Field of the invention
[0001] The present invention relates to replaceable liner segments for use in a topshell
of a gyratory or cone crusher.
[0002] Gyratory crushers and cone crushers are two types of rock crushing systems which
generally break apart rock, stone or other material in a crushing gap between a stationary
element and a moving element.
[0003] A gyratory or cone crusher is comprised of a head assembly including a crusher head
that gyrates about a vertical axis within a stationary bowl attached to a main frame
of the rock crusher. The crusher head is assembled surrounding an eccentric that rotates
about a shaft to impart the gyratory motion to the crusher head which crushes rock,
stone or other material as the material travels through a crushing gap between the
crusher head and the bowl. The crushed material exits the crusher through the bottom
of the crushing gap.
[0004] The eccentric can be driven by a variety of power drives, such as an attached gear,
driven by a pinion and countershaft assembly, and a number of mechanical power sources,
such as electrical motors or combustion engines.
[0005] While gyratory crushers and cone crushers operate according to the same principles,
the longer shaft or spindle of a gyratory crusher regularly has its upper end supported
by a spider bearing, whereas the shorter spindle of the cone crusher is not suspended
but supported in a bearing below the gyratory head or cone. Gyratory crushers are
often used as primary crushers, i.e. heavy-duty machines designed to process large
material sizes. Secondary and tertiary crushers are intended to process relatively
smaller feed materials. Cone crushers are often utilised as downstream crushers.
Prior Art
[0006] Gyratory and cone crushers utilize wear parts to protect the machine from damage
and perform the actual crushing of the material. The two types of wear part are the
mantle and a set of several liner segments, often concave liner segments. The mantle
is fixed to the main shaft, and the concave liners (or simply "concaves") are fixed
to the frame of the topshell of the crusher. The concaves are arranged in several
rows sitting on top of each other.
[0007] Wear parts may be made from chilled cast iron or from steel alloy, such as manganese
steel, depending on the character of the material to be crushed and the particular
class of service for which the machine is intended. Manganese steel combines extreme
toughness with high wear resistance and has therefore developed into the universal
choice for crushing hard, tough rock, even regardless of the class of service or the
type of crusher. A common material is 12-14% manganese steel, also known as Hadfield
steel. Different alloys have been used for liner segments in upper, middle and bottom
parts of the crushing chamber.
[0008] Typically, both the mantle and the concaves wear and distort due to the significant
pressures and impact loading forces they transmit. It is common to use backing compounds,
e.g. an epoxy backing, to structurally reinforce the concaves and assist with contact
between the radially outward facing surface of the concaves and the radially inward
facing surface of the topshell or frame. In fact, the crushing forces must be transferred
to the liners from the structural crusher parts which they protect, and for that,
intimate contact is needed between the back of the liners and the surface of the topshell
or frame.
[0009] The aforementioned wear parts are changed regularly, i.e. in intervals of 12, 18
or 24 months. The replacement is a relatively fast process for the mantle, which is
usually replaced by swapping for a spare main shaft assembly. In contrast, the replacement
of the concave liners is cumbersome. Typically, one unit per row - the so-called keystone'
or 'key segment' - is removed first so as to release any hoop stresses stored in the
respective row of concaves. This is commonly done by using a thermal lance to cut
a valley in the concave which therefore allows it to be chiselled off with a rock
breaker or other such hammer system. Once the 'keystone' is removed, the remaining
concaves in the row are removed one by one along the circumferential direction - a
rock breaker, i.e. a hydraulic or pneumatic hammer, is driven behind the concaves
at the top leading edge to break the epoxy backing between the concaves and the supporting
frame of the crusher and to remove the concaves one by one.
[0010] In a large primary gyratory crusher, there are several rows of concaves to replace,
such as e.g. four tiers (rows) with 20 segments per tier. The existing methodology
for the removal and replacement of concave liners - a process also known as a "re-metal"
- is very time consuming, often taking multiple days to complete. This equals downtime
and lost production for the operator of the mine. As explained above, gyratory crushers
are frequently used for first stage sizing in the minerals processing industry, so
that any associated downtime can have serious consequences for downstream processing
and therefore the overall plant productivity.
[0011] The removal of concaves requires the use of hot works as well as the operation of
a large rock breaker. Also, workers have to be specially trained to be able to operate
inside the topshell area of the crusher.
