The present disclosure relates generally to a hydraulic system and, for example, to electrical control of a hydraulic system.
Work machines or construction machines, such as excavators or other similar types of vehicles, may be used to perform one or more worksite operations (e.g., material transfer, digging, scraping, dozing, and/or the like). Typically, such machines include a hydraulic system to perform the worksite operations to control movement of the machines and/or a component of the machines. For example, a hydraulic system may be used to control an implement of a machine. More specifically, a hydraulic system of an excavator may be used to control movement of the excavator, rotation of a body of the excavator (e.g., for a swing operation), and/or movement of an implement of the excavator that includes a boom, stick, bucket, and/or the like.
In many instances, the hydraulic system includes a plurality of hydraulic pumps and/or hydraulic circuits that individually include a plurality of circuit valves. More specifically, a hydraulic circuit, in previous techniques, may include a main spool valve that permits or denies flow through the individual circuits and a flow control valve to hydromechanically control the flow of fluid throughout the hydraulic system based on a sensed pressure of the hydraulic circuit and a hydraulic flow command, which may be based on an operator input to the hydraulic system. Accordingly, in such cases, hydraulic flow balance among the individual hydraulic circuits is achieved via hydromechanical control of one or more of a plurality of valves within the individual hydraulic circuits.
One approach for a construction machine control is disclosed in Chinese Patent No. CN105008623 that issued to Akinori et al. on Jul. 14, 2017 (“the '623 patent”). In particular, the '623 patent describes a work equipment control that controls a control valve, a pilot hydraulic line opening, and includes a pressure sensor.
While the '623 patent describes detecting a pilot pressure adjusted by the control valve, in the '623 patent, after a pressure adjustment has been provided by a first control valve of the supplied hydraulic oil to the directional control valve, a spool is moved to one side in an axial direction; and after a pressure adjustment has been provided by a second control valve of the supplied hydraulic oil to the directional control valve, the spool is moved to another side in the axial direction.
According to some implementations, a method may include identifying a set of active hydraulic circuits of the hydraulic system, wherein the hydraulic system includes a hydraulic pump to cause fluid to flow throughout the set of active hydraulic circuits; determining a maximum active circuit pressure from active circuit pressures of the set of active hydraulic circuits; comparing the maximum active circuit pressure to a circuit pressure of a hydraulic circuit of the hydraulic system to determine a pressure difference between the maximum active circuit pressure and the circuit pressure; determining, based on a hydraulic flow command for the hydraulic circuit and the circuit pressure, a desired circuit delta-pressure for the hydraulic circuit; determining, based on the desired circuit delta-pressure being associated with a reduction in pressure that is less than the pressure difference, a circuit valve setting for a circuit valve of the hydraulic circuit that corresponds to the reduction in pressure; and causing a control device to set a position of the circuit valve according to the circuit valve setting to reduce the pressure difference.
According to some implementations, a hydraulic system controller may include a memory and a processor, communicatively coupled to the memory, that is configured to: obtain a circuit pressure of a hydraulic circuit of a hydraulic system, wherein the hydraulic system includes a hydraulic pump to cause fluid to flow throughout a set of active hydraulic circuits; determine active circuit pressures of the set of active hydraulic circuits; determine, from the active circuit pressures, a maximum active circuit pressure of the hydraulic system; determine, based on a hydraulic flow command for the hydraulic circuit and the circuit pressure, a desired circuit delta-pressure for the hydraulic circuit; determine, based on the desired circuit delta-pressure and a pressure difference between the maximum active circuit pressure and the circuit pressure, a circuit valve setting for a circuit valve of the hydraulic circuit; and instruct, based on the circuit valve setting, a control device to set a position of the circuit valve to reduce an opening through the circuit valve and reduce the pressure difference.
According to some implementations, a hydraulic system may include a hydraulic pump to provide, from a main line, a fluid to the hydraulic system; a plurality of hydraulic circuits configured to control a plurality of components of the machine; a plurality of circuit valves to control respective flows of the fluid through the plurality of hydraulic circuits; and a controller configured to: determine a maximum active circuit pressure of a set of active hydraulic circuits of the hydraulic system, wherein the hydraulic system includes a hydraulic pump to cause fluid to flow throughout the set of active hydraulic circuits; determine a circuit pressure of a hydraulic circuit of the hydraulic system; determine, based on a hydraulic flow command for the hydraulic circuit and the circuit pressure, a desired circuit delta-pressure for the hydraulic circuit; determine, based on the desired circuit delta-pressure and a pressure difference between the maximum active circuit pressure and the circuit pressure, a circuit valve setting for a circuit valve of the hydraulic circuit; and cause a control device to set a position of the circuit valve according to the circuit valve setting.
