KR930003266Y1 - Socket of connector - Google Patents

Abstract

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Description

Fluid Connection Socket

Figure 1 is a longitudinal side view of a quarter portion showing an embodiment of the present invention with a plug.

2 and 3 are longitudinal cross-sectional views of a quarter portion showing another embodiment of the present invention.

4 and 5 are longitudinal side views respectively before and after connection of a conventional fluid connection port.

* Explanation of symbols for main parts of the drawings

1 fluid connection 11 plug

12: fluid passage hole 21: socket

24: main body portion 28: stopper portion

33: sleeve 43: fluid passage hole

The present invention is a fluid connector used to extend the length of the fluid supply, discharge, and the like to the required length, branch to an appropriate number, or aggregate to an appropriate number in various fluid tools, fluid equipment, pipes such as water or air. Is about the socket.

Conventionally, in the case of supplying, discharging, etc. of a fluid, the fluid connection port used for extending, branching, gathering, etc. of the fluid supply and discharge piping has a structure shown in FIG. 4, for example.

The fluid connection port 61 shown in FIG. 4 has a fluid passage hole 62 and a fluid connection to the plug 65 having the lock ball engaging groove 64 on the outer circumference of the socket fitting portion 63. FIG. In this case, it is connected to one direction side, and the adapter which has the fluid through-hole 72 similarly is screwed to the main-cylinder part 74 which forms the plug fitting part 73, and the lockball 75 is attached to the said main-body part 74. The lock ball fixing sleeve 77 having the contact portion 77a on the lock ball 75 at the outer circumference of the main body portion 74 at the same time as the coil spring 78; A stop ring fitting groove is disposed in a state in which the body portion 74 is elastically supported in the distal direction, and a stop ring 79 for supporting the sleeve 77 elastically supported in the distal end in the distal end portion of the main cylinder portion 74. When the socket 80 configured to fit in the 74a is fluidly connected, the socket 80 is connected to the other side.

When the lug 65 and the socket 80 are connected, the sleeve 77 is moved to the left in FIG. 4 against the coil spring 78. Because of this movement, the lock ball escape space is formed between the distal end of the main cylinder portion 74 and the inner circumferential side of the sleeve 77, so that the socket insertion portion 63 of the plug 65 and the plug insertion of the socket 80 are inserted. It becomes possible to mutually interlock with the part 73, and when it is inserted, the holding hole 76 of the lock ball 75 and the lock ball engagement groove 64 are in a coincidence state. When the coil spring 78 is rebounded, the sleeve 77 slides in the right direction until it comes into contact with the stop ring 79 as shown in FIG. 5, and the lock ball contact portion formed in the sleeve 77 ( Since 77a restricts the operation of the lock ball 75, the plug 65 and the socket 80 remain connected.

To reduce the cost of fluid connections, it is important to reduce the machining power or reduce the number of parts. Therefore, the cost reduction can be achieved by eliminating the stop ring of the threaded portion and the sleeve engaging with the main body constituting the socket and the adapter with respect to the socket of the conventional fluid connector.

The present invention provides a cylindrical caulking portion at the rear end of the main cylindrical portion constituting the socket with an adapter having a recessed portion at one end of the cylindrical portion, and plastically deforms one end of the cylindrical caulking portion corresponding to the recessed portion to provide the main cylindrical portion and the adapter. It is a means to solve the above problem that the stopper portion of the sleeve elastically supported by the coil spring is formed by integrally engaging and radially plastic deformation of the front end of the main cylinder portion of the socket.

FIG. 1 shows an embodiment of the present invention, and the fluid connection port 1 shown in FIG. 1 has a plug connected to one axis in the case of supplying and discharging fluid, for example, a consumption side of the fluid ( 11) and the socket 21 connected to the other side, for example, the supply side of the fluid.

