CN209308162U - Highlight lines area frame structure node of column and beam overall structure - Google Patents

Abstract

The utility model discloses a kind of highlight lines area frame structure node of column and beam overall structure, especially a kind of highlight lines area frame structure node of column and beam overall structure for building engineering field.Frame structure node of column and beam overall structure in highlight lines area used by the utility model, including frame column, Vierendeel girder and cast-in-situ floor, the Vierendeel girder intersects with frame column, it is provided with frame beam steel in the Vierendeel girder, cast-in-situ floor reinforcing bar is provided in the cast-in-situ floor, it is characterised in that: the frame beam steel is located at the outside of frame column, the cast-in-situ floor reinforcing bar is located at the outside of frame column, and the cast-in-situ floor and frame column junction are provided with energy consumption seam.The highlight lines area frame structure node of column and beam overall structure of the utility model can effectively increase node region frame column relative rigidity, reduce beam-ends relative rigidity, dramatically increase Seismic Behavior of Frame Structure.

Description

Highlight lines area frame structure node of column and beam overall structure

Technical field

The utility model relates to a kind of highlight lines area frame structure node of column and beam overall structures, especially a kind of to be used for room The highlight lines area frame structure node of column and beam overall structure of room building engineering field.

Background technique

To finding that the earthquake that occurs in strong earthquakes of frame structure is larger in earthquake seimic disaster census, strong column and weak beam is frame Very important important content in seismic design of structures, and realize the important feature measure of beam hinge.But in practical work Cheng Zhong, there is no the structures for realizing strong column and weak beam well, since the reinforcing bar in cast-in-situ floor is actual to end of frame girder just The influence of section antidetonation bend-carrying capacity there is no specific quantized data so far, and due to cannot be effective consideration Vierendeel girder lower part Influence of the reinforcing bar to the actual normal section antidetonation bend-carrying capacity of end of frame girder, cannot be effective consideration cast-in-situ floor to beam-ends Design-calculated defect caused by the humidification of rigidity；Unreasonable with anti-seismic construction is waited so that can not reach in Practical Project To the effect of strong column and weak beam.

Since the arrangement of reinforcement of cast-in-situ floor influences horizontal knife to Vierendeel girder actual cross-section bearing capacity.In beam-ends section effectively by pull wing In edge width range, there is very big shadow with practical anti-bending bearing capacity of the frame beam span floor bar in the same direction to end of frame girder It rings.But the prior art causes the practical normal section antidetonation bend-carrying capacity variation of end of frame girder to the slab muscle of cast-in-situ floor It is specific to influence, there is no any regulation and approximate algorithm, therefore the prior art for frame structure node of column and beam design method not It it can arrive the effect in highlight lines area resistance violent earthquake well.

Utility model content

The technical problem to be solved by the utility model is to provide one kind can effectively increase node region column relative rigidity, Reduce beam-ends relative rigidity, the highlight lines area frame structure node of column and beam for dramatically increasing Seismic Behavior of Frame Structure is integrally tied Structure.

The utility model solves frame structure node of column and beam overall structure in highlight lines area used by its technical problem, packet Frame column, Vierendeel girder and cast-in-situ floor are included, the Vierendeel girder intersects with frame column, and frame joist steel is provided in the Vierendeel girder Muscle is provided with cast-in-situ floor reinforcing bar in the cast-in-situ floor, and the frame beam steel is located at the outside of frame column, the cast-in-place building Slab muscle is located at the outside of frame column, and the cast-in-situ floor and frame column junction are provided with energy consumption seam.

Further, being filled with pitch or resin in the energy consumption seam.

Further, being provided with bracket at the node that frame column and Vierendeel girder intersect, the bracket is located at cast-in-place building With the position between Vierendeel girder bottom surface, the bracket top surface is propped up to sliding is provided between cast-in-situ floor bottom surface in board bottom face Seat.

Further, the sliding support is tetrafluoroethene plate.

Further, be provided with attractive joint in bracket outer edge and Vierendeel girder joint, the attractive joint pitch or The filling of person's resin.

Further, the bracket plane width exceeds frame column side 200mm or more.

Further, the energy consumption seam stitches with a thickness of 49.5mm~50.5mm.

Further, the attractive joint stitches with a thickness of 49.5mm~50.5mm.

It, in this way can be with the beneficial effects of the utility model are: the technical solution slab muscle using the application does not protrude into column Avoid the problem that the reinforcing bar in cast-in-situ floor enhances the actual normal section antidetonation bend-carrying capacity of end of frame girder, because beam, Column junction, which is equivalently employed without cast-in-situ floor also, does not have slab muscle, so structure is not by floor and slab muscle to end of frame girder The influence of normal section antidetonation bend-carrying capacity can preferably realize " weak beam ".The application floor and column also at beam, Column border node Handover forms energy consumption seam, and energy consumption seam is arranged in the surrounding that frame column connects with floor.In the case where structure bears Static behavior, energy consumption seam Packing material do not influence the normal use of building, cast-in-situ floor, frame column etc. around energy consumption seam are normal operating conditions. When an earthquake occurs, pitch destroys in advance at energy consumption seam, deforms between cast-in-situ floor, bracket therewith, consumes a large amount of earthquakes Failure energy, so that the seismic energy for being transmitted to beam-ends frame column is greatly reduced, more conducively frame structure resists geological process.

