JPH0357358B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a fluid coupling configured such that a socket and a plug separate when an abnormal force is applied in a direction of pulling them apart from the outside.

When supplying fuel to a vehicle from an LP gas metering machine or a gasoline refueling machine using a refueling hose, for example, if the vehicle is accidentally started while refueling, an abnormal tensile force will be applied to the hose, damaging the hose and causing further damage. may damage a part of the vehicle's fuel filler port or fuel dispenser. However, in order to cope with such a situation, the hose is equipped with a safety device, that is, a fluid coupling that separates with a strong tensile force.

The above-mentioned fluid joints are, for example,
As disclosed in Publication No. 19829, it consists of a socket connected to one end of the hose and a plug connected to the other end, and these sockets and plugs have valves that open when they are connected and close when they are separated. is provided. When an abnormal tensile force is applied, the socket and plug separate, releasing the abnormal force and preventing damage to the hose, vehicle, or fuel dispenser. Of course, when the socket and plug are separated, the valve closes, so no fuel leaks out.

By the way, although the fluid joint described above is effective to some extent as a safety device as described above, it is structured so that the fluid pressure inside the joint acts in the direction of separating the socket and plug, so there is a risk of malfunction. be. That is, when the internal pressure becomes high, the socket and the plug may become separated due to the internal pressure even if no abnormal tensile force is applied to the hose. In this way, the internal pressure within the joint is related to the separation pressure between the socket and the plug, so there is also the drawback that pressure testing of the equipment to which the joint is attached cannot be carried out on the finished product, that is, with the joint attached.

Therefore, an object of the present invention is to eliminate the influence of internal pressure in the fluid joint as described above, and to prevent the socket and plug from being damaged only when an abnormal force is applied from the outside.
The object of the present invention is to provide a fluid coupling in which a socket and a plug are separated.

According to the present invention, in a fluid joint consisting of a socket, a plug, and an on-off valve provided inside the socket and the plug, the pressure of the fluid that acts in the direction of pulling the socket and the plug apart is applied to the joint between the socket and the plug. A pressure chamber is provided to offset the

Therefore, at the joint between the socket and plug, internal pressure is constantly acting in the direction of pulling them apart.
The pressure of the fluid applied to the pressure chamber acts in a direction that cancels out the acting force in the direction of pulling them apart, so the socket and plug will not be accidentally separated due to the pressure of the fluid, and abnormal forces from the outside will not occur. It separates only when it acts.

Examples of the present invention will be described below. Although the present invention can be applied to an LP gas metering machine, a gasoline refueling machine, and even a general fluid export device, an example in which the present invention is applied to a gasoline refueling machine I would like to talk about this.

FIG. 1 shows a refueling machine embodying the present invention. In the figure, the refueling machine K is equipped with a pump P for sucking up oil from a tank T, and the pump P is driven by a motor M. The oil sucked up by the pump P flows through a flow meter 1 to a hose H, and is then discharged from an oil supply nozzle N. The flow rate measured by the flow meter 1 is displayed on the display meter 5. A fluid coupling C is interposed in the hose H.

As shown in FIG. 2, the fluid coupling C includes a plug 10 that is connected to the nozzle side and a socket 3 that is connected to the refueling machine side.
0, on-off valves provided in the plug and socket, respectively, and an outer case provided around the outer periphery of the socket 30.

The plug 10 is formed into a substantially cylindrical shape so that fluid can pass therethrough, and has an internal thread 11 for connecting a hose, for example, formed at one end, and a valve seat 12 at the other end.
is provided. This valve seat 12 is formed into a substantially funnel shape. An on-off valve is provided inside the plug 10, and this valve includes a truncated conical valve body 13 that cooperates with the valve seat 12, and a valve that supports the valve body so as to be movable in the axial direction. It consists of a rod 14. The valve rod 14 is inserted into a through hole formed in the center of the bearing 15, and a spring 16 is interposed between the valve body 13 and the bearing 15. Therefore, when the valve body 13 is not pushed to the left (as shown in FIG. 2), the valve body 13 comes into close contact with the valve seat 11. The bearing 15 has a disk shape,
It is fixed to the inner wall of the plug 10 with a snap spring 17. The bearing also has through holes 1 for fluid circulation.
8 and 18 are the applicable numbers.

