EP3499033A1 - Hydraulic pump with crimped spheres - Google Patents

Abstract

Hydraulic pump comprising a plurality of spheres fixed to the plate, each sphere being linked by crimping to a piston which slides in a bore machined in the barrel of the pump. The spheres are mechanically fixed on the pump plate.

Description

The present invention relates to a hydraulic piston pump.

It is known piston pumps adjustable in the direction of rotation, which can rotate either in right rotation or left rotation depending on the PTO to which the pump is confronted. In such piston pumps, the dispensing ice is symmetrical so that the discharge zone of the pump can become an intake zone and vice versa. Likewise, the orifices of the distribution yoke are symmetrical in order to be able to receive either an inlet connection or a discharge connection.

Such pumps are illustrated for example in FR3012181 .

In such an arrangement, the performance of the pump is sacrificed to allow the choice of the direction of rotation. Indeed, in use, the suction port being of the same size as the discharge port, because of the symmetry, the suction port then creates a pressure drop at the suction of the pump. This loss of load is detrimental to the performance of the pump. In particular, it reduces the possibility of using the pump at a high rotational speed.

Piston pumps are also known in which the pistons have spherical piston heads and the plate has machined housings. The machined housings have a truncated spherical shape. The spherical head has a circular flattened at a large circle perpendicular to the axis of the piston, so that it is possible to penetrate the spherical head in its machined housing when the axes of the head and the housing coincide and that it is no longer possible to bring it out when these axes no longer coincide. Thus, the piston head is integral in traction of the machined housing. Such pumps are illustrated for example in FR2692008 . Such pumps are preferably fixed displacement pumps.

An object of the present invention is to provide a piston pump rotatable in either right or left rotation without at least some of the disadvantages of the prior art. An object of the present invention is to provide a piston pump with fixed or variable displacement.

• un barillet présentant des alésages cylindriques ménagés dans le barillet selon un axe du barillet,
• une pluralité de pistons aptes à coulisser dans les alésages,
• un carter, le barillet étant monté en rotation dans le carter autour de l'axe du barillet,
• un arbre d'entrainement apte à entraîner en rotation le barillet, l'arbre d'entrainement étant apte à être connecté à une prise de mouvement,
• un plateau, un axe perpendiculaire au plateau et l'axe du barillet présentant une inclinaison relative entre eux, les pistons étant accouplés au plateau incliné afin d'être aptes à suivre un mouvement de translation alternatif dans les alésages lors de la rotation du barillet.

For this purpose, the pump according to the present invention comprises:

• a barrel having cylindrical bores formed in the barrel along an axis of the barrel,
• a plurality of pistons able to slide in the bores,
• a casing, the barrel being mounted in rotation in the casing around the axis of the barrel,
• a drive shaft adapted to rotate the barrel, the drive shaft being adapted to be connected to a power take-off,
• a plate, an axis perpendicular to the plate and the axis of the barrel having a relative inclination between them, the pistons being coupled to the inclined plate so as to be able to follow an alternative translation movement in the bores during the rotation of the barrel.

• Notamment, selon un mode de réalisation, une telle pompe est utilisable dans les deux sens de rotation et comporte en outre une culasse de distribution présentant une surface intérieure orientée vers l'intérieur du carter et une surface extérieure orientée vers l'extérieur du carter, le barillet étant disposé contre la surface intérieure, la culasse de distribution présentant en outre deux conduites connectant chacune la surface extérieure avec la surface intérieure, une extrémité extérieure des deux conduites étant apte à être connectée à un circuit hydraulique,
• une première conduite présentant une section plus grande qu'une seconde conduite,
• la culasse de distribution étant configurée pour être fixée au carter dans une première position correspondant à un premier sens de rotation de l'arbre d'entrainement et dans une seconde position correspondant à un second sens de rotation de l'arbre d'entrainement, de manière à ce que la première conduite soit une conduite d'admission et la seconde conduite soit une conduite de refoulement selon le sens de rotation de la pompe.

