JP6755366B2 - Resin fittings - Google Patents

Description

The present invention relates to a resin pipe joint.

Conventionally, resin pipe fittings that can be used in manufacturing equipment in technical fields such as semiconductor manufacturing, medical / pharmaceutical manufacturing, food processing, and chemical industry are known (see, for example, Patent Document 1). This type of resin pipe joint is for connecting a tube for circulating a fluid such as ultrapure water or a chemical solution to another tube or a fluid device, and is configured to be joinable to the tube.

The resin pipe joint includes a joint body, an inner ring, and a union nut for joining to the tube, and the inner ring and one end portion of the tube press-fitted thereto in the longitudinal direction are combined with the joint body. One end of the tube in the longitudinal direction is held by the union nut so that a seal region is formed between the inner ring and the joint body.

The resin pipe joint is often used in the manufacturing apparatus while being loaded with a heat cycle (specific example: normal temperature (about 20 ° C.) → high temperature (about 200 ° C.) → normal temperature). Therefore, even after the resin pipe joint is exposed to an environment higher than normal temperature due to its use, the sealing performance between the joint body and the inner ring can be maintained satisfactorily. Improvement of sealing performance has been desired.

Japanese Unexamined Patent Publication No. 10-054489

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a resin pipe joint capable of improving the sealing performance between the joint body and the inner ring.

The present invention
In resin fittings that can be joined to tubes
A joint body with a cylinder and
An inner ring having an insertion portion that can be inserted into the cylinder portion so as to be in contact with the cylinder portion in the radial direction, and a press-fit portion that can be press-fitted to one end side in the longitudinal direction of the tube.
A union nut configured to be connectable to the joint body is provided so that the insertion portion can be held in the state of being inserted into the cylinder portion.
The joint body and the inner ring are made of different resin materials, and each has a property of shrinking with a change in atmospheric temperature.
The radial shrinkage rate of the tubular portion of the joint body is set to be 0.09% or more larger than the radial shrinkage rate of the inner ring insertion portion.

According to this configuration, when the tube is joined to the resin pipe joint and the joint body and the inner ring are heated by heat transfer from a fluid flowing inside them and then cooled (heat). When a cycle is applied), the tubular portion of the joint body can be contracted in the radial direction more than the insertion portion of the inner ring.

Therefore, when the thermal cycle is performed, the tubular portion of the joint body is deformed (reduced) so that the inner diameter thereof decreases by a large amount of change as compared with the outer diameter of the insertion portion of the inner ring, and the joint The tubular portion of the main body can be pressed against the insertion portion of the inner ring that is radially overlapped with the tubular portion.

Therefore, the sealing performance between the tubular portion of the joint body and the insertion portion of the inner ring can be satisfactorily maintained even after the resin pipe joint is exposed to an environment higher than normal temperature. Can be improved. That is, it is possible to improve the sealing performance between the joint body and the inner ring.

According to another aspect of the invention
The joint body
With the main body cylinder
An outer cylinder portion as the cylinder portion, which is coaxially projected from the main body cylinder portion in one axial direction thereof,
The same as the outer cylinder portion from the main body cylinder portion so that the outer cylinder portion is arranged inward in the radial direction and the protruding end portion is located closer to the main body cylinder portion than the protruding end portion of the outer cylinder portion. The inner cylinder part that protrudes coaxially in the direction,
It has a groove portion formed by being surrounded by the main body cylinder portion, the outer cylinder portion, and the inner cylinder portion so as to open in one direction in the axial direction.
The inner ring
When the insertion portion is inserted into the outer cylinder portion, the insertion portion is press-fitted into the groove portion so that a first seal region acting in the radial direction is formed between the insertion portion and the inner cylinder portion. ..

According to this configuration, when the outer cylinder portion of the joint body contracts through the heat cycle, the insertion portion of the inner ring press-fitted into the groove portion is inserted into the inner cylinder portion of the joint body by the outer cylinder portion of the joint body. It becomes possible to press toward, and the pressure contact force between these insertion portions and the inner cylinder portion in the radial direction can be strengthened.

Therefore, the resin pipe joint is exposed to a higher temperature environment than the normal temperature for the sealing performance of the first seal region formed between the inner cylinder portion of the joint body and the insertion portion of the inner ring. It can be improved so that it can be sustained well later. As a result, the sealing performance between the joint body and the inner ring can be further improved.

According to the present invention, it is possible to provide a resin pipe joint capable of improving the sealing performance between the joint body and the inner ring.

