Organic slurry storage basin cover

A cover assembly for an organic waste lagoon basin and a method of making and deploying such a cover assembly. A cover includes connected cover panels or sections. In one form of the invention the panels are comprised of a single layer of geotextile fabric. In another form of the invention the panels are comprised of interconnected strata including a sacrificial layer which faces the sun and protects the cover from ultraviolet light degradation; a foam layer that floats the cover; and a geotextile fabric layer. The geotextile fabric is porous and suppresses the release of malodorous gases from the lagoon basin. The cover can be constructed and deployed by laying out cover panels in fanfold fashion along a side of the basin; connecting adjacent edges of the panels; attaching flotation to the free edge of the top panel; and using deployment lines and a mandrel to move the cover across the filled basin.

BACKGROUND OF THE INVENTION

Malodorous emissions from open organic slurry storage structures are a nuisance for nearby receptors. Large scale livestock facilities and subsequent malodorous gas emissions therefrom have become a source of national controversy.

Many methods have been tried to control malodorous emissions on open organic slurry storage basins: impervious covers with and without gas collection systems, bioaugmentation, chemical additives, enzymes and full and partial aerobic treatment systems. Impervious cover systems are quite costly and gas collection systems require significant initial capital investment as well as ongoing maintenance expense. Bioaugmentation, chemical additives and enzymes have not delivered consistent odor control and usually require significant ongoing labor and maintenance costs in addition to product costs. Aerobic methods work most convincingly, but excessive cost has prevented widespread acceptance of aeration as the preferred method of odor control. Floating biomats of straw provide partial aeration, have performed well and are reasonably economical. But it is difficult to place and maintain a solid straw cover on areas greater than two hundred feet wide. They also require regular maintenance to cover an increasing slurry storage surface area as sloped earthen basins fill, and to fill holes that appear as straw sinks to the bottom of the basin. Crossover piping and recycle pumps and plumbing have been clogged with sunken straw, potentially compromising basin capacity and requiring additional manpower to periodically unclog problem appurtenances. Sinking straw also increases organic loading in the basin, potentially compromising design storage capacity.

SUMMARY OF THE INVENTION

The invention relates to a cover system for an organic waste storage lagoon, as well as a method for construction of a cover and a method of deploying it over an at least partially filled organic waste storage lagoon. A cover is fabricated from a geotextile material that can be a polypropylene fiber, non-woven, needle punched fabric stabilized to resist degradation due to ultraviolet light exposure. The cover can be constructed from a plurality of panels of geotextile material that are connected edgewise as they are laid out in fanfold fashion along an edge of a lagoon basin. The cover system can include deployment ropes attached to the cover having a length sufficient to span the basin and engage a pulley system to pull the cover across the surface of material in the basin. Tether lines are attached to the cover and are connectable to anchoring structure along side the basin in order to secure the floating cover in place on the surface of material contained in the lagoon basin. The cover is effective to reduce malodorous gas emissions by 60% to 90%. The cover fabric is porous and it restricts the release of gas to a volume regulated by this porosity. Vapor pressure under the cover causes small areas of the cover to inflate and rise from the surface of the organic slurry in a low profile manner which creates a humid, aerobic environment along the unsubmerged surface of the cover. The anaerobic zone on the underside of the cover provides a substrate to which anaerobic bacteria attach and break down malodorous gases passing through the cover to the atmosphere.

An embodiment of the cover system includes a multiple strata cover. A top stratum is a sacrificial layer to shield the lower strata from ultraviolet light damage due to sun exposure. Lower strata include a non-woven, geotextile fabric layer and a flotation foam layer. The foam layer is comprised of foam strips that can either be placed on the bottom or sandwiched between the other two strata. The three strata are needle-punched together, using fiber stands from both the non-woven and sacrificial strata to bind all strata together.

DESCRIPTION OF PREFERRED EMBODIMENTS

A lagoon basin cover system according to the invention has a cover that is fabricated on site from geotextile material which is typically a polypropylene fiber, non-woven, needle punched fabric that is stabilized to resist degradation due to ultraviolet light exposure. This is typically a felt-like material that has a specific gravity less than 1 and, therefore, floats like a sponge on water. It can stretch half of its original length, has a grab tensile strength of 200 lbs. or more, weighs 8 oz/yd or more, has an apparent opening size equal to a 100 U.S. Sieve, and has a permitivity of 1.5 gal./min./ft2/sec or less. Stock rolls of geotextile material are fabricated into a single cover approximately the size of the top inside dimensions of the open storage structure.