[0012] WO 01/28688 A1 discloses securement means for fixing and locating a head liner on the head bearing
housing of a gyratory crusher. The securement means includes an inner substantially
annular band and an outer substantially annular band. The inner band has an inner
circumferential surface for contacting the external surface of the housing and an
outer circumferential surface which tapers frusto-conically. The outer band has an
outer circumferential surface for contacting an internal surface of the liner and
an inner circumferential surface which tapers frusto-conically. The securement means
defines a circumferential array of axially extending holes intermediate the inner
and outer surfaces whereby, fasteners such as bolts are able to be inserted into the
securement means to enable application of axial forces to the securement means. The
outer and inner frusto-conical surfaces of said bands are adapted to interact whereby
the axial forces force the inner band to contract radially and force the outer band
to expand radially.
[0013] From
US 720,853 a rock crusher is known which has concaves with parallel side edges whereby they may
be reversed end for end. Longitudinally tapering keys are provided between adjacent
concaves to lock the concaves together.
[0014] Also known is a concave removal press sold by Tri Star Design
(https://tristardesign.com/product/concave-removal-press/) . Said press attaches to the outside of the frame of the gyratory crusher and has
a push rod extending into the crusher through a hole drilled into the frame in the
area of the concave to be removed. The push rod is actuated by a hydraulic cylinder
to push against the outer surface of the worn concave, thereby loosening the concave
from the frame.
Summary of the invention
[0015] In view of the above, an object underlying the invention is to facilitate the removal
of worn liner segments from a gyratory or cone crusher.
[0016] To achieve this object, the present invention provides, on the one hand, a key liner
segment for a gyratory or cone crusher as recited in claim 1.
[0017] The key liner segment of the invention is for use in a topshell of a gyratory or
cone crusher. The topshell comprises a frame and a plurality of replaceable liner
segments arranged in at least one tier or row along the inner circumference of the
frame, with side surfaces of each liner segment facing adjacent liner segments in
the tier or row.
[0018] According to the invention, the side surfaces of the key liner segment converge in
a radially outward direction of the topshell.
[0019] The invention thereby provides a specially configured key segment or key concave
having sidewalls which converge in the radially outward direction. Due to this wedge-shaped
configuration, the key segment can be dismounted from the frame by being pressed radially
inwards. This removes the need for hot-works on the inside of the crusher requiring
the use of a thermal lance to cut away the key segment in order to allow the remainder
of the set to be removed.
[0020] The key segment of the invention is particularly useful in combination with at least
one complementary liner segment as recited in claim 2, which is configured to be arranged
adjacent to the key liner segment in a tier or row along the inner circumference of
the topshell, wherein facing side surfaces of the key liner segment and at least one
complementary liner segment are essentially parallel to each other in the mounted
state of the segments. In this constellation, the complementary sidewalls of the key
segment and the complementary segment(s) provide for a wedge effect which creates
a force perpendicular to the adjacent side walls of the segments, thereby forcing
the segments further together in the hoop direction and providing for a tight joint
between the individual segments in a tier or row of segments in which the key segment
and complementary segment(s) are installed. This effect can be influenced by manufacturing
the key segment and/or the and complementary segment(s) to a tight tolerance. The
wedge effect is particularly pronounced if two complementary liner segments are configured
to be arranged adjacent to the key liner segment at either side thereof in the mounted
state of the segments.
[0021] The combination of the key liner segment and the complementary liner segment(s) may
have a shape which substantially corresponds to the shape of at least one further
liner segment of the set. In an embodiment, the set of liner segments has a series
of liner segments which are all substantially identical with each other, wherein one
of the identical segments is replaced by a combination of a key liner segment and
at least one complementary segment, such as a combination of a key liner segment and
two complementary liner segments at either side thereof. In practice, a tier or row
of segments could for example include 20 identical segments, one of which is replaced
by a combination of a key liner segment and two complementary liner segments, so that
19 identical segments remain.
[0022] The set of liner segments may further comprise means for tightening the key liner
segment against the frame, such as at least one bolt configured to extend through
a bolt hole in the frame from the outside of the frame and to be fastened, e.g. threadingly
fastened, to the key liner segment. Instead of said bolt or bolts, alternative tightening
means could be used, including e.g. slotted rods cooperating with wedges or spreaders.