It is sectional drawing which shows the joint structure of the resin pipe joint which concerns on one Embodiment of this invention, and one end part in the longitudinal direction of a tube. It is a figure which shows the partial dimension of the inner ring and the joint body in each of Example 1, Example 2, and Example 3 of this invention. It is a figure which shows the partial dimension of the inner ring and the joint body in each of Comparative Example 1, Comparative Example 2, and Comparative Example 3. 2 is a diagram showing the shrinkage rate of the inner ring and the joint body in each of Example 1, Example 2, Example 3, Comparative Example 1, Comparative Example 2, and Comparative Example 3 based on the description of FIG. 2 or FIG. is there. It is a figure which shows the sealing performance in each of Example 1, Example 2, Example 3, Comparative Example 1, Comparative Example 2, and Comparative Example 3.

An embodiment of the present invention will be described with reference to the drawings.

The resin pipe joint 1 according to the embodiment of the present invention can be used in a semiconductor, liquid crystal, organic EL manufacturing apparatus, or the like. When the resin pipe joint 1 is used in the manufacturing apparatus or the like, the tube 2 is connected to another tube (not shown) or a fluid device such as a valve or a pump, as shown in FIG. It is configured so that it can be joined with.

The resin pipe joint 1 can be joined to the tube 2 with the longitudinal end 5 of the tube 2 inserted inside the resin pipe joint 1, and the joint body 11 and the inner ring 12 And a union nut 13. In the present embodiment, the tube 2 is a flexible cylindrical one having a substantially constant inner diameter, and is configured by using a resin material such as a fluororesin material.

In the following description, the one side in the axial direction refers to the tube 2 side in the resin pipe joint 1 in FIG. 1, and the other side in the axial direction refers to the joint body 11 side in the resin pipe joint 1 in FIG. Point to.

The joint body 11 has a tubular portion (outer tubular portion 22 described later) into which one end portion 5 in the longitudinal direction of the tube 2 can be inserted. The joint body 11 also has a fluid flow path 16. The fluid flow path 16 communicates with the fluid flow path 7 of the tube 2 when the longitudinal end portion 5 of the tube 2 is inserted into the outer cylinder portion 22 (the receiving portion 15 thereof). Is provided inside the joint body 11.

In the present embodiment, the joint main body 11 includes a main body cylinder portion 21, an outer cylinder portion 22, and an inner cylinder portion 23. The main body tubular portion 21 has a cylindrical portion, and has a first fluid flow path 24 that can communicate with the fluid flow path 7 of the tube 2. The first fluid flow path 24 has a substantially circular cross section, and is provided inside the main body tubular portion 21 along the axial direction so as to form a part of the fluid flow path 16.

The outer cylinder portion 22 has a screwed portion that can be screwed with the union nut 13, and has one axial direction from one axial end of the main body tubular portion 21 so as to form the receiving portion 15. It is projected coaxially to. The outer cylinder portion 22 is formed in a cylindrical shape, and the receiving portion 15 is provided inside. The screwed portion is provided as a male screw portion 25 on the outer peripheral portion of the outer cylinder portion 22 along the axial direction.

The inner cylinder portion 23 is arranged inward in the radial direction of the outer cylinder portion 22. The inner cylinder portion 23 has a protruding end portion 26 so that the protruding end portion 26 is located closer to the main body cylinder portion 21 than the protruding end portion 27 provided on the outer cylinder portion 22. It is coaxially projected from one end of the main body cylinder portion 21 in the axial direction in the same direction as the outer cylinder portion 22 (one of the axial directions of the main body cylinder portion 21).

The inner cylinder portion 23 has an inner diameter substantially the same as the inner diameter of the main body cylinder portion 21, and is formed in a cylindrical shape having an outer diameter smaller than the inner diameter of the outer cylinder portion 22. It has a second fluid flow path 28 that can communicate with the fluid flow path 7. The second fluid flow path 28 has a substantially circular cross section, and is coaxially connected to the first fluid flow path 24 so as to form the fluid flow path 16 together with the first fluid flow path 24. Has been done.

The joint body 11 further includes a groove 29 formed by being surrounded by the main body cylinder portion 21, the outer cylinder portion 22, and the inner cylinder portion 23 so as to open in one axial direction. The groove portion 29 is formed in an annular shape extending along the entire circumference of the outer peripheral surface of the inner cylinder portion 23 so that the other end portion (insertion portion 36 described later) of the inner ring 12 in the axial direction can be press-fitted. ing.

Further, the inner ring 12 has an insertion portion 32 that can be inserted into the outer cylinder portion 22 so as to be in contact with the outer cylinder portion 22 in the radial direction, and a press-fit portion that can be press-fitted into the longitudinal end portion 5 side of the tube 2. Has 31. The outer cylinder 31 is in a state where at least a part of the press-fitting portion 31 is press-fitted from the opening portion 8 into the longitudinal end portion 5 side of the tube 2 together with the insertion portion 32 and the longitudinal end portion 5 of the tube 2. The structure is such that it can be inserted into the receiving portion 15 (inside the joint body 11) of the portion 22.

