This application pertains to crushers, particularly gyratory crushers. More particularly, this application relates to a method for assembling a gyratory crusher including introducing a main shaft assembly into the crusher.
Gyratory crushers comprise a mainshaft assembly which rests within a lined eccentric. During routine maintenance of such crushers, it is required to periodically remove the mainshaft assembly to gain access to internals, service the mainshaft assembly, or service other components within the crusher.
Difficulties exist in aligning the mainshaft assembly upon reintroduction of the same into the gyratory crusher. This is, in part, because the axial line of the mainshaft and the rotation axis line of the eccentric bushing are not parallel. Instead, the lines intersect at a so-called “pivot point” which typically is located above the crushing surfaces.
Present methods for removing the main shaft assembly generally do not involve much risk of personal injury when performed in accordance with specified procedures. However, present methods of re-installing the mainshaft assembly back into the gyratory crusher involve significant risk of injuries—since operators must work underneath an overhead suspended main shaft assembly (which can weigh as much as 100 tons) to guide the mainshaft into place and prevent seals from being compromised.
During conventional mainshaft installation, personnel guide the mainshaft assembly manually into the offset/off-kilter eccentric bushing. In some gyratory crushers, personnel may also have to manually guide a seal located on the main shaft into a sealing sleeve bore while working underneath the mainshaft assembly.
Any failure of the lifting equipment, the crane, cable or lifting hook or erroneous crane operation might risk serious or fatal injury to the operator below. Pinch point hazards also exist during the process.
It is therefore desired to carry out mainshaft assembly installation in a manner which mitigates risk for the operators involved. In particular, there is a need to obviate the need to place maintenance personnel below a mainshaft assembly for purposes of guiding a distal end of the mainshaft assembly into an eccentric. There further exists a need to obviate the requirement of manual intervention to ensure seals are not compromised (e.g., bent, folded, jammed, caught, impinged) upon introduction of a mainshaft assembly into a gyratory crusher.
It is, therefore, an objective of the invention to circumvent the aforementioned dangers associated with prior art gyratory crusher devices.
It is also an objective of embodiments to provide a safer method for installing a mainshaft assembly into a gyratory crusher through the provision of self-alignment means for minimizing human exposure to danger and unnecessary risk.
It is a further objective of embodiments to provide a quick, cost-effective, and efficient manner in which to introduce a distal end of a mainshaft assembly into a lined eccentric.
This and other objects of the invention will be apparent from the drawings and description herein. Although every object of the invention is believed to be attained by at least one embodiment of the invention, there is not necessarily any one embodiment of the invention that achieves all of the objects of the invention.
Disclosed, is an annular dust bonnet (9) for a gyratory crusher (1). The dust bonnet (9) may be configured to facilitate alignment between a mainshaft assembly (2) and a bore (56) of an eccentric (11) or eccentric liner (12) upon the introduction of the mainshaft assembly (2) into the gyratory crusher (1); for example, by lowering the mainshaft assembly (2) from above the gyratory crusher (1) into the gyratory crusher (1). The dust bonnet (9) may comprise an inner sidewall (22) configured for receiving a lower mainshaft (26) of the mainshaft assembly (2) therethrough, and an outer sidewall (52) configured for engaging an annular dust seal (10) provided within the mainshaft assembly (2).
The dust bonnet (9) may comprise a plurality of guides (15) arranged radially-inwardly with respect to the inner sidewall (22). Each of the plurality of guides (15) may have a guiding surface (15′) configured to contact the mainshaft assembly (2). The guiding surface (15′) may form an angle (58) with respect to the inner sidewall (22), such that a lower portion of each guiding surface (15′) may be positioned further radially-inwardly with respect to the inner sidewall (22) than a respective upper portion of each guiding surface (15′). The guides (15) may collectively be arranged and/or configured to bias the lower mainshaft (26) into concentric alignment with the bore (56); for example, when the mainshaft assembly (2) is lowered into the gyratory crusher (1), without limitation.
In some embodiments, the dust bonnet (9) may comprise a plurality of guide mounts (14) provided to the inner sidewall (22). Each of the guide mounts (14) may be configured to support and supporting a respective one of said guides (15); for example, in at least a radial direction, without limitation.
