KR101406938B1 - The composite girder with various pattern as web members - Google Patents

Abstract

The present invention relates to the development of composite girders made of abrasive material of steel, under-concrete concrete and concrete upper deck. Conventional composite truss girders with concrete bottoms have problems such as the occurrence of large localized forces in the critical section due to the use of steel failure points, and the problems associated with the installation of midpoint partition walls.
In the present invention, instead of the conventional triangular truss structure, various types of patterns capable of transmitting a strong force between the members are used for the abdomen material and the structure type of the residential structure is converted from the truss structure to the beam structure according to the main construction steps And to develop composite girder bridges. To this end, the composite girder of the present invention comprises a skeleton frame made of a steel material having a structure similar to a truss, a concrete abdomen material filling a part of the abdomen space of the skeleton frame, And a concrete bottom plate coupled with the phase current of the skeleton frame.
The composite girder according to the present invention can advantageously utilize the advantages of the truss structure and the beam structure and the advantages of the steel and concrete depending on the construction conditions and construction steps.

Description

The composite girder with various shapes of abdomen material is known as a composite girder with various patterns as web members.

The present invention relates to a composite girder structure which is manufactured by first manufacturing a skeleton frame made of a steel material, transporting the skeleton frame to a site of construction, and then integrating the concrete structure with a concrete member and a shear connection member on a manufacturing site or pier, Or each tube is subjected to bending using high-frequency heating to produce a unit member having a predetermined shape, and then these unit members are coupled to each other through a connecting plate to form an abdominal member having various shapes of patterns, And the directional beam members are coupled to each other to form a skeletal frame of a steel material. Then, a longitudinal beam member attached to the lower part of the skeletal frame is coupled with a concrete member having a predetermined shape, and a part of the hollow belly member is filled with concrete, And then attaching to the upper part of the skeletal framework a longitudinal direction Relates to the development of a composite girder as the main characterized in that the coupling member and the concrete and the upper bottom plate.

Conventional residential houses have a truss structure with abdominal wall clogged or triangular shaped open space. The biggest difference between the two types of structures is that a residential house with a redundant structure resists the vertical external force through the shear force of the abdominal material and the residential house with the truss structure resists through the axial force of the material.

It is preferable to use different thicknesses or different heights of the abdomen material in accordance with the change in the magnitude of the shearing force in view of the use of materials. A countermeasure for varying the thickness of the abdomen material according to the magnitude of the shear force may be appropriately used when the abdomen material is a steel plate. However, since a steel plate having a certain thickness or more is required for preventing shear buckling, There is a problem that the thickness is not determined.

In addition, when the abdomen is made of concrete, the thickness of the abdomen material is determined based on the place where the shear force is maximized. As a result, there is always room for the abdominal material resistance against shear force, ≪ / RTI >

In order to prevent the increase of the weight of the girder due to the surplus use of the abdomen material, it is effective to reduce the height of the residence, but the problem is that the height of the residence is not determined by the shear force, but the size of the bending moment and deflection And so on. The most effective way to increase the resistance of the residence to bending moment and deflection is to increase the height of the residence. However, if the height of the residence is increased, the surplus of the resisting capacity against the shear force increases more and the unnecessary increase in self- Resulting in an increase in the bending moment due to the bending moment.

In addition, the continuous beam structure increases the shear force and increases the magnitude of the bending moment. Therefore, it is possible to partially apply the method corresponding to the shear force change by changing the height of the residence girder. However, in the simple beam structure, the shear force and bending moment Since the changes show a tendency to be inconsistent with or opposite to each other, it is not possible to reduce the height of the residence by decreasing the shear force.

On the other hand, when the abdomen has a truss structure, since the vertical load inducing the shear force is transmitted to the axial force of the work, the cross-sectional design of each work can be changed according to the shear force. Therefore, The problem can be solved fundamentally. One of the most effective ways to reduce the weight of a house is to use a steel material with excellent material efficiency for the abdomen while using a truss structure type with excellent structural efficiency. The truss structure type differs in appearance and name depending on the arrangement of the abdomen material. The best type of double structure and material efficiency is a warren truss structure in which the materials subjected to compressive and tensile forces are alternately arranged.