In the present embodiment, the insertion portion 32 includes a fitting portion 35, the insertion portion 36, and a contact portion 37. The inner ring 12 also has a fluid flow path 38 capable of communicating the fluid flow path 7 of the tube 2 and the fluid flow path 16 of the joint body 11.

Specifically, the outer peripheral shape of the press-fitting portion 31 is the same as the inner peripheral shape (cylindrical shape) of one end portion 5 in the longitudinal direction of the tube 2 (the portion whose diameter is expanded by press-fitting the press-fitting portion 31). The inner ring 12 is arranged on one side in the axial direction. The press-fitting portion 31 has an inner diameter substantially the same as the inner diameter of the tube 2 (the inner diameter in a state where the diameter is not expanded, and the same applies hereinafter), and the axial one-side portion of the fluid flow path 38. Is provided so as to include the inside. Here, the fluid flow path 38 has a substantially circular cross section.

The press-fitting portion 31 also has an outer diameter larger than the inner diameter of the tube 2, and is inside the longitudinal end portion 5 side of the tube 2 so as to expand the diameter of the longitudinal end portion 5 side of the tube 2. The tube 2 is press-fitted from the opening portion 8 to the longitudinal end portion 5 side of the tube 2 while being press-fitted over the entire circumference, and can be held at a predetermined press-fit position with respect to the longitudinal end portion of the tube 2. It is configured.

Then, the press-fitting portion 31 is pressed into the longitudinal end portion 5 side of the tube 2 so that the press-fitting position of the tube 2 with respect to the longitudinal direction end portion does not change. It is configured so that it can be inserted into the receiving portion 15 (inside of the joint body 11) of the outer cylinder portion 22 from the other side in the axial direction of the press-fitting portion 31 together with the 5.

When the press-fitting portion 31 is inserted into the receiving portion 15 of the outer cylinder portion 22, the one end portion 5 in the longitudinal direction of the tube 2 is sandwiched between the outer cylinder portion 22 and the receiving portion 15. That is, the press-fitting portion 31 presses against the longitudinal end portion 5 of the tube 2 from the inside in the radial direction over the entire circumference and the entire length in the axial direction, and the outer cylinder portion 22 is in full contact with the longitudinal end portion 5 of the tube 2. It touches from the outside in the radial direction over the entire circumference and axial direction.

The press-fitting portion 31 further has a bulging portion 39. When the press-fitting portion 31 is press-fitted to the longitudinal end portion 5 side of the tube 2, the bulging portion 39 improves the sealing performance between the two and prevents the tube 2 from coming off. It is an annular convex portion for planning, and is formed so as to bulge outward in the radial direction of the inner ring 12 on one side in the axial direction of the press-fitting portion 31.

The bulging portion 39 includes a tapered first outer peripheral surface and a second outer peripheral surface arranged so as to face each of one and the other in the axial direction with the top portion (the outermost end portion in the radial direction) interposed therebetween. It has a convex cross section. On the second outer peripheral surface of the bulging portion 39, when the press-fitting portion 31 is inserted into the outer cylinder portion 22, one side portion in the axial direction of the longitudinal end portion 5 of the tube 2 is referred to as the outer cylinder portion 22. It can be sandwiched between.

The insertion portion 32 is arranged outside the tube 2 when the press-fitting portion 31 is press-fitted to the one end portion 5 side in the longitudinal direction of the tube 2. The insertion portion 32 has a tubular shape and is arranged on the other side of the inner ring 12 in the axial direction. The insertion portion 32 has an inner diameter substantially the same as the inner diameter of the press-fitting portion 31, and is provided so as to include a portion of the fluid flow path 38 on the other side in the axial direction.

The insertion portion 32 has an outer diameter generally larger than the outer diameter of the press-fitting portion 31, and the press-fitting portion 31 is inserted into the receiving portion 15 of the outer cylinder portion 22 together with the longitudinal end portion 5 of the tube 2. When this is done, the outer cylinder portion 22 is inserted into the receiving portion 15 of the outer cylinder portion 22 before the press-fitting portion 31 so as to be in contact with the outer cylinder portion 22 from the inside in the radial direction over the entire circumference and the entire length in the axial direction. Has been done.

In the insertion portion 32, the fitting portion 35 has a tubular shape and is coaxially connected to the other end portion in the axial direction of the press-fitting portion 31. The fitting portion 35 is formed in a cylindrical shape having an inner diameter substantially the same as the inner diameter of the press-fitting portion 31 and the inner diameter of the tube 2, and is a part of the other side portion of the fluid flow path 38 in the axial direction. It has a fluid flow path that forms a structure.

The fitting portion 35 has an outer diameter larger than the outer diameter of the press-fitting portion 31 (excluding the vicinity of the top of the bulging portion 39), and the insertion portion 32 is a receiving portion 15 of the outer cylinder portion 22. When inserted into, the outer cylinder portion 22 is brought into close contact, contact with, or pressure contact from the inside in the radial direction. Here, the fitting portion 35 is brought into close contact, contact with, or pressure contact with the outer cylinder portion 22 over the entire circumference and the entire length in the axial direction.

