CN218292242U - Bracket overhanging type prestress compression joint assembled concrete frame - Google Patents

Abstract

The application belongs to the technical field of building structure, provides an overhanging type prestressing force crimping assembled concrete frame of bracket, including prefabricated post, coincide roof beam, coincide floor and coupling assembling. The superposed beam comprises a prefabricated beam arranged at the outer end of the bracket of the prefabricated column, a beam post-pouring layer arranged on the prefabricated beam and a bracket upper layer arranged on the bracket; the laminated floor slab comprises a precast slab arranged on the precast beam and a slab post-pouring layer arranged on the precast slab; the connecting assembly comprises a post-tensioned prestressed reinforcement bundle for fastening the prefabricated column and the prefabricated beam, a bonding layer arranged between the bracket and the prefabricated beam, and bending-resistant energy-consuming reinforcements and shearing-resistant reinforcements arranged on a post-beam pouring layer and an upper layer of the bracket, wherein the bending-resistant energy-consuming reinforcements are connected with anchoring reinforcements extending into the upper layer of the bracket from the prefabricated column. This overhanging type prestressing force crimping assembled concrete frame of bracket makes things convenient for assembled beam column node to link to each other with the frame brace, and prefabricated post and prefabricated beam connecting portion displacement play beam column node core district, and the joint position atress is littleer, the construction is more convenient, the quality is changeed the guarantee.

Description

Bracket overhanging type prestress compression joint assembled concrete frame

Technical Field

The application relates to the technical field of building structures, in particular to an outward-extending prestressed compression joint assembly type concrete frame for a bracket.

Background

The assembly type concrete frame structure is a frame structure formed by prefabricating, assembling and connecting prefabricated components serving as main stressed components, and the assembly type frame structure becomes one of important directions of building structure development in China.

At present, the fabricated concrete frame structure system in China mainly adopts two connection modes, one mode is a wet connection node, a prefabricated beam column is generally disconnected at the node, and the prefabricated beam column is connected through concrete pouring in a construction site. The connection mode has large workload of site construction, dense node steel bars and difficult guarantee of construction quality; a dry type connection represented by a prestressed fabricated concrete pressure joint (PPEFF fabricated joint for short) disclosed in Chinese patent CN107165272A is characterized in that in the PPEFF fabricated joint, a prefabricated column penetrates through the joint, and a prefabricated beam is connected with the beam-column joint in a pressure welding manner through a post-tensioned prestressed tendon penetrating through the beam-column joint and a gap-filling fast-hardening fiber grouting material, so that the assembly efficiency of a structural construction site is improved, and the use of the prestressed tendon also improves the disaster resistance of the structure. However, to the frame bearing structure that high-rise building adopted, the axis of its bearing diagonal need pass through beam column node center, and original PPEFF assembly node that sets up the joint seam at the post surface needs to improve, and to the roof beam and the non-orthogonal condition of rectangle post, the processing method of original PPEFF node is also comparatively complicated in addition. Adjustment of the joint position of the fabricated frame node needs to comprehensively consider installation convenience and the influence of bearing failure mode change, and an optimal solution is provided.

SUMMERY OF THE UTILITY MODEL

An object of the embodiment of the application is to provide an overhanging type prestressing force crimping assembled concrete frame of bracket for solve original prestressing force assembled concrete crimping node (for short PPEFF assembly node) and can not be used for frame bearing structure, and promote the assembly efficiency of its roof beam and the non-orthogonal condition of rectangular column. After the beam column assembly joint is moved to the extending bracket of the column, the joint stress is smaller, the energy-consuming steel bar connection is more convenient, and the construction quality is easier to guarantee.

In order to achieve the purpose, the technical scheme adopted by the application is as follows: the utility model provides an overhanging type prestressing force crimping assembled concrete frame of bracket, overhanging type prestressing force crimping assembled concrete frame of bracket includes:

the prefabricated column comprises a prefabricated column body, a bracket and an anchoring steel bar, wherein the bracket extends outwards from the side part of the prefabricated column body, and the first end of the anchoring steel bar is arranged in the prefabricated column body;

the composite beam comprises a precast beam, a beam post-pouring layer and a bracket upper layer, the precast beam is connected to the outer end of the bracket, and the beam post-pouring layer is arranged on the upper surfaces of the bracket and the precast beam; the upper layer of the bracket is arranged on the upper surface of the bracket, and the second end of the anchoring steel bar is arranged in the upper layer of the bracket;

the composite floor slab comprises a precast slab and a slab post-pouring layer, the edge of the precast slab is supported on the precast beam, and the slab post-pouring layer is arranged on the upper surface of the precast slab and is integrally poured with the beam post-pouring layer; and

the post-tensioned prestressed reinforcement bundle sequentially penetrates through the precast column body, the bracket and the precast beam and is used for tensioning and fixing the precast column and the precast beam; the bonding layer is arranged at the joint of the bracket and the precast beam and is used for bonding the bracket and the precast beam; the first end of the bending-resistant energy-consuming reinforcing steel bar is arranged in the post-beam casting layer, and the second end of the bending-resistant energy-consuming reinforcing steel bar extends into the upper layer of the bracket and is connected with the second end of the anchoring reinforcing steel bar; the first end of shear reinforcement is located the roof beam post-cast layer, shear reinforcement's second end is located in the bracket upper strata.

In one embodiment, the bracket upper layer is a bracket post-pouring layer, and the bracket post-pouring layer, the beam post-pouring layer and the plate post-pouring layer are integrally poured.