Such a pump may further comprise one or more of the following characteristics:

• In particular, according to one embodiment, such a pump is usable in both directions of rotation and further comprises a distribution yoke having an inner surface oriented towards the inside of the casing and an outer surface oriented towards the outside of the casing, the barrel being disposed against the inner surface, the distribution yoke further having two ducts each connecting the outer surface with the inner surface, an outer end of the two ducts being adapted to be connected to a hydraulic circuit,
• a first pipe having a section larger than a second pipe,
• the distribution yoke being configured to be fixed to the housing in a first position corresponding to a first direction of rotation of the drive shaft and in a second position corresponding to a second direction of rotation of the drive shaft, so that the first pipe is an intake pipe and the second pipe is a discharge pipe in the direction of rotation of the pump.

Thanks to these characteristics, the hydraulic pump is adaptable to the direction of rotation of the power take-off without loss of efficiency, for example by a 180 ° rotation of the distribution yoke around the axis of the barrel.

The breech head can have a wide variety of shapes.

According to one embodiment, the distribution yoke has a substantially cylindrical shape.

Both lines can have a wide variety of shapes.

For example, both lines can be bent. The inner surface and the outer surface of the distribution yoke, that the two lines connect to one another, may be in planes substantially perpendicular to each other.

Preferably, the two pipes are straight. The inner surface and the outer surface of the distribution yoke, which the two lines connect to each other, can be mutually opposed in a thickness dimension of the distribution yoke. Preferably, the inner surface and the outer surface of the distribution yoke are substantially parallel to each other.

According to one embodiment, the inner surface is flat and is treated to reduce the coefficient of friction, for example it comprises a bronze coating.

According to one embodiment, the intake and discharge pipes each have a circular arc-shaped section, the two arc-shaped sections being concentric and each extending over a distinct portion of a circle.

According to one embodiment, such a pump further comprises a plurality of spheres fixed on the plate, the pistons each having a rod capable of sliding in the bore and further comprising a head crimping one of said spheres. This form of coupling can be used in pumps of different types: for example in a fixed displacement pump, a variable displacement pump, a reversible cylinder head pump or not.

According to one embodiment, bores are formed on the plate, the pump further comprising lugs fixed to said spheres, the lugs cooperating with the bores formed on the plate.

According to one embodiment, the stem of each piston has a channel extending longitudinally in the rod so as to hydraulically connect the bore and the piston head, in order to lubricate the piston head to facilitate the rotation of the coupling. pistons to the plateau.

According to one embodiment, the lugs are welded to said spheres, such an assembly can be obtained for example by a friction method.

According to one embodiment, the pump further comprises two annular seals mounted on the drive shaft, the pump further comprising a hydraulic leak sensor disposed between the first seal and the second seal so as to emit a signal in response the detection of fluid leakage between the two seals.

For example, the signal is a light signal or an electrical signal. Thanks to these characteristics, the first seal isolating the hydraulic chamber of the oil from the vehicle power take-off and the second insulating seal the drive shaft of the hydraulic fluid of the hydraulic chamber, the sensor makes it possible to immediately identify any leakage of engine oil or hydraulic fluid to prevent hydraulic fluid leaking into the engine of the vehicle to avoid flooding the engine of the vehicle or seizing the pump in the absence of hydraulic fluid.

According to one embodiment, the coupling of the pistons to the plate is a spring-type restoring force and / or a pivoting crimping of the pistons on the plate.

According to one embodiment, the relative inclination between an axis perpendicular to the plate and the axis of the barrel is variable. Such a hydraulic pump is also called variable displacement pump. For example, the inclination of the plate and / or the barrel is adjustable via cylinders.

According to one embodiment, the axis of the drive shaft is not parallel to the axis of the barrel. This is called a broken axle pump. When the variable displacement pump is also broken axis, preferably, it is the inclination of the cylinder which is adjustable relative to the axis perpendicular to the plate.

According to one embodiment, the plate and the drive shaft are integral in rotation. According to one embodiment, the plate and the drive shaft are formed in one piece.

According to one embodiment, the drive shaft is orthogonal to the plate, and wherein the barrel is tilting to a position in which it is parallel to the axis of the drive shaft. The invention will be better understood, and other objects, details, characteristics and advantages thereof will appear more clearly in the course of the following description of several particular embodiments of the invention, given solely for illustrative and non-limiting purposes. with reference to the accompanying drawings.

