BR122022021485B1 - STABILIZING WEAR LIMB ASSEMBLY INCLUDING A NOSE AND A WEAR LIMB - Google Patents

Abstract

A wear member assembly includes a nose and a wear member. The nose includes the rear, middle and front portions. The rear portion includes a first set of surfaces converging towards a longitudinal axis including a first subset of top and bottom surfaces, a second subset of side surfaces, and a third subset of surfaces inclined and positioned between the first and second subsets. The front portion includes a second set of surfaces converging towards the longitudinal axis including a fourth subset of top and bottom surfaces, a fifth subset of side surfaces, and a sixth subset of surfaces inclined and positioned between the fourth and fifth subsets. The intermediate portion includes several surfaces in cross-section different from the front portion and the rear portion. The wear member includes a cavity including bearing surfaces corresponding to the surfaces of the front and rear portions of the nose.

Description

[0001] This application claims the benefit of US Provisional Order No. 62/335,789 filed May 13, 2016 and entitled "Wear Member Stabilization System with Octagonal Interface" and US Provisional Order No. 62/441,779 filed on January 3, 2017 and titled "Stabilization Features in a Wear Member Assembly", the descriptions of which are incorporated by reference in their entirety.

TECHNICAL FIELD

[0002] This description is typically directed to earth engaging wear member assemblies including adapters for attaching digging wear members to bucket flaps. More particularly, this disclosure is directed to stabilizing load bearing surfaces between adjacent wear members.

FUNDAMENTALS

[0003] Material-moving apparatus, such as excavation buckets found in construction, mining, and other earth-moving equipment, typically include replaceable wear portions, such as earth-engaging teeth. These are often detachably attached to larger base structures, such as excavation buckets, and come into wear, abrasive contact with the earth or other materials being displaced. For example, sets of digging tines provided on digging equipment, such as digging buckets and the like, typically comprise a relatively massive adapter portion which is suitably anchored to the front bucket lip. The adapter portion typically includes a forward projecting nose. A replaceable tooth typically includes a rearward facing cavity that releasably receives the adapter nose. To retain the tooth in the adapter nose, generally aligned transverse openings may be formed in both the tooth and the adapter nose, and a suitable connector structure is driven into and forcibly retained within the aligned apertures to releasably anchor the replaceable tooth in the adapter nose. its associated adapter nose.

[0004] During normal operations, the tooth experiences loading in various directions. If the tooth is not positioned on the nose in a stable way, the loads experienced by the tooth can cause additional wear on the adapter. Therefore, there is a need for an improved adapter nose and corresponding opening in the tooth.

SUMMARY

[0005] According to some example implementations, a wear member assembly may include an attachable nose on a bucket lip. The nose may include a rear portion having a first set of eight substantially planar surfaces converging towards a longitudinal axis of the nose toward a distal end of the rear portion. The first set of substantially planar surfaces may include a first subset of surfaces having a top and bottom surface, a second subset of side surfaces, and a third subset of surfaces comprising support surfaces. The third subset of surfaces being angled and positioned between the first subset of surfaces and the second subset of surfaces. The nose may also include a forwardly positioned front portion adjacent the rear portion, the front portion having a second set of eight substantially planar surfaces converging toward the longitudinal axis of the nose toward the distal end of the front portion. The second set of substantially planar surfaces may include a fourth subset having a top and bottom surface, a fifth subset of side surfaces, and a sixth subset of surfaces comprising support surfaces, the sixth set of surfaces being angled and positioned between the first subset of surfaces and the second subset of surfaces. The wear member assembly may also include a wear member having a cavity opening towards a rear end, the cavity comprising rear and front support surfaces corresponding to the third subset of surfaces and the sixth subset of surfaces.

[0006] According to some example implementations, a wear member includes a cavity having a rear portion having a first set of eight surfaces converging towards a longitudinal axis at a first angle towards a distal end of the rear portion. The first set of substantially planar surfaces may include a top and bottom surface, a set of side surfaces, and a set of diagonal surfaces comprising support surfaces. The cavity may further include a forwardly positioned front portion adjacent the rear portion, the front portion having a second set of eight surfaces converging towards the longitudinal axis at a second angle which is less than the first angle. The cavity may further include an array of pockets positioned at least partially along the diagonal surfaces, the pockets having inwardly facing vertical surfaces.

[0007] According to some example implementations, a wear member assembly may include an adapter nose having a tail portion having a cross-section width and a cross-section height, the cross-section width being different from the cross-section height. cross-section, the rear portion having two non-support surfaces and four substantially planar support surfaces, the two non-support surfaces being substantially horizontal in cross-section and the four substantially plan support surfaces being oblique in cross-section, the first two of four substantially planar support surfaces being disposed on a first lateral side of the two substantially planar non-support surfaces, and the second two of the four substantially planar support surfaces being disposed on the second lateral side of the two substantially planar non-support surfaces, wherein at a distal end of the rear portion, the cross-sectional width of one of the two non-supporting surfaces is substantially different from the cross-sectional width of any of the four supporting surfaces.

[0008] According to some example implementations, a wear member includes a cavity having a rear portion and a front portion. The rear portion may have a cross-section width and a cross-section height, the cross-section width being different from the cross-section height. The cavity may have two substantially flat non-supporting surfaces and four substantially flat supporting surfaces. The two substantially planar non-supporting surfaces may be substantially horizontal in cross-section and the four substantially planar support surfaces may be oblique in cross-section. The first two of four substantially planar support surfaces can be arranged on a first lateral side of the two substantially planar non-support surfaces, and the second two of the four substantially planar support surfaces can be disposed on a second lateral side of the two support surfaces. not substantially flat support. At a distal end of the rear portion, the cross-sectional width of any two substantially planar non-supporting surfaces may differ from the cross-sectional width of any of the substantially four supporting surfaces.

[0009] The present description is directed to a wear member assembly having a particularly shaped support surface disposed on a wear member nose, such as an adapter nose, and a corresponding molded support surface on a wear member additional introduced over the nose. It is to be understood that both the foregoing general description and the following drawings and detailed description are exemplary and explanatory in nature and are intended to provide an understanding of the present disclosure without limiting the scope of the present disclosure. In this regard, additional aspects, features and advantages of the present disclosure will be apparent to one skilled in the art from the following.

[0010] The present disclosure is directed to stabilizing load-bearing surfaces on wear members that provide stability and support during material shifting/ground engagement excavation operations. In some implementations, the present disclosure describes a hollow ground engaging wear member attachable to a support structure that may include a leading end arranged to engage the ground and a trailing end having a cavity formed therein. The cavity may have an inner surface and have a longitudinally extending axis and a front portion and have a rear portion adjacent the rear end. The inner surface may have horizontally spaced apart inner walls and have vertically spaced apart inner walls forming an upper inner surface and a lower inner surface. The upper inner surface and the lower inner surface may each have a centrally disposed inwardly projecting support surface portion arranged to provide a support fit to the support structure. Each inwardly projecting support surface portion may be disposed at the rear portion of the cavity and may have a transverse width less than a longitudinal length and receptive in a depression of the support structure. The inwardly projecting portion of the support surface may be arranged to support vertically imposed loads at the front end.

[0011] In accordance with some example implementations, the present description is directed to a support structure arranged to receive a wear member, the support structure may include a nose arranged to receive a cavity of the wear member. The nose may include a front portion having a plurality of outwardly facing surfaces, the outwardly facing surfaces angled with respect to a longitudinal axis of the nose at a first angle. The nose may further include a rear portion having two horizontally separated outward facing surfaces and two vertically separated outward facing surfaces including an upward surface and a downward surface, the outward facing surfaces horizontally separated and the outward facing surfaces vertically separated being angled with respect to the longitudinal axis at a second angle which is different from the first angle. The nose may further include a first concave support surface positioned on the upwardly facing surface. The nose may further include a second concave support surface positioned on the downwardly facing surface.

