The present invention is a discharge grate assembly formed to impede worn rock pieces from lodging in the apertures therein.
As is well known in the art, grinding media (e.g., grinding balls) that have become worn over time sometimes tend to become jammed in apertures in the discharge grates that are located at a discharge end of a mill shell chamber in a grinding mill. This can occur when the grinding balls have become sufficiently worn that they are small enough to partly fit into the apertures in the discharge grates, to partially block the apertures.
Typically, at the same time as the grinding media are becoming worn, and therefore smaller, the discharge grates are also subjected to wear, with the result that the apertures in the discharge grates gradually become larger over time. Accordingly, the risk that a discharge grate may become plugged (in whole or in part) increases over the operating life of the discharge grate.
Once the worn grinding ball is small enough that it can at least partly fit into the apertures, the worn grinding ball may stay positioned in the aperture. In this situation, the worn grinding ball tends to be pressed further into the apertures by the charge in the mill shell chamber hammering against the worn grinding ball positioned in the aperture, as the grinding mill shell rotates about its axis. As is well known in the art, most discharge grates are positioned at an obtuse angle relative to the horizontal. The worn grinding ball that stays positioned in the aperture is subjected to very harsh hammering conditions, pushing the worn grinding media into the aperture so that it becomes trapped in the aperture of the discharge grate. However, it is believed that not all of the worn grinding balls that are positioned in the aperture stay in the aperture.
Although the worn grinding ball may have any shape (and may be worn down to a somewhat irregular shape), for clarity of illustration, the worn grinding ball 10 as illustrated has a generally round exterior. The discharge grate 14 is formed and installed so that slurry (not shown in
The discharge grate 14, as originally installed, had exterior surfaces 15, 16 and interior surfaces 17, 18 that had previously defined an original aperture therebetween that was smaller than the current aperture 12′. The original aperture was sized so that the slurry passing therethrough was screened to prevent rock pieces or worn grinding balls larger than the aperture from passing through the original aperture. As can be seen in
Because the interior surfaces 17′, 18′ and the exterior surfaces 15′, 16′ are worn, the aperture 12′ that is defined thereby is larger than the original aperture that had been defined by the original interior surfaces 17, 18 and the original exterior surfaces 15, 16. In addition, and as can be seen in
The worn grinding ball 10 has a center of gravity identified in
It will be understood that the discharge grate 14 is positioned in the mill shell so that the original exterior surface 15 is located at an obtuse angle, e.g., approximately 105° from the horizontal. Accordingly, as illustrated in
When a worn grinding ball is only partially located in the aperture, and its center of gravity is above the plane 22 as illustrated in
As is well known in the art, the discharge grate 14 typically is made of a material that is not as hard as the material of the grinding balls. Accordingly, once a worn ball becomes lodged in an aperture between the worn interior surfaces defining the aperture (i.e., when the center of gravity is in the aperture 12′), and when the worn ball has been urged into the aperture by the impacts of the charge thereon as the mill shell rotates, the discharge grate 14 may suffer some plastic deformation, where the discharge grate 14 is engaged by the worn ball 10. In effect, the worn grinding media 10 may become embedded, to an extent, in the worn surfaces of the worn discharge grate.
As is well known in the art, rock pieces that are sufficiently small to become lodged in the aperture may also become jammed there.
The result is that a worn grinding ball that becomes lodged in an aperture (i.e., with its center of gravity in the aperture 12′) tends to stay lodged in the aperture. In this situation, an individual worn grinding ball partially blocks slurry from passing through the aperture to the pulp chamber in communication with the aperture. A number of worn balls may become lodged along the length of an aperture, so that most of the potential flow of the slurry through that aperture may be blocked. Over time, a sufficient number of apertures of a sufficient number of discharge grates may become partially blocked, to the extent that the grinding capacity of the mill may become significantly limited thereby.
For the foregoing reasons, there is a need for an anti-plugging discharge grate that overcomes or mitigates one or more of the defects or disadvantages of the prior art.
