KR102326134B1 - Socket for connecting hume pipe - Google Patents

Abstract

The present invention is a connection socket connected to a joint portion between structures (hereinafter, referred to as 'tubular structures') having a flow path formed therein to change the path of the flow path, comprising: a first pipe portion having a first flow path formed therein; a second pipe part integrally extending from the other end of the first pipe part so that a second flow path formed therein communicates with the first flow path; and a third pipe part integrally extending from the other end of the second pipe part so that the third flow path formed therein communicates with the second flow path. Including, wherein the third flow path provides a Hume pipe connection socket, characterized in that bent at a specific angle from the second flow path.

Description

Hume pipe connection socket

The present invention relates to a Hume pipe connection socket, and more particularly, in forming a flow path, which is a movement path of a fluid, more various angles between the Hume pipe and the Hume pipe so that it can be flexibly applied to a section where the direction change of the flow path is required according to field conditions It is about the Hume pipe connection socket to connect with.

A hume pipe (centrifugal reinforced concrete pipe) is one of the pipes applied to the upper/sewer pipe, drainage pipe, etc. buried underground. When installing, by connecting neighboring Hume pipes to each other, the movement path through which the fluid can pass (hereinafter referred to as the 'flow path') ') can be formed.

At this time, the Hume tube is a hollow tubular body having a preset length, and when forming a flow path in a straight section, it can be easily implemented by connecting the Hume pipes one after another. In this section, it is common to change the flow path by placing a separate structure at the joint between the Hume pipes.

As a more specific example, when other facilities are buried underground, it may be unavoidable to change the path of the flow path to avoid this. In this case, by changing the arrangement angle of one Hume tube and the other Hume tube, various methods for mutual communication can be sought, one of which is Republic of Korea Utility Model Registration No. 20-0318133 (Registration date: 2003) As suggested in 06. 17, “Manhole Hume Pipe Connection Device”), it is a method of changing the path of the flow path by applying a manhole.

However, when installing a manhole, not only the construction cost increases, but there is a problem that it is difficult to apply to an area where installation of the manhole is difficult or a slight path change must be made.

Another method is to separately order a double-wall tube having a diameter larger or smaller than that of the Hume tube, connect the Hume tube and the double-wall tube, and then use mortar around the connection to fill in the separation space. How to change the path of

However, since it takes a certain amount of time to manufacture the above-described structure, it is difficult to immediately respond to the case where a route change is required due to on-site conditions during the work, not the intended route change in the design stage. There was a problem in that work efficiency such as schedule adjustment became inevitable. In addition, this could also increase the overall construction cost due to the production of the structure and adjustment of the construction schedule.

The present invention is to solve the above problems, and in forming a flow path of a fluid, that is, a flow path, to provide a Hume pipe connection socket that can be flexibly applied to a section where a direction change of the flow path is required according to field conditions. There is this.

In order to achieve this object, the Hume pipe connection socket according to an embodiment of the present invention is connected to a joint portion between structures (hereinafter, referred to as 'tubular structures') having flow paths formed therein, and a connection socket for changing the path of the flow path. As a first pipe portion having a first flow path formed therein; a second pipe part integrally extending from the other end of the first pipe part so that a second flow path formed therein communicates with the first flow path; and a third pipe part integrally extending from the other end of the second pipe part so that the third flow path formed therein communicates with the second flow path. Including, the third flow path may be bent at a specific angle from the second flow path.

In this case, the specific angle may be 10° to 20°.

And, an end of the tubular structure is inserted and coupled to one end of the first tube portion toward the first flow passage; is provided, and a fastening hole to which a fastening member for restricting the movement of the tubular structure inserted into the intubation unit is fastened; may be formed on the side of the intubation unit.

In addition, the first flow path may have a diameter formed concentrically with the diameter of the second flow path, and an inner circumferential surface from the first pipe part to the second pipe part may be formed to have a step in the longitudinal direction.

At this time, the other end of the third pipe part is provided with a coupling part for insertion and coupling inside the tubular structure, and the coupling part is provided with a ring-shaped sealing member that is in close contact with the inner circumferential surface of the tubular structure and surrounds the outer periphery to ensure watertightness. can be

In addition, the third pipe part, from one end in contact with the second pipe part to the other end where the coupling part is located has a length shorter than the length of the other side, the side of the second pipe part and the third pipe part The boundary portion, which is a boundary point on one side, may limit the degree of insertion of the third pipe part into the tubular structure.