[0012] In accordance with further example implementations, the present description is directed to a wear member that may include a cavity arranged to fit over a nose of an adapter. The cavity may include a front portion having a plurality of inwardly facing surfaces, the inwardly facing surfaces angled with respect to a longitudinal axis of the cavity at a first angle. The cavity may include a rear portion having two horizontally spaced apart inwardly facing surfaces, and two vertically spaced apart inwardly facing surfaces including an upside surface and a downside surface, the inwardly facing surfaces horizontally spaced apart and the inwardly facing surfaces vertically spaced apart. being angled with respect to the longitudinal axis at a second angle which is different from the first angle. The cavity may include a first convex support surface positioned on the upwardly facing surface. The cavity may include a second convex support surface positioned on the downward facing surface.

[0013] In accordance with even more example implementations, the present description is directed to a wear member assembly that may include an adapter having a trailing end arranged to secure the adapter to a bucket lip and a leading end having a nose. The wear member may also include a substantially flat upwardly facing surface at least partially circumscribing a concave upwardly facing support surface and a substantially flat downwardly facing surface at least partially circumscribing a concave downwardly facing support surface. The wear member assembly may also include a wear member having a leading end arranged to engage the ground and a trailing end having a recess. The cavity may include a downwardly facing surface having a first outwardly protruding therefrom, the first outwardly protruding arranged to fit within the concave upwardly facing support surface. The cavity may include an upwardly facing surface having a second outwardly protruding therefrom, the second outwardly protruding arranged to fit within the concave downwardly facing support surface.

BRIEF DESCRIPTION OF THE DRAWINGS

[0014] The attached drawings illustrate implementations of the systems, devices and methods disclosed herein and together with the description, serve to explain the principles of the present description.

[0015] Figure 1 is a view of a ground engaging wear member assembly according to an example incorporating principles described herein.

[0016] Figure 2 illustrates a perspective view of an adapter nose with a support surface portion on a top and bottom surface according to an example incorporating principles described herein.

[0017] Figures 3A and 3B are diagrams showing longitudinal cross-sectional views of the support surface portion on the adapter nose according to an example incorporating principles described herein.

[0018] Figures 4A and 4B are diagrams showing cross-sectional cross-sectional views of the nose support surface portion according to an example incorporating principles described herein.

[0019] Figure 5 is a top view of the nose with a support surface portion according to an example incorporating principles described herein.

[0020] Figure 6 is a front view of the nose with a support surface portion according to an example incorporating principles described herein.

[0021] Figure 7A is a perspective view of a tooth having a protrusion corresponding to the supporting surface portion in the nose according to an example incorporating principles described herein.

[0022] Figure 7B is a longitudinal cross-sectional view of the tooth with the protrusion according to an example incorporating principles described herein.

[0023] Figures 8 and 9 are cross-sectional views of the tooth with the protrusion according to an example incorporating principles described herein.

[0024] Figure 10 is a rear view of the tooth examining within the cavity according to an example incorporating principles described herein.

[0025] Figure 11A is an exploded perspective view of a ground engaging wear member assembly in accordance with an example of principles described herein.

[0026] Figure 11B illustrates an adapter nose examining along the longitudinal axis of the nose according to an example of principles described herein.

[0027] Figure 11C illustrates a side view of the adapter nose in accordance with an example of principles described herein.

[0028] Figure 12A illustrates the tooth examining within the cavity according to an example of principles described herein.

[0029] Figure 12B illustrates a cross-sectional side view of the tooth assembly in accordance with an example of principles described herein.

[0030] Figure 13 illustrates a perspective view of the adapter nose according to an example of principles described herein.

[0031] Figure 14A illustrates an adapter nose with twist control features in accordance with an example of principles described herein.

[0032] Figure 14B illustrates a side view of an adapter nose with twist control features in accordance with an example of principles described herein.

[0033] Figure 14C illustrates a perspective view of an adapter nose with twist control features in accordance with an example of principles described herein.

[0034] Figure 14D illustrates a top view of an adapter nose with torque control features in accordance with an example of principles described herein.

[0035] Figure 15 illustrates a diagram showing a tooth having a cavity designed to fit an adapter nose with torque control features in accordance with an example of principles described herein.

[0036] Figure 16A illustrates a cross section of the adapter nose orthogonal to the longitudinal axis according to an example of principles described herein.

[0037] Figure 16B illustrates a cross section of the adapter nose with torsion control features orthogonal to the longitudinal axis according to an example of principles described herein.

[0038] Figure 16C illustrates a cross-section of the front portion of the adapter nose according to an example of principles described herein.

[0039] Figure 16D illustrates a cross section of the adapter nose with offset twist control features in accordance with an example of principles described herein.

[0040] These figures will be better understood by reference to the following detailed description.

DETAILED DESCRIPTION

[0041] In order to promote understanding of the principles of the present disclosure, reference will now be made to the implementations illustrated in the drawings and specific language will be used to describe them. However, it will be understood that no limitation on the scope of the disclosure is intended. All changes and other modifications to the devices, instruments, methods and other applications described, and any further application of the principles of the present description are fully contemplated, as would normally occur to one skilled in the art to which the disclosure pertains. Furthermore, this description describes some elements or features in detail in relation to one or more implementations or Figures, when those same elements or features appear in subsequent Figures, without such a high level of detail. It is fully contemplated that features, components and/or steps described with respect to one or more implementations or Figures may be combined with features, components and/or steps described with respect to other implementations or Figures of the present disclosure. For simplicity, in some cases the same or similar reference numerals are used throughout the drawings to refer to the same or similar parts.

[0042] The present description is directed to a ground engaging wear member assembly that includes an adapter nose that can be attached to a bucket lip. The earth-engaging wear member assembly also includes a tooth or other wear member, such as an intermediate adapter, that can be attached to the adapter nose. The wear member includes a rearward facing cavity designed to fit over the adapter nose. The nose can include a front set of surfaces and a back set of surfaces, and in some implementations, both the front set of surfaces and the back set of surfaces can form a substantially octagonal shape in cross section. Multiple surfaces of both the front set of surfaces and the back set of surfaces may be mating (or support) surfaces, while other surfaces of the front set of surfaces and back set of surfaces may be non-matching (or non-supporting) surfaces. . In some particular embodiments, the top surface and bottom surface of the rear set of surfaces may be mating surfaces and include an interference support feature such as a protrusion on one of the tooth or adapter and a mating indentation on the other of the tooth. tooth or adapter. These can cooperate to distribute vertical loading in a manner assisting with stability and alignment of the wear member in the adapter nose. As used herein, a mating surface is a load-bearing surface.

[0043] In some implementations, the ground engagement wear assembly adapter includes mating surfaces on angled side surfaces. These mating surfaces may be arranged in a manner that provides stabilizing contact on more than one mating surface when the earth engagement wear assembly is subjected to a vertical load or a horizontal load. For example, an applied vertical downward load can be supported by two angled mating surfaces, and an applied vertical upward load can be supported by two separate angled mating surfaces. Likewise, a left horizontal load can be supported by two angled mating surfaces and a right horizontal load can be supported by two angled mating surfaces. In some implementations, one set of angled mating surfaces is disposed on a distal or front portion of the adapter nose and another set of angled mating surfaces is disposed on a proximal or rear portion of the adapter nose. In this way, a wear member, such as a tooth, can be supported by angled mating surfaces at both the distal end and the proximal end of the adapter nose.

[0044] Figure 1 is a view of an exemplary earth engaging wear member assembly 100 in accordance with an example of the present disclosure. In the implementation shown, the earth-engaging wear member assembly 100 includes a tooth (or wear member) 104, an adapter 102, and a locking pin 106. In this example, the wear assembly 100 also includes a protective wear 108. Adapter 102 includes a hole (not shown) for receiving lock pin 106. Teeth 104 also includes a hole through which lock pin 106 can be inserted. Locking pin 106 can secure tooth 104 on adapter 102. Adapter 102 may also be referred to herein as a support structure as it provides stabilizing support for an additional component, which in this implementation is tooth 104.

