The invention relates to a distribution system for distribution torque between front and rear axles in all wheel drive vehicles and/or distribution of torque between left and right wheels in two or four wheel drive vehicles. The invention refers more precisely to a pump coupling or hydraulic actuator controlling one or more limited slip couplings of a distribution system.
In all wheel drive vehicles there is often a multiple disc clutch that is actuated for distribution of torque between front and rear axles. Such a multiple disc clutch may also be used in distribution of torque between left and right wheels. The multiple disc clutches are often actuated by some kind of hydraulic actuation. In EP 1 256 478 one example of such a hydraulic actuation is shown. It has a hydraulic pump, acting in opposite directions of speed, an oil pressure sensor, two bypass orifice valves, a non-return valve, a relief valve and a quick open valve.
There is a constant strive to reduce costs. This is often done by simplifying existing system and it could also be done by reducing the space needed for a specific system. Less space occupied will simplify adapting the system to different vehicles.
Thus, one object of the present invention is to reduce the number of the hydraulic components (no bypass orifice valves) for a robust design, more compact installation, lower weight and lower productions costs. Furthermore, in the present invention no pressure sensor is needed. A further general object is to arrange a simple but yet reliable actuation system for a multiple disc clutch in a torque distribution system for example for all wheel drive vehicles. Another object is that the actuation system should react promptly on regulation signals.
According to the invention this is achieved in a torque distribution system having a hydraulic actuator comprising an electric motor, a hydraulic pump and a limited slip coupling. The hydraulic pump is driven by means of a drive shaft of the electric motor. The limited slip coupling comprises a disc package and a piston acting on the disc package. The piston is actuated by means of the hydraulic pump. Furthermore, a centrifugal regulator is connected to a rotating part of the electric motor or the hydraulic pump. The rotating part is often the drive shaft of the electric motor. The centrifugal regulator controls a pressure overflow valve connected to an oil outlet of the hydraulic pump. A relief valve is connected to a cylinder chamber encompassing the piston of the limited slip coupling.
Further objects and advantages of the present invention will be obvious to a person skilled in the art reading the detailed description below of embodiments of the present invention.
The invention will be described by way of examples below and with reference to the enclosed drawings. In the drawings
In
The examples of
In the example of
In the example of
In the example of
In the example of
The piston 13 of the limited slip coupling 7 shown in
The electric motor 16 is normally a brush DC motor. A drive shaft 18 of the electric motor 16 is connected to and drives the hydraulic pump 17. The hydraulic pump 17 may be any kind of pump, such as a gear pump, a van pump, a radial piston pump or an axial piston pump. A centrifugal regulator 23 is integrated with the hydraulic pump 17 and controls the pressure overflow valve. Also the centrifugal regulator 23 is connected to and is driven by the drive shaft 18 of the electric motor 16. In other embodiments the centrifugal regulator 23 is connected to a rotating part of the hydraulic pump 17 instead of the drive shaft 18 of the electric motor 16.
The hydraulic pump 17 has an oil inlet 20 and an oil outlet 21. The oil outlet 21 is connected to the cylinder chamber 14 encompassing the piston 13. The relief valve 19 is also connected to said cylinder chamber 14 encompassing the piston 13. Both the oil outlet 21 of the hydraulic pump 17 and the relief valve 19 are connected to the same side of the piston 13. Furthermore, an overflow outlet 28 of a pressure overflow valve is connected to the oil outlet 21 of the hydraulic pump 17.
One further function of the pressure overflow valve is to have a leakage in the system so that the electric motor 16 will run constantly (not burn brushes in a not running DC motor). The electric motor 16 will have a very short reaction time to build up pressure in the system as the electric motor 16 already is running, and, thus, less energy will be spent for accelerating rotating parts.
The pressure overflow valve has a washer 27 closing off an overflow outlet 28 of the hydraulic pump 17. One or more springs 29 are acting on one side of the washer 27 to lift the washer from the overflow outlet 28. The one or more springs 29 are placed in one or more recesses 30 of the hydraulic pump 17. The centrifugal regulator 23 is acting on the opposite side of the washer 27 to press the washer 27 against the overflow outlet 28. The force of the centrifugal regulator 23 acting on the washer 27 depends on the rotational speed of the centrifugal regulator 23, or put in other words, the rotational speed of the drive shaft 18 of the electric motor 16 or a rotating part of the hydraulic pump 7, whichever the centrifugal regulator 23 is connected to. The higher rotational speed the higher the force generated by the centrifugal regulator 23.
The washer 27 of the pressure overflow valve may be supported in several different ways. In one embodiment an axial bearing supports the washer 27 and in another embodiment the washer 27 is a glide washer gliding on an oil film.
The integrated centrifugal regulator 23 regulates the pressure at the oil outlet 21 of the pump 17. In the embodiment of
An alternative embodiment of the centrifugal regulator is indicated in
Instead of connecting to the outlet port of the pump the pressure overflow valve could also be connected to each piston in a piston pump.
The function of the relief valve 19 is to get rid of air in the system in the assembly process, to have a second way to control maximum pressure in the system and have a chance to calibrate the system during its lifetime.
The hydraulic pump 17 should be of a design having a good correlation between input torque to the pump 17 and pressure at a certain temperature. With an electrical controller 105 with a temperature sensor 110 integrated in the limited slip coupling 7 the control system 100 take care of changes between pressure/input pump torque and changes of current/DC-motor torque at different temperatures. In the preferred application the pressure is in principle controlled by current. The voltage to the DC motor 16 is regulated by means of the centrifugal regulator 23, see
Another way of controlling the pressure in the system is to control the DC motor 16 speed using the information from the centrifugal regulator 23, see
The DC motor 16 is always running when the vehicle drives. In open mode (ABS situation for example) of the clutch, the motor is running with a speed keeping the pressure overflow valve open, area A in
Compared to the prior art systems the opening time (go to ABS mode) will be shorter as the motor does not need to go down to zero, then reverse and open a quick open valve. The pressure will go down when the DC motor starts to decelerate.
In
Number | Date | Country | Kind |
---|---|---|---|
0801794 | Aug 2008 | SE | national |
The present application is a continuation of pending International patent application PCT/SE2009/050883 filed on Jul. 9, 2009 which designates the United States and claims priority from Swedish patent application 0801794-9 filed on Aug. 14, 2008, the content of which is incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
3748928 | Shiber | Jul 1973 | A |
4084601 | Rowen | Apr 1978 | A |
Number | Date | Country |
---|---|---|
1256478 | Nov 2002 | EP |
1795391 | Jun 2007 | EP |
1830096 | Sep 2007 | EP |
2278674 | Dec 1994 | GB |
5104974 | Apr 1993 | JP |
Number | Date | Country | |
---|---|---|---|
20110192695 A1 | Aug 2011 | US |
Number | Date | Country | |
---|---|---|---|
Parent | PCT/SE2009/050883 | Jul 2009 | US |
Child | 13021316 | US |