According to some embodiments, each of the guide mounts (14) may extend radially-inwardly from the inner sidewall (22), without limitation.
According to some embodiments, each of the guides (15) may be removably affixed to one of the guide mounts (14). For example, one or more fasteners (16, 24) may extend through one or more apertures (16, 17) of each guide (15) and into its respective guide mount (14), without limitation.
According to some embodiments, each of the guide mounts (14) may comprise an inclined base surface (20). The inclined base surface (20) may be configured for supporting its respective one of said guides (15), without limitation.
According to some embodiments, each of the guide mounts (14) may comprise side rails (21). The side rails (21) may protrude further radially-inwardly than the inclined base surface (20), without limitation.
According to some embodiments, the side rails (21) may be configured to provide lateral support for the guides (15). The side rails (21) may alternatively or additionally facilitate positioning of the guides (15) with respect to their respective guide mounts (14), without limitation. The side rails (21) may comprise one or more side apertures (19) for receiving side pins (24) or other fasteners or fastening means to secure guides (15) to guide mounts (14), without limitation.
According to some embodiments, the dust bonnet may comprise a lower sidewall (23). The lower sidewall may extend radially inwardly with respect to the inner sidewall (22). The lower sidewall (23) may form an inner annular lip or inner annular flange proximate a lower portion of the dust bonnet (9). According to some embodiments, the guide mounts (14) may be generally configured as triangular prisms or gussets, without limitation.
According to some embodiments, the inclined base surface (20) may extend at an angle (58) between the inner sidewall (22) and lower sidewall (23), relative to the inner sidewall (22), without limitation.
According to some embodiments, the dust bonnet (9) may comprise an annular upper radially-outer chamfer (49). The upper radially-outer chamfer (49) may be located proximate an upper rim of the dust bonnet (9), without limitation. The upper radially-outer chamfer (49) may be configured to engage a complementary annular lower radially-inner chamfer (50) of a dust seal (10), without limitation. The upper radially-outer chamfer (49) may be configured to bias the dust seal (10) into concentric alignment with the dust bonnet (9). The upper radially-outer chamfer (49) may be configured to guide the dust seal (10) over an outer surface (52) of the dust bonnet (9) when the mainshaft assembly (2) is lowered into the gyratory crusher (1), without limitation.
According to some embodiments, the guides (15) may be configured to bias the lower mainshaft (26) into concentric alignment with one or more annular oil seals (53); for example, one or more annular oil seals (53) which may be located below the guides (15). This may be accomplished, for example, by virtue of sliding contact with the lower mainshaft (26) (e.g., sliding contact between guide surfaces 15′ and outer surfaces of mainshaft (26)—including surfaces of an end plate (32) provided thereto), when the mainshaft assembly (2) is lowered into the gyratory crusher (1), without limitation.
An end plate (32) for provision to a lower distal end of a mainshaft assembly (2) of a gyratory crusher (1) is further disclosed. The end plate (32) may comprise a lower side and an upper side. The lower side may be configured to rest on a thrust bearing (48) (e.g., located above a hydraulic cylinder (59)), without limitation. The upper side of the end plate (32) may be configured to be received in a recess (46) (e.g., provided in a lower mainshaft (26) of the mainshaft assembly (2)), without limitation. The recess (46) may be defined by a bottom surface (29) of the lower mainshaft (26) which may be surrounded by a lower annular projection (28) of the lower mainshaft (26), without limitation.
The end plate (32) may be configured to bias a lower mainshaft (26) of the mainshaft assembly (2) into concentric alignment with a bore (56) of an eccentric (11) or eccentric liner (12); for example, upon the introduction of the mainshaft assembly (2) into the gyratory crusher (1) by lowering the mainshaft assembly (2) from above the gyratory crusher (1) into the gyratory crusher (1). This may be accomplished, for example, by virtue of a lower alignment chamfer (36) being provided to the end plate (32) at its radially-outermost periphery. The lower alignment chamfer (36) may be configured to synergistically work with guide surfaces (15′) of guides (15), without limitation.
