KR20180070481A - Apparatus for connecting steel pipe - Google Patents

Abstract

An apparatus for connecting a steel pipe according to the present invention comprises: a pin joint including a first groove and a rotation constraining groove formed in a circumferential direction on the outer surface thereof; a box joint including a second groove forming a circumferential groove with the first groove when being fastened to the pin joint, and a connecting groove extended from the outer surface to the second groove; a first shear connecting material fastened to the circumferential groove and constraining relative movement of the pin joint and the box joint in a shaft direction; and a second shear connecting material fastened to the connecting groove and the rotation constraining groove, and constraining relative movement of the pin joint and the box joint in the circumferential direction.

Description

[0001] APPARATUS FOR CONNECTING STEEL PIPE [0002]

The present invention relates to a steel pipe connecting apparatus which mechanically connects an upper steel pipe and a lower steel pipe without welding at a steel pipe file construction site.

The pile foundation is one of the basic types used to stably support the superstructure on the ground, such as concrete pile and steel pipe pile. Concrete piles have a low cost of materials and low resistance to shear and bending moments. On the other hand, steel pipe pile has high resistance to shear force and bending moment even though material cost is high. It is widely used as a file basis for structures.

Since steel pipe files are manufactured with a certain length (12 m to 15 m) in steel pipe, when the penetration depth exceeds the steel pipe length at the construction site, it is necessary to connect the upper pipe pipe file and the lower pipe pipe file. The connection method for connecting them is a method of joining two steel pipes by welding or metallurgically joining two steel pipes by using a mechanical connection device.

Metallurgical welding of the upper steel pipe file and the lower steel pipe file requires welding and nondestructive inspection at the construction site, which leads to a longer construction period. In the case of steel pipe file withdrawal, it is difficult to cut and pull out, Since the welding method and the nondestructive inspection are not required in the field, the connection method is advantageous in that the construction period is shortened and disassembly is easily performed.

The existing steel pipe file mechanical connection device consists of a pin joint, a box joint and the like. The pin joint faces the groove of the box joint, and the outer circumferential groove is cut. The box joint in which the upper steel pipe is circumferentially welded is inserted into the pin joint where the lower steel pipe is welded circumferentially and then the bolt is rotated so that the shear connection member inserted in the inner circumferential groove of the box joint is inserted into the groove of the pin joint, So that the mechanical coupling of the steel pipe is completed.

However, these existing steel pipe file mechanical connections must be thicker in order to provide a structurally stable support. That is, after the shear connectors connect the box joints and the pin joints, the voids in the box joints fail to function structurally, which causes the overall connector thickness to increase, It causes.

In addition, due to the internal void space, the shear connectors are easily rotated by the shear force, and the shear connectors exert concentrated stress on the pin joints and box joints. To prevent this, box joints and pin joints must be made of high-strength thick materials, which ultimately leads to cost increases.

Further, in order to smoothly insert the shear connection member, a slight tolerance and clearance are required. When the tensile force is applied to the steel pipe due to this space, the shear connection member is rotated to apply a force for separating and breaking the two box joint and the pin joint . Furthermore, the shapes of the box joints and the end portions of the pin joints are difficult to process, and are not efficient in resisting compressive forces.

JP 3336430 B2 (KUBOTA CORP) 2002.08.09. (Registration date)

It is an object of the present invention to securely combine a box joint and a pin joint using a shear connection member and to suppress the circumferential rotation, thereby reducing the thickness of the mechanical connecting device and further improving the economical efficiency and manufacturing.

According to an aspect of the present invention, there is provided a steel pipe connecting apparatus for connecting neighboring steel pipes, comprising: a pin joint fixedly coupled to one end of a steel pipe; and a box joint fixedly coupled to the other end of the steel pipe, Wherein a first groove is provided on an outer circumferential surface of the pin joint which is in surface contact with the box joint, and an inner circumferential surface of the box joint which is in surface contact with the pin joint portion is provided with the pin joint and the box joint, Wherein a second groove is provided at a position corresponding to the first groove and a connecting groove is formed in an outer circumferential surface of the box joint so as to partially communicate with the second groove, And a second groove which is inserted through the connecting groove to fill the circumferential groove formed by the first groove and the second groove, A steel pipe connecting apparatus having a connecting member may be provided.

Wherein the connection groove is formed to have a predetermined length along an outer circumferential surface of the box joint, wherein the connection groove has a communication hole communicating with the second groove, and a communication hole communicating with the outer circumferential surface of the box joint in the axial direction of the box joint from the communication hole And may have a stepped surface formed to be stepped.

Wherein the shear connection member includes an arc-shaped shear connection member having a cross section corresponding to the circumferential groove, the circular shear connection member being inserted into the circumferential groove through the connection groove to fill the circumferential groove; And a final shear connection member fastened to the box joint by a fastening bolt to prevent the shear connection member from escaping from the connection groove.

The connection length of the plurality of shear connection members may be formed to have a length corresponding to the length of the circumferential groove.

Wherein the shear connection member includes an arc-shaped shear connection member having a cross section corresponding to the circumferential groove and divided into a plurality of segments to be inserted into the circumferential groove through the connection groove; And a final shear connector inserted into the circumferential groove together with the shear connector to fill the circumferential groove and fastened to the box joint by a fastening bolt to close the connecting groove.

Wherein the total length of the plurality of shear connection members has a length of the circumferential groove except for the length of the connection groove, the final shear connection member includes an insertion portion to be inserted into the circumferential groove, And the like.