[0023] The invention also provides a topshell for a gyratory or cone crusher as claimed
in claim 7. The topshell comprises a frame and a plurality of replaceable liner segments
arranged in at least one tier or row along the inner circumference of the frame, with
side surfaces of each liner segment facing adjacent liner segments in the tier or
row. According to the invention, the plurality of replaceable liner segments include
at least one key liner segment which is configured as described above, i.e. which
has side surfaces which converge in a radially outward direction of the topshell.
[0024] The plurality of replaceable liner segments may further comprise at least one complementary
liner segment configured to be arranged adjacent to the key liner segment in a tier
or row along the inner circumference of the frame of the crusher, wherein facing side
surfaces of the key liner segment and at least one complementary liner segment are
essentially parallel to each other in the mounted state of the segments. Specifically,
the plurality of replaceable liner segments may include two complementary liner segments
adjacent to the key liner segment at either side thereof. The combination of the key
liner segment and the complementary liner segment(s) preferably has a shape which
substantially corresponds to the shape of at least one further liner segment in the
set of liner segments.
[0025] The topshell may further comprise means for tightening the key liner segment against
the frame. The tightening means may include at least one bolt configured to extend
through a bolt hole in the frame from the outside of the frame and to be fastened,
e.g. threadingly fastened, to the key liner segment. To accommodate the tightening
means, a portion of an outer circumferential surface of the frame at a location radially
outward of the key liner segment may be formed with a mounting seat for an installation
tool.
[0026] Also, in a manner known per se, backing such as an epoxy backing may be disposed
between the outer surface of the liner segment and the inner surface of the frame.
[0027] Alternatively or in addition, a through hole may be formed through a wall of the
frame of the crusher at a location radially outward of the key liner segment, the
through hole being sized for an installation tool to pass through. The tool could
be the tool of a hydraulic push/pull ram.
[0028] The invention further provides a gyratory or cone crusher as recited in claim 14,
comprising a key liner segment, a set of liner segments, and/or a topshell as described
above. The gyratory or cone crusher as such may comprise a head assembly including
a crusher head provided with a first crushing shell or mantle, and a topshell comprising
a frame provided with a second crushing shell or bowl, wherein the mantle and bowl
define a crushing gap between them. The bowl is constituted by a plurality of liner
segments, with outer surfaces of the liner segments facing an inner surface of the
frame.
[0029] The invention also provides a method for installing replaceable liner segments to
an inner wall of a frame of a topshell of a gyratory or cone crusher as claimed in
claim 15. The method comprises:
- arranging a plurality of replaceable liner segments in at least one tier or row along
the inner circumference of the frame, with an inner surface of each liner segment
facing towards the center of the topshell, an outer surface of each of the liner segments
facing an inner surface of the frame, and side surfaces of each liner segment facing
adjacent liner segments in the tier or row, wherein a gap is left between two of the
liner segments which are placed next to each other in the hoop direction of the topshell,
and
- installing at least one key liner segment in the gap between the two liner segments,
the key liner segment having side surfaces which converge in a radially outward direction
of the topshell.
[0030] The step of installing the key liner segment may include pulling the key liner segment
in a radially outward direction of the frame, preferably by providing an installation
tool at the outside of the frame, passing the tool through a wall of the frame towards
the key liner segment, engaging the tool with the key liner segment, and operating
the tool to apply a pulling force to the key liner segment.
[0031] The wedge shape of the key liner segment resulting from the converging side walls
thereof can be suitably made use of by arranging, prior to installing the key liner
segment, at least one complementary liner segment in the tier or row, wherein the
said gap is left between the complementary liner segment and another liner segment
placed next to it in the hoop direction of the topshell. When the key liner segment
is then installed in the gap and adjacent to the complementary liner segment so that
facing side surfaces of the key liner segment and the complementary liner segment
are essentially parallel to each other in the mounted state of the segments, the key
liner segment applies a force onto the adjacent complementary segment in a direction
perpendicular to the adjacent side walls of the segments. This can result in a tight
joint between the adjacent segments, removing the need to shim the liner segments
as it is necessary with conventional arrangements.
[0032] Finally, the invention also provides a method for removing replaceable liner segments
from an inner wall of a frame of a topshell of a gyratory or cone crusher as claimed
in claim 18, the liner segments being arranged in at least one tier or row along the
inner circumference of the frame, with an inner surface of each liner segment facing
towards the center of the topshell, an outer surface of each of the liner segments
facing an inner surface of the frame, and side surfaces of each liner segment facing
adjacent liner segments in the tier or row. The method comprises removing at least
one key liner segment from the tier or row of liner segments, the key liner segment
having side surfaces which converge in a radially outward direction of the topshell.
