FR2708329A1 - Submerged connection device for hydraulic couplings - Google Patents

Abstract

This device is of the type composed of two couplings (7, 8) with respectively a male end (38) and a female end (16), each fitted with a valve for shutting them off in the disconnected position. According to the invention, each female coupling (8) is arranged vertically with its internal cavity (48, 50) pointing upwards, in the bottom of a vertical container (14) containing hydraulic fluid (15), while each male connector (7) is attached dismantleably to a socket (18) which, positioning it vertically along the axis of the female coupling (7) with immersion of its end in the fluid (15) of the container, is itself secured to a piston (22), the said piston being able to move vertically in the container between a stand-by position in which the end (38) of the male coupling (7) is not engaged in that (16) of the female coupling (8), and a coupling position.

Description

"Submerged connection device for fittings
hydraulic "
The invention relates to the field of connection of hydraulic fluid transport circuits by means of the engagement of the end piece of a male fitting, integral with a first element of the circuit, in the end piece of a female fitting. integral with a second element of the same circuit.

 It relates more particularly, but not exclusively, to connections for fluid circuits used in a contaminated site, or in an ionizing or radioactive environment.

 With the current connection devices, and even when the two connections are provided with shut-off valves opposing any flow of fluid when they are disconnected, the connection and disconnection operations very often generate, on the one hand, fluid leaks, with the resulting risks of pollution and contamination, and, on the other hand, the penetration of a small amount of air into the hydraulic circuit. Despite the presence of means for trapping this air, it is not uncommon for the latter to remain in cavities of the circuit and, by accumulation, form a volume sufficient to disturb the operation of the means actuated by the fluid, for example, by driving phenomena of cavitation or irregularity in the movements, since the air is compressible, while the hydraulic fluid is not, at the envisaged operating pressure.

 The present invention aims to provide a connection device for ensuring the connection and disconnection of two elements of a circuit without risk of introducing air into this circuit.

To this end, in the device according to the invention, each female connector is arranged vertically, with its internal cavity facing upwards, in the bottom of a vertical tank containing a hydraulic fluid, fluid whose level maintained constant is at- above this fitting,
- while each male connector is removably attached in a socket which, ensuring its vertical positioning in the axis of the female connector with immersion of its end, in the fluid of the tank, is itself secured to a piston, said piston being movable vertically in the tank between a standby position, in which the end piece of the male connector is not engaged in that of the female connector, and a connection position, in which each male end piece is connected with the corresponding female end cap,
- And that the piston is connected to means capable of imparting to it a stroke greater than the opening stroke of the shutter valves of the two coupled couplings.

Thus, the connection is made in two phases, namely
- a first phase consisting in mounting the male connector (s) on the corresponding sockets of the piston,
- And a second phase consisting in controlling the displacement of the piston from its standby position to its connection position.

 During this second phase, the tip of each male fitting, already immersed in the fluid of the tank, is introduced into the tip of the female fitting. In a first sub-phase, its volume drives out all or part of the fluid contained in this female end piece by creating a hydrodynamic current entraining, outside of this female end piece, any air bubble that can still adhere to the male end piece.

 It is only after this cleaning sub-phase that, under the displacement of the end piece of the male fitting, the shutter valves of the two fittings are opened automatically and the fluid contained in the first element of the hydraulic circuit with that contained in the second element of the same circuit.

 In one embodiment of the invention, the end piece of each female connector has an axial bore for receiving the end piece of the male connector, this bore being associated with a seal capable of cooperating with the male end piece and, in the extension of this bore, a bore which, opening to the outside, has a larger diameter to form, with the male end piece, an annular hydrodynamic ejection chamber.

 This chamber promotes the elimination of air from the connection area.

 Other characteristics and advantages will emerge from the description which follows with reference to the appended diagrammatic drawing, representing by way of nonlimiting example, an embodiment of the device according to the invention in the case of its application to the connection of two hydraulic circuits.

FIG. 1 represents the simplified hydropneumatic diagram of an installation implementing the device for ensuring the connection of two hydraulic circuits,
FIG. 2 is a plan view from above of the device cabinet,
FIG. 3 is a partial view in cross section of an embodiment of the connection device,
FIG. 4 is a partial cross-section view showing, on an enlarged scale, the male and female connectors, when they are in the standby position and before connection,
Figure 5 is a partial view showing the tips of Figure 4, when connected.

 In FIG. 1, the reference numeral 2 designates a double-acting hydraulic cylinder intended to actuate any member and whose chambers 3 and 4 are connected, by first circuit elements, respectively 5a and 6a, to two male connectors 7. Each of these male connectors 7 corresponds to a female connector 8, itself connected to the second element 5b or 6b of the same circuit.

 In the embodiment shown, the circuit element 5b is connected to a manually operated emitting cylinder 9 by a lever 10, while the element 6b is connected to an accumulator 12 providing a return pressure.

