Classifications

• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
  • F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
  • F04B13/00—Pumps specially modified to deliver fixed or variable measured quantities
  • F04B13/02—Pumps specially modified to deliver fixed or variable measured quantities of two or more fluids at the same time
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
  • F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
  • F04B9/00—Piston machines or pumps characterised by the driving or driven means to or from their working members
  • F04B9/08—Piston machines or pumps characterised by the driving or driven means to or from their working members the means being fluid
  • F04B9/10—Piston machines or pumps characterised by the driving or driven means to or from their working members the means being fluid the fluid being liquid
  • F04B9/103—Piston machines or pumps characterised by the driving or driven means to or from their working members the means being fluid the fluid being liquid having only one pumping chamber
  • F04B9/107—Piston machines or pumps characterised by the driving or driven means to or from their working members the means being fluid the fluid being liquid having only one pumping chamber rectilinear movement of the pumping member in the working direction being obtained by a single-acting liquid motor, e.g. actuated in the other direction by gravity or a spring

Definitions

• the invention relates to a differential hydraulic machine, in particular a differential hydraulic motor, of the type comprising:
• a differential piston suitable for sliding in reciprocating motion in the envelope comprising two parts of different diameter adapted to move in two corresponding chambers of one envelope; hydraulic switching means for supplying and discharging the respective chambers, these switching means being driven by the piston and being able to assume two stable positions relative to the piston; control means for a sudden change in the position of the switching means relative to the piston, comprising elastic means suitable for accumulating energy; and trigger means suitable for releasing, at the end of the piston stroke, the energy accumulated by the elastic means, and for causing the abrupt change in position of the switching means, these trigger means comprising thrust means bearing on end of stroke of the piston against fixed stops relative to the casing.
• a differential hydraulic motor of this type is known, for example from EP-B-0255791, or from US-A-5505224, and can be used for a device for injecting an additive into a main fluid.
• the elastic means are constituted by springs of small size relative to the parts constituting the entire mechanism. These springs act transversely to the direction of movement of the piston and require rod-type return means, mounted to rotate about axes of rotation which are generally orthogonal, or at least intersecting, to the lines of action of the forces developed by the springs.
• a hydraulic motor which, according to the variant of Fig.2, comprises elastic means exerting a force along the geometric axis of displacement of the piston.
• the spring is arranged around a rod inside a frame provided, on its longitudinal sides, with teeth cooperating with pinions controlling an eccentric and a link system.
• the arrangement of the spring along the axis of the piston allows a simplification as regards the transmission of the forces exerted by this piston, but the spring remains of reduced size and the whole system is relatively complicated.
• a hydraulic motor comprising a differential piston with reciprocating movement that reverses automatically, in particular for a volumetric metering device.
• the engine does not have locking means controlled so that there is no sequential switching, guaranteeing repeatability and reliability. Locking is essentially hydraulic and switching is only caused by pressure balances generated by direct action on sealing elements. The springs provided in this motor do not directly cause switching.
• EP-A-0 161 614 shows a differential hydraulic motor in which the triggering means comprise rods subjected to the action of elastic means arranged transversely. The change of position of the valves, and the reversal of the movement, occur with the impact of a pin against another part.
• US-A-5,513,963 shows a differential hydraulic motor in which the locking system is passive, that is to say not controlled. The switching is only caused by the direct action of the springs on the sealing elements which end up balancing the holding forces resulting from the locking and from the hydraulic effects. Such a design does not make it possible to accumulate energy greater than that capable of breaking the balance.
• the object of the invention is, above all, to provide a hydraulic machine, in particular a differential hydraulic motor, which is of a simple construction, while having elastic means exerting a force along the geometric axis of displacement of the piston, and which reduce friction caused by the spring load and the guide surfaces.
• a differential hydraulic machine with reciprocating movement in particular a differential hydraulic motor, of the type defined above comprises elastic means exerting a force along the geometric axis of displacement of the piston, and is characterized in that:
• the switching means are carried by a lantern with a side wall coaxial with the piston, driven by this piston but which can take two different stable positions relative to the piston, and the elastic means are arranged outside the lantern and are guided internally by the side wall of this lantern.
• the elastic means comprise a spring coaxial with the lantern and surrounding it.
• the spring is a helical compression spring.
• This spring can thus have a large diameter and a large section of wire, which makes it possible to obtain a great flexibility of operation.
• the large section of the spring wire gives it good resistance to corrosion wear.
• the lantern is guided in its lower part by a cylindrical zone of the differential piston.