And warren truss structure are used for a composite truss girder that uses concrete for truss-less current because it transfers the vertical load applied to the structure to the point through the shortest path and is excellent in resistance to external lateral loads such as prestressing force have. That is, the axial force acting on the adjacent workpiece is converted from the compressive force to the tensile force at the lower junction where it meets the concrete bottom current. In this process, the horizontal force is transferred to the concrete bottom current. In this case, when the center axis of the adjacent workpiece and the center axis of the under-concrete current do not coincide at one point, a large shear force and eccentric moment act at the point interval. In order to securely withstand these forces, And the use of PS steel for the introduction of the preceding compressive force is necessary.

As mentioned earlier, beam-type residential houses are constructed in most cases so that the abdominal portion, which resists the shear force, has greater resistance than the vertical force actually acting, which results in an increase in the weight of the girder that is not needed . As the span length becomes longer, the specific gravity of the section force due to the weight of the girder becomes larger. Therefore, in order to achieve more efficient structural behavior and reduction of the construction cost, a method of reducing the weight of the girder by optimizing the shape of the abdomen is needed.

On the other hand, the use of a truss structure on the abdomen makes it very effective to reduce its own weight, but special attention is paid to design and construction due to the following specific characteristics of the truss structure type. In a triangular truss structure combining straight members, sudden force changes direction between members connected to each other at every point interval. The closer to the point, the larger the axial force acting on the workpiece and the larger the local shear force applied to the point. However, at the point of the outermost span of the simple support structure or the continuous support structure, the workpiece axial force increases, but the axial force due to the bending moment generated at the present moment decreases sharply as it approaches the point. That is, the thickness of the current steel sheet in this section is thin, while the problem of the thickness difference between the severe members, in which the steel sheet thickness of the steel sheet is to be thickened, is problematic and prevents smooth transfer of force and local current shear deformation In addition, the use of additional jumbo steel plates becomes inevitable.

In addition, the truss structure intersects the forces having different directions of action at the points where the upper and lower currents, which resist the axial force and resist the bending moment, contact each other. Careful attention must be paid to the design so that it can match at one point. In the conventional steel truss structure, a very large gusset plate is additionally attached at a point interval so that the force of the truss members connected to each other at one point in the point of view.

However, in the case of composite truss girder bridges using steel pipes in the abdominal material and concrete under load, there are various problems in using exposed large set plates, maintenance problems due to corrosion of concrete and steel contact surfaces, , The steel ball point structure embedded in concrete is mainly used due to problems such as austenite hindrance due to a low girder height. In this case, the axial force acting on the adjacent work is directly or indirectly transmitted through the concrete current . In this process, the vertical component of the axial force acting on the workpiece and the bending moment of the local workpiece due to the steeping treatment are generated at the point of intersection. Due to these forces, special design care is required to prevent harmful cracks in the concrete under- .

On the other hand, as the span length becomes longer, the absolute magnitude of the axial force acting on the spindle depends on the position, and accordingly, the specifications of the spindle and the point to be used must be diversified. However, in order to meet the design and manufacturing simplification, the use of too many kinds of workpieces and points is avoided, which often results in the use of more steel than is necessary in the calculation.

In order to solve the problem of unnecessarily increasing the amount of steel used due to the remarkable difference in sectional force between the members constituting the truss, there is a method of applying the double and the rent structure in which the rent and rent are overlapped with each other at the counterpoint of the truss. It is not used very well except in very special cases due to problems such as the processing of the intersection of intersections, the processing of the points in the intermediate piers, and the deterioration of the visibility. Do not.

In addition, one of the problems that arise when a composite truss girder with a concrete bottom is applied to a continuous structure is a phenomenon that a very large bending moment is generated in the concrete bottom due to the local bending strain restraint at the intermediate point portion. Unlike the ideal truss behavior in which all the members constituting the truss are joined to each other in a pin structure at a point, the bottom of the concrete at the point of intersection is a phenomenon caused by being joined to a continuous beam member having a bending stiffness.

