The present disclosure relates to a dragline bucket and a machine including the dragline bucket.
Machines, such as dragline excavators, typically include a dragline bucket associated therewith. The dragline bucket may be used in mining and earth moving operations. For example, the dragline bucket may be used to capture materials such as rocks/aggregate, or other large finds. The dragline bucket is suspended from a boom of the machine by a rigging assembly. The dragline bucket is maneuvered by means of the rigging assembly.
An amount of material that can be carried by the dragline bucket is typically governed by a volume of the dragline bucket. Further, the volume of the dragline bucket may vary based on a shape of the dragline bucket. Conventionally, the dragline bucket includes a pair of side walls, a base member, and an end wall/rear wall. The end wall of the bucket is generally curved. Such a curved profile of the end wall may reduce the volume of the dragline bucket. Reduction in the volume may in turn reduce a productivity at a worksite as the conventional dragline bucket may hold reduced amount of material therein, which is not desirable.
U.S. Pat. No. 10,544,562 describes a dragline bucket including a base member. A first side member extends from the base member. The dragline bucket further includes a first top edge. A second side member extends from the base member. Further, a rear member extends from the base member. Further, the dragline bucket includes a second top edge, a mouth for receiving material into the bucket. The dragline bucket includes a first beveled wall extending from the first side member forming a first compound angle with the base member. Moreover, a second beveled wall extends from the rear member proximate the first beveled wall forming a second compound angle with the base member.
In an aspect of the present disclosure, a dragline bucket is provided. The dragline bucket includes a base member defining a first end, a second end, and a third end. The dragline bucket also includes a first side wall extending from the base member proximate to the first end of the base member. The first side wall defines a first edge that is distal to the base member. The dragline bucket further includes a second side wall extending from the base member proximate to the second end of the base member. The first side wall is laterally spaced apart from the second side wall. The second side wall defines a second edge that is distal to the base member. The dragline bucket includes an end wall extending from the base member proximate to the third end of the base member such that the end wall is connected to each of the first side wall and the second side wall. The base member, the first side wall, the second side wall, and the end wall define a material receiving portion of the dragline bucket. The end wall includes a first portion connected to the base member. The first portion is disposed such that a first angle is defined between the base member and the first portion. The end wall also includes a second portion extending from the first portion. The second portion is substantially perpendicular to the base member. The end wall further includes a third portion extending from the second portion such that the second portion is disposed between the first portion and the third portion. The third portion is disposed such that a second angle is defined between the second portion and the first portion.
In an aspect of the present disclosure a machine is provided. The machine includes a boom. The machine also includes a rigging assembly adapted to be coupled to the boom. The machine further includes a dragline bucket adapted to be coupled to the rigging assembly. The dragline bucket includes a base member defining a first end, a second end, and a third end. The dragline bucket also includes a first side wall extending from the base member proximate to the first end of the base member. The first side wall defines a first edge that is distal to the base member. The dragline bucket further includes a second side wall extending from the base member proximate to the second end of the base member. The first side wall is laterally spaced apart from the second side wall. The second side wall defines a second edge that is distal to the base member. The dragline bucket includes an end wall extending from the base member proximate to the third end of the base member such that the end wall is connected to each of the first side wall and the second side wall. The base member, the first side wall, the second side wall, and the end wall define a material receiving portion of the dragline bucket. The end wall includes a first portion connected to the base member. The first portion is disposed such that a first angle is defined between the base member and the first portion. The end wall also includes a second portion extending from the first portion. The second portion is substantially perpendicular to the base member. The end wall further includes a third portion extending from the second portion such that the second portion is disposed between the first portion and the third portion. The third portion is disposed such that a second angle is defined between the second portion and the first portion.
Wherever possible, the same reference numbers will be used throughout the drawings to refer to same or like parts.
The machine 100 includes a house 104. The machine 100 further includes a power source (not shown) supported by the house 104. The power source may supply power to various components of the machine 100 for operation, movement, and the like. In one example, the power source may include an engine, such as a diesel engine, a gasoline engine, a gaseous fuel-powered engine, or any other type of combustion engine known in the art. In other examples, the power source may include an electric drive assembly having an electric motor (not shown).