• La figure 1 est une vue en coupe longitudinale d'une pompe hydraulique selon un mode de réalisation.
• La figure 2 est une vue en coupe selon la ligne D-D de la figure 1.
• La figure 3 est une vue en perspective de la pompe de la figure 1 en rotation droite.
• La figure 4 est une vue en perspective de la pompe de la figure 1 en rotation gauche.
• - La figure 5 est une vue partielle en perspective de la pompe de la figure 1 sur laquelle la culasse de distribution est fixée de sorte à ce que la prise de force dans le sens horaire soit configurée pour faire fonctionner la pompe.
• La figure 6 est une vue partielle, en coupe longitudinale, illustrant le fonctionnement de la zone d'admission et de la zone de refoulement de la pompe.
• - La figure 7 est une vue en coupe longitudinale d'une pompe hydraulique à axe brisé à cylindrée variable.

On these drawings:

• The figure 1 is a longitudinal sectional view of a hydraulic pump according to one embodiment.
• The figure 2 is a sectional view along the line DD of the figure 1 .
• The figure 3 is a perspective view of the pump from the figure 1 in right rotation.
• The figure 4 is a perspective view of the pump from the figure 1 in left rotation.
• - The figure 5 is a partial perspective view of the pump of the figure 1 on which the distribution yoke is fixed so that the clockwise PTO is configured to operate the pump.
• The figure 6 is a partial view, in longitudinal section, illustrating the operation of the intake zone and the discharge zone of the pump.
• - The figure 7 is a longitudinal sectional view of a variable displacement hydraulic pump with variable displacement.

The hydraulic pump Figures 1 to 6 has several specificities, including a reversible distribution yoke and a special connection between the pistons and the plate.

The figure 1 represents the hydraulic piston pump comprising a drive shaft 1 provided with a plate 2. The plate 2 is formed in a plane perpendicular to the axis of the drive shaft 1.

The hydraulic pump further comprises a casing 6 of axis inclined with respect to the axis of the drive shaft 1.

The housing 6 has a first portion and a second portion. The first portion of the housing 6 has a substantially cylindrical shape about a first axis and comprises the drive shaft 1 whose axis is parallel to this first axis. The first part of the housing 6 is equipped with bearings 20 allowing rotation of the drive shaft 1.

The second portion of the housing 6 has a substantially cylindrical shape around a second axis and comprises a distribution yoke 9 whose axis is parallel to this second axis. The first axis and the second axis form a non-zero angle. The distribution yoke 9 is fixed to the casing 6 as will be described later with reference to the Figures 3 and 4 .

The hydraulic pump further comprises a barrel 5 adapted to rotate in the casing 6 around the second axis of the casing 6. Cylindrical bores 4 are formed in the barrel 5. The bores 4 are formed parallel to the axis of the barrel 5.

The hydraulic pump also comprises a plurality of pistons 3. The pistons 3 are able to slide in the bores 4 formed in a rotating barrel 5 housed in the casing 6.

The cylinder 5 bears against the cylinder head 9. Thus, the cylinder 5 is rotated relative to the cylinder head 9.

When the drive shaft 1 rotates the plate 2, the pistons 3 whose head is connected to the plate 2 by means described later also drive the cylinder 5 in rotation.

The relative inclination of the plate 2 relative to the axis of the pistons 3 imposes the pistons 3 reciprocating when the cylinder 5 is rotating. Thus, the rotation of the drive shaft causes a half-turn recoil of one of the pistons 3 in its bore 4 of the barrel 5, and on the other half-turn the advance of the piston 3 in the 4. At each turn, one after the other, the pistons 3 will therefore go from a top dead center to a bottom dead center and vice versa.

The distribution yoke 9 comprises a guide 16 in the form of a cylindrical hollow formed around the axis of the distribution yoke 9. A compression spring 15 is mounted on a guide pin 14, the spring 15 bearing against the bottom of the distribution yoke 9 and the guide pin 14 bearing against a bore formed in the plate 2, so that the spring 15 maintains the cylinder 5 in abutment against the cylinder head 9.

It is later described how the hydraulic fluid is admitted into the hydraulic pump to be discharged.

The distribution yoke 9 has a substantially cylindrical shape between two surfaces. One of the two surfaces is a connecting surface 17. The other is a bearing surface 12. The rear face of the cylinder 5 bears on the bearing surface 12 of the distribution yoke 9.

