FR2999122A1 - HYDROSTATIC TRANSMISSION OF VEHICLE WITH ENGINE ENGAGEMENT ACCORDING TO THEIR OPTIMUM OPERATING RANGES. - Google Patents

Abstract

The present invention relates to a hydrostatic transmission system of a vehicle, characterized in that it comprises: - a primary motor rotating a primary shaft, - an output shaft adapted to drive a rotating wheel, - a slow hydraulic motor to radial pistons configured to rotate at the speed of said wheel - a gear train forming a mechanical chain between the primary shaft and the output shaft via a secondary shaft. a variable displacement hydraulic pump adapted to be selectively coupled or disengaged from the primary shaft and adapted to supply pressure to said hydraulic motor; a control adapted to control the rotational drive of the output shaft by the motor; slow hydraulic, or by the primary shaft depending on the speed of the output shaft.

Description

GENERAL TECHNICAL FIELD The present invention relates to the field of transmissions for vehicles comprising hydraulic drive means.

STATE OF THE ART Conventional transmission systems make it possible to use a thermal or electrical engine in its optimal utilization range in order to obtain a desired speed on an output shaft, by using several reduction ratios, typically by means of wheels. jaws and jaw. Both types of heat engine and electric may be present on the same vehicle in the case of a hybrid engine.

Conventional thermal engines conventionally the primary means of vehicle propulsion, however, have an optimum range of use restricted to the desired speed range for the vehicle, and are not able to work at rest and at low speed. It is the same for electric motors, which have a very low efficiency at low speed. These electric motors have low efficiencies at very low speed and a mass density and low power density. Their high-speed energy consumption imposes an important dimensioning, both of the motor and the batteries. For these reasons, it is necessary to provide a clutch and multiple stages of reduction for thermal engines, and power limitations and binding cooling systems for electric motors.

Complex systems are also known associating a hydraulic motor of rapid type, for example a hydraulic motor with axial pistons and inclined plate, with a heat engine, this association making it possible to selectively assist the heat engine by the hydraulic motor. However, the known systems lead to the operation of such hydraulic motors for use ranges having an inefficient performance. For example, for a tilting-plate fast motor, the leakage rate in the small-displacement position is high, whereas the efficiency in the high-displacement position is low. The range of good performance of such a machine is reduced.

The present invention thus aims to provide a system improving the vehicle transmissions, and in particular the transmission performance at low speed and for the stopped start, while using the prime mover in an optimum range of use. In this way, the proposed system provides a driving pleasure for vehicles with a combustion engine, it optimizes the operation of hybrid electric-electric or pure electric engines. It also makes it possible to perform very simply additional functions such as coast stop, slow speed movement commonly known as "inching", stop-start, energy recovery and restitution, and a 4-wheel drive connection. PRESENTATION OF THE INVENTION To this end, the invention proposes a hydrostatic transmission system of a vehicle, characterized in that it comprises: - a primary motor rotating a primary shaft, - an output shaft adapted to drive a wheel in rotation, - a slow hydraulic motor with radial pistons configured to rotate at the speed of said wheel, - a gear train forming a mechanical chain between the primary shaft and the output shaft via a secondary shaft. - A variable displacement hydraulic pump adapted to be selectively coupled or disengaged from the primary shaft and adapted to supply pressure to said slow hydraulic motor, - a control adapted to control the rotational drive of the output shaft by the slow hydraulic motor, or by the primary shaft depending on the speed of the output shaft. In a variant, said control is adapted to define a plurality of rotational speed value ranges of the output shaft: a first range of values for which the output shaft is driven by the slow hydraulic motor; a second range; of values for which the output shaft is driven by the primary motor through said gear train; said first and second ranges of values having common values. Said command is then typically adapted to, when the rotational speed of the output shaft is out of the first range of values, disengage said slow hydraulic motor. According to another variant, the speed of the output shaft is distributed over the following ranges: the first range of values ranges from 0 revolutions per minute to a value of between 400 and 600, typically 500 revolutions per minute; the second range of values comprises the values beyond 400, 600 or 500 revolutions per minute. According to a particular embodiment, said system further comprises a differential mounted on the output shaft and dividing it into a first and a second output shaft, said differential comprising a differential case comprising housing gears adapted for cooperating with pinions connected to said output shafts and thus driving said output shafts, the radial piston slow hydraulic motor being coupled to said differential, and comprising - a distributor and a multilobe cam defining a first set, - a cylinder block defining a second together, one of said sets being rotatably mounted relative to the differential case, and the other of said sets being rotatably mounted relative to the differential case so as to allow the differential case to be rotated by said engine slow hydraulic piston radial.