Detailed description of the invention

Fig. 1 is the layout drawing of the application cast-in-situ floor reinforcing bar.

Fig. 2 is the structure and layout drawing of the application bracket.

Fig. 3 is the structure chart of the application attractive joint and energy consumption seam.

Fig. 4 is the C-C cross-sectional view of Fig. 3.

Components, position and number in figure: frame column 1, Vierendeel girder 2, cast-in-situ floor 3, frame beam steel 4, cast-in-situ floor Reinforcing bar 5, bracket 6, tetrafluoroethene plate 7, energy consumption seam 8, attractive joint 9.

Specific embodiment

The utility model is described in further detail with reference to the accompanying drawing.

The highlight lines area frame structure node of column and beam overall structure of the utility model, including frame column 1,2 He of Vierendeel girder Cast-in-situ floor 3, the Vierendeel girder 2 intersect with frame column 1, and frame beam steel 4, the cast-in-place building are provided in the Vierendeel girder 2 Cast-in-situ floor reinforcing bar 5 is provided in plate 3, the frame beam steel 4 is located at the outside of frame column 1, the cast-in-situ floor reinforcing bar 5 In the outside of frame column 1, the cast-in-situ floor 3 is provided with energy consumption seam 8 with 1 junction of frame column.As shown in Figure 1, due to using The technical solution slab muscle of the application does not protrude into column, in this way can be to avoid the reinforcing bar in cast-in-situ floor 3 to 2 end of Vierendeel girder reality The problem of normal section antidetonation bend-carrying capacity enhancing on border, because beam, column junction are equivalently employed without cast-in-situ floor 3 also without plate Reinforcing bar, so structure does not influence 2 end normal section antidetonation bend-carrying capacity of Vierendeel girder by floor and slab muscle, Ke Yigeng Good realization " weak beam ".The application floor and column also at beam, Column border node as shown in Figure 3 and Figure 4 join to form energy consumption seam 8, consumption 8 can be stitched and be arranged in the surrounding that frame column 1 connects with floor, having a size of 50mm wide, length changes with interface length, energy consumption seam 8 It is filled using pitch.In the case where structure bears Static behavior, the asphalt material filled in energy consumption seam 8 does not influence normally making for building With cast-in-situ floor 3, frame column 1 around energy consumption seam 8 etc. are normal operating conditions.When an earthquake occurs, it is dripped at energy consumption seam 8 It is green to destroy in advance, it deforms between cast-in-situ floor 3, bracket 6 therewith, a large amount of earthquake failure energies is consumed, so that being transmitted to beam The seismic energy of end frame column 1 is greatly reduced, and more conducively frame structure resists geological process.

Pitch or resin are filled in the energy consumption seam 8: in the case where structure bears Static behavior, being filled in energy consumption seam 8 The materials such as pitch do not influence the normal use of building, and cast-in-situ floor 3, frame column 1 around energy consumption seam 8 etc. are normal work shape State.When an earthquake occurs, pitch destroys in advance at energy consumption seam 8, deforms between cast-in-situ floor 3, bracket 6 therewith, consumption is big Eaerthquake damage energy is measured, so that the seismic energy for being transmitted to beam-ends frame column 1 is greatly reduced, more conducively frame structure resists earthquake Effect.

As shown in Fig. 2, being provided with bracket 6 at the node that frame column 1 and Vierendeel girder 2 intersect, the bracket 6 is located at cast-in-place 3 bottom surface of floor is provided with cunning between 3 bottom surface of cast-in-situ floor with the position between 2 bottom surface of Vierendeel girder, 6 top surface of bracket Dynamic support.

As shown in figure 4,5mm is arranged the application between 2 bottom surface of Vierendeel girder below soffit also at beam, Column border node Bracket 6,6 top surface of bracket is to filled polytetrafluoroethylene 7 is used as sliding support plate within the scope of 5mm between board bottom.Bracket 6 and frame column 1 forms entirety at bean column node, bears vertical load together, and the bracket 6 being arranged at beam, Column border node can support floor, protect Card Static behavior lower floor plate can bear the vertical load that construction floor transmits as usual, and can increase the cutting at node of frame column 1 Face size, and strengthened beam, the antidetonation of Column border node core space pillar are preferably realized " Qiang Zhu " by curved rigidity.

The application, which fills 7 plate of tetrafluoroethene, to be gathered in 6 top surface of bracket between board bottom within the scope of 5mm, 7 plate friction of tetrafluoroethene Coefficient is low, makes 6 top surface of bracket may be implemented to have slided connection relatively to board bottom formation, makes bracket 6 and frame column 1 in bean column node Place forms entirety, bears vertical load together, and the bracket 6 being arranged at beam, Column border node can support floor, guarantee under Static behavior Floor can bear the vertical load that construction floor transmits as usual, and can increase sectional dimension of the frame column 1 at node, and enhance Beam, Column border node core space pillar antidetonation by curved rigidity, preferably realize " Qiang Zhu ".

