The present invention relates to crushing devices and, more particularly, to a modular bottom shell for gyratory crushers and/or cone crushers.
Crushing devices, such as cone crushers and gyratory crushers, are typically used to crush rock, ore or minerals. Crushers may form a circuit of a process configured to crush material from a first size to a smaller size. After the material is crushed, the material may be moved to a grinding circuit for grinding the material to an even smaller size.
One type of crushing device that is commonly used is a cone crusher, which typically breaks rock by squeezing the rock between an eccentrically gyrating spindle and an enclosing concave hopper. As rock enters the top of the cone crusher, it becomes wedged and squeezed between the mantle and the bowl liner or concave. Large pieces of ore or rock are broken and then fall to a lower position (because they are now smaller) where they are broken again. This process continues until the pieces are small enough to fall through a narrow opening at the bottom of the crusher. The crusher head of cone crushers is typically guided by an eccentric assembly to actuate movement of the head for crushing material. It can be appreciated that there are generally two types of cone crusher designs. One in which the concave hopper can be adjusted in position relative to the gyrating spindle to adjust for wear and change product size. The other type is designed such that the gyrating spindle can be raised and lowered.
Gyratory crushers are also well established machines that are used for crushing rocks, ore, and other materials. A gyratory crusher is a cone crusher designed for very large feed. The gyratory crusher is usually the first stage of size reduction equipment in a mining operation. They are very large and their basic structure comprises a bowl shaped as a cone with the wider end of the cone near the top of the crusher. A conical head assembly is located on the axis of the bowl, and the head assembly is oriented so that its smaller dimension is at the top of the crusher. To perform the crushing action gyratory motions are applied to the conical head assembly.
In the typical gyratory crusher, large material is fed into the top of the crusher between the large opening of the bowl and the small end of the head assembly where the volume is largest. The gyration of the head assembly is furnished by an eccentric assembly, the rotation of which is driven by a gear. Vertical support and minor vertical adjustment of the head assembly is furnished by a hydraulic support assembly. These parts are typically located at the bottom of the crusher, and more specifically they are located at the bottom of the conical head assembly. The gyration applies forces that crush the pieces of material, and they fall lower into the reduced space within the bowl as they are reduced in size. Ultimately, the material leaves the crusher through openings at the bottom of the crusher.
Gyratory and cone crushers typically are constructed from large steel castings. However, suppliers for such castings are limited, which can result in long lead times and potentially lost orders. In addition, large steel castings are expensive and can be difficult to transport to job sites.
Accordingly, it can be would be desirable to replace the traditional large steel casting with a modular casting, which includes a central hub and a plurality of modular shells having a vertical split therein and upon assembly thereof form a modular bottom shell or mainframe for use with gyratory and/or cone crushers.
In accordance with an exemplary embodiment, a modular bottom shell of a multi-shell crusher device, the shell comprises a central hub having a centered cylindrical support hole and at least two support arms extending orthogonally from the centered cylindrical support hole, each support arm having an end plate, and wherein at least one of the two support arms has an orthogonal bore therein which extends from within the centered cylindrical support hole to an outer portion of the support arm; and at least two outer shell sections having an annular inner surface, and wherein each of the outer shell sections has an upper surface and a lower surface, the upper and lower surfaces extending from one end of the outer shell section to the other end of the outer shell, and a first vertical end plate on one end of the outer shell section and a second vertical end plate on the other end of the outer shell section, and wherein each vertical end plate has at least one bore therein, which has a corresponding bore within one of the end plates of the support arm.
In accordance with another exemplary embodiment, a modular bottom shell of a multi-shell crusher device, the shell comprises: a central hub having at least two support arms extending orthogonally from the centered cylindrical support hole, and wherein each support arm has an end plate; and a plurality of outer shell sections having an annular inner surface, and wherein each of the outer shell sections has an upper surface and a lower surface, the upper and lower surfaces extending from one end of the outer shell section to the other end of the outer shell, and a first vertical end plate on one end of the outer shell section and a second vertical end plate on the other end of the outer shell section, and wherein each vertical end plate has at least one bore therein, which has a corresponding bore within one of the end plates of the support arm.
