CN211523533U - Prefabricated post nodal connection structure - Google Patents

Abstract

The utility model provides a prefabricated post nodal connection structure, including first prefabricated post, the prefabricated post of second and half opening sleeve. The first end of the first prefabricated column is opposite to the second end of the second prefabricated column and is arranged at a certain distance; a first end of the first prefabricated column is provided with a first prefabricated column steel bar which extends outwards; and a second end of the second prefabricated column is provided with a second prefabricated column steel bar extending outwards. The half-opening sleeve comprises a first connecting end and a second connecting end; the first connecting end is fixedly connected with the first prefabricated column steel bar; the second prefabricated column steel bar is inserted into the half-opening sleeve from the second connecting end; and ultrahigh-performance concrete is filled between the second prefabricated column reinforcing steel bars and the half-opening sleeve. For the node connection structure of current solid prefabricated post, this disclosure is convenient for observe when hoist and mount, but quick hoist and mount, grout quality easily ensure. Compared with the existing cavity prefabricated column node connecting structure, the cavity prefabricated column node connecting structure has the advantages that a specially-made steel bar connecting piece is not needed, and the cost is lower.

Description

Prefabricated post nodal connection structure

Technical Field

The utility model relates to a building element construction field especially relates to a prefabricated post node connection structure.

Background

The fabricated building refers to a building fabricated at a construction site using prefabricated parts. In recent years, the development of the assembled building in China is rapid, and the assembled integral type superposed shear wall structure is produced at the same time. Superimposed shear walls and prefabricated columns are common fabricated components. The prefabricated column node used for connecting prefabricated columns is used as an important component connecting node of a fabricated structure and is always a difficulty solved by the fabricated frame structure.

The existing prefabricated column node connection is divided into a prefabricated solid column node and a prefabricated cavity column node. The prefabricated solid column node is characterized in that a groove is reserved at the bottom of the upper prefabricated solid column, a sleeve is embedded in the groove, and a steel bar in the upper prefabricated solid column is connected with the upper end of the sleeve. And the steel bars in the prefabricated solid column at the lower part extend upwards out of the end part of the prefabricated column and extend into the sleeve in the groove at the bottom of the prefabricated solid column at the upper part, and then grouting material is used for grouting into the sleeve to form connection. The prefabricated cavity column is exposed at the connecting position, namely, the reinforcing steel bars at the two ends of the prefabricated cavity column extend outwards, and the reinforcing steel bars of the upper prefabricated cavity column and the lower prefabricated cavity column are connected by adopting the connecting piece.

However, the connection mode of the prefabricated solid column node adopted at present cannot be observed when grouting materials are injected into the sleeve, and the construction quality is difficult to guarantee. The connecting piece of the adopted prefabricated hollow column needs to adopt a specially-made steel bar connecting piece, and the cost is higher.

SUMMERY OF THE UTILITY MODEL

To solve or at least alleviate at least one of the above technical problems, the present disclosure provides a prefabricated pillar node connecting structure.

According to an aspect of the present disclosure, a prefabricated pillar node connection structure includes:

the prefabricated column comprises a first prefabricated column and a second prefabricated column, wherein a first end of the first prefabricated column is opposite to a second end of the second prefabricated column and is arranged at a certain distance; a first prefabricated column steel bar extending outwards is arranged at the first end of the first prefabricated column; a second end of the second prefabricated column is provided with a second prefabricated column steel bar extending outwards; the first prefabricated column steel bars and the second prefabricated column steel bars are arranged at intervals along the edge profiles of the first prefabricated column and the second prefabricated column; and

the half-opening sleeve comprises a first connecting end and a second connecting end; the first connecting end is fixedly connected with the first precast column steel bar; the second prefabricated column reinforcing steel bar is inserted into the half-opening sleeve from the second connecting end;

and ultrahigh-performance concrete is filled between the second prefabricated column reinforcing steel bars and the half-opening sleeve, so that the first prefabricated column reinforcing steel bars and the second prefabricated column reinforcing steel bars are connected.

