JP5193689B2 - Fitting for flexible pipe - Google Patents

Description

  The present invention relates to an improvement in a plug-in type flexible pipe joint that allows a flexible pipe to be connected in a seal-like manner by inserting a flexible pipe for guiding a fluid such as gas or liquid, and pushing a push wheel.

  As this type of insertion-type flexible pipe joint, for example, as shown in FIGS. 5A and 5B, a joint main body 42 having a pipe insertion hole 41 for inserting a bellows-like flexible pipe 40, A retainer member 44 having a rear projection 44 a that is disposed in the tube insertion hole 41 and is inserted into the annular recess 43 on the outer surface of the flexible tube 40, and the rear projection 44 a of the retainer member 44 is inserted into the annular recess 43 on the outer surface of the flexible tube 40. And a packing member 46 that seals between the flexible pipe 40 and the joint main body 42. The pusher wheel 45 slides in the axial direction within the tube insertion hole 41 of the joint main body 42, the position where the rear protrusion 44 a of the retainer member 44 does not fit into the annular recess 43 of the flexible tube 40, and the rear protrusion 44 a of the retainer member 44. Is displaceable between the position where the state of being fitted into the annular recess 43 of the flexible tube 40 is maintained.

  Furthermore, a lock means is provided for locking the pusher wheel 45 at a position where the rear protrusion 44 a of the retainer member 44 is fitted in the annular recess 43 of the flexible tube 40. As the locking means, a first groove (stop ring receiving recess) 48 and a second groove (stop ring holding step) 49 that are engaged with the outer peripheral portion of the stop ring member 47 are formed in the joint main body 42. The outer peripheral portion of the stop ring member 47 is moved to the first groove in accordance with the slide of the pusher wheel 45 while the inner peripheral portion of the C-shaped stop ring member 47 is engaged with the groove portion 50 formed on the outer peripheral surface of the base end side of 45. 48 and the second groove 49 can be displaced. When the outer peripheral portion of the stop ring member 47 is engaged with the first groove 48, the pusher wheel 45 is positioned at a position where the rear protrusion 44 a of the retainer member 44 does not fit into the annular recess 43 of the flexible tube 40. The joint body 42 is temporarily fixed in a half-inserted state. When the outer peripheral portion of the stop ring member 47 engages with the second groove 49, the pusher wheel 45 is locked while being held in a state in which the rear protrusion 44a of the retainer member 44 is fitted into the annular recess 43 of the flexible tube 40. (For example, refer to Patent Document 1). Incidentally, the stroke length S (see FIG. 6A), which is the pushing amount of the push wheel 45, is set to be substantially the same as the distance between the first groove 48 and the second groove 49.

  According to this flexible pipe joint, it is possible to connect the flexible pipe 40 while maintaining good sealing performance by simply pushing the push wheel 45.

JP 2003-176888 A

  However, in the flexible pipe joint, the half-inserted state in which the presser wheel 45 is temporarily fixed to the joint main body 42 is configured to be held only by engaging the outer peripheral portion of the stop ring member 47 with the first groove 48. When the pusher wheel 45 is pushed in unexpectedly due to a strong pushing force applied to the pusher wheel 45 during inventory, storage or transportation of the joint before the flexible pipe 40 is inserted, the retainer member is pushed by the pusher wheel 45. There was a problem that 44 may be pushed in and compression deformation may be applied to the packing member 46.

  The present invention has been made to solve such problems, and the object of the present invention is to connect the flexible tube in a seal shape by a one-touch operation of inserting the flexible tube and pushing the push wheel. In addition, to provide a joint for flexible pipes that can reliably prevent the seal rubber from being pushed and deformed by a press ring in a half-inserted state when the joint is in stock, stored or transported before the flexible pipe is inserted. It is in.

