EP0566449A1 - Hydraulic maximum load and pressure compensating valve - Google Patents

Abstract

Hydraulic distributor with pressure compensation including: a body (1) equipped with a movable slide valve (4); a passage (12) in the body for connecting to working orifices (A, B) a distribution chamber (11), associated with the slide valve and capable of being connected selectively to an intake orifice (P) by the moved slide valve; a duct (8) for the line for detecting load combined with means (14) for selecting the highest pressure taken from among the pressure prevailing in the duct and the pressure of the fluid in the distributor; and means (14) for compensating for the pressure which are placed in the passage (12) and are sensitive to the difference between the pressures in the passage and in the duct to generate a fixed pressure drop in the pressurised fluid flowing in the passage towards the working orifices (A, B), the pressure compensation means being combined with means for selecting the maximum pressure so that, if the pressure in the duct is greater than or equal to the pressure of the fluid coming from the slide valve, there is no communication between the passage and the duct and the pressure in the duct retains its value or, if the pressure in the duct is less than the pressure in the fluid coming from the slide valve, a communication is set up between the passage and the duct and the pressure in the duct becomes that of the pressurised fluid. …<IMAGE>…

Description

• - un corps de distributeur ;
• - un tiroir logé dans le corps pour pouvoir y être déplacé longitudinalement pour une transmission sélective d'un fluide hydraulique sous pression vers des orifices de travail prévus dans le corps à partir d'un orifice d'admission du fluide hydraulique sous pression ;
• - un passage dans ledit corps pour relier aux orifices de travail une chambre de distribution, associée au tiroir et apte à être reliée sélectivement à l'orifice d'admission par le tiroir déplacé;
• - un canal de ligne de détection de charge (load sensing) combiné avec des moyens sélecteurs de pression la plus élevée agencés pour établir dans ledit canal la pression la plus élevée sélectionnée parmi la pression régnant dans ledit canal et la pression du fluide sous pression du distributeur ; et
• - des moyens de compensation de pression placés dans ledit passage et sensibles à la différence entre la pression de fluide dans le distributeur et la pression régnant dans ledit canal, afin d'engendrer une chute de pression sensiblement fixe dans le fluide sous pression s'écoulant en direction des orifices de travail.

The present invention relates to improvements made to hydraulic distributors combining pressure compensation and selection of maximum (or highest) pressure for controlling a supply pump (so-called "load sensing" or "load sensing" system). ") and, more particularly, it relates to improvements made to a hydraulic distributor with pressure compensation, comprising:

• - a distributor body;
• - A drawer housed in the body to be able to be moved longitudinally there for a selective transmission of a pressurized hydraulic fluid to working orifices provided in the body from an inlet port of the pressurized hydraulic fluid;
• - A passage in said body to connect to the working orifices a distribution chamber, associated with the drawer and able to be selectively connected to the inlet orifice by the displaced drawer;
• a load sensing line channel combined with the highest pressure selector means arranged to establish in said channel the highest pressure selected from the pressure prevailing in said channel and the pressure of the fluid under pressure of the distributor; and
• - pressure compensation means placed in said passage and sensitive to the difference between the fluid pressure in the distributor and the pressure prevailing in said channel, in order to generate a substantially fixed pressure drop in the pressurized fluid flowing towards the work orifices.

It will be recalled briefly that the load detection system consists, in a set of distributors controlling respective loads requiring different hydraulic powers, in detecting which of the loads which requires the highest power, and therefore the highest pressure for the fluid. working hydraulic which feeds it, and to bring this highest pressure to a pump control input so as to control the latter as required. This function is carried out by providing, in each distributor, a selector which is sensitive, on the one hand, to the pressure of the working fluid supplied to the load controlled by the distributor and, on the opposite side, to the pressure of the working fluid supplied to another load controlled by a distributor and which is capable of selecting the higher of these two pressures; by selection step by step, it is the highest pressure of the entire hydraulic system that ultimately ensures the control of the pump.

The installation, within distributors, of the means (selectors and connecting channels) necessary for the creation of a load detection system has led to a notable complexity in the structure of the distributors. Simplification solutions have been found for certain types of distributors, but none has been found to date for proportional distributors.

Furthermore, the load detection lines are conventionally supplied by a pressure tap made at the level of the load. At the very start of a distribution phase, the load detection line is supplied first, before the load is. If this detection line has a leak (such a leak can in particular be created voluntarily for certain operating modes of the hydraulic circuit), the control pressure applied to the load begins to decrease before rising to the nominal value imposed by the distributor. It follows that the load (an articulated arm for example) begins to descend before climbing in accordance with the command imposed on it and, in all cases, it occurs suddenly when the normal conditions are restored. This is a real disadvantage of the system, which can be dangerous.