An on-off valve is also provided inside the socket 30, but its configuration is the same as that of the on-off valve provided on the plug 10, so the same reference numeral has a suffix a.
is added to omit duplicate explanation.

Since the on-off valves are constructed symmetrically in the same way, as shown in FIG. 2, when the plug and socket are assembled, the valve bodies 13, 13a
The tops of the coil springs 16,
16a to vacate. Therefore, valve body 1
An annular passage 19, 19a is formed between the outer peripheral surface of the valve seat 3, 13a and the valve seat 12, 12a.

A large diameter portion 20 and a small diameter portion 21 are formed on the outer circumference of the plug 10. On the other hand, a small inner diameter portion 31 and a large inner diameter portion 32 are formed on the inner circumference of the portion of the socket 30 that is inserted into the outer circumference of the plug 10. The small diameter portion 21 of the plug 10 and the small inner diameter portion 31 of the socket 30 are in close contact with each other so that they can slide against each other, and an O-ring 22 is interposed therebetween. A ring-shaped groove 23 is formed on the outer periphery of the large diameter portion 20 of the plug 10, and a plurality of balls 24 are mounted in this groove. The ball 24 is held by a holding portion 25 which is held against the outer peripheral surface of the large diameter portion 20 of the plug 10 and against the inner peripheral surface of the large inner diameter portion 32 of the socket 30. The ball 24 can be slid freely, and its thickness is smaller than the diameter of the ball 24. As shown in FIG. 2, the holding portion 25 has a plurality of holes 26 at approximately equal intervals that taper toward the inner diameter side, and the balls 24 are held in the holes 26. has been done. Further, the holding portion 25 is locked to a flange 51 of the outer case 40.

The outer circumferential portion of the socket 30 has a portion that cooperates with the inner circumferential surface of the outer case 40, and the portion can be roughly divided into a portion forming the pressure chamber 36 and a portion forming the spring chamber 35.
It is the part that forms the . That is, the outer peripheral portion of the socket 30 has a small diameter portion 33, an annular protrusion 34, and an annular recess 38 forming a spring chamber 35 in order from the end toward the plug 10 side, and the end surfaces of the small diameter portion 33 and the annular protrusion 34 is the inner peripheral surface 4 of the outer case 40
1 and the end face 42 cooperate to form an annular pressure chamber 36. Further, the annular recess 38 is formed in the outer case 4.
The spring chamber 35 is formed in cooperation with the inner circumferential surface 43 and end surface 44 of the spring. and spring chamber 35
A coil spring 45 is provided between the end surface 37 of the annular recess and the end surface 44 of the outer case, and biases the socket 30 and the outer case 40 in a direction to separate them from each other. A snap ring 47 is provided on the outer periphery of the socket 30 and locks the end of the outer case 40. In addition, the outer case 40 and the flange 51 are connected by screws 46.
are screwed together.

When fluid flows through the plug and socket and fluid pressure is applied in the condition shown in FIG. 2, the fluid pressure acts to move the plug 10 and socket 30 apart from each other. In other words, the fluid pressure is at valve seat 1
2, 12a flows into the gap S, and as a result, a force F is generated that tries to separate the two, and that force F is
When the outer diameter of the small diameter portion 21 of the plug 10 is D and the pressure is P, F=(π/4)D ² P. Therefore, when a force is applied to cancel this force F, the only force that separates the plug 10 and the socket 30 is the external force. According to the embodiment of the present invention, this canceling force is applied to the outer peripheral surface of the socket 30 and the outer case 4.
This is provided by a pressure chamber 36 formed between the inner circumferential surface of Therefore, the pressure receiving area A of the pressure chamber 36 is selected to be (π/4)D ² . That is, the pressure chamber 36 has the pore 3 formed in the socket 30.
8, and the annular pressure receiving area A of the annular convex portion 34 of the socket 30 on the pressure chamber 36 side is selected to be (π/4)D ² . Note that O-rings 39, 39 are provided between the outer peripheral surface of the socket 30 and the inner peripheral surface of the outer case, with the pressure chamber 36 in between.

