Patent Grant
8459394
This disclosure relates generally to the art of earth moving equipment and particularly to a fluid operated rear wheel drive assist for an articulated machine with a control system that modulates power to the rear wheel assist based on articulation angle.
The wheel tractor scraper is a machine employed in various industries, such as agriculture, construction and mining to load, haul, eject and spread layers of earth. Such machines are particularly suited for applications, for example, in roadway construction and site preparation, where material needs to be removed or added while creating or maintaining grade and hauling occurs over moderate distances, e.g. under one mile. Conventional wheel tractor scrapers typically include a tractor portion having a forward frame member that supports the operator station and a power source operatively coupled to the driven wheels of the machine. An articulated joint couples the tractor portion to the rear scraper portion, the scraper portion having a rear frame member that supports both a bowl for collecting and hauling material, and the rear wheels. During operation, the bowl is typically lowered to engage the ground along a cutting edge that is driven forward by the machine, loading the bowl. Many of these machines will have an earth-moving work tool, such as an elevator, conveyor, auger, or spade, associated with the bowl to facilitate penetration and/or loading of the material to be transported.
One of the limiting factors associated with wheel tractor scraper operations are the traction conditions of the work site. Tractor scraper operations can be limited, for example, by the type of material, geographic location, and seasonal conditions of the work site.
Various improvements and methods of operation have been adopted by the industry to increase the versatility and efficiency of these machines. For example, wheel tractor scrapers are often employed in push-pull operations, wherein a first tractor scraper is either pulled or pushed by a second machine, for example, a track-type dozer or another wheel tractor scraper, during the loading process. Wheel tractor scrapers are often provided with hitches or push bars to facilitate these operations. However, the option of a second machine is not always possible, and this increases operating costs. Further, this does not address concerns of the tractor scraper becoming stuck during the remainder of the work cycle.
As an alternative, some large wheel tractor scrapers are provided with an additional, rear mounted engine operatively connected to drive the rear wheels of the machine (twin-engine scrapers), making these machines better suited for handling adverse terrain and worksite conditions. However, another alternative has been to provide a fluid operated rear wheel assist.
For example, U.S. Pat. No. 5,682,958 to Kalhorn et al. provides a hydrostatic rear wheel assist that includes a reversible variable displacement pump operatively coupled to an engine and mounted to the front frame section of an articulated scraper. The pump is fluidly connected to a pair of motors positioned on the rear frame section for driving the right and left rear wheels, respectively. The pump may be actuated via a floor pedal that controls an engagement/disengagement valve having two positions, an engagement position for directing pressurized fluid to the motors, and a disengagement position for preventing flow to the motors. However, this requires an additional and dedicated fluid pump, fluid lines, and other components that significantly add to overall vehicle complexity and cost.
Another difficulty associated with providing a rear wheel assist for an articulated machine is that as the articulation angle is increased to effectuate a turn, if too much power is supplied to the rear wheels, and the traction of the front driven wheels is insufficient, the machine may be driven forward rather than turning. This may also cause the front end of the machine to “hop” when the front wheels catch or regain traction. The result of both of these conditions is decreased machine control and undesirable stresses that may damage the machine.
In general, the need exists in the industry for wheel tractor scrapers that are capable of efficient operation under a greater range of terrain conditions. In particular, the need exists for an improved rear wheel assist design and efficient methods of operation thereof, and, more particularly, for a rear wheel assist that responds to machine articulation.
In one aspect, the present disclosure provides an articulated machine, such as a wheel tractor scraper, having a first frame section with a power source drivingly connected to at least one front wheel, and a second frame section having at least one rear wheel, the first and second frame sections being pivotally connected at an articulation hitch. An articulation sensor is configured to provide an articulation signal indicative of an articulation angle formed between longitudinal axes of the first and second frame sections. A rear wheel drive assist is also provided that includes a drive motor operatively connected to the rear wheel of the machine. A controller is configured to control operation of the rear wheel drive assist based upon the articulation signal.
In another aspect, provided is an articulated machine having a first frame section with a power source drivingly connected to at least one front wheel, and a second frame section having at least one rear wheel, the first and second frame sections being pivotally connected at an articulation hitch. An articulation sensor is configured to provide an articulation signal indicative of an articulation angle formed between longitudinal axes of the first and second frame sections. A first speed sensor provides an indication of a front wheel speed, and a second speed sensor provides an indication of rear wheel speed. A rear wheel drive assist is also provided that includes a drive motor operatively connected to the rear wheel of the machine. A controller is configured to control operation of the rear wheel drive assist to reduce the rear wheel speed relative to the front wheel speed based on the articulation signal.