The distribution yoke 9 has a friction function on the bearing surface 12. For example, the bearing surface 12 is treated by a bronze melting process so that its coefficient of friction is low.

Two straight ducts pass through the intake yoke 9 so as to connect the two surfaces 17 and 12. The fluid communication between the two surfaces 17 and 12 is allowed by these two ducts. A first duct is an intake duct 8 and a second duct is a discharge duct 13. These two ducts are shown with reference to figures 2 and 6 . The figure 2 is a sectional view according to DD of the figure 1 , and the figure 6 is a sectional view according to EE of the figure 1 .

The intake duct 8 connects the connection surface 17 of the distribution yoke 9 at a first end configured to receive an inlet duct A. The first end has a substantially circular cylindrical shape. The intake duct 8 connects the bearing surface 12 of the distribution yoke 9 at a second end which has a cylindrical shape whose base is of substantially circular circumferential arc shape, less than half a turn, at close to the bearing surface 12. The intake duct 8 flares circumferentially.

The discharge duct 13 connects the connecting surface 17 of the distribution yoke 9 at a first end configured to receive a discharge pipe B. The first end has a substantially circular cylindrical shape. The discharge duct 13 connects the bearing surface 12 of the distribution yoke 9 at a second end which has a cylindrical shape whose base has a shape of a substantially circumferential arc of less than half a turn, close to of the bearing surface 12. The discharge conduit 13 flares circumferentially.

The pressure on the intake duct 8 is generally that of the atmospheric pressure. In order to facilitate the suction of the pump, it is important to minimize the pressure losses on the intake duct 8. The intake duct 8 is therefore dimensioned to create little resistance to the admission of the fluid hydraulic. Also, the intake duct 8 has a section greater than that of the discharge duct 13. This asymmetrical dimensioning therefore reduces the loss of loads compared to a symmetrical dimensioning.

The intake duct 8 has a larger section than that of the discharge duct 13 in order to limit the pressure drops.

Each bore 4 is provided at its base with a pipe 7. When the barrel 5 rotates, the pipe 7 of each bore 4 of the barrel 5 passes alternately during each rotation turn on the intake duct 8 during the intake phase. then on the discharge pipe 13 during the discharge phase.

When the piston 3 leaves its bore 4, the hydraulic fluid fills the piston chamber is the admission. When the piston 3 enters its bore 4 the hydraulic fluid is expelled, it is the discharge.

Each piston 3 has a cubic capacity, the total displacement will be a function of the number of pistons 3 and the relative inclination of the plate 2 relative to the axis of the pistons 3.

It is later described how the hydraulic pump can be optionally and reversibly configured as a right or left rotating hydraulic pump.

Indeed, the hydraulic pump may be intended to be mounted on a vehicle power take-off, for example truck. Depending on the type of truck, the output of the PTO turn right or left: it is therefore advantageous to offer users the hydraulic pump that can turn in one direction or the other so that they have only one only model in store.

The distribution yoke 9 has, as previously described, two ducts 8 and 13 asymmetrical. The cylinder head 9 is adapted to be fixed on the casing 6 in two different ways, as desired:
The distribution yoke 9 can be fixed on the housing 6 so that the intake duct 8 is located on the right, and the discharge duct 13 is located on the left from the connection surface 17 of the cylinder head 9, on the section EE. Such an arrangement corresponds to a right rotation, also called a clockwise rotation, and is represented for example on the figures 3 and 5 .

The distribution yoke 9 can also be fixed on the casing 6 so that the intake duct 8 is located on the left, and the discharge duct 13 is located on the right from the connection surface 17 of the cylinder head 9 on the EE section. Such an arrangement corresponds to a left rotation, also called counterclockwise rotation, and is represented for example on figures 4 and 6 .

Thus, the distribution yoke 9 is designed to be fixed between two angular positions offset by 180 ° from each other relative to the casing 6, the two angular positions respectively corresponding to the two possible directions of rotation of the shaft. training 1.

The figure 3 illustrates the position of the intake pipe A, when the drive shaft 1 is in right rotation, and the figure 4 illustrates the position of this intake pipe A when the drive shaft rotates in left rotation. In both cases, a discharge pipe B is connected to the discharge pipe 13 of the distribution cylinder head 9.

