JP2010174905A - Sealing material - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sealing material capable of reducing inserting force (joining force) required for inserting a spigot into a socket. <P>SOLUTION: The sealing material 45 includes a valve 47 held between the inner peripheral face of the socket and the outer peripheral face of the spigot, the valve 47 having a circular cross section and consisting of a first valve 48 and a second valve 49 joined to each other. On an outer peripheral portion of the first valve 48, a first seal portion 50 is formed to be pressed against the inner peripheral face of the socket. On an inner peripheral portion of the second valve 49, a second seal portion 51 is formed to be pressed against the outer peripheral face of the spigot. A constricted portion 53 is formed on a joint area between the first valve 48 and the second valve 49. The second valve 49 whose inner diameter is set to be smaller than the outer diameter of the spigot is expandable in a tube-radial direction with the deformation of the constricted portion 53. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a sealing material used for a pipe joint that inserts an insertion opening formed at an end of the other pipe into a receiving opening formed at the end of one pipe connected to each other.

  Conventionally, as this type of sealing material, there is one used for a slip-on type separation preventing pipe joint 11 as shown in FIG. In this pipe joint 11, an insertion opening 15 formed at the end of the other pipe 14 is inserted into a receiving opening 13 formed at the end of one pipe 12 connected to each other.

  An annular seal material 18 made of rubber is disposed in a seal material arrangement recess 17 formed on the inner periphery of the receiving port 13, and a lock ring groove 19 is formed on the back side of the seal material arrangement recess 17. The lock ring groove 19 is provided with a lock ring 20 that is divided by one in the circumferential direction, and for fixing the lock ring 20 between the outer periphery of the lock ring 20 and the bottom surface of the lock ring groove 19. Elastic urging means 21 such as a rubber ring is disposed. Further, a protrusion 22 that can be engaged with the lock ring 20 from the back of the receiving port is formed on the outer periphery of the distal end of the insertion port 15.

  As shown in FIGS. 6 and 7, the sealing material 18 includes a heel portion 25 that fits and engages in a locking groove 24 formed in the peripheral surface 23 of the sealing material disposing recess 17, and the peripheral surface 23 and the insertion opening. And a valve portion 26 that is compressed between the outer peripheral surfaces 15 and generates a seal surface pressure. The valve portion 26 is formed to have a smaller inner diameter toward the back of the receiving port, and its cross-sectional shape is formed in a substantially oval shape protruding in a tongue shape in an oblique direction toward the center of the tube.

  According to the above configuration, when the insertion port 15 is inserted into the receiving port 13 and joined, when the protrusion 22 of the insertion port 15 passes through the inner periphery of the sealing material 18, as shown in FIG. The inner peripheral portion of the portion 26 is deformed (expanded) so as to bend outward in the tube radial direction from the state indicated by the phantom line.

  Thereafter, when the protrusion 22 passes through the inner periphery of the sealing material 18, the valve portion 26 is interposed between the outer peripheral surface of the insertion port 15 and the peripheral surface 23 of the sealing material disposing recess 17 as shown in FIG. 6. The inner peripheral portion of the valve portion 26 is pressed against the outer peripheral surface of the insertion port 15, and the outer peripheral portion is pressed against the peripheral surface 23 (the inner peripheral surface of the receiving port 13) of the sealing material disposing recess 17. Surface pressure is secured.

  In addition, about the sealing material 18 used for the above pipe joints 11, it describes in the following patent document 1, for example.

JP-A-5-231570

  However, in the above-described conventional format, as shown in FIG. 8, when the insertion port 15 is inserted into the receiving port 13, the inner peripheral portion of the valve portion 26 is outward in the pipe radial direction as indicated by the solid line from the phantom line. It has been difficult to reduce the force required for deformation (expansion) so as to be bent. For this reason, when inserting the insertion port 15 into the receiving port 13, there existed a problem that it was necessary to apply a big insertion force (joining force).

  An object of this invention is to provide the sealing material which can reduce the insertion force (joining force) required when inserting an insertion port in a receptacle.