[0045] Figure 2 illustrates a perspective view of the adapter 102. According to the present example, the adapter 102 includes a front end 201 and a rear end 212. The front end 201 includes a nose 203 and the rear end 212 includes a pair of forked legs 214a, 214b arranged to secure the adapter 102 to a bucket brim (not shown). A longitudinal axis 211 is shown through the front end 201 and the rear end 212. A transverse axis 215 is shown for reference in a position that would be parallel to an edge of the bucket lip (not shown).

[0046] According to the present example, the nose 203 includes a front portion 205, a rear portion 207 and an intermediate portion 209 extending between the front portion 205 and the rear portion 207. The front portion 205 includes a facing end surface forward 220 and a plurality of outwardly facing surfaces 202 in an octagonal array adjacent end surface 220. In this implementation, each of the surfaces 202 is angled with respect to the longitudinal axis 211. In addition, at least four of the surfaces are angled in with respect to transverse axis 215. In some examples, at least four of the plurality of surfaces 202 may be load-bearing mating surfaces. For example, in some implementations, surfaces 202 may include angled surfaces 202a, 202b, 202c, and 202d as load-bearing mating surfaces. In other implementations, surfaces 202 may include vertical and horizontal surfaces 202e, 202f, 202g and 202h as load-bearing mating surfaces. In some implementations, each of the surfaces 202 may be substantially flat, while in other implementations, only four of the eight surfaces 202 are substantially flat. In still other implementations, a different number of the eight surfaces 202 are substantially planar.

[0047] In the present example, the rear portion 207 also includes a plurality of outwardly facing surfaces 204 in an octagonal array. Each of the surfaces 204 is angled with respect to the longitudinal axis. Each of the rear surfaces 204 can be angled differently with respect to the longitudinal axis. For example, the side surfaces 204f, 204h may be angled differently with respect to the longitudinal axis than the top and bottom surfaces 204e, 204g. In the present example, the rear surfaces 204 are angled with respect to the longitudinal axis at a different angle than the front surfaces 202. Specifically, the rear surfaces 204 are angled at a greater angle with respect to the longitudinal axis than the front surfaces 202. In the examples , the multiple front surfaces 202 can have different angles with respect to the longitudinal axis. Likewise, the rear surfaces 204 are at different angles to the longitudinal axis. In such examples, the average angle at which each of the rear surfaces 204 converge towards the longitudinal axis may be greater than the average angle at which the front surfaces 202 converge towards the longitudinal axis. As shown in the perspective view of Figure 2, the rear surfaces 204 include angled surfaces 204a, 204b, 204c. The opposite side of the nose 203 includes an additional angled surface 204d, which is identified in Figures 4A and 4B, for example. The rear surfaces 204 also include a top surface 204e and a side surface 204h. The nose 203 also includes a bottom surface 204g and an opposing side surface 204f which are identified in Figures 4A and 4B, for example. The rear surfaces 204 can also be supporting or mating surfaces. In some examples, each of the rear surfaces 204 can be supporting mating surfaces. In some examples, only the angled surfaces 204a, 204b, 204c, 204d can be mating surfaces. In some examples, only the horizontal and vertical surfaces 204e, 204f, 204g, 204h can be mating surfaces. In some implementations, each of the surfaces 204 may be substantially flat, while in other implementations, only four of the eight surfaces 204 are substantially flat. In still other implementations, a different number of surfaces 204 are substantially flat.

[0048] In the present example, the intermediate portion 209 includes a plurality of outwardly facing surfaces 216. These outwardly facing surfaces 216 may extend between and intersect surfaces 202 and surfaces 204. In some implementations, surfaces 216 may be angled differently than surfaces 202 and surfaces 204 relative to longitudinal axis 211. Referring to Figure 2, outwardly facing surfaces 216 may include a plurality of surfaces including, among other surfaces, an upwardly facing surface 216a, a downward facing surface 216b (Figures 3A and 3B). In this implementation, the side surfaces of the midportion 209 may contain a hole 206. Additional angled surfaces 216c, 216d, 216e, 216f (best seen in Figures 5 and 6) are arranged around the midportion of the nose.

[0049] With reference to Figures 2, 3A, 3B, 5 and 6, the upward facing surface 216a of the intermediate portion 209 may extend at a different angle from the adjacent top surface 204e of the rear portion 207 and the adjacent top surface 202e of the front portion 205. Therefore, the upwardly facing surface 216a may be non-planar with the adjacent top surface 204e of the rear portion 207 and be non-planar with the adjacent top surface 202e of the front portion 205. In a similar manner, the downward facing surface 216b of the middle portion 209 may extend at a different angle from the adjacent bottom surface 204g of the rear portion 207 and the bottom surface 202g of the front portion 205.

[0050] In the present example, the top surface 204e includes a concave support surface 210 positioned thereover. In some examples, top surface 204e circumscribes concave support surface 210. In some implementations, concave support surface 210 bridges the intersection of upward facing surface 216a and top surface 204e. The concave support surface 210, in this implementation, is an indentation that can cooperate with a corresponding protrusion in the wear member 104 to provide load bearing stability as well as lateral stability. Although not seen from this perspective view, the nose 203 may also have a similar concave support surface portion on the bottom surface that is opposite the top surface 204e. In some implementations, the concave support surface on the bottom surface may be shaped identically to the concave support surface 210 on the top surface 204e. In the present example, the concave support surface 210 has a substantially elliptical shape. Other forms are also contemplated. For example, instead of being elliptical in shape, the concave support surface 210 could be circular or could have some other configuration.

[0051] The nose 203 also includes a hole 206 extending from the side surface 204h to the opposite side surface (not shown in this perspective). In this implementation, hole 206 is formed in the intermediate portion 209 of nose 203. Hole 206 is sized and shaped to receive a locking pin. In the present example, hole 206 is positioned forward of concave support surface 210. In other words, at least a portion of concave support surface 210 is positioned rearward of hole 206. In some examples, the entire support surface concave 210 may be positioned rearward of hole 206. In other implementations, hole 206 extends only partially through nose 203. A corresponding hole 206 may be formed on the opposite side of nose 203. In these implementations, two separate locking pins may be provided. used to secure wear member 104 to adapter 102 (see Figure 1).

[0052] The nose also includes torsion control surfaces 230b, 230d. Torque control surfaces 230a, 230c are illustrated in Figures 4B and 6. Torque control features 230a, 230b, 230c and 230d may be substantially flat surfaces that face outwards and are sized and shaped to fit against mating surfaces. inside the tooth cavity, which will be described in further detail below. In the present example, the torsion control surfaces 230a, 230b, 230c, 230d respectively intersect the angled surfaces 204a, 204b, 204c, 204d of the rear portion 207. Particularly, the torsion control surfaces 230a, 230b, 230c, 230d intersect the angled surfaces 204a, 204b, 204c, 204d near where such surfaces meet the vertical surfaces 204f, 204h. In some examples, twist control surfaces 230a, 230b, 230c, 230d may be aligned with vertical surfaces 204f, 204h.

[0053] In some examples, the angled surfaces of both the front surfaces 202 and the rear surfaces 204 may be support (or socket) surfaces. Specifically, surfaces 202a, 202b, 202c, 202d, 204a, 204b, 204c, 204d can be support surfaces. Furthermore, the horizontal and top surfaces of the front surfaces 202 and the rear surfaces 204 may be non-supporting (or non-engaging) surfaces. Specifically, surfaces 202e, 202f, 202g, 202h, 204e, 204f, 204g, 204h may be non-supporting surfaces. Other combinations of supporting and non-supporting surfaces are also contemplated.

