Patent Grant
11142911
The present application claims the benefit of priority to International (PCT) patent application No. PCT/CN2019/095008, filed Jul. 8, 2019, which patent application claims priority to Chinese patent application 201910519725.4, filed Jun. 17, 2019, the contents of which applications are incorporated herein by reference.
The present invention relates to the technical field of concrete-encased concrete-filled steel tube (CFST) columns, to structures comprising a plurality of such columns and a connection structure, and in particular to a construction method for constructing a concrete-encased CFST column connection structure to connect two or more such columns such as two split concrete-encased CFST columns.
Concrete-encased CFST columns advantageously combine the characteristics of steel tubes and concrete. A concrete-encased CFST column typically has high bearing capacity and a relatively small cross-sectional size. Because the CFST column is isolated from the outside world by the concrete encasement, the concrete-encased CFST column has good fire resistance and corrosion resistance. The concrete-encased CFST column also has the advantages of good seismic performance, ductility, convenient construction and low cost, among other benefits. Therefore, this type of column has been widely used in constructing high-rise buildings, bridges and other such large-span structures.
In practical applications, however, there are typically various complex construction requirements. Sometimes it is necessary to use connection nodes in connecting concrete-encased CFST columns, which requires connecting two split concrete-encased CFST columns together to ensure the requisite connection strength. However, at present, there is no acceptable and reliable connection structure that is capable of easily and soundly making such connections.
In order to address the above-mentioned technical problems, the present invention provides a connection structure and a construction method for a concrete-encased concrete-filled steel tube (CFST) column. The present invention comprises setting a connection node in a concrete-encased CFST column structure.
To achieve the above purpose, the present invention provides the following technical solutions.
A connection structure for a concrete-encased CFST column according to this invention includes a core positioning sleeve, a plurality of longitudinal bar sleeves, a hoop restraining sleeve and an external sealing sleeve, wherein the core positioning sleeve is used to connect two exposed steel tubes that are aligned opposite to each other. An inner diameter of the core positioning sleeve is substantially the same as the outer diameters of the exposed steel tubes; and, a plurality of slurry-flowing holes are opened on a side wall of the core positioning sleeve to facilitate a concrete slurry inflow in the space between and surrounding the two exposed steel tubes. An inner side wall of the core positioning sleeve is circumferentially provided with a plurality of cushions for bracing the exposed steel tubes.
The plurality of longitudinal bar sleeves are each used to connect two exposed longitudinal bars that are aligned opposite to each other. An inner diameter of the longitudinal bar sleeve is larger than an outer diameter of the exposed longitudinal bars.
The hoop restraining sleeve is used to restrain the position of the core positioning sleeve and the longitudinal bar sleeves; and, each longitudinal bar sleeve is fixedly connected to an inner side wall of the hoop restraining sleeve. The hoop restraining sleeve is sleeved outside the core positioning sleeve and fixedly connected to an outer side wall of the core positioning sleeve through one or more first connection keys.
The external sealing sleeve is used to seal a space between a first split concrete-encased CFST column and a second split concrete-encased CFST column. The external sealing sleeve is sleeved outside the hoop restraining sleeve and fixedly connected to the hoop restraining sleeve through one or more second connection keys.
In some invention embodiments, the slurry-flowing holes and the cushions are arranged alternately at intervals along the circumferential direction of the core positioning sleeve.
The present invention further provides a concrete-encased CFST column including a first split concrete-encased CFST column, a second split concrete-encased CFST column and the concrete-encased CFST column connection structure as described above, wherein: the first split concrete-encased CFST column comprises first exposed longitudinal bars and a first exposed steel tube; and the second split concrete-encased CFST column comprises second exposed longitudinal bars and a second exposed steel tube.
Each first exposed longitudinal bar is connected to a corresponding aligned second exposed longitudinal bar through a longitudinal bar sleeve such that one end of the first exposed steel tube and one end of the second exposed steel tube are nested inside a core positioning sleeve and are respectively braced on both ends with cushions. An external sealing sleeve is provided between the first split concrete-encased CFST column and the second concrete-encased CFST column; and, one end of the external sealing sleeve is connected to one end of the first split concrete-encased CFST column, while the other end of the external sealing sleeve is connected to one end of the second split concrete-encased CFST column. One of the split concrete-encased CFST columns is provided with an outlet port, and the other split concrete-encased CFST column is provided with a grouting port.
In some invention embodiments, the external sealing sleeve is provided with at least an observation hole.
In some invention embodiments, the concrete-encased CFST column further includes first stirrup rings for tightening a plurality of first exposed longitudinal bars and second stirrup rings for tightening a plurality of second exposed longitudinal bars, where the first stirrup rings are provided along a length direction of the first exposed longitudinal bars, and the second stirrup rings are provided along a length direction of the second exposed longitudinal bars.