In yet another aspect, provided is a wheel tractor scraper having a tractor portion with a power source drivingly connected to at least one front wheel, and a scraper portion pivotally connected to the tractor portion at an articulation hitch, the scraper portion having a bowl and at least one rear wheel. First and second linear actuators are connected between the tractor portion and the scraper portion in opposed position, the actuators configured to move the tractor portion relative to the scraper portion about the articulation hitch. An articulation sensor is configured to provide an articulation signal indicative of an articulation angle formed between longitudinal axes of the tractor and scraper portions of the machine. A first speed sensor is configured to provide an indication of a front wheel speed, and a second speed sensor is configured to provide an indication of a rear wheel speed. In this embodiment, the rear wheel drive assist includes a fluid pump connected to a drive motor to drive the rear wheel, a controller configured to control operation of the rear wheel drive assist to reduce the rear wheel speed relative to the front wheel speed based on the articulation signal.
These and other aspects and advantages of the present disclosure will become apparent to those skilled in the art upon reading the following detailed description in connection with the drawings and appended claims.
The front frame section 12 supports a cooling system (not shown) and power source 20, the power source 20 operatively connected through a transmission 22 (
The rear frame section 14 may support the bowl 28 and rear wheels 26. The bowl 28 may also include a fluid powered work tool 30, such as an elevator 52 (shown), auger, conveyor, or spade, to facilitate penetration and/or loading of the material to be transported.
Power source 20 may include an engine such as, for example, a diesel engine, a gasoline engine, a gaseous fuel powered engine such as a natural gas engine, or any other type of engine apparent to one of skill in the art. Power source 20 may alternatively include a non-combustion source of power such as a fuel cell, a power storage device, an electric motor, or other similar mechanism.
As shown in
In an alternative embodiment (not shown), scraper 10 may include an electric or hydraulic drive (not shown). For example, power source 20 may be operatively connected to a pump, such as a variable or fixed displacement hydraulic pump. The pump may produce a stream of pressurized fluid directed to one or more motors associated with front wheels 24 for the primary means of propulsion. Alternatively, power source 20 may be drivably connected to an alternator or generator configured to produce an electrical current used to power one or more electric motors for driving the front wheels 24.
In addition to driving the front wheels 24, power source 20 may be configured to supply power to a work tool 30 employed by the scraper to penetrate and/or transfer material into bowl 28. In one embodiment, shown in
In one embodiment, work tool 30 is an elevator 52 such as that depicted in
In certain operating conditions where, for example, mud, ice or snow, cause the primary driven wheels 26 of the scraper 10 to lose traction and/or the machine becomes stuck, the scraper 10 may be provided with a fluid operated rear wheel drive assist 86 that may be engaged manually or automatically. Referring to
The Pump Assembly 102 generally includes a charge pump 112, main pump 114, filters 124, 156, and a main pump control group 116, the charge pump 112 and main pump 114 being driven by shaft 118 operatively connected to the power source 20. Charge pump 112 is fluidly connected to fluid reservoir 120 to deliver a flow of pressurized fluid through charge line 122 and in-line charge filter 124 to control line 126. Disposed along control line 126 are forward and reverse solenoid control valves 128,130 that open to provide fluid flow along actuator control lines 132,134, respectively.
Actuator control lines 132,134 can be pressurized to control movement of swashplate spool actuator 144, which is mechanically linked to control the position of the three-way swash plate control spool 146. Swash plate control spool 146 is both mechanically linked to main swash plate actuator 148 and provides pressure from control line 126 to further provide movement of main actuator 148. Swash plate actuator 148 is mechanically linked to the swash plate 152 of variable displacement pump 114.
The actuator control lines 132, 134 are fluidly connected to max pressure control group 136 through pressure relief lines 138. Pressure relief lines 138 are connected to two-position pressure relief valves 140 that are controlled by pressure transmitted along relief valve control lines 142 connected to forward 106 and reverse 104 supply/return lines, respectively. Cross-over relief valves 150 are also provided to relieve pressure from forward 106 and reverse 104 supply/return lines, further protecting the pump assembly 102 from excessive pressure build-up. A case drain 154 is provided for the pump group 102 that includes a filter 156 fluidly connected to tank 120.
