KR100992038B1 - Architectural beam by filled concrete - Google Patents

Abstract

PURPOSE: A concrete filled construction member is provided to improve earthquake-resistance by increasing resistance against twisting and bending. CONSTITUTION: A concrete filled construction member comprises a steel frame(20), a cover plate, a wood member, and concrete. The steel frame is formed in a square column shape in which one surface is longitudinally opened. The cover closes the opened surface of the steel frame. The wood member is attached on the outer surface of the steel frame and the cover plate. A concrete placing part(28) is formed inside the steel frame and is filled with concrete.

Description

ARCHITECTURAL BEAM BY FILLED CONCRETE}

The present invention relates to a concrete-filled building member, and more particularly, to constitute a steel frame of a metal material of which one side is opened, and to fasten and fix the outer surface of the steel frame integrally with a plate-like finish made of wood integrally. By curing concrete inside the frame to increase the bearing capacity and increase the resistance to irregular external forces such as warping and bending, it is possible not only to improve the strength and stability of the building but also to enhance the seismic resistance, fire resistance and appearance. It relates to the structure of the type building member.

In general, beam refers to a long and thin rod that supports a bending load among various structural components. Among the long and thin rods that make up the architectural skeleton such as steel structure, reinforced concrete structure, and timber structure It is placed in the horizontal direction and mainly serves to support the bending load in the direction perpendicular to the reaxial line.

In most cases, the beams in the building skeleton are rigidly joined to the columns to form a ramen (hardening of the material joints, ie the structural form or structure of the building in which the reinforcing bars or steel frames are the framework) and the weight of each part. In addition to supporting loads or loads, the entire armature, along with the pillars, also plays a role in forming the ability to withstand horizontal wind loads or seismic external forces.

The beam is largely classified into a girder, a bell beam, a marvelous beam, a scaled beam, a degenerate, and a woomi-yang. The girder, which spans between the columns and the columns, has a significant influence on the structural design of the structure.

This conventional beam, as shown in Figure 7a, forms a slab structure with the H-beams 70 and the slab 40. Here, the height of each floor of the building is the height of the interior space and the height of the slab structure. That is, as the height of the slab structure is reduced, the height of each layer can be reduced. Therefore, even if the building of the same number of floors, as the height of the slab structure is smaller, the height of the floor is smaller, the construction cost is reduced.

When the height of the H-shaped steel beam 70 or the height of the slab 40 is reduced in order to reduce the height of the slab structure, the support force or the bending resistance of the slab structure is weakened, which affects the safety of the structure. In addition, if the size of the H-shaped steel beam 70 is reduced in order to reduce the height of the slab structure, there is a problem that the cross-sectional area of the H-shaped steel beam is also reduced, which is vulnerable to compressive and bending stress acting in the longitudinal direction.

In order to solve this problem, as shown in FIG. 7B, the deck plate 74 having the groove 76 corresponding to the upper flange 72 of the H-beams 70 is installed in the H-beams 70. After that, a method of manufacturing a slab structure by pouring concrete has been proposed. The slab structure has an advantage that the height is reduced by the depth of the groove 76. However, the slab structure is effective for the stress acting in the direction perpendicular to the slab 40, but for the stress acting in the direction parallel to the slab 40, because the thickness of the slab in the portion where the groove 76 is thin Shear and flexural stresses are greatly concentrated and have a disadvantage in that they are also susceptible to compressive forces.

FIG. 7C is a cross-sectional view illustrating a slab structure including a cradle 78 welded to the web of the H-shaped steel beam 70 and a deck plate 74 installed on the cradle 78. That is, it is a slab structure in which a predetermined portion of the H-shaped steel beam 70 is embedded in concrete by welding the mounting bracket 78 to the web and installing the deck plate 74 on the mounting bracket 78 to pour concrete. Such a slab structure has the advantage of being structurally safe compared to the slab structure of Figure 5b. However, the process of welding the cradle 78 to the web additionally, and if the welding portion of the cradle 78 and the web is not robust, there is a problem that seriously affect the safety of the structure.

In addition, in the slab structure shown in Figure 7a to 7c is H-shaped steel is exposed to the outside is vulnerable to fire. That is, the high heat due to the fire is transmitted to the H-shaped steel as it may cause a problem that the H-shaped steel is deformed. In order to prevent this, the exposed H-beams must be separately coated with fireproof coating on the outside of the steel like steel structures.

On the other hand, in the conventional construction of beams and slabs, after connecting the H-beams between the pillar and the pillar must be installed so as to surround the formwork. Therefore, process delay and economic loss due to the removal of formwork and curing after curing become a problem.

