KR102135898B1 - Structure for preventing nut unlocking of synthetic resin tube joint - Google Patents

Abstract

The present invention relates to a structure for preventing loosening of a nut of a joint portion of a synthetic resin pipe, a synthetic resin pipe having an expansion portion at an end portion; A paral inserted into the expansion portion of the synthetic resin tube; A fitting for accommodating a synthetic resin pipe and a parallel, protrudingly formed on an outer circumferential surface, and having a wing portion having a first surface on the side of the synthetic resin pipe and a second surface on the opposite side, and a groove formed in the wing portion; A nut which is fastened to the fitting and has a groove formed on an outer circumferential surface; And it is formed protruding on the inner circumferential surface to provide a nut loosening preventing structure of a synthetic resin pipe joint comprising a nut ring having a first protrusion which is inserted into the groove of the wing and the groove of the nut, respectively.

Description

Structure for preventing nut unlocking of synthetic resin tube joint

The present invention relates to a structure for preventing loosening of a nut of a joint of a synthetic resin pipe.

Various liquid chemicals or water are frequently used in manufacturing processes such as semiconductors and displays. Various liquid chemicals include, for example, acidic solutions such as hydrofluoric acid, sulfuric acid, hydrochloric acid, nitric acid, and phosphoric acid, and alkaline solutions containing potassium hydroxide, sodium hydroxide, ammonium, etc., and chemicals used in cleaning solutions. have. Among these, ozonated diluted hydrofluoric acid is used in processes such as cleaning and etching semiconductor substrates.

These chemicals are transported through a transport system including tubes or pipes, where synthetic resin tubes made of fluorine resin are generally used. Since the chemical flowing through the synthetic resin pipe used in the transfer system of the semiconductor manufacturing facility is high purity and highly toxic, the leakage of the chemical can be fatal to humans as well as the production yield of the semiconductor products. Therefore, more stringent sealing performance is required for a plurality of synthetic resin tubes constituting a transfer system, unions, nuts, connectors, valves, etc. for connection and opening and closing of the synthetic resin tubes.

High purity chemicals are required in semiconductor and chemical chemical factories, and fluorine resins with excellent properties for all chemicals are required for tubes and fittings. When the nut is loosened finely due to vibration or temperature change when tightening with a nut on a fitting or tube connection made of fluorine resin, it can cause human injury and factory shutdown due to leakage of chemicals, and prevent it in advance. In order to do this, the nut must never loosen.

An object of the present invention relates to a nut loosening preventing structure of a synthetic resin pipe joint that can effectively prevent the loosening of a nut using a nut ring.

The present invention, in order to achieve the above object, a synthetic resin tube having an expansion portion at the distal end; A paral inserted into the expansion portion of the synthetic resin tube; A fitting for accommodating a synthetic resin pipe and a parallel, protrudingly formed on an outer circumferential surface, and having a wing portion having a first surface on the side of the synthetic resin pipe and a second surface on the opposite side, and a groove formed in the wing portion; A nut which is fastened to the fitting and has a groove formed on an outer circumferential surface; And it is formed protruding on the inner circumferential surface to provide a nut loosening preventing structure of a synthetic resin pipe joint comprising a nut ring having a first protrusion which is inserted into the groove of the wing and the groove of the nut, respectively.

In the present invention, the groove of the wing, the groove of the nut, and the first protrusion of the nut ring may be formed independently of each other, and the groove of the wing may be aligned with the groove of the nut after the fitting and the nut are fastened.

In the present invention, the wing portion may be formed in a vertical direction, the groove of the wing portion may be formed over the entire thickness of the wing portion, and two or more wing portion grooves may be symmetrically arranged.

In the present invention, the first protrusion may be formed over the entire length of the nut ring, and two or more first protrusions may be symmetrically arranged.

In the present invention, the nut ring may include a hook having an incision cut in the longitudinal direction and a locking portion protruding inward from the incision.

In the present invention, the hook portion of the hook may be elastically engaged to the second surface of the wing portion after fastening the nut ring and the fitting.

In the present invention, two or more hooks may be arranged symmetrically, one or more hooks may be formed in the longitudinal front, and one or more hooks may be formed in the longitudinal back.

