JP4127189B2 - Pipe fitting - Google Patents

Description

  According to the present invention, in order to supply compressed air from a compressed air supply source side such as a compressor to an air moving tool driven by compressed air, the compressed air supply source side and the tool side are detachably connected. It relates to the pipe joint made.

  In general, a hose is used to supply compressed air from a compressed air source such as an air compressor to a pneumatic tool operated by compressed air, and the compressed air source and the hose or the hose and the tool are connected. Alternatively, a pipe joint composed of a plug connected to the tool side and a coupler arranged on the compressed air source side for separation is used. On the other end side of the coupler whose one end is connected to the compressed air supply source side, a female socket part into which a plug connected to the tool side can be inserted is formed. By inserting the plug into the socket part, the coupler is inserted. Side and plug-side flow paths are connected to supply compressed air from the compressed air supply source to the tool side, and locking balls that protrude in the inner diameter direction from the peripheral wall surface of the socket part are formed on the outer peripheral surface of the plug. The plug is mounted and held in the socket portion of the coupler by engaging with the annular groove and holding the locking ball in a position protruding in the inner diameter direction by an operation sleeve formed slidably on the outer periphery of the coupler. Then, the plug is attached to or detached from the socket portion by sliding the operation sleeve so that the locking ball can be moved in the outer diameter direction.

When the plug is attached to the socket portion of the coupler, a pipe joint that allows the coupler and the plug to be connected by a one-touch operation of simply inserting the plug into the coupler socket portion without operating the operation sleeve. Proposed. In this pipe joint, a one-touch sleeve that is spring-biased so as to be slidable along the inner peripheral wall surface forming the socket portion of the coupler is provided, and a locking ball disposed on the inner peripheral wall surface is connected to a socket for plug mounting. By holding the one-touch sleeve against the spring biasing force by inserting the plug so that it does not protrude into the part, the locking ball is advanced into the socket part to engage with the groove of the plug, The operation sleeve moves forward to restrain the locking ball at the lock position so that the plug is mounted on the socket portion. When the plug is detached from the coupler, the locking ball is removed from the socket when the one-touch sleeve moves forward following the movement of the plug from the socket and the plug is detached from the socket of the coupler. It is made to hold | maintain so that it may retract in radial direction.
No. 3-5757

In addition, the operation of each tool to both the normal pressure tool used in the normal pressure region where the working air pressure is 10 kg / cm ² or less and the high pressure tool used in the high pressure region where the working air pressure is higher than this, for example. In compressed air supply systems that supply pneumatic compressed air, plugs attached to each tool, hose, etc. have special shapes for normal pressure and high pressure, respectively, to prevent incorrect connections. In addition, the high pressure plug and the normal pressure plug can be installed together, and when the high pressure plug is installed, the compressed air in the high pressure range supplied from the compressed air source is supplied to the high pressure tool. When a normal pressure plug is installed, compressed air with the pressure reduced to the normal pressure range is supplied to the normal pressure tool by the built-in pressure reducing valve. Such couplers have already been proposed.
JP 2003-97448 A

  In a coupler that can be mounted with both a high pressure dedicated plug and a normal pressure dedicated plug as described above, a seal portion for fluid connection with the normal pressure dedicated plug is formed at the end of the one-touch sleeve. Yes. In addition, in order to prevent the compressed air from flowing out between the one-touch sleeve and the cylindrical body forming the seal portion with the high-pressure dedicated plug arranged on the inner diameter side of the one-touch sleeve, A sliding seal is also formed. In couplers that can be fitted with high-pressure and normal-pressure couplers, the high-pressure power supplied to the tool and the hose when the high-pressure plug connected to the high-pressure tool is removed from the coupler. The compressed air in the area is ejected from the plug tip at the moment when the seal between the coupler and the plug is removed, and this compressed air is momentarily filled in the socket part of the coupler and acts on the end part of the one-touch sleeve. May slide against the spring biasing force. Note that this may occur in the same situation when the normal pressure plug is removed from the coupler as well as the high pressure plug. If the plug is removed while the one-touch sleeve slides against the spring biasing force in this way, the locking ball is locked by the operation sleeve while protruding in the inner diameter direction in the socket, and the one-touch sleeve is Even if biased by the spring force, the front end hits the locking ball and stops. As described above, since the locking ball is locked in a state of protruding into the socket portion, there has been a problem that the plug cannot be inserted into the socket portion and the plug cannot be attached by one-touch operation.

