SE518835C2 - Disk filter oscillating shower - Google Patents

Abstract

An oscillating shower (30) for use with a disc filter. The disc filter includes at least one disc (2) and oscillating showers that periodically remove a precoat layer of solids from the surface of the disc. Each oscillating shower (30) moves over the surface of the disc (2) at a varying speed so that water is uniformly applied to the interior and exterior of the disc. At the interior of the disc, where there is a smaller surface area, the oscillating shower moves faster than at the exterior of the disc where the surface area is greater.

Description

518 855 After running the filter for a while, the precoat layer becomes less permeable and no longer provides suitable filtration. Accordingly, it is necessary to periodically remove the precoat layer. The disc filter shown in Fig. 2 provides a removal of the precoat layer by using an oscillating spray tube 14 equipped with a spray nozzle 15. The spray nozzle 15 for fl extends between the edge and the center of the disc 2, sprays the water on the disc 2 and removes the coating layer.

The use of an oscillating shower to remove solid material from a disk alter is also described in U.S. Patents 3,252,577 and 4,332,680. A problem common to all of these devices is that the shower arm moves at a fixed speed. Since the disc surface is much smaller towards the middle of the disc, more water is used than necessary on this inner part of the disc, which wastes water. If the speed of the oscillating shower is increased to correspond to the inner area of the disc, insufficient spraying will occur at the outer area of the disc.

SUMMARY OF THE INVENTION The above-mentioned and other disadvantages and weaknesses of the prior art are overcome or improved by the disc filter system of the present invention. In accordance with the present invention, the disc filter includes oscillating showers that periodically remove the solid particle coating layer from the disc filters. Each oscillating shower moves over the surface of the disc at a varying speed so that water is sprayed uniformly on the outer and inner surface of the disc. At the inside of the disc, where the surface is smaller, the oscillating shower moves faster than at the outer edge of the disc where the surface is larger.

The oscillating shower, which oscillates at varying speeds, sprays an even amount of water on the surface of the disc. This reduces the amount of water used to remove the pre-coating layer and reduces the number of nozzles.

Reducing the number of nozzles reduces the initial costs and maintenance costs of discs. The above and other features and advantages of the present invention will be best understood by those skilled in the art from the following detailed description and drawings.

Brief Description of the Drawings With reference to the drawings, like elements are designated by the same numerals: Fig. 1 is a cross-sectional view of a conventional disc filter; F ig. 2 is a cross-sectional end view of a conventional disk alter; Fig. 3 is a cross-sectional end view of the board filter according to the present invention; Fig. 3A is a block diagram of the turntable control system; Fig. 4 is an enlarged view of the oscillating shower rod; Fig. 5 is a cross-sectional view of the disc filter of Fig. 4; Fig. 6 is an enlarged view of the oscillating shower control unit; Figs. 7A-7C show the path and velocity of the oscillating shower over the filter discs for the first pass and subsequent passes; and Detailed description of invention Figs. 3 is a cross-sectional end view of the disc filter of the present invention.

The disc filter includes at least one disc 2. The disc 2 is similar to those described in the prior art in that solid material is removed from liquid by forcing the liquid through the filter discs 2. The liquid is forced through the discs 2 by creating a pressure difference between the container or the vessel 5 and the inside of the discs 2 (eg by pressurizing the container 5 or creating a vacuum inside the discs 2). The discs 2 may be of a perforated material, e.g. metal covered with a filter material, e.g. polypropylene. The filter material is generally referred to as 518 835 as a filter cloth. Each disc 2 is divided into disc sectors 70 which are covered with filter cloth. The discs 2 are placed inside a container 5 which contains the solid / liquid sludge. The level of the sludge may vary but is typically around the center of the disc 2. As the disc 2 rotates, each sector 70 enters the sludge entirely and an amount of solid material is deposited on the surface of each disc sector 70.

The solid material is then removed from each sector 70 to separate the solid material from the liquid.

An oscillating shower 30 includes an oscillating shower rod 32 having shower nozzles 34. The oscillating shower 30 is used to remove the pre-coating layer of solid particles formed on the surface of the disc 2. During normal filtration, the oscillating shower 30. At the end of a filter cycle cycle, the precoat layer has become impermeable to effectively filter and must be removed. The container 5 is drained, the disc being rotated counterclockwise (as shown in Fig. 3) at a low speed and the oscillating shower removing the precoat layer formed on the disc 2. In accordance with an important feature of the present invention, the oscillating shower sprays the surface of the disc 2 evenly at a varying speed and with a predetermined pattern. The details of this oscillating pattern for the oscillating shower 30 are described below with reference to Figs. 7A-7C.

