The present disclosure relates to a hydraulic management system and method for a work vehicle. More particularly, the present disclosure relates to a hydraulic management system and method for a work vehicle that accounts for auxiliary work tool usage.
A work vehicle may be configured to receive a primary work tool, such as a bucket, as well as one or more auxiliary work tools. Compared to the primary work tool, the auxiliary work tool may allow more dirt and debris to enter the hydraulic fluid (e.g., oil) of the vehicle. As a result, the hydraulic fluid in the vehicle may become contaminated faster when operating an auxiliary work tool than when operating a primary work tool. The filters used to clean the contaminated hydraulic fluid may also become clogged faster when operating an auxiliary work tool than when operating a primary work tool. Therefore, the hydraulic fluid and the hydraulic filters may require more frequent maintenance when operating an auxiliary work tool than when operating a primary work tool. In practice, it becomes difficult to anticipate and schedule downtime to perform such maintenance.
The present disclosure provides a hydraulic management system and method that account for auxiliary work tool usage. The hydraulic management system automatically calculates an effective use time of a hydraulic element, such as a hydraulic fluid or hydraulic filters, by multiplying work tool usage by a desired gain factor, where the gain factor may exceed 1 for auxiliary work tools.
According to an embodiment of the present disclosure, a work vehicle is provided including a chassis, a plurality of traction devices supporting the chassis, a first hydraulic work tool selectively coupled to the work vehicle for movement relative to the chassis, a second hydraulic work tool selectively coupled to the work vehicle for movement relative to the chassis, and a hydraulic management system including a controller that determines an effective use time of at least one hydraulic element of the work vehicle. The controller increases the effective use time at a first rate based on usage of the first hydraulic work tool and at a second rate based on usage of the second hydraulic work tool, the second rate differing from the first rate.
According to another embodiment of the present disclosure, a work vehicle is provided including a chassis, a plurality of traction devices supporting the chassis, at least one hydraulic work tool selectively coupled to the work vehicle for movement relative to the chassis, a hydraulic management system including a controller and a gain input that communicates a gain factor associated with the at least one hydraulic work tool to the controller. The controller multiplies usage of the at least one hydraulic work tool by the gain factor to determine an effective use time of at least one hydraulic element of the work vehicle.
According to yet another embodiment of the present disclosure, a method is provided for managing a hydraulic system of a work vehicle. The method includes the steps of: receiving a gain factor associated with a hydraulic work tool; operating the work vehicle with the hydraulic work tool coupled to the work vehicle; monitoring an actual time of the operating step; and determining an effective use time of at least one hydraulic element of the work vehicle by multiplying the actual time of the operating step by the gain factor.
The above-mentioned and other features and advantages of this disclosure, and the manner of attaining them, will become more apparent and the invention itself will be better understood by reference to the following description of embodiments of the invention taken in conjunction with the accompanying drawings, wherein:
Corresponding reference characters indicate corresponding parts throughout the several views. The exemplifications set out herein illustrate exemplary embodiments of the invention and such exemplifications are not to be construed as limiting the scope of the invention in any manner.
Referring initially to
Vehicle 100 further includes a primary hydraulic work tool, illustratively a bucket 110, that is moveably coupled to chassis 102 via boom assembly 112. The primary bucket 110 may be configured to dig, scoop, carry, and dump dirt and other materials. A plurality of hydraulic cylinders 114 may be provided to move boom assembly 112, as well as the primary bucket 110 located thereon, relative to chassis 102. The primary bucket 110 may be installed and sold by the original equipment manufacturer (OEM).
Vehicle 100 is also configured to receive one or more secondary or auxiliary hydraulic work tools. The primary bucket 110 (
The secondary hammer 120 and the secondary shears 122, like the primary bucket 110, may be moveably coupled to chassis 102 via boom assembly 112. The same hydraulic cylinders 114 that were used to operate boom assembly 112 with the primary bucket 110 in place may be used to operate boom assembly 112 with the secondary hammer 120 or the secondary shears 122 in place. Additional hydraulic actuators may also be provided to operate auxiliary functions of the secondary work tools 120, 122. In the case of the secondary hammer 120, for example, an additional hydraulic cylinder 124 (shown in phantom in
Referring next to
Controller 132 may include a processor 150 that is capable of receiving inputs and generating appropriate outputs and a memory 152 that is capable of storing information. The components of hydraulic management system 130 may communicate with controller 132 via a CAN network or via wired connections, for example. The operation of controller 132 is discussed further below with reference to
Timer 134 may operate whenever vehicle 100 is powered on, even when the operator is not operating a hydraulic work tool. It is also within the scope of the present disclosure that timer 134 may operate only during hydraulic operations of vehicle 100, such as during operation of a hydraulic work tool. Controller 132 is able to monitor timer 134 to determine the start time of an event and the end time of the event, for example.
