This application claims priority to European Patent Application No. 17306646.5 filed Nov. 27, 2017, the entire contents of which is incorporated herein by reference.
The present disclosure relates to mode valves used to manage the control of fluid and thereby to manage the control of moveable surfaces e.g. to control a hydraulic flight control actuator.
Mode valves find a wide range of applications for controlling air or fluid flow to effect driving or control of another part e.g. an actuator.
Mode valves are well-known in drive or actuator systems to select a functional mode. Conventional spool/sleeve mode valves comprise a spool, linearly moveable within a bore or sleeve in a valve cylinder or housing in response to a control input, such as to enable hydraulic fluid flow paths through the valve to a port to provide output drive power. The spool moves between an ON and an OFF state at respective ends of the sleeve.
Conventionally, electro-hydraulic primary flight control actuators incorporate two modes of operation from a single spool/sleeve valve, namely an active mode and a damped mode. In the active mode, the actuator drives the surface of e.g. the aircraft. In the damped mode, the actuator is back-driven by the surface (aerodynamic load or adjacent active actuator) and provides a drag load.
In the active mode, the spool is positioned in the sleeve such that fluid from a fluid distributor or driver such as a servovalve flows into the chambers of the actuator to drive the actuator to move the surface. In the damped mode, the spool is positioned within the sleeve so that the fluid from the servovalve cannot flow through the spool/sleeve ports into the actuator chambers and, instead, the lands and ports of the spool/sleeve are aligned so as to fluidly connect the actuator chambers such that fluid in the system flows between the actuator chambers. The easier the fluid circulates, the less drag is generated on the actuator rod motion. One of the ports of the spool/sleeve valve defining the fluid path between the actuation chambers is a damping orifice which is a small orifice to restrict the fluid path. This creates a pressure drop between the actuator chambers and results in a drag force on the actuator rod motion.
More recently, there have been calls for actuators to have a third mode of operation, e.g. a bypass mode where no drag force is created and, hence, no resistance to movement of the surface, e.g. in the case of hydraulic failure.
One solution that has been considered is to provide two spool/sleeve valves to control the actuator, namely a conventional active/damped spool/sleeve valve and, in addition, a second spool for the bypass mode. This would, of course, considerably add to the size and weight of the actuator control system, and the solution has not been pursued.
The present disclosure aims to meet the need for a three-mode actuator with an improved spool/sleeve valve arrangement.
According to an embodiment, the disclosure provides a mode valve assembly comprising a spool axially moveable within a sleeve in response to a command, the spool comprising channels and lands, and the sleeve comprising ports in fluid communication with a hydraulic fluid supply and ports in connection with control chambers of an actuator responsive to the valve, wherein the mode valve comprises first drive means for moving the spool, relative to the sleeve, between a first position, in which fluid can flow through the mode valve from the fluid supply to the actuator chambers, and a second position in which fluid flow from the fluid supply to the actuator chambers through the valve is blocked and wherein a fluid path with a first pressure drop is defined in the mode valve for fluid flow between actuator chambers; the mode valve comprising second drive means for moving the spool relative to the sleeve to a third position in which fluid flow from the fluid supply to the actuator chambers through the valve is blocked and wherein a fluid path with a second pressure drop is defined in the mode valve for fluid flow between actuator chambers.
In a preferred embodiment, the first drive means comprises a solenoid valve causing movement of the spool by application of fluid pressure to one end of the spool according to the desired position of the spool, and the second drive means is means for applying an electrical signal to cause movement of the spool to the third position.
The electrical signal may be applied to the spool by being applied by an electromechanical solenoid to move a drive member to mechanically move the spool. The drive member may be e.g. a pin that pushes against the spool.
In the preferred embodiment, the third mode is a bypass mode where the fluid flow path between the actuator chambers is via orifices in the spool/sleeve valve that are larger than the orifices defining the flow path in the damped mode, such that a lower pressure drop, or even substantially no pressure drop, is created between the fluidly connected actuator chambers.
According to another aspect, the disclosure provides a method of controlling a mode valve comprising a spool axially moveable within a sleeve for selective operation in three modes, the method comprising: controlling a first drive means to move the spool, relative to the sleeve, between a first position, in which fluid can flow through the mode valve from the fluid supply to control chambers of an actuator, and a second position in which fluid flow from the fluid supply to the actuator chambers through the valve is blocked and wherein a fluid path with a first pressure drop is defined in the mode valve for fluid flow between actuator chambers; and controlling a second drive means to move the spool relative to the sleeve to a third position in which fluid flow from the fluid supply to the actuator chambers through the valve is blocked and wherein a fluid path with a second pressure drop is defined in the mode valve for fluid flow between actuator chambers.
Preferred embodiments will now be described by way of example only with reference to the drawings.
A mode valve as described below can, for example, be used in an actuator control system. The mode valve is controlled by a drive assembly to control a flow of fluid that is output via e.g. a so called solenoid valve to enable the movement of the spool of the mode valve.
A conventional mode valve will first be described with reference to
A typical mode valve is shown in
In an example, the assembly is arranged to control an actuator based on the fluid flow from the control port e.g. via a solenoid valve.
Supply pressure is provided to the mode valve housing or sleeve 1 and to the spool via supply ports 11,12 (possibly from a servovalve.
The spool 2 is in the form of a tubular member arranged in a valve block or sleeve 1 to be moved axially by the hydraulic fluid.
As mentioned above, in such conventional systems, the valve is only able to operate in two modes—an active mode and a damped mode. The assembly of the present disclosure enables a third mode of operation e.g. a bypass mode.
With reference to
For operation in the damped mode, shown in
The present disclosure provides a system in which the same spool/sleeve valve that can be operated in active and damped modes can also provide operation in a third, different mode, e.g. a bypass mode, shown in
Thus, the arrangement of this disclosure allows operation in three different modes—active mode and damped mode and also a third mode e.g. bypass mode—using just a single spool/sleeve valve. This keeps the number of parts, and, hence, the overall size, weight and cost of the system to a minimum whilst maintaining reliability. Having the third (e.g. bypass) mode on actuators can improve aircraft availability.
Although this disclosure has been described in terms of preferred examples, it should be understood that these examples are illustrative only and modifications and alterations are possible within the scope of the claims.
Number | Date | Country | Kind |
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17306646.5 | Nov 2017 | EP | regional |