In one embodiment, the bracket upper layer is a bracket prefabricated layer, and the bracket prefabricated layer is integrally prefabricated with the prefabricated column body and the bracket.

In one embodiment, the bending-resistant energy-consuming steel bars are arranged in a manner of bonding in the column, and the first ends of the anchoring steel bars are embedded and anchored in the prefabricated column body.

In one embodiment, the bending-resistant energy-consuming steel bars are arranged in a partially unbonded or column-outside fully bonded mode, when the upper layer of the bracket is a bracket post-cast layer, the second ends of the anchoring steel bars and the second ends of the bending-resistant energy-consuming steel bars are both poured in the bracket post-cast layer, and the first ends of the bending-resistant energy-consuming steel bars are poured in the beam post-cast layer.

In one embodiment, the bending-resistant energy-consuming reinforcing steel bars are arranged in a partially unbonded or post-outer fully bonded mode, when the upper bracket layer is a bracket prefabricated layer, the second ends of the anchoring reinforcing steel bars are embedded in the upper bracket layer and extend to be tightly attached to the outer side wall of the bracket prefabricated layer, the first ends of the bending-resistant energy-consuming reinforcing steel bars are poured in the post-beam pouring layer, and the second ends of the bending-resistant energy-consuming reinforcing steel bars are connected to the second ends of the anchoring reinforcing steel bars.

In one embodiment, when the upper bracket layer is a prefabricated bracket layer, the prefabricated bracket layer has a slope surface, one end of the frame support is connected to the slope surface, and the other end of the frame support is used for connecting the bottom of another prefabricated beam above the prefabricated bracket layer.

In one embodiment, the shear reinforcement is disposed below the bending-resistant energy consuming reinforcement.

In one embodiment, the length of the shear reinforcement above the corbel is not less than 10 times the diameter of the shear reinforcement, and the length of the shear reinforcement above the precast beam is not less than 10 times the diameter of the shear reinforcement.

In one embodiment, the precast column is further provided with a column prestressed tendon pore passage which horizontally penetrates through the precast column body and the corbel, the precast beam is provided with a beam prestressed tendon pore passage which is parallel to the column prestressed tendon pore passage, the connecting assembly further comprises a prestressed anchorage device, the post-tensioned prestressed steel tendon is arranged in the column prestressed tendon pore passage and the beam prestressed tendon pore passage in a penetrating manner, and the end part of the post-tensioned prestressed steel tendon extending out of the precast column is connected to the prestressed anchorage device and is fastened to the precast column and the precast beam through tensioning equipment.

In one embodiment, the preformed post body and the cross-section are circular or polygonal.

In one embodiment, a plurality of brackets are arranged on the precast column body, and the included angle between two adjacent brackets is an acute angle or an obtuse angle.

In one embodiment, the width of the joint between the corbel and the precast beam is 10mm to 30mm.

In one embodiment, the bond coat comprises one or more of a high strength rapid hardening cement Sha Gaojiang rapid hardening cement based grouting material, a fiber rapid hardening cement based grouting material, or a polymer mortar having a compressive strength greater than or equal to 45 MPa.

In one embodiment, the post-tensioned prestressed reinforcement bundles are located within 1/2 of the lower cross-sectional area of the precast beam.

In one embodiment, the prefabricated column further comprises a transverse steel bar, one end of the transverse steel bar is arranged in the prefabricated column body, and the other end of the transverse steel bar is arranged in the bracket.

In order to achieve the above object, the present application further provides a construction method of the corbel overhanging type prestressed compression joint fabricated concrete frame, including the steps of:

producing the precast columns, the precast beams and the precast slabs;

installing the prefabricated column: hoisting the prefabricated column, and fixing the hoisted prefabricated column in place;

installing the precast beam: hoisting the precast beam and adjusting the position of the precast beam to enable the precast beam to correspond to the position of the bracket, and temporarily fixing the precast beam and the precast column;

mounting post-tensioned prestressed steel bundles: paving the post-tensioned prestressed reinforcement bundles in the precast column body, the bracket and the precast beam of the precast column;

filling joints between the corbels and the precast beams: filling high-strength non-shrinkage fiber filling bonding materials into joints between the corbels and the precast beams to form bonding layers, wherein the width of the joints between the corbels and the precast beams is 10-30 mm;

tensioning the post-tensioned prestressed reinforcement bundle: after the bonding layer reaches the preset strength, tensioning and fixing the post-tensioned prestressed reinforcement bundles;

installing the precast slab: hoisting the precast slab, and temporarily fixing the precast slab;

enabling the first end of the bending-resistant energy-consuming steel bar to be arranged in the post-beam casting layer, and enabling the second end of the bending-resistant energy-consuming steel bar to be arranged in the upper bracket layer and connected with the second end of the anchoring steel bar; enabling the first end of the shear steel bar to be arranged in the post-beam casting layer and the second end of the shear steel bar to be arranged in the upper layer of the bracket; and forming the bracket upper layer, the beam post-cast layer and the plate post-cast layer.

Compared with the prior art, the beneficial effect that the overhanging type prestressing force crimping assembled concrete frame of bracket that this application provided lies in:

firstly, the bracket-extending type prestress compression-joint assembly type concrete frame provided by the embodiment is characterized in that a bracket is arranged on the outer side of a prefabricated column body, a prefabricated beam is connected to the outer end of the bracket, a beam-column joint (the joint of the bracket and the prefabricated column body) and the prefabricated column are prefabricated and formed together, and when a frame support is arranged on the bracket, the axis of the frame support cannot pass through the joint of the prefabricated beam and the prefabricated column, so that the frame support structure can be suitable for a frame support structure commonly adopted by high-rise buildings; in addition, the cantilever type prestressing force crimping assembled concrete frame of bracket that this embodiment provided can also be applicable to the non-orthogonal condition between the precast column body of rectangle and the precast beam through the quantity and the position of adjustment bracket on the precast column body, and the assembly efficiency of precast column and precast beam is high under the non-orthogonal condition between the precast column body of above-mentioned rectangle and the precast beam, and the construction is simple, the quality easily guarantees.

