KR102142304B1 - Connecting sturcture between column and wide beam and floor structure - Google Patents

Abstract

The present invention is a column member; A wide beam connected in a direction crossing the column member and installed to surround the cross section of the column member; And a shear stiffener which is provided in pairs and is joined to both sides of the column member and extends in a first direction in the front and rear direction of the column member to be embedded in the concrete member of the wide beam; It provides a bonding structure.

Description

Joint structure of column member and wide beam, and floor structure {CONNECTING STURCTURE BETWEEN COLUMN AND WIDE BEAM AND FLOOR STRUCTURE}

The present invention relates to a joint structure of a column member and a wide beam with increased rigidity of the joint, and a floor structure.

It should be noted that the contents described in this section merely provide background information about the present invention and do not constitute the prior art.

The concrete-filled steel pipe column prevents the decrease in the strength of the steel pipe due to buckling because the concrete filled inside the steel pipe suppresses the local buckling deformation of the steel pipe.

In addition, since the filled concrete is constrained by the steel pipe, the steel price rises without falling out of concrete due to cracks appearing in the reinforced concrete column or the steel frame reinforced concrete column.

Therefore, the concrete-filled steel pipe column exhibits high strength characteristics and deformation capacity, and can maintain the strength to the large deformation area after the maximum strength.

However, if the details of the junction where the dissimilar materials meet are not properly constructed, there is a problem that the column surface and the concrete surface are separated and collapse occurs.

An object of the present invention is to improve the load performance of the joint by improving the joint performance of the joint of heterogeneous materials to improve the separation of the column surface and the concrete surface.

In addition, referring to Fig. 1, the structure that is currently most widely applied is a column 10, a girder member 20 connecting the column 10 and the column 10, and between the girder 20 and the girder 20 It is a ramen structure (RC) consisting of a beam member 30 connecting the.

The present invention eliminates the member corresponding to the beam member installed between the girder and the girder of FIG. 1, and applies the wide beam only in one direction of the floor structure to reduce the amount of construction and the floor height.

KR 10-2006-0011050 A

An aspect of the present invention is to provide a joint structure of a column member and a wide beam capable of improving load performance by improving the joint performance of the joint portion.

In one aspect, the present invention is to provide a floor structure capable of reducing the amount of construction and floor height by excluding the installation of additional beam members between wide beams.

As an aspect for achieving the above object, the present invention is a column member; A wide beam connected in a direction crossing the column member and installed to surround the cross section of the column member; And, a shear stiffener which is provided in a pair and is bonded to both side surfaces of the column member and extends in a first direction, which is a front and rear direction of the column member, and is embedded in the concrete member of the wide beam, wherein the shear stiffener, It includes a cross section of a bent shape and is provided as an angle member extending in the first direction, and the angle member is disposed in a region outside the cross section of the column member in a second direction, which is a lateral direction of the column member, , In the angle member, two angle members having a'b' shape are disposed to be spaced apart in a third direction, which is the height direction of the column member, and the angle member is disposed to be opposed to form a pair with the column member interposed therebetween, The shear stiffener provides a joint structure of a column member and a wide beam further comprising a truss angle or connection reinforcement connecting the two angle members of the'b' shape.

Preferably, the wide beam is formed extending in the longitudinal direction, the reinforcing assembly reinforcing member is disposed therein; And a concrete member in which the assembly reinforcing member and the shear stiffener are embedded.

Preferably, the shear stiffener is disposed in a second direction in the lateral direction of the column member, in an area out of the cross-section of the column member, in a first direction in the front and rear direction of the column member, corresponding to the cross section of the column member It may be disposed to a region outside the cross-section of the column member including the region.

Preferably, the shear stiffener has a length protruding from the column member in a first direction in the front and rear direction is set in a range of 0.4 to 1.2 times the height of the wide beam, and in the second direction in the lateral direction from the column member The protruding length may be set in a range of 5 to 40 times the thickness of the angle member constituting the shear stiffener.

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Preferably, it is bonded to the upper and lower ends of the angle member, respectively, the attachment reinforcement bars extending in the longitudinal direction of the angle member; may further include.

Preferably, a plurality of attachment studs are bonded to the upper and lower ends of the angle member and are spaced apart in the longitudinal direction of the angle member to be installed; may further include.