[0033] Considering that the converging side walls of the key liner segment allow for a removal
of the key liner segment towards the interior of the frame (which is not possible
with conventional, self-retaining segments), the step of removing the key liner segment
may suitably include pushing the key liner segment in a radially inward direction
of the frame, preferably by providing an installation tool at the outside of the frame,
passing the tool through a wall of the frame towards the key liner segment, engaging
the tool with the key liner segment, and operating the tool to apply a pushing force
to the key liner segment.
[0034] Removing the key segment releases any hoop stresses in the tier or row of segments.
Thereafter, the remaining liner segments can be separated from the frame.
[0035] If several rows of liners are provided, as is usually the case in gyratory crushers,
the removal of the rows of segments would start with the uppermost row of segments
in the crusher.
[0036] Upon completion of the dismounting of one row of segments, the dismounted liner segments
can then be removed from the crusher in any known manner. For example, a removal tray
or bin may be positioned below the row of liner segments being ejected, and an entire
tier or row of segments may be lifted out of the crusher at the same time.
[0037] The installation tool used for installing and/or removing the segments may be operated
pneumatically or hydraulically. Also conceivable in principle are mechanically operated
tools, though.
Brief description of the drawings
[0038] The above, as well as additional objects, features and advantages of the present
invention will be better understood through the following illustrative and non-limiting
detailed description of preferred embodiments of the present invention, with reference
to the appended drawings, where the same reference numerals will be used for similar
elements, wherein:
Figure 1 illustrates a topshell of a gyratory crusher equipped with liner segments;
Figure 2 is a sideview of a crusher;
Figure 3 is a top view of a topshell of a conventional crusher;
Figure 4 is a top view of the topshell of Figure 1;
Figure 5 is a cross sectional view of the topshell of Figure 1 in the area of a key
liner segment according to the invention;
Figure 6 is a partial view of Figure 4;
Figure 7 is a top view of the topshell of Figure 1 with a key segment partially removed;
and
Figure 8 shows schematically a gyratory crusher of the prior art.
Detailed description of a preferred embodiment
[0039] Figure 8 schematically illustrates a previously known gyratory crusher 100 in section.
[0040] The sole purpose of this illustration is to explain the basic operating principle
of a gyratory or cone crusher, and it is not to be understood to imply any limitation
of the present invention.
[0041] The gyratory crusher 100 has a vertically extending main shaft 102 and a frame 104.
The shaft 102 has a longitudinal axis coinciding with a central axis A of the crusher.
Other than most gyratory crushers which have their main shaft suspended from a spider
bearing, the one illustrated here is spider-less. The crusher includes an eccentric
assembly which in this previously known embodiment is provided in the form of two
eccentric rings 106, 108 rotatably supported about the shaft 102. A crusher head 110
is radially supported by and rotatable about the eccentric rings 106, 108.
[0042] A drive shaft 112 is connected to a drive motor and is provided with a pinion 114.
The drive shaft 112 is arranged to rotate the lower eccentric ring 108 by the pinion
114 engaging a gear rim 116 mounted on the lower eccentric ring 108. When the drive
shaft 112 rotates the lower eccentric ring 108, the crusher head 110 executes a gyrating
movement.
[0043] An inner crushing shell 118, also designated a mantle, is mounted on the crusher
head 110. Crusher head 110 and mantle 118 are parts of an overall head assembly. An
outer crushing shell 120, also designated a bowl, is mounted on the frame 104. A crushing
gap 122 is formed between the two crushing shells 118, 120. When the crusher 100 is
operated, material to be crushed is introduced in the crushing gap 122 and is crushed
between the mantle 118 and the bowl 120 as a result of the gyrating movement of the
crusher head 110, during which movement the mantle 118 approaches the bowl 120 along
a rotating generatrix and moves away therefrom along a diametrically opposed generatrix.
[0044] Figure 1 illustrates a topshell 1 of a gyratory crusher which is constructed in accordance
with the present invention.
[0045] The topshell 1 includes an outer frame 4 which is substantially annular, and a bowl
which is constituted by a plurality of liner segments 3 (only hinted at in Figure
1), with inner surface of each liner segment 3 facing towards the center of the bowl,
and outer surfaces of the liner segments 3 facing an inner circumferential surface
of the frame 4.