The insertion portion 36 has a tubular shape that can be press-fitted into the groove portion 29 of the joint body 11, and is coaxially projected from the fitting portion 35 in the other direction in the axial direction. The insertion portion 36 has an inner diameter slightly smaller than the outer diameter of the inner cylinder portion 23 of the joint body 11, and has a cylindrical shape having substantially the same or slightly larger outer diameter than the fitting portion 35. It is formed.

When the insertion portion 32 is inserted into the receiving portion 15 of the outer cylinder portion 22, the insertion portion 36 is press-fitted into the groove portion 29 and has a first seal region 41 between the insertion portion 32 and the inner cylinder portion 23. Is pressed against the inner cylinder portion 23 from the outside in the radial direction in order to form the inner cylinder portion 23. Here, the insertion portion 36 is in contact with the inner cylinder portion 23 over the entire circumference and the entire length in the axial direction.

At this time, the insertion portion 36 is adapted to abut or press contact with the outer cylinder portion 22 from the inside in the radial direction. Here, too, the insertion portion 36 is in contact with the outer cylinder portion 22 over the entire circumference and the entire length in the axial direction.

The contact portion 37 has a tubular shape and is arranged inward in the radial direction of the insertion portion 36. The contact portion 37 is said so that the protruding end portion 43 of the contact portion 37 is located closer to the fitting portion 35 than the protruding end portion 44 of the insertion portion 36 in the axial direction of the inner ring 12. It projects coaxially from the fitting portion 35 in the same direction as the insertion portion 36 (the other in the axial direction of the fitting portion 35).

The contact portion 37 is formed in a cylindrical shape having an inner diameter substantially the same as the inner diameter of the fitting portion 35 and the inner diameter of the inner cylinder portion 23 of the joint body 11. The contact portion 37 is smaller than the inner diameter of the insertion portion 36 so that the protruding end portion 26 side of the inner cylinder portion 23 can be sandwiched between the contact portion 37 and the one side portion in the axial direction of the insertion portion 36. It has an outer diameter.

Then, when the insertion portion 36 is press-fitted into the groove portion 29, the contact portion 37 regulates the radial inward deformation movement of the inner cylinder portion 23 due to the press-fitting, and the inner cylinder portion 23. In order to form the second seal region 42 between the two, the inner cylinder portion 23 is pressed against the inner cylinder portion 23 from one side in the axial direction. Here, the contact portion 37 is in contact with the inner cylinder portion 23 over the entire circumference thereof.

Further, the union nut 13 is said to hold a state in which the insertion portion 32, at least a part of the press-fitting portion 31, and one end portion 5 in the longitudinal direction of the tube 2 are inserted into the outer cylinder portion 22. It is configured to be connectable to the joint body 11. In the present embodiment, the union nut 13 has a through hole in the shaft portion through which the tube 2 can pass.

The union nut 13 is configured to be playable in the tube 2 so that it can move relative to the tube 2 in the longitudinal direction thereof, and the joint body 11 is provided with the tube 2 passed through the through hole. It is configured so that it can be fastened to the outer cylinder portion 22 of the above. The union nut 13 has a connecting portion 46 and a pressing portion 47.

In the connecting portion 46, the press-fitting portion 31 is inserted into the receiving portion 15 together with the longitudinal end portion 5 of the tube 2 so as to connect the longitudinal end portion 5 side of the tube 2 to the joint body 11. In this state, it is configured so that it can be screwed to the outer peripheral portion of the joint body 11 so as to sandwich the longitudinal end portion 5 of the tube 2 with the press-fitting portion 31 in the radial direction.

The connecting portion 46 includes a part of the through hole and also includes a screwed portion that can be screwed with a screwed portion (the male screw portion 25) of the outer cylinder portion 22 of the joint body 11. The connecting portion 46 has a tubular shape and is arranged on the other side in the axial direction of the union nut 13. The screwed portion of the connecting portion 46 is provided as a female screw portion 49 on the inner peripheral portion of the connecting portion 46 along the axial direction so as to correspond to the screwed portion of the outer cylinder portion 22 of the joint body 11. ing.

The connecting portion 46 has a diameter of the outer cylinder portion 22 when the female screw portion 49 is screwed with respect to the male screw portion 25 in the outer cylinder portion 22 of the joint body 11 and then screwed in the other direction in the axial direction. Surrounding from the outside in the direction, the outer cylinder portion 22 and the longitudinal end portion 5 of the tube 2 inserted into the outer cylinder portion 22 together with the press-fit portion 31 of the inner ring 12 are sandwiched between the outer cylinder portion 22 and the press-fit portion 31.