The machine 100 includes a boom 106. The boom 106 is controlled by a suspension system 108 connected to a mast 110 and a gantry frame 112. The machine 100 further includes a rigging assembly 114 coupled to one or more hoist ropes 116. Moreover, the machine 100 includes the dragline bucket 102 coupled to the rigging assembly 114. The rigging assembly 114 includes a drag socket 118 and one or more drag ropes 120. The hoist ropes 116 pass over a boom point sheave 122 of the boom 106 and suspends the dragline bucket 102 therefrom. Further, the dragline bucket 102 is coupled to the drag ropes 120 by the drag socket 118.
The base member 142 defines a fourth end 160 proximate to the mouth portion 158. The fourth end 160 of the base member 142 is covered by various devices such as edge protectors or shrouds 164 and ground engaging tools 166. The ground engaging tools 166 may be attached to the fourth end 160 using tool adapters (not shown). In other embodiments, the base member 142 may include a continuous edge protector proximate to the fourth end 160 of the base member 142. Alternatively, any form of protection proximate to the fourth end 160 may be omitted. Moreover, the base member 142 includes a number of wear bars 168. The wear bars 168 extend from a bottom surface 170 of the base member 142.
The dragline bucket 102 includes the first side wall 150 extending from the base member 142 proximate to the first end 144 of the base member 142. The first side wall 150 defines a first edge 172 that is distal to the base member 142. The first edge 172 is a top edge of the first side wall 150. Further, a curvature (not shown) is defined between the first side wall 150 and the base member 142. The dragline bucket 102 also includes the second side wall 152 extending from the base member 142 proximate to the second end 146 of the base member 142. The first side wall 150 is laterally spaced apart from the second side wall 152. The second side wall 152 defines a second edge 174 that is distal to the base member 142. The second edge 174 is a top edge of the second side wall 152. Further, a curvature 176 is defined between the second side wall 152 and the base member 142.
Further, each of the first side wall 150 and the second side wall 152 includes the trunnion attachment structure 128 disposed proximate to the end wall 154. The trunnion attachment structure 128 associated with the first side wall 150 is illustrated herein. However, it should be noted that the trunnion attachment structures 128 associated with each of the first and second side walls 150, 152 have a similar design. The trunnion attachment structure 128 is coupled with a portion (described as the lower hoist chains 130 shown in
Moreover, each of the first and second side walls 150, 152 includes a bracket member 188. The bracket members 188 are disposed proximate to the mouth portion 158. The bracket members 188 define an opening 190 that allows connection of the dragline bucket 102 with the drag chains 136. Further, an arch portion 192 is disposed between the first side wall 150 and the second side wall 152. The arch portion 192 includes an attachment structure 194 that allows coupling of the dragline bucket 102 with the dump rope 138.
Further, each of the first side wall 150, the second side wall 152, and the end wall 154 defines a number of perforations 196. As illustrated, the perforations 196 in the first side wall 150 and the second side wall 152 are provided proximate to the end wall 154 of the base member 142. In some examples, the base member 142 may also include the perforations 196. When the dragline bucket 102 is used to excavate material 157 from water bodies, excess liquid contained in the dragline bucket 102 may drain out of the dragline bucket 102 via the perforations 196. In this embodiment, the perforations 196 are depicted as circular holes. In other embodiments, the perforations 196 may be embodied as slots. In some embodiments, the dragline bucket 102 may omit the perforations 196.
The dragline bucket 102 includes the end wall 154 extending from the base member 142 proximate to the third end 148 of the base member 142 such that the end wall 154 is connected to each of the first side wall 150 and the second side wall 152. As illustrated, a curvature 198 is defined between each of the first and second side walls 150, 152 and the end wall 154. The end wall 154 defines a third edge 200 proximate to the base member 142 and a fourth edge 202 distal to the base member 142. The fourth edge 202 is connected to each of the first edge 172 of the first side wall 150 and the second edge 174 of the second side wall 152.
