KR102622505B1 - Pipe structure that can be combined with multiple axes - Google Patents

Abstract

The present invention includes a reference pipe formed of a square pipe; a first pipe having a first fastening means coupled to the reference pipe formed at an end; A first joint that secures the first pipe to the reference pipe; a second pipe having a second fastening means coupled to the reference pipe formed at an end; It relates to a multi-axially coupled pipe structure that is provided as a pair and includes a second joint for fixing the second pipe to the reference pipe.
According to the present invention, square pipes can be simply connected in multiple axes and firmly fixed without welding.

Description

Pipe structure that can be combined in multiple axes {PIPE STRUCTURE THAT CAN BE COMBINED WITH MULTIPLE AXES}

The present invention relates to a multi-axially coupled pipe structure in which square pipes can be simply connected and fixed without welding.

In general, in order to connect multiple pipes in different directions, skilled technicians have used the method of welding the joints of each pipe.

However, the welding connection method has the problem that only skilled technicians can perform the work, which increases the burden on labor costs and takes a long time because the connection parts of the pipes must be welded one by one.

Additionally, there is a problem that post-work is required to smooth the welded part.

In order to solve the above-mentioned problems, weldless pipe joints that can connect multiple pipes to each other without welding have been developed and are widely used.

However, the above-described non-welded pipe joint has a complicated configuration, making connection work difficult and the work time being long.

Meanwhile, the technology behind the present invention is disclosed in Republic of Korea Patent No. 10-2054232.

The purpose of the present invention is to provide a multi-axially coupled pipe structure that can simply connect and secure square pipes without welding.

The present invention includes a reference pipe formed of a square pipe; a first pipe having a first fastening means coupled to the reference pipe formed at an end; A first joint that secures the first pipe to the reference pipe; a second pipe having a second fastening means coupled to the reference pipe formed at an end; It is provided as a pair and includes a second joint that secures the second pipe to the reference pipe.

The reference pipe may have a plurality of cutting grooves formed at the corners through which the first fastening means and the second fastening means can be simultaneously fastened.

A first slit is formed between the first fastening means and the end of the first pipe, and when the first fastening means is inserted into the cutting groove, a portion of the surface on which the cutting groove is formed will be inserted into the first slit. You can.

The second fastening means may extend so that second slits are formed on both sides of the ends of the second pipe, and may be inserted into the cutting groove.

The first joint may be installed on the reference pipe and may be coupled with the first fastening means to secure the first pipe to the reference pipe.

The second joint may be inserted into the second slit of the pair of second fastening means and may be installed on the reference pipe to fix the position of the second pipe.

The multi-axial pipe structure according to the present invention can be firmly fixed by simply connecting square pipes in multiple axes without welding.

1 is an overall view showing a multi-axial pipe structure according to an embodiment of the present invention,
Figure 2 is a diagram showing the reference pipe and the first pipe of the multi-axially coupled pipe structure of Figure 1;
Figure 3 is a diagram showing the reference pipe and the second pipe of the multi-axially coupled pipe structure of Figure 1;
Figure 4 is a view showing the disassembled multi-axial pipe structure of Figure 1;
Figure 5 is a view showing the front of the first joint of the multi-axially joined pipe structure of Figure 1;
Figure 6 is a diagram showing the first pipe of the multi-axially coupled pipe structure of Figure 1 coupled to the reference pipe;
Figure 7 is a diagram showing the first pipe and the second pipe of the multi-axial pipe structure of Figure 1 coupled to the reference pipe;
Figure 8 is a cross-sectional view of Figure 7,
Figure 9 is a diagram showing a first pipe and a first joint of a multi-axially coupled pipe structure according to another embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail through illustrative drawings. When adding reference numerals to components in each drawing, it should be noted that identical components are given the same reference numerals as much as possible even if they are shown in different drawings.

Also, when describing embodiments of the present invention, if it is determined that detailed descriptions of related known configurations or functions interfere with understanding of the embodiments of the present invention, the detailed descriptions will be omitted.

Additionally, when describing the components of an embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, sequence, or order of the component is not limited by the term.

Hereinafter, a multi-axial pipe structure according to an embodiment of the present invention will be described with reference to the drawings.

