KR100521754B1 - Split T scissors girder & beam - Google Patents

Abstract

As a means of increasing the section modulus of the end portion of the conventional uniform section H-beam having the maximum bending moment, as shown in FIGS. 4A and 5A, the web plate of the end is cut into an L-shape to split the upper and lower split Ts. After dividing into a pair of scissors, the scissors girder 10 and the scissors beam 10a are reinforced by attaching a web reinforcement plate 11 to the beginning of the end face. As shown in FIG. 4B, the shear beam has an effect similar to that of the reinforcement of the beam end of the uniform section with the niblace 7, so that the end stress is alleviated and the joint stress is also reduced. In addition, since the shear stress of the shear girder 10 is widely distributed, the lateral resistance is increased, and consequently, the shear girder 10 can be designed as a H-section steel having a smaller cross section than a uniform cross-section H-beam girder. If the beam is also formed by the end of the scissors beam (10a) and continuous with the adjacent beam can exhibit the same bending moment resistance capacity as the shear girder bonded to the column, so that the maximum amount of deflection is reduced and cracks in the bottom plate are also controlled.

Since the shear beam is relieved at the end joint stress and the lower split is inclined, the shear force is excellent, so even if the web joint is omitted, the reinforced CT (6), the warped reinforced CT (6a) and the joint plate 13 can bear the shear force. have.

Description

Split T scissors girder & beam}

Although the bending moment value is not uniform through the entire length, it is common to use the factory-produced uniform section H-shaped steel as it is. Therefore, the first purpose is to eliminate the waste, and the second is to solve the stress concentration caused by the stress concentration due to the joining of the beam at the end of the largest bending moment, and the danger in the secondary construction. In addition, the third objective is to simplify the safety of the upper and lower flange joints by omitting the web joint from the burden of connecting the upper and lower flanges and the three webs to one beam.

Generally, beams joined to columns are called girders, and beams joined to girders are called beams. H-shaped steel, which has the same cross-sectional area, is also tall, so that the cross-sectional coefficient and the cross-sectional secondary moment are large, resulting in large bending resistance moment and less deflection. However, the use of tall beams is undesirable because it requires a relatively high floor height. Therefore, in order to overcome this, open webs such as lattice trusses or honeycomb can be used instead of solid web H-beams.

It is a common steel structure to stiffen a uniform section H-beam girder to H-beam or box column. The H-beam is a web plate attached vertically to the center between the vertical flanges to maintain a constant gap between flanges. It is also highly converted. For example honeycomb, wave truss or lattice truss. The upper and lower flanges exhibit compressive and tensile strengths, respectively, to resist bending moments, and the web plate mainly resists shear forces.

Since the section modulus of H-beams is proportional to the square of the height, the higher the height, the greater the resistance to the bending moment, but the higher the unit weight, the higher the unit weight.

6 and 8, the ratio of the end bending moment and the central bending moment value of the steel beam is dependent on the load state but usually exceeds 1. In other words, it is 1 for the centralized load, 1.5 for the equally distributed load, and 2 for two equally concentrated loads at the third point. Therefore, the guideline for selecting the cross section of uniform section H-beams is to select the one that is suitable for the maximum bending moment. Therefore, when it is seen as a rigid, most of the remaining length except for a part of both ends, there is room for waste. Therefore, in the past, when large-size uniform section H-shaped steel was not produced, it was built up with a sectional plate girder with an inclined haunch at the end of the girder. In rare cases, the nibble 7 may be attached to the end of the uniform section H-beam, as shown in FIG. 4B, but the construction cost is added because it is excessively reinforced.

The end of the girder is a widely used method of treating the H-beam girder with a bracket moment joint or spot welding the end as shown in FIG. 2A, but the bracket moment joint has to bear double the cost for factory welding and field bolt jointing. The construction cost increases due to the cumbersomeness, and the method of spot welding the beam end tends to be reluctant because quality control is difficult. In addition, the column part to which the girder is joined must resist the bending moment in addition to the compressive force, so the cross section of the column must be large, and when lateral loads such as earthquakes or winds are applied, more stress is concentrated at the end of the girder and the column, increasing the difficulty.

