This is the first application filed for the present invention.
1. Technical Field
The present invention relates to low weight, non or minimal water retaining, non-biodegradable, soil replacement material contained in a properly constructed and fastened permeable bag.
2. Background of the Invention
Generally speaking, once existing soil is excavated from a construction site the decision to replace the soil is a difficult one usually requiring engineering analysis. The native soil is sometimes reused but this is generally undesirable if it is not consistent and free draining. In most instances the soil is replaced with imported natural aggregate materials such as stone, gravel, and sand. These imported materials are expensive to transport. They also are labour intensive to install and may require the use of large machinery. On difficult sites with existing structures the work could become very labour intensive.
A further limitation with existing soil replacement materials is the lack of long term drainage capacity, possibly increases in the weight compared to the soil replaced, and a lack of insulating ability. In colder climates, the possibility of structural damage due to freezing soil is also not fully eliminated. In the example where a contractor is undertaking a repair on a structure or wall, the contractor is required to combine different construction materials applied in a very strict and complicated manner to try and provide the engineering requirements to insure no further damage to the structure occurs. The drainage, loading and insulation requirements set out by the engineer will likely be expensive and difficult to accomplish.
It would be desirable to have a light weight, soil replacement product with a multitude of applications that would provide suitable drainage and reduced loading with some insulating characteristics. It should be easily conformable to the opening into which it is to be charged like other materials. It must also be easier to transport and install to reduce the labour and machinery costs associated with other materials.
A final important aspect of a soil replacement product is that it must not exhibit unusual or unacceptable characteristics as compared to other natural soil replacement materials. The multitude of applications for a soil replacement product will allow some flexibility, however the final analysis must insure a reasonable margin of safety is maintained when using any soil replacement product.
The present invention is focused upon satisfying the requirements which have been overlooked by prior art techniques by combining a lightweight soil replacement material in a permeable bag. This light weight, non water retaining, non-biodegradable product will provide good, long term water drainage, reduced loading on structures, insulating ability and will insure reasonable margin of safety characteristics similar to existing natural soil replacement materials.
One object of one embodiment of the present invention is to provide a lightweight, non water retaining, non-bio-degradable soil replacement product with an improved method of employing the same.
A further object of one embodiment of the present invention is to provide a lightweight, non or minimal water retaining, non-biodegradable soil replacement material contained in a permeable bag, comprising:
Advantageously, by providing the lightweight material in the bag, the overall weight of the product is significantly reduced compared to a similar volume of natural material, improving the ease of handling and reducing the loading characteristics of the volume of soil replaced. A particularly useful feature of the product is the ability to create air voids which most certainly will provide a resistance to heat flow. This will give the product an R-value or thermal resistance quality which is required in many construction and engineering situations.
In respect of the material of which the bag is made, the material which provides the requisite strength will depend on the environment in which the bag is used and can be selected by the designer.
A further object of one embodiment of the present invention is to provide a method of filling an area to be backfilled, comprising:
The ease of use makes the product particularly well suited to a host of applications. The ability to open and reseal the bag would allow for flexible use where the specific size of the space to be filled is variable. As a useful feature, the otherwise closed container having the sealable opening could include a zipper type fastener or conventional bag sealer which would allow for adjustment of the amount of material in the bag.
As an option, the individual bags may also be reconfigurable into an assembly by using individual containers connected either end to end or atop one another. In order to maintain the connection, fasteners will be employed such as ties, zippers, heat, tape inter alia.
Having thus generally described the invention, reference will now be made to the accompanying drawings illustrating preferred embodiments.
Similar numerals denote similar elements.
With reference to
In terms of suitable flexible materials for the container 10, each will be selected from non biodegradable materials which may or may not include UV stabilization compounds in order to prevent UV degradation. This would be required where the bag is in direct exposure to the sun or some other source of ultra violet radiation. With respect to the material of which