KR20210033629A - Grip ring for pipe connecting - Google Patents

Abstract

The present invention relates to a grip ring for connecting pipes, which is able to be mounted in a ring shape on the circumference of an insertion pipe inserted into a central unit of a press wheel and to prevent the insertion pipe from escaping from the central unit of the press wheel. On the outer circumference, an inclined surface is formed to correspond to the inner circumferential surface of the central unit of the press wheel. A pressure can be applied to the inclined surface by the movement of the press wheel. One or more outer pipe penetrating grooves are formed to penetrate the outer circumference in a longitudinal direction of the insertion pipe. On the inner circumference, a compression surface is formed to correspond to the outer circumferential surface of the insertion pipe. On the compression surface, a compression blade is formed to be extended to be long in a circumferential direction. One or more inner pipe penetrating grooves are formed to penetrate the inner circumference in a longitudinal direction of the insertion pipe. By the movement of the press wheel, the width of the outer pipe penetrating grooves or the inner pipe penetrating grooves is narrowed, and the compression surface becomes able to come in close contact with the outer surface of the insertion pipe. According to the present invention, the grip ring for connecting pipes has effects to remove a middle ring which has been essential for the conventional structure, to improve the fastening convenience of the grip ring, and to further improve the watertightness in connecting pipes.

Description

Grip ring for pipe connecting}

The present invention relates to a pipe connection device requiring a watertight function and separation prevention, and more particularly, to a pipe connection device inserted into and connected to a socket. More specifically, it relates to a grip ring for pipe connection that serves to fix the insertion pipe together with a pressure ring so that the insertion pipe inserted into the socket does not fall out of the socket-type connection device of the pipe.

The most commonly used mechanical connection method for connecting cast iron pipes, synthetic resin pipes, and coated steel pipes is the socket connection method. In the socket connection method, the ends of two pipes that meet and connect to each other become a socket, and the other becomes a spigot inserted into the socket.

A pipe connection device of a socket connection method will be described with reference to the accompanying drawings. 1 is a cross-sectional view showing the configuration of a conventional pipe connecting device. The socket 61 is formed at one end of the socket tube 6, so that one end of the connected insertion tube 1 is inserted into the socket. The sealing ring 4 fills the gap between the socket and the insertion tube inserted into the socket. When the connection bolt 7 is tightened in the pipe connection structure of FIG. 1, the pressure ring 5 approaches the socket along the insertion tube. As the pressure ring moves, the pressure ring pushes the grip ring 2, and at this time, the grip ring plays two roles in sequence. In the first step, the grip ring pushed by the pressure ring moves along the insertion tube in the longitudinal direction of the insertion tube and pushes the adjacent intermediate ring 3, and the intermediate ring pushes the sealing ring 4 described above. In the second step, when the grip ring (2) pushed by the pressure ring can no longer proceed in the longitudinal direction of the insertion tube, the grip ring has the role of holding the insertion tube while tightening the insertion tube around the circumference of the insertion tube as the inner diameter of the grip ring decreases. Will do. The grip ring crimped to the insertion tube is caught by the pressure ring together with the insertion tube, so that the central opening 64 of the pressure ring cannot be released. When the grip ring grips the insertion tube while tightening the insertion tube, a compression blade 25 extending long along the inner circumference is formed on the inner circumferential surface of the grip ring in order to prevent slipping off the insertion tube held by the grip ring.

2 is a front view and a cross-sectional view showing a conventional grip ring. In order for the grip ring 2 to be compressed to the insertion tube 1, the inner diameter of the grip ring must be reduced. To this end, there is a cutting portion 27 in which the grip ring is cut, and a compression space 21, which is an extra space that can be reduced when the grip ring is pressed against the insertion tube, is formed in the cutting portion. Since the part with the compression space is a space without the grip ring 2, the sealing ring 4 cannot be pushed. There is a problem in that the intermediate ring 3 is absolutely necessary to push the sealing ring in the compression space without the grip ring. The intermediate ring serves to uniformly transmit the pressure of the grip ring to the entire sealing ring between the grip ring and the sealing ring.