As another aspect for achieving the above object, the present invention is a joint structure of the plurality of column members and wide beams; And a floor slab installed on the upper side of the wide beam and integrated with the column member to form a floor plate.

Preferably, a plurality of wide beams are provided to be spaced apart from the bottom of the floor slab, and may be installed to extend only in the first direction, which is the front and rear direction of the column member.

Preferably, the column member may be provided as a connecting column member connected to an interlayer column member disposed between adjacent layers and having an upper end embedded in the floor slab while passing through the wide beam.

According to one embodiment of the present invention as described above, there is an effect of improving the load performance by improving the bonding performance of the joint portion of the column member and the wide beam.

As an aspect of the present invention, there is an effect of reducing the height of the floor by excluding the installation of additional beam members between wide beams, thereby reducing the amount of construction material, shortening the construction period and reducing the construction cost.

1 is a diagram schematically showing a conventional ramen structure (RC).
2 is a view schematically showing the arrangement of the column member and wide beam including the bonding structure of the present invention.
3 is a view showing a bonding structure according to an embodiment of the present invention.
4 is a view showing a bonding structure according to another embodiment of the present invention.
5 is a plan view of FIG. 3.
6 is a side view of FIG. 3.
7 is a front view of FIG. 3.
8 is a view showing a bonding structure according to another embodiment of the present invention.
9 is a view showing a floor structure according to an embodiment of the present invention.
10A to 10D show the results of performing finite element analysis of the joint structure of the present invention according to the protruding length of the shear stiffener in the first direction.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, embodiments of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. In addition, embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. The shape and size of elements in the drawings may be exaggerated for a more clear description.

Hereinafter, a joint structure of a column member and a wide beam according to an embodiment of the present invention will be described in detail with reference to the drawings.

2 to 10D, the joint structure of a column member and a wide beam according to an embodiment of the present invention includes a column member 100, a wide beam 200, and a shear stiffener 300, and additionally attaching reinforcement (400) And, it may include an attachment stud (500).

2 and 3, the joint structure of the column member and the wide beam is connected in a direction crossing the column member 100 and the column member 100, and surrounds the cross section of the column member 100. The wide beam 200 is installed so as to be installed, and the wide beam 200 is provided to form a pair and is bonded to both sides of the column member 100, and extends in the first direction D1, which is the front and rear direction of the column member 100, It may include a shear stiffener 300 embedded in the concrete member 230 of 200).

3 to 5, at least the outer surface of the column member 100 may be formed of a metal material.

For example, the column member 100 may be provided as a filled steel pipe column filled with concrete therein.

The metal material constituting the outer surface of the column member 100 may be made of a steel material such as steel or stainless steel.

Of course, it goes without saying that various types of metals except steel can be applied.

Referring to FIG. 3, the column member 100 may be provided as a filled steel pipe column having a rectangular cross section, and concrete may be poured into the filled steel pipe column.

The pillar member 100 may be integrally installed through a plurality of wide beams 200 installed on a plurality of layers.

For example, the column member 100 may be formed of a filled steel pipe column of about 12 m, and may be integrally installed through three wide beams 200 formed on three layers.

The column member 100 may be provided as a rectangular filled steel pipe column in which the length of the lengthwise side of the wide beam 200 is relatively longer than the length of the widthwise side of the wide beam 200.

This requires securing a cross section of a size set in order for the column member 100 to have structural performance for supporting a load.

Therefore, it is to configure the wide beam 200 to surround the pillar member 100 if the width of the wide beam 200 is not excessively secured while securing a cross section (cross-sectional size) required for the structural performance of the pillar member 100 .

The column member 100 has a length of a side in the first direction D1 extending in the longitudinal direction of the wide beam 200 is 1.2 to 2 of the length of a side in the second direction D2 extending in the width direction of the wide beam 200 It may be provided as a rectangular filled steel pipe column provided in the range of a ship.

More preferably, in the column member 100, the length of the side in the first direction (D1) of the wide beam 200 is provided in a range of 1.5 to 2 times the length of the side in the second direction (D2) of the wide beam 200 It may be provided as a rectangular filled steel pipe column.

As an example, referring to FIGS. 3 to 5, the column member 100 includes a first unit member 110 with one side open, and a predetermined gap with an open side of the first unit member 110. A second unit member 130 disposed to face each other and a pair of the second unit members 130 are respectively fastened to connect both ends of the first unit member 110 and the second unit member 130 to form a closed cross-section. have.

