KR20200000739U - Reinforced concrete structure for reinforced concrete with high vibration resistance - Google Patents

Abstract

The present invention relates to a reinforcing bar structure provided in a pillar and a wall of a building, and the position of reinforcing bars provided in a reinforcing bar structure and a reinforcing member of a building wall is varied to increase the fastening force and durability of the reinforcing bar structure, thereby increasing the seismic resistance. Providing this large reinforcing bar structure for reinforced concrete to increase the durability by varying the positions of the lumbar and auxiliary muscles among the reinforced structures composed of the main, large, lumbar and auxiliary muscles to prevent damage to the reinforced concrete structure for reinforced concrete. And it relates to a reinforcing bar structure for reinforced concrete with high seismic resistance by increasing the durability of the reinforcing bar structure.

Description

Reinforced concrete structure for reinforced concrete with high vibration resistance}

The present invention relates to a reinforcing bar structure provided in a pillar and a wall of a building, and the position of reinforcing bars provided in a reinforcing bar structure and a reinforcing member of a building wall is varied to increase the fastening force and durability of the reinforcing bar structure, thereby increasing the seismic resistance. It relates to a reinforcing bar structure for a large reinforced concrete.

First, looking at the prior art,

In general, when a building is installed, a reinforced structure forms a foundation in order to properly transmit the upper load of the structure to the ground.

At this time, as the size of the reinforcing bar structure becomes larger and higher, the volume or thickness of the reinforcing bar concrete for forming the foundation also gradually increases.

In the building, pillars, beams, slabs, and walls form each reinforced structure and form the basis of the building.

In general, the pillar is composed of a main root, a large root, and an auxiliary large root to form a foundation, and the concrete inside the foundation is hardened to form the foundation of the pillar.

At this time, inside the pillar, the main root is vertically positioned, and a large root (strip reinforcing bar) that wraps around the main root and is fixed is arranged.

On the lower foundation of the column, the upper and lower roots are installed in a ‘井’ form, and a part of them intersects the main root.

Even in such a structure, cracks may occur when the thickness of the foundation is thin or insufficient.

In order to prevent such cracks, the foundation must be made thicker, and as the thickness increases, the volume and volume of concrete increase, the construction period increases, and the construction cost increases excessively. There is a hassle to do.

In addition, the construction method currently being constructed is a situation in which the specifications of the building structure continue as it was.

Although some changes and reinforcements have been made, the amount of rebar consumption due to over-design is rapidly increasing due to the idea that only unconditional rebars need to be added.

Accordingly, in the prior art, the registration number 10-0684149, the centrifugal force of the building precast reinforced concrete pillars and the manufacturing method of the reinforced concrete pillars and the method of constructing the reinforced concrete pillars, and the registration number 10-1258842, 'Factory assembled reinforced pillars 'Reinforcement beam on-site joint', registration number 10-1458435, 'saddle-shaped reinforcing bar and double-root HPC pillar manufacturing method and construction method using the same' and publication number 10-2015-0085209 'basic reinforcement structure 'Has been disclosed, but the above problems are still not improved.

The present invention has been devised to solve the problems of the prior art described above, and by changing the positions of the lumbar muscles and lumbar muscles in the reinforcing bar structures composed of the main, proximal, lumbar, and auxiliary muscles, the durability of the reinforced concrete is increased by increasing the durability. It was completed as a technical task with the emphasis on providing a reinforced concrete structure for reinforced concrete by preventing damage to the structure in advance and increasing the durability of the reinforced structure.

Therefore, the present invention is included in a pillar or a wall of a building, but in the reinforcing bar structure for a reinforced concrete consisting of a main bar, a large bar, and an auxiliary bar, the main bar is composed of a plurality of longitudinal sections at each corner portion of the column, and the large bar is the main bar. The outer periphery of the column is composed of a plurality of mutually spaced apart longitudinally forming the pillar, and the two ends of the auxiliary roots are formed in a ring shape, and both ends of the ring shape are interconnected by surrounding the outer circumference of the corresponding large muscles, The technical feature of the reinforced concrete structure for reinforced concrete is characterized in that a plurality of lumbar muscles are formed in the longitudinal direction between the main root and the main root, but are formed on the outside of the main root.