When the pressure ring pushes the grip ring, the first step of the sealing ring crimp and the second step of the insertion tube crimp must occur sequentially. When the second stage in which the grip ring is pressed against the insertion tube begins and the grip ring is pressed against the insertion tube, the grip ring can no longer move in the longitudinal direction of the insertion tube. Therefore, in the case where the first step of crimping the insertion tube is started while the first step of crimping the sealing ring is not sufficiently performed, there is a problem in that the sealing ring may not properly seal between the insertion tube and the socket, and thus fluid may leak. In the pipe connection process, the connecting bolts (7) around the pressure ring must be moved up and down, left and right evenly, but in the actual connection process, there may be cases where the connecting bolt on one side is excessively advanced compared to the other due to an operator's mistake. In this case, as the grip ring 2 is inclined and is caught in the insertion tube, it is impossible to advance toward the sealing ring, so that the second step is started before the first step is completed. The smaller the tolerance between the sealing ring and the insertion tube, the more serious this phenomenon can be.

The present invention has been conceived to solve the above problems, and provides a structure in which the compression space required for the grip ring is divided and distributed over the entire grip ring. When the compression space is dispersed, the unevenness occurring in the compression space is dispersed, and the intermediate ring, which was essential in the existing structure, can be removed. In addition, it provides a structure capable of smoothly moving along the insertion tube without the grip ring being pinched in the insertion tube in the first step, the sealing ring compression step. It is an object of the present invention to provide a grip ring for pipe connection with lower manufacturing cost and improved fastening convenience.

The grip ring for pipe connection according to the present invention for realizing the above object; It is mounted in the form of a ring around the insertion tube inserted into the central hole of the pressure ring so that the insertion tube does not deviate from the central hole of the pressure ring; An inclined surface corresponding to the inner circumferential surface of the central hole of the pressure ring is formed on the outer circumference so that pressure may be applied to the inclined surface by the movement of the pressure ring, and at least one outer cylindrical groove penetrating the outer circumference in the longitudinal direction of the insertion tube is formed; In the inner circumference, a pressing surface corresponding to the outer circumferential surface of the insertion tube is formed, and a pressing blade extending in a circumferential direction protrudes on the pressing surface, and an inner through-groove penetrating the inner circumference in the longitudinal direction of the insertion tube At least one of these is formed; By the movement of the pressure ring, the width of the outer cylindrical groove or the inner through-groove is narrowed, and the pressing surface may be in close contact with the outer surface of the insertion tube.

In addition, the shape of the ring may have a cut portion so that the middle of the ring may be cut.

In addition, the cut portions may be formed to contact each other without a space between both end faces.

In addition, the cut portion may have irregularities corresponding to each other on both end surfaces.

In addition, one or more through-holes passing through between the outer circumference and the inner circumference may be formed.

In addition, a thin and long inter-wall formed on the bottom side of the outer through-groove or the inner through-groove may be damaged by the movement of the pressure ring.

The main problem solving means of the present invention as described above will be described more specifically and clearly through examples such as'specific details for the implementation of the invention' to be described below, or the attached'drawings'. In addition to the main problem solving means as described above, various problem solving means according to the present invention will be additionally presented and described.

According to an embodiment of the present invention, the compression space formed in the cutting portion of the grip ring is eliminated, the compression space required for inner diameter reduction is divided and distributed to the entire grip ring, thereby removing the unevenness occurring in the existing cutting portion. This provides the effect of removing the intermediate ring, which was essential in the existing structure. In addition, as the compression space is divided, it becomes easier for the grip ring to be compressed to the outer surface of the insertion tube as a whole along the circumference, and the watertight function is improved.