Said primary engine is for example a heat engine or an electric motor. In a variant, said system further comprises a fast motor of the axial piston hydraulic motor or electric motor type, said drive being adapted to define a plurality of ranges of rotational speed values of the output shaft: a first range of values for which the output shaft is driven only by the slow hydraulic motor; a second range of values for which the output shaft is driven jointly by the slow hydraulic motor and the fast motor; a third range of values for which the output shaft is driven by the fast hydraulic motor only; a fourth range of values for which the output shaft is driven jointly by the fast motor and the primary motor via a gear train; a fifth range of values for which the output shaft is driven solely by the primary motor via a gear train.

Alternatively, said system further comprises at least one hydraulic accumulator, said system being configured so that during braking of the vehicle, the pump and / or the hydraulic motor or motors have a reversible operation and load said hydraulic accumulator in pressure to perform a function of energy recovery. Said at least one hydraulic accumulator is then typically adapted to selectively power the hydraulic pump so that it has engine operation and provides assistance in driving the input shaft. Alternatively, the pump is typically adapted to operate as a motor being powered by said at least one hydraulic accumulator 10, and thus provide assistance of the primary motor for driving the primary shaft. The invention also relates to a method for controlling the drive of an output shaft to which is connected a wheel of a vehicle, in which the drive of said output shaft is controlled according to the desired speed, so as to the output shaft is selectively rotated by a slow hydraulic motor; a primary motor via a gear train forming a mechanical chain between the primary shaft and the output shaft; depending on the speed of the output shaft. Said control method is advantageously implemented by means of a system as presented above. According to a particular embodiment of said method, a first range of values is defined for which the output shaft is driven by the slow hydraulic motor; a second range of values for which the output shaft is driven by the primary motor via said gear train, said first and second ranges of values being able to present common values.

Alternatively, for rotational values of the output shaft being outside the first range, said hydraulic motor is disengaged. According to a particular embodiment, during a braking of the vehicle, said hydraulic motor slow so that it loads a hydraulic accumulator and thus performs a function of energy recovery. Beyond a threshold value, then typically drives a reversible hydraulic pump so that it is fed a hydraulic accumulator, and it provides assistance to the primary engine. PRESENTATION OF THE FIGURES Other features, objects and advantages of the invention will emerge from the description which follows, which is purely illustrative and nonlimiting, and which should be read with reference to the accompanying drawings, in which: FIG. schematic view of a system according to one aspect of the invention; FIG. 2 is a schematic view of a variant of the system shown in FIG. 1; FIG. 3 is a diagrammatic view of a variant of the system shown in FIG. 1; FIG. 5 schematically shows the various operating modes of FIG. a variant of such a system according to one aspect of the invention.

In all the figures, the common elements are identified by identical reference numerals.

DETAILED DESCRIPTION As a preliminary remark, it will be noted that throughout the present text, a hydraulic apparatus will be used to designate an apparatus that can function as an engine or as a hydraulic pump. A hydraulic apparatus conventionally comprises a plurality of pistons disposed in housings, and reciprocating in contact with a cam in the case of a radial piston apparatus, or a broken axis, or a plate in the case of an axial piston apparatus. Hydraulic devices with radial pistons operate at speeds conventionally described as slow, for example between 0 and 300 revolutions per minute, whereas axial piston hydraulic devices and electric motors commonly used for electric traction operate at fast speeds, typically between 300 and 5000 rpm. It is also noted that the output shaft of a transmission, rotating at the speed of the wheels, must be able to rotate between 0 and 1500 rpm for a light vehicle, and it must be able to turn in the reverse direction between 0 and -300 rpm. On the other hand, in the range of 0 to +/- 300 rpm, it is necessary to have high torque to perform sloping maneuvers or point obstacles, as well as satisfactory starts. The maximum speed of a hydraulic machine of this type may vary between 200 and 800 rpm depending on the number of cam lobes chosen. In general, a small axial piston hydraulic machine with a reduced number of cam lobes will have a higher maximum speed respectively and a lower torque, while a large axial piston hydraulic machine will be used. , with a high number of cam lobes will have respectively a lower maximum speed and a higher torque.

