The present invention relates to a gyratory crusher topshell and a topshell assembly in which the crushing shell is axially and rotatably locked within the topshell via a plurality of ears and lock lugs projecting from the shell.
Gyratory crushers are used for crushing ore, mineral and rock material to smaller sizes. Typically, the crusher comprises a crushing head mounted upon an elongate main shaft. A first crushing shell (typically referred to as a mantle) is mounted on the crushing head and a second crushing shell (typically referred to as a concave) is mounted on a frame such that the first and second crushing shells define together a crushing chamber through which the material to be crushed is passed. A driving device positioned at a lower region of the main shaft is configured to rotate an eccentric assembly positioned about the shaft to cause the crushing head to perform a gyratory pendulum movement and crush the material introduced in the crushing chamber. Primary crushers, such as jaw crushers, are heavy-duty machines designed to process large material sizes of the order of one meter. Secondary and tertiary crushers are intended to process relatively smaller feed materials typically of a size less than 35 centimetres and cone crushers represent a sub-category of gyratory crushers that are typically utilised as downstream crushers due to their high reduction ratios and low wear rates.
A variety of different mechanisms have been described to both axially and rotatably secure the outer crushing shell within the topshell so as to prevent the concave from being pushed out of the topshell and rotating with the gyroscopic precession of the mantle (mounted about the central shaft). U.S. Pat. No. 5,769,340 describes a positioning device in which the concave is provided with a plurality of tabs that sit radially between the concave and the topshell to provide respective abutment surfaces to frictionally grip radially outer regions of the concave so as to maintain it in position.
U.S. Pat. No. 5,915,638 describes the mounting of an outer crushing shell to the topshell via stop blocks that are received within key slots (formed at an upper annular rim of the topshell) to cooperate with separate and independently mounted wedge shaped keying elements that frictionally engage the topshell to provide a rotational lock.
WO 2004/110626 discloses a number of different embodiments for mounting a concave at a topshell via an intermediate spacer ring. The spacer ring is secured to the topshell via flanges that project radially outward from an upper annular rim of the ring to be seated within stepped regions formed in the upper annular rim of the topshell.
However, conventional arrangements are disadvantageous for a number of reasons. In particular, the upper and/or lower annular rims of the topshell are typically subjected to significant loading forces as the topshell is mated against additional components within the crusher such as a spider and the bottom shell. Removing excessive material from the respective topshell upper and lower rims to accommodate locking attachments that engage the crushing shell can weaken the topshell and increases the likelihood of stress concentrations and fracture propagation. Additionally, conventional locking mechanisms commonly employ an axially extending locking bolt that is secured into the topshell to provide the ‘stop’ for rotationally locking the crushing shell. It is not uncommon for such bolts to shear during use resulting in the concave rotating within the topshell and in some instances falling into the bottom shell and damaging further components of the crusher. Accordingly, what is required is a locking mechanism for a crushing shell that addresses the above problems.
It is an objective of the present invention to provide a gyratory crusher outer crushing shell adapted for convenient mounting and disassembly from a topshell whilst being mountable reliably to inhibit axial and rotational movement during use without compromising the structural integrity of the topshell and the crushing shell. It is a further specific objective to provide an outer crushing shell locking mechanism that provides a reduced likelihood of failure following extended use and a locking mechanism that is limited only by the operational lifetime of the outer crushing shell as determined by the crushing mechanism of the shell in cooperation with the mantle. It is a further specific objective to provide a shell locking arrangement conveniently adaptable for use with different types of crusher and crushing shell.
The objectives are achieved by providing a gyratory crusher outer crushing shell having a plurality of attachment ears that are configured to be secured to the topshell via separate mechanisms to provide firstly an axial lock with the topshell and secondly a rotational lock within the topshell. Axial locking is achieved by respective locking bolts and rotational locking is achieved by a lug that projects from each ear and is configured to sit within a corresponding recess formed within the annular rim of the topshell. In particular, according to one aspect, each lug projects axially from each ear and depending upon the orientation of the topshell, each lug projects axially downward (in the case of an upper crushing shell) or axially upward into the topshell (in the case of a lower crushing shell). Accordingly, the topshell is specifically adapted via the plurality of recesses at the respective upper or annular rim to receive each lug and mate with the crushing shell.
