SE523974C2 - Sedimentation unit, sedimentation plant and method of separation - Google Patents

Abstract

The present invention relates, inter alia, to a sedimentation unit (1) for separating solid particles or the like from a flowing fluid containing such particles, wherein the unit (1) includes at least one lamellate pack (2) and at least one outlet channel (3), and wherein the lamellate pack (2) shows at least one inlet (15) for said particle­ containing fluid, at least one first outlet (16) for fluid that is substantially free of such particles, and at least one second outlet (17) for separated particles. The sedimentation unit (1) is characterised in that the lamellate pack (2) includes at least two flanged, generally planar lamellar plates (4) which are joined together to form a unit and which together define at least one channel for said flowing fluid, said channel sloping obliquely upwards from said inlet (15) to said first outlet (16) when the sedimentation unit (1) is in use.

Description

523 974 2 provide a lamella plate for use in a sedimentation unit according to the invention. A third object of the invention is to provide a sedimentation plant based on the sedimentation unit according to the invention.

A fourth object of the invention is to provide a method for separating solid particles or the like existing in a fluid from a flowing fluid by means of the sedimentation unit according to the invention.

The invention thus comprises a sedimentation unit for separating solid particles or the like present in a fluid from a flowing fluid, which unit comprises at least one lamella package and at least one outlet chute, the lamella package having at least one inlet for said fluid with particles, at least a first outlet for said fluid mainly without particles and at least one second outlet for separated particles. The lamella package comprises at least two, flattened substantially flat lamella plates joined together to form a unit and together form at least one channel for said flowing fluid, which channel, when using the sedimentation unit, slopes obliquely upwards from said inlet to said first outlet.

The lamella package may also comprise a substantially flat cover plate which together with said lamella plates forms as many channels for said flowing fluid as there are lamella plates in the lamella package, the lamella package also having as many of each of said inlets, first outlets and second outlets as there are lamella plates in the lamella package.

Each said enamel plate may be substantially rectangular and provided with a continuous flange along each of two of its edges. Said continuous flange can extend substantially perpendicular to said lamella plate on its front side so that said lamella plate with its two flanges constitutes a gutter with a U-profile. Said lamella plates can be placed next to each other in the lamella package in such a way that all flanges are facing in the same direction, the flanges on each but one of said lamella plates with their edges abutting against and being permanently joined to the adjacent side of lamella plate and the flanges on one of said lamella plates with their edges abut against and are permanently joined to adjacent said cover plate. At least one of said flanges may be provided with at least one recess in the part of the flange which, when using the sedimentation unit, is located closest to said first outlet.

Each of said inlets may be the same as each of said second outlets, respectively.

Said lamella plates can be made of sheet steel or the like with a wall thickness of 0.3-1.0 mm, preferably 0.5-0.75 mm. Said lamella plates may be made of plastic or the like with a wall thickness of 1.5-3.0 mm, preferably 2.0-2.5 mm.

Each said channel for said flowing fluid, which channel, when using the sedimentation unit, slopes obliquely upwards from said inlet to said first outlet, may have an angle of inclination towards the horizon of 45-70 degrees, preferably 55-60 degrees. Said outlet chute may enable fluid leaving said first outlet to flow up to and through at least one opening in said outlet chute. Said opening in said outlet chute may be provided with at least one pipe connection for connection to a further pipeline or the like. Said outlet chute may be made of sheet steel or the like with a wall thickness of 1.5-3.5 mm, preferably 2.0-3.0 mm. Said outlet chute may be made of plastic or the like with a wall thickness of 5.0-7.0 mm, preferably 6.0 mm.

At least one bracket may be provided for suspending and / or attaching the sedimentation unit to a sedimentation plant such as a basin or the like. Two brackets may be present, a first of said brackets being located, when using the sedimentation unit, at the bottom and front of the lamella package at said inlet while a second of said brackets is located at the top and rear of the lamella package at said first outlet.

The invention also comprises a lamella plate for use in a sedimentation unit as above. It is substantially rectangular and provided with a continuous flange along each of two of its edges, said flange extending substantially perpendicular to said lamella plate on its front side so that said lamella plate with its two flanges forms a groove with U-profile. The invention further comprises a sedimentation plant comprising at least one sedimentation unit as above and a method for separating from a flowing fluid solid particles or the like existing in the fluid where the separation is carried out with a sedimentation unit as above.