In some invention embodiments, the first exposed steel tube and the second exposed steel tube are each provided with at least a first shear key on an outer side wall, and the external sealing sleeve is provided with at least a second shear key on an inner side wall. The first shear key enhances adhesion between the first exposed steel tube and the second exposed steel tube and the slurry, and the second shear key enhances adhesion between the external sealing sleeve and the slurry.
In some invention embodiments, one end of the first split concrete-encased CFST column is provided with a first sealing boss nested inside one end of the external sealing sleeve, and one end of the second split concrete-encased CFST column is provided with a second sealing boss nested inside the other end of the external sealing sleeve.
In some invention embodiments, the first split concrete-encased CFST column, the external sealing sleeve and the second split concrete-encased CFST column when connected form a column with a rectangular parallelepiped configuration.
The present invention further provides a construction method for constructing the above-described connection structure and the associated concrete-encased CFST column, including the following steps:
Compared with the prior art, the present invention achieves the following advantageous technical effects:
The present invention provides a concrete-encased CFST column connection structure, a concrete-encased CFST column and a concrete-encased CFST column construction method. Exposed steel tubes of two split concrete-encased CFST columns are connected through a core positioning sleeve of a concrete-encased CFST column connection structure. Exposed longitudinal bars of the two split concrete-encased CFST columns are connected through longitudinal bar sleeves of the concrete-encased CFST column connection structure. A space between the two split concrete-encased CFST columns is sealed by an external sealing sleeve of the concrete-encased CFST column connection structure. Spaces in the external sealing sleeve and around a first exposed steel tube and a second exposed steel tube are filled with slurry. The concrete-encased CFST column connection structure provided by the present invention is used to connect two split concrete-encased CFST columns by setting a connection node in the concrete-encased CFST column while ensuring the connection strength.
To describe the technical solutions in the examples of the present invention or in the prior art more clearly, the accompanying drawings are briefly described below. It should be understood that the accompanying drawings and the following drawing descriptions show merely some examples of the present invention, and a person of ordinary skill in the art may still derive other drawings from these accompanying drawings without creative efforts, which also should be deemed to be within the scope of this invention.
The reference numerals used in
The technical solutions in the examples of the present invention are clearly and completely described with reference to the accompanying drawings. It should be understood, however, that the described examples are merely some rather than all of the examples of the present invention. All other examples obtained by a person of ordinary skill in the art based on the examples of the present invention without creative efforts are intended to also fall within the scope of protection of the present invention.
An objective of the present invention is to provide a connection structure, a concrete-encased concrete-filled steel tube (CFST) column comprising the connection structure, and a construction method thereof. The present invention comprises setting a connection node in a concrete-encased CFST column as a connection structure for two aligned split CFST columns.
In order to describe the above objectives, features, and advantages of the present invention more clearly, the present invention is described in further detail below with reference to the accompanying drawings and specific implementations.
This example provides a concrete-encased CFST column connection structure 1 (
The core positioning sleeve 101 of connection structure 1 is used to connect ends of two exposed steel tubes positioned opposite to each other (as illustrated in
A plurality of longitudinal bar sleeves 104 are used to connect the longitudinal bars projecting respectively from the connection ends of the two CFST columns that are being connected (
The hoop restraining sleeve 105 is used to restrain the position of the core positioning sleeve 101 and the longitudinal bar sleeves 104. Each longitudinal bar sleeve 104 is fixedly connected to an inner side wall of the hoop restraining sleeve 105 (
The external sealing sleeve 107 (
In order to save space and facilitate grouting, the slurry-flowing holes 102 and the cushions 103 are arranged alternately at intervals along the circumferential direction of the core positioning sleeve 101 (
In operation, the respective exposed steel tubes 201 and 301 of the two split concrete-encased CFST columns 2 and 3 are connected through the core positioning sleeve 101 of the concrete-encased CFST column connection structure 1. The respective exposed longitudinal bars 202 and 302 of the two split concrete-encased CFST columns 2 and 3 are connected through the longitudinal bar sleeves 104 of the concrete-encased CFST column connection structure 1. A space between the two split concrete-encased CFST columns is sealed by the external sealing sleeve 107 of the concrete-encased CFST column connection structure 1. A space inside the external sealing sleeve 107, which includes first exposed steel tube 201 and second exposed steel tube 301, is filled with slurry. The concrete-encased CFST column connection structure 1 provided by this example is used to longitudinally connect two split concrete-encased CFST columns end-to-end (as shown in
This example provides additional description for forming a connected concrete-encased CFST column, as shown in
A first exposed longitudinal bar 202 is connected to a corresponding second exposed longitudinal bar 302 through one of the longitudinal bar sleeves 104. One end of the first exposed steel tube 201 and one end of the second exposed steel tube 301 are nested inside a core positioning sleeve 101, and respectively braced on both ends by the cushions 103. An external sealing sleeve 107 is provided between the first split concrete-encased CFST column 2 and the second concrete-encased CFST column 3. One end of the external sealing sleeve 107 is connected to a connection end of the first split concrete-encased CFST column 2, and the other end of the external sealing sleeve 107 is connected to a connection end of the second split concrete-encased CFST column 3. The first split concrete-encased CFST column 2 is provided with an outlet port 205, and the second split concrete-encased CFST column 3 is provided with a grouting port 305. Specifically, the grouting port 305 is a tapered grouting port, and the outlet port 205 is a tapered outlet port.
