초록 ▼

A valve assembly (2) forming a bridge circuit and a hydraulic actuator comprising at least one valve assembly (2) are disclosed. The valve assembly (2) is fluidly connectable between a fluid source (3) and a fluid drain (4). The valve assembly (2) comprises a first valve (8) fluidly connected betwee

A valve assembly (2) forming a bridge circuit and a hydraulic actuator comprising at least one valve assembly (2) are disclosed. The valve assembly (2) is fluidly connectable between a fluid source (3) and a fluid drain (4). The valve assembly (2) comprises a first valve (8) fluidly connected between the fluid source (3) and a first diagonal point (12) of the bridge circuit, a second valve (9) fluidly connected between the fluid source (3) and a second diagonal point (13) of the bridge circuit, a third valve (10) fluidly connected between the first diagonal point (12) and the fluid drain (4), and a fourth valve (11) fluidly connected between the second diagonal point (13) and the fluid drain (4). The valves (8, 9, 10, 11) are such that in the case of a power cut off, flows of fluid away from the diagonal points (12, 13) are prevented. Thereby a hydraulic servomotor (5) connected across the diagonal points (12, 13) will be hydraulically locked in its instantaneous position, and a safety feature is accordingly provided. The first valve (8) and the second valve (9) are furthermore of a kind which is closed in an energized state. Thereby it is possible to control the valve assembly (2) in such a manner that a piston member (14) of a servomotor (5) connected across the diagonal points (12, 13) can be moved at a high velocity, thereby providing a servomotor (5) having a quick response time.

대표청구항 ▼

What is claimed is: 1. A hydraulic circuit comprising: at least one valve assembly forming a bridge circuit and being fluidly connectable between a fluid source and a fluid drain, the valve assembly comprising: at least one first valve fluidly connected between the fluid source and a first diagonal

What is claimed is: 1. A hydraulic circuit comprising: at least one valve assembly forming a bridge circuit and being fluidly connectable between a fluid source and a fluid drain, the valve assembly comprising: at least one first valve fluidly connected between the fluid source and a first diagonal point of the bridge circuit, said at least one first valve being a valve which is normally open in a de-energized state, at least in a direction from the fluid source towards the first diagonal point, at least one second valve fluidly connected between the fluid source and a second diagonal point of the bridge circuit, said at least one second valve being a valve which is normally open in a de-energized state, at least in a direction from the fluid source towards the second diagonal point, at least one third valve fluidly connected between the first diagonal point of the bridge circuit and the fluid drain, said at least one third valve being a valve which is normally closed in a de-energized state, and at least one fourth valve fluidly connected between the second diagonal point of the bridge circuit and the fluid drain, said at least one fourth valve being a valve which is normally closed in a de-energized state, and a hydraulic servomotor having a first chamber fluidly connected to the first diagonal point and a second chamber fluidly connected to the second diagonal point such that the valve assembly controls flow in and out of the first and second chambers to move the hydraulic servomotor, wherein the valve assembly retains the position of the hydraulic servomotor in the event that a failure is detected. 2. The hydraulic circuit according to claim 1, wherein at least one of the valves is an electrically operable valve. 3. The hydraulic circuit according to claim 1, wherein the valves of the valve assembly are controlled by means of a closed loop control of the hydraulic servomotor. 4. The hydraulic circuit according to claim 3, further comprising at least one sensor, said sensor(s) being adapted to provide an input signal to the closed loop control. 5. The hydraulic circuit according to claim 1, wherein at least one of the valves of the valve assembly is driven by a pulse train signal. 6. Use of a hydraulic circuit according to claim 1 in a hydro-mechanical transmission (HMT). 7. The hydraulic circuit according to claim 1, further comprising at least one additional hydraulic servomotor fluidly connected between the first diagonal point and the second diagonal point. 8. The hydraulic circuit according to claim 1, wherein the at least one valve assembly is arranged in a modular configuration. 9. The hydraulic circuit according to claim 1, wherein the at least one valve assembly is arranged with a number of identical valve assemblies in such a manner that redundant control of the hydraulic servomotor is obtained. 10. A hydraulic circuit comprising: at least one valve assembly forming a bridge circuit and being fluidly connected between a fluid source and a fluid drain, the valve assembly comprising: at least one first valve fluidly connected between the fluid source and a first diagonal point of the bridge circuit, said at least one first valve being a valve which is normally open in a de-energized state, at least in a direction from the fluid source towards the first diagonal point, at least one second valve fluidly connected between the fluid source and a second diagonal point of the bridge circuit, said at least one second valve being a valve which is normally open in a de-energized state, at least in a direction from the fluid source towards the second diagonal point, at least one third valve fluidly connected between the first diagonal point of the bridge circuit and the fluid drain, said at least one third valve being a valve which is normally closed in a de-energized state, and at least one fourth valve fluidly connected between the second diagonal point of the bridge circuit and the fluid drain, said at least one fourth valve being a valve which is normally closed in a de-energized state, and a variable displacement unit having a first chamber fluidly connected to the first diagonal point and a second chamber fluidly connected to the second diagonal point such that the valve assembly controls flow in and out of the first and second chambers to vary the displacement volume of the variable displacement unit, wherein the valve assembly retains the position of the variable displacement unit in the event that a failure is detected. 11. The hydraulic circuit according to claim 10, wherein the at least one valve assembly is arranged in a modular configuration. 12. Use of a hydraulic circuit according to claim 10 in a hydro-mechanical transmission (HMT). 13. A hydraulic circuit comprising: at least one valve assembly forming a bridge circuit and being fluidly connectable between a fluid source and a fluid drain, the valve assembly comprising: at least one first valve fluidly connected between the fluid source and a first diagonal point of the bridge circuit, said at least one first valve being a valve which is normally open in a de-energized state, at least in a direction from the fluid source towards the first diagonal point, at least one second valve fluidly connected between the fluid source and a second diagonal point of the bridge circuit, said at least one second valve being a valve which is normally open in a de-energized state, at least in a direction from the fluid source towards the second diagonal point, at least one third valve fluidly connected between the first diagonal point of the bridge circuit and the fluid drain, said at least one third valve being a valve which is normally closed in a de-energized state, and at least one fourth valve fluidly connected between the second diagonal point of the bridge circuit and the fluid drain, said at least one fourth valve being a valve which is normally closed in a de-energized state, a variable displacement unit, fluidly arranged in a hydraulic main line, having a first chamber fluidly connected to the first diagonal point and a second chamber fluidly connected to the second diagonal point such that the valve assembly controls flow in and out of the first and second chambers to vary the displacement volume of the variable displacement unit, and a fixed displacement unit in fluid communication with the variable displacement unit through a hydraulic main line, wherein the valve assembly retains the position of the variable displacement unit in the event that a failure is detected.