Next, the operation of the above embodiment will be explained.

In the normal state shown in FIG.
Since the heads of the valve bodies 13 and 13a are in contact with each other, an annular flow path 19 and 19a is formed between the valve bodies 13 and 13a and the valve seats 12 and 12a. Fluid therefore flows freely within this fluid coupling C. Therefore, as described above, refueling from the refueling nozzle N can be carried out in the same manner as usual. by the way,
For example, assuming that the vehicle starts while refueling, an abnormal tensile force acts on the hose H. Then, the plug 10 and the outer case 40 move to the left against the force of the coil spring 45. Then, from the state in which the outer case 40 and the plug 10 are integrated by the ball 24 (as shown in FIG. 2), the ball 24 separates from the groove 23 as shown in FIG. In other words, when a tensile force greater than the set load of the coil spring 45 is applied, the coil spring 45
is compressed and the socket 30 and plug 10 move away from each other. Then socket 30
The hold on the ball 24 by the inner diameter part 32 of the plug 10 is released, and the ball 24 comes out of the groove 23 formed in the large diameter part 20 of the plug 10 (FIG. 3). Therefore, the outer case 40 and the plug 10 attached to the socket 30 are released from the integrated state by the ball 24 and separated. Upon separation, valve arrangements incorporated in the socket and plug are actuated.
That is, from the state in which the heads of the valve bodies 13, 13a are in contact with each other and retreated against the springs 16, 16a to form the passages 19, 19a, the restoring force of the springs causes the heads of the valve bodies 13, 13a to is in close contact with the valve seats 12, 12a. Therefore, fluid will not flow out from either the socket side or the plug side. By the way, not only during normal refueling, but also when an abnormal force is applied to the hose, the fluid pressure is lower than the valve seat 1.
2, 12a, a force is generated that tends to separate the socket and the plug.According to the present invention, a pressure chamber 36 is formed, and its pressure receiving area is equal to the pressure receiving area on the valve seat side. Since they are chosen to be equal, the forces that tend to force them apart cancel each other out. Therefore, according to the present invention, the only force that separates the socket and plug is an external force.
To reconnect after separation, as shown in FIG. 4, it is sufficient to loosen the screw 46 of the outer case 40, insert the plug 10, and then tighten the screw 46.

As detailed above, the fluid joint according to the present invention functions as a safety device, but according to the present invention, a pressure chamber is formed within the joint, and the fluid pressure within the joint acts to separate the socket and plug. Since it is configured so that it does not participate, it is actuated only by abnormal external forces. Therefore, it is easy to design the set load of the coil spring that integrates the socket and plug, and even if the separation pressure value is less than the pressure test pressure specified for the refueling machine, the finished product can be subjected to pressure tests. You can also get this advantage.

[Brief explanation of drawings]

Fig. 1 is a front view showing a refueling machine embodying the present invention, Fig. 2 is a cross-sectional view showing one embodiment of the invention, showing the socket and plug in a connected state, and Fig. 3 is a diagram showing the separation. FIG. 4 is a cross-sectional view showing the initial state, and FIG. 4 is a cross-sectional view showing the completely separated state. 10...Plug, 12, 12a...Valve seat, 1
3, 13a... Valve body, 24... Ball, 30...
Socket, 45...Coil spring, 40...
Outer case.

Claims (1)

[Claims] 1. In a fluid joint consisting of a socket, a plug, and an on-off valve provided inside the socket and the plug, a pressure chamber that offsets the pressure of the fluid acting in the direction of separation applied to the joint between the socket and the plug. A fluid joint characterized by being provided with.