This invention relates generally to the use of pilot hydraulics for controlling a pair of stabilizer legs for a backhoe loader machine and more particularly to the ability to simultaneously retract the pair of stabilizer legs from an extended position to a fully retracted position.
It is well known that a machine, such as a backhoe loader, is used to dig ditches, foundations, basements, and the like. During such machining operations, the backhoe loader machine utilizes a pair of stabilizer legs to maintain a steady and solid working foundation. The foundation is established when the pair of stabilizer legs are extended either individually or together by separate and continuous activation of a pair of control switches. Each one of the pair of control switches is coupled with a respective one of the pair of stabilizer legs and the amount of stabilizer leg extension depends on the surrounding terrain. Generally, upon completion of machining operations, the pair of stabilizer legs are retracted through the separate and continuous activation of the pair of control switches. The ability to retract both of the stabilizer legs simultaneously without continuous operation of the pair of control switches, however, would be beneficial for an operator due to an ease in operation.
A design disclosed in U.S. Pat. No. 4,124,226 issued to Frank T. Phillips on Nov. 7, 1978 utilizes four hydraulically operated outrigger assemblies on a mobile crane. A control system is provided for operating the eight cylinders to extend, retract, and lower and raise the outriggers through actuation of horizontal and vertical stabilizer cylinders, respectively. Simultaneous extension or retraction of the outrigger assemblies is achieved by the continuous operation of various switches in combination. Unfortunately, the ability to simultaneously retract the outrigger assemblies through a single switch that does not require continuous operation is not disclosed. The ability to simultaneously retract the outrigger assemblies in such a manner would improve operator flexibility by lessening the time and energy normally spent on retracting the outrigger assemblies.
The present invention is directed to overcoming the problems as set forth above.
In one aspect of the present invention, a method is disclosed for automatically retracting a stabilizer leg for a work machine. The work machine is operatively associated with a power source and has a control device for selecting forward or reverse directions of movement. The method includes utilizing a control lever for moving the stabilizer leg between fully extended and fully retracted positions. The control lever is normally located in and biased to a neutral position. Next, manually moving the control lever to either of an extend position or a retract position. Then, manually holding the control lever in either of the extend or retract positions to respectively extend or retract the stabilizer leg to any of a plurality of desired positions between the fully extended and fully retracted positions. Next, manually moving the control lever to an auto-retract position. Finally, retaining the control lever in the auto-retract position without further manual manipulation thereof through a responsive means that overcomes the biasing action of the control lever to facilitate the automatic retraction of the stabilizer leg from any of the plurality of desired positions to the fully retracted position.
In another aspect of the present invention, a work machine has front and rear end portions. A control panel is disposed within an interior of the work machine. A pair of stabilizer legs are connected to the rear end portion. A hydraulic cylinder is operatively associated with each of the pair of stabilizer legs for moving the stabilizer legs in a plurality of desired positions between fully extended and fully retracted positions via a source of hydraulic fluid. A control device is located within the interior of the work machine for selecting the forward or reverse direction of the work machine. The present invention comprises a main valve that is connectable with each of the hydraulic cylinders for controlling the movement of the stabilizer legs. A pair of pilot valves are in connection with each of the main valves. A pair of control levers are in connection with a respective pair of pilot valves for actuation thereof. The control levers are normally biased to a neutral position and movable between a first position for actuating the main valves in response to the actuation of one of the pilot valves to extend the stabilizer legs to any of the desired positions, a second position for actuating the main valves in response to the actuation of the other of the one of the pilot valves to retract the stabilizer legs to any of the desired positions, and a third position. Means are provided for automatically retaining the pair of control levers in the third position for actuating the main valves in response to the actuation of the other one of the pilot valves to simultaneously retract the stabilizer legs from any of the desired positions to the fully retracted position within a preselected period of time.
In yet another aspect of the present invention, a method is disclosed for automatically retracting a stabilizer leg for a work machine. The work machine is operatively associated with a power source and has a control device for selecting forward or reverse directions of movement for the work machine. The method comprises the steps of utilizing a pair of control levers for moving a pair of stabilizer legs between fully extended and fully retracted positions. The control levers are normally located in a neutral position and movable to first, second, and third positions. The movement of either of the control levers to the first position promotes the movement of a respective stabilizer leg to a plurality of extended positions and the movement of either of the control levers to the second position promotes the movement of the respective stabilizer leg to a plurality of retracted positions. The control levers are biased to the neutral position when in the first, second, or third positions. Next, the method includes moving either of the control levers to the third position. Finally, automatically maintaining either of the control levers in the third position to overcome the biasing action on the control levers for moving the respective stabilizer leg from any of the plurality of extended or retracted positions to the fully retracted position.
The present invention includes the ability to simultaneously retract a pair of stabilizer legs for a work machine through a control lever that is automatically retained in a auto-retract position for a preselected time. The simultaneous and automatic retraction of the pair of stabilizer legs increases ease of operation and operator flexibility.
While the invention is susceptible to various modifications and alternative forms, a specific embodiment thereof has been shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that there is no intent to limit the invention to the particular form disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.
