FR2809153A1 - Assembly for vehicle transmission has first and second gears with pinions mobile around the same axis and pinions associated to the stage carrier, equilibrated with a mass - Google Patents

Abstract

Assembly is made of two parallel gear, where the crown gear (C) is driven by the motor couple and both the planetary gear (P) and the stage carrier (S) are submitted to a resistant couple. The first gear (C,SE) and the second gear (P,SI) have pinions (C,P) mobile around the same axis and pinions (SE,SI) associated to the stage carrier (S). The stage carrier is equilibrated with a mass (M). The tolerance between teeth (C,SE) can be compensated by a mechanism.

Description

The present invention relates to a planetary differential composed of two parallel gears for limiting the angular operating gears for distributing motor torque as required.

An all-wheel drive for a motor vehicle uses three planetary differentials; a first to distribute the engine torque between the front and rear gear in a ratio that is a function of the characteristics of the motor vehicle, and two others to distribute the engine torque in a ratio <B> 50150 </ B> between the two wheels of the same train.

Often used, the planet differential shown in Figure 01 has nine contacts between teeth and its angular play of operation is important.

Automatic or driver-controlled mechanical systems to manage slips of these three differentials are heavy, bulky and lack flexibility and speed; to overcome these defects and improve the dynamic behavior of the motor vehicle, the slips are increasingly often managed by braking individual and appropriate each wheel axle from a theoretical rotation speed.

Sensors inform the electronic system which manages the dynamic behavior of the motor vehicle of the angular displacements of the four driving wheels and the accumulation of the operating sets of the three planetary differentials disrupts the efficiency of the system.

The planetary differential composed of two parallel gears according to the invention overcomes this disadvantage because it is composed of two parallel gears and a parallel gear can operate with limited backlash and even zero with the use of a catch-up mechanism. Thu.

According to particular embodiments - The two gears that make up the planetary differential combine a pinion with external toothing and a pinion with internal teeth.

The satellite can be in one piece with an external toothing and an internal toothing or formed by the assembly of two pinions, one with external toothing and the other with internal toothing.

- The satellite door which is an eccentric must be dynamically balanced. The planetary differential according to FIG. 02 is composed of two parallel gears whose gears rotate two by two around the same axis; a first parallel gear associates the ring gear with internal teeth et and the outer gear gear SE; a second parallel gear associates the sun gear with external toothing P and the gear with internal teeth the ring gear C and the sun gear P rotate around the same axis of rotation; two pinions, with external toothing SE and with internal toothing SI are connected in rotation to form the satellite which rotates the satellite gate S, which to balance dynamically by a mass M.

C: number of crown teeth C.

Ç: angular displacement of the crown Ç. P: number of teeth of the sun gear P.

P: angular displacement of the sun gear P.

<B> SE: </ B> number of teeth of the SE satellite with external toothing. SI: number of teeth of the SI satellite with internal teeth. S: angular displacement of the satellite gate S.

For the gears, the same mark represents the number of teeth and underlines its angular displacement.

 Installation rules to follow: SI - P = C - SE, with the same module for all sprockets.

The coppice formula (C-S) I (P-S) + (PIC) applies both to the epicyclic gear train commonly used in FIG. 01 and to the epicyclic gear train according to the invention of FIG. angular displacements between the crown Ç, the sun gear P and the satellite gate S, are established as follows: = = + (PIC) P + (C-PIC) S.

most of the time, the crown Ç is driven by the engine torque while the sun gear P and the satellite carrier S are subjected to the two resistant couples; when crown ne does not rotate, the relationship between the angular displacements between sun gear P and the satellite gate S is established in both cases according to P = - (C - PIP) S, which indicates that it is a good a differential distribution with torque distribution the angular displacement of the sun gear P causes an angular displacement in the opposite direction of the satellite carrier S, and vice versa.

The torque distribution between the two outlets is a function of the number of teeth of the crown et and the sun gear P, and by way of non-limiting example - When crown C has 40 teeth and the sun gear P has 22 teeth, distribution of 55 I 45 which may correspond to a planetary differential with a distribution of torque situated between the nose gear and the rear axle of a four-wheel drive motor vehicle.

- When the ring Ç has twice the number of teeth than the sun gear P the distribution is 50I50, which corresponds to a differential symmetrical torque distribution between two wheels of the same motor vehicle train.

According to a first variant illustrated in FIG. 03, the torque distribution planetary differential shown in FIG. 02 is supplemented by an RJC backlash mechanism, on the teeth of the parallel gear formed by ring gear C and the gear wheel. external SE, and an RJP clearance mechanism, on the teeth of the parallel gear formed by the sun gear with external teeth P and the inner gear SI.

According to a second non-illustrated variant, the planetary differential torque distribution is supplemented by an automatic mechanical system controlled by the driver to manage or eliminate the angular displacements between its three elements which are: the crown Ç, the sun gear P and satellite holder S.

According to a third variant not shown, the planetary differential torque distribution has a satellite in one piece with an external toothing and an internal toothing.

planetary differential according to the invention is particularly intended to equip motor vehicles with two or four driving wheels which use an electronic system to manage the dynamic behavior by braking individually and appropriately each wheel axle from the theoretical values of the speeds of rotation.

Claims (1)

Planetary differential composed of two parallel gears for limiting angular operating sets to distribute a motor torque according to needs characterized in that it is formed of three elements whose angular displacements are connected so that when the crown Ç is driven by the motor torque, the sun gear P and the satellite carrier S can be subjected to two resistant pairs. 2) planetary differential for distributing a motor torque according to claim 1 characterized in that, relative to the ring,, angular displacement of a member subjected to a resistive torque causes angular displacement in the opposite direction of the other element also subjected to torque resistant. 3) planetary differential for distributing a driving torque according to claim 1 or claim 2 characterized in that it is composed of two parallel gears whose gears rotate two by two around the same axis; a first parallel gear associates the ring gear with internal teeth et and the outer gear gear SE; a second parallel gear combines the sun gear P and the inner gear SI; the crown Ç and the sun gear P rotate around the same axis of rotation; the two pinions, with external teeth SE and with internal teeth SI, are connected in rotation to form the satellite which rotates the satellite gate S. 4) Planetary differential for distributing a driving torque according to any one of the preceding claims, characterized in that that the satellite gate S must be dynamically balanced. 5) Planetary differential for distributing a driving torque according to any one of the preceding claims, characterized in that it allows a backlash mechanism between RJC teeth, to equip the first parallel gear that combines the ring gear with internal teeth et and the outer gear SE, and a mechanism for compensating clearance between RJP teeth, to equip the second parallel gear that combines the sun gear with external gear P and inner gear SI gear. 6) Planetary differential for distributing a driving torque according to any preceding claim characterized in that it authorizes automatic mechanical system or controlled by the driver to limit remove angular displacements between its three elements which are: the crown Ç, the sun gear P and the satellite gate S.