This disclosure relates to electrical (or electronic) control of a hydraulic system using a hydraulic system controller. The hydraulic system controller has universal applicability to any machine utilizing such a hydraulic system. The term “machine” may refer to any machine that performs an operation associated with an industry such as, for example, mining, construction, farming, transportation, or any other industry. As some examples, the machine may be a vehicle, a backhoe loader, a cold planer, a wheel loader, a compactor, a feller buncher, a forest machine, a forwarder, a harvester, an excavator, an industrial loader, a knuckleboom loader, a material handler, a motor grader, a pipelayer, a road reclaimer, a skid steer loader, a skidder, a telehandler, a tractor, a dozer, a tractor scraper, or other above ground equipment, underground equipment, or marine equipment. Moreover, one or more implements may be connected to the machine and driven from hydraulic components (e.g., cylinders, actuators, solenoids, valves, and/or the like) of hydraulic circuits of the hydraulic system and/or controlled by the hydraulic system controller, as described herein.
As shown in
As shown in
As shown in
The hydraulic system of the machine 100 may include a hydraulic pump 126 that is to provide a flow source (e.g., a fixed flow rate or variable flow rate) of fluid (e.g., oil or other type of hydraulic fluid) to a plurality of hydraulic circuits (e.g., individual hydraulic circuits associated with the boom cylinder 120, the stick cylinder 122, the bucket cylinder 124, one or more swing cylinders to swing the machine body 106, and/or the like) of the hydraulic system. According to some implementations, the hydraulic pump 126 may be a single (or the only) hydraulic pump 126 that is configured to control a plurality of functions described herein. Additionally, or alternatively, the hydraulic pump 126 may be one of a plurality of hydraulic pumps that are configured to, in combination, provide a single flow source of fluid to the hydraulic system of the machine. The hydraulic pump 126 provides the fluid, from a main line fluidly coupled to a discharge end of the hydraulic pump to the plurality of hydraulic circuits. As described herein, flow through the plurality of hydraulic circuits may be controlled via electromechanical control of individual circuit valves of the plurality of hydraulic circuits. As further described herein, a circuit valve of an individual hydraulic circuit may be the only (or a single) circuit valve of the individual hydraulic circuit.
As shown in
As shown in
As indicated above,
In
The circuit valves 222 may be any suitably configured valve that is capable of being controlled by the respective valve control devices 240 (e.g., based on receiving instructions from controller 210). For example, the circuit valves 222 may be individually configured spool valves with electromechanical configurations that are configured specific for functional control of the cylinders 250 (e.g., according to responsiveness, performance, sizes, ranges of operation, cylinder type, and/or the like).
The hydraulic pump 202, during operation, and according to configurations of the circuit valves 222 (e.g., based on a setting or a position of the circuit valves), causes fluid to flow to, through, and/or from the hydraulic circuits 220. In the example of
The pressure sensor configurations 230 may include one or more pressure sensors that are configured to monitor individual pressures of the hydraulic circuits 220. For example, pressure sensor configuration 230a may include a first pressure sensor to measure and/or indicate a pressure at a rod end of cylinder 250a, a pressure at a head end of cylinder 250a, and/or a pressure within a circuit line between the circuit valve 222a and cylinder 250a. As shown, the pressure sensor configurations are communicatively coupled with the controller 210. Accordingly, the controller 210 may receive, obtain, and/or monitor pressure measurements associated with the hydraulic system 200.
As described herein, the controller 210 causes the valve control devices 240 to configure or position one or more components (e.g., spools, stems, actuators, plugs, apertures, and/or the like) of the circuit valves 222 to increase and/or decrease an opening of the circuit valves 222 (e.g., by increasing or decreasing an area of a passageway that flows through one or more of the respective circuit valves 222). More specifically, the controller 210 may instruct the valve control devices 240 to set positions of spools of the circuit valves 222 to control the sizes of openings and, correspondingly, the flow of the fluid throughout the hydraulic circuits 220 (e.g., according to a hydraulic flow command of the hydraulic system, of one or more of the hydraulic circuits 220, and/or the like).
As indicated above,
Operator interface 320 (e.g., corresponding to operator interface 110 of
The sensors 330 may include any type of sensor configured to monitor operating conditions of machine 100 and/or implement 112. The sensors 330 may correspond to the sensors 130 of
The valve control device 340 includes any suitable device that may be used by hydraulic system controller 310 to electrically control a flow of fluid through one or more hydraulic circuits (e.g., the hydraulic circuits 220 of
Hydraulic system controller 310 may correspond to controller 128 of
The valve control module 316 is configured to determine and/or control valve control devices 340 to control a flow rate of fluid through one or more hydraulic circuits of the machine 100. The valve control module 316 may receive measurements from sensors 330 associated with operating conditions of the machine 100 and/or the implement 112. Additionally, or alternatively, the valve control module 316 may receive operator inputs from operator interface 320 in association with an operator performing operation associated with the machine 100 and/or the implement and/or controlling a function of the machine 100 and/or the implement 112, as described herein.