In its broad aspect, the invention provides a discharge grate assembly having a body with a number of elongate apertures therein. Each aperture extends between respective first and second ends thereof. The first end has a predetermined first end width, and the second has a predetermined second end width that is larger than the first end width.
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. In particular, to simplify the description, the reference numerals used in
As can be seen in
In many grinding mills, the charge includes water, and the fluid in the mixture is water. In these circumstances, the mixture is commonly referred to as “slurry”. However, those skilled in the art would appreciate that, alternatively, in “dry” grinding, comminution may be effected in the absence of water. Accordingly, the fluid may be air, or any suitable gas or gases.
As can be seen in
In one embodiment, the grinding mill 130 preferably includes a discharge end wall 138 attached to the shell 132. As can be seen in
It is also preferred that the grinding mill 130 includes a discharge end wall system 146. In one embodiment, the discharge end wall system 146 preferably includes a number of discharge grate assemblies 248 and a number of pulp chambers 150 located between the respective discharge grate assemblies 248 and the discharge end wall 138. As will be described, the pulp chambers 150 are for directing the slurry (or mixture) 180 received therein toward the central opening 144, to exit the grinding mill 130 therethrough. Each of the discharge grate assemblies 248 is positioned to screen the slurry (or mixture) 180 flowing from the mill shell chamber 134 into each said pulp chamber 150 respectively, as the shell 132 rotates about the central axis 136.
It will be understood that each of the discharge grate assemblies 248 is rotatable with the shell 132 about the central axis 136 between a lowered condition, in which the slurry (or mixture) is flowable through at least part of the discharge grate assembly 248 into the pulp chamber 150 adjacent thereto respectively, and a raised condition, in which the discharge grate assembly 248 is positioned above the charge “C”.
As an example, in
When a discharge grate assembly is in the raised condition, the slurry (or mixture) in the pulp chamber adjacent to that discharge grate assembly flows out of the pulp chamber 150 under the influence of gravity and exits the grinding mill via the central opening 144. In
In one embodiment, the discharge grate assembly 248 preferably includes a body 252 having a number of elongate apertures 254 therein that are formed to screen the slurry (or mixture) flowing therethrough from the mill shell chamber 134 into the pulp chamber 150 therefor (
The elongate aperture 254 is defined by aperture walls 264 that are formed in the body 252. In one embodiment, the aperture walls 264 preferably include first and second end walls 266, 268 that are at least partially rectilinear, and partially define the first and second ends 256, 258 respectively. As will also be described, the first and second ends 256, 258 are formed to impede the worn grinding balls 110′ and the worn rock pieces 111′ in the slurry 180 from lodging in the aperture.
It will be understood that the grinding balls 110 that are illustrated in
For the purposes hereof, a worn grinding ball 110′ or a worn rock piece 111′ is considered to be lodged in the aperture 254 if the center of gravity thereof is in the aperture 254. If a center of gravity 184 of the worn grinding ball 110′ or the worn rock piece 111′ is not in the aperture, but instead is in the mill shell chamber 134, then the worn grinding ball 110′ or the worn rock piece 111′ (as the case may be) is not lodged in the aperture 254.
As will be described, if the center of gravity 184 of a particular worn rock piece 111′ or worn grinding ball 110′ is located in the aperture 254, then that worn rock piece 111′ or worn grinding ball 110′ is “lodged” therein, and is likely to stay lodged (i.e., jammed) in the aperture 254. Conversely, if the center of gravity 184 of a particular worn rock piece 111′ or worn grinding ball 110′ is outside the aperture 254, i.e., in the mill shell chamber 134, then the worn rock piece 111′ or worn grinding ball 110′ is not positioned sufficiently far enough in the aperture 254 to remain in the aperture (i.e., the worn rock piece 111′ or the worn grinding ball 110′ is not “lodged” in the aperture), and the worn rock piece or worn grinding ball will not remain partly in the aperture, but will fully return to the mill shell chamber 134.
