The present invention is related to a mill liner assembly to be mounted on a shell of a grinding mill, the mill liner assembly including a layer providing a substantially non-sticking surface for impeding adhesion of elements of the mill liner assembly with each other or with the shell.
As is well known in the art, an inner diameter of a shell of a grinding mill typically is lined with a mill liner, for wear protection, i.e., to protect the shell. The mill liner may include, for instance, shell plates positioned on the inner diameter so as to substantially cover the shell's inner diameter, and lifter bars spaced apart from each other, with the shell plates positioned between the lifter bars and the shell. The heads of bolts extending through the shell are held in the lifter bars respectively, so that tightening nuts on the portions of the bolts extending outside the shell urges the lifter bars against the shell plates and ultimately the shell, for securing the lifter bars and shell plates to the shell. The lifter bars are positioned to press onto portions of the shell plates, to hold the shell plates against the inner diameter. As is known, the shell plates and the lifter bars typically are made of various materials, for instance, the shell plates may be made of steel and/or a rubber or rubber-like material, and the lifter bars may be made of steel, and/or rubber or rubber-like material.
Typically, once the mill liner has become worn to a certain extent, all or part of the mill liner is replaced. Often, only a part of the mill liner is to be replaced. For instance, the lifter bars may have a substantially shorter useful life than the shell plates on which the lifter bar is at least partially positioned. In this situation, when the lifter bars have become worn, it is sometimes intended to replace only the lifter bars, i.e., where the shell plates still have a substantial portion of their useful life remaining. However, in practice, removal of the lifter bars alone (i.e., without removing some or all of the shell plates) is usually very difficult. This is because each lifter bar, and the shell plates with which the lifter bar is engaged, tend to become relatively securely fused or bonded to each other over time. It appears that the mechanism which results in parts of the mill liner adhering together after use over a period of time has not been studied in detail. It is thought that, where the fused elements include one or more elastomeric materials, the elements tend to adhere together over time due to compression set.
For the foregoing reasons, there is a need for an improved mill liner assembly in which elements thereof are readily separable from each other after use over a time period.
In its broad aspect, the invention provides a mill liner assembly for mounting on an inner diameter of a shell of a grinding mill. The mill liner assembly includes one or more shell plates for engagement with the shell, each of the shell plates having a cooperating portion thereof, one or more lifter bars, each of the lifter bars having a mounting portion thereof, the mounting portion being receivable on the cooperating portion, and one or more layers having one or more substantially non-resilient materials and a substantially non-sticking surface. The layer is at least partially positioned on at least a first selected one of the cooperating portion and the mounting portion, to position the non-sticking surface thereof for engagement with a second selected one of the cooperating portion and the mounting portion, to impede adhesion of the shell plate and the lifter bar to each other.
An embodiment of the present invention provides a mill liner assembly for mounting on an inner diameter of a shell of a grinding mill. The mill liner assembly includes one or more shell plates for engagement with the shell, each of the shell plates having a cooperating portion thereof, one or more lifter bars, each of the lifter bars having a mounting portion thereof, the mounting portion being receivable on the cooperating portion, and two or more layers, each of the layers having one or more substantially non-resilient materials and a substantially non-sticking surface. The layers are respectively positioned, at least partially, on the cooperating portion and the mounting portion, to position the respective non-sticking surfaces of the layers for engagement with each other, to impede adhesion of the shell plate and the lifter bar to each other.
According to one aspect of the present invention, there is provided a method of forming a mill liner assembly for mounting on an inner diameter of a shell of a grinding mill. The method includes the steps of: providing one or more shell plates for engagement with the shell, each of the shell plates having a cooperating portion thereof; providing one or more lifter bars, each of the lifter bars having a mounting portion thereof, the mounting portion being receivable on the cooperating portion; and positioning one or more layers including one or more substantially non-resilient materials and a substantially non-sticking surface on at least a first selected one of the cooperating portion and the mounting portion, to position the non-sticking surface thereof for engagement with a second selected one of the cooperating portion and the mounting portion, to impede adhesion of the shall plate and the lifter bar to each other.