  When the present invention is described with reference to the reference numerals attached to FIGS. 1 to 4 in order to facilitate understanding of the contents of the present invention as described in claim 1, it extends to the entire circumference in the circumferential direction. A joint body 5 having a receiving portion 3 into which a tip portion of a flexible pipe 2 in which peaks 8 and valleys 9 are alternately arranged in the tube axis direction is inserted, and received in the receiving portion 3. A seal rubber 6 that seals between the outer periphery in the vicinity of the distal end of the flexible tube 2 inserted into the portion 3 and the inner periphery of the receiving portion 3, and a push ring 7 that is inserted into the receiving portion 3. 7 is inserted in a semi-insertion state in which the push-in allowance remains in the receiving part 3, and when the push-in part is completely pushed in, the seal rubber 6 moves back toward the inlet side of the push-receiving part 3 at the tip of the push ring 7. In the joint for flexible pipes, which is designed to suppress the pressing, the pusher wheel 7 in the half-inserted state has a tip portion thereof. The first positioning and holding means that is positioned and held at the initial position located on the rear side of the seal rubber 6 before the rexible pipe is inserted, and the pusher wheel 7 that is completely pushed in, the tip part of the first is used for the insertion of the flexible pipe 2 first. A second positioning and holding means that is positioned and held at the pushing position located on the rear side of the pushed seal rubber 6 is provided, and the first positioning and holding means is a snap ring housing and holding provided on the outer periphery of the push wheel 7. A groove 21, a snap ring 27 in which an inner peripheral portion is fitted in the snap ring receiving and holding groove 21, and a first snap ring that is provided on the inner periphery of the receiving portion 3 and engages with the outer peripheral portion of the snap ring 27. The engagement groove 22 and a tapered surface 22a formed in a gradually narrowed shape toward the front on the front groove wall in the first snap ring engagement groove 22 are provided, and the half insertion state Covered with a heat-shrinkable plastic film or the tube 32 over the outer surface of the joint body 5 from the exposed outer surface of the pressing ring 7, heat shrinkage to those having features that formed by encapsulating.

  According to the above configuration, the first positioning and holding means engages the outer peripheral portion of the snap ring 27 fitted in the snap ring housing and holding groove 21 of the push wheel 7 with the first snap ring engaging groove 22 of the receiving portion 3. In addition to the mechanism, the heat shrinkable plastic film or its tube 32 is covered from the exposed outer surface of the presser wheel 7 in the half-inserted state to the outer surface of the joint body 5, and is covered by heat shrinkage. The tube 32 fits and closely adheres to the exposed outer surface shape of the pusher wheel 7 and the outer surface shape of the joint body 5. The external force to be pushed in can be sufficiently counteracted, and the movement due to the push wheel 7 being pushed in can be reliably prevented. In addition, the plastic film or its tube 32 encased from the exposed outer surface of the press wheel 7 to the outer surface of the joint body 5 may be damaged when the push wheel 7 and the joint body 5 are touched with other objects during stocking / storage or transportation. Demonstrate the protective function to prevent.

  After the flexible tube 2 is inserted, the seal rubber 6 is prevented from returning and moving toward the inlet side of the receiving portion 3 at the tip of the push ring 7 when the push wheel 7 is completely pushed by the pushing allowance. A sealing function between the vicinity of the distal end portion of the flexible tube 2 by the seal rubber 6 and the inner periphery of the receiving portion 3 can be secured.

The second positioning and holding means prevents the seal rubber 6 from moving in the inlet side direction after the flexible tube 2 is inserted and the push wheel 7 is pushed in, so that the sealing state and the retaining state by the seal rubber 6 can be secured. In this case, the second positioning means includes a second snap ring engagement groove 23 arranged in front of the first snap ring engagement groove 22 on the inner periphery of the receiving portion 3 as described in claim 2. The snap ring 27 is slid out of the tapered surface 22a of the first snap ring engaging groove 22 as the press ring 7 is pushed by the pushing amount by removing the heat shrinkable plastic film or its tube 32. The two snap ring engaging grooves 23 can be configured to engage with each other. According to this, the tip end portion of the push ring 7 is reliably positioned and held at the pushing position located on the rear side of the seal rubber 6 pushed in with the insertion of the flexible tube 2, and the sealing state and the retaining state by the seal rubber 6 are further ensured. Can hold.
Since the heat-shrinkable plastic film or its tube 32 is only heated and shrunk and is not bonded, it can be easily removed from the joint body 5 and the push ring 7 after the flexible tube 2 is inserted and the push ring 7 is pushed. .

