The present disclosure relates generally to a hydraulic system, and more particularly, to a hydraulic system having multiple circuits.
Hydraulic systems are often used to control the operation of hydraulic actuators of machines. These hydraulic systems typically include valves, arranged within hydraulic circuits, fluidly connected between the actuators and pumps. These valves may each be configured to control a flow rate and direction of pressurized fluid to or from respective chambers within the actuators.
In some instances, multiple actuators may be connected to a common pump. During actuation of multiple actuators one actuator may require a significantly higher pressure from the pump than other actuators. Actuation of one such actuator may also create undesirable pressure or flow conditions in other parts of the system. The pressure and flow of the fluid provided to each actuator can be controlled, in part, by valves between the pump and the actuator. It is generally desirable to control the valves in a way that improves the efficiency of the system.
One method of reducing pressure fluctuations in hydraulic systems is described in U.S. Pat. No. 5,878,647 (“the '647 patent”) issued to Wilke et al. While the hydraulic circuit described in the '647 patent may reduce pressure fluctuations, it may also result in unnecessarily high system pressure.
A hydraulic system is disclosed having a source of pressurized fluid, and first and second hydraulic circuits configured to receive pressurized fluid from the source. The hydraulic system further includes a controller configured to determine a requested flow for the first circuit, determine a requested flow for the second circuit, and apportion pressurized fluid from the source between the first circuit and the second circuit based on a predetermined assumed available flow rate, wherein the predetermined assumed available flow rate is greater than an actual flow rate of the source.
As illustrated in
Hydraulic system 25 may further include a source 26 of pressurized fluid and a tank 28. Hydraulic circuits 50a, 50b, may each include a pressure compensating valve 30a, 30b. Each hydraulic circuit 50a, 50b may further include two supply valves 31a, 31b: a head-end supply valve 32a, 32b and a rod-end supply valve 34a, 34b; as well as two drain valves 33a, 33b: a head-end drain valve 36a, 36b, and a rod-end drain valve 38a, 38b. Each hydraulic circuit may also include a head-end make-up valve 40a, 40b, a head-end relief valve 42a, 42b, a rod-end make-up valve 44a, 44b, and a rod-end relief valve 46a, 46b. It is contemplated that hydraulic system 25 may include additional and/or different components such as, for example, a temperature sensor, a position sensor, an accumulator, and/or other components known in the art.
Hydraulic actuators 20a, 20b may include a piston-cylinder arrangement, a hydraulic motor, and/or any other known hydraulic actuator having one or more fluid chambers therein. According to an embodiment of this disclosure, hydraulic actuators 20a, 20b may include a tube 51a, 51b and a piston assembly 52a, 52b. Hydraulic actuators 20a, 20b may also include a head-end chamber 54a, 54b and a rod-end chamber 56a, 56b separated by piston assembly 52a, 52b.
Source 26 may be configured to produce a flow of pressurized fluid and may include a variable displacement pump such as, for example, a swashplate pump, a variable pitch propeller pump, and/or other sources of pressurized fluid known in the art. Source 26 may be controlled by a control system 100 and may be drivably connected to a power source (not shown) of machine 10 by, for example, a countershaft (not shown), a belt (not shown), an electrical circuit (not shown), and/or in any other suitable manner. Source 26 may be disposed between tank 28 and hydraulic actuators 20a, 20b and may be configured to be controlled by control system 100.
Pressure compensating valves 30a, 30b may be proportional control valves disposed between source 26 and an upstream supply passageway 60a, 60b, respectively, and may be configured to control a pressure of the fluid supplied to upstream supply passageway 60a, 60b, respectively. Pressure compensating valves 30a, 30b may include a proportional valve element that may be spring and hydraulically biased toward a flow passing position and hydraulically biased toward a flow blocking position.
Pressure compensating valves 30a, 30b may be movable toward the flow blocking position by a fluid directed via a fluid passageway 78a, 78b from a point between pressure compensating valve 30a, 30b and upstream supply passageway 60a, 60b. A restrictive orifice 80a, 80b may be disposed within fluid passageway 78a, 78b to minimize pressure and/or flow oscillations within fluid passageway 78a, 78b. Pressure compensating valve 30a, 30b may be movable toward the flow passing position by the combined forces of a spring and a fluid directed via a fluid passageway 82a, 82b from a shuttle valve 74a, 74b. A restrictive orifice 84a, 84b may be disposed within fluid passageway 82a, 82b to minimize pressure and/or flow oscillations within fluid passageway 82a, 82b. It is contemplated that the proportional valve element of pressure compensating valve 30a, 30b may alternately be spring biased toward a flow blocking position, that the fluid from fluid passageway 82a, 82b may alternately bias the valve element of pressure compensating valve 30a, 30b toward the flow blocking position, and/or that the fluid from passageway 78a, 78b may alternately move the proportional valve element of pressure compensating valve 30a, 30b toward the flow passing position. It is also contemplated that pressure compensating valve 30a, 30b may alternately be located downstream of supply valves 31a, 31b, or in any other suitable location. It is further contemplated that restrictive orifices 80a, 80b, and 84a, 84b may be omitted, if desired.