According to at least one embodiment of the disclosure, the first connecting end is provided with a threaded hole, and the half-open sleeve is connected with the first precast column steel bar through the threaded hole; the second connecting end is provided with a pouring cavity which is opened to the outside at the side surface and the bottom surface of the semi-open sleeve and is used for enabling the ultra-high performance concrete to flow into the pouring cavity from the side surface and the bottom surface of the semi-open sleeve; and the second prefabricated column steel bar extends into the pouring cavity and is fixedly connected with the half-opening sleeve through the ultra-high performance concrete.

According to at least one embodiment of the present disclosure, the half split sleeve is provided with a first body and a second body arranged in an axial direction; the first body is in a frustum cone shape, and the second body is in a semi-cylindrical shape split along the axial direction;

the first body forms the first connecting end, and the threaded hole is a through hole which penetrates through the first body along an axis;

the second body forms the second link, fills the cavity and is setting up for the semi-cylindrical recess in the second body, the semi-cylindrical recess along the axis from the bottom of second body run through to the top and with the screw hole intercommunication.

According to at least one embodiment of the present disclosure, the maximum outer diameter of the first body is the same as the outer diameter of the second body.

According to at least one embodiment of the present disclosure, the first body and the second body are integrally formed.

According to at least one embodiment of the present disclosure, the first body and the second body are formed as two parts, fixedly connected together.

According to at least one embodiment of the present disclosure, an interval between the first end of the first precast column and the second end of the second precast column is filled with ultra high performance concrete; the first prefabricated column reinforcing steel bar, the second prefabricated column reinforcing steel bar and the half-opening sleeve are buried in the ultra-high performance concrete, so that the first prefabricated column and the second prefabricated column are connected to form a whole.

According to at least one embodiment of the present disclosure, the first prefabricated column reinforcing bars are bound with stirrups that wind each first prefabricated column reinforcing bar in the same horizontal plane.

According to at least one embodiment of the present disclosure, the first and second prefabricated columns are solid prefabricated columns.

According to at least one embodiment of the present disclosure, the first and second precast columns are cavity precast columns.

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 perspective view of one direction of an exemplary embodiment of a precast column node connection structure of the present disclosure.

Fig. 2 is a perspective view of another direction of an exemplary embodiment of a precast column node connection structure of the present disclosure.

Fig. 3 is an elevation view of an exemplary embodiment of a prefabricated pillar node connection structure of the present disclosure.

Fig. 1 to 3 are internal structural views each of which is seen after one side of the template is removed.

Description of reference numerals:

1-first prefabricated column (upper prefabricated column); 2-second prefabricated column (lower prefabricated column); 3-first prefabricated column steel bars; 4-second prefabricated column steel bars; 5-a half-split sleeve; 6-stirrup; 7-template; 8-split bolt.

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 existing prefabricated column node connection is divided into a prefabricated solid column node and a prefabricated cavity column node. The prefabricated solid column node is characterized in that a groove is reserved at the bottom of the upper prefabricated solid column, a sleeve is embedded in the groove, and a steel bar in the upper prefabricated solid column is connected with the upper end of the sleeve. And the steel bars in the prefabricated solid column at the lower part extend upwards out of the end part of the prefabricated column and extend into the sleeve in the groove at the bottom of the prefabricated solid column at the upper part, and then grouting material is used for grouting into the sleeve to form connection. The prefabricated cavity column is exposed at the connecting position, namely, the reinforcing steel bars at the two ends of the prefabricated cavity column extend outwards, and the reinforcing steel bars of the upper prefabricated cavity column and the lower prefabricated cavity column are connected by adopting the connecting piece.

However, the connection mode of the prefabricated solid column node adopted at present cannot be observed when grouting materials are injected into the sleeve, and the construction quality is difficult to guarantee. The connecting piece of the adopted prefabricated hollow column needs to adopt a specially-made steel bar connecting piece, and the cost is higher.