In the present invention, the nut ring may be formed to protrude in the center of the inner circumferential direction in the longitudinal direction and include a second protrusion having a length shorter than the first protrusion.

In the present invention, the second protrusion can be inserted into the groove of the nut, and can be brought into contact with the first surface to be blocked by the first surface of the wing after fastening the nut ring and the fitting.

In the present invention, two or more second protrusions may be symmetrically arranged.

According to the present invention, it is possible to effectively prevent the loosening of the nut of the joint portion of the synthetic resin pipe by the fitting groove, the nut groove, and the protrusion and hook structure of the nut ring.

1 is an exploded perspective view of a nut loosening preventing structure of a synthetic resin pipe joint according to the present invention.
2 is an assembled perspective view of the synthetic resin pipe joint according to the present invention before fastening the nut ring of the nut loosening preventing structure.
3 is an assembled perspective view after fastening the nut ring of the nut loosening preventing structure of the synthetic resin pipe joint according to the present invention.
Figure 4 is a perspective view of the rear assembly of the nut loosening preventing structure of the synthetic resin pipe joint according to the present invention.
5 is a perspective view of a nut ring according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view of a nut loosening preventing structure of a synthetic resin pipe joint according to the present invention, FIG. 2 is an assembled perspective view before fastening the nut ring, FIG. 3 is an assembled perspective view after fastening the nut ring, and FIG. 4 is an assembled perspective view when viewed from the rear side , The joint structure according to the present invention may be composed of a synthetic resin pipe 10, a parallel 20, a fitting 30, a nut 40, a nut ring 50, and the like.

Synthetic resin pipe 10 may be composed of a body portion 11 and the expansion portion formed on the distal end occupies most of the length. The dilated portion is an artificially enlarged diameter. Since the synthetic resin pipe 10 is made of synthetic resin, the diameter can be easily enlarged by applying heat or inserting a parallel or the like using a press-fit jig. The diameter of the expansion portion is larger than the diameter of the body portion 11 over the entire length. The thickness of the expansion portion may be the same over the entire length, and may be the same as the thickness of the body portion 11. The paral 20 to be described later is inserted into the expansion portion, and the inner diameter of the expansion portion may be changed corresponding to the outer diameter.

The expansion portion may be formed of a taper portion 12, an expansion portion 13, and the like sequentially from the side close to the main body portion 11. The tapered portion 14 is a portion whose diameter gradually increases just before the enlarged portion 13 toward the distal end of the synthetic resin pipe 10, and may be composed of a flat surface and/or a curved surface. The enlarged diameter portion 13 may have a uniform diameter portion having a uniform diameter as a whole, and may also include a tapered structure, for example, the end of the synthetic resin pipe 10 from the largest diameter portion that is the end of the tapered portion 12 It may include a tapered portion whose diameter gradually decreases toward, and a tapered portion and a uniform diameter portion may also be combined. The length and inclination angle of the tapered portion 12 and the length of the enlarged diameter portion 13 are not particularly limited and can be appropriately changed as necessary.

When a plurality of tapered portions are formed on both sides based on the maximum diameter portion, the sealing performance can be improved upon fastening with the parasol 20, the fitting 30, and the nut 40, and a high pressure in the synthetic resin pipe 10 Even if the synthetic resin pipe 10 is caught, it is possible to effectively prevent the phenomenon. That is, when the synthetic resin pipe 10 is expanded and the paral 20 is inserted, the outer diameter of the synthetic resin pipe 10 is large and the end portion of the synthetic resin pipe 10 is contracted at the largest diameter portion, which is the protruding portion of the parallel 20. Thus, since the outer diameter is small, it is possible to prevent the phenomenon that the synthetic resin pipe 10 is removed even when high pressure is applied to the synthetic resin pipe 10.

The synthetic resin tube 10 may be manufactured using a fluorine-based resin, for example, high-purity perfluoroalkoxy (PFA HP). The polymer resin is very suitable as a resin for a tube for semiconductor equipment, and the weight average molecular weight may be 500,000 to 700,000. The synthetic resin pipe 10 may be formed in a cylindrical shape. The diameter of the synthetic resin pipe 10 is not particularly limited, and can be appropriately changed as necessary.