A scraper mechanism 40 includes a blade 42 which removes the cake layer from the precoat layer. During filtering, the disc rotates 2 counterclockwise (as shown in fi g. 3). As each slice sector 70 passes through the sludge and emerges from the sludge, additional solid material is deposited on the surface of the slice sector 70. As the slice sector 70 passes through the scraper blade 42, the cake layer formed on top of the precoat layer is removed. The removed solid material falls into the gutter 46. A gutter shower 44 sprays water into the gutter 46 and allows the solid material to slide down to the bottom of the gutter 46. The solid material is discharged into a mesa mixing tank, using gutter sprayers and recycled sludge from the mixing tank.

A washing shower 50 is an option for the disc filter. The wash shower includes a wash tube 52 and a plurality of wash shower nozzles 54. The wash shower nozzles 54 spray water at the solid material formed on the disc sectors 70 when each disc sector 70 is in the sludge. each disk sector 70 emerging from the sludge contains both solid particles and some liquid. The washing shower 50 replaces part of the liquid with water, thus preventing the liquid containing higher concentrations of chemicals from being discharged into the gutter 40. This increases the filter efficiency of the disc filter.

The operation of the disc generator will now be summarized. The solid / liquid sludge is fed to the container 5 through an inlet pipe. The container 5 is then pressurized and the discs 2 are rotated counterclockwise (as shown in Fig. 3). When the disc sectors 70 emerge from the sludge, they are coated with a cake of solid material and liquid. The wash shower 50, if used, replaces the liquid to prevent the liquid from draining into the gutter 40. The cake layer formed on top of the precoat layer is then removed by the scraper blade 42. This process continues for a desired period of time until the precoat layer becomes too impenetrable and must be removed to maintain the ter lter capacity. At this time, the container is drained, the discs 2 are rotated slowly and the oscillating shower 30 removes the pre-coating layer. Once the precoat layer has been removed, the filtering process resumes.

Instead of removing the precoat at the end of the filtration cycle, the decision to initiate the oscillating shower 30 can be made automatically by the control circuits.

When either a high sludge level or a pressure drop is detected by the control circuits, the oscillating shower is activated. As shown in Fig. 3A, a sludge level sensor 200, which is located inside the container 5, detects the level of the sludge. A pressure sensor 210 detects if the pressure in the vacuum system increases. Both of these conditions indicate that the fate through the filter discs 2 is hindered and that the filter sectors 70 need to be cleaned. Upon detection of one of these two conditions, the control circuits 220 initiate the pre-coating removal cycle.

Fig. 4 is an enlarged view of the oscillating shower 30 shown in Fig. 3. The oscillating shower rod 32 consists of an upper section 35 and a nozzle section 33. These two sections of the pipe are joined by the coupling unit 36. which have threads shaped at both ends. The coupling unit 36 allows the nozzle section 33 to be removed from the upper section 35 for replacement and / or maintenance of the nozzles 34. The nozzles 34 are formed on the nozzle section 33 and direct water away from the nozzle section 33 towards the surface of the discs 2. Support angles 37 are formed on the upper section 35 to reinforce the oscillating shower rod 32. The oscillating shower rod 32 receives water from the high pressure pipe 3 1. The high pressure pipe 31 is mounted in bearings 39 carried by bearing holders 38. Fig. 4 shows the oscillating shower rod 32 in three positions.

Fig. 5 is a side cross-sectional view of the disc filter. As described above, the oscillating shower rod 32 is connected to a high pressure tube 31. The high pressure tube 31 rotates inside the bearings 39 (shown in Fig. 4) carried by bearing support holders 38. The oscillating shower rod 32 is located adjacent to each surface. of the discs 2.

Nozzles 34 extend away from the oscillating shower rod 32 and direct a jet of water towards the surface of the discs 2. The coating layer removed by the nozzles 34 falls into gutters 40 as described previously.

The oscillating shower rods 32 are driven by a pneumatic actuator 82 mounted on an actuator support 80. The pneumatic actuator 82 drives an actuator arm 85 which oscillates the high pressure tube 31. A feed pipe 84 provides water to the high pressure pipe 31. The feed pipe includes a rotating section 89 which is connected to the high pressure pipe 31. A bearing / ball link 86 connects the rotating section 89 to the feed pipe 84 and allows water to pass from the feed pipe 84 to the rotating section. 89 and allows the rotating section 89 to rotate relative to the feed pipe 84. The bearing / ball joint 86 is mounted on a support bearing holder 87. The rotating section 89 is connected to the high pressure pipe 31 by a split seal 83 and a sealing mounting plate 81. Sealing mounting plate 81 seals the container 5 at the area where the high pressure pipe 31 extends through the container wall. When the control arm 85 is driven up and down, the feed tube 84 remains stationary while the rotating section 89 and the high pressure tube 31 are rotated. 518 855 Fig. 6 is an enlarged view of the area including the pneumatic actuator 82. The bearing / ball link 86 is not shown in Fig. Ö for simplicity.