In order to solve the above problem, unlike the conventional steel truss bridge, a concrete bulkhead having a very high stiffness at each intermediate point is additionally installed from a single point to a truss point of a truss in a composite truss girder bridge, However, problems such as an increase in the cost due to the provision of the bulkhead, an increase in the capacity of the used support due to an increase in its own weight, and an increase in the specification of the lower supporting structure are separately accompanied.

As described above, since the conventional composite truss girder having a concrete bottom current exhibits the structural behavior of the truss in the entire force flow, the original purpose of reducing the weight can be achieved, And the problem of the installation of mid-point bulkheads, etc., which are caused by the use of steel stippling points. Have

In order to solve the problems of the above-described composite truss girder, various shapes of patterns capable of transmitting a strong force between members are used for the abdomen material instead of the conventional triangular truss structure, Is to develop composite girder bridges that convert the structural form of a girder bridge from a truss structure to a beam structure.

In order to achieve the above object, the composite girder of the present invention includes a skeletal frame made of a steel material having a structure similar to a truss, a concrete material completely surrounding the lower steel material of the skeleton framework, An abdominal material, and a concrete bottom plate coupled with the phase current of the skeletal framework.

At this time, as a skeletal frame made of a steel material, a member having a circular or semicircular shape is used for the abdomen material instead of a conventional truss structure in which a pair of straight lines meet alternately at a predetermined inclination angle at an upper or lower side The vertical force applied to the abdominal material forms a load path that is directly transmitted to the adjacent abdominal material without passing through the upper and lower abdomen. At the position where the abdominal abdominal abdomen current or lower abdomen meets, So that the axial force directions are parallel or orthogonal to each other so that the force is transferred between the members by the direct shear in which the force is transmitted at the shortest distance.

The vertical force can be transmitted through the direct coupling between the abdominal material through the use of a member having a heart shape in the abdomen material of the skeleton frame made of steel, By arranging them side by side, it is possible to direct the force between the abdominal member and the bottom current to the shear, and the intersection angle between the members to be about 70 degrees, so that the point scale is greatly reduced compared to the conventional truss structure. In addition, since the length of the portion in which the axial member of the straight line is formed is greatly shortened, the resistance to buckling when receiving the compressive force is greatly improved, and the effect of increasing the inclination angle of the workpiece is obtained while maintaining the same interval. The specification is reduced. Here. By superimposing the abdomen material and phase current over the entire range of the point of contact, a portion of the vertical force can be transmitted through the shear resistance of the top piece and the abdomen.

Further, when rhombic members are continuously arranged as the abdomen material of the skeleton framework, it is possible to secure the same structural behavior as that for dispersing the axial force acting on the abdomen material, such as the conventional double and leotrus. In addition, the vertical force generated in the abdominal material is transmitted through the direct shear between the abdominal members without going through the upper and lower currents. The horizontal force generated by the directional change of the axial force acting on the abdominal member is also directly shaped as shear, It can be delivered to the present.

Apart from reducing the size of the force acting on the point of impact by changing the shape of the abdominal material described so far, another main object of the present invention is to convert the structure type of the residential structure from the quasi truss structure to the beam structure according to the construction step The present invention relates to a method of manufacturing a lightweight composite girder which can support not only the axial resistance of the abdominal member but also the shear resistance of the abdomen member, That is, in the step of forming the residential sheath by using the skeletal frame of the steel material which is the basic skeleton of the residential sheath, a structure similar to the truss is dominant, and in the step of joining with the upper deck concrete, So that the beam shows the structural behavior of the beam.

When comparing the composite girder according to the present invention by the weight of each constituent member, the weight of the skeletal frame of the steel is 15%, that of the concrete is 30%, and that of the concrete upper deck occupies 55% The additional fixed loads such as curb and pavement and the moving loads of vehicles are about 30% of the total weight of composite girder. That is, the vertical force up to the stage where the concrete bottom current is formed is about 35% of the total size, and after that, the vertical force added to the housing up to the common stage is about 65%, and the vertical force It is possible to reduce the size of the abdomen material. As a result, it is possible to largely reduce the size of the points where the abdomen material and the upper or lower abdomen meet.