In this example, in order to facilitate external observation of the internal grouting condition of the external sealing sleeve 107 during the connecting and slurry filling procedure, an observation hole 6 is provided on the external sealing sleeve 107 of the concrete-encased CFST column. Specifically, the observation hole 6 is provided at upper and lower ends of the external sealing sleeve, and there are two observation holes 6 on each end.
In order to improve the strength and stability of the concrete-encased CFST column, the concrete-encased CFST column further includes first stirrup rings 203 for tightening a plurality of first exposed longitudinal bars 202 and second stirrup rings 303 for tightening a plurality of second exposed longitudinal bars 302. A plurality of the first stirrup rings 203 are provided along a length direction of the first exposed longitudinal bars 202, and a plurality of the second stirrup rings 303 are provided along a length direction of the second exposed longitudinal bars 302.
In order to enhance the adhesion with the slurry, the first exposed steel tube 201 and the second exposed steel tube 301 are each provided with at least a first shear key 4 on an outer side wall, and the external sealing sleeve 107 is provided with at least a second shear key 5 on an inner side wall. Specifically, the first shear key 4 is a first shear key ring, and the second shear key 5 is a second shear key ring. The first shear key 4 is arranged along a height direction of the first exposed steel tube 201 and the second exposed steel tube 301, and the second shear key 5 is arranged along a height direction of the external sealing sleeve 107. The part of the first exposed steel tube 201 and the second exposed steel tube 301 nested inside the core positioning sleeve 101 is not provided with the first shear key 4, and the part of the external sealing sleeve 107 connected with the first split concrete-encased CFST column 2 and the second concrete-encased CFST column 3 is not provided with the second shear key 5.
In order to prevent the leakage of grout around the connections between the external sealing sleeve 107 and the first split concrete-encased CFST column 2 and the second split concrete-encased CFST column 3 during grouting, a connection end of the first split concrete-encased CFST column 2 is provided with a first sealing boss 204 nested inside the corresponding end of the external sealing sleeve 107, and a connection end of the second split concrete-encased CFST column 3 is provided with a second sealing boss 304 nested inside the other end of the external sealing sleeve 107.
In addition, specifically, the first split concrete-encased CFST column 2, the external sealing sleeve 107 and the second split concrete-encased CFST column 3 together form a connected column with a rectangular parallelepiped configuration. The hoop restraining sleeve 105 has a rectangular cross section, and each side of the hoop restraining sleeve 105 is parallel to a corresponding side of the external sealing sleeve 107. The four longitudinal bar sleeves 104 are located at the four inner corners of the rectangular hoop retaining sleeve 105, respectively.
A construction method for constructing the concrete-encased CFST column comprises the following steps:
An existing concrete-encased CFST column is typically provided with a steel tube and longitudinal bars along a height direction thereof. The longitudinal bars are evenly arranged along a circumferential direction of the steel tube. Such an existing concrete-encased CFST column is formed by casting the steel tube, the longitudinal bars and concrete. A first split CFST column and a second split CFST column are two separate structures formed by the disconnection of an integral CFST column. After the integral CFST column is disconnected, the steel tube and the longitudinal bars that were originally wrapped inside the integral concrete column are partially exposed. The exposed parts of the steel tube and the longitudinal bars form exposed steel tubes and exposed longitudinal bars, respectively.
Specific examples are applied in this specification to describe the principle and implementations of the present invention. The description of the aforementioned examples, however, is intended only to be illustrative and for facilitating understanding of the method and the core idea of the present invention. It will be understood that for those of ordinary skills in the art, there may be changes in specific implementations and applications which are still considered within the scope of the present invention. In conclusion, the content of this specification should not be construed as a limitation of the present invention.
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| 201910519725.4 | Jun 2019 | CN | national |
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| International Search Report and Written Opinion dated Mar. 6, 2020 issued in corresponding International PCT Application No. PCT/CN2019/095008. |
| Number | Date | Country | |
|---|---|---|---|
| 20200392732 A1 | Dec 2020 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/CN2019/095008 | Jul 2019 | US |
| Child | 16901250 | US |