Further, the end wall 154 includes a second portion 214 extending from the first portion 208. The second portion 214 is substantially perpendicular to the base member 142. Further, the second portion 214 includes the perforations 196. The second portion 214 defines a second inner surface 216 (shown in
Further, the end wall 154 includes a third portion 220 extending from the second portion 214 such that the second portion 214 is disposed between the first portion 208 and the third portion 220. The third portion 220 is disposed such that a second angle “A2” is defined between the second portion 214 and the third portion 220. The second angle “A2” ranges from 170 degrees to 180 degrees. In some examples, the second angle “A2” ranges from 175 degrees to 180 degrees. The third portion 220 defines a third inner surface 222 (shown in
Further, the second portion 214 includes the perforations 196. The third portion 220 defines the fourth edge 202 of the end wall 154 that is connected to each of the first edge 172 of the first side wall 150 and the second edge 174 of the second side wall 152. Further, in the illustrated example, each of the first portion 208, the second portion 214, and the third portion 220 of the end wall 154 includes a substantially planar profile. The planar profile relates to the inner surfaces 210, 216, 222 and the outer surfaces 212, 218, 224 of the first, second, and third portions 208, 214, 220. More particularly, the inner surfaces 210, 216, 222 and the outer surfaces 212, 218, 224 of the first, second, and third portions 208, 214, 220 are embodied as flat surfaces. Each of the first portion 208, the second portion 214, and the third portion 220 is embodied as a substantially rectangular plate.
Further, the dragline bucket 102 may hold an amount of the material 157 in the material receiving portion 156. The amount of the material 157 held in the dragline bucket 102 may be adjudged by a struck capacity “Sc” of the dragline bucket 102 or a rated capacity “Rc” of the dragline bucket 102. The struck capacity “Sc” may be defined as an actual measured or calculated box volume of the dragline bucket 102. The struck capacity “Sc” may relate to a volume of the material receiving portion 156 between a first line “L1” and the end wall 154. Further, the rated capacity “Rc” may relate to a volume of the material receiving portion 156 between a second line “L2” and the end wall 154. When the material 157 is received within the material receiving portion 156, an angle of repose “A3” is defined by a heap of the material 157. The angle of repose “A3” may be defined as an angle formed by the material 157 proximate to the mouth portion 158. The angle of repose “A3” may be measured between the first line “L1” and the second line “L2”.
In the equation (1), “Ha” is an average inside height of the dragline bucket 102, “L” (shown in
In the equation (2), “Wb” is an inside width of the base member 142 (see
In the above equation (3), the factor “0.9” expresses a 10% loss of the struck capacity “Sc” due to the angle of repose “A3” (see
The present disclosure relates to the dragline bucket 102 that may be associated with a number of different machines. The dragline bucket 102 includes an improved design that may lead to an increase in the struck capacity “Sc” and therefore the rated capacity “Rc” of the dragline bucket 102. More particularly, the dragline bucket 102 includes the end wall 154 having an improved design. The end wall 154 includes a tight wall profile. The design of the first portion 208, the second portion 214, and the third portion 220 of the end wall 154 may collectively reduce the form factor “F” which may in turn increase the struck capacity “Sc” and the rated capacity “Rc” of the dragline bucket 102. In an example, a total volume deduction in the form factor “F” observed in the dragline bucket 102 described herein may be less than 3%. Further, in some examples, the design of the first portion 208, the second portion 214, and the third portion 220 may increase the total volume of the dragline bucket 102 by 2% to 10%, however, this value may vary based on a size of the dragline bucket 102. Further, the increase in the struck capacity “Sc” and the rated capacity “Rc” of the dragline bucket 102 may in turn increase a productivity of operations that employ the dragline bucket 102 described herein.
While aspects of the present disclosure have been particularly shown and described with reference to the embodiments above, it will be understood by those skilled in the art that various additional embodiments may be contemplated by the modification of the disclosed machines, systems and methods without departing from the spirit and scope of what is disclosed. Such embodiments should be understood to fall within the scope of the present disclosure as determined based upon the claims and any equivalents thereof.
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Number | Date | Country |
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2008202822 | Jul 2014 | AU |
39147 | Jul 2004 | RU |
Number | Date | Country | |
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20210395973 A1 | Dec 2021 | US |