JPH07293761A - Fluid coupling - Google Patents

Abstract

PURPOSE:To reduce the production of metallic impurities and particles, facilitate the mounting of parts and reduce the misses of assembly by making the end face of a body abut against the opposite side surface to the surface abutting against a pipe of a gasket to fasten a male screw of a body to a female screw of a cap nut with predetermined torque. CONSTITUTION:A pipe 5 is mounted on the inside of a first ferrule part 3. The end face part of the pipe 5 is beveled on the tip part and the tip end face 5b is finished into a mirror surface by roll vanishing. Also, the pipe 5 is provided on the peripheral surface with a groove 5a in which a sleeve 2 of a second ferrule part is fitted. An end face 6b is finished by roll vanishing. A male screw 6a of a body 6 formed on the outer periphery with the male screw 6a is fastened to a female screw 1a of a cap nut 1. The end face 6b of the body 6 abuts against the surface at the opposite side to the surface abutting against the pipe end face 5b of a gasket 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid coupling used in a gas supply device used in an industrial manufacturing apparatus such as a semiconductor manufacturing apparatus, and more particularly, to a device supplying a toxic gas. The present invention relates to a gas joint having a high degree of airtightness.

[0002]

2. Description of the Related Art Conventionally, in a semiconductor manufacturing process, thermal diffusion has been performed on a silicon base using a supertoxic gas such as silane, arsine, phosphine, or diborane as an impurity source. Pyrophoric gases are also used.
For example, the lethal dose of arsine is 0.5 ppm, and since a small amount of leakage causes personal injury, these gas pipes were connected by welding in principle to prevent leakage.

On the other hand, in the method of connecting pipes without using welding, the joint shown in FIG. 10 was used for piping of nontoxic gas such as compressed air. Pipes 5 and 7 are inserted into both ends of the through hole of the body 6. A male screw 6a is formed on the outer periphery of the body 6, and a female screw 1a formed inside the cap nut 1 is fastened to the male screw 6a. Large chamfers are formed at the entrances of the through holes of the body 6, and a sleeve 12 having a wedge-shaped cross section is fitted into the chamfers. A through hole is formed at the center of the sleeve 12 and is fitted with the pipes 5 and 7. On the bottom surface of the sleeve 12, a co-rotating seat brace 11 is in contact. The opposite end surface of the seat 11 is in contact with the inner end surface of the cap nut 1. A through hole is formed in the center of the sleeve 12,
Fitted with pipes 5 and 7. In the joint having such a configuration, when the cap nut 1 is screwed into the body 6 with a predetermined torque, the sleeve 12 is pressed inward by the body 6 and comes into close contact with the outer circumferences of the pipes 5, 7, Transform. As a result, the close contact between the outer peripheral surfaces of the pipes 5 and 7 and the inner surface of the sleeve 12 and the close contact between the outer peripheral surface of the sleeve 12 and the inner surface of the chamfered portion of the body 6 are secured, and the airtightness of the joint is secured.

However, the joint shown in FIG. 10 has the following problems. (1) The airtightness is not sufficient and it is dangerous to use it for piping of toxic gas. (2) When removing the pipes 5 and 7, the body 6
Since it cannot be removed unless it is removed from the pipe, it is wasteful because it is necessary to provide an extra relief part in the pipe. (3) Since the pipe is crushed and deformed once it is fastened, the airtightness becomes poor when it is detached and reassembled. In spite of the above problems, it is necessary to use a joint when connecting to a valve, so the joint shown in FIG. 11 is used with great care in a semiconductor manufacturing process that handles toxic gases and the like. There is.

On the other hand, in recent years, as a means for solving the above problems, a joint disclosed in Japanese Patent Publication No. 2-46830 which can maintain high airtightness is used. here,
In this joint, since the sleeve used has a special shape, the sleeve and the pipe for piping were connected by welding. However, when a toxic gas is used as an impurity source used for heat diffusion, there is the following problem when the pipes are connected by welding. (1) Floating elements are generated by welding and are mixed into the wafer as metal impurities, and the reliability of the device is impaired.

