Patent Grant
9937501
This application is a § 371 National Stage Application of PCT International Application No. PCT/EP2014/060244 filed May 19, 2014 claiming priority of EP Application No. 13175060.6, filed Jul. 4, 2013.
The present invention relates to a gyratory crusher outer crushing shell and in particular, although not exclusively, to a shell having a ledge positioned at an axially upper region of the shell to seat a sealing ring for positioning between the crushing shell and the topshell or an intermediate spacer ring.
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. Example gyratory crushers are described in WO 2004/110626; WO 2008/140375, WO 2010/123431, US 2009/0008489, GB 1570015, U.S. Pat. No. 6,536,693, JP 2004-136252, U.S. Pat. No. 1,791,584 and WO 2012/005651.
Primary crushers are heavy-duty machines designed to process large material sizes of the order of one meter. Secondary and tertiary crushers are however intended to process relatively smaller feed materials typically of a size less than fifty centimeters. Cone crushers represent a sub-category of gyratory crushers and may be utilised as downstream crushers.
Typically, both the inner and outer crushing shells wear and distort due to the significant pressures and impact loading forces they transmit. In particular, it is common to use backing compounds to structurally reinforce the outer shell and assist with contact between the radially outward facing surface of the outer shell and the radially inward facing surface of the topshell. In particular, a backing compound (typically an epoxy or polyurethane material) is cured around the outer region of the concave to provide structural support to the concave during the crushing operation particularly in tough high-pressures applications involving, for example, processing extremely hard materials. Example backing compounds are available from ITW (‘Korroflex’) Ltd, Birkshaw UK under brand names Korrobond 65™ and 90™; and Monach Industrial Products (I) Pvt., Ltd, India, under brand name KrushMore™.
However, the majority of widely used backing compounds are disadvantageous for health and environmental reasons and require long curing times that extend the downtime of the crusher. Accordingly, there is a general preference to avoid their use. However, the backing material also has a further function to seal the region between the outer crushing shell and the topshell (or intermediate spacer ring) to prevent downward passage of debris particles and dust into the region between the crushing shell and the topshell which is undesirable. Accordingly, there is a need for an outer crushing shell configured for use without a backing compound whilst facilitating a means of sealing the radially outer region between the crushing shell and the topshell (or intermediate spacer ring) to prevent the ingress of contaminant particles and fines.
It is an objective of the present invention to provide an outer crushing shell, a topshell and crushing shell assembly and a sealing ring configured to prevent contaminant particles, such as stone and dust, from penetrating and damaging contact surfaces between the crushing shell, intermediate spacer ring and topshell. It is a further objective to provide a sealed assembly that is effective to prevent the ingress of contaminant material without the need for a backing compound positioned between the crushing shell, the spacer ring and/or topshell. It is a further objective to provide a sealing ring configured to be self-adapting and universal for different configurations of crushing shell for direct contact with the topshell or in contact with an intermediate spacer ring.
The objectives are achieve by providing an outer crushing shell specifically adapted to seat a sealing ring to be accommodated within a cavity region formed between the crushing shell and the radially outer topshell or intermediate spacer ring. In particular, the present crushing shell comprises an annular shoulder formed at an upper region of the shell wall that projects radially outward from the wall to define an annular ledge with an abutment face or seat region to support the sealing ring optionally via an underside surface. The annular shoulder is positioned at an axially upper region of the crushing shell at or above an upper contact surface intended to be positioned in direct contact with either the intermediate spacer ring or the inward facing surface of the topshell. The shoulder is configured to support the sealing ring and provide an abutment stop that is effective to act against the downward force on top of the sealing ring resultant from the accumulation of fines and debris materials. Accordingly, the present sealing ring is adapted to compress axially and to try and expand radially outward within the cavity region immediately above the crushing shell shoulder to maintain and optimise the seal strength. Accordingly, the present crushing shell and sealing ring arrangement is effective to prevent axially downward ingress of rock dust and particles between the contact surfaces of the crushing shell, sealing ring and/or topshell wall.