In order to achieve the above object, the composite girder according to the present invention has the same structure as that of the reinforced concrete structure having a thickness of about 150 mm, except for the space enclosed by the abdomen only, among the openings provided in the abdomen .

The main effects of the composite girder according to the present invention are as follows.

First, it is possible to simplify the point structure where the abdomen material and the current or the lower current meet with each other, thereby improving the workability and maintenance.

Second, since the absolute size of the axial force applied to the abdomen material is reduced, the standard of the abdomen material used for the construction of the long diameter can be reduced to two or three or less, so that the purchase of the product becomes easy and the production efficiency of the steel member is greatly improved .

Thirdly, it is possible to construct a synthetic girder structure which has a variety of shapes in the abdominal space and which can feel a new sensation and has excellent beauty.

Fourth, the advantages of the truss structure and beam structure, and the advantages of steel and concrete can be properly combined according to the construction conditions and the construction steps, thereby making it possible to construct a composite girder structure satisfying economical efficiency and workability at the same time.

FIG. 1 is a view showing the shape of a unit member for the manufacture of the abdomen according to the present invention
FIG. 2 is a cross-sectional view of a member used for manufacturing a unit member according to the present invention
FIG. 3 is a schematic view of the apparatus for bending the unit member according to the present invention;
FIG. 4 is a schematic view of a steel frame structure according to the present invention;
5 shows the flow of forces between members of a steel frame structure according to the invention
FIG. 6 shows an example of a steel framework which can be produced by a combination of unit elements according to the invention
7 shows a composite girder construction flowchart according to a first preferred embodiment of the present invention.
FIG. 8 is a schematic view of a composite girder construction flowchart according to a second preferred embodiment of the present invention.
FIG. 9 is a cross-sectional view showing a composite girder construction flowchart according to a third preferred embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a view showing the shape of a unit member used for manufacturing the abdomen according to the present invention. As shown in Fig. 1, the abdomen of the composite girder according to the present invention has a circular shape 1, a heart 2, an inequality 3, and a shape of a semicircle 4 bending at a predetermined radius R It is manufactured to have various patterns at regular intervals by using the unit member.

FIG. 2 shows a cross-sectional shape used in the unit member according to the present invention, which is a cross-section of a round steel pipe or a square pipe in which a change in material characteristics due to bending can be minimized.

3 shows an outline of an apparatus for manufacturing a unit member according to the present invention. As shown in Fig. 3, after a fixing clamp 5 for holding a constant radius at the beginning of the circular curve is attached, the linear member passes through the high-frequency heating device 6 in front of the fixing roller 7 And bending is performed so as to have a predetermined radius (R). In other words, bending through high-temperature high-frequency heating can be performed to minimize damage to the material properties inherent to the steel material, so that the radius of curvature can be reduced by two times or more as compared with the cold working at room temperature.

Figure 4 illustrates the shape of a steel framework that may be implemented using a unit according to the present invention. The truss structure that can be implemented using the unit member according to the present invention can be divided into four basic shapes.

First, the circular unit members 1 are connected to each other through welding of the connecting plate 10 to form a belly member, and then the upper current 8 and the lower current 9 are welded to the upper and lower portions of the belly member A skeletal framework is formed, and abdominal stiffening plates 11 are attached to both ends where the spots are located, thereby fabricating a steel skeleton structure having circular openings in the abdomen (Fig. 4 (a)).

The steel frame structure having the opening of the heart-shaped pattern on the abdomen is formed by connecting the curved portions of the heart-shaped unit member 2 to each other through welding of the connecting plate 10 to form the abdomen material, And the lower portion of the abdomen material is welded to the lower plate 9 by welding the reinforcing plate 12 and the lower plate 9 welded together to close the heart-shaped unit member 2 (Fig. 4 (b)).

The steel frame structure having the openings of the rhomboid pattern on the abdomen is formed by arranging curved portions of the inequality-shaped unit members 3 to face each other and then connecting them to each other through welding of the connecting plate 10 to form abdomen material (FIG. 4 (c)) by welding the upper current 8 and the lower current 9 to the upper and lower portions of the abdomen material, respectively.

The steel frame structure having the semicircular opening in the abdomen is formed by connecting the lower ends of the semicircular unit pieces 4 by welding to form abdomen materials, (Fig. 4 (d)).