Figure 1 is a diagram showing the overall multi-axially coupled pipe structure according to an embodiment of the present invention, Figure 2 is a diagram showing the reference pipe and the first pipe of the multi-axially coupled pipe structure of Figure 1, and Figure 3 is a diagram showing the It is a diagram showing the reference pipe and the second pipe of the multi-axially coupled pipe structure of Figure 1, Figure 4 is a diagram showing the exploded view of the multi-axially coupled pipe structure of Figure 1, and Figure 5 is a diagram showing the multi-axially coupled pipe structure of Figure 1. It is a view showing the front of the first joint of the pipe structure, and FIG. 6 is a view showing the first pipe of the multi-axially coupled pipe structure of FIG. 1 coupled to the reference pipe, and FIG. 7 is a diagram showing the multi-axially coupled pipe structure of FIG. 1. This is a diagram showing the first pipe and the second pipe of the pipe structure being coupled to the reference pipe, and FIG. 8 is a diagram showing a cross section of FIG. 7.

Referring to Figures 1 and 8, the pipe structure 100 that is multi-axially coupled includes a reference pipe 110, a first pipe 120, a first joint 130, a second pipe 140, and/or a second pipe. Includes joint 150.

The reference pipe 110 may be formed as a hollow rectangular pipe.

For example, the reference pipe 110 may be formed as a square pipe including a first side (1), a second side (2), a third side (3), and a fourth side (4).

Here, the first side (1) faces the third side (3), the second side (2) is connected to one end of the first side (1) and the third side (3), and the fourth side ( 4) is connected to the other end of the first side (1) and the third side (3).

A cutting groove (C) may be formed at the edge of the reference pipe 110.

The cutting groove C may be a groove penetrating from each side of the reference pipe 110 in the hollow direction of the reference pipe 110.

For example, straight cutting grooves C may be formed in the edge direction on the first surface 1 and the second surface 2 forming the corners of the reference pipe 110, respectively.

And one end of the cutting groove (C) on the first side (1) and one end of the cutting groove (C) on the second side (2) may communicate with each other.

Straight cutting grooves C may be formed in the edge direction on the second surface 2 and the third surface 3 forming the corners of the reference pipe 110, respectively.

And one end of the cutting groove (C) on the second side (2) and one end of the cutting groove (C) on the third side (3) may communicate with each other.

The cutting grooves C may be formed at regular intervals on the same edge, or may be formed at edges facing each other.

The formation position of the cutting groove (C) can be changed depending on the coupling position, coupling number, and coupling direction of the first pipe 120 and the second pipe 140, and the first fastening means 121 and the second fastening means It may be changed depending on the form of (141).

The shape of the cutting groove (C) is made to correspond to the shape of the second fastening means 121 and the second fastening means 141 so that the second fastening means 121 and the second fastening means 141 can be inserted. You can.

The first fastening means 121 and the second fastening means 141 may be fastened to the cutting groove (C) at the same time.

The first pipe 120 may be formed as a square pipe with four sides, similar to the reference pipe 110.

For example, the first pipe 120 may be formed as a square pipe including a first side (1a), a second side (2a), a third side (3a), and a fourth side (4a).

Joint coupling slits j to which the first joint 130 can be coupled may be formed on both sides of the end of the first pipe 120, respectively.

For example, the joint coupling slit j may be formed on the first surface 1a and the third surface 3a of the first pipe 120 and positioned to face each other.

The joint coupling slit j formed on the first surface 1a of the first pipe 120 is formed in the direction from one end of the first surface 1a to the other end of the first surface 1a, and the first pipe 120 The joint coupling slit (j) formed on the third surface (3a) of (120) may be formed in the direction from one end of the third surface (3a) to the other end of the third surface (3a).

A first fastening means 121 may be formed at the end of the first pipe 120.

The first fastening means 121 may be inserted into the cutting groove C of the reference pipe 110.

The first pipe 120 can be temporarily coupled to the reference pipe 110 by inserting the first fastening means 121 into the cutting groove (C).

For example, when the reference pipe 110 is referred to as the Z-axis, the first pipe 120 may be coupled to the reference pipe 110 in the X-axis or -X-axis direction.

That is, the first pipe 120 may be coupled to the first side 1 and/or the third side 3 of the reference pipe 110.

The first fastening means 121 may extend from the end of the first pipe 120.

For example, the first fastening means 121 may extend in the longitudinal direction from the ends of both sides of the first pipe 120 and be re-extended in the downward direction.