The valve control module 316 may be configured to monitor pressures of the hydraulic system using a plurality of pressure sensors of sensors 330. Based on the pressures throughout the hydraulic system, the valve control module 316 may instruct the valve control devices 340 to adjust a setting of one or more circuit valves to cause a flow rate of through a particular hydraulic circuit to increase or decrease. For example, the valve control module 316 may identify, based on the pressures and/or an operator input, which hydraulic circuits of the hydraulic system are active (e.g., which hydraulic circuits have a non-zero flow rate). For those hydraulic circuits that are active, the valve control module 316 may determine a maximum active circuit pressure (e.g., a highest circuit pressure relative to the circuit pressures of the active hydraulic circuits). The valve control module 316 may compare the maximum active circuit pressure to a desired circuit delta-pressure for a hydraulic circuit (e.g., one of the active hydraulic circuits), and determine whether an area of a circuit valve for that can be reduced to increase a flow rate of fluid for the hydraulic circuit that has the maximum active circuit pressure.
The valve control module 316 may determine the desired circuit delta-pressure for a particular hydraulic circuit based on a desired hydraulic flow command (e.g., as determined from an operator input of the operator interface 320, an automated flow command generated based on sensor measurements of the sensors 330, and/or the like) and an actual or operating pressure as indicated by one of the sensors 330 monitoring the hydraulic circuit. If the desired circuit delta-pressure indicates that the area can be reduced (e.g., the measured pressure is higher than a pressure corresponding to the hydraulic flow command), the valve control module 316, using the valve mapping module 318, instructs the valve control device 340 of the hydraulic circuit to correspondingly reduce the area of the circuit valve of the hydraulic circuit. In this way, the flow rate (and/or pressure) of the hydraulic circuit associated with the maximum active circuit pressure could be increased by control of the other circuit valve.
The valve control module 316 may store information and/or logic in the valve mapping module 318. For example, such information may be included in a list of hydraulic circuits (and/or corresponding circuit valves), a priority associated with the circuits (e.g., an indication of whether control for one or more hydraulic circuits is to be prioritized over another by default and/or under a particular condition), and a plurality of valve mappings (shown as “M1,” “M2,” “M3”) corresponding to certain circuit valves of hydraulic circuits of a hydraulic system. A valve mapping may map a position of a valve with a particular area of a circuit valve, a particular pressure of a hydraulic circuit, a particular flow rate for the hydraulic circuit, and/or the like. Accordingly, the valve mappings stored and/or maintained by the valve mapping module 318 may be valve-specific, operation-mode specific, and/or function-specific valve mappings. In this way, the valve control module 316 may cause the valve control devices 340 to saturate a delta-pressure compensation (e.g., an adjustment of an opening) according to a particular tuning strategy for the individual hydraulic circuits.
The valve mappings may be stored in a data structure (e.g., a database, a table, an index, a graph, and/or the like) of the memory 314 and/or in a memory that is communicatively coupled with the memory 314. The valve mappings may be associated with circuit valve settings for a desired pressure, a desired flow rate, a desired circuit delta-pressure, and/or the like. Further, a valve mapping, for a particular circuit valve, may correspond to a mapping of specific positions of a spool of the circuit valve to area of an opening of the valve for particular operating conditions of the machine 100 and/or the implement 112. In this way, a valve mapping identifies a circuit valve setting and/or a position for a component of a circuit valve. The valve control module 316 may use the valve mappings of the valve mapping module 318 to rate limit flow rates through one or more hydraulic circuits of the hydraulic system of the machine 100.
The number and arrangement of devices shown in
As shown in
If the hydraulic system controller 310 determines that the hydraulic flow command is not associated with a prioritized hydraulic circuit according to the operating conditions, the hydraulic system controller 310 controls the hydraulic system according to a limit scheme that is based on the operating conditions. For example, the hydraulic system controller 310 may control the valve control devices 340 to limit the flow rate associated with one or more of the hydraulic circuits according to a rate limit strategy for the hydraulic circuits and/or according to an adjustment to the hydraulic flow command that is based on the operating conditions.
As an example, a stick-in function (e.g., for a dig operation), associated with the stick 116, can be limited based on the operating conditions indicating a swing velocity of the machine body 106 and/or a circuit pressure associated with the hydraulic circuit that controls the swinging of the machine body 106. In such a case, the hydraulic system controller 310 can cause a valve control device 340 to limit a flow rate of a hydraulic circuit of the stick 116 to be less than a particular maximum flow rate. Additionally, or alternatively, the stick-in function can be limited based on an ongoing boom flow command associated with the boom cylinder 120, a bucket flow command associated with the bucket cylinder 124, and/or a swing flow command associated with a swing cylinder. As another example, based on the operating conditions indicating that the machine 100 is moving (e.g., during a travel operation), a hydraulic flow command associated with bucket cylinder 124 can be ignored and/or adjusted to prevent reduction in the flow rate of the fluid that is being used to move the machine 100. Similarly, a hydraulic flow command for the boom cylinder 120 and/or stick cylinder can be ignored and/or adjusted during a move operation and/or other type of operating condition associated with the machine 100.