In accordance with a further exemplary embodiment, a method of assembling a modular bottom shell for a multi-shell crusher device comprises the steps of providing a central hub having at least two support arms extending orthogonally from the centered cylindrical support hole, and wherein each support arm has an end plate; and securing a plurality of outer shell sections to the end plates of the at least two support arms, wherein each of the outer shell sections has an upper surface and a lower surface, and a first vertical end plate on one end of the outer shell section and a second vertical end plate on the other end of the outer shell section, and wherein each vertical end plate has at least one bore therein, which has a corresponding bore within one of the end plates of the support arm.
Other details, objects, and advantages of the invention will become apparent as the following description of certain present preferred embodiments thereof and certain present preferred methods of practicing the same proceeds.
Present preferred embodiments of crushing devices, such as gyratory crushers, crushing circuits or cone crushers, and methods of making and/or assembly of such devices are shown in the accompanying drawings in which:
Reference will now be made in detail to the present preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the description to refer to the same or like parts.
The head assembly 120 is located adjacent to an eccentric assembly 130 which is rotated by a ring gear. In accordance with an exemplary embodiment, the eccentric assembly 130, within which the lower portion of a main shaft is held, imparts to the head assembly 120 an eccentric motion, essentially a gyration, for the crusher 100 to function. The motion is imparted to the head assembly 120 by the eccentric assembly 130 that has an eccentric center volume, although the eccentric assembly 130 is itself cylindrical and mounted in a centered cylindrical support hole within a center hub. The eccentric assembly 130 along with the annular shell 110 is part of the bottom support structure of crusher 100. The eccentric assembly 130 rotates about the centered cylindrical support hole and, as eccentric assembly 130 rotates, its eccentric center volume moves the bottom end of mainshaft in an eccentric path imparting the gyratory motion to head assembly 120.
As shown in
As shown in
In accordance with an exemplary embodiment, at least one of the two support arms 230, 240 has an orthogonal bore 232 therein and which extends from within the central hub 210 to an outer portion of the support arm 230, 240. The at least one orthogonal bore 232 is preferably configured to house a drive shaft, which imparts to the head assembly 120 (
In accordance with another exemplary embodiment, each of the two support arms 230, 240 has an orthogonal bore 232 therein which extends from within the central hub 210 to an outer portion of the support arms 230, 240. As shown in
As shown in
Each of the outer shell sections (or horizontal sections) 270, 280 also preferably include a first vertical end plate 279, 289 on one end and a second vertical end plate (not shown) on the other end. Each vertical end plates has one or more bores (or holes) 253 therein, which is configured to receive a fastener 290, which extends through a corresponding bore (or hole) 255 on each of the vertical plates 252, 254 of the central hub 210 when the modular bottom shell 200 is assembled. It can be appreciated that in accordance with an exemplary embodiment, the outer lower shell sections 270, 280 are identical, such that each of the outer lower shell sections 270, 280 is interchangeable with other outer lower shell sections 270, 280.
In accordance with an exemplary embodiment, the at least two outer shell sections 270, 280 have an C-shaped cross-sectional configuration, which extends from the upper member (or upper plate) 272, 282 to the lower member (or lower plate) 276, 286. In addition, the at least two outer shell sections 270, 280 preferably include at least one support rib (or gusset plate) 292, which extends from an underside of the upper member (or upper plate) 272, 282 to an upper surface of the lower member (or lower plate) 276, 286. It can be appreciated that the at least one support rib (or gusset) can have any suitable configuration and/or shape to provide further structural support to the modular bottom shell 200. For example, in accordance with an exemplary embodiment, each of the outer shell sections 270, 280 includes a central support rib 294 and a pair of outer support ribs 296, 298, which extend from the upper member (or upper plate) 272, 282 to the lower member (or lower plate) 276, 286 and have a generally triangular profile or shape.