The shoulder may be formed at the wall of the shell as a single annular flange being continuous or discontinuous circumferentially around the outward facing surface of the shell. Additionally, the shoulder may represent a lower part of a groove indented within the wall of the shell, the groove extending radially inward from the outward facing mount surface. When formed as a groove, the abutment face of the shoulder represents a lowermost surface that defines the groove being positioned opposed to an uppermost surface that defines the groove. A trough surface extends between the opposed lowermost and uppermost faces such that the sealing ring is accommodated within the groove in contact with the inward facing surfaces that define the groove. The groove configuration is advantageous to inhibit axial movement of the sealing ring in both upward and downward directions.
According to a first aspect of the present invention there is provided a gyratory crusher outer crushing shell mountable within a region of a topshell of a gyratory crusher and extending around a longitudinal axis, the crushing shell comprising: a mount face being outward facing relative to the axis for positioning opposed to a least a part of the topshell and a crushing face being inward facing relative to the axis to contact material to be crushed, a wall defined by and extending radially between the mount surface and the crushing surface, the wall having a first upper axial end and a second lower axial end; a raised first contact region positioned axially towards the first upper axial end and extending radially outward at the mount surface and in a direction around the axis, the contact region having a radially outward facing raised first contact surface for positioning opposed to a radially inward facing surface of the topshell or an intermediate spacer ring; a raised second contact region positioned axially towards the second lower axial end and extending radially outward at the mount surface in a direction around the axis, the second contact region having a radially outward facing raised second contact surface for positioning opposed to a radially inward facing surface of the topshell; characterised by: a ledge or groove provided at the mount face side of the wall at a position of the raised first contact region or axially between the first upper axial end and the raised first contact region, the ledge or groove providing an abutment face to seat a sealing ring positionable between the mount face and the topshell or spacer ring, a radial length of the abutment face being less than a radial thickness of the wall at the region between the first upper axial end and the raised first contact region.
Preferably, the ledge or groove extends continuously in a direction around the axis or is discontinuous around the axis. Optionally, the abutment face extends substantially perpendicular or traverse to the axis to provide a secure seat for the ring. Optionally, a region of the mount face immediately axially above the ledge or groove extends substantially perpendicular to the abutment face. Optionally, a region of the mount face immediately axially above the ledge or groove extends substantially parallel to the axis. Such configurations are advantageous to provide a strong seal at the region between the ring and the crushing shell.
According to one embodiment, the raised first contact surface is positioned radially outward beyond the ledge or groove and the abutment face. Accordingly, the ledge and ring do not interfere with the mating of the crushing shell at the topshell or intermediate spacer ring. Optionally, a radial length of the abutment face is less than a radial thickness of the wall at a position immediately axially above the ledge or groove. As such the ledge does not change, to any significant degree, the physical and mechanical properties of the crushing shell that is optimised for cooperation with the inner shell to act on the material passing through the crushing zone. Optionally, a radial length of the abutment face is in a range 5 to 50% of the thickness of the wall at a position immediately axially above the ledge or groove. Optionally, a radial length of the abutment face is less than 80% of the thickness of the wall at a position immediately axially above the ledge or groove. Accordingly, a radial length of the abutment face at the ledge or groove is less than a radial thickness of the wall at the raised upper contact region. That is, the radial length of the ledge (or abutment face) is sufficient only to prevent the axially downward movement of the ring.
Optionally, the shoulder or groove may be positioned between an upper end of the crushing shell and the upper contact surface. According to a one embodiment, the abutment face may be positioned at an axial position between the first upper end and the raised first contact surface so as to optimise the seal with regard to increasing the seal strength and to provide a shallower or deeper trough into which dust debris and particles accumulate above the sealing ring. As will be appreciated, the greater volume of material accumulated above the sealing ring, the greater the sealing strength between the crushing shell and the intermediate spacer ring or topshell. In one embodiment the groove or ledge is positioned at an axially upper section of the raised first contact region so as to prevent the axially downward passage of debris and particles to and beyond the first contact surface.