• At least one pusher is provided at each axial end of the lantern, the plunger (s) of one end being independent of the plunger (s) of the other end of the lantern, these plungers being in abutment against the elastic means and being retained axially by stops provided on the lantern, which guides the pushers in translation.
• the lower pusher may comprise a diametrical crosspiece provided with a rod coaxial with the piston, projecting from the side opposite to the elastic means.
• the rod sealingly crosses a transverse wall of the piston and abuts, at the end of the lower stroke, against a transverse bar which bears against part of the casing.
• the bar can be slidably mounted in a support linked to the piston.
• the diametrical cross member may be integral with a ring bearing against the lower edge of the lantern, this ring surrounding the side wall of the lantern which has two longitudinal guide openings through which the cross member passes.
• Two diametrically opposite upper pushers are provided and are guided by the lantern, in particular by said longitudinal openings.
• the lantern may include an upper plate provided, inwards, with two diametrically notches opposite in which are engaged and slide the upper pushers.
• the upper plate can be assembled by snap-fastening.
• the switching means advantageously include valves.
• the assembly of the lantern, of the elastic means and of the pushers has an axial symmetry of construction guaranteeing the balance of the various forces involved, and making it possible to reduce the risks of jamming.
• the stable maintenance of the lantern in one of its two positions relative to the piston is advantageously provided by a type of toggle type device with three axes, comprising a link and a trigger.
• the rod is articulated, at one end, on the upper plate of the lantern and at its other end on the trigger; the trigger is itself articulated on a part linked to the piston.
• the trigger comprises two diametrically opposite extensions capable of coming into abutment against a stop linked to the piston, respectively above and below this stop following a rotation of about 180 °, each extension of the trigger being able to cooperate with a projection provided respectively on an upper pusher and a lower pusher to cause the trigger to tilt when the elastic means are under sufficient load.
• Figure 1 of these drawings is a vertical axial section of a differential hydraulic motor according to the invention.
• Figure 2 is a left view, with respect to Figure 1, of engine components located inside the casing, the differential piston not being shown.
• Figure 3 is a section along the line
• Figure 4 is a partial axial section, similar to Figure 1, showing the hydraulic motor in another configuration.
• Figure 5 is a section of the lantern, pushers and elastic means along the line V-V of Figure 6.
• Figure 6 is a top view with respect to Figure 2, the valves being removed.
• Figure 7 is an exploded perspective view of engine components, the differential piston not being shown.
• Figure 8 is a perspective view of the lantern alone.
• Figure 9 is a perspective view of
• Figure 10 illustrates in perspective a particular embodiment of a link for the toggle joint device.
• FIG 11 is a partial section, similar to Fig.4, illustrating a toggle device equipped with the link of Fig.10.
• a hydraulic machine M constituted by a differential hydraulic motor 1.
• This motor comprises a casing 2, or machine body, consisting of an upper part 2a and a lower part 2b tightly assembled.
• the general shape of the envelope 2 is cylindrical of revolution around a vertical axis AA.
• the upper part 2a is closed, at its upper end, by a dome comprising a central opening 3 which, when the engine is running, is closed by a shutter 3a.
• the lower part 2b has an inner cylindrical wall 4 of smaller diameter defining an annular chamber 5 around it, inside 2b.
• This wall 4 further defines a cylindrical interior chamber 6 of smaller diameter than the chamber 7 determined in the upper part by 2a.
• Part 2b has at its lower end a rim 10 surrounding an opening 11.
• the rim 10 serves to support a sleeve 12 axially traversed by a rod 13, partially shown, for driving a mechanism, for example a pump .
• the cylindrical wall of the sleeve 12 has openings 14 for the passage of the liquid.
• a differential piston 15 is able to slide in reciprocating vertical movement in the body 2 of the engine.
• the piston 15 has a large section at the level of the chamber 7 and a smaller section at the level of the chamber 6.
• the differential piston 15 comprises an upper part 15a and a lower part 15b assembled to one another in leaktight manner.
• the 15a comprises an upper flange provided with a sealing lip 16 forming a skirt whose concavity is turned towards the side of the chamber 5.
• the lip 16 slides in leaktight manner against the internal cylindrical surface of the part 2a.
• the flange carrying the lip 16 is connected by a frustoconical part 17, of decreasing section downwards, to a cylindrical part 18 of diameter smaller than that of the chamber 6.
• the part 18 ends with a transverse bottom 19 perpendicular to the axis AA.