According to some embodiments, the end plate (32) may be configured to bias the lower mainshaft (26) of the mainshaft assembly (2) into concentric alignment with one or more annular oil seals (53) configured to surround the lower mainshaft (26) of the mainshaft assembly (2); for example, upon the introduction of the mainshaft assembly (2) into the gyratory crusher (1) by lowering the mainshaft assembly (2) from above the gyratory crusher (1) into the gyratory crusher (1), without limitation.
According to some embodiments, the lower alignment chamfer (36) may be configured to smoothly transition to a lower alignment chamfer (27) which may be provided proximate to the lower annular projection (28) of the lower mainshaft (26).
According to some embodiments, the end plate (32) may comprise an upper annular lip (38). The upper annular lip (38) may surround an upper projection (45) provided to the end plate (32). The upper annular lip (38) may be configured to seat against a lower surface of the lower annular projection (28) of the mainshaft assembly (2), without limitation.
According to some embodiments, the upper projection (45) may be configured to be received in the recess (46) provided in the lower mainshaft (26), without limitation.
According to some embodiments, an upper surface of the upper projection (45) may be configured to seat against the bottom surface (29) of the of the lower mainshaft (26), without limitation.
According to some embodiments, the upper annular lip (38) may intersect the lower annular chamfer (36) to form a top annular edge (60); e.g., at the widest part of the end plate (32), without limitation.
According to some embodiments, the lower alignment chamfer (36) may be configured to blend with the lower alignment chamfer (27) provided proximate the lower annular projection (28) of the lower mainshaft (26), without limitation. The two lower alignment chamfers (36, 37) may blend together such that the lower alignment chamfer (36) of the end plate (32) is flush with the lower alignment chamfer (27), without limitation. The two lower alignment chamfers (36, 37) may blend together such that the lower alignment chamfer (36) shares the same (or similar) taper angle with lower alignment chamfer (27), without limitation.
A counterweight (13) for a gyratory crusher (1) is also disclosed. The counterweight may be adapted for provision to an upper portion of an eccentric (11) and/or eccentric liner (12) within the gyratory crusher (1). The counterweight (13) may have an upper side and an underside. According to some embodiments, the counterweight (13) may comprise a unique C-shaped arcuate profile having two ends. The counterweight (13) may also comprise a concave alignment chamfer (41).
The alignment chamfer (41) may be defined by a ramped surface which faces upwardly and radially-inwardly (with respect to the c-shaped arcuate profile, eccentric (11), and/or liner (12)). The ramped surface defining the alignment chamfer (41) may extend between the upper side and the underside of the counterweight. The ramped surface may extend between the two ends of the C-shaped arcuate profile. Accordingly, the counterweight (13) may be narrower in width across its upper side than across its underside, without limitation.
According to some embodiments, the alignment chamfer (41) may be configured to bias a lower mainshaft (26) of a mainshaft assembly (2) of the gyratory crusher (1) into concentric alignment with a bore (56) of the eccentric (11) or eccentric liner (12) to which it is provided; for example, upon the introduction of the mainshaft assembly (2) into the gyratory crusher (1) by lowering the mainshaft assembly (2) from above the gyratory crusher (1) into the gyratory crusher (1), without limitation.
According to some embodiments, the counterweight (13) may comprise projections (42) on the underside of the counterweight (13), without limitation.
According to some embodiments, the counterweight (13) may comprise mounting holes (43). The mounting holes (43) may extend through the counterweight (13) and be configured to secure the counterweight (13) to the eccentric (11) and/or eccentric liner (12), without limitation. For example, the mounting holes (43) may be configured to secure the counterweight (13) to an upper portion of an eccentric (11) and/or eccentric liner (12).
According to some embodiments, at least one of the mounting holes (43) may pass through one of the projections (42), without limitation. In some embodiments all mounting holes (43) may pass through respective projections (42), without limitation.
A gyratory crusher (1) can benefit from the above apparatus. For example, a gyratory crusher (1) according to some embodiments may comprise the dust bonnet (9) described above, the end plate (32) described above, or the counterweight (13) described above. In some embodiments, the gyratory crusher (1) may comprise the dust bonnet (9) described above in combination with the end plate (32) or counterweight (13) described above. In some embodiments, the gyratory crusher (1) may comprise the end plate (32) and counterweight (13) described above. In some embodiments, all three of the dust bonnet (9), end plate (32) and counterweight (13) described above may be provided to the gyratory crusher, without limitation.