In the context of an application with hydraulic machine with axial pistons rotating at the speed of the wheel alone, the engineer will choose more particularly a machine of this type having a maximum speed of the order of 500 rpm, which allows to bring the vehicle up to 50 km / h, so as to circulate pleasantly in urban cycle without changing mode. In the context of an application with axial piston engine and radial piston engine, the engineer will particularly choose a machine of this type having a maximum speed of the order of 200 to 300 rpm, which will give a better aptitude. at startup, the slow motor being relayed easily and smoothly by an axial piston machine. The hydraulic devices are conventionally configured so as to be able to alternate between a service configuration in which the pistons are in contact with the cam for the radial piston and cam machines, or in which the angle of the broken axis or the plate is not zero for fast machines, or a freewheel configuration in which the rotation of the hydraulic apparatus is at zero displacement. This zero displacement is obtained by zero inclination of the axis or plate for fast machines, and for example by retracting pistons in their respective slots for radial piston and cam machines.

Figure 1 shows a schematic view of a system according to one aspect of the invention. This figure shows a driving axle 1 of the vehicle, in this case a steering axle.

The driving axle 1 as shown comprises a differential 2, dividing the driving axle 1 into two sub-axles 11 and 12, each carrying a wheel, respectively 13 and 14.

The vehicle comprises a primary motor M, for example a heat engine or an electric motor, associated with a gear train 3 forming a mechanical chain between the primary shaft 31 and the driving axle 1, adapted to allow the drive of the engine. driving axle 1 by the primary motor M according to an architecture well known to those skilled in the art. In the embodiment shown, a first hydraulic device 41 is connected to a primary shaft 31 of the gear train 3, the driving axle 1 is equipped with a second hydraulic device 42, and an optional fast motor 43, in one embodiment. A third hydraulic apparatus is mounted so that it can be selectively coupled to a secondary shaft 32 of the gear train 3 by means of a clutch 44 to drive the driving axle 1. The clutch can also be made under the shape of a dog. The apparatus 41 may also be equipped with a clutch 47 to selectively engage or disengage it from the primary shaft 31, this clutch 47 may for example be embodied in the form of a dog clutch.

These clutches make it possible to disengage the associated hydraulic devices when they are not used, thus avoiding unnecessary parasitic torque. The first hydraulic device 41 is for example an axial piston hydraulic apparatus, and generally has a pump operation. It will be referred to in the rest of the text by the name pump 41. Nevertheless, a use in engine mode is possible to perform startups of the primary engine, or a turbo mode or "boost" in case of undersizing of the engine primary to support the latter. The second hydraulic apparatus 42 is a radial piston hydraulic apparatus, and has a motor operation.

Reference will be made later in the text by the slow motor designation 42. Such a hydraulic apparatus advantageously operates at low rotational speeds, and produces a high torque for a small footprint.

This slow motor 42 is advantageously arranged so as to rotate at the speed of the wheels, for example by being mounted on the driving axle 1. It is well understood that is thus designated by a motor rotating at a wheel speed a motor running at the speed of its associated wheel in the case of a motor linked to a single wheel, each wheel of an axle then being equipped with a clean engine, or a motor rotating at the average speed of the associated wheels in the case of a motor linked to several wheels mounted on a shaft equipped with a differential, for example according to the particular embodiment presented below.

