Patent Grant
7943051
This invention relates to liquid-solid separation, and more particularly to dewatering thin slurry.
There are circumstances where disposing of a slurry comprised of water and debris requires a separation of the liquid and solid phases. Such a circumstance occurs when vehicles used in dirty operations, such as construction or fire-fighting, and particularly in operations where there is an exposure to contaminants, are washed in a post-service cleanup. Commonly, the collected debris is comprised of mud, but may also comprise a suspended element which is harmful to life or to the environment. Accordingly, the solids in the slurry must be separated for safe disposal. Even if hazard is not an issue, it would be desirable for cost purposes to avoid transporting the water weight to a disposal site.
The cleaning process may occur over a mat or a containment system that collects the runoff water and debris. The slurry is then pumped from the mat to a settling tank to allow separation by gravity. The sludge that precipitates is then shoveled into sand bags, which are loaded onto pallets and evacuated by fork lift and truck transport to a land fill. The process, wherein bags of up to fifty pounds are loaded and lifted by hand, is labor intensive and prone to back injuries.
When the washing is done in a backwoods location, for example, both access and expense are involved in bringing a rough terrain fork lift to the location.
A portable settling tank offers an advantage in such a case because transferring the sludge in sand bags can be avoided. The portable tank would be moved directly to the land fill site after a dewatering process on location. U.S. Pat. No. 4,929,353 to Harris and U.S. Pat. No. 5,595,654 to Caughman both disclose portable dewatering tanks. In both Harris and Caughman, a filter medium is supported by a structure internal to the tank which is designed to create a cavity for drainage around the structure. Dewatering involves draining the filtrate from the cavity. When transported to the disposal site, the sludge must be removed from the structure and cleaned along with the tank. In the case of Caughman, the filter medium must also be cleaned.
The present invention is directed to an improvement in the art of portable settling tanks, wherein a thin slurry may be efficiently separated into liquid and solid components, and the resulting residue removed by dumping the contents of the tank in a manner where no cleaning is required.
It is accordingly an object of the present invention to substantially avoid labor in the disposal of the end products of dewatering a thin slurry.
It is a further object of the present invention to provide an apparatus for dewatering a thin slurry which substantially avoids any terminal cleanup.
It is a further object of the present invention to accomplish dewatering in the same container in which the residue of dewatering will be transported for disposal.
It is a further object of the present invention to provide a disposable liner for a portable container to shield the container from soil and contamination.
It is a further object of the present invention to provide a disposable porous percolation field for the filtrate product of dewatering.
It is a further object of the present invention to provide a disposable filtration medium.
It is a further object of the present invention to provide a method of dewatering which allows the cyclical addition of slurry to amass the residue.
It is a further object of the present invention to provide a method of dewatering which substantially avoids clogging the filtration medium.
These objects, and others to become hereinafter apparent, are embodied in a settling tank for dewatering slurry, comprising a portable open-top container having a bottom and four sides, a disposable watertight liner covering the bottom and the four sides, a layer of disposable coarse granular material with interstitial space therein covering the bottom of the watertight liner, a disposable filter cloth covering the coarse granular material and the liner, and a drain port through the liner into the interstitial space. The slurry containing particulate is pumped into the container through the open top, the action of settlement then separates relatively clean water from settled particulate, and the relatively clean water is removed through the open top by pumping to make room for more slurry until a preferred buildup of settled particulate is achieved. The settled particulate is ultimately dewatered by pumping out the filtrate, or allowing it to drain by gravity means, through the drain port.
In a particularly preferred embodiment, the container is a roll-on container. In another particularly preferred embodiment, the coarse granular material is river rock. In still another particularly preferred embodiment, the preferred buildup of settled material is is signaled by slurry appearing in the relatively clean water effluent.
An alternate embodiment provides a method of dewatering slurry. The method comprises the steps of providing a portable open-top container having a bottom and four sides, covering the bottom and four sides with a disposable watertight liner, covering the bottom of the liner with coarse granular material having interstitial space therein, layering a disposable filter cloth over the coarse granular material and the liner, and providing a drain port through the liner into the interstitial space. The method further comprises pumping slurry containing particulate into one end of the container through the open top, whereby settlement produces relatively clean water at the top of the container and settled particulate at the bottom, and filtering through the filter cloth produces a filtrate in the interstitial space. The method further comprises using a means for reducing water in the slurry while substantially avoiding clogging of the filter cloth, whereby room is provided for the cyclical addition of more slurry. The final steps include draining any remaining separated water through the drain port, transporting the container and its residual contents to a disposal site, and discarding the liner, coarse granular material, filter cloth and residue by dumping the contents to leave the container in its original state.
In a particular alternate embodiment, the means for reducing water while substantially avoiding clogging comprises pumping the relatively clean water off the top at the opposite end in cycle with the addition of slurry until a predetermined buildup of settled particulate has been achieved. The means further comprises avoiding the application of suction in the drainage of the filtrate, thereby avoiding packing of the settled particulate is against the filter cloth, other than by means of gravity alone.