To complement the description which is being made, and for the purpose of aiding to better understand the features of the invention, a set of drawings illustrating new and novel methods and apparatus for assisting self-centering and alignment during mainshaft assembly 2 installation is attached to the present specification as an integral part thereof, in which the following has been depicted with an illustrative and non-limiting character. It should be understood that like reference numbers used in the drawings (if any are used) may identify like components.
Prior art
In the following, the invention will be described in more detail with reference to drawings in conjunction with exemplary embodiments.
While the present invention has been described herein using exemplary embodiments of a gyratory crusher 1 and method of assembling the same, it should be understood that numerous variations and adaptations will be apparent to those of ordinary skill in the field from the teachings provided herein.
The detailed embodiments shown and described in the text and figures should not be construed as limiting in scope; rather, all provided embodiments should be considered to be exemplary in nature. Accordingly, this invention is only limited by the appended claims.
The inventors have recognized a novel and heretofore unappreciated gyratory crusher 1 which includes features which are configured to assist centering of a mainshaft assembly 2 upon the introduction of the same, without limitation. For example, novel features described herein are configured to promote self-centering and/or self-aligning when lowering a portion (e.g., lower mainshaft 26) of the mainshaft assembly 2 into a liner 12 of an eccentric 11, without limitation.
When a component of the gyratory crusher 1 is worn (including, but not limited to, an eccentric liner 12, mantle 7, dust seal 10, lower mainshaft 26, concave 8, or other component), a spider 6 may be removed from the gyratory crusher 1 and the mainshaft assembly 2 removed by lifting the mainshaft assembly 2 upwardly from the gyratory crusher 1 via an overhead crane. The mainshaft assembly 2 may need to be removed completely from the gyratory crusher 1 to replace a mantle 7 thereon, or, to gain access to replace portions of concave 8 which have worn.
Turning now to
The gyratory crusher 1 may further comprise a mainframe which may include a lower top shell 3, a bottom shell 4, and a top shell 5, without limitation. Any two or more of the shell portions 3, 4, 5 may be made integral with each other, without limitation. A spider 6 may span a top opening as shown. A concave 8 (e.g., inner crushing surface liner) may protect the inner portions of the mainframe. The mainshaft assembly 2 may be received within a liner 12 of an eccentric 11. An annular dust bonnet 9 may be provided around the mainshaft assembly 2, and an annular dust seal 10 may be provided around an outer surface of the dust bonnet 9. A counterweight 13 may be affixed to an upper portion of eccentric 11 and/or eccentric liner 12. The counterweight 13 may comprise a non-annular arcuate shape (e.g., a “C” shape), as shown, without limitation.
As exemplified in
As depicted in
The guide mounts 14 may be configured with an integrally-formed guide surface or, as shown, may be configured to receive one or more separable guides 15. Each guide 15 may comprise, for instance, a replaceable wear surface or liner, without limitation. Guides 15 may comprise a bearing material such as bronze or a polymer, without limitation.
In the particular exemplary, non-limiting embodiment shown (most clear from
To better support a guide 15 from lateral forces and/or side loading (e.g., tangential forces within dust bonnet 9) caused during mainshaft assembly 2 insertion, one or more side rails 21 protruding from inclined base surface 20 may be provided on either or both sides of the guide(s) 15 as shown. The side rails 21 may project radially inwardly from guide mount 14 with respect to the dust bonnet 9, and may extend along guide mount 14 at an angle between inner 22 and lower 23 sidewalls. The side rails 21 may extend generally perpendicularly from the inclined base surface 20, without limitation.
Each guide 15 may comprise one or more apertures 16 (e.g., one or more countersunk recesses) for receiving one or more respective fasteners 25 as depicted. An aperture 16 described herein may be sized and shaped to complimentarily receive a head of a fastener 25 as shown, and/or configured such that the fastener 25 does not protrude past an outer guide surface of a guide 15, without limitation.