Figure 5 shows a flow diagram of forces between members of a steel framework according to the invention. 5 (a), when the circular unit member is used for the abdomen, the vertical force due to the external load acts in the form of shear force at the position where the abdominal region meets the upper and lower currents, In the center, the direction of the force is changed by the axial force in the vertical direction, and the behavior in which the unit member rotates toward the smaller vertical force due to the difference in the vertical axial force (V1, V2) acting on the connecting point between the front and rear of the unit member In order to restrain the rotational behavior, compressive forces (C1, C2) are generated at the upper phase and tensile forces (T1, T2) are generated at the lower phase. In other words, in the conventional truss structure, all the vertical forces are transmitted only by the axial force of the straight line. However, in the skeleton structure having the circular abdominal structure according to the present invention, the structure resistant to the vertical force .

As shown in Fig. 5 (b), when the heart-shaped unit member is used for the abdomen member, truss structures of the respective triangles are formed on the upper and lower sides with reference to the connection point between the unit members, The vertical forces (V1, V2) applied to the connecting points are divided into two truss structures located at the upper and lower sides. The vertical force components transmitted to the upper truss cause compressive forces (C1, C2) Tensile forces (T1, T2) are generated at the bottom by the force components. In the conventional truss structure, the axial force acting on the workpiece is always kept constant in size and direction over the entire length of the member, and since the magnitude and direction of the force are changed only in the interval of the point of contact with the present, In the skeleton structure having the heart-shaped abdomen structure according to the present invention, the magnitude and direction of the force acting on one abdomen can be changed differently depending on the position of the member, Thereby reducing the absolute magnitude of the vertical force acting on the stator. In addition, by making the connection point of the abdomen material with vertical force concentrated between the upper and lower currents, a part of the vertical force can be shared through the shear resistance between the upper and lower currents.

As shown in Fig. 5 (c), when a lozenge-shaped abdominal member is constructed by using an inequality-shaped unit member, two triangular truss structures having the same specifications as the upper and lower sides of the abdomen are used As a result, the vertical forces (V1, V2) applied to the unit member connecting points are equally distributed to the upper and lower two truss structures. Due to the vertical force component transmitted to the upper truss, ) And tensile forces (T1, T2) are generated at the bottom due to the vertical force components shearing at the lower truss. That is, the skeleton structure having the lozenge-shaped abdominal structure according to the present invention exhibits the same structural behavior as the conventional double-and-rent structure.

On the other hand, as shown in Fig. 5 (d), in the case of a semicircular abdominal member, the vertical load acting on the upper current acts as a concentrated load at the position where the upper abdomen meets the upper abdomen, (T1, T2), and the vertical reaction force is directly applied to the abdomen through the shear between the abdomen material and the abdomen material. . On the other hand, the vertical load acting on the bottom current is transmitted to the point through the bending resistance of the bottom current which acts as a continuous beam structure with the end of the semicircular abdomen material as the point, and the vertical force transmitted to the point is transmitted through the arch action of the abdomen, (V1, V2), which is caused by the arch action of the abdomen, is transmitted to the apex of the abdomen, which is transformed into a horizontal force and a shear force at the vertex of the semicircle, It is delivered to the end of the contralateral abdomen.

FIG. 6 shows the shape of a steel frame structure having a pattern of abdomen made by combining two or more unit members of the same or different shapes according to the present invention.

First, as shown in Fig. 6 (a), a circular unit member 1 is formed by using a unit member 3 having an inner angle perpendicular to the abdomen member connected to each other via the connecting plate 10, The unit member 1 is further connected through the upper current 8 and the lower current 9 so that the magnitude of the shear force and the moment generated in the circular abdomen 1 is greatly reduced, The effect of dispersing the vertical load acting on the present can be obtained.

As another means for reducing the shearing force and moment generated in the circular unit member 1, a pair of inequality-like unit members 3 having a rectangular internal angle is welded to the inside of the circular unit member 1, So that it is shaped like a wheel of an automobile (Fig. 6 (b)).

