NL2014751B1 - Dewatering device and method for dewatering sludge-like material. - Google Patents

Abstract

The invention relates to a dewatering device for dewatering sludge-like material at the location of a dewatering location, the dewatering device comprising a bottom, as well as a basin wall surrounding a basin defined by the bottom and the basin wall. At least a part of the basin wall is water-permeable and coated with a semi-permeable membrane element, preferably a geotextile. The basin wall has, at least in plan view, a curved course at least along part of its circumference. The invention also relates to a method for dewatering sludge-like material.

Description

Brief indication: Dewatering device and method for dewatering sludge-like material.

DESCRIPTION

The present invention relates to a dewatering device and to a method for dewatering sludge-like material, in particular sludge or animal manure.

The dewatering of sludge-like material, for example of sludge removed from a water body, is known per se. To this end, use can be made of a dewatering device. NL 2010129 discloses a dewatering device for dewatering sludge. The sludge is pumped into a basin of the establishment. Water will come out of the sludge through the water-permeable filtration screen. Over time, a more or less dry mass of dewatered sludge, including any organic material, remains in the basin. The dewatered sludge can then be removed.

An object of the invention is to provide an improved, more robust dewatering device with more uses.

To this end, the present invention provides a dewatering device for dewatering sludge-like material at a dewatering location, the dewatering device comprising a bottom, as well as an at least substantially form-retaining basin wall that surrounds a basin defined by the bottom and the basin wall, wherein at least one part of the basin wall is permeable to water and coated with a semi-permeable membrane element, preferably a geotextile. According to the invention, the dewatering device is characterized in that the basin wall, at least in top view, has a curved course at least along a part of its circumference.

With the dewatering device, sludge-like material such as sludge or manure can be dewatered at the location of a dewatering location. The dewatering location herein comprises a bottom and a basin wall that surrounds a basin defined by the bottom and the basin wall for the sludge-like material to be drained. At least a portion of the basin wall is permeable to water and is coated with a semi-permeable membrane element such as preferably a geotextile. A more robust dewatering device is provided by the basin wall that is curved along at least a part of its circumference, wherein forces on the basin wall exerted by the sludge-like material can be absorbed more effectively. The semi-permeable membrane element thereby functions as a filtration cloth for the passage of liquid from the sludge and the retention of solid constituents from the sludge. The bottom preferably retains the sludge to be dehydrated in its entirety. At least a part of the basin wall has the semi-permeable membrane element, while any remaining part can stop the sludge to be dehydrated in its entirety or water can be impermeable.

The part of the basin wall with the curved course preferably extends over at least 120 degrees, more preferably over at least 180 degrees, from the circumference.

In a favorable preferred embodiment, the basin wall is free of corners, at least in top view. That is, the course of the direction of the tangent of the basin wall is continuous along the entire circumference of the basin wall.

In this context, it is advantageous if the basin wall has a curved course, at least in top view, along its entire circumference, and even more preferably, at least in top view, has a substantially circular course.

In the case of a substantially circular course, the basin wall has an inscribed circle and a circumscribed circle, the radius of the circumscribed circle preferably being in the range from a smallest radius to a largest radius, the smallest radius being the radius of the written circle and the largest radius is 110 percent, preferably 105 percent, of the radius of the inscribed circle. In the case of a circular gradient, the radius of the inscribed circle is the same as that of the circumscribed circle.

Preferably, the surface of the basin is in the range of 15 to 500 square meters. In case the basin wall has an at least substantially circular course, at least in top view, the radius thereof is preferably in the range of 2 to 15 meters.

The basin wall is most preferably coated on the inside, or the side facing the basin, with the membrane element.