As this is not intended to be an exhaustive recitation, other embodiments may be learned from practicing the invention or may otherwise become apparent to those skilled in the art.
Various other objects, features and attendant advantages of the present invention will become fully appreciated as the same becomes better understood through the accompanying drawings, in which like reference characters designate the same or similar parts throughout the several views, and wherein:
The cross-section view of
Referring to
The watertight liner 3 is draped over the bottom 41 and four sides 42 of the open-top container 40 to shield the interior surfaces of the container. The watertight liner 3 may lap over the top edges of the container, or otherwise be fixed thereto, so that the liner cannot be caused to expose the interior surfaces. The watertight liner 3 is preferably a film with a gauge of 5-10 mils. While any waterproof film is suitable, a preferred choice would be one of bio-degradable or recycled resin composition, in order of preference. The preferred resins are those comprising polyethylene, polypropylene, or a mixture thereof, or polyolefin, which may be a blend of those resins.
A layer of coarse granular material 10 is laid over the bottom of the watertight liner 3 to effectively provide a reservoir for drainage by means of interstitial space 14. Interstitial space 14 is comprised of all space within the boundaries of the layer which is not filled with the material of the coarse granular material 10. Preferably, the layer is 6-12 inches in depth, but may be any depth consistent with the volume of drainage desired. The coarser the consistency, the larger the interstitial space 14 for a given volume of the layer; consequently, therefore, coarsening provides a means for optimization. The coarse granular material 10 may be anything disposable which has the property of maintaining is interstitial space therein, as, for example, pine cones, or discarded bricks arrayed in a jumble. It may also be discarded old pallets, or broken up construction materials, although not granular in the same sense. In the preferred embodiment, the coarse granular material 10 is stones 11, and in a particularly preferred embodiment, the stones are river rock 12.
The drain port 10 vents the watertight liner 3 and ducts into the interstitial space 14 to drain said space. In the preferred embodiment, an intermittent pump provides the means for draining. The intermittent pump should be of a peristaltic, or otherwise of a self-priming, type because the pump may outstrip the flow of drainage. In an alternate embodiment, shown in
The disposable filter cloth 20 is draped over the watertight liner 3 and the layer of coarse granular material 10. The filter cloth 20 may lap over the top edges of the container, or otherwise be fixed proximate thereto, so that the filter cloth remains at all times above the liquid surface level. The filter cloth 20 is a woven or nonwoven textile having a sieve matched to the tiniest allowable particle in the filtrate. In the preferred embodiment, the filter cloth 20 is a geotextile cloth, or equivalent, fabricated with polyester or polypropylene yarns, or, otherwise laid up with polypropylene fibers. Such a material is sometimes used in road construction or for environmental stabilization. The preferred sieve size is in the 100-200 micron range, and a particular preference requires 150 microns or less to trap seeds.
The filter cloth 20 is designed to substantially trap the particulate 32 and separate it from the filtrate 22 by filtering action. This filtering action may or may not be assisted by pump suction through the drain port 2. Applying pump suction before the particulate 32 has had a chance to naturally settle, however, might clog the filter cloth 20 prematurely by driving particles into the pores of the cloth. In a similar way, slurry maintained at full tank capacity, or in other words, with a full “head”, would hydraulically pressurize the sediment layer on the bottom. A means for reducing water in the slurry while substantially avoiding clogging of the filter cloth 50 (
It is recognized that the stratification of particulate 32 within the pool of slurry 30 is in the form of a gradient, rather than discrete in the form of layers. That is to say, there is a distribution of particulate 32 decreasing from bottom to top over any relatively short period of time, such that a “clean” top layer is only an approximation. It is further recognized that the addition of more slurry 30 will inevitably disturb this distribution. The preferred means for reducing water 50, therefore, further comprises pumping in slurry at one end of the open-top container 40 and pumping out clean water at the opposite end. The preferred means still further comprises locating the distal end of the inlet port 5 at or near the top of the bottom settlement and the distal end of the outlet port 6 at or near the top of the clean water layer. As the bottom settlement collects over time and rises in level, the distribution will cause more and more of the particulate 32 to remain present in the clean water layer. When a recognizable amount of particulate is pumped out with the clean water, it is either a signal that the current pumping cycle is excessive; or, otherwise, that the preferred buildup of settled particulate 33 has been reached. The latter will be hallmarked by shorter and shorter pumping cycles. An amount of particulate 32 in the clean water 31 which is recognizable might be that is amount clogging a filter to the pump, for example. When the preferred buildup of settled particulate 33 has been reached, the pumping of filtrate 22 may proceed unrestricted until all water is substantially removed and an essentially dry residue remains.
It is to be understood that the invention is not limited in its application to the details of construction and to the arrangements of the components set forth in the preceding description or illustrated in the drawings. The means for reducing water 50 might be carried out by evaporation in place of pumping clean water, for example. Also, it is to be understood that the phraseology and terminology employed herein are for the purpose of the description and should not be regarded as limiting.
This application claims priority to Provisional Application 61/153,501, filed Feb. 18, 2009, which is incorporated herein by reference.
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