SE528037C3 - Sludge dewatering device - Google Patents

Description

¶ '__-__-________ I__III-I__IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII 528 037 060519 LK P: \ 5040 Niclas Eriksson \ P \ OO3 \ SE \ P5D400003 ___ 051220_ & ndja kankenten patent. For this to work, the membrane must be kept moist at all times and thereby sufficiently moistened to give the effect of a solvent collection. As the water concentration increases in the membrane, water will fall out of the membrane. The water that falls out of the membrane is suitably collected and used to moisten the membrane.

Because the theory is universal, it means that the present invention can be used for basically any solvent and any solid, or solutes.

The present invention relates to a device for dewatering sludge. It comprises a semipermeable membrane placed to receive the sludge. An air gap is provided on the side of the membrane which does not receive the sludge. Furthermore, means are provided for wetting the membrane with water before the sludge is received. The membrane has several horizontal cell layers, with alternating convex and concave cells.

The device according to the present invention is well suited for use in an automated process, where the device often only forms part of a larger process.

Additional objects and advantages of the present invention will become apparent to those skilled in the art upon reading the detailed description below. Brief Description of the Figures The invention is explained in more detail below with the aid of an example of an embodiment shown in the accompanying figures. In the figures: Fig. 1 shows a principle sketch as a sectional view of a device 30 which utilizes the principle according to the invention, fig. Fig. 2 is a sectional view of a conveyor at the device according to Fig. 1 and Fig. 3 is an enlarged sectional view of a membrane according to the present invention. 35 528 037 10 15 20 25 30 35 060519 LK P: \ 5040 Niclas E: iksson \ l> \ 003 \ SE \ P50-l00003_051220__endzad patenttextndoc Detailed description of preferred embodiments The terms "upper", "lower" and similar terms, as used in this description are with reference to the accompanying figures.

The accompanying figures describe an example of a device according to the present invention, used for dewatering digestate. In this example, a casing or housing 1 is provided. The housing 1 has an inlet 2 for receiving non-dewatered sludge, such as e.g. digestate from the digestion chamber of a sewage treatment plant.

Furthermore, there are two outlets, an outlet 3 for water and an outlet 4 for dewatered sludge. The outlet 4 for dewatered sludge leads to a drying device 5 for further dehumidification of the sludge. Since the design of the drying device 5 has no significance for the present invention, it will not be described further here.

In the housing 1 a conveyor 6 is further arranged, on which sludge 8 which has been fed in via the inlet 2 is received.

In the example shown, the conveyor 6 has a number of rollers 9 which support a metal cloth 10 in a tray-like shape. One skilled in the art will appreciate that the exact design of the conveyor may vary, as long as it meets the most elementary requirements for the invention to function. These requirements include that water must be let through and that the sludge 8 must be received in a safe manner. It is e.g. possible to have a straight conveyor with fixed edges.

According to the invention, a membrane 11 is placed on top of the metal cloth 10 of the conveyor 6, i.e. closest to the sludge 8. The metal cloth 10 is a support for the membrane 11, but if the membrane 11 has sufficient load-bearing capacity on its own, the metal cloth 10 can be removed. One skilled in the art will appreciate that the part carrying the membrane ll need not be a metal cloth, but may be of any material which permeates liquid.

The membrane 11 is made up of a number of layers with alternating convex cells 12 and concave cells 13. The layers with alternating concave and convex cells 12, 13 are horizontal 528 057 10 15 20 25 30 35 060519 LK P: \ 5040 Niclas Eriksson \ P \ 003 \ 8E \ P5040000 _O51220__Bndzad patenttextudoc 4 sontell ordnade, ie. lies at different depths in the membrane 11, as indicated in Figure 3. The cell surfaces are arranged tightly to give a relatively large total surface area. The arrangement of alternately convex and concave cells 12, 13 gives long life to the membrane 11. Practical tests also show that the result is improved in this way. The membrane II may be made of any suitable material, such as e.g. nylon fibers.

Nylon fibers are suitable for e.g. drainage of sludge from digesters at treatment plants. Depending on the solutions and solvents used, the cells in the membrane II may be composed of many different materials.