Secondly, after the assembling parts of the precast beam and the precast column are moved out of the core area of the beam-column joint, the stress of the joint of the precast beam and the precast column is smaller; meanwhile, the precast beam and the precast column are tensioned and fastened by the post-tensioned prestressed reinforcement bundles, the joint between the bracket and the precast column is bonded by the bonding layer, the shear-resistant steel bars and the bending-resistant energy-consuming steel bars for connecting the anchoring steel bars of the precast column are arranged in the post-cast beam layer and the upper bracket layer, and the laminated floor slab, the post-cast plate layer and the post-cast beam layer are integrally cast and formed, so that the precast column, the laminated beam and the laminated floor slab are connected into a complete stress system, and the overall stress state of the cantilever type prestressed compression joint assembly type concrete frame of the bracket is better.

Third, the overhanging type prestressing force crimping assembled concrete frame of bracket that this embodiment provided, the intraformational bending resistance power consumption reinforcing bar of post-cast beam can not weaken the section and handle and do not have the bondn and handle, and the job site operation is more simple and convenient, nimble, and the installation effectiveness is high, and construction cycle is shorter.

Fourth, the overhanging type prestressing force crimping assembled concrete frame of bracket that provides in this embodiment, beam column node (the junction of bracket and prefabricated post body) is kept away from with the position of the seam of precast beam to its bracket, the space around the seam is comparatively broad, when needs are with the pre-buried bellows in the pore canal in the precast beam and the pre-buried bellows in the prefabricated post in seam department sealing connection, operating space is big, the construction is more high-efficient swift, can avoid leaking of the pre-buried bellows in the pore canal of seam department as far as possible, guarantee the reliability of seam department construction quality.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings required to be used in the embodiments or the related technical descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

Fig. 1 is a sectional view of a prefabricated column and a superposed beam of a corbel overhanging type prestressed compression joint fabricated concrete framework provided by an embodiment of the application;

fig. 2 is a schematic structural diagram of a bracket overhanging type prestressed compression joint fabricated concrete frame provided in the embodiment of the present application, in which a prefabricated column is an angle column;

fig. 3 is a schematic structural diagram of a prefabricated column in a corbel overhanging type prestressed compression joint assembly type concrete frame provided by the embodiment of the present application, where the prefabricated column is a side column;

fig. 4 is a cross-sectional view illustrating connection of a precast column and superposed beams on opposite sides when the precast column is a side column in the corbel overhanging type prestressed compression-joint fabricated concrete framework according to the embodiment of the present application;

fig. 5 is a schematic structural diagram of a bracket overhanging type prestressed compression joint fabricated concrete frame provided by an embodiment of the present application, in which a prefabricated column is a center column;

fig. 6 is a component arrangement diagram of a corbel overhanging type prestressed compression joint fabricated concrete frame provided in an embodiment of the present application;

fig. 7 is a reinforcement diagram of a corbel overhanging prestressed compression joint fabricated concrete framework according to an embodiment of the present application;

fig. 8 is a schematic front view of a bracket overhanging type prestressed compression-joint fabricated concrete frame provided by an embodiment of the present application when a frame support is provided;

FIG. 9 is a cross-sectional view of an outrigger type prestressed compression joint fabricated concrete frame with a framing support according to an embodiment of the present application;

fig. 10 is a schematic structural view of a prefabricated column of a corbel overhanging type prestressed compression joint fabricated concrete frame provided in an embodiment of the present application, where the cross section of the prefabricated column is square and two adjacent corbels are not perpendicular to each other;

fig. 11 is a schematic structural diagram of a prefabricated column of a corbel overhanging type prestressed compression joint fabricated concrete frame provided in an embodiment of the present application, where the cross section of the prefabricated column is circular and two adjacent corbels are not perpendicular to each other.

Wherein, in the figures, the various reference numbers:

100-prefabricated columns; 110-prefabricating a column body; 111-column prestressed tendon pore channel; 120-bracket; 130-anchoring a steel bar; 140-transverse reinforcement;

200-a laminated beam; 210-precast beams; 211-beam prestressed reinforcement ducts; 220-post-beam casting layer; 230-upper bracket layer; 231-a bracket post-pouring layer; 232-bracket prefabricated layer; 233-slope surface;

300-laminated floor slab; 310-precast slab; 320-post-pouring the plate;

400-a connection assembly; 410-post-tensioned pre-stressed steel tendons; 420-a tie layer; 430-bending-resistant energy-consuming reinforcing steel bars; 440-shear reinforcement; 450-prestressed anchorage device; 460-a connecting member;

500-frame support.

Detailed Description

Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present application and should not be construed as limiting the present application.