In accordance with an exemplary embodiment, upon assembly of the central hub 210 and the at least two outer shell sections 270, 280, the upper horizontal plate member 256, 266 of the end plate 250, 260, and the horizontal upper surfaces 274, 284 of the at least two outer shell sections 270, 280 form an annular ring having a relatively flat and/or smooth upper surface.
In accordance with an exemplary embodiment, at least one of the three support arms 320, 330, 340 has a bore 342 therein which extends orthogonally (or outward) from the central hub 310 to an outer portion of the support arm 320, 330, 340, and which is configured to receive a drive shaft (not shown). Each support arm 320, 330, 340 preferably has at least one end plate 350, 360, 370 attached thereto, and preferably includes at least one vertical plate member 352, 362, 372, 374. Each of the vertical plate members 352, 362, 372, 374 preferably includes one or more bores (or holes) 356, 366, 376, which extend therethrough and are configured to receive a fastener 290.
As shown in
In accordance with an exemplary embodiment, the outer shell sections (or modular sections) 380 have an inner surface 382, which is preferably annular in shape from side to side and a conical shape from an upper edge to a lower edge. As shown in
As shown in
In accordance with an exemplary embodiment, each of the outer shell sections 380 have a first vertical end plate 391 on one end and a second vertical end plate 393 on the other end. Each vertical end plate 391, 393 has one or more bores (or holes) therein, which is configured to receive a fastener 290, which extends through a corresponding bore (or hole) of each of the vertical plates 352, 362, 372, 374 of the central hub 310 when the modular bottom shell 300 is assembled.
In accordance with an exemplary embodiment, the outer shell sections 380 have an C-shaped cross-sectional configuration, which extends from the upper member (or upper plate) 384 to the lower member (or lower plate) 386. In addition, the outer shell sections 380 preferably include at least one support rib (or gusset plate) 395, 397, which extends from an underside of the upper member (or upper plate) 384 to an upper surface of the lower member (or lower plate) 386. It can be appreciated that the at least one support rib (or gusset plate) can have any suitable configuration and/or shape to provide further structural support to the modular bottom shell 300. For example, in accordance with an exemplary embodiment, each of the outer shell sections 380 includes a pair of support ribs (or gusset plates) 395, 397, which extend from the upper member (or upper plate) 384 to the lower member (or lower plate) 386 and have a generally triangular shape.
In accordance with an exemplary embodiment, upon assembly of the central hub 310 and the outer shell sections 380, the upper horizontal plate member (or portion thereof) of each of the end plate 350, 360, 370, and the outer shell sections 380 form an annular ring having a relatively flat and/or smooth upper surface.
In accordance with an exemplary embodiment, the central hub 210, 310 and the at least two outer shell sections 270, 280, 380 are secured via a bolting and shear connection type system 500 as shown in
In accordance with another exemplary embodiment, the bottom modular shell 200, 300 is a mainframe component for a Symons style crusher that utilizes vertical splits/multi-piece lower section in addition to horizontal ring upper portion. The bottom modular shell 200, 300 is preferably attachable to one or more shells and/or structures upon assembly having a bowl shaped configuration such that upon assembly, the bottom modular shell 200, 300 is a component of a crusher device having a cone with its wider opening approaching a top of the bowl.
It should be understood that a customer may be provided with a gyratory crusher such as a cone crusher in one sale. Thereafter, a customer may be told of a method of retrofitting that cone crusher or other gyratory crusher to form a cone crusher as shown in
It is to be understood that the form of this invention as shown is merely a preferred embodiment. Various changes may be made in the function and arrangement of parts; equivalent means may be substituted for those illustrated and described; and certain features may be used independently from others without departing from the spirit and scope of the invention as defined in the following claims.
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Entry |
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International Search Report and Written Opinion dated Feb. 21, 2012, 8 pages. |
Number | Date | Country | |
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20120091241 A1 | Apr 2012 | US |