According to a particular embodiment, the slow motor 42 is associated with the differential 2 of the driving axle 1, thus forming an assembly comprising a differential 2 linking a first and a second output shaft, in this case the two sub-axles 11 and 12. The differential has for example a known structure comprising a differential housing comprising case gears adapted to cooperate with sprockets connected to said output shafts and thus drive said output shafts. The slow motor 42 is then advantageously coupled to the differential 2, the slow motor 42 - a distributor and a multi-lobe cam defining a first set, - a cylinder block defining a second set, one of said sets being mounted fixed in rotation relative to to the differential case, and the other of said sets being rotatably mounted relative to the differential case so as to allow the rotation of the differential case by said hydraulic apparatus.

Such a structure is described in patent application FR1259208 in the name of the applicant, not yet published, this patent application to which one skilled in the art can refer to several structures finding a particular application in the present system. Such a hydraulic apparatus structure makes it possible to drive it to the speed of the wheels, or more precisely to the average rotational speed of the two sub-axles 11 and 12. In the case of such a structure, the drive of the driving axle can be achieved for example by means of a ring gear disposed on the assembly rotatably connected to the differential housing, with which cooperates a toothed gear with straight or inclined toothing or a conical pinion connected to a shaft of the train of gears or an output shaft of an engine. Alternatively, the drive wheels of the vehicle may be independent; they are typically each equipped with a slow motor 42 as shown.

In a variant, the slow motor or motors 42 may be offset on another axle than that driven by the fast motor 43, the slow motor or motors 42 being always at the speed of the wheels to which they are connected. The optional fast motor 43 is for example an axial piston hydraulic apparatus, and has a motor operation.

Such a hydraulic apparatus advantageously operates at speeds higher than that of the slow motor 42, and produces a lower torque than that of the slow motor 42. The fast motor 43 is for example linked to the output shaft without a gear ratio, or selectively coupled to a gearbox or gearbox secondary shaft 32 having one or more gear ratios for rotating the output shaft as shown in FIG. 1.

The motors 42 and 43 are reversible machines, which can operate in "4 quadrants", that is to say, produce a motor or resistant torque, and in both directions of rotation.

The structure presented further comprises a control 5, comprising, for example, a computer and a plurality of valves adapted to selectively connect the pump 41 to the slow motor 42 and / or, where appropriate, to the fast motor 43. This control 5 can be realized under the form of a structural block, or composed of several spatially distributed elements in the structure. Alternatively, the optional fast motor 43 is an electric motor as shown in FIG.

In this embodiment, the system comprises an electric machine E mounted for example on the primary shaft 31 of the gear train 3, adapted to generate an electric current during the application of an input movement. The electric machine E and the fast motor 43 are connected to a converter 45 adapted to convert the direct current generated by the electrical machine E into alternating current so as to supply the fast motor 43. The converter 45, the electric machine E and the fast motor 43 are typically connected to the control 5 which carries out their control, and typically comprises an electronic control unit. The system shown in FIG. 2 further comprises a battery 46 connected to the converter 45, said battery 46 being able to be charged for example during the braking of the vehicle or when its drive is not performed by the fast motor 43 in order to perform a function storage and energy restoration. The system presented makes it possible to selectively drive the driving axle 1 either mechanically by means of gears of the gear train 3, or by means of one or more motors 42 and / or where appropriate 43, or even by means of a combination of a mechanical drive and a drive by a motor 42 or where appropriate 43.

We first consider a system as shown in Figures 1 and 2, for a stationary vehicle in which the driving axle 1 is the only driving axle. The various steps are described below with a gradual increase in the speed of rotation of the driving axle 1.

In order to start driving the driving axle 1, a large torque is required for starting. The control 5 then drives the gear train 3 so that the mechanical connection between the gear train 3 and the driving axle 1 is disengaged, and the pump 41 feeds the slow motor 42 which is in service configuration and thus carries out driving of the driving axle 1. When the speed of the driving axle 1 reaches a first threshold value s1, the control 5 drives the pump 41 and, if appropriate, its associated clutch 47, as well as the fast motor 43 and if necessary its associated clutch 44 so that the pump 41 feeds both the fast motor 43 and the slow motor 42, the latter being in the service configuration and thus jointly carrying out the driving axle drive 1. The control 5 controls the displacement of 41 and if necessary 43 so that the speed of the primary motor M is at desired values. This rotational speed can be chosen on criteria of comfort, economy, silence, or power. The speed of the primary motor M can be controlled by 5, and vary throughout the different modes of use of the transmission.

