The present invention relates to a belt (or filter cloth) for use in a tower press, a tower press comprising such a belt, and a method of operating a tower press comprising such a belt.
Tower presses are a well known type of filtration apparatus comprising recessed plate membrane filters, in which the chambers are stacked horizontally with rollers at each end. In tower presses, a belt runs over the chambers and rollers, and as such the belt forms an elongated corrugated shape threading through the stack of horizontal chambers and rollers. Typically this belt is continuous, i.e. its two ends are joined together so as to form a closed loop. When filtration occurs, cake builds up on the horizontal part of the elongated corrugations of the belt, and this cake is removed by advancing the belt past the rollers at the end of each horizontal chamber, which encourages the cake to ‘fall off’ as the belt turns through 180° to begin its next corrugation. Cake discharge is further encouraged by scrapers that are fixed to each plate and which bear onto the belt.
Tower presses of this kind are readily available, for example, from suppliers such as Outotec (for example the Outotec Larox® PF). In prior art tower presses, tower press belts are woven and finished so that they have the same properties (e.g. permeability, surface finish, etc) on each side of the belt. Therefore, in use, the belt passes over a roller to remove cake, and the “cake side” of the belt can then swap over without affecting the operational performance of the tower press. The tower press operator can choose the number of plate lengths that the belt advances during cake discharge. An even number of plate lengths means that a particular piece of belt will always have the same orientation during filtration, while an odd number means that a particular piece of belt will be used in alternating orientations.
When used in this conventional manner, the early stages of filtrate in each cycle can be cloudy, due to embedded solids from the last cycle being flushed out. This is because the belt has a ‘tight’ filtration surface on both sides, which will not readily allow free drainage of contaminants. It is therefore desirable to find a belt design that reduces the occurrence of filtrate cloudiness.
According to a first embodiment of the present invention, there is provided a belt for use in a tower press, the belt comprising a first surface and a second surface having differing properties.
According to a second embodiment of the present invention, there is provided a tower press comprising a belt according to the first embodiment of the invention.
According to a third embodiment of the present invention, there is provided a method of operating a tower press comprising rollers and a belt according to the first embodiment of the invention, wherein the method comprises the steps of:
According to a fourth embodiment of the present invention, there is provided a method of cleaning a tower press, comprising the steps of:
The present invention gives rise to a filtrate with improved clarity (i.e. reduced cloudiness), in particular in the early stages of each cycle, as there is less solid material flushed out of the cloth at the beginning of a cycle. Further, as the belt is intended for use in one direction only, the lifetime of the belt is increased due to back flushing being more effective.
The belt of the present invention preferably has a first surface and a second surface having differing permeability and/or particle capture properties. This can be achieved by one surface being fine (i.e. designed for maximum particle retention) and the other surface being coarse (i.e. allowing passage of particles). The fine surface is typically the ‘filtration surface’, and preferably it is the first surface and is presented uppermost during a filtration cycle. The coarse surface is typically the ‘drainage surface’, and preferably it is the second surface and is presented lowermost during a filtration cycle. Suitable ways of rendering one surface fine and one coarse include using a weave design that gives rise to more fibres on the fine surface and fewer fibres on the coarse surface, such as a twill or satin weave. This technique is described in for example Solid-Liquid Filtration: A User's Guide to Minimizing Cost & Environmental Impact, Maximizing Quality & Productivity Trevor Sparks (Butterworth-Heinemann, 1 Nov. 2011, pages 137-138). Typically the number of fibres in a fine surface compared to the number of fibres in a coarse surface is approximately 3:1, although it is preferably approximately 4:1.
Further details concerning the construction of the belt of the present invention shall now be outlined. The belt shall preferably be of woven construction, preferably comprising or consisting of interlacing warp and weft yarns. Both warp and weft yarns may be formed from a range of materials including, but not limited to: PET (polyester), PA (polyamide), or PP (polyproplylene); all of which may be monofilament, multifilament or staple fibre construction or mixtures thereof. For both warp and weft yarns; suitable multifilament yarns may have a linear density in the range of 470-3300 dtex (g/10,000 m); suitable staple fibres may have a metric count (length in metres of one gram of product) in the range 2 to 10 Nm (m/g); and suitable monofilament yarns may have a diameter in the range 0.16 to 0.6 mm.