In addition, most of the girders applied to the construction of prefabricated houses use solid wood, which has the advantage of maintaining the texture of the wood as it is, but it is very expensive and sensitive to atmospheric conditions such as temperature and humidity. Or twisting, and damage may be caused by pests or insects, resulting in weakened durability and shortened service life. In addition, wooden girders are difficult to handle due to heavy construction and very heavy weight. There is a problem that requires a more demanding design for the safety of the house. In addition, when rafters are connected to these girders, the rafters should be machined at the site, which leads to a waste of time and manpower, and the support strength of the girders is weakened by the rafters. There is.

Therefore, in consideration of the problems of the wooden beams as described above, there are cases in which steel frame or reinforced concrete is used as the girders. It is easy to corrode, which requires cumbersome rust prevention treatment and provides a disadvantage in that it is not easy to design a structure. Since its weight and volume are considerable, it has a significant load load on its own and structurally. There is this.

Meanwhile, reference numeral 50 in FIGS. 7A to 7C shows reinforcement bars in the slab 40.

The present invention is to solve the above problems, an object of the present invention is to improve the up and down bearing capacity of the column or beam and to increase the resistance to irregular external forces such as warping and bending to improve the seismic efficiency through the robustness and stability of the building In addition, it provides concrete-filled building members that can improve the reliability of products through the convenience and robustness of construction by preventing the degradation of durability due to the occurrence of cracks caused by temperature and moisture or damage caused by pests. It is.

In addition, the present invention can reduce the height of the slab structure to effectively reduce the height without affecting the safety of the structure, and provides a concrete-filled building member to be able to pour the concrete integrally with the slab and the beam. The purpose is to.

The concrete-filled building member according to the present invention includes a steel frame 20 having a square column shape in which one side thereof is opened in the longitudinal direction, a cover plate 23 for closing the open surface of the steel frame 20, and the It characterized in that it comprises a wooden member attached to the outside of the steel frame 20 and the cover plate 23, and the concrete 30 is filled in the concrete placing portion 28 formed inside the steel frame 20 It is done.

At this time, the wood member is fitted to the pair of wood finishing plates (10, 12) and the fitting portion 18 of the wood finishing plates (10, 12) formed with fittings (18) at both ends, respectively. It is preferably composed of the trials 13 and 15 and used as a pillar member.

On the other hand, the concrete-filled building member according to the present invention, the steel frame 20 of the rectangular column shape with one side open in the longitudinal direction, and the inside of the steel frame 20 on both sides of the steel frame 20 outside Longitudinal wood finishing plates 10 and 12 attached to the fixing nail 24 to the outside, and fitted wooden board 14 mounted in the longitudinal direction outside the lower surface of the steel frame 20, and the steel frame Spacer plate 22 to cover a part of the open surface of the 20, and the concrete 30 is poured into the hollow portion of the steel frame 20, characterized in that it is used as a beam member.

At this time, the plate-shaped slab 40 is formed on the open surface of the steel frame 20 to be balanced, integrally formed with the concrete 30 filled in the hollow portion of the steel frame 20, the steel frame ( 20 is preferably configured to further include a reinforcing bar 50 inserted into the hollow portion or the slab 40.

In addition, the upper portion of the spacer plate 22 may be configured to further include a wooden member for closing the open surface of the steel frame 20, the reinforcing bar 50 is inserted into the hollow portion of the steel frame 20. have.

The present invention by laying a wooden finishing material on the outside of the metal material with one side opening, and also by building the slab integrally with the inside of the metal material to improve the up and down support and increase the resistance to irregular external forces such as warping and bending It can greatly improve the robustness and stability.

In addition, it is possible to effectively prevent the degradation of durability due to the occurrence of cracks caused by temperature and moisture or damage caused by pests in the conventional wooden columns or wooden beams, as well as easy to fireproof structure and seismic design and beautiful appearance do.

On the other hand, the present invention can effectively reduce the height of the floor without affecting the safety of the structure, there is no need to install additional H-shaped steel or formwork, so the construction is very easy to have an effect of greatly improving the productivity.

1 is a concrete filled building member used as a pillar member according to an embodiment of the present invention,
FIG. 2 is an exploded view of FIG. 1;
3 is a cross-sectional view of FIG.
Figure 4a is a cross-sectional structural view of the concrete-filled building member used as a slab integrated wooden beam according to an embodiment of the present invention,
4b is a cross-sectional structural view of a concrete-filled building member used as a slab integrated wooden beam according to another embodiment of the present invention,
5a to 6b is a wooden beam in a concrete-filled building member used as a slab integrated wooden beam according to an embodiment of the present invention and another embodiment,
7a to 7c are structural views of a conventional general slab and beams.

Hereinafter, with reference to the accompanying drawings will be described in detail the structure of the concrete-filled building member according to the present invention.

1 is a concrete-filled building member used as a pillar member according to an embodiment of the present invention, Figure 2 is an exploded view of Figure 1, Figure 3 is a cross-sectional view of FIG.

