CN212656384U - High-strength concrete connecting piece, high-strength concrete post-cast assembled frame system and support frame - Google Patents

High-strength concrete connecting piece, high-strength concrete post-cast assembled frame system and support frame Download PDF

Info

Publication number
CN212656384U
CN212656384U CN202020959670.7U CN202020959670U CN212656384U CN 212656384 U CN212656384 U CN 212656384U CN 202020959670 U CN202020959670 U CN 202020959670U CN 212656384 U CN212656384 U CN 212656384U
Authority
CN
China
Prior art keywords
column
frame
support
strength concrete
post
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN202020959670.7U
Other languages
Chinese (zh)
Inventor
马荣全
和超
赵卫
孙伯禹
王洪强
吴迪
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Sany Construction Technology Co Ltd
Original Assignee
Sany Construction Technology Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Sany Construction Technology Co Ltd filed Critical Sany Construction Technology Co Ltd
Priority to CN202020959670.7U priority Critical patent/CN212656384U/en
Application granted granted Critical
Publication of CN212656384U publication Critical patent/CN212656384U/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Abstract

The present disclosure provides a high-strength concrete connecting member, including: the connecting piece is prefabricated by high-strength concrete; a column support 15 with a rectangular cross section and a beam support 14 with a U-shaped cross section; the column support 15 is a tubular shape which is penetrated up and down, and the plurality of beam supports 14 are respectively positioned on the side surface of the column support 15 and communicated with the column support 15; and the beam supports 14 are used for embedding at least a part of the frame beam 5; the column bracket 15 is used for connection between frame columns. The present disclosure also provides a high strength concrete post-cast fabricated frame system. And the cracking resistance of the reinforced concrete member is improved by adopting a UHPC joint connecting piece and a post-pouring mode.