Therefore, the present disclosure is directed to a prefabricated column node connection structure, and seeks to solve or at least alleviate at least one of the above technical problems, and discloses a prefabricated column node connection structure and a construction method.

In the application document of the present disclosure, for convenience of describing the position relationship of each component in the prefabricated column node connection structure, the vertical height direction of the prefabricated column node connection structure is referred to as longitudinal direction or vertical direction by taking the position of the prefabricated column node connection structure after being constructed in place as a standard; the left and right width directions of the prefabricated column node connecting structure are called as transverse directions or horizontal directions; the thickness direction of the prefabricated column node connecting structure is vertical to a plane formed in the vertical direction and the horizontal direction. The prefabricated column node connecting structure is provided with an axis in the vertical direction.

According to an aspect of the present disclosure, refer to a perspective view diagram of one direction and a perspective view diagram of another direction of an exemplary embodiment of a precast column node connection structure of the present disclosure shown in fig. 1 and 2. A prefabricated column node connection structure is provided, comprising a first prefabricated column 1, a second prefabricated column 2 and a half-split sleeve 5. First prefabricated post 1 and second prefabricated post 2 are prefabricated the shaping by concrete placement, and the reinforcing bar has been buried underground in the prefabricated post. Both ends of the first prefabricated column 1 and the second prefabricated column 2 may be provided as planar ends, wherein a first end of the first prefabricated column 1 is arranged opposite and at a distance from a second end of the second prefabricated column 2. For example, a first prefabricated column 1 is above a second prefabricated column 2, and the lower end of the first prefabricated column 1 is opposite to and spaced apart from the upper end of the second prefabricated column 2. A first prefabricated column steel bar 3 extending outwards is arranged at the first end of the first prefabricated column 1; and a second end of the second prefabricated column 2 is provided with a second prefabricated column steel bar 4 extending outwards. First prefabricated column rebar 3 and second prefabricated column rebar 4 protrude out of the planar end of the prefabricated column and function to form a rebar connection between the two prefabricated columns. First prefabricated post reinforcing bar 3 and second prefabricated post reinforcing bar 4 are all arranged along the marginal profile interval of first prefabricated post 1 and second prefabricated post 2. The half-opening sleeve 5 comprises a first connecting end and a second connecting end; the half-split sleeve 5 is a sleeve-like member having two opposite ends, having a shaped sidewall enclosing a space; the half opening is that the side of the sleeve is formed with half side wall, and the other half is an open opening. The first connecting end is fixedly connected with the first prefabricated column reinforcing steel bar 3. The first connecting end of the half-opening sleeve 5 is sleeved at the end of the first precast column steel bar 3, and the fixed connection mode can adopt threaded connection, welding and the like. The second pre-cast column reinforcing bars 4 are inserted into the inside of the half split sleeve 5 from the second connection end. That is to say, half open sleeve 5's second link cover is established at the tip of prefabricated post reinforcing bar 4 of second, has certain space between the lateral wall of half open sleeve 5 and the prefabricated post reinforcing bar 4 of second, and this space is used for filling ultra high performance concrete usefulness. Wherein, it has ultra high performance concrete to fill between second prefabricated post reinforcing bar 4 and the half-opening sleeve 5, makes first prefabricated post reinforcing bar 3 and second prefabricated post reinforcing bar 4 form to be connected. The Ultra-High Performance Concrete, called UHPC (Ultra-High Performance Concrete) for short, also called Reactive Powder Concrete (RPC), has Ultra-High durability, Ultra-High mechanical properties, stronger fluidity, compressive strength and bond stress which meet the design requirements of the precast column, and certain tensile and shear resistance. The semi-open sleeve 5 is used as a connecting piece between the first prefabricated column reinforcing steel bar 3 and the second prefabricated column reinforcing steel bar 4, one end of the semi-open sleeve is fixedly connected with the first prefabricated column reinforcing steel bar 3, and the connection can be performed before pouring construction, so that the construction is convenient; the other end of the second prefabricated column steel bar 4 can form firm connection with the filled ultrahigh-performance concrete, and the connection is realized after pouring construction.