The pneumatic actuator 82 is mounted on a hinge link 88 which allows the pneumatic actuator to move away from the rotating section 89 as required. The operating arm 85 is connected to the rotating section 89 by a connecting arm (not shown in the drawings) which is welded to the rotating section 89 and rotatably coupled to the operating arm 85. As previously described, the rotating section 89 rotates and causes the high pressure tube 31 to rotate in an oscillating manner, when the control lever 85 moves up and down. The rotation of the high pressure pipe 31 oscillates the oscillating shower rods 32 over the surfaces of the discs 2.

Figs. 7A-7C show the path followed by the oscillating shower nozzles 34 over the surface of a disc (shown in Fig. 3). Fig. 7A shows a single passage of the oscillating shower, fi g. 7 B shows a double pass and ñg. 7C shows a triple pass. The path of the oscillating shower nozzles 34 is indicated by the groove 90. The oscillating shower rod 32 runs between a first radial position and a second radial position on the surface of the disc 2. As shown in ñg. 7A is the first radial position at or near the periphery of the disc 2. The second radial position is close to the center of the disc 2.

The groove 90 is divided into a number of groove sections 92 which indicate the distance that the shower nozzles 34 run per unit time. As shown in ñg. 7A, the groove sections 92 near the center of the disc are larger than the groove sections 92 at the periphery of the disc. The shower nozzles 34 move faster near the center of the disc than at the periphery of the disc. The pneumatic arm 85 is driven faster when the nozzles 34 are near the center of the disc and slower when the nozzles 34 are near the periphery of the disc. There is less area near the center of the disc 2 and thus the nozzles 34 move faster at the center of the disc and still spray the disc surface efficiently. As the disc surface increases on the way from the center of the disc, the nozzles 34 slow down to achieve even coverage of the disc surface. The speed of the oscillating shower rod 32 depends on the radial position of the oscillating shower rod 32. Fig. 7B shows the amount of coverage when the oscillating shower passes over the surface of the disc twice. Fig. 7 C shows that the entire disk surface is covered when the oscillating shower passes over the disk surface three times.

The variation in the speed of the shower nozzles provides several advantages.

Smaller nozzles are needed to effectively cover the surface of the disc compared to stationary showers. This reduces the costs of manufacturing and maintaining the nozzles. In addition, less water is used due to the varying speed of the oscillating shower compared to ordinary showers with fixed speed. Furthermore, a better cleaning job of the surface is provided without leaving unclean areas.

In accordance with the present invention, the oscillating shower uses variable speed to evenly apply water to the entire surface of the discs in a disc filter. Near the periphery of the disc, the oscillating shower rod moves more slowly than near the center of the disc due to the larger amount of area per degree at the periphery of the circular disc. This variation in speed reduces the amount of water used and reduces the number of nozzles needed to distribute the water. Although preferred embodiments have been shown and described, various modifications and changes may be made without departing from the scope of the invention. Thus, it is to be understood that the present invention has been described for purposes of illustration and not limitation.

Claims (10)

518,835 Claims An oscillating shower for use with a disc filter including at least one disc, the shower (30) comprising means for moving over the surface of the disc (2) at a varying speed so that an even amount of liquid is sprayed on the surface of the disc in a pre-determined pattern. An oscillating shower according to claim 1, in which the oscillating shower extends radially over the surface of the disc. An oscillating shower according to claim 2, in which the speed of the oscillating shower depends on the radial position of the oscillating shower. An oscillating shower according to claim 3, in which the velocity of the oscillating shower is greater at a second radial position than at a first radial position. An oscillating shower according to claim 4, in which the first radial position is close to the periphery of the disc and the second radial position is close to the center of the disc. The oscillating shower of claim 1, wherein the oscillating shower comprises an oscillating shower rod and at least one nozzle for directing the liquid toward the surface of the disc. An oscillating shower according to claim 6, wherein the oscillating shower rod is connected to a high pressure pipe, the high pressure pipe supplying the liquid to the oscillating shower rod. A disc filter with a filter material, the disc filter comprising: at least one sensor for detecting a predetermined condition; and control circuits responsive to the at least one sensor for initiating an oscillating shower according to any one of claims 1-7. The filter of claim 8, wherein the filter comprises a sludge and the sensor comprises a sludge level detector for detecting the sludge level. The filter of claim 8, wherein the filter is a pressure filter and the sensor includes a pressure sensor for detecting the pressure in the filter. A filter according to claim 8, wherein the filter is a pressure filter containing a sludge and the at least one sensor comprises a sludge level detector for detecting the sludge level and a pressure sensor for detecting the pressure in the filter.