The tool operation inputs, illustratively a left joystick 140, a right joystick 142, and a slider 144 mounted on the right joystick 142, allow the operator to control the movement of boom assembly 112 and the desired work tool 110, 120, 122. When the operator moves left and/or right joysticks 140, 142, controller 132 may control the movement of boom assembly 112 via hydraulic cylinders 114, for example. When the operator moves slider 144, controller 132 may control an auxiliary work tool function. For example, controller 132 may control the movement of tip 125 of hammer 120 via hydraulic cylinder 124, or the movement of arms 127 of shears 122 via hydraulic cylinder 126. The type, number, and arrangement of tool operation inputs 140, 142, 144 may vary. For example, a foot pedal (not shown) may be used instead of the illustrative slider 144. Also, additional joysticks, sliders, or other user inputs may be provided to control additional work tools and work tool functions.
Tool selector input 146 allows the operator to inform controller 132 which work tool has been selected for use on vehicle 100. The illustrative tool selector input 146 of
Gain input 148 allows the operator to input a desired gain factor into controller 132. In an exemplary embodiment, the gain factor is a number greater than or equal to 1, such as 1, 2, 3, 4, 5, or more. Other numerical values are also within the scope of the present disclosure. The gain factor may default to 2 or 3, for example, unless changed by the operator. Gain input 148 may be in the form of a numerical key pad, up and down selector buttons, a dial, a multi-option menu, or another suitable user input. In an exemplary embodiment, display 136 visually communicates the current gain factor to the operator. Gain input 148 may be enabled when tool selector input 146 identifies a secondary work tool “S1” or “S2,” allowing the operator to input a corresponding gain factor (e.g., 1, 2, 3, 4, 5, or more) to controller 132. However, gain input 148 may be disabled to the operator when tool selector input 146 identifies a primary work tool “P,” automatically supplying a gain factor of 1 to controller 132.
In operation, vehicle 100 delivers hydraulic fluid to operate the selected work tool. For example, vehicle 100 may deliver hydraulic fluid to the hydraulic cylinders 114 of boom assembly 112, the hydraulic cylinder 124 of the secondary hammer 120, and/or the hydraulic cylinder 126 of the secondary shears 122. Compared to a primary work tool (e.g., the primary bucket 110), a secondary work tool (e.g., the secondary hammer 120, the secondary shears 122) may allow more dirt and debris to enter the hydraulic fluid of vehicle 100. As a result, the hydraulic fluid in vehicle 100 may become contaminated faster when operating a secondary work tool than when operating a primary work tool. The filters used to clean the contaminated hydraulic fluid may also become clogged faster when operating a secondary work tool than when operating a primary work tool. Therefore, the hydraulic fluid, the hydraulic filters, and/or other hydraulic elements of vehicle 100 may require more frequent maintenance when operating a secondary work tool than when operating a primary work tool.
Various characteristics of the secondary work tool may influence the cleanliness/dirtiness of the hydraulic system. Such characteristics include, for example, the type of secondary work tool, the age and condition of the secondary work tool and its hydraulic seals, the quality of the hydraulic coupling between the secondary work tool and vehicle 100 (
Hydraulic management system 130 of the present disclosure may automatically account for the increased dirtiness and frequent maintenance associated with secondary work tools when calculating the usage of the hydraulic fluid, the hydraulic filters, and/or other hydraulic elements of vehicle 100. For each hydraulic element, hydraulic management system 130 may automatically calculate an effective use time (i.e., time of operation) of the hydraulic element by multiplying work tool usage by a desired gain factor, according to Formula (I) below.
Effective Use Time=GP(TP)+GS1(TS1)+GS2(TS2) (I)
wherein:
For a primary work tool, the gain factor (GP) is generally equal to 1. In operation, gain input 148 may automatically supply a gain factor (GP) of 1 to controller 132. With primary work tool usage, the effective use time of the hydraulic element may be the same as the actual use time of the hydraulic element.
For secondary work tools, the gain factor (GS1 and GS2) may be greater than 1. In operation, the operator may use gain input 148 to manually specify an appropriate gain factor (GS1 and GS2) to controller 132 based on one or more characteristics of the secondary work tool, which are discussed above. It is also within the scope of the present disclosure for controller 132 to automatically determine an appropriate gain factor based on the type of secondary work tool selected for use and/or other characteristics of the work tool. In this embodiment, secondary work tool usage will increase the effective use time of a hydraulic element at a faster rate than primary work tool usage. Secondary work tool usage may also cause the effective use time of the hydraulic element to exceed the actual use time of the hydraulic element. As a result, the operator will know to conduct more frequent maintenance of the hydraulic element with secondary work tool usage.