In a device of this kind, where the cells 12, 13 are arranged in a certain structure, the solvent, in this case water, is driven from cell 12, 13 to cell 12, 13 through the membrane 11 towards the higher concentration of solvent.

Thereafter, excess water falls off the membrane 11.

In the lower part of the housing 1, water separated from the membrane 11 accumulates with a water level 7 which lies between the upper and lower parts of the conveyor 6. As a result, the membrane 11 is continuously moistened, at the same time as there is an air gap between the upper part of the conveyor 6 and the water level 7. The membrane 11 is thus normally rinsed during half its turn, which is sufficient to maintain the moisture content. One skilled in the art will recognize that the wetting of the membrane 11 can also be arranged in other ways, such as e.g. by a jet of water moistening the membrane ll just before the sludge 8 is received.

The lower part of the housing 2 has two compartments separated by a partition 15. At the bottom of one compartment the water outlet 3 is arranged, while the sludge outlet 4 is arranged at the bottom of the other compartment. The partition wall 15 thus keeps separated water in the space above the water outlet 3, without the risk of it spilling over into the second compartment.

In the area of the end of the conveyor 6 where the sludge is discharged, a scraper 14 is arranged to scrape off any 528 residual material on the conveyor. In the example shown, the scraper 14 is arranged on the partition wall 15 between the two lower sections of the housing 1.

In one embodiment, the size of the water outlet 3 can be adjusted to keep water level 7 at a suitable height. This is done in an example with the help of switches that close or open the outlet 3 so that the water level 7 is between the permitted maximum and minimum level.

Thanks to the air gap between the water level 7 and the upper part of the conveyor 6, excess water will quickly fall out of the membrane 11 and into the water collection in the lower part of the housing 1.

In a practical example at a treatment plant, the membrane 11 has a cell size of approx. 1 μm while the metal fabric has a cell size of about 50 μm, which has been shown to work well. As an example, the metal fabric 10 may be made of stainless steel.

By varying the speed of the conveyor 6, via a suitable regulator (not shown), the degree of dewatering can be regulated. In a practical test, digestate sludge 8 with 2% TS was fed at 10,000 kg / h through the sludge inlet 2, which, by appropriate control of the conveyor speed, gave water at 9,000 kg / h at the water outlet 3 and sludge at 20% TS with 1 000 kg / h at the sludge outlet 4.

Claims (7)

10 15 20 25 30 åh F \ J f w kdïn / G3 QN -dq PAEENTKRAV A device for dewatering sludge (8), which comprises a semipermeable membrane (11) placed to receive the sludge (8), wherein an air gap is provided on the one (11) which does not receive the sludge (8) and means is arranged to moisten the membrane (11) with water before the sludge (8) is received, characterized in that the membrane side of the membrane (11) has several horizontal cell layers, with alternating (13). Device according to claim 1, characterized in that mem- (ll) Device according to claim 1, characterized in that memconvex cells (12) and concave cells of the branch are made of nylon fibers. the bran (11) forms part of a conveyor (6), that the membrane (11) is supported by a metal cloth (10) and / or that the metal cloth (10) and the membrane (11) are supported by a number of rollers (9 ) to form a trough-shaped transport path. Device according to claim 3, characterized in that the sludge (8) is digestate sludge from a sewage treatment plant and that the conveyor (6) is arranged in a housing (1) which has an inlet (2) for sludge, an outlet ( 3) for water and an outlet (4) for dewatered sludge. Device according to claim 4, characterized in that the lower part of the housing (1) has two compartments separated by a partition wall (15) located next to the end of the conveyor where the dewatered sludge is discharged and where the sludge outlet (4) is arranged at the bottom of the compartment receiving the dewatered sludge while the water outlet (3) is the bottom of the second compartment, over which second compartment the predominant part of the conveyor (6) is arranged. is arranged in Device according to claim 5, characterized in that a scraper (14) is arranged abutting against the conveyor (4), which scraper is arranged on the upper part of the partition wall (15) and / or that the water outlet (3) has an adjustable opening (fi N i 33 "23 fis ._, l wN] to regulate a water level (7) in one section of the lower part of the house (1). Device according to claim 6, characterized in that the lower part of the conveyor (6) is below the water level (7) in the housing (1) and that the air gap is arranged between the water level (7) and the upper part of the conveyor (6).