The positioning means of the distribution yoke 9 between the position of the figure 3 and that of the figure 4 can be, for example, an indexing screw 44 which can be mounted in one or the other of two orifices 45 and 46 provided in the distribution yoke 9 of the pump, in the direction of rotation of the pump.

On the figure 5 , the screw 44 is shown mounted in the orifice 45. The pump rotates clockwise. In order for the pump to turn counterclockwise, it is necessary to remove the screw 44, to turn the distribution cylinder 9 bearing the inlet and discharge lines B by 180 °, and to fix the screw 44 in the orifice 46. Advantageously , in the embodiment of the figure 5 it is possible to turn the distribution head 9 180 ° without removing it from the housing 6.

The screw 44 may also serve as a key so that, depending on the mounting position of the screw 44, the operator can visually determine what is the direction of rotation of the pump. For this, a visual marker 99 indicating the clockwise direction, or SH, is etched on the cylinder head next to the orifice 45 and a mark 98 indicating the reverse clockwise or SIH is etched on the cylinder head next to the orifice 46.

On the figure 1 a particular embodiment of the connection, also called the coupling, between the plate 2 and the pistons 3 is shown.

The plate 2 has two cylindrical depressions 21. The cylindrical recesses 21 are of axis parallel to that of the axis of the drive shaft 1. The drive shaft 1 and the plate 2 are formed of a single taking.

Each piston 3 has an attachment stud 33. The fixing stud 33 is formed of elements of different functions each referenced by a different reference numeral, although these different elements are formed in one piece in the example of the figure 1 . In particular, the fixing stud 33 comprises a sphere 32. The sphere 32 is in connection with the plate 2.

Each piston 3 comprises a rod 31 whose end 35 forms a crimping. During the manufacture of the hydraulic pump, each piston 3 is mounted crimping the sphere 32 of the fixing stud 33. The end 35 thus irreversibly encloses the sphere 32.

The rod 31 is able to slide in a bore 4 while the end 35 forming the crimping remains, in operation, external to the bore 4.

In the example of the figure 1 , the connection between the spheres 32 and the plate 2 is performed as described below.

The sphere 32 is mounted on a cylindrical pin 34. The cylindrical pin 34 has a straight cylindrical shape whose diameter is slightly smaller than that of the cylindrical hollow 21. The sphere 32 is mounted on one of the planes of the cylindrical pin 34. Advantageously, during the manufacture of the hydraulic pump, the cylindrical pin 34 and the sphere 32 may be made in one piece or are fixed together by welding, for example friction welding.

The cylindrical lug 34 of each fastening stud 33 is introduced into one of the two cylindrical depressions 21 of the plate 2.

In order to keep the fixing studs 33 fixed to the plate 2, the cylindrical depressions 21 have a circular groove on their inner surface while the cylindrical lugs 34 have a circular groove on their outer surface. Thus, a fastener washer 36, for example a circlip washer, is assembled on the circular groove of the cylindrical lug 34 prior to its introduction into the cylindrical recess 21. Once the cylindrical lug 34 has been inserted into the cylindrical recess 21, the fastening washer 36 extends in the circular groove of the cylindrical recess 21 so as to maintain the fastening between the cylindrical stud 34 and the cylindrical recess 21.

Other examples of connection between the sphere 32 of the attachment stud 33 are possible. For example, the sphere 32 could be welded, mounted tightly or still stuck directly on the plate, in place of the cylindrical lugs 34 and cylindrical depressions 21.

An advantage of this piston-plate connection is to be adapted to fixed or variable displacement pumps. Indeed, whatever the angle of inclination of the plate, even zero, the pistons 3 remain irreversibly coupled rotatably on the plate 2.

Other types of connections of the pistons 3 to the plate 2 can however be envisaged.

For example, the pistons 3 may have spherical piston heads and the plate may have machined housings shaped truncated sphere. In comparison with the embodiment shown on the figure 1 , the male and female parts can be reversed.

