, 200: Bo

Claims (16)

A concrete body formed long in the longitudinal direction and having a lower surface of at least one of both ends formed above the lower surface of the center portion;
A cast iron bar disposed below the concrete body along the length direction; And
Includes; each of the reinforcing structure is installed on both sides of the main reinforcement along the longitudinal direction to reinforce the shear force;
The reinforcing structure,
An upper bar installed to protrude above the concrete body;
A lower reinforcing bar positioned under the upper reinforcing bar and embedded in the concrete body; And
It includes; lattice reinforcing bar installed to connect the upper and lower reinforcement,
The upper reinforcement and the lower reinforcement is extended together in the longitudinal direction, the lattice reinforcement is coupled with the upper and lower reinforcement at predetermined intervals along the longitudinal direction to connect the upper and lower reinforcement,
Both ends of the concrete body is provided with a connection for connecting the concrete body and the pillar,
The connection part,
A first plate disposed to cover at least a portion of the lower surface of both ends;
A second plate coupled with the first plate and installed to at least partially cover both sides 26 and 27 of the concrete body; And
And a third plate installed to be perpendicular to the second plate, coupled to the second plate, and having a perforation hole into which the fastening member is inserted. The method of claim 1,
The concrete constituting the concrete body in the state in which the main reinforcing bar is cast and the compressive force acts on the lower part of the concrete body by prestressing, the tensile force acts on the upper part and the upper reinforcing bar of the concrete body, and the upper bar receives the tensile force. Beam, characterized in that the tensile force acting on the upper surface of the. The method according to claim 1 or 2,
The lower reinforcing bar includes end lower reinforcing bars installed at both ends, and a central lower bar reinforcing parts installed at the central part.
The center lower reinforcing bar is characterized in that located below the at least one end lower reinforcing bar. delete delete The method of claim 1,
A beam comprising: a fourth plate installed on the opposite side of the surface on which the third plate is installed, on both sides of the second plate, and embedded in the concrete body. The method according to claim 1 or 2,
The lattice reinforcing bar is bent in a zigzag shape and characterized in that it is alternately coupled to the upper and lower reinforcement. A concrete body formed long in the longitudinal direction and having a lower surface of at least one of both ends formed above the lower surface of the center portion;
A cast iron bar disposed below the concrete body along the length direction; And
Includes; each of the reinforcing structure is installed on both sides of the main reinforcement along the longitudinal direction to reinforce the shear force;
The reinforcing structure,
An upper bar installed to protrude above the concrete body;
A lower reinforcing bar positioned under the upper reinforcing bar and embedded in the concrete body; And
It includes; lattice reinforcing bar installed to connect the upper and lower reinforcement,
The upper reinforcement and the lower reinforcement is extended together in the longitudinal direction, the lattice reinforcement is coupled with the upper and lower reinforcement at predetermined intervals along the longitudinal direction to connect the upper and lower reinforcement,
Lattice reinforcing bars are bent in a zigzag shape and alternately coupled to upper and lower bars,
Lattice rebar includes a first lattice rebar and a second lattice rebar,
The first lattice reinforcing bar is coupled to one side of the upper bar and one side of the lower bar,
The second lattice reinforcing bar is characterized in that it is coupled to the other side of the upper bar and the other side of the lower bar. The method according to claim 1 or 2,
Beams, characterized in that a plurality of lattice reinforcing bars vertically coupled to the upper and lower reinforcement at predetermined intervals. The method according to claim 1 or 2,
The large shear stress is applied to the beam, characterized in that the spacing of the lattice rebars is narrower than the small shear stress. The method according to claim 1 or 2,
The lattice reinforcing bar connecting the upper reinforcing bar and the lower reinforcing bar is characterized in that the beam is not bent toward the upper or facing lower reinforcing bar above the concrete body. The method according to claim 1 or 2,
A beam, which is disposed on an upper portion of the concrete body along a longitudinal direction of the concrete body, comprises a stranded wire or a tensile reinforcing bar which is prestressed to provide a compressive force to the concrete body. The method according to claim 1 or 2,
Beams, characterized in that it comprises a lightweight body embedded in the longitudinal direction to reduce the weight of the concrete body having a specific gravity less than concrete. The method according to claim 1 or 2,
Beams comprising a fixing means for fixing the light body at a predetermined position inside the formwork or for fixing the light body to the cast iron or reinforcing bar structure. The method of claim 14,
The lightweight body is installed to be spaced apart at a predetermined interval along the longitudinal direction,
Wherein,
And a bar assembly surrounding each of the lightweight bodies spaced at predetermined intervals. The method of claim 14,
The fixing means is characterized in that for fixing the lightweight body to be located on the neutral axis of the beam before the slab is formed.

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