The first fastening means 121 may extend downward to form a first slit (S1).

That is, a first slit (S1) may be formed between the first fastening means 121 and the end of the first pipe 120.

When the first fastening means 121 is inserted into the cutting groove (C), the first pipe 120 can be temporarily coupled to the reference pipe 110.

Afterwards, the first pipe 120 can be completely fixed to the reference pipe 110 by the first joint 130.

When the first fastening means 121 is inserted into the cutting groove (C), a portion of the surface where the cutting groove (C) is formed may be inserted into the first slit (S1).

For example, when the first fastening means 121 is inserted into the cutting groove C formed on the first surface 1 and the second surface 2 of the reference pipe 110 in the direction of the first surface 1, A portion of the first surface 1 may be inserted into the first slit S1.

The first joint 130 fixes the first pipe 120 to the reference pipe 110, and can be installed on the reference pipe 110 by being coupled to the first pipe 120.

In more detail, the first joint 130 may include an upper surface member 131, a connecting member 132, a lower surface member 133, and a leg member 134.

The upper member 131 is provided in a trapezoidal plate shape and can be inserted into the joint coupling slit (j) of the first fastening means 121 and coupled to the first pipe 120.

The connecting member 132 is provided in a plate shape and is installed on the upper surface member 131 so as to form a right angle with the upper surface member 131.

For example, one end of the connecting member 132 is connected to one end of the upper member 131.

A plurality of threaded holes may be formed in the connecting member 132.

The connecting member 132 may be installed on the reference pipe 110 using screws or bolts.

A through slit (t) through which the first fastening means 121 can pass may be formed in the connecting member 132.

The through slit (t) may be formed in a shape corresponding to the first fastening means 121 so that the first fastening means 121 can pass through.

The first fastening means 121 may pass through the through slit (t) and be coupled to the connecting member 132.

The first fastening means 121 combined with the connecting member 132 may be inserted into the cutting groove C of the reference pipe 110.

The lower surface member 133 is arranged to face the upper surface member 131, and one end of the lower surface member 133 is connected to the other end of the connecting member 132.

The lower member 133 is provided as a pair, and each lower member 133 may be installed at the other end of the connecting member 132 to be spaced apart from each other.

The distance between each lower surface member 133 is preferably set to be equal to the width of the first pipe 120. This is because the end of the first pipe 120 must be inserted between each lower member 133.

Each lower surface member 133 may contact both sides of the first pipe 120 to restrict left and right movement of the first pipe 120.

The leg member 134 connects each of the lower surface members 133 and the upper surface member 131, and may be provided as a pair.

One end of each leg member 134 may be connected to the other end of each lower surface member 133, and the other end of each leg member 134 may be connected to the other end of the upper surface member 133.

The leg member 134 may be in contact with both sides of the first pipe 120 to limit left and right movement of the first pipe 120.

Meanwhile, an inlet space 10 into which the end of the first pipe 120 can be inserted may be formed between each lower member 133 and each leg member 134.

When the end of the first pipe 120 is inserted into the above-mentioned entry space 10, the upper surface member 131 is inserted into the joint coupling slit (j) of the first pipe 120, and the first pipe 120 and the second pipe 120 are connected to each other. One joint 130 may be coupled to each other.

At this time, the first fastening means 121 may be moved toward the outside of the connecting member 132 through the through slit (t).

Thereafter, the first fastening means 121 is fastened to the coupling slit of the reference pipe 110, so that the reference pipe 110, the first pipe 120, and the first joint 130 can be coupled to each other.

The second pipe 140, like the first pipe 120, may be formed as a square pipe with four sides.

For example, the second pipe 140 may be formed as a square pipe including a first side (1b), a second side (2b), a third side (3b), and a fourth side (4b).

A second fastening means 141 coupled to the reference pipe 110 may be formed at the end of the second pipe 140.

The second pipe 140 can be fixed to the reference pipe 110 by fastening the second fastening means 141 to the cutting groove (C).

For example, when the reference pipe 110 is referred to as the Z-axis, the second pipe 140 may be coupled to the reference pipe 110 in the Y-axis or -Y-axis direction.

That is, the second pipe 140 may be coupled to the second side 2 and/or the fourth side 4 of the reference pipe 110.