For example, it is possible to keep the primary motor M at a relatively constant speed, for example in the range of 1500 to 2000 revolutions / min.

When the speed of the driving axle 1 reaches a second threshold value S2, the control 5 drives the slow motor 42 so that it switches to freewheel configuration. The drive axle 1 is then driven only by the fast motor 43. The displacement of the pump 41 is modified by the control 5 to take into account the reduction in the displacement of the engines to be powered, only 43 being in function . While the control 5 continues to drive the displacement of 41 and 43 as a function of the requested setpoint, the speed of rotation of the driving axle 1 then continues to increase until a third threshold value S3 is reached; the control 5 then drives the gear train 3 so that it mechanically engages the driving axle 1 so that it is rotated by the primary motor M via the gear train 3.

The driving of the driving axle 1 is then carried out jointly by the fast motor 43 and the primary motor M. The choice of rotation speeds is made so that the engagement of the locking system of the gears is done when the rotational speeds of both shafts are at the ideal speed suitable for locking without cracks. When the gear train 3 is engaged, the speed of the vehicle is linked to the speed of the primary motor M. The primary motor M must therefore vary its speed so that the speed of the vehicle changes.

The speed of rotation of the driving axle 1 then continues to increase until reaching a fourth threshold value S4; the control 5 drives the fast motor 43 so that it switches in the freewheel configuration and / or disengages from the driving axle 1. By controlling by the control 5 of the pump 41 and the fast motor 43, their cubic capacity is varied so as to reduce it gradually to zero, while remaining synchronized with the speed of rotation imposed on the pump 41 and the fast motor 43 by the gear train 3. The pump 41 can then be disengaged, or to be switched to freewheel configuration. The driving of the driving axle 1 is then carried out by the primary motor M via the gear train 3.

Beyond this fourth threshold value S4, the gear train 3 can define additional threshold values associated with different mechanical reduction ratios.

Thus, several ranges of values corresponding to the various operating modes are defined: From the stop (zero revolutions per minute) to the first threshold value Si: a first range of values V1. - From the first threshold value S1 to the second threshold value S2: a second range of values V2. - From the second threshold value S2 to the third threshold value S3: a third range of values V3. - From the third threshold value S3 to the fourth threshold value S4: a fourth range of values V4. - Beyond the fourth threshold value S4: a fifth range of values V5. The first value range can be understood in forward and reverse, from -V1 to + V1 via zero. When reducing the speed of the driving axle 1, the various steps described above are carried out in the opposite direction: - Training by the primary motor M via the gear train 3 up to the fourth threshold value S4; - Training by the primary motor M via the gear train 3 and the fast motor 43 of the fourth threshold value S4 to the third threshold value S3; - Training by the fast motor 43 of the third threshold value S3 to the second threshold value S2; - Driving by the fast motor 43 and the slow motor 42 of the second threshold value S2 to the first threshold value Si; - Driving by the slow motor 42 only the first threshold value Si until the stop of the vehicle.

Several examples are given below for the various threshold values, these examples being purely illustrative and in no way limitative: the first threshold value Si is typically between 150 revolutions per minute and 200 revolutions per minute, for example equal to 150 revolutions per minute. The second threshold value S 2 is typically between 200 revolutions per minute and 300 revolutions per minute, for example equal to 200 revolutions per minute. The third threshold value S3 is typically between 200 revolutions per minute and 300 revolutions per minute, for example equal to 300 revolutions per minute, it being understood that the third threshold value S3 is greater than or equal to the second threshold value S2. The fourth threshold value S4 is typically between 700 revolutions per minute and 900 revolutions per minute, typically equal to 800 revolutions per minute. FIG. 3 schematically represents an example of staggering of these different threshold values and the associated value ranges.