Suitable weave designs may include the following: imbalanced twill weaves of 2×1, 3×1, 3×2, 4×1, 4×2, 5×1, 6×2 construction or combinations of the same patterns, satin weaves of 3×1, 4×1, 5×1, 6×1, 7×1 or 6×2 construction, with the design reversing at intervals of every filter plate length. Most suitable designs include the following: twill weave 3×2, satin weaves of 3×1 or 5×1, with the design reversing at intervals of every filter plate length. By way of further example, a 3×1 twill may be reversed to a 1×3 twill design at intervals of each filter plate length.
Air permeability of a filter belt of the present invention may be in the range from 1 to 250 l/dm2 min.
The capacity of a belt according to the present invention (in terms of liquid throughput) is higher than a conventional belt with an equivalent filtration surface on both sides, for example since the liquid only passes through one fine surface.
Furthermore, the belt suffers from a smaller and/or slower drop-off in performance since any particles which do pass through the fine surface will then pass straight through the coarse surface of the belt (in contrast with conventional belts in which the particle will frequently be trapped within the structure of the belt (i.e. it will not be able to pass out). This leads to a build-up of solid matter within the structure of the belt and a drop-off in throughput. Hence belts as envisaged in the present invention provide (i) a higher initial throughput for the same filtration performance in terms of filtrate clarity, (ii) more consistent throughput through the lifetime of the belt, and (iii) a longer lifetime as they do not block as quickly.
The belt is typically divided into at least two segments, and preferably there are multiple adjacent segments wherein each segment is in contact with two other segments; one either side. Typically the number of segments is at least equal to the number of plates in the filter press, and preferably there are extra segments to allow for other mechanical operations of the filter press, such as tensioning and returning the cloth to the top of the plate-pack. When the belt is laid flat, each segment has an upper face and a lower face. Typically the upper face of a first segment is the first surface, and the lower face of this first segment is the second surface. When this is the case, the upper face of each segment adjacent to the first segment is preferably the second surface, and the lower face of each segment adjacent to the first segment is the first surface. Preferably every second segment has the same configuration as the first segment, such that as one moves along the length of the belt, the upper face of each segment alternates between the first surface and the second surface, and the lower face of each segment alternates between the second surface and the first surface (such that each segment contain both first and second surfaces, but that they alternate between the upper and lower faces). Typically each segment is approximately one filter length long, such that, in operation on a tower press, the first surface is the uppermost surface on all chambers during a filtration cycle, and the second surface is the lowermost surface on all chambers during a filtration cycle.
The belt preferably comprises an RFID (Radio Frequency Identification) tag. The tag is typically placed between two adjacent segments, preferably between all adjacent segments. The tag serves to identify how far the belt needs to be moved along in between each filtration cycle in order to ensure that, for example, the first surface always remains the uppermost surface. In the instance where an RFID tag is positioned between each segment (i.e. one filter length apart), the tag would have to be moved on two ‘positions’(i.e. two filter lengths) in order to keep the fine surfaces as the uppermost surface. An alternative would be to have a tag at an interval of a certain number of plate lengths, e.g. 2, 3, 4, 5 or 6.
The belt of the present invention can be used in a standard tower press. When used in a standard tower press, the belt is not flat but folded into elongated corrugations such that the first surface is substantially always uppermost, in other words the belt is arranged on the stacked horizontal chambers of a tower press such that the first surface is always above the second surface, with the second surface in contact with each horizontal chamber. Once filtration has occurred for a time period and cake has built up, the belt is passed over rollers (usually with scrapers) at the ends of each horizontal chamber, which removes the cake. The belt can them be repositioned to ensure that the first surface is substantially always uppermost. This is usually done by advancing the belt until an RFID tag identifies a stop point. As RFID tags are usually placed between segments in the belt, they mark the points where the first surface changes from being uppermost to lowermost. Alternatively other belt position identifiers can be used such as optical sensors, metallic/magnetic/seam sensors, or index wheels which detect the actual movement of the cloth.
Optionally, the belt can be back-flushed between each, or a certain number of, filtration cycle(s) by positioning the belt such that the second surface is substantially always uppermost, and temporarily running a wash liquid (possibly a clean filtrate) in the opposite direction to that present during filtration. Once this back-flushing is complete, the belt can be advanced to its regular position with the first surface substantially always uppermost. Again, RFID (or other) tags can be used to mark the stop points for back-flushing and filtration.
In order that the present invention may be more readily understood, a specific embodiment thereof will now be described by way of example only, with reference to the accompanying figures:
In
Number | Date | Country | Kind |
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1321008.3 | Nov 2013 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/075338 | 11/21/2014 | WO | 00 |