The flexible pipe joint according to claim 1 has a large-diameter hole 11, a medium-diameter hole 12, and a small-diameter hole 13 in order from the inlet side toward the inner back side in the receiving portion 3, as described in claim 3. A tubular rubber body 6a having a sealing rubber 6 that has an inner diameter substantially the same as the outer diameter of the crest 8 of the flexible tube 2, and a tube projecting inwardly at the front end of the front body 6a. An end receiving portion 6b, an annular sealing action portion 6c projecting outward from the rear end portion of the front barrel portion 6a, and a rearward inner diameter larger than the inner diameter of the front barrel portion 6a, which is continuously provided rearward from the sealing action portion 6c. A side barrel portion 6d and an inner diameter that is connected to the rear end portion of the rear barrel portion 6d and is smaller than the inner diameter of the rear barrel portion 6d and larger than the outer diameter of the mountain portion 8 and larger than the outer diameter of the rear barrel portion 6d. It is integrally formed in a shape having an outer diameter retaining claw 6e, and between the small diameter hole 13 and the medium diameter hole 12. The first taper 15 is formed in a constricted shape toward the small diameter hole 13, and the second taper 16 is formed in a constricted shape toward the medium diameter hole 12 between the medium diameter hole 12 and the large diameter hole 11. In the free state, the seal rubber 6 has a tube end receiving portion 6b and a front body portion 6a located in the small diameter hole 13, a seal action portion 6c located in the medium diameter hole 12, and a retaining claw portion 6e. The flexible tube 2 is housed and disposed so as to be positioned in the radial hole 11, and the distal end portion of the flexible tube 2 is inserted into the seal rubber 6 as the distal end portion of the flexible tube 2 is inserted into the presser wheel 7 in a semi-inserted state. The seal rubber 6 is pushed inwardly in the receiving portion in contact with the end receiving portion 6b, and the sealing action portion 6c is slidably brought into contact with the constricted side of the first taper 15 along with the pushing, so that the diameter of the flexible tube 2 is reduced. Dense at least on the slope 9a of the valley 9 Those having features that are configured to.
In the present specification and claims, the “free state” means a state in which the rubber seal 6 is not deformed so as to expand and contract and no compressive stress or tensile stress is applied.

According to such a configuration, the sealing and sealing state by the seal rubber 6 between the outer peripheral surface near the tip of the flexible tube 2 and the inner peripheral surface of the small-diameter hole 13 is such that the sealing action portion 6c of the seal rubber 6 is a valley of the flexible tube 2. Since it is obtained by being in close contact with at least the inclined surface 8a of the portion 8, it is affected by the distal end portion inserted into the receiving portion 3 of the flexible tube 2, the deformation in the vicinity of the distal end portion, the bending after construction, and the like. It becomes difficult to improve the sealing performance.
Further, as the flexible tube 2 is inserted into the receiving portion 3, the distal end portion of the flexible tube 2 is inserted into the seal rubber 6 and comes into contact with the tube end receiving portion 6 b so that the seal rubber 6 is moved inwardly of the receiving portion 3. As a result of the pushing, the sealing action portion 6c is slidably in contact with the narrowed side of the first taper to reduce the diameter inward so as to be in close contact with at least the slope 9a of the valley portion 9 of the flexible tube 2. By simply inserting the flexible tube 2, it can be easily connected in a seal shape.

  Further, since the seal rubber 6 protrudes outward from the sealing action portion 6c at the beginning, that is, before the flexible pipe is inserted, when the distal end portion of the flexible pipe 2 is inserted, the distal end portion is inserted into the sealing action portion 6c. The flexible tube 2 can be smoothly inserted into the seal rubber 6 without causing an obstacle, and the ease of insertion of the flexible tube 2 can be ensured.

When the push ring 7 in the half-inserted state is positioned and held by the first positioning holding means at the initial position where the tip end portion thereof is located behind the retaining claw portion 6e of the seal rubber 6 before the flexible tube 2 is inserted. The seal rubber 6 is not likely to be pushed by the pusher wheel 7 in the semi-insertion state when the joint is stocked / stored or transported before the flexible pipe 2 is inserted, and the seal action portion 6c is in the middle diameter hole 12 in a free state. Therefore, no internal stress is generated in the sealing portion 6c, and the sealing portion 6c is elastically reduced in diameter only when the flexible tube 2 is inserted into the trough portion 9 of the flexible tube 2. Since it adheres, an appropriate compression allowance is maintained over a long period of time, and a predetermined service life can be guaranteed.
In addition, the push-in wheel 7 that has been completely pushed in has a tip portion positioned at the rear side of the retaining claw 6e of the seal rubber 6 that has been pushed into the small-diameter hole 13 with the insertion of the flexible tube 2 first. If the second positioning and holding means that is positioned and held is provided, it is possible to prevent the seal rubber 6 from moving in the inlet side direction after the insertion of the flexible tube 2 and the push wheel 7 is completed. The state can be ensured and the pull-out preventing force of the flexible tube 2 can be generated. Since the retaining claw portion 6e is formed integrally with the seal rubber 6, it is possible to reduce the number of members, the number of assembly steps, and the cost accordingly.