In this case, the reinforcing member 150 may protrude to the inside of the closed cross-section while being welded to the inner surfaces of the first unit member 110 and the second unit member 130, respectively.

The wide beam 200 may be connected in a direction crossing the column member 100 and may be installed to surround the cross section of the column member 100.

The wide beam 200 may have a width that is relatively larger than the length of the side of the second direction D2, which is a lateral direction of the column member 100.

3 to 5, the wide beam 200 may be installed in a direction crossing the column member 100, and may be attached to the column member 100 while being installed to surround the cross-section of the column member 100. .

That is, the wide beam 200 may be configured to have a larger width than the column member 100 so as to surround the cross section of the column member 100.

For example, the column member 100 may be composed of a filled steel pipe column filled with concrete therein, and the wide beam 200 may be composed of a reinforced concrete beam installed to surround the joint portion of the filled steel pipe column.

Figure 5 does not show the assembly reinforcement member 210 of the wide beam 200 in order to more clearly show the coupling relationship between the column member 100 and the shear stiffener 300, in Figure 6 the wide beam 200 The assembly reinforcement member 210 and the concrete member 230 are shown.

5 and 6, the wide beam 200 is formed extending in the longitudinal direction, the shear stiffener 300 is an assembly reinforcement member 210 disposed therein, and the assembly reinforcement member 210 And, the shear stiffener 300 may be provided with a concrete member 230 is embedded.

The assembly reinforcement member 210 may include a plurality of main reinforcing bars 211 extending in the longitudinal direction of the wide beam 200 and a stirrup muscle 213 surrounding the plurality of main reinforcing bars 211.

In this case, the shear stiffener 300 may be disposed in an inner region of the assembly reinforcing bar member 210 formed of a plurality of main reinforcing bars 211 and stirrup bars 213.

The concrete member 230 extends in the longitudinal direction and may be installed to surround the assembly reinforcing member 210 and the shear stiffener 300.

The wide beam 200 includes a first width direction region corresponding to a cross section of the pillar member 100 in the width direction, and a second width direction deviating from the cross section of the pillar member 100 on both sides of the first width direction region. A region is formed, and the shear stiffener 300 is disposed in the second width direction region, and may be disposed in an inner region of the reinforcing reinforcing member 210 of the wide beam 200.

The wide beam 200 may be divided into a first width direction region and a second width direction region in the width direction.

The first widthwise region is a region corresponding to the cross section of the column member 100 in the width direction of the wide beam 200, and the second widthwise region is a region outside the first widthwise region.

The shear stiffener 300 is installed at the joint portion between the column member 100 and the wide beam 200, and is buried in the concrete member 230 of the wide beam 200 to increase the shear strength of the joint portion. .

The shear stiffener 300 and the column member 100 may have at least a joint portion made of a metal material such as steel, and the shear stiffener 300 and the column member 100 may be welded together.

3 to 5, the shear stiffener 300 extends in the first direction D1, which is the front and rear direction of the column member 100, in a state attached to the side surface of the column member 100, and the column member ( 100) may be extended to a region outside the cross-section.

That is, the shear stiffener 300 is formed extending in the longitudinal direction of the wide beam 200 in a state of being bonded to both sides of the column member 100, and deviating from the cross section of the column member 100 in the first direction (D1). It can protrude to the area.

For example, the shear stiffener 300 may be disposed to cross vertically with the column member 100 in the longitudinal direction and may be embedded in the wide beam 200.

3 to 5, the joint structure of the column member and the wide beam is formed by bonding in the front and rear direction of the cross section of the column member 100, extending in the longitudinal direction of the wide beam 200, and the shear stiffener 300 It may further include shear studs (T) arranged in parallel.

5 and 6, the shear stiffener 300 is disposed in a second direction D2, which is a lateral direction of the column member 100, in an area outside the cross-section of the column member 100, and the In the first direction D1, which is the front-rear direction of the column member 100, it may be disposed to a region outside the cross-section of the column member 100 including a region corresponding to the cross-section of the column member 100.

The angle member 310 constituting the shear stiffener 300 is in a first direction (D1) corresponding to the longitudinal direction of the wide beam 200 and a second direction (D2) corresponding to the width direction of the wide beam 200 By extending the structure, it is possible to improve the workability of the joint portion of the column member 100 and the wide beam 200, and at the same time, the shear reinforcement in the two directions intersecting at the joint portion can be stably improved, thereby improving structural stability. It works.