The ferrule 20 is a member that is inserted into the synthetic resin pipe 10 and inserted into the fitting 30 at the same time to improve the sealing performance. The parallel 20 may be made of plastic or metal such as fluorine-based resin such as high-purity perfluoroalkoxy (PFA HP). The parallel 20 may be configured in a cylindrical shape, like the synthetic resin pipe 10. The outer diameter of the parallel 20 may vary along the longitudinal direction, but the inner diameter may be the same over the entire length for smooth flow of fluid. The parallel 20 may be largely divided into a tube insertion portion and a fitting contact portion.

The pipe inserting portion is inserted into the expansion portion of the synthetic resin pipe 10 and has a shape corresponding to the shape of the expansion pipe portion, and specifically, the taper portion 21 sequentially from the innermost portion inserted into the expansion portion of the synthetic resin pipe 10 ), shaft diameter portion 22 and the like. The tapered portion 21 is a portion corresponding to the tapered portion 12 of the synthetic resin pipe 10, and is a portion whose outer diameter gradually increases toward the fitting contact portion, which is an end portion of the fitting, and may be formed of a flat surface and/or a curved surface. . Shaft diameter portion 22 is a portion having a diameter reduced from the largest diameter portion (border portion) that is the end of the tapered portion 21, similar to the diameter portion 13 of the synthetic resin tube 10, a uniform diameter portion of a uniform diameter and / Or a tapered structure in which the diameter gradually decreases. The outer diameter of the shaft diameter portion 22 is smaller than the outer diameter of the maximum diameter portion and the enlarged diameter portion 24. The length and inclination angle of the tapered portion 21 and the length of the shaft diameter portion 22 are designed to correspond to the expanded portion of the synthetic resin pipe 10.

The fitting contact portion may be composed of a locking portion 23, an enlarged portion 24, and a round portion 25 sequentially from the synthetic resin pipe 10 side. The locking portion 23 is a boundary portion between the shaft diameter portion 22 and the diameter expansion portion 24, and may be formed in a structure forming a step. The end of the synthetic resin pipe 10 may be in close contact with the locking portion 23, and the height of the locking portion 23 may be the same as the thickness of the synthetic resin pipe 10. The enlarged diameter portion 24 is a portion whose outer diameter is enlarged through the locking portion 23, and the outer diameter is larger than the outer diameter of the shaft portion 22 by the height of the locking portion 23 and is uniform in the longitudinal direction. The round portion 25 may be composed of an arc surface rounded from immediately after the enlarged portion 24 to the end of the fitting side. Sealing performance can be maximized even at high pressure by the round portion 25.

The fitting 30 is for connecting two synthetic resin pipes 10, for example, a reducer connecting a first synthetic resin pipe 10 having a large diameter and a second synthetic resin pipe having a small diameter (not shown). It may be a (reducer), and vice versa, it is also possible to connect two synthetic resin tubes 10 having the same diameter. The fitting 30 may be formed of a cylindrical and/or polyhedron, and a step may be partially formed along the longitudinal direction on the outer circumferential surface and/or the inner circumferential surface, so that the outer diameter and/or inner diameter may be different for each part. The stepped portion may consist of straight lines and/or curves when viewed in cross section. The fitting 30 may be made of plastic or metal such as a fluorine-based resin such as high-purity perfluoroalkoxy (PFA HP).

The fitting 30 includes a pipe receiving portion, which is an inner space for receiving the expansion portion and the paral 20 of the synthetic resin pipe 10 at one end. The tube receiving portion may include a round portion, a uniform diameter portion and/or a taper portion sequentially from inside to outside. The round portion is a portion corresponding to the round portion 25 of the paral 20, and may be formed of an arc-shaped round surface so as to have the same shape as the round portion 25 of the paral 20. When the ferrule 20 and the fitting 30 are fastened, the two round parts are engaged and brought into close contact, so that sealing performance can be maximized even at high pressure. That is, the seal portion of the parallel 20 and the fitting 30 is R, so that the sealing effect can be maximized at high pressure. The uniform diameter portion and/or the tapered portion may be configured to correspond to the synthetic resin pipe 10 and the paral 20.

