Refuse vehicles collect a wide variety of waste, trash, and other material from residences and businesses. Refuse vehicles generally include a lifting system that is movable to engage and lift a waste receptacle so that the waste receptacle's contents can be transferred into a receptacle onboard the refuse vehicle. The lifting system includes an arm assembly that is movable to engage and lift the waste receptacle using one or more hydraulic cylinders that extend or retract to adjust the position of the lifting system relative to the refuse vehicle. The hydraulic cylinders on the refuse vehicle are supplied with pressurized hydraulic fluid from a hydraulic pump positioned onboard the refuse vehicle.
One exemplary embodiment relates to a refuse vehicle. The refuse vehicle includes a chassis and a vehicle body. The chassis supports both wheels and the vehicle body. The vehicle body defines a receptacle for storing refuse. A variable displacement pump is positioned within or adjacent the vehicle body and is configured to pump hydraulic fluid from a hydraulic fluid reservoir into a high pressure line of a hydraulic circuit on the refuse vehicle. A lifting system is coupled to (e.g., directly or indirectly) the vehicle body and is movable relative to the receptacle to invert refuse containers to remove the contents stored therein and transfer the contents to the receptacle. The lifting system includes at least one actuator in fluid communication with the variable displacement pump. The variable displacement pump delivers pressurized hydraulic fluid from the hydraulic fluid reservoir to the actuator through the high pressure line to adjust a position of the actuator. A valve is positioned within the hydraulic circuit downstream of the variable displacement pump, and is movable between at least two positions. In a first position, the valve restricts flow outward from the high pressure line. In the second position, the valve directs fluid from the high pressure line through the valve and into a lower pressure line within the hydraulic circuit that reduces the hydraulic pressure within the high pressure line and adjusts an output parameter of the variable displacement pump (e.g., torque, displacement, RPM, etc.).
Another exemplary embodiment relates to a refuse vehicle. The refuse vehicle includes a chassis and a vehicle body. The chassis supports both wheels and the vehicle body. The vehicle body defines a receptacle for storing refuse. A variable displacement pump is positioned within or adjacent the vehicle body and is configured to pump hydraulic fluid from a hydraulic fluid reservoir into a high pressure line of a hydraulic circuit on the refuse vehicle toward actuators positioned about the vehicle body. The actuators include at least a lifting actuator and a compacting actuator. Delivering hydraulic fluid from the hydraulic fluid reservoir to the actuators through the high pressure line adjusts a position of at least one of the actuators. A valve is positioned downstream of the variable displacement pump and is configured to selectively control hydraulic fluid flow between the variable displacement pump and the actuators. In a first position, the valve restricts flow between the high pressure line and a lower pressure control line. In a second position, the valve directs hydraulic fluid from the high pressure line into the control line to reduce a hydraulic pressure within the high pressure line and to adjust an output parameter of the variable displacement pump (e.g., torque, displacement, RPM, etc.)
Another exemplary embodiment relates to a refuse vehicle. The refuse vehicle includes a chassis and a vehicle body. The chassis supports wheels and the vehicle body. The vehicle body defines a receptacle for storing refuse. The vehicle includes a variable displacement pump. The variable displacement pump is positioned on, within, or adjacent the vehicle body and is configured to pump hydraulic fluid from a hydraulic fluid reservoir into a high pressure line of a hydraulic circuit toward actuators that are positioned about the vehicle. Delivering hydraulic fluid from the hydraulic fluid reservoir to the actuators through the high pressure line adjusts a position of at least one of the actuators. A torque limiting valve is positioned downstream of the variable displacement pump and is configured to move between a first open position, a blocking position, and a second open position in response to hydraulic pressure within the high pressure line. When the torque limiting valve is in the first open position, the torque limiting valve restricts flow between the high pressure line and a lower pressure control line. When the torque limiting valve is in the second open position, the torque limiting valve directs hydraulic fluid from the high pressure line into the control line toward the variable displacement pump to adjust an output parameter of the variable displacement pump. Fluid pressure within the high pressure line moves the torque limiting valve between the first open position, the blocking position, and the second open position. Fluid pressure within the control line adjusts a displacement of the variable displacement pump.