(2) Most of the gas as an impurity source has corrosiveness, and the pipe is usually made of SUS material. However, the material of the welded portion is changed by welding and is easily corroded. Therefore, particles are generated, and the defective product rate due to pattern defects increases. (3) Welding of SUS pipe requires a skilled technique, and it is not easy to secure a skilled welding operator in the construction of semiconductor manufacturing process. In order to solve these problems, the applicant of the present invention has disclosed in
A new fluid coupling has been proposed in Japanese Patent Application Laid-Open No. 312283 and Japanese Patent Application Laid-Open No. 5-31284.

[0007]

However, the above-mentioned Japanese Unexamined Patent Application Publication No.
The fluid couplings disclosed in Japanese Patent Laid-Open No. 312128/1993 and Japanese Patent Laid-Open No. 5-31284 have the following problems. That is, since many parts are attached, it may happen that the user forgets to install the parts. Even if a toxic gas is used, after assembling, the test is performed by flowing an inert gas, so there is no concern for the human body, but reassembly is required, which is inefficient. Further, since the sleeve that fits into the groove of the pipe and constitutes the ferrule has a structure with one slit for mounting the sleeve on the pipe, the thrust of the sleeve is transmitted to the ferrule evenly. No
There was a risk of non-uniformity in the gasket seal. In addition, in the semiconductor process where the fluid coupling is installed, many pipes are arranged in close contact with each other, and a spanner is fitted to the outer circumference of the cap nut to tighten the cap nut with screws, as in the conventional case. The work was difficult, and it took a lot of time to remove and install the cap nut.

An object of the present invention is to solve the above problems and to provide a fluid coupling used in a semiconductor manufacturing process or the like in which generation of metal impurities and particles is small, mounting is easy, and assembly errors are small. To do.

[0009]

In order to achieve this object, the fluid coupling of the present invention has the following construction. (1) A cap nut having an internal thread formed on the inside, a pipe having a mirror-finished surface on the end surface and a groove on the outer circumference,
On the end face side having a trapezoidal cross section and a large area, the first ferrule part in which co-rotation preventing means for integrally preventing the co-rotation between the cap nut and the pipe by contacting with the inner end face of the cap nut is formed, The second ferrule part, which is fitted in the groove on the outer circumference and has a wedge-shaped cross section and a small area, is located on the co-rotation preventing means side, is fitted to the end of the pipe, and the entire circumference of the end face of the pipe is in contact. It is equipped with a gasket and a body that has a mirror-finished surface on the end face and an external thread formed on the outer circumference.The end surface of the body abuts the surface of the gasket opposite to the surface abutting the pipe and The female screw of the cap nut is fastened with a predetermined torque.

(2) A cap nut having an internal thread formed on the inside, a first pipe having a mirror-finished surface on the end face and a groove formed on the outer periphery, and an end face side having a trapezoidal cross section and a large area. A first pipe first ferrule part integrally formed with a first pipe co-rotation preventing means that comes into contact with the inner end surface of the cap nut and prevents co-rotation of the cap nut and the first pipe,
The second ferrule part for the first pipe, which is fitted in the groove on the outer periphery of the first pipe, has a wedge-shaped cross section, and has a small end surface located on the side of the first pipe co-rotation preventing means, and a male screw on the outer periphery. The formed body, the second pipe having a mirror-finished surface on the end face and the groove formed on the outer periphery, and the end face side having a trapezoidal cross section and a large area, contacting the end face of the body and the cap nut and the second A second pipe first ferrule part integrally formed with a second pipe co-rotation preventing means for preventing co-rotation with the pipe and a second pipe outer peripheral groove, and having a wedge-shaped cross section, The second pipe second ferrule part whose end face having a small area is located on the side of the second pipe co-rotation preventing means, and the first pipe or the end of the second pipe is fitted to the first pipe end face and the second pipe. Gasket where the entire circumference of the end face contacts from both sides And a female screw of the male screw and the cap nut body is fastened with a predetermined torque.

(3) The fluid coupling described in (1) or (2) above, wherein the second ferrule part has two or more grooves evenly arranged on the outer circumference. (4) The fluid coupling according to (1) or (2) above, characterized in that two or more spanner holes are formed in the end surface of the cap nut.

