The present application is a National Stage of International Application No. PCT/AU2017/050925, filed on Aug. 30, 2017, which claims the benefit of Australian Application No. 2016903443, filed on Aug. 30, 2016. All of the foregoing are incorporated as though set forth herein in their entirety.
The present invention relates generally to the manufacture and use of wire members used in separating centrifuges. Separating centrifuges are commonly used in many sorting and dewatering processes. More specifically the invention relates to wedge wire used in improved screen baskets for use in separating centrifuges.
Centrifuges, such as screen scroll centrifuges, are often used to filter or dewater crystalline or amorphous solid/liquid slurries. These centrifuges typically utilize a screen to separate the solid portion of the slurry from the liquid phase. The screen, moreover, is typically sized to retain the larger solids portion of the slurry while allowing the liquid to pass through and thus, the two phases of the slurry may be separately collected. Instead of relying on gravity to filter the slurry through the screen, however, filtration occurs under large centrifugal forces (on the order of many times the force of gravity), caused by high rotational speed of the centrifuge. These large centrifugal forces substantially increase the separation efficiency of the centrifuge.
Specifically, the slurry is delivered to the interior of a rotating basket that includes a frusto-conical screen body. The screen body is typically formed from a plurality of wedge wires that are spaced side-by-side. For structural support, the wedge wires may be welded to circumferential ribs spaced out along the rotational axis of the body. Rotation of the screen basket drives the slurry against the inner surface of the body and the liquid phase is forced through the slots formed between adjacent wedge wires. The larger solid particles do not pass through the slots and are instead collected on the inside of the basket.
To convey the solids out of the inside of the basket, a scroll conveyor having a helical blade is typically mounted concentrically within the basket. The tip of the blade, however, is spaced from the inner surface of the basket by a small radial clearance. The scroll conveyor is rotated in the same direction as the basket but at a slightly different rotational speed relative to the basket. Through this differential speed, the solids accumulating along the inside surface of the basket are conveyed by the helical blade from the small diameter end and toward the basket's larger end where they are dumped in a discharge chute and collected.
Another type of separating centrifuge is a vibrating centrifuge. Vibrating centrifuges also include a screen basket that is similar in design to the basket of screen scroll centrifuges. A vibrating centrifuge, however, does not utilize a helically bladed scroll to move the solid particles collecting on the inside surface of the basket to the discharge chute. Instead, the vibrating centrifuge includes a mechanism for shaking the basket back-and-forth along its axis. By shaking or vibrating the basket along its rotational axis, solid particles accumulating on the inside of the basket are conveyed axially toward the discharge chute and collected.
Therefore, as described above, scroll and vibrating centrifuges are very useful for separating liquid/solid slurries. Nonetheless, these centrifuges are subject to significant wear requiring frequent maintenance and corresponding down time. For example, solid particles of the slurry often get trapped in the slots of the basket, damaging the screen and reducing the separation efficiency of the centrifuge. Furthermore, the slurries often include highly abrasive components that wear out the body of the screen basket. The corresponding maintenance and replacement of parts significantly increase operating costs.
A conventional method of manufacture of the centrifuge baskets described above includes manufacture of the body from stainless steel wedge wire cut from flat sheets. Commonly, wedge wires are arranged as a screen cylinder which is then split and flattened into a sheet form. The frusto-conical body forming the basket is then developed and a layout made on this flat wedge wire sheet. To minimize the material used, the body is usually divided into several sections. Each section is cut from the flat sheet and rolled into a frusto-conical shape. A set of panels is placed on an appropriate jig and welded into the required complete frusto-conical form. However, when the sections are joined to form a body, the welded joints located between each adjacent section end up having a “herring bone” or V shaped pattern similar to the V shaped pattern found in twill fabric.
This also results in a cone with slots on the inside of the basket running in a relatively vertical pattern (i.e., slots are in the general longitudinal direction of the cone).
The inner surface of the body is produced by wedge wires which are welded to a network of support rods at the exterior of the body. The support rods run at right angles to the internal wedge wires and generally run circumferentially on the outside of the basket. The wedge wires have a wedge shaped cross sectional shape. An example of such a basket is described in U.S. Pat. No. 4,487,695.
However, in this arrangement, there is usually only one wire in each section which is parallel to the rotation axis of the body. This cannot be avoided using current materials and techniques. This means that for reasons explained hereinafter that as the particles in mine slurries (e.g. coal slurries) travel outwardly of the centrifugal basket due to centrifugal force and vibration, some coal particles will cut across the wedge wires, resulting in excessive wear and premature failure of the basket.