In addition, Figure 4a is a cross-sectional structural view of the concrete-filled building member used as a slab integrated wooden beam according to an embodiment of the present invention, Figure 4b is a concrete filled used as a slab integrated wooden beam according to another embodiment of the present invention Figure 5 is a cross-sectional structural view of the building member, Figures 5a to 6b is a wooden beam in a concrete-filled building member used as a slab integrated wooden beam according to one embodiment and another embodiment of the present invention.

In adding the reference numerals to the components of the drawings, the same components are to have the same reference numerals as possible even if displayed on different drawings, and known functions that are determined to unnecessarily obscure the subject matter of the present invention Detailed description of the configuration will be omitted. Also, directional terms such as 'top', 'bottom', 'front', 'back', 'tip', 'front', 'back' and the like are used in connection with the orientation of the disclosed figure (s). Since the components of the embodiments of the present invention may be positioned in various orientations, the directional terminology is used for the purpose of illustration and not limitation.

Concrete-filled building member according to an embodiment of the present invention can be used as a pillar member to receive the weight of the building roof and deliver it to the cornerstone. It can also be used as a beam member that transfers the weight of the roof over the column. In particular, when used as the beam can be formed integrally with the slab (slab) to increase the resistance to irregular external forces, such as up and down support, twisting and bending can improve the seismic efficiency through the robustness and stability of the building. In addition, even if the concrete-filled building member of the present invention is used as any member, such as pillar member or beam member, it is possible to prevent the degradation of durability due to the occurrence of cracks caused by temperature and moisture or damage caused by pests greatly increases the reliability of the product Will be improved.

1 to 3 illustrate a concrete-filled building member used as a pillar member according to an embodiment of the present invention, the steel frame of the square pillar shape of the metal material having one side open in the longitudinal direction (20) And a cover plate 23 for closing the open surface of the steel frame 20, a wood member attached to the outside of the steel frame 20 and the cover plate 23, and an inside of the steel frame 20. It is configured to include concrete 30 is filled in the concrete pouring portion 28 formed in.

At this time, the wood member is fitted to the pair of wood finishing plates (10, 12) and the fitting portion 18 of the wood finishing plates (10, 12) formed with fittings (18) at both ends, respectively. It may be composed of a trial (13, 15), the wooden finishing plate (10, 12) is firmly using a plurality of fixing nails 24 in the outward direction from the concrete placing portion 28 of the steel frame 20 Is fixed. Therefore, the wood member exposed to the outside does not generate any traces of fixation, which is beautiful in appearance, and prevents problems such as corrosion as steel is exposed to the outside in advance. On the other hand, the fitted wood boards (13, 15) is a configuration for easy construction by fitting to the wood finishing boards (10, 12). In other words, the present invention is not limited to this, since various types of wood members may be attached to the outside of the steel frame 20 using adhesive or fixing nails 24.

The steel frame 20 and the cover plate 23 may be used by changing the thickness according to the construction environment, the steel frame 20 and the cover plate 23 is closely coupled to the concrete (30) ) Should not leak outside.

4A to 4B illustrate concrete-filled building members used as slab-integrated wooden beams according to the present invention, the steel frame 20 having one surface opened in a longitudinal direction in the shape of a hollow rectangular column of metal; A wooden member attached to the outside of the both sides in the steel frame 20 by the fixing nail 24, a spacer plate 22 to cover a part of the open surface of the steel frame 20, and the steel frame 20 It is configured to include a slab (40) is formed by pouring concrete to the inside of the and continuous with the open surface.

In addition, it is preferable to further include a reinforcing bar 50 is inserted into the hollow portion or the slab 40 of the steel frame 20.

Here, the wood member, the wood finishing plate (10, 12) coupled to the side of the steel frame 20, and the fitting wood plate (14) attached to the outside of the lower surface in the interior of the steel frame (20) It may be configured, the fitting wood plate 14 is fitted to the fitting portion formed at the lower end of the wood finishing plate (10, 12) is coupled.

In addition, as shown in FIG. 4b, the insulating material 60 may be further configured on the bottom surface of the slab 40 adjacent to the wood finishing plates 10 and 12.

The steel frame 20 is preferably formed of a steel sheet of steel, and is formed to be sealed to fill the concrete 30 therein. In addition, the open surface is such that the shape of the steel frame 20 is not deformed by the spacer plate 22, so that the slab 40 and the concrete 30 composed of the upper end of the steel frame 20 is continuous.

The wood finishing plates (10, 12) are formed of wood, exposed to the outside after the construction is completed to make the appearance beautiful.

The fitted wood plate 14, as shown in Figures 4a to 6a, is coupled to the wood finishing plate (10, 12) by fitting, can be bonded with an adhesive, but with the fixing nail (24) It is fixed to the steel frame 20.