[0012]

The assembling method of the present invention having the above construction will be described. The pipe with the second ferrule part and the gasket attached is inserted into the cap nut on which the first ferrule part is attached, and the cap nut is screwed into the body.
At this time, the inner diameter of the second ferrule part is the same as the outer diameter of the pipe, but the inner diameter of the second ferrule part is expanded by elastic deformation due to the two or more grooves evenly arranged on the outer circumference to fit the outer groove of the pipe. Are combined. With the body fixed so that it does not turn, screw in the cap nut until it reaches the specified torque.

When screwing the cap nut into the body,
The thrust is transmitted to the pipe by the first ferrule part and the second ferrule part. At this time, the thrust bearing formed on the first ferrule part prevents the cap nut and the pipe from rotating together. Further, since the pipe is positioned with respect to the cap nut by the first ferrule part and the second ferrule part, the end surface of the pipe and the end surface of the body are accurately aligned. Here, the end surface of the pipe and the end surface of the body are mirror-finished by roller burnishing, improving the adhesion between each and the gasket,
The tightness of the joint is increased.

The Vickers hardness of the SUS material is about 180, but by roller burnishing,
Vickers hardness can be about 300. Thus, even if the pipe end surface and the body end surface are pressed against the gasket by a strong pressing force, the pipe end surface and the body end surface are not deformed, so that the pipe can be repeatedly used. The gasket is pressed from both sides by the end face of the pipe and the end face of the body. The gasket is made of soft metal, and is pressed against the end surface of the pipe and the end surface of the body, which have high hardness, so that each of them can adhere well. At this time, since the grooves of the second ferrule part are formed evenly on the outer circumference, the thrust of the second ferrule part acts uniformly on the first ferrule part, so that the pipe end surface is pressed by the gasket with a uniform force, There is no risk of leakage in the gasket. Also, if you remove the cap nut,
You can easily disconnect by simply sliding the pipe to the side. Further, when the cap nut is screwed in, the protrusion of the spanner is engaged with the spanner hole formed in the end surface of the cap nut so that the cap nut can be screwed in. Therefore, the cap nut can be screwed in easily even in a narrow space. Further, since the torque can be transmitted uniformly, the sealing force can be stabilized.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A fluid coupling which is an embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows a sectional view of an embodiment in which pipes are connected to both ends of a body. Further, the configuration of the main parts of the joint is shown in an exploded perspective view in FIG.
FIG. 8 is a sectional view showing the structure of the first ferrule part 3 in which the thrust ball bearing 9 is integrally formed at one end. The rotary wheel 10 of the thrust ball bearing 9 is extended in a direction parallel to the shaft, and an inclined surface 10a is formed on the extended inner surface of the rotary wheel 10. The first ferrule part 3 is fitted to the inner end surface of the cap nut 1 having the internal thread 1a formed therein in the direction in which the fixed ring of the thrust ball bearing 9 abuts. Here, as shown in the sectional view (a) and the side view (b) in FIG. 5, the spanner holes 31 are formed in the end surface of the cap nut 1 at six intervals on the circumference.

A pipe 5 is attached to the inside of the first ferrule part 3. As shown in FIG. 7, the end surface of the pipe 5 is chamfered at the tip, and the tip end surface 5b is mirror-finished by roll burnishing. A groove 5a is cut on the peripheral surface of the pipe 5. The sleeve 2 which is the second ferrule part shown in FIG. 9 is fitted in the groove 5a. 9A shows a plan view and FIG. 9B shows a side view. The wedge-shaped inclination of the sleeve 2 constitutes the same angle as the inclination of the inner surface of the first ferrule part. Six grooves 2 are formed on the outer circumference of the sleeve 2 at equal intervals of 60 degrees.
a is formed. The outer wall 2b formed between the groove 2a and the inner diameter has a thickness of 0.15 mm. The sleeve 2 has a wedge-shaped cross section and an end surface having a small area is located on the thrust ball bearing 9 side. The first ferrule 3 part and the sleeve 2 are fitted together to form a ferrule.