To complete a useable basket, mounting flanges of various styles are welded to the ends of the basket body and often there are reinforcing ribs and, depending on design, strengthening and wear plates added.
Thus, the manufacture of a screen basket involves a number of processes, is time consuming and labour intensive and the quality of the end product is dependent on the skill of personnel involved in the manufacturing. In a large part, the time and expense in building a screen basket is brought about by the method of fabricating the body of the basket from a number of panel sections. Depending on the size of the basket, the process of cutting these panel sections from flat sheet can also be wasteful of expensive stainless steel materials.
Another problem with the conventional centrifuge baskets as described above is that they did not process coal slurries in an efficient manner. In this regard coal generally has a stratified form and thus, in other words, has a laminar structure. Thus, in use coal may travel from a smaller diameter end of the centrifuge basket to a larger diameter end. However, due to its structure, coal tends to split into smaller particles or dust. The presence of the herring bone pattern in the welded joints between each section of the body as described above also was detrimental to the coal particles as it tended to cut the coal particles. In this regard, it was necessary that the coal particles were caused to travel on the internal surfaces of each longitudinal wedge wire to avoid fracturing. Therefore because of the herring bone pattern in each welded joint it was necessary to spin the centrifuge at 300 rpm to introduce vibration into movement of the basket to facilitate the coal particles to travel on the internal surfaces of each wedge wire. However, such vibration also resulted in fracturing of the coal particles.
It is an object of the invention to overcome or at least alleviate one or more of the above problems and/or provide the consumer with a useful or commercial choice.
In one form, although it need not be the only or indeed the broadest form, the invention resides in a screen basket for centrifuges comprising a wedge wire having a broad end and an opposite narrow end, wherein the wedge wire narrows in width from the broad end to the narrow end.
The wedge wire may increase in depth from the broad end of the wedge wire to the narrow end of the wedge wire.
The wedge wire suitably has a generally triangular-shaped profile in cross-section.
The degree of narrowing may be uniform over the length of the wedge wire.
The wedge wire may have a flat planar head face having edges between which the width of the wedge wire is defined. The head face tapers inwardly from the broad end of the wedge wire to the narrow end of the wedge wire.
In another form, the invention resides in a screen basket for centrifuges, the screen basket having a body of frusto-conical shape, the body including a plurality of wire members and a number of support rods, wherein each wire member is oriented in a common plane with a rotational axis of the body and the support rods are oriented circumferentially of the body and there are longitudinal slots located between adjacent wire members.
The wire members suitably have a broad end and an opposite narrow end, wherein the wire members narrow in width from the broad end to the narrow end.
The wire members may be wedge wires as defined and described in the first form of the invention.
The support rods may have a plurality of teeth spaced around an annulus of the support rod, wherein each pair of adjacent teeth defines a recess for receiving a wire member.
The longitudinal slots may have a constant width. Alternatively, the longitudinal slots may have a varying width.
In yet another form, the invention resides in a method of manufacture of a screen basket for centrifuges, the method including:
feeding a feed wire between rollers in a rolling operation;
gradually displacing at least one of the rollers closer to an adjacent roller as the feed wire is fed between the rollers to form a wedge wire; and
forming a centrifuge basket from the wedge wire.
A rolling machine for forming a wedge wire from a feed wire includes two rollers which are displaced relative to each other as the feed wire is fed between the rollers.
Each roller may have a rotational axis and a groove which has a floor inclined relative to the rotational axis.
The rolling machine includes a controller which controls the rate of displacement of the rollers relative to each other as the feed wire is fed between the rollers. The controller also controls the rate of feed of the feed wire by controlling the rotation of at least one of the rollers.
To assist in understanding the invention and to enable a person skilled in the art to put the invention into practical effect, exemplary embodiments of the invention will be described by way of example only with reference to the accompanying drawings, wherein:
In this patent specification, adjectives such as first and second, left and right, top and bottom, etc., are used solely to define one element or method step from another element or method step without necessarily requiring a specific relative position or sequence that is described by the adjectives. Words such as “comprises” or “includes” are not used to define an exclusive set of elements or method steps. Rather, such words merely define a minimum set of elements or method steps included in a particular embodiment of the present invention. In the drawings, like reference numerals refer to like parts.