The utility model discloses a prefabricated post nodal connection structure, the link of first prefabricated post 1 and the prefabricated post 2 of second is relative and the interval sets up, and two prefabricated post links set up the prefabricated post reinforcing bar that outwards stretches out, connect corresponding two prefabricated post reinforcing bars through half open sleeve 5, and half open sleeve 5's one end and 3 fixed connection of first prefabricated post reinforcing bar, half open sleeve 5's the other end forms firm being connected through forming between filled ultra high performance concrete and the prefabricated post reinforcing bar 4 of second. Due to the fact that the fluidity of the ultra-high performance concrete is better, and the special half-opening structure of the half-opening sleeve 5 is added, the ultra-high performance concrete is filled between the second precast column reinforcing steel bars 4 and the half-opening sleeve 5 more easily. For the node connection structure of current solid prefabricated post, this disclosure is convenient for observe when hoist and mount, but quick hoist and mount, grout quality easily ensure. Compared with the existing cavity prefabricated column node connecting structure, the cavity prefabricated column node connecting structure has the advantages that a specially-made steel bar connecting piece is not needed, and the cost is lower.

In an embodiment of the present disclosure, the first connection end of the half-open sleeve 5 is provided with a threaded hole, the end of the first precast column steel bar 3 is provided with an external thread, and the half-open sleeve 5 is connected with the first precast column steel bar 3 through the threaded hole. Half-split sleeves 5 may be screwed to the ends of the corresponding first prefabricated column reinforcing bars 3 when the first prefabricated column 1 is not hoisted in place. The second connecting end of the half-split sleeve 5 is provided with a pouring cavity which is open to the outside at both the side surface and the bottom surface of the half-split sleeve 5, and is used for enabling the ultra-high performance concrete to flow into the pouring cavity from the side surface and the bottom surface of the half-split sleeve 5. For example, the second connecting end of the half-open sleeve 5 may be provided with only a part of side wall, preferably a side wall capable of circumferentially surrounding at least half of the second prefabricated column reinforcing steel bar 4, the bottom of the second connecting end is not sealed, the part without the side wall is an open opening, and a part of space surrounded by the side wall forms a pouring cavity. The second precast column reinforcing steel bars 4 can extend into the pouring cavity from the bottom of the second connecting end and are fixedly connected with the half-opening sleeve 5 through the ultra-high performance concrete.

In one embodiment of the present disclosure, the half split sleeve 5 is provided with a first body and a second body disposed in the axial direction. The first body is in a cone frustum shape, and the second body is in a semi-cylindrical shape split along the axial direction. The small diameter end of the frustum cone-shaped first body faces outwards, and the large diameter end of the frustum cone-shaped first body is connected with the semi-cylindrical second body. The first body forms a first connecting end, and the threaded hole is a through hole which penetrates through the first body along an axis. The tip of first prefabricated post reinforcing bar 3 is equipped with the external screw thread, and the minor diameter end of the first body of truncated cone form passes through screw hole threaded connection at the tip of first prefabricated post reinforcing bar 3. The second body forms the second link, pours the cavity for setting up the semi-cylindrical recess in the second body, and the semi-cylindrical recess runs through to the top and communicates with the screw hole from the bottom of second body along the axis. That is, in this mode, the second body is formed by a semi-cylinder cut from the axis, and a semi-cylindrical groove extending along the axis is formed on a plane of one side of the semi-cylinder to form a pouring cavity, and the diameter of the semi-cylindrical groove is larger than the outer diameter of the second precast column reinforcing steel bar 4. The semi-cylindrical second body may also be formed by a sidewall that surrounds half of the axis, the sidewall having a thickness, the space surrounded by the sidewall forming a perfusion cavity. The second body can also adopt other modes to form, can understand, in the different modes that the second body adopted, all be formed with at the outside open-ended opening in bottom and side to make inside pouring cavity can be better fill ultra high performance concrete, avoid the retention space.