The second fastening means 141 may be extended so that second slits S2 are formed on both sides of the end of the second pipe 140, respectively.

For example, the second fastening means 141 may extend from ends of both sides facing each other. That is, the second fastening means 141 may be formed on the first surface 1b and the third surface 3b, or on the second surface 2b and the fourth surface 4b.

The second fastening means 141 may be provided in pairs on both sides of the second pipe 140, respectively.

Meanwhile, the left and right pair of second fastening means 141 may be re-extended in directions facing each other.

For example, the left second fastening means 141L extending from the left sides of the first surface 1b and the third surface 3b of the second pipe 140, respectively, and the first surface 1b of the second pipe 140. ) and the right second fastening means 141R extending from the right side of the third surface 3b may be extended in directions facing each other.

The left second fastening means 141L and the right second fastening means 141R may be extended in directions facing each other to form a second slit S2.

The second joint 150 may be inserted into the second slit S2.

The second fastening means 141 may be inserted into the cutting groove C, temporarily coupled to the reference pipe 110, and fixed to the reference pipe 110 by the second joint 150.

The second joint 150 fixes the second pipe 140 to the reference pipe 110 and may include a fixing part 151 and a guide part 152.

The fixing part 151 may be inserted into the second slit (S2) of the second fastening means 141 and coupled to the second pipe 140, and then fixed to the reference pipe 110.

For example, the fixing part 151 may be made in a rectangular plate shape.

And a plurality of screw holes into which screws can be inserted may be formed in the fixing part 151.

The width of the fixing part 151 is preferably set to a width that can be inserted into the second slit (S2).

A guide part 152 may be installed at one end of the fixing part 151 to guide the insertion position of the fixing part 151.

The guide part 152 may be installed upward at one end of the fixing part 151 to form a right angle with the fixing part 151.

When the fixing part 151 is inserted into the second slit (S2) of the second fastening means 141, the guide part 152 is in contact with the second pipe 140 and can guide the position of the fixing part 151. there is.

The second joint 150 may be provided as a pair and inserted into the second slit (S2).

For example, the second joint 150 may be stacked up and down and placed in the second slit S2 of the second fastening means 141.

As shown in FIG. 4, the second joint 150 is stacked up and down. In this case, the guide portion 152 may be stacked to face different directions with respect to the fixing portion 151.

For example, the lower second joint 150 may be arranged so that the guide part 152 is located on the right, and the upper second joint 150 may be arranged so that the guide part 152 is located on the left.

According to this laminated structure, each guide portion 152 may be in contact with both sides of the second pipe 140, so the left and right movement of the second pipe 140 may be restricted.

From now on, we will explain in detail the joining process of the pipe structure joined in multiple axes.

The user can first couple the first pipe 120 and the first joint 130 to each other.

The first fastening means 121 of the first pipe 120 may penetrate the through slit t of the connecting member 132 via the lead-in space 10 of the first joint 130.

And at the same time, the upper surface member 131 of the first joint 130 is inserted into the joint coupling slit (j) of the first pipe 120, so that the first pipe 120 and the first joint 130 can be coupled to each other. .

Afterwards, the user can couple the first pipe 120 coupled with the first joint 130 to the reference pipe 110.

In more detail, the user inserts the first fastening means 121 into the cutting groove C formed on the first surface 1 and/or the third surface 3 of the reference pipe 110 and performs the first fastening. The first slit (S1) of the means (121) is moved downward so as to be fastened to the other end of the cutting groove (C).

According to this combination, a portion of one surface of the first pipe 120 can be inserted into the first slit (S1).

In addition, the first fastening means 121 may be located in the inner hollow of the reference pipe 110 and contact the inner surface of the reference pipe 110.

Afterwards, the user can fix the first joint 130 to the first surface 1 or the third surface 3 of the reference pipe 110 through screw coupling.

According to this, the first pipe 120 can also be fixed to the reference pipe 110.

The fixed first pipe 120 may be restricted from moving up and down and left and right by the first joint 130, and forward and backward movement may be restricted by fastening the first fastening means 121 and the reference pipe 110. It can be.

After the first pipe 120 is fixed to the reference pipe 110, the user can fix the second pipe 140 to the reference pipe 110.

The user can first stack and place the second joint 150 on the second slit S2 formed by the second fastening means 141 of the second pipe 140.