  According to the present invention, it is possible to connect the flexible pipe in a seal shape by simply inserting the push ring, and the seal rubber is in a semi-inserted state when the joint is stocked, stored or transported before the flexible pipe is inserted. It is possible to reliably prevent deformation by being pushed by a certain pusher wheel, and after the insertion of the flexible tube and pushing of the pusher wheel is completed, the seal rubber can be prevented from moving in the direction of the inlet, and the sealing state by the seal rubber is ensured. Can do. In particular, without applying any special processing to the joint body and the press ring, the heat-shrinkable plastic film or its tube is covered from the exposed outer surface of the half-inserted press ring to the outer surface of the joint body, and it is simply heat-shrinked and encapsulated. This simple method is advantageous in that it is possible to reliably prevent the pressing wheel from being inadvertently pushed during inventory / storage or transportation.

  Preferred embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a half cutaway cross-sectional view showing a flexible pipe joint according to an embodiment of the present invention in a state before insertion of the flexible pipe, and FIG. 2 is a half cutout cross section of the flexible pipe joint shown in the state of being inserted into the flexible pipe. FIG. 3 is a half cutaway cross-sectional view of the joint for the flexible pipe shown in a state after completion of insertion of the flexible pipe, FIG. 4A is a cross-sectional view of the half cutout of the seal rubber, and FIG. 3B is a rear view of the seal rubber. (C) is a side view of a seal rubber.

  As shown in FIG. 1, the joint 1 for flexible pipes which concerns on this invention forms the receiving part 3 which receives the front-end | tip part of the metal flexible pipe 2 in one end part, and has the external thread 4 for a connection in the outer periphery of the other end part. A formed joint body 5, a seal rubber 6 accommodated in the receiving portion 3 of the joint body 5, and a push ring 7 that is initially inserted in a semi-inserted state that leaves a pushing allowance in the receiving portion 3. .

  As shown in FIG. 1, the flexible tube 2 is formed by alternately arranging ridges 8 and valleys 9 extending along the entire circumference in the outer circumferential part in the pipe axis direction, and the outer circumference is made of a synthetic resin such as vinyl chloride. Covered with layer 10.

  As shown in FIG. 1, a large-diameter hole 11, a medium-diameter hole 12, and a small-diameter hole 13 are formed in communication from the inlet side toward the inner back side in the receiving port 3 of the joint body 5. A stopper portion 14 projects radially inward from the inner back end of the small diameter hole 13. A first taper 15 is formed between the small diameter hole 13 and the medium diameter hole 12 so as to narrow toward the small diameter hole 13, and a second taper 16 is formed between the medium diameter hole 12 and the large diameter hole 11. It is formed in a narrowed shape toward the medium diameter hole 13.

As shown in FIGS. 4A to 4C, the seal rubber 6 includes a cylindrical front body 6a having an inner diameter substantially the same as the outer diameter of the crest 8 of the flexible tube 2, and the front body 6a. A tube end receiving portion 6b projecting inwardly at the front end portion of the tube, an annular sealing action portion 6c projecting outward at the rear end portion of the front body portion 6a, and a front side connected to the rear side from the seal action portion 6c. A rear barrel portion 6d having an inner diameter larger than the inner diameter of the trunk portion 6a, and an outer diameter of the peak portion 8 of the flexible tube 2 that is connected to the rear end portion of the rear barrel portion 6d and is smaller than the inner diameter of the rear barrel portion 6d. The retaining claw 6e has a larger inner diameter and an outer diameter larger than the outer diameter of the rear body 6d, and is integrally formed.
The front side barrel portion 6a, the sealing action portion 6c, and the rear side barrel portion 6d are formed of NBR, SBR, EPDM, or the like. The tube end receiving portion 6b is formed of the same material or different material as the front side barrel portion 6a, the sealing action portion 6c, the rear side barrel portion 6d, and the like, and a reinforcing cored bar 6f such as a brass washer is embedded and molded.
The retaining claw portion 6e is formed in a partial arc shape with a metal material such as brass or hard resin harder than the front barrel portion 6a, the sealing action portion 6c, and the rear barrel portion 6d, and a plurality of these are formed on the rear barrel portion. 6d is integrally formed at a predetermined interval in the circumferential direction of the rear end portion. At the corner where the outer periphery and rear end surface of the retaining claw 6e intersect, a taper 25 having a rearward constriction is formed.