The inner surface is fitted to the end portion of the pipe 5, and the inner end surface is in contact with the entire circumference of the pipe end surface 5b, so that the gasket 4 is attached. Further, the end surface 6b is roll burnished, and the male screw 6a of the body 6 having the male screw 6a formed on the outer periphery is fastened to the female screw 1a of the cap nut 1. The end surface 6b of the body 6 is in contact with the surface of the gasket 4 opposite to the surface with which the pipe end surface 5b is in contact. Since the mounting structure of the pipe 7 on the opposite side is the same as that of the pipe 5, the description thereof will be omitted.

Next, the operation of the fluid coupling having the above structure will be described. The connecting pipes 5 and 7 are cut to a length to be actually used, the end faces are chamfered, and then the roller burnishing process is performed. The roll burnishing finish can be easily processed by a portable roll burnishing finisher or the like. The mirror finish by roller burnishing improves the adhesion between the pipe end surface 5b and the gasket 4 and improves the airtightness of the joint. The Vickers hardness of the SUS material is about 180, but the Vickers hardness can be set to about 300 by roller burnishing.
Thus, even if the pipe end surface 5b is pressed against the gasket by a strong pressing force, the pipe end surface 5b is not deformed, so that it can be repeatedly used.

A groove 5a shown in FIG. 7 is formed on the peripheral surface of the pipe 5.
Is cut by lathe processing. Thus, if there is a lathe or the like, the pipe itself that needs to be connected can be easily processed on the spot. The sleeve 2 is attached to the groove 5 a of the pipe 5. At this time, the outer diameter of the pipe 5 and the inner diameter of the sleeve 2 are substantially the same, but six grooves 2a are formed on the outer circumference of the sleeve 2 at equal intervals, and the outer wall 2b has a thin thickness of 0.15 mm. Therefore, since the outer wall 2b is elastically deformed, the sleeve 2 can be easily mounted in the groove 5a. The first ferrule part 3 is mounted so as to fit the inclination of the outer surface of the sleeve 2. Further, the gasket 4 is fitted to the end of the pipe 5.

With the sleeve 2 and the gasket 4 attached, the pipes 5 and 7 are inserted into the cap nut 1 on which the first ferrule part 3 is attached, and the cap nut 1 is attached to the body 6
Screw into. Here, as the spanner 40, the one shown in FIG. 6 is used. The spanner 40 includes a spanner body 33 and a handle 32. The wrench body 33 is formed with four protrusions 34 corresponding to the wrench hole 31 of the cap nut 1, and the escape portion 3 for escaping the pipe is formed in the center.
8 is formed. By engaging the protrusion 34 of the wrench 40 with the wrench hole 31 of the cap nut 1 and rotating the handle 32, the cap nut 1 can be screwed into the body 6. Here, since the wrench 40 can be engaged with and screwed into the wrench hole formed in the end surface of the cap nut 1, it is possible to easily screw in even if there is an obstacle in the surroundings. .

Further, with the body 6 fixed so as not to rotate, the cap nut 1 is screwed in until a predetermined torque is reached. The propulsive force when screwing the cap nut 1 into the body 6 is transmitted to the pipes 5 and 7 via the sleeve 2 and the first ferrule part 3. That is, the sleeve 2 forming the ferrule has the groove 5 formed on the outer circumference of the pipe.
Since the propulsive force is transmitted to the first ferrule component 3 by the sleeve 2 by the action of the wedge, the first ferrule component 3 can transmit the strong propulsive force to the pipe. Here, since the wrench 40 is engaged with and screwed into the wrench hole formed in the end surface of the cap nut 1, the torque can be evenly transmitted to the cap nut 1, so that the first ferrule is provided. The propulsive force transmitted to the component 3 can be constant. Further, since the pipe 5 is positioned with respect to the cap nut 1 by the first ferrule part 3 and the sleeve 2, the end surface 5b of the pipe and the end surface 6b of the body 6 are accurately aligned. Here, the body end surface 6b is mirror-finished by roller burnishing, the adhesion between the body end surface 6b and the gasket 4 is improved, and the airtightness of the joint is improved.