On the other hand, in a conventional hydraulic distributor, the flow rate of the hydraulic fluid delivered by the working orifice of the distributor undergoes fluctuations as a function of its importance determined by the position of the slide and as a function of the pressure supplied by the pump. It is known (for example US 3 827 453) to overcome this drawback and to make the flow rate of the working fluid constant whatever the circumstances by providing in the distributor pressure compensation means which constantly compare the working pressure in source of the pump at a fixed or variable setpoint; in the latter case, it may be the highest pressure selected in the load sensing line, in order to laminate the working fluid accordingly and thus creates a constant pressure drop in this working fluid.

In known distributors (for example US 4,693,272), the presence of these pressure compensation means further adds to the complexity of the structure since said pressure compensation means, although using the most pressure information present in the load detection line, are established independently of the means used for selecting the highest pressure.

In addition, the implementation of this pressure compensation leads in particular to pass part of the necessary hydraulic connections through the slide. Drilling the corresponding conduits in the drawer considerably increases the manufacturing cost thereof. In addition, the presence of these conduits drilled through the drawer clutters the internal volume thereof and it is then no longer possible to provide other useful holes for other purposes, for example. example those required by the implementation of a load braking system. These other systems must then be designed in the form of piped external circuits, which further adds to the complexity and cost of the assembly.

In other known distributors (US 5,138,837, EP 0 438 606), there is certainly an attempt to simplify and integrate the pressure compensation means and load detection means. However, the load detection means remain arranged with a pressure tap located in the line connected to the load: these known distributors therefore always have the drawbacks mentioned above for this type of arrangement.

It can also be added that, in known distributors whose pressure compensation function is provided by a valve returned by a spring, the pilot pressure of the pump differs from the pressure of the pressurized fluid supplied by the pump not only from the value of the pressure drop imposed by the pressure compensation means, but also of the value of the pressure drop which is introduced by the non-return function provided by the valve of the most loaded distributor and which corresponds to the value of the calibration of the valve return spring. Thus, in such an arrangement, the presence of the return spring disturbs the theoretical operation of the system, which proves to be a notable drawback which is particularly noticeable in the range of very low pressures.

The object of the invention is therefore essentially to remedy the drawbacks presented by current hydraulic distributors of the type with pressure compensation and selection of the highest pressure and to propose an improved distributor which better meets the various requirements of the practice, and which in particular is of a simpler structural and constructive technology and therefore of a lower cost, which retains the same operating sensitivity throughout the pressure range, including for very low pressures, and above all which is arranged so that the control of the variable flow pump which feeds this distributor is ensured in a more efficient manner independent of the reactions of the load.

• . si la pression dans le canal est supérieure ou égale à la pression du fluide dans le passage en amont des moyens de compensation de pression, aucune communication n'existe entre ledit passage et ledit canal et la pression dans le canal conserve sa valeur, ou bien,
• . si la pression dans le canal est inférieure à la pression du fluide dans le passage en amont des moyens de compensation de pression, une communication est établie entre ledit passage en amont des moyens de compensation de pression et ledit canal et la pression dans le canal devient celle du fluide présent dans le passage en amont des moyens de compensation de pression.

For these purposes, the invention provides a pressure compensation distributor of the type indicated in the preamble which, being arranged in accordance with the invention, is essentially characterized in that the pressure compensation means are combined with the pressure selector means la higher and in that there are selective connection means capable of selectively establishing a connection between the channel and the passage upstream of the pressure compensation means such that:

• . if the pressure in the channel is greater than or equal to the pressure of the fluid in the passage upstream of the pressure compensation means, no communication exists between said passage and said channel and the pressure in the channel retains its value, or else ,
• . if the pressure in the channel is lower than the pressure of the fluid in the passage upstream of the pressure compensation means, a communication is established between said passage upstream of the pressure compensation means and said channel and the pressure in the channel becomes that of the fluid present in the passage upstream of the pressure compensation means.

Thanks to the arrangements according to the invention, the combination and mutual integration of the pressure compensation means and the highest pressure selection means leads to a considerable simplification of the internal structure of the distributor by eliminating the particular channels and the specific selector provided so far to constitute the means for selecting the highest pressure and ensuring this selection function. There now remains only a single channel crossing directly (for example in the width direction) the body of the distributor, up to one end of the pressure compensation means. As, moreover, the pressure selection means can be constituted in a very simple structural form as it appears below, one understands all the interest of the improvement brought by the invention both at the level of the manufacturing (much less machining in the body and fewer component parts, therefore much lower manufacturing cost) than in terms of use and maintenance (reduction of possible sources of malfunction, reduction of maintenance).

Above all, the arrangement in accordance with the invention notably improves the operating reliability of the hydraulic system built around the distributor. Indeed, we have seen that the arrangement of the distributor is such that, in the case where the pressure in the distributor is higher than the pressure in the load sensing line channel, communication is established directly between the transmitting passage the pressurized fluid and the channel. In this way, the pressure which reigns in said channel is the pressure of the fluid coming from the pump and a possible leak in the line connected to said channel does not have the unfavorable influence reported above in current devices.