By dividing and dispersing the compression space, more compression space can be secured than before, and the inner diameter of the grip ring can be enlarged using this. In addition, in the step of attaching the grip ring to the insertion tube, as the cut portion is opened, the inner diameter of the grip ring may be enlarged. By using this, the inner diameter of the grip ring can be enlarged to provide an effect of improving the fastening convenience of the grip ring.

The present invention has the effect of providing a pipe connection grip ring with improved watertightness, improved convenience of fastening, and low manufacturing cost by removing the intermediate ring.

1 is a cross-sectional view showing the configuration of a conventional pipe connecting device.
2 is a front view and a cross-sectional view showing a conventional grip ring.
3 is a conceptual diagram showing a grip ring according to the present invention.
4 is a conceptual diagram showing a through hole formed in a grip ring according to the present invention.
5 is a conceptual diagram showing a through hole and a through hole formed in a grip ring according to the present invention.
6 is a conceptual diagram showing a cut portion formed in the grip ring according to the present invention.

A preferred embodiment of the present invention will be described with reference to the accompanying drawings. In a preferred embodiment of the present invention described below, the insertion pipe and the socket pipe include not only a synthetic resin pipe and a coated steel pipe having a smooth surface, but also a metal pipe such as a cast iron pipe, an aluminum pipe, and a steel pipe. In addition, the shape of the pipe is not limited to the straight pipe, and may include all connecting pipes including a deformed pipe having various shapes including a curved pipe, a T-shaped pipe, and the like. In an embodiment of the present invention, several embodiments of a pipe connection device for connecting the above pipes to each other and a grip ring for pipe connection used in the pipe connection device will be described.

2 is a front view and a cross-sectional view showing a conventional grip ring. The outer circumferential surface of the grip ring corresponding to the inner circumferential surface 55 of the central opening 54 of the pressure wheel 5 becomes the tapered inclined surface 22. The inner circumferential surface of the grip ring forms a pressing surface 24 that is in close contact with the insertion tube. On the pressing surface, a pressing blade 25 is formed to protrude along the circumferential direction of the insertion tube. Among both sides of the grip ring, the side with the sealing ring 4 becomes the sealing surface 23 that applies pressure to the sealing ring. When the pressing wheel presses the inclined surface of the grip ring and the pressing surface of the grip ring is compressed into the insertion tube, the pressing blade of the grip ring is stuck in the insertion tube, and the grip ring and the insertion tube are integrated. When the insertion tube tries to exit the socket, the grip ring integrated with the insertion tube is stuck like a wedge between the insertion tube and the pressure ring, so that the insertion tube cannot come out of the socket. In the conventional grip ring shown in Fig. 2, the space in the cut portion where the ring is cut is the compression space 21. In order to prevent separation of the insertion tube, the inner diameter of the grip ring must be reduced, and the compression space is essential for reducing the inner diameter of the grip ring. As the inner diameter of the grip ring is reduced, the compression space is reduced as the circumference of the grip ring is shortened.

3 is a conceptual diagram showing a grip ring according to the present invention. The front view of the pipe connection grip ring (2) is shown. Four outer cylindrical grooves 81 penetrating through the outermost surface 29 are formed, and four inner through grooves 82 penetrating the pressing surface 24 adjacent to the outer cylindrical groove are formed. Between the outer through-groove and the inner through-groove, an inter-wall 83 is formed long along the lower side of the groove. The outer through-groove and the inner through-groove are evenly arranged at equal intervals in 4 places. The grip ring shown in FIG. 3 is a distribution of eight large-sized compression spaces 21 that existed as one in the existing structure of FIG. 2, and thus, one large non-pressurized surface existing on the sealing surface 23 of the grip ring It is divided into 8 small non-pressurized surfaces and distributed over the entire sealing surface. As the number of the outer through-groove and the inner through-groove is increased, the non-pressurized surface can be divided more finely and evenly distributed throughout the grip ring. By using this feature, the compression space of the grip ring is divided into smaller portions and the spaces are again arranged at equal intervals, thereby making it easier to reduce the inner diameter of the grip ring. In the present invention, the non-pressurized surface is dispersed, and the non-uniformity due to the non-pressurized surface disappears, so that an intermediate ring is not required. In addition, it is also possible to secure more compression space than in the existing structure. Therefore, it is possible to make the inner diameter of the grip ring larger than the outer diameter of the insertion tube before being reduced. When the inner diameter of the grip ring is larger than the outer diameter of the insertion tube, the grip ring becomes easier to move the outer surface of the insertion tube, thereby facilitating the grip ring fastening process and increasing the accuracy of the grip ring fastening.