• the lower part 15b of the piston 15 is essentially cylindrical open downwards, and closed in the upper part by a transverse wall 20 which is applied sealingly against the bottom 19 to which it is fixed by screws not shown.
• the wall 20 is provided at its periphery with a rim 21 which covers the lower end of the part 15a.
• the lower end of the part 15b is provided, externally, with a lip 22, turned towards the chamber 7, sliding in leaktight manner against the internal surface of the wall 4.
• Hydraulic switching means C (see in particular Fig. 2 and Fig. 9) for the supply of liquid and the evacuation of chambers 5, 6 and 7 are provided. These switching means C can take two stable states. In a first state, corresponding to the representation of FIG. 1, the annular chamber 5 situated below the lip 16 is isolated from the chamber 7 situated above the piston 15. This chamber 7 is then connected to the chamber 6 and at the exhaust 9. The pressurized liquid arriving through the connector 8 causes the piston 15 to move up.
• the switching means C advantageously comprise two diametrically opposed valves 23 (FIG. 2) capable of cooperating with a seat 24 (FIG. 9) provided on the large section of the piston 15.
• Two other valves 25 diametrically opposed, but angularly offset with respect to to the valves 23, are provided to cooperate with seats provided in the walls 19 and 20 of small section of the piston 15.
• valves 23 and 25 close in the opposite direction.
• the valves 23 close by being raised against their seat, while the valves 25 close by being lowered against their seat.
• Compression springs R1, R2 are provided to ensure the application of the respective valves 23,25 against their seat and to compensate for manufacturing tolerances.
• the valves 23, 25 are the preferred solution ensuring a very good seal, the switching means C could be constituted by one or more drawers.
• valves 23, 25 are located in front and behind the plane of Figure 1.
• the switching means C are carried by a lantern 26, or open cylindrical case, clearly visible in Fig.7 and Fig.8.
• the lantern 26 comprises a body with a cylindrical side wall 27, coaxial with the piston, provided at its lower part with a flange 28 projecting radially.
• Two diametrically opposed notches 29 are provided in the lower part, to which correspond, inwards, two projections 30 (Fig.8) substantially semi-cylindrical, diametrically opposite.
• Rectangular openings 31 are provided in the projections 30 to allow the latching of the valves 25 provided, at their upper end, with elastic hooks 32.
• the attachment of the valves 25 to the lantern 26 is provided so as to allow a certain freedom of sliding vertical of the valve to allow the R2 valve spring mentioned above to properly apply the valve against its seat.
• the cylindrical wall 27 of the body has two longitudinal openings 33, diametrically opposite, with vertical parallel edges.
• the openings 33 are offset at a right angle relative to the notches 29, open upwards but are closed at the bottom above the flange 28.
• the wall or body 27 further comprises notches 34 open upwards, diametrically opposite, in the same angular position as the notches 29 but separated from them by a sector 35 of material.
• the body 27 has hooks 36 in the upper part, for example four in number, regularly distributed, having a certain flexibility.
• a plate 37 open in its central part and comprising two diametrically opposite notches 38 suitable for coming into alignment with the openings 33, is provided.
• This plate 37 has a number of rectangular openings 37a equal to the number of hooks 36 for 1 • snap hooks in these openings.
• the front end edge of the wall 27 forms an abutment surface 39 against which the underside of the plate 37 abuts while the hooks 36 are snapped in, as illustrated in Fig. 8.
• the upper valves 23 are provided with elastic hooks 40 (FIG. 7) suitable for snapping into rectangular openings 41, diametrically opposed, provided on a crosspiece 42 comprising, in its central part, a crown 43.
• the plate 37 comprises two columns 44 perpendicular to the plate, diametrically opposite and provided with an axial hole. On these columns 44 slide, respectively, two diametrically opposite housings 45 provided on the crosspiece 42, in the vicinity of the ring 43.
• a spring RI is placed around each column 44 between the plate 37 and the crosspiece 42 According to the representation in FIG. 2, the springs RI tend to lift the cross-member 42 and with it the valves 23 to apply them against their seat.
• a retaining means may be provided at the upper end of the columns 44 to prevent the crosspiece 42 from escaping. It should be noted that before assembling the valves 23 to the crosspiece 42 and to the lantern 26, the latter is first installed in the piston 15, being guided by the cylindrical part 18 of this piston. The valves 23 are placed on the side of the lip 16 of the piston opposite to the crosspiece 42 and their rods provided with the hook 40 are engaged through the seat provided on the piston, then are hooked to the crosspiece 42.