The invention is capable of other embodiments and of being carried out in various ways. Alternative exemplary embodiments relate to other features and combinations of features as may be recited herein.
The disclosure will become more fully understood from the following detailed description, taken in conjunction with the accompanying figures, wherein like reference numerals refer to like elements, in which:
Before turning to the figures, which illustrate the exemplary embodiments in detail, it should be understood that the present application is not limited to the details or methodology set forth in the description or illustrated in the figures. It should also be understood that the terminology is for the purpose of description only and should not be regarded as limiting.
Referring to the FIGURES generally, the various exemplary embodiments disclosed herein relate to systems, apparatuses, and methods for controlling a refuse vehicle. Specifically, the disclosure provides systems and methods for monitoring and controlling a swashplate variable displacement pump to avoid over-torqueing or stalling the pump motor when pump output demand is increased. The control systems include a sensor that monitors the pressure of hydraulic fluid leaving the hydraulic pump and another sensor that monitors the position of the swashplate of the hydraulic fluid flow to determine the pump output. A spool valve is positioned within the hydraulic circuit and controls fluid flow between a high pressure line at the outlet of the swashplate variable displacement pump and a hydraulic fluid reservoir. The spool valve is biased into a first open position blocking fluid flow between the high pressure line and the hydraulic fluid reservoir. If the pressure of the hydraulic fluid downstream of the swashplate variable displacement pump exceeds a threshold pressure, the bias on the spool valve is overcome and the spool valve translates to a second open position. In the second open position, hydraulic fluid within the high pressure line is directed through the spool valve and into an intermediate pressure line. The intermediate pressure line directs hydraulic fluid toward the variable displacement pump to urge the swashplate of the swashplate variable displacement pump toward a flow reducing position (e.g., vertical) to decrease pump output and, as a result, decrease the torque experienced by the motor of the swashplate variable displacement pump. The spool valve remains in the second position until the pressure within the high pressure line returns to a level below the threshold pressure, where the bias can overcome hydraulic forces to return the spool valve to the first position. The spool valve serves as a torque limiting bypass valve that can prevent a motor of the hydraulic pump from stalling when power consumption is raised.
Referring to
According to an exemplary embodiment, the refuse truck 10 is configured to transport refuse from various waste receptacles within a municipality to a storage or processing facility (e.g., a landfill, an incineration facility, a recycling facility, etc.). As shown in
Referring again to the exemplary embodiment shown in
Referring to the exemplary embodiment shown in
With additional reference to
The pump 202 is in communication with a processing unit, shown as processor 100. The processor 100 at least partially controls the pump 202 to deliver pressurized hydraulic fluid to accommodate variable pump loads 206 that may be requested during normal refuse truck 10 operation. The processor 100 receives signals from various inputs throughout the refuse truck 10 and can subsequently control different components within the hydraulic circuit 200 to execute different tasks. For example, the processor 100 may receive an input from one or more buttons or controls within the cab 18 of the refuse truck 10 that prompt the lifting system 30 to move in order to raise and empty the contents of a waste receptacle (e.g., waste receptacle 102, shown in
A sensor 210 positioned within the hydraulic circuit 200 can monitor a pressure and/or a flow rate of hydraulic fluid downstream of the pump 202 to determine a current pump flow rate and/or the pressure of hydraulic fluid being output by the pump 202. Another sensor 212 coupled to the pump 202 can measure a current angle of a swashplate 208 on the pump 202, which corresponds to a current pump 202 displacement. In some examples, the processor 100 receives data from each of the sensors 210, 212 and, using the data received from the sensors 210, 212, determines an appropriate adjustment to the angle of the swashplate 208 to meet the new requested pump load 206 corresponding with the input received (e.g., to execute a compactor or ejection stroke or lift a waste receptacle with the lifting system 30) by the processor 100. The processor 100 then adjusts the swashplate 208 angle in order to arrive at the swashplate angle that was determined by the processor 100 so that the pump 202 can efficiently deliver the desired pump flow or fluid pressure associated with the requested pump load 206.
