The present disclosure generally pertains to machines. More particularly this disclosure is directed toward a work tool coupling assembly for a machine.
Excavators, backhoes, and other machines commonly have a movable linkage for controlling motion of an implement, such as a bucket, blade, hammer, grapple, fork arrangement, etc. A coupler may be used to increase the functionality and versatility of a machine by allowing different implements to be interchangeably connected to a stick or arm of the machine.
U.S. Pat. No. 6,241,455 to Schupback et. al. describes an earth-moving machine that includes a coupling releasably joining a bucket to an end of a dipper stick. The coupling includes a hook pivotably coupled to the dipper stick about a first axis and configured to engage a pin secured to the bucket. The coupling further includes a pair of pins coaxially disposed along the axis and movable between an extended position in which the pins are received within a pair of spaced openings on the bucket to join the bucket to the dipper stick and a retracted position in which the pins are removed from the openings. The pins are actuated between the extended position and the retracted position by an actuator disposed along the axis between the pins. The actuator preferably includes a cylinder, first and second pistons disposed within the cylinder and coupled to the first and second pins, respectively, and at least one source of hydraulic pressure fluidly coupled to the cylinder to pressurize the cylinder and to move the first and second pistons and the first and second pins. The cylinder is preferably disposed within a bushing coupled to the dipper stick.
The present disclosure is directed toward improvements in the art.
A work tool coupling assembly for a machine is disclosed herein. The work tool coupling assembly includes an excavator stick and a pin grabber coupler. The excavator stick includes a stick body and a first stick leg extending from the stick body. The first stick leg includes a first leg bore distal to the stick body. The excavator stick further includes a second stick leg extending from the stick body substantially parallel with the first stick leg. The second stick leg is spaced from the first stick leg. The second stick leg includes a second leg bore distal to the stick body. The second stick leg bore is aligned with the first leg bore.
The pin grabber coupler includes a first plate, a second plate, and a middle plate. The first plate includes a first plate front end and a first plate back end located opposite the first plate front end. The first plate further includes a first plate linkage bore and a first plate bottom bucket receiver located adjacent to the first plate front end. The first plate further includes a first plate top bucket receiver located adjacent to the first plate back end. The second plate includes a second plate front end and a second plate back end located opposite the second plate front end. The second plate further includes a second plate linkage bore aligned with the first plate linkage bore. The second plate further includes a second plate bottom bucket receiver located adjacent to the second plate front end. The second plate bottom bucket receiver is aligned with the first plate bottom bucket receiver. The second plate further includes a second plate top bucket receiver located adjacent to the second plate back end. The second plate top bucket receiver is aligned with the first plate top bucket receiver. The middle plate is positioned between and affixed to the first plate and the second plate. The middle plate includes a middle plate front portion protruding beyond the first plate and the second plate and away from the first plate top bucket receiver and the second plate top bucket receiver. the middle plate front portion includes a middle plate front end distal to the first plate back end and the second plate back end. The middle plate front portion further includes a middle plate stick bore extending therethrough. The middle plate stick bore is located proximate to the middle plate front end. The middle plate further includes a middle plate bottom bucket receiver located proximate to the first plate front end and the second plate front end. The middle plate bottom bucket receiver is aligned with the first plate bottom bucket receiver and the second plate bottom bucket receiver.
The details of embodiments of the present disclosure, both as to their structure and operation, may be gleaned in part by study of the accompanying drawings, in which like reference numerals refer to like parts, and in which:
The detailed description set forth below, in connection with the accompanying drawings, is intended as a description of various embodiments and is not intended to represent the only embodiments in which the disclosure may be practiced. The detailed description includes specific details for the purpose of providing a thorough understanding of the embodiments. However, it will be apparent that those skilled in the art will be able to understand the disclosure without these specific details. In some instances, well-known structures and components are shown in simplified form for brevity of description. Furthermore, some of the features and surfaces have been left out or exaggerated for clarity and ease of explanation.