Referring to
Referring now to
The pair of stabilizer legs 24,28 are secured on the rear end portion 40 of the frame 32 in a conventional manner. The stabilizer legs 24,28 are movable between a fully extended position 130 (shown in
Referring directly to an electro-hydraulic circuit 180 in
The electro-hydraulic circuit 180 includes a main control valve system 250 with a reservoir 274 for holding a quantity of hydraulic fluid. The reservoir 274 is connected to a pump 280 via line 286. The pump 280 may be of any suitable type capable of pressurizing the hydraulic fluid. The pump 280 is connected to a pair of spool valves 290,294 via line 300. The spool valves 290,294 may be of any suitable type but capable of actuation from a normally closed position (shown in
A pilot control valve system 340 is connected with the main control valve system 250 and includes a pair of pilot valves 344,348 connected with each control lever 208,212 and each spool valve 290,294, respectively. A pump 352 of any suitable type capable of pressurizing the hydraulic fluid is connected with each of the pilot valves 344,348. An additional reservoir 356 for holding a quantity of hydraulic fluid is also connected with the pilot valves 344,348. One of the pair of pilot valves 348 includes a solenoid detent 360 therein of a magnetic type.
An electrical control system 364 is connected between the main control valve system 250 and the pilot valve system 340. The electrical control system includes a control switch 374 connected with one of the pair of pilot valves 348. The control switches 374 are activated by the control levers 208,212 when the control levers 208,212 are moved to the second or third positions 228,232 via the electrical power source 48 in a well-known manner. A timer relay 390 is connected with each of the solenoid detents 360 and the control switches 374. An alarm device 404 is connected with the control switches 374 and the control device 200 and located therebetween.
Prior to operation of the backhoe loader 10 for digging, trenching, and the like, the operator (not shown) will generally stabilize the backhoe loader 10 by extending the stabilizer legs 24,28 into contact with the surrounding terrain. To accomplish the extension, the operator (not shown) will manually move the control levers 208,212 from the neutral position 220 to the first (or extend) position 224. The movement of the control levers 208,212, actuates the pilot valves 344 which, in turn, actuate the respective spool valves 290,294 in a well-known manner. The actuation of the spool valves 290,294 directs high pressure hydraulic fluid into the upper portion 320 of the hydraulic cylinders 140,144 to move the stabilizer legs 24,28 accordingly. It should be understood that the control levers 208,212 may be operated individually to set the stabilizer legs 24,28 at any location between the retracted and extended positions 134,130.
For retraction of the stabilizer legs 24,28, the operator (not shown) will manually move the control levers 208,212 from the neutral position 220 to the second (or retract) position 228 opposite of the first position 224. The movement of the control levers 208,212, actuates the pilot valves 348 which, in turn, actuate the respective spool valves 290,294 in a well-known manner. The actuation of the spool valves 290,294 directs high pressure hydraulic fluid into the lower portion 324 of the hydraulic cylinders 140,144 to move the stabilizer legs 24,28 accordingly. Again, it should be understood that the control levers 208,212 may be operated individually to set the stabilizer legs 24,28 at any location between the extended and retracted positions 130,134. Additionally, the movement of the control levers 208,212 to the second position 228 activates the control switches 374. The control switches 374, in turn, activate the timer relay 390 which activates the solenoid detents 360. The movement of the control device 200 to operate the backhoe loader 10 in either the forward or reverse direction will cause the alarm device 404 to sound when the control levers 208,212 are in the retract position 228. This occurs when the alarm device 404 is activated by a signal from both the activated control device 200 and the activated timer relay 390. However, when the control levers 208,212 are in the retract position 228, the solenoid detents 360 are sufficiently distanced from the control levers 208,212 to prevent the magnetic forces of the solenoid detents 360 from acting on (holding) the control levers 208,212, even though the solenoid detents 360 are activated. Therefore, it should be understood that the control levers 208,212 are designed to return to the neutral position 220 after being moved to either the extend or retract positions 224,228 in response to a spring (not shown) of well-known design disposed within the control levers 208,212.
The automatic retraction of the stabilizer legs 24,28 is accomplished by manually moving either of the control levers 208,212 to the third (or auto-retract) position 232. Similar to the retract position 228, the movement of the control levers 208,212 to the auto-retract position 232 activates the control switches 374. The control switches 374, in turn, activate the timer relay 390 which activates the solenoid detents 360. However, when the control levers 208,212 are located in the auto-retract position 232, the distance of the control levers 208,212 from the solenoid detents 360 is sufficiently close to allow the solenoid detents 232 to magnetically hold the control levers 208,212 in the auto-retract position 232. The magnetic hold of the solenoid detents 360 is controlled by the timer relay 390 for a preselected time, preferably greater than the total time necessary to fully retract the respective stabilizer leg 24,28 from the fully extended position 130. Therefore, the stabilizer legs 24,28 may be moved completely to the fully retracted position 134 from any one of the plurality of extended positions 130 within the preselected time. Of course, it should be understood that simultaneous retraction is accomplished when both of the control levers 208,212 are moved to the auto-retract position 232. However, if the control levers 208,212 are moved by the operator (not shown) during the preselected time, the automatic or simultaneous retraction of the stabilizer legs 24,28 is interrupted. This occurs due to the deactivation of the control switch 374 which allows for the release of the magnetic hold of the solenoid detents 360 on the control levers 208,212. Further, if the operator (not shown) moves the control device 200 into gear during the preselected time, thus selecting the forward or reverse direction of movement for the backhoe loader 10, the alarm device 404 will sound, as similar to when the control levers 208,212 are in the retract position 228. Also, it should be understood that the alarm device 404 will sound if the backhoe loader 10 is in the forward or reverse direction and the control levers 208,212 are moved to the retract position 228. Further, it should be understood that the control lever 208 may be configured in such a manner so as to facilitate the auto-retraction of both of the stabilizer legs 24,28 without the use of control lever 212. This may be accomplished through the utilization of a joystick controller (not shown) in place of the control lever 208 that is capable of movement in various directions.
Other aspects, objects and advantages of this invention can be obtained from a study of the drawings, disclosure and the appended claims.
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