The synthetic resin pipe 10 is inserted into the pipe receiving portion of the fitting 30, and can be inserted only up to the maximum diameter, and the tapered portion 12 of the synthetic resin pipe 10 is not inserted and is disposed outside the fitting 30 Can be. The largest diameter portion of the synthetic resin pipe 10 and the pipe receiving portion inlet of the fitting 30 are engaged to form a primary sealing structure, and the two round portions of the parallel 20 and fitting 30 are engaged to form a secondary sealing structure. Can. A thread portion for fastening with the nut 40 may be formed on the outer circumferential surface of the fitting 30. So far, only one part of the fitting 30 has been described, but the opposite part may have substantially the same configuration by a symmetrical structure.

A protrusion may be formed on the inner circumferential surface of the fitting 30. The number of protrusions may be 1 to 10, preferably 2 to 5. The protrusion may be formed in a radial direction perpendicular to the central axis, or may be formed slightly inclined. The protrusion may be formed entirely or partially along the inner circumferential surface. The end of the protrusion may be pointed, and the cross section of the protrusion may be triangular. As the end of the protrusion is sharp, the synthetic resin pipe 10 is easily inserted into the fitting 30, and at the same time, the adhesion between the tapered portion of the synthetic resin pipe 10 and the protrusion of the fitting 30 is increased to maximize sealing performance. Can. Since the tertiary sealing structure is formed by the protrusion, the sealing performance can be maximized by the tertiary sealing structure. In addition, even if there is an eccentricity of the synthetic resin tube 10, the protrusion formed on the inner surface of the fitting 30 presses the eccentric synthetic resin tube, thereby effectively preventing leakage.

In particular, the fitting 30 may be provided with a wing portion 31 protruding from the outer circumferential surface. The wing portion 31 may have a flange structure formed to protrude vertically to the outer circumferential surface of the fitting 30. The wing part 31 has a first surface 31a on the side of the synthetic resin tube 10 and a second surface 31b on the opposite side. The second surface 31b can be seen in FIG. 4. The wing portion 31 is provided with at least one, preferably a plurality of grooves (32). The wing groove 32 is a portion into which the first protrusion 51 of the nut ring 50 to be described later is inserted to prevent the nut 40 from loosening. The wing groove 32 is formed over the entire thickness of the wing 31, that is, may be formed through the wing 31 at the outer end of the wing 31. Two or more wing grooves 32 may be symmetrically arranged, for example, two at 180° intervals, or four at 90° intervals. In addition, there may be grooves 32 at two points, 0 degrees and 90 degrees.

The nut 40 may be fastened to the fitting 30 with the assembly of the synthetic resin tube 10 and the parallel 20 inserted into the fitting 30 to fix the synthetic resin tube 10. The nut 40 may be formed of a cylindrical and/or polyhedron, and a step may be partially formed along the longitudinal direction on the outer circumferential surface and/or the inner circumferential surface, so that the outer diameter and/or the inner diameter may be different for each part. The stepped portion may consist of straight lines and/or curves when viewed in cross section. The nut 40 may be made of plastic or metal such as fluorine-based resin such as high-purity perfluoroalkoxy (PFA HP).

The nut 40 includes a fitting accommodation portion, which is an internal space for receiving the distal end portion of the fitting 30, and may have a screw portion for fastening with the fitting 30 on the inner circumferential surface. The inner side edge portion of the fitting receiving portion is a fourth sealing structure by strongly pressing the boundary portion and/or taper portion 12 of the body portion 11 and the taper portion 12 of the synthetic resin pipe 10 when fastening with the fitting 30 Can form.