A basin to be covered is evaluated to select the most efficient side of the basin upon which to build the cover. A berm is selected which will preferably be along the longest edge if the basin is a rectangle, the longest edge adjacent to the right angle if the basin is a right triangle, along the hypotenuse if an obtuse triangle, along either long edge of an isosceles triangle, and along the longest edge of a polygon. A circular or oblong basin cover will be fabricated parallel to the longest distance across the surface area of the basin.

A cover is constructed by successively laying out panels of geotextile material or fabric and fastening adjacent edges. A first panel of geotextile fabric is rolled out along the berm selected for fabrication. A second panel of geotextile is rolled out on top of the first. The fabric is laid out in fanfold fashion. One edge of the under panel of geotextile is rolled back to overlap the edge of the next panel by approximately three inches. A seaming process described below can be employed to join the two panels of geotextile fabric together. Another panel of geotextile is then rolled out on top of the top panel of seamed geotextile. The unseamed edge of the panel of geotextile under the top panel is rolled back to overlap the top panel of geotextile by approximately three inches. This process will continue until the last panel of geotextile necessary to cover the inside top surface area dimensions of the basin has been seamed to make a one-piece cover. Individual geotextile panel lengths are cut to the length necessary and/or are shifted along the length of the panel beneath it to create the desired shape coverage of surface area.

Referring toFIG. 1, there is shown a lagoon basin10in top plan view that is generally rectangular in shape. A cover14has a cover base15that has been constructed on site along a long berm12. Cover14is constructed of multiple interconnected panels of geotextile fabric of the type described above. The panels are assembled in fanfold relationship as shown in FIG.2.

FIG. 1Ashows the interconnection of two adjacent panels16,18of cover14. The edge of the lower panel16is overlapped the edge of the upper panel18. A heat seaming device20is used to connect adjacent edges. Seaming is best accomplished using heat to fuse overlapping seams together, but may also be accomplished with a sewing machine using an ultraviolet light inhibiting thread, indicated at17in FIG.1A.

As shown inFIG. 2, the unseamed edge of the last or top panel of the cover is wrapped around floatation and tacked together using a hot air gun to lightly fuse the adjoined geotextile material together. This is done to create a leading edge that will float over the surface of material located in the basin as the cover is pulled into position across the basin. Deployment ropes or lines are attached to the floating leading edge of the cover. These deployment lines are stretched across the basin to the opposite berm. FIG.2shows a float tube22connected to the top or leading edge24of the cover14. The leading edge24is wrapped around the float tube22and secured at spot weld points26. A plurality of deployment lines28are connected at one end to the leading edge24as by being connected to float tube22.

FIG. 3shows deployment lines28spanning the basin10to the opposite berm30preparatory to deployment of cover14across the lagoon. As shown inFIG. 3A, posts32with flange plates are pressed into the middle of the top flat area of the berm30. The posts32are approximately equal-distant to each other. Each post has an attached pulley36connected to a mounting plate34. Posts32are aligned with attachment points of the deployment lines28to the float tube22. The deployment lines28are threaded through pulleys36and trained to a central point where a single mandrel40is located. The cover is deployed using the single segmented mandrel40to which the deployment lines28are attached. The mandrel is rotated to wind the deployment lines onto the mandrel. This pulls the cover base15squarely across the basin as the fan-folded cover on the berm unfolds to cover the surface area.

FIG. 4shows the cover of the invention installed on the lagoon basin. Anchors42are installed around the perimeter of the basin. Tethers44connect the anchors to the cover. A typical spacing between anchors can be twenty to thirty feet. The anchors can be traditional steel fence posts as shown inFIG. 4A, set back from the berm so as not to impair the integrity of a compacted clay liner. As shown inFIGS. 4 and 4A, tether44extends from the cover14to an anchor42. The tether44is connected to the cover in such a fashion as not to puncture the geotextile material. An edge section of the cover14is wrapped around a ball45(FIG. 4B) to provide a neck to tie the tether44. Another form of anchor comprised as a ground anchor is shown inFIG. 4C, having a lower end buried in the ground set back sufficiently from the berm so as not to damage the basin liner.

FIG. 5shows an alternate form of tethering in high wind prone geography. A wide margin of the cover is placed in a trench with a vertical side wall that is prepared around the perimeter of the basin above the operational high water line, typically a distance indicated as “A” inFIG. 5of about two and one-half feet from the edge. The trench is back filled with fill material50after the margin of the cover has been placed in the open trench. The margin of the cover is buried at a depth sufficient to withstand weather related stress.

