Assemblable structural column joint connection using fiber-reinforced concrete filled round double steel tubes and mounting method thereof

Abstract

An assemblable structural column joint connection using fiber-reinforced concrete filled round double steel tubes, including an outer high-strength round steel tube, an inner high-strength round steel tube and a round separation plate. The wedge-shaped teeth are provided at two sides of the outer and inner high-strength steel tubes, and wedge-shaped teeth spaced are uniformly distributed along circumferences of the inner and outer high-strength round steel tubes. The round separation plate includes a round plate provided with a central through-hole, and vertical separation walls are provided with on upper and lower surfaces of the round plate. The vertical separation walls are provided with wedge-shaped sliding grooves matching the wedge-shaped teeth. The inner and outer high-strength round steel tubes are fixedly connected to the round separation plate by matching the wedge-shaped teeth with the wedge-shaped sliding grooves.

Claims

1. An assemblable structural column joint connection, comprising: an outer round steel tube, an inner round steel tube, and a round separation plate; wherein: the inner round steel tube is provided in the outer round steel tube, and is concentric with the outer round steel tube; a plurality of dove-tail teeth are provided at both the outer round steel tube and the inner round steel tube, and the plurality of dove-tail teeth spaced are uniformly distributed along circumferences of the inner round steel tube and the outer round steel tube; the round separation plate comprises a round plate provided with a central through-hole; a plurality of vertical separation walls corresponding to the plurality of dove-tail teeth are provided on upper and lower surfaces of the round plate; the plurality of vertical separation walls comprise a first vertical separation wall fitted with the inner round steel tube and a second vertical separation wall fitted with the outer round steel tube, so that the outer round steel tube and the inner round steel tube are fixedly connected to the round separation plate; and a plurality of dove-tail sliding grooves for matching the plurality of dove-tail teeth are provided on the plurality of vertical separation walls.

2. The assemblable structural column joint connection of claim 1, wherein the dove-tail teeth are arranged on inner and outer sides of both the outer round steel tube and the inner round steel tube.

3. The assemblable structural column joint connection of claim 1, wherein each vertical separation wall comprises two opposite walls on which the plurality of dove-tail sliding grooves are provided to engage with the plurality of dove-tail teeth.

4. The assemblable structural column joint connection of claim 1, wherein a crescent through-hole is provided on the round separation plate and is configured for pouring concrete.

5. The assemblable structural column joint connection of claim 1, wherein two or three groups of the dove-tail teeth are uniformly distributed along the circumferences of the inner round steel tube and the outer round steel tube.

6. The assemblable structural column joint connection of claim 1, wherein an external reinforcement ring is welded on an outer side of the outer round steel tube, and is connected to a steel girder via welding or bolts.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic diagram of an assemblable structural column joint connection using fiber-reinforced concrete filled round double steel tubes of the present invention.

(2) FIG. 2 is a schematic diagram of an end of a fiber-reinforced concrete filled round double steel tubes.

(3) FIG. 3 is a partial enlarged view of A in FIG. 1.

(4) FIG. 4 is a plan view of a round separation plate.

(5) FIG. 5 is a perspective view of the round separation plate.

(6) FIG. 6 is a schematic diagram showing the distribution of vertical separation walls according to a first embodiment of the present invention.

(7) FIG. 7 is a schematic diagram showing the distribution of the vertical separation walls according to a second embodiment of the present invention.

(8) In the drawings: 1, outer high-strength round steel tube; 2, inner high-strength round steel tube; 3, wedge-shaped connection tooth; 4, round separation plate; 5, round plate; 6, vertical separation wall; 7, wedge-shaped sliding groove; 8, central through-hole; 9, crescent through-hole; 10, external reinforcement ring; 11, steel girder.

DETAILED DESCRIPTION OF EMBODIMENTS

(9) The present invention will be further described in detail below with reference to the accompanying drawings.

Example 1

(10) As shown in FIG. 1, an assemblable structural column joint connection using fiber-reinforced concrete filled round double steel tubes includes an outer high-strength round steel tube 1, an inner high-strength round steel tube 2 and a round separation plate 4. The inner high-strength round steel tube is provided in the outer high-strength round steel tube, and is concentric with the outer high-strength round steel tube. The round separation plate connects upper and lower fiber-reinforced concrete filled double steel tubes. An external reinforcement ring 10 is welded on an outer side of the outer high-strength round steel tube, and is connected to a steel girder 11 via welding or bolts.