 The connection and disconnection of the male connections 7 and the female connections 8 is ensured by the device according to the invention comprising, as shown in FIG. 3, a tank 14 containing a constant level h of hydraulic fluid 15, and in particular of water.

 The female connections 8 are arranged vertically in the bottom of the tank and in such a way that the cavity, formed in their end piece 16, opens upwards, below the level h of the water in the tank.

 Each male connector is removably attached, in particular by a thread 17, in a threaded sleeve 18 ensuring its vertical positioning in the longitudinal axis of the female connector 8. This sleeve is made integral, for example by a flange 19 and a ring d 'stop 20, of a piston 22 slidingly mounted, in a sealed manner in the internal bore of the tank 14. The rod 23 of this piston passes axially through the bottom of the tank and is coupled to the rod of a cylinder actuation 24. In the embodiment shown in FIG. 1, this actuator is a pneumatic actuator supplied by a circuit 26 through a manually operated distributor 27.

 The piston 22 can occupy two positions, namely a standby position, represented in strong lines in FIG. 7, and a connection position, represented in FIG. 5.

 This piston is associated with means ensuring its setting in rotation, means which, in the embodiment shown, consist of an eccentric finger 30, for example by a split tubular pin fitted elastically in a bore 32 of this piston. The pin projects downwards from the lower face of the piston and engages in a vertical well 33, formed in the bottom of the tank and opening out inside the latter. This well communicates by a conduit 34 with an expansion tank 35 (fig. 1) ensuring the regularity of the level h in the tank.

 As shown in more detail in FIG. 4, each male connector 7 is integral with a ring 37 with external thread 17 and comprises, in its tubular body 38, an axial piston 39 forming a tight shut-off valve for its axial bore 40.

 FIG. 4 clearly shows that when the axial piston 39 is in the closed position, its lower face is at least at the level of the lower end of the tubular end piece 38 and, in this case, projects from this face to avoid the formation of any air retention cavity at this part of the fitting. The piston 39 is provided with an axial bore 42 communicating downward with radial bores 43 and upward with an axial channel 44, formed in the body of the fitting, and communicating with the first element 5a or 6a of a circuit hydraulic.

 Finally, the lower end of the end piece 38 is provided with a chamfer 45, while the lower end of the piston 39 is provided with a chamfer 46. This latter chamfer is intended to ensure progressive compression of the seal. seal 47, disposed between the piston 39 and the axial bore of the end piece 38, when the piston returns to its closed position after having occupied its open position, shown in FIG. 5.

 The end piece 16 of each female connector 8 is tubular and has an axial bore 48 capable of receiving, with a seal by a seal 49, the end piece 38 of the male connector 7. In the extension of this bore 48, the end piece also includes , opening outwards, an axial bore 50 of larger diameter than that of bore 48, and capable of forming, with the end piece 38 of the male connector, an annular chamber 52, visible in FIG. 5, and of which the usefulness will be specified later.

 The bottom of the bore 48 has an axial passage 53 which is closed by a conical valve 54, pressed against an O-ring 55 by a spring 56. The valve 54 is crossed by radial perforations 57 opening into an axial channel 58 communicating with the internal chamber of the connector, itself connected to the second element 5b or 6b of the hydraulic circuit.

 The conical valve 54 is integral with an axial plunger 60 extending longitudinally in the bore 48 and in the bottom of the bore 50.

 In the disconnected position, as shown in Figure 4, the valve 54 is in the closed position and opposes any communication of the bore 53 with the circuit element to which the female connector is connected. The same applies to the piston 39 of the male connector 7, which is held in the closed position by the spring 41 interposed between the head of this piston and a diametrical face of the connector 7.

 With this device, the connection of the two male fittings 7 with the two female fittings 8 takes place in two phases. The first phase consists in screwing each male connector 7 into the corresponding socket 18 of the piston 22, then in the standby position shown in FIG. 3. This figure clearly shows, moreover, that each socket 18 constitutes a centering barrel, by making the axes of the two fittings coaxial and perfectly positioning the lower end of each male end piece 38 just above each female end piece 16. It will be noted that, in this position, the active parts of the two end pieces are embedded in the fluid hydraulics 15.

 In the following phase, the operator actuates the distributor 27, so as to control the supply of the pneumatic cylinder 24 to cause the displacement of the piston 22 in the direction of the arrow 21 in FIG. 3.

 During this movement, the male end piece 38 of each connector 7 sinks inside the bore 50 of the female end piece 16 thereby expelling the fluid contained in this bore, and generating in the annular chamber 52 ( fig. 5), a hydrodynamic current directed upwards, carrying with it the air bubbles which can still adhere to the male end piece 38.