  As shown in FIG. 1, the seal rubber 6 has the tube end receiving portion 6b and the front body portion 6a positioned in the small diameter hole 13 and the sealing action portion 6c in the middle before the flexible tube 2 is inserted (initial state). While being located in the diameter hole 12, the retaining claw portion 6 e is accommodated and disposed so as to be located in the large diameter hole 11.

  As shown in FIG. 1, a tip latch member 17 is attached to the stopper portion 14 in the joint body 5. The tip latching member 17 has a C-shaped ring portion 17a that can freely expand and contract, and a resiliently deformable check claw 17b that protrudes from several locations on the inner diameter portion of the ring portion 17a. Etc. are formed. Then, the tip latching member 17 is engaged with the circumferential groove 14 a provided on the outer diameter side of the stopper portion 14 while the outer diameter portion of the ring portion 17 a is overlapped with the stopper portion 14. The pawl 17 b is attached to the stopper portion 14 so as to protrude into the small diameter hole 13.

  As shown in FIG. 1, the push wheel 7 has a cylindrical portion 7 a that is inserted in the axial direction so as to be movable in the axial direction of the large-diameter hole 11 of the joint body 5, and through which the flexible tube 2 can be inserted. A flange portion 7b having an outer diameter larger than that of the large-diameter hole 11 is integrally formed on the outer periphery of the inlet-side rear end portion. A packing groove 18 is formed in the circumferential direction on the inner periphery of the rear end on the inlet side of the cylindrical portion 7a of the push ring 7, and a waterproof packing 19 having a T-shaped section made of EPDM or the like is fitted into the packing groove 18. A tapered taper 20a having substantially the same gradient as the second taper 16 is formed on the outer periphery of the distal end portion of the cylindrical portion 7a, and a tapered taper 20b is formed on the inner periphery of the distal end portion of the cylindrical portion 7a.

As shown in FIG. 1, a snap ring housing and holding groove 21 is formed in the circumferential direction on the outer periphery of the cylindrical portion 7 a of the push ring 7, while the inner periphery of the large-diameter hole 11 of the joint body 5 is on the inner side from the inlet side. A first snap ring engaging groove 22 and a second snap ring engaging groove 23 are formed in the circumferential direction in this order. A taper surface 22 a that gradually narrows forward is formed on the front groove wall in the first snap ring engagement groove 22. A plurality of pin-shaped selectively permeable members 26 that transmit gas but do not transmit solids or liquids are embedded in several places in the circumferential direction of the waterproof packing 19 to enable gas leakage inspection. The permselective member 26 has, for example, a continuous pore formed from a sheet material including a continuous porous film formed from a tetrafluoroethylene resin powder, or a thermoplastic resin powder such as polyethylene, polypropylene, polymethyl acrylate, or the like. It is a porous body.
A waterproof packing groove 28 is provided behind the snap ring housing and holding groove 21 of the cylindrical portion 7 a of the push ring 7, and a waterproof packing 29 is fitted in the waterproof packing groove 28. A fireproof packing groove 30 is provided on the inner periphery of the medium-diameter hole 12 of the joint body 5, and a fireproof packing 31 made of rubber with thermally expandable graphite or the like is fitted into the fireproof packing groove 30.

  As shown in FIG. 1, the push wheel 7 is positioned and held in a semi-inserted state (initial position) located at the rear side of the retaining claw 6e of the seal rubber 6 before the flexible tube 2 is inserted as shown in FIG. As shown in FIG. 3, the holding means and the front end portion are located with a slight gap behind the retaining claw portion 6e of the sealing rubber 6 that is pushed into the small diameter hole 13 as the flexible tube 2 is inserted. A second positioning and holding means that is positioned and held at a proper pushing position.