According to a second aspect of the present invention there is provided a gyratory crusher outer crushing shell assembly mountable within a region of a topshell of a gyratory crusher, the assembly comprising: an outer crushing shell as claimed herein; a sealing ring seated at the abutment face and extending in contact with and around the shell, the ring prevented from passing axially downward towards the raised first contact region via abutment with the abutment face.
The mounting of the sealing ring at the axially upper region of the concave is further advantageous to provide automatic centring of the concave within the topshell as the topshell is lowered into position during assembly. In particular, as the sealing ring projects radially from the concave upper region, it is capable of contacting the inner wall of the topshell during downward movement such that the concave is forced reliably and conveniently to a true axial centre by radial deflections of the sealing ring. Accordingly, the need for additional centring steps and specific tools is therefore avoided and the downtime of the crusher reduced.
Optionally, the sealing ring comprises a main body to seat at the abutment face and to extend radially outward beyond the ledge or groove to contact the topshell or the radially intermediate spacer ring.
Optionally, the sealing ring comprises a main body to seat at the abutment face and at least one flange projecting radially outward from the main body to contact the topshell or the radially intermediate spacer ring. Preferably, the at least one flange extends at an upwardly inclined angle from the main body. Preferably, the assembly of the sealing ring comprises at least two flanges projecting radially outward from the main body at upwardly inclined angles from the main body. Optionally, the sealing ring may comprise a single flange extending radially outward from what may be considered a main body positioned and supported by the annular shoulder.
Preferably, the sealing ring comprises a plurality of ribs projecting radially inward from the main body to contact the mount face at the region immediately axially above the ledge or groove. Optionally, the sealing ring may comprise a single annular rib projecting radially inward from what may be considered the main body in contact with the annular shoulder.
Optionally, the assembly further comprises a spacer ring positioned radially outward of the shell, the sealing ring positioned radially intermediate between the shell and the spacer ring.
According to a third aspect of the present invention there is provided a gyratory crusher comprising an outer crushing shell as claimed herein or an outer crushing shell assembly as claimed herein.
According to a fourth aspect of the present invention there is provided an annular sealing ring for a gyratory crusher mountable between an outer crushing shell and a topshell or intermediate spacer ring, the sealing ring comprising: a main body extending around a longitudinal axis; at least one flange projecting radially outward from the main body to contact the topshell or the radially intermediate spacer ring; at least one rib projecting radially inward from the main body to contact a radially outward facing surface of the crushing shell.
Preferably, at least a part of the at least one flange extends at an upwardly inclined angle from the main body relative to the axis.
Optionally, the sealing ring or a main body of the sealing ring comprises a rectangular, square, oval, circular, O-shaped, C-shaped, D-shaped, E-shaped or I-shaped cross sectional profile. Optionally, the sealing ring comprises a rubber material. Optionally, the rubber comprises a natural or synthetic rubber. Optionally, the sealing ring comprises a polyurethane or a polyurethane derivative material. Optionally the sealing ring comprises a having a Shore A hardness in the range between 35 to 90. Optionally, the sealing comprises a Shore A hardness in the range between 60 to 70 or more preferably 62 to 68. Such configurations enable the ring to compress radially outward to increase the seal strength between the crushing shell and the topshell or spacer ring.
Preferably, a radial length by which the at least one flange extends from the main body is greater or approximately equal to a radial length of the main body. Preferably, a radial length of the at least one rib is less than a radial length of the main body. Preferably, the sealing ring comprises two flanges and a plurality of ribs.
Optionally, the sealing ring or ring main body is hollow. Optionally, the sealing ring or ring main body is substantially solid. Optionally, where the sealing ring or ring main body is substantially solid, it may comprise internal cavities or voids to provide an internal ‘open’ structure that allows the ring (and main body) to compress with a desired compression characteristic radially and/or axially between the crushing shell and topshell or spacer ring. Optionally, the sealing ring comprises a resiliently deformable material.
