KR102131957B1 - A horizontal beam manufacturing method of a Rahmen building structure - Google Patents

Abstract

The present invention relates to a method for manufacturing a horizontal member of a ramen structure building, and more specifically, to produce a formwork that sags as much as a horizontal correction value considering the deflection factor of the horizontal member, and prestressing so that it rises as much as creep by the slab weight and slab weight. The invention relates to a method of manufacturing a horizontal member of a ramen structured structure by allowing the strength panel to be uniformly installed on the outer wall of the structure of the ramen structure by increasing the horizontality during the construction of the slab.
To this end, in a ramen structure structure in which horizontal members are installed on the upper and lower sides, a load-bearing panel is sandwiched between the upper and lower horizontal members, and a slab is installed on the horizontal members, wherein the horizontal members are prestressed A ramen structure building characterized by being made of a beam and convex upward so that the horizontal member is horizontal with respect to the ground when the slab is constructed on the horizontal member in consideration of the slab self-weight and creep caused by the slab self-weight. Provides a method for manufacturing a horizontal member.

Description

A horizontal beam manufacturing method of a Rahmen building structure}

The present invention relates to a method of manufacturing a horizontal member of a ramen structure building, and more particularly, to a method of manufacturing a horizontal member of a ramen structure building so that the accuracy of horizontality can be maximized during slab construction.

In general, an outer wall refers to an outer wall surface that is seen as the exterior of a building. In the past, it was mainly painted or decorated with bricks, but recently, a stone or metal plate structure has been fixed outside the building wall. There are many methods of pursuing beautiful appearance.

At this time, the stone or metal plate structure fixed to the outside of the wall of the building is also called an exterior panel.

On the other hand, the method of fixing the plate structure to the finished wall surface of the building is largely wet and dry, and the wet method is a method of placing plate structures on the outside of the wall surface and placing cement, etc. to fix it. It is rarely used at present because of the long construction period including and the workability and workability are poor.

On the other hand, the dry method is a method of joining a plate structure to the outside of the wall surface by using a separate fastener made of metal or the like, and is relatively excellent in workability and workability.

Hereinafter, with reference to the accompanying Figures 1a to 2 to look at with respect to the construction of the exterior panel through a dry method.

A first bracket 10 fixed to the side of each floor slab 2 and a plurality of fixed beams 20 fixed to the first bracket 10 and projecting substantially vertically from the side of the slab 2 And, a basic skeletal structure of a plurality of horizontal beams 30 fixed to the fixed beam 20 and horizontally arranged, and a plurality of vertical beams 40 fixed to the outside of the horizontal beam 30 and vertically arranged. On the other hand, along the outer side of each vertical beam 40, the exterior panel P of a stone or metal material is supported in all directions by a second bracket 50 to form an outer wall.

In addition to this, as shown in FIG. 1B, the connecting beam 60 is horizontally installed on the slab 2, and the exterior panel P is fixed in the longitudinal direction of the connecting beam 60 along the connecting beam 60. To construct the outer wall of the building.

At this time, in the construction of the exterior panel (P), uniform arrangement of the exterior panel (P) is very important because it affects the aesthetic sense of the building and the durability of the exterior wall.

The construction structure of the exterior panel (P) is the constructional error, that is, even when the exterior panel (P) is not uniform in a straight line construction, the horizontal beam 30 or the vertical beam 40 or the connection beam 60 position By calibrating, it is possible to eliminate errors in the construction of the exterior panel P.

On the other hand, in addition to the structure in which the exterior panels P are installed on the beams 30, 40 and 60 themselves, the proof panel structure having a new proof structure designed to reinforce the structure from external forces such as earthquakes and fires has been published in the Republic of Korea. No. 10-1731493' has been disclosed by the applicant.

2, the inner plate 210 constituting the rear surface of the proof strength panel 200 has a shear key in a space constituted by the ramen horizontal member 100 and the ramen vertical member 110. It is fixed through and installed to resist horizontal, vertical and external forces.

When constructing the above-described ramen structure, the ramen horizontal member 100 uses a pre-stress beam, which is sensitive to sagging and rising so that the beam longitudinal curve changes in each step of the process.