At this time, the connecting portion 46 is in contact with the outer cylinder portion 22 over the entire circumference of the screwed region in which the female screw portion 49 is screwed to the male screw portion 25 in the outer cylinder portion 22 from the radial outside. It indirectly contacts the longitudinal end portion 5 of the tube 2 inserted into the receiving portion 15 of the tubular portion 22 via the outer tubular portion 22 over the entire circumference of the screwed region.

The pressing portion 47 has the connecting portion 46 with respect to the male screw portion 25 in the outer cylinder portion 22 in a state where the press-fitting portion 31 is inserted into the receiving portion 15 together with the longitudinal end portion 5 of the tube 2. As the tube 2 is screwed, the one end portion 5 side in the longitudinal direction of the tube 2 is pressed toward the joint body 11 from one side in the axial direction thereof, and the press-fitting portion 31 is directed from the radial outside thereof. It is configured so that it can be pressed.

The pressing portion 47 has a tubular shape and is arranged on one side in the axial direction of the union nut 13. The pressing portion 47 is coaxially connected to the connecting portion 46 so that the inner peripheral portion thereof is located radially inside the inner peripheral portion of the connecting portion 46. The pressing portion 47 has an inner diameter smaller than the inner diameter of the connecting portion 46 and slightly larger than the outer diameter of the tube 2, and includes the remaining portion of the through hole.

The pressing portion 47 sandwiches the longitudinal end portion 5 of the tube 2 into which the connecting portion 46 is inserted together with the outer cylinder portion 22 and the press-fitting portion 31 of the inner ring 12 between the outer cylinder portion 22 and the press-fitting portion 31. When, it is arranged outside the outer cylinder portion 22 in one axial direction thereof, and the one end portion 5 side in the longitudinal direction of the tube 2 can be sandwiched between the press-fitting portion 31 and the press-fitting portion 31.

Specifically, the pressing portion 47 has a corner portion 48 provided on the other side of the inner peripheral portion in the axial direction, and the connecting portion 46 is screwed with respect to the male screw portion 25 in the outer cylinder portion 22. At that time, the one end portion 5 side in the longitudinal direction of the tube 2 is pressed from one side in the axial direction toward the joint body 11 by the corner portion 48, and the press-fitting portion is pressed by the corner portion 48 from the radial outside thereof. It can be pressed toward 31, in other words, sandwiched (sandwiched) between the press-fitting portion 31 and the press-fitting portion 31.

Here, in the corner portion 48, the connecting portion 46 is screwed with respect to the male screw portion 25 in the outer cylinder portion 22, that is, the tightening of the union nut 13 to the joint body 11 is advanced. The bulging portion 39 presses the enlarged diameter portion of the tube 2 so as to drive a wedge into the enlarged diameter portion (the portion along the first outer peripheral surface) of the tube 2 over the entire circumference thereof. ..

The union nut 13 is also made of a predetermined resin material. Preferably, the union nut 13 is constructed by using a fluororesin material as in the present embodiment. Specific examples of the fluororesin material include PFA (perfluoroalkoxy alkane resin), PTFE (polytetrafluoroethylene), and ETFE (ethylene / tetrafluoroethylene copolymer).

When joining the tube 2 to the resin pipe joint 1 configured in this way, for example, first, the union nut 13 is loosely fitted into the tube 2. Next, in order to connect the inner ring 12 to the tube 2, the press-fitting portion 31 is coaxially connected to the one end portion 5 in the longitudinal direction from the opening portion 8 while expanding the diameter of the tube 2 by the bulging portion 39. Press-fit.

Then, the insertion portion 32 of the inner ring 12 outside the tube 2 is inserted into the receiving portion 15 (inside of the resin pipe joint 1) of the outer cylinder portion 22, and then the press-fitting portion 31 and the press-fitting portion 31 thereof. Insert the one end portion 5 in the longitudinal direction of the tube into which the tube is press-fitted. Finally, the connecting portion 46 of the union nut 13 is screwed into the male threaded portion 25 of the outer cylinder portion 22 and screwed to a predetermined position toward the joint body 11.

At the time of this screwing, in the present embodiment, the insertion portion 36 can be press-fitted into the groove portion 29 so that the first seal region 41 on which the sealing force acts in the radial direction is formed, and the seal is sealed. The union nut 13 is tightened so that the contact portion 37 can be pressed against the inner cylinder portion 23 so that the second seal region 42 on which the force acts in the axial direction is formed.

In addition, in the resin pipe joint 1, the joint body 11 and the inner ring 12 are made of different resin materials, and each has a property of shrinking with a change in atmospheric temperature. .. The radial shrinkage rate of the outer cylinder portion 22 of the joint body 11 is 0.09% or more larger than the radial shrinkage rate of the insertion portion 32 (particularly, the insertion portion 36) of the inner ring 12. It is set. That is, for the joint body 11, a resin material having a larger shrinkage rate after molding than the resin material used for the inner ring 12 is used.