Further, the maximum outer diameter of the truncated cone-shaped first body is the same as the outer diameter of the semi-cylindrical second body. A flat surface is formed on the outside to facilitate better contact with the concrete.

Alternatively, the first body and the second body may be integrally formed. Alternatively, the first body and the second body may be formed as two parts and then fixedly coupled together. The manufacturing method can be appropriately selected according to the manufacturing cost.

In the above respective embodiments, the first precast column 1 and the second precast column 2 are precast-formed of ordinary concrete; and ultrahigh-performance concrete is filled in the space between the first end of the first prefabricated column 1 and the second end of the second prefabricated column 2 to form a connecting node of the two prefabricated columns. The first prefabricated column reinforcing steel bar 3, the second prefabricated column reinforcing steel bar 4 and the half-opening sleeve 5 are all embedded in the ultra-high performance concrete, so that the first prefabricated column 1 and the second prefabricated column 2 are connected to form a whole. Meanwhile, the ultrahigh-performance concrete is filled between the second prefabricated column reinforcing steel bars 4 and the half-opening sleeve 5, so that the first prefabricated column reinforcing steel bars 3 are connected with the second prefabricated column reinforcing steel bars 4 into a whole through the half-opening sleeve 5, and reinforcing steel bar connection and concrete connection are formed between the two prefabricated columns. Referring to fig. 3, which is a front view of an exemplary embodiment of a prefabricated column node connection structure according to the present disclosure, a prefabricated column reinforcement protruding from a lower end of a first prefabricated column 1 located above is connected to a prefabricated column reinforcement protruding from an upper end of a second prefabricated column 2 located below through a half-split sleeve 5. The space between the upper prefabricated column and the lower prefabricated column is filled with ultra-high performance concrete to form a node connecting structure between the two prefabricated columns.

In the above respective embodiments, the first prefabricated column reinforcing bars 3 are bound with the stirrups 6, and the stirrups 6 wind each of the first prefabricated column reinforcing bars 3 in the same horizontal plane. The stirrups 6 can be formed by winding a slightly thin steel bar on the prefabricated column steel bars extending out of the periphery in sequence according to a certain sequence to form a criss-cross winding form. One row of stirrups 6 can be arranged, and a plurality of rows of stirrups 6 can also be arranged in the longitudinal direction, and each row of stirrups 6 is positioned in different horizontal planes in the longitudinal direction. Through winding stirrup 6, can guarantee that the relative position of each prefabricated post reinforcing bar is fixed when the first prefabricated post of hoist 1 on the one hand, on the other hand can bury into the concrete after pouring the ultra high performance concrete and strengthen structural strength.

In each of the above embodiments, the first prefabricated column 1 and the second prefabricated column 2 may be solid prefabricated columns. Alternatively, the first prefabricated column 1 and the second prefabricated column 2 may be hollow prefabricated columns.

In order to further illustrate the advantages of the prefabricated column node connecting structure provided by the disclosure in construction, a construction method of the prefabricated column node connecting structure is described, the prefabricated column node connecting structure is used for connecting two prefabricated columns in the vertical direction, and the prefabricated column node connecting structure adopts the node connecting structure in any embodiment. The construction method comprises the following steps:

and binding the stirrups 6 of the first prefabricated column steel bars 3 in place, wherein the binding in place refers to binding operation at the positions where the stirrups 6 need to be bound. And connecting the first prefabricated column reinforcing steel bar 3 with the half-open sleeve 5. Wherein, one end of the semi-open sleeve 5 can be screwed on the end of the first prefabricated column steel bar 3, and the mode needs to provide an external thread on the end of the first prefabricated column steel bar 3; or may be fixed to the end of the first precast column reinforcing bar 3 by welding.