[0046] The liner segments 3 are arranged in at least one tier or row along the inner circumference
of the frame 4. In the present case, the liner segments are provided in the form of
concave liners, also designated concaves, in view of their concave shape which follows
the concave shape of the inner circumference of the frame 4. The expressions "concaves",
"liners" and "segments" may therefore be used interchangeably to designate the liner
segments.
[0047] In the operational state of the crusher, an epoxy backing (not specifically illustrated)
would be poured into the remaining gap between the outer surfaces of the liner segments
3 and the facing inner circumferential surface of the frame 4. The epoxy backing is,
in a manner known per se, provided to structurally reinforce the concaves 3 and assist
with contact between the radially outward facing surfaces of the concaves 3 and the
radially inward facing surfaces of the frame 4. The backing material fills the void
between the concaves 3 and the frame 4 to provide a solid assembly.
[0048] For the position and arrangement of the topshell 1 in a crusher, reference is made
to Figure 2: Figure 2 illustrates a crusher having an upper topshell 101 and a lower
topshell 102. The topshell 1 of the invention could be used as the upper 101 and/or
the lower topshell 102 or as the only topshell of a crusher.
[0049] Figure 3 schematically illustrates a topshell of a conventional crusher from above.
It is apparent from this illustration that the liner segments 3 are arranged adjacent
to each other in a tier or row along the circumference of the frame 104 of the topshell.
The side surfaces of the segments 3 are generally aligned along radial lines, which
makes the side surfaces of each of the individual segments 3 diverge in a radially
outward direction of the frame (see the diverging lines "d" in Figure 3). Due to this
configuration, the segments 3 are self-retaining (i.e. cannot easily be moved towards
the radial center of the topshell, as indicated by the crossed-out arrow in Figure
3). If the liner segments 3 are worn and need to be exchanged, a first liner segment
3 - the so-called "key segment" - must therefore be cut away before the remaining
concaves can be disassembled. The removal of the "key segment" releases any hoop stresses
stored in the respective row of concaves. Once the "key segment" is removed, the remaining
concaves in the row are removed one by one along the circumferential direction.
[0050] Conventional crushers therefore require the gouging out of one concave in order to
allow the remainder of the set to be removed. Conventionally, the key concave is often
removed by thermal lancing.
[0051] In contrast, according to the present invention, the key segment is specifically
configured to facilitate its removal from the frame and to avoid the need to use a
thermal lance. This will be described with reference to Figure 4 which shows the topshell
1 of Figure 1 from above.
[0052] Similar as in the conventional topshell, the frame 4 of the topshell 1 of the invention
is equipped with a series of liner segments 3, most of which correspond to standard
liner segments 3 similar to the ones used in the conventional topshell of Figure 3.
The standard liner segments 3 are arranged in a tier or row along the inner circumference
of the frame 4, with their side surfaces adjacent to each other. Similar as in the
conventional case, the side surfaces of each of the standard liner segments 3 diverge
as seen in a radially outward direction of the frame 4 (see the diverging lines "d"
in Figure 4).
[0053] Between two of the standard liner segments 3 which are arranged next to each other
in the hoop direction of the topshell 1, a key liner segment 3k is located, and two
complementary liner segments 3c are provided in the embodiment illustrated here.
[0054] The key liner segment 3k has side surfaces SK which converge as seen in a radially
outward direction of the frame 4 (see the converging lines "c" in Figure 4).
[0055] The complementary liner segments 3c are arranged to both sides of the key liner segment
3k in the circumferential or hoop direction of the frame 4, and each of the two side
surfaces SK of the key liner segment 3k is essentially parallel to the facing side
surface SC of the respective adjacent complementary liner segment 3c in the mounted
state of the segments. At the sides facing away from the key liner segment 3k in the
hoop direction of the frame 4, the side surfaces of the complementary liner segments
3c are in turn parallel to the side surfaces of the respective adjacent standard segments
3.
[0056] In the embodiment, the key segment 3k and the complementary segments 3c to both sides
thereof together have a shape which is basically identical with the shape of a standard
concave 3. In other words, it can be said that a standard concave 3 has been divided
into three parts 3c, 3k, 3c; or that a standard concave 3 has been replaced by the
combination of the key liner segment 3k and the two complementary liner segments 3c.