Once in place, the cover suppresses the release of malodorous gases in several ways: First, the cover fabric is porous and it restricts the release of gas to a volume regulated by this porosity. Second, vapor pressure under the cover causes small areas of the cover to inflate and rise from the surface of the organic slurry in a low profile manner. Under observation, the cover appears to develop sand dune-like ripples. These elevated areas create a humid, aerobic environment along the unsubmerged surface of the cover. The presence of oxygen enables endemic facultative and/or aerobic bacteria to exist and break down malodorous gases passing through the cover to the atmosphere. Of particular note is significant nitrification/denitrification stimulated in this environment. Third, the anaerobic zone on the underside of the cover provides a substrate to which anaerobic bacteria attach and break down malodorous gases passing through the cover to the atmosphere. Fourth, the thin layer of geotextile material forms a barrier to mass transfer of gas, especially air-phase limited gases, based on two-film theory. This provides especially effective reduction in the transfer of short chain carbon ring volatile organic compounds through the cover to the atmosphere. Reduced disruption of the equilibrium of water-phase limited gases improves the retention time and subsequently improves reduction and release of these gases. The result is effective odor control.

The physical barrier of the cover plays an important metering function. Large volumes of malodorous gases are normally stripped from open structures due to agitation caused by wind, wave action or pummeling rainfall. The basin cover prevents stripping of gases and the porosity of the fabric helps to meter malodorous gas through the biofilm environment ubiquitous in and under the cover.

The cover can remain in place year around once in position and does not require regular inspection or maintenance. The geotextile fabric has superior elongation properties that allow it to accommodate freeze-thaw without damage. If the storage structure is emptied periodically, the cover may be loosened and pulled back during agitation and pump-out of stored organic slurry, then returned to the proper position.

FIGS. 6 through 8show a further embodiment of a basin cover according to the invention. Ultraviolet light degradation is a major limitation on the useful life of a basin cover including a basin cover constructed of a geotextile fabric as described above. In addition, while the geotextile fabric cover floats on the material contained in the basin, eventually the flotation may be compromised by sedimentation, struvite crystallization on the underside of the cover, reduced gas pressure, or any combination of these factors. The embodiment of the invention shown inFIGS. 6 through 8addresses these factors.

FIG. 6is a view similar to that ofFIG. 4but showing only a corner view of a cover system having a cover indicated generally at54covering a lagoon basin55at least partially surrounded by a berm56. Cover54is held in position by tether lines59as previously described.

Cover54is comprised of several strata including first, second and third layers. As shown inFIGS. 6 and 7, cover54includes a first or top layer60. Top layer60is a sacrificial layer that is exposed to the ultraviolet light from the sun and protects the layers beneath it from ultraviolet light degradation. Top layer60can be a porous material such as a geotextile material.

In the embodiment shown inFIGS. 6 and 7, a second layer or intermediate stratum is comprised as a flotation foam layer61. Foam layer61can be formed of parallel, spaced apart foam strips62. Strips62are constructed of a closed or open cell foam and impart a significant amount of floatation to the cover. As one example of the distribution of the foam strips, the strips can be 18 inches in width and spaced apart from one another by a distance of 24 inches.

The third stratum or layer is a layer64of non-woven polypropylene fabric or geotextile fabric as previously described. The third stratum interfaces with the foam layer61and interfaces with the sacrificial layer60at the spaces between foam strips62. The three stratum are connected by suitable means. In the example shown, the stratum are connected by a needle punching procedure. Needle punching intertwines fibers of the sacrificial stratum and the geotextile stratum to connect them.FIG. 7shows intertwined fiber strands68connecting the various stratum.

The sacrificial layer60significantly extends the useful life of the cover54. It does this by intercepting or blocking the destructive ultra violet light waves that would otherwise impinge upon the surface of the geotextile layer. Flotation provided by the floatation layer will decrease maintenance procedures on the cover.

A modification of the cover ofFIGS. 6 and 7is shown in FIG.8. The cover indicated at68inFIG. 8differs from that shown inFIGS. 6 and 7through interchanging of positions of the foam layer and geotextile layer. The cover68has a top layer or sacrificial stratum69. A second stratum is comprised as a layer of non-woven polypropylene fabric or geotextile material. A third stratum is a foam layer consisting of an array of foam strips arranged in parallel spaced-apart relationship. The stratum are connected by intertwined fabric fibers indicated at73resulting from a needle punching procedure. The foam layer provides flotation to the cover. The sacrificial stratum69significantly increases the life of the cover.

Cover54can be fabricated on-site as earlier described. The panels are laid out in fanfold fashion, with the sacrificial layers of adjacent panels alternately facing toward and away from the sacrificial layer of the next panel to assure that the sacrificial layers will be on top when the cover is deployed over the basin.

While certain embodiments of the invention have been shown and described, it will be apparent to those skilled in the art that deviations can be had from the embodiments shown without departing from the scope and spirit of the attached claims.