This disclosure relates generally to hydraulic circuits, and more specifically, this disclosure relates to hybrid hydraulic circuits with a means for utilizing excess pressurized fluid from a pilot system.
Hybrid hydraulic circuits are used to capture, store and reuse either kinetic energy or braking energy on a machine to improve efficiency. For example, U.S. Pat. No. 7,908,852 discloses machines, such as excavators, that include a swing mechanism which enable an upper structure to be rotated about a base machine on a central pivot by a hydraulic swing motor. The hydraulic swing motor is part of a hydraulic circuit that includes a directional control valve configured to control the swing motor. The large mass and geometry of the upper structure of the machine create high inertial loads when the upper structure is rotated.
The '852 patent discloses a hydraulic system and method for recovering the kinetic energy generated by the operation of a swing motor, converting the kinetic energy into hydraulic potential energy, and reusing the hydraulic potential energy for swing motor acceleration to improve the machine productivity and fuel efficiency of the overall system. The hydraulic system includes an accumulator for collecting kinetic energy caused by the motion of the swing motor. The accumulator stores exit fluid from the swing motor that is pressurized by the inertia torque applied on the moving motor via movement of an upper structure of the machine, such as an excavator. The stored pressurized exit fluid in the accumulator can then be used to accelerate or decelerate the swing motor.
Instead of, or in addition to, using stored pressurized fluid to assist in accelerating or decelerating the motor responsible for generating the excess pressurized fluid, stored pressurized fluid can be used to perform useful work or assist in performing useful work elsewhere in the system. For example, torque assistance motors are motors used to supplement the operation of other motors or pumps. Typically, a torque assistance motor is driven by stored pressurized fluid delivered by an accumulator. The stored pressurized fluid drives the torque assistance motor which may be coupled to a pump or another hydraulic motor to assist in the driving or operation of said pump or motor. Torque assistance motors can also be used to provide torque assistance to the engine itself.
The term peak shaving refers to returning stored energy back to the system when energy demand is high. In hydraulics, peak shaving refers to using stored and pressurized fluid produced by one circuit for operating or supplementing the operation of a component of the same or a different circuit. The use of stored, pressurized fluid for driving a torque assistance motor, assisting in the acceleration or deceleration of a swing motor and providing torque assistance to an engine are just three examples discussed above. Other examples of using stored pressurized fluid generated from peak shaving exist, as will be apparent to those skilled in the art. Given the complexity of today's hydraulic circuits, especially those associated with various types of machines in vehicles, other sources of pressurized fluid for peak shaving purposes may be available and should be exploited.
In one aspect, a hydraulic system is disclosed. The system may include a pilot pump, a pilot circuit and a hybrid circuit configured to receive fluid from the pilot pump. They system may further include a selector valve that is moveable between first and second positions to direct pressurized fluid from the pilot pump to a pilot circuit in the first position and to direct pressurized fluid from the pilot pump to a hybrid circuit in the second position. The pilot circuit may include a pilot accumulator for storage of pressurized fluid from the pilot pump. And, the hybrid circuit may include a hybrid accumulator for storage of pressurized fluid from the pilot pump.
In another aspect, a machine is disclosed which may include an engine and a pilot pump mechanically driven by the engine. The machine may further include a selector valve that is moveable between first and second positions to direct pressurized fluid from the pilot pump to a pilot circuit in the first position and to direct pressurized fluid from the pilot pump to a hybrid circuit in the second position. The pilot circuit may include a pilot accumulator for storage of pressurized fluid from the pilot pump when the selector valve is in the first position and the hybrid circuit may include a hybrid accumulator for storage of pressurized fluid from the pilot pump when the selector valve is in the second position. The machine may further include an unloader valve disposed between the hybrid circuit and the selector valve. The unloader valve may be moveable between first and second positions. In the first position, the unloader valve may provide communication between the selector valve and the hybrid accumulator. In the second position, the unloader valve may provide communication between the selector valve and a reservoir.
In another aspect, a method for peak shaving is disclosed wherein the peak shaving diverts pressurized fluid from a pilot pump of a machine that includes a pilot circuit and a hybrid circuit. The disclosed method may include supplying pressurized fluid from the pilot pump to a pilot circuit via a selector valve that is in a first position. The method may further include supplying pressurized fluid from the pilot pump to the hybrid circuit via the selector valve in a second position based on the pressure of the pressurized fluid of the pilot circuit exceeding a first predetermined value. The method may further include storing a hybrid accumulator of the hybrid circuit.