In another aspect, the invention provides a grinding mill, including a shell having an inner diameter thereof, and a mill liner assembly for mounting on the inner diameter of the shell. The mill liner assembly includes one or more shell plates for engagement with the shell, each of the shell plates having a cooperating portion thereof, one or more lifter bars, each of the lifter bars having a mounting portion thereof, the mounting portion being receivable on the cooperating portion, one or more fastener subassemblies, for at least partially securing the shell plate and the lifter bar to the shell, and one or more layers including one or more substantially non-resilient materials and a substantially non-sticking surface at least partially positioned on at least a first selected one of the cooperating portion and the mounting portion, to position the non-sticking surface thereof for engagement with a second selected one of the cooperating portion and the mounting portion, to impede adhesion of the shell plate and the lifter bar to each other, when the shell plate and the lifter bar are secured to the shell.
In another of its aspects, the invention provides a mill liner assembly including one or more lifter bars for engagement with a shell surface defining an inner diameter of a shell of a grinding mill, each of the lifter bars having a mounting portion receivable on the shell surface, and one or more layers including one or more non-resilient materials and a substantially non-sticking surface at least partially positioned on a first selected one of the mounting portion and the shell surface, to position the non-sticking surface for engagement with a second selected one of the mounting portion and the shell surface, to impede adhesion of said at least one lifter bar and the shell to each other.
In another of its aspects, the invention provides a mill liner assembly including one or more shell plates for engagement with a shell surface defining an inner diameter of a shell of a grinding mill, each of the shell plates including a cooperating portion thereof, and one or more layers including one or more non-resilient materials and a substantially non-sticking surface at least partially positioned on a first selected one of the cooperating portion and the shell surface, to position the non-sticking surface for engagement with a second selected one of the cooperating portion and the shell surface, to impede adhesion of the shell plate and the shell to each other.
In yet another of its aspects, the invention provides a mill liner assembly including one or more shell plates for engagement with an inner diameter of a shell of a grinding mill, the shell including a shell body having an interior surface and an elastomeric sheet positioned on the interior surface to define the inner diameter. The mill liner assembly includes one or more protective elements attached to the shell plate for engagement with the elastomeric sheet when the shell plate is fastened to the shell, the protective element including one or more substantially tear-resistant materials, for substantially protecting the elastomeric sheet.
The invention will be better understood with reference to the attached drawings, in which:
In the attached drawings, like reference numerals designate corresponding elements throughout. Reference is first made to
As can be seen in
It will be understood that the mill liner assembly 20 preferably includes a number of shell plates 28 and a number of lifter bars 32 that, once installed, are positioned around a circumference of the inner diameter 22 of the shell 24 (
In
In
Another embodiment, in which layers 36 are mounted on both the cooperating and the mounting portions 30, 34 (as will be described), is illustrated in
Those skilled in the art will appreciate that various arrangements are possible. For instance, the lifter bars may be mounted directly onto the shell, or the shell plates may be formed so that separate lifter bars are not required, as will be described.
As can be seen in
As can be seen, for example, in
As can also be seen in
As can be seen in
For the purposes hereof, “adhesion” means the act of sticking (to something) or the state of being stuck together. As described above, the layer 36 preferably includes substantially non-resilient material(s), and also preferably includes a substantially non-sticking surface 38 that, in the embodiment illustrated in
It can be seen in
When the lifter bar 32 and the shell plate(s) 28 are to be secured to the shell 24, the nut 64 is tightened, pulling the lifter bar 32 and the shell plate(s) 28 in the direction indicated by arrow “A” in
To remove the lifter bar 32 from the shell plate(s) 28, the lifter bar 32 is separated from the shell plate(s) 28 and moved in the direction indicated by arrow “B” in
Various materials are suitable materials to be included in the layer 36. It will be understood that the layer 36 may include any suitable substantially non-resilient material(s). For instance, in one embodiment, the substantially non-resilient material preferably is ultra high molecular weight polyethylene. Alternatively, in another embodiment, the substantially non-resilient material includes polytetrafluoroethylene. The non-resilient material(s) may provide the substantially non-sticking surface. However, the non-sticking surface may alternatively be provided by additional material(s) included in the layer 36, as will be described. Preferably, the layer 36 is relatively thin. For instance, where the layer 36 is an adhesive tape (as described below), it may have a thickness of approximately 0.07 mm (2.7 mil). In one embodiment, the layer 36 may be applied in the form of a coating. It will be appreciated by those skilled in the art that, because the layer 36 is relatively thin, it can be retrofit (i.e., included in a mill liner of the prior art that was not specifically designed to accommodate the layer) to provide improved performance. Also, the layer 36 preferably is sufficiently thin that it does not materially affect the extent to which the lifter bars and the shell plates are securable to the shell by the fastener subassembly.