According to the reinforcing bar structure for a reinforced concrete with high seismic resistance according to the present invention, the positions of the main and proximal muscles constituting in the reinforcing bar structure are positioned in the same manner as in general use, and the positions of the lumbar muscles and auxiliary muscles are varied to increase the fastening force. It is designed to maximize durability by placing the major bars located in the reinforcing bar structure at the same intervals in the upper part, the middle part, and the lower part.

1 is a perspective view showing a conventional reinforced structure
Figure 2 is a plan view of the reinforcing bar structure of Figure 1
3 is a perspective view showing a rebar structure used in the present invention
4 is a plan view of the reinforcement structure of Figure 3
5 is a plan view showing another embodiment of FIG. 4
Figure 6 is a plan view showing that the present invention is provided with a fixed root
7 is a plan view showing another embodiment of FIG. 4
Figure 8 is a plan view showing that the support root is provided in the subject innovation

Referring to Figures 1 and 2 with reference to the method currently being constructed prior to explaining the present invention,

The components provided in the reinforcing bar structure include a main root, a large muscle, a waist muscle, and an auxiliary muscle.

The auxiliary muscle is configured to wrap the outer circumference of the corresponding lumbar muscle.

In the reinforcing bar structure provided with the main, proximal, lumbar and auxiliary muscles, the proximal muscles are spaced apart at equal intervals in the upper and lower ends, and the proximal muscles provided in the middle part are spaced farther than the upper and lower spaces. It is composed.

Due to this, when excessive pressure is applied from the upper part of the reinforcing bar structure, the middle part having the largest spaced apart space is pushed out, and cracks are generated in the concrete due to the bending of the main bar and the reinforcing bar structure. The loss of roles increases the risk of building collapse, which can result in enormous human damage.

Accordingly, the present invention relates to a reinforcing steel structure for concrete having high seismic resistance by varying the positions of the lumbar muscles and the auxiliary muscles in the reinforcing bar structures provided as the main, major, lumbar, and auxiliary muscles.

Hereinafter, with reference to Figures 3 to 8 for the preferred configuration and operation of the present invention for achieving the above object with reference to the accompanying drawings are as follows.

The reinforcing bar structure of the present invention is included in a pillar or wall of a building, but in a reinforcing bar structure for reinforced concrete composed of a main bar, a large bar, and an auxiliary bar, the plurality of main bars 100 are vertically formed at each corner portion of the column, The proximal muscle 300 wraps the outer circumference of the main muscle 100 and forms a plurality of mutually spaced apart longitudinally forming the pillars, and the auxiliary proximal muscle 400 has both ends formed in an annular shape, but both ends of the annular shape The parts are interconnected by surrounding the outer circumferences of the corresponding large muscles 300, and between the main muscles 100 and the main muscles 100 is configured inside the large muscles 300, but a plurality of lumbar muscles 200 in the longitudinal direction is configured. .

According to the size of the entire pillar, the auxiliary muscle 400 is connected only to the outer circumferences of the mutually corresponding large muscles 300, or is connected to each other, including the external muscles of the large muscles 300 and the main muscles 100.

The proximal bars 300 are spaced apart at the same intervals, respectively, to the upper end 11, the middle end 12, and the lower end 13 of the reinforcing bar structure 10.

If the present invention reinforcing bar structure is described in more detail,

The main root 100 is composed of a plurality in the longitudinal direction of each corner portion of the pillar.

In the case of the main root 100, it is configured at a corner portion of a pillar that is generally used, and the thickness can be varied according to the size of the pillar.

The lumbar muscle 200 is composed of a plurality of one or more in the longitudinal direction between the main root 100 and the main root 100.

At this time, the lumbar muscle 200 is spaced apart from each other in the inner portion of the large muscle 300 is composed of one or more.

In addition, one or more of the lumbar muscles 200 may be configured depending on the pillars, or at a user's option or for durability, spaced apart from each other on the outer portion of the large muscles 300.

The large muscle 300 is composed of a plurality of spaced apart from each other in the longitudinal direction forming the pillar surrounding the outer circumference of the main root 100.

The proximal bars 300 are spaced apart at equal intervals to the upper end portion 11, the middle end portion 12, and the lower end portion 13 of the entire reinforcing bar structure 10.