In a particularly advantageous preferred embodiment, the basin wall is provided on a top side thereof with a rail which follows the basin wall at least along its water-permeable part thereof, preferably along the entire circumference of the basin wall. The dewatering device is preferably provided with a flushing device with a sprayer for spraying flushing liquid against the membrane element in operation and / or with a nozzle for forcing compressed air into operation under pressure against the membrane element, the flushing device preferably displaceable along the rail is provided with the flushing device in use during its movement along the rail spraying flushing liquid against the membrane element of the water-permeable part of the basin wall, or compressing air against the membrane element of the water-permeable part of the basin wall. As a result, the dewatering device can be used to a greater extent more effectively, since now there is the possibility, for example, after dewatering a batch of sludge-like material, and after removing at least a part of the dewatered sludge-like material from the basin, to rinse the membrane element and to be cleaned in such a way that it functions as effectively as possible when dewatering another batch of sludge-like material.

The rinsing device is also of particular use if, in operation of the dewatering device, a thin but compact layer of sludge-like material builds up against the membrane element during the dewatering of sludge-like material, depending on the type of sludge-like material, reduces water drainage through the membrane element there. By spraying with flushing liquid from the outside of the basin wall or spraying the membrane element with compressed air, that is, already during the dewatering of the sludge-like material, the surprising effect is achieved that this layer of sludge-like material is sprayed at least at the place where the membrane element is sprayed. sprayed, or both, as it were, disengages from the membrane element and / or breaks down, which speeds up draining of water at that location.

The use of such a flushing device is particularly favorable if the basin wall is free of corners, at least along the water-permeable part of the basin wall. A rail which follows the basin wall and along which the flushing device moves can hereby be realized particularly easily. In one embodiment the basin wall has a substantially circular course, the rail has a corresponding circular course, and the basin wall is preferably water-permeable with a semi-permeable membrane element along substantially its entire circumference.

Use of such a flushing device with a sprayer for spraying flushing liquid against the membrane element in operation and / or with a nozzle for forcing compressed air into operation under pressure against the membrane element, which flushing device is provided for displaceably along the basin wall, is also advantageous in dewatering devices according to the introduction, which comprise a bottom, as well as a basin wall that is at least substantially form-retaining, which surrounds a basin defined by the bottom and the basin wall, wherein at least a part of the basin wall is water-permeable and coated with a semi-permeable membrane element , preferably a geotextile.

In a particularly favorable preferred embodiment, the basin wall is built up from a number of separate, at least substantially form-retaining wall elements, which are mutually coupled, wherein at least a sub-number of the number of wall elements forms the water-permeable part of the basin wall. Transport of the dewatering device to a dewatering location can hereby be realized particularly easily. In one embodiment, the semi-permeable membrane element is provided as a part along the entire circumference of the basin wall. Alternatively, the membrane element is provided in several parts, wherein preferably each of the sub-number of wall elements is provided with a separate membrane element which connect to each other in the mutually coupled state of the wall elements, such as by mutual overlap at adjacent edges of the membrane element.

In a cost-effective preferred embodiment, the number of wall elements relates to identical curved wall elements.

It is advantageous here if each of the sub-number of the wall elements is designed as a grid element, wherein preferably all of the number of wall elements are water-permeable as a grid element coated with a semi-permeable membrane element, preferably a geotextile.

The semi-permeable membrane element extends most preferably to the bottom of the basin.

It is also favorable if the rail is formed by a concatenation of respective rail elements provided on the upper edge of each wall element with the number of wall elements.

The soil preferably already forms part of the dewatering location. The soil can thereby be any terrain, for example a meadow, a piece of grassland, or a partially asphalted terrain. To limit transport of sludge to be drained, the bottom is preferably located near the sludge-like material to be drained. The site can therefore be located near surface water, for example. The soil is thereby preferably highly water-permeable, although it is also conceivable that soil is naturally semi-permeable. By making use of the floor already present, only the wall elements need be provided, so that the dewatering device is relatively compact. Transport costs are therefore relatively low and the total costs of the dewatering device can therefore be relatively low.