The cutting part 27 shown in FIG. 3 is where the grip ring is broken. It is possible to enlarge the size of the grip ring by opening the cut. In the existing grip ring structure, the cut portion is formed together with the compression space 21 to have a function of reducing the inner diameter of the grip ring. In the present invention, as a structure to secure a compression space by using the outer cylindrical groove and the inner through groove, a cutting part is not required to reduce the inner diameter of the grip ring. In addition, since there is no compression space in the cut part, the inner diameter of the grip ring cannot be reduced in the cut part. In the structure of the present invention, it functions to make the size of the grip ring easily large by forming a cut part and opening the cut part. The ability to increase the size of the grip ring makes it much easier to insert the grip ring into the insertion tube and move it to a suitable position. In addition, the probability that the grip ring is stuck in the tube during the grip ring movement process is lowered. In addition, when the grip ring is manufactured by a process such as injection, it is very difficult to separate the product from the injection mold when there is a pressing blade formed on the inner circumferential surface. Even in this case, there is an advantage that the grip ring can be easily separated from the injection mold by expanding the grip ring if there is a cut part.

4 is a conceptual diagram showing a through hole formed in a grip ring according to the present invention. A partial front view and a cross-sectional view of the through holes 81 and 82 in the grip ring are shown. The through groove is a groove passing through the outer or inner circumference of the grip ring back and forth. In the grip ring, an outer cylindrical groove 81 that penetrates back and forth through the outermost surface 29 having the largest outer diameter is formed. In addition, in the grip ring, an inner through groove 82 penetrating the pressing surface 24 having the smallest inner diameter back and forth is formed adjacent to the outer cylindrical groove. The crimping blade 25 formed on the crimping surface protrudes from the crimping surface and thus has a smaller inner diameter than the crimping surface, and the inner through-groove is formed from the inner diameter of the crimping blade. The outermost surface 29 on which the outer cylindrical groove 81 is formed in the grip ring has the largest outer diameter on the outer circumferential surface where the inclined surface 22 is formed. Branches can also be outer circumferences.

Between the outer through-groove and the inner through-groove, an inter-wall 83 is formed long along the side of the bottom of the groove. When viewed in the circumferential direction, the outer through-groove and the inner through-groove partially overlap each other, and a thin and long wall 83 is formed along the overlapping part. When the grip ring receives a force in the direction in which the inner diameter decreases by the pressure ring, the wall is damaged and the width of the outer tube groove and the inner through groove can be narrowed. As a result, the outer cylindrical groove and the inner through groove become the compression space 21 of the grip ring. It is preferable that the outer through-groove and the inner through-groove have the same width as each other overlaps and narrows the width. The through holes may be formed in two or more places at equal intervals, and the grip ring of the present invention has the effect of dividing and dispersing the compression space in the grip ring of the present invention compared to one large compression space of the existing grip ring. The pressing space is a space in which the sealing surface 23 of the grip ring is empty, and becomes the non-pressing surface 85. Therefore, due to the dispersion of the compression space, the non-pressurized surface in which the sealing surface is empty is dispersed. In addition, as each of the dispersed non-pressurized surfaces is reduced to a certain size or less, the intermediate ring 3 that serves to block the non-pressurized surface becomes unnecessary. That is, by dividing and dispersing the compression space of the grip ring by the structure proposed in the present invention, the intermediate ring, which was essential in the existing structure, becomes unnecessary.