• valves 25 on the other hand are hooked to the lantern 26 before it is placed in the piston 15, the seats of the valves 25 being on the wall 19, 20.
• the lantern 26 is driven by the piston 15 and can take two stable positions relative to this piston.
• a first high position (Fig.l) relative to the piston corresponds to the support of the valves 23 against their seat, while the lower valves 25 are open.
• the second position, or lower position of the lantern (Fig. 4) relative to the piston corresponds to the closing of the valves 25 and to the opening of the valves 23. Maintaining in one or the other of the stable positions of the lantern 26 relative to piston 15 can be provided by any suitable means.
• An advantageous solution for ensuring the stability of one or other of the positions during the stroke of the piston consists of a link mechanism 46 of the toggle type, with three parallel axes of rotation XI, X2, X3, perpendicular to the plane of the Figs. 3 and 5.
• a support 47 is arranged inside the lantern 26 and is fixed, for example by screws, to the transverse walls 19, 20 of the differential piston 15.
• the support 47 consists of two vertical parallel plates 47a, 47b (Fig. .7) separated from each other having a contour substantially in the shape of a rectangular trapezoid; a large vertical side is adjacent to the interior surface of the lantern 26, the edge opposite this large vertical side is inclined.
• the two plates 47a, 47b are connected together, in their upper part, by a horizontal transverse bar 48.
• a trigger or rocker 49 is disposed between the plates 47a, 47b and is articulated on a shaft 50 of geometric axis XI.
• This shaft 50 is carried by two bearings provided in the plates 47a, 47b.
• the axis XI is located in a diametral vertical plane of the lantern 26.
• the shaft 50 is located substantially at the height of the bar 48.
• the trigger 49 has two radial extensions 49a, 49b whose thickness is less than that of the trigger, and which are offset from each other in the direction of the shaft 50.
• a link 51 (Figs. 3, 5 and 7) of a material having a certain elasticity, for example plastic, establishes an articulated connection between the trigger 49 and the plate 37 of the lantern 26.
• the link 51 as clearly visible in Fig.7, has substantially the shape of an inverted U, the two branches 51a, 51b, in the form of a plate, surround the rocker 49. These two branches are connected at their upper end by a bar 52 of narrower width than Branches .
• Each branch has in its upper part, in the vicinity of the bar 52, a circular hole 53 suitable for receiving an anti-friction ring 54 itself traversed by a shaft 55 engaged, from the outside, in a bearing 56 provided on the plate 37.
• Two diametrically opposite bearings 56 and two shafts 55 are provided to cooperate with the two diametrically opposite holes 53.
• Each shaft 55 projects radially inwards to engage in the ring 54 and the corresponding hole 53.
• the outer radial end of the shaft 55 is provided with a rectangular head 57 which comes to lock in a corresponding housing of the plate 37.
• the bearings 56 admit X2 as a geometric axis, parallel to the shaft 50.
• the axis X2 is located in the same vertical diametral plane as the geometric axis XI.
• the two branches of the link 51 further include, towards their lower end, a circular hole 58 to serve as a bearing for a shaft 58a which freely rotates through a circular hole of the rocker 49.
• a ring 58b is provided at each end of the 'shaft 58a in the corresponding hole 58.
• X3 is the geometric axis of the tree 58a.
• Two stable positions of the trigger 49 are determined by the abutment of a part of the extension 49a with the upper face of the bar 48
• X3 is passed on the side of XI opposite to X2.
• the traces of the three axes XI, X2 and X3 still form a flattened triangle, the axis X3 being slightly to the left of the plane passing through X2-X1.
• the lantern 26, and with it the valves, then occupy the low position relative to the support 47 and to the piston 15.
• the upper valves 23 are open while the valves 25 are closed.
• Control means are provided to ensure a sudden change from the position of Fig. 3 to that of Fig .5 and vice versa.
• These control means comprise elastic means E exerting a force along the geometric axis AA of displacement of the piston.
• the elastic means E are arranged outside the cylindrical wall of the lantern 26 and are guided internally by the wall of the body 27 of the lantern 26.
• the elastic means E consist of a single helical spring 59 coaxial with the lantern 26, and suitable for working essentially in compression.
• the large-diameter spring 59 makes it possible to obtain great operating flexibility and contributes to a simple construction.
• the cross section of the spring is relatively large, which improves its resistance to wear and corrosion.
• the axes of these springs would be parallel to the axis A-A but spaced radially from this axis.
