초록 ▼

A pressure control valve assembly is disposed in the hydraulic flow path of a differential assembly and is connected to a passageway leading to a limited slip device within the differential case to establish fluid communication there between. The invention includes a machined or formed blind hole, a

A pressure control valve assembly is disposed in the hydraulic flow path of a differential assembly and is connected to a passageway leading to a limited slip device within the differential case to establish fluid communication there between. The invention includes a machined or formed blind hole, a groove which partially intersects the blind hole, a ball member seated in the blind hole, and a spring resiliently acting on the ball to apply a force biasing the ball into the blind hole. At the intersection of the blind hole and groove, an area, which is not sealed by the ball, is formed that provides a controlled leakage path for the hydraulic fluid. As the hydraulic fluid flow increases, the hydraulic pressure of the fluid on the pressure side increases which increases the force on the ball acting against the spring. As the pressure increases further, the resultant forces on the ball deflect the spring to increase the bleed area and increase the fluid bled proportionally to the fluid pressure. Therefore, a pressure control mechanism is provided.

대표청구항 ▼

1. A pressure control valve assembly, comprising: an intermediate member separating a first area of high pressure with a second area of low pressure; a bore defining a blind hole extending from said first area to said second area to provide fluid communication therebetween; a groove which partiall

1. A pressure control valve assembly, comprising: an intermediate member separating a first area of high pressure with a second area of low pressure; a bore defining a blind hole extending from said first area to said second area to provide fluid communication therebetween; a groove which partially intersects the blind hole, said groove being disposed on a high pressure side of said intermediate member, said groove extending along a length of said bore from said first area to said blind hole; a ball member seated in the blind hole, said ball member disposed on a low pressure side of said intermediate member; and a spring resiliently acting on the ball member to apply a force biasing the ball into the blind hole, wherein at an intersection of the blind hole and groove, an area is formed that provides a controlled leakage path for the hydraulic fluid when said ball member is seated in said blind hole, wherein as flow of the hydraulic fluid increases, hydraulic pressure of the fluid on the first area of high pressure increases which increases the force on the ball acting against the spring, and wherein fluid disposed in said first area of high pressure actuates a limited slip device within a differential gear assembly. 2. The valve assembly according to claim 1, wherein as the pressure further increases, a resultant forces on the ball member deflect the spring to increase the bleed area and increase the fluid bled proportionally to the fluid pressure. 3. The valve assembly according to claim 1, wherein said intermediate member is a differential case of a differential gear assembly. 4. The valve assembly according to claim 1, wherein said intermediate member is an actuation piston for applying axial force to a limited slip device of a differential gear assembly. 5. The valve assembly according to claim 1, wherein said spring is a cantilevered beam affixed to said intermediate member. 6. The valve assembly according to claim 1, wherein said spring is formed of a temperature sensitive material having a spring force that varies with changes in temperature. 7. The valve assembly according to claim 1, wherein an area defined by said controlled leakage path may be varied by changing dimensions of at least one said blind hole, said groove and said ball member. 8. A pressure control valve assembly in a differential axle assembly comprising: a differential case containing a differential gear assembly driven by an input shaft and adapted to allow differential rotational speed between a pair of opposing output shafts; a hydraulic flow path for hydraulic fluid of said differential gear assembly leading to a limited slip device within the differential case; a valve member comprising: a bore defining a blind hole disposed in said differential case;a groove which partially intersects the blind hole, said groove being disposed on a high pressure side of said differential case, said groove extending along a length of said bore and extending from said high pressure side to said blind hole;a ball member seated in the blind hole adjacent said groove; anda spring resiliently acting on the ball member to apply a force biasing the ball member into the blind hole toward said high pressure side, wherein at an intersection of the blind hole and groove, an area is formed that provides a controlled leakage path for the hydraulic fluid, and wherein as flow of the hydraulic fluid increases, hydraulic pressure of the fluid on the high pressure side increases which increases the force on the ball member acting against the spring. 9. The valve assembly according to claim 8, wherein as the pressure further increases, a resultant forces on the ball member deflect the spring to increase the bleed area and increase the fluid bled proportionally to the fluid pressure. 10. The valve assembly according to claim 8, wherein said spring and ball member are removably secured to said differential case. 11. The valve assembly according to claim 8, wherein said sp ring is a cantilevered beam affixed to said differential case. 12. The valve assembly according to claim 8, wherein said spring is a coil spring mounted to said differential case. 13. A pressure control valve assembly in a torque coupling assembly comprising: a torque input member driven by an input shaft; a torque output member receiving torque from said torque input member; a clutch device for drivingly connecting said torque input member with said torque output member; a hydraulic actuation assembly for actuating said clutch device; a hydraulic flow path for hydraulic fluid of said hydraulic actuation assembly leading from a first area of high pressure to a second area of low pressure; a valve assembly interposed between said first area of high pressure and said second area of low pressure, said valve assembly comprising: a bore defining a blind hole disposed in an intermediate member of said actuation assembly;a groove which partially intersects the blind hole, said groove being disposed on a high pressure side of said intermediate member and extending along a length of said bore from said first area to said blind hole;a ball member seated in the blind hole opposite said groove with respect to said intermediate member; anda spring resiliently acting on the ball member to apply a force biasing the ball member into the blind hole toward said high pressure side, wherein at an intersection of the blind hole and groove, an area is formed that provides a controlled leakage path for the hydraulic fluid, and wherein as flow of the hydraulic fluid increases, hydraulic pressure of the fluid on the high pressure side increases which increases the force on the ball member acting against the spring. 14. The valve assembly according to claim 13, wherein as the pressure further increases, a resultant forces on the ball deflect the spring to increase the bleed area and increase the fluid bled proportionally to the fluid pressure. 15. The valve assembly according to claim 13, wherein said intermediate member is an actuation piston actuating said clutch device. 16. The valve assembly according to claim 15, wherein said spring is a cantilevered beam affixed to said actuation piston. 17. The valve assembly according to claim 15, wherein said spring is a coil spring mounted to said actuation piston. 18. The valve assembly according to claim 13, wherein said spring is formed of a temperature sensitive material having a spring force that varies with changes in temperature.