When the proof strength panel 200 is installed due to the change in the beam longitudinal curve, the proof strength panel 200 is not uniformly positioned in a straight line, so there is a problem in that the aesthetic sense of the building exterior is deteriorated.

That is, since the ramen horizontal member 100 is designed and manufactured in such a way that various deflection factors such as slab load are not considered, when the slab 2 is installed on the ramen horizontal member 100, the ramen horizontal member 100 is downward. As the sag is not uniform, the proof strength panel 200, which is installed between the horizontal members 100 of the ramen, has to be constructed along the horizontal horizontal members 100 of which the sag is not constant downward. will be.

In addition, due to the change in the beam longitudinal curve of the horizontal member 100 of the ramen, the shear key, which is an important element that resists external force, is not uniformly installed because it is installed between the inner plate 210 of the proof strength panel 200 and the horizontal member 100 of the ramen. There was a problem in that it was difficult to maximize the force resisting external forces caused by earthquakes and fires.

Republic of Korea Registered Patent Publication No. 10-1731493

The present invention has been devised to solve the above-mentioned problems, and the object of the present invention is to construct a load-bearing panel of a ramen structured building by maximizing the horizontal level of horizontal members of a ramen-structured building, thereby constructing a structure through uniform construction of the load-bearing panel The purpose of the present invention is to provide a method for manufacturing a horizontal member of a ramen structured structure that can enhance the aesthetics of the outer wall and maximize the resistance by external force.

In the present invention, in order to achieve the above object, horizontal members are installed on the upper and lower sides, a load-bearing panel is sandwiched between the upper and lower horizontal members, and a slab is installed on the horizontal members in a ramen structure building. , The horizontal member is made of a prestressed beam, characterized in that the horizontal member is convex upward so as to be horizontal with respect to the ground when the slab weight and the creep caused by the slab weight applied to the horizontal member act on the slab. Provides a method for manufacturing horizontal members of ramen structures.

At this time, (a) producing a formwork so that the center of the floor sags downward by the horizontal correction value of the horizontal member; (b) placing reinforcing bars and steel wires for prestressing in the formwork; (c) pouring concrete into the formwork And curing; (d) pulling the steel wire of the cured concrete to both sides to convexly prestress against the ground: comprising, wherein the convexly prestressed height of step (d) is a horizontal member. When the slab self-weight and the creep due to the slab self-weight are applied to the horizontal member, it is preferable that the horizontal member is leveled with respect to the ground.

At this time, the horizontal correction value, the lower eccentric stress of the horizontal member, the loss of stress of the horizontal member, the creep caused by the horizontal member stress, the horizontal member weight, the creep caused by the weight of the horizontal member, the weight of the slab, the weight of the creep by the weight of the slab It is preferably a value.

The method of manufacturing a horizontal member of a ramen structure building according to the present invention has the following effects.

By manufacturing the formwork considering various horizontal member deflection factors and considering the sum of the weight of the slab and the creep sum due to the weight of the slab, the horizontal member is produced, so that when the slab is constructed on the horizontal member, the horizontal member does not sag without leveling. Can be maintained.

Accordingly, since the proof panel can be uniformly constructed along the horizontal member, the aesthetic sense of the outer wall of the building does not decrease, and the fastening force of the proof panel that can resist external forces due to factors such as earthquake and fire is maximized. It has the effect.

Figure 1a is a perspective view of a main portion showing an external panel mounting structure according to the prior art
Figure 1b is a side view of a main portion showing another example of the exterior panel installation structure according to the prior art
Figure 2 is a perspective view of a main portion showing a state in which the load-bearing panels and slabs of a general ramen structure building are constructed;
3 is a flow chart showing a method of manufacturing a horizontal member of a ramen structure building according to a preferred embodiment of the present invention
4 is a view schematically showing a process of manufacturing a horizontal member of a ramen structure building according to a preferred embodiment of the present invention
Figure 5 is a table showing the horizontal compensation sag relationship when manufacturing a horizontal member of a ramen structure building according to a preferred embodiment of the present invention.

The terms or words used in the specification and claims are not to be construed as being limited to ordinary or lexical meanings. It should be interpreted in a sense and concept consistent with the technical idea of the present invention.