The layer 36 is securable to the cooperating portion 30 and/or the mounting portion 34 by any suitable means. For instance, the layer 36 may be so secured by a suitable glue. The glue, or adhesive, may be integral to the layer 36, or the glue may be applied shortly before the layer 36 is applied to the cooperating portion 30 and/or the mounting portion 34.
It is also preferred that the layer 36 includes one or more substantially water-repellent material. This can be advantageous where, for instance, a slurry inside the shell is corrosive.
As described above, the layer 36 is positioned on the cooperating portion 30 so that the substantially non-sticking surface 38 is positioned for engagement with the mounting portion 34 (
Where the backing surface 39 of the layer 36 is adhesive, to secure the layer 36 on the cooperating portion 30, the layer 36 is moved onto the cooperating portion 30 (i.e., in the direction indicated by arrow “C” in
Because of the substantially non-sticking or non-adhesive surface 38, the layer 36 and the mounting portion 34 substantially do not adhere to each other, even after the lifter bar 32 and the shell plate(s) 28 have been secured to the shell 24 for some time. The lifter bar 32 and the shell plate(s) 28 are separated relatively easily due to the substantially non-sticking surface 38, which (in the embodiment illustrated in
As illustrated in
As illustrated in
As can be seen in
Because the substantially non-sticking surfaces 38A, 38B are engaged with each other in this embodiment, the mounting and cooperating portions 34, 30 substantially do not adhere to each other. Also, the surfaces 38A, 38B substantially do not adhere to each other. Accordingly, upon release of the fastener subassembly 40, the lifter bar 32 is relatively easily separable from the shell plate(s) 28, even after the lifter bar 32 and the shell plate(s) 28 have been secured to the shell 22 for some time.
As can be seen in
In one embodiment, the layer 36 of the substantially non-resilient material preferably is an adhesive tape having an adhesive backing on the backing surface 39 (
In one embodiment, it is preferred that the adhesive tape is a metallic foil tape. Where the adhesive tape 36 is foil tape, the non-sticking surface 38 is provided by the metallic foil portion thereof (
As described above, the shell 24 preferably includes the shell body 42, which is partially defined by the interior surface 46, and also includes the elastomeric sheet 44 positioned on the interior surface 46 to define the inner diameter 22. As can be seen in
In the prior art, separation of the shell plates 28 from the elastomeric sheet 44 can be difficult after a prior art mill liner has been in use for a period of time, probably due (at least in part) to compression set. However, it is desirable to minimize the risk of damage to the elastomeric sheet 44, because the elastomeric sheet 44 protects the shell body 24. As described above, the elastomeric sheet 44 typically is a relatively thin sheet of a suitable material, usually a suitable rubber.
Accordingly, where the outer element 68 is positioned between the shell plate 28 and the elastomeric sheet 44 as described above, separation of the shell plate 28 from the elastomeric sheet 44 is relatively easily achieved. This is because the substantially non-adhesive surface 70 engages the elastomeric sheet 44, when the shell plate 28 is secured to the shell 22. The outer element 68 and the elastomeric sheet 44 substantially do not adhere to each other, even after the shell plate 28 has been secured to the shell 22 for some time. Because of this, the shell plate 28 and the elastomeric sheet 44 substantially do not adhere to each other. Accordingly, when the shall plates 28 are to be removed, they are relatively easily separated from the elastomeric sheet 44.
It will be understood that the mill liner assembly 20, in one embodiment, includes one or more layers 36 as well as the outer element 68. Alternatively, the mill liner assembly 20 may include only the outer element 68, i.e., without the layer(s) 36. For instance, another embodiment of the mill liner assembly 20, including the layers 36A, 36B and also the outer element 68, is illustrated in
In another embodiment, the mill liner assembly 20 preferably includes one or more protective elements 72 attached to the shell plate(s) 28 for engagement with the elastomeric sheet 44 when the shell plate(s) 28 is secured to the shell 24. Preferably, the protective element 72 includes one or more substantially tear-resistant (i.e., tough) materials, for protecting the elastomeric sheet 44. Because the protective element 72 is intended to resist abrasion or tearing when the shell plate is moved relative to it, the protective element 72 preferably is relatively tough. The protective element 72 preferably is at least partially made of any suitably tough, and/or tear-resistant material. Those skilled in the art would be aware that various materials are suitable. For instance, it has been found that high-density polyethylene is suitable. The protective element 72 preferably has a thickness between approximately 12 mm and approximately 15 mm. (The protective element 72 is relatively thick compared to the layer 36 because of the significant weight of the steel shell plates 28, i.e., to enable the protective element 72 to resist tearing when steel shell plates are installed.) The protective element 72 preferably is secured to the shell plate in any suitable manner, e.g., by a suitable glue.