The elevator motor assembly 108 is fluidly connected to the elevator pump assembly 102 through forward and reverse supply/return lines 106,104. Lines 104,106 provide pressurized fluid to drive bi-directional elevator motor 158 that is operatively connected to elevator drive shaft 66 for rotation thereof. A pressure-actuated 3-position flushing valve 160 is fluidly connected to both the supply/return lines 104,106. Flushing valve 160 is controlled via pressure communicated from either of supply/return lines 104,106 via flushing valve control lines 162,164, respectively. Flushing valve 160 (pictured in closed orientation) can be opened to allow fluid from either supply/return lines 104,106 to drain to tank 120. Also provided to relieve pressure within motor assembly 108 are cross-over relief valves 166. Fluid from motor assembly 108 leakage and/or flushing valve 160 may drain to tank 120 via drain line 168 and through filter 170.
Motor supply/return line 226 is split at junction 230 between the right and left motor assemblies 202,204. Motor assemblies 202,204 each include a two-stage radial motor 232 having a first stage 234 and a second stage 236 that correspond to a first and second fixed displacement (not shown). For example, the motor assemblies 202, 204 may include a rotary two stage motor such as the ML series motor by Poclain Hydraulics, France, that include a series of radial pistons that can be moved between a first and second position to modify pump displacement. The motor supply/return line 226 is fluidly connected to directly drive the first stage 234, which is also fluidly connected to supply/return lines 238,240.
The second stage 236 of the right and left motor assemblies 202,204 is engaged or disengaged via motor control group 208. The motor control group 208 includes a motor speed control valve 242 that is controlled via an electrical signal that may be dependent upon, for example, vehicle speed, transmission output speed and/or a transmission output speed ratio. Upon energizing, the motor speed control valve 242 may move between a first, closed position 244 and a second, open position 246, in which flow is directed from pilot supply line 212, along motor stage control line 248 to actuate second stage control valves 250. As shown, motor speed control valve 242 is normally spring biased in the closed position 244.
As shown, second stage control valves 250 are spring biased in an open configuration (shown), first position 252, that allows pressurized fluid from supply/return lines 226, 238, 240 to flow to motor second stage 236 through second stage control lines 256. The pressurized fluid supplied via control lines 256 moves one or more pistons (not shown) within the rotary pump to increase pump displacement. Primary flow is directed into the pump along supply/return lines 226,238,240. When pressure from control line 248 overcomes the spring bias of valves 250, the valves 250 are moved to a second position 254 that directs the second stage control lines 256 to drain lines 258, causing the pistons to move to a second position and decrease overall pump displacement.
Disposed between supply/return line 228 and supply/return lines 238,240 is a pressure-responsive valve 206 that provides a limited slip function between the left and right motor assemblies 202,204. When one of the rear wheels 26 is slipping, this creates a low pressure condition at the associated motor assembly as there is less resistance and pressure build up associated with the spinning wheel. Pressurized fluid naturally flows to the less resistive, low pressure motor assembly, decreasing power available to the wheel with traction. The limited slip function serves to restrict flow to the motor assembly associated with the slipping wheel, and increase flow to the motor associated with the wheel with traction. More specifically, under equal pressure conditions, valve 206 is spring-biased in a first position 260 (shown) that distributes flow equally to the left and right drive motor assemblies 202,204. If a predetermined pressure differential exists between lines 238 and 240, valve 206 will shift to restrict flow to the lower pressure line.
In an alternative embodiment to valve 206, shown in
In yet another embodiment, motor control group 208 may also include a clutch control valve 266. This solenoid controlled, two-position valve 266 is normally spring biased in a closed, first position 268 that opens clutch control lines 272 to drain line 214. In this position, the clutch assembly 274 is disengaged, allowing the wheels to spin freely relative to motor output shafts 276. When energized to a second position 270, clutch control line 272 may be pressurized to engage clutch assembly 274, connecting output shafts 276 to drive the rear wheels. In another embodiment, a similar valve arrangement (not shown), either alone or in combination with the clutch assembly 274, may be employed to engage a brake assembly associated with, for example, the output shafts 276 or final drives 82.