[0057] Due to its converging side walls SK, the key concave 3k can easily be forced radially
inwards, unlike the standard segments 3 which are self-retaining and therefore require
the use of a thermal lance or the like to remove a key segment.
[0058] The angle which the converging side surfaces SK of the key liner segment 3k form
with each other is suitably chosen according to the individual case and considering
the overall geometric configuration of the topshell. Suitable angles may for example
be in the range of up to 45 degrees, or up to 30 degrees, or between 5 and 25 degrees,
or between 10 and 20 degrees, or at about 15 degrees.
[0059] Figure 5 provides further details as to the installation and fastening of the key
liner segments 3k according to the invention. Figure 5 is a cross sectional view of
that part of the topshell 1 of Figure 1 which accommodates the key liner segments
3k of two tiers or rows of segments. In the present embodiment, the key liner segments
3k are located at approximately the same location in the hoop direction of the frame
4.
[0060] In the mounted state of the segments including the key liner segments 3k which is
illustrated in Figure 5, two threaded bolts 6 are used to fasten each of the key liner
segments 3k to the frame 4. The threaded bolts 6 extend from the outside of the frame
4 through corresponding bolt openings 8 (Figure 1) provided in the frame 4. The heads
7 of the bolts 6 rest against a seating surface machined for this purpose on the outward
facing surface of one of a series of vertically extending stays 5 formed on the outside
of the frame 4. Due to the wedge shape of the key segment 3k created by the converging
side walls SK thereof, the key segment 3k in its fastened state acts on the adjacent
complementary segments 3c in a direction perpendicular to the side walls thereof,
thereby pushing the segments 3 in the tier or row further together in the hoop direction
of the topshell 1.
[0061] The technical effects achieved by the invention will become further apparent from
the following description of a process of installing a series of segments 3 including
the key liner segment 3k and the complementary segments 3c of the invention to the
topshell of a crusher, wherein reference is further made to Figures 1 to 7.
[0062] In a first step, a tier or row of standard liner segments 3 is assembled to the frame
4 in a manner known per se wherein, however, a gap or space is left between a first
and a last liner segment 3 in a hoop direction of the frame 4. A combination of the
above described key liner segment 3k and two complementary segments 3c is then installed
within said space, so that the two complementary segments 3c come to rest with their
side surfaces SC facing the key liner segment 3k and their opposite side surfaces
facing adjacent standard segments 3.
[0063] The key segment 3k and complementary segments 3c are installed at a specific location
of the frame 4, i.e. so that the key segment 3k is aligned with one of the aforementioned
mounting seat surfaces provided to the frame 4. In addition to the aforementioned
bolt holes 8, each of the two mounting seat surfaces associated with the key liner
segments 3k also accommodates a further through hole 10 which is provided in this
embodiment between the two bolt openings 8 as seen in a vertical direction. This further
through hole 10 is provided to allow for the rod-shaped tool 21 of a ram to pass through.
A corresponding ram 20 including tool 21 is very schematically illustrated in Figure
5. A hydraulic push/pull ram can suitably be used, or e.g. a jacking bolt.
[0064] To fasten the key liner segment 3k to the frame 4, the tool 21 of the hydraulic ram
20 is engaged with to the key liner segment 3k, and the hydraulic ram 20 is then operated
in its pull mode to force the key segment 3k towards the outer circumference of the
topshell 1. Due to the wedge shape of the key segment 3k created by the converging
side walls SK thereof, one component of the pull force applied to the key segment
3k acts on the adjacent complementary segments 3c in a direction perpendicular to
the side walls thereof, thereby pushing the segments 3 in the tier or row further
together in the hoop direction of the topshell 1. In Figure 6 which is a partial enlarged
view of Figure 4, the pull force is illustrated at Fpull, and the force component
acting on the complementary segments 3c is illustrated by way of a series of smaller
arrows.
[0065] The key segment 3k is preferably dimensioned so that a tight joint between the individual
segments 3, 3k, 3c in the row is achieved when wedging the key segment 3k in between
the complementary segments 3c. This removes the need to shim concave segments during
installation. The pulling force which is applied onto the key segment 3k can be monitored
by e.g. detecting the pressure in a hydraulic circuit of the ram 20. When a predetermined
force has been reached which signals that the segments in the tier or row have achieved
the desired tight fit, the key segment 3k is fastened to the frame 4 using the aforementioned
bolts 6 or other tightening elements. The ram 20 may be de-energised and stored.