We thus represent in this figure a graph having the abscissa X the speed of a vehicle in kilometers per hour, and Y ordinate the speed of the wheels in revolutions per minute. The positive values are taken arbitrarily to correspond to a forward movement of the vehicle, and the negative values to a reverse of the vehicle considered. This graph shows the different threshold values Si, S2, S3 and S4, as well as the associated value ranges V1, V2, V3, V4 and V5. This graph in particular explains the function of the slow motor 42, used only for very low speeds of the vehicle, and disengaged as soon as the vehicle reaches a speed of the order of 20 kilometers per hour, at 5 or 10 kilometers per hour. It is also clear that for high speeds of the vehicle, the drive is done by the primary motor M alone or associated with the fast motor 43. Also on this graph is the reverse, for which we can define a first value negative threshold -Si and range -If associated, it being understood that the speed in reverse is conventionally limited on vehicles, and that one can therefore consider limiting itself to the mode of operation corresponding to the drive of the axle leading 1 by the slow motor 42 of this first negative threshold value -Si until the vehicle stops.

FIG. 4 shows a variant of the system shown in FIG. 1, not including the fast motor 43 and the associated clutch 44. In the context of this variant with an axial piston hydraulic apparatus rotating at the speed of the wheel alone, a hydraulic apparatus having a maximum speed of the order of 500 revolutions per minute will be chosen more particularly, which makes it possible to take a vehicle up to around 50 km / h, so as to circulate pleasantly in the urban cycle without changing the mode . This variant makes it possible to advantageously realize a recovery-restitution of energy below the first threshold value, by using the reversibility of the slow motor 42.

For this purpose, the control 5 typically comprises valves for distributing the hydraulic flows and is connected to one or more accumulators. Depending on whether energy recovery, energy restitution, or assistance from the primary motor M is requested, the slow motor 42 is powered. This variant also makes it possible to advantageously achieve a recovery-restitution of energy above the first threshold value, by using the reversibility of the hydraulic pump 41. In this case, the slow motor 42 is in the out of service configuration, and only the pump hydraulic 41 is connected by the control 5 to the accumulators. Depending on whether energy recovery, energy restitution or assistance from the primary motor M is required, the hydraulic pump 41 is energized. FIG. 5 diagrammatically represents an example of staggering of these different threshold values and the associated value ranges for a system as represented in FIG. 4 not including the fast motor 43. As in FIG. 3, this figure is represented a graph with the abscissa X the speed of a vehicle in kilometers per hour, and Y the speed of the wheels in revolutions per minute. The positive values are taken arbitrarily to correspond to a forward movement of the vehicle, and the negative values to a reverse of the vehicle considered. Thus, a first range of values W1 corresponding to a drive realized only by the slow hydraulic motor 42, a second range of values W2 corresponding to a drive realized jointly by the slow hydraulic motor 42 and the primary motor M via a first range of values W1 is represented in this figure. the gear train, and a third range of values W3 corresponding to a drive carried out only by the primary motor M via the gear train.

The second range of values W2 thus corresponds to an overlap of the operating mode where the drive is performed by the slow hydraulic motor 42 and the operating mode where the drive is carried out by the primary motor M via the gear train 3.

In the same way as in FIG. 3, an operating range -W1 corresponding substantially to the equivalent of the range W1 but in reverse is defined. FIG. 4 shows the different threshold values from which one goes from one range of values to the next; A first threshold value Ti at the transition between the first range of values W1 and the second range of values W2; a second threshold value T2 at the transition between the second range of values W2 and the third range of values W3.