  By setting the urging force of the spring that urges the one-touch sleeve to slide more than the pressing force that the compressed air pressure in the high-pressure region acts on and presses the end of the one-touch sleeve, the one-touch sleeve is It is possible to prevent it from moving, but when attaching the plug, the one-touch sleeve is slid against the spring urging force by the plug insertion operation, so this spring load If a large value is set, the operation load at the time of plug mounting becomes large, which causes a problem that it is difficult to perform the mounting operation.

  The present invention solves the above-described problems in the prior art, and the one-touch sleeve is not slid by the compressed air ejected from the plug when the plug is removed from the socket portion of the coupler. It is an object to provide a coupler that can be mounted by a one-touch operation.

In order to solve the above problems, the pipe joint of the present invention is formed with a plug connected to the tool side, and a socket part having one end connected to a compressed air supply source and the other end being detachably mounted with the plug. And a coupler configured to supply the compressed air supplied from the compressed air supply source to the plug side attached to the socket portion, wherein the coupler has a socket portion on one end side. A coupler housing formed, a locking ball disposed on a peripheral wall surface of the socket part so as to engage with an annular groove formed on an outer peripheral surface of a plug inserted into the socket part, and the locking ball protruding. was the cause operation sleeve and locking the slide operation in the longitudinal direction of the socket portion in position, the locking ball along the inner circumferential surface of the coupler housing so as not to protrude radially inward And a one-touch sleeve arranged so as to be able to ride, and further, an opening communicating between the inner side and the outer peripheral side of the socket portion is formed in a radial direction on each peripheral wall of the one-touch sleeve, the housing, and the operation sleeve. When the plug is removed from the socket portion, the compressed air discharged from the plug end is discharged to the outside of the socket portion through the opening, and the outer periphery of the plug inserted into the one-touch sleeve is formed. A seal member that is in close contact with the surface is formed, and the opening formed in the one-touch sleeve is formed closer to the opening end side of the socket into which the plug is inserted than the seal member .

As described above, according to the pipe joint of the present invention, the opening communicating with the outer peripheral side of the coupler from the inside of the socket portion is formed in the peripheral direction of the one-touch sleeve, the housing, and the operation sleeve in the radial direction, and the plug is connected to the socket. Since the compressed air discharged from the plug end is discharged to the outside of the socket part through the opening when being detached from the part, the compressed air remaining in the hose on the tool side is ejected to the socket part. Compressed air does not act on the end face of the one-touch sleeve and slides the one-touch sleeve against the biasing force of the spring, and the locking ball is locked in a state of protruding into the socket with the plug removed. Therefore, the plug can be securely attached with a one-touch operation just by inserting the plug into the socket. It can be. The one-touch sleeve is formed with a seal member that is in close contact with the outer peripheral surface of the inserted plug, and the opening formed in the one-touch sleeve is formed closer to the opening end side of the socket into which the plug is inserted than the seal member. Therefore, since the compressed air from the plug is discharged from the opening and does not act on the one-touch sleeve, the one-touch sleeve is not slid and the locking ball is not locked.

  The purpose of the present invention is to prevent the compressed air remaining in the hose from being ejected into the socket when the plug is removed from the coupler, and the one-touch sleeve is prevented from sliding due to this compressed air. This is achieved by forming an opening communicating with the outer peripheral side of the coupler in the radial direction on the peripheral walls of the one-touch sleeve, the housing, and the operation sleeve, and more specific embodiments will be described below.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a cross-sectional view of a coupler 10 constituting a pipe joint of the present invention. This coupler 10 is, for example, as shown in FIG. 2, driven by compressed air in a normal pressure range from an air compressor. It is used in a compressed air supply system that supplies compressed air in an operating pressure range for driving each tool to a tool and a high-pressure tool driven by compressed air in a pressure range higher than normal pressure. The compressed air supply system generates high-pressure compressed air that can drive a high-pressure dedicated tool by an air compressor including compressors 2 and 3 driven by an electric motor 1 and stores the compressed air in an air tank 4. Is done. The air tank 4 includes a pressure regulator 5 that arbitrarily adjusts the pressure of compressed air supplied to the pneumatic tool, and a compression unit 10 that connects a plug attached to an end of a hose connected to the tool side. At least one air supply means 6 is installed. In the figure, reference numerals 7 and 8 denote pressure gauges for displaying the air pressure value in the air tank 4 and the pressure value adjusted by the pressure regulator 5, respectively. The pressure regulator 5 reduces the pressure of the compressed air stored in the air tank 4 to an arbitrary adjustment pressure from the operating pressure region of the normal pressure tool to the operating pressure region of the high pressure tool and supplies the pressure to the coupler 10. .