In order to achieve the above object, the present invention provides a pipe joint in which an insertion opening formed at an end of one pipe is inserted into a receiving opening formed at an end of one pipe connected to each other. An annular sealing material made of an elastic material used,
A heel portion fitted in a fitting portion formed in the receiving port, and a valve portion sandwiched between the inner peripheral surface of the receiving port and the outer peripheral surface of the insertion port,
The valve portion includes a first valve and a second valve joined to each other,
A first seal portion that is in pressure contact with the inner peripheral surface of the receiving port is formed on the outer peripheral portion of the first valve,
A second seal portion that is in pressure contact with the outer peripheral surface of the insertion port is formed on the inner peripheral portion of the second valve,
The first valve is joined to the heel,
A constricted portion thinner than the first and second valves is formed at the joint between the first valve and the second valve,
The second valve is located on the back side of the receiving port with respect to the first valve, and is inclined from the first valve toward the pipe center,
The heel portion is located on the front side opposite to the back side of the receiving port with respect to the first valve,
The second valve has an inner diameter set smaller than the outer diameter of the insertion opening, and can be expanded and contracted in the tube diameter direction by deformation of the constricted portion.

  According to this, when the insertion port is inserted into the receiving port and joined, the second valve is expanded (expanded) in the tube diameter direction by the insertion port, the insertion port is inserted into the inner periphery of the sealing material, The first seal portion is in pressure contact with the inner peripheral surface of the receiving port, and the second seal portion is in pressure contact with the outer peripheral surface of the insertion port. Thereby, high watertightness can be maintained between the receiving port and the insertion port.

  When the insertion port is inserted into the receiving port as described above, the second valve expands in the tube diameter direction by deforming the narrower portion thinner than the first and second valves. The force required for enlarging is reduced, so that the insertion force (joining force) required for inserting the insertion port into the receiving port can be reduced.

In the second aspect of the invention, the position of the first seal portion and the position of the second seal portion are shifted in the tube axis direction.
According to this, the diameter of the first valve can be reduced, and the inner diameter of the receiving port can be reduced, whereby the gap between the receiving port and the insertion port is reduced, and the water pressure acting on the sealing material at the time of hydraulic load is reduced. The absolute value becomes smaller. Therefore, it is difficult for the sealing material to be detached from the gap between the receiving port and the insertion port even under a high water pressure load. Moreover, the inner diameter of the end surface opening of the receiving port can be made larger than before, and the insertion port can be joined to the receiving port in a bent state.

Further, according to the third aspect of the present invention, concave portions are respectively formed on the inner peripheral surface and the outer peripheral surface of the constricted portion.
According to this, when the insertion port is inserted into the receiving port and joined, if the first valve is compressed in the tube diameter direction by the protrusion formed on the outer periphery of the distal end portion of the insertion port, the recess becomes a clearance allowance. The compression amount of the first valve is reduced. Thereby, since the protrusion part of an insertion port passes smoothly the inner periphery of a 1st valve | bulb, the insertion force (joining force) required when inserting an insertion port into a receiving port can be reduced.

Further, according to the fourth aspect of the present invention, a concave portion is formed at a joint portion between the first valve and the heel portion.
According to this, when the insertion port is inserted into the receiving port and joined, if the first valve is compressed in the tube diameter direction by the protrusion formed on the outer periphery of the distal end portion of the insertion port, the recess becomes a clearance allowance. The compression amount of the first valve is reduced. Thereby, since the protrusion part of an insertion port passes smoothly the inner periphery of a 1st valve | bulb, the insertion force (joining force) required when inserting an insertion port into a receiving port can be reduced.

  As described above, according to the present invention, it is possible to reduce the insertion force (bonding force) required when inserting the insertion port into the receiving port, and to maintain high water tightness between the receiving port and the insertion port. it can.

It is sectional drawing of the pipe joint provided with the sealing material in embodiment of this invention. FIG. 3 is a cross-sectional view of the sealing material in a natural state (an uncompressed state in which the sealing material is removed from the pipe joint). FIG. 6 is a cross-sectional view showing the dimensions of each part in the natural state of the sealing material (non-compressed state in which the sealing material is removed from the pipe joint). It is sectional drawing which shows the procedure which joins pipes using a sealing material similarly. It is sectional drawing which shows the procedure which joins pipes using a sealing material similarly. It is sectional drawing of the pipe joint provided with the conventional sealing material. FIG. 3 is a cross-sectional view of the sealing material in a natural state (an uncompressed state in which the sealing material is removed from the pipe joint). It is sectional drawing which shows the procedure which joins pipes using a sealing material similarly.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
As shown in FIG. 1, reference numeral 31 denotes a push-on type separation preventing pipe joint, which is formed at a receiving port 33 formed at the end of one pipe 32 connected to each other and at an end of the other pipe 34. The insertion slot 35 is inserted.