[0054] Figures 3A and 3B are diagrams showing longitudinal cross-sectional views of a portion of the adapter 102, showing upper concave support surfaces 210 and a lower concave support surface 213. Figure 3B in particular shows the portion of support surface 213 to bottom surface 204g of adapter nose 102. In some embodiments, top surface 204e and bottom surface 204g can both be mating surfaces. In that case, other surfaces, such as the side surfaces or angled surfaces, can be either mating or non-matching surfaces. For example, it could be that all angled surfaces are non-matching surfaces, while the top, bottom, and side surfaces are mating surfaces. As indicated above, some implementations of concave support surface 210 intersect the intersection of upward facing surface 216a and top surface 204e. In such implementations, the upward facing surface 216a may be a non-mating surface, while the concave support surface 210 forms a mating surface. In some examples, concave surfaces 210, 213 may be non-supporting surfaces. In such examples, multiple combinations of the horizontal, vertical, and angled surfaces can be mating surfaces, and in some cases only the angled surfaces are mating surfaces. It could be that all surfaces are mating surfaces. Other combinations of mating and non- mating surfaces are contemplated. For example, angled surfaces can be mating surfaces, while horizontal and vertical surfaces are non-matching surfaces in a similar manner as described below in the text accompanying Figures 11A-16D.

[0055] The bottom concave support surface 213 may be substantially identical to the top concave support surface portion 210. In some examples, the position and shape of the bottom concave support surface portion 213 may mirror the position and the shape of the top concave support surface portion 210. Therefore, similar to the arrangement described above, the bottom concave support surface 213 can bridge the intersection of the downward facing surface 216b and the bottom surface 204g. In such implementations, the downward facing surface 216b may be a non-mating surface, while the bottom concave support surface 213 forms a mating surface. In some examples, the bottom concave support surface portion 213 may be longitudinally displaced from the top concave support surface portion 210. For example, the bottom concave support surface portion 213 may be closer or further farther in front of the nose than the top concave support surface portion 210.

[0056] The concave support surface portions 210, 213 in this implementation are formed as indentations having smooth rounded surfaces as the shape transitions from the concave surface to the planar top surface 204e. The indentation provides lateral stability at the rear of the wear member 104 when loaded during use. Furthermore, when vertical loads are directed towards the front end of the wear member 104, the indentation distributes the load in the rear portion of the wear member and the load is transferred through the concave support surface portions 210, 213 to the adapter ( or an intermediate adapter if so equipped). Furthermore, the concave load-bearing surface portions 210, 213 provide a smooth surface, with curved sides that aid in lateral stability. Therefore, lateral loads on the leading edge of the wear member 104 that result in opposing loads on the end of the wear member can be alleviated to some extent by the curved lateral sides of the concave support surface portions 210, 213. As can be seen, indentations are formed in the top surface 204e which is angled longitudinally to face the front end surface 220 of the adapter 102. Accordingly, corresponding protrusions on the inner surface of the wear member 104 can engage directly with the recessed support surface portion 210 and 213.

[0057] Figures 4A and 4B are diagrams showing cross-sectional cross-sectional views of the concave support surface portions 210, 213 on the adapter 102. Figures 4A and 4B also show each of the back surfaces 204. Specifically, Figures 4A and 4B illustrate upwardly facing top surface 204e, outwardly facing side surfaces 204f, 204h, and downwardly facing bottom surface 204g. Figures 4A and 4B also illustrate outwardly facing angled surfaces 204a, 204b, 204c, 204d. In the exemplary implementation shown, the concave support surface portions 210, 213 are formed on the rear portion 207 only on the upwardly facing top surface 204e and the downwardly facing bottom surface 204g, while the outwardly facing side surfaces 204f, 204h and the outwardly facing angled surfaces 204a, 204b, 204c, 204d are all formed to be relatively flat. This can provide additional mating surface support for vertical loading on a supported tooth 104, while also providing standard support for horizontal loading or side-by-side loading.

[0058] Figure 5 is a top view of the nose 203 of the adapter 102. The concave support surface portion 210 is shown extending into and through the intersection of the upwardly facing surface 216a and the top surface 204e. In some examples, the transverse width 504 of the concave support surface portion 210 may be within a range of about 60-80 percent of the transverse width 508 of the top surface 204e. In some examples, the transverse width 504 of the concave support surface portion 210 may be about 70% of the transverse width 508 of the top surface 204e. The longitudinal length 502 of the concave support surface portion 210 may be similar to the transverse width 504 of the concave support surface portion 210. In some examples, the longitudinal length 502 of the concave support surface portion 210 may be within a range of about 0-50 percent greater than the transverse width 504. The concave support surface portion 210 can be sized to provide stability and increase the surface area of the top surface 204e, while minimizing weakening of the adapter 102 by elevators. of tension. Therefore, the depth of the recessed support surface portion can be selected to provide the necessary balance of stability and strength. In some implementations, the depth of the support surface portion is selected to be within the range of approximately 0.1 inches to about 0.625 inches, although other depths are contemplated.

[0059] Figure 6 is a front and slightly angled view of the adapter 102 with the concave support surface portion 210. Figure 6 also illustrates the top surface 204e and the top surface 202e, and the top surface 216a. Figure 6 also illustrates rear angled surfaces 204a, 204b, front angled surfaces 202a, 202b, and intermediate non-supporting surfaces 216c and 216f.

[0060] Figure 7A is a perspective view of the wear member 104 which includes protrusions extending from inner surfaces of the cavity. The wear member 104 may also be referred to as a hollow ground engaging wear member. While wear member 104 may also be referred to as a tooth, wear member 104 may also form an intermediate adapter or other wear member configured to be supported by or to support other wear members. Wear member 104 includes a front end 708 at the front end 701 of the wear member. The front end 708 is arranged to engage or penetrate the ground, and typically may be referred to as the working end. Wear member 104 also includes a rear end, which has a cavity (shown in cross section in Figure 7B) that is sized and shaped to receive nose 203 of adapter 102.

[0061] In the present example, the side 709 of the wear member 104 includes a hole 711 that is sized and shaped to receive the locking pin 106 (Figure 1). In some implementations, the opposite side of wear member 104 may include a similar hole. Hole 711 can be positioned so that when wear member 104 is properly fitted into nose 203, hole 711 is aligned with hole 206 of adapter 102. Thus, locking pin 106 can be inserted through both holes 206, 711 and adjusted to maintain wear member 104 in adapter 102.

[0062] In the present example, the wear member 104 includes a wear indicator 731. The wear indicator 731 may be a split or indentation in the wear member 104 that indicates to an operator when the wear member 104 should be replaced. Specifically, wear member 104 wears as it is used for digging operations. When it wears to a point where the bottom of wear indicator 731 is flush with the rest of wear member 104, then this indicates to an operator that it is time to replace wear member 104. Wear indicator 731 can be sized and shaped so that it has a depth associated with an expected amount of wear before the wear member 104 is replaced. This expected amount of wear can be based on historical data representing the manner in which the wear member 104 wears during normal operations. Wear indicator 731 may also be positioned elsewhere on wear member 104.

[0063] Figure 7B is a longitudinal cross-sectional view of the wear member 104 showing an upper protrusion 706 and a lower protrusion 707 arranged to correspond with the concave support surfaces 210, 213 on the adapter 102. The wear member 104 includes the front end 708 and a rear end 703. A cavity 702 is formed in the rear end 703, extending longitudinally inwardly from the rear end 703. The cavity 702 opens in the rear of the wear member 104 and is shaped and sized to fit over the nose 203 of the adapter 102.