As can be seen in
In one embodiment, the body 252 includes an at least partially planar front side 274 that faces the mill shell chamber 134 (
As can be seen in
It will be understood that the discharge grate assembly 248 includes fasteners and other ancillary elements (not shown) that are used to locate the discharge grate body 252 in a preselected location thereof in the discharge end wall system 146 (
Those skilled in the art would appreciate that the ore-bearing rocks 111 may be a variety of sizes. The charge “C” includes fines “F”. In the charge, the fines “F” are generally located in interstices between the ore-bearing rocks 111, and between the rocks 111 and the shell 132, however, for clarity of illustration, the fines “F” in the charge that are illustrated in
For the purposes hereof, the terms “ore-bearing rocks” and “rocks” are deemed to include any materials (e.g., rocks or agglomerations of any materials) that are subjected to comminution in the grinding mill, to produce smaller diameter materials (e.g., rocks and worn rock pieces, or pieces of agglomerated materials) that are screened by discharge grate assemblies to limit the materials passing to a preselected size distribution. For example, agglomerated materials such as cement clinker may be considered to be “rocks” for the purposes hereof. Similarly, for the purposes hereof, “rock pieces” are considered to be pieces of the comminuted materials (e.g., agglomerations, or ore-bearing rocks) that have been broken off or worn off such materials by the comminution. As noted above, the materials that are comminuted may be subjected to wet or dry grinding.
Those skilled in the art would also appreciate that the comminution may be effected in the absence of grinding balls, or with grinding balls or other grinding media included in the charge.
It will also be understood that, although the ore-bearing rocks 111 are intended to include ore, the ore-bearing rocks may in practice include some rocks that are waste, i.e., some of the rocks in the charge may not include any ore, due to variations in quality control and mining practices in the mine supplying the feed for the grinding mill. However, for the purposes hereof, all the rocks inside the mill shell chamber 134 are considered to be ore-bearing rocks. Those skilled in the art would appreciate that the charge and additions thereto are directed into the mill 130 at the feed end thereof, as schematically indicated by arrow “B” (
It will be understood that the mill shell 132 and the discharge end wall system 146 secured to the mill shell 132 rotate about the central axis 136 at a relatively high rate of speed, e.g., approximately 10 rpm. Those skilled in the art would appreciate that, as a result, any particular discharge grate is in its lowered condition, and then in its raised condition, for only a short period of time in each case. Because of the rotation of the shell, the charge “C” is forced to tumble over itself, and the ore-bearing rocks 111 are consequently subjected to comminution.
As is known in the art, while the mill shell 132 and the discharge end wall system 146 secured to it rotate about the central axis 136, the slurry or mixture 180 (including the fines “F” and worn rock pieces, and the fluid 178 accompanying the fines “F” and worn rock pieces) passes through the apertures 254 of the discharge grate assemblies 248 into the pulp chambers 150 (
Another embodiment of a discharge grate assembly 148 is illustrated in
As a result, the width of the aperture 154 varies along the length “L” of the aperture 154 (
As can be seen in
Those skilled in the art would appreciate that, in
It will be understood that the design of the elongate aperture 154 in the discharge grate body 152 typically involves a balance or compromise between different design factors. For instance, although it is desirable to form the aperture 154 so that it is relatively small (i.e., to keep more coarse material in the slurry or mixture from entering into the pulp chambers, and ultimately exiting the grinding mill), it is also desirable to form the aperture 154 so that it is relatively large, in order to have a greater throughput through the grinding mill.
Accordingly, those skilled in the art would appreciate that the average width “W” of the aperture 154 in the discharge grate body 152 are determined by taking the factors outlined above into account to arrive at the width, and the first and second end widths.