As shown in FIG. 1, the first positioning and holding means is configured such that the inner peripheral portion of a snap ring 27 that is freely expandable / contractible and is formed of a C-shaped retaining ring for a hole is fitted in the snap ring receiving and holding groove 21 of the push ring 7. And the outer peripheral portion of the snap ring 27 protrudes from the outer peripheral surface of the cylindrical portion 7a of the push ring 7 and is detachably engaged with the first snap ring engaging groove 22 of the joint body 5. The snap ring 27 is housed in the snap ring housing / holding groove 21 in a state where the diameter can be increased.
Further, the first positioning and holding means covers a heat-shrinkable plastic film or a tube 32 thereof from the outer surface exposed from the joint body 5 of the press ring 7 in the half-inserted state to at least the outer surface of the receiving portion 3 of the joint body 5. Encapsulated by heat shrinkage. The heat-shrinkable plastic film or the tube 32 thereof is preferably a non-vinyl chloride material that is environmentally friendly, such as a polystyrene shrink film, a polyolefin shrink film, a polyester shrink film, or a polypropylene shrink film.

  By means of the first positioning and holding means, as shown in FIG. 1, the pusher wheel 7 is a retaining claw in which the tip of the pusher wheel 7 in a half-inserted state is positioned in the medium diameter hole 12 of the seal rubber 6 before the flexible tube 2 is inserted. It is positioned and held at the initial position located on the rear side of the portion 6e. That is, in the initial position, the half-inserted push wheel 7 is in close contact with the outer peripheral portion of the snap ring 27 and the first snap ring engaging groove 22 and from the exposed outer surface of the push wheel 7 to the outer surface of the joint body 5. It is surely prevented from being pushed in by the enclosing plastic film or its restraining force by the tube 32. The push wheel 7 is prevented from being inadvertently pushed from the half-insertion state of the initial state by the first positioning and holding means, thereby preventing a problem that the seal rubber 6 is inadvertently pushed and deformed.

  The second positioning and holding means is provided with a second snap ring engaging groove 23 arranged in front of the first snap ring engaging groove 22 on the inner periphery of the receiving portion 3, and a heat shrinkable plastic film or its The snap ring 27 slides out of the tapered surface 22a of the first snap ring engaging groove 22 and engages with the second snap ring engaging groove 23 as the push ring 7 in the half-inserted state is pushed after the tube 32 is removed. (See FIG. 3). The stroke length S (see FIG. 2), which is the pushing allowance of the push wheel 7, is set to be substantially the same as the distance between the first snap ring engaging groove 22 and the second snap ring engaging groove 23. Has been.

  Next, a procedure for connecting the flexible pipe 2 to the flexible pipe joint 1 will be described with reference to FIGS.

  When the joint 1 is stocked / stored or transported before the flexible pipe 2 is connected as shown in FIG. 1, the engaging action between the outer peripheral portion of the snap ring 27 and the first snap ring engaging groove 22, and the press ring 7 is inadvertently pushed by the first positioning and holding means by the plastic film formed by tightly enveloping from the exposed outer surface of the joint 7 to the outer surface of the joint body 5 or the restraining force of the tube 32. Generation | occurrence | production of the malfunction which deform | transforms the seal rubber 6 can be prevented.

  When connecting the flexible tube 2, first, the heat-shrinkable plastic film or the tube 32 thereof is removed from the joint body 5 and the push ring 7, the synthetic resin layer 10 is peeled off, and about 6 peaks 8 are exposed. 2 is inserted from the inlet side of the pusher wheel 7 in the order of the retaining claw 6e of the seal rubber 6 in the receiving part 3 of the joint body 5, the rear body part 6d, the sealing action part 6c, and the front body part 6a. The distal end portion of the tube 2 is brought into contact with the tube end receiving portion 6 b of the seal rubber 6. At that time, since the sealing action portion 6c of the seal rubber 6 is formed so as to protrude outward, the distal end portion of the flexible pipe 2 is not disturbed when the flexible pipe 2 is inserted. It can be smoothly inserted into the seal rubber 6.