(11) As shown in FIG. 2, a plurality of wedge-shaped teeth 3 are provided at two sides of both the outer high-strength round steel tube and the inner high-strength steel tube. The wedge-shaped teeth are welded at the sides of both the inner high-strength round steel tube and the outer high-strength round steel tube, and the wedge-shaped teeth spaced are uniformly distributed along circumferences of the inner high-strength round steel tube and the outer high-strength round steel tube. As shown in FIG. 6, three groups of wedge-shaped teeth are provided on sides of the inner high-strength round steel tube and the outer high-strength round steel tube. A central angle of each group of the wedge-shaped teeth is 60 degree, and an angle between two groups of the wedge-shaped teeth is 60 degree.

(12) As shown in FIGS. 4 and 5, the round separation plate includes a round plate 5. A central through-hole 8 and a crescent through-hole 9 are provided at the round plate. Vertical separation walls 6 are provided at upper and lower surfaces of the round plate. As shown in FIG. 3, the vertical separation walls include a first vertical separation wall fitted with the inner high-strength round steel tube and a second vertical separation wall fitted with the outer high-strength round steel tube, so that the outer high-strength round steel tube and the inner high-strength round steel tube are fixedly connected to the round separation plate. There are at least one first vertical separation wall and at least one second vertical separation wall which are provided with a plurality of wedge-shaped sliding grooves 7 matching the wedge-shaped teeth.

(13) During mounting, the wedge-shaped teeth of the inner high-strength round steel tube are placed in a gap between two vertical separation walls, and the wedge-shaped teeth are aligned with the wedge-shaped sliding grooves. Then, the inner high-strength round steel tube is rotated such that the wedge-shaped teeth are engaged with the wedge-shaped sliding grooves in a snap fit. The outer high-strength round steel tube is mounted in a same way as the inner high-strength round steel tube. Therefore, the distribution of vertical separator plates corresponds to the wedge-shaped teeth.

(14) When the wedge-shaped teeth are disposed on either the inner side or the outer side of the steel tubes, each vertical separation wall requires only one part. When the wedge-shaped teeth are disposed on both the inner side and the outer side of the steel tubes, each vertical separation wall requires two parts. The wedge-shaped sliding grooves are arranged on two opposite walls of the vertical separation wall to match the wedge-shaped teeth. The connection between the wedge-shaped sliding grooves and the wedge-shaped teeth ensures the bearing capacity and reliability of the connection section, which is suitable for structures with higher requirements for bearing capacity.

(15) The present invention is not only suitable for connecting columns with a same cross-section, but also for connecting columns with different cross-sections. If the round separation plate connects two identical fiber-reinforced concrete filled round double steel tubes, the vertical separation walls on the upper and lower surfaces of the round separation plate have a same distribution. If the upper and the lower fiber-reinforced concrete filled round double-tube steel tubes have different cross-sections, diameters of the vertical separation walls can accordingly be changed.

(16) The method for mounting the assemblable structural column joint connection using fiber-reinforced concrete filled round double steel tubes includes the following steps.

(17) Step 1: The wedge-shaped teeth are welded on two sides of both the outer high-strength round steel tube and the inner high-strength round steel tube.

(18) Step 2: The wedge-shaped teeth of the inner high-strength round steel tube are placed in a gap between two opposite walls of the first vertical separation wall, and the wedge-shaped teeth are aligned with the wedge-shaped sliding grooves. Then, the inner high-strength round steel tube are rotated such that the wedge-shaped teeth are engaged with the wedge-shaped sliding grooves in a snap fit.

(19) Step 3: The wedge-shaped teeth of the outer high-strength round steel tube are placed in a gap between two opposite walls of the second first vertical separation wall, and the wedge-shaped teeth are aligned with the wedge-shaped sliding grooves. Then, the outer high-strength round steel tube are rotated such that the wedge-shaped teeth are engaged with the wedge-shaped sliding grooves in a snap fit.

(20) Step 4: The fiber-reinforced concrete is poured into the outer high-strength round steel tube and the inner high-strength round steel tube through the central through-hole and the crescent through-hole.

(21) Step 5: The external reinforcement ring are welded on the outer side of the outer high-strength round steel tube.

(22) Step 6: The steel girder are connected to the external reinforcement ring.

Example 2

(23) As shown in FIG. 7, the differences between the present example and Example 1 are that two groups of the wedge-shaped teeth are provided on each side of the steel tubes, and a central angle of each group of the wedge-shaped teeth is 90 degree, and an angle between two groups of the wedge-shaped teeth is 90 degree. The rest is the same as in Example 1.

(24) The above is only some preferred embodiments of the present invention, and is not intended to limit the present invention. Variants and modifications may be made by those skilled in the art. Any modifications, equivalent substitutions and improvements within the spirit and principle of the present invention shall fall into the scope of the present invention.