The hydraulic circuit 200 includes a series of valves and pressure lines that are configured to direct pressurized hydraulic fluid between the hydraulic fluid reservoir 204, the pump 202, and the load 206 to execute operations with the various actuators on the refuse truck 10. The valves and pressure lines are arranged so that the hydraulic circuit 200 is divided into a high pressure line 220, an intermediate pressure or “control” line 222, and a low pressure or “drain” line 224.
One or more valves 226, 228, 230 are positioned between the lines 220, 222, 224 and selectively provide fluid communication between the lines 220, 222, 224 to control operation of the pump 202 and distribute hydraulic fluid to the various actuators within the pump load 206. As depicted in
During normal operation, and as depicted in
When the processor 100 initially receives or otherwise generates an input to adjust the pump load 206 (e.g., to provide pressurized hydraulic fluid to an actuator), the pump 202 begins to operate to deliver the requested pump load 206 from the hydraulic fluid reservoir 204. Hydraulic fluid is drawn from the hydraulic fluid reservoir 204 into the pump 202 along a first branch 240. The fluid is pressurized within the pump 202 and directed outward along a first branch 242 of the high pressure line 220. The pressurized hydraulic fluid is delivered through the first branch 242 to the pump load 206, which expands and extends the actuators so that the actuators can execute the various functions inputted and/or requested to the processor 100. As depicted in
As discussed above, the pump 202 is a swashplate-type variable displacement pump. The pump 202 includes a plurality of pistons that operate to compress fluid. The stroke length of the pistons, which is determined by the angle of the swashplate 208, determines the displacement (e.g., flow rate) of hydraulic fluid that exits the pump 202. Because the sensor 212 monitors the position (e.g., the angle) of the swashplate 208, the sensor 212 can effectively serve as a flow rate sensor. By communicating the monitored position of the swashplate 208 to the processor 100, the processor can then determine (e.g., calculate or access from a table of values) the flow rate (Q) out of the pump 202. The sensor 212 can be a mechanical position sensor (e.g., an encoder or an LVDT).
The sensor 210 can be used to monitor other characteristics of pump operation by monitoring the pressurized hydraulic fluid within the high pressure line 220. The sensor 210 is positioned along the first branch 242 of the high pressure line 220 to monitor one or more pump parameters. For example, the sensor 210 can monitor the hydraulic fluid pressure within the high pressure line 220. By being located just downstream of the pump 202, the sensor 210 provides a near real-time measurement of pump output. Using the measured hydraulic fluid pressure within the high pressure line 220 and the measured orientation of the swashplate 208 to determine the flow rate through the pump 202, the processor 100 can calculate the torque experienced by a motor of the pump 202. The torque (T) experienced by the motor of the pump 202 is the product of the pump pressure (P) and the flow rate (Q) through the pump 202 (i.e., T=P*Q).
The pump 202 is configured to provide pressurized hydraulic fluid from the hydraulic fluid reservoir 204 to multiple actuators that together define the pump load 206. In some instances, the pump load 206 may exceed the available pressure or flow rate that the pump 202 can produce. For example, if the lifting system 30 is attempting to raise a heavy waste receptacle while the compactor system 42 is executing a compactor stroke within the receptacle, further expansion of the hydraulic cylinders may be opposed. The resistance provided by the mass of the heavy waste receptacle 16 and the refuse within the receptacle's resistance to packing can oppose further movement of the hydraulic cylinders attempting to perform the lifting and compacting functions, respectively. Because the flow rate of the pump 202 does not change (e.g., the amount of hydraulic fluid necessary to move the piston 246 to a desired position within the actuator reservoir 244 remains constant), the resistance to movement causes a pressure spike within the first branch 242 of the high pressure line 220. With the flow rate (Q) remaining constant, the pressure spike (P) within the first branch 242 of the high pressure line 220 causes a subsequent spike in torque (T) experienced by the pump motor.