According to a first aspect of the present invention there is provided a crushing shell for mounting within a gyratory crusher topshell, the crushing shell comprising: an annular wall extending around a longitudinal axis, the wall terminated at an axial end by an annular rim; a plurality of fastening ears projecting radially outward from the wall at the region of the rim, each ear being attachable to an annular rim of a topshell of a gyratory crusher; characterised by: a lock lug projecting from each ear to be received within respective recesses at the annular rim of the topshell to rotatably lock the crushing shell at the topshell.
Preferably, each ear comprises a hole or notch to receive an attachment bolt for securing axially the crushing shell to the topshell. Preferably, each notch is formed as a cut-out section or indent extending radially inward from an outer perimeter edge of the ear in a direction towards the central axis around which the annular wall of the topshell extends. Preferably, the notch does not extend the full radial length of the ear so as to enhance the structural integrity of the ear to withstand the rotational sheer forces. Preferably, the notch is formed approximately at a mid-length region of each ear (in the circumferential direction).
Preferably, each lug projects axially from each respective ear. Such an arrangement is advantageous to enable the ear to sit on top (or below) the topshell rim so that the lug projects axially into the rim to sit within the recess. Accordingly, the topshell rim is adapted only to receive the lock lug and not the ear. Such an arrangement is advantageous to minimise the volume of material removed from the topshell rim to accommodate the lug and accordingly maintain the structural integrity of the topshell and minimise the likelihood of stress concentrations and fracture.
Preferably, each lug comprises an abutment surface to contact a corresponding abutment surface that in part defines each respective recess. More preferably, the abutment surface is substantially planar. Such an arrangement is advantageous to provide an effective surface through which loading forces are transmitted from the crushing shell to the topshell so as to distribute the loading forces evenly into the ear and avoid stress concentrations. Preferably, each lug extends across substantially the full radial width of each ear. The lug radial width is optimised for force transfer between crushing shell and topshell whilst minimising the size of the lug so as to in turn minimise the size of the recess in the topshell rim to avoid weakening the rim. Moreover, and preferably each lug comprises a length in a circumferential direction around the axis that is less than half of a corresponding circumferential length of each ear. Additionally, each lug may comprise a cross sectional area in a plane perpendicular to the axis that is at least half of the corresponding cross sectional area of each ear. Accordingly, the lug volume is less than the ear to minimise the size of the recess within the topshell rim. The size of the lugs therefore represents a compromise between maximising the loading force transfer (to avoid stress concentrations) and minimising the volume of the recesses within the topshell rim that receive the lugs (to avoid weakening the taper fit rims of the topshell). Optionally, a circumferential length of each lug is greater than a radial width of each lug. Such an arrangement is advantageous to strengthen the lug at the ear to avoid stress concentrations and to avoid cracking of the lug at the junction with the ear. Preferably, the lug is formed integrally with the ear and the ear is formed integrally with the crushing shell. Preferably, the lock lug does not project circumferentially or radially outward beyond each ear.
Preferably, the shell comprises between two to six ears each having a respective lug. Optionally, the crushing shell may comprise four to six ears symmetrically arranged around the axis and spaced apart from one another in a circumferential direction by a uniform separation distance. This configuration provides sufficient distribution of the rotational sheer forces around the crushing shell and the topshell.
According to a second aspect of the present invention there is provided a gyratory crusher topshell assembly comprising: a topshell terminated at an axial end by an annular rim; a crushing shell as claimed herein; a plurality of attachment bolts to extend through each ear and the annular rim of the topshell to axially lock the crushing shell at the topshell; and a plurality of recesses provided at the annular rim of the topshell to receive the respective lugs.
Preferably, the assembly further comprises at least one extractor mounted at the topshell and comprising an axially adjustable shaft having an engaging end positioned to contact respectively at least one of the lugs to force axially movement of the crushing shell relative to the topshell. Preferably, the extractor comprises an elongate bolt extending axially through a region of the topshell having a head engagable by a tool for rotation and an opposite end positioned adjacent the lug when installed within the topshell. Preferably, the assembly comprises a plurality of extractor bolts to engage each respective lug or each respective ear. Accordingly, each extractor bolt is separately axially adjustable.