The plug 11 has an axial fluid passage hole 12 at the center thereof, a large diameter portion 13 at the center portion thereof, and a socket insertion portion 14 at the socket 21 side of the large diameter portion 13. And a lock ball engaging groove 15 formed on a circumference of the outer circumference of the socket fitting portion 14, and a hose connected to a fluid consumer device not shown on the opposite side of the large diameter portion 13. The nipple 16 is provided.

The socket 21 is divided into a main body member 22 and an adapter 42 of the socket body. Among these, the main cylinder member 22 has the plug insertion part 23 which fits the socket insertion part 14 provided in the said plug 11, and the main cylinder part which forms this plug insertion part 23. As shown in FIG. In the 24, four taper holding holes 26 of the lock ball 25 are formed at equal intervals in the circumferential direction. Moreover, the coil spring engaging part 27 is formed in the outer peripheral part of the main cylinder part 24. As shown in FIG. Similarly, an inwardly protruding portion 31 for fixing the lock ball 25 is provided on the inner circumferential side of the main cylinder portion 24 and a sleeve 33 having the concave and convex operating portions 32 on the outer circumferential side thereof. ) Slides in the axial direction. A coil spring 34 is provided between the coil spring engaging portion 27 and the side wall portion 31a of the inwardly projecting portion 31. The sleeve 33 is elastically supported to the first degree rightward.

Further, a sleeve 33 is in contact with the inclined side wall surface portion 31b of the inwardly projecting portion 31 at the front end of the main cylinder portion 24 and is elastically supported in the first direction by the coil spring 34. A stopper portion 28 for preventing the deterioration of the roller is formed by bulging plastic deformation in the centrifugal direction. In the inner circumference of the sleeve 33, when the sleeve 33 is slid to the left in the first direction against the coil spring 34, between the inclined side wall surface portion 32b and the stopper portion 28. The release space 35 of the lock ball 25 is formed. Furthermore, the main cylinder member 22 of the socket body is provided with a cylindrical caking portion 29 extending from the rear end of the main cylinder portion 24, the tip portion of which is a caulking end with the following adapter 42 ( 29a).

The adapter 42 has an axial fluid through hole 43 at its center, but at its outer circumference there is a cylindrical portion 44 which fits into the inner circumference of the circular caulking portion 29, and the nut portion 45. And a male screw portion 46, and a recessed portion 47 is formed in the circumferential direction on the nut portion 45 side of the cylindrical portion 44. As shown in FIG.

The adapter 42 fits the cylindrical portion 44 to the cylindrical caulking portion 29 of the main cylindrical member 22, and caulks the caulking end 29a of the caulking portion 29 toward the recess 47. The socket body is integrally coupled with the socket body main body member 22 and the adapter 42. In this way, an annular seal member 51 for a valve seat is provided between the socket body main body member 22 and the adapter 42 that are coupled to each other. The valve 52 which contacts and cuts off the trunk | drum and holes 12 and 43 is arrange | positioned in the state pressed by the cone coil spring 53 to the valve seat direction.

Next, the operation of the embodiment will be described.

When connecting the plug 11 and the socket 21, as shown in FIG. 1, the sleeve 33, which is in engagement with the stopper portion 28, is held against the tension of the coil spring 34. Slide to the left. In this state of sliding and colliding, the lock ball 25 is movable into the lock ball releasing space 35 formed between the sleeve 33 and the main cylinder portion 24, so that the plug 11 is in this state. ), The socket fitting portion 14 and the plug fitting portion 23 of the socket 21 are fitted to each other.

When this fitted state becomes a perfect state, the lock ball engaging groove 15 with the holding hole 26 of the lock ball 25 will match. When the sleeve 33 is in this state, the sleeve 33 slides in the right direction due to the repulsive force of the coil spring 34 to come into contact with the topper portion 28 to stop, and the inclined side wall surface portion 31b is stopped. Since the lock ball 25 is press-fitted into the taper holding hole 26, it engages with the lock ball engaging groove 15 provided in the plug 11, and the inward protrusion part 31 of the rib 33 is locked. By restricting the position of 25, the plug 11 and the socket 21 are in a fully connected state. In addition, the valve 52 is pushed in the first direction to the left by the tip of the plug 11 so as to be separated from the seal member 51 serving as the valve seat, and the fluid passage holes 12 and 43 are in communication with each other. To be maintained.