The first threshold value Ti is for example between 400 revolutions per minute and 600 revolutions per minute, for example equal to 500 revolutions per minute. The second threshold value T2 is for example between 500 revolutions per minute and 800 revolutions per minute, for example equal to 700 revolutions per minute, it being understood that the second threshold value T2 is greater than or equal to the first threshold value Ti. There are thus several advantageous features of the system 25 thus proposed. In the first place, the various devices are exploited in their optimum efficiency ranges, whether they are hydraulic units or the primary thermal or electric motor. Indeed, the system presented thus makes it possible to use a primary motor such as a thermal or electric motor only in its optimum utilization range, the lowest speeds of the output shaft being obtained via the intermediate gear. one or more adapted hydraulic devices possibly associated with a motor or electric, in this case a hydraulic pump with variable displacement driven by the primary motor and a radial piston hydraulic motor for very low speeds, and possibly a hydraulic piston engine axial or an electric motor for intermediate speeds. Indeed, instead of varying the rotational speed of the primary motor M as conventionally achieved, the present invention makes it possible to maintain it in an optimum range of use, and to vary the displacement of the hydraulic pump to control the speed of rotation of the hydraulic motors and thus the speed of the output shaft. The slow hydraulic motor can thus advantageously replace one or more gear ratios of a gear train or a conventional gearbox, corresponding for example to the first gear, or to the first speeds and to the reverse gear. The use of a slow hydraulic motor for slow speeds thus makes it possible to use a motor running at the speed of the wheel shaft in question, without a reduction ratio, which thus makes it possible to obtain a higher efficiency with a component. high power density, so space-saving. When the speed of the axle considered increases, the slow motor goes into freewheel configuration to avoid parasitic halftone or useless resistor torque. The slow hydraulic motor advantageously makes it possible to perform forward and reverse. Furthermore, the proposed system makes it possible to achieve ranges of values for which the driving of the driving axle 1 is carried out jointly by several motors, which ensures a fluidity and a flexibility during the transitions during the passage between the different threshold values and ranges of values.

The present invention also makes it possible to produce a system with efficient energy recovery by means of hydraulic accumulators mounted in replacement of the pump 41 and / or in addition to the pump 41.

Indeed, during the braking of the driving axle 1, the motors 42 and 43 being reversible, they then take a pump operation which can advantageously be used to load one or more hydraulic accumulators, such a battery charge can be operated in replacement or in conjunction with the pump 41 for driving the motors 42 and 43 during acceleration of the vehicle. The hydraulic pump 41 can also be used during the braking phases, even if the motors 42 and 43 are decoupled from the wheels, the pump 41 being then driven by the mechanical transmission between the wheels and the primary motor M to supply accumulators hydraulic. Such energy storage can also be used by the hydraulic pump 41, which is reversible, and can thus be used as a motor to act on the primary shaft 31, and perform a function of assistance of the primary motor M, commonly called "boost". Such hydraulic accumulators also make it possible to obtain a high torque at start-up, and load over very short intervals, unlike electric accumulators for which the energy recovery is carried out over longer time intervals. One consequence is to allow optimal energy recovery in the urban cycle, that is to say having a very good recovery-recovery performance, including very intense and very short cycles. The volume of components required is very small compared to the volume of batteries needed for the same recovery by the electrical way. It thus becomes possible to achieve excellent energy recovery-restitution in urban cycle with significant weight and space savings compared to an electrical solution. If the fast motor 43 is of the electric type, it is possible to define an electric hybrid vehicle having a very high recoverability-energy recovery capacity, and to minimize the weight and the volume of the electric transmission motor and the batteries. It is therefore particularly advantageous for a vehicle equipped with a system as shown to perform energy recovery during braking by using the hydraulic components first, when they are engaged in one of their speed range. . This energy recovery can be discriminated and controlled by the command. The recovery of electrical energy is advantageously used for the phases of engine braking or braking is not required, for example in descents.

Claims (14)