Because the protective element 72 preferably is relatively thin and relatively flexible, it can be retrofit (i.e., used with prior art elements not specifically designed to accommodate the layer). Also, including the protective element 72 in the mill liner assembly 20 does not materially affect the extent to which the lifter bars and the shell plates are securable to the shell.
As noted above, the shell plate 28 may be made of any suitable material. For instance, shell plates are often made of a suitable rubber, one or more suitable steels or other metals, or one or more suitable ceramics, or combinations thereof. In practice, it has been found that, where the shell plates 28 are very heavy (e.g., because they are made of steel), there is a tendency to pierce or tear the elastomeric sheet 44 as such shell plates 28 are installed or removed. For instance, the elastomeric sheet 44 may be damaged when the heavy shell plates 28 are dragged over the elastomeric sheet 44, to make small adjustments in the shell plates' positions. Accordingly, the invention provides the protective element 72, for further protecting the elastomeric sheet 44 in this situation (
As described above, the lifter bar 32 and the shell plate(s) 28 preferably are secured to the shell 24 by the fastener assembly 40. As can be seen, for instance, in
In one embodiment, and as can be seen in
It will be understood that the protective element 72 may be used regardless of whether the mill liner assembly 20 includes any one or more of the layers 36. From the foregoing it can be seen that, because of the protective element 72, the risk of damage to the elastomeric sheet 44 is significantly decreased.
In use, the mill liner assembly 20 is formed by an embodiment of a method 101 of the invention including the steps of providing one or more shell plates 28 for engagement with the shell 22, each shell plate 28 including the cooperating portion 30 thereof (step 103,
It will be appreciated by those skilled in the art that certain steps of the method 101 may be performed in an alternative sequence. For instance, although step 103 is described above and is shown in
Another embodiment of a method 201 of the invention of securing the mill liner assembly 20 to the shell 22 of the grinding mill 26 includes the step of providing a number of shell plates 28 for engagement with the shell, each shell plate 28 having a cooperating portion 30 thereof (step 203,
In another embodiment, the invention provides the grinding mill 26, which preferably includes the shell 24 with the inner diameter 22 thereof, and the mill liner assembly 20 for mounting on the inner diameter 22 of the shell 24. Preferably, and as described above, the mill liner assembly 20 includes a number of shell plates 28, a number of lifter bars 32, and a number of fastener subassemblies 40. It is also preferred that the mill liner assembly 20 includes one or more layers 36, each of which includes one or more substantially non-resilient materials and the substantially non-sticking surfaces 38. Also as described above, the layer 36 preferably is positioned on at least the first selected one of the cooperating and mounting portions, for engagement with the other of the cooperating and mounting portions 34, 30, i.e., the second selected one thereof, to position the non-sticking surface 38 for engagement with the other of the cooperating and mounting portions (i.e., the second selected one of the cooperating portion and the mounting portion), to impede adhesion of the shell plate(s) 28 and the lifter bar 32 to each other, when the shell plates and the lifter bars are attached to the shell by the fastener subassemblies 40. Because of the layer 36, the lifter bar 36 and the shell plate(s) 28 are relatively easily separable from each other.
In another embodiment, the invention provides the mill liner assembly 20 including a number of the shell plates 28 for engagement with the inner diameter 22 of the shell 24 of the grinding mill 26. Each of the shell plates 28 includes the cooperating portion 30 thereof and a number of lifter bars 32, each lifter bar 32 including the mounting portion 34. The mounting portion 34 is receivable on the cooperating portion 30. The shell 24 includes the shell body 42 having the interior surface 46, and the elastomeric sheet 44 positioned on the interior surface 46 to define the inner diameter 22. Preferably, the mill liner assembly 20 also includes one or more outer elements 68 positionable between the shell plate 28 and the elastomeric sheet 44. Preferably, the outer element 68 includes the substantially non-adhesive surface 70 positioned for engagement with the elastomeric sheet 44, to impede adhesion of the shell plate and the elastomeric sheet with each other.
