This patent disclosure relates generally to a bucket for a loading machine to scoop, haul, and dump material and, more particularly, to a bucket designed for a loading machine operating underground.
Wheel loaders and track loaders are machines used to dig, move, and dump material at different locations about a worksite. Such loading machines typically include a bucket attached to the distal end of a lift implement, which may be linkage configured to lift and tilt the bucket. The lift implement can demonstrate a substantial range of movement with respect to the loading machine to dig material from the ground and to lift and dump the material into a truck. A particular class of loading machines, however, are purposefully designed to work in underground mines where space is confined by low clearances and narrow passages. Underground operation is also considered relatively heavy duty because the material of interest is often hard, blasted rock, mining ores, and other hard, dense materials. Underground loading machines are therefore designed to be more compact and to conduct particular maneuvers to increase their effectiveness despite the operative space constraints and harsh conditions.
U.S. Pat. No. 10,246,849 (“the '849 patent”) describes a bucket designed specifically for an underground loading machine to address the imposed space constraints and conditions. The '849 patent describes that the bucket may be tilted from a loading or digging position in which the bucket is oriented to penetrate into a pile of material to a curled or racked position in which the bucket and the associated loading machine can haul the material out of the mine without having to raise the lift implement. The loading machine is thus able to maintain a low profile even when hauling material underground. The '849 patent recognizes that utilizing the bucket in the foregoing manner may impart asymmetrical or uneven forces across the lateral length of the roof or upper surface of the bucket that could cause damage or premature wear. The '849 patent therefore proposes to add a torque tube across the lateral length of the bucket roof to reinforce the bucket roof against such forces. The present disclosure in contrast is directed to strengthening and reinforcing the lower floor of the bucket that is intended for similar underground applications.
The disclosure describes, in one aspect, a bucket for an underground loading machine assembled from a bucket shell assembly including an opened bucket front and a concaved bucket back delineating a bucket depth along a bucket centerline. The bucket shell assembly can also include a center shell, a first outer shell flanking the center shell to a first lateral side, and a second outer shell flanking the center shell to a second lateral side wherein the center shell is forwardly offset with respect to the first and second side shells. The bucket shell assembly can further include a first sidewall joined to the first outer shell and a second sidewall joined to the second outer shell to define a lateral dimension of the bucket. A paddle plate can be joined to a bucket underside and can have a trumpet-shape that tapers from a flared forward edge extending the lateral dimension of the bucket to a plate tail disposed rearward toward the concaved bucket back. First and second backstay can extend rearwardly between plate tail and the concaved bucket back and can be associated with backstay side plates to provide enclosed space between the paddle plate and concaved bucket back.
In another aspect, the disclosure describes a bucket for an underground loading machine that includes a bucket shell assembly having an opened bucket front and a concaved bucket back. The bucket shell assembly further includes a bucket floor and a bucket roof with the concaved bucket back interconnecting the bucket floor and bucket roof. To strengthen the bucket floor, a paddle plate can be joined to a bucket underside of the bucket floor and can be spaced therefrom to provide a separation gap. The bucket shell further includes a center shell, a first outer shell flanking the center shell to a first lateral side, and a second outer shell flanking the center shell to a second lateral side. To prevent collapse of the separation gap, a plurality of spacer wedges that can have inclined first and second surfaces can be disposed between and adjacent to the bucket underside and the paddle plate. The spacer wedges can generally overlap the weld seams between the center shell and the first and second outer shells of bucket shell assembly.
In yet another aspect, the disclosure describes a bucket shell assembly including an opened bucket front, a concaved bucket back, and a bucket floor and bucket roof extending between the opened bucket front and the concaved bucket back. The bucket shell further includes a center shell, a first outer shell flanking the center shell to a first lateral side, and a second outer shell flanking the center shell to a second lateral side. The center shell can be forwardly offset with respect to the first and second side shells. Joined to the bucket underside can be a paddle plate having a trumpet-shape that tapers from a flared front edge to narrower a plate tail disposed rearward toward the concaved bucket back. Extending at a rearward angle between concaved bucket back and the plate tail can be a first backstay and second backstay, each associated with a backstay side plate to provide an enclosed space between the paddle plate and the concaved bucket back. A plurality of spacer wedges can be located between and spacing apart the bucket underside and the paddle plate to support the relative spacing of the bucket underside and the paddle plate.