List of figures Figure 1 shows, in perspective, a sedimentation unit according to the invention.

Figure 2a shows, in side view and partly in section, a sedimentation unit according to the invention.

Figure 2b shows, in a view from above, the sedimentation unit in figure 2a.

Figure 2c shows, in front view, the sedimentation unit in figure 2a.

Figure 3a shows, in side view, a lamella plate included in the sedimentation unit in figure 2a.

Figure 3b shows, in front view, the lamella plate in figure 3a.

Figure 3c shows, in top view, the lamella plate in figure 3a.

Figure Sd shows, in perspective, the lamella plate in figure 3a.

Figure 4a shows, in side view, an end plate with a front bracket included in the sedimentation unit in figure 2a.

Figure 4b shows, in front view, the end plate with the front bracket in figure 4a.

Figure 4c shows, in a top view, the end plate with the front bracket in figure 4a.

Figure 4d shows, in perspective, the end plate with the front bracket in figure 4a.

Figure 5a shows, in side view, a rear bracket included in the sedimentation unit in figure 2a.

Figure 5b shows, in front view, the rear bracket in figure 5a.

Figure 5c shows, in top view, the rear bracket in figure 5a.

Figure 5d shows, in perspective, the rear bracket in Figure 5a.

Figure 6a shows, in perspective, a first embodiment of an outlet gutter included in the sedimentation unit in figure 2a.

Figure 6b shows, in perspective, a second embodiment of an outlet gutter included in the sedimentation unit in figure 2a. 523 974 Figure 6c shows, in perspective, a third embodiment of an outlet gutter included in the sedimentation unit in figure 2a.

Figure 7 shows, in side view and partly in section, part of a sedimentation plant according to the invention with a sedimentation unit according to the invention.

Description of embodiments Figures 1 and 2a-2d show that a sedimentation unit 1 comprises a lamella package 2 and an outlet gutter 3. The lamella package 2 comprises a number of flanged lamella plates 4 and between the flanges - more precisely 23 lamella plates 4 in the embodiment according to figure 2a and more plates in the embodiment according to figure 1. In the flanges 5 of the lamella plates there are recesses 6 with V-shape. In the lamella package 2 there is also an end plate 7 without flanges.

In addition, there is a front bracket 8 and a rear bracket 9 for suspending and / or attaching the sedimentation unit 1 to a sedimentation plant such as a basin or the like. The outlet gutter 3 has an opening 10 with a pipe connection 11.

As can be seen from Figures 3a-3d, each lamella plate 4 is rectangular and provided with a continuous flange 5 along each of two of its sides - more precisely two of its opposite sides - and in the entire length of the sides. The flanges 5 extend perpendicular to the main part of the lamella plate 4 and in the same direction relative to the main distribution plane of the plate so that a lamella plate 4 with its two flanges 5 forms a groove with a U-profile. The lamella plates 4 are in the lamella package stacked next to / on top of each other with all flanges facing in the same direction - to the left in figure 2a, but it could just as easily have been to the right. The flanges on each but one of the lamella plates 4 thus abut with their edges - and here the thin edge which consists of the thickness of the flange material - against the back side of the adjacent lamella plate, i.e. the side which forms the underside in the U described above.

The flanges 5 on the remaining enamel plate 4 instead abut with their corresponding edges against the adjacent end plate 7. Each flange 5 abuts the adjacent plate in its entire length and the flanges 5 are permanently joined to the respective adjacent plate by welding, soldering, brazing, gluing or in another appropriate manner. The joint can also be reinforced or replaced with surface-mounted laminate over joints. Thus, between each pair of adjacent plates there is a channel for flowing fluid. The recesses 6 are present in all the flanges 5 in order to enable a so-called toothed ski table in the part of the lamella package 2 where this opens into the outlet channel 3.