As indicated above,
As shown in
The controller may identify the set of active hydraulic circuits based on one or more hydraulic flow commands associated with controlling one or more hydraulic components of the hydraulic system. The controller may determine, from pressure sensors associated with the set of active hydraulic circuits, individual pressure measurements of the set of active hydraulic circuits, and identify, from the individual pressure measurements, the maximum active circuit pressure.
As further shown in
The hydraulic circuit may be one of the set of active hydraulic circuits. Additionally, or alternatively, the hydraulic circuit is a first hydraulic circuit, with a first circuit valve, of the hydraulic system and the maximum active circuit pressure is associated with a second hydraulic circuit of the hydraulic system that is different from the first hydraulic circuit. The first circuit valve and a second circuit valve of the second hydraulic circuit may be fluidly coupled to a main line of the hydraulic pump.
As further shown in
The circuit pressure may correspond to an operating pressure received from a pressure sensor of the hydraulic circuit, and the desired circuit delta-pressure may include a difference between the operating pressure and a desired pressure that is based on the hydraulic flow command.
As further shown in
The controller may determine that the maximum active circuit pressure is greater than the circuit pressure, determine that the desired circuit delta-pressure indicates a desired reduction in pressure in the hydraulic circuit that is less than the pressure difference between the maximum active circuit pressure and the circuit pressure, and determine the position of the circuit valve that provides the desired reduction in pressure.
In some implementations, the controller may identify a valve mapping, associated with the hydraulic circuit, that maps a plurality of circuit pressures to corresponding positions of the circuit valve, and obtain, from the valve mapping and based on the desired circuit delta-pressure, the circuit valve setting, which may indicate a position for the circuit valve.
Additionally, or alternatively the controller may determine an operating condition associated with one of the set of active hydraulic circuits, determine, based on the operating condition, a flow rate limit associated with the hydraulic circuit, and determine the circuit valve setting based on the flow rate limit. The one of the set of active hydraulic circuits may be associated with controlling movement of a machine, and the hydraulic circuit may be associated with controlling a component of the machine.
As further shown in
Although
The disclosed hydraulic system controller may be used with any machine that uses a hydraulic system to control the machine and/or an implement of the machine. The disclosed hydraulic system controller may electrically control the flow of fluid through a plurality of hydraulic circuits based on monitoring and/or determining pressures associated with the hydraulic circuits. For example, based on a maximum active circuit pressure identified in one hydraulic circuit (e.g., a highest circuit pressure relative to a set of active hydraulic circuits), the hydraulic system controller may determine whether a circuit valve of another hydraulic circuit in the hydraulic system is to be adjusted to increase a flow rate of fluid through the hydraulic circuit that is associated with the maximum active circuit pressure (e.g., to improve performance and/or responsiveness of a function or component associated with the hydraulic circuit). In this way, based on being communicatively coupled with one or more pressure sensors and/or valve control devices, the hydraulic system controller can automatically control flow rate and/or fluid distribution throughout the hydraulic system.
Furthermore, the hydraulic system controller, as configured herein, enables a hydraulics system to include a hydraulic pump, because multiple (or all) hydraulic circuits can be simultaneously be monitored and controlled electromechanically, rather than hydromechanically. Moreover, because the hydraulic system controller electromechanically (rather than hydromechanically) controls circuit valves of the hydraulic system, the hydraulic system controller enables a hydraulic system that includes a plurality hydraulic circuits, to independently control the flow rates of fluid through the hydraulic circuits using individual circuit valves (e.g., one control valve per hydraulic circuit), while simultaneously controlling flow throughout the active hydraulic circuits. In this way, rather than a machine requiring a plurality of separate hydraulic pumps for a hydraulic system, and/or a plurality of separate circuit valves for a single hydraulic circuit, the hydraulic system can be controlled using a hydraulic pump, a single flow source, and/or singular circuit valves for hydraulic circuits of the hydraulic system controller, thus reducing a hardware resources, reducing complexity of the hydraulic system, and improving efficiencies associated with the hydraulic system and/or a machine associated with the hydraulic system (e.g., by reducing weight of the hydraulic system, power requirements and/or consumption of the hydraulic system, and/or the like).
This application is a continuation of U.S. patent application Ser. No. 16/834,810, filed Mar. 30, 2020, which is incorporated herein by reference in its entirety.
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Number | Date | Country | |
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Parent | 16834810 | Mar 2020 | US |
Child | 17301867 | US |