The plurality of first grooves may be spaced apart from each other by a predetermined distance in the axial direction of the pin joint, and the second grooves may be formed at a predetermined distance in the axial direction of the box joint so as to correspond to the first grooves.

Wherein the pin joint has a first concavo-convex portion having an outer concavo-convex inclined portion inclined from the outer circumferential surface to the inner accommodating portion and an inner concavo-convex inclined portion inclined toward the first engaging portion at the outer concavo-convex inclined portion, A first engaging portion having an engaging slope portion and an inner engaging slope inclined from the protruding end portion toward the first engaging portion formed with the first recess, wherein the box joint includes a second engaging portion having the second recess, A second engaging portion having a shape corresponding to the first concave-convex portion, and a second engaging portion having a shape corresponding to the first concave-convex portion, wherein when the pin joint and the box joint are engaged, And the second latching portion is fitted to the first concavo-convex portion, so that the radial relative movement of the pin joint and the box joint can be restrained.

A pin joint having a first groove formed on an outer surface in a circumferential direction and a rotation restricting groove; A box joint having a second groove forming a circumferential groove together with the first groove when fastened to the pin joint and a connection groove extending from the outer surface toward the second groove; A first preheating and heating material fastened to the circumferential groove to restrain axial relative movement of the pin joint and the box joint; And a second shear connector coupled to the coupling groove and the rotation constraint groove and restricting relative movement of the pin joint and the box joint in the circumferential direction.

The connection groove includes a communication hole communicating with the second groove; A rotation constraint hole formed on an opposite surface of the rotation restraint groove; And a stepped surface formed stepwise inward from an outer circumferential surface of the box joint.

The second shear connection member includes an axial restraining portion for restricting axial relative movement of the pin joint and the box joint together with the first shear connection member; A circumferential restraining part which is fitted in the rotation restricting groove; And a cover plate fastened to the stepped surface.

The rotation restraint groove may be provided perpendicularly to the first groove, and the axial restraint portion and the circumferential restraint portion may be integrally provided, and may protrude in a cross shape from the cover plate.

Wherein the pin joint comprises a first engaging portion and a first concave and convex portion, the box joint has a second engaging portion and a second concave and convex portion, and when the pin joint and the box joint are engaged, And the second engaging portion is fitted in the first concave / convex portion, so that the radial relative movement of the pin joint and the box joint can be restrained.

Wherein the first engaging portion is provided with an inner engaging sloped portion which is inclined from an inner circumferential surface of the pin joint to a protruding end portion and an inclined sloping portion inclined from the protruding end portion to a first engaging portion formed with the first groove, Wherein the box joint has an outer concavo-convex inclined portion inclined from the outer circumferential surface of the pin joint to the inner accommodating portion and an inner convex-concavo portion inclined toward the first engaging portion at the outer concavo-convex inclined portion, A second engaging portion formed with the second groove facing the first groove at the time of engaging, a second concave-convex portion having a shape corresponding to the first engaging portion, and a second engaging portion having a shape corresponding to the second concave- A latching portion can be provided.

The first shear connection member may have an arcuate shape having a cross section corresponding to the circumferential groove and being divided into a plurality of portions to be inserted into the circumferential groove through the connecting groove to fill the circumferential groove.

The steel pipe connecting apparatus according to the present invention can secure sufficient structural rigidity by connecting the box joint and the pin joint without the empty space, and it is possible to improve the economical efficiency and manufacturing by reducing the thickness remarkably.

In addition, since the circumferential relative rotation of the box joint and the pin joint can be suppressed by the circumferential restraining portion of the second front end coupling member without a separate rotation inhibition device, the manufacturing cost can be reduced and the ease of installation can be improved.

Further, the concave-convex portion and the engaging portion of the box joint and the pin joint are each inclined so as to prevent detachment due to the force applied to each joint, to be advantageous in fabrication and machining in a smooth shape, and also to be resistant to compressive force.

1 is an exploded perspective view of a part of a steel pipe connecting apparatus according to a first embodiment of the present invention.
2 is an assembled perspective view of FIG.
3 is a cross-sectional view illustrating a steel pipe connecting apparatus according to a first embodiment of the present invention.
4 is a view showing a state where a shear connection member is installed in a circumferential groove formed between a pin joint and a box joint of a steel pipe connecting apparatus according to the first embodiment of the present invention.
5 is a view showing a second embodiment of a front end connecting member provided in the steel pipe connecting apparatus according to the first embodiment of the present invention.
6 is a view showing a state in which a shear connection member according to a second embodiment of the present invention is installed.
7 is a cross-sectional view illustrating a state in which a steel pipe connecting apparatus according to a third embodiment of the present invention is assembled.
8 is an assembled cross-sectional view of Fig.
9 is an exploded perspective view showing a part of a steel pipe connecting apparatus according to a fourth embodiment of the present invention.
10 is a cross-sectional front view of Fig.
11 is a cross-sectional side view after assembly of Fig.
FIG. 12 shows a method in which a first shear connector is installed in a circumferential groove of a steel pipe connecting apparatus according to a fourth embodiment of the present invention.
13 is a side sectional view after the first shear connector is installed in Fig.
14 shows a state in which a second shear connector is installed in a steel pipe connecting apparatus according to a fourth embodiment of the present invention.
Fig. 15 is a plan sectional view of Fig. 14; Fig.
16 is a side sectional view showing a state in which a steel pipe connecting apparatus according to a fifth embodiment of the present invention is assembled.
17 is a side sectional view showing a state before assembling the steel pipe connecting apparatus according to the sixth embodiment of the present invention.
18 is a partially enlarged view of the left part of the steel pipe connecting apparatus in Fig.
19 is a side sectional view showing a state after assembly of a steel pipe connecting apparatus according to a sixth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided to fully convey the spirit of the present invention to a person having ordinary skill in the art to which the present invention belongs. The present invention is not limited to the embodiments shown herein but may be embodied in other forms. For the sake of clarity, the drawings are not drawn to scale, and the size of the elements may be slightly exaggerated to facilitate understanding.