The Vickers hardness of the SUS material is about 180. However, by roller burnishing,
Vickers hardness can be about 300. With this, even if the body end surface 6b is pressed against the gasket by a strong pressing force, the body end surface 6b is not deformed, and thus it can be repeatedly used. The gasket 4 is pressed from both sides by the end surface 5b of the pipe and the end surface 6b of the body 6. The gasket 4 is made of nickel in this embodiment,
The end surface 5b of the pipe having a high hardness and the end surface 6b of the body 6 are pressed so that they can be in close contact with each other. The gasket 4 will be deformed once assembled, so when reassembling, replace it with a new gasket 4. Since the position of the gasket 4 of this embodiment is determined only by fitting it to the pipe 5, the gasket 4 can be replaced very easily. Cap nut 1 to body 6
Since the first ferrule part 3 is mounted when screwed in, the pipe 5 is prevented from co-rotating with the cap nut 1. Therefore, between the pipe end surface 5b and the gasket 4 or between the gasket 4 and the body. No rubbing occurs between the end surface 6b and particles do not occur.

According to the fluid coupling having the above-mentioned structure, the first ferrule part 3 and the sleeve 2 can be easily attached to the ordinary pipe by a simple additional process, so that the pipe can be welded without welding. They can be connected to each other in a highly airtight state. Further, if the cap nut 1 is removed, the connection can be easily released simply by sliding the pipe 5 laterally, so that it is not necessary to provide extra relief in the pipe, and the cost can be reduced. Further, since the thrust ball bearing 9 is formed at one end of the first ferrule part 3, the number of parts can be reduced and troubles due to forgetting to attach parts can be reduced. Further, since the six grooves 21 provided on the outer circumference of the sleeve 2 are evenly arranged on the circumference, the thrust of the sleeve 2 can be evenly transmitted to the first ferrule part 3, and the gasket 4 Can improve the adhesion.

Further, since the pipe end surface 5b and the body end surface 6b are finished by the roller burnishing process, the adhesion with the gasket 4 is good and the fluid coupling can be constructed with high airtightness. Further, since the pipe end surface 5b and the body end surface 6b have high hardness, the gasket 4 is only deformed, so that the gasket 4 can be repeatedly used only by replacing it.

Next, a second embodiment will be described with reference to the sectional view shown in FIG. 2 and the exploded perspective view shown in FIG. The second embodiment is a fluid coupling that uses one cap nut to connect a set of pipes. The thrust ball bearing 9 is provided on the inner end surface of the cap nut 1 having the female screw 1a formed therein.
The first ferrule part 3a is fitted so that the a contacts. Here, as shown in the sectional view (a) and the side view (b) of FIG. 5, the end face of the cap nut 1 has a spanner hole 3
Six 1s are formed on the circumference at equal intervals. A pipe 5, which is a first pipe, is attached to the inside of the first ferrule part 3a. As shown in FIG. 4, the end surface of the pipe 5 is chamfered at the tip, and the tip end surface 5b is mirror-finished by roll burnishing. Also, pipe 5
A groove 5a is cut on the peripheral surface of the. The groove 5a has six grooves in the longitudinal direction and has a wedge-shaped cross section.
a is fitted. A first ferrule part 3a having the same inclination as the wedge-shaped inclination of the sleeve 2a on the inner surface is fitted with the sleeve 2a. The first ferrule part 3a and the sleeve 2a are fitted to each other to form a ferrule. The sleeve 2a has a wedge-shaped cross section and an end surface having a small area is located on the thrust ball bearing 9a side.

The inner surface is fitted to the end portion of the pipe 5, and the inner end surface is in contact with the entire circumference of the pipe end surface 5b, and the gasket 4 is attached. Inside the cap nut 1, a pipe 7 that is a second pipe having a roll burnished surface on its end face is attached. The end surface portion of the pipe 7 is mirror-finished by roll burnishing similarly to the pipe end surface 5b.