In particular, controller 302 may be configured to receive a motor speed signal 304,306 from a left and right motor speed sensor 336,338, respectively. Other machine input may include an engine speed signal 310 from an engine speed sensor 342 associated with power source 20; a front transmission condition signal 314 from, for example, a transmission sensor 346 or an operator transmission control mechanism (not shown), and indicative of, for example, a transmission gear ratio; a transmission output speed signal 312 from an output speed sensor 344 associated with, for example, output shaft 34; a hydraulic temperature signal 320 from a hydraulic fluid temperature sensor 352 associated with, for example, the hydraulic pump 44; and/or a front wheel speed signal 370 from one or more front wheel speed sensors 372 associated with one or both of the front wheels 24.
Controller 302 may also be configured to receive an articulation signal 362 from an articulation sensor 364, the articulation signal 362 being indicative of an angle of articulation α,−α (
In an alternative embodiment, the articulation sensor 364 may include one or more pivot angle sensors, such as a rotary dual hall effect PWM (Pulse Width Modulation) sensor associated with a pivot pin of articulation hitch 16. Other sensors 364, such as lasers, radar or cameras may also be employed. For example, a laser sensor may be employed to detect the relative position of the front frame section 12 relative to the rear frame section 14.
In addition, input may be received from various operator controls located, for example, in the operator station 18. These may include, for example, a rear wheel assist engagement signal 308 from a rear wheel assist control switch 340; a parking brake signal 316 associated with a parking brake control mechanism 348 indicative of engagement/disengagement of a parking brake (not shown); and/or a service brake signal 318 associated with a service brake control mechanism 350 and indicative of engagement/disengagement of the vehicle service brakes (not shown).
In yet another embodiment, in the place of or in addition to the various sensors 364, the controller 300 may be configured to receive a steering control signal 366 from an operator steering control 368, such as a joystick, steering wheel, or other known device the operator employs for steering the machine, and may thereby determine the angle of articulation α,−α. For example, if the operator employs the operating steering control 368 to command the steering actuators 32 to turn the machine left 15 degrees, this same signal may be employed to indicate the corresponding articulation angle −α.
Controller 302 may be configured to control operation of the rear wheel assist system 86 through signals 322-334. These include, for example, forward and reverse pump control signals 322,324 for actuating pump forward and reverse control mechanisms 354,356, such as solenoid control valves 128,130 (
Controller 302 may also be configured to communicate the status of the rear wheel assist system 86 to the operator via, for example, a status signal 334 operatively connected to one or more indicators 360, such as an indicator light located in the operator station 18. Alternatively, status signal 334 may be connected to an operator display screen, audible signal indicator, or any other type of indicator known in the art.
The present disclosure provides a wheel tractor scraper 10 that includes a rear wheel assist 86 for improving machine operations in poor traction conditions, thereby increasing machine efficiency and versatility to operate in a greater range of environmental, material and worksite conditions. In particular, provided is a fluid operated rear wheel drive assist 86 that employs a common pump 44 or pumps that are shared with a fluid powered work tool 30, such as an elevator 52, auger, conveyor or spade. When the system is engaged, fluid flow is diverted from the elevator motor 68 to one or more rear wheel drive motors 78,80. The operation of one embodiment of the disclosed rear wheel assist systems is explained in the paragraphs that follow.
Referring again to
When the operator determines that it is desirable to engage 400 the rear wheel drive assist, the operator may employ the rear wheel assist control switch 340 providing an engagement signal 308 to controller 302. The transmission 22 is capable of operation through a range of gear ratios and vehicle speeds. In one embodiment, the rear wheel assist 86 is designed to operate only at relatively low machine speeds, e.g. below 9 mph. This protects the motors and hydraulic system from overspeed conditions. Moreover, in one embodiment, the purpose of the system is to provide additional traction only when the vehicle becomes disabled due to poor traction conditions, and thus operation may be limited to lower gear ratio, high torque transmission conditions. Accordingly, the controller 302 is provided with a transmission condition signal 314 indicative of, for example, the current transmission gear for performing a transmission status check 402. During status check 402, if the transmission 22 is in the lowest gear ratios, for example, first to third gear, the system 300 proceeds to perform a hydraulic fluid temperature check 404. Otherwise, the rear wheel assist 86 is not engaged (or is disengaged) 406 until the condition is met. In an alternative embodiment, check 402 may be based on the current speed of the machine, as provided, for example, by one or more speed sensors (not shown) associated with the front axle shafts 40, final drives 42 or wheels 24.
