The present invention pertains to a lip for an excavating bucket, and particularly to a cast lip for use with excavating machines such a dragline machines, cable shovels, face shovels, hydraulic excavators and the like.
Excavating machines, such as used in mining and construction operations, include buckets that are driven into the ground to gather a load of earthen material. The bucket is generally defined by a rear wall, a bottom wall and sidewalls to define a cavity with an open front for receiving the excavated material. The front edge of the bottom wall is provided with a lip on which ground engaging tools such as teeth, adapters and/or shrouds are generally attached to protect the lip against wear and to better break up the ground during digging. The lips are either formed of plate steel (which are called plate lips) or by a casting process (which are called cast lips). Either style of lip is welded into the bucket, i.e., to the front edge of the bottom wall and to the lower, front corners of each sidewall.
Cast lips are generally used on larger excavating machines such as dragline machines, cable shovels, face shovels, and hydraulic excavators. These lips are large steel structural members able to withstand the impact and other heavy loading experienced as the bucket is driven through the ground, resist undue wearing caused by the high abrasion environment, and securely support and hold the ground engagement tools in place for efficient digging. Accordingly, cast lips tend to be very heavy, which reduces the load each bucket can gather in each digging cycle. That is, excavating machines are designed for certain maximum loads, which include the weight of the excavated material as well as the weight of the bucket.
Existing lips typically have a structure that resists the many loads encountered in a digging operation and tends to carry the cantilevered tooth loads in torsion. The lips, however, tend to be massive and heavy to survive the very large loads and high abrasion environments commonly encountered in a digging operation and particularly in many mines. Mining and other excavating machines are constructed to lift loads up to a certain specified level. The more weight that exists in the lip, wear parts and other components of the bucket, the smaller the maximum payload that can be achieved by the bucket. The great size and weight also tends to increase manufacturing difficulties and cost of cast lips.
The present invention is a lip design of reduced weight that provides the requisite strength and durability needed for satisfactory operation.
In one aspect of the invention, a lip for an excavating bucket comprises front and rear beams extending across the lip to provide resistance to heavy loading during use, and recesses between the beams to reduce the weight of the lip.
In another aspect of the invention, a lip for an excavating bucket comprises a pair of spaced beams extending along the length of the lip, ribs interconnecting the spaced beams, and recesses between the beams and the ribs.
In another aspect of the invention, a lip for an excavating bucket has one or more recesses that comprise a substantial portion of the entire lip volume for an advantageous weight-savings construction. In the present invention, the total collective volume of the recesses is at least about 15%, and preferably at least about 18% or more, of the total volume of the lip including the volume of the recesses.
In another aspect of the invention, an excavator bucket comprises a plurality of walls defining a cavity into which is gathered earthen material, and a lip secured to the front of the bucket to define the leading digging edge. The lip includes a front beam spanning the lip with noses extending forward of the front beam for mounting ground engaging tools and a rear beam spanning the lip and abutting a front portion of the excavator bucket.
The present invention pertains to a lip for excavating buckets such as used with dragline machines, cable shovels, face shovels, hydraulic excavators and the like. The lip includes a dual beam construction and recessed portions to reduce the lip weight while maintaining the needed strength and resistance to bending and twisting.
A lip 10 in
Lip 10 includes a rear side 16 with rear face 44, a front side 20, and opposite ends 22, 24. Front side 20 defines a mounting portion 25. Mounting portion 25 forward of beam 32 comprises a series of spaced apart noses 26. Noses 26 receive ground engaging tools such as intermediate adapters or points (not shown) that separate material and direct the material into the bucket while protecting the lip. Noses on the mounting portion are separated by mounting areas 30 for attaching additional ground engaging tools such as shrouds (not shown). Lip 10 is preferably a cast lip, though it could be formed of parts (preferably cast parts) welded 58 together (
In the illustrated embodiment, lip 10 is a stepped lip such that the front side 20 is stepped forward toward the center so that the noses 26 closer to the center of the lip are farther forward than those closer to ends 22, 24 with portions between the noses extending generally along the length of the lip. A lip in accordance with the present invention, though, could have a spade configuration with intermediate portions between the noses inclined to the length of the lip, or reversed step or reverse spade configurations. Further, although lip 10 is shown as linear in front view, it could be bowed or angled vertically across its length, and/or include ends that curve upward.