FIG. 1 is an exploded perspective view of a part of a steel pipe connecting apparatus according to a first embodiment of the present invention, FIG. 2 is an assembled perspective view of FIG. 1, and FIG. 3 is a sectional view showing the steel pipe connecting apparatus.

1 to 3, a steel pipe connecting apparatus according to an aspect of the present invention includes a pin joint 110 fixedly coupled to one end of a steel pipe 10, 20, A box joint 120 fixedly coupled to the other end of the box joints 110 and 20 and a shear connection member 130 for restraining relative movement of the pin joint 110 and the box joint 120. In this case, the pin joint 110 is fixed to the upper part of the lower steel pipe 10 by welding, and the box joint 120 is shown to be fixed to the lower part of the upper steel pipe 20 by welding. However, And the box joint 120 are installed in one steel pipe 10, 20, respectively. In other words, a pin joint 110 is provided on the upper side of the steel pipes 10 and 20 for connecting the upper and lower parts of the neighboring steel pipes 10 and 20. On the lower side of the steel pipes 10 and 20, ). Accordingly, the steel pipes 10 and 20 are connected through the box joint 120 provided at the lower part of the upper steel pipe 20 and the pin joint 110 provided at the upper part of the lower steel pipe 10.

The pin joint 110 has a cylindrical shape and is fixed to the upper portion of the lower steel pipe 10 by welding. More specifically, the pin joint 110 has a first base portion 111 fixed to the upper portion of the lower steel pipe 10 and a first engagement portion 113 extending in the vertical direction from the first base portion 111 . The first base portion 111 is provided with a first concave portion 112 protruding outwardly and having a structure of a protrusion 112a and a groove 112b.

The first engaging portion 113 is formed to have an outer diameter smaller than the outer diameter of the first base portion 111 and a first groove 115 is formed on the outer peripheral surface along the outer peripheral surface. The first engaging portion 113 is formed at its distal end with a first engaging portion 114 formed to be stepped inwardly from the outer circumferential surface of the first engaging portion 113.

The box joint 120 has a cylindrical shape and is welded to the lower portion of the upper steel pipe 20 by welding. More specifically, the box joint 120 has a second base portion 121 fixed to the lower portion of the upper steel pipe 20 and a second engagement portion 123 extending in the vertical direction from the second base portion 121 . The second base portion 121 is provided with a second concavo-convex portion 124 protruding inwardly and having a structure of a projection 124a and a groove 124b so as to be in contact with the first coupling portion 114. [

The second engaging portion 123 has an inner diameter smaller than the inner diameter of the second base portion 121 and has an inner circumferential surface formed with a second groove 125 along the inner circumferential surface thereof. At this time, the inner diameter of the second coupling portion 123 is set to have a diameter corresponding to the outer diameter of the first coupling portion 113. The length of the second coupling portion 123 has a length corresponding to the length of the first coupling portion 113. When the pin joint 110 and the box joint 120 are coupled to each other, the first engaging portion 113 of the pin joint 110 is fitted into the box joint 120 and the outer surface of the first engaging portion 113 and the second engaging portion 113 And the inner circumferential surface of the engaging portion 123 is in surface contact. On the other hand, the second engaging portion 123 is formed at its distal end with a second engaging portion 122 formed to be stepped outward from the inner circumferential surface of the second engaging portion 123. The second engaging portion 122 is configured to contact the first concave and convex portion 112 when the pin joint 110 and the box joint 120 are engaged.

The overall outline of the pin joint 110 and the box joint 120 as described above has a shape corresponding to each other with a phase difference of 180 degrees. When the pin joint 110 and the box joint 120 are engaged, the protruded portion of the first engaging portion 114 is fitted in the groove 124b of the second concave and convex portion 124, and the second engaging portion 122 Is fitted into the groove 112b of the first concavity and convexity 112 so that the pin joint 110 and the box joint 120 are compactly engaged with each other.

Meanwhile, when the pin joint 110 and the box joint 120 are coupled, the first groove 115 and the second groove 125 are formed at positions corresponding to each other. A circumferential groove S having a rectangular cross section is formed between the pin joint 110 and the box joint 120 by the first groove 115 and the second groove 125. In order to insert the front end connecting member 130 to be described later, the outer circumferential surface of the box joint 120 is provided with a connecting groove 126 communicating with the second groove 125. More specifically, the connection groove 126 is formed on the outer circumferential surface of the box joint 120, and is formed at a position corresponding to the position where the second groove 125 is formed. Further, the connection groove 126 is formed to have a predetermined length along the outer peripheral surface of the box joint 120. The connection groove 126 has a communication hole 126a communicating with the second groove 125 and an outer peripheral surface 126b of the box joint 120 in the axial direction (longitudinal direction) of the box joint 120 from the communication hole 126a. And a stepped surface (126b) formed so as to be stepped. At this time, the communication hole 126a is for inserting the front end connecting member 130 to be described later into the circumferential groove S, and the stepped surface 126b is formed so as to block the connecting groove 126 through the front end connecting member 130 And has a function of a mounting surface to be combined.