In one embodiment the bottom is made up of a waterproof sealing foil, preferably from LDPE, which extends radially beyond the basin wall, on which sealing foil a drainage layer is applied, preferably from grass tiles or similar grid-shaped elements which are at least horizontally or parallel to the soil are water-permeable, which drainage layer preferably also extends radially beyond the basin wall, the basin wall resting on the drainage layer, wherein a semi-permeable filter cloth is preferably provided on the drainage layer, such as preferably from a geotextile, wherein on the drainage layer filter cloth is furthermore preferably provided with a further drainage layer, preferably of grass tiles which are water-permeable at least in the vertical direction.

It is furthermore advantageous here if the dewatering device comprises a circumferential support element outside the basin wall and at a distance from the bottom, such as a circumferential tube, the sealing foil being suspended outside the basin wall on the support element so as to form a circumferential gutter between the circumferential gutter. support element and the basin wall. The support element is preferably supported on the subsurface with supporting legs provided at mutual distances along the circumference of the basin wall, and is furthermore preferably connected to rods provided with rods provided at mutual distances along the circumference of the basin wall.

Such a bottom constructed from layers is also advantageously applicable to dewatering devices according to the introduction, which optionally also comprise the said bearing element.

It is favorable if the number of wall elements is mutually coupled by means of a bolt connection.

The water-permeable part of the basin wall is preferably a grid element. The number of wall elements are preferably each grid elements. A fence with a metal grid generally known in the construction industry, or a fence with a metal frame with a somewhat flexible mesh inside it can already meet the requirements.

The membrane element is preferably geotextile made of woven polypropylene.

The invention also relates to a method for dewatering sludge-like material at the location of a dewatering location, using a dewatering device according to the invention, the method comprising the steps of: - filling at least partly with the sludge-like material the basin; - draining liquid via the semi-permeable membrane element.

Advantages of the method are analogous to the above-mentioned advantages of the dewatering device according to the invention.

The method preferably comprises the further step of: - building up the basin wall by mutually coupling the number of wall elements so as to form the basin;

In a particularly favorable embodiment, the method comprises the further step of moving the flushing device along the basin wall, preferably along the rail, preferably automatically, while the flushing liquid is spraying against the membrane element of the water-permeable part of the basin wall and / or compressed air against the membrane element of the water-permeable part of the basin wall, preferably from the outside of the basin wall.

In operation of the dewatering device, depending on the type of sludge-like material, a thin but compact layer of sludge-like material can build up against the membrane element on the basin side of the membrane element when dewatering sludge-like material, thereby reducing the water discharge through the membrane element there. If the said rinsing step with rinsing liquid and / or compressed air is already carried out during the discharge of water via the semi-permeable membrane element, the surprising effect is achieved that this layer of sludge-like material is sprayed or sprayed at least at the place where the membrane element is sprayed or sprayed, as it actually comes loose from the membrane element and / or breaks down, which speeds up draining of water at that location. The flushing device can have several nozzles which are distributed in height direction along the basin wall, wherein, depending on the flow of water through the basin wall, the basin wall is sprayed at a desired height. The same applies to compressed air nozzles. A particularly effective dewatering process is obtained by this additional rinsing step. A method comprising an additional flushing step wherein the flushing device is moved along the basin wall while this flushing liquid sprays against the membrane element of the water-permeable part of the basin wall and / or forces compressed air against the membrane element of the water-permeable part of the basin wall, preferably from the outside of the basin wall, is also advantageously applicable to dewatering devices according to the introduction, wherein according to the method at least also the steps are carried out of at least partially filling the basin with the sludge-like material and discharging liquid via the semi-permeable membrane element .

In one embodiment the dewatering device comprises vibrating means for causing the basin wall to vibrate. If during operation of the device the method step is applied of temporarily vibrating the basin wall with the vibrating means, such as an electrically actuated vibrating actuator, the effect described above of loosening or breaking down the compact layer of sludge-like material also becomes. This is also applicable to dewatering devices according to the introduction.

In one embodiment the method comprises the additional step of: - removing at least a part of the dewatered sludge-like material from the basin, after and / or during the step of discharging liquid via the semi-permeable membrane element.

