RU2654260C1 - Self-locking differential for automobile - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to differential mechanisms with automatic blocking devices. Said self-locking differential includes a casing, half-axle gears with satellites and a locking device made in the form of a reversible hydraulic pump, that includes a stator, rotor, blades with springs, distribution disk, cover, back-pressure valves and suction, discharge and outlet channels. Above locking device has two differential lock valves installed after the check valves in the axial parts of the output channels, each of which consists of a piston with diametrically located axial rectangular grooves along its height and compression spring, which is installed in the coaxial hole following the bore of the piston, with a diameter equal to the inner diameter of said axial rectangular grooves on the piston. Said piston has a conical chamfer on the right of the height of these axial rectangular grooves, and the bottom of the hole under the piston - the corresponding conical surface.

EFFECT: increase in the blocking properties of the differential and high efficiency is achieved.

1 cl, 2 dwg

Description

The invention relates to transport engineering, in particular to differential mechanisms with locking devices, and is intended for use in vehicles as cross-axle or center differential.

A self-locking differential with hydraulic resistance is known, comprising a gear reducer with bevel gears installed in the differential box and a locking device made in the form of hydraulic machines to slow down the relative rotation of the box and one of the gears of the gearbox (US patent No. 2861477, 1958).

The disadvantages of this differential are minor blocking properties and the complexity of the design of the hydraulic lock.

The closest in technical essence to the proposed device is a hydraulic differential (a conical self-locking differential with hydraulic resistance), containing semi-axial gears installed in the differential housing engaged with the satellites, and a locking device for connecting the differential housing and semi-axial gears, made in the form of a reversed blade oil pump with check valves, the rotor of which is rigidly connected to the left half-axle gear, and the stator is fixed on and in the differential case, in the case when the semi-axial gears rotate at different angular speeds, the oil pump pumps oil (working fluid) through a narrow output channel, receiving power through the suction channel, which creates resistance to the rotation of the semi-axial gears; the oil flow into the cavity of the differential housing is provided by scoops, locking is carried out both when moving forward and backward (Osepchugov V.V., Frumkin A.K. Automobile. Structural analysis, calculation elements. - M .: Mechanical Engineering, 1989. - P. 161-162, Fig. 133).

The disadvantage of this differential is the low blocking properties, due to the fact that to increase them, it is necessary to increase the resistance to rotation of the vane pump by (with other specified parameters) reducing the cross section of the output channel of the working fluid, which, in turn, will lead to a decrease in the efficiency ( Efficiency) of the differential also when driving a vehicle (ATS) on a bend or on rough roads and increase fuel consumption.

The technical result of the proposed self-locking differential to the car is to increase the blocking properties of the differential in the case of slipping of one of the wheels of the drive axle of the vehicle and the absence (insignificance) of the blocking properties of the differential, and its high efficiency when the ATS moves on a bend or on rough roads.

The specified technical result is achieved by the fact that in the limited-slip differential to the car, containing semi-axial gears installed in the differential case, engaged into gears mounted on the axles, and a locking device for coupling the differential case and semi-axial gears, made in the form of a rotary reversible hydraulic pump filled with working fluid, including stator, rotor, blades with springs, distribution disk, cover, check valves and suction, discharge and outlet e channels, the locking device has two differential lock valves installed after the check valves in the axial parts of the output channels, each of which consists of a piston facing the check valve with diametrically located axial rectangular grooves along its height and a return spring installed in the hole following under the piston is a coaxial bore with a diameter equal to the inner diameter of the indicated axial rectangular grooves on the piston, and this piston is on the right height of these axial holes of the angular grooves has a conical chamfer, and the bottom of the hole for the piston has the corresponding conical surface, and the piston, in the absence of slipping of one of the drive wheels of the ATS bridge, does not reach the bottom of the hole for this piston, and when the piston is moved to the right, when the ATS is slipping, the bottom of the hole for the piston can close the outlets of the working fluid from the axial rectangular grooves of the piston and thus block the differential, which allows the vehicle to move on a bend or on rough roads due to the small difference the angular velocities of the differential housing and semiaxis and, therefore, the small pressure of the working fluid created by the hydraulic pump, have the outlets for the working fluid from the axial rectangular grooves of the piston fully open, the differential blocking properties are insignificant (absent), and the differential efficiency is high, and when slipping one of the drive wheels of the ATS bridge due to the large difference in the angular velocities of the differential housing and the semi-axis by the action of high pressure of the working fluid created by the hydraulic pump, place the piston of the locking valve to the right and with the bottom of the hole for this piston to partially or completely block the flow of working fluid from the axial rectangular grooves of this piston, thus blocking the differential, providing it with high blocking properties, the possibility of stopping slipping and further movement of the vehicle.

The device of the proposed limited slip differential to the vehicle is illustrated by the attached drawings, where in FIG. 1 shows a frontal section, in FIG. 2 - profile section.