• - un alésage prévu dans le corps et relié, à une extrémité, audit passage en provenance de la chambre commandée par le tiroir et, à son autre extrémité, audit canal de ligne de détection de charge,
• - un plongeur mobile de commande libre de coulisser dans ledit alésage sous l'action des pressions s'exerçant sur ses extrémités opposées,
• - des premiers moyens obturateurs disposés dans ledit passage du fluide sous pression, solidaires dudit plongeur,
• - des seconds moyens obturateurs disposés dans une connexion entre ledit passage de fluide sous pression et ledit canal, solidaires dudit plongeur,
  ledit plongeur étant apte à occuper :
  • . une première position extrême ou position de fermeture double, occupée en l'absence du fluide sous pression, dans laquelle les premiers et seconds moyens obturateurs sont fermés,
  • . un ensemble de positions intermédiaires, occupées lorsque du fluide sous pression est présent dans le passage, la position du plongeur étant déterminée par la différence entre la pression dans le passage et la pression dans le canal alors que celle-ci est supérieure à celle-là, dans laquelle les seconds moyens obturateurs sont maintenus fermés et les premiers moyens obturateurs sont ouverts avec un degré d'ouverture propre à provoquer dans l'écoulement de fluide sous pression une chute de pression prédéterminée,
  • . et une seconde position extrême ou position d'ouverture double, occupée lorsque la pression du fluide dans le passage est supérieure à la pression dans le canal, pour laquelle les premiers moyens obturateurs sont ouverts au maximum et les seconds moyens obturateurs sont eux aussi ouverts en établissant une communication entre ledit passage et ledit canal.

Preferably, in a structurally simple embodiment, the pressure compensation means combined with the maximum pressure selector means comprise

• - a bore provided in the body and connected, at one end, to said passage coming from the chamber controlled by the drawer and, at its at the end, at said load detection line channel,
• a movable plunger for free control of sliding in said bore under the action of pressures exerted on its opposite ends,
• - first shutter means arranged in said passage of the pressurized fluid, integral with said plunger,
• - second shutter means arranged in a connection between said passage of pressurized fluid and said channel, integral with said plunger,
  said plunger being able to occupy:
  • . a first extreme position or double closed position, occupied in the absence of the pressurized fluid, in which the first and second shutter means are closed,
  • . a set of intermediate positions, occupied when pressurized fluid is present in the passage, the position of the plunger being determined by the difference between the pressure in the passage and the pressure in the channel while the latter is greater than that , in which the second shutter means are kept closed and the first shutter means are open with a degree of opening capable of causing a predetermined pressure drop in the flow of pressurized fluid,
  • . and a second extreme position or double opening position, occupied when the pressure of the fluid in the passage is greater than the pressure in the channel, for which the first shutter means are opened to the maximum and the second shutter means are also open in establishing communication between said passage and said channel.

• - la partie dudit passage reliée à la chambre commandée par le tiroir communique avec une extrémité de l'alésage,
• - la partie dudit passage reliée aux orifices de travail s'ouvre radialement dans l'alésage,
• - lesdits premiers moyens obturateurs sont constitués par ledit plongeur réalisé sous forme allongée de manière que
  • . dans sa première position extrême, il obture totalement ladite ouverture du passage,
  • . dans son ensemble de positions intermédiaires, il obture partiellement ladite ouverture pour créer la chute de pression prédéterminée
  • . et dans sa seconde position extrême, il dégage au maximum ladite ouverture.

In a particular embodiment, it is advantageous that:

• - the part of said passage connected to the chamber controlled by the slide communicates with one end of the bore,
• the part of said passage connected to the working orifices opens radially into the bore,
• - Said first shutter means are constituted by said plunger produced in elongated form so that
  • . in its first extreme position, it completely closes said opening of the passage,
  • . in its set of intermediate positions, it partially seals said opening to create the predetermined pressure drop
  • . and in its second extreme position, it releases said opening as much as possible.

• . quand le plongeur est dans sa première position extrême et dans son ensemble de positions intermédiaires, le débouché radial dudit conduit soit obturé par l'alésage et
• . quand le plongeur est dans sa seconde position extrême, le débouché radial dudit conduit soit sorti de l'alésage et en communication avec ledit canal.

In the latter case, provision may be made for the second obturating means to be constituted by said plunger provided with an internal conduit opening, on one side, into the face of the plunger subjected to the action of the pressure of the fluid in the passage and , on the other side, radially in the vicinity of the other face of the plunger which is subjected to the pressure of the channel, so that:

• . when the plunger is in its first extreme position and in its set of intermediate positions, the radial outlet of said duct is closed by the bore and
• . when the plunger is in its second extreme position, the radial outlet of said conduit is out of the bore and in communication with said channel.

In a simple embodiment, the pressure compensation means and the maximum pressure selection means, combined together, are unique and selectively connectable to the two working orifices.

However, it is also possible, at least for certain specific applications for which the previous arrangement cannot be adopted and which require complete independence of the two hydraulic paths leading respectively to the two working orifices of the distributor, that the means of pressure compensation and the maximum pressure selection means, combined together, are double and associated respectively with the two working orifices.