In the description of the present application, it is to be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like, as used herein, refer to an orientation or positional relationship indicated in the drawings, which is for convenience and simplicity of description, and does not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus, is not to be considered as limiting.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1 and 2, a corbel overhanging type prestressed compression-joint fabricated concrete frame and a construction method thereof according to an embodiment of the present invention will now be described. The corbel overhanging type prestress compression joint assembly type concrete frame comprises prefabricated columns 100, superposed beams 200, superposed floor slabs 300 and connecting assemblies 400. The prefabricated column 100 comprises a prefabricated column body 110, a bracket 120 and an anchoring steel bar 130, wherein the bracket 120 is formed by extending outwards from the side part of the prefabricated column body 110, and the first end of the anchoring steel bar 130 is arranged in the prefabricated column body 110; the composite beam 200 comprises a precast beam 210, a beam post-pouring layer 220 and a bracket upper layer 230, wherein the precast beam 210 is connected to the outer end of the bracket 120, namely, the end of the bracket 120 far away from the precast column body 110; the post-beam-casting layer 220 is arranged on the upper surface of the precast beam 210; the upper bracket layer 230 is arranged on the upper surface of the bracket 120, and the second end of the anchoring steel bar 130 extends out of the prefabricated column body 110 and is arranged in the upper bracket layer 230; the laminated floor slab 300 comprises precast slabs 310 and a slab post-cast layer 320, wherein the edges of the precast slabs 310 are supported on the precast beams 210, and the slab post-cast layer 320 is arranged on the upper surfaces of the precast slabs 310 and integrally cast with the beam post-cast layer 220; the connecting assembly 400 comprises a post-tensioned prestressed reinforcement bundle 410, a bonding layer 420, bending-resistant energy-consuming reinforcements 430 and shear reinforcements 440, wherein the post-tensioned prestressed reinforcement bundle 410 sequentially penetrates through the precast column body 110, the corbel 120 and the precast beam 210 and is used for tensioning and fixing the precast column 100 and the precast beam 210; the bonding layer 420 is arranged at the joint of the bracket 120 and the precast beam 210 and is used for bonding the bracket 120 and the precast beam 210; a first end of the bending-resistant energy-consuming steel bar 430 is arranged in the post-beam-casting layer 220, and a second end of the bending-resistant energy-consuming steel bar 430 is connected with a second end of the anchoring steel bar 130 in the upper bracket layer 230; a first end of the shear reinforcement 440 is provided in the beam post-cast layer 220, and a second end of the shear reinforcement 440 is provided in the corbel upper layer 230.

It should be noted that the bending-resistant energy consuming reinforcing bars 430 may be connected to the second end of the anchoring reinforcing bar 130 in various forms, such as mechanical connection joints or sleeve grouting connection, and may be disposed as required, which is not limited herein.

It should be noted that, in this embodiment, the precast columns 100 may be used as corner columns, side columns or center columns in the corbel overhanging type prestressed compression-assembled concrete framework (please refer to fig. 6, the precast column 100 located in the middle of the framework structure is a center column, the precast columns 100 located at the corners of the framework structure are corner columns, and the precast columns 100 located at the sides of the framework structure are side columns). The number of the brackets 120 on the precast column body 110 may be set according to the type of the precast column 100, please refer to fig. 1 and 2, when the precast column 100 is used as a corner column, the first side and the second side of the precast column body 110 perpendicular to each other are both connected with precast beams 210, the first side of the precast column body 110 is provided with the brackets 120 and connected with the corresponding precast beams 210 through the brackets 120, the second side of the precast column body 110 is connected with the corresponding precast beams 210 in a conventional PPEFF node manner, and two ends of the precast plates 310 are supported on the precast beams 210 on the first side of the precast column body 110; referring to fig. 3 and 4, when the precast column 100 is used as a side column, the precast column body 110 is provided with two brackets 120, and the two brackets 120 extend in different directions on the same straight line (the direction of the two brackets 120 corresponds to the placing direction of the precast slab 310 and is used for bearing the precast slab 310), and the precast column body 110 can be connected with the precast beam 210 on the other side by adopting a beam-column joint connection manner in the related art; referring to fig. 5, when the precast column 100 is used as a center column, the precast column body 110 is provided with two brackets 120, and the two brackets 120 extend in different directions on the same straight line (the direction of the two brackets 120 corresponds to the placing direction of the precast slabs 310 for bearing the precast slabs 310), and the precast column body 110 can be connected to the precast beams 210 at the other two sides by using the beam-column joint connection method in the related art. And it can be understood that, when two brackets 120 are provided on the precast column body 110, the post-tensioned prestressed reinforcement bundles 410 corresponding to the two brackets 120 are staggered in the height direction of the precast column 100, and the anchor reinforcements 130 corresponding to the two brackets 120 are also staggered in the height direction of the precast column 100.

Specifically, the width of the joint between the corbel 120 and the precast girder 210 may be 10mm to 30mm.

Specifically, the bonding layer 420 may include one or more of a high strength rapid hardening cement Sha Gaojiang rapid hardening cement based grouting material, a fiber rapid hardening cement based grouting material, or a polymer mortar having a compressive strength greater than or equal to 45 MPa.

The application provides an overhanging type prestressing force crimping assembled concrete frame of bracket compares with the correlation technique, has following beneficial effect:

first, the corbel overhanging type prestressed compression joint fabricated concrete frame provided by this embodiment is formed by prefabricating the precast column body 110 and the corbel 120 as a whole, the joint between the precast beam 210 and the precast column 100 is moved out of the core area of the beam-column joint (the joint between the corbel 120 and the precast column body 110), when the bracket 120 is provided with the inclined frame support 500 (see fig. 8 and 9), the axis of the frame support 500 does not pass through the joint between the precast beam 210 and the precast column 100, and the frame support structure can be applied to a frame support structure commonly used in high-rise buildings; in addition, the corbel overhanging type prestressed compression joint assembly type concrete frame provided by this embodiment can also be applied to the case that the rectangular precast column body 110 and the precast beam 210 are not orthogonal (the case that the axis of the precast beam 210 in the length direction is not perpendicular to the surface of the precast column body 110 for connecting the precast beam 210) by adjusting the number and the position of the corbels 120 on the precast column body 110, and the assembly efficiency of the precast column 100 and the precast beam 210 is high, the construction is simple, and the quality is easy to ensure under the condition that the precast column body 110 and the precast beam 210 are not orthogonal.