Figures 4a-4d show that the end plate 7 is of the same size as the non-flanged part of the lamella plate 4. On the end plate 7, the front bracket 8 is fastened in a suitable manner or made in one piece with the end plate 7. Figures 5a-5d show how the rear bracket 9 looks. If the lamella plates 4 in the lamella package are instead stacked next to / on top of each other with all flanges 5 facing the other way, ie to the right in figure 2a, the end plate 7 may of course be placed at the rear end of the lamella package and then instead cooperate with the rear bracket 9. are in that case suitably modified at the ends closest to the lower edge of the lamella package so that the lower edge also in this case becomes even. Regardless of where the end plate 7 is located in the lamella package, the two brackets 8, 9 can also be of the same design, ie both brackets can either be designed as the front bracket 8 shown here or as the rear bracket 9 shown here and in all cases of course turn over appropriate manner. Two attachment points - a front / lower and a rear / upper - are sufficient for the sedimentation unit 1 because the lamella package is of such a rigid construction due to its construction and through the design of the lamella plates 4.

Figures 6a and 6b show alternative embodiments of the outlet gutter 3, wherein figure 6a primarily, but not exclusively, refers to design in plastic or the like, while figure 6b primarily, but not exclusively, refers to design in sheet steel or the like. The outlet gutter 3 consists of a continuous gutter with L-profile which runs along three of the sides of the lamella package, the upper end of the lamella package, when using the sedimentation unit 1. The lower edge of the L-profile - and this refers to the thin edge which consists of the thickness of the gutter material - abuts the Iamell package and is permanently joined to it by welding, soldering, brazing, gluing or in another suitable way. In an alternative embodiment, the sedimentation unit 1 can instead be single-sided and outlet gutter 3 with L-profile thus only occur on one side of the lamella package 2, which in that case would be either left or right side when the sedimentation unit 1 is seen as in figure 2c. Both gutter 3 on the left and gutter 10 25 25 525 974 7 3 on the right can each be combined with a front gutter 3 with L-profile and with or without opening 10 and pipe connection 11. On the side of the lamella package 2 where outlet gutter 3 with L-profile does not occur, there should instead be a cover plate that makes it difficult or impossible for uncontrolled leakage of purified fluid, see figure 60 where the cover plate appears on the left. Recesses 6 should not occur in flanges 5 closest to the cover plate.

The sedimentation unit 1 according to the invention constitutes a ready-made module which can be installed in sedimentation plants of different types and sizes and which is easy to assemble. In Figure 7, a sedimentation unit 1 is mounted in a part of a basin, one of the walls of the basin being denoted by 12. The front bracket 8 is attached to the wall 12 in a suitably known manner, while the rear bracket 9 is either attached to a rear wall (not shown) in the pool or held in position by the action of a suitable brace or the like from the pool wall or bottom. The pipe connection 11 is connected to an outer pipeline 13 which extends through the pool wall 12 and further out. The sedimentation unit 1 is deeply, but not completely, immersed in the surrounding pool fluid, for example water. The level of the fluid in the sedimentation unit 1 is normally 2-3 cm below the level 14 of the surrounding pool fluid. It is of course also possible to install several sedimentation units 1 in one and the same sedimentation plant.

The function of the sedimentation unit 1 will now be described in more detail in connection with Figure 7. Fluid with solid particles, for example water with solid contaminants such as biosludge, precipitated heavy metals or the like, is pressed by self-pressure and thus without pumping through the lamella package 2 whereby the fluid enters the lamella package 2 lower edge in each of the existing plate gaps and emerges in the upper edge of the lamella package 2 through and possibly above recesses 6. Upon passage through the lamella package 2, the fluid is purified from impurities which by the action of gravity sediment on the U-shaped lamella plates and are caused to sink through respective plate gaps and further down to the bottom of the pool. Each plate gap thus has an inlet 15 for contaminated fluid, a first outlet 16 for substantially purified fluid and a second outlet 17 for separated particles, the same opening functioning as inlet 15 and second outlets 17. The purified fluid continues out into the outlet channel 3, the opening 10, the pipe connection 11 and the outer pipeline 13.

By using the sedimentation unit according to the invention, the required pool area for sedimentation can be reduced to about one tenth of the need for traditional pool sedimentation.

The invention is not limited to the embodiments shown here but can be varied within the scope of the appended claims.