A machine 10 (sometimes referred to as a track vehicle or track machine) may include a pair of track assemblies 14, only one of which is shown in
Each track assembly 14 may be configured to support machine 10 from and move along the ground, roads, and/or other types of terrain. Each track assembly 14 may include a track roller frame 22, various guide components engaged to track roller frame 22, a drive sprocket 26, an idler 28, rollers 30, and an endless track 24 extending around drive sprocket 26, the idler 28, and rollers 30.
The excavator stick 120 can include a concave portion 160 located adjacent to the interface of the stick body 130, the first stick leg 140, and the second stick leg 150.
The second plate 220 can include a second plate back end 222. The second plate 220 can include a second plate linkage bore 223 aligned with the first plate linkage bore 213. The second plate 220 can include a second plate top bucket receiver 225 located adjacent to the second plate back end 222. The second plate top bucket receiver 225 can be aligned with the first plate top bucket receiver 215 collectively the top bucket receiver of the pin grabber coupler. The second plate top bucket receiver 225 can form an L shape.
The middle plate 230 can be positioned between the first plate 210 and the second plate 220 and affixed to the first plate 210 and the second plate 220. The middle plate 230 can include a middle plate front portion 232 which protrudes beyond the first plate 210 and the second plate 220 and away from the first plate top bucket receiver 215 and the second plate top bucket receiver 225. The middle plate front portion 232 can include a middle plate front end 231 distal to the first plate back end 212 and the second plate back end 222. The middle plate front portion 232 can include a middle plate stick bore 233 extending therethrough. The middle plate stick bore 233 can be located proximate to the middle plate front end 231.
The pin grabber coupler 180 can include a linkage pin 310 extending through the first plate linkage bore 213 and the second plate linkage bore 223.
The pin grabber coupler 180 can include an external portion 240 of a locking assembly. The external portion 240 of the locking assembly can be affixed along a top edge of the middle plate 230 and approximately positioned between the middle plate stick bore 233, the first plate linkage bore 213 and the second plate linkage bore 223.
The middle plate 230 can include a locking assembly cylinder or bore 236, for example, machined into the middle plate 230. The locking assembly bore 236 can extend from between the first plate 210 (shown in
The external portion 240 of the locking assembly can include hydraulic tubes 241 and hydraulic valves 242. The locking assembly includes the external portion 240, a cylinder rod 243, a cylinder head 251 and a locking wedge 245. In an embodiment the hydraulic valves 242 can be positioned along the upper perimeter of the middle plate front portion 232. The hydraulic valves 242 can be in fluid communication with one or more of the hydraulic tubes 241. The cylinder rod 243 can be positioned within the locking assembly bore 236 and can include a piston 247. The locking assembly bore 236 can be in fluid communication with the hydraulic valves 242 which are arranged to selectively deliver hydraulic force to either side of the piston 247. A cylinder head 251 is located at the open end of the locking assembly bore 236. In an embodiment, the cylinder head 251 is threaded into the locking assembly bore 236 and includes one or more seals about the cylinder rod 243.
The locking wedge 245 can be positioned between the first plate 210 and the second plate 220. The locking wedge 245 can extend from proximate the cylinder rod 243 towards the first plate top bucket receiver 215 and the second plate top bucket receiver 225. The locking wedge 245 can be operable to extend into the first plate top bucket receiver 215 (shown on
A portion of the locking assembly 240 can be positioned between the first plate 210 (shown on
A portion of the locking assembly 240 can be positioned adjacent to the concave portion 160. The concave portion 160 can extend diagonally with respect to the first stick leg 140 and second stick leg 150 to accommodate the external portion 240 of the locking assembly.
The linkage pin 310 can extend through a linkage assembly 350 and through the second plate linkage bore 223 (shown on
The bucket 20 can include a bottom bucket pin 330. The bottom bucket pin 330 can extend through the second plate bottom bucket receiver 224 (shown on
The bucket 20 can include a top bucket pin 340. The top bucket pin 340 can extend through the second plate top bucket receiver 225, and the first plate top bucket receiver 215 (shown on
The second plate 220 can include a hydraulic channel 226. The hydraulic channel 226 can be in fluid communication with the hydraulic tubes 241 and the hydraulic valves 242. The second plate 220 can include a locking aperture 227 in fluid communication with the hydraulic channel 226. In an embodiment, the hydraulic channel 226 can extend from the hydraulic tubes 241 to a locking aperture 227. The locking aperture 227 can be adjacent to and extending into the second locking wedge slot 228.