  A fitting groove 37 (an example of a fitting portion), a concave portion 38 positioned on the deeper side of the receiving port than the fitting groove 37, and a lock ring positioned on the deeper side of the receiving port than the concave portion 38 are formed on the inner peripheral surface of the receiving port 33. Each of the housing grooves 39 is formed over the entire circumference. A convex portion 44 is formed between the fitting groove 37 and the concave portion 38. Further, a deep end face 40 in the tube radial direction is formed inside the receiving port 33 which is spaced from the lock ring receiving groove 39 to the far side.

  The lock ring housing groove 39 houses a metal-made circumferentially divided lock ring 41. The lock ring 41 is configured to elastically hold onto the outer peripheral surface of the insertion opening 35 by having an elastic diameter reducing force. A centering rubber body 42 is disposed between the outer peripheral surface of the lock ring 41 and the bottom surface of the lock ring receiving groove 39, and the lock ring 41 is received when the insertion port 35 is not inserted into the reception port 33. 33 can be held in a centered state. Further, a protrusion 43 that can be engaged with the lock ring 41 from the back of the receiving port is formed on the outer periphery of the distal end of the insertion port 35. The protrusion 43 is formed at a position retracted in the extraction direction by a predetermined distance from the distal end surface of the insertion opening 35.

The space between the receiving port 33 and the insertion port 35 is made of rubber (an example of an elastic material) and sealed around the entire circumference by an annular sealing material 45. The sealing material 45 is configured as follows.
As shown in FIGS. 1 to 3, the sealing material 45 includes a heel portion 46 fitted into the fitting groove 37, and a valve portion 47 sandwiched between the inner peripheral surface of the receiving port 33 and the outer peripheral surface of the insertion port 35. have. The heel portion 46 is an annular member whose transverse cross-sectional shape (cross-sectional shape perpendicular to the circumferential direction) is square.

  The valve portion 47 is an annular member, and includes a first valve 48 and a second valve 49 that are joined to each other. The cross-sectional shape of the first valve 48 is an oval shape that is long in the tube axis direction and has semicircular portions with a radius r1 at both ends. The cross-sectional shape of the second valve 49 is a circular shape with a radius r2. The radius r1 is smaller than the radius r2, and the thickness T1 of the first valve 48 is thinner than the thickness T2 of the second valve 49. The diameter (= 2 × r2) of the cross section of the second valve 49 is formed larger than the interval S in the tube diameter direction between the inner peripheral surface of the convex portion 44 and the outer peripheral surface of the insertion opening 35.

  The first valve 48 is joined to the heel portion 46, and a recess 52 is formed on the outer peripheral portion of the joint portion between the first valve 48 and the heel portion 46. Note that the inner diameter of the first valve 48 is slightly smaller than the outer diameter of the insertion opening 35, and the outer diameter of the first valve 48 is slightly larger than the inner diameter of the convex portion 44.

  The heel portion 46 is located on the front side opposite to the back side of the receiving port 33 with respect to the first valve 48. Further, a constricted portion 53 that is thinner than the first and second valves 48 and 49 is formed at the joint portion between the first valve 48 and the second valve 49. Arc concavities 54 and 55 are formed on the inner peripheral surface and the outer peripheral surface of the constricted portion 53, respectively.

  The second valve 49 is located on the back side of the receiving port 33 with respect to the first valve 48 and is inclined from the first valve 48 toward the tube center. As shown in FIG. 3, the surface including the center P1 of the semicircular portion of the end portion of the first valve 48 near the second valve 49 and the center P2 of the second valve 49 is L1, and includes the center P1. Further, assuming that the radial surface of the sealing material 45 is L2, the inclination angle M of the surface L1 with respect to the surface L2 is set to 15 to 35 °. Furthermore, the inner diameter d of the second valve 49 is set to be smaller than the outer diameter D of the insertion opening 35, and the second valve 49 can be expanded and contracted in the tube diameter direction by elastic deformation of the constricted portion 53. Further, the inner diameter J of the heel portion 46 is set larger than the inner diameter K of the first valve 48.

  A first seal portion 50 that is in pressure contact with the inner peripheral surface of the convex portion 44 (the inner peripheral surface of the receiving port 33) is formed on the entire outer periphery of the first valve 48. A second seal portion 51 that is in pressure contact with the outer peripheral surface of the insertion port 35 is formed on the inner peripheral portion of the second valve 49 over the entire periphery. The position of the first seal portion 50 and the position of the second seal portion 51 are shifted in the tube axis direction. The length of the convex portion 44 in the tube axis direction is set to a length that does not compress the second valve 49. The heel portion 46 is formed of rubber that is harder than the valve portion 47.