One or more side apertures 17 may be provided transversely to a separable or integral guide 15 as shown, and these may serve to receive one or more respective side pins 24 for temporarily or permanently securing a guide 15 to a guide mount 14, without limitation. Side pins 24 may extend entirely through guide mount 14, or partially into each guide 15 as shown. Side pins 24 may comprise roll pins, rollers, screws or other type of fastener which are pressed screwed into, or otherwise received through a side rail 21 and guide 15, without limitation. Guide mounts 14 may also comprise one or more side apertures 19 to receive the side pins 24 as shown, without limitation. As shown in the particular embodiment, side pins 24 may intersect apertures 16 so as to serve as set screws against fasteners 25, or other locking features without limitation. As shown, side pins 24 may extend through side rails 21.
One or more mounting holes 18 may be provided to each guide mount 14 for receiving fasteners 25 (e.g., a fastener 25 extending through guide 15 and received within aperture 16).
Turning now to
As exemplified in
A lower side of the bottom plate 32 may comprise a number of radial oil grooves 33 and/or one or more annular oil grooves 34 may be provided on its bottom surface, without limitation. The grooves 33, 34, may assist with the holding and channeling of oil between the end plate 32 and thrust bearing 48 thereby facilitating lubrication. The radial oil grooves 33 may be interrupted along a radial line as shown, so as to form a plurality of staggered arcuate block projections 55. The staggered arcuate block projections 55 may form a circular tile mosaic pattern as illustrated. The radial 33 and annular 34 oil grooves may be interconnected such that they collectively form a tortuous path for oil to move, thereby improving upon the “rose” pattern shown in
A central pocket 35 may be provided to the lower side of the end plate 32 for receiving a fastener 30 for securing the end plate 32 to the lower mainshaft 26. However, it is conceived that a pattern of spaced pockets (centrally-disposed or not) may be provided and arranged within end plate 32 in order to provide means for securing the end plate 32 to the lower mainshaft 26.
As suggested in the particular non-limiting embodiment shown, the fastener 30 may comprise a bolt or threaded pin, without limitation. The fastener 30 may, as shown in
Another feature which may be employed to the end plate 32 is a lower alignment chamfer 36 (e.g., a frustoconical taper or lead-in surface). The lower alignment chamfer 36 may match the taper angle of an upper alignment chamfer 27 of the lower annular projection 28 as shown. A lower annular edge of the upper alignment chamfer 27 may abut or meet with an upper annular edge of the upper annular lip 38, as shown. Surfaces of the upper alignment chamfer 27 and lower alignment chamfer 36 may be flush with one another, collectively continuous, or generally follow the same outer chamfer taper angle—thereby creating a smooth homogeneous transition between lower mainshaft 26 and end plate 32.
To prevent relative movement between end plate 32 and lower mainshaft 26, mating surfaces between upper annular lip 38 and lower annular projection 28 may be interlocking (e.g., undulating, scalloped, undulating), without limitation. Moreover, the outer surface of upper projection 45 and inner surface of lower annular projection 28 can be complimentary splined surfaces, without limitation. However, as shown, in some embodiments, rotation of end plate 32 with respect to lower mainshaft 26 may be discouraged or prevented by providing one or more alignment pins 44 to bottom surface 29 such that they protrude into respective alignment holes 40. In this regard, upper projection 45 can be prevented from spinning within lower annular projection 28 during operation, which could cause loosening of fasteners 30, 31 attaching the end plate 32 to the lower mainshaft 26.
Turning now to
The alignment chamfer 41 may, as shown, be provided to an inner concave portion of the counterweight, such that the counterweight 13 is generally narrower in width adjacent an upper part of the counterweight 13 and generally wider in width adjacent a lower part of the counterweight 13.
In some embodiments, a number of projections 42 may be provided to a lower face of the counterweight 13 (
Turning now to
Upon even further lowering of mainshaft assembly 2, the smooth lead-in taper collectively formed by the flush lower alignment chamfers 27, 36 subsequently presents itself to the alignment chamfer 41 of counterweight 13. One or both of lower alignment chamfers 27, 36 may ride against surfaces of alignment chamfer 41 to supplementally finish guiding the lower mainshaft 26 into the eccentric 11 (e.g., into a liner 11 disposed therein), without limitation.
Synergistic combinations of features 15, 27, 36, 41, 49, 50, disclosed herein may contribute to a greater self-aligning/self-centering effect.
The disclosure of every patent, patent application, and publication cited, listed, named, or mentioned herein is hereby incorporated by reference in its entirety, for any and all purposes, as if fully set forth herein.