Supply valves 31a, 31b may be disposed between source 26 and hydraulic actuator 20a, 20b, respectively, and may be configured to regulate a flow of pressurized fluid to actuators 20a, 20b. Specifically, head-end supply valves 32a, 32b may be disposed between source 26 and head-end chamber 54a, 54b, and rod-end supply valves 34a, 34b may be disposed between source and rod-end chambers 56a, 56b, respectively. Depending on the direction of actuation of the actuator 20a, 20b, one of head-end supply valve 32a, 32b or rod-end supply valve 34a, 34b will provide the supply of pressurized fluid to the actuator 20a, 20b for its respective circuit 50a, 50b. For example, if pressurized fluid is provided to the head end 54a of actuator 20a in circuit 50a, head-end supply valve 32a would be the acting supply valve 31a in circuit 50a.
Supply valves 31a, 31b may each include a proportional valve element that may be spring biased and solenoid actuated to move the valve element to any of a plurality of positions from a first position in which fluid flow may be substantially blocked from flowing toward actuator 20a, 20b to a second position in which a maximum fluid flow may be allowed toward actuator 20a, 20b. Additionally, the proportional valve elements of supply valves 31a, 31b may be controlled by control system 100 to vary the size of a flow area through which the pressurized fluid may flow.
Drain valves 33a, 33b may be disposed between hydraulic actuator 20a, 20b and tank 28 and may be configured to regulate a flow of pressurized fluid from head-end chamber 54a, 54b, or rod-end chamber 56a, 56b, depending on the direction of actuation. Specifically, head-end drain valves 36a, 36b and rod-end drain valves 38a, 38b may each include a two-position valve element that may be spring biased and solenoid actuated between a first position at which fluid may be allowed to flow from head-end chamber 54a, 54b or rod-end chamber 56a, 56b, depending on the direction of actuation, and a second position at which fluid may be substantially blocked from flowing from head-end chamber 54a, 54b or rod-end chamber 56a, 56b. Supply valves 31a, 31b and drain valves 33a, 33b may be fluidly interconnected as illustrated in
Shuttle valve 74a, 74b may be disposed within downstream system signal passageway 62a, 62b. Shuttle valve 74a, 74b may be configured to fluidly connect the one of head-end supply valve 32a, 32b and rod-end supply valve 34a, 34b having a lower fluid pressure to pressure compensating valve 30a, 30b. In this manner, shuttle valve 74a, 74b may resolve pressure signals from head-end supply valve 32a, 32b and rod-end supply valve 34a, 34b to allow the lower outlet pressure of the two valves to affect movement of pressure compensating valve 30a, 30b via fluid passageway 82a, 82b.
Hydraulic system 25 may include additional components to control fluid pressures and/or flows within hydraulic system 25. Specifically, hydraulic system 25 may include pressure balancing passageways 66a, 66b configured to control fluid pressures and/or flows within hydraulic system 25. Pressure balancing passageways 66a, 66b may fluidly connect upstream supply passageway 60a, 60b and downstream system signal passageway 62a, 62b. Pressure balancing passageways 66a, 66b may include restrictive orifices 70a, 70b, to minimize pressure and/or flow oscillations within fluid passageways 66a, 66b. Hydraulic system 25 may also include a check valve 76a, 76b disposed between pressure compensating valve 30a, 30b and upstream supply passageway 60a, 60b and may be configured to block pressurized fluid from flowing from upstream supply passageway 60a, 60b to pressure compensating valve 30a, 30b.
Control system 100 may be configured to control the operation of head-end supply valves 31a, 31b and drain valves 33a, 33b source 26. Control system 100 may include a controller 102 configured to receive pressure signals from pressure sensors 108a, 108b via communication lines 112a, 112b. Controller 100 may also be configured to deliver control signals to supply valves 31a, 31b, drain valves 33a, 33b, and source 26 via communication lines 112a, 112b. It is contemplated that the pressure and control signals may each be any conventional signal, such as, for example, a pulse, a voltage level, a magnetic field, a sound or light wave, and/or another signal format.
Controller 102 may be configured to control hydraulic system 25 in response to the pressure signals received from pressure sensors 108a, 108b, 108c. Controller 102 may be configured to perform one or more algorithms to determine appropriate output signals to control the movement of the valve elements of, and thus the amount of flow directed through, supply valves 31a, 31b and drain valves 33a, 33b and to control the output, e.g., displacement and/or input speed, of source 26. Controller 102 may determine the appropriate control signals by, for example, predetermined equations, look-up tables, and/or maps. It is further contemplated that controller 102 may control the operation of other components within hydraulic system 25.
In operation, source 26 provides pressurized fluid to either head-end chamber 54a, 54b or rod-end chamber 56a, 56b of one or more actuators 20a, 20b, depending on the direction of actuation. Flow of fluid to the actuator 20a, 20b may be controlled in part by control of source 26. For example, source 26 may be a variable displacement axial piston pump, in which case the rate of flow from source 26 may be controlled by the angle of the swashplate and/or the speed of the pump.