[0064] In some implementations, the cavity 702 is shaped to have surfaces corresponding to the multiple surfaces of the nose 203. In some implementations, since not all surfaces are mating surfaces, only the mating surfaces of the cavity 702 and the nose 203 have the same shape. That is, the cavity 702 can be contoured so that the mating surfaces of the cavity 702 correspond to the mating surfaces of the adapter 102. Because of this, the descriptions applied here relating to the external surfaces of the nose 203 are equally applicable to the internal surfaces of the nose 203. cavity 702 of wear member 104. Similar to nose 203, cavity 702 includes a front portion 720, a rear portion 722, and an intermediate portion 724. Cavity 702 also includes a longitudinal axis 718 which in this implementation is coaxial with the longitudinal axis of wear member 104. A transverse axis 719 (Figures 7A and 10) extends perpendicular to longitudinal axis 718 and is arranged to be substantially parallel to a front end of a bucket lip.

[0065] According to the present example, the cavity 702 includes a front portion 720, an intermediate portion 724 and a rear portion 722. The front portion 720 includes a plurality of substantially planar inwardly facing surfaces 721a, 721b, 721e, 721f , 721g in an octagonal shape (not all eight surfaces are shown in the cross-sectional view of Figure 7B). These surfaces 721a, 721b, 721e, 721f, 721g may correspond to some of the outwardly facing surfaces 202 of the front portion 205 of the adapter 102. As described above, some surfaces 202 of the front portion 205 may be mating surfaces while some may be mating surfaces. not fit. The mating surfaces of the adapter 102 can mate with the mating surfaces of the cavity 702 while the mating surfaces of the adapter 102 can be shaped slightly different from the mating surfaces of the cavity 702 or can be displaced from the mating surfaces of cavity 702.

[0066] The intermediate portion 724 includes a plurality of substantially planar inwardly facing surfaces 723a, 723b, 723e, 723f, 723g (not all surfaces are shown in the cross-sectional view of Figure 7B). These surfaces 723a, 723b, 723e, 723f, 723g may mate with some of the outwardly facing surfaces 216 of the intermediate portion 209 of the adapter 102. Specifically, the mating surfaces of the adapter 102 mate with the mating surfaces of the cavity 702 while the mating surfaces The non-matching surfaces of the adapter 102 may be shaped slightly different from the non-matching surfaces of the cavity 702 or may be offset from the non-matching surfaces of the cavity 702.

[0067] The rear portion 722 includes a plurality of substantially planar inwardly facing surfaces 704a, 704b, 704c, 704d, 704e, 704f, 704g, 704h in an octagonal shape (some surfaces are best shown in Figures 8A and 8B). These surfaces include an upper inner surface 704e and a lower inner surface 704g (which are vertically separated side surfaces, horizontally separated side surfaces 704f, 704h, upper angled inner surfaces 704a, 704c, and lower angled inner surfaces 704b, 704g. These surfaces 704a, 704b 704c, 704d, 704e, 704f, 704g, 704h may mate with the outwardly facing surfaces 204 of the front portion 207 of the adapter 102. Specifically, the mating surfaces of the adapter 102 may mate with the mating surfaces of the cavity 702 while the mating surfaces of non-matching surfaces of the adapter 102 may be shaped slightly different from the non-matching surfaces of the cavity 702 or may be displaced from the non-matching surfaces of the cavity 702.

[0068] The cavity 702 includes an upper inwardly facing surface 704e that is designed to mate with the upwardly facing surface 204e of the nose 203. In some implementations, the upper inwardly facing surface 204e may be substantially flat. The upper inwardly facing surface 704e also includes an upper protrusion 706 extending therefrom. Upper protrusion 706 can also be described as an inwardly projecting support surface portion 706 as it projects inwardly towards a longitudinal axis 718 of wear member 104 and cavity 702. The projecting support surface portion 706 The upper inwardly facing surface 706 is sized and shaped to mate with the concave support surface portion 210 of the nose 203. Similarly, the cavity includes a lower inwardly facing surface 704g that is designed to mate with the downwardly facing surface 204g of the nose 203. nose 203. The lower downward facing surface 704g also includes an inwardly projecting support surface portion 707. The cavity also includes other surfaces that correspond to surfaces 202, 204 of the nose 203. The inwardly supporting surface portions 706 , 707 are convex and are arranged to support vertically imposed loads at the front end.

[0069] The protrusions 706, 707 may be centrally located on their respective surfaces 704e, 704g. Thus, protrusions 706, 707 may be circumscribed by planar portions of surfaces 704e, 704g. Furthermore, the protrusions 706, 707 can be laterally displaced from each other if the corresponding concave support surface portions 210, 213 of the nose 203 are displaced from each other. Either the upper protrusion 706 or the lower protrusion 706 may form a cross-sectional arc having tangents at oblique angles. In some examples, there may be only a single protrusion 706 on top surface 704 and only a single protrusion 707 on bottom surface 704g. In some examples, however, there may be additional protrusions on each surface 704e, 704g.

[0070] In the present example, the surfaces of the protrusions 706, 707 can act as support surfaces against the support surface portions 210, 213 of the adapter nose 203. Thus, the interference features comprising the protrusions 706, 707 and support surface portions 210, 213 can provide additional support for loads in various directions. Furthermore, by their curved nature, the protrusions and indentations provide lateral stability as well as act as vertical support surfaces.

[0071] The cavity 702 may also include a hole 725 that aligns with the hole 206 when the wear member 104 is positioned in the adapter 102. This alignment allows the locking pin to be inserted therethrough. In some examples, wear member 104 may include a single hole on one side of cavity, and in some examples, wear member 104 may include two holes, one on each side of cavity 702.

[0072] The cavity 702 also includes inwardly facing torque control surfaces 727a, 727c. The twist control surfaces 727b, 727d are shown in Figure 10. The inwardly facing twist control surfaces 727a, 727b, 727c, 727d are sized and shaped to fit against the twist control features 230a, 230b, 230c, 230d from adapter nose.

[0073] Figures 8 and 9 are cross-sectional views of the tooth with the protrusion. Figure 8 illustrates opposing vertically spaced inner walls 704e, 704g corresponding to walls 204e, 204g of nose 203. Figure 8 also illustrates opposing horizontally spaced inner walls 704f, 804h corresponding to walls 204f, 204h of nose 203 Figure 8 also illustrates the transversely angled inwardly facing walls 704a, 704b, 704c, 704d which correspond to the transversely angled outwardly facing walls 204a, 204b, 204c, 204d of nose 203.

[0074] Figure 10 is a rear view of the tooth examining inside the cavity 702. Looking inside the cavity, the surfaces 721a, 721b, 721c, 721d, 721e, 721f, 721g, 721h of the front portion 720 of the cavity 702 can be seen . Furthermore, the surfaces 723a, 723b, 723c, 723d, 723e, 723f, 723g, 723h of the intermediate portion 724 of the cavity 702 can be seen. Furthermore, surfaces 704a, 704b, 704c, 704d, 704e, 704g as well as protrusions 706, 707 can be seen.

[0075] While the concave support surface portions 210, 213 and protrusions 706, 707 are substantially elliptical in shape, some embodiments may have support surface portions and protrusions of polygonal shape. In some examples, the support surface portions may be positioned on the side surface near or adjacent the holes 206, 711 through which the locking pin is inserted. Because the protrusions 706, 707 are sized and shaped to match the size and shape of the concave support surface portions, the description of one applies equally to the other.

[0076] Although the indentations are depicted on the adapter 102 and the protrusions are depicted on the inner surfaces of the wear member 104, it should be noted that some implementations are oppositely arranged to have the protrusion on the adapter 102 and the indentations on the wear member 104.