While this subject matter has been disclosed with reference to specific embodiments, it is apparent that other embodiments and variations can be devised by others skilled in the art without departing from the true spirit and scope of the subject matter described herein. The appended claims may include some, but not all of such embodiments and equivalent variations.
For example, it is envisaged that in some embodiments, an eccentric liner 12 may be entirely optional. The eccentric liner 12 may be omitted from the eccentric 11 (wherein the bore 56 and/or inner diameter 57 may be formed directly through the body of eccentric 11). Or, an eccentric liner 12 may be provided as an integral surface portion of eccentric 11. The eccentric liner 12 and eccentric 11 may be, in some embodiments, provided as a monolithic unitary structure and may be inseparable from each other, without limitation. The eccentric liner 12 and eccentric may also be provided as separable parts which have a clearance fit or press fit between them. Accordingly, where it is used herein and in the claims, the terms “bore 56” and “inside diameter” 57 may relate to an opening through an eccentric 11 or its liner 12—whichever is smaller in diameter, configured to receive the lower mainshaft 26, and/or which comprises the bearing surfaces designed to abut, envelope, or constrain lateral movement of the outer peripheral diametrical surface of lower mainshaft 26, without limitation.
As yet another example, it should be further understood that where it is used herein and in the claims, the term “guide 15” may refer to a separable guide structure that is removably affixed or mounted to a separate guide mount 14 as depicted in the figures; or, it may broadly refer to or encompass any structure connected to, integral with, attached to, or extending from the inner surface 22 of the dust bonnet 9 which is adequately configured to help concentrically align a lower mainshaft 26 of the mainshaft assembly 2 with one or more oil seals 53 and/or the inside diameter 57 of bore 56 of the eccentric 11 or its optional liner 12. The term “guide 15” may also refer to or encompass any structure connected to, integral with, attached to, or extending from the inner surface 22 of the dust bonnet 9 which is adequately configured to help guide the lower mainshaft 26 into an oil seal(s) 53, eccentric 11, eccentric liner 12, bore 56, and/or inside diameter 57 when the mainshaft assembly 2 is lowered into the gyratory crusher 1, without limitation.
The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated and governed only by the appended claims, rather than by the foregoing description. All embodiments which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
A contractor or other entity may provide a gyratory crusher 1 or component(s) thereof as substantially shown and described herein, or, may practice any one or more of the methods or method steps shown and described herein, without limitation. A contractor or other entity may operate a gyratory crusher 1 as shown and described.
A contractor or other entity may fabricate, provide, or install a gyratory crusher 1 as substantially shown and described herein, and this may include conversion of an existing gyratory crusher to provide a gyratory crusher 1 configured to improve mainshaft self-alignment during installation. A contractor or other entity may receive a bid request for a project related to designing, fabricating, delivering, installing, operating, or performing maintenance on a gyratory crusher, or, for providing a component thereof as substantially described herein, with the intention or purpose of converting an existing gyratory crusher to one incorporating the inventive features, concepts, and associated advantages described herein. A contractor or other entity may offer to design such a gyratory crusher 1 or component thereof, for a client. A contractor or other entity may subcontract or facilitate the fabrication, delivery, sale, and/or installation of any component(s) of the gyratory crusher disclosed.
The contractor or other entity may also maintain, modify, retrofit, or upgrade a gyratory crusher (or one or more components thereof) in order to produce a gyratory crusher 1 as shown and described. The contractor or other entity may provide such maintenance or modifications by subcontracting such services or by directly providing those services or components needed for said maintenance, modifications, retrofit, or upgrades. In some cases, the contractor or other entity may modify an existing gyratory crusher by virtue of provision of a retrofit kit to arrive at a modified gyratory crusher 1 comprising any number of the components described herein, or one or more of the inventive method steps, design features, devices, or inventive concepts discussed herein.
Although the invention has been described in terms of particular embodiments and applications, one of ordinary skill in the art, in light of this teaching, can generate additional embodiments and modifications without departing from the spirit of or exceeding the scope of the claimed invention.
Number | Date | Country | |
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Parent | 18025569 | Mar 2023 | US |
Child | 18543525 | US |