The nut 40 may have a groove 41 formed on the outer circumferential surface. The nut groove 41 is a portion into which the first protrusion 51 of the nut ring 50 to be described later is inserted in order to prevent the nut 40 from loosening. A plurality of nut grooves 41 may be formed on the outer circumferential surface of the nut 40 along the circumferential direction of the nut 40. After the fitting 30 and the nut 40 are fastened by screwing, in order to insert the first protrusion 51 of the nut ring 50 into the wing groove 32 of the fitting 30, the nut groove 41 ) Should be aligned with the wing groove 32. After the nut groove 41 and the wing groove 32 are aligned, the first protrusion 51 of the nut ring 50 can be inserted into these grooves 32 and 41 simultaneously. The nut groove 41 may be formed over the entire length of the nut 40 along the longitudinal direction of the nut 40. As illustrated in the figure, the width of the nut groove 41 may vary depending on its longitudinal direction, but the width may be the same. At least a portion of the nut groove 41, particularly a section in contact with the wing portion may have a size (width, depth) corresponding to the wing groove 32.

5 is a perspective view of a nut ring according to the present invention, the nut ring 50 is after the fastening of the fitting 30 and the nut 40, the fastening of the nut 30 and the fitting 30 and the nut 40 at the same time It serves to prevent loosening. The nut ring 50 may be formed in a ring shape, and may be made of a fluorine-based resin such as polyvinylidene fluoride (PVDF). The inner diameter of the nut ring 50 may be the same or similar to the outer diameter of the wing portion 31. 4, the wing portion 31 of the fitting 30 may be inserted into the nut ring (50). The nut ring 50 may include a first protrusion 51, a hook 52, and a second protrusion 53 to prevent the nut 40 from loosening.

The first protrusion 51 is formed to protrude in the inner and vertical directions of the inner circumferential surface 50a of the nut ring 50 and inserted into the wing groove 32 and the nut groove 41, thereby loosening the nut 40. Can be prevented. Referring to FIG. 5, the first protrusion 51 may be formed to extend over the entire length of the nut ring 50. A plurality of first protrusions 51 may be formed, and two or more first protrusions may be symmetrically arranged, for example, two at 180° intervals, or four at 90° intervals. Can. In this way, the first projections 51 are symmetrically arranged, and the nut ring 50 may be used in any direction. The width and height of the first protrusion 51 may be the same or similar to the width and depth of the wing groove 32. When fastening the fitting 30 and the nut 40, after the groove 41 of the nut 40 and the groove 32 of the fitting 30 are matched, the nut ring 50 is inserted in the direction of insertion (arrow). When pushed to A), the first protrusion 51 protruding on the inner part of the nut ring 50 is inserted into the groove 41 of the nut 40 and the groove 32 of the fitting 30 sequentially. By doing so, it is possible to prevent the rotation of the nut 40 and the fitting 30.

The hook 52 may include a cut-out portion 52a cut in the longitudinal direction and a locking portion 52b protruding inward from the cut-out portion 52a, and may be configured in an approximately a-shaped shape. The incision 52a may be formed by cutting two adjacent portions in the longitudinal direction (arrow C direction) of the nut ring 50 in parallel from an approximately intermediate region in the longitudinal direction to one end in the longitudinal direction. The incision 52a may be formed over the entire thickness of the nut ring 50. Since the incision part 52a is formed by being incised, it has flexibility and elasticity, so that it can be rotated to a certain degree in the thickness direction of the nut ring 50 by using the intermediate incision starting part as an axis, thereby engaging the hook 52 Combination becomes possible. The engaging portion 52b may be formed to protrude inwardly and vertically from the incision 52a.

Referring to FIG. 4, the engaging portion 52b may be elastically engaged to the second surface 31b of the wing portion 31 after the nut ring 50 and the fitting 30 are fastened. As such, when the nut ring 50 is pushed in the insertion direction (arrow A direction) so that the hook 52 of the nut ring 50 is caught on the second surface 31b of the wing portion 31 of the fitting 30, Hook 52 is caught on the wing portion 31 of the fitting 30, and serves as a hook to prevent the nut ring 50 from falling away from the fitting 30 (arrow B direction). That is, the hook 52 serves to prevent the reverse of the nut ring 50 and the fall in the direction of the arrow B. Two or more hooks 52 may be disposed symmetrically, for example, two at 180 degree intervals, or four at 90 degree intervals. Further, one or more hooks may be formed in the longitudinal direction forward (arrow A direction), and one or more hooks may be formed in the longitudinal direction backward (arrow B direction). In this way, the hooks 52 are arranged symmetrically, and the nut ring 50 may be used in any direction.