The proposed self-locking differential for the vehicle contains the axle gears 2 installed in the differential housing 1 engaged into engagement with the satellites 4 mounted on the axles 3, and a locking device for coupling the differential housing and the axle gears, made in the form of a hydraulic reversible (double-acting) impeller hydraulic pump including stator 5, rotor 6, blades 7 with springs 8, distribution disk 9, cover 10, check valves 11 and suction 12, pressure 13 and output channels 14 (two in two) in the differential housing. The stator 5 is attached to the differential housing 1, and its rotor 6 is connected to the left gear axle 2 and through it to the gear axle 15 of the drive axle. The locking device has installed after the check valves 11 in the axial parts adjacent to the stator 5, the openings 16, 17 of the output channels in the differential housing have two differential lock valves. Each blocking valve consists of a piston 18 facing the non-return valve 18 with axial rectangular grooves 19 diametrically located on its lateral cylindrical surface along its height and a compression return spring 20 installed in the coaxial bore (smaller diameter) 17 of the diameter following the piston bore 16, equal to the inner diameter (the diameter of the longitudinal axis of symmetry of the bottom) of the indicated axial rectangular grooves on the piston, and this piston is to the right of the height of these axial rectangular grooves has a conical facet 21, and the bottom 22 of the hole for the piston has a corresponding conical surface, and the piston in the absence of slipping of one of the drive wheels of the bridge or in the inoperative state of the vehicle does not reach the conical bottom (in the form of a ring) 22 holes 16 for this piston (as in Fig. 1), and when moving the piston to the right, when slipping the ATS, the conical bottom 22 of the hole 16 for the piston can close the outlets (to the right of the piston) of the working fluid from the axial rectangular grooves of the piston and thus block the differential l The cross-sectional area of the holes 16, 17 for the blocking valve and the outlet channel 14 should be several times larger than the total cross-sectional area of all axial rectangular grooves of the piston. The cavity of the lock-up valve opening in the area of the return spring may additionally communicate with the differential cavity by a compensation hole (not shown in the diagram).

The flow of working fluid into the cavity of the differential housing and to the suction channel 12 of the vane pump of the locking device is provided by the scoops 23.

The use of a reversible hydraulic pump and, accordingly, in this regard, two blocking valves in the differential is due to the fact that one blocking valve works with one half (Fig. 2) of its stator, in the case when the stator and rotor with different angular velocities when slipping the drive wheel of a vehicle rotate in one direction, and the second - with the other half of the stator, when the rotor of the hydraulic pump (axle shaft with a wheel) is standing, and the stator rotates, which can occur both when the vehicle moves forward and rear m move.

In the proposed limited-slip differential, it is desirable to apply a working fluid to the vehicle, the viscosity of which, under given operating conditions, varies slightly depending on its temperature. In other cases, the calculation of the parameters of the interlock and the interlock valve should take into account changes in the viscosity of this fluid.

The proposed limited-slip differential to the car works as follows.

When the vehicle is moving on a bend or on rough roads due to the small difference in the angular velocities of the differential housing 1 and the axle shaft 15 and, therefore, the small supply and pressure of the working fluid created by the hydraulic pump in the radial discharge channel 13 of the stator, the blocking valve is in the position as in FIG. . 1, and the working fluid, passing through the check valve 11, flows freely through the axial rectangular grooves 19 of the piston 18, the cavity of the holes 16, 17 for this piston and the return valve 20 of the blocking valve and the output channel 14 into the differential cavity, while the differential blocking properties are absent , and the efficiency of the differential is high. When slipping one of the drive wheels of the ATS bridge, due to the large difference in the angular speeds of the differential housing and the axle shaft under the action of high pressure of the working fluid generated by the hydraulic pump in the radial discharge channel 13 of the stator, the piston 18 of the lock valve, compressing the return spring 20, moves to the right and the conical bottom 22 holes 16 for this piston partially or completely (depending on the slipping of the wheel) the flow of working fluid from the axial rectangular grooves 19 of the piston 18 is blocked and, therefore, through a blocking valve, which causes a corresponding significant increase in the pressure of the working fluid in the injection cavity and the resistance to rotation of the hydraulic pump (thus blocking the differential) and limits (up to a stop) slipping of the skid wheel and the vehicle if the resistance to its movement does not exceed the total traction force the clutch of the wheels of this drive axle with the road will continue to move. In this case, due to the absence (or small) difference in the angular velocities of the differential housing and the axle shaft of the bridge, the pressure of the working fluid will drop in the radial discharge channel of the stator of the hydraulic pump and as a result of this, under the action of the return spring 20, the piston 18 of the lock valve will move to the left (it will move away from the conical bottom 22 of the hole 16) , to the initial position (as in Fig. 1), and the passage for the working fluid from the axial rectangular grooves 19 of the piston 18 of the lock valve will again become completely open, i.e. differential unlocks.

Thus, the proposed self-locking differential to the car allows to provide high blocking properties when slipping one of the drive wheels of the bridge and, therefore, a high cross-country ability of the vehicle and the absence (insignificance) of the blocking properties and high efficiency of the differential when the ATS moves on a bend or on rough roads.

Claims (1)

A self-locking differential to the car, containing the semi-axial gears installed in the differential housing engaged with the satellites mounted on the axles, and a locking device for connecting the differential housing and the semi-axial gears, made in the form of a rotary reversible hydraulic pump filled with working fluid, including a stator, a rotor, and blades with springs, distribution disk, cover, check valves and suction, discharge and output channels, characterized in that the locking devices о has two differential lock valves installed after the check valves in the axial parts of the output channels, each of which consists of a piston facing the check valve with diametrically located axial rectangular grooves along its height and a return spring installed in the coaxial hole following the piston bore a diameter equal to the inner diameter of said axial rectangular grooves on the piston, and this piston has a conical right height for these axial rectangular grooves th facet and the bottom of the hole for the piston - corresponding conical surface, the piston being in the absence of slippage of the drive wheels of one vehicle axle does not reach the bottom of the hole under the piston.

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