Secondly, after the joint between the precast beam 210 and the precast column 100 is moved out of the core area of the beam-column joint, the joint between the precast beam 210 and the precast column 100 is stressed less; meanwhile, the precast beam 210 and the precast column 100 are tensioned and fastened by the post-tensioned prestressed reinforcement bundle 410, the bonding layer 420 bonds the joint between the precast beam 210 and the precast column 100, the shear reinforcement 440 and the bending-resistant energy-consuming reinforcement 430 connecting the precast column 100 are arranged in the post-beam casting layer 220 and the upper bracket layer 230, and the composite floor slab 300, the post-slab casting layer 320 and the post-beam casting layer 220 are integrally cast and formed, so that the precast column 100, the composite beam 200 and the composite floor slab 300 are connected into a complete stress system, and the overall stress state of the bracket-extending prestressed compression joint assembly type concrete frame is better.

Third, the outrigger prestressed crimping assembled concrete frame of bracket that this embodiment provided, the anti-bending power consumption reinforcing bar 430 in the layer 220 is watered after the roof beam, but local unbonded processing also can not weaken the processing, and the job site operation is more simple and convenient and nimble, and the installation effectiveness is high, and construction cycle is shorter.

Fourth, the overhanging prestressing force crimping assembled concrete frame of bracket that provides in this embodiment, the position of its bracket 120 and precast beam 210's seam is kept away from beam column node (the junction of bracket 120 and precast column body 110), and the space around the seam is comparatively broad, when needs with the pre-buried bellows in pore canal in precast beam 210 and the pre-buried bellows in pore canal in precast column 100 in seam department sealing connection, operating space is big, the construction is more high-efficient swift, can avoid the pre-buried bellows in pore canal of seam department to leak thick liquid as far as possible, guarantee the reliability of seam department construction quality.

In another embodiment of the present application, referring to fig. 1, as a form of the upper bracket layer 230, the upper bracket layer 230 is a post-cast bracket layer 231, and the post-cast bracket layer 231 is integrally cast with the post-cast beam layer 220.

In the corbel overhanging prestressed compression-joint assembled concrete frame provided by this embodiment, the anchoring bars 130 in the prefabricated column 100 may extend out of the surface of the prefabricated column 100, and extend into the upper portion of the corbel 120 and then be connected to the energy dissipation bending-resistant bars 430 through the connecting members 460 (e.g., mechanical connectors). In the process of manufacturing the precast column 100 in a factory, the connecting member 460 is arranged outside the precast column 100, so that the requirements on the pre-embedding precision and position are low, and the construction quality is ensured more easily. When the assembly is carried out on the construction site, the connecting part 460 is arranged in the bracket post-pouring layer 231, the position of the connecting part 460 is easier to determine and adjust, the operation is simpler, and in addition, after the installation error occurs in the construction, the adjustment is easier, and the remedial measures are easier to take for remediation after the engineering quality problem occurs.

Moreover, the corbel overhanging type prestress compression joint assembly type concrete frame provided by the embodiment can directly place the shear steel bars 440 on the upper portion of the joint at a construction site, pour the first ends of the shear steel bars 440 in the post-beam casting layer 220, pour the second ends of the shear steel bars 440 in the corbel casting layer 231, and does not need to pre-embed anchoring steel bar pieces and connecting pieces (such as straight threaded sleeve connecting joints) for connecting the shear steel bars 440 in the precast column 100 in advance, so that the construction is more convenient and quicker.

In another embodiment of the present application, please refer to fig. 9, as another form of the upper bracket layer 230, the upper bracket layer 230 is a prefabricated bracket layer 232, and the prefabricated bracket layer 232 is integrally prefabricated with the prefabricated column body 110 and the bracket 120.

The application provides an overhanging type prestressing force crimping assembled concrete frame of bracket, its construction method includes following step:

firstly, producing a precast column 100, a precast beam 210 and a precast slab 310;

step two, mounting the prefabricated column 100: hoisting the prefabricated column 100, and fixing the prefabricated column 100 after being hoisted in place;

step three, mounting the precast beam 210: hoisting the precast beam 210 and adjusting the position of the precast beam 210 to make the precast beam 210 correspond to the position of the corbel 120, and temporarily fixing the precast beam 210 and the precast column 100;

step four, mounting the post-tensioned prestressed reinforcement bundle 410: laying post-tensioned prestressed steel bar bundles 410 in the precast column body 110, the bracket 120 and the precast beam 210 of the precast column 100;

and step five, filling joints between the corbels 120 and the precast beams 210: filling high-strength non-shrinkage fiber filling bonding materials into the joint between the bracket 120 and the precast beam 210 to form a bonding layer 420, wherein the width of the joint between the bracket 120 and the precast beam 210 is 10mm-30mm;

step six, tensioning the post-tensioned prestressed reinforcement bundle 410: after the adhesive layer 420 reaches a predetermined strength, the post-tensioned pre-stressed reinforcement bundle 410 is tensioned and fixed;

step seven, mounting the prefabricated plate 310: hoisting the prefabricated slab 310 and temporarily fixing the prefabricated slab 310;

eighthly, arranging the first ends of the bending-resistant energy-consuming steel bars 430 in the post-beam casting layer 220, and arranging the second ends of the bending-resistant energy-consuming steel bars 430 in the upper bracket layer 230 and connecting the second ends with the anchoring steel bars 130; the first end of the shear reinforcement 440 is arranged in the post-cast beam layer 220, and the second end of the shear reinforcement 440 is arranged in the upper bracket layer 230; and forms a corbel upper layer 230, a beam post-cast layer 220, and a slab post-cast layer 320.