Claims (16)

20 25 30 523 974 Cl CLAIMS A sedimentation unit (1) for separating solid particles or the like present in a fluid from a flowing fluid, which unit (1) comprises at least one lamella package (2) and at least one outlet chute (3), the lamella package (2) having at least one inlet (15) for said fluid with particles, at least a first outlet (16) for said fluid substantially without particles and at least a second outlet (17) for separated particles, the lamella package (2) comprising at least two, flanged together substantially flanged flat lamella plates (4) which together form at least one channel for said flowing fluid, which channel, when using the sedimentation unit (1), slopes obliquely upwards from said inlet (15) to said first outlet (16) and each said lamella plate (4) is substantially rectangular and provided with a continuous flange (5) along each of two of its edges, said continuous ns end (5) extending substantially perpendicular to said lamella lath (4) on the front side thereof so that said lamella plate (4) with its two flanges (5) constitutes a gutter with a U-profile, characterized in that said lamella plates (4) are placed next to each other in the lamella package (2) in such a way that all flanges (5) are turned in the same direction, the flanges (5) on each but one of said lamella plates (4) with their edges abutting against and being permanently joined to the rear side of said lamella plate (4). Sedimentation unit (1) according to claim 1, characterized in that the lamella package (2) also comprises a substantially flat cover plate (7) which together with said lamella plates (4) forms as many channels for said flowing fluid as there are lamella plates (4) in the lamella package (2), the lamella package (2) also having as many of each of said inlets (15), first outlet (16) and second outlet (17) as there are lamella plates (4) in the lamella package (2). Sedimentation unit (1) according to claim 2, characterized in that the flanges (5) on one of said lamella plates (4) with their edges abut against and are permanently joined to adjacent said cover plate (7). 15 20 25 30. .. ............. .. Sedimentation unit (1) according to any one of the preceding claims, characterized in that at least one of said flanges (5) is provided with at least one recess (6) in the part of the flange (5) which, when using the sedimentation unit (1), is located closest to said first outlet (16). Sedimentation unit (1) according to any one of the preceding claims, characterized in that each of said inlets (15) is the same as each of said second outlets (17), respectively. Sedimentation unit (1) according to any one of the preceding claims, characterized in that said lamella plates (4) are made of sheet steel or the like with a wall thickness of 0, 3-1, 0 mm, preferably 0.5-0.75 mm. Sedimentation unit (1) according to any one of claims 1-5, characterized in that said lamella plates (4) are made of plastic or the like with a wall thickness of 1.5-3.0 mm, preferably 2.0-2.5 mm . Sedimentation unit (1) according to any one of the preceding claims, characterized in that each said channel for said flowing fluid, which channel, when using the sedimentation unit (1), slopes obliquely upwards from said inlet (15) to said first outlet (16) , has an inclination angle to the horizon of 45-70 degrees, preferably 55-60 degrees. Sedimentation unit (1) according to any one of the preceding claims, characterized in that said outlet channel (3) enables för uidum leaving said first outlet (16) to flow up to and through at least one opening (10) in said outlet channel (3). Sedimentation unit according to claim 9, characterized in that said opening (10) in said outlet chute (3) is provided with at least one pipe connection (11) for connection to a further pipeline (13) or the like. 15 20 25 523 974 ll Sedimentation unit (1) according to any one of claims 9 and / or 10, characterized in that said outlet gutter (3) is made of sheet steel or the like with a wall thickness of 1.5-3.5 mm, preferably 2.0-3, 0 mm. Characterized in that said outlet chute (3) is made of plastic or the like with Sedimentation unit (1) according to any one of claims 9 and / or 10, a wall thickness of 5.0-7.0 mm, preferably 6.0 mm. Sedimentation unit (1) according to one of the preceding claims, characterized by at least one bracket (8, 9) for suspending and / or attaching the sedimentation unit (1) to a sedimentation plant such as a basin or the like. Sedimentation unit (1) according to claim 13, characterized by two brackets (8, 9) wherein a first (8) of said brackets is located, when using the sedimentation unit (1), at the bottom and front of the lamella package (2) at said inlet (15) while a second (9) of said brackets is located at the top and rear of the lamella package (2) at said first outlet (16). Sedimentation unit (1) according to any one of claims 1-14. Sedimentation plant characterized in that it comprises at least one Method for separating solid particles or the like existing in a fluid from a flowing fluid, characterized in that the separation is carried out with at least one sedimentation unit (1) according to any one of claims 1-14.