[0066] The push/pull ram 20 is suitably also used to remove the key concave 3k when the
liner segments are to be replaced. To remove the key concave 3k, the ram 20 is reconnected,
the fasteners 6 are removed and the ram 20 is operated in its push mode. The ram 20
applies a pushing force onto the key concave 3k which is sufficient to overcome the
strength of the epoxy backing holding the key concave 3k in place, and the key concave
3k will come loose. Due to its converging side walls SK, the key concave 3k can easily
be forced radially inwards (see Figure 7), unlike the standard segments 3 which are
self-retaining (see Figure 3) and therefore require the use of a thermal lance or
the like to remove a key segment. The invention thereby removes the need for hot-works
on the inside of the crusher requiring gouging out of one concave in order to allow
the remainder of the set to be removed.
[0067] The dismounted liner segments 3, 3k, 3c are then removed from the crusher in any
known manner. For example, a removal tray or bin (not shown) could be positioned below
the row of liner segments being ejected, and an entire tier or row of segments could
be lifted out of the crusher at the same time.
[0068] It is apparent from the above that the invention requires certain modifications to
the structure of the topshell. In the embodiment illustrated above, holes 8, 10 are
to be drilled for allowing the bolts 6 and the tool 21, respectively, to pass through.
The flat mounting seat surfaces are to be machined into the topshell.
[0069] The key liner segment 3k is customized, too: apart from the converging side walls
SK which differentiates it from the standard liner segments 3, the key liner segment
3k in the illustrated embodiment also requires threaded openings receiving the bolts
6 as well as a portion for engagement with the tool 21 of the push/pull ram 20.
[0070] The invention will result in an overall improvement in shutdown efficiency and effectiveness
for all concave re-metal works. The user will also be able to recognise a financial
benefit by reducing maintenance shutdown duration.
[0071] While one embodiment of the invention has been described with reference to Figures
1 to 7, the scope of the invention is not restricted to this embodiment but defined
by the appended claims. Various modifications are included within the scope.
1. A key liner segment (3k) for use in a topshell (1) of a gyratory or cone crusher,
the topshell (1) comprising a frame (4) and a plurality of replaceable liner segments
(3) arranged in at least one tier or row along the inner circumference of the frame
(4), with side surfaces of each liner segment (3) facing adjacent liner segments (3)
in the tier or row,
characterized in that
the side surfaces (3k) of the key liner segment (3) converge in a radially outward
direction of the topshell (1).
2. A set of liner segments (3, 3k, 3c) for use in a topshell (1) of a gyratory or cone
crusher,
the set including the key liner segment (3k) of claim 1 and at least one complementary
liner segment (3c) configured to be arranged adjacent to the key liner segment in
a tier or row along the inner circumference of the topshell (1),
wherein facing side surfaces of the key liner segment and at least one complementary
liner segment are essentially parallel to each other in the mounted state of the segments.
3. The set of liner segments of claim 2, including two complementary liner segments configured
to be arranged adjacent to the key liner segment at either side thereof in the mounted
state of the segments.
4. The set of liner segments of claim 2 or 3, wherein the combination of the key liner
segment and the complementary liner segment or segments has a shape which substantially
corresponds to the shape of at least one further liner segment (3) of the set.
5. The set of liner segments of any one of claims 2 to 4, further comprising means for
tightening the key liner segment against the frame (4).
6. The set of liner segments of claim 5, wherein the tightening means include at least
one bolt configured to extend through a bolt hole in the frame (4) from the outside
of the frame and to be fastened, e.g. threadingly fastened, to the key liner segment
(3k).
7. A topshell (1) for a gyratory or cone crusher, comprising a frame (4) and a plurality
of replaceable liner segments (3) arranged in at least one tier or row along the inner
circumference of the frame (4), with side surfaces of each liner segment (3) facing
adjacent liner segments (3) in the tier or row,
characterized in that
the plurality of replaceable liner segments (3) include at least one key liner segment
(3) having side surfaces which converge in a radially outward direction of the topshell
(1).
8. The topshell (1) of claim 7, wherein the plurality of replaceable liner segments (3)
further comprise at least one complementary liner segment (3c) configured to be arranged
adjacent to the key liner segment in a tier or row along the inner circumference of
the frame (4) of the crusher, wherein facing side surfaces of the key liner segment
and at least one complementary liner segment are essentially parallel to each other
in the mounted state of the segments.