The first prefabricated column 1 is hoisted to the operation surface and slowly falls down, so that the second prefabricated column steel bars 4 all extend into the half-opening sleeve 5. The second prefabricated post reinforcing bar 4 is located the top of the prefabricated post 2 of second below, upwards stretches out, aligns second prefabricated post reinforcing bar 4 and corresponding half open sleeve 5 under workman's assistance through tower crane or mobile crane.

A formwork 7 is installed around the space between the first end of the first prefabricated column 1 and the second end of the second prefabricated column 2 to form a closed casting space. The upper part of the formwork 7 abuts against the side wall of the first prefabricated column 1 and the lower part of the formwork 7 abuts against the side wall of the second prefabricated column 2. The formworks 7 can be fixed by using split bolts 8, and the stability of the upper and lower prefabricated columns 1 is ensured through the split bolts 8. The construction of the split bolt 8 adopts the existing construction mode, and auxiliary components such as a sleeve, a plug and the like can be adopted.

And pouring ultra-high performance concrete into the pouring space, so that the ultra-high performance concrete is filled between the second prefabricated column reinforcing steel bars 4 and the half-open sleeve 5 and the pouring space. In the process of filling the ultra-high performance concrete into the pouring space, because the ultra-high performance concrete has stronger fluidity, and the side surface and the bottom surface of the half-open sleeve 5 are provided with open openings, the ultra-high performance concrete easily flows into the gap between the second prefabricated column reinforcing steel bar 4 and the half-open sleeve 5 and fills the whole gap, and the construction quality problem that an air gap is easily generated in the prior art is avoided. And filling ultrahigh-performance concrete into the pouring space, and embedding the first prefabricated column reinforcing steel bars 3, the second prefabricated column reinforcing steel bars 4 and the half-opening sleeve 5 into the poured concrete.

In one embodiment of the present disclosure, the step of pouring the ultra-high performance concrete into the pouring space has different construction methods according to different precast column forms, including:

and under the condition that the first prefabricated column 1 and the second prefabricated column 2 are solid prefabricated columns, a pouring opening and an observation opening are reserved on the template 7, and ultrahigh-performance concrete is poured through the pouring opening. Because the solid prefabricated column does not have other channels capable of being filled, a filling port and an observation port are required to be arranged on the template 7.

In the case where the first and second prefabricated columns 1 and 2 are cavity prefabricated columns, ultra high performance concrete is poured from the top opening of the first prefabricated column 1 located at the upper portion. The cavity of the cavity precast column can be poured with ultra-high performance concrete, so that the overall mechanical performance of the precast column is improved.

The following is a preferred exemplary embodiment of the construction method:

1. the stirrups 6 of the upper prefabricated column 1 are bound in place, the extending steel bars are connected with the sleeve, the upper prefabricated column 1 is hoisted to an operation surface by using a tower crane or a mobile crane and slowly falls, and the steel bars extending out of the lower prefabricated column 2 are enabled to completely extend into the sleeve.

2. And a template 7 and a split bolt 8 are arranged between the lower end of the upper prefabricated column 1 and the upper end of the lower prefabricated column 2, and the stability of the upper prefabricated column 1 and the lower prefabricated column 1 is ensured through the split bolt 8.

3. For the solid prefabricated column, a filling port and an observation port are reserved on the template 7, and slurry is filled.

4. For the cavity prefabricated column, holes are not reserved on the template 7, and slurry is poured from the top opening of the upper prefabricated column 1.

The grouting slurry is made of ultra-high performance concrete (UHPC), has stronger fluidity, higher compressive strength than that of a prefabricated column, and a bond stress meeting the design requirement and certain tensile and shear resistance.

