KR930001149Y1 - Pipe coupling - Google Patents

Abstract

No content.

Description

Low Temperature Pipe Fittings

1, 2, and 3 show an embodiment of the present invention, and FIG. 1 is a partially sectional side view showing the socket and the plug separately.

2 is a partial end side view showing the connection of a socket and a plug.

3 is a longitudinal sectional side view of the main portion of the socket to enlarge the fixing state of the sealing ring for end face sealing and the sealing ring for outer circumference sealing.

Figure 4 is a longitudinal side view showing a conventional general two-way opening and closing pipe connection mechanism.

* Explanation of symbols for main parts of the drawings

1: socket 2: plug

3: socket body 9, 34: sliding valve

11: operation sleeve 12: fastener

19: slope 20: outer groove

27: sealing ring for end face sealing 28: sealing ring for outer peripheral sealing

32: plug body 25: fish face

This invention relates to a low temperature pipe fitting, in particular a pipe fitting suitable for the connection of low temperature fluid pipes.

It is essential that the pipe connecting device for connecting the fluid pipes does not cause fluid leakage during use.

As a pipe connection mechanism provided with this summary, the same thing as that of FIG. 4 is mentioned, for example.

In the conventionally used connection mechanism, a seal ring such as an O-ring 44 is provided where necessary to prevent fluid leakage, but the sealing structure cannot be counted.

However, the structure is limited to the one using a rubber O ring or a metal triangular ring anyway. However, in FIG. 4, the outer circumference of the plug is defined by the O ring 44. This is just to seal the socket (1) and the plug (2) between.

In the conventional pipe joint mechanism, there are many kinds of materials for forming plugs and sockets. However, the O-ring sealing the outer circumferential surface of the plug differs from that of the metallic material when used in extreme locations or under extremely low temperatures. There is a problem that the sealing effect is remarkably lowered due to the decrease in the diameter of the wire or the radius of the wire, and the general material such as rubber is not able to withstand the use due to the remarkable decrease in strength.

The present invention has been made to solve such a problem, and an object of the present invention is to provide a low-temperature pipe connecting device that can completely prevent fluid leakage even when used in an ultra low temperature fluid pipe or under an ultra low temperature environment.

The pipe connecting mechanism according to the present invention is an inclined surface for fixing fixtures for monolithically supporting a force for pressing the plug socket recess in the axial direction to an inner circumferential surface of an operation sleeve mounted to an outer circumferential surface of a socket as a means for solving the above problems. And a cross section of the fixture, the inclined pressing surface, and the outer peripheral surface of the plug form a fastening mechanism by a reversed outer circumferential groove, the sealing ring sealing the joint surface of the socket and the plug, and the circumferential direction of the socket and the plug. The sealing ring which seals a joint surface is formed as a cold-resistant material.

The seal ring for end surface sealing is U-shaped in cross section, and the side seal surface is fixed to the surface perpendicular to the axis center in the fluid passage of the socket, and the seal ring for outer circumference sealing is U-shaped in cross section, and the opening of the groove is Is fixed inside the socket in the same direction as the axial direction of the fluid passage.

The pipe connecting mechanism of the present invention adopts a structure that seals the end face and the outer circumferential surface of the plug fitted into the socket by using at least two seal rings having the same or approximate U-shape in cross-sectional shape. By forming the fixture pressing surface of the sleeve to be inclined to the inclined surface, the fixture is elastically supported at all times in the centripetal direction, and the elastic support force is transmitted to the inclined wall surface of the plug's opposite circumferential groove through the fixture to direct the plug toward the fluid passage of the socket. Pressure That is, the force that presses the plug into the socket is always applied to the plug.

When the pressure in the axial direction is applied to the plug in this way, even if the radiuses of the seals for end face sealing and the seals for outer circumferential sealing shrink in the radial direction due to low temperature, the sealing performance of the U-shaped seals in the cross section is not deteriorated. Leakage does not occur.

1 to 3 is a partial longitudinal cross-sectional side view showing an embodiment of the present invention in a two-way opening and closing type pipe connecting mechanism.

The socket 1 and the plug 2, shown as mutually separated states in FIG. 1, form a pair, and the socket 2 is screwed into the socket outer cylinder 5 and the socket outer cylinder having a joint 4 with the plug 2; The combined adapter 6 constitutes a socket body 3, which has a fluid passage 7 at its axial center, which is elastically supported by a spring 8 in the fluid passage 7. It has a sliding valve (9).

In addition, the socket body 3 has an operation sleeve 11 elastically supported in the axial direction by the compression spring 10 on the outer circumferential surface thereof, and a fastener 12 pressed on the inner circumferential surface of the operation sleeve 11.

The socket body 3 is formed of a cold-resistant material, for example, aluminum or fluorine resin having a high breaking strength at low temperature.