A groove 7a is cut on the peripheral surface of the pipe 7. The groove 7a has six grooves in the longitudinal direction,
A sleeve 2b having a wedge-shaped cross section is fitted. The first ferrule part 3b having the same inclination as the wedge-shaped inclination of the sleeve 2b on the inner surface is fitted to the sleeve 2b. The first ferrule part 3b and the sleeve 2b are fitted together to form a ferrule. The sleeve 2b has a wedge-shaped cross section and a small end surface located on the thrust ball bearing 9b side. The first ferrule part 3b is attached so that the end surface having a trapezoidal cross section and a large area contacts the thrust ball bearing 9b. The thrust ball bearing 9b is in contact with the end surface of the body 8 having an external thread 8a formed on the outer periphery thereof.

Next, the operation of the second embodiment will be described. With the body 8 fixed so as not to rotate, the cap nut 1 is screwed in until a predetermined torque is reached. Here, as the spanner 40, the one shown in FIG. 6 is used. The spanner 40 includes a spanner body 33 and a handle 32. In the wrench body 33, four protrusions 34 corresponding to the wrench hole 31 of the cap nut 1 are formed,
An escape portion 38 for escaping the pipe is formed in the center. The protrusion 34 of the wrench 40 is fitted with the wrench hole 3 of the cap nut 1.
By engaging 1 and rotating the handle 32,
The cap nut 1 can be screwed into the body 6. The propulsive force when screwing the cap nut 1 into the body 6 is transmitted to the pipes 5 and 7 via each ferrule. Since the sleeves 2a and 2b forming the ferrule are fitted in the grooves 5a and 7a formed on the outer circumference of the pipe, the ferrule can transmit a strong propulsive force to the pipe.

At this time, since the pipes 5 and 7 are positioned by the ferrule with respect to the cap nut 1, the end surface 5b of the first pipe and the end surface 7b of the second pipe are accurately aligned. Further, a pair of pipes 5 and 7 are butted against each other with the gasket 4 in between and pressed. Pipe end face 5
Both b and 7b are roller burnished, and the nickel gasket 4 is deformed so that the pipe end faces 5b and 7b are deformed.
Since it comes into close contact with b, airtightness is improved.

According to the above embodiment, since the airtightness is high, there is no danger even when a highly toxic gas is used in the semiconductor manufacturing process. Also, if you remove the cap nut, you can easily remove the pipe just by sliding it sideways,
Easy to maintain. Further, since the thrust ball bearings 9a, 9b are formed at one end of the first ferrule parts 3a, 3b, the number of parts can be reduced and troubles due to forgetting to attach parts can be reduced. In addition, the six grooves 2 provided on the outer circumference of the sleeves 2a and 2b
1 are evenly arranged on the circumference, so that the sleeve 2
The thrusts of a and 2b can be evenly transmitted to the first ferrule parts 3a and 3b, and the adhesion at the gasket 4 can be improved. Further, since the wrench 40 can be screwed by engaging with the wrench hole formed in the end surface of the cap nut 1, it can be easily screwed in even when there is an obstacle in the surroundings. . Further, since the wrench 40 is engaged with and screwed into the wrench hole formed in the end surface of the cap nut 1, torque can be evenly transmitted to the cap nut 1, so that the first ferrule part. The propulsive force transmitted to 3 can be made constant, and the sealing force can be stabilized.

[0031]

As is apparent from the above description, according to the fluid coupling of the present invention, the first ferrule part and the second ferrule part can be easily attached to the ordinary pipe by simply performing additional machining. Since it is possible to connect pipes in a highly airtight state without welding, floating elements are generated by welding, and they are mixed into the wafer as metal impurities, impairing device reliability. Moreover, since the thrust bearing is formed at one end of the first ferrule part, the number of parts is reduced, and troubles such as forgetting to attach parts can be reduced.

Further, since the plurality of grooves provided on the outer circumference of the second ferrule part are evenly arranged on the circumference, the thrust of the second ferrule part is uniformly transmitted to the first ferrule part. As a result, the adhesion with the gasket can be improved and the airtightness can be improved. In addition, since the material is not changed by welding, particles are not generated and the defective product rate due to pattern defects is reduced. Also,
Easy to assemble, for semiconductor manufacturing process construction, etc.
A skilled welding operator is not required, and construction can be performed efficiently. Further, if the cap nut is removed, the connection can be easily released simply by sliding the pipe laterally, so that it is not necessary to provide extra relief in the pipe, and the cost can be reduced.