6 (c), the pair of heart-shaped unit members 2 are made to face each other with respect to the horizontal line, and then the connecting plate 10 is welded to have the abdomen having the butterfly pattern You can make a steel frame structure.

On the other hand, a steel frame structure having a semicircular abdominal material has an advantage that an opening of the widest area can be secured compared to a abdominal material having a different pattern when the abdomen height is the same. On the contrary, There is a disadvantage that the magnitude of the moment becomes remarkably larger than that of the other types. 6 (d), two inequality-shaped unit members 3 having different sizes are added to the inside and the outside of the semicircular member 4, The shear force and the bending moment magnitude occurring in the semicircular member can be significantly reduced and the bending moments occurring in the upper and lower currents are greatly reduced.

FIG. 7 shows a composite girder construction procedure according to a first preferred embodiment of the present invention. The composite girder according to the present invention can be manufactured using only the steel frame structure composed of the abdomen material only when the construction load including the self weight before the formation of the girder is applied by a separate support facility. First, as shown in Fig. 7 (a), the abdomen material 4 having the shear connection member 13 is connected to the concrete through the connecting plate 10, and then, as shown in Fig. 7 (b) The abdominal material 4 is joined with the concrete bottom 14 and the concrete top deck 15 and the space between the concrete top deck 15 and the abdomen 4 is filled with the abdominal concrete 16, A composite girder is constructed to perform the structural behavior of beams. At this time, the concrete compressive force (P) is introduced by using the high strength PS steel (17) embedded in the concrete, where the tensile stress occurs due to the external load.

FIG. 8 shows a composite girder construction procedure according to a second preferred embodiment of the present invention. The composite girder according to the present invention can be manufactured using only the steel frame structure composed of the abdomen material and the phase current only when the pre-composite girder has a temporary condition capable of collective mounting by a crane. First, as shown in Fig. 8 (a), connecting plates 10 and 12 are welded to a unit member 2 having a predetermined shape to form abdomen material, and a shear connection member 13) and the abdomen material are welded together to produce a steel frame structure. Next, as shown in FIG. 8 (b), a concrete bottom current 14 in which a preceding compressive force P is introduced by using a high strength PS steel material 17 embedded in a steel frame structure in a ground- And the abdominal concrete (16). Then, the manufactured dowel is mounted on a pier or a pillar using a crane, and a composite girder is completed by combining the dowel and a concrete upper deck 15 (Fig. 8 (c)).

FIG. 9 illustrates a composite girder construction sequence according to a third preferred embodiment of the present invention. In case the composite girder according to the present invention can not be constructed in a construction sequence as shown in FIG. 8 because of a very long span or a large crane, it is necessary to use the steel frame structure to resist the external load, And the bottom current. 9 (a), a connecting plate 10 is welded to a unit member 1 having a predetermined shape to form a stiffener, and a shear connection member 13 is formed for joining the stiffener and the concrete bottom plate. (8) and the lower end (9) of the steel material with the steel material are welded to the abdomen material to fabricate the steel material frame structure. Next, as shown in FIG. 9 (b), the steel frame structure is connected to the concrete under-floor 14 using a crane, and the high-strength PS steel 17 embedded in the concrete under- To introduce the preceding compressive force (P). Then, as shown in Fig. 9 (c), the upper current 8 of the steel frame structure and the concrete upper deck 15 are synthesized, and the abdomen material 1 of the steel frame structure, The empty space surrounded by the plate is filled with abdominal concrete (16) to complete the composite girder.

The embodiments of the present invention described above may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described above. The terms used to describe the embodiments of the present invention are used for the purpose of illustrating the present invention and are not used to limit the meaning or limit the scope of the present invention described in the claims.