The sliding valve 9 provided in the fluid passage 7 is formed as a cold-resistant material similarly to the socket body 3, and is formed in a cylindrical shape, and the fluid passage 14 closes the valve head 13 in the centripetal direction. It penetrates toward the side.

The sliding valve (9) has a valve head (16) protruding the valve pressure portion (15) on the front face thereof and formed in the shape of a cone, and the valve seat (16) provided on the inner circumferential surface of the fluid passage (7) of the socket body (3). When the socket 1 and the plug 2 are separated from each other, they are strongly pressed against the valve seat 16.

The sliding valve (9) is axially oriented in the fluid passage (7) of the socket body (3) by a spring (8) and a spring (8) mounted to the stop ring (17) inside the socket body (3). It is mounted so that it can slide.

The operation sleeve 11 is formed in a cylindrical shape, and an inclined surface 19 for pressing the fixing tool 12 in the centripetal direction at one opening end on the inner surface side thereof is provided over the entire circumference.

This inclined surface 19 is gentler than the inclination angle of the opposite outer circumferential groove 20 of the plug 2 in order to prevent the escape of the fastener 12 and to increase the pressing force in the axial direction of the plug 2. Good to do.

However, in the drawings, the inclination angle of the inclined surface 19 is set to 45 ° in accordance with the inclination angle of the counter-circumferential outer circumferential groove 20 for easy understanding.

A large diameter space portion 22 is provided in the other opening portion on the inner circumferential surface side of the sleeve 11 for operation through a spring support end portion 21, and a compression spring 10 is provided in the large diameter space portion 22 to provide a compression spring. As a function of (10), the fastener 12 is joined to the inclined surface 23 of the outer circumferential groove 20 of the plug 2 through the inclined surface 19.

The operation sleeve 11 is prevented from falling off by the stopper 25 fixed to the socket body 3 as the snap ring 24.

In addition, the fastener 12 is larger in diameter than the conventional fastener.

That is, if the diameter is larger than the dimension of the depth of the tapered ball hole 26 and the depth of the outer circumferential groove 20 of the plug 2 provided through the socket body 3, the socket ( When 1) and plug 2 are in the connected state, the fixture 12 protrudes largely on the outer circumferential surface of the socket body 3 so as to be sufficiently pressed by the inclined surface 19 of the operation sleeve 11.

(27) is a U-shaped seal ring in the cross section, and (28) is a U-shaped seal ring in the same manner, and is a sealing ring having excellent cold resistance, chemical resistance, etc., which are all made of fluorine resin. The sealing seal ring 27 for sealing is fitted to the fluid passage 14 of the socket main body 3 with both sides facing in the axial direction, and is provided such that both sides act as a sealing surface.

As a result, the collar 29 and the stop ring 30 are fixed to the socket body 3, and one side surface is in surface contact with a surface perpendicular to the axis center provided in the fluid passage of the socket body 3.

In addition, the seal ring 28 for outer circumference sealing is formed in a U-shaped cross section in a direction sealing the inner circumferential surface of the socket body and the outer circumferential surface of the plug 2, respectively, and the outer circumferential surface is in surface contact with the tube wall surface of the socket body 3. The flange 31 provided in the one end surface of the direction toward the centrifugal direction is firmly fitted by the socket outer cylinder 5 and the adapter 6.

The plug 2 has a fluid passage 33 and a sliding valve 34 at the shaft center of the plug body 32.

At the distal end of the plug body 32, a seal surface 35 which is in surface contact with the seal ring 27 for end face sealing is provided perpendicular to the axis of the fluid passage.

On the outer circumferential surface of the plug main body 32, inclined surfaces 23 and 36 are formed to face the symmetrical face of the above-described large outer circumferential groove 20 to be engaged with the fastener 12.

The sliding valve 34 has a valve pressure portion 37 for pressing the sliding valve 9 of the socket (1) shaft on the front side, and a plurality of fluid passages 38 are provided on the side surface like the sliding valve 9. The valve head 39 is axially pressed by the spring seat 41 and the compression spring 42 fixed as the stop ring 40 so as to be adjacent to the valve seat 43 and the fluid passage of the plug body 32. It is supposed to close.

Next, the operation of the embodiment configured as described above will be described.

When connecting the socket 1 and the plug 2, the sleeve 11 for operation of the socket 1 is operated in the first direction to the left against the compression spring 10, and is inclined to the fixture 122 in the centripetal direction. Relieve the pressure.

Here, when the tip of the plug 2 is inserted into the junction 4 of the socket 11, the outer peripheral surface of the plug 1 is first joined to the inner peripheral surface of the sealing ring 28 for outer circumference sealing, so that the outer peripheral surface of the plug 2 is sealed. Sealed by a ring 28.