And, the coupling portion is inserted and coupled to the intubation portion of the adjacent Hume tube connection socket, and by connecting at least two or more Hume tube connection sockets, it is possible to adjust the bending angle of the joint portion between the plurality of tubular structures.

In addition, an identification tag for recognizing the construction direction on the outer surface of the first pipe part; may be provided.

In addition, the first pipe part, the second pipe part, and the third pipe part may be made of cast iron.

As described above, according to the present invention, there are the following effects.

First, as the flow path formed inside the Hume pipe connection socket of the present invention is provided to be bent in one direction with a bending angle of 15°, one or more Hume pipe connection sockets are interconnected to change the flow path of the joint portion between the Hume pipes. In this case, the flow path of the corresponding joint portion may be provided to have various angles and paths while ensuring maximum straightness. That is, the degree of freedom in design can be secured.

Second, when a change of the flow path is required due to on-site conditions during work, rather than the intended path change in the design stage, an immediate response is possible, so the constructability can be improved.

Third, as the Hume pipe connection socket of the present invention is provided with cast iron, it can have high strength even though it has a thin thickness, so it is possible to reduce the weight of the product, and its workability is also excellent, so that the aforementioned manhole or additional structure is applied. Construction costs can be reduced compared to

Figure 1a is a perspective view showing a Hume tube connection socket according to an embodiment of the present invention.
Figure 1b is a cross-sectional view showing the AA' section of the Hume tube connection socket shown in Figure 1;
2 to 4 are exemplary views showing an example in which the Hume pipe connection socket according to an embodiment of the present invention is applied to the joint portion of the Hume pipe.

A preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings, but already known technical parts will be omitted or compressed for the sake of brevity of description.

<Description of the Hume tube connection socket>

Figure 1a is a perspective view showing a Hume tube connection socket according to an embodiment of the present invention, Figure 1b is a cross-sectional view showing a section AA' of the Hume tube connection socket shown in Figure 1, Figure 2 is an embodiment of the present invention It is an exemplary view showing an example in which the Hume pipe connection socket according to the Hume pipe is applied to the joint part of the Hume pipe.

1 to 2, the Hume pipe connection socket 100 according to an embodiment of the present invention is connected to a joint portion between structures (hereinafter, referred to as 'tubular structures') having a flow path formed therein, the path of the flow path As a connection socket for changing the, it is configured to include a first tube portion 110, a second tube portion 120 and a third tube portion (130).

For reference, the tubular structure referred to in this description means at least any one of the Hume tube (HP) and the Hume tube connection socket 100, but is not limited thereto, and any structure may be applied as long as a flow path is formed therein. Of course.

The first pipe part 110 is a hollow tubular body having a first flow path FR1 formed therein, and an intubation part 111 to which an end of the tubular structure is inserted and coupled to the first flow path FR1 is provided at one end.

In addition, a fastening hole 111a to which the fastening member B for restricting the movement of the tubular structure inserted into the intubation part 111 is fastened is formed on the side of the intubation part 111 . For reference, although the fastening hole 111a is not separately illustrated in FIG. 1A , the existence of a corresponding configuration may be considered.

As an example, the fastening member (B) may be a commonly used fastening bolt, and this fastening member (B) is fastened to the fastening hole (111a) and then the end thereof is in contact with the fastening hole (111a) on the outer circumferential surface of the tubular structure. By entering a predetermined length, the connection between the Hume tube connection socket 100 and the tubular structure can be made. In this case, the tubular structure may be provided with a fastening hole (not shown) through which the fastening member (B) can be inserted and fastened.

As another example, the fastening member B may be a headless bolt. At this time, the end of the fastening member (B) inserted into the fastening hole (111a) is in contact with the outer circumferential surface of the tubular structure inserted into the intubation part 111, and depending on the degree of tightening the fastening member (B) from the outside. The pressing pressure is adjusted, and the fastening member (B) can limit the movement of the tubular structure.