The pin grabber coupler 180 can include a locking member 260. The locking member 260 can be positioned within the locking aperture 227 and can extend into the second locking wedge slot 228. The locking member 260 can have locking member teeth 261. In an embodiment the locking member teeth 261 are located on a face opposite to the face on which the locking wedge teeth 246 are located. The locking wedge teeth 246 and the locking member teeth 261 can be shaped to mate with each other. A locking member biasing member such as spring 263 provides a force to cause the locking member 260 to engage with the locking wedge in the absence of hydraulic pressure to overcome the force of the biasing member such as biasing spring 263.
The present disclosure generally applies to a work tool coupling assembly 100 for a machine 10. It is understood that the work tool coupling assembly 100 may be used with any stationary or mobile machine known in the art. Such machines may be used in construction, farming, mining, power generation, and/or other like applications. Accordingly, such machines may include, for example, excavators, track-type tractors, wheel loaders, on-road vehicles, off-road vehicles, generator sets, motor graders, or other like machines.
In use, the excavator stick 120 and pin grabber coupler 180 may allow different implements to be interchangeably connected to a machine 10. The pin grabber coupler 180 can have reduced coupler offset and provide a reduced tip radius, which can provide a reduction in the force required to rotate working implements such as the bucket 20. In an embodiment, the configuration of the pin grabber coupler 180 can reduce tip radius by approximately 6% and a reduction in force required by approximately 16%.
During operation of the machine 10, the linkage assembly 350 can be actuated to pivotally rotate the pin grabber coupler 180 about the stick pin 320. The excavator stick 120 can include a stick gap 135 and a concave portion 160 that are sized to provide clearance for the middle plate 230 and a portion of the external portion 240 of the locking assembly.
The working implement 20 can be picked up and coupled to the pin grabber coupler 180 by utilizing the locking assembly. Hydraulic fluid can be transported via the hydraulic tubes 241 to the hydraulic valves 242. From the hydraulic valves 242, the hydraulic fluid can be transported into the locking bore 236, behind the piston 247, away from pin 244, to actuate the cylinder rod 243 to extend further out of the locking bore 236. As the cylinder rod 243 is actuated, the locking wedge 245 is actuated forward. If the top bucket pin 340 is positioned within the first plate top bucket receiver 215 and the second plate top bucket receiver 225, then the forward movement of the locking wedge 245 locks in the working implement 20 to the pin grabber coupler 180. In other words, the forward position of the locking wedge 245 prevents unintended disengagement of the working implement 20 from the pin grabber coupler 180. The locking wedge 245 can be moved to its original position by applying the hydraulic pressure/hydraulic fluid on the opposite side (in front) of the piston 247 to drive it back into the locking bore 236.
In an embodiment, the hydraulic valves 242 include a pilot operated check valve. When the locking wedge 245 is extended, in the event of the loss of hydraulic fluid pressure, the pilot operated check valve closes which locks the hydraulic fluid in the locking assembly bore 236 which keeps the locking wedge 245 in its extended position.
Hydraulic fluid can also be transported from the hydraulic valves 242 to the hydraulic channel 226 and subsequently to the locking aperture 227. The presence of hydraulic fluid/pressure within the locking aperture 227 can move the locking member 260 away from the locking wedge 245, overcoming the force of the biasing spring 263, disengaging the locking member teeth 261 from the locking wedge teeth 246. Without hydraulic pressure, the locking member teeth 261 can engage and mate with the locking wedge teeth 246 because of the force from the biasing spring 263. In an event that hydraulic pressure is lost inadvertently, the locking member 260 can be positioned to prevent the locking wedge 245 from disengaging with the top bucket pin 340.
Although this disclosure has been shown and described with respect to detailed embodiments thereof, it will be understood by those skilled in the art that various changes in form and detail thereof may be made without departing from the spirit and scope of the claimed disclosure. Accordingly, the preceding detailed description is merely exemplary in nature and is not intended to limit the disclosure of the application and uses of the disclosure.
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