This invention relates to a system and method for capturing particles in runoff water from sites undergoing grading, landscaping, mining maintenance, logging, road building, land fills, utility and building construction, and other types of soil and environmental disturbances and for controlling erosion at such sites. The erosion control method of the invention is also useful for controlling flash flooding in flood prone areas, in areas subject to hazardous fires, in areas requiring industrial waste management and in containing environmental spills and nuclear wastes. The invention particularly relates to a system and method employing filters, settling, and polymeric removal of solids and suspended particles in the water run-on and runoff.
In the development of subdivisions and shopping centers, in urban expansion, and in road and highway construction, huge quantities of earth often must be either removed or disturbed leaving large areas of exposed land without any cover or means to prevent erosion. Not only do good environmental practices require erosion control but so do many local, state, and federal laws and regulations.
In addition to requiring control of the quantity and flow of water from sites being developed, the quality of the water is also subject to regulatory requirements that grow more stringent each year. These stringent storm water regulations require more than conventional silt fencing products and straw bales. The Clean Water Act is changing the face of erosion control devices. Noncompliance with the National Pollutions Discharge Elimination System, Phase II Storm Water Regulations, implemented in 2005, is subject to administrative orders, civil actions, and/or criminal prosecutions on federal, state, county and municipal government levels. All states review their erosion and sediment control manuals to reflect new information on best management practices, and many are requiring that erosion and sediment control practices meet a minimum performance standard. Most of the prior products do not provide compliance with the new act. As examples of a few of the many prior art processes and products for erosion control reference is made to U.S. Patent Application Publication no. 2004/0005198A1 and no. 2004/0133176A1.
Accordingly, an important object of the present invention is to provide an erosion control and water clarification system and method that exceed the new standards for storm water run-off.
Another object of the present invention is to provide compliant erosion control and water clarification and filtration systems that can be quickly installed and removed, require limited site preparation or staking, and are low maintenance during and after installation, and result in improved water flow.
Another object of the present invention is to provide compliant erosion control and water clarification products that are easily configured to the landscape, contour, or lay out of the site and conform effectively to the soil, sand, rock, and paved surfaces at the site to provide superior soil confinement with minimal land disturbing activity. However, the invention may also be used where there has been no land disturbance and it is desirable to control surface water flow.
Still another object of the present invention is to provide an effective erosion control method and means that can be readily used in a wide variety of applications.
The above objectives are accomplished according to the present invention which removes unwanted contaminants from run-off water and in one aspect sequentially employs the steps of settling, filtering, and agglomerating particulate matter in run-off water. In one aspect this is accomplished by providing an erosion control system comprising a plurality of elongated, closed filter bags constructed from a filtration fabric. The bags act as a dam to pool water for settling and, as water seeps through the bags, the bags also act as a filter to remove soil particles. A polymeric material is preferably disposed within the filter bag for agglomerating colloidally suspended particles in water passing through the bag wall from the dammed up pool whereby the agglomerated particles settle within the filter bag and remain.
In another aspect, after passing through a filter bag the water encounters a skirt or apron of filter material that is also impregnated with an agglomerating polymer to further group suspended particles together so that they will settle out. The skirt is positioned down slope from the bag and may be attached to the bag for stable positioning as the terrain dictates.
In yet another aspect the present invention employs a polymer system that includes a special formulation of a blended water-soluble anionic polyacrylamide dry powder product referred to hereinafter as “PAM” that is used to minimize soil erosion caused by water and wind. There are other flocculants or agglomeration promoters that are known and have been used in water treatment for a long number of years. Alum, gypsum and chitosan have been used but PAM has been found especially useful in erosion control. PAM decreases soil sealing by binding soil particles, especially clays, to hold them on site. In addition, these types of products may also be used as a water treatment additive to remove suspended particles from runoff. This system is designed as a more effective replacement of prior art velocity dissipating devices such as the conventional siltation fence product, baffle units, and other tube type products currently in use today.
Water clarity is achieved primarily by particle reduction or removal, that is, by removing the suspended particulate matter. Particulate matter which can be removed by normal gravitational settling is classified as a settleable solid. These solids are removed by reducing the velocity of the water to a “ponding” state that will allow settling to take place. The filter bag units act first as a dam to create a pond or pool by retarding the flow of water and sediment thereby allowing time for sedimentation of suspended particles. This takes place on the influent side of the bag and is a first step in the process of the invention. The present invention provides a unique combination of three water treatment phases of settling, agglomeration, and filtering. In one aspect, the bag of the present invention can perform all three phases. Agglomeration and filtering may be looked at as methods of “capturing” unwanted particles.