To eliminate the influence of an overpressure in the working orifice, a non-return valve can be provided in the above passage, between the pressure compensation means and each working orifice. It is then possible to provide, depending on the needs and the structure adopted, a single non-return valve in the above passage, between the pressure compensation means and a working orifice, or two non-return valves in the above passage , between the pressure compensation means and respectively two working orifices.

It is desirable to return the plunger to a predetermined position when it is not subjected to any pressure, and for this it is provided that the pressure compensation means combined with the maximum pressure selector means further comprise elastic return means acting on the movable plunger in a direction identical to the direction of action of the pressure prevailing in the channel: in the absence of pressure, the plunger is thus held in abutment by its head against a corresponding retaining shoulder.

Thanks to the means used in the context of the invention, it can be seen that all of the fluid connections can be provided in the body of the dispenser alone and that it is not necessary to provide certain connections through the drawer like this. was at otherwise the case so far in distributors of the prior art. The elimination of these specific machinings makes it possible to reduce the costs of manufacturing the drawer or, at the very least, leaves space available to equip the drawer with connections provided for other purposes, in particular to provide additional functions which are not of interest not selecting the highest pressure and / or pressure compensation.

• - de plusieurs distributeurs hydrauliquea agencés conformément à l'invention tels que décrits plus haut,
• - d'un élément terminal,
• - et d'un élément d'entrée qui est transparent pour les lignes P et T des distributeurs empilés reliés respectivement à la sortie sous pression de la source et au réservoir de retour,
  • qui comporte un régulateur de débit de décompression à débit nul interposé entre une ligne de commande de la source par détection de charge issue des distributeurs empilés et la ligne de retour,
  • et qui comporte un gicleur interposé entre la ligne de commande de la source par détection de charge issue des distributeurs empilés et l'entrée de commande de la source, ce gicleur étant agencé pour créer une chute de pression aux bornes du plongeur de chaque distributeur ; avantageusement, dans un tel circuit, entre la sortie de second gicleur et la ligne de retour est interposé un circuit limiteur de la pression de commande de pompe par détection de charge apte à limiter ladite pression de commande lorsque la pompe fournit sa pression maximale.

The invention also provides a multiple hydraulic control device interposed between a source of fluid under pressure with variable flow rate and a return tank, on one side, and several hydraulic load members to be controlled respectively and selectively from said source. . In a first possible embodiment, this device comprises a side-by-side stack

• several hydraulic distributors arranged in accordance with the invention as described above,
• - a terminal element,
• - and an input element which is transparent for the lines P and T of the stacked distributors connected respectively to the pressure outlet of the source and to the return tank,
  • which includes a zero flow decompression flow regulator interposed between a source control line by load detection from the stacked distributors and the return line,
  • and which comprises a nozzle interposed between the source control line by load detection from the stacked distributors and the source control input, this nozzle being arranged to create a pressure drop across the terminals of the plunger of each distributor; advantageously, in such a circuit, between the output of the second nozzle and the return line is interposed a circuit limiting the pump control pressure by load detection capable of limiting said control pressure when the pump supplies its maximum pressure.

• - de plusieurs distributeurs hydrauliques agencé comme indiqué plus haut, chaque distributeur comportant un gicleur interposé entre le canal de ligne de détection de charge et la chambre de distribution, ce gicleur étant rendu fonctionnel lorsque une communication est établie entre le passage et le canal et étant agencé pour créer une chute de pression aux bornes du plongeur du distributeur,(
• - d'un élément terminal,
• - et d'un élément d'entrée qui est transparent pour les lignes P et T des distributeurs empilés reliés respectivement à la sortie sous pression de la source et au réservoir de retour, et
• qui comporte un régulateur de débit de décompression à débit nul interposé entre une ligne de commande de la source par détection de charge issue des distributeurs empilés et la ligne de retour.

In another possible embodiment, this device comprises a side-by-side stack

• - Several hydraulic distributors arranged as indicated above, each distributor having a nozzle interposed between the load detection line channel and the distribution chamber, this nozzle being made functional when communication is established between the passage and the channel and being arranged to create a pressure drop across the distributor plunger, (
• - a terminal element,
• - And an input element which is transparent for the lines P and T of the stacked distributors connected respectively to the pressurized outlet of the source and to the return tank, and
• which includes a zero flow decompression flow regulator interposed between a source control line by load detection from the stacked distributors and the return line.

• - la figure 1 est une vue en coupe d'un distributeur hydraulique agencé conformément à l'invention, le tiroir dudit distributeur étant disposé en position neutre ou inactive ;
• - la figure 2 est une vue en coupe d'une variante de réalisation du distributeur de la figure 1 ;
• - les figures 3 et 4 sont des vues en coupe du distributeur de la figure 1 montrant celui-ci respectivement dans deux autres positions fonctionnelles différentes ;
• - la figure 5 est une vue en coupe d'encore une autre variante d'un distributeur hydraulique agencé selon l'invention ;
• - la figure 6 est un schéma illustrant un exemple de constitution d'un circuit de commande hydraulique multiple incluant des distributeurs conforme à l'invention;
• - la figure 7 est un schéma illustrant un autre exemple de constitution d'un circuit de commande hydraulique multiple incluant des distributeurs conformes à l'invention; et
• - la figure 8 est une vue à plus grande échelle d'une partie du distributeur agencé en vue de son incorporation dans le circuit de la figure 6.