In the discharge grate assembly 148 of the invention, one end (i.e., the second end 158) of the aperture 154 preferably is slightly larger than the other end (i.e., the first end 156). That is, the first end width 160 is slightly smaller than the average width “W”, and the second end width 162 is slightly larger than the average width “W”.
A first worn grinding ball (identified by reference character A110′ for convenience) having a diameter “Gmax” is illustrated in
As noted above, the grinding balls may become worn down by comminution to various shapes, some of them irregular. Those skilled in the art would appreciate that the worn grinding balls may be ellipsoid or spheroid, in whole or in part. Many of the worn grinding balls may be substantially spherical, or at least partially spherical. The worn rock pieces also may, in practice, be at least partially ellipsoid, spheroid, or spherical, due to comminution. It will be understood that, in the drawings referred to herein, the worn grinding balls and the worn rock pieces are shown as having generally round shapes for convenience, and for clarity of illustration.
Because the discharge grate assembly 148 provides a larger aperture width 162 at the second end 158, any worn grinding ball that has been worn to a diameter that is smaller than 162 may pass through the second end 158. For example, as can be seen in
From the foregoing, it can be seen that, in the discharge grate assembly 148, the first end 156 is unlikely to become plugged. This is because, when the diameter of any particular worn grinding ball has a diameter less than “Gmax”, but before such diameter has decreased to “Gmin”, that particular worn grinding ball will pass through the aperture 154 at the second end 158, or at some other point in the aperture 154 where the width of the aperture 154 is greater than the particular worn grinding ball's diameter.
Those skilled in the art would appreciate that, similarly, a particular rock piece 111′ with a diameter less than “Gmax” will pass through the aperture 154 at the second end 158, or at another point in the aperture 154 where the width of the aperture is greater than the particular worn rock piece's diameter.
Those skilled in the art would also appreciate that the foregoing represents an analysis of an ideal situation. As a practical matter, even though it appears unlikely, any particular worn grinding ball 110′ or worn rock piece 111′ having a diameter greater than “Gmin” but less than “Gmax” may, for example, not pass through the aperture 154 (e.g., via the second end 158) due to the random nature of the movement of the worn grinding balls 110′ and the worn rock pieces 111′ in the mill shell chamber 134, as the mill shell 132 rotates. Also, because the worn grinding balls and the worn rock pieces may be worn into irregular shapes, they may still occasionally become lodged in the aperture 154 in practice. For example, an individual worn grinding ball may be worn so that it has a first diameter less than “Gmax”, and also a second diameter greater than “Gmax”, and due to this, that particular item may become lodged in the second end 158.
However, it is believed that, in general, the worn grinding media become lodged in the aperture 154 less frequently than when the discharge grates of the prior art are used, for the reasons set out above, and as further described below.
From the foregoing, it can be seen that forming the discharge grate body 152 so that the apertures 154 each extend between an end with a smaller width 160, and an end with a larger width 162, mitigates the risk of the worn grinding balls or worn rock pieces becoming lodged in the aperture. Although the aperture walls 164 in the discharge grate body 152 are subjected to wear over time, thereby causing the aperture's dimensions to gradually increase, it is believed that the beneficial effect of having one end of the aperture larger than the other end continues, even after the discharge grate body has been subjected to wear to a significant extent. Due to the shape of the aperture 154, the discharge grate assembly 148 has a self-cleaning aspect, as will be described.
Each of the apertures 154, which extends between the first end 156 thereof in which the width 160 of the aperture 154 is less than the aperture's average width “W”, and the second end 158 thereof in which the width 162 of the aperture 154 is greater than the aperture's average width “W”, represents a compromise between a larger width (i.e., larger than 162, which may tend to allow slurry with a larger particle size distribution through) and a smaller width (i.e., smaller than 160, which may tend to become plugged with worn grinding balls or worn rock pieces).