Description

High-strength concrete connecting piece, high-strength concrete post-cast assembled frame system and support frame
Technical Field
The disclosure relates to the field of assembly type buildings, in particular to a high-strength concrete connecting piece and an assembly type frame system for post-pouring of high-strength concrete.
Background
Building industrialization is the key point of construction and development in recent years, and comprises the steps of vigorously popularizing assembly type buildings, encouraging assembly type construction of building enterprises, building national assembly type building production bases, improving the proportion of assembly type buildings to newly built buildings and the like. The fabricated building refers to a building fabricated at a construction site using prefabricated parts. In recent years, the development of assembly type buildings in China is rapid, a novel assembly type structure system is arranged in a lot of flowers, a vertical bearing structure is designed to be prefabricated walls, prefabricated columns are connected by grouting sleeves or sleeve connectors, a horizontal structure is formed by prefabricated superposed beams and superposed floors, grooves are reserved at the bottoms of prefabricated solid columns in the prior art, sleeves are reserved in the grooves, upper column steel bars are connected by the sleeves, lower column steel bars extend into the grooves and are connected by grouting materials after extending into the grooves and sleeves; the prefabricated cavity column is exposed at the connecting position of the steel bars, and the upper steel bars and the lower steel bars are connected by adopting a sleeve connecting piece. The grouting material can not be observed when being injected into the connecting mode of the prefabricated solid column, the construction quality is difficult to guarantee, and the cost of the sleeve connecting piece of the prefabricated cavity column is high. The prefabricated column and the superposed beam are connected at the joint position, because the number of the steel bars is large, the difficulty is increased in the hoisting and positioning process of the prefabricated beam, and the cost is too high by adopting the beam column steel bar sleeve connecting piece. Therefore, how to find a connecting member for precast concrete units, which is suitable for solving the above problems in the process of prefabrication, and which can self-support the precast concrete units during construction, is of great significance in building industrialization.
SUMMERY OF THE UTILITY MODEL
To solve at least one of the above technical problems, the present disclosure provides a novel fabricated structural system and a construction method using high strength concrete post-cast.
According to one aspect of the present disclosure, a high-strength concrete connection member is prefabricated from high-strength concrete;
comprises a column support 15 with a rectangular cross section and a beam support 14 with a U-shaped cross section;
the column support 15 is a tubular shape which is penetrated up and down, and the plurality of beam supports 14 are respectively positioned on the side surface of the column support 15 and communicated with the column support 15; and
the beam support 14 is used for embedding at least one part of the frame beam 5;
the column bracket 15 is used for connection between frame columns.
According to another aspect of the present disclosure, there is provided a high strength concrete post cast fabricated frame system comprising: the high-strength concrete connecting piece, the frame column and the U-shaped frame beam 5,
the frame column comprises an upper column 1 and a lower column 2, the frame column is prefabricated by concrete and provided with a cavity, and reinforcing steel bars extend out of two ends of the frame column;
the upper column 1 is above and aligned with the lower column 2, so that the upper column steel bars 3 and the lower column steel bars 4 form a complete lap joint;
the upper column steel bar 3 and the lower column steel bar 4 penetrate through the column support 15;
the bottom of the frame beam 5 is flush with the top end of the lower column 2;
and high-strength concrete is at least poured at the lap joint of the upper column reinforcing steel bars 3 and the lower column reinforcing steel bars 4 and in the cavity of the frame beam 5 to the top of the frame beam 5 to form a beam-column connecting node.
According to at least one embodiment of the present disclosure, at least a portion of the frame beam 5 is embedded in the beam-support 14 and forms a fixed connection with the frame column by post-cast high strength concrete.
According to at least one embodiment of the present disclosure, further comprising a precast floor slab,
the precast floor slabs are arranged on the frame beams 5 and are fixedly connected with the frame beams 5 through post-poured concrete.
According to at least one embodiment of the present disclosure, the frame beam 5 is spaced apart from the frame column in the horizontal direction to form a reserved space, and a beam stirrup 6 and a beam upper layer additional rib 10 are further provided in the reserved space.
According to at least one embodiment of the present disclosure, the frame beam 5 is further provided with U-shaped stirrups 17 and beam lower-layer additional ribs 11.
According to at least one embodiment of the present disclosure, the frame rail 5 is further provided with an upper stirrup 18 and a beam wale 9.
According to still another aspect of the present disclosure, there is provided a supporting frame for use in the above-mentioned high-strength concrete post-cast fabricated frame system,
the support frame 13 is of a truss structure, one end of the support frame 13 is fixedly connected with the upper column 1, and the other end of the support frame 13 is fixedly connected with the lower column 2.
According to at least one embodiment of the present disclosure, further comprising a first end plate and a second end plate,
the first end plate is fixedly connected to the upper column 1, and one end of the support frame 13 is fixedly connected with the first end plate; and
the second end plate is fixedly connected to the lower column 2, and the other end of the support frame 13 is fixedly connected to the second end plate.