Here, different resin materials mean not only that the resin names are different, but also that the resin names are the same but the resin grades are different. That is, different resin grades may have different MFR (melt fluidity) during molding, flex life (flexibility) after molding, etc. due to differences in molecular structure, molecular weight, crystallinity, etc. , There may be a difference in the shrinkage rate of the molded product. Therefore, even if different resin grade resin materials are used between the joint body 11 and the inner ring 12, a significant difference (a difference of 0.09% or more) can be caused in the shrinkage rates of the two. May be possible.

The joint body 11 and the inner ring 12 are each made of a predetermined resin material. Preferably, the joint body 11 and the inner ring 12 are each constructed by using a fluororesin material as in the present embodiment. Specific examples of the fluororesin material include PFA, PTFE, and ETFE.

The joint body 11 is heated when the ambient temperature (including the fluid temperature flowing inside the resin pipe fitting 1) rises by a predetermined value from around room temperature (about 25 ° C.), and the ambient temperature rises from that state to the room temperature. It is cooled by descending to the vicinity, and when such a temperature fluctuation occurs for the first time, the outer cylinder portion 22 can be contracted in the radial direction as compared with the initial portion.

The inner ring 12 is heated when the ambient temperature (including the fluid temperature flowing inside the resin pipe joint 1) rises by a predetermined value from around room temperature, and the ambient temperature drops from that state to around room temperature. When such a temperature fluctuation occurs for the first time, the insertion portion 32 can be contracted in the radial direction as compared with the initial portion.

Specifically, the joint body 11 and the inner ring 12, including the outer cylinder portion 22 and the insertion portion 32, are heat-applied during heating (when a predetermined amount of heat is applied due to a change in atmospheric temperature). It expands compared to before, and when it cools after that (when heat is taken away by a change in atmospheric temperature), it contracts more than it did at the beginning (before the first heat application).

Upon the contraction, the outer cylinder portion 22 of the joint body 11 is set to contract more in the radial direction than the insertion portion 32 of the inner ring 12.

As described above, the joint main body 11 and the inner ring 12 are made of different resin materials so that the radial shrinkage ratio of the outer cylinder portion 22 of the joint main body 11 and the insertion portion 32 of the inner ring 12 can be obtained. Although a difference in a predetermined range can be brought about with the shrinkage rate in the radial direction in the above, the difference between the shrinkage rates may be further increased by adjusting the presence or absence of heat treatment and the molding conditions. Specifically, only the inner ring 12 is heat-treated so that the shrinkage rate after temperature fluctuation becomes substantially zero (so that there is almost no shrinkage) so that the difference between the two shrinkage rates becomes even larger. You may.

The heat treatment here is, for example, for the purpose of removing internal strain from the molded product formed during the production of the inner ring 12, at a predetermined temperature for a predetermined time (for example, the material is PFA or PTFE). In the case of, heating is performed in the range of about 200 ° C. to about 250 ° C. for about 180 minutes, and when the material is ETFE, heating is performed in the range of about 120 ° C. to about 140 ° C. for about 180 minutes (annealing treatment).

Further, in the present embodiment, the difference between the radial contraction rate of the outer cylinder portion 22 of the joint body 11 and the radial contraction rate of the insertion portion 32 of the inner ring 12 is about 0.09% to about 10. It is set to a value within the range of%. Preferably, the difference in shrinkage between the two is set to a value in the range of about 0.09% to about 5%.

With such a configuration, in a state where the tube 2 is joined to the resin pipe joint 1, the joint body 11 and the union nut 13 are heated by heat transfer or the like from a fluid flowing inside them and then cooled. In this case (when a thermal cycle is applied), the outer cylinder portion 22 of the joint body 11 can be contracted in the radial direction more than the insertion portion 32 of the inner ring 12.

Therefore, when the heat cycle is performed, the outer cylinder portion 22 is deformed (reduced in diameter) so that the inner diameter thereof decreases by a large amount of change as compared with the outer diameter of the insertion portion 32, and the outer cylinder portion 22 is formed. Can be pressed against the insertion portion 32 which is radially superposed on the insertion portion 32.

Therefore, the sealing performance between the outer cylinder portion 22 of the joint body 11 and the insertion portion 32 of the inner ring 12 is good even after the resin pipe joint 1 is exposed to an environment higher than normal temperature. It can be improved so that it can be sustained. That is, it is possible to improve the sealing performance between the joint body 11 and the inner ring 12.

Further, in the present embodiment, as described above, the joint main body 11 has the main body tubular portion 21 and the outer tubular portion 22 coaxially projecting from the main body tubular portion 21 in one axial direction thereof. From the main body cylinder portion 21 so as to be arranged inward in the radial direction of the outer cylinder portion 22 and the protruding end portion 26 is located closer to the main body cylinder portion 21 than the protruding end portion 27 of the outer cylinder portion 22. The inner cylinder portion 23 is provided coaxially in the same direction as the outer cylinder portion 22, and the main body cylinder portion 21, the outer cylinder portion 22, and the inner cylinder portion 23 are opened so as to open in one axial direction. It has the groove 29 formed by being surrounded.