[0077] The present description is also directed to a ground engaging wear member assembly that includes an adapter nose capable of being attached to a bucket lip and a tooth. The nose includes angled support surfaces arranged to be received in a cavity of the tooth. The cavity includes support surfaces that correspond with and engage the nose support surfaces. According to some examples, the adapter nose may include a front portion at the distal end of the nose and a rear portion at the proximal end of the nose. The rear portion may include eight substantially planar surfaces converging towards the longitudinal axis of the nose. The forward portion may also include eight substantially flat surfaces converging towards the longitudinal axis of the nose, but at a lower angle. In some implementations, both the front portion and the rear portion thus have substantially octagonal cross sections. In some implementations, in the rear portion, the horizontal and vertical surfaces of the octagon-shaped cross section may be non-support surfaces, and the angled surfaces (for example, the non-horizontal and non-vertical surfaces) may be support surfaces. In the front portion, the angled surfaces can also be support surfaces.

[0078] Figure 11A is an exploded perspective view of a ground engaging wear member assembly 10. According to the present example, the wear member assembly 10 includes a nose 1100 and a wear member 1200. An exemplary implementation of wear member 1200 is a tooth 1200. In another implementation, wear member 1200 is an intermediate adapter. Other wear members are contemplated. The nose 1100 includes a forward portion 1124 and a rear portion 1122. In the example shown, the nose 1100 extends from a base frame which is shown as a block, but represents any additional attachment structure which supports the nose including a bucket receiving portion having bifurcated adapter legs, similar to adapter 102 in Figure 1. In some implementations, the nose can be attached to a bucket lip of an excavator. The nose may form a part of an adapter or an intermediate adapter, and may also be referred to herein as a support structure, as it provides stabilizing support to an additional component, which in this implementation is the tooth 1200. The nose 1100 is also includes a hole 12 for receiving a locking pin. In the present example, the nose includes twist control features 18. The tooth 1200 also includes a hole 14 through which the locking pin can be inserted. Since any of a number of known locking pins can be employed here, locking pin details are not included. The tooth 1200 also includes a rearward facing cavity (not shown in Figure 11A) and a ground engaging end as a front end 16. A rod 1105 extends through the wear member assembly 10.

[0079] Figure 11B shows a view of the nose 1100 looking along the longitudinal axis 1105 of the nose 1100. Figure 11C shows a side view of the nose 1100 looking along a transverse axis 1107. The transverse axis 1107 is aligned at a position that would run parallel to an edge of the bucket flap (not shown). As described above, the nose 1100 attachable to a bucket lip and includes a front portion 1124 and a rear portion 1122. The rear portion 1122 includes a set of eight substantially planar surfaces. Particularly, the assembly includes a subassembly having a top surface 1108a and a bottom surface 1108b, a subassembly of two side surfaces 1106a, 1106b and a subassembly of four angled surfaces 1110a, 1110b, 1110c, 1110d. The top and bottom surfaces can be referred to as horizontal surfaces and the side surfaces can be referred to as vertical surfaces because these surfaces are both horizontal and vertical in cross section. The four angled surfaces 1110a, 1110b, 1110c, 1110d can be support surfaces arranged to contact and interact with tooth surfaces 1200. Because each support surface is angled, each support surface is able to resist both horizontal and vertical loading. Angled surfaces may also be referred to as diagonal or oblique surfaces. Both horizontal surfaces 1108a, 1108b and vertical surfaces 1106a, 1106b can be non-supporting surfaces.

[0080] In this exemplary implementation, each of the eight substantially planar surfaces converge towards the longitudinal axis 1105 of the nose 1100. In some examples, the angle of the eight substantially planar surfaces relative to the longitudinal axis 1105 may be within a range of about 5-25 degrees. In some examples, the angle may be within a range of about 8-15 degrees. Other ranges are also contemplated. In this implementation, top and bottom surfaces 1108a, 1108b may be wider than side surfaces 1106a, 1106b. Thus, the octagon-shaped cross section can be different in width 1132 than in height 1134. This helps with torsion control and stability.

[0081] In the exemplary implementation shown, the front portion 1124 also includes a set of eight substantially planar surfaces. Particularly, the assembly includes a subassembly having a top surface 1114a and a bottom surface 1114b, a subassembly of two side surfaces 1112a, 1112b, and a subassembly of four angled surfaces 1116a, 1116b, 1116c, 1116d. The four angled surfaces 1116a, 1116b, 1116c, 1116d can be support surfaces arranged to contact and interact with tooth surfaces 1200. Because each support surface is angled, each support surface is able to resist both horizontal and vertical loading. The top and bottom surfaces 1114a, 1114b can also be non-supporting surfaces. In some examples, side surfaces 1112a, 1112b can be support surfaces. In some examples, however, side surfaces 1112a, 1112b may be non-supporting surfaces. In some implementations, the non-supporting surfaces of either the front portion 1124 or the rear portion 1122 may not be substantially flat.

[0082] In some implementations, each of the eight substantially flat surfaces of the front portion 1124 converge towards the longitudinal axis 1105 of the nose 1100, but at an angle that is lower than the angle at which the eight substantially flat surfaces of the rear portion 1122 converge towards longitudinal axis 1105. In some examples, the angle of the eight substantially planar surfaces of front portion 1124 relative to longitudinal axis 1105 can be within a range of about 0-15 degrees. In some examples, the angle may be within a range of about 1-8 degrees. Additionally, the top and bottom surfaces 1114a, 1114b may be wider than the side services 1112a, 1112b. Thus, the octagon-shaped cross section is different in width 1132 than it is in height 1134. This also helps with stability and torsion control. In some examples, the ratio of the top or bottom surface width to the side surface width is different on the front portion 1124 than on the rear portion 1122. For example, the ratio of the top or bottom surface width to the side surface width may be greater at front portion 1124 than at rear portion 1122.

[0083] Figure 12A shows a view of tooth 1200 looking into cavity 1205. Figure 12B is a cross-sectional view of tooth 1200 along longitudinal axis 1105, taken along lines 12B-12B in Figure 12A. Cavity 1205 is formed at rear end 1209 of tooth 1200, extending longitudinally inwardly from rear end 1204. Cavity 1205 has support surfaces that correspond with and interact with nose support surfaces 1100. It also has a longitudinal axis 1105 and reference transverse axis 1107. Cavity 1205 also includes a front portion 1224 and a rear portion 1222. The rear portion 1222 includes an array of eight substantially planar surfaces. Therefore, in this exemplary implementation, the set of substantially planar surfaces includes a subset of having a top surface 1208a and a bottom surface 1208b, a subset of two side surfaces 1206a, 1206b, and a subset of four angled surfaces 1210a, 1210b, 1210c, 1210d. The four angled surfaces 1210a, 1210b, 1210c, 1210d can be support surfaces. Because each support surface is angled, each support surface is able to withstand the horizontal and vertical loading that can be applied to tooth 1200 during use. Both top and bottom surfaces 1208a, 1208b and side surfaces 1206a, 1206b can be non-supporting surfaces. In some examples, the non-supporting surfaces may not be substantially flat. For example, non-supporting surfaces can be curved.

[0084] The forward portion 1224 also includes a forward assembly of eight substantially planar surfaces. Particularly the forward assembly includes a subassembly having a top surface 1214a and a bottom surface 1214b, a subassembly of two side surfaces 1212a, 1212b, and a subassembly of four angled surfaces 1216a, 1216b, 1216c, 1216d. The four angled surfaces 1216a, 1216b, 1216c, 1216d can be support surfaces. Again, because each support surface is angled, each support surface is able to withstand both horizontal and vertical loading. Horizontal surfaces 1214a, 1214b can also be non-supporting surfaces. In some examples, vertical surfaces 1212a, 1212b can be support surfaces. In some examples, however, vertical surfaces 1212a, 1212b may be non-supporting surfaces.

[0085] Referring now to Figure 11C, the nose 1100 includes a rear surface 1101 and a front octagonal shaped abutment surface 1118. The front abutment surface 1118 may be octagonal in shape. Front abutment surface 1118 can be a mating surface since it is designed to make contact with a front abutment surface 1218 of cavity 1205 (shown in Figures 12A and 12B). Front abutment surface 1218 of cavity 1205 may also be octagonal in shape. The rear surface 1201 on the rear end 1109 of the tooth 1200 may or may not contact the rear surface 1101 of the nose 1100.