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
Topshell 100 is divided into a chamber wall region 101 extending axially between an upper annular rim 103 and a lower annular rim 102 secured to the bottom shell. A spider forms an upper region of topshell 100 and is positioned axially above rim 103. The spider comprises a pair of spider arms 104 that project radially outward from central boss 105 to terminate at their radially outermost end at rim 103.
Topshell wall region 101 comprises topshell walls 222 defined between a radially inward facing surface indicated generally by reference 223 and a radially outward facing surface 224 relative to axis 106. Inward facing surface 223 defines an internal chamber 202 through which material to be crushed is fed via an input hopper (not shown) mounted generally above topshell 100 via rim 103.
As illustrated in
Inward facing surface 223 of topshell wall region 101 is divided axially into a plurality of annular regions in the axial direction. A first mount region 204 is positioned axially uppermost towards rim 103. A second mount region is positioned axially lower than region 204 and towards rim 102. Second (lower) mount region is divided into an intermediate mount region 205 and a lowermost mount region 206 with intermediate region 205 positioned axially between upper and lowermost regions 204, 206.
Crushing shell 200 is positioned in direct contact against topshell 100 via mating contact between lower contact surface 212 and the radially inward facing surface of the lowermost mount region 206. Due to the function and geometry of crushing shell 200 an intermediate spacer ring 203 is positioned radially between an upper region of shell 200 and topshell 100. In particular, spacer ring 203 comprises a radially outward facing surface having a first upper mount surface 207 and a corresponding second lower mount surface 208. Upper surface 207 is positioned in direct contact with topshell region 204 whilst the second lower mount surface 208 is positioned in direct contact with the intermediate mount region 205. Spacer ring 203 comprises a radially inward facing surface axially divided into an upper region 217, a lower region 226 and an intermediate region 218. Intermediate region 218 is formed as an annular shoulder projecting radially inward relative to upper and lower regions 217, 226. According to the present implementation, the radially inward facing surface at shoulder region 218 is positioned in direct contact with the radially outward facing upper contact surface 211. Accordingly, spacer ring 203 is positioned radially intermediate the upper region of shell 200 and topshell wall 222. An annular cavity 304 extends circumferentially around axis 106 between the opposed radially outward facing surface of shell 200 at an upper region 221 (immediately below upper end 215) and the radially inward facing surface at the upper region 217 of spacer ring 203. An intermediate sealing ring indicated generally by reference 214 is positioned radially intermediate spacer ring 203 and shell 200 within cavity region 304.
According to the specific implementation, sealing ring 214 comprises a generally annular configuration extending around axis 106. A main body 301 comprises a cross sectional O-shaped profile. A pair of flanges 302 project radially outward from main body 301 at an upwardly inclined angle from an outward facing side of main body 301. A plurality of ribs 303 project radially inward from an opposed inner facing side of main body 301. When located within cavity 304, ribs 303 are positioned in contact with the radially outward facing face 225 of crushing shell 200 at upper region 221 and flanges 302 are positioned in contact with the radially inward facing surface of the spacer ring 203 at upper region 217.
To provide an axial lock for sealing ring 214, crushing shell 200 comprises an annular ledge 213 formed as a shoulder projecting radially outward from an upper region of wall 201. Accordingly, an abutment face 300 is defined by ledge 213 and extends substantially perpendicular to axis 106 and in particular the substantially cylindrical outward facing surface of shell 200 at upper region 221. That is, abutment face 300 terminates at its radially innermost end by the surface of upper region 221 and is terminated at its radially outermost end by the surface of lower region 210 that is aligned transverse to the surface of upper region 221 and axis 106. According to the specific implementation, a radial length of abutment face 300 is less than a thickness of wall 201 immediately below upper end 215 as defined between the inward 209 and outward 225 facing surfaces at this upper region 221. Ledge 213 is positioned axially between upper end 215 and the raised first contact region 219.