• a symmetrical arrangement with respect to the axis A-A of these springs would make it possible to obtain a component along the axis A-A.
• Triggering means D are provided to release, at the end of the stroke of the piston 15, the energy accumulated by the spring 59 and to cause the sudden change in position of the lantern 26 and of the switching means C relative to the piston 15.
• the triggering means D comprise, in the upper part, two upper diametrically opposite pushers 60a, 60b connected to their base by a circular ring 61, and a lower pusher 62 in the lower part.
• the upper pushers 60a, 60b are constituted by vertical branches engaged and guided in the indentations 38 of the plate 37 of the lantern 26.
• the ring 61 passes around the cylindrical wall of the body 27 of the lantern which also serves to guide the assembly.
• the pushers 60a, 60b have projections 63a, 63b radially inwardly which engage in the longitudinal openings 33 of the lantern, also contributing to the guidance.
• the projection 63a provided in the lower part of the pusher 60a extends radially inwards a sufficient distance to cooperate, at the end of the high stroke of the piston 15, with the extension 49b of the trigger 49 (Fig.3) and bring the trigger 49 in the position of Fig. 5.
• the thicknesses are offset so that 63a cannot cooperate with 49a.
• the spring 59 is in abutment against the ring 61 itself in abutment against the underside of the plate 37.
• the lower pusher 62 has a diametrical crosspiece 64 passing through the openings 33 which provide sliding guidance of the pusher 62.
• the crosspiece 64 is integral with a ring 65 surrounding the lower part of the body 27 of the lantern 26, and taking axial support against the flange 28.
• Significantly semi-circular openings (FIG. 7) exist between the diametrical walls of the crosspiece 64 and the interior contour of the ring 65, allowing the passage of the plates 47a, 47b of the support 47.
• the cross-member 64 is provided with a rod 66, coaxial with the piston 15, projecting from the side opposite the spring 59.
• the rod 66 crosses in a sealed manner, by virtue of an O-ring, a central opening of the walls 19, 20.
• the bar 67 is slidably mounted in a retaining part 69 fixed to the piston 15 under the wall 20.
• the bar 67 has, on each of its long sides, a rib 70 parallel to the axis AA, suitable for sliding in a groove (not shown) provided in the part 69
• the cross-member 67 rests on the bottom of the housing of the part 69 at a certain distance from the lower end of the rod 66.
• the bar 67 bears on the wall 68 and ceases to descend while the piston 15 can continue its stroke so that the rod 66 comes into abutment against the bar 67.
• the crosspiece 42 comprises, towards each of its ends, a cylindrical ring 42d suitable for engaging with reduced clearance around the corresponding column 15d.
• the two rings 42d are located on either side of the crosspiece 42.
• Elastic means J (FIG. 5) are provided to recall the link 51 of the toggle mechanism in a locking position for which the axes XI, X2, X3 are not coplanar. According to the representation of FIG. 5 the link 51 is subjected, by the elastic return means J schematically shown, to a torque tending to rotate it clockwise around the shaft 55.
• the elastic means J may be constituted by a means of traction or compression disposed between a point of attachment on the link 51 and a point of attachment fixed to the plate 37 of the lantern, or by a bending spring such as a substantially straight pin extending diametrically and taking support from one side against two pawns diametrically opposite, integral with the plate 37 and, on the other side, in its middle part against a pin projecting upwards on the link 51.
• the crosspiece 64 of the lower pusher has on one side a projection 64a upward capable of cooperating with the extension 49a of the rocker 49 during the descent of the piston 15.
• the thicknesses are offset so that 64a cannot cooperate with 49b.
• the thickness offsets as well as the section plane offsets explain why 64a appears in FIG. 5 but not in Fig. 3.
• valves 23 are closed, the crosspiece 42 occupying a high position relative to the lantern 26.
• the chamber 5 is isolated from the chamber 7.
• the lower valves 25 are open and the chamber 7 communicates with the chamber 6.
• the pressurized liquid arriving through the chamber 5 pushes the piston 15 upwards along its large annular section, while the liquid from the chamber 7 is discharged towards the chamber 6 and the exhaust 9.
• the pushers 60a, 60b are retained by the plate 37 against the action of the spring 59, while the lower pushbutton 62 is retained by the flange 28 of the lantern 26.