The hydraulic fluid temperature check 404 is performed to prevent damage to the hydraulic system components. A temperature signal 320 is provided via one or more temperature sensors 352 associated with, for example, pump assembly 102, to controller 302. If the temperature is above, for example, 90 to 93 degrees Celsius (194 to 199.4 degrees Fahrenheit), the system will not engage (or is disengaged) 406 until the temperature condition is met.
The wheel tractor scraper 10 may include a parking brake, for example, a friction type brake associated with one or more elements of the powertrain, such as the power source 20 or transmission 22 output shafts 34. The controller 302 may be configured to receive a parking brake signal 316 and determine whether the parking brake is engaged or disengaged 408. In the embodiment shown, the rear wheel assist will not engage (or will disengage) 406 if the parking brake is engaged.
Once the controller 302 has determined that the above conditions have been met, the controller 302 will engage the rear wheel assist 410. To engage the rear wheel assist, the controller may provide a diverter valve control signal 326 to diverter valve 70 (
In one embodiment, the rear wheel drive assist 86 may also include a clutch 84,274 configured to mechanically engage or disengage the left and right drive motor assemblies 202,204 from the rear final drives 82 or wheels 26. Controller 302 may provide a clutch control signal 328 to energize solenoid control valve 266, moving from first position 268 to second position 270, thereby creating flow between pilot supply 212 and clutch control line 272 to engage the clutch 274, transferring power from the motor assemblies 202,204 to drive rear wheels 26.
“Disengaged” or “disengaging the system” refers generally to any condition in which power is not supplied to the rear wheels. As described, this may be accomplished by, for example, interrupting pressurized flow to the rear motor assemblies 202,204, or disconnecting the motor assemblies 202,204 from driving the rear wheels 26, alone or in combination. Disengagement may also include shutting down pressurized flow from pump assembly 202.
Also at step 410, the system 300 may signal the operator that the rear wheel assist has been engaged via status signal 334 directed to a rear wheel assist indicator 360, such as an indicator light, display, and/or audible alert. Generally, this will alert the operator when he has employed the control switch 340 that power is not being supplied to drive the rear wheels due to some other operating condition that must be met.
The control system 300 is also configured to control the amount of power supplied to drive the rear wheels 26. This is generally accomplished by controlling operation of the pump assembly 102 and motor assemblies 202,204 in response to various machine and or operator inputs.
More specifically, at step 412 the control system 300 may be configured to modify pump displacement to match the current front transmission output ratio or gear. The controller 302 is configured to receive a transmission condition signal 314 indicative of, for example, the current output ratio or gear selection, and to modify displacement of main pump 114 based thereon. For example, in first to second gear, the main pump 114 may be upstroked to provide a higher flow rate and pressure than in third gear. The controller 302 may be configured to send a pump forward control signal 322 to pump forward control mechanism 354, such as solenoid valve 128 to increase the displacement of pump 114. While shown in
Typically, the wheel tractor scraper 10 will include service brakes (not shown), such as conventional wet or dry friction brakes, employed to slow or stop the scraper 10 during ordinary operations. Conventional service brakes may be actuated via an operator control, such as a foot pedal, disposed within the operator station 18. When the brakes are employed 416, it may be desirable to disengage 414 the rear wheel assist 86 to reduce the amount of force required to slow the vehicle and to avoid damage to the rear wheel assist 86 components. At step 416, the controller 302 is configured to receive a service brake signal 318 indicative of the status of the service brakes 350, and to thereafter disengage 414 if the service brakes have been engaged. Brake signal 318 may be associated with the degree of movement of a brake pedal (not shown) such that over a first portion of movement thereof, for example, over the first 15 percent of total movement, there is a “deadband” period over which the rear wheel assist 86 remains engaged. When the control pedal moves past 15 percent, the controller 302 is configured to disengage 414 the rear wheel assist 86.
The rear wheel assist control system 300 may also include a closed loop wheel speed control 418 that is generally employed to modify displacement of the main pump 114 to approximately match front 24 and rear 26 wheel speeds (or an average thereof). The purpose of this feature is to provide increased power to drive the rear wheels 26 in the event that the front wheels 24 are slipping, and vice versa.
