FR2705423A1 - Distributor for fluid, especially pneumatic, of the flat spool and flat plate type - Google Patents

Abstract

The invention relates to a distributor for fluid, especially pneumatic, in a fluid supply system. The distributor is of the type with switching provided by a device with a flat spool (1) in sealed sliding contact over a distributor element in the form of a flat plate (2) provided with fluid inlet and outlet orifices (11-15), this spool comprising cells (17, 18) for establishing communication paths between the orifices of the plate and thus paths for supplying the system through the distributor, and being mounted so that it can move in a hollow body, the spool being pressed against the plate by a force generated by the fluid to be distributed let into a pressurising chamber (4) inside the body (13) above the spool (1). The distributor is characterised in that it includes means for bringing the pressurising chamber (4) into communication exclusively with the orifice (11-15) receiving the fluid with the highest pressure when several orifices are being fed. The invention can be used for pneumatic fluid distributors.

Description

 The invention relates to a fluid distributor, in particular pneumatic, arranged in a fluid supply system, of the switching type provided by a plane drawer device in leaktight sliding contact on a distributor element in the form of a glass provided with '' fluid inlet and outlet ports, this drawer comprising cells for establishing communication channels between the orifices of the glass, and thus for supplying the system through the distributor, and being mounted movably in a hollow body, the drawer being applied to the glass by a force generated by the fluid to be dispensed admitted into a pressurization chamber inside the housing, above the drawer.

 Fluid distributors of this type are already known, but have the drawback of not being usable in application cases where there is switching of fluids subjected to different pressures, including pressures below atmospheric pressure . In these known distributors, the supply is generally made exclusively through the central main orifice of the glass, which excludes any supply through other orifices.

 The object of the present invention is to propose a dispenser which does not have the disadvantage of known dispensers, which has just been described.

 To achieve this object, the fluid distributor according to the invention is characterized in that it includes means for placing the pressurization chamber in exclusive communication with the orifice receiving the fluid having the highest pressure, when several orifices are powered.

 According to an advantageous characteristic of the invention, each possible supply path is connected by a channel to the pressurization chamber and each channel is provided with a non-return valve device.

The invention will be better understood and other objects, characteristics, details and advantages thereof will appear more clearly in the explanatory description which follows, given with reference to the appended schematic drawings given solely by way of example illustrating an embodiment of the invention and in which:
FIG. 1 is a view in axial section of a fluid distributor according to the invention,
- Figure 2 is a sectional view along line II-II of Figure I
- Figure 3 is a bottom view of the dispenser according to Figure 1;
- Figure 4 is a sectional view along the line IV-IV of Figure 1;
- Figure 5 is a top view of a specific seal of the invention;
- Figure 6 is a sectional view along line VI-VI of Figure 5;
- Figures 7 to 9 are three views in axial section of a dispenser according to the invention and illustrate in three phases the switching process controlled by a self-powered solenoid valve.

 FIG. 1 shows the general structure of a pneumatic fluid distributor switched by a plane drawer device in sealed sliding contact on a distributor element such as a window. In the figure, the drawer and the glass element bear the reference numbers 1 and 2 respectively.

They are integrated into a distributor body 3, which is hollow and has a pressurization chamber indicated at 4. The body has a generally parallelepiped shape and comprises on its underside a recess in which is mounted a sole 6 by which the distributor is placed on a base not shown and on which is disposed the ice-forming element 2, with the interposition of a seal 7 made of an elastomeric material, an advantageous embodiment of which is shown in FIG. 5. The drawer 1 is movable axially between its different switching positions by a translational drive device 9 which can be controlled in any suitable manner known per se, either by piloting by manual control, or by internal piloting (self-supply) or external, with or without solenoid valve or logical component. The drawer 1 is advantageously made of a self-lubricating plastic material. The glass is preferably made of ground ceramic.

 Since the general structure is known, only the aspects of this structure which are of interest in the context of the present invention will be described in more detail.

 Thus, it can be seen that the glass-forming element 2 has several orifices, namely a central orifice 1 1 and, on either side of it, orifices 12 and 13, on the one hand, and 14 and 15, on the other hand. These orifices have the form of through slots which extend perpendicular to the axis of the distributor and are offset in the axial direction of the latter. Each orifice communicates through an appropriate orifice made in the sole 6 with the outside. The holes in the sole bear the corresponding references 11 'to 15' respectively. The flat drawer 1 comprises two cells 17, 18 which are arranged so as to be able to establish different fluid supply paths through the distribution glass 2, by placing the appropriate orifices in the ice in communication.

 It can also be seen that the distributor body 3 comprises chambers 20 and 21 at the ends of the drive device 9 of the drawer 1, which can be used as control chambers of the device 9 to print the axial switching movements thereon. . For an external pneumatic piloting, an external piloting channel 23 is practiced in the body 3 which opens at one end towards the outside through a light 24 and at its other end at 25 at the level of the upper surface of the body 3.

The opening 25 can be brought into communication by any suitable means with a channel 26 in the body 3, which opens into an annular space 27 communicating with the pilot chamber 20 in the example shown of a distributor of the bistable type. A pilot selector joint 30 is provided for the communication of the channels 25 and 26 in view of an external or internal piloting according to its position.