• the upper end of the pushers 60a, 60b Towards the end of the upward stroke of the piston 15, the upper end of the pushers 60a, 60b abuts against the internal surface 3b of the dome of the envelope. The pushers 60a, 60b are stopped in their upward stroke but the piston 15 continues to rise. The spring 59 is then compressed by the pushers 60a, 60b, against the lower pushbutton 62. The upper plate 37 of the lantern continues to rise and moves away from the base of the upper pushers.
• the spring 59 can relax by causing the rotation of about 180 ° in the clockwise direction of the rocker 49 which comes to bear by its extension 49b under the bar 48 in the position of Fig .5.
• the lantern 26 and the switching means C have passed into the second stable position, namely the low position, relative to the differential piston 15.
• the ring 61 is again in abutment against the plate 37.
• the valves 23 are open while the valves 25 are closed.
• the piston 15 starts again for an upward stroke.
• the invention makes it possible to use a compression spring 59 of large diameter which provides great operating flexibility and a simple construction. The engine efficiency is improved and the shocks during switching are reduced resulting in quieter operation.
• FIGS. 10 and 11 illustrate an alternative embodiment of a link 151 for the three-axis toggle joint system. XI, X2, X3.
• the link 151 is made in one piece from an elastic material specified below.
• This link 151 comprises a substantially U-shaped central part, the horizontal transverse lower branch 151a of which is provided to constitute the articulation shaft of the rocker 49.
• this horizontal branch 151a is connected to a sort of arch 151b, 151c substantially in an arc located in a plane orthogonal to the branch 151a.
• the arches 151b, 151c are parallel. Their arcuate shape allows them a flexural deformation and these hoops can then exert substantially vertical traction and compression forces, to allow the passage from the position where the traces of the three axes XI, X2, X3 are aligned.
• the arches 151b, 151c are extended, at their upper end, by horizontal segments 151d, 151e curved outwards and parallel to the branch 151a.
• segments 151d, 151e have a certain elasticity in torsion around their geometric axis X2 so as to exert a return on the branches 151b and 151c (and on the branch 151a) in rotation around the axis X2 in a non-coplanar position of the axes XI, X2, X3 corresponding to a locking position.
• the segments 151d, 151e are extended by other segments 151f, 151g curved at right angles to the side opposite the arches, parallel to each other, and orthogonal to the branch 151a.
• the ends of these segments 151f, 151g can be embedded in a part K integral with the lantern 26, this part K possibly being, for example, the plate 37.
• an auxiliary opening 153 communicating with the previous one to pass the different bends of the link 151 through the rocker 49 and to bring finally the branch 151a in the opening 152.
• the link 151 performs both the function of the link 51 and the function of the elastic means J of FIGS. 1 to 9.
• the link 151 is advantageously made with longitudinal fibers with high mechanical strength, for example glass fibers, juxtaposed, parallel to each other and embedded in a plastic matrix.
• the longitudinal fibers provide elasticity in tension and compression in the vertical direction, at the level of the arches 151b, 151c.
• segments 151d, 151e torsional elasticity is provided by the plastic matrix.
• the link 151 in Fig. 10 simplifies the locking system of the toggle type shown in Fig. 11.
• the advantages of the realization of Figs. 1 to 9 are kept in the device of FIG. 11.

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• Engineering & Computer Science (AREA)
• Mechanical Engineering (AREA)
• General Engineering & Computer Science (AREA)
• Hydraulic Motors (AREA)
• Reciprocating Pumps (AREA)
• Retarders (AREA)
• Motor Power Transmission Devices (AREA)
• Actuator (AREA)
• Fluid-Pressure Circuits (AREA)

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• 1999
  • 1999-02-09 FR FR9901482A patent/FR2789445B1/fr not_active Expired - Fee Related
• 2000
  • 2000-01-20 ES ES00900619T patent/ES2202036T3/es not_active Expired - Lifetime
  • 2000-01-20 EP EP00900619A patent/EP1151196B1/de not_active Expired - Lifetime
  • 2000-01-20 DE DE60004168T patent/DE60004168T2/de not_active Expired - Lifetime
  • 2000-01-20 US US09/913,065 patent/US6684753B1/en not_active Expired - Fee Related
  • 2000-01-20 PT PT00900619T patent/PT1151196E/pt unknown
  • 2000-01-20 AT AT00900619T patent/ATE246314T1/de active IP Right Revival
  • 2000-01-20 DK DK00900619T patent/DK1151196T3/da active
  • 2000-01-20 JP JP2000598772A patent/JP2002536592A/ja active Pending
  • 2000-01-20 WO PCT/FR2000/000116 patent/WO2000047895A1/fr active IP Right Grant

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