If the torque experienced by the pump motor approaches or exceeds the amount of torque that the pump motor can produce, the pump motor will slow or stall and potentially burn out. To avoid these potentially fatal motor conditions, the valve 230 is arranged to override the hydraulic circuit and mechanically control the pump 202 when the torque experienced by the motor exceeds a set threshold limit (e.g., 90% of maximum torque output). The valve 230 drops the torque experienced by the pump motor by mechanically adjusting the swashplate 208 position to reduce the piston stroke length of the pump 202. By lowering the displacement of the pump (Q), the torque experienced by the pump motor (T=P*Q) will also be reduced.
With continued reference to
In the first open position, the valve 230 is in communication with each of the high pressure line 220, the control line 222, and the drain line 224. The valve 230 provides a fluid flow path that allows flow from a first relief line 262 of the control line 222 through the valve 230 and into a first unloading branch 252 of the drain line 224, so that hydraulic fluid can be returned to the hydraulic fluid reservoir 204.
Simultaneously, the valve 230 is subjected to fluid pressure from the high pressure line 220. In the first open position, the valve 230 is in fluid communication with a first bypass line 256 and is subjected to hydraulic pressure from a first pressure line 258. Flow from the first bypass line 256 through the valve 230 is blocked when the valve 230 is in the first open position. Pressure and flow within the first pressure line 258 acts upon a spool of the valve 230, against the bias of the spring 236. During normal operating conditions (e.g., T≤80% maximum torque output), the hydraulic force within the first pressure line 258 acting upon the spool of the valve 230 does not overcome the spring force generated by the spring 236. Accordingly, the spring 236 maintains the valve 230 within the first open position. The hydraulic force generated by the first pressure line 258 is the product of the hydraulic pressure (P) within the first pressure line 258 and a surface area (A) of the spool that is subjected to the hydraulic pressure (e.g., F=P*A).
The first bypass line 256 and the first pressure line 258 are arranged in parallel to one another and are supplied with pressurized hydraulic fluid from a control branch 260 of the high pressure line 220. The control branch 260 is in fluid communication with the first branch 242 and supplies pressurized hydraulic fluid to each of the valves 226, 228, 230 to execute various control processes within the hydraulic circuit 200. Because the control branch 260 is supplied with pressurized fluid downstream of the pump 202 and directly from the first branch 242, the hydraulic pressure within the control branch 260, the first bypass line 256, and the first pressure line 258 are theoretically equal (e.g., assuming frictional losses are zero). Accordingly, when the pressure and/or flow within the first branch 242 rises, the pressure and/or flow within the control branch 260, the first bypass line 256, and first pressure line 258 rise as well. Because each of the valves 226, 228, 230 block the flow from the control branch 260 in their first open positions, after the control branch 260 is filled with hydraulic fluid from the first branch 242, increases in pump output increase the hydraulic pressure of the hydraulic fluid within the control branch 260.
If the torque calculated by the processor 100 and theoretically experienced by the pump 202 exceeds normal operating conditions (e.g., T>80% maximum torque output), the hydraulic pressure within the first pressure line 258 is likely elevated. The increased hydraulic pressure provides an increase in hydraulic force within the first pressure line 258 that is sufficient to overcome the bias of the spring 236 and move the spool of the valve 230 toward and into the intermediate “closed” position shown in
As the calculated torque continues to rise (e.g., T≥90% maximum torque output) and the pressure within the first pressure line 258 continues to climb, the hydraulic force within the first pressure line 258 pushes the spool of the valve 230 from the intermediate position to the second open position, shown in
When the spool of the valve 230 transitions from the intermediate position to the second open position, the valve 230 provides a flow path that places the first bypass line 256 in fluid communication with the first relief line 262 of the control line 222. High pressure hydraulic fluid then passes through the valve 230 into the lower-pressure control line 222, relieving pressure within first bypass line 256. Because the first bypass line 256 is in fluid communication with the first branch 242 of the high pressure line 220, additional highly pressurized hydraulic fluid can be diverted from the first branch 242 into the control branch 260, through the first bypass line 256, into and through the valve 230 to the lower pressure control line 222.