The invention will be better understood on reading the following detailed description of a preferred embodiment given solely by way of purely illustrative example. In this description, reference is made to the appended drawings in which:

• - Figure 1 is a sectional view of a hydraulic distributor arranged in accordance with the invention, the drawer of said distributor being disposed in neutral or inactive position;
• - Figure 2 is a sectional view of an alternative embodiment of the dispenser of Figure 1;
• - Figures 3 and 4 are sectional views of the dispenser of Figure 1 showing it respectively in two other different functional positions;
• - Figure 5 is a sectional view of yet another variant of a hydraulic distributor arranged according to the invention;
• - Figure 6 is a diagram illustrating an example of constitution of a multiple hydraulic control circuit including distributors according to the invention;
• - Figure 7 is a diagram illustrating another example of constitution of a multiple hydraulic control circuit including distributors according to the invention; and
• FIG. 8 is a view on a larger scale of a part of the distributor arranged for its incorporation into the circuit of FIG. 6.

Referring first to FIG. 1, the distributor which is represented therein comprises a body 1 provided with an orifice P for admission of the pressurized fluid (constituted in the form of a channel 2 passing through the body 1 transversely to the drawing plane and opening onto the two main faces of said body serving as support during stacking side by side and one against the other of several distributors), of at least one orifice T (formed in the form a channel passing through the body 1 transversely to the plane of the drawing and emerging on the two main faces of said body) for the return of the fluid to a reservoir (not shown), two orifices A, B for connection to a hydraulic device or component ( not shown), and a drawer 4 capable of sliding in a bore 5 of the body 1; the bore 5 passes longitudinally through the body 1 and opens onto two opposite faces, or end faces 6, 7 thereof. Conventionally, the body 1 and the drawer 4 have passages and / or pipes and / or grooves arranged so as to cooperate in order to establish the desired connections or closings of the various orifices of the body of the dis tributor according to the position occupied by the drawer. The arrangements specific to the invention of these passages and / or pipes and / or grooves will be indicated below.

In addition, the body 1 comprises yet another transverse channel 8 extending between the main faces of the body and combined with at least one pressure selector making it possible to transmit, in the channel 18 downstream of the distributor, the highest (pressure " load sensing "or pressure LS) of the two pressures constituted respectively by the pressure upstream of the distributor and a working pressure of the distributor. At each end, the channel 8 opens into a cavity, hollowed out in the corresponding main face of the body (a cavity 9 is visible in Figure 1). The positioning of the cavities on the main faces is such that, when stacking two distributors face to face, the cavity 9 provided on a main face of one and the cavity provided on the main cooperating face of the other cooperate to constitute a chamber in which is housed a seal (not shown), whereby said channel 8 passes right through the control block consisting of a stack of several distributors regardless of the number of these. The principle of the general operation of such a highest pressure selector is well known to those skilled in the art and will not be repeated here.

The channel 2 connected to the intake orifice P opens into the bore 5 of the body in an intake chamber 10 thereof, near which another comunic chamber 11, through a passage 12, with a housing 13 in which a plunger 14 is mounted in free sliding movement. The passage 12 opens into the housing 13 at one end thereof (corresponding to an end face of the plunger 14), while at its opposite end the housing 13 opens into a cavity 15 into which the head 16 of the plunger 14 can move. The head 16, enlarged relative to the body of the plunger, bears on a shoulder formed at the outlet of the housing 13 in the cavity 15 to retain the plunger 14 A spring 17 can be provided in the cavity 15 to push the plunger 14 against said shoulder so as to fix its position in the absence of pressure. The aforementioned channel 8 is in communication with the cavity 15, so that the pressure prevailing in the channel 8 is also present in the cavity 15 and is then exerted on the corresponding end of the plunger 14.

In addition, the plunger 14 is traversed by an axial channel 18 opening on one side in its end face opposite the passage 12 and on the other side in a diametral channel 19 passing through the plunger 14 and arranged so as to be closed by the wall of the housing 13 when the plunger 14 is in the rest position imposed by the spring 17 (shown in Figure 1) or in a position not fully raised as will appear below.

The portion of the drawer 4 which extends, in neutral position, between the chambers 10 and 11 by isolating them from one another is provided with progressivity notches 20 intended to ensure a controlled flow of the hydraulic fluid in the direction suitable when the drawer is moved in one direction or the other.

From the aforementioned housing 13 extend for example in two approximately diametrically opposite directions, two conduits 21 in each of which is arranged if necessary a non-return valve 22, the two conduits 21 opening into the bore 5 in two respective chambers 23 .