Hereinafter, the operation of the above configuration will be described.
When joining the one pipe 32 and the other pipe 34, first, the lock ring 41 and the centering rubber body 42 are accommodated in the lock ring accommodating groove 39, and as shown in FIG. The heel portion 46 is fitted into the fitting groove 37, and the sealing material 45 is mounted inside the receiving port 33.

  Next, the insertion opening 35 is inserted into the receiving opening 33. At this time, as shown in FIG. 4B, the distal end of the insertion port 35 is inserted into the inner periphery of the first valve 48, contacts the second valve 49, and pushes the second valve 49 in the insertion direction. As a result, the second valve 49 is expanded (expanded) in the tube diameter direction.

  Thereafter, when the insertion port 35 is further inserted into the receiving port 33, the protrusion 43 of the insertion port 35 passes through the inner periphery of the heel portion 46 as shown in FIG. The first valve 48 is sandwiched between the outer peripheral surface of the protrusion 43 and the inner peripheral surface of the convex portion 44 (the inner peripheral surface of the receiving port 33), and is compressed in the tube diameter direction. At this time, a gap 57 is formed over the entire circumference between the outer periphery of the second valve 49 expanded (expanded) in the tube diameter direction and the bottom surface of the recess 38.

  Thereafter, when the insertion port 35 is further inserted into the receiving port 33, the protrusion 43 of the insertion port 35 passes through the inner periphery of the first valve 48, as shown in FIG. Contact the circumference. At this time, since the gap 57 is formed, the second valve 49 can be displaced outward with respect to the protrusion 43 in the radial direction of the pipe.

  Thereafter, when the insertion port 35 is further inserted into the receiving port 33, as shown in FIGS. 5B and 1, the protrusion 43 of the insertion port 35 passes through the inner periphery of the second valve 49, Pass the lock ring 41 from the front side of the receiving port to the back side of the receiving port. Thereby, one pipe | tube 32 and the other pipe | tube 34 are joined. At this time, the second valve 49 is in an expanded (expanded) state in the tube diameter direction, and therefore sticks to the outer peripheral surface of the insertion port 35 and is attached to the expanded diameter of the second valve 49. Is pushed outward in the pipe radial direction. As a result, the first seal portion 50 of the first valve 48 is pressed against the inner peripheral surface of the convex portion 44 (the inner peripheral surface of the receiving port 33), and the second seal portion 51 of the second valve 49 is connected to the insertion port 35. Since it press-contacts to an outer peripheral surface, high watertightness can be maintained between the receiving port 33 and the insertion port 35. FIG.

  When the insertion port 35 is inserted into the receiving port 33 as described above, the constricted portion 53 thinner than the first and second valves 48 and 49 is elastically deformed so that the second valve 49 expands in the tube diameter direction. The force required to expand the second valve 49 in the tube diameter direction is reduced, and thereby the insertion force (joining force) required when the insertion port 35 is inserted into the receiving port 33 can be reduced.

  Further, as shown in FIG. 4B, first, the tip of the insertion opening 35 expands the second valve 49 in the tube diameter direction, and then the projection 43 is the first as shown in FIG. 4C. Since the valve 48 is compressed, the expansion of the second valve 49 in the pipe radial direction and the compression of the first valve 48 do not occur at the same time, so that the insertion force (joining) required for inserting the insertion port 35 into the receiving port 33 is prevented. Force) can be reduced. Further, since the inner diameter J of the heel portion 46 is larger than the inner diameter K of the first valve 48, when the first valve 48 is compressed, a part of the first valve 48 is interposed between the heel portion 46 and the insertion opening 35. I can escape. Also by this, the insertion force (bonding force) can be reduced.

  4C, when the first valve 48 is sandwiched between the outer peripheral surface of the protrusion 43 and the inner peripheral surface of the convex portion 44 and compressed, the concave portions 52, 54, 55 are provided. (Refer to FIG. 2) becomes a clearance and the compression amount of the first valve 48 decreases. Thereby, since the protrusion 43 of the insertion port 35 passes smoothly through the inner periphery of the first valve 48, the insertion force (joining force) required when the insertion port 35 is inserted into the receiving port 33 can be reduced. . Further, as shown in FIG. 3, since the thickness T1 of the first valve 48 is thinner than the thickness T2 of the second valve 49, this also reduces the amount of compression of the first valve 48 in the tube diameter direction, The protrusion 43 of the insertion opening 35 passes smoothly through the inner periphery of the first valve 48, and the insertion force (joining force) required for inserting the insertion opening 35 into the receiving opening 33 can be further reduced.