[0086] In some implementations, the nose 1100 and tooth 1200 can be designed symmetrically so that the tooth can rotate 180 degrees and still fit properly in the tooth. This allows the 1200 tooth to be reversed after some period of wear. Teeth 1200 can continue to be used in the inverted position. This extends the life of tooth 1200.

[0087] Figure 13 is a perspective view of the nose 1100. In addition to the substantially flat surfaces 1106a, 1106b, 1108a, 1108b, 1110a, 1110b, 1110c, 1110d, 1112a, 1112b, 1114a, 1114b, 1116a, 1116b, 1116c, 1116d, both the front portion 1124 and the rear portion 1122 may have curved surfaces positioned between the flat surfaces. In implementations having the rear surface 1101, the nose 1100 may include surfaces 1302 disposed between and transitioning from the rear surface 1101 to the eight substantially planar surfaces 1106a, 1106b, 1108a, 1108b, 1110a, 1110b, 1110c, 1110d of the rear portion 1122 The nose 1100 may also include elongated curved surfaces 1304 between adjacent edges of each of the flat surfaces 1106a, 1106b, 1108a, 1108b, 1110a, 1110b, 1110c, 1110d, 1112a, 1112b, 1114a, 1114b, 1116 a, 1116b, 1116c, 1116d on both the front portion 1124 and the rear portion 1122. The nose 1100 may also include curved surfaces 1306 positioned between the flat surfaces 1106a, 1106b, 1108a, 1108b, 1110a, 1110b, 1110c, 1110d of the rear portion 1122 and the flat surfaces of the rear portion 1122. nose 1124. Nose 1100 may also include curved surfaces 1308 positioned between front abutment surface 1118 and flat surfaces 1112a, 1112b, 1114a, 1114b, 1116a, 1116b, 1116c, 1116d of front portion 1124. In some implementations, these surfaces Curves can be fillet or round to minimize location stress during use. Curved surfaces can also help provide clearance for the wear member cavity.

[0088] In some examples, the cross-section width W1 of the top and bottom non-supporting surfaces 1108a, 1108b is different at the distal end 1307 of the rear portion 1122 than the cross-section width W3 at the proximal end 1305 of the portion 1122. For example, the cross-section width W1 of the top and bottom non-supporting surfaces 1108a, 1108b may be less at the distal end 1307 of the rear portion 1122 than the cross-section width W3 at the proximal end 1305 of the rear portion 1122. rear 1122 or vice versa. Furthermore, the cross-section width W2 of the support surfaces 1110a, 1110b, 1110c and 1110d at the distal end 1307 of the rear portion 1122 may be different from the cross-section width W4 at the proximal end 1305. For example, the cross-section width W2 of support surfaces 1110a, 1110b, 1110c and 1110d at distal end 1307 of rear portion 1122 may be less than cross-sectional width W4 at proximal end 1305 or vice versa. Furthermore, the cross-section width W1 of the top and bottom surfaces 1108a, 1108b at the distal end 1307 of the rear portion 1122 may be different from the cross-section width W2 of the support surfaces 1110a, 1110b, 1110c, 1110d at the distal end 1307 of the rear portion 1122. For example, the cross-section width W1 of the top and bottom surfaces 1108a, 1108b at the distal end 1307 of the rear portion 1122 may be less than the cross-section width W2 of the support surfaces 1110a, 1110b, 1110c, 1110d at the distal end 1307 of the rear portion 1122 or vice versa. Furthermore, the cross-section width W3 of the top and bottom surfaces 1108a, 1108b at the proximal end 1305 of the rear portion 1122 may be different from the cross-section width W4 of the support surfaces 1110a, 1110b, 1110c, 1110d at the proximal end 1305 of the rear portion 1122. For example, the cross-section width W3 of the top and bottom surfaces 1108a, 1108b at the proximal end 1305 of the rear portion 1122 may be greater than the cross-section width W4 of the support surfaces 1110a, 1110b, 1110c, 1110d at the proximal end 1305 of the rear portion 1122 or vice versa.

[0089] Figure 14A shows a view of an illustrative adapter nose 1400 with twist control features 1402a, 1402b, 1402c, 1402d that resist twisting movement of wear member 1200 relative to nose 1100. Figure 14B shows a side view of the 1400 adapter nose with twist control capabilities. Figure 14C is a perspective view of adapter nose 1400 with twist control features. Figure 14D is a top view of adapter nose 1400 with torque control features. In the exemplary implementation shown, adapter nose 1400 includes the angled support surfaces described with reference to Figures 11A, 11B, 11C and 13. For convenience, these support surfaces will not be described again with reference to Figures 14A, 14B, 14C and 14D. The twist control features 1402a, 1402b, 1402c, 1402d comprise projections extending from the nose 1400. Each of the twist control features includes a flat vertical outward facing surface 1404a, 1404b, 1404c, 1404d. Twist control features 1402a, 1402b, 1402c, 1402d are positioned near the rear end of adapter nose 1400. Twist control features 1402a, 1402b, 1402c, 1402d are also positioned such that vertical surfaces 1404a, 1404b, 1404c, 1404d intersect the angled support surfaces 1110a, 1110b, 1110c, 1110d of the nose 1400. As illustrated in Figure 14D, the vertical surfaces 1404a, 1402b, 1402c, 1404d are tapered towards the longitudinal axis. This allows tooth 1200 to be removed from nose 1100 more easily.

[0090] As best seen in the side view of Figure 14B, the twist control features 1402a, 1402b, 1402c, 1402d are contained within the boundary created by the flat surfaces 1108a and 1108b. In the exemplary embodiment shown, adapter nose 1400 includes torque control features 1402a, 1402b disposed in an upper portion and includes torque control features 1402c, 1402d disposed in a lower portion. In some implementations, adapter nose 1400 includes twist control features on only one of the top portion or the bottom portion. Furthermore, in the implementation shown, the twist control features 1402a, 1402b are shown vertically aligned with the twist control features 1402c, 1402d. In some implementations, twist control features are not vertically aligned.

[0091] Figure 15 is a diagram showing a tooth 1500 having a cavity 1505 designed to fit an adapter nose, such as adapter nose 1400, with twist control features, such as twist control features 1402a, 1402b, 1402c, 1402d. Cavity 1505 can include a number of pockets 1502a, 1502b, 1502c, 1502d. Pouches 1502a, 1502b, 1502c, 1502d may be designed to receive the twist control features 1402a, 1402b, 1402c, 1402d of adapter nose 1400. In the exemplary implementation shown, pockets 1502a, 1502b, 1502c, 1502d include facing surfaces inward, vertical, flat, 1504a, 1504b, 1504c, 1504d corresponding to vertical surfaces 1404a, 1404b, 1404c, 1404d of adapter nose 1400. Thus, vertical surfaces 1404a, 1404b, 1404c, 1404d of nose 1400 are designed to engage and interact with the vertical surfaces 1504a, 1504b, 1504c, 1504d of the tine 1500 so as to resist twisting motion between the nose 1400 and the tine 1500. The tine 1500 may have, as indicated with reference to Figures 12A and 12B, planar support surfaces that interact with planar support surfaces on the adapter nose 1400.