According to at least one embodiment of the present disclosure, the support bracket 13 is plural, and the support bracket 13 is located at the corresponding corner of the upper column 1 and the lower column 2.
According to yet another aspect of the present disclosure, a method of producing a high strength concrete post cast assembled frame system comprises: the frame column comprises an upper column 1 and a lower column 2, is prefabricated by concrete and is provided with a cavity, and two ends of the frame column extend out of steel bars;
pouring concrete into at least the cavity of the lower column 2 to a preset height;
installing the upper column 1 above the lower column 2 and aligning the upper column with the lower column so that the upper column steel bars 3 and the lower column steel bars 4 form complete lap joint to fix the upper column 1;
mounting the frame beam 5 to a predetermined position such that the bottom of the frame beam 5 is flush with the top end of the lower column 2; and
and high-strength concrete is at least poured at the lap joint of the upper column reinforcing steel bars 3 and the lower column reinforcing steel bars 4 and in the cavity of the frame beam 5 to the top of the frame beam 5.
According to at least one embodiment of the present disclosure, the method further comprises prefabricating a floor slab;
hoisting the prefabricated floor slab;
binding the upper reinforcing steel bars of the prefabricated floor slab;
arranging a reserved embedded pipeline on the prefabricated floor slab; and
and pouring concrete to the structural surface.
According to at least one embodiment of the present disclosure, a high strength concrete prefabricated connecting member 12 is further included;
in the step of installing the upper column 1 to the lower column 2 above and aligned such that the upper column reinforcing bars 3 and the lower column reinforcing bars 4 form a full lap joint, fixing the upper column 1,
installing the upper column 1 into the connector 12 and aligning with the lower column 2; and
a support frame 13 is arranged on the upper column 1 to fix the position of the upper column 1, and the other end of the support frame 13 is supported on the lower column 2;
in the step of mounting the frame rails 5 to a predetermined position such that the bottom of the frame rails 5 is flush with the top ends of the lower columns 2,
one end of the frame beam 5 falls into the connecting piece 12.
According to at least one embodiment of the present disclosure, the connecting member 12 includes a column bracket 15 of a rectangular cross section and a beam bracket 14 of a U-shaped cross section;
the column support 15 is a tubular shape which is penetrated up and down, and the plurality of beam supports 14 are respectively positioned on the side surface of the column support 15 and communicated with the column support 15; and a section of the frame beam 5 is embedded in the beam support 14, and the upper column reinforcement 3 and the lower column reinforcement 4 are located in the column support 15.
In accordance with at least one embodiment of the present disclosure, further includes a plurality of diagonal braces 16,
in the step of installing the upper column 1 to the lower column 2 above and aligned such that the upper column reinforcing bars 3 and the lower column reinforcing bars 4 form a full lap joint, fixing the upper column 1,
each diagonal brace 16 is fixedly connected at one end to the upper column 1 and supported at the other end to the frame beam 5.
According to at least one embodiment of the present disclosure, further comprising a beam support,
in the step of mounting the frame rails 5 to a predetermined position such that the bottom of the frame rails 5 is flush with the top ends of the lower columns 2,
the frame beams 5 are mounted to the beam supports.
According to at least one embodiment of the present disclosure, in the step of dropping one end of the frame beam 5 into the connecting member 12,
and placing the upper-layer steel bars 7 of the beam.
According to at least one embodiment of the present disclosure, in the step of mounting the frame beam 5 to a predetermined position such that the bottom of the frame beam 5 is flush with the top end of the lower column 2,
the frame beam 5 is spaced apart from the frame column in the horizontal direction to form a reserved space, and the beam stirrup 6 and the beam upper layer additional rib 10 are placed in the reserved space.
According to at least one embodiment of the present disclosure, in the step of placing the beam stirrup 6 in the reserved space,
the U-shaped stirrups 17 are placed firstly, then the beam lower-layer additional reinforcements 11 are placed, and after all the frame beams 5 are installed, the beam upper-layer additional reinforcements 10 and the upper stirrups 18 are placed.
According to another aspect of the present disclosure, a high-strength concrete connecting member is provided, which is applied to the production method of the assembled frame system for post-pouring of the high-strength concrete.
Drawings
The accompanying drawings, which are included to provide a further understanding of the disclosure and are incorporated in and constitute a part of this specification, illustrate exemplary embodiments of the disclosure and together with the description serve to explain the principles of the disclosure.
Fig. 1 is a schematic diagram of the overall structure of a fabricated frame architecture with connectors according to an embodiment of the present disclosure.
Fig. 2 is a schematic structural view of a fabricated frame system with a support bracket according to an embodiment of the present disclosure.
Fig. 3 is a schematic view of a fabricated frame system connector according to an embodiment of the present disclosure.
Fig. 4 is a schematic illustration of a cross section of a frame beam of a fabricated frame system according to an embodiment of the present disclosure.
Fig. 5 is a schematic structural view with diagonal bracing of a fabricated frame system according to an embodiment of the present disclosure.
Fig. 6 is a schematic view of an embodiment of a method for producing a fabricated frame system.
Fig. 7 is a schematic view of an embodiment of a production method of the fabricated frame system.
Fig. 8 is a third schematic view of an embodiment of a production method of the fabricated frame system.