  As shown in FIG. 1, an air supply port 11 connected to the pressure regulator 5 and supplied with compressed air is formed at one end of the coupler 10, and a tool is provided at the opposite end. A female socket 12 is formed for receiving and mounting a plug attached to an air hose connected to. The socket portion 12 is formed so that plugs P1 and P2 having different shapes for normal pressure and high pressure can be connected. The coupler 10 is blocked when the plug is not connected to prevent the compressed air from flowing out from the socket portion 12 side, and the plugs P1 and P2 are opened by being attached to the socket portion 12 so as to be plugged. Two shut-off valves 13a and 13b are formed to supply compressed air to P1 and P2.

  One shut-off valve 13a is constituted by an O-ring attached to the outer peripheral surface of the cylindrical body 14 that is slid by the normal pressure dedicated plug P1 being attached to the socket portion 12, and the normal pressure dedicated plug P1. Is connected to the socket portion 12 so that the cylindrical body 14 is slid and the O-ring 13a is separated from the valve seat 16 formed in the coupler housing 15 forming the socket portion 12, and the cylindrical body is The compressed air is conducted to the socket portion 12 side through the opening 17 formed in the peripheral wall 14. The other shut-off valve 13b is configured to be slid together with the rod 18 by a stop ring 19 attached to the outer periphery of the rod 18 slid by the attachment of the high-pressure plug P2. 13b is configured to be engaged / disengaged from the open end of the cylindrical body 14 so that the socket 12 side and the air supply port 11 are disconnected and communicated with each other, and a high-pressure plug P2 is attached. As a result, the rod 16 is slid to open the shut-off valve 13b, and the compressed air is conducted to the high-pressure dedicated plug P2 side.

Further, on the side of the air supply port 11 of the coupler 10, an open / close valve 20 that opens and closes a compressed air passage from the air supply port 11 to the socket portion 12 side is provided. The on-off valve 20 is brought into close contact with the upstream side surface of the valve seat 22 formed in the coupler housing 15 by the air pressure supplied from the biasing spring 21 and the air supply port 11 so as to block the compressed air. A pressure regulating piston 23 is slidably disposed on the downstream side of the on-off valve 20 so as to open and close the on-off valve 20 and generate a reduced pressure on the downstream side of the on-off valve 20. The pressure adjusting piston 23 is configured to adjust the pressure of the compressed air acting on the pressure receiving surface 23a that receives the pressure of the compressed air on the downstream side of the on-off valve 20 and the pressure adjustment by the pressure adjusting spring 24 disposed on the opposite side of the pressure receiving surface 23a. The on-off valve 20 is slidably operated to open and close by a balance with a spring force that presses the piston 23. The pressing force of the pressure adjusting spring 24 and the area of the pressure receiving surface 23a act on the pressure receiving surface 23a with the pressure of compressed air acting on the pressure receiving surface 23a as a boundary, for example, 10 kg / cm ² , which is the upper limit pressure for operating the normal pressure tool. When the air pressure to be operated becomes larger than this, the valve is operated so as to close the on-off valve 20, and when the air pressure acting on the pressure receiving surface 23a becomes small, the valve is operated to open. .

  That is, the on-off valve 20 and the pressure regulating piston 23 function as a pressure reducing valve set by the pressure regulating spring 24 and the pressure receiving surface 23a, and compress the high pressure region to the air supply port 11 via the pressure regulator 5. When the normal pressure plug P1 is connected to the socket part 12 as shown in FIG. 3, the on-off valve 20 is closed, and the normal pressure plug P1 is connected to the normal pressure plug P1. Compressed air reduced in pressure to a normal pressure range set by the pressure receiving surface 23a and the pressure adjusting spring 24 is supplied. When the normal pressure tool is used at a pressure lower than the set pressure, the pressure regulator 5 adjusts the air pressure supplied to the air supply port 11 to be lower than the set pressure. As a result, the pressure adjusting piston 23 is operated in a state in which the on-off valve 20 is opened by the spring force of the pressure adjusting spring 24 so that compressed air having a pressure adjusted by the pressure adjuster 5 is supplied to the normal pressure tool. Has been.

  Further, as shown in FIG. 4, the other end of the rod 18 that is operated by contacting the tip of the plug P2 by attaching the high-pressure dedicated plug P2 to the socket portion 12 opens the central opening of the pressure regulating piston 23. The rod 18 is extended and extended in the direction of the on-off valve 20, and the rod 18 is slid by the high-pressure dedicated plug P <b> 2 being attached to the socket portion 12. The valve 20 abuts and is separated from the valve seat 22 to keep the on-off valve 20 open. As a result, when the high pressure plug P2 is mounted to use the high pressure tool, the on-off valve 20 is maintained in an open state, and the high pressure tool is supplied with compressed air having a pressure in the high pressure range adjusted by the pressure regulator 5. it can.