The grip ring should be able to pressurize the sealing ring 4 primarily by means of a pressure ring, and secondarily press the sealing ring 4 to the insertion tube 1 after the sealing ring is sufficiently pressed. If the inner diameter of the grip ring is reduced due to the breakage of the inter-wall 83 in a state in which the sealing ring is not sufficiently pressurized, it may cause a problem in the watertightness of the pipe connection. Therefore, the inter-wall must have a certain thickness and length to withstand the shear stress of the stage in which the sealing ring is pressed. In order to reduce the stress caused by the breakage of the walls, a part of the walls may be removed so that the length of the walls is shortened, or the thickness of the walls may be partially made thin.

Another feature of the grip ring structure of the present invention is that the grip ring is divided and operated in each fastening step. Since the inner diameter of the grip ring does not decrease until the wall is damaged, the sealing ring can be sufficiently pressed without the grip ring being caught or pinched in the insertion tube. It is a structure in which the grip ring is compressed and fixed to the insertion tube. Therefore, the watertight performance is better than before.

5 is a conceptual diagram showing a through hole and a through hole formed in a grip ring according to the present invention. A partial front view and a cross-sectional view of the through holes 81 and 82 and the through holes 84 are formed in the grip ring. The through hole 84 is a hole penetrating between the outermost surface 29 and the pressing surface 24 of the grip ring, and in FIG. 5, a square hole is formed. The through hole and the through hole partially overlap each other when viewed in the circumferential direction, and a thin and long wall 83 is formed along the overlapping portion. Like the wall formed between the two adjacent through holes, the wall formed between the through hole and the through hole adjacent to each other is also formed so that the grip ring can be damaged in the step of being pressed against the insertion tube. In FIG. 5, the outer tube groove, the through hole, and the inner through hole were formed adjacent to each other, so that a continuous compression space in one place was separated into three. At this time, the through holes or through holes do not overlap each other when viewed in the radial direction. As a result, the non-pressurized surfaces do not overlap each other in the radial direction, and the non-pressurized surfaces are evenly distributed throughout the sealing surface 24. It is preferable to disperse the through holes and the through holes so that they do not overlap each other when viewed in the radial direction. On the other hand, when viewed in the circumferential direction, the through hole and the through hole partially overlap each other, and an inter wall is formed along the overlapping portion. In a structure in which two or more through-holes are arranged adjacent to each other, an inter-wall may also be formed between the through-holes. The more the through hole is formed, the better and wider the pressurized space can be dispersed, and thus the non-pressurized surface is dispersed, so that the pressure uniformity for the sealing ring is further improved. In consideration of the ease of manufacture and uniformity of pressure of the grip ring, it is preferable that two or less through holes are continuously formed together with two through holes. If the number of neighboring through holes is increased, the non-pressurized surfaces divided into smaller ones are gathered next to each other. In order to more reliably disperse the non-pressurized surface, it is preferable to divide the through hole and the through hole in more places at equal intervals in several places of the entire grip ring.

6 is a conceptual diagram showing a cut portion formed in the grip ring according to the present invention. A partial plan view, a front view, and a cross-sectional view of the location where the cut portion 27 is formed in the grip ring is shown. The cutting portion 27 of the conventional grip ring has a compression space 21 formed in the cutting portion, and has the effect of reducing the circumference of the grip ring as the compression space is reduced. On the other hand, there is no compression space in the cut portion presented in the present invention, and both cut ends may come into contact with each other and contact each other. In the present invention, the cut portion may be opened, and the inner diameter of the grip ring may be enlarged as both cross-sections of the cut portion are moved away from each other.

The grip ring may be formed of a synthetic resin, may be formed of a metal such as aluminum, and may be formed by an injection process or a casting process. In order to separate the grip ring molded from injection or casting from the injection mold or the casting mold, one or more crimping blades 25 formed by protruding long along the circumference from the crimping surface 24 cannot be formed. However, even when two or more crimping blades are formed to overlap each other when viewed in the longitudinal direction of the insertion tube, if there is a cut in the grip ring, the cut part of the grip ring can be widened and the inner diameter can be enlarged to separate the grip ring from the mold.