It should be noted that, the order of installing the bending-resistant energy-consuming steel bars 430, installing the shear-resistant steel bars 440, forming the upper bracket layer 230, forming the post-cast beam layer 220, and forming the post-cast plate layer 320 in the step eight is not limited herein.

Specifically, when the upper bracket layer 230 is the rear bracket pouring layer 231 and the rear bracket pouring layer 231, the rear beam pouring layer 220 and the plate thickness glue layer are integrally cast and formed, the eight steps include: paving bending-resistant energy-consuming steel bars 430 and shear-resistant steel bars 440 at the positions of the post-beam-casting layer 220 and the bracket post-casting layer 231, fixedly connecting the second ends of the bending-resistant energy-consuming steel bars 430 with the position of the bracket post-casting layer 231 of the anchoring steel bars 130, and enabling the shear-resistant steel bars 440 to be positioned above the joints between the brackets 120 and the precast beams 210, namely the first ends of the shear-resistant steel bars 440 are positioned at the position of the post-beam-casting layer 220, and the second ends of the shear-resistant steel bars 440 are positioned at the position of the bracket post-casting layer 231; and integrally pouring and molding the bracket post-pouring layer 231, the beam post-pouring layer 220 and the plate post-pouring layer 320, and curing the bracket post-pouring layer 231, the beam post-pouring layer 220 and the plate post-pouring layer 320 after pouring is finished.

Specifically, when the upper bracket layer 230 is a prefabricated bracket layer 232 and the prefabricated bracket layer 232, the bracket 120 and the prefabricated column body 110 are integrally formed, the eighth step includes: the second ends of the anchor bars 130 and the shear bars 440 are both pre-embedded in the corbel precast layer 232 and extend to be tightly attached to the outer side wall of the corbel precast layer 232, the bending-resistant energy-consuming bars 430 are laid at the position of the post-beam casting layer 220, the second ends of the bending-resistant energy-consuming bars 430 and the second ends of the anchor bars 130 are fixedly connected in the corbel precast layer 232, and the first ends of the shear bars 440 and the second ends of the shear bars 440 are fixedly connected in the corbel precast layer 232; and integrally pouring and molding the post-beam pouring layer 220 and the post-plate pouring layer 320, and curing the post-beam pouring layer 220 and the post-plate pouring layer 320 after pouring is finished.

In the construction method provided by this embodiment, a temporary support may be first disposed on the precast column 100, the precast beam 210 is supported during the construction stage, then, a bonding layer 420 is filled in a gap between the precast beam 210 and the corbel 120, after the strength requirement is met, the precast beam 210 and the precast column 100 are tensioned and fastened by using a post-tensioned prestressed reinforcement bundle 410 to form a primary stable stress system, then, the precast slabs 310 are installed and temporarily fixed, then, the bending-resistant energy-consuming reinforcements 430 and the shear reinforcements 440 are installed between two adjacent precast slabs 310, when the corbel upper layer 230 is the corbel precast layer 232, the precast beam post-cast layer 220 is poured between two adjacent precast slabs 310, the slab post-cast layer 320 is poured on the upper surfaces of the precast slabs 310, the corbel upper layer 230 is the corbel post-cast layer 231, the beam post-cast layer 220 and the corbel post-cast layer 231 are poured between two adjacent precast slabs 310, and the slab post-cast layer 320 is poured on the upper surfaces of the precast slabs 310 at the same time, and the whole construction process is simple, low in process, high in efficiency and short in cycle.

In another embodiment of the present application, referring to fig. 1, the anti-bending energy-consuming steel bars 430 are arranged in a column in a bonding manner, and the first ends of the anchoring steel bars 130 are embedded and anchored in the prefabricated column body 110. The bending-resistant energy-consuming reinforcing steel bars 430 are arranged in a partially unbonded or column-outside fully bonded manner.

Specifically, referring to fig. 1, when the upper layer 230 of the bracket is the post-cast layer 231 of the bracket, the specific manner of setting the bending-resistant energy-consuming steel bars 430 in a partially unbonded or post-outer fully bonded manner is as follows: the second ends of the anchoring steel bars 130 and the second ends of the bending-resistant energy-consuming steel bars 430 are both poured in the bracket post-cast layer 231, and the first ends of the bending-resistant energy-consuming steel bars 430 are poured in the beam post-cast layer 220;

specifically, referring to fig. 9, when the upper layer 230 of the bracket is the prefabricated layer 232 of the bracket, the specific manner of arranging the bending-resistant energy-consuming steel bars 430 in a partially unbonded or fully bonded manner outside the column is as follows: the second end of the anchoring bar 130 is pre-buried in the corbel pre-cast layer 232 and extends to closely adhere to the outer side wall of the corbel pre-cast layer 232, the first end of the anti-bending energy dissipation bar 430 is cast in the post-beam casting layer 220, and the second end of the anti-bending energy dissipation bar 430 is connected to the second end of the anchoring bar 130.