When the plug 2 is inserted deeply into the socket 1 in this state, the valve pressure portion 37 of the sliding valve is joined to the valve pressure portion 15 of the sliding valve 9, and the sliding valve 9 and The sliding valve 34 is pushed back to each other and separated from the valve seats 16 and 43 so that the fluid passages 14 and 38 of the socket 1 and the plug 2 are connected together.

The operating sleeve 11 when the plug 2 is fully inserted into the socket 1 and the seal face 35 at the tip of the plug 2 contacts the sealing ring 27 for end face sealing and comes into surface contact. When the hand touches the sleeve 11, the operation sleeve 11 is sequentially advanced by the elastic force of the compression spring 10, and presses the fixture 12 in the centripetal direction on the inclined surface 19 installed on the inner surface of the tip. Engage with the outer circumferential groove 20 of the plug 2.

At this time, there is a gap between the inner circumferential slope 45 of the socket (1) and the outer circumferential slope (46) of the plug (2), the fixture 12 is inclined to the left inclined surface (23) in the figure of the outer circumferential groove (20) Press the plug 2 in the axial direction.

In this way, the fastener 12 and the outer circumferential groove 20 are engaged, and the plug 2 can be completely fixed to the socket 1.

When the socket 1 and the plug 2 are in contact with each other, when the inclined surface 19 of the operation sleeve 11 presses the fixture 12, the component force of the pressing force is the outer peripheral groove 20 of the plug 2. It acts on the inclined surface 23 of) to act to press the plug 2 in the inner direction of the socket (1).

Therefore, the sealing surface 35 at the tip of the plug 2 always pushes the sealing ring 27 for end face sealing in a constant axial direction so that the sealing ring 27 between the socket 1 and the plug 2 is closed by the sealing ring 27. The cross section can be completely sealed.

Next, when the outside temperature is lowered or the low-temperature fluid flows through the fluid passage in the connected state, the socket 1 and the plug 2 are contracted as compared with the use state at normal temperature. However, the compression spring 10 continues to maintain the elastic force even at low temperatures, so that the inclined surface 19 of the sleeve 11 for operation continuously presses the fixture 12 in the centripetal direction, and the sealing ring 27 and plug 2 for sealing in cross section. The tight contact with the seal surface 35 at the tip is kept invariably to prevent fluid leakage even during low temperature use.

In this example, it was possible to adapt to the use of ultra low temperature of -196 ° C.

On the other hand, even if the outer circumferential sealing ring 28 provided on the pipe wall surface of the socket 1 contracts radially at low temperatures, its inner circumferential surface always adheres to the outer circumferential surface of the plug 2 so that it can Prevents fluid from leaking

Then, in order to increase the sealing property of each seal surface of the U-shaped sealing ring 27 and the outer sealing seal 28, the leaf springs can be inserted into the grooves of the U-shaped sealing rings 27 and 28. There is also.

As described above, as described above, the U-shaped seal ring has a U-shaped seal ring for the end face sealing, and the plug joint portion is provided near the valve seat of the socket body toward the center of the socket body and the opening in the axial direction for sealing the outer circumferential surface, respectively. On the inner circumferential surface of the operating sleeve, a surface for pressing the fixture is formed to have an inclined surface that is farther from the shaft center, so that the component force for pressing the fixture is acted on the inclined surface of the counter-circular outer circumferential groove installed on the outer circumferential surface of the plug through the fixture. Since the plug is always pressed toward the inside of the socket, one side of the sealing does not only seal the end face between the socket and the plug, but the outer seal between the other socket and the plug, and in cryogenic environments including low temperature fluid piping. With this connector, even if the material of the pipe connector shrinks at low temperatures, the plug The sealing ring for end face sealing is always pressurized, and the elasticity of the seal ring makes it possible to completely seal between the end faces of the socket and the plug.

Claims (1)

A socket (1) and a plug (2), the socket having an operating sleeve (11) axially elastically supported by a compression spring (10) on its outer circumferential surface, and being fastened at the inner circumferential surface of the sleeve upon connection with the plug; A fitting mechanism having a pressing surface for pressing the 12 in the centripetal direction, and the plug 2 having a counter-circular outer circumferential groove 20 that engages the fixture when connected to the socket. An inclined surface 19 formed on the inner circumferential surface of the sleeve 11 for pressing in the centripetal direction and acting together with the compression spring 10 for elastically supporting the sleeve 11 to press the fastener in the centripetal direction; A seal ring 27 for sealing a cross section of a plug formed of a cold-resistant material, having a U-shaped cross section, and having a U-shaped opening directed toward the centripetal direction and fitted to the fluid passage l4; Similarly formed of a cold-resistant material, the cross section is U-shaped, the U-shaped opening is made in the axial direction of the fluid passage 14 to seal the outer ring sealing ring 28 of the plug fitted to the fluid passage 14 A low temperature pipe connecting mechanism, characterized in that provided.