Now referring to the drawings, wherein whenever possible like reference numbers will refer to like elements, there is illustrated in
Because the loading machine 100 may need to dump the material into the bed of a hauling truck, the lift implement 104 can be raised (indicated in dashed lines) so that the bucket 102 is located above the machine frame 106. However, as indicated by the lines representing the ground 112 and ceiling 113, raising the lift implement 104 when underground or in another constrained location will collide the bucket 102 with the ceiling. Accordingly, the bucket 102 is coupled in a manner to tilt with respect to the lift implement 104 between a loading or digging orientation as shown and a racked orientation (indicated in dashed lines) in which the bucket 102 is able to hold and carry material while maintaining the low profile of the loading machine 100 and without striking the ceiling 113. In the racked orientation, the lift implement 104 remains lowered and the bucket 102 remains proximate the ground 112 but is oriented so that the material-receiving volume of the bucket is directed toward the ceiling 113.
The orientations at which the bucket 102 is located with respect to the rest of the loading machine 100 may be further constrained by underground operation. For example, the loading machine 100 may be equipped with a LIDAR system 114 located above the operator cab 108 that requires a line of sight (indicated in dashed lines) that must clear above the bucket 102 when in the racked orientation. Further, the bucket 102 may be filled with material rising above the bucket that could protrude into the line of sight from the LIDAR system 114. Accordingly, in the racked orientation, its desired to maintain the bucket 102 close to the ground 112. However, when the bucket 102 is tilted into the racked position, the backside of the bucket that rotates downward should still be capable of clearing the ground 112 in front of the traction devices 110 (as indicated in dashed lines). In various embodiments, the loading machine may be an articulated machine in which the frame 106 is joined between front and rear portions at a pivot joint 105 that allows the machine to make sharp turns as may be necessary in underground operations. It will be appreciated that the farther forward the bucket 102 is positioned with respect to the rest of the frame 106, the turn radius becomes larger because the overall length of the machine is increased. To address the foregoing constraints, the bucket 102 is desirably positioned in close proximity adjacent to the front of the loading machine 100 when in the racked orientation and is vertically disposed between the line of sight from the LIDAR system 114 while providing tilting clearance for the bucket 102 above the ground 112.
Referring to
The tilt assembly 122 includes a tilt lever 126 that is pivotally connected at its mid-body to the distal end of the lift arm 120. An upper end of the tilt lever 126 is connected to a tilt actuator 128 such as a hydraulic cylinder that is also connected to the loading machine 100. The lower end of the tilt lever 126 is pivotally connected to an upper coupling connector 130 on the concaved bucket back 118 of the bucket 102 through a connector link 132. The upper coupling connector 130, which may be a pin joint that forms a single axis journal or a revolute joint, defines an upper pivot axis 134 that extends laterally across the length of the bucket 102. The concaved bucket back 118 of the bucket 102 is also directly connected to the lift arm 120 at a lower coupling connector 136, which may also be a pin joint forming a single axis journal or revolute joint that defines a lower pin axis 138 that also extends laterally across the length of the bucket 102. Whereas actuating the lift actuator 124 raises and lowers the lift implement 104, actuating the tilt actuator 128 articulates the tilt lever 126 to tilt or revolve the bucket 102 about the lower pin axis 138. Thus, the bucket 102 can tilt or move between the racked or hauling position shown in
Referring to
In the illustrated embodiment, the bucket 102 can be assembled as a bucket shell assembly made from three subcomponents including a center shell 160, a first outer shell 162 flanking the center shell 160 to a first lateral side 166, and a second outer shell 164 flanking the center shell 160 to an opposite second lateral side 168. The center shell 160, first outer shell 162, and second outer shell 164 can be manufactured separately from cast or finished steel or other metal and can be joined in the lateral arrangement by, for example, welding. To join the first and second sidewalls 144, 146 to the first outer shell 162 and the second outer shell 164 respectively, the first and second sidewalls can also be made of steel or metal that can be joined by welding. Like the bucket 102, each of the center shell 160, first outer shell 162, and second outer shell 164 can have a planar shell floor 170, a planar shell roof 172, and a concaved shell back 174 curving between and interconnecting the planar shell floor and the planar shell roof. The shell floor 170 of the center shell 160 and the shell floor 170 of the flanking first and second outer shells 162, 164 can align in a common plane to form the planar bucket floor 150. Likewise, the shell roof 172 of the center shell 160 and the shell roof 172 the flanking first and second outer shells 162, 164 can align in a common plane to form the planar bucket roof 152. However, in an embodiment, the concave shell back 174 of the center shell 160 can be offset forwardly along the bucket centerline 154 toward the opened bucket front 116 with respect to the concaved shell backs 174 of the flanking first and second outer shells 162, 164. Accordingly, the center shell 160 appears to protrude into the trough-like volume defined by the bucket 102.