Reference numerals: 1-upper column; 2-lower column; 3-upper column reinforcement; 4-lower column reinforcement; 5-a frame beam; 6-beam stirrups; 7-upper-layer ribs of the beam; 8-beam lower layer ribs; 9-beam waist tendon; 10-additional ribs are arranged on the upper layer of the beam; 11-adding ribs on the lower layer of the beam; 12-a connector; 13-a support frame; 14-beam support; 15-column support; 16-inclined support; 17-U-shaped ribs; 18-upper stirrups; 19-concrete layer.
Detailed Description
The present disclosure will be described in further detail with reference to the drawings and embodiments. It is to be understood that the specific embodiments described herein are for purposes of illustration only and are not to be construed as limitations of the present disclosure. It should be further noted that, for the convenience of description, only the portions relevant to the present disclosure are shown in the drawings.
It should be noted that the embodiments and features of the embodiments in the present disclosure may be combined with each other without conflict. The present disclosure will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.
The vertical bearing structure of the prefabricated concrete structure system adopts the prefabricated concrete superposed column member, the horizontal structure adopts the precast beam, the whole structure is safe and reliable, the assembly rate is high, and the prefabricated concrete structure system accords with the industrialized development trend of prefabricated and standardized buildings. The connection node adopts a UHPC (Ultra-High Performance Concrete) High-Performance Concrete connector and pouring, so that the reinforced Concrete member has good compression resistance, tensile resistance and shear resistance. The method solves the technical problems that the existing precast concrete column and beam column connection mode has the defects of high construction quality control difficulty, long construction period, low tensile strength, poor anti-seismic performance, poor ductility under the action of earthquake and easy brittle failure. The frame column is a Concrete prefabricated cavity column, the cavity column is prefabricated in a PC (Precast Concrete) factory, Concrete wrapping steel bars are arranged on the periphery of the middle section of the cavity column, and the steel bars at two ends of the cavity column are exposed. The frame beam can adopt one or more of a superposed beam and a pretensioned prestressing frame beam; the connecting piece is prefabricated by UHPC high-strength concrete.
According to the first embodiment of the disclosure, a novel assembly type structure system and a construction method using high-strength concrete post-cast are provided, and the technical problems that the construction quality control difficulty is high, the construction period is long, the tensile strength is low, the anti-seismic performance is poor, the extension performance under the action of an earthquake is poor, and brittle failure is easy to occur in the existing connection mode of the precast concrete column and a beam column are solved. As shown in fig. 2, which is a schematic structural diagram of an assembled frame system with a supporting frame according to an embodiment of the present disclosure, and fig. 5, which is a schematic structural diagram of an assembled frame system with an inclined support, the assembled frame system includes a frame column and a U-shaped frame beam 5, the frame column includes an upper column 1 and a lower column 2, the frame column is prefabricated with a cavity for concrete, and two ends of the frame column both extend out of a steel bar; pouring concrete into at least the cavity of the lower column 2 to a preset height; installing the upper column 1 above the lower column 2 and aligning the upper column with the lower column so that the upper column steel bars 3 and the lower column steel bars 4 form complete lap joint to fix the upper column 1; mounting the frame beam 5 to a predetermined position such that the bottom of the frame beam 5 is flush with the top end of the lower column 2; and high-strength concrete is at least poured at the lap joint of the upper column reinforcing steel bars 3 and the lower column reinforcing steel bars 4 and in the cavity of the frame beam 5 to the top of the frame beam 5. The upper column 1 to the lower column 2 are prefabricated in a PC (precast concrete member) factory, concrete wrapping steel bars are arranged around the middle section of the frame column, and the steel bars at two ends of the cavity column are exposed to form a rib part. The frame beam 5 can adopt one or more of a superposed beam and a pretensioned prestressed frame beam.
According to at least one embodiment of this disclosure, still include prefabricated floor, hoist and mount prefabricated floor, ligature prefabricated floor upper portion reinforcing bar accomplishes pre-buried reservation of water and electricity pipeline on the floor and arranges to concreting to the structural plane.
Optionally, as shown in fig. 1, which is a schematic view of an overall structure of an assembled frame system with connecting members according to an embodiment of the present disclosure, a connecting member 12 is further included, a specific structure of the connecting member 12 is as shown in the schematic view of the connecting member of the assembled frame system of fig. 3, and the connecting member 12 is prefabricated by high-strength concrete, and is used for fixing a connecting node between a frame column and a frame beam and can be used as a formwork when concrete is poured. The connecting piece 12 comprises a column support 15 with a rectangular cross section and beam supports 14 with a U-shaped cross section, the column support 15 is in a tubular shape which is penetrated up and down, the beam supports 14 are respectively positioned on the side surfaces of the column support 15 and are communicated with the column support 15, for example, if the column support 15 is in a rectangular cross section, 4 beam supports 14 are respectively positioned on the side surfaces of the column support 15; and a section of the frame beam 5 is embedded in the beam holder 14, and at least a part or all of the upper column reinforcing bars 3 and the lower column reinforcing bars 4 are located in the column holder 15. Installing upper portion post 1 to lower part post 2 top and adjusting well for upper portion post reinforcing bar 3 and lower part post reinforcing bar 4 form whole overlap joint, in the step of fixed upper portion post 1, included in installing upper portion post 1 to connecting piece 12 and adjusting well lower part post 2, use and use tower crane or travelling crane with upper portion post 1 handling to the operation face, slowly fall, make upper portion post 1 and the tip of lower part post 2 expose the reinforcing bar and all form the overlap joint. And continues to fall down so that the upper column 1 is aligned with the beam-column node connecting piece 12 and falls into the column bracket 15 of the connecting piece 12; in the step of mounting the frame beam 5 to a predetermined position such that the bottom of the frame beam 5 is flush with the top end of the lower column 2, one end of the frame beam 5 is dropped into the beam bracket 14 of the connecting member 12. A plurality of frame beams 5 each having one end of the frame beam 5 dropped into the beam holder 14 of the connecting member 12.