The cantilever type prestressing force crimping assembled concrete frame of bracket that this embodiment provided, bending resistance power consumption reinforcing bar 430 can not carry out the processing of unbonded weakening, and the site operation degree of difficulty is low, and the flexible operation, simple process.

In another embodiment of the present application, referring to fig. 8 and 9, when the upper bracket layer 230 is a prefabricated bracket layer 232, the upper bracket layer 230 has a slope surface 233, the prefabricated concrete frame is further comprised of a frame support 500 extended from the bracket, one end of the frame support 500 is connected to the slope surface 233, and the other end of the frame support 500 is used to connect to the bottom of another precast beam 210 located above the precast beam 210.

It should be noted that the frame support 500 may be a concrete support, a steel support, or a buckling restrained brace, and may be disposed as required, which is not limited herein. The frame support 500 and the bracket 120 may be connected by welding, bolting, etc., and may be disposed as required, but is not limited thereto.

The overhanging type prestressing force crimping assembled concrete frame of bracket that this embodiment provided, when 230 in bracket upper strata are bracket prefabricated layer 232, set up domatic 233 on 230 in bracket upper strata, make the operation of being connected between frame brace 500 and the bracket 120 more simple convenient, and increase frame brace 500 and regard as frame construction's anti lateral force system, can make frame construction use in high-rise assembled building better, application scope is wider.

In another embodiment of the present application, referring to fig. 1, as a specific implementation manner of fixing the pre-cast column 100 and the pre-cast beam 210 by the post-tensioned prestressed reinforcement bundle 410, the pre-cast column 100 is further provided with a column prestressed reinforcement hole 111 horizontally penetrating through the pre-cast column body 110 and the bracket 120, the pre-cast beam 210 is provided with a beam prestressed reinforcement hole 211 parallel to and communicated with the column prestressed reinforcement hole 111, the connection assembly 400 further includes a prestressed anchor 450, the post-tensioned prestressed reinforcement bundle 410 is inserted into the column prestressed reinforcement hole 111 and the beam prestressed reinforcement hole 211, and an end of the post-tensioned prestressed reinforcement bundle 410 extending out of the pre-cast column 100 is connected to the prestressed anchor 450 and the pre-cast column 100 and the pre-cast beam 210 are tensioned and fastened by a tensioning device.

Optionally, the post-tensioned prestressed reinforcement bundles 410 are located within 1/2 of the middle to lower portion of the cross-section of the precast beam 210. Because the bending-resistant energy-consuming steel bars 430 are arranged in the post-beam casting layer 220 of the composite beam 200, the post-tensioned prestressed steel bar bundles 410 are arranged in the range from the middle part to 1/2 of the lower part of the cross section of the precast beam 210, so that a part of bending-resistant bearing capacity can be provided for the middle lower part of the composite beam 200, and the seismic performance of the frame structure is improved.

In another embodiment of the present application, referring to fig. 1, the shear bars 440 are disposed below the moment-resistant energy-consuming bars 430, the length of the shear bars 440 above the corbel 120 is not less than 10 times the diameter of the shear bars 440, and the length of the shear bars 440 above the precast girders 210 is not less than 10 times the diameter of the shear bars 440.

According to the corbel overhanging type prestressed compression joint assembly type concrete frame provided by the embodiment, the length of the shear steel bars 440 in the precast columns 100 and the beam post-cast layer 220 is set within a proper range, and the shear steel bars 440 are arranged at proper positions of the cross section of the composite beam 200, so that the shear steel bars 440 can be guaranteed to better bear the shear force at the joint between the precast beam 210 and the corbel 120.

In another embodiment of the present application, referring to fig. 7, the prefabricated column 100 further includes a transverse reinforcement 140, and the transverse reinforcement 140 is used for connecting the prefabricated column body 110 and the bracket 120. Specifically, one end of the transverse steel bar 140 is disposed in the prefabricated column body 110, and the other end of the transverse steel bar 140 extends to the corbel 120 and then extends back into the prefabricated column body 110. The integrity of beam column joints of the corbel overhanging type prestress compression joint assembly type concrete frame can be improved.

In another embodiment of the present application, referring to fig. 10 and 11, the preformed column body 110 and the cross section are circular or polygonal, a plurality of brackets 120 are disposed on the preformed column body 110, and an included angle between two adjacent brackets 120 is an acute angle or an obtuse angle.

It should be noted that the cross section of the prefabricated column body 110 may be a circular, square, rectangular or other polygonal structure, and may be configured as required, which is not limited herein. The cross section of the precast column 100 is square; as another example, the preformed post 100 may be circular in cross-section.

As mentioned above, the number of the corbels 120 may be two, three, etc., and may be set according to the requirement, and the two adjacent corbels 120 may be set to form an acute angle or an obtuse angle with each other, besides being able to be orthogonally set. For example, two brackets 120 are disposed on the side of the prefabricated column 100, and the included angle between the brackets 120 is an acute angle. Similarly, when the number of the corbels 120 is plural, the plurality of post-tensioning prestressed reinforcement bundles 410 corresponding to the plurality of corbels 120 are arranged in a staggered manner in the height direction of the precast column 100, and the plurality of anchor reinforcements 130 corresponding to the plurality of corbels 120 are also arranged in a staggered manner in the height direction of the precast column 100, so as to avoid interference with each other.