Hereinafter, a method of manufacturing a horizontal member of a ramen structure building according to a preferred embodiment of the present invention will be described with reference to the attached FIGS. 3 to 5.

In order to manufacture the horizontal member 100, the formwork 300 is manufactured. (S100)

The horizontal member 100 is made of concrete and is manufactured through prestressing.

At this time, the formwork 300 is manufactured so that the central portion sags downward, as shown in Fig. 4 (a).

This is to ensure that the prestressing of the horizontal member 100 is effectively performed in the process of applying prestressing to the horizontal member 100 that is cured later.

That is, after the horizontal member 100 is manufactured horizontally, compared to the stiffness when the prestressed horizontal member 100 is leveled due to the slab self-weight and creep displacement due to the slab self-weight by pulling the steel wire 500. This is because the stiffness is high when the center portion of the (100) is made to sag downward, and the prestressed horizontal member 100 is pulled by the steel wire 500 and leveled by creep displacement due to slab self-weight and slab self-weight.

At this time, the production of the formwork 300 is first made only the bottom (低部) of the formwork (300).

On the other hand, the numerical value of the center of the formwork drooping downward corresponds to the horizontal correction value δ of the horizontal member 100.

At this time, the downward deflection of the formwork 300 is installed according to the deflection curve.

In the present invention, in manufacturing the formwork 300, the sagging of the center of the formwork 300 is not arbitrarily designed.

That is, when the slab 2 is constructed, the horizontal member 100 is maintained horizontally, so that the stress is uniformly transmitted to the horizontal member 100, and the homogeneity of the proof strength panel 200 installed on the horizontal member 100 is uniform. Since the aesthetics must be considered, the downward deflection value is very important when manufacturing the formwork.

The condition for calculating the horizontal correction value δ may be described through a table as shown in FIG. 5.

In order to calculate the horizontal correction value δ, the deflection factor of the horizontal member 100 is grasped, and the horizontal correction value δ can be calculated by correcting the deflection factor value.

At this time, the deflection factors of the horizontal member 100 include the lower eccentric stress (δ1) of the horizontal member 100, the stress loss (δ2) of the horizontal member 100, and the horizontal member 100 stressing. The creep (δ3), the self-weight (δ4) of the horizontal member 100, the creep (δ5) due to the self-weight of the horizontal member 100, the self-weight (δ6) of the slab 2, and the weight of the slab 2 Creep (δ7).

By calculating and summing each deflection factor of the horizontal member 100, a horizontal correction value (δ) is calculated, and the center of the bottom of the formwork is sagged as much as the horizontal correction value (δ).

At this time, the equation for calculating the deflection factor of each horizontal member 100 is as follows.

① Horizontal member lower eccentric stress rise (δ1)

: 초기솟음량

: Initial rise

: 초기긴장력

: Initial tension

e: Steel wire 500 eccentric

: 콘크리트 탄성계수

: Concrete modulus

: 콘크리트 단면 2차 모멘트

: Second moment of concrete section

: 수평보정 프리스트레스트빔 길이

: Horizontal compensation prestress beam length

② Deflection of horizontal member stress loss (δ2)

α : 스트레싱 손실계수

α: Stress loss factor

③ Creep rise due to horizontal member stressing (δ3)

: 크리프계수

: Creep coefficient

④ Self-deflection of the horizontal member (δ4)

= 수평보정 프리스트레스트빔 단위 자중

= Self-weighted horizontal compensation prestress beam

ℓ = horizontal compensation prestress beam length

⑤ Creep by self-weight of horizontal member (δ5)

⑥ Self-deflection of the upper slab (δ6)

= 상부슬라브자중

= Upper slab weight

⑦ Creep due to the weight of the upper slab (δ7)

The horizontal correction value δ is calculated by summing the respective calculated values calculated through the above equation, and the center of the bottom of the formwork 100 is sag downward along the deflection curve by the horizontal correction value δ.

Next, the reinforcing bar 400 for increasing the stiffness of the horizontal complement 100 and the steel wire 500 for prestressing and prestressing are placed in the formwork 300. (S200)

The reinforcing bar 400 is reinforced along the curvature of the formwork 300, as shown in FIG. 4(b).