[0092] Figure 16A shows a cross section of adapter nose 1100 orthogonal to the longitudinal axis (eg, 1105, Figure 11B) in an assembled condition. Accordingly, Figure 16A also illustrates the cross-section of tooth 1200. As illustrated, angled support surfaces 1110a, 1110b, 1110c, 1110d of nose 1100 mate against angled support surfaces 1210a, 1210b, 1210c, 1210d of tooth 1200 These angled support surfaces minimize or prevent vertical and lateral movement of the tooth 1200 relative to the adapter nose 1100. In some examples, there may be a gap between the horizontal non-support surfaces 1108a, 1108b of the nose and the non-support surfaces 1108a, 1108b. horizontal supports 1208a, 1208b of tooth 1200. Likewise, there may be a gap between the vertical non-support surfaces 1106a, 1106b of the nose and the vertical non-support surfaces 1206a, 1206b of tooth 1200. However, in some examples, the non-supporting surfaces of both the nose 1100 and the tooth 1200 can contact when the tooth 1200 is fitted over the nose 1100. Due to the angled support surfaces, both vertical movement and lateral movement can be minimized.

[0093] Figure 16B shows a cross section orthogonal to the longitudinal axis of the adapter nose 1400 with torque control features. As described above, the vertical surfaces 1404a, 1404b, 1404c, 1404d of the 1400 nose fit the 1504a vertical surfaces, 1504b, 1504c, 1504d of the 1500 tooth. to resist twisting and twisting between nose 1400 and tooth 1500. This can help stabilize tooth 1500 on adapter nose 1400 during use.

[0094] Figure 16C shows a cross section of the front portion of the adapter nose 1100. Figure 16C also illustrates the cross section of the tooth 1200. As illustrated, the angled support surfaces 1116a, 1116b, 1116c, 1116d of the nose 1100 fit against the angled support surfaces 1216a, 1216b, 1216c, 1216d of the tooth 1200. In some examples, there may be a gap between the horizontal non-support surfaces 1114a, 1114b of the nose and the horizontal non-support surfaces 1214a, 1214b of the tooth 1200 In the present example, the vertical surfaces 1112a, 1112b of the nose 1100 and the vertical surfaces 1212a, 1212b of the tooth 1200 are support surfaces and therefore there is no gap between them. In some examples, however, there may be a gap between the vertical surfaces 1112a, 1112b of the nose 1100 and the vertical surfaces 1212a, 1212b of the tooth 1200. In this exemplary implementation, the angled support surfaces 1116c and 1116d are adjacent, but do not part of, a bottom surface 1114b of the adapter nose 1100. This angled design can, in some cases, extend the life of the adapter nose 1100. It is not uncommon during use for an operator to wear down a bottom portion of a tooth, inadvertently exposing and eroding a bottom surface of the adapter nose 1100. In conventional systems that utilize a lower surface of an adapter nose as a support surface, this can adversely affect the stability of a subsequent tooth positioned on the adapter nose. A worn support surface can introduce wobble, further accelerating wear, and potentially permanently damaging the adapter nose. However, the exemplary implementation described herein includes support surfaces on angled bottom surfaces, rather than a horizontal bottom surface. Because of this, if an operator inadvertently wears down a portion of a bottom surface of the adapter nose, the angled support surfaces can still provide stability to the tooth in both the horizontal and vertical directions. This can increase the life of the adapter nose because the tooth can be properly supported even with a worn bottom surface of the adapter nose.

[0095] Figure 16D illustrates a cross section of adapter nose 1450 with offset twist control features. For example, surface 1454a is offset from surface 1454c. Likewise, surface 1454b is offset from surface 1454d. The tooth 1550 includes mating surfaces 1554a, 1554b, 1554c, 1554d. The offsets are such that tooth 1550 can still be flipped upside down and engage nose 1450. In other words, tooth can be engaged with adapter nose 1450 in two rotational positions.

[0096] Although described as having eight flat surfaces, some implementations of the adapter noses and teeth described herein include four angled flat surfaces and less than four vertical or horizontal flat surfaces. In some implementations, the adapter noses and teeth described herein include a round or arched outer surface connecting two adjacent flat angled surfaces. For example, some implementations do not include the vertical side, with rounds connecting adjacent surfaces 106a and 1106b. In these implementations, surfaces 1106a and 1106b can be replaced with a round surface connecting planar support surfaces 1110a and 1110c. The tooth can be formed to match. In some implementations, the adapter nose can be formed with eight flat surfaces, but the tooth cavity, like cavity 1205, can be formed with only six flat surfaces. In some examples, the vertical surfaces 1206a and 1206b described herein may be round, while the cavity 1205 may further be formed to engage and engage the flat angled support surfaces of the adapter nose.

[0097] US Provisional Application No. 62/441,756 filed January 3, 2017 and entitled "Attachment Spring Connector for a Ground Engagement Wear Member Assembly" and US Provisional Application No. 62/335,424 filed May 12, 2016 and entitled "Fastener for a Wear Member Assembly", are hereby incorporated by reference in their entirety.

[0098] Persons of ordinary skill in the art will appreciate that the implementations encompassed by the present disclosure are not limited to the particular exemplary implementations described above. In this regard, although illustrative implementations have been shown and described, a wide range of modification, change, combination and substitution is contemplated in the foregoing disclosure. It is to be understood that such variations can be made to the foregoing without departing from the scope of the present disclosure. Therefore, it is appropriate that the appended claims be interpreted broadly and in a manner consistent with the present disclosure.

Claims (15)

1. Thinning member assembly characterized by comprising: a pluggable nose in a vessel shoulder comprising: a rear portion having a first set of surfaces converging towards a longitudinal axis of the nose towards a distal end of the rear portion, the first set of surfaces comprising: a first subset of surfaces having an upper and lower surface; a second subset of side surfaces; and a third subset of surfaces angled and positioned between the first subset of surfaces and the second subset of surfaces; and a front portion positioned in advance of the rear portion, the front portion has a second set of surfaces converging towards the longitudinal axis of the nose towards the distal end of the front portion, the second set of surfaces comprising: a fourth subset which has a top and bottom surface; a fifth subset of side surfaces; and a sixth subset of surfaces angled and positioned between the first subset of surfaces and the second subset of surfaces; and an intermediate portion disposed between the rear portion and the front portion, the intermediate portion comprising a number of surfaces in cross-section that is different from a number of surfaces of the front portion in cross-section and the rear portion in cross-section; a trimming member having a recess with opening for a rear end, the recess comprising bearing surfaces corresponding at least to some surfaces of the rear and forward portions of the nose. 2. Set according to claim 1, characterized in that the third subset of surfaces and the sixth subset are arranged to resist horizontal and vertical load. 3. Set according to claim 1, characterized in that it comprises an octagonal-shaped resistance surface at the distal end of the nose. 4. Assembly according to claim 1, characterized in that the first subset of surfaces are longer in a perpendicular direction on the longitudinal axis than the second subset of surfaces. 5. Set according to claim 1, characterized in that the fourth subset of surfaces is longer in a direction perpendicular to the longitudinal axis than the second subset of surfaces. 6. Set according to claim 1, characterized in that it comprises a set of four projections extending from the third subset of surfaces. 7. Assembly according to claim 6, characterized in that the projections have vertical facing surfaces externally arranged to resist torsional movement of the roughing member. 8. Assembly, according to claim 6, characterized in that each of the projections is aligned with each other. 9. Assembly, according to claim 6, characterized in that two of the projections are offset from the other two projections that the thinning member is fitable with the nose in two rotational positions. Assembly according to claim 1, characterized in that it comprises curved surfaces positioned between each of the surfaces within the first set of surfaces. Assembly according to claim 1, characterized in that the second set of surfaces have a shallower angle with respect to the longitudinal axis than the first set of surfaces. 12. Member according to claim 1, characterized in that the trimming member is connectable to the nose in two rotational positions. Member according to claim 1, characterized in that the roughing member includes a roughing member on an outer surface of the roughing member, the roughing member comprises an excavation. 14. A wear element assembly according to claim 1, characterized in that the first subset of surfaces comprises bearing surfaces. A wear element assembly according to claim 1, characterized in that the second subset of surfaces comprises unsupported surfaces.