The corbel overhanging type prestress compression joint assembly type concrete frame provided by the embodiment is suitable for non-orthogonal connection of the prefabricated columns 100 and the superposed beams 200 with special-shaped building planes and various shapes of cross sections, and is good in adaptability.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. The utility model provides an overhanging type prestressing force crimping assembled concrete frame of bracket, its characterized in that, the overhanging type prestressing force crimping assembled concrete frame of bracket includes:

the prefabricated column comprises a prefabricated column body, a bracket and an anchoring steel bar, wherein the bracket extends outwards from the side part of the prefabricated column body, and the first end of the anchoring steel bar is arranged in the prefabricated column body;

the composite beam comprises a precast beam, a beam post-pouring layer and a bracket upper layer, the precast beam is connected to the outer end of the bracket, the beam post-pouring layer is arranged on the upper surface of the precast beam, the bracket upper layer is arranged on the upper surface of the bracket, and the second end of the anchoring steel bar is arranged in the bracket upper layer;

the composite floor slab comprises a precast slab and a slab post-pouring layer, the edge of the precast slab is supported on the precast beam, and the slab post-pouring layer is arranged on the upper surface of the precast slab and is integrally poured with the beam post-pouring layer; and

the post-tensioned prestressed reinforcement bundle sequentially penetrates through the precast column body, the bracket and the precast beam and is used for tensioning and fixing the precast column and the precast beam; the bonding layer is arranged at the joint of the bracket and the precast beam and is used for bonding the bracket and the precast beam; the first end of the bending-resistant energy-consuming steel bar is arranged in the post-beam casting layer, and the second end of the bending-resistant energy-consuming steel bar extends into the upper layer of the bracket and is connected with the second end of the anchoring steel bar; the first end of the shear steel bar is arranged on the beam post-pouring layer, and the second end of the shear steel bar is arranged on the upper layer of the bracket.

2. The corbel overhanging prestressed compression joint assembly type concrete frame as claimed in claim 1, wherein the bending-resistant energy-consuming steel bars are arranged in a manner of bonding in the column, and the first ends of the anchoring steel bars are embedded and anchored in the prefabricated column body.

3. The corbel overhanging prestressed compression joint fabricated concrete framework as claimed in claim 1, wherein the corbel upper layer is a corbel post-cast layer, and the corbel post-cast layer is integrally cast with the beam post-cast layer and the slab post-cast layer; or, the bracket upper strata is the prefabricated layer of bracket, the prefabricated layer of bracket with prefabricated post body with the integrative prefabrication of bracket forms.

4. The corbel overhanging type prestressed compression joint fabricated concrete framework as claimed in claim 3, wherein the bending-resistant energy-consuming reinforcing steel bars are arranged in a partially unbonded or column-outside fully bonded form;

when the upper bracket layer is a rear bracket pouring layer, the second ends of the anchoring steel bars and the second ends of the bending-resistant energy-consuming steel bars are both poured in the rear bracket pouring layer, and the first ends of the bending-resistant energy-consuming steel bars are poured in the rear beam pouring layer;

when the bracket upper strata was the prefabricated layer of bracket, the second end of anchor reinforcing bar pre-buried in the bracket upper strata and extend to hug closely the lateral wall on the prefabricated layer of bracket, the first end of bending resistance power consumption reinforcing bar is pour in the roof beam post-cast layer, the second end of bending resistance power consumption reinforcing bar connect in the second end of anchor reinforcing bar.

5. The cantilever type prestressed crimping fabricated concrete frame of claim 3, wherein when the upper bracket layer is a prefabricated bracket layer, the prefabricated bracket layer has a slope surface, the cantilever type prestressed crimping fabricated concrete frame further comprises a frame support, one end of the frame support is connected to the slope surface, and the other end of the frame support is used for connecting the bottom of another precast beam above the prefabricated bracket layer.

6. The corbel overhanging prestressed compression joint fabricated concrete framework as claimed in claim 1, wherein the shear reinforcement is disposed under the anti-bending energy dissipation reinforcement, the length of the shear reinforcement above the corbel is not less than 10 times the diameter of the shear reinforcement, and the length of the shear reinforcement above the precast girders is not less than 10 times the diameter of the shear reinforcement.

7. The cantilever-type prestressed compression-joint assembled concrete frame of a corbel according to claim 1, wherein a column prestressed tendon duct horizontally penetrating through the precast column body and the corbel is further arranged in the precast beam, a beam prestressed tendon duct parallel to the column prestressed tendon duct is further arranged in the precast beam, the connecting assembly further comprises a prestressed anchorage device, the post-tensioned prestressed tendon is arranged in the column prestressed tendon duct and the beam prestressed tendon duct in a penetrating manner, and the end portion of the post-tensioned prestressed tendon extending out of the precast column is connected to the prestressed anchorage device and is fastened to the precast column and the precast beam through a tensioning device.

8. The corbel overhanging prestressed crimp fabricated concrete framework as claimed in claim 1, wherein the precast column body and the cross-section are circular or polygonal; be equipped with a plurality ofly on the prefabricated post body the bracket, adjacent two the contained angle scope between the bracket is acute angle or obtuse angle.

9. The corbel overhanging prestressed crimp fabricated concrete framework as claimed in claim 1, wherein the post-tensioned prestressed tendons are located within 1/2 of a lower portion of a cross-section of the precast beams.

10. The corbel overhanging prestressed crimp fabricated concrete frame of any one of claims 1-9, further comprising at least one of:

the width of a joint between the bracket and the precast beam is 10-30 mm; and

prefabricated post still includes horizontal reinforcing bar, horizontal reinforcing bar one end is located prefabricated this internal, the other end of horizontal reinforcing bar is located in the bracket.

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