Of course, other arrangements are possible in this context. By way of example, FIG. 2 shows a variant according to which a single conduit 21 is provided from the housing 13, with a single non-return valve 22 beyond which the conduit 21 splits into two branches 21a, 21b, joining the two chambers 23 respectively.

Near the chambers 23, two respective distribution chambers 24 of the bore 5 are joined, by conduits 25, to the respective working or outlet orifices A and B.

Finally, beyond the distribution chambers 24, respectively two return chambers 26 of the bore 5 are connected, by conduits 27, to the return channel 3 opening onto the return orifice T.

The operation of the dispenser which has just been described is as follows.

It will be assumed, for this explanation, that the distributor is part of a multiple control block constituted by a stack, face to face, of several identical distributors (an exemplary embodiment will be given below), in which the orifices P, T and 9 provided on the main faces communicate with each other; in particular, the channels 8 constitute a line for transmitting the highest pressure (“load sensing” line or LS line) which is connected to a control input of a variable flow pump (not shown), the output of which pressure is connected to ports P.

The slide 4 being in neutral position as shown in FIG. 1, all the chambers of the bore 5 are isolated from each other and no fluid flows between the orifices P, T, A and B. The plunger 14 is then pushed back, by the spring 17, in the support position on its head, closing the conduits 21, whatever the respective pressures prevailing in the passage 12 and the cavity 15 (pressure LS).

When the slide is moved gradually (for example to the left, Fig. 3), the hydraulic fluid coming from the orifice P flows, with a pressure drop, through the progressivity notches 20 in the passage 12 in which the pressure gradually increases. As long as the force due to the pressure prevailing in the passage 12, acting on the underside of the plunger 14, remains less than the sum the setting force of the spring 17 and the force due to the pressure LS in the cavity 15 which are exerted on the upper face of the plunger 14, the plunger 14 remains in the same position. As soon as the pressure in passage 12 becomes greater than the pressure exerted on the other face of the plunger (spring setting and pressure LS), the plunger begins to move (upwards in the drawing) as shown in the Figure 3, to come into a new equilibrium position in which the pressure in the passage 12 is equal to the pressure LS increased by the force of the calibration spring. The plunger then partially clears the inlet of the conduit 21 and the fluid flows by this path, undergoing a constant pressure drop whatever the flow rate and regulated by the difference between the intake pressure and the LS pressure. The non-return valve 22 (the one located on the right in FIG. 3 in the example considered) opens and the fluid flow is routed to the orifice B. In this context, the plunger 14 behaves like a valve. (or balance) of traditional pressure regulation.

If the slide 4 is moved and if the pressure LS in the cavity 15 allows it (that is to say if the pressure LS is lower than the maximum pressure in the chamber 12), the pressure in the chamber 12 becomes such that the plunger 14 lifts up as far as possible, clearing the inlet of the duct 21 as much as possible, while the channel 19 of the plunger comes out into the cavity 15. Fluid from the passage 12 then flows, through the channels 18 and 19, in the cavity 15 and, thereby, in the channel 8: the distributor considered thus imposes its control pressure as LS pressure. In this context, the plunger 14 behaves as the highest pressure selector in the control line LS of the pump.

The interest of the distributor arranged in accordance with the invention is due both to the structural simplification which it represents (the same plunger serves both as pressure compensator and pressure selector for the LS line, while two separate elements , corresponding to two separate hydraulic circuits, have been used until now) and the greater control accuracy of the pump that it drives: in fact, in the previous circuits, the pressure LS was taken from the actual working pressure said or charge pressure (for example at the level of the outlets) with the drawbacks exposed at the beginning of this description, while, in the distributor arranged according to the invention, the line LS is supplied by the highest pressure coming from directly from the pump and a possible leak in the LS line no longer has an influence on the load (in particular is no longer likely to cause a descent of the dependent).

In addition, the drawer is simple in design, without internal channels, and its manufacture is made easier and less expensive.

Finally, a distributor arranged according to the invention allows the hydraulic circuit in which it is included to preserve the advantage of a flow division operation which cannot be obtained by the only "load sensing" system, that is to say that in a saturated circuit the speeds of all the receivers are reduced in proportion to the respective bit rates in these receivers and there is therefore a slowdown or immobilization of the receiver having the highest load.

FIG. 5 shows an alternative embodiment of the hydraulic distributor in accordance with the invention, in which the pressure compensation circuit and the selection of the highest pressure are split respectively in correspondence with the two starting circuits A and B. same reference numerals have been used to designate the same members as for the dispenser of FIG. 1; the two cavities 15 are joined to a single LS8 channel. The operation remains identical to what has been described above, except that a single plunger is in operation according to the direction of movement of the slide 4 and depending on whether the departure is made through the orifice A or the orifice B.

FIG. 6 is a diagram illustrating an example of a hydraulic multiple control circuit using a multiple hydraulic control block using a stack of several distributors according to the invention.

The hydraulic control unit comprises a stack of several distributors D _i , D ₂ ..., D _n , the inlet ports P, return port T and pump control LS of which are all joined together by simple watertight juxtaposition of the main faces of the bodies of the distributors, in a manner well known to those skilled in the art. For example, a blind terminal element 28 is mounted at one end of the stack to close the respective conduits P, T and LS of the stack; this terminal element could, for certain applications, be provided with a pressure reducing device (not shown).