The shear connecting member 130 is inserted into the circumferential groove S and closes the connecting groove 126 to restrict the relative movement of the pin joint 110 and the box joint 120. The shear connecting member 130 has a final shear connecting member 136 which is fastened to the stepped surface 126b of the connecting groove 126 by a plurality of divided shear connecting members 132 and fastening bolts 134.

The plurality of divided shear connecting members 132 have a cross section and an arc shape corresponding to the circumferential grooves S so as to be inserted into the circumferential grooves S and fill the circumferential grooves S. [ The connection length of the plurality of shear connection members 132 has a length corresponding to the length of the circumferential groove S. The front end connection member 132 is inserted into the circumferential groove S through the communication hole 126a of the connection groove 126. [ 4, after inserting one shear connector 132 into the circumferential groove S, an external force is applied to the inserted shear connector 132 so as to move the circumferential groove S in the left or right circumferential direction of the circumferential groove S And then the other shear connector 132 is inserted into the circumferential groove S and is moved in the circumferential direction. Thus, the void space of the circumferential groove S is filled. The plurality of shear connectors 132 have a number obtained by dividing the length of the circumferential groove S by 1 / n so as to compactly fill the empty space of the circumferential groove S. For example, the plurality of shear connectors 132 may be divided into a total of eight shear connectors 132 so as to have an angle of from 0 to 45 degrees with respect to the central axis so as to fill the circumferential groove S having a circumference of 360 degrees. . It is preferable that the connection groove 126 has an angle from 0 ° to 45 ° so that the front end connection member 132 is inserted into the circumferential groove S through the communication hole 126a. The number of the plurality of shear connectors 132 is not limited to eight, and the number of the shear connectors 132 can be optionally increased or decreased as long as the hollow space of the circumferential groove S can be filled. At this time, it is obvious that the length of the connection groove S is formed to have a length corresponding to the length of the front end coupling member 132, which is changed according to the number of divided portions.

The final shear connector 136 is engaged to close the connecting groove 126 through the fastening bolt 134. The final shear connection member 136 is formed to have a shape that coincides with the connection groove 126. The final shear connecting member 136 is fastened to the box joint 120 through the fastening bolt 134 in such a state that the final shear connecting member 136 is in close contact with the step surface 126b so that the outer circumferential surface has the same surface as the outer circumferential surface of the box joint 120. The fastening bolt 134 is fastened to the pin joint 110 through the box joint 120 to prevent rotation of the pin joint 110 and the box joint 120 when the final shear connector 136 is installed desirable.

Although it has been shown and described that the circumferential groove S is compactly filled through the shear connection member 132 and is then finished with the final shear connection member 136, the final shear connection member 136 ' And may be provided to fill the groove S. A second embodiment of this shear connecting member 130 'is shown in Figs. 5 and 6. Fig.

5 and 6, the front end connecting member 130 'according to the second embodiment of the present invention includes a front end connecting member 132 divided into a plurality of pieces to be inserted into the circumferential groove S through the connecting groove 126, And a final shear connection member 136 'closing the connection groove 126 by a fastening bolt 134. The shear connecting member 130 'according to the present embodiment is formed so as to fill the circumferential groove S formed through the engagement of the pin joint 110 and the box joint 120 and to close the connecting groove 126, So as to restrain the relative movement of the pin joint 110 and the box joint 120.

More specifically, the plurality of shear connectors 132 each have a cross section corresponding to the circumferential groove S. The plurality of shear coupling members 132 are divided into a total of seven with an arc shape. For example, the plurality of shear connectors 132 inserted into the circumferential grooves S having an angle of 360 degrees are divided to have an angle of 0 ° to 45 ° with respect to the central axis, and are provided with seven shear connectors 132 do. The connection length of the plurality of shear connection members 132 is formed to be smaller than the length of the circumferential groove S,

As described above, since the circumferential groove S can not be compactly filled with the plurality of shear connection members 132 and an empty space is formed, the final shear connection member 136 'is formed with a plurality of shear connection members 132, S to fill the remaining empty space. The final shear connection member 136 'has an insertion portion 136a' inserted into the circumferential groove S and a flange portion 136b 'extended from the insertion portion 136a' to cover the connection groove 126 Respectively. That is, the final shear connector 136 'is provided so that its cross section has a "T" shape. The final shear connection member 136 'is provided so that the flange portion 136b' is in surface contact with the step surface 126b in a state where the insertion portion 136a 'is inserted into the circumferential groove S, The outer circumferential surface of the shear connecting member 136 'is disposed on the same plane as the outer circumferential surface of the box joint 120. Thus, the upper steel pipe 20 and the lower steel pipe 10 are stably connected by fixing the final shear connection member 136 'to the box joint 120 and the pin joint 110 using the fastening bolts 134.

The steel pipe connecting apparatus described above is shown and described as having one first groove 115 and one second groove 125 in the pin joint 110 and the box joint 120, A plurality of first grooves 115a and 115b may be formed in the box joint 120 and a plurality of second grooves 125a and 125b may be formed in the box joint 120. [ 7 and 8 show a steel pipe connecting apparatus having a plurality of first grooves 115a and 115b and second grooves 125a and 125b. Here, the same reference numerals as in the drawings shown above indicate members having the same function.

FIG. 7 is a cross-sectional view illustrating a state in which a steel pipe connecting apparatus according to a third embodiment of the present invention is assembled, and FIG. 8 is an assembled cross-sectional view of FIG.