Then, when the inner ring 12 inserts at least a part of the insertion portion 32 and the press-fitting portion 31 into the outer cylinder portion 22, the first seal region 41 acting in the radial direction is the insertion portion 32 (the said). The insertion portion 32 (the insertion portion 36) is press-fitted into the groove portion 29 so as to be formed between the insertion portion 36) and the inner cylinder portion 23.

Therefore, when the outer cylinder portion 22 of the joint body 11 contracts through the heat cycle, the insertion portion 32 (the insertion portion 36) press-fitted into the groove portion 29 is inserted into the inner cylinder portion 23 by the outer cylinder portion 22. It becomes possible to press toward, and the pressure contact force between the insertion portion 32 and the inner cylinder portion 23 in the radial direction can be strengthened.

Therefore, the sealing performance of the first seal region 41 formed between the inner cylinder portion 23 of the joint body 11 and the insertion portion 32 (insertion portion 36) of the inner ring 12 is adjusted to the resin pipe joint. 1 can be improved so that it can be sustained well even after being exposed to an environment higher than normal temperature. As a result, the sealing performance between the joint body 11 and the inner ring 12 can be further improved.

The above-mentioned effects were confirmed by conducting a comparative experiment on the sealing performance. In this comparative experiment, first, Examples 1, 2, and 3 of the present invention are prepared, and the present invention relates to a joint body and an inner ring having the same structure as the resin pipe joint 1. Comparative Example 1, Comparative Example 2, and Comparative Example 3 having a difference in shrinkage rate different from those of the above were prepared.

Next, by raising the atmospheric temperature of Example 1, Example 2, Example 3, Comparative Example 1, Comparative Example 2, and Comparative Example 3 from room temperature to about 200 ° C., each is 1 at about 200 ° C. Heated for hours. Then, Example 1, Example 2, Example 3, Comparative Example 1, Comparative Example 2, and Comparative Example 3 were naturally cooled by lowering the ambient temperature from about 200 ° C. to room temperature.

In addition, this heating and natural cooling are in the state before each of Example 1, Example 2, Example 3, Comparative Example 1, Comparative Example 2, and Comparative Example 3 is joined to the tube (each joint body and the joint body). With the inner rings separated from each other and also separated from the joint body), each of Example 1, Example 2, Example 3, Comparative Example 1, Comparative Example 2, and Comparative Example 3 was carried out.

As shown in FIGS. 2 and 3, the joint main body of Example 1, Example 2, Example 3, Comparative Example 1, Comparative Example 2, and Comparative Example 3 before and after the temperature fluctuation (heating), respectively. Measure the inner diameter of the outer cylinder and the outer diameter of the inner ring insertion part, and calculate the radial shrinkage of the outer cylinder of the joint body and the radial shrinkage of the inner ring insertion part. did.

Then, as shown in FIG. 4, the difference in the contraction rate of the radial contraction rate in the outer cylinder portion of the joint body with respect to the radial contraction rate in the insertion portion of the inner ring was calculated.

Here, the first embodiment includes a joint body made of PFA and an inner ring made of ETFE. The radial shrinkage rate of the outer cylinder portion of the joint body is 0.09% higher than the radial shrinkage rate of the inner ring insertion portion.

The second embodiment includes a joint body made of PFA and an inner ring made of PTFE. The radial shrinkage rate of the outer cylinder portion of the joint body is 0.27% higher than the radial shrinkage rate of the inner ring insertion portion.

The third embodiment includes a joint body made of ETFE and an inner ring made of PTFE. The radial shrinkage rate of the outer cylinder portion of the joint body is 0.22% higher than the radial shrinkage rate of the inner ring insertion portion.

Comparative Example 1 includes a joint body made of PFA and an inner ring made of PFA. The radial contraction rate of the outer cylinder portion of the joint body is 0.22% lower than the radial contraction rate of the inner ring insertion portion.

Comparative Example 2 includes a joint body made of ETFE and an inner ring made of ETFE. Then, the radial shrinkage rate of the outer cylinder portion of the joint body has a difference of 0.05% or more with respect to the radial shrinkage rate of the inner ring insertion portion.

Comparative Example 3 includes a joint body made of PTFE and an inner ring made of PTFE. The radial shrinkage rate of the outer cylinder portion of the joint body is 0.04% higher than the radial contraction rate of the inner ring insertion portion.