Referring to
To support and reinforce the coupling connections made between the upper and lower forks 178, 179 of the bucket 102 and the lift implement, a plurality of hinge plates can be assembled to the concaved bucket back 118 and disposed within the indentation 176. The hinge plates may include first and second outer hinge plates 180 that may be located at the joint or seam between the center shell 160 and the first outer shell 162 and between the center shell 160 and the second outer shell 164 respectively. Two inner hinge plates 182 can also be included that are located laterally between the first and second outer hinge plates 180 and joined directly to the concaved shell back of the center shell 160. Accordingly, a total of four outer and inner hinge plates 180, 182 are arranged vertically in the indentation 170 and can extend between the bucket floor 150 and the bucket roof 152 so as to be perpendicular to the lateral dimension 148 of the bucket 102, although in other embodiments, different numbers and arrangements of hinge plates may be used. The outer and inner hinge plates 180, 182 can be generally C-shaped to conform to the profile of the concaved bucket back 118 and can be made of metal to facilitate welding of the components into the indentation 170. The laterally spaced-apart arrangement of the four outer and inner hinge plates 180, 182 separates the indentation 176 in the concaved bucket back 118 into three parallel, laterally arranged connector slots 188. The upper fork 178 can be located in the middle connector slot 188 and the first and second lower forks 179 can be located in the two outer connector slots 188. The elongated connector slots 188 provide space to accommodate the distal ends of the connector link and lift arms from the lift implement and can align those components with the upper fork 176 and lower forks 179.
In use, the bucket underside 198, which may be the exterior surface of the bucket floor 150, contacts the ground and is forcibly moved there along to dig or penetrate into material, subjecting the bucket underside 198 to significant abrasive wear and imparted loads and stresses. Additionally, as the forwardly located cutting edge 142 is forcibly moved into the material, reactive loads and forces must be transferred rearward to the concaved bucket back 118 through the bucket floor 150. In the embodiment in which the center shell 160 is offset forwardly of the flanking first and second outer shells 162, 164, the offset geometry at those intersections may concentrate stresses and forces that can crack or cause failure of the joints or seams. Accordingly, to resist wear and strengthen the bucket floor 150 against such loads and forces, a wear plate may be joined to the bucket underside 198 to which a plurality of wear pads can be attached. The wear pads resist abrasive wear from the ground and the wear plate may strengthen the bucket underside 198 against forces imparted to the cutting edge 142. The wear plate, however, may add weight to the bucket 102 that must be offset by limiting the quantity of material that can be accommodated per load.
Referring to
In an embodiment, the plate tail 204 can have a lateral extension 212 sufficient to overlap the center shell 160 and portions of the flanking first and second outer shells 162, 164 while still being spaced toward the bucket centerline 154 inwardly from the first sidewall 144 and second sidewall 146. A possible advantage of tapering the paddle plate 200 to the plate tail 204 with the first and second converging arcuate edges 206, 208 is that the weight of the paddle plate may be reduced while the flared forward plate edge 202 is still laterally coextensive with the lateral dimension of the bucket 102. Accordingly, loads applied at any location laterally along the cutting edge 142 can be directed rearward to the flared forward plate edge 202, then directed centrally toward the bucket centerline 154, in accordance with the first and second arcuate edges 206, 208, as the paddle plate tapers to the rearward plate tail 204 where the load is transferred to the hinge plates 180, 182. Even if loads are applied to the corners of the bucket 102 (i.e., proximate the first and second sidewalls 144, 146), for example by striking a mine wall, the loads may be centrally directed to the hinge plates 180, 182 by the trumpet shape of the paddle plate 200. A possible related advantage of the trumpet shape is that the paddle plate 200 still provides significant coverage of the bucket underside 198 and reduce the weight stress imparted to the bucket underside. In addition, because the plate tail 204 may overlap the interfaces between the center shell 160 and the first and second outer shells 162, 164, the plate tail can protect the weld seams joining the components together proximate the bucket heel 210.