The suspended particulate matter which does not settle during the ponding phase from gravitational settling or is not removed by the filtering effect of the bag wall material is considered to be colloidal. Colloidal particles maintain a negative ionic charge and do not have enough mass to settle. These are the particulates that cause the water to appear turbid or opaque. The effective removal of these colloids can be greatly enhanced through the introduction of a polymeric agent to the turbid water. These agents collectively bond naturally suspended particles together causing them to gain sufficient weight to settle out of suspension through gravitational sedimentation. The preferred agent, PAM, is placed within a filter bag in powder form without mixing or it may be mixed with the ballast. Water flow through the bag is relatively slow giving the agglomerated particles time to settle. In the bag, water is absorbed into or is trapped in the ballast if the ballast comprises materials that tend to absorb water such as mulch, wood chips, saw dust, cotton seed hulls, pecan shells and/or other natural, organic, vegetable materials. In addition, the ballast may comprise synthetic material such as synthetic foam shavings, synthetic fibers such as shredded polyester cord reclaimed from rubber tires, or ground rubber, and comprise inorganic materials such as gravel or crushed stone. The ballast preferably is a combination of the synthetic and organic materials. The water trapped within the ballast greatly increases the bag weight and its stability on a slope.
Soil types can vary greatly depending on variables such as type of clay, humus, and soil pH. Due to these variations, on-site soil testing and evaluation is a recommended procedure. For example, the site may be one where coal slurries, mine trailings, or waste petroleum products are present. The soil test will determine the correct dosage amount and polymer system to be recommended and selected. By ensuring the correct dose and type of polymer, greater water clarity can be achieved through a prescribed formulation.
Water that passes through the bag may still contain colloidal particles. In a preferred embodiment, as this water leaves the bag it contacts the mesh skirt that is impregnated with PAM to induce further agglomeration of the suspended particles. The mesh may be jute, cotton, or other suitable organic or inorganic material. In addition to exposing the run off water to the PAM, the skirt also retards water flow and is a backup to restrain and prevent any breakthrough of higher velocity water streams in a heavy downpour. As the particles settle they may settle directly on the surface soil. These sediments tend to increase flocculation thus increasing the pore volume of the soil which reduces the quantity of water run-off while increasing its quality. For further erosion control, grass or other ground cover seed can be attached to the skirt. Also, additional skirts may be provided downslope to ensure a high level of erosion control. In one aspect, a skirt in and by itself may perform the erosion control functions of agglomerating and filtering. Skirts may be placed on steep inclines and used as ditch liners.
In another aspect, the ballast which is disposed within the filter bag with the polymeric material to filter water passing through, restrains movement of the filter bag when placed on a surface across which water may flow. The ballast enables the filter bag to remain where positioned and effectively dam water flow for a time sufficient to promote settling as well as filtering the water passing through the bag.
Preferably, the ballast filter material may comprise the materials mentioned above and the fabric, preferably, a polymeric material, may be a woven polypropylene, and the polymeric material may comprise a water soluble anionic polyacrylamide (PAM).
Advantageously, the filter bag is in the shape of a tube with closed ends wherein the diameter of the tubular filter bag is in the range from about 8″ to about 12″. The bags are marketed under the trademark “EROSION EEL”™ owned by Denny Hastings FLP14, a family Limited Liability Company of Nevada. A tube shape is one very useful configuration but the bag may also be multi-sided or gusseted. The filter bags are stackable; one upon another, and/or the fabric preferably comprises a non-toxic, flame retardant polymeric material. A UV inhibitor as well as a flame retardant is included in the skirt and bag material.
In another aspect of the invention, a method of controlling erosion is provided comprising the steps of forming elongated filter bags from woven fabric having weave openings of a size that will filter the sediment from the water passing through the fabric openings and at least partially filling the filter bag with a ballast material that also filters the water. The method comprises disposing an agent within the filter bag for agglomerating colloidal particles suspended in water passing through the filter bag and closing the filter bag to enclose the ballast and the agglomerating material. The filter bags, when positioned on a surface with a skirt, control the flow of water across the surface. Advantageously, the ballast material is selected as mentioned above to provide sufficient weight for stabilizing the movement of a filter bag on the surface upon which it is placed. The fabric of the bag may comprise a sealable material and the filter bag may be formed and closed in a form-fill-seal process. A pre-formed bag may be filled on site by gravity feed, or by mechanical means such as by pumping or blowing the ballast into the bag on site. While on-site filling is possible it has proven to be impractical, because the ballast does not blow or pump readily without clogging as a bag is filled and it is inconvenient to mix ballast on site. A preferred method is described below.
The fabric of the filter bags has uniform openings to provide a constant level of filtration and sediment control over the life of the product and to provide handling of higher flow rates while being easily cleaned if needed. The filter bag units and skirts may be easily transported or moved temporarily for ingress or egress activity, or for installation on the most difficult to reach job sites. Through installation designs and the ability to stack the filter bag units, a multitude of erosion control designs can be achieved. Bags can be rotated and cleaned by rain water or removed and mechanically cleaned on or off site. The skirt which is attached underneath or to the down hill side of the bag is laid parallel to the bag. It may comprise the same material as the bag or may be jute or cotton mesh impregnated with PAM or other agglomerating agent.