In another example, the heads of the pistons 3 can be held in contact with the plate 2 via a return plate associated with a ball joint. In this example, the return of the piston 3 is effected by means of the return plate which holds the piston head 3 with a piston pad placed on the plate 3. The return plate is pressed against the plate 2 by a ball joint. An advantage of this piston-plate connection is to be adaptable to fixed or variable displacement pumps. In fact, whatever the angle of inclination of the plate, the spring makes it possible to push the ball and hold the return plate in position. Advantageously, the ball is itself pushed on the return plate by a compression spring.

An example of a variable displacement pump is shown with reference to the figure 7 . Elements having the same function as those represented by reference to Figures 1 to 6 are designated by the same reference numbers.

A variable displacement pump is variable flow. The flow rate can be adjusted for example by having means for varying the relative inclination between the plate 2 against which the pistons are supported and the axis of the pistons, so as to vary the stroke of the latter.

The drive shaft 1 drives the plate 2.

The barrel 5 is rotatably mounted and held against a dispensing window 22. The barrel 5 is further centered about its axis by a guide 77 of variable orientation.

Depending on the needs, the angle formed between the axis of the cylinder 5 and that of the plate 2 varies via a control cylinder 27 which is supplied by a distributor.

In order to make it possible to vary the angle between the axis of the barrel 5 and that of the plate 2, the guide 77 is connected to a connecting rod 60 sliding in a plane substantially perpendicular to the axis of the barrel 5. A plate 40 connected to the connecting rod 60 slides on a cradle shaped hollow cylinder according to the stroke of the control cylinder 27 and allows the variation of the displacement of the engine.

The pistons 3 are in connection with the plate 2.

The inclination of the axis of the barrel 5 relative to that of the plate 2 which is integral with the drive shaft 1 allows the reciprocating movement of the pistons 3 in their bores 4.

As in the examples of pumps shown in the other figures, during the rotation of the drive shaft 1, the radial component resulting from the force of the plate 2 on the piston 3 is transmitted as a torque to the cylinder 5, thus causing it to rotate. During the rotation of the barrel 5, the pistons 3 make a round trip between the bottom of their bore 4 and their high point. During their race from the bottom of the bore to the high point, the hydraulic fluid is sucked into the piston chamber 3 through a dispensing glass 22. During their return stroke from the high point to the bottom of the bore, the hydraulic fluid is discharged at high pressure by the discharge light of the dispensing glass 22.

As shown, the heads of the pistons 3 are held in contact with the plate 2 via a return plate 111. The heads of the pistons 3 are spherical and the plate 2 has machined housings of truncated spherical shape, the return plate 111 maintaining the connection between the heads of the pistons 3 and the machined housing.

As previously described, several alternative ways of attaching the heads of the pistons 3 to the plate 2 can be envisaged. Preferably, the mode of connection of the figure 1 for its simplicity of manufacture.

With reference to the figure 1 a hydraulic leakage sensor 28 is shown.

The pump comprises two annular seals 29 and 30 mounted on the drive shaft 1 between each of the bearings 20.

The annular seal 29 is mounted on the side of the drive shaft 1 intended to be in engagement with the power take-off.

The annular seal 30 is mounted on the side of the drive shaft 1 which is in contact with the plate 2.

Silicone grease is disposed between the two annular seals 29 and 30, and a tube 37 of the hydraulic leak sensor 28 is slid between the first annular seal 29 and the second annular seal 30. The hydraulic leak sensor 28 further includes a 38 level connected to the tube 37 and connected to an electronic alarm 39. For example, the level 38 comprises a float and a proximity detector.

The hydraulic leak sensor 28 is configured to detect the presence of fluid between the two annular seals 29 and 30.

Indeed, when the hydraulic pump is installed on a vehicle, the power take-off on which is connected the drive shaft 1 is immersed in the oil of the gearbox or the engine and a sealing defect at this level would cause significant damage.

Furthermore, the hydraulic pump comprises a hydraulic chamber 31 in which are the cylinder 5 and the pistons 3. The hydraulic chamber 31 is filled with hydraulic fluid when the pump is in operation. The suctioned and discharged fluid can be introduced around the plate 2 and at the level of the bearing 20 on the side of the plate 2.

Thus, the two annular seals 29 and 30 serve as hydraulic insulation between the hydraulic chamber 31 and the side of the drive shaft 1 which is intended to be engaged with the power take-off.