According to at least one embodiment of the present disclosure, as shown in fig. 1 to 2, the present disclosure further includes a supporting frame 13, one end of the supporting frame 13 is fixed on the upper column 1 through a frame structure, the other end of the supporting frame 13 is fixed on the lower column 2 through a frame structure, the supporting frame 13 is a truss structure, which can ensure stability, and the supporting frame 13 can fix the relative position of the upper column 1 and the lower column 2, so that the upper column 1 is maintained at the installation position. The use of the support frame 13 is not dependent on whether the frame beam 5 is installed or not, and therefore, the support frame 13 can be applied to an installation process using the connecting member 12 (as shown in fig. 1) or an installation process not using the connecting member 12 (as shown in fig. 2), the end of the support frame 13 is disposed at the corner position of the upper column 1 or the lower column 2, and the frame beam 5 can be avoided, so that the installation of the frame beam 5 is not interfered by the support frame.
According to at least one embodiment of the present disclosure, as shown in fig. 5, a plurality of diagonal braces 16 are further included, the diagonal braces 16 are respectively installed above the upper column 1 to the lower column 2 and aligned so that the upper column reinforcing bars 3 and the lower column reinforcing bars 4 form a complete lap joint, in the step of fixing the upper column 1, each diagonal brace 16 is respectively connected with the tops of the upper column 1 and the frame beam 5, the diagonal braces 16 are after the frame beam 5 is completely installed in place so that the upper column 1 can be fixed in place by the diagonal braces 16 depending on the frame beam 5, the upper column 1 reinforcing bars 3 and the reinforcing bars 4 of the lower column 2 form a complete lap joint, and the upper column 1 is aligned to the lower column 2. When the beam-column node is 4 frame beams, 4 inclined supports 16 can be arranged on the upper column 1 for fixing and supporting the upper column 1.
According to at least one embodiment of the present disclosure, there is further included a beam support for supporting the frame beam 5 to a predetermined position, that is, a position where the bottom of the frame beam 5 is flush with the top of the lower column 2, in the step of mounting the frame beam 5 to the predetermined position, that is, the bottom of the frame beam 5 is flush with the top of the lower column 2, although not shown in fig. 5, according to the present disclosure, the beam support may be a reinforcing frame, a scaffold, or the like, which may support the entire frame beam 5 from below until the entire beam column node is cured by high strength concrete pouring, and then may be removed.
According to at least one embodiment of the present disclosure, during the step of dropping one end of the frame girder 5 into the connector 12, as shown in fig. 1 and 5, a girder upper layer reinforcing bar 7 is further placed on top of the frame girder 5. In the step of installing the frame beam 5 to a preset position, so that the bottom of the frame beam 5 is flush with the top end of the lower column 2, the frame beam 5 is spaced from the frame column in the horizontal direction to form a reserved space, then the beam stirrups 6 and the beam upper-layer additional ribs 10 are placed in the reserved space, in the step of placing the beam stirrups 6, the U-shaped stirrups 17 are placed firstly, then the beam lower-layer additional ribs 11 are placed, and after all the frame beams 5 are installed, the beam upper-layer additional ribs 10 and the upper-layer additional ribs 18 are placed. And after all the steel bars are placed, pouring high-strength concrete to the top of the frame beam at the beam-column joint or pouring the high-strength concrete to the structural surface when a floor slab exists to complete the construction of the whole beam-column joint, and performing the construction of the next layer.
According to another aspect of the present disclosure, a high-strength concrete connecting member is provided, which is applied to the production method of the assembled frame system for post-pouring of the high-strength concrete. The connecting member 12 is prefabricated from high-strength concrete.
The connecting piece and the production method of the assembly type frame structure system for post-pouring of the high-strength concrete,
(1) the vertical bearing structure of the prefabricated concrete structure system adopts a prefabricated concrete superposed column member, the horizontal structure adopts a prefabricated beam, the whole structure is safe and reliable, the assembly rate is high, and the prefabricated concrete structure system conforms to the industrialized development trend of prefabricated and standardized buildings;
(2) the assembled prefabricated cavity column integral member in the structural system has light weight, the using amount of the template is reduced by 90 percent, and the hoisting construction is convenient; and the field constructors are reduced. Concrete is poured in the cavity area to form a stressed member of the superposed column, so that the industrialized development trend of assembled buildings is met;
(3) the UHPC has good compression resistance, tensile resistance and shear resistance, and the joint connecting piece and the post-pouring mode of the UHPC are adopted, so that the anti-cracking performance of the reinforced concrete member is improved, and the early crack of the reinforced concrete member is avoided;