In another embodiment, the invention includes the mill liner assembly 20, which includes a number of shell plates 28 for engagement with the inner diameter 22 of the shell 24 of the grinding mill 26, the shell including the shell body 42 having the interior surface 46 and the elastomeric sheet 44 positioned on the interior surface 46 to define the inner diameter 22. The mill liner assembly 20 preferably also includes the protective element(s) 72 attached to the shell plate(s) 28 for engagement with the elastomeric sheet 44 when the shell plate 42 is fastened to the shell 24, the protective element 72 including one or more substantially tear-resistant materials, for protecting the elastomeric sheet 44.
Alternative embodiments of the mill liner assembly of the invention are illustrated in
As described above, in
Those skilled in the art will appreciate that, in alternative embodiments of the invention, the layer 36, when mounted on the cooperating portion 30, may have alternative configurations.
For example, an alternative embodiment of the mill liner assembly 320 of the invention is illustrated in
An alternative embodiment of a mill liner assembly 420 of the invention is illustrated in
As described above, the layer of substantially non-resilient material with the substantially non-sticking surface may alternatively be mounted on the mounting portion 34. As can be seen in
Another alternative embodiment of a mill liner assembly 520 of the invention is illustrated in
Yet another alternative embodiment of a mill liner assembly 620 of the invention is illustrated in
In another embodiment, a mill liner assembly 720 of the invention includes one or more lifter bars 732 for engagement with a shell surface 729 defining an inner diameter 722 of a shell 724 of a grinding mill 726. Each of the lifter bars 732 includes a mounting portion 734 which is receivable on the shell surface 729. Preferably, the mill liner assembly 720 also includes one or more layers 736 including one or more non-resilient materials, and a substantially non-sticking surface 738 that is at least partially positioned on a first selected one of the mounting portion 734 and the shell surface 729, to position the non-sticking surface 738 for engagement with a second selected one (i.e., the other one) of the mounting portion 734 and the shell surface 729, to impede adhesion of the lifter bar 732 and the shell 724 to each other. Because of the layer 736, the lifter bar 732 is relatively easily separable from the shell 724.
As can be seen in
In
In
In each case, the layer 736 impedes adhesion of the lifter bar 732 and the shell 724 to each other. It will be understood that the layer 736 preferably is sufficiently thin (as described above) that it fits between the lifter bar 732 and the shell 724, e.g., the layer 736 may be retrofit (i.e., used with prior art mill liner elements not specifically designed to accommodate the layer). Due to the non-sticking surface 738, the lifter bar 732 can relatively easily be separated from the shell (i.e., from the shell surface 729), resulting in lower installation costs.
In another embodiment, a mill liner assembly 820 of the invention includes one or more shell plate(s) 828 for engagement with a shell surface 829 defining an inner diameter 822 of a shell 824 of a grinding mill 826. Each of the shell plate(s) 828 includes a cooperating portion 830 which is receivable on the shell surface 829. Preferably, the mill liner assembly 820 also includes one or more layers 836 including one or more non-resilient materials, and a substantially non-sticking surface 838 that is at least partially positioned on a first selected one of the cooperating portion 830 and the shell surface 829, to position the non-sticking surface 838 for engagement with a second selected one (i.e., the other one) of the cooperating portion 830 and the shell surface 829, to impede adhesion of the shell plate(s) 828 and the shell 824 to each other. Because of the layer 836, the shell plate 828 is relatively easily separable from the shell 824.
As can be seen in
In
In
In each case, the layer 836 impedes adhesion of the shell plate(s) 828 and the shell 824 to each other. It will be understood that the layer 836 preferably is sufficiently thin (as described above) that it fits between the shell plate(s) 828 and the shell 824, e.g., the layer 836 may be retrofit. Due to the non-sticking surface 838, the shell plate(s) 828 can relatively easily be separated from the shell (i.e., from the shell surface 829), resulting in lower installation costs.
It will be appreciated by those skilled in the art that the invention can take many forms, and that such forms are within the scope of the invention as described above. The foregoing descriptions are exemplary, and their scope should not be limited to the preferred versions provided therein.
This application claims the benefit of U.S. Provisional Patent Application No. 61/432,406, filed on Jan. 13, 2011, and incorporates such provisional patent application in its entirety by reference.
Number | Date | Country | |
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61432406 | Jan 2011 | US |