6 outer edge of bracket and 2 joint of Vierendeel girder are provided with attractive joint 9, the attractive joint 9 is filled out with pitch or resin It fills.As shown in figure 4, attractive joint 9 can be arranged in 2 both side surface of Vierendeel girder by the application, having a size of 50mmx50mm, attractive joint 9 are filled using materials such as pitches.In the case where structure bears Static behavior, bracket 6 forms at bean column node whole with frame column 1 Body, Vierendeel girder 2 bear vertical load with frame column 1 together, share vertical load jointly, and attractive joint 9 is not had an effect, also not shadow Ring the synergistic effect of Vierendeel girder 2 with frame column 1；When an earthquake occurs, attractive joint 9 is artificial geological process attractive joint 9, works as earthquake When acting on excessive, 2 attractive joint of Vierendeel girder, 9 position is destroyed in advance, and destruction consumes a large amount of earthquake failure energies, so that being transmitted to The geological process of beam-ends frame column 1 substantially reduces, and can guarantee that frame structure preferably accomplishes that " no damage in small earthquake, middle shake can in this way Repair, no collapsing with strong earthquake " it destroys.

As shown in Fig. 2, 6 plane width of bracket exceeds 1 side 200mm of frame column or more.Leg plane width need to meet building Edges of boards edge has the bearing length of 150mm, i.e. 6 planar dimension of bracket exceeds column side 200mm.

Energy consumption seam 8 stitches with a thickness of 49.5mm~50.5mm.Energy consumption seam 8 can be guaranteed using foregoing thickness ranges in structure It bears under Static behavior, the materials such as pitch filled in energy consumption seam 8 do not influence the normal use of building, showing around energy consumption seam 8 Pouring floor 3, frame column 1 etc. is normal operating conditions.When an earthquake occurs, pitch destroys in advance at energy consumption seam 8, cast-in-place therewith It deforms between floor 3, bracket 6, consumes a large amount of earthquake failure energies, so that being transmitted to the seismic energy of beam-ends frame column 1 It is greatly reduced, more conducively frame structure resists geological process.

Attractive joint 9 stitches with a thickness of 49.5mm~50.5mm.9 gap of attractive joint can guarantee tying using foregoing thickness ranges Structure is born under Static behavior, and bracket 6 and frame column 1 form entirety at bean column node, and Vierendeel girder 2 is born together with frame column 1 Vertical load shares vertical load jointly, and attractive joint 9 is not had an effect, and nor affect on Vierendeel girder 2 and frame column 1 cooperates with work With；When an earthquake occurs, attractive joint 9 is artificial geological process attractive joint 9, when geological process is excessive, 2 attractive joint 9 of Vierendeel girder Position is destroyed in advance, and destruction consumes a large amount of earthquake failure energies, so that being transmitted to the geological process of beam-ends frame column 1 substantially Reduce.

Claims (8)

1. highlight lines area frame structure node of column and beam overall structure, including frame column (1), Vierendeel girder (2) and cast-in-situ floor (3), the Vierendeel girder (2) is intersected with frame column (1), is provided with frame beam steel (4) in the Vierendeel girder (2), described cast-in-place Cast-in-situ floor reinforcing bar (5) are provided in floor (3), it is characterised in that: the frame beam steel (4) is located at the outer of frame column (1) Portion, the cast-in-situ floor reinforcing bar (5) are located at the outside of frame column (1), and the cast-in-situ floor (3) sets with frame column (1) junction It is equipped with energy consumption seam (8).

2. frame structure node of column and beam overall structure in highlight lines area as described in claim 1, it is characterised in that: the energy consumption It stitches and is filled with pitch or resin in (8).

3. frame structure node of column and beam overall structure in highlight lines area as described in claim 1, it is characterised in that: in frame column (1) and Vierendeel girder (2) intersection node at be provided with bracket (6), the bracket (6) be located at cast-in-situ floor (3) bottom surface with down toward Position between Vierendeel girder (2) bottom surface, bracket (6) top surface are provided with sliding support between cast-in-situ floor (3) bottom surface.

4. frame structure node of column and beam overall structure in highlight lines area as claimed in claim 3, it is characterised in that: the sliding Support is tetrafluoroethene (7) plate.

5. frame structure node of column and beam overall structure in highlight lines area as claimed in claim 3, it is characterised in that: in bracket (6) Outer edge and Vierendeel girder (2) joint are provided with attractive joint (9), attractive joint (9) pitch or resin filling.

6. frame structure node of column and beam overall structure in highlight lines area as claimed in claim 3, it is characterised in that: the bracket (6) plane width exceeds frame column (1) side 200mm or more.

7. frame structure node of column and beam overall structure in highlight lines area as described in claim 1, it is characterised in that: the energy consumption seam (8) with a thickness of 49.5mm~50.5mm seam.

8. frame structure node of column and beam overall structure in highlight lines area as claimed in claim 5, it is characterised in that: the attractive joint (9) with a thickness of 49.5mm~50.5mm seam.