  Subsequently, when the flexible tube 2 is inserted to a predetermined depth as shown in FIG. 2, the seal rubber 6 is pushed into the receiving portion in the inner direction along with the flexible tube 2, and the seal action portion 6 c of the seal rubber 6 is first tapered along with this pushing. 15 is pressed by the first taper 15 by sliding in contact with the narrowed side of 15 and deformed inwardly, and as soon as it passes through the first tapered surface 15 and moves into the small-diameter hole 13, the valley of the flexible tube 2. When the slope 9a and the valley bottom 9b of the portion 9 are in close contact with each other or at least the slope 9a in a compressed state, the retaining claw 6e of the seal rubber 6 is slidably brought into contact with the narrowed side of the second taper 16 at the same time. The taper 16 moves to the medium diameter hole 12 while being pressed in the diameter reducing direction. As a result, the space between the outer peripheral surface of the distal end portion of the flexible tube 2 and the inner peripheral surface of the small-diameter hole 13 of the joint body 5 is reliably sealed and sealed by the seal rubber 6, and the fluid flowing in the flexible tube 2 flows. Thus, it is possible to prevent leakage from passing between the outer periphery of the distal end portion of the flexible tube 2 and the inner periphery of the small diameter hole 13 of the joint body 5. A sealing function can also be expected between the tip of the flexible tube 2 and the tube end receiving portion 6b of the seal rubber 6.

When the flexible tube 2 is inserted to a predetermined depth as shown in FIG. 2, the inner diameter portion of the tube end receiving portion 6 b of the seal rubber 6 and the inner surface of the distal end portion of the flexible tube 2 are the check claws 17 b of the distal end latching member 17. And the inner periphery of the small-diameter hole 13 are engaged with the check claw 17b after passing through the elastic claw deformation of the check claw 17b. When this pipe end receiving portion 6b passes through the check claw 17b, the installer feels responsive and can feel that the flexible pipe 2 has been inserted to a predetermined depth.
Moreover, while the front-end | tip part of the flexible pipe | tube 2 engages with the non-return claw 17b of the front-end | tip latching member 17, the flexible claw part 6e enters into the trough part 9, and it suppresses that the flexible pipe | tube 2 shakes. can do.

  After the insertion of the flexible tube 2 is completed, the push ring 7 is completely pushed in by the pushing allowance as shown in FIG. Along with this pushing, the snap ring 27 is in sliding contact with the tapered surface 22a of the first snap ring engagement groove 22 of the joint body 5 in a state where the inner peripheral portion is fitted and accommodated in the snap ring accommodation holding groove 21. The diameter is elastically reduced. When the push ring 7 is completely pushed in, the outer peripheral portion of the reduced snap ring 27 reaches the second snap ring engaging groove 23 and the snap ring 27 is expanded in diameter by an elastic restoring action, and the outer peripheral portion. The second positioning and holding means for engaging with the second snap ring engaging groove 23 acts. As a result, the pusher wheel 7 is held at the complete pushing position where the tip end portion thereof is located behind the retaining claw portion 6e of the seal rubber 6, so that the seal rubber 6 moves back toward the inlet side of the receiving portion 3. Can be prevented. Therefore, the sealing state by the seal rubber 6 can be ensured.

  Further, as the push ring 7 is completely pushed, the taper 20 b at the tip end of the push ring 7 comes close to and opposes the taper 25 of the retaining claw 6 e of the seal rubber 6. Therefore, even if an external force is applied in the direction in which the flexible tube 2 is pulled out at this time, the taper 25 of the retaining claw portion 6e that accompanies the flexible tube 2 comes into contact with the constricted side of the taper 20b of the push ring 7, so The tube 2 is reliably prevented from coming out.

  In the above embodiment, the joint portion for the male threaded flexible pipe in which the receiving port 3 is formed at one end of the joint body 5 and the male thread for connection 4 is formed at the outer periphery of the other end is described, but the present invention is not limited thereto, and other structures, For example, the present invention can be applied to symmetrical socket-type flexible pipe joints having receiving portions at both ends, elbow-type flexible pipe joints, and the like.

It is a half notched cross-sectional view showing the joint for flexible pipe showing an embodiment of the present invention in a state before insertion of the flexible pipe. It is a half notched cross-sectional view of the joint for flexible pipes shown in the state during insertion of the flexible pipes. It is a half notched cross-sectional view of the joint for flexible pipes shown in a state after completion of insertion of the flexible pipes. (A) is a half cutaway cross-sectional view of the seal rubber, (b) is a rear view of the seal rubber, and (c) is a side view of the seal rubber. (A) is sectional drawing which shows the joint for flexible pipes of a prior art example in the state in the middle of flexible pipe insertion, (B) is sectional drawing which shows the joint for flexible pipes in the state after completion of flexible pipe insertion.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Joint for flexible pipes 2 Flexible pipe 3 Receiving part 5 Joint main body 6 Seal rubber 6a Front side trunk | drum 6b Pipe end receiving part 6c Sealing action part 6d Rear side trunk | drum 6e Stopping claw part 7 Push ring 8 Crest part 9 Valley part 9a Slope 11 Large diameter hole 12 Medium diameter hole 13 Small diameter hole 15 First taper 16 Second taper 21 Snap ring receiving and holding groove 22 First snap ring engagement groove 22a Tapered surface 23 Second snap ring engagement groove 27 Snap ring 32 Heat Shrinkable plastic film or its tube