The second protrusion 53 is formed to protrude inward and vertically in the longitudinal center of the inner circumferential surface 50a of the nut ring 50, but may be formed to have a shorter length than the first protrusion 51. The second protrusion 53 extends to both sides from the center of the inner circumferential surface 50a, and its length may be 10 to 50% of the total length of the nut ring 50. The second protrusion 53 may be inserted into the nut groove 41, and after fastening the nut ring 50 and the fitting 30, the first surface to be blocked by the first surface 31a of the wing 31 (31a). As described above, when the second protrusion 53 fastens the nut 40 to the fitting 30 and fits the nut ring 50, the nut ring 50 is caught by the wing portion 31 of the fitting 30. It can be prevented from being pushed toward the fitting 30.

Referring to FIG. 4, when the second protrusion 53 is not provided, when the nut ring 50 is continuously pushed forward in the insertion direction (arrow A direction), the nut ring 50 has a wing portion of the fitting 30 It passes through (31) and is completely removed from the fitting (30). That is, the second projection 53, the opposite of the hook 52, serves to prevent excessive advancement of the nut ring 50 and the fall in the direction of the arrow A. To this end, the distance between the longitudinal front end of the nut ring 50 and the second projection 53 may be equal to or greater than the thickness of the wing 31. Two or more second protrusions 53 may be symmetrically disposed, for example, two at 180 degree intervals, or four at 90 degree intervals. In this way, the second projections 53 are arranged symmetrically, and the nut ring 50 may be used in any direction.

10: synthetic resin tube
11: main body
12: tapered portion
13: enlarged part
20: Farrell
21: tapered portion
22: Shaft neck
23: Jam
24: enlarged part
25: round part
30: fitting
31: wing
31a: front page
31b: page 2
32: wing groove
40: nut
41: nut groove
50: nut ring
50a: Inner surface
51: first projection
52: Hook
52a: incision
52b: Jam
53: second projection

Claims (10)

A synthetic resin tube having a dilated portion at the distal end;
A paral inserted into the expansion portion of the synthetic resin tube;
A fitting accommodating a synthetic resin pipe and a parallel, protrudingly formed on an outer circumferential surface, and having a wing portion having a first surface on the side of the synthetic resin pipe and a second surface on the opposite side, and a groove formed in the wing portion;
A nut which is fastened to the fitting and has a groove formed on an outer circumferential surface; And
It includes a nut ring having a first projection that is protruded on the inner circumferential surface and is inserted into the groove of the wing and the groove of the nut, respectively.
The nut ring includes a hook having an incision cut in the longitudinal direction and a locking portion protruding inward from the incision,
After engaging the nut ring and the fitting, the hook portion of the hook is elastically engaged to the second surface of the wing portion,
The nut ring is formed to protrude in the center of the inner peripheral surface in the longitudinal direction and includes a second protrusion having a length shorter than that of the first protrusion,
The second protrusion is inserted into the groove of the nut, and after the nut ring and the fitting are fastened, the nut loosening preventing structure of the joint portion of the synthetic resin pipe that can contact the first surface to be blocked by the first surface of the wing. According to claim 1,
The groove of the wing, the groove of the nut, and the first protrusion of the nut ring are each independently formed in plural, and the groove of the wing is prevented from being loosened by a synthetic resin pipe joint that is aligned with the groove of the nut after the fitting and the nut are fastened. According to claim 1,
The wing portion is formed in the vertical direction, the groove of the wing portion is formed over the entire thickness of the wing, the grooves of the two or more wing portions are arranged symmetrically to prevent the nut loosening structure of the synthetic pipe joint. According to claim 1,
The first protrusion is formed over the entire length of the nut ring, and two or more first protrusions are symmetrically arranged to prevent the nut loosening structure of the synthetic resin pipe joint. delete delete According to claim 1,
Two or more hooks are arranged symmetrically, one or more hooks are formed in the longitudinal direction forward, and one or more hooks are formed in the longitudinal direction of the synthetic resin tube joint nut loosening preventing structure. delete delete According to claim 1,
A structure for preventing the nut from loosening at the joint of a synthetic resin pipe in which two or more second protrusions are symmetrically arranged.

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