On the other hand, the beam supported by the girder is designed based on the central maximum bending moment because it is a general method of pin contact as shown in Figs. 3, 3A and 7. Therefore, column B girders and column a beams arranged in parallel in FIG. 1 may have a larger cross section than the girders despite the same length and load conditions. Therefore, in order to overcome this difficulty, there is a method of welding the sheath connector 20 to the bottom flange of the beam as shown in FIG. 3a and a composite design with the floor slab, but in order to automatically weld the sheath connector 20 in the field, the construction capacity must be increased. It is often difficult for on-site steel assemblers to step on the top of the beam, and the sheath connector is difficult to weld when deck plates are laid.

If the steel beams are made of the cross section to fit the stress value of each part, the material usage can be minimized, but the manufacturing cost will increase. Therefore, almost all steel structures use factory-shaped H-shaped steel of uniform cross-section as a material, so the reality is that the large size of the steel sheet must be used in preparation for the large stress corresponding to a very small portion of the beam. In addition, since the girder is joined to the column at the end of the largest bending moment, the construction ratio of the joint increases, and if it is not installed, it may lead to dangerous diameter.

If the girder or beam uses a uniform section H-shaped steel but increases the height of the end of the large bending stress to increase the bending resistance moment, the cross section can be efficiently used and the stress concentration at the joint can be eliminated. As shown in FIGS. 6 and 8, the value of the rigid beam end bending moment decreases rapidly in a short section, so that a reasonable design may be achieved if the beam can be rapidly changed according to the cross-sectional shape of the beam. This is because it is not advisable to increase the height of the beam overall, but it is acceptable to increase the height of the beam at an end only at the end because there is a need for a space between the lower surface of the beam and the ceiling in the building. .

The method of joining the beam to the girder is generally pinning. Therefore, if the cross sections of girders and beams arranged in the same direction with the same working load are designed with the same deflection value, the bottom plate will be out of flat state and unwanted vibrations and cracks will occur. This is because the maximum deflection between the rigid beam and the pinned beam is 1: 5 when the load is equally distributed. On the other hand, especially if there is a difference in the height of the girder and the beam to be bonded to the girder, the conventional method is difficult to force the joint because the expensive and cumbersome. Therefore, a new method is needed to reduce the overall cross-section of the existing H-beams, to increase the bending strength of the end with the largest bending moment and to reduce the stress concentration at the joint.

As shown in Fig. 4a and Fig. 5a in the H-beams the web plate of the end of the large bending moment is cut to the letter 'A' and bisected into two upper and lower splits, then spread with scissors and reinforced with the web reinforcement plate. One is the scissors. The lower split opening angle of the scissors beam is 30 ° and can be adjusted within 45 ° if necessary. The bottom split may be processed while heating, but may also be cut and welded if necessary. It can be applied to the beam as well as the scissors girders, and the joint of the scissors girders is joined to the flange and the column surface of the upper split 9 by the reinforcement CT (6) and the flange and the column surface of the lower inclined split 9a as shown in FIG. Is joined by inclined reinforced CT 6a.

Reinforcement CT 6 and the reinforcement inclination CT (6a) is a shear beam joining means produced by steel plates or cast steel products so as to omit a separate web joint corresponding to the shear force of the beam as shown in FIG.

Reinforcement CT (6) is to weld the quadrilateral horizontal plate 17 to the quadrilateral vertical plate 16 as shown in Fig. 9 and reinforce the trapezoidal reinforcement rib 19 between the two bonded plates of the scissors girder 10 It is used to join the upper split (9) to the column.

The inclined reinforcement CT 6a welds the four-sided inclined plate 17 to the four-sided vertical plate 16 and reinforces the triangular reinforcement rib 19a between the two joined plates as shown in FIG. It is used to join the splitty (9a) to the pillar.

The method of joining the scissors beam 10a to the girder is as shown in FIG. 5A, in which the upper split 9 is the same as a conventional rigid beam, and the lower slanted split 9a is a stiffener 14 welded to the lower reinforcing flange. Is factory welded to the lower flange of the girder and bolted to the site with the flange and reinforcing flange of the lower split of the scissors. The bent angle of the reinforcing flange matches the angle of the lower split.