This is to increase the durability of the upper, middle, and lower portions 11, 12, and 13 in the same manner, in order to prevent a decrease in durability caused by increasing the spacing of the middle portion 12 in the prior art.

Referring to FIG. 6, the apex 300 that connects the mutually corresponding large muscle 300 and the large muscle 300 is configured.

The width fixation root 310, for example, when the large root 300 surrounds the outer circumference of the main root 100 and is configured in a horizontal direction, generally sees square pillars in a plan view, for example, the left, right, and upper and lower sides correspond to each other. The left and right surfaces of the large muscles 300 to be connected to the upper and lower surfaces, respectively.

Both ends of the auxiliary muscle 400 are formed in a ring shape.

Both ends of the ring shape of the auxiliary muscle 400 wrap around the outer circumference of the large muscle 300 corresponding to each other and are interconnected.

This allows the auxiliary muscle 400 to wrap the outer periphery of the lumbar muscle 200, and consequently, due to the auxiliary muscle 400, the lumbar muscle 200 and the large muscle 300 can be fastened at the same time. It was allowed to be raised.

In addition, when the pressure or shaking of the reinforcing bar structure 10 occurs from the outside, the problem that each component is prevented from functioning due to the separation of the individual components (main, proximal, lumbar, and auxiliary muscles) It is a structure that you want to prevent.

According to the size of the entire pillar, the auxiliary muscle 400 may be connected only to the outer circumferences of the mutually corresponding large muscles 300 or to include the external circumferences of the mutually corresponding large muscles 300 and the main roots 100.

Referring to FIG. 8, the main root 100 is formed inside the corner portion of the reinforcing bar structure 10 around the large root 200, and the support root 500 is formed outside.

The support bar 500 is located outside the corner of the reinforcing bar structure 10 in which the main bar 100 is constituted, and one or more of the support bars 500 are configured.

In addition, the corner fixator 510 is configured to interconnect the large muscle 200 and the support muscle 500, and the corner fixator 510 includes the entire circumference of the large muscle 200 and the support muscle 500, Connected in a '0' shape, or includes the outer periphery of the apex 200 and the support muscle 500, respectively, and connected in a '8' shape or include the outer periphery of the apex 200 and the support muscle 500 And can be connected in an 'S' shape.

According to the present invention as described above, the positions of the main and proximal muscles constituting in the reinforcing bar structure are positioned in the same manner as the positions generally used, and the positions of the lumbar muscles and the auxiliary proximal muscles are varied to increase the fastening force, and the positions of the reinforcement structures It is possible to maximize durability by placing the proximal muscles at the same intervals in the upper part, the middle part, and the lower part.

10: Reinforcing bar structure
11: Upper part 12: Middle part 13: Lower part
100: main root 200: lumbar muscle
300: approx. 310: width fixed root 400: auxiliary muscle
500: support root 510: corner fixator

Claims (3)

In the reinforcement structure for reinforced concrete that is included in the pillars or walls of the building, but consists of the main, major and auxiliary
The main root 100 is composed of a plurality in the longitudinal direction of each corner portion of the pillar,
The large root 300 is wrapped around the outer periphery of the main root 100 and is composed of a plurality of mutually spaced apart longitudinally forming the pillar,
The auxiliary muscle 400 is formed at both ends in a ring shape, and both ends of the ring shape are interconnected by surrounding the outer circumference of the corresponding large muscle 300,
Reinforced concrete structure for reinforced concrete, characterized in that one or more lumbar muscles 200 are formed in the longitudinal direction between the main roots 100 and the main roots 100, but configured in the longitudinal direction.
According to claim 1,
According to the size of the entire pillar, the auxiliary muscle 400 is connected to only the outer periphery of the mutually corresponding large muscle 300 or includes and connects the mutually corresponding large muscle 300 and the outer periphery of the major muscle 100 to each other. Rebar structure for this large reinforced concrete.
According to claim 1,
The reinforcing bar structure for the reinforced concrete is characterized in that the large bars 300 are spaced apart at equal intervals, respectively, at the upper end 11, the middle end 12, and the lower end 13 of the reinforcing bar structure 10.

Images