In one embodiment, the controller 302 is configured to receive a signal indicative of the speed of the front wheels 24. For example, controller 302 may be configured to receive a transmission output speed signal 312 that is employed by the controller 302 to calculate an approximation of the average front wheel speeds 26. The scraper 10 may include a front differential such that the right and left wheel speeds may be independently variable. Accordingly, the transmission output speed signal 312 provides an estimation of average front wheel 24 speeds. Alternatively, sensors (not shown) associated with the front axle shafts, final drives, or wheels may provide a signal indicative of actual front wheel speed. In addition, the power source speed, provided by a power source sensor 342 via signal 310 could also be employed in combination with the transmission output speed signal 312. The front wheel speeds provided to or derived by the controller 302 are employed to control displacement of the pump 44 to control speed of the rear wheel drive motors 78,80 and associated rear wheels 26.
The controller 302 is also configured to receive an indication of rear wheel 26 speeds from right and left motor speed sensors 336,338 via right and left motor speed signals 304,306. The feedback to the control system 300 is determined by the average of the rear wheel 26 speeds as determined by the controller 302. A speed error signal is determined from the difference between the average front and rear wheel speeds, which is received by a proportional-integral (PI) controller. The PI controller is configured to bring the speed error signal to zero by adjusting the commands to the pump 44 (increasing or decreasing pump displacement accordingly) to attempt to match front and rear wheel speeds.
For example, if the machine is loading, with only the front driven wheels 24 engaged, and the machine becomes stuck, the average front wheel speed could be spinning at, for example, 10 mph, and the rear wheel speed would be zero. The rear wheel assist is engaged, and the pump 44 will stroke up to make the rear motors 78,80 rotate the rear wheels 26 at the same speed as the front wheels 24. Because of efficiency losses and calibration errors associated with the hydrostatic system, transmission output speed signal 312 and/or rear wheel speed determination by the controller, the pump command 322 may not initially match the front and rear wheel speeds. The closed loop speed control will then produce an error and command the pump 44 to increase displacement even higher until the front and rear wheel speeds are approximately equal (speed error equals zero).
As shown in
Therefore, to improve operations, the control system 300 may be configured to modify operation of the rear wheel assist 86 based on the degree of articulation of the machine 10 and/or based on machine travel speed. For example, an articulation-based control 420 (
In one embodiment, controller 302 is configured to receive an articulation signal 362 from an articulation sensor 364, for example, from linear hall effect sensors associated with steering actuators 32. The positional information provided by the linear sensors is employed to provide an indication of articulation angle α,−α. When separate sensors are employed for both the left and right cylinders 32, the signals can be used individually or in concert to provide further accuracy.
Controller 302 is also configured to receive an indication of both front and rear wheel speeds. For example, the controller may determine an average rear wheel speed from left and right motor speed signals 304,306. The front wheel speed may be determined as an average of the front wheel speeds provided by left and right front wheel speed sensors 372. Alternatively, controller 302 may be configured to receive a transmission output speed signal 312 that is employed by the controller 302 to calculate an approximation of the average front wheel speeds 26. Further, speed sensors associated with the front axle shafts, final drives, or other drive train components may also provide a signal indicative of actual front wheel speeds. In addition, the power source speed, provided by a power source sensor 342 via signal 310 could also be employed in combination with the transmission output speed signal 312.
Based on the indication of articulation angle 362 and front and rear wheel speeds, the controller 302 may modulate the output to rear wheels 26 to improve machine control. That is, controller 302 may be configured to provide pump control signals 322,324, a diverter valve control signal 326, clutch control signal 328, brake control signal 330, and/or motor speed control signal to modulate rear wheel speed by a factor provided, for example, by way of an algorithm, look-up table, or map. For example, shown in Table 1 is a range of articulation angles α,−α with corresponding changes in rear wheel speed, expressed as the average rear wheel speed as a percentage of average front wheel speed. This is further exemplified in
As illustrated in
As the travel speed of the machine 10 increases, the negative effects in terms of decreased machine control and potential damage may be amplified. Accordingly, in yet another embodiment, the machine travel speed, as determined, for example, by front wheel speed sensor 372 and/or output shaft speed sensor 344, may also be employed by the controller 302, in combination with articulation angle, to modify rear wheel speed. For example, below a desired travel speed, for example, 5 mph, the controller may not modulate rear wheel speed, regardless of articulation angle. As machine speed increases, for example, from 5 to 9 mph, the controller 302 may increase the average rear wheel speed percentage above the corresponding reductions illustrated in Table I. For example, at a maximum operating speed of the rear wheel assist (e.g., 9 mph), all of the percentages may be increased by a fixed amount or by some additional percentage. For example, at approximately α, −α equals 90 degrees, instead of modifying rear wheel speed to approximately 19% of average front wheel speed, at 9 mph, the rear wheel speed is decreased to approximately 25% of average front wheel speed. A “machine speed signal indicative of machine travel speed” may be provided by the same front and rear speed sensors discussed above. For example, front wheel speed sensors 372, transmission sensor 246, and rear wheel speed sensors 336, 338 could all be employed, alone or in combination, to provide an indication of machine travel speed. Other methods of providing an indication of machine travel speed, such as, for example, via radar, lasers, or GPS, should be known to those of skill in the art.