As a means of increasing the section modulus of the end with the highest bending moment in conventional H-beams, the sheared beam is divided into two splits up and down, and the scissors shears open like scissors. As shown in FIG. 4B, the effect obtained by reinforcing with the nibble 7 is relieved, and the end stress is alleviated, and the joint stress is also greatly reduced. In addition, the stresses at the joints with the columns are widely dispersed, and the lateral resistance strength from earthquakes and wind loads increases. As a result, it is reasonable to select and use H-section steel with a smaller cross section than to design a beam with a uniform cross section.

The beam is usually pin-joined to the girder, but when the beam ends are formed in scissors as shown in FIG. 5A and continuous with the adjacent beams, the beams can exhibit the same bending moment resistance as that of the scissors girder 10 bonded to the column, thereby reducing the amount of deflection and the bottom. The torsion of the plates is prevented and the cracks are also controlled. Since the shear beam 10a has an end joint stress relieved and the lower slanted split 9a is inclined downward, which is a load-carrying shortcut, the shear force is excellent, so that the shear bond CT 6 or the warp reinforced CT 6a can be omitted even if the web joining is omitted. Bonding can bear up to shear force.

1 is a bottom frame top view of steel frame building.

Figure 2 is a row B column H girder furniture of Figure 1;

Figure 2a is a joint detail of the column and the girder of Figure 2;

3 is a furniture diagram in which the column a H beam of FIG. 1 is joined to the H-beam girder;

Figure 3a is a junction detail view of FIG.

Figure 4 is a row B scissors girder furniture of Figure 1;

Figure 4a is a joint column and scissors girder junction of Figure 4 in detail.

Figure 4b is a detailed view of the junction of the column and the nibble girder of Figure 4

5 is a view of the furniture in which the row a shear scissors of FIG. 1 are bonded to the girder;

5A is a junction detail view of FIG. 5.

6 is a bending moment diagram of FIGS. 2 and 4.

7 is a bending moment of FIG.

8 is a bending moment of FIG.

9 is a reinforcement CT and an inclination reinforcement CT.

<Short description of the symbols in the drawings>

1: pillar

2 girder

3 beam

4: Bracket Moment Junction

5: pin junction

6: Reinforcement CT 6a: Slope Reinforcement CT

7: knee brace

8: H section steel

9: Upper Split T 9a: Lower Slope Split T

10: scissors girder 10a: scissors beam

11: web gusset

12: opening

13: joint plate

14: Stiffener

15: reinforcing flange

16: vertical plate

17: horizontal plate

18: inclined plate

19: trapezoid reinforcing rib 19a: triangle reinforcing rib

20: Shea Connector

Claims (6)

Girder (2) connected to the column; The girder is composed of a shear girder 10 bisecting the H-shaped steel end at a predetermined position on the column flange face; The scissors girder is divided into an upper split 9 and a lower tilt split 9a and connected to a reinforcement CT 6 and a warp reinforcement CT 6a, respectively, and bolted to a column flange; The split portion of the upper split and the inclined split is cut by the web reinforcing plate 11 to relieve the stress at the end of the beam and to increase the bending moment resistance. The girder (2) according to claim 1, wherein the girder (2) is provided with reinforcement CT (6) and inclined reinforcement CT (6a) at the upper flange and the lower flange of the girder end, respectively; The reinforcement CT welds the quadrilateral horizontal plate 17 to the quadrilateral vertical plate 16 and reinforces the trapezoidal reinforcing rib 19 between the two joined plates; And The warp reinforcement CT is configured to weld the quadrilateral horizontal plate 18 to the quadrilateral vertical plate 16 and reinforce the triangular reinforcing ribs 19a between the two joined plates; The inclined reinforcement CT 6a is bolted to the lower flange of the H-beam steel 8, which is a girder by connecting with the niblace 7; Split shear beams and reinforced CTs are bolted to column flanges to relieve the joint stress at the ends of beams and to increase bending moment resistance. The scissors beam 2a connected to the girder 2 according to claim 1 divides the end separated by a predetermined position from the girder end into the upper split 9 and the lower inclined split 9a; The upper split bolts the beam (9) flange together with the joint plate (13); And The lower inclined splitty is configured to bolt to the stiffener 14 welded to the girder bottom flange and the reinforcing flange 15 using a joint plate 13; The split portion of the upper split 9 and the inclined split 9a is cut by the web reinforcement plate 11 so as to connect the scissors beam to the girder without separate web joining. delete delete delete