The second pipe part 120 is integrally formed extending from the other end of the first pipe part 110 so that the second flow path FR2 formed therein communicates with the first flow path FR1 . At this time, the first flow path FR1 has a diameter formed concentrically with the diameter of the second flow path FR2, and the inner circumferential surface from the first pipe part 110 to the second pipe part 120 is a step P in the longitudinal direction. ) is formed so that

That is, the diameter of the first flow path FR1 has a larger diameter than the diameter of the second flow path FR2, which is designed in consideration of the outer diameter of the insert, which is a tubular structure. At this time, the outer diameter of the insert may be the same as or smaller than the inner diameter of the first flow path FR1, and in this case, the diameter of the flow path formed inside the insert may have a diameter corresponding to the diameter of the second flow path FR2. .

For reference, when the insert is inserted toward the first flow path FR1, to ensure watertightness so that there is no space between the outer circumferential surface of the insert and the inner circumferential surface of the first pipe part 110 in which the first flow path FR1 is formed. A sealing member (not shown) may be located.

The third pipe part 130 is integrally formed extending from the other end of the second pipe part 120 so that the third flow path FR3 formed therein communicates with the second flow path FR2 . Here, the other end of the third pipe 130 may be provided with a coupling part 131 for being inserted and coupled to the inside of the tubular structure, that is, the flow path formed in the tubular structure.

At this time, the coupling part 131 is provided to have an outer diameter smaller than the outer diameter of one end of the third pipe part 130, and is in close contact with the inner circumferential surface of the tubular structure, and a ring-shaped sealing member 131a surrounding the outer periphery to secure watertightness. can be provided. For reference, the sealing member 131a may be a rubber ring made of a rubber material.

In addition, the third flow path FR3 may be bent at an angle of 10° to 20° from the second flow path FR2 . More specifically, the third flow path FR3 may be bent at an angle of 15° from the second flow path FR2 . This is to ensure maximum straightness and flexibly produce various angles in changing the flow path of the joint portion of the tubular structure.

In addition, the third pipe part 130 has a length (d1) of one side from one end in contact with the second pipe part 120 to the other end where the coupling part 131 is located is shorter than the length d2 of the other side, The boundary portion BP, which is a boundary point between the side surface of the second tube portion 120 and one side of the third tube portion 130 , may limit the degree of insertion of the third tube portion 130 into the tubular structure.

More specifically, as one side of the end of the tubular structure into which the third tube 130 is inserted comes into contact with the boundary portion BP, the end of the tubular structure reaches only the connection limit line LL.

And, the outer surface of the first pipe part 110 may be provided with a neighboring Hume pipe connection socket 100, that is, an identification tag (M) for leveling with the tubular structure. At this time, the identification tag 111b may be a mark provided with letters, pictures, a structure formed extending from the first pipe part 100, etc., and in constructing the Hume pipe connection socket 100, any mark that can be recognized by the installer also applicable.

More specifically, at least two identification tags M of the Hume pipe connection socket 100 may be provided, and when two identification tags M are provided, any one identification tag (for convenience of explanation, ' M1') may be positioned at a position rotated by 180° from another identification tag (hereinafter, referred to as 'M2' for convenience of description), that is, positioned to correspond to each other. At this time, when the installer looks down at the corresponding Hume pipe connection socket 100 based on M1, the bending directions of the first flow path FR1 and the second flow path FR2 of the Hume pipe connection socket 100 are bent to the right. Also, when the installer looks down at the corresponding Hume pipe connection socket 100 based on M2, the flow path bending direction of the Hume pipe connection socket 100 may be bent to the left.

At this time, any one of the identification tags (M, for convenience of explanation, hereinafter referred to as 'first identification tags') of the Hume tube connection socket 100 that is initially connected to the tubular structure (HP) is disposed to face upward, and is initially installed Any one identification tag (M, for convenience of explanation, hereinafter referred to as a 'second identification tag') of the neighboring Hume connection socket 100 connected to the Hume pipe connection socket 100 faces upward, but with the first identification tag and By being arranged on the same horizontal line, it may be possible to maintain the horizontal level of the Hume pipe connection socket 100 during construction.