(4) the structural concept of strong node weak members and strong columns and weak beams is met.
The method for producing the above-described high-strength concrete post-cast fabricated framed structural system will be described in detail with reference to specific embodiments.
The production method specifically comprises the following steps:
s1, pouring lower column concrete to an appointed height: filling concrete into the hollow cavity of the hollow column to a specified height by using pumping equipment;
s2, placing a node connecting piece on the lower prefabricated column: the lower prefabricated column is provided with a beam column node connecting piece and is reliably connected with the lower prefabricated column;
s3, hoisting an upper prefabricated column: and hoisting the upper prefabricated column to the operation surface by using a tower crane or a mobile crane, and slowly dropping the upper prefabricated column to ensure that the upper prefabricated column and the lower prefabricated column steel bars are completely overlapped. Continuously falling to enable the upper prefabricated column to be aligned with the beam-column joint connecting piece;
s4, mounting a support frame: placing a support frame for supporting the upper prefabricated column, wherein if the prefabricated beam is installed at the moment, the support frame is supported at the top of the prefabricated beam, and if the prefabricated beam is not installed, the support frame is supported at the lower prefabricated column;
s5, hoisting the prefabricated frame beam: the handling prefabricated frame roof beam, frame roof beam one end probably directly falls into the post within range, also can reserve space, lets have the certain distance on roof beam and the post horizontal plane, and the hoist and mount of prefabricated frame roof beam fall into in beam column node connecting piece or fall into the beam brace. If the beam and the column are at a certain distance, placing beam stirrups and upper-layer additional steel bars of the precast beam in the reserved space, and if the beam and the column are not at a certain distance, placing the upper-layer steel bars. Optionally, the beam stirrups are formed by firstly placing the U-shaped stirrups, then placing the lower-layer additional steel bars of the precast beams, and then placing the upper-layer additional steel bars and the upper-layer stirrups of the precast beams after all the precast frame beams are hoisted;
s6, pouring UHPC to the top of the precast beam: using UHPC high-strength concrete to pour the node to the top of the precast beam;
s7, binding and reserving pre-buried hoisting plates and floor slab steel bars: hoisting the precast slabs, completing the reservation and pre-burying of the water and electricity pipelines on the floor slab and the binding of upper reinforcing steel bars;
and S8, pouring concrete to the structural surface.
Example one
A method of producing a fabricated frame system as shown in fig. 6, comprising:
s1, pouring concrete into a cavity of a lower column 2 to a specified height;
s2, placing and fixing a connecting piece 12 on the lower column 2;
s3, hoisting the upper column 1 to a preset position (for example, aligning with the lower column);
s4, mounting a support frame of the frame beam 5;
s5, hoisting the frame beam 5 to a support frame;
s6, pouring UHPC to the top of the frame beam 5;
s7, hoisting the floor slab, binding the floor slab reinforcing steel bars, reserving pre-buried pipeline grooves on the floor slab and the like;
and S8, pouring concrete to the structural surface.
Wherein the steps of S6 and S7 are interchanged.
Example two
A method of producing a fabricated frame system as shown in fig. 7, comprising:
s1, pouring concrete into a cavity of a lower column 2 to a specified height;
s2, placing and fixing a connecting piece 12 on the lower column 2;
s3, installing a frame beam 5 and a floor support;
s4, hoisting the frame beam 5 to a support frame;
s5, pouring UHPC to the top of the frame beam 5;
s6, hoisting the floor slab, binding reinforcing steel bars of the floor slab, reserving a pre-buried pipeline groove on the floor slab and the like;
s7, pouring concrete to a structural surface;
s8, hoisting the upper column 1 to a preset position (for example, aligning with the lower column).
Wherein the steps of S5 and S6 are interchanged.
EXAMPLE III
A method of producing a fabricated frame system as shown in fig. 8, comprising:
s1, installing a frame beam 5 and a floor support;
s2, hoisting the frame beam 5 to a specified position;
s3, erecting a frame beam 5 and a frame column template;
s4, pouring concrete into a cavity of the lower column 2 to a specified height;
s5, pouring UHPC to the top of the frame beam 5;
s6, hoisting the floor slab, binding reinforcing steel bars of the floor slab, reserving a pre-buried pipeline groove on the floor slab and the like;
s7, pouring concrete to a structural surface;
s8, hoisting the upper column 1 to a preset position (for example, aligning with the lower column).
Wherein the steps of S5 and S6 are interchanged.
In the description herein, reference to the description of the terms "one embodiment/mode," "some embodiments/modes," "example," "specific example," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment/mode or example is included in at least one embodiment/mode or example of the application. In this specification, the schematic representations of the terms used above are not necessarily intended to be the same embodiment/mode or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments/modes or examples. Furthermore, the various embodiments/aspects or examples and features of the various embodiments/aspects or examples described in this specification can be combined and combined by one skilled in the art without conflicting therewith.
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 at least one such feature. In the description of the present application, "plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.
It will be understood by those skilled in the art that the foregoing embodiments are merely for clarity of illustration of the disclosure and are not intended to limit the scope of the disclosure. Other variations or modifications may occur to those skilled in the art, based on the foregoing disclosure, and are still within the scope of the present disclosure.