For example, the shear stiffener 300 is a single member, by attaching the angle member 310 to the side of the column member 100, the shear stiffener 300 is a joint portion of the column member 100 and the wide beam 200 At the same time, while extending in the first direction D1, which is the front and rear direction of the column member 100, while extending in the second direction D2, which is the side direction of the column member 100, the column member 100 and the wide beam 200 There is an effect of stably reinforcing the shear stress generated at the joint of

Referring to FIG. 5, as an example, the shear stiffener 300 is provided with an angle member 310 having a cross section of a bent shape, and the angle member 310 is in the first direction D1 and the column member 100 , May be formed to protrude in the second direction D2, respectively.

The angle member 310 is joined from the side surface of the column member 100, and the bent cross section protrudes in the first direction D1 and the second direction D2, and is disposed in an area outside the cross-section of the column member 100 Can be.

The shear stiffener 300 has a length protruding from the column member 100 in the first direction D1, which is the front and rear direction, 0.4 to 1.2 times (0.4h to 1.2h) of the height h of the wide beam 200 ), and the length protruding from the column member 100 in the second direction D2 in the lateral direction is 5 times the thickness t of the angle member 310 constituting the shear stiffener 300 It can be set in the range of ~ 40 times (5t ~ 40t).

First, the shear stiffener 300 has a length protruding from the column member 100 in the first direction D1, which is the front and rear direction, 0.4 times to 1.2 times the height h of the wide beam 200 (0.4h to 1.2 h) can be set.

That is, the length of the shear stiffener 300 protruding in the first direction (D1) so as to deviate from the cross section of the column member 100 from the front and rear surfaces of the column member 100 is equal to the height (h) of the wide beam 200 It can be set in the range of 0.4 times to 1.2 times (0.4h to 1.2h).

Table 1 shows the length of the shear stiffener 300 protruding from the column member 100 in the first direction D1 in the front-rear direction in the finite element analysis of the joint structure of the present invention shown in FIGS. 10A to 10D. The total yield strength and the yield strength increase rate were indicated. (At this time, the height h of the wide beam 200 in the finite element analysis of the joint structure of the present invention was set to 500 mm.)

The protruding length of the shear stiffener 300 in the first direction (D1) (unit: mm) Load at yield
(Total strength, unit: KN) Load increase
(Proof growth rate) Standard history 204 1.00 Example 1 200 213 1.04 Example 2 400 223 1.09 Example 3 600 232 1.14 Example 4 800 232 1.14

Referring to Table 1, it can be seen that when the shear stiffener 300 has a protruding length in the first direction D1, the load performance is improved while the overall strength of the joint structure between the column member and the wide beam increases.

The set reference strength required in the joint structure of the column member and the wide beam is 204 KN, and the protrusion length of the shear stiffener 300 in the first direction (D1) must be at least 200 mm (0.4h) or more.

When the protrusion length of the shear stiffener 300 in the first direction (D1) is at least 200 mm (0.4h), the total proof strength is 213 KN, and the proof strength increase rate is 1.04, which is 4% higher than the standard proof strength 1.00. have.

However, it can be seen that the protrusion length of the shear stiffener 300 in the first direction D1 is not less than 600 mm (1.2h) to improve the overall strength.

Referring to the results of Example 3 and Example 4 in Table 1, the total strength when the protrusion length of the shear stiffener 300 in the first direction (D1) is 600 mm (1.2h), 800 mm (more than 1.2h) It can be seen that is the same as 232 KN, and the strength increase rate is also the same as 1.14.

That is, even if the protrusion length in the first direction (D1) of the shear stiffener 300 exceeds 600 mm (1.2h), it can be seen that the proof strength increase rate remains at 1.14 and does not increase by more than 14% compared to the reference proof strength 1.00. .

Therefore, it may be more preferable in terms of increased proof strength and construction cost that the protrusion length of the shear stiffener 300 in the first direction D1 is limited to within 600 mm (1.2h).

10A to 10D, results of finite element analysis of the joint structure of the column member and the wide beam of the present invention according to the protruding length of the shear stiffener 300 in the first direction D1 are shown.

Next, the length of the shear stiffener 300 protruding from the column member 100 in the second direction D2 in the lateral direction is 5 times the thickness t of the angle member 310 constituting the shear stiffener 300 It can be set in the range of ~ 40 times (5t ~ 40t).