The wedge wire 10 has three planar faces, namely head face 11 and two side faces 12, 13. Head face 11 has edges 14 and 15 which are common with side faces 12 and 13. A head width (w) of the wedge wire 10 is defined across the head face 11 extending between the edges 14 and 15. The head width (w) is measured perpendicularly to the longitudinal axis 20 of the wedge wire 10.
The wedge wire 10 has a broad end 17 and a narrow end 18. It will be noted that edges 14 and 15 of head face 11 taper or converge inwardly from the broad end 17 to the narrow end 18. That is to say the head width (w) decreases from the broad end 17 to the narrow end 18.
The side faces 12 and 13 share a common edge 16. A depth (d) of the wedge wire 10 is defined as the shortest distance from the edge 16 to the head face 11. In regard to side face 12, side edges 15 and 16 taper or diverge outwardly from end 17 to end 18. In regard to side face 13, side edges 14 and 16 taper or diverge outwardly from end 17 to end 18. That is to say the depth (d) increases from the broad end 17 to the narrow end 18.
The broad end 17 is in the shape of approximately an isosceles triangle and narrow end 18 is also approximately in the shape of an isosceles triangle. The narrow end 18 thus has a greater depth (d) than broad end 17, which has a greater width (w).
The body 19 has a frusto-conical shape (truncated cone) as shown, having a smaller diameter end 24 and a larger diameter end 25. The wedge wires 10 are circumferentially spaced about a rotational axis 56 of the body 19. Each of the wedge wires 10 are welded to support hoops 21, 22 and 23 at points 26. There are also provided longitudinal or axially oriented slots 27 between adjacent wedge wires 10 having a constant width as shown by distance “X” in
The wedge wires 10 and each longitudinal slot 27 are in a common plane with the rotational axis 56 of the body 19.
In the case that lines 50, 51 and 52, represent wedge wires 10, the longitudinal axis 20 of each wedge wire 10 will lie on one of the lines 50, 51 and 52.
End faces of the wedge wires 10 at their narrow ends 18 are to square to the rotational axis 56. Similarly, the end faces of the wedge wires at their broad ends 17 are square to the rotational axis 56.
One method of manufacturing wedge wire 10 is described in
The process includes an initial step of placing annealed feed wire 35 in groove 32 as shown in phantom in
The side face 120 of wedge wire 100 has a body surface 122 and a nose surface 124. The body surface 122 and nose surface 124 are contiguous along an edge 126. The flat plane of the body surface 122 is angled relative to the flat plane of the nose surface 124. Similarly, the side face 130 of wedge wire 100 comprises a body surface 132 and a nose surface 134. The body surface 132 and nose surface 134 are contiguous along an edge 136. The flat plane of the body surface 132 is angled relative to the flat plane of the nose surface 134.
The nose surfaces 124 and 134 share a common leading edge 160 of the wedge wire 100.
A nose 102 of the wedge wire 100 is defined between the nose surfaces 124 and 134. A body 104 of the wire 100 is defined between the body surfaces 122, 132. The wedge wire 100 is symmetrical about a symmetrical plane (p) extending square from the head face 110 to the leading edge 160. The symmetrical plane (p) extends through a longitudinal axis 200 of the wedge wire 200.
The body surfaces 122, 132 are slanted at about a 3 degree angle to the symmetrical plane (p) along the whole of the wire 100. Although an approximately 3 degree angle may be advantageous, it will be appreciated that the angle could be of varying degrees. The angle may advantageously fall within the range of 1 degree to 15 degrees, and more particularly in the range of 1 degree to 10 degrees, and even more particularly in the range of 1 degree to 6 degrees, and still more particularly between about 2 degrees and about 4 degrees.
The depth (d) of the wedge wire 100 increases from the broad end 170 to the narrow end 180. As such, depth d1 measured at the broad end 170 is shallower than depth d2 measured at the narrow end 180. In order for the depth to increase and the body surfaces 122, 132 to remain at around 3 degrees, the body 104 elongates in the depth direction.
The head width (w) decreases from the broad end 170 to the narrow end 180. The head width w1 measured at the broad end 170 is thus wider than the head width w2 measured at the narrow end 180.
The wedge wires 10 of the screen basket body 19 depicted in
The wedge wire 100 is formed from constant cross-section feed wire using a rolling process.
The upper roller 202 is selectively displaceable in the frame 210 relative to the lower roller 204 so that the spacing between the rotational axes 206, 208 vary. Even though the spacing between the axes 206, 208 may vary, the rotational axes 206, 208 remain parallel.