In a further embodiment, because the plate tail 204 may extend partially under the indentation 170 disposed in the concaved bucket back 118, the plate tail 204 proximate the bucket heel 210 can be configured as a forked plate tail. For example, the plate tail 204 can be separated into a center heel branch 214 and first and second outer heel branches 216, 218 that laterally flank the center heel branch 214. The lateral spacing of the center heel branch 214 and the first and second outer heel branches 216, 218 delineate a first lift arm notch 220 between the center branch and first outer heel branch and a second lift arm notch 222 between the center branch and second outer heel branch. The first and second lift arm notches 220, 222 can be generally parallel to the bucket centerline 154 and can align with the two outer connector slots 188 of the indentation 170 to provide clearances thereto. Accordingly, when the bucket 102 is tilted, the lift arms of the lift implement can be received into the first and second lift arm notches 220, 222 without damaging the plate tail 204. A further possible advantage of including the center heel branch 214 and the first and second outer heel branches 216, 218 at the bucket heel 210 is that additional wear pads can be attached thereto, providing additional abrasion resistance at the bucket heel 210 which may forcibly contact the ground 112 during tilting of the bucket 102.
Referring to
In addition, the seat frame 230 can include a first backstay 238 and a second back stay 239 that are parallel to the lateral dimension 148 of the bucket 102 and that are located proximate the bucket heel 210. For example, the first and second backstays 238, 239 can project downwardly from the portions of the concaved bucket back 118 corresponding to the first and second outer shells 162, 164 and are adjacent the first and second outer hinge plates 180 respectively. The first and second backstays 238, 239 serve to interconnect the plate tail 204 and curved segment of the concaved bucket back 118 at the bucket heel 210 where they may be otherwise spaced apart. The backstays 238, 239 may extend laterally from the first and second outer hinge plates 180 toward the respective first and second side plates 144, 146 and may be laterally coextensive with the reduced lateral dimension 212 of the plate tail 210. The backstays 38, 239 can therefore transfer load from the plate tail 204 to the outer hinge plates 180. To enclose the space between the curved bucket back 118 and the plate tail 204 defined by the backstays, 238, 239, each backstay can be associated with a backstay side plate 237 that may be perpendicular to the lateral dimension and parallel to the bucket centerline 154. The backstay side plates 237 can be triangular in shape, are laterally offset from the outer hinge plates 180, and can be welded to and enclose the backstays 238, 239, the concaved bucket back 118, and the plate tail 204, thereby providing an enclosed space to increase stiffness and prevent debris from collecting on the bucket back. The backstay side plates 237 can complete the rearward extension between the first and second arcuate edges 234, 236 and the backstays 238, 239. In an embodiment, the first and second backstays 238, 239 can be disposed at a rearward angle with respect to the vertical as they extend between the plate tail 204 and the concaved bucket back 118 to provide a clearance and a turning radius for when the bucket 102 is tilted into the racked position. In particular, because the backstays 238, 239 are oriented on a rearward slanted angle between the plate tail 204 and the concaved bucket back 118, they will avoid interfering with the ground clearance, for example, as indicated by the lower dashed line in
When the paddle plate 200 is joined to the bucket underside 198, for example, by welding, the outline of the paddle plate 200 may be coextensively set adjacently against the projecting ribbing 232 of the seat frame 230. The projecting ribbing 232 serves to position and box the paddle plate 200 with respect to the bucket underside 198 of the bucket floor 150. The paddle plate 200 provides a planar surface on the bucket underside 198 that can contact and physically engage the ground when digging or loading with material.
In an embodiment, the bucket 102 can be configured as a wedge bottomed bucket in which the bucket floor 150 slopes upward as it extends from the forward cutting edge 142 at the opened bucket front 116 toward the rearward concaved bucket back 118. In accordance with the assembly of a wedge bottomed bucket, the bucket floor 150 can include a plurality of spacer wedges 240 that can be laterally disposed along and disposed between the bucket underside 198 and the paddle plate 200. In the illustrated example, four spacer wedges 240 can be included between and in abutting contact with the bucket underside 198 and the paddle plate 200 as illustrated in order to space the two components apart. Including the spacer wedges 240 in the gap between the bucket underside 198 and the paddle plate 200 and generally normal to the planar extension of the bucket underside and paddle plate may increase the structural integrity of the bucket 102, including the weld seams between the center shell 160 and the flanking first and second outer shell 162, 164, and may better may accommodate imparted loads and forces applied to the concaved bucket back 118. For example, the spaced-apart spacer wedge 140 direct loads between the plane of the paddle plate 200 and the plane of the bucket underside 198, while the space created between the paddle plate and bucket underside reduces the mass of the bucket 102. In addition, sloping the bucket floor 150 upwards may assist in receiving material into the bucket 102.