  As shown in detail in FIG. 5, a plurality of openings 25 are formed in the peripheral wall of the coupler housing 15 forming the socket portion 12 of the coupler 10 at intervals in the circumferential direction. The steel locking balls 26 are accommodated so as to protrude into the socket portion 12. This locking ball 26 advances into the socket portion 12 so that it can engage with an annular groove 27 formed on the outer peripheral surface of the plugs P1 and P2 inserted into the socket portion 12. Further, an operation sleeve 28 that can be slidably operated is provided outside the coupler housing 15. The operation sleeve 28 projects inward of the socket portion 12 and engages with the annular grooves 27 of the plugs P 1 and P 2. The plugs P1 and P2 are mounted and held in the socket portion 12 by locking the ball 26 so as not to move in the outer diameter direction.

  Further, a one-touch sleeve 29 for holding the locking ball 26 so as not to protrude inward of the socket portion 12 is slidably disposed inside the coupler housing 15. The annular portion at the tip of the coupler housing 15 is advanced to the inner peripheral surface side of the portion where the opening 25 of the coupler housing 15 is formed, thereby preventing the locking ball 26 from protruding from the opening 25 to the inside of the socket portion 12. I am doing so. The one-touch sleeve 29 is slidably biased by a spring 30 so that the tip portion is advanced to the inside of the locking ball 26. Inside the one-touch sleeve 29 is disposed a cylindrical body 14 that guides compressed air to the plug side when the aforementioned shut-off valves 13a and 13b are opened, and on the inner peripheral surface of the front end portion of the cylindrical body 14. Is formed with a seal member 31 slidably in contact with the outer peripheral surface of the high-pressure plug P2, and guides the compressed air supplied through the shutoff valve 13b to the high-pressure plug P2.

  Further, in order to connect the normal pressure plug P1 having a seal portion whose outer dimension is larger than that of the high pressure plug P2 in order to eliminate compatibility, the outer peripheral surface of the normal pressure plug P2 is connected to the inner peripheral surface of the one-touch sleeve 29. A seal member 32 that is slidably contacted is formed, and the compressed air supplied through the cylindrical body 14 is guided to the normal pressure plug P1. When the normal pressure plug P1 is connected to the socket portion 12, the compressed air supplied through the shutoff valve 13a and the cylindrical body 14 leaks from between the one-touch sleeve 29 and the cylindrical body 14. In order to prevent this, a sliding seal 33 is also formed between the inner peripheral surface of the one-touch sleeve 29 and the outer peripheral surface of the cylindrical body 14. As described above, the seal portion 33 is formed between the one-touch sleeve 29 and the cylindrical body 14, so that the compressed air discharged from the plug side into the socket portion 12 in the socket portion 12 acts on the end surface of the one-touch sleeve 29. As a result, a phenomenon occurs in which the one-touch sleeve 29 slides against the urging force of the spring 30.

  Further, the socket portion 12 in the coupler 10 of the present invention passes through the peripheral walls of the one-touch sleeve 29, the coupler housing 15 and the operation sleeve 28, and communicates the inside of the socket portion 12 to the outer peripheral surface side of the operation sleeve 28. An opening 34 is formed. When the normal pressure or high pressure plugs P1 and P2 are separated from the coupler 10 by the opening 34, compressed air is injected into the socket portion 12 at the moment when the plugs P1 and P2 are detached from the seal portions 31 and 32 of the coupler 10. Is discharged from the socket 12 to the outer peripheral side of the operation sleeve 28, and the compressed air blown into the socket 12 acts on the end of the one-touch sleeve 29 to resist the urging force of the spring 30. The slide is not moved.

  A plurality of openings 34 a formed in the one-touch sleeve 29 are formed on the front end side of the seal member 32 that is in close contact with the normal pressure plug P 1 at a circumferential interval, and the openings 34 b formed in the coupler housing 15. Are formed on the peripheral wall surface on the rear side of the opening 25 accommodating the locking ball 26 at intervals in the circumferential direction so as to be at the same position as the opening 34 a formed in the one-touch sleeve 29. Further, a plurality of openings 34 c formed in the operation sleeve 28 are formed at intervals in the circumferential direction so as to be aligned with the openings 34 a and 34 b formed in the one-touch sleeve 29 and the coupler housing 15. These openings 34a, 34b, and 34c are aligned with each other when the tip of the one-touch sleeve 29 slides against the biasing force of the spring 30 just before the tip of the one-touch sleeve 29 comes off the locking ball 26. Thus, the compressed air in the socket portion 12 may be discharged through the aligned openings 34a, 34b, 34c.