The implement system 11 may include a linkage structure acted on by one or more hydraulic actuators such as hydraulic cylinders to move the work tool 12. The hydraulic cylinders may include any device configured to receive pressurized hydraulic fluid and convert a hydraulic pressure and/or flow from the pressurized hydraulic fluid into mechanical force and/or motion. For example, the implement system 11 may also include a boom 16 and a stick 17 for pivotally connecting the work tool 12 to the machine 10. In an embodiment, the boom 16 may be vertically pivotal about a horizontal axis relative to a work surface by one or more hydraulic cylinders 18. Although not shown in
Numerous different work tools 12 may be attachable to a single machine 10 and may be operator controllable. The work tool 12 may include any device used to perform a particular task such as, for example, a bucket, a fork arrangement, a blade, a shovel, a ripper, a dump bed, a broom, a snow blower, a propelling device, a cutting device, a grasping device or any other task-performing device known to those skilled in the art. Although connected to the machine 10 of
The power source 14 may embody an engine such as, for example, a diesel engine, a gasoline engine, a gaseous fuel-powered engine or any other type of combustion engine known to those skilled in the art. It is contemplated that the power source 14 may alternatively embody a non-combustion source of power such as a fuel cell, a power storage device or any other source known in the art. The power source 14 may produce mechanical or electrical power output that may then be converted to hydraulic power for moving the hydraulic cylinders, one of which is shown at 18 in
The operator station 15 may include devices that receive input from an operator indicative of the desired machine maneuvering. Specifically, the operator station 15 may include one or more operator interface devices (e.g., a joystick, a steering wheel, a pedal, etc.) that are located proximate to an operator seat. The operator interface devices may initiate movement of the machine 10 (e.g., travel and/or tool movement) by producing displacement signals that are indicative of the desired machine maneuvering. As an operator moves the interface device, the operator may affect a corresponding machine movement in a desired direction, with a desired speed and/or with a desired force.
As shown in
Still referring to
Fluid pressure in the line 42 may also be used as pilot fluid for shifting the selector valve 37 from the first position shown in
The unloader valve 46, like the selector valve 37, may be a three-way, two-position valve with a biasing element 54, such as, e.g., a spring, that maintains the unloader valve 46 in a first position as shown in
When the hybrid accumulator 56 becomes fully charged or pressure in the line 58 reaches a first predetermined value, the pressure is communicated through the lines 59, 62 to the hydraulic actuator 55. This action results in the shifting of the unloader valve 46 to a second position which provides communication between the line 63 that leads to the unloader valve 46 and the line 64 that connects the unloader valve 46 to the return line 53. Thus, when the hybrid accumulator 56 becomes sufficiently charged, pressure in the line 58 builds and that pressure that reaches a third predetermined value is communicated to the hydraulic actuator 55 to shift the unloader valve 46 to a second position where fluid proceeding from the pilot pump 34, through the selector valve 37, through the check valve 36 and to the unloader valve 46 is redirected to the line 64 and the return line 53 rather than overcharging the hybrid accumulator 56. Further, if pressure in the line continues to build and said pressure exceeds a third predetermined value, that pressure is communicated through the line 59 to the pilot line 65 which shifts the hybrid relief valve 61 from its normally closed position shown in
As shown in
As noted above, the hybrid accumulator 56 stores pressurized fluid from the pilot pump 34 and that pressurized fluid can be used to accelerate or decelerate a swing motor of a swing motor circuit 31, provide pressurized fluid to a hydraulic motor of a torque assistance motor circuit 32 which, in turn, may be used to drive an additional power consuming device 33 or the torque assistance motor 32 may be coupled directly to the power source 14 for providing torque assistance to the power source 14. Further, any one or more combinations of the above may be employed, as will be apparent to those skilled in the art.
The disclosed hydraulic system 30 may have particular applicability with machines to allow recovery and/or reuse of potential energy associated with the pilot pump 34 which may run constantly as it is coupled to the power source 14. After the pilot pump 34 is sufficiently utilized to charge the pilot accumulator 41, the selector valve 37 may be shifted to redirect flow from the pilot pump 34 to the hybrid circuit 70 by way of the unloader valve 46. The hybrid circuit 70 may include a hybrid accumulator 56. Pressurized fluid is stored in the hybrid accumulator 56 which may then be later used to provide pressurized fluid to any one or more of a variety of components such as a swing motor 31, a torque assistance motor 32 or any other power consuming component. If a torque assistance motor 32 is utilized, the torque assistance motor 32 may be used to deliver mechanical energy to another power consuming component 33 or provide additional mechanical energy to the power source 14. Further, any combination of one or more of the above concepts may be employed.
One disclosed method is illustrated in the flow chart of