According to each embodiment, this disclosed prefabricated post nodal connection structure, the link of first prefabricated post 1 and the prefabricated post 2 of second is relative and the interval sets up, and two prefabricated post links set up the prefabricated post reinforcing bar that outwards stretches out, connect corresponding two prefabricated post reinforcing bars through half open sleeve 5, and half open sleeve 5's one end and 3 fixed connection of first prefabricated post reinforcing bar, half open sleeve 5's the other end forms firm being connected through between filled ultra high performance concrete and the prefabricated post reinforcing bar 4 of second. Due to the fact that the fluidity of the ultra-high performance concrete is better, and the special half-opening structure of the half-opening sleeve 5 is added, the ultra-high performance concrete is filled between the second precast column reinforcing steel bars 4 and the half-opening sleeve 5 more easily. For the node connection structure of current solid prefabricated post, this disclosure is convenient for observe when hoist and mount, but quick hoist and mount, grout quality easily ensure. Compared with the existing cavity prefabricated column node connecting structure, the cavity prefabricated column node connecting structure has the advantages that a specially-made steel bar connecting piece is not needed, and the cost is lower.

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 precast column node connection structure characterized by comprising:

the prefabricated column comprises a first prefabricated column and a second prefabricated column, wherein a first end of the first prefabricated column is opposite to a second end of the second prefabricated column and is arranged at a certain distance; a first prefabricated column steel bar extending outwards is arranged at the first end of the first prefabricated column; a second end of the second prefabricated column is provided with a second prefabricated column steel bar extending outwards; the first prefabricated column steel bars and the second prefabricated column steel bars are arranged at intervals along the edge profiles of the first prefabricated column and the second prefabricated column; and

the half-opening sleeve comprises a first connecting end and a second connecting end; the first connecting end is fixedly connected with the first precast column steel bar; the second prefabricated column reinforcing steel bar is inserted into the half-opening sleeve from the second connecting end;

and ultrahigh-performance concrete is filled between the second prefabricated column reinforcing steel bars and the half-opening sleeve, so that the first prefabricated column reinforcing steel bars and the second prefabricated column reinforcing steel bars are connected.

2. The precast column node connection structure of claim 1, wherein the first connection end is provided with a threaded hole through which the half-open sleeve is connected with the first precast column reinforcing bar; the second connecting end is provided with a pouring cavity which is opened to the outside at the side surface and the bottom surface of the semi-open sleeve and is used for enabling the ultra-high performance concrete to flow into the pouring cavity from the side surface and the bottom surface of the semi-open sleeve; and the second prefabricated column steel bar extends into the pouring cavity and is fixedly connected with the half-opening sleeve through the ultra-high performance concrete.

3. The precast column node connection structure of claim 2, wherein the half split sleeve is provided with a first body and a second body which are arranged in an axial direction; the first body is in a frustum cone shape, and the second body is in a semi-cylindrical shape split along the axial direction;

the first body forms the first connecting end, and the threaded hole is a through hole which penetrates through the first body along an axis;

the second body forms the second link, fills the cavity and is setting up for the semi-cylindrical recess in the second body, the semi-cylindrical recess along the axis from the bottom of second body run through to the top and with the screw hole intercommunication.

4. The precast column node connection structure of claim 3, wherein a maximum outer diameter of the first body is the same as an outer diameter of the second body.

5. The precast column node connection structure of claim 4, wherein the first body and the second body are integrally formed.

6. The precast column node connection structure of claim 4, wherein the first body and the second body are formed as two pieces, fixedly connected together.

7. The precast column node connection structure of any one of claims 1 to 6, wherein an interval between the first end of the first precast column and the second end of the second precast column is filled with ultra high performance concrete; the first prefabricated column reinforcing steel bar, the second prefabricated column reinforcing steel bar and the half-opening sleeve are buried in the ultra-high performance concrete, so that the first prefabricated column and the second prefabricated column are connected to form a whole.

8. The prefabricated column node-connecting structure of claim 7, wherein the first prefabricated column reinforcing bars are bound with stirrups, and the stirrups wind each of the first prefabricated column reinforcing bars in the same horizontal plane.

9. The precast column node connection structure of claim 7, wherein the first precast column and the second precast column are solid precast columns.

10. The precast column node connection structure of claim 7, wherein the first precast column and the second precast column are cavity precast columns.

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