7 and 8, the steel pipe connecting apparatus includes a pin joint 110 fixedly coupled to an upper end of a lower steel pipe 10, a box joint 120 fixedly coupled to a lower end of the upper steel pipe 20, And a shear connecting member 130 for restraining relative movement of the joint 110 and the box joint 120. The steel pipe connecting apparatus according to the present embodiment has first grooves 115a and 115b formed on the outer circumferential surface of the first engaging portion 111 of the pin joint 110 along the outer circumferential surface thereof, (110). As shown, two first grooves 115a and 115b are formed on the outer circumferential surface of the pin joint 110. Second grooves 125a and 125b are formed in the inner circumferential surface of the second engaging portion 121 of the box joint 120. The second grooves 125a and 125b are formed at regular intervals in the axial direction of the box joint 120 And a plurality of them are formed apart from each other. As shown in the figure, two second grooves 125a and 125b are formed on the inner circumferential surface of the box joint 120. [ That is, the second grooves 125a and 125b are formed to correspond to the first grooves 115a and 115b when the pin joint 110 and the box joint 120 are coupled to each other, and the two first grooves 115a and 115b And two circumferential grooves Sa and Sb are formed by the second grooves 125a and 125b.

In order to insert the shear connection member 130 into the circumferential grooves Sa and Sb by providing two circumferential grooves Sa and Sb, the second grooves 125a and 125b are formed on the outer circumferential surface of the box joint 120, The connecting groove 126 is formed at a position corresponding to the connecting groove 126. [

A plurality of shear connection members 132 of the shear connecting member 130 are inserted into the circumferential grooves 126 to fill the circumferential grooves Sa and Sb and the final shear connecting member 136 is inserted through the fastening bolts 134 And is coupled to the box joint 120. Although not shown, it may be combined to seal the two connection grooves 126 at one time through one final shear connector after filling the respective circumferential grooves Sa and Sb.

Although two first grooves 115a and 115b and two second grooves 125a and 125b are shown in the pin joint 110 and the box joint 120 as described above, .

As a result, compactness of the circumferential groove S between the pin joint 110 and the box joint 120 secures the structural rigidity and reduces the thickness of the steel pipe connecting device by eliminating the unnecessary empty space as in the prior art. Thereby making it possible to improve the economical efficiency and the writing performance.

FIG. 9 is an exploded perspective view of a part of a steel pipe connecting apparatus according to a fourth embodiment of the present invention, FIG. 10 is a front elevational view of the assembly of FIG. 9, and FIG. 12 shows a state in which the first shear connection member 230 is installed in the circumferential groove S formed between the pin joint 210 and the box joint 220. Fig. 13 shows a state in which the first shear connection member 230 Is provided. 14 shows a state in which the second shear connecting member 240 is installed in the steel pipe connecting apparatus according to the fourth embodiment, and Fig. 15 is a plan sectional view of Fig.

Referring to the drawings, a steel pipe connecting apparatus according to a fourth embodiment of the present invention is an apparatus for connecting neighboring steel pipes. The steel pipe connecting apparatus includes a pin joint 210 fixedly connected to one end of a steel pipe 10, A box joint 220 fixedly coupled to the other end of the box joint 220 and a first shear connection member 230 restricting upward and downward relative movement of the pin joint 210 and the box joint 220.

The pin joint 210 may be welded to the upper portion of the lower steel pipe 10 and the box joint 220 may be welded to the lower portion of the upper steel pipe 20. [ That is, the steel pipe connecting device is for connecting upper and lower parts of the neighboring steel pipes 10 and 20, and a pin joint 210 is provided on the upper side of the lower steel pipe 10, (Not shown).

The pin joint 210 has a cylindrical shape and can be welded to the upper portion of the lower steel pipe 10. Specifically, the pin joint 210 includes a first engaging portion 213 extending from the upper portion of the lower steel pipe 10 and a first irregular portion having a structure of protrusions 212a and a groove 212b 212).

On the outer circumferential surface of the first engagement portion 213, a first groove 215 is formed in the circumferential direction. The first engaging portion 213 is formed at its distal end with a first engaging portion 214 formed to be stepped inward from the outer circumferential surface of the first engaging portion 213.

The box joint 220 has a cylindrical shape and is welded to the lower portion of the upper steel pipe 20 by welding. Specifically, the box joint 220 includes a second engaging portion 223 formed at a lower portion of the upper steel pipe 20 and extending in the vertical direction, and a projection 224a and a groove 224b to be in contact with the first engaging portion 214. [ The second concavo-convex portion 224 having the structure of Fig.

On the inner circumferential surface of the second engagement portion 223, a second groove 225 is formed in the circumferential direction. At this time, the inner diameter of the second coupling portion 223 is set to have a diameter corresponding to the outer diameter of the first coupling portion 213. The length of the second engagement portion 223 has a length corresponding to the length of the first engagement portion 213. When the pin joint 210 and the box joint 220 are coupled to each other, the first coupling portion 213 of the pin joint 210 is inserted into the box joint 220 and the outer peripheral surface of the first coupling portion 213 and the second coupling portion 213 The inner circumferential surface of the engaging portion 223 is in surface contact.

The second engaging portion 223 is formed with a stepped second engaging portion 222 at a lower end thereof inwardly from the outer peripheral surface of the second engaging portion 223. The second engaging part 222 is configured to contact the first concave and convex part 212 when the pin joint 210 and the box joint 220 are engaged.