Claims (10)

1. A high-strength concrete connecting piece is characterized in that,
the connecting piece is prefabricated by high-strength concrete;
comprises a column support (15) with a rectangular section and a beam support (14) with a U-shaped section;
the column support (15) is in a tubular shape which is through up and down, and the beam supports (14) are respectively positioned on the side surface of the column support (15) and communicated with the column support (15); and
the beam supports (14) are used for embedding at least one part of the frame beam (5);
the column supports (15) are used for connecting the frame columns.
2. The utility model provides an assembled frame system of high-strength concrete post-cast which characterized in that includes: high strength concrete connection, frame column and U-frame beam (5) according to claim 1,
the frame column comprises an upper column (1) and a lower column (2), wherein the frame column is prefabricated by concrete and provided with a cavity, and reinforcing steel bars extend out of two ends of the frame column;
the upper column (1) is above and aligned with the lower column (2) so that the upper column steel bars (3) and the lower column steel bars (4) form a complete lap joint;
the upper column steel bar (3) and the lower column steel bar (4) penetrate through the column support (15);
the bottom of the frame beam (5) is flush with the top end of the lower column (2);
and high-strength concrete is at least poured at the lap joint of the upper column reinforcing steel bar (3) and the lower column reinforcing steel bar (4) and in the cavity of the frame beam (5) to the top of the frame beam (5) to form a beam-column connecting node.
3. The high strength concrete post cast fabricated frame system of claim 2,
at least a part of the frame beam (5) is embedded in the beam support (14) and forms a fixed connection with the frame column through the post-cast high-strength concrete.
4. The high strength concrete post cast fabricated frame system of claim 2, further comprising precast floor slabs,
the precast floor slabs are arranged on the frame beams (5) and are fixedly connected with the frame beams (5) through post-poured concrete.
5. The high strength concrete post cast fabricated frame system of claim 2,
the frame beam (5) and the frame column are spaced in the horizontal direction to form a reserved space, and a beam stirrup (6) and a beam upper-layer additional rib (10) are further arranged in the reserved space.
6. The high strength concrete post cast fabricated frame system of claim 5,
the frame beam (5) is also provided with U-shaped stirrups (17) and beam lower-layer additional ribs (11).
7. The high strength concrete post cast fabricated frame system of claim 6,
the frame beam (5) is also provided with an upper hoop (18) and a beam waist rib (9).
8. A support frame, characterized in that, when applied to the high-strength concrete post-cast fabricated frame system as claimed in claim 2,
the support frame (13) is of a truss structure, one end of the support frame (13) is fixedly connected with the upper column (1), and the other end of the support frame is fixedly connected with the lower column (2).
9. The support bracket of claim 8 further comprising a first end plate and a second end plate,
the first end plate is fixedly connected to the upper column (1), and one end of the support frame (13) is fixedly connected with the first end plate; and
the second end plate is fixedly connected to the lower column (2), and the other end of the support frame (13) is fixedly connected with the second end plate.
10. A support as claimed in claim 9, wherein the support (13) is plural and the support (13) is located at the corresponding corner of the upper (1) and lower (2) columns.
CN202020959670.7U 2020-05-29 2020-05-29 High-strength concrete connecting piece, high-strength concrete post-cast assembled frame system and support frame Active CN212656384U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202020959670.7U CN212656384U (en) 2020-05-29 2020-05-29 High-strength concrete connecting piece, high-strength concrete post-cast assembled frame system and support frame