Subsequently, in a preferred embodiment of the method, the step is carried out of moving the flushing device along the rail, preferably automatically, while this flushing liquid is spraying against the membrane element of the water-permeable part of the basin wall. As a result, after the dewatering of a batch of sludge-like material, the membrane element can be rinsed clean again so that the semi-permeable nature of the membrane element can be utilized as optimally as possible in the dewatering of a subsequent batch of sludge-like material.

By incorporating the sludge-like material in the basin, the sludge-like material can be dewatered in a simple manner. The water in the sludge-like material will be able to flow out of the basin via the semi-permeable membrane element. The semi-permeable membrane element thereby stops the solid parts, such that the solid components remain in the sludge in the container.

By making use of parts already present at the dewatering location, it becomes possible to carry out the method relatively quickly and cheaply. In addition, it is relatively easy to set the desired capacity, by using wall elements with a larger or smaller size.

The invention will be explained below with reference to a figure description, with reference to the accompanying figures, in which:

FIG. 1 shows schematically and in three-dimensional view obliquely from above a preferred embodiment of a dewatering device according to the invention,

FIG. 2 shows diagrammatically and in three-dimensional representation obliquely from above a preferred embodiment of a component of a dewatering device according to the invention,

FIG. 3 shows a detail of figure 1, and

FIG. 4 schematically shows a cross section of a part of the dewatering device according to figure 1.

FIG. 1 schematically shows an embodiment of a dewatering device 1 according to the present invention. The dewatering device comprises a bottom 2 that is flat and on which a basin wall 4 is placed. The bottom 2 and basin wall 4 together define a basin 3 of the dewatering device 1. The basin wall 4 is made up of, at least in the present example 16, separate wall elements 6 and mutually coupled to a bolt connection. The wall elements 6 extend substantially perpendicularly from the bottom 2, upwards. The wall elements 6 are designed as a grid element, for example a fence generally known in the construction industry. The mesh width of the grid element increases as seen from bottom to top, as can be seen from figure 1. The strength of the wall elements 6 is therefore greater at the bottom than at the top, which is also desirable in view of the higher at the bottom exerted by the sludge-like material. busy. In the present example, all wall elements 6 are of identical design and are curved with a radius of curvature R of 5 meters. It is per se conceivable that, for example, on opposite sides of the basin wall, one or a few flat wall elements are interposed, although a substantially circular basin wall is preferred.

Each of the wall elements 6 is coated on the inside with a filter element in the form of a semi-permeable membrane element in the form of a piece of geotextile that completely covers the surface of each wall element. In figure 1, for the sake of clarity, only one wall element 6 is covered with a membrane element 8. It is also conceivable that the entire inside of the basin wall 4 is provided with one strip-shaped membrane element which thus extends along all wall elements and thus covers all wall elements . The semi-permeable membrane element is adapted to allow liquid to pass through, while at the same time retaining solid components from the sludge. At the top of the basin sludge-like material to be dehydrated can be supplied.

Figure 2 shows one separate, flat wall element 106 that can form part of a dewatering device according to the invention. With, for example, 16 such wall elements, an at least substantially circular basin can be formed. The wall element 106 is in the form of a fencing, grid-shaped, and is covered with a piece of geotextile 108 (partially shown). The piece of geotextile protrudes outside the wall element in the circumferential direction of the basin wall, so that when interconnecting wall elements the respective pieces of geotextile overlap each other with an overlap strip 109. At the bottom a flap 111 is also provided for realizing an overlap with the bottom . The overlap provides a good seal and a good filtering effect. The attachment between the two semi-permeable membranes 108 can be done with a semi-releasable attachment, and preferably with a so-called nylon delphinium, or other equivalent attachment.

FIG. 3 shows a detail of the dewatering device 1 according to figure 1. More specifically, a separate wall element 6 is shown, at the location of which a flushing device 20 is present. the flushing device 20 is displaceable along the entire circumference of the basin 3, or along the basin wall 4. For this purpose, an upper edge of each of the wall elements is formed as a rail element 21. When the wall elements are coupled to each other, the rail elements 21 form a mutually connected rail which extends endlessly around the circumference of the basin.