The cutting part of the grip ring is also very useful when attaching the grip ring to the insertion tube. If the cut part is slightly opened and the inner diameter is enlarged, it can be easily inserted into the insertion tube, and it is easy to move along the insertion tube. When the inner diameter of the grip ring is small, it is difficult to move along the insertion tube, or when it is caught on the surface of the insertion tube during movement, the grip ring cannot sufficiently press the sealing ring 4, resulting in poor watertightness. As a result, the cut portion formed on the grip ring has an effect of improving manufacturing productivity and mounting convenience of the grip ring.

When the pressure ring 5 moves and presses the inclined surface 22 of the grip ring, the grip ring presses the sealing ring 4 in a first step. And as a second step, force is applied in the direction of reducing the inner diameter of the grip ring. In the second step, the through hole formed in the grip ring is subjected to force in the narrowing direction, and both cross-sectional views of the cut portion 27 are pressed while being pushed to each other. In this case, in order for both cross-sections of the cut portion to be accurately matched with each other, irregularities corresponding to each other may be formed on both end surfaces of the cut portion. In FIG. 6, a convex convex portion 71 is formed in one cross section of the cut portion 27 as a boundary, and a concave concave portion 72 is formed in the other cross section corresponding thereto. When there are irregularities corresponding to each other in this way, the positions of both sides can be exactly matched to each other when both sides are pressed against each other.

As described above, the technical ideas described in the embodiments of the present invention may be implemented independently, respectively, and may be implemented in combination with each other. In addition, the present invention has been described through the embodiments described in the drawings and the detailed description of the invention, but this is only illustrative, and various modifications and equivalent other embodiments are provided from those of ordinary skill in the art to which the present invention pertains. It is possible. Therefore, the technical protection scope of the present invention should be determined by the appended claims.

1: insertion tube 2: grip ring
3: intermediate ring 4: sealing ring
5: pressure ring 6: socket tube
7: connection bolt 21: compression space
22: inclined surface 23: sealing surface
24: crimping surface 25: crimping blade
27: cut portion 29: outermost surface
81: outer through groove 82: inner through groove
83: between wall 84: through hole

Claims (6)

Mounted in the form of a ring around the insertion tube inserted in the central hole of the pressure ring so that the insertion tube is not separated from the central hole of the pressure ring;
The outer circumference is formed with an inclined surface corresponding to the inner circumferential surface of the central hole of the pressure ring, so that pressure can be applied to the inclined surface by the movement of the pressure ring, and one or more external cylindrical grooves penetrating the outer circumference in the longitudinal direction of the insertion tube are formed. ;
In the inner circumference, a pressing surface corresponding to the outer circumferential surface of the insertion tube is formed, and a pressing blade extending in the circumferential direction protrudes on the pressing surface, and an inner through-groove penetrating the inner circumference in the longitudinal direction of the insertion tube At least one of these is formed;
A grip ring for pipe connection, characterized in that the compression surface can be in close contact with the outer surface of the insertion tube while the width of the outer cylindrical groove or the inner through groove is narrowed by the movement of the pressure ring. The method according to claim 1,
A grip ring for pipe connection, characterized in that there is a cut in the shape of the ring so that the middle of the ring is cut off. The method according to claim 2,
The cutting portion is a grip ring for pipe connection, characterized in that formed to contact each other without a space between both end faces The method according to claim 2,
The cutting portion is a grip ring for pipe connection, characterized in that the unevenness corresponding to each other is formed on both ends The method according to claim 1,
A grip ring for pipe connection, characterized in that at least one through hole penetrating between the outer circumference and the inner circumference is formed. The method according to claim 1,
A grip ring for pipe connection, characterized in that a thin and long inter-wall formed elongated along a side surface of the bottom of the outer cylindrical groove or the inner through groove may be damaged by the movement of the pressure ring.

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