When the plug 11 and the socket 21 in the connected state are separated from each other, the sleeve 33 in contact with the stopper portion 28 is slid in the first direction to the left and the inclined side wall portion 31b The lock ball release space 35 is formed between the stoppers 28. At this time, since the lock ball 25 is ready to move toward the lock ball release space 35, by the repulsive force of the cone coil spring 53, or by disconnection operation of the socket 21 and the plug 11 The socket 21 and the plug 11 can be easily separated. When the lock ball 25 moves to the lock ball release space 35 in the process of separating the socket 21 and the plug 11, the valve 52 contacts the seal member 51 for the valve seat combined with the fluid. To prevent leakage.

FIG. 2 shows another embodiment of the present invention. In the socket of the fluid connector 1 of the embodiment shown in FIG. 1, the adapter 42, for example, connects the male screw section 46 to the connection on the fluid supply side. In contrast, in the socket 21 of the fluid connection port shown in FIG. 2, the adapter 42 differs in that, for example, the inner thread portion 146 is used for connection to the fluid supply side. The stopper portion of the sleeve 33 elastically supported by the coil spring 34 by bulging and plasticizing the tip end portion of the main cylinder portion 24 in the centrifugal direction in the same manner as in FIG. (28) is formed.

FIG. 3 shows yet another embodiment of the present invention, and shows the case where the hose nipple 246 is used for the adapter 42 in the socket 21 of the fluid connector shown in FIG. Also in this case, the socket body main cylinder member 22 expands and deforms the tip portion of the main cylinder portion 24 in the centrifugal direction in the same manner as in FIG. 1, so that the sleeve 33 elastically supported by the coil spring 34 is provided. ), A stopper portion 28 is formed.

In each of the above embodiments, the main body member 22 of the socket body has the same structure irrespective of the two types other than the male screw type of the adapter 42, and can be used in common. In addition, since the socket main body member 22 and the adapter 42 are not screwed together, there is no need to form a coupling thread part, and the socket body main body member 22 is provided with a tool for screwing. It is not necessary to provide a locking portion (nuts, etc.). Therefore, the fluid connection port of the present invention can be said to be a socket structure with a low number of assemblies. However, the present invention has screwed the socket main body member 22 and the adapter 42 together. Naturally, it is also applicable to the one integrated by the structure of FIG. 4, and also to the socket in which the main body member of the socket body and the adapter are integrally formed.

Incidentally, in each of the above embodiments, the socket 21 has a valve 52, which illustrates the case, but is applicable to a socket without a valve.

As described above, the fluid connection port according to the present invention makes the connection between the plug and the socket disconnected by swelling and deforming in the centrifugal direction the tip of the main body portion that forms the plug insertion portion of the socket. Since the sleeve of the lock mechanism used for the operation is formed to form a stopper when the sleeve is elastically supported in the distal end direction of the main cylinder portion, the stop ring can be eliminated for preventing the sleeve from falling off. Of course, there is no need to form grooves for fitting, and there is no need for assembling the stop ring, and there is an excellent effect that the sleeve can be more reliably supported.

Claims (1)

In the cylindrical caulking portion 29 at the rear end of the main cylinder portion 24 constituting the socket 21, an adapter 42 having a recess portion 47 is fitted at one end of the cylindrical portion 44, and the recess portion ( Plastic deformation of one end of the cylindrical caulking portion 29 corresponding to 47) causes the main cylinder portion 24 and the adapter 42 to be integrally coupled, and the front end of the main cylinder portion 24 of the socket 21 is removed. And a stopper portion of the sleeve (33) elastically supported by the coil spring (34) by radially plastic deformation.