As noted above, a worn grinding ball or worn rock piece with a diameter less than “Gmax” but greater than “Gmin” is likely to pass through the aperture 154 at the second end 158, or at any point along the length of the aperture 154 where the width of the aperture 154 is greater than the diameter of that worn grinding ball or worn rock piece. In addition, it is believed that a worn grinding ball or worn rock piece with a diameter greater than “Gmax” will not become lodged in the aperture 154, because the worn grinding ball or worn rock piece with a diameter greater than “Gmax” will, when positioned in the second end 158, have its center of gravity located outwardly relative to the front side 174, i.e., the center of gravity thereof is located in the mill shell chamber 134.
When the center of gravity 184 is not in the aperture 154, the worn grinding ball A110′ is only partly in the aperture 154, and it may easily be knocked or bumped out of the aperture 154, or may simply fall out due to movement of the discharge grate assembly around the central axis 136. It is believed that the worn grinding ball A110′, if it remains in contact with the body 152, may be moved along the aperture 154 (i.e., in the direction indicated by arrow “K” in
Those skilled in the art would appreciate that, in one embodiment, each of the discharge grate assemblies 148 may be positioned at an angle other than 90° relative to the horizontal. For example, in
From
In the example illustrated in
With the worn grinding ball A110′ located at the first end 156, and based on certain assumptions (set out below), it is possible to determine, in one embodiment, what the ideal “Gmin” (i.e., the first end width 160) may be, relative to a given “Gmax” (i.e., the second end width 162).
In the example illustrated in
“Gmin”=(30.5/2)“Gmax”
Accordingly, it is believed that the discharge grate assembly 148 is generally self-cleaning, as described above, when the relationship between “Gmax” and “Gmin” (i.e., the second end width 162 and the first end width 160, respectively) is as set out above. Those skilled in the art would appreciate that the foregoing determination is based on the proportions that are believed to be relevant, and which are shown in
Those skilled in the art would also appreciate that the aperture 154 may have any suitable length “L”. As noted above, the aperture 154 is elongate. In one embodiment, for example, it is believed that “L” may be equal to 3“Gmax”.
It will also be understood that the discharge grate body 152, 252 may be made of any suitable material, or materials. For example, the body 152, 252 may be made of a suitable steel, or a suitable rubber or other polymer. Alternatively, the body 152, 252 may include any combination thereof, e.g., steel and rubber. As additional examples, the body 152, 252 may be made of suitable ceramics, or suitable composite materials.
Although the discharge grate assembly 148 has been described mounted in a grinding mill, those skilled in the art would appreciate that the discharge grate assembly 148 may be used in other applications, e.g., in a screening facility. For example, the discharge grate assembly 148 may be used in a cement plant. The discharge grate assembly 148 may be used in any situation where the output of a comminution process (wet or dry) includes pieces or particles that are to be screened, to limit the portion of the output that passes to a particular particle size distribution that is less than a specified size.
From the foregoing, it can be seen that the differences between the embodiment of the discharge grate assembly 148 illustrated in
“Gmin”=(30.5/2)“Gmax”
For exemplary purposes, a worn grinding ball A210′ having a diameter “Gmax” and a second worn grinding ball B210′ having a diameter “Gmin” are illustrated in
It is believed that, because the first and second end walls 266, 268 are at least partially rectilinear, they impede worn grinding balls 110′ or worn rock pieces 111′ that might otherwise fall into, or be received into, the aperture 254 from lodging therein. For the purposes hereof, a worn grinding ball or a worn rock piece is considered to be received or lodged in the aperture 254 if the center of gravity thereof is between a plane “Z” defined by the front side 274, and the pulp chamber 150 (
In
A side view of the worn grinding ball 2A110′ at the second end 258 is also provided in
As can be seen in
In the same way, a portion 288 of the worn grinding ball 26110′ overlaps the first end wall 266. Because of this overlap, the worn grinding ball 26110′ is impeded from lodging in the aperture 254 at the first end 256, even though the worn grinding ball 26110′ has a diameter 289 that is approximately equal to the width of the aperture 254 at the first end 256. In this case, because the first end wall 266 is rectilinear, the worn grinding ball 26110′ is impeded thereby from lodging in the aperture 254. Although the aperture walls 264 are worn down over time because of the wear to which they are subjected, it is believed that the end walls 266, 268 and the side walls 170, 172 remain generally rectilinear, even after they are subjected to significant wear over time.