A support structure 28 of the lip is rearward of and supports mounting portion 25. Support structure 28 is formed to resist all kinds of loads and turning and bending forces encountered during a digging operation. In the present invention, members forming the support structure include a front beam 32 and a rear beam 34 extending along the length of the lip with at least one recess between the two beams. Conventional lips are formed with a single beam structure to resist the very high loads in a digging operation, particularly the large mining machines. While the single beam structure provides adequate strength and support, the lips tend to be massive and heavy. Some existing lips have recesses, but the weight savings is limited due to the mass that has been required to adequately counter the high loads.
Ribs 35 preferably extend between beams 32, 34 to better couple the beams and transfer loads from the noses 26 to the bucket. The ribs subdivide the space between the beams to define a set of recesses 36 between beams 32, 34. Beams 32, 34 and ribs 35 are of a substantial depth or thickness relative to the lip along recesses 36. Recesses are defined by rear surface 40 of front beam 32 and front surface 42 of rear beam 34, and the side surfaces of ribs 35.
Beams 32 and 34 are free of substantial or sudden changes in dimension, and are generally continuous between ends 22 and 24; though they may terminate prior to the actual ends. Superficial changes in the beam structure are possible so long as the primary bulk of each beam as a generally continuous and uninterrupted extension along the length of the lip. The beam can incorporate curves in extending across the lip. Curves in the beam preferably coincide with the intersection of a rib to compensate for stress concentrations induced by the curve. This generally continuous and uninterrupted construction gives the lip a dual beam construction to resist heaving loads and twisting despite the presence of recesses 36. Various changes in beam configuration are possible without departing from the invention. For example, the depth of beam 32 may taper out before the ends. Alternatively, the beams may taper from the ends 22, 24 towards the center of the lip. In the illustrated embodiment ends 22, 24 have wings 45 for welding to sidewalls 12 of the bucket at upper surface 47 and rear surface 49. Wings 45, in this embodiment, extend above the main portion of the lip.
Preferably, lip 10 is generally smooth and continuous along its upper surface 46 for unobstructed loading of the earthen material into the bucket. The lower surface 50 of the lip is structured for weight savings with the beams 32, 34, recesses 36, and ribs 35. Nevertheless, upper surface 46 and lower surface 50 could have other configurations. For example, recesses 36 are preferably open, but they could be enclosed by a plate welded over the bottom, e.g., between beams 32, 34.
The top surface 46 of lip 10 can be considered as a panel support structure 28A that couples front beam 32 to rear beam 34. Ribs 35 also preferably join the beams and resist axial and twisting forces as the bucket moves forward through the excavated material. Additionally, one or more panels 56 can be secured to and connect ribs 35 and beams 32, 34 along the underside of the lip to enclose recesses 36 (
In a preferred embodiment, front beam 32 is oriented forward in the lip 10, i.e., just rearward of mounting portion 25 to provide greater strength and stability to the wear parts. Front surface 38 of front beam 32 slopes upward from supporting structure 25 to define a smooth transition between beam 32 and ground engaging tool mounts. The beam 32 generally has a greater depth than mounting portion 25. Rear surface 40 of front beam 32 transitions to recessed portion 36. The bottom surface 54 of beam 32 also preferably slopes rearward to reduce wearing during digging, but could have different orientations.
Since the illustrated embodiment is a stepped lip, front beam 32 is preferably laterally bowed such that the central section 52 is farther forward than end sections 22, 24 (
Rear beam 34 preferably has a reduced depth compared to front beam 32 for enhanced weight savings, improved penetration, reduced wearing, and to match the front of the bucket bottom wall. Rear beam 34 has a front surface 42 that slopes upward to recessed portion 36. Rear surface 44 is generally vertical to match the front of the bucket bottom wall to which it is welded along with the rear face 49 of wings 45 but can include features such as bevels to receive weld material for attaching the lip to the bucket. Rear beam 34 is preferably linear to accommodate the welding to bottom wall, but could be non-linear to facilitate attachments to other bottom wall configurations.