The flushing device 20 has a frame 22 comprising wheels 23 with which the flushing device 20 can roll over the rail 21. The flushing device can be moved manually, or can be provided with a drive such as an electric drive motor connected to at least one of the wheels 23 or hydromotor, wherein the hydromotor is preferably driven by the rinsing liquid itself, under pressure, for automatically moving the rinsing device 20 along the rail. The frame 22 comprises a frame part 24. extending downwards on the outside of the basin wall. , at least in the present example, five nozzles are provided, each of which faces the basin wall to spray the basin wall 4 from the outside with a flushing liquid such as water during operation. Because the basin wall 4 is composed of grid-shaped wall elements 6, each of which is lined on the inside with the membrane element in the form of a geotextile, the nozzles 25 spray the geotextile directly and clean the geotextile, for example after a batch of sludge has been dewatered and removed from the sludge. basin is drained as by scooping. The nozzles 25 are provided such that they spray the basin wall over an important part of its height.

The nozzles 25 are fed by a supply tube 26 connected to the nozzles. The supply tube 26 is closed at a lower free end but is open at an upper free end so that a supply member such as a supply hose for flushing liquid can be connected thereto. The dewatering device 1 may further comprise a water pump for forcing flushing liquid to the nozzles.

Figure 3 also shows flanges 30 at the location of longitudinal edges of the wall element 6. The flanges are provided with a number of bolt holes so that two adjacent wall elements 6 can be robustly interconnected with a bolt connection. Another connection method, whether or not in combination with a bolt connection, such as for instance a hook connection, is also possible within the scope of the invention. The mentioned are releasable connections. An inextricable connection, such as, for example, a welded connection, is also possible within the scope of the invention.

Figure 4 is a sectional view and highly diagrammatic view of a wall element 6. The membrane element provided thereon is not shown in Figure 4. The bottom 2 of the dewatering device is a combination provided on a substrate 40 of, as bottom layer, a water-sealing foil 41 of LDPE with a thickness of about 0.5 to 1.5 mm. This foil 41 extends radially until beyond the basin wall 4, or beyond the basin. A drainage layer 42 of plastic grass tiles is provided on top of the foil, such as with a thickness of about 40 mm. The drainage layer 42 extends radially below the basin wall 4. the drainage layer is configured to be water-permeable at least in the horizontal direction or parallel to the bottom. On top of the drainage layer 42 a semi-permeable membrane element 43 such as a filter cloth such as, for example, geotextile is provided. In addition, a further drainage layer 44 is provided to protect the membrane element 43, such as when removing dewatered sludge-like material from the basin. The further drainage layer 44 is constructed from plastic grass tiles which are water-permeable at least in the vertical direction. In operation, therefore, water from the sludge-like material can flow downwards through layers 44 and 43 and flow through layer 42 horizontally underneath the basin wall through the basin. Outside the basin a circumferential support element is provided in the form of a circumferential tube 45. The tube 45 is supported with a number of support legs 46 and fixed to the basin wall with a number of rods 47 (both not shown in Figure 1). As a result, between the outside of the basin wall 4 and the tube 45, through the watertight foil 41, a gutter 48 is formed in which water flows out through the water-permeable part of the basin wall 4 and below the basin wall 4. This water can then be drained further, by means not shown in the figures.

It will be apparent to those skilled in the art that the invention has been explained above with reference to a few preferred exemplary embodiments thereof. However, the invention is not limited to these exemplary embodiments. Various equivalent embodiments are conceivable within the scope of the present invention, which possibly fall within the requested scope of the appended claims.