As an example, when the thickness of the angle member 310 constituting the shear stiffener 300 is 6 mm, the length of the shear stiffener 300 protrudes from the column member 100 in the second direction D2 in the lateral direction is 30 It can be set in the range of ~ 240 mm.

This is, when the shear stiffener 300 protrudes to less than 30 mm, the effect of shear reinforcement in the second direction (D2) decreases, and when it exceeds 240 mm, the assembly reinforcing member 210 constituting the wide beam 200 This is because there is a risk that the width of the wide beam 200 may be excessively increased due to the shear stiffener 300 disposed inside the).

Next, the thickness of the angle member 310 constituting the shear stiffener 300 may be set to 6 mm or more.

This is to secure a minimum thickness for the angle member 310 to preferably resist shear load acting in the third direction D3, which is the height direction of the column member 100.

More preferably, the thickness of the angle member 310 may be composed of a steel material set in the range of 6 ~ 15 mm.

The shear stiffener 300 includes a cross section of a bent shape, protrudes in the first direction D1 and the second direction D2, respectively, and includes angle members 310 that are bonded to both sides of the column member 100, respectively. Can be configured.

For example, when the height (h) of the wide beam 200 is 500 mm, and the thickness of the angle member 310 constituting the shear stiffener 300 is 6 mm, the angle member 310 constituting the shear stiffener 300 ) Is, the length protruding from the pillar member 100 in the first direction D1 in the front and rear direction is 200 to 200, which is 0.4 to 1.2 times (0.4h to 1.2h) of the height h of the wide beam 200 It is set in the range of 600 mm, and the length protruding from the column member 100 in the second direction D2 in the lateral direction is 5 of the thickness t of the angle member 310 constituting the shear stiffener 300 It can be set to 30 to 240 mm, which is a range of times to 40 times (5t to 40t).

5 and 6, the shear stiffener 300 includes an angle member 310 extending in the first direction D1, including a cross-section of a bent shape, and the angle member ( Reference numeral 310 may be disposed in a region outside the cross-section of the column member 100 in a second direction D2 that is a lateral direction of the column member 100.

3 and 5, the angle member 310 is arranged so that two angle members 311 having a'b' shape are spaced apart in a third direction D3 which is the height direction of the column member 100 And, the angle member 310 may be disposed to be opposed to form a pair with the column member 100 interposed therebetween.

The'b'-shaped angle member 311 may include a bonding flange bonded to the outer surface of the column member 100 and a support flange extending outward from the column member 100 from the bonding flange.

The shear stiffener 300 may further include a truss angle 313 or a connection reinforcement (not shown) connecting the two angle members 311 of the'b' shape.

Referring to FIG. 7, the shear stiffener 300 may include a truss angle 313 connecting between two angle members 311 having a'b' shape.

Here, the truss angle 313 may be composed of a truss plate attached to the upper angle member 311 and the lower angle member 311, and a bending member integrally connecting the two truss plates.

Although not shown, the shear stiffener 300 may include a plurality of connection reinforcing bars (not shown) integrally connecting the two angle members 311 of the'b' shape.

A truss angle 313 or a connecting reinforcement (not shown) is connected between the two angle members 311 of a'b' shape, so that the angle member 310 may be integrally installed on one side of the column.

Referring to FIG. 4, the shear stiffener 300 may be disposed so that the angle member 310 having a'C'-shaped cross-section forms a pair with the column member 100 interposed therebetween.

A'C'-shaped angle member 311 may be installed to cross the column member 100, and the opening portion of the angle member 311 may be disposed toward the outside of the column member 100.

4 to 6, the joint structure of the column member and the wide beam is attached to the upper and lower ends of the angle member 310, respectively, the attachment reinforcing bar 400 extending in the longitudinal direction of the angle member 310 ) May be further included.

The attachment reinforcement 400 is joined to the upper and lower ends of the angle member 310 and protruded in the longitudinal direction of the column member 100, so that the concrete member 230 of the wide beam 200 and the angle member 310 are attached. It can improve performance.

Referring to Figure 8, the joint structure of the column member and the wide beam is attached to the upper and lower ends of the angle member 310, respectively, and spaced apart in the longitudinal direction of the angle member 310, a plurality of attachment studs 500 are installed. ) May be further included.