In addition, as shown in FIG. 5B, the reinforcing wood 26 may be added to the sandwiching wood board 14 in the longitudinal direction to further enhance the appearance.

The reinforcing bar 50 is preferably configured to reinforce the concrete 30 to be placed in the interior of the steel frame 20, it is preferable that the reinforcement to the slab 40.

The slab 40 is formed in the form of a plate by pouring concrete 30 in succession with the beam formed of the steel frame 20, depending on the construction site as shown in Figure 4b the lower surface of the insulating material (60) ) Can be covered by construction.

6A and 6B illustrate that the slab 40 is used as a beam member that is not formed. That is, after fixing the wooden finishing plate (10, 12) and the fitting wooden plate (14) to the steel frame (20) by fixing nails (24), respectively, to construct a beam, the concrete pouring portion that is the interior of the steel frame (20) The concrete 30 is poured into the 28. At this time, the open surface of the steel frame 20 is maintained by the spacer plate 22, and finished with a wooden member to close the open surface to complete the beam member.

Here, Figure 6b shows a prototype of the actually produced beam member.

Since the pillar member of the present invention configured as described above is similar to that formed by standing the beam member, the slab is integrally formed.

The steel frame 20 and the spacer plate according to the invention 22 or cover plate 23, wood finishing plate (10, 12) and the fitting wood plate (13 to 15) consisting of a large number of beams or factory in advance factory It is preferable to produce as. That is, the steel frame 20 and the wood finishing plate (10, 12) and the fitting wood plate (13 to 15) is used to manufacture and assemble in advance.

At this time, the wood finishing plate (10, 12) and the fitting wood plate (13 to 15), because the use of the fixing nails 24 or bonding pins from the inside of the steel frame 20 to the outside is neatly formed appearance . In other words, it is possible to prevent the degradation of durability due to the occurrence of cracks caused by temperature and moisture or damage by pests, and provides convenience and robustness of construction.

Then, in the case of the assembled beam is placed in accordance with the structure of the building, to form a slab to form a slab, concrete in the formwork to form the slab 28 and the slab formed inside the steel frame 20 concrete To finish the construction by pouring.

Therefore, since the beam according to the present invention is formed integrally with the slab, the up and down bearing force is improved, and the resistance against irregular external forces such as warping and bending is increased.

In addition, by pouring concrete integrally with the slab to provide the convenience and robustness of the construction. And the inside is made of concrete, but the outside is made of wood and the exterior is beautiful, allowing construction of nature-friendly buildings.

The embodiments of the present invention described above and illustrated in the drawings should not be construed as limiting the technical spirit of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those skilled in the art can change and change the technical idea of the present invention in various forms. Therefore, such improvements and modifications will fall within the protection scope of the present invention if it is obvious to those skilled in the art.

10, 12: wood finishing member 13 ~ 15: fitted wood member
18: fitting 20: steel frame
22: spacer 23: cover plate
24: nail 26: reinforcement wood
28: concrete pouring part 30: concrete
40: slab 50: rebar
60: insulation 70: H-beam
72: upper flange 74: deck plate
76: groove 78: holder

Claims (5)

Square-shaped steel frame 20 having one side open in the longitudinal direction, a cover plate 23 for closing the open surface of the steel frame 20, the steel frame 20 and the cover plate 23 Concrete-filled building member, characterized in that it comprises a wooden member attached to the outside and the concrete 30 is filled in the concrete placing portion 28 formed inside the steel frame 20.
The method of claim 1,
The wood member is fitted with a pair of wood finishing plates (10, 12) and the fitting portion 18 of the wood finishing plates (10, 12) formed with fittings (18) at both ends ( 13, 15), the concrete-filled building member, characterized in that used as a pillar member.
Steel frame 20 having a rectangular columnar shape in which one side is opened in the longitudinal direction, and the longitudinal direction is attached to the fixing frame 24 from the inside of the steel frame 20 to the outside on both sides of the steel frame 20 Wood finishing plates (10, 12), fitted wooden board 14 which is mounted in the longitudinal direction on the outside of the lower surface of the steel frame 20, and the spacer plate for covering a portion of the open surface of the steel frame (20) 22) and the concrete-filled building member, characterized in that it is used as a beam member including the concrete (30) to be poured to fill the hollow portion of the steel frame (20).
The method of claim 3,
Plate-shaped slab 40 is formed on the open surface of the steel frame 20 to be balanced, integrally formed with the concrete 30 filled in the hollow portion of the steel frame 20,
Concrete-filled building member, characterized in that it further comprises a reinforcement (50) inserted into the hollow portion or the slab (40) of the steel frame (20).
The method of claim 3,
It is characterized in that it further comprises a wooden member for closing the open surface of the steel frame 20, the reinforcing bar 50 is inserted into the hollow portion of the steel frame 20 in the upper portion of the spacer plate 22 Concrete-filled building members.

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