Then, a tube made of PFA is joined to each of Example 1, Example 2, Example 3, Comparative Example 1, Comparative Example 2, and Comparative Example 3 so as to assemble the joint body and the inner ring. Then, a heat cycle (normal temperature → high temperature (about 200 ° C.) → normal temperature) was applied. Then, before and after applying the heat cycle, the leakage limit pressure ratio of the tube was measured.

The leakage limit pressure ratio of the tube here is the leakage limit pressure of the tube after every 0 to 5 heat cycles, and the leakage before the heat cycle (that is, when the number of heat cycles is O). It is compared with the limit pressure, and specifically, the leakage limit pressure of the tube after the heat cycle is divided by the leakage limit pressure of the tube before the heat cycle.

From the measurement results shown in FIG. 5, it was found that in Example 1 and Example 2, the leakage limit pressure ratio of the tube was larger than that in Comparative Example 1, Comparative Example 2, and Comparative Example 3. That is, according to the present invention, it has been clarified that the sealing performance of the resin pipe joint can be maintained satisfactorily even when the thermal cycle is repeatedly loaded.

In consideration of the above teachings, it is clear that the present invention can take many modified and modified forms. Therefore, it should be understood that the present invention may be practiced in a manner other than that described herein, within the scope of the appended claims.

1 Resin pipe fitting 2 Tube 5 One end of the tube in the longitudinal direction 11 Joint body 12 Inner ring 13 Union nut 22 Outer cylinder (cylinder)
31 Press-fitting part 32 Inserting part

Claims (4)

It is a method of joining a resin pipe joint and a tube.
The resin pipe fitting
A joint body with a cylinder and
An inner ring having an insertion portion that can be inserted into the cylinder portion so as to be in contact with the cylinder portion in the radial direction, and a press-fit portion that can be press-fitted to one end side in the longitudinal direction of the tube.
A union nut configured to be connectable to the joint body is provided so that the insertion portion can be held in the state of being inserted into the cylinder portion.
The joint body and the inner ring are molded from different resin materials among perfluoroalkoxy alkane resin (PFA), polytetrafluoroethylene (PTFE), and ethylene / tetrafluoroethylene copolymer (ETFE). ,
Only the inner ring was heated in the range of 200 degrees Celsius to 250 degrees Celsius when the resin material was PFA or PTFE, and in the range of 120 degrees Celsius to 140 degrees Celsius when it was ETFE . After that, by cooling, the radial shrinkage rate at the press-fitting portion of the inner ring is set to be smaller than the radial shrinkage rate at the tubular portion of the joint body.
The press-fitting portion of the inner ring is press-fitted into one end in the longitudinal direction of the tube.
The inner ring is inserted into the tubular portion of the joint body together with one end in the longitudinal direction of the tube.
A method of screwing the connecting portion of the union nut into the outer peripheral portion of the joint body so that one end portion in the longitudinal direction of the tube is sandwiched between the connecting portion of the union nut and the press-fitting portion of the inner ring. The method according to claim 1, wherein the radial shrinkage rate of the press-fitting portion of the inner ring is set to be 0.09% or more smaller than the radial shrinkage rate of the tubular portion of the joint body. The joint body
With the main body cylinder
An outer cylinder portion as the cylinder portion, which is coaxially projected from the main body cylinder portion in one axial direction thereof,
The same as the outer cylinder portion from the main body cylinder portion so that the outer cylinder portion is arranged inward in the radial direction and the protruding end portion is located closer to the main body cylinder portion than the protruding end portion of the outer cylinder portion. The inner cylinder part that protrudes coaxially in the direction,
It has a groove portion formed by being surrounded by the main body cylinder portion, the outer cylinder portion, and the inner cylinder portion so as to open in one direction in the axial direction.
When the inner ring insertion portion is inserted into the outer cylinder portion, the insertion portion is inserted into the groove portion so that a first seal region acting in the radial direction is formed between the insertion portion and the inner cylinder portion. Press into
The method according to claim 1 or 2 . It is a method of manufacturing resin pipe fittings.
The resin pipe fitting
A joint body with a cylinder and
An inner ring having an insertion portion that can be inserted into the cylinder portion so as to be in contact with the cylinder portion in the radial direction, and a press-fit portion that can be press-fitted to one end side in the longitudinal direction of the tube.
A union nut configured to be connectable to the joint body is provided so that the insertion portion can be held in the state of being inserted into the cylinder portion.
The joint body and the inner ring are molded from different resin materials among perfluoroalkoxy alkane resin (PFA), polytetrafluoroethylene (PTFE), and ethylene / tetrafluoroethylene copolymer (ETFE). ,
Only the inner ring was heated in the range of 200 degrees Celsius to 250 degrees Celsius when the resin material was PFA or PTFE, and in the range of 120 degrees Celsius to 140 degrees Celsius when it was ETFE . After that, a method of setting the radial shrinkage rate of the press-fitting portion of the inner ring to be smaller than the radial shrinkage rate of the tubular portion of the joint body by cooling.

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