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202020959670.7U CN212656384U (en) 2020-05-29 2020-05-29 High-strength concrete connecting piece, high-strength concrete post-cast assembled frame system and support frame

Publications (1)

Publication Number Publication Date
CN212656384U true CN212656384U (en) 2021-03-05

Family

ID=74746562

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202020959670.7U Active CN212656384U (en) 2020-05-29 2020-05-29 High-strength concrete connecting piece, high-strength concrete post-cast assembled frame system and support frame

Country Status (1)

Country Link
CN (1) CN212656384U (en)

Similar Documents

Publication Publication Date Title
CN111576619A (en) Production method of high-strength concrete post-cast assembled frame system
EA029731B1 (en) Method of casting in-situ steel wire mesh cement slab with spliced rack and suspended formwork
CN111188457A (en) Edge sealing beam structure of super high-rise steel structure building and construction method
CN206769200U (en) First wear formula post stretching vertical prestressing cast-in-place concrete rod structure
CN212656384U (en) High-strength concrete connecting piece, high-strength concrete post-cast assembled frame system and support frame
KR20070023274A (en) PC Integrating Construction Method of an Underground Parking Lot and PC Column-Beam Joint System for Long Span PC Beam therein
CN104453013A (en) Prefabricated wall component and fabricated reinforced concrete shear wall
KR100860592B1 (en) Temporary system for vertical structure using precast concreat block
KR101004747B1 (en) Pillar construction method by layer-built and frame construction method adapting the same
CN110670722A (en) Implementation method of beam-column connecting node of fabricated building
CN206769199U (en) After wear formula post stretching vertical prestressing cast-in-place concrete rod structure
CN102242551B (en) Reinforcing bars building block reinforced concrete structure and shock insulation, shock absorption system
CN214061940U (en) Precast concrete assembled structure with rib mold structure
CN213204438U (en) Semi-prefabricated and semi-cast-in-place building component
CN108755944B (en) Construction method of composite connection assembly type building structure
CN211368416U (en) Prefabricated decking is with pouring template and decking
CN215888962U (en) Thin-bottom groove type prestressed concrete superposed beam
CN207998964U (en) The assembled floorslab with bars of reserved anchor hole and horse tooth trough overlap edge construction
CN216130338U (en) Primary and secondary beam connecting joint
CN211285212U (en) Small box girder structure suitable for medium and small span simply supported girder bridge
CN214168790U (en) Steel pipe concrete assembled truss composite beam construction system
CN212716089U (en) Power distribution room structure capable of being installed quickly
CN212224622U (en) Pouring mold for constructional column of filler wall
CN210421403U (en) Semi-dry type connecting joint of frame beam and frame column
CN210976062U (en) Assembled frame construction combination system

Legal Events

Date Code Title Description
GR01 Patent grant
GR01 Patent grant
CP03 Change of name, title or address

Address after: 102206 1st floor, building 6, 8 Beiqing Road, Huilongguan town, Changping District, Beijing

Patentee after: Sany Construction Technology Co.,Ltd.

Address before: Room 301, building 6, No. 8, Beiqing Road, Huilongguan town, Changping District, Beijing

Patentee before: SANY CONSTRUCTION TECHNOLOGY Co.,Ltd.

CP03 Change of name, title or address