For each hydraulic element, the effective use time from Formula (I) above may be used to calculate the spent life of the hydraulic element. The spent life may be expressed as a fraction or percentage of a predetermined expected life, according to Formula (II) below. The spent life may be communicated to the operator to warn the operator of an immediate or future need for maintenance. For example, when the spent life of a hydraulic element reaches 70%, 80%, 90%, or more, controller 132 may issue warning notifications to the operator via display 136 or another suitable communication device. When the spent life reaches 100%, the warning notifications from controller 132 may become more intense, such as by flashing text on display 136 or by issuing an audible signal.
Also, the effective use time from Formula (I) above may be used to calculate the remaining life of each hydraulic element. The remaining life may be expressed as a fraction or percentage of the expected life, according to Formula (III) below. Again, the remaining life may be communicated to the operator to warn the operator of an immediate or future need for maintenance. For example, when the remaining life of a hydraulic element reaches 30%, 20%, 10%, or less, controller 132 may issue warning notifications to the operator via display 136 or another suitable communication device. When the remaining life reaches 0%, the warning notifications from controller 132 may become more intense, such as by flashing text on display 136 or by issuing an audible signal.
The effective use time of Formula (I) above may be reset to 0 hours after performing an appropriate maintenance procedure, such as an oil change or a filter change. As a result, the spent life of Formula (II) above will be reset to 0% and the remaining life of Formula (III) above will be reset to 100%.
The following scenario is presented to illustrate the calculations discussed above. Since the last hydraulic oil change was performed, the operator in the present example operates a vehicle with a primary bucket for 400 hours (TP), a single-acting secondary hammer for 100 hours (TS1), and double-acting secondary shears for 100 hours (TS2). The gain factor for the primary bucket (GP) is automatically set to 1. The operator designates a gain factor for the secondary hammer (GS1) of 5, because the secondary hammer is old, poorly maintained, and used in a dirty environment. The operator designates a gain factor for the secondary shears (GS2) of 2, because the secondary shears are relatively new and in good condition. Although the hydraulic oil has an actual use time of only 600 hours (calculated as 400 hours with the primary bucket+100 hours with the secondary hammer+100 hours with the secondary shears), the hydraulic oil has an effective use time of 1,100 hours (calculated as 1*400 hours with the primary bucket+5*100 hours with the secondary hammer+2*100 hours with the secondary shears) according to Formula (I) above. Assuming that the hydraulic oil has a predetermined expected life of 2,000 hours, the hydraulic oil life is 55% spent based on Formula (II) above with 45% remaining based on Formula (III) above after 1,100 hours of effective operation.
An exemplary method 200 for operating hydraulic management system 130 is shown in
In step 202 of
In step 206, controller 132 communicates with tool selector input 146 (
Continuing to step 210, controller 132 communicates with timer 134 (
Method 200 also includes step 214, which allows for displaying the “Saved Use Time” to the operator via display 136 (
Method 200 further includes step 216, which allows for resetting the “Saved Use Time” upon request. The resetting step 216 may be performed after the operator performs an appropriate maintenance procedure, such as an oil change or a filter change.
While this invention has been described as having exemplary designs, the present invention can be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the invention using its general principles. Further, this application is intended to cover such departures from the present disclosure as come within known or customary practice in the art to which this invention pertains and which fall within the limits of the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
5809779 | Bruso | Sep 1998 | A |
5970436 | Berg et al. | Oct 1999 | A |
7493112 | Adachi et al. | Feb 2009 | B2 |
8160784 | Fukumoto | Apr 2012 | B2 |
20030051470 | Maddock | Mar 2003 | A1 |
20060129280 | Thomas et al. | Jun 2006 | A1 |
20060150446 | Ottoni | Jul 2006 | A1 |
20070222573 | Navarro et al. | Sep 2007 | A1 |
20090198409 | Rector et al. | Aug 2009 | A1 |
20100087985 | Boss et al. | Apr 2010 | A1 |
20100275589 | Meyers et al. | Nov 2010 | A1 |
20110137491 | Self et al. | Jun 2011 | A1 |
20120250815 | Oksman et al. | Oct 2012 | A1 |
Number | Date | Country | |
---|---|---|---|
20140150304 A1 | Jun 2014 | US |