For example, the user inserts the second joint 150 into the second slit (S2) in one direction, and then inserts another second joint 150 into the second slit (S2) in the other direction to make each The second joint 150 can be inserted into the second slit S2 so that they are stacked on top of each other.

And the user can fix the second joint 150, which is stacked up and down, to the second surface 2 or the fourth surface 4 of the reference pipe 110 through screw coupling.

According to this, the second pipe 120 can be fixed to the reference pipe 110.

The fixed second pipe 140 may be restricted in its vertical movement by the second joint 150, and may be restricted in its movement in the longitudinal direction of the reference pipe 110.

Additionally, since the second fastening means 141 is inserted into the reference pipe 110 and comes into contact with the inner surface of the reference pipe 110, movement of the second pipe 140 may be restricted.

Multi-axially coupled according to an embodiment of the present invention including the above-described reference pipe 110, first pipe 120, first joint 130, second pipe 140, and second joint 150. According to the pipe structure 100, square pipes can be easily assembled in a desired direction without welding.

From now on, the first pipe 120 and the first joint 130 of a multi-axially coupled pipe structure according to another embodiment of the present invention will be described.

Figure 9 shows a first pipe 120 and a first joint 130 of a multi-axially coupled pipe structure according to another embodiment of the present invention.

The first pipe 120 according to another embodiment of the present invention may be provided as a square pipe, and a first fastening means 121 may be formed at the end.

The first joint 130 may include an upper surface member 131, a connecting member 132, a lower surface member 133, and a leg member 134.

A slit portion 20 may be formed in the upper member 131 into which both sides of the first pipe 120 can be slidably inserted.

According to the slit portion 20, the first pipe 120 and the first joint 130 can be coupled to each other.

At this time, a portion of the upper surface member 131 of the first joint 130 is disposed in the inner hollow of the first pipe 120 and contacts the inner surface of the first pipe 120, thereby preventing the movement of the first pipe 120. It can be limited.

The first pipe 120 coupled with the first joint 130 may be fastened to the reference pipe 110.

Thereafter, as the first joint 130 is installed on the reference pipe 110 with a screw, the first pipe 120 may also be fixed to the reference pipe 110.

In the above, even though all the components constituting the embodiment of the present invention have been described as being combined or operated in combination, the present invention is not necessarily limited to this embodiment. That is, as long as it is within the scope of the purpose of the present invention, all of the components may be operated by selectively combining one or more of them.

In addition, terms such as “include,” “comprise,” or “have” described above mean that the corresponding component may be present, unless specifically stated to the contrary, and therefore do not exclude other components. Rather, it should be interpreted as being able to include other components. All terms, including technical or scientific terms, unless otherwise defined, have the same meaning as generally understood by a person of ordinary skill in the technical field to which the present invention pertains. Commonly used terms, such as terms defined in a dictionary, should be interpreted as consistent with the contextual meaning of the related technology, and should not be interpreted in an idealized or overly formal sense unless explicitly defined in the present invention.

100: Pipe structure joined in multiple axes
110: standard pipe
120: first pipe
130: 1st joint
140: second pipe
150: 2nd joint

Claims (6)

A reference pipe formed of a square pipe;
a first pipe having a first fastening means coupled to the reference pipe formed at an end;
A first joint that secures the first pipe to the reference pipe;
a second pipe having a second fastening means coupled to the reference pipe formed at an end;
It is provided as a pair and includes a second joint for fixing the second pipe to the reference pipe,
The reference pipe is,
Characterized in that a plurality of cutting grooves are formed at the corners through which the first fastening means and the second fastening means can be simultaneously fastened,
The second fastening means is,
The second pipe is extended so that second slits are formed on both sides of the ends of the second pipe, respectively,
Characterized by being inserted into the cutting groove,
The second joint is,
A pipe structure coupled in multiple axes, characterized in that it is inserted into the second slit of the pair of second fastening means and installed on the reference pipe to fix the position of the second pipe.
delete In claim 1,
A first slit is formed between the first fastening means and the end of the first pipe,
When the first fastening means is inserted into the cutting groove, a part of the surface where the cutting groove is formed is inserted into the first slit.
delete In claim 1,
The first joint is,
A multi-axially coupled pipe structure installed on the reference pipe and coupled with the first fastening means to secure the first pipe to the reference pipe.
delete

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