Next, with reference to the drawings will be described in detail with respect to the floor structure.

2 to 10D, the floor structure according to an embodiment of the present invention may include a joint structure of a column member and a wide beam, and a floor slab 600.

9, the floor structure is a joint structure of the plurality of column members and the wide beam, and a floor slab installed on the upper side of the wide beam 200 and integrally with the column member 100 to form a bottom plate. It may include 600.

Referring to FIG. 2, a plurality of pieces may be spaced apart from each other under the floor slab 600, and may be installed so as to extend only in the first direction D1 that is the front and rear direction of the column member 100.

At this time, the plurality of wide beams 200 may support the floor slab 600 installed on the upper side while being spaced apart and arranged in parallel in a second direction D2, which is a side direction of the column member 100. .

A plurality of pillar members 100 may be spaced apart and installed along the longitudinal direction of the wide beam 200.

In this case, the column member 100 may be integrated with the shear stiffener 300 through the wide beam 200 in a state penetrating through the wide beam 200.

That is, in the case of the present invention, a separate beam member installed to cross the wide beam 200 for supporting the floor slab 600 is excluded.

The floor structure is installed so that the wide beams 200 extend only in the first direction D1, and a plurality of wide beams 200 are disposed at intervals set in the second direction D2, while the floor slab 600 Can support.

In the present invention, a plurality of wide beams 200 are installed to extend only in the first direction D1 in the floor structure, and the amount of construction can be reduced by excluding small beams extending in the second direction D2. .

In addition, by configuring the component supporting the floor slab 600 in the floor structure with a wide beam 200 having a width wider than that of the column member 100, the floor height of the floor structure can be reduced, thereby reducing the amount of construction work. It has the effect of shortening the construction period and reducing the construction cost by reducing the floor height.

In the case of constructing the joints for each floor, subsequent processes can be performed after the construction is completed for each floor, and the overall construction period is affected by the speed of construction for each floor.

In the present invention, a single column member 100 may be installed over a plurality of layers.

That is, the column member 100 may be integrally installed through the wide beam 200 installed on a plurality of layers.

According to the present invention, by installing the column member 100 over a plurality of layers, the column member 100 may be introduced early to a subsequent process, thereby improving workability.

For example, the column member 100 may be formed of a filled steel pipe column of about 12 to 15 m, and may be integrally installed through the wide beam 200 formed in 3 to 4 layers.

Referring to FIG. 9, the column member 100 is connected to the interlayer column member 100-2 disposed between adjacent floors, and the top of the column member 100 is connected to the floor slab 600 while passing through the wide beam 200. It may be provided as a connection pillar member 100-1 to be buried.

The connecting column member 100-1 is formed to protrude in a circumferential direction from an end portion of the protruding column body and a column body through which both ends protrude through the wide beam 200, and the interlayer column member 100-2 It may be provided with a connection plate 170 forming a junction with.

The interlayer column member 100-2 is a component connected between the adjacent connection column members 100-1 and disposed between the adjacent floor slabs 600.

A connection plate 170 may be formed at a connection portion between the connection column member 100-1 and the interlayer column member 100-2.

For example, in a state in which the connection plate 170 of the connection column member 100-1 and the interlayer column member 100-2 are disposed in contact with each other, it may be fastened by a bolt and a nut.

Referring to FIG. 9, the connection plate 170 installed on the upper end of the connection column member 100-1 may be embedded in the floor slab 600 of the upper layer, and the connection installed at the bottom of the connection column member 100-1 The plate 170 may be disposed in the ceiling space 700 of the lower layer.

Accordingly, the connection plate 170, which is a connection part between the connection column member 100-1 and the interlayer column member 100-2, is disposed inside the floor slab 600 and in the ceiling space 700 to the outside of the indoor space. There is an effect that may not be exposed.

And, the connection plate 170 installed on the upper end of the connection column member (100-1) is buried in the floor slab 600 and hardened, so that the connection plate 170 is the length of the column member 100 in the floor slab 600 By transferring the load acting in the direction to the floor slab 600, there is an effect of securing a more robust structural performance.

As an example, the connecting pillar member 100-1 can be transported to the site while being embedded in the concrete member 230 of the hardened wide beam 200, and the connecting pillar member integrally connected with the wide beam 200 As (100-1) is connected to the interlayer column member (100-2), workability may be improved.