Claims (19)

A dewatering device (1) for dewatering sludge-like material at the location of a dewatering location, the dewatering device (1) comprising a bottom (2), as well as a basin wall (4) which is at least substantially form-retaining and which particular basin (3), wherein at least a part of the basin wall is water-permeable and coated with a semi-permeable membrane element (8), preferably a geotextile, characterized in that the basin wall (4), at least in top view, has a curved course at least along part of its circumference. Dewatering device according to claim 1, wherein the part of the basin wall (4) with the curved course extends over at least 120 degrees, preferably over at least 180 degrees, of the circumference. Dewatering device according to claim 1 or 2, wherein the basin wall (4) is free of corners, at least in top view. Dewatering device according to claim 3, wherein the basin wall (4), at least in top view, has a curved course along its entire circumference. Dewatering device according to claim 4, wherein the basin wall (4) has, at least in top view, a substantially circular course. Dewatering device according to claim 5, wherein the basin wall (4) has an inscribed circle and a circumscribed circle, wherein the radius of the circumscribed circle is in the range from a smallest radius to a largest radius, the smallest radius being the radius of the inscribed circle and the largest radius is 110 percent, preferably 105 percent, of the radius of the inscribed circle. Dewatering device according to any of the preceding claims, wherein the basin wall (4) is provided on a top side thereof with a rail (21) which follows the basin wall at least along its water-permeable part thereof, wherein the dewatering device is further provided with a flushing device (20) with a sprayer (25) for spraying flushing liquid against the membrane element in operation, wherein the flushing device is provided so as to be movable along the rail such that the flushing device in use during its movement along the rail flushing liquid against the membrane element of the water-permeable part of the basin wall is spraying. 8. Dewatering device according to any of the preceding claims, wherein the basin wall is made up of a number of separate at least substantially form-retaining wall elements (6) which are mutually coupled, at least a sub-number of the number of wall elements comprising the water-permeable part of the basin wall. Dewatering device according to claim 8 and according to claim 5 or a claim dependent thereon, wherein the number of wall elements (6) relates to identical curved wall elements. 10. Dewatering device as claimed in claim 8 or 9, wherein each of the sub-number of the wall elements is designed as a grid element, wherein preferably all of the number of wall elements are water-permeable as a grid element coated with a semi-permeable membrane element, preferably a geotextile. 11. Dewatering device according to claim 7 and according to claim 8, 9 or 10, wherein the rail is formed by a concatenation of respective rail elements provided on the upper edge of each wall element with the number of wall elements. A dewatering device according to any of the preceding claims, wherein the bottom is composed of a water-tight sealing foil (41) extending radially beyond the basin wall, on which sealing foil a drainage layer (42) is also arranged radially beyond the basin wall wherein the basin wall rests on the drainage layer, wherein a semi-permeable membrane element (43) such as a filter cloth is provided on the drainage layer, a further drainage layer (44) being provided on the membrane element. A dewatering device according to claim 12, further comprising a circumferential support element (45) outside the basin wall and at a distance from the bottom, the sealing foil (41) being suspended outside the basin wall on the support element so as to form a circumferential gutter (48) ) between the circumferential support element and the basin wall. A dewatering device according to claim 8 or a claim dependent thereon, wherein the number of wall elements is mutually coupled by means of a bolt connection. Dewatering device according to any of the preceding claims, wherein the membrane element geotextile is made from woven polypropylene. A method for dewatering sludge-like material at a dewatering site, using a dewatering device (1) according to any of the preceding claims, the method comprising the steps of: - at least partially with the sludge-like material filling the basin; - draining liquid via the semi-permeable membrane element. A method according to claim 16 and claim 8 or a claim dependent thereon, further comprising the step of - building up the basin wall by mutually coupling the number of wall elements so as to form the basin; A method according to claim 16 or 17, comprising the additional step of: - moving the flushing device along the rail while this flushing liquid is spraying against the membrane element of the water-permeable part of the basin wall. A method according to claim 16, 17 or 18, comprising the additional step of: - removing at least a part of the dewatered sludge-like material from the basin, after and / or during the step of discharging via the semi-permeable membrane element of liquid.