In one aspect, the topshell comprises an axially upper annular rim and an axially lower annular rim and the assembly further comprises: a first axially upper crushing shell secured via the ears, lugs and recesses to the upper annular rim of the topshell; and a second axially lower crushing shell secured via the respective ears, lugs and recesses to the lower annular rim of the topshell. Accordingly, the lugs of the upper shell project axially downward into the upper rim and the lugs of the lower shell project axially upward to the lower rim.
According to a third aspect of the present invention there is provided a gyratory crusher comprising a topshell assembly as claimed herein.
According to a fourth aspect of the present invention there is provided a gyratory crusher topshell assembly comprising: a topshell terminated at an axial end by an annular rim, a crushing shell mounted at the topshell at or towards the annular rim; an axial and rotational lock mechanism to axially and rotationally lock the crushing shell at the topshell; and at least one extractor mounted at the topshell and comprising an axially adjustable shaft having an engaging end positioned to contact a region of the crushing shell to force axial movement of the crushing shell relative to the topshell.
Preferably, the assembly comprises a plurality of extractors in the form of elongate bolts axially adjustable through respective regions of the topshell.
The extractor is advantageous to initiate the axial pushing of the crushing shell from the topshell that is often difficult following extended use of the crusher as the crushing shell becomes fused to the topshell due to the compressive crushing forces.
A specific implementation of the present invention will now be described, by way of example only, and with reference to the accompanying drawings in which:
Referring to
Assembly 100 comprises a first outer crushing shell (concave) 101 secured at topshell 102 via rim 103 and collar 105. Assembly 100 further comprise a second crushing shell 101 secured to topshell 102 via the lower rim 104 and collar 200. Each crushing shell 101 comprises an end annular rim 106 and four fastening ears indicated generally by reference 107 projecting radially outward from rim 106 and being spaced apart from one another by a uniform separation distance in a circumferential distance around axis 110. Referring to
Each upper and lower outer crushing shell 101 is secured axially at each respective collar 105, 200 via ears 107 and a corresponding locking bolt 108. Each bolt 108 projects axially through a region of topshell 102 from each respective collar 105, 200. Each bolt 108 is received respectively within each ear notch 302 so as to be located within the body of each ear 107 circumferentially between each respective lock lug 400 and region 401. As each bolt 108 is tightened, each shell 101 is forced and compressed axially against topshell 102 and in particular each respective collar 105, 200. Additionally, crushing shell 101 is rotationally locked at topshell 102 via each ear 107 engaging with selected regions 109 of each rim 103, 104 as described in detail below. Topshell assembly 100 further comprises a shell extractor formed from a plurality of bolts 111 positioned immediately adjacent each locking bolt 108 so as to extend axially through topshell 102. Each extractor bolt 111 is configured to axially abut each respective lock lug 400 as described with reference to
Referring to
Referring to
Referring to
Referring to
In particular, the plurality of lock bolts 111 extend through bores 608 between a mount region 804 that co-mounts one end of lock bolts 108. Each extractor bolt 111 comprises a tightening head 805 at a first end and an abutment flange 802 at a second end 806. Abutment flange 802 is formed as an annular collar being flared radially outward at end 806 and shaped to sit within depression 609 is close fitting contact. Flange 802 is secured to bolt end 806 so as to be axially movable with the main shaft of bolt 111. With shell 101 axially and rotationally locked at topshell 102, extractor bolts 111 are axially locked within each bore 608 via a fork washer 803 positioned between mount region 804 and bolt head 805. Once the lock bolts 108 have been removed, fork washer 803 is then removed to allow axial adjustment of extractor bolts 111 relative to each collar 105, 200 and in particular each recess 303. That is, with the lock lugs 400 accommodated with recesses 303, flange 802 is advanced axially to contact lug underside face 505. By axially advancing each extractor bolt 111 through bore 608, shell 101 is forced (via each lock lug 400 and ear 107) axially from topshell 102.
According to further specific implementations, topshell assembly 100 may comprises a single outer crushing shell 101 secured only to the upper collar 105 and annular rim 103. The subject invention may be utilised to secure axially and rotational a crushing shell 101 at topshell 102 directly or via an intermediate spacer ring 800 as illustrated in
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2015/065214 | 7/3/2015 | WO | 00 |