The hydraulic fluid offloaded from the high pressure line 220 into the control line 222 can then be used to override the pump 202. The fluid exiting the valve 230 travels along the first relief line 262 of the control line 222 toward the valve 226. Because the valve 226 is also subjected to hydraulic force from hydraulic fluid passing through the control line 260 (and the hydraulic force acts against the bias of the spring 232), the valve 226 is also in its second open position when an over-torque condition (e.g., T≥90% maximum torque output) is detected by the processor 100 or experienced, generally, within the high pressure line 220. In the second open position, the valve 226 blocks flow from the first relief line 262. Accordingly, once hydraulic fluid has filled the first relief path 262 of the control line 222, additional flow through the first relief line 262 and the valve 230 may be limited (e.g., the pressure within the first relief line 262 approaches the pressure within the first branch 242 of the high pressure line 220).
While the valve 226 blocks flow from the first relief line 262 in the second open position, the valve 226 also provides a flow path connecting a second bypass line 264 of the high pressure line 220 with a second relief line 266 of the control line 222. Highly pressurized hydraulic fluid from the control line 260 and the first branch 242 is directed through the valve 226 and into the lower pressure second relief line 266. Hydraulic fluid within the second relief line 266 flows toward or around the valve 228 within the control line 222. Because the valve 228 is also subjected to hydraulic force from hydraulic fluid passing through the control line 260 (and the hydraulic force acts against the bias of the spring 234), the valve 228 is also in its second open position when an over-torque condition (e.g., T≥90% maximum torque output) is detected by the processor 100.
While fluid flowing toward the valve 228 may be blocked when the valve 228 is in its second open position, the valve 228 similarly creates a flow path connecting a third bypass line 268 of the high pressure line 220 with a third relief line 270 of the control line 222. Highly pressurized hydraulic fluid from the control line 260 and the first branch 242 is directed through the valve 228 and into the lower pressure third relief line 270, where it may join the pressurized hydraulic fluid that was directed from the valve 226 and the second relief line 266 around the valve 228.
The pressurized hydraulic fluid within the control line 222 can then be used to prevent the pump 202 from over-torqueing. Pressurized hydraulic fluid travels from the control line 260 and first branch 242 of the high pressure line into the third relief line 270 of the control line 222 and toward the pump 202. A swashplate positioner 214 is positioned at the end of the third relief line 270 of the control line 222, and is subjected to the hydraulic forces exerted by the hydraulic fluid within the third relief line 270. The swashplate positioner 214 biases the swashplate 208 away from a minimum flow condition (e.g., swashplate angle of 0 degrees) using a spring 216 or other mechanical biasing element, for example. As the pressure within the third relief line 270 builds, the hydraulic force exerted on the swashplate positioner 214 overcomes the bias provided by the spring 216, and begins to move the swashplate positioner 214. Movement of the swashplate positioner 214 moves the swashplate 208 of the pump 202 toward its minimum flow orientation (e.g., swashplate angle of 0 degrees).
By moving the swashplate positioner 214 and changing the angle of the swashplate 208 of the pump 202, the control line 222 effectively overrides the pump 202 to reduce the displacement (e.g., flow rate Q) of the pump 202. Because the torque experienced by the pump's motor is the product of the pump flow rate (Q) and the pressure (P) within the first branch 242 of the high pressure line 220, lowering the displacement (Q) of the pump 202 will lower the amount of torque experienced by the pump's motor. Over-torqueing, slowdown, and stalling conditions are avoided that could otherwise cause irreparable damage to the pump 202.
With the displacement of the pump 202 minimized by the manual positioning of the swashplate 208 performed by the control line 222, pressure within the high pressure line 220 will eventually begin to fall. As the pressure within the high pressure line 220 continues to drop, eventually the biasing forces provided by the springs 232, 234, 236 will be sufficient to overcome the hydraulic forces acting on the valve spools. Accordingly, the valves 226, 228, 230 will return to their first open positions, as shown in
In some examples, the spring constants of the springs 232, 234, 236 are variable, such that the valves 226, 228, 230 may be subject to transitioning between their first open positions and their second open positions under different operating conditions. For example, the springs 232, 234 controlling the valves 226, 228 may be provided with a higher spring constant so that the valve 230 will transition to its second open position before either of the valves 226, 228 move from their respective first open positions.