REVENDICATIONS1. Hydrostatic transmission system of a vehicle, characterized in that it comprises: - a primary motor (M) driving in rotation a primary shaft (31), - an output shaft (1) adapted to drive a rotating wheel, - a slow-moving hydraulic motor (42) with radial pistons configured to rotate at the speed of said wheel - a gear train (3) forming a mechanical chain between the primary shaft (31) and the output shaft (1) via a secondary shaft (32), - a variable displacement hydraulic pump (41) adapted to be selectively coupled or disengaged from the primary shaft (31), and adapted to supply pressure to said slow hydraulic motor (42), - a control (5), adapted to control the rotational drive of the output shaft (1) by the slow hydraulic motor (42), or the primary shaft (31) as a function of the speed of the output shaft (1). 2. System according to claim 1, wherein said control is adapted to define ranges of rotational speed values of the output shaft (1): a first range of values (W1) for which the output shaft (1) is driven only by the slow hydraulic motor (42); a second range of values (W3) for which the output shaft is driven by the primary motor (M) via said gear train (3); said first and second ranges of values (W1, W3) may comprise a plurality of common values (W2). 3. System according to claim 2, wherein said control (5) is adapted for, when the speed of rotation of the output shaft (1) is outside the first range of values, disengage said slow motor (42). . 4. System according to one of claims 2 or 3, wherein - the first range of values extends from 0 rpm to a value between 400 and 600, typically 500 revolutions per minute; the second range of values comprises the values beyond 400, 5600 or 500 revolutions per minute. 5. System according to one of claims 1 to 4, further comprising a differential (2) mounted on the output shaft and dividing it into a first (11) and a second (12) output shaft, said differential comprising a differential case comprising case gears adapted to cooperate with gears connected to said output shafts and thus drive said output shafts, the radial hydraulic slow-piston motor being coupled to said differential, and comprising a distributor and a multi-lobe cam defining a first set, - a cylinder block defining a second set, one of said sets being rotatably mounted relative to the differential case, and the other of said sets being rotatably mounted relative to the differential case so as to allowing the differential gearbox to be rotated by said slow hydraulic motor with radial pistons. 6. System according to one of claims 1 to 5, wherein said primary motor (M) is a heat engine or electric. 25 7. System according to one of claims 1 to 6, further comprising a fast motor (43) of the type axial piston hydraulic motor or electric motor, said control (5) being adapted to define a plurality of ranges of speed values. rotation of the output shaft: - a first range of values (V1) for which the output shaft (1) is driven only by the slow hydraulic motor (42) - a second range of values (V2) wherein the output shaft (1) is driven together by the slow hydraulic motor (42) and the fast motor (43); a third range of values (V3) for which the output shaft (1) is driven by the fast hydraulic motor (43) only; a fourth range of values (V4) for which the output shaft (1) is driven jointly by the fast motor (43) and the primary motor (M) via a gear train (3) ; a fifth range of values (V5) for which the output shaft (1) is driven solely by the primary motor (M) via a gear train (3). 8. System according to one of claims 1 to 7, further comprising at least one hydraulic accumulator, said system being configured so that during braking of the vehicle, the pump (41) and / or the hydraulic motors (42 and 43) have a reversible operation and load said hydraulic accumulator under pressure to perform a function of energy recovery. The system of claim 8, wherein said at least one hydraulic accumulator is adapted to selectively power the hydraulic pump (41) so that it has engine operation and provides assistance for driving the primary shaft. (31). 10. System according to one of claims 8 or 9, wherein the pump (41) is adapted to operate as a motor being powered by said at least one hydraulic accumulator, and thus perform a primary motor assistance (M) for driving the primary shaft (31). 11. A method of controlling the drive of an output shaft to which a wheel of a vehicle is connected, in which the driving of the output shaft (1) is controlled according to the desired speed, so that the output shaft (1) is selectively rotated - a slow hydraulic motor (42) configured to rotate at a speed of said wheel, or - a prime mover (M) via a gear train , the drive being selectively driven according to the speed of the output shaft. The method of claim 9, wherein a first range of values (W1) is defined for which the output shaft is driven only by the slow hydraulic motor (42); a second range of values (W3) for which the output shaft is driven by the primary motor via said gear train; said first and second ranges of values (W1, W3) may comprise a plurality of common values (W2). 13. Method according to one of claims 11 or 12, wherein during a braking of the vehicle, said slow hydraulic motor (42) is piloted so that it charges a hydraulic accumulator and thus performs a recovery function. energy. 14. The method of claim 13, wherein beyond a threshold value, driving a hydraulic pump (41) reversible so that it is fed a hydraulic accumulator, and it performs a motor assistance primary (M).