Claims (3)

A joint body having a receiving portion into which a distal end portion of a flexible pipe is alternately arranged in the pipe axis direction with crests and troughs extending in the circumferential direction all around the outer periphery, and accommodated in the receiving portion A seal rubber that seals between the outer periphery of the vicinity of the distal end of the flexible tube inserted into the receiving part and the inner periphery of the receiving part, and a push ring inserted into the receiving part, The pusher wheel is inserted in a semi-insertion state that leaves a pushing allowance in the receiving part, and when the pushing wheel is completely pushed in by the pushing allowance, the seal rubber moves back toward the inlet side of the receiving part at the tip of the pushing wheel. In a flexible pipe joint that is designed to suppress
The pusher wheel in the half-inserted state has first positioning and holding means for positioning and holding the tip portion of the pusher wheel at the initial position located on the rear side of the seal rubber before inserting the flexible tube, and the pusher wheel fully pushed in is A second positioning and holding means that is positioned and held at a pushing position located on the rear side of the seal rubber that has been pushed in with the insertion of the flexible tube.
The first positioning and holding means is provided on a snap ring receiving and holding groove provided on an outer periphery of the push ring, a snap ring having an inner peripheral portion fitted in the snap ring receiving and holding groove, and an inner periphery of the receiving portion. A first snap ring engaging groove that engages with an outer peripheral portion of the snap ring, and a tapered surface that is gradually narrowed toward the front on the front groove wall in the first snap ring engaging groove. A flexible pipe joint comprising: a heat-shrinkable plastic film or a tube covering the outer surface of the joint body from the exposed outer surface of the half-inserted press wheel;   The second positioning means includes a second snap ring engagement groove arranged in front of the first snap ring engagement groove on an inner periphery of the receiving portion, and removes the plastic film or its tube. The snap ring is configured to slide out of the tapered surface of the first snap ring engagement groove and engage with the second snap ring engagement groove as the push wheel is pushed by the pushing amount. The joint for flexible pipes according to claim 1. In the joint for flexible pipes according to claim 1,
A large-diameter hole, a medium-diameter hole, and a small-diameter hole are formed in order from the inlet side toward the inner back side in the receiving portion.
The sealing rubber has a cylindrical front barrel having an inner diameter substantially the same as the outer diameter of the ridge of the flexible tube, a pipe end receiving portion projecting inwardly to the front end of the front barrel, and the front barrel An annular sealing portion projecting outward from the rear end portion of the rear portion, a rear trunk portion having an inner diameter larger than the inner diameter of the front barrel portion, which is connected to the rear from the sealing action portion, and a rear portion of the rear barrel portion. And a retaining claw that is continuous with the end and has an inner diameter that is smaller than the inner diameter of the rear trunk and larger than the outer diameter of the peak and larger than the outer diameter of the rear trunk. Has been
A first taper is formed between the small diameter hole and the medium diameter hole so as to be narrowed toward the small diameter hole, and a second taper is formed between the medium diameter hole and the large diameter hole toward the medium diameter hole. It is formed in a ball shape,
When the seal rubber is in a free state, the tube end receiving portion and the front body portion are located in the small diameter hole, and the sealing action portion is located in the medium diameter hole, and the retaining claw portion is the large diameter hole. It is housed so as to be located inside,
As the distal end portion of the flexible tube is inserted into the push ring in a half-inserted state, the distal end portion of the flexible tube is inserted into the seal rubber and abuts against the tube end receiving portion so that the seal rubber is inserted into the interior of the receiving portion. In accordance with this depression, the sealing action portion is configured to be slidably brought into contact with the narrowed side of the first taper to reduce its diameter and to be in close contact with at least the slope of the valley portion of the flexible tube. A flexible pipe joint.

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