A side view of the worn grinding ball 26110′ at the first end 256 is also provided in
Because the second end 258 is wider than the first end 256, the side walls 270, 272 are not parallel. Due to the aperture 254 gradually narrowing from the second end 258 to the first end 256, the discharge grate assembly 248 is self-cleaning, as is the other embodiment of the discharge grate assembly 148. From the foregoing, it can be seen that the discharge grate assembly 248 is both self-cleaning and also has rectilinear end walls 266, 268 that impede worn grinding balls and worn rock pieces from lodging in the aperture 254.
It is preferred that the aperture wall edges 276 of each of the aperture walls defining the second end 258 engage the worn grinding balls and the rock pieces having diameters equal to or larger than the second end width 262 to locate the centers of gravity 184 of the worn grinding balls and the rock pieces having diameters equal to or larger than the second end width in the mill shell chamber 134, to impede lodging thereof in the respective apertures 254 (
It is also preferred that the aperture wall edges 276 of the aperture walls 264 defining the first end 256 engage the worn grinding balls and the rock pieces having diameters equal to or larger than the first end width 260 to locate the centers of gravity 184 of the worn grinding balls and the rock pieces in the mill shell chamber 134, to impede lodging thereof in the first end 256 of the apertures 254 (
As can be seen in
As can be seen in
From the foregoing, it can be seen that the body 252 of the discharge grate assembly 248 has a front side 274 facing the mill shell chamber 134 and an opposite rear side 298. The rear side 298 of the body 252 faces the pulp chamber 150 to which the discharge grate body 252 is adjacent. As noted above, the body 252 includes a number of the apertures 254 for permitting the worn grinding balls and the worn rock pieces that have a predetermined maximum permitted size sufficiently small to pass through the apertures into the pulp chamber.
The first end 256 preferably is defined by the first end wall 266, which is at least partially rectilinear, and the second end 258 of the aperture 254 preferably is defined by the second wall 268, which also is at least partially rectilinear. As noted above, the second end width 262 is greater than the first end width 262. The first and second end walls 266, 268 are formed to impede the worn grinding balls and the worn rock pieces that are larger than the predetermined maximum permitted size from being lodged in the aperture 254.
Those skilled in the art would appreciate that the discharge end wall system 146 preferably includes a number of pulp lifters 301 radially arranged on the discharge end wall 138 relative to the central axis 136. The pulp lifters 301 are located for partially defining the pulp chambers 150.
The bodies 252 of the discharge grate assemblies 248 are located between the mill shell chamber 134 and the respective pulp chambers 150. As can be seen in
In
As can be seen in
In the same way, a portion 307 of the worn rock piece B111′ overlaps the first end wall 266. The portion 309 overlaps the first end wall 266 because the worn rock piece B111′ is at least partially rounded. Because of this overlap, the worn rock piece B111′ is impeded from lodging in the aperture 254 at the first end 256, even though the worn rock piece B111′ has a diameter 309 that is approximately equal to the width of the aperture 254 at the first end 256. In this case, because the first end wall 266 is rectilinear, the worn rock piece B111′ is impeded thereby from lodging in the aperture 254. It will be understood that the center of gravity of the worn rock piece B111′ is located in the mill shell chamber 134.
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 claimed. The scope of the claims should not be limited by the preferred embodiments set forth in the examples, but should be given the broadest interpretation consistent with the description as a whole.
This application claims the benefit of U.S. Provisional Patent Application No. 63/032,017, filed May 29, 2020, the entirety of which is hereby incorporated herein by reference.
Number | Date | Country | |
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63032017 | May 2020 | US |