Ribs 35 extend laterally (i.e., front to back) between front beam 32 and rear beam 34 for increased strength and stiffness of the lip. Ribs 35 are relatively thin supports that intersect rear surface 40 of front beam 32 and front surface 42 of rear beam 34. Preferably, ribs 35 taper in depth rearward to gradually slope from the greater depth of front beam 32 to the lesser depth of rear beam 34. This taper of the ribs reduces weight, improves penetration and lessens wearing. As seen in
The configuration of support structure 28 also allows ribs 35 to be narrower than the width of the nose 26 of mounting portion 25. Conventional lips have substantial ribs with widths exceeding that of the noses they support. Using a narrow rib that can provide adequate support and coupling of the front and rear beams in a way that significantly reduces the mass of the lip. Nevertheless, the ribs could have other orientations (e.g., parallel to the axes of the noses, inclined in opposite directions, and the like) and could have other configurations besides generally linear. Also, in this embodiment, wings 45 also extend between beams 32, 34 at ends 22, 24 and function in part similarly to ribs 35. The wings and ribs are collectively referred to as lateral supports.
Recessed portions 36 between beams 32 and 34 are thinner than adjacent support members and comprise a large portion of the lip. In the illustrated example, the recesses define the entire portion between beams 32, 34 except for ribs 35 and wings 45. As can be seen, the lip has a substantially reduced thickness (or depth) than either of the beams 32, 34. In this example, the centers of the recesses have depths that are less than 25% of the depth at the center of the front beam 32. Similarly, the thickness (or depth) at the center of the recesses is about 50% of the thickness at the center of the rear beam 34. Of course, other relative thicknesses could be used. Recesses 36 can be domed so that they taper in thickness from the edges to the center.
The recesses of support structure 28 make up a significant portion of the lip in order to achieve the desired weight savings. In certain preferred embodiments of the present invention, the weight-savings can be maximized beyond prior lips. For example, in these certain preferred embodiments, the total collective volume of the recesses in the lip is at least about 15% of the total volume of the lip including the volume of the recesses. In one preferred embodiment, the volume of the recesses is about 22% of the total volume of the lip. For example, the total volume of the lip is about 0.731 cubic meters, and the total collective volume of the recesses is about 0.163 cubic meters. The inventive lip can, of course, be used in lips of many different sizes and types. As a comparison, in one prior lip of comparable size, the volume of the recesses is about 12% of the total volume of the lip (including the volume of the recesses). For example, the prior lip volume of 0.80 cubic meters, and the volume of the recesses is about 0.099 cubic meters. In other prior lips, the volume of the recesses range from 7.3% to 14.1%. The prior lips lack the maximized weight-savings construction of the present invention and requires more mass and less recesses to maintain the desired strength. The invention, though, is not dependent on having a total collective volume of the recesses being at least 15% of the total volume of the lip (including the volume of the recesses). In some uses and sizes, a lip in accordance with the present invention (e.g., a lip with front and rear beams separated by one or more recesses) can have a construction where the total collective volume of the recesses is much less than 15% of the total volume of the lip (including the volume of the recesses).
This advantageous construction of using a pair of spaced apart beams 32, 34 on opposite sides of a recessed portion 36 defined largely by a substantially reduced thickness saves considerable weight in the lip. In one example, the weight savings for a lip of 15,000 pounds is about 1200 pounds. In general, weight savings are anticipated to be around 2-12%, but could be more over a conventional lip. Greater or lesser weight savings will be possible depending on the size of the lip and the type of machine.
Number | Date | Country | |
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61654501 | Jun 2012 | US |
Number | Date | Country | |
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Parent | 13906085 | May 2013 | US |
Child | 15834557 | US |