In yet another embodiment, in place of or in addition to the above rear wheel speed modifications, the system 300 may include an initial check 409, wherein prior to engaging 410 the rear wheel assist 86, the controller 302 determines whether the articulation angle α,−α is greater than a desired threshold, for example, wherein a is above 60 degrees, or −α is beyond −60 degrees, and, if the condition is met, prevents engagement 410 of the rear wheel assist.
In connection with the articulation angle control 420, the determinations are made based on an “indication of” articulation angle. The term “indication of” or “indicates” refers to the fact that the system may make determinations by calculating an articulation angle α,−α, based on, for example, signals provided by the various articulation sensors discussed herein, or by employing such signals without actually converting the data into a numeric value of degree. For example, the system could employ as the articulation sensor a laser sensor that determines a distance between the front frame section 12 and rear frame section 12. In this case, the distance provides an “indication” of the articulation angle, but does not actually employ a calculation thereof. In another example, a linear sensor may provide a signal indicative of actuator position that is mapped against a reduction in rear wheel speed. Again, this provides an “indication of” articulation angle α,−α, but does not provide calculation thereof. Numerous other methods for providing an indication of articulation angle that can be employed to modulate output to the rear wheels 26 should be apparent to those of skill in the art in view of this disclosure.
Finally, at step 422, once the operator determines that the rear wheel drive assist is no longer necessary, the operator may turn off the rear wheel assist 86 via control switch 340, de-energizing the solenoid control valve 210, which is spring biased to direct flow from control line 216 along pilot drain line 214 to tank. This shifts diverter valve 218 back to first position 220, re-directing flow from pump assembly 102 to the elevator motor assembly 108.
It should be understood that the above description is intended for illustrative purposes only. In particular, it should be appreciated that all methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context.
While aspects of the present disclosure have been particularly shown and described with reference to the embodiments above, it will be understood by those skilled in the art that various additional embodiments may be contemplated by modification of the disclosed machines, systems and methods without departing from the spirit and scope of what is disclosed. Such embodiments should be understood to fall within the scope of the present invention as determined based upon the claims below and any equivalents thereof.
This application is a continuation-in-part of U.S. application Ser. No. 12/179,186, filed on Jul. 24, 2008, and U.S. application Ser. No. 12/179,267, filed on Jul. 24, 2008, the disclosures of which are incorporated herein by reference.
| Number | Name | Date | Kind |
|---|---|---|---|
| 3584698 | Larson et al. | Jun 1971 | A |
| 3981374 | Johns, Jr. | Sep 1976 | A |
| 5682958 | Kalhorn et al. | Nov 1997 | A |
| 5884204 | Orbach et al. | Mar 1999 | A |
| 6267163 | Holmes | Jul 2001 | B1 |
| 20060266565 | Fontecchio et al. | Nov 2006 | A1 |
| 20080116000 | Huang et al. | May 2008 | A1 |
| Entry |
|---|
| Displacement Change, Poclain Hydraulics, Poclain Hydraulics Training Center, available at http://www.poclain-hydraulics.com/portals/0/self%20training/Changement%20de%20cylindree—GB.pdf. |
| Number | Date | Country | |
|---|---|---|---|
| 20100023227 A1 | Jan 2010 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 12179186 | Jul 2008 | US |
| Child | 12414803 | US | |
| Parent | 12179267 | Jul 2008 | US |
| Child | 12179186 | US |