An inlet element 29 is transparent for the inlet line P which is connected to the outlet under pressure from a source of pressurized fluid with variable flow rate -which may for example be a variable flow pump Pp as shown in FIG. Figure 6 or even a fixed flow pump with open center valve - and for the return line T which is connected to a tank R.

Furthermore, the line LS is connected, in the input element 29, to the return line T through a first flow regulator such as a nozzle or throttle 30 intended to allow the decompression of the entire device when the flow is zero (i.e. when all the valves are in neutral position).

Finally, the pressure LSp for controlling by load detection intended for the pump is taken from the line LS, upstream of the first nozzle 30, through a second nozzle 31. This nozzle 31 has the function of recreate a pressure drop across the plunger 14 of each of the block's distributors. In the example considered, a single nozzle 31 is placed in the inlet element 29. A limiting valve 32, intended to limit the maximum value of the charge detection control pressure when the pump is operating at its maximum flow rate, is interposed between the line LSp and the return line T.

FIG. 7 is a diagram illustrating another example of a hydraulic multiple control circuit using a multiple hydraulic control block using a stack of several distributors arranged according to the invention. This arrangement differs from that of FIG. 6 by the fact that a nozzle 31 is here provided in each of the distributors, in place of the single nozzle 31 previously housed in the input element 29.

In FIG. 7, the inlet element devoid of the nozzle is designated by the reference 29 ', while the distributors each equipped with a nozzle 31 are respectively designated D' _i , D ' ₂ , ..., D' _n . In each block D ' ₁ , D' ₂ , ..., D ' _n a very simplified representation of the distributor is given, accompanied by the numerical references used in FIG. 1, so as to show the situation of the nozzle 31. The nozzle 31 is interposed between the load detection line channel 8 and the distribution chamber 11; this nozzle is made functional when a communication is established between the passage 12 and the channel 8 by the displacement of the plunger 14 and it is arranged to create a pressure drop lower than the setting of the plunger spring of the distributor which it equips.

FIG. 8 shows an example of installation of the nozzle 31. In this enlarged view showing more particularly the plunger 14, the nozzle 19 is housed in the upper, narrow part of the axial channel 18 drilled in the plunger and connecting the diametral channel 19 drilled in the plunger with passage 12. The adaptation of the distributor for this type of circuit is therefore easy and inexpensive to carry out.

As goes without saying and as it already follows from the above, the invention is in no way limited to those of its modes of application and embodiments which have been more particularly envisaged; on the contrary, it embraces all its variants.

Claims (14)