However, the gearbox oil or the hydraulic fluid can be introduced between the two annular seals 29 and 30 in the event of failure of the annular seals. The risk is that the hydraulic fluid enters the gearbox and drowns the engine or that the absence of hydraulic fluid is influencing the hydraulic pump.

The hydraulic leakage sensor 28 makes it possible immediately to identify any oil leakage from the gearbox or hydraulic fluid.

The hydraulic leak sensor is configured to emit a signal in response to the detection of fluid leakage between the two annular seals 29 and 30. The signal is a light signal or an electronic signal, for example a signal sent on the vehicle control dial or on an application capable of displaying an alert on a device of the user, for example on a smartphone.

Although the invention has been described in connection with several particular embodiments, it is obvious that it is not limited thereto and that it comprises all the technical equivalents of the means described and their combinations if they are within the scope of the invention.

The use of the verb "to include", "to understand" or "to include" and its conjugated forms does not exclude the presence of other elements or steps other than those set out in a claim. The use of the indefinite article "a" for an element does not exclude, unless otherwise stated, the presence of a plurality of such elements.

In the claims, any reference sign in parentheses can not be interpreted as a limitation of the claim.

Claims (10)

Hydraulic axial piston pump, comprising: a barrel having cylindrical bores (4) formed in the barrel (5) along an axis of the barrel, a plurality of pistons (3) able to slide in the bores, a casing (6), the barrel being mounted in rotation in the casing (6) around the axis of the barrel, - A drive shaft (1) adapted to rotate the barrel, the drive shaft being adapted to be connected to a power take-off, - A plate (2), an axis perpendicular to the plate and the axis of the cylinder (5) having a relative inclination between them, the pistons being coupled to the inclined plate to be able to follow an alternative translation movement in the bores. (4) when rotating the barrel, the pump further comprising a plurality of spheres (32) fixed on the plate, the pistons each comprising a rod capable of sliding in the bore and further comprising a head crimping one of said spheres,
in which the plate (2) and the drive shaft (1) are integral in rotation, the plate (2) is formed in a plane perpendicular to the axis of the drive shaft (1), and tilting of the barrel (5) is adjustable relative to the axis of the drive shaft (1). Hydraulic pump according to claim 1, wherein bores are formed on the plate (2), the pump further comprising lugs fixed to said spheres, the lugs cooperating with the bores formed on the plate (2). Hydraulic pump according to claim 1 or 2, wherein the rod of each piston (3) comprises a channel extending longitudinally in the rod so as to hydraulically connect the bore and the piston head (3), in order to lubricate the piston. piston head (3) to facilitate the rotation of the coupling of the pistons to the plate (2). Hydraulic pump according to any one of claims 1 to 3, wherein the lugs (34) are fixed to said spheres (32). Hydraulic pump according to any one of claims 1 to 4, further comprising a distribution yoke (9) having an inner surface facing inwardly of the housing (6) and an outer surface facing out of the housing (6). ), the barrel (5) being disposed against the inner surface, the distribution yoke further having two ducts each connecting the outer surface with the inner surface, an outer end of the two ducts being adapted to be connected to a hydraulic circuit, a first pipe having a section larger than a second pipe,
the distribution yoke being configured to be fixed in a first position corresponding to a first direction of rotation of the drive shaft and in a second position corresponding to a second direction of rotation of the drive shaft, so as to the first pipe (8) is an intake pipe and the second pipe (13) is a discharge pipe in the direction of rotation of the pump. Pump according to any one of claims 1 to 5, further comprising two annular seals mounted on the drive shaft, the pump further comprising a hydraulic leak sensor (28) disposed between the first seal and the second seal of so as to emit a signal in response to the detection of fluid leakage between the two seals. Pump according to any one of claims 1 to 6, wherein the coupling of the pistons (3) to the plate is a crimping pivoting pistons on the plate (2). Pump according to any one of claims 1 to 7, wherein the relative inclination between the axis perpendicular to the plate and the axis of the barrel is variable. Pump according to any one of claims 1 to 8, wherein the plate and the drive shaft are integrally formed. Pump according to any one of claims 1 to 9, wherein the coupling of the pistons (3) to the plate (2) is a crimping pivoting pistons (3) on the plate (2) ..

Images