That is, the identification tag (M) prevents the bending direction of the flow path in the Hume pipe connection socket 100 from being distorted in the intended construction direction while maintaining the horizontal, so the Hume pipe connection socket 100 of the present invention having this is It goes without saying that the workability can be improved when it is coupled to the joint between the tubular structures.

In addition, the Hume pipe connection socket 100 of the present invention, that is, the first pipe part 110 , the second pipe part 120 and the third pipe part 130 may be made of cast iron. Although cast iron has a high strength even if it is provided with a thinner thickness than concrete, the weight can be reduced, and the manufacturing cost can also be reduced, so that work efficiency can be increased.

For reference, the cast iron presented as the material of the Hume pipe connection socket 100 of the present invention has various advantages while having excellent workability compared to concrete, but at the temperature level such as the temperature of the fluid flowing through the internal flow and the ambient temperature change according to the seasonal change. As a result, thermal expansion or contraction may occur. Accordingly, the outer diameter of at least one of the third pipe part 130 and the coupling part 131 of the Hume pipe connection socket 100 is the inner diameter of the tubular structure facing it or the inner diameter of the first pipe part 110 of the first flow path (FR1). ) may be preferably provided smaller than the diameter of.

At this time, by the fastening member (B) is fastened to the connection portion of the tubular structure and the Hume tube connection socket 100, the position is fixed, and the tubular structure inserted and coupled to the intubation portion 111 of the Hume tube connection socket 100, that is, As the sealing member 131a is provided at the end of the Hume pipe or another Hume pipe connection socket 100, the sealing member 131a is interposed in the space between the outer circumferential surface of the tubular structure and the inner circumferential surface of the first pipe part 110, thereby watertightness this can be secured.

<Application example of Hume pipe connection socket>

3 to 4 are exemplary views showing an example in which the Hume pipe connection socket according to an embodiment of the present invention is applied to the joint portion of the Hume pipe. Hume pipe connection socket 100 according to an embodiment of the present invention can change the flow path of the joint portion between the tubular structure as a plurality of connection.

3 to 4, the coupling part 131 is inserted and coupled to the intubation part 111 of the adjacent Hume pipe connection socket 100, and at least two or more Hume pipe connection sockets 100 are connected. Accordingly, the bending angle of the joint portion between the plurality of tubular structures HP may be adjusted.

At this time, as shown in Figure 3, when a plurality of Hume tube connection sockets 100 are connected to communicate so that the bending direction of the flow path in the Hume tube connection socket 100 is the same, a plurality of Hume tube connection sockets, that is, the Hume tube connection assembly 100A ), the total bending angle (θ _t ) of the joint between the Hume pipes may be the sum of the bending angles (θ) of the flow path in each Hume pipe connection socket 100 . As an example, the bending angle θ of the flow path in one Hume tube connection socket 100 is 15°, and as shown in FIG. 3 , the total bending angle in the case of the Hume tube connection assembly 100A in which the three Hume tube sockets 100 are combined. (θ _t ) may be provided at 45°.

For reference, looking at the coupling between the Hume pipe connection socket 100 and the tubular structure of the present invention, as shown in FIGS. FR2) may be coupled while being spaced apart a predetermined distance from the step P located at the boundary, but in some cases, the end of the coupling part 131 is supported in contact with the step P, and any one Hume pipe connection socket The third flow path FR3 of 100 and the second flow path FR2 of the other Hume pipe connection socket 100 may be coupled to communicate. This is not limited only to the connection between the Hume tube connection socket 100, but can also be applied to the coupling between the Hume tube connection socket 100 and the Hume tube HP, that is, tubular structures other than the Hume tube connection socket 100, of course.

As a result, the Hume pipe connection socket 100 of the present invention secures maximum straightness and can flexibly produce various angles in changing the flow path of the tubular structure, that is, the Hume pipe (HP) joint portion, and one Hume pipe connection socket When 100 is provided to have a bending angle of 45° or 90°, it is possible to prevent problems caused by the hydraulic pressure of the fluid passing through the flow path.