1. Hydraulic distributor with pressure compensation, comprising: - a distributor body (1); - a drawer (4) housed in the body (1) in order to be able to be moved longitudinally therein for a selective transmission of a hydraulic fluid under pressure to working orifices (A, B) provided in the body from a orifice (P) admission of the hydraulic fluid under pressure; - a passage (12) in said body (1) for connecting to the working orifices (A, B) a distribution chamber (11), associated with the drawer (4) and capable of being selectively connected to the intake orifice (P) by the drawer (4) moved; a load sensing line channel (8) combined with the highest pressure selector means arranged to establish in said channel the highest pressure selected from the pressure prevailing in said channel and the pressure of the fluid under pressure from the distributor; and - pressure compensation means placed in said passage (12) and sensitive to the difference between the fluid pressure in the distributor and the pressure prevailing in said channel (8), in order to generate a substantially fixed pressure drop in the pressurized fluid flowing towards the working orifices (A, B), characterized in that the pressure compensation means are combined with the highest pressure selector means and in that there are connecting means selective capable of selectively establishing a connection between the channel (8) and the passage (12) upstream of the pressure compensation means such that: . if the pressure in the channel (8) is greater than or equal to the pressure of the fluid in the passage (12) upstream of the pressure compensation means, no communication exists between said passage (12) and said channel (8) and the pressure in the channel (8) retains its value, or else, . if the pressure in the channel (8) is lower than the pressure of the fluid in the passage (12) upstream of the pressure compensation means, a communication is established between said passage (12) upstream of the pressure compensation means and said channel (8) and the pressure in the channel (8) becomes that of the fluid present in the passage (12) upstream of the pressure compensation means. 2. Hydraulic distributor according to claim 1, characterized in that the pressure compensation means combined with the maximum pressure selector means comprise a bore (13) provided in the body (1) and connected, at one end, to said passage (12) coming from the chamber (11) controlled by the drawer (4) and, at its other end, said load detection line channel (8), a movable control plunger (14) free to slide in said bore (13) under the action of the pressures exerted on its opposite ends, - first shutter means arranged in said passage of the pressurized fluid, integral with said plunger, - second shutter means arranged in a connection (18, 19) between said passage of pressurized fluid and said channel, integral with said plunger, said plunger being able to occupy: . a first extreme position or double closed position, occupied in the absence of the pressurized fluid, in which the first and second shutter means are closed, . a set of intermediate positions, occupied when pressurized fluid is present in the passage, the position of the plunger being determined by the difference between the pressure in the passage and the pressure in the channel while the latter is greater than that , in which the second shutter means are kept closed and the first shutter means are open with a degree of opening capable of causing a predetermined pressure drop in the flow of pressurized fluid, . and a second extreme position or double opening position, occupied when the pressure of the fluid in the passage is greater than the pressure in the channel, for which the first shutter means are opened to the maximum and the second shutter means are also open in establishing communication between said passage and said channel. 3. Hydraulic distributor according to claim 2, characterized in that: the part of said passage (12) connected to the chamber (11) controlled by the slide (4) communicates with one end of the bore (13), the part of said passage (12) connected to the working orifices (21) opens radially in the bore (13), - Said first shutter means are constituted by said plunger (14) produced in elongated form so that . in its first extreme position, it completely closes said opening of the passage, . in its set of intermediate positions, it partially seals said opening to create the predetermined pressure drop . and in its second extreme position, it releases said opening as much as possible. 4. Hydraulic distributor according to claim 3, characterized in that the second shutter means are constituted by said plunger provided with an internal conduit (18, 19) opening, on one side, into the face of the plunger subjected to the action of the pressure of the fluid in the passage and, on the other side, radially in the vicinity of the other face of the plunger which is subjected to the pressure of the channel, so that: . when the plunger is in its first extreme position and in its set of intermediate positions, the radial outlet of said conduit (19) is closed by the bore (13) and . when the plunger is in its second extreme position, the radial outlet of said conduit (19) is out of the bore (13) and in communication with said channel (8). 5. Hydraulic distributor according to any one of claims 1 to 4, characterized in that the pressure compensation means and the maximum pressure selection means, combined together, are unique and selectively connectable to one of the two orifices of job. 6. Hydraulic distributor according to any one of claims 1 to 4, characterized in that the pressure compensation means and the maximum pressure selection means, combined together, are double and associated respectively with the two working orifices. 7. Hydraulic distributor according to any one of claims 1 to 6, characterized in that at least one non-return valve (22) is provided in the above passage, between the pressure compensation means and at least one orifice of job. 8. Hydraulic distributor according to claim 7, characterized in that it comprises a single non-return valve in the above passage, between the pressure compensation means and a working orifice. 9. Hydraulic distributor according to claim 7, characterized in that it comprises two non-return valves in the above passage, between the pressure compensation means and respectively two working orifices. 10. Hydraulic distributor according to any one of claims 2 to 9, characterized in that the pressure compensation means (14) combined with the maximum pressure selector means (14) further comprise elastic return means (17) acting on the movable plunger (14) in a direction identical to the direction of action of the pressure prevailing in the channel (8). 11. Multiple hydraulic control device interposed between a source of pressurized fluid with variable flow rate (P _P ) and a return tank (R), on one side, and several hydraulic load members to be controlled respectively and selectively from from said source, characterized in that it comprises a side-by-side stack - several hydraulic distributors (D ₁ , D ₂ , ..., D _n ) according to any one of claims 1 to 10, - a terminal element (28), - And an input element (29) which is transparent for the lines P and T of the stacked distributors connected respectively to the pressure outlet of the source (Pp) and to the return tank (R), which comprises a regulator zero pressure decompression flow (30) interposed between a source control line (LS) by load detection from the stacked distributors and the return line (T),
and which comprises a nozzle (31) interposed between the line (LS) for controlling the source by detecting a load from the stacked distributors and the input controlling the source (Pp), this nozzle (31) being arranged to create a pressure drop below the plungers of each distributor. 12. Multiple hydraulic control device interposed between a source of pressurized fluid with variable flow (P _P ) and a return tank (R), on one side, and several hydraulic load members to be controlled respectively and selectively from from said source, characterized in that it comprises a side-by-side stack - several hydraulic distributors (D ₁ , D ₂ ..., Dn) according to any one of claims 1 to 10, each distributor comprising a nozzle (31) interposed between the channel (8) of load detection line and the distribution chamber (11), this nozzle (31) being made functional when communication is established between the passage (12) and the channel (8) and being arranged to create a pressure drop across the distributor plunger, - a terminal element (28), - And an input element (29) which is transparent to the lines P and T of the stacked distributors connected respectively to the pressurized outlet of the source (Pp) and to the return tank (R), and which comprises a zero pressure decompression flow regulator (30) interposed between a source control line (LS) by load detection from the stacked distributors and the return line (T). 13. Multiple hydraulic remote control device according to claim 12, characterized in that, in each distributor, the nozzle (31) is housed in the connection (19) provided inside the plunger (14). 14. Multiple hydraulic remote control device according to any one of claims 11 to 13, characterized in that between the source control input (Pp ₎ and the return line (T) is interposed a circuit (32) source control pressure limiter by load detection capable of limiting said control pressure when the source supplies its maximum pressure.

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