The overall external shape of the pin joint 210 and the box joint 220 is cylindrical and the upper side of the pin joint 210 and the upper side of the box joint 220 correspond to each other. When the pin joint 210 and the box joint 220 are coupled to each other, the protruding portion of the first engaging portion 214 is engaged with the groove 224b of the second concave and convex portion 224, and the second engaging portion 222 Is fitted into the groove 212b of the first concavo-convex portion 212. As a result,

When the pin joint 210 and the box joint 220 are coupled, the first groove 215 and the second groove 225 are formed at positions corresponding to each other. A circumferential groove S having a rectangular cross section is formed between the pin joint 210 and the box joint 220 by the first groove 215 and the second groove 225.

The connection groove 226 is formed in communication with the second groove 225 on the outer circumferential surface of the box joint 220 to insert a first shear connection member 230 to be described later into the circumferential groove S. That is, the connection groove 226 is formed on the outer circumferential surface of the box joint 220, and is formed at a position corresponding to the position where the second groove 225 is formed.

The connection groove 226 is formed to have a predetermined length along the outer circumferential surface of the box joint 220. The connection groove 226 has a communication hole 226a communicating with the second groove 225, a rotation constraint hole 226b formed perpendicular to the communication hole 226a, a communication hole 226a extending from the box joint 220 And a stepped surface 226c formed so as to be stepped with the outer peripheral surface of the box joint 220 in the radial direction of the box joint 220. At this time, the communication hole 226a is for inserting a first shear connection member 230 to be described later into the circumferential groove S and the rotation constraint hole 226b is for connecting the pin joint 210 and the box joint 220 in the circumferential direction And the step surface 226c has a function of a mounting surface that is coupled to close the connecting groove 226 through a second shear connecting member 240 to be described later.

The shear connector includes a plurality of first shear connectors 230 and a second shear connector 240 for final fastening which are inserted into the circumferential grooves S and the connecting grooves 226 to form a box joint 220 and a pin joint 220. [ Thereby restricting the relative movement of the second arm 210.

The first shear connector 230 is inserted into the circumferential groove S and functions to restrain the relative movement of the pin joint 210 and the box joint 220 in the axial direction. The circumferential groove S is formed by joining the first groove 215 of the pin joint 210 and the second groove 225 of the box joint 220. The first shear coupling member 230 is inserted into the circumferential groove S, Is inserted to prevent the longitudinal displacement of the pin joint 210 or the box joint 220.

The first shear connector 230 divided into a plurality of sections has a cross section and a shape corresponding to the circumferential grooves S so as to be inserted into the circumferential grooves S and fill the circumferential grooves S, respectively. The first shear connection member 230 may be inserted into the circumferential groove S through the communication hole 226a of the connection groove 226. [ That is, after inserting one first shear connector 230 into the circumferential groove S, an external force is applied to the inserted first shear connector 230 to move it in the circumferential direction to the left or right of the circumferential groove S, The other first shear connector 230 is inserted into the circumferential groove S and is repeatedly moved in the circumferential direction to fill the empty space of the circumferential groove S. [

The plurality of first shear connecting members 230 and the second shear connecting members 240 for finishing fastening have a number obtained by dividing the length of the circumferential groove S by 1 / n so as to fill the empty space of the circumferential groove S. For example, the plurality of first shear connection members 230 and the second shear connection members 240 are divided so as to have an angle of 0 to 45 degrees with respect to the central axis so as to fill the circumferential groove S having a circumference of 360 degrees A total of seven first shear connectors 230 and one second shear connector 240 may be provided. At this time, the connection groove 226 may be provided at an angle of 0 ° to 45 ° so that the first shear connection member 230 is inserted into the circumferential groove S through the communication hole 226a.

The second shear connection member 240 is finally coupled to close the connection groove 226 when the insertion of the first shear connection member 230 is completed. The second shear connecting member 240 has a shape that coincides with the connecting groove 226. The second shear connection member 240 is connected to the box joint 220 through a fastening bolt (not shown) in a state where the cover plate 243 is in close contact with the step surface 226c so that the outer circumferential surface smoothly connects to the outer circumferential surface of the box joint 220. [ As shown in Fig.

The second shear connection member 240 includes an axial restricting portion 241 for restricting axial relative movement of the pin joint 210 and the box joint 220 together with the first shear connection member 230, A circumferential restraining portion 242 fitted to the stepped surface 226c, and a cover plate 243 fastened to the stepped surface 226c. At this time, the axial restraining portion 241 and the circumferential-direction restraining portion 242 are integrally provided, and can protrude in a cross shape from the cover plate 243.

Accordingly, the first shear coupling member 230 restricts the axial movement of the pin joint 210 and the box joint 220, the second shear coupling member 240 restricts the axial movement and the circumferential movement, (212, 222) and the concave and convex portions (214, 224) can restrict the movement in the three-axis coordinate system of the steel pipe connecting device by restraining the radial relative movement.

In addition, the box joint 220 and the pin joint 210 are connected to each other without an empty space, sufficient structural rigidity can be ensured, and economical efficiency and preparation can be improved through remarkable thickness reduction. Further, since the circumferential relative rotation of the box joint and the pin joint can be suppressed by the circumferential restricting portion 242 of the second front end coupling member 240 without a separate rotation inhibiting device, the manufacturing cost can be reduced and the ease of installation can be improved have.

16 is a side sectional view showing a state in which a steel pipe connecting apparatus according to a fifth embodiment of the present invention is assembled. A plurality of first grooves 315a and 315b are formed in the pin joint 310 and a plurality of second grooves 325a and 325b are formed in the box joint 320 As shown in FIG. Each of the plurality of grooves forms two circumferential grooves, and the corresponding first and second shear connectors 332 and 234 of a corresponding number and size can be fitted thereinto.