9. The topshell (1) of claim 8, wherein the plurality of replaceable liner segments (3)
include two complementary liner segments adjacent to the key liner segment at either
side thereof, wherein the combination of the key liner segment and the two complementary
liner segments preferably has a shape which substantially corresponds to the shape
of at least one further liner segment (3) in the set of liner segments (3).
10. The topshell (1) of any one of claims 7 to 9, further comprising means for tightening
the key liner segment to the frame (4).
11. The topshell (1) of claim 10, wherein the tightening means include at least one bolt
configured to extend through a bolt hole in the frame (4) from the outside of the
frame and to be fastened, e.g. threadingly fastened, to the key liner segment (3k)
.
12. The topshell (1) of any one of claims 7 to 11, wherein a portion of an outer circumferential
surface of the frame (4) of the crusher at a location radially outward of the key
liner segment (3k) is formed with a mounting seat for an installation tool.
13. The topshell (1) of any one of claims 7 to 12, wherein a through hole (10) is formed
through a wall of the frame (4) of the crusher at a location radially outward of the
key liner segment (3k), the through hole (10) being sized for an installation tool
to pass through.
14. A gyratory or cone crusher comprising
- a key liner segment (3k) as recited in claim 1,
- a set of liner segments (3, 3k, 3c) as recited in any one of claims 2 to 6, and/or
- a topshell as recited in any one of claims 7 to 13.
15. A method for installing replaceable liner segments (3, 3k, 3c) to an inner wall of
a frame (4) of a topshell (1) of a gyratory or cone crusher, the method comprising:
- arranging a plurality of replaceable liner segments (3) in at least one tier or
row along the inner circumference of the frame (4), with an inner surface of each
liner segment (3) facing towards the center of the topshell (1), an outer surface
of each of the liner segments (3) facing an inner surface of the frame (4), and side
surfaces of each liner segment (3) facing adjacent liner segments (3) in the tier
or row, wherein a gap is left between two of the liner segments which are placed next
to each other in the hoop direction of the topshell (3), and
- installing at least one key liner segment (3) in the gap between the two liner segments
(3), the key liner segment (3k) having side surfaces which converge in a radially
outward direction of the topshell (1).
16. The method of claim 15, wherein the step of installing the key liner segment (3k)
includes pulling the key liner segment in a radially outward direction of the frame
(4), preferably by providing an installation tool (21) at the outside of the frame
(4), passing the tool (21) through a wall of the frame (4) towards the key liner segment
(3k), engaging the tool (21) with the key liner segment (3k), and operating the tool
(21) to apply a pulling force to the key liner segment (3k).
17. The method of claim 15 and 16, wherein, prior to installing the key liner segment
(3k), at least one complementary liner segment (3c) is arranged in the tier or row,
the said gap is left between the complementary liner segment (3c) and another liner
segment placed next to it in the hoop direction of the topshell (3), and the key liner
segment (3k) is then installed in the gap and adjacent to the complementary liner
segment (3c) so that facing side surfaces of the key liner segment and the complementary
liner segment are essentially parallel to each other in the mounted state of the segments.
18. A method for removing replaceable liner segments (3, 3k, 3c) from an inner wall of
a frame (4) of a topshell (1) of a gyratory or cone crusher, the liner segments (3)
being arranged in at least one tier or row along the inner circumference of the frame
(4), with an inner surface of each liner segment (3) facing towards the center of
the topshell (1), an outer surface of each of the liner segments (3) facing an inner
surface of the frame (4), and side surfaces of each liner segment (3) facing adjacent
liner segments (3) in the tier or row, the method comprising:
- removing at least one key liner segment (3) from the tier or row of liner segments
(3), the key liner segment (3k) having side surfaces which converge in a radially
outward direction of the topshell (1).
19. The method of claim 18, wherein the step of removing the key liner segment (3k) includes
pushing the key liner segment in a radially inward direction of the frame (4), preferably
by providing an installation tool (21) at the outside of the frame (4), passing the
tool (21) through a wall of the frame (4) towards the key liner segment (3k), engaging
the tool (21) with the key liner segment (3k), and operating the tool (21) to apply
a pushing force to the key liner segment (3k).
20. The method of claim 18 or 19, wherein the remaining liner segments are separated from
the frame (4) subsequent to the removal of the key liner segment (3k).