The upper roller 202 is displaced upwardly or downwardly by electric motors 216 of the rolling machine 100 mounted on top of the frame 210. The rollers 202, 204 have axles 212. The axle 212 of the upper roller 202 is journaled at either end in a block 214. The blocks 214 are movable up and down in the frame 210. The motors 216 rotate screws which engage the blocks 216 to translate the blocks 214 up and down in the frame 210.
The axles 212 are driven via drive shafts 218. The drive shafts 218 are connected to the axles 212 via universal joints 220. The universal joints 220 allow the upper roller 202 to be displaced while still driving the axle 212 of the upper roller 202.
It will be appreciated that although the upper roller 202 has been described as being displaceable, the lower roller 204 may also be displaceable. Either way, the upper roller 202 and the lower roller 204 are displaceable relative to each other.
The speed of rotation of the drive shafts 218, govern the rate of feed of wedge wire between the rollers 202, 204. The drive shafts 218 are driven by a hydraulic motor (not shown).
In one example, the upper roller 202 is displaced 0.88 mm from the start position to the end position over 750 mm of travel of feed wire between the roller 202, 204. That is to say that between the start position and the end position, the upper roller 202 moves about 0.11733 . . . mm closer to the lower roller 204 for every 100 mm of pre-formed feed wire fed between the rollers. In the example, the head width of the wedge wire 100 decreases from 3 mm to 2.12 mm over 750 mm. The decrease in head width is at a constant rate over the length of the wedge wire 100. The depth of the wedge wire 100 increases as the head width decreases. The depth of the wire 100 is 6.22 mm at the wide end 170 and 6.92 mm at the narrow end 180.
In use, the body surface 122 or 132 of the wedge wire 100 is supported between the floors 232 of the grooves 230 with its head face against the shoulder faces 234 of the grooves 230.
The steps to manufacture a screen basket from either wedge wire 10 or 100 is described herein below as the process is the same irrespective of whether wedge wire 10 or 100 is used. Wedge wire 10, 100 is straightened and in one step may be placed in a rotating table 40 as shown in
Alternatively, use may be made of a split conical jig 43 shown in
Alternatively, a screen basket 240, shown in
The support hoop 250, shown in more detail in
Alternatively, a plurality of individual frusto-conical segments may be formed and then connected together to form the frusto-conical body. The segments may be connected to each other using any suitable affixing means, such as bolting or welding. Each segment may be constructed as a flat panel first and then curved to the desired frusto-conical segment shape. The plurality of segments may include at least 4 segments, more particularly at least 8 segments, and even more particularly 12 segments. However, it will be appreciated that the number of segments may be varied according to the size and shape of the desired frusto-conical body.
In practice, wedge wire 10, 100 is laid across rods 42 as shown in
It will be appreciated from the foregoing with the wires 10, 100 having the cross-sectional shapes described above, that centrifugal screen basket body 19 may be produced having a longitudinal slot 27 of uniform or constant width which is also in a common plane with the rotational axis of body 19. This means that coal particles included in a slurry being processed by centrifugal screen basket body 19 will travel from one end 24 to the other end 25 on tapered head face 11, thereby reducing fracturing and providing a greater harvest of coal from processing of the coal slurries.
It will be appreciated from the foregoing that because each wedge wire and thus each longitudinal slot is in a common plane with the rotational axis of the frusto-conical body, and also each slot has a constant width, that fracturing of particles in coal slurries is substantially reduced and thus the magnitude of the coal harvest from the processing of coal slurries is considerably increased.
Number | Date | Country | Kind |
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2016903443 | Aug 2016 | AU | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AU2017/050925 | 8/30/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2018/039719 | 3/8/2018 | WO | A |
Number | Name | Date | Kind |
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2526475 | Glesmann | Oct 1950 | A |
3123557 | McPhee et al. | Mar 1964 | A |
3491888 | Benson | Jan 1970 | A |
4487695 | Connolly | Dec 1984 | A |
4569761 | Spiewok | Feb 1986 | A |
5378364 | Welling | Jan 1995 | A |
6736968 | Mullins | May 2004 | B2 |
20100263819 | Maurais | Oct 2010 | A1 |
Number | Date | Country |
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19502572 | Aug 1996 | DE |
0061539 | Oct 1982 | EP |
0494708 | Jul 1992 | EP |
2282763 | Apr 1995 | GB |
S5861911 | Apr 1983 | JP |
Entry |
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International Search Report and Written Opinion dated Oct. 9, 2017 for PCT/AU2017/050925. |
Number | Date | Country | |
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20190240679 A1 | Aug 2019 | US |