Referring to
Ribs 303 project radially inward from a radially inner side 503 of main body 301. The radial length of ribs 303 is much less than the corresponding radial length of flanges 302. In particular, a radial length of ribs 303 is approximately equal to the thickness of inner wall 503 of main body 301. Ribs 303 as illustrated in
According to further specific implementations, main body 301 may comprise alternate configurations including for example and I-shaped cross sectional profile with flanges 302 extending from a first side and ribs 303 extending from a second side.
An upper face of ring 214 may be divided radially into a radially inner annular face 501 and radially outer annular face 500. Face 501 is defined by an upper end of main body 301 and face 500 is defined by an upper face of the uppermost flange 302. Accordingly, face 500 is inclined upwardly relative to face 501 that is aligned approximately perpendicular to axis 106. Accordingly, faces 500 and 501 in combination with the inward facing surface of the spacer ring 203 at region 204 and the outward facing surface 225 of crushing shell 200 at region 221 define an annular trough into which debris crushing material is collected to press axially downward onto sealing ring 214.
As will be appreciated, the present shell 200 is compatible and intended for use with a range of sealing ring shapes and configurations not restricted to a seal having a main body and at least one radially extending flange. In particular, the present shell 200 and topshell assembly may comprise a sealing ring formed by a more ‘conventional’ construction being either a solid or hollow body having a rectangular, square, circular or oval cross sectional profile. According to further embodiments, the cross section profile may be O-shaped, C-shaped, D-shaped, E-shaped or I-shaped. In particular, and according to a preferred embodiment, the sealing ring may comprise any one of these cross sectional shape profiles and does not comprise a radially extending flange.
Referring to
In use, sealing ring 214 is configured to prevent dust and debris particles from passing downwardly beyond cavity 304 and between the mating surfaces 218, 211 of the intermediate spacer ring 203 and crushing shell 200 respectively. Advantageously, the present sealing ring 214 is configured to be both self-sealing to provide a seal strength between the opposed spacer ring 203 and shell 200 that increases as more debris and particles collect on top off ring 214 from within the crushing zone 202. That is, as material is crushed within zone 202, particulates and ‘fines’ settle into the upper region of cavity 304 directly on top of ring 214 and in contact with uppermost surface of the ring 214 (i.e., surfaces 500, 501 referring to the embodiment of
In particular and referring to
A further embodiment is illustrated in
As will be noted from
According to further embodiments, groove 1000 may be embedded within upper region 221 a distance below upper end 215 at a position corresponding to the location of ledge 213 described with reference to
According to the specific embodiment, sealing ring 214 comprises a rubber material having a Shore A hardness of between 35 to 90 and preferably substantially 65. Additionally, the ring 214 of
| Number | Date | Country | Kind |
|---|---|---|---|
| 13175060 | Jul 2013 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2014/060244 | 5/19/2014 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2015/000626 | 1/8/2015 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 1791584 | Symons | Feb 1931 | A |
| 2110276 | Rumpel | Mar 1938 | A |
| 2970775 | Everett | Feb 1961 | A |
| 2971705 | Ewald | Feb 1961 | A |
| 4198003 | Polzin | Apr 1980 | A |
| 4454994 | Johnson et al. | Jun 1984 | A |
| 5769340 | Jean | Jun 1998 | A |
| 6007009 | Sheridan et al. | Dec 1999 | A |
| 6536693 | Van Mullen et al. | Mar 2003 | B2 |
| 20050156070 | Olsson et al. | Jul 2005 | A1 |
| 20090008489 | Nieminen et al. | Jan 2009 | A1 |
| Number | Date | Country |
|---|---|---|
| 1507614 | Nov 1969 | DE |
| 1570015 | Jun 1980 | GB |
| 2004136252 | May 2004 | JP |
| 2004110626 | Dec 2004 | WO |
| 2008140375 | Nov 2008 | WO |
| 2010123431 | Oct 2010 | WO |
| 2012005651 | Jan 2012 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 20160129448 A1 | May 2016 | US |