[Brief description of drawings]

FIG. 1 is a sectional view showing a configuration of a fluid coupling which is a first embodiment of the present invention.

FIG. 2 is a sectional view showing a structure of a fluid coupling which is a second embodiment of the present invention.

FIG. 3 is an exploded perspective view showing a configuration of a main part of the first embodiment.

FIG. 4 is an exploded perspective view showing the configuration of the main part of the second embodiment.

FIG. 5 is a view showing a shape of a cap nut.

FIG. 6 is an external view showing the shape of a spanner for a cap nut.

FIG. 7 is a cross-sectional view of a pipe end portion.

FIG. 8 is a sectional view showing a configuration of a first ferrule part.

9A and 9B are a plan view and a side view showing a configuration of a sleeve.

FIG. 10 is a sectional view showing a configuration of a conventional fluid coupling.

[Explanation of symbols]

 1 Cap Nut 2 Sleeve 3 First Ferrule Part 4 Gasket 5,7 Pipe 6,8 Body 9 Thrust Bearing 31 Hole for Spanner

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor's view Yuichi Inside the Toshiba Research Institute, 1 Komukai Toshiba-cho, Kouki-ku, Kawasaki-shi, Kanagawa

Claims (4)

[Claims] 1. A cap nut having an internal thread formed inside, a pipe having a mirror-finished surface formed at an end face and a groove formed at an outer periphery, and the bag having an end face having a trapezoidal cross section and a large area. A first ferrule part in which a co-rotation preventing means for preventing co-rotation between the cap nut and the pipe is formed integrally with the inner end surface of the nut, and the first ferrule part is fitted into the groove on the outer periphery of the pipe and has a cross section. A second ferrule part having a wedge shape and an end surface having a small area on the side of the co-rotation preventing means, a gasket fitted to the end portion of the pipe, and the entire circumference of the pipe end surface abutting, and a mirror finish on the end surface A body having a surface and a male thread formed on the outer periphery thereof, the end surface of the body abutting a surface of the gasket opposite to the surface abutting the pipe, the male screw of the body and the bag. The female thread of the nut A fluid coupling characterized by being fastened with a predetermined torque. 2. A cap nut having a female screw formed on the inside, a first pipe having a mirror-finished surface on the end face and a groove formed on the outer periphery, and an end face having a trapezoidal cross section and a large area, A first ferrule part for a first pipe, which is integrally formed with a first pipe co-rotation preventing means that abuts on an inner end surface of the cap nut and prevents co-rotation of the cap nut and the first pipe; A second ferrule part for the first pipe, which is fitted in the groove on the outer periphery of the one pipe, has an end face having a wedge-shaped cross section and a small area, which is located on the side of the first pipe co-rotation preventing means, and a male screw on the outer periphery. A second pipe with a mirror-finished surface on the end face and a groove on the outer periphery; and a cap pipe that abuts the end face of the body on the end face side with a trapezoidal cross section and a large area. And co-rotation with the second pipe A second pipe first ferrule part integrally formed with a second pipe co-rotation preventing means, and an end face having a wedge-shaped cross section and a small area, which is fitted in the groove on the outer periphery of the second pipe. A second ferrule part for a second pipe located on the side of the second pipe co-rotation preventing means, and fitted to an end of the first pipe or the second pipe, the first pipe end surface and the second pipe A fluid coupling, comprising: a gasket with which the entire circumference of the end face abuts from both sides, and a male screw of the body and a female screw of the cap nut are fastened with a predetermined torque. 3. The fluid coupling according to claim 1 or 2, wherein the second ferrule part is evenly arranged on the outer circumference.
A fluid coupling having the above groove. 4. The fluid coupling according to claim 1 or 2, wherein two or more spanner holes are formed in the end surface of the cap nut.