  Hereinafter, the operation state by the coupler 10 of the present invention according to the above embodiment will be described. As shown in FIG. 6, in a state where the high pressure plug P2 is connected to the socket portion 12 of the coupler 10, the seal member 31 formed on the cylindrical body 14 is in sliding contact with the outer peripheral surface of the high pressure plug P2, and the cylindrical body. 14 is connected to the high-pressure plug P2 side. Further, the rod 18 is pressed by the tip of the plug P2 mounted on the socket portion 12 to open the on-off valve 20, and the shut-off valve 13b is opened by the rod 18 to be supplied from the compressed air supply source. Is connected to the high-pressure plug P2 side and supplied to the high-pressure tool through a hose connected to the plug P2.

  In order to remove the plug P2 from the coupler 10, when the operating sleeve 28 arranged on the outer periphery of the socket part 12 is slid against the spring biasing force as shown in FIG. The locked state of the locking ball 26 which has been released is released, and the locking ball 26 can be moved in the outer diameter direction. The action of the compressed air acting on the end face of the plug P2 and the action of the spring 30 acting on the one-touch sleeve. As a result, the plug P2 is moved in the direction in which the plug P2 is pulled out from the socket portion 12, and the rod 18 slides and the shut-off valve 13b is closed as the plug P2 moves. Thereby, the supply of compressed air from the compressed air supply source side to the plug P2 side is interrupted.

  Further, when the plug P2 is pulled out from the socket portion 12, as shown in FIG. 8, the high pressure plug P2 and the sealing member 31 of the cylindrical body 14 are separated from each other, and the tool side hose connected to the plug P2 at this moment. The compressed air remaining in the interior flows backward and is ejected from the plug P2 into the socket portion 12. The compressed air discharged into the socket portion 12 is discharged to the outer peripheral side of the socket portion 12 through openings 34a, 34b, 34c formed on the peripheral wall surfaces of the one-touch sleeve 29, the coupler housing 15 and the operation sleeve 28, The pressure by compressed air is not generated in the socket part 12. Therefore, the one-touch sleeve 29 is not slid and moved against the urging force of the spring 30 and locked in a state where the locking ball 26 protrudes into the socket portion 12. 29, the socket is retracted from the inside of the socket portion 12 in the outer diameter direction, and it is not necessary to operate the operation sleeve 28 when the plug is attached, and the plug can be attached by one-touch operation only by inserting the plug into the socket portion 12. can do.

Longitudinal side view showing a coupler constituting the pipe joint of the present invention The block diagram which shows the compressed air supply system which uses the pipe joint of this invention Longitudinal side view showing the coupler with the normal pressure plug connected Longitudinal side view showing coupler with high-voltage plug connected 1 is an enlarged side view of the same coupler as in FIG. It is a vertical side view which shows the operation state which makes a plug detach | leave from a socket part, and shows the state with which the plug is mounted | worn Longitudinal side view showing the operating state immediately after operating the operating sleeve in the process of removing the plug Longitudinal side view of the state where the seal member is detached from the plug and the compressed air on the hose side is discharged into the socket Longitudinal side view with the plug completely detached from the coupler mounting area

Explanation of symbols

10 coupler 12 socket 15 coupler housing 26 locking ball 27 annular groove (for plug)
28 Operation sleeve 29 One-touch sleeve 34 Opening

Claims (1)

A plug connected to the tool side, a socket part for connecting one end side to a compressed air supply source and a detachable attachment of the plug to the other end side are formed, and compressed air is supplied to the plug side attached to the socket part. A pipe joint comprising a coupler configured to supply compressed air supplied from a supply source, wherein the coupler is inserted into the socket part, a coupler housing having a socket part formed on one end side Locking balls arranged on the peripheral wall surface of the socket part so as to engage with an annular groove formed on the outer peripheral surface of the plug, and locking the sliding ball in the longitudinal direction of the socket part at a position where the locking ball protrudes One-touch three arranged so as to be slidable along the inner peripheral surface of the coupler housing so as not to project the locking ball in the inner diameter direction. Furthermore, an opening that communicates between the inner side and the outer peripheral side of the socket part is formed in a radial direction on the peripheral walls of the one-touch sleeve, the housing, and the operation sleeve, and the plug is connected to the socket part. Compressed air discharged from the plug end when being removed from the socket is discharged to the outside of the socket portion through the opening, and the one-touch sleeve is formed with a seal member that is in close contact with the outer peripheral surface of the inserted plug An opening formed in the one-touch sleeve is formed on an opening end side of a socket into which a plug is inserted rather than the seal member .

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