In a state in which a plurality of connection pillar members 100-1 are installed in the wide beam 200, each connection pillar member 100-1 is a state in which the connection plate 170 of the interlayer pillar member 100-2 is fastened As the floor slab 600 is poured on the upper side of the wide beam 200, the upper connection plate is buried in the floor slab 600, and the lower connection plate 170 may be disposed in the ceiling space 700.

In addition, it goes without saying that various embodiments of a joint structure of a column member and a wide beam having various embodiments described above may be applied to the floor structure of the present invention.

Therefore, the configuration of the column member 100, the wide beam 200, and the shear stiffener 300 of the joint structure of the column member and the wide beam used in the floor structure, as already described, the configuration of the joint structure of the column member and the wide beam A detailed description of the same bar is omitted to avoid redundancy.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and variations are possible without departing from the technical spirit of the present invention described in the claims. It will be obvious to those of ordinary skill in the field.

10: pillar 20: girder
30: beam member 100: column member
100-1: connecting column member 100-2: interlayer column member
110: first unit member 130: second unit member
150: reinforcing member 170: connection plate
200: wide beam 210: assembly reinforcement member
211: main reinforcement 213: stirrup
230: concrete member 300: shear stiffener
310: angle member 311: angle member
313: truss angle 400: attachment reinforcement
500: attachment stud 600: floor slab
700: ceiling space
D1: first direction, front and rear direction of the column member
D2: second direction, lateral direction of the column member
D3: the third direction, the height direction of the column member
T: Shear stud

Claims (13)

Pillar member;
A wide beam connected in a direction crossing the column member and installed to surround the cross section of the column member; And,
Including; a shear stiffener which is provided to form a pair and is bonded to both side surfaces of the column member, extends in a first direction, which is the front and rear direction of the column member, and is embedded in the concrete member of the wide beam,
The shear stiffener,
It includes a cross section of a bent shape and is provided as an angle member extending in the first direction,
The angle member,
It is disposed in a region outside the cross section of the column member in a second direction, which is a lateral direction of the column member,
The angle member,
Two angle members of the'b' shape are arranged spaced apart in the third direction, which is the height direction of the column member,
The angle member is disposed opposite to form a pair with the column member interposed therebetween,
The shear stiffener,
The joint structure of a column member and a wide beam further comprising a truss angle or a connecting reinforcement connecting the two angle members of the'b' shape.
The method of claim 1, wherein the wide beam,
An assembly reinforcing member extending in the longitudinal direction and in which the shear stiffener is disposed therein; And,
The assembly reinforcement member and the concrete member in which the shear stiffener is embedded; the joint structure of the column member and the wide beam having a.
The method of claim 1, wherein the shear stiffener,
In a second direction that is a lateral direction of the column member, it is disposed in an area outside the cross-section of the column member,
The joint structure of the column member and the wide beam, characterized in that arranged in a first direction that is the front and rear direction of the column member, including a region corresponding to the cross section of the column member and to a region outside the cross section of the column member.
The method of claim 3, wherein the shear stiffener,
The length protruding from the pillar member in the front and rear direction in the first direction is set in a range of 0.4 to 1.2 times the height of the wide beam,
The joint structure of the column member and the wide beam, characterized in that the length protruding from the column member in the second direction in the lateral direction is set in a range of 5 to 40 times the thickness of the angle member constituting the shear stiffener.

delete delete delete delete The method of claim 1,
Bonding structure of the column member and the wide beam further comprising; an attachment reinforcing rod that is joined to the upper and lower ends of the angle member and extends in the longitudinal direction of the angle member.
The method of claim 1,
Bonding structure of the column member and the wide beam further comprising a; attachment studs are attached to the upper and lower ends of the angle member, respectively, and spaced apart in the longitudinal direction of the angle member to be installed.
A joint structure of a plurality of column members and wide beams according to any one of claims 1 to 4; And,
Floor structure comprising a; a floor slab installed on the upper side of the wide beam and integrated with the column member to form a floor plate.
The method of claim 11, wherein the wide beam,
A floor structure that is installed to be spaced apart from the bottom of the floor slab, and is installed to extend only in a first direction, which is a front-rear direction of the column member.
The method of claim 11, wherein the column member,
A floor structure connected to an interlayer column member disposed between adjacent floors, and provided with a connecting column member having an upper end embedded in the floor slab while penetrating the wide beam.

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