In a further aspect, the invention is a method of making the elongated filter bag comprising the steps of mixing predetermined quantities of 1) organic materials which may include, for example, hardwood chips, straw, cocoa shells, ground corn cobs or cotton seed hulls; 2) recycled shredded rubber or foam rubber shavings or from tires; 3) synthetic, organic, or mineral fibers which may include carpet shavings; and 4) a chemical agglomerating agent to form a filler mixture. These steps are preferably performed with the assistance of a conveyor. The mixture is agitated so that it flows freely, and is then deposited by gravity into vertically positioned, fabric tubular-shaped bag with one open end, and then the tubes or bags are closed and removed after filling. The filled bags are now ready for positioning for erosion control.
In a still further aspect, the bags may be equipped with RFID tags, i.e., radio frequency, identification devices making required periodic inspection of sites easier and more complete. The RFID device may record each time an inspector with a transmitting and recording device of the appropriate range and frequency has been at the site to make an inspection. Likewise, the inspector will be able to tell if all bags remain at the site and are intact. Reports may be readily generated in this manner. Also the length of time a bag has been installed can be monitored since, at present, 24 months is the projected effective lifetime of a bag.
In yet one additional aspect, the present invention is a method of controlling erosion on a sloping surface having soil susceptible to erosion comprising the steps of providing a filtering fabric with an agglomerating or flocculating polymer embedded therein; forming a shaped article from said fabric, and securing said article to said sloped surface. The article may be a bag or tube or skirt and the means for securing the article may be ballast in the case of a bag or attaching the skirt to another article or by staking it. The skirt may also be a receptacle that, when essentially flat, may be filled with ballast. The article may also be secured by its own weight and the adhesive properties that develop with the contact of the polymer with the soil.
The construction designed to carry out the invention will hereinafter be described, together with other features thereof.
The invention will be more readily understood from a reading of the following specification and by reference to the accompanying drawings forming a part thereof, wherein an example of the invention is shown and wherein:
Referring now in more detail to the drawings, the invention will be described in more detail.
As can best be seen in
The composition of ballast 18 is preferably selected for the major contaminant to be removed. For removal of suspended soil particle or coal in coal slurries a mixture of approximately equal parts on a volume basis of inorganic, organic and synthetic material is preferred. Virtually 100% synthetic material is desirable where absorption of contaminant particles may be desired e.g. chemical contaminant, mine trailings etc. may require different ratios and materials depending on the contaminant. Thus, selection of the ballast composition will preferably be matched to the contaminant to be removed.
It will be noted in
As can best be seen in
Referring to
Specified amounts by volume of wood chips, shredded rubber, synthetic recycled carpet fibers, straw, cocoa shells, ground corn cobs, or cotton seed hulls are deposited in pre-set amounts from hopper 80 onto the continuously moving mixing conveyor 85. As the mixing conveyor moves under hopper 81 a pre-set amount of shredded rubber is deposited onto of the ingredients previously deposited from hopper 80. As the mixing conveyor moves under the bale processing unit 82, synthetic carpet fibers, if included in the mix, are deposited in a pre-set amount on top of the previously deposited ingredients. As the ingredients from hopper 80, hopper 81, and the bale processing unit 82 move under the chemical hopper 83, a pre-set amount of PAM is deposited onto the previously deposited ingredients. From chemical hopper 83 the combined raw materials are thoroughly mixed in the mixing conveyor 85. As the mixed filler ingredients leave the mixing conveyor 85, they are deposited by gravity onto incline conveyor 86 which transports them into bagging unit hopper 87. Ingredients are agitated by the settling device 89 and flow freely into the geo-textile tube attached at the bottom of bagging unit hopper 87. Dust controller 88 reduces and collects particles that are made airborne by the process. Filled bags are manually released from the bagging unit, are manually tied and dropped to the bagging facility floor.
The best mode of the invention which, in one aspect, is the complete erosion control system including the selection of the appropriate ballast mix, making the filter bags and properly placing them on a sloping surface that is subject to erosion. The best mode process for making the erosion control bag product has been described above in connection with
While a preferred embodiment of the invention has been described using specific terms, such description is for illustrative purposes only, and it is to be understood that changes and variations may be made without departing from the spirit or scope of the following claims.
This application claims priority under 35 USC §120 from U.S. provisional application Ser. No. 60/831,835 filed Jul. 19, 2006 entitled “Polymer Filtration System and Method for Erosion Control and Water Clarification”.
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Number | Date | Country | |
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