1: absence of circular unit for abdominal rework
2: Heart-shaped unit member for abdominal remodeling
3: Inequality type unit member for abdominal remodeling
4: Semicircular unit member for abdominal reconstruction
5: Fixing clamp for bending of unit member
6: High-frequency heating device
7: Fixing roller
8: Phase current of steel frame structure
9: bottom current of steel frame structure
10: unit member connecting plate
11: Branch reinforcing plate
12: Unit member lower connecting plate
13: Shear connector
14: Concrete bottom current
15: Concrete upper floor plate
16: abdominal concrete
17: High strength PS steel

Claims (6)

(a) fabricating a skeleton structure of a steel material including a abdomen material formed by connecting steel materials of predetermined shapes formed separately through bending;
(b) joining the lower portion of the skeletal structure with the lower concrete force into which the preceding compressive force is introduced, and the upper portion of the skeletal structure with the concrete upper deck; And
(c) filling each of the abdominal spaces surrounded by the abdomen material of the skeletal structure, the concrete bottom current, and the skeletal abdomen material and the concrete upper deck with concrete, and finally, the structural behavior as a beam And,
Wherein the abdomen is provided with a continuous pattern formed only of unit pieces of the same shape, which are separately formed in a circular shape, a heart shape, or an inequality shape,
Wherein the skeleton structure is manufactured at a factory and then transported to a construction site. (a) fabricating a skeleton structure of a steel material including abdominal members formed by connecting steel members formed in a semicircular shape through a bending process;
(b) joining the lower portion of the skeletal structure with the lower concrete force into which the preceding compressive force is introduced, and the upper portion of the skeletal structure with the concrete upper deck; And
(c) filling the abdominal space surrounded by the abdomen material of the skeletal structure and the concrete upper deck with concrete, and finally performing the structural behavior as a beam,
Wherein the skeleton structure is manufactured at a factory and then transported to a construction site. (a) fabricating a skeleton structure of a steel material including a abdomen material formed by connecting steel materials of predetermined shapes formed separately through bending;
(b) joining the lower portion of the skeletal structure with the lower concrete force into which the preceding compressive force is introduced, and the upper portion of the skeletal structure with the concrete upper deck; And
(c) filling each of the abdominal spaces surrounded by the abdomen material of the skeletal structure, the concrete bottom current, and the skeletal abdomen material and the concrete upper deck with concrete, and finally, the structural behavior as a beam And,
Wherein the abdomen member of the steel frame structure has a continuous pattern formed by combining unit members formed separately from a circular shape, a heart shape, an inequality shape, or a semicircular shape,
Wherein the skeleton structure is manufactured at a factory and then transported to a construction site. (a) fabricating a skeleton structure of a steel material including a abdomen material formed by connecting steel materials of predetermined shapes formed separately through bending;
(b) joining the lower portion of the skeletal structure with the lower concrete force into which the preceding compressive force is introduced, and the upper portion of the skeletal structure with the concrete upper deck; And
(c) filling each of the abdominal spaces surrounded by the abdomen material of the skeletal structure, the concrete bottom current, and the skeletal abdomen material and the concrete upper deck with concrete, and finally, the structural behavior as a beam And,
Wherein the steel frame structure comprises only abdomen members formed of unit members separately formed in a circular shape, a heart shape, or an inequality shape,
Wherein the skeleton structure is manufactured at a factory and then transported to a construction site. The lower part of the skeletal structure is combined with the lower concrete of the concrete introduced with the preceding compressive force, and the lower part of the skeletal structure is joined to the upper part of the skeletal structure, The concrete is combined with the upper deck of concrete, and the concrete is filled with the abdomen material of the skeletal structure, the concrete material of the bottom of the concrete, the abdomen material of the skeleton structure and the concrete upper deck, As a result,
The steel frame structure may include a longitudinal beam welded with a shear connection material for the composite behavior of the abdominal member and the concrete bottom plate formed of unit members separately formed from a circular shape, a heart shape, an inequality shape or a semicircular shape, Of the composite girder. The lower part of the skeletal structure is combined with the lower concrete of the concrete introduced with the preceding compressive force, and the lower part of the skeletal structure is joined to the upper part of the skeletal structure, The concrete is combined with the upper deck of concrete, and the concrete is filled with the abdomen material of the skeletal structure, the concrete material of the bottom of the concrete, the abdomen material of the skeleton structure and the concrete upper deck, As a result,
The steel frame structure may include a longitudinal beam welded with a shear connection material for the composite behavior of the abdominal member and the concrete member formed of unit members separately formed from a circular shape, a heart shape, an inequality shape or a semicircular shape, So as to be able to independently resist an external load.

Images