Meanwhile, although not shown, after the respective circumferential grooves are filled with the first shear connectors 332 and 234, finally, the two shear connectors (not shown) are used to close the two connecting grooves (not shown) . As a result, the structural rigidity can be secured by compactly filling the circumferential groove between the pin joint 310 and the box joint 320, and the thickness of the steel pipe connecting device can be reduced by eliminating the unnecessary empty space, It is possible to improve the composition.

FIG. 17 is a side sectional view showing a state before assembling the steel pipe connecting apparatus according to the sixth embodiment of the present invention, FIG. 18 is an enlarged view of one part of the steel pipe connecting apparatus corresponding to FIG. 17, Sectional side view showing the assembled state of the apparatus.

In order for the shear connection member 430 to be smoothly inserted, a slight tolerance and clearance are required. When the tensile force acts on the steel pipes 10 and 20 due to the space, the shear connection member 430 rotates, And the pin joint 410 are separated from each other to apply a force to break it. At this time, each of the joints 410 and 420 undergoes a flexural load, and fracture occurs at the starting point.

For this, in the steel pipe connecting apparatus according to the sixth embodiment, the thickness of the inner surface, which receives a large moment force, may be increased as compared with the end surface. Is gradually increased from the end section to the portion of the shear connection member 430, is maintained at the vertical portion again at the portion of the shear connector 430, and then is inclined to the inner surface.

This is because the end of the box joint 420 and the inner surface of the pin joint 410 are brought into contact with the front end surface to provide a strong resistance against the external load and a slope is provided on the end contact surface to prevent detachment between the two joints 410, Given that, the two joints 410, 420 prevent deformation from being separated. In this case, since the end portion is formed in a smooth shape without protrusions and grooves, it is advantageous in manufacturing and machining.

The pin joint 410 of the steel pipe connecting apparatus according to the sixth embodiment of the present invention is provided with an outer concavo-convex slope 412a inclined from the outer circumferential surface to the inner accommodating portion 412b and an outer concave- A first concave-convex portion 412 having an inner convex-concave inclined portion 412c inclined toward the first engaging portion 413 from the first concave portion 412a to the first engaging portion 413; A first engaging portion 414 having an inner engaging slope portion 414c inclined to the first engaging portion 413 where the first groove 415 is formed in the end portion 414b may be provided.

Likewise, the box joint 420 is provided with an outer concavo-convex slope 422a inclined from the outer circumferential surface toward the inner accommodating portion 422b and an inner concavo-convex inclined portion 422a inclined from the outer concave-convex slope 422a toward the first engaging portion 423 A first engaging portion 422 having an outer engaging slope 424a inclined toward the projecting end 424b in the inner peripheral surface and a first recess 425 formed at the projecting end 424b, The first engaging portion 424 may be provided with an inner engaging slope 424c inclined to the first engaging portion 414 when the pin joint 410 and the box joint 420 are engaged with each other. The second engaging portion 422 is fitted in the first concave and convex portion 412 and can restrain the relative movement of the pin joint 410 and the box joint 420 in the radial direction have.

As described above, the concave and convex portions 412 and 422 and the engaging portions 414 and 424 are inclined to prevent detachment due to the force applied to the joints 410 and 420, respectively. The engaging portions 413 and 423 may be vertically aligned and then may be inclined to the inner receiving portions 414b and 424b again have.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, You will understand. Accordingly, the true scope of the invention should be determined only by the appended claims.

S: circumferential groove 10: lower side steel pipe
20: upper steel pipe 110: pin joint
120: box joint 130: shear connection member
111: first base portion 113: first coupling portion
112a: projection 112b: groove
112: first concave / convex portion 115: first groove
114: first latching portion 121: second base portion
123: second engaging part 123: second concave-convex part
124a: projection 124b: groove
125: second groove 126: connecting groove
126a: communication hole 126b: stepped surface
132: shear connection member 134: fastening bolt
136: final shear connector 210: pin joint
212: first irregular portion 213: first engaging portion
214: first latching part 215: first groove
216: rotational restraint groove 220: box joint
222: second engaging portion 223: second engaging portion
224: second concave / convex portion 225: second groove
226: connection groove 226a: communication hole
226b: rotation restraining hole 226c:
230: first shear connector 240: second shear connector
241: Axial restraining part 242: Circumferential restraining part
243: cover plate 310: pin joint
315a, 315b: first groove 320: box joint
325a. 325b: second grooves 332, 334: first shear connector
410: pin joint 411: pin joint
412: first concave-convex portion 412a: outer convex-
412b: Inner receiving portion 412c: Inner rugged inclined portion
413: first engaging portion 414: first engaging portion
414a: outer hooking inclined portion 414b: projecting end
414c: inner engaging slope part 415: first groove
420: box joint 422: second engaging portion
422a: outer engaging slope part 422b:
422c: inner engaging slope part 423: second engaging part
424: second concave-convex portion 424a: outer concave-
424b: Inner receiving portion 424c: Inner rugged inclined portion
425: second groove 430: shear connector

Claims (15)