  Further, as shown in FIG. 5A, when the protrusion 43 of the insertion port 35 passes through the inner periphery of the second valve 49, the gap 57 becomes a clearance, and the second valve 49 is moved to the protrusion 43. On the other hand, it is displaced outward in the pipe diameter direction and escapes. Thereby, the insertion force (joining force) required when inserting the insertion port 35 into the receiving port 33 can be further reduced.

  When water pressure acts in the pipes 32 and 34 joined to each other, as shown in FIGS. 1 and 5B, the water pressure tries to push the valve portion 47 from the back side of the receiving port 33 to the near side. Extrusion force F1 acts in the tube axis direction. On the other hand, since the position of the first seal portion 50 and the position of the second seal portion 51 are displaced in the tube axis direction, the valve portion 47 is pushed out from the back side of the receiving port 33 to the near side by the pushing force F1. Can be prevented. In particular, the larger the deviation A in the tube axis direction between the position of the first seal portion 50 and the position of the second seal portion 51, the more the valve portion 47 is prevented from being pushed out with respect to a large pushing force F1. can do. Thereby, the watertightness between the receiving port 33 and the insertion port 35 is improved.

  Further, since the diameter (= 2 × r2) of the cross section of the second valve 49 is formed larger than the interval S in the tube diameter direction between the inner peripheral surface of the convex portion 44 and the outer peripheral surface of the insertion opening 35, the valve Even if the portion 47 is pushed by the pushing force F1, the second valve 49 is difficult to pass through the interval S, and this also prevents the valve portion 47 from being pushed out from the back side of the receiving port 33 to the near side. can do.

  Further, since the water pressure also acts on the gap 57, the pressing force F2 directed toward the tube center acts on the second valve 49, whereby the second seal portion 51 of the second valve 49 becomes the outer peripheral surface of the insertion port 35. The water tightness between the receiving port 33 and the insertion port 35 is further improved.

  In the above embodiment, as shown in FIG. 1, when the insertion port 35 is inserted into the receiving port 33 and one tube 32 and the other tube 34 are joined, the inner peripheral surface of the first valve 48 is Although it contacts the outer peripheral surface of the insertion port 35, a gap may be formed between the inner peripheral surface of the first valve 48 and the outer peripheral surface of the insertion port 35. In this case, when the valve portion 47 is pushed by the pushing force F1, the second valve 49 is pushed so as to enter the gap between the inner peripheral surface of the first valve 48 and the outer peripheral surface of the insertion port 35. And the watertightness between the insertion opening 35 is further improved.

31 Pipe joint 32 One pipe 33 Receptor 34 Other pipe 35 Insertion slot 37 Insertion groove (insertion part)
45 Seal material 46 Heel portion 47 Valve portion 48 First valve 49 Second valve 50 First seal portion 51 Second seal portions 52, 54, 55 Recessed portion 53 Constriction portion d Inner diameter D of second valve Outer diameter of insertion port

Claims (4)

An annular sealing material made of an elastic material used for a pipe joint that inserts an insertion port formed at the end of the other tube into a receiving port formed at the end of one of the tubes connected to each other,
A heel portion fitted in a fitting portion formed in the receiving port, and a valve portion sandwiched between the inner peripheral surface of the receiving port and the outer peripheral surface of the insertion port,
The valve portion includes a first valve and a second valve joined to each other,
A first seal portion that is in pressure contact with the inner peripheral surface of the receiving port is formed on the outer peripheral portion of the first valve,
A second seal portion that is in pressure contact with the outer peripheral surface of the insertion port is formed on the inner peripheral portion of the second valve,
The first valve is joined to the heel,
A constricted portion thinner than the first and second valves is formed at the joint between the first valve and the second valve,
The second valve is located on the back side of the receiving port with respect to the first valve, and is inclined from the first valve toward the pipe center,
The heel portion is located on the front side opposite to the back side of the receiving port with respect to the first valve,
A sealing material characterized in that the second valve has an inner diameter set smaller than an outer diameter of the insertion opening, and can be expanded and contracted in the tube diameter direction by deformation of the constricted portion. The sealing material according to claim 1, wherein the position of the first seal part and the position of the second seal part are shifted in the tube axis direction. The sealing material according to claim 1 or 2, wherein a concave portion is formed on each of an inner peripheral surface and an outer peripheral surface of the constricted portion. The sealing material according to any one of claims 1 to 3, wherein a concave portion is formed at a joint portion between the first valve and the heel portion.

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