Referring to
Referring to
Referring to
Referring generally to the drawings, in operation, the loading machine 100 can be used to dig or penetrate into a pile or wall of material thereby imparting loads and forces to the cutting edge 142 of the bucket 102. To transfer the loads to the lift implement 104 and onto the loading machine 100 in a manner that avoids distorting or applying uneven bending stresses to the bucket floor 150, a paddle plate 200 can be joined to and offset from the underside 198 of the bucket floor 150. When the cutting edge 142 contacts the material, the imparted loads can be transferred rearward to both the bucket floor 150 and the paddle plate 200 that are disposed on the diverging angle 262. Loads and forces may be further transferred from the bucket floor 150 and paddle plate 200 to the plurality of spaced-apart spacer wedges 240 that are linearly aligned with the plurality of outer and inner hinge plates 180, 182 that reinforce the structure of the bucket 102. Moreover, because the hinge plates 180, 182 are directly coupled to the lift implement, forces directed thereto can be accommodated and distributed. The foregoing design provides an improved load path through the bucket floor 150. Inclusion of the paddle plate 200 to the bucket underside 198 increase stiffness and resists bending loads and distortion of the bucket floor 150 while the trumpet-shape reduces weight of the bucket 102 overall while maintaining an effective load path between the cutting edge 142 and the hinge plates 180, 182 that connect with the lift implement 104.
It will be appreciated that the foregoing description provides examples of the disclosed system and technique. However, it is contemplated that other implementations of the disclosure may differ in detail from the foregoing examples. All references to the disclosure or examples thereof are intended to reference the particular example being discussed at that point and are not intended to imply any limitation as to the scope of the disclosure more generally. All language of distinction and disparagement with respect to certain features is intended to indicate a lack of preference for those features, but not to exclude such from the scope of the disclosure entirely unless otherwise indicated.
Recitation of ranges of values herein are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. All methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context.
The use of the terms “a” and “an” and “the” and “at least one” and similar referents in the context of describing the invention (especially in the context of the following claims) are to be construed to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. The use of the term “at least one” followed by a list of one or more items (for example, “at least one of A and B”) is to be construed to mean one item selected from the listed items (A or B) or any combination of two or more of the listed items (A and B), unless otherwise indicated herein or clearly contradicted by context.
Accordingly, this disclosure includes all modifications and equivalents of the subject matter recited in the claims appended hereto as permitted by applicable law. Moreover, any combination of the above-described elements in all possible variations thereof is encompassed by the disclosure unless otherwise indicated herein or otherwise clearly contradicted by context.
Number | Name | Date | Kind |
---|---|---|---|
4523397 | Lucas | Jun 1985 | A |
7266914 | Grant | Sep 2007 | B2 |
7429158 | McFarland | Sep 2008 | B2 |
10246849 | Marek et al. | Apr 2019 | B2 |
20030066215 | Grant | Apr 2003 | A1 |
20060182590 | McFarland | Aug 2006 | A1 |
20160362873 | Campomanes | Dec 2016 | A1 |
20180087236 | Marek et al. | Mar 2018 | A1 |
20180127952 | Magliulo et al. | May 2018 | A1 |
Number | Date | Country |
---|---|---|
2017228636 | Apr 2018 | AU |
107165206 | Sep 2017 | CN |
109098219 | Dec 2018 | CN |
109983183 | Jul 2019 | CN |
3604683 | Feb 2020 | EP |
1177839 | Jan 1970 | GB |
Entry |
---|
PEBJ0030-02 “CAT © Ground Engaging Tools for Surface Extraction Machines”, (Author Unknown), copyright 2015, last modified Apr. 29, 2016, demonstrated to be available for download as early as Dec. 1, 2017 via Internet Archive Wayback Machine (Year: 2017). |
Caterpillar Inc., “988K XE Wheel Loader,” product brochure, 36 pp. (2017). |
Komatsu Mining Corp., “Joy 22HD Hybrid Loader—Underground Hard Rock Mining,” product brochure downloaded from the Internet at https://mining.komatsu/product-details/joy-22hd on Nov. 4, 2019, , 4 pp. |
Komatsu Mining Corp., “Wheel Loader WA900-8,” product brochure, 7 pp. (2019). |
Canadian Examination Report for Int'l. Patent Appln. No. 3169778, dated Mar. 9, 2023 (6 pgs). |
CAT® Ground Engaging Tools for Surface Extraction Machines [retrieved from internet on Feb. 23, 2023] <URL: https://wheelercat.com/wp-content/uploads/2015/07/GET-Surface-Extraction-Machines.pdf> published on Dec. 1, 2017 as per Wayback Machine Whole Document. |
Australian Examination Report for Patent Appln. No. 2021229907, dated Feb. 23, 2023 (3 pgs). |
Number | Date | Country | |
---|---|---|---|
20210277623 A1 | Sep 2021 | US |