A steel pipe connecting apparatus for connecting adjacent steel pipes,
A pin joint fixedly coupled to one end of the steel pipe, a box joint fixedly coupled to the other end of the steel pipe and fitted with the pin joint,
Wherein a first groove is provided along an outer circumferential surface of an outer circumferential surface of the pin joint which is in surface contact with the box joint,
Wherein a second groove is provided on an inner circumferential surface of the box joint which is in surface contact with the pin joint portion at a position corresponding to the first groove in a state where the pin joint and the box joint are engaged, A connecting groove is formed so as to communicate with the two grooves,
And a front end connecting member inserted to fill the circumferential groove formed by the first groove and the second groove through the connecting groove to constrain the relative movement of the pin joint and the box joint, Steel pipe connection device. The method according to claim 1,
Wherein the connection groove is formed to have a predetermined length along an outer peripheral surface of the box joint,
Wherein the connection groove has a communication hole communicating with the second groove and a stepped surface formed so as to be stepped with the outer circumferential surface of the box joint in the axial direction of the box joint from the communication hole. The method according to claim 1,
The shear connection member
An arc-shaped shear connection member having a cross section corresponding to the circumferential groove and inserted into the circumferential groove through the connection groove to fill the circumferential groove; And
And a final shear connection member fastened to the box joint by a fastening bolt so as to block the connection groove so as to prevent the shear connection member from coming out from the connection groove. The method of claim 3,
Wherein the connection length of the plurality of shear connection members is formed to have a length corresponding to the length of the circumferential groove. The method according to claim 1,
The shear connection member
An arc-shaped shear connection member having a cross section corresponding to the circumferential groove and divided into a plurality of segments to be inserted into the circumferential groove through the connection groove; And
And a final shear connection member inserted into the circumferential groove together with the shear connection member to fill the circumferential groove and fastened to the box joint by a fastening bolt to close the connection groove. 6. The method of claim 5,
Wherein the total length of the plurality of shear connectors has a length of the circumferential groove excluding the length of the connecting groove,
Wherein the final shear connector has an insertion portion to be inserted into the circumferential groove and a flange portion extending from the insertion portion to block the connection groove. The method according to claim 1,
A plurality of first grooves are formed at predetermined intervals in the axial direction of the pin joint,
Wherein a plurality of the second grooves are formed so as to be spaced apart from each other in the axial direction of the box joint so as to correspond to the first grooves. The method according to claim 1,
Wherein the pin joint has a first concavo-convex portion having an outer concavo-convex inclined portion inclined from the outer circumferential surface to the inner accommodating portion and an inner convex-concavo portion inclined toward the first engaging portion at the outer concavo-convex inclined portion, And a first engaging portion having an engaging slope portion and an inner engaging slope portion inclined to the first engaging portion formed with the first groove at the projecting end portion,
Wherein the box joint has a second engaging portion provided with the second groove, a second concave-convex portion having a shape corresponding to the first engaging portion, and a second engaging portion having a shape corresponding to the first concavo-
Wherein the first engaging portion is fitted to the second concave-convex portion when the pin joint and the box joint are engaged, and the second engaging portion is fitted to the first concave-convex portion to restrict radial relative movement of the pin joint and the box joint Steel pipe connection device. A pin joint having a first groove formed on an outer surface in a circumferential direction and a rotation restricting groove;
A box joint having a second groove forming a circumferential groove together with the first groove when fastened to the pin joint and a connection groove extending from the outer surface toward the second groove;
A first preheating and heating material fastened to the circumferential groove to restrain axial relative movement of the pin joint and the box joint; And
And a second shear connection member fastened to the connection groove and the rotation restraint groove and restricting relative movement of the pin joint and the box joint in the circumferential direction. 10. The method of claim 9,
The connecting groove
A communication hole communicating with the second groove;
A rotation constraint hole formed on an opposite surface of the rotation restraint groove; And
And a stepped surface stepped inward from an outer peripheral surface of the box joint. 11. The method of claim 10,
The second shear connector
An axial restraining unit for restricting axial relative movement of the pin joint and the box joint together with the first shear connector;
A circumferential restraining part which is fitted in the rotation restricting groove; And
And a lid plate fastened to the stepped surface. 12. The method of claim 11,
Wherein the rotation restricting groove is provided perpendicular to the first groove,
Wherein the axial restraining part and the circumferential restraining part are provided integrally and protrude in a cruciform shape from the cover plate. 12. The method of claim 11,
Wherein the pin joint has a first engaging portion and a first concave and convex portion,
The box joint has a second engaging portion and a second concave and convex portion,
Wherein the first engaging portion is fitted to the second concave-convex portion when the pin joint and the box joint are engaged, and the second engaging portion is fitted to the first concave-convex portion to restrict radial relative movement of the pin joint and the box joint Steel pipe connection device. 14. The method of claim 13,
Wherein the first engaging portion is provided with an inner engaging sloped portion that is inclined from an inner circumferential surface of the pin joint to a protruding end portion and an outer engaging sloped portion inclined from the protruding end portion toward a first engaging portion formed with the first groove,
Wherein the first concavo-convex portion is provided with an outer concavo-convex inclined portion inclined from the outer circumferential surface of the pin joint toward the inner accommodating portion and an inner concavo-convex inclined portion inclined from the outer concave-convex inclination portion toward the first coupling portion,
Wherein the box joint includes a second engaging portion formed with the second groove facing the first groove when engaged with the pin joint, a second concave-convex portion having a shape corresponding to the first engaging portion, And a second latching portion having a shape corresponding to the portion of the second pipe. 10. The method of claim 9,
Wherein the first shear connector has a cross section corresponding to the circumferential groove and is inserted into the circumferential groove through the connecting groove to be divided into a plurality of portions to fill the circumferential groove.

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