If the valve 230 transitions toward the second open position (shown in
Once the displacement of the pump 202 is minimized by the control line 222 and swashplate positioner 214, the pressure within the high pressure line 220 will once again fall. As the pressure within the first pressure line 258 drops, the force exerted on the spool of the valve 230 falls below the biasing force of the spring 236. The spring 236 then forces the valve 230 to transition from the second open position (
Although the refuse truck 10 is described in the context of front-end loaders and side loaders, other types of refuse vehicles can incorporate the torque limiting hydraulic circuit 200 disclosed above. For example, rear-end loaders can incorporate the valves 226, 228, 230 and other schematics as well. Additionally, the various loads on the refuse truck 10 can also include external accessories that are hooked into the hydraulic circuit 200. For example, and as depicted in
Using the foregoing refuse vehicle control systems and methods, a refuse truck can be controlled to avoid over-torqueing or stalling of the motor during operation. The refuse truck maintains desired pump performance while avoiding potentially irreparable damage to various components within the hydraulic circuit. By mechanically overriding the swashplate of the variable displacement pump to limit piston stroke and flow rate out of the pump, the pump can remain operational without flooding or flushing the entire hydraulic circuit, even when the pump load approaches a maximum allowable limit.
Although this description may discuss a specific order of method steps, the order of the steps may differ from what is outlined. Also two or more steps may be performed concurrently or with partial concurrence. Such variation will depend on the software and hardware systems chosen and on designer choice. All such variations are within the scope of the disclosure. Likewise, software implementations could be accomplished with standard programming techniques with rule-based logic and other logic to accomplish the various connection steps, processing steps, comparison steps, and decision steps.
As utilized herein, the terms “approximately”, “about”, “substantially”, and similar terms are intended to have a broad meaning in harmony with the common and accepted usage by those of ordinary skill in the art to which the subject matter of this disclosure pertains. It should be understood by those of skill in the art who review this disclosure that these terms are intended to allow a description of certain features described and claimed without restricting the scope of these features to the precise numerical ranges provided. Accordingly, these terms should be interpreted as indicating that insubstantial or inconsequential modifications or alterations of the subject matter described and claimed are considered to be within the scope of the invention as recited in the appended claims.
It should be noted that the term “exemplary” as used herein to describe various embodiments is intended to indicate that such embodiments are possible examples, representations, and/or illustrations of possible embodiments (and such term is not intended to connote that such embodiments are necessarily extraordinary or superlative examples).
The terms “coupled,” “connected,” and the like, as used herein, mean the joining of two members directly or indirectly to one another. Such joining may be stationary (e.g., permanent, etc.) or moveable (e.g., removable, releasable, etc.). Such joining may be achieved with the two members or the two members and any additional intermediate members being integrally formed as a single unitary body with one another or with the two members or the two members and any additional intermediate members being attached to one another.
References herein to the positions of elements (e.g., “top,” “bottom,” “above,” “below,” “between,” etc.) are merely used to describe the orientation of various elements in the figures. It should be noted that the orientation of various elements may differ according to other exemplary embodiments, and that such variations are intended to be encompassed by the present disclosure.
It is important to note that the construction and arrangement of the refuse vehicle as shown in the exemplary embodiments is illustrative only. Although only a few embodiments of the present disclosure have been described in detail, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited. For example, elements shown as integrally formed may be constructed of multiple parts or elements. It should be noted that the elements and/or assemblies of the components described herein may be constructed from any of a wide variety of materials that provide sufficient strength or durability, in any of a wide variety of colors, textures, and combinations. Accordingly, all such modifications are intended to be included within the scope of the present inventions. Other substitutions, modifications, changes, and omissions may be made in the design, operating conditions, and arrangement of the preferred and other exemplary embodiments without departing from scope of the present disclosure or from the spirit of the appended claims.
This application claims priority to U.S. patent application Ser. No. 17/232,244, filed Apr. 16, 2021, which claims the benefit of and priority to U.S. Provisional Patent Application No. 63/011,631, filed Apr. 17, 2020, the contents of which are hereby incorporated by reference in their entirety.
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Parent | 17232244 | Apr 2021 | US |
Child | 18310902 | US |