 So that the distributor can be controlled by a self-supplied valve, indicated diagrammatically at 31, the pressurization chamber 4 communicates through an annular space 32 with a channel 33 which opens at 34 at the level of the upper face of the body 3 This channel 23 can be put in communication by the solenoid valve 31 with the channel 26 which is in communication with the piloting chamber 20, as will be explained in more detail below, with reference to FIGS. 7 to 9.

 A major feature of the invention resides in the possibility offered by the dispenser according to the invention, of being able to be supplied either by the main central orifice 11, or by one or the other of the orifices 13 and 15, etc. .. This allows switching of fluids subjected to different pressures, including pressures below atmospheric pressure.

 To ensure such universal use, the dispenser is designed so as to put the pressurization chamber 4 in communication with the orifice of the glass 2, which contains the fluid having the highest pressure.

 To this end, each of the supply channels achievable by the distributor, by appropriate switching of the drawer 1, is connected by a channel 36 to the pressurization chamber 4, as shown in FIG. 6, each channel being provided with a device for non-return valve 37. The channel is located next to the orifices, for example 1 1 and 11 'in FIG. 4, and opens into the orifice 11'. The movable member 38 of the valve can be pushed back onto a stop element 39. The movable member 38 being thus spaced from its seat 40, the fluid can reach the pressurization chamber 4. The rise in pressure in this chamber ensures, on the one hand, the plating of the drawer 1 on the glass 2 by difference in sections, and on the other hand, the closing of the valves provided in the communication channels with the other channels, by difference in pressures. It is easily understood that in the case where several pressure signals appear simultaneously, the channel subjected to the highest pressure is that which ensures the function of plating the drawer and the isolation of the chamber 4 from the other channels.

 FIG. 5 shows an advantageous embodiment of the various non-return devices, which are incorporated into the seal 7 interposed between the glass 2 and the sole plate. We note the presence of three non-return valve devices 37 arranged so as to be able to be placed in channels 36 which communicate directly with the orifices 15 ', 11' and 13 'of the sole 6. The movable element 38 of each valve device 37 is mounted coaxially on an external annular support 40, by means of three flexible radial connecting lugs 41 arranged angularly equidistant between the member 38 and the support 40. The latter is integral with the seal 7 and is located in the plane thereof. It can also be seen that seals 43 for the external control channels 23 are associated with the seal 7. Each seal 43 is connected to the seal 7 by a flexible tab 44.

 Referring to FIGS. 7 to 9, the piloting of the distributor will be described below by a self-powered solenoid valve 31. FIG. 10 schematically shows the distributor in the state before piloting. The channel 33 in communication with the pressurization chamber 4 is connected to an internal channel 46 of the solenoid valve which is closed by the valve 47 thereof. When the coil indicated at 48 of the solenoid valve is energized, the valve 47 is raised so that the channel 46 can communicate with the channel 26 and thus with the control chamber 20 of the distributor. The fluid thus withdrawn from the pressurization chamber creates an imbalance on the valve device 37 subjected to the highest pressure, which then frees the passage until a new pressure balance is obtained. The passage sections in the valves being greater than the section of the supply port of the solenoid valve, the compensation is instantaneous and the seal is maintained on the plane of the glass. FIG. 9 shows the position of the distributor after the Em of the piloting, the coil 48 no longer being excited, and the piloting chamber 20 is exhausted.

 As indicated above, the distributor according to the invention can be used for switching fluids subjected to different pressures including pressures below atmospheric pressure and thus allows circuit selection applications.

 It is obvious that multiple modifications can be made to the dispensers as shown. In particular, any suitable non-return device, for example free valves such as balls and any other arrangement of the different channels can be envisaged.

Claims (6)

 1. Fluid distributor, in particular pneumatic, in a fluid supply system, of the switching type provided by a plane drawer device in leaktight sliding contact on a distributor element in the form of a glass provided with orifices fluid inlet and outlet, this drawer comprising cells for establishing communication paths between the orifices of the glass and thus for supplying the system through the distributor, and being movably mounted in a hollow body, the drawer being applied to the ice by a force generated by the fluid to be dispensed admitted into a pressurization chamber inside the body, above the drawer, characterized in that it comprises means for placing the communication chamber exclusively in communication pressurization (4) with the orifice (11-15) receiving the fluid having the highest pressure, when several orifices are supplied.  2. Fluid distributor according to claim 1, characterized in that each supply path realizable by switching is connected by a channel (36) to the pressurization chamber (4) and each channel (36) is provided with a device non-return valve (37) arranged so as to be subjected to the differential pressure of the pressures prevailing in the supply path and the pressurization chamber (4).  3. Fluid distributor according to claim 2, characterized in that each non-return device (37) is produced in the form of a free valve such as a ball.  4. Fluid distributor according to claim 2, comprising a static seal (7) between the glass element (2) and a sole element (6) on which the ice element (2) rests, characterized in that the non-return valve devices (37) are integrated into this static seal (7).  5. Fluid distributor according to claim 3, characterized in that the movable member (38) of a non-return valve device (37) is arranged coaxially in an annular support (40) which is integral with the static seal (7 ) and connected to this support (40) by flexible connecting lugs (41) so as to be movable in the axial direction of the support and perpendicular to the plane of the static seal (7).  6. Fluid distributor according to one of the preceding claims, characterized in that it is adapted to be controlled by a solenoid valve (31) self-supplied with the fluid withdrawn from the pressurization chamber (4) and by creation of '' an imbalance on the non-return valve (37) subjected to the highest pressure.