 After this phase of cleaning by bubble removal, the head of the sealing piston 39 comes into contact with the pusher 60 causing, as shown in FIG. 5, the opening of the male connector 7 and, simultaneously, the opening of the female connector 8. At the end of the operation, the hydraulic fluid contained in the circuit element 5b or 6b communicates, through the connections 8 and 7 their respective channels and bores, with the circuit element 5a connected to the male connector 7.

 It is obvious that the connection maneuver, like that of disconnection, takes place while each of the circuits concerned is not under pressure.

 It will be noted that the stroke C1 of the piston 22, and consequently, of the end of the end pieces 38 of the male fittings 7, is greater than the stroke C2 bringing the means for closing the fittings 7 and 8 and that this difference is brought to advantage to cause the hydrodynamic evacuation of the air, until the end piece 39 of the male connector 7 comes into sealing contact with the seal 49 of the female end piece 16.

 During the connection maneuver, the fluid 15, contained in the tank 14, and which is subjected to compression by the piston 22, is driven from the tank by the well 33 and by the conduit 34 to the expansion tank 35 , shown in Figure 1, and this until the piston 22 returns from its connection position to its standby position.

 It follows from the above that the connection is made by immersion in the hydraulic fluid and, consequently, without any risk of air entering into any of the elements of the hydraulic circuits leading to the device.

 It is the same for disconnection, since the valves are brought into the closed position during the ascent phase of the piston 22 and while the active parts of the ends of the male connectors 7 are still immersed in the tank.

 In the embodiment shown, the tank 14 is closed by a cover 62 attached and fixed on it and comprising, at least one perforation 63, for the communication with the outside of the air contained between the piston 22 and this cover.

 Many seals are fitted to the device according to the invention. They have not been described because their nature and their implementation are within the reach of those skilled in the art.

 Finally, it is advantageous for the hydraulic fluid 15, contained in the tank 14, to be of the same nature or, even better, identical to the fluid conveyed by the circuit elements terminating in the tank.

 It is obvious that this device can be used to ensure the simultaneous connection of any number of pairs of male and female fittings.

This device can also be applied to connection-disconnection
- a measurement sensor (pressure, force, temperature) using a hydraulic fluid to transmit a pressure whose value varies proportionally with that of the physical quantity measured
- a hydraulic circuit containing a polluting or precious fluid.

Claims (7)

 1. Connection device for hydraulic circuits of the type composed of two fittings (7, 8) with end pieces, male (38) and female (16) respectively, each provided with a shut-off valve in the disconnected position, characterized in that each female connector (8) is arranged vertically, with its internal cavity (48, 50) turned upwards, in the bottom of a vertical tank (14) containing hydraulic fluid (15), fluid whose level kept constant is above this fitting,  - while each male connector (7) is removably attached in a socket (18) which, ensuring its vertical positioning in the axis of the female connector (7), with its end immersed in the fluid (15) of the tank, is itself integral with a piston (22), said piston being movable vertically in the tank between a standby position, in which the end piece (38) of the male connector (7) is not engaged in that (16) of the female connector (8), and a connection position, in which each male connector (38) is connected with the corresponding female connector (26),  - And that the piston (22) is connected to means (24) capable of communicating to it a stroke C1 greater than the stroke (C2) of opening the shutter valves of two couplings (7, 8) coupled.  2. Device according to claim 1, characterized in that the end piece (38) of each male connector (7) is tubular and comprises a shutter valve (39), spring return, while each female connector (8 ) comprises, at its bottom, a shutter valve (54), with spring return, extending into the receiving cavity of the male connector, by an axial pusher (60) suitable, during the engagement of the nozzle (38) of the male connector in the end piece (16) of the female connector, coming into contact with the valve (39) of the male connector to bring it into the open position.  3. Device according to any one of claims 1 and 2, characterized in that, when it is in the closed position, the shutter valve (39) of the end piece (38) of the male connector (7) comes at least at the lower end of this nozzle to eliminate any air pocket formation.  4. Device according to any one of claims 1 to 3, characterized in that the end piece (16) of each female connector (7) has an axial bore (48), for receiving the end piece of the male connector, this bore being associated with a seal (49) capable of cooperating with the male end piece (38) and, in the extension of this bore (48), a bore (50) which, opening out to the outside, has a larger diameter to form, with the male end piece (38), an annular chamber (52) of hydrodynamic ejection.  5. Device according to any one of claims 1 to 4, characterized in that the piston (22) is locked in rotation in the tank (14) by an eccentric finger (30) which, projecting from its underside, is mounted sliding in a vertical well (35) opening into the bottom of the tank.  6. Device according to claim 5, characterized in that the vertical well (33) is connected, by a pipe (34), to an expansion tank (35).  7. Device according to any one of claims 1 to 6, characterized in that the hydraulic fluid (15) contained in the tank (14) is of the same nature as that of the hydraulic circuit whose connection must be ensured.