Flow of pressurized fluid from the source 26 to actuator 20a, 20b may also be controlled in part by the respective supply valve 31a, 31b. By altering the flow passing area of supply valve 31a, 31b, the flow of fluid to the respective actuator 20a, 20b, and the pressure drop over supply valve 31a, 31b may be controlled.
During operation, the flow available from source 26 may be limited, for example, by an actual maximum flow rate of source 26. For example, when each actuator 20a, 20b is operating at relatively low pressure, the source may operate in a non-power-limited state, in which the flow available from source could depend on, among other things, a maximum speed and displacement of source 26. However, if one or more of the actuators 20a, 20b is operating at a relatively high pressure, the source may operate in a power-limited state in which the flow available from source could be limited by available power. In a power-limited state available flow could depend on, among other things, an output pressure from source 26 and the power available to source 26. Generally, the actual available flow from source 26 will be less in a power-limited state as compared to a non-power-limited state.
When multiple circuits 50a, 50b simultaneously request flow to actuate multiple actuators 20a, 20b, controller 102 may apportion available flow from the source 26 to each of the multiple circuits 50a, 50b by controlling, for example, the supply valves 31a, 31b and/or drain valves 33a, 33b of the respective circuits. For example, controller 102 may control multiple supply valves 31a, 31b, to be actuated to provide a certain flow passing area, such that fluid will pass through the supply valves 31a, 31b at a desired rate, given a known pressure drop over the valve 31a, 31b.
Controller 102 may include logic that relates a set of inputs, such as an operator input or inputs, to flow passing position of supply valves 31a, 31b, and/or drain valves 33a, 33b. The logic may include a look-up table, an algorithm, priority schemes or other methods for relating inputs to desired flow passing positions of supply valves 31a, 31b as may be known in the art.
As discussed in greater detail below, when apportioning flow between multiple circuits 50a, 50b, the logic of controller 102 may be configured to assume a constant available flow rate in both power-limited and non-power-limited states.
The disclosed hydraulic system may be applicable to increase the efficiency of a machine 10. By configuring the controller 102 to assume a constant available flow rate in both power-limited and non-power-limited states the overall pressure demand on source 26 may be reduced, while maintaining appropriate levels of control and operator feedback.
Regarding an exemplary hydraulic system 25, a controller 102 may be configured to assume a constant available flow rate of 200 LPM. The source 26 of high pressure fluid in this exemplary system 25 may be capable of producing 200 LPM when operating at relatively low pressure and in a non-power-limited state. In this state, if one hydraulic circuit 50a requests 75 LPM of flow, and the other hydraulic circuit 50b requests 100 LPM of flow, the controller 102 may set a flow command equal to the minimum of the requested flow and the constant assumed available flow, which in this case would be the sum of the requested flow from each circuit, 175 LPM. In this case each circuit would receive the flow it requested. However, if the requested flow increased, for example, to 110 LPM and 125 LPM, the controller would utilize the assumed flow rate of 200 LPM, and set flow commands such that the sum of the flow command to each circuit 50a, 50b would substantially equal 200 LPM. The controller may utilize a prioritization scheme, algorithm, look-up table, or other methods known in the art for determining the ratio of flow provided to each circuit 50a, 50b.
To further this example, in a power-limited state, source 26 may, for example, only be capable of providing 150 LPM of flow. In this case, if circuit 50a is requesting 100 LPM and circuit 50b is requesting 125 LPM, controller will still apportion flow under the assumed available flow rate of 200 LPM, such that the flow passing areas of supply valves 31a, 31b will be sized as if the assumed available flow of 200 LPM was available. In this manner, the high-pressure circuit may have an oversized supply valve 31a, 31b or be stalled. In the first instance, the effect may be an overall reduction in system pressure caused by a reduced pressure drop over the supply valve 31a, 31b of the high-pressure circuit 50a, 50b. The overall reduction in system pressure may be compounded as a lower pressure drop over the supply valve 31a, 31b may also tend to bias the pressure compensating valve 30a, 30b towards a more open position, thereby reducing the pressure drop over the pressure compensating valve 30a, 30b as well. Alternatively, if the high-pressure circuit 50a, 50b stalls, the operator is provided with meaningful feedback regarding the state of the system, and may alter the command to relieve the stall.
It will be apparent to those skilled in the art that various modifications and variations can be made to the disclosed hydraulic system. Other embodiments will be apparent to those skilled in the art from consideration of the specification and practice of the disclosed hydraulic system. It is intended that the specification and examples be considered as exemplary only, with a true scope being indicated by the following claims and their equivalents.
This application is based upon and claims the benefit of priority from U.S. Provisional Application No. 61/245,709 by Michael Todd Verkuilen et al., filed Sep. 25, 2009, the contents of which are expressly incorporated herein by reference.
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