The steel wire 500 is eccentrically disposed below e from the neutral axis of the cross section.

Next, after the reinforcement of the steel wire 500 and the reinforcing bar 400 is completed, as shown in (c) of FIG. 4, the side of the formwork 300 is manufactured and concrete is poured into the formwork 300. (S300)

At this time, the height of the side of the formwork 300 corresponds to the height of the horizontal member 100.

Thereafter, the concrete is cured for a certain period of time.

Next, when the concrete is cured, prestressing is applied to the cured concrete by pulling the steel wire 500 (S400).

At this time, the pre-stressing is made so that the concrete rises convex upward as shown in Fig. 4 (d).

At this time, the raised height of the prestressed concrete consists of a numerical value (δ6 + δ7) obtained by summing the creep by the weight of the slab (2) and the weight of the slab (2).

Such a design, when the upper slab 2 is constructed on the prestressed horizontal member 100, so that the horizontal member 100 is maintained horizontally, then applied to the horizontal member 100 according to the additional construction Losing load will be considered without consideration.

That is, it is a design that considers only the dead load, not the live load. When the slab 2 is constructed on the horizontal member 100, it will be okay if the level of the horizontal member 100 is maintained.

Next, the horizontal member 100 manufactured as described above is installed on a pillar, and the slab 2 is mounted on the horizontal member 100 as shown in FIG. 4(e). (S500)

At this time, the horizontal member 100 maintains the level by deflecting the amount of creep deformation deflection (δ6 + δ7) due to the weight of the slab 2 and the weight of the slab 2.

At this time, since the horizontal member 100 is designed in consideration of the weight of the slab and various conditions, the accuracy of the horizontality of the horizontal member 100 can be maximized.

Next, although not shown, it is constructed by sandwiching the proof strength panel 200 between the horizontal members 100 installed for each layer.

At this time, since the inner plate 210 of the proof strength panel 200 supports the horizontal member 100, the horizontal holding force of the horizontal member 100 can be further maximized.

In addition, by horizontally maintaining the horizontal member 100, since the installation of the proof strength panel 200 can be made uniform, not only can the aesthetic sense of the ramen structure building be increased, but also the external force resistance can be made uniformly in each part. It is possible to maximize the quality of construction of the proof strength panel 200.

In the above, the present invention has been described in detail with respect to the described embodiments, but it is obvious to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, and it is natural that such modifications and modifications belong to the appended claims.

100: horizontal member 200: proof panel
210: inner plate 300: formwork
400: Rebar 500: Steel wire

Claims (3)

In the ramen structure building, horizontal members are installed on the upper and lower sides, a load-bearing panel is sandwiched between the upper and lower horizontal members, and slabs are mounted on the horizontal members.
The horizontal member,
It is made of a prestressed beam, and when the slab is constructed on the horizontal member in consideration of the slab self-weight and creep caused by the slab weight, the horizontal member is made convex upward so as to be horizontal with respect to the ground. The steps are,
(a) producing a formwork such that the center of the floor sags downward by the horizontal correction value of the horizontal member;
(b) placing steel wires for rebar and prestressing in the formwork;
(c) pouring and curing concrete in the formwork;
(D) pulling the steel wire of the cured concrete to both sides to act to pre-stress the cured concrete convex upward with respect to the ground;
The height of the convex prestressing in the step (d) is a height such that the horizontal member is horizontal to the ground when the slab weight and the creep caused by the slab weight applied to the horizontal member act on the horizontal member,
The horizontal correction value,
Characterized in that the lower eccentric stress of the horizontal member, the loss of stress of the horizontal member, the creep caused by the horizontal member stress, the horizontal member weight, the creep caused by the horizontal member weight, the slab weight, the creep sum by the slab weight,
In the step (a), the formwork is made only at the bottom of the formwork, and the sidewalls of the formwork are made after the step (b),
(e) a step in which a slab is installed on the horizontal member;
(f) constructing a proof strength panel between the horizontal members for each floor of the building, including:
Method of manufacturing a horizontal member of a ramen structure building, characterized in that the installation of the proof strength panel is made uniform through the horizontal maintenance of the horizontal member, so that the external force resistance can be made uniformly in each part of the proof strength panel.

delete delete

Images