And, as shown in FIG. 4, when a plurality of Hume pipe connection sockets 100 are connected and coupled in the same or unequal direction in which the bending direction of the flow path within the Hume pipe connection socket 100 is coupled, the combination of the Hume pipe connection socket In the Hume pipe connection assembly (100A), the flow path in the Hume pipe (HP) located at both ends is parallel, and is spaced apart by a predetermined interval in the width direction by the Hume pipe connection assembly (100A), and the flow path path secures the maximum straightness and is flexible It can be bent to connect the Hume tube (HP).

This may be applied when there is an obstacle buried at the installation position of the Hume pipe HP, and a flow path change to avoid this is unavoidable. In particular, it may be preferable to be applied when a slight change in the path of the flow path needs to be made.

At this time, the above-described application example is described only as a representative example in which the Hume pipe connection socket 100 according to an embodiment of the present invention can be applied to the joint portion of the Hume pipe, and is not limited to the above-described example, and the Hume pipe connection socket 100 ) It is possible to implement the Hume tube connection assembly (100A) coupled in an appropriate number and direction through a design in consideration of the bending direction of the inner flow path.

Through this, the Hume pipe connection socket 100 proposed in the present invention can be flexibly applied to a section in which a direction change of the flow path is required according to site conditions in forming a flow path of a fluid, that is, a flow path.

For reference, after the flow path change is completed by applying the Hume pipe connection socket 100 to the joint between the Hume pipes (HP), the finishing work to fill the spaced space using mortar around the connection between the tubular structures can be additionally performed. However, it can be omitted in some cases.

As described above, the detailed description of the present invention has been made by the embodiments with reference to the accompanying drawings, but since the above-described embodiments have only been described with preferred examples of the present invention, the present invention is limited only to the above embodiments It should not be understood as being, and the scope of the present invention should be understood as the following claims and their equivalents.

100: Hume pipe connection socket
110: first pipe part
111: intubation part
111a: fastener
M: Dog tag
FR1: 1st Euro
120: second pipe
FR2: 2nd Euro
130: third official
131: coupling part
131a: sealing member
FR3: 3rd Euro
BP: border
LL: Connection limit line
HP: Hume tube
B: fastening member

Claims (9)

As a connection socket for changing the path of the flow path by being connected to the joint between the structures (hereinafter referred to as 'tubular structures') in which the flow path is formed therein,
a first pipe portion having a first flow path formed therein;
a second pipe part integrally extending from the other end of the first pipe part so that a second flow path formed therein communicates with the first flow path; and
a third pipe part integrally extending from the other end of the second pipe part so that the third flow path formed therein communicates with the second flow path; including,
The third flow path is bent at a specific angle from the second flow path, and the specific angle is 10° to 20°,
One end of the first tube portion is an intubation portion in which an end of the tubular structure is inserted and coupled to the first flow passage; is provided,
The first flow path has a diameter formed concentrically with respect to the diameter of the second flow path, and the inner circumferential surface from the first pipe part to the second pipe part is formed to have a step in the longitudinal direction,
At the other end of the third pipe part, a coupling part for insertion and coupling to the inside of the tubular structure is provided,
The third pipe part has a length shorter than the length of the other side from one end in contact with the second pipe part to the other end where the coupling part is located,
The boundary portion, which is a boundary point between the side surface of the second tube portion and one side of the third tube portion, limits the degree of insertion into which the third tube portion is inserted into the tubular structure,
The outer surface of the first pipe part is provided with two identification tags for leveling with the neighboring Hume pipe connection socket, one identification tag is located to correspond to a position rotated 180 ° from the other identification tag
Hume tube connection socket.
delete According to claim 1,
A fastening hole to which a fastening member for limiting the movement of the tubular structure inserted into the intubation part is fastened is formed on the side of the intubation part
Hume tube connection socket.
delete According to claim 1,
The coupling portion is characterized in that a ring-shaped sealing member is provided to close the inner circumferential surface of the tubular structure and surround the outer periphery to secure watertightness.
Hume tube connection socket.
delete According to claim 1,
The coupling part is inserted and coupled to the intubation part of the adjacent Hume pipe connection socket, characterized in that the bending angle of the joint between the tubular structures is adjusted by connecting at least two or more Hume pipe connection sockets.
Hume tube connection socket.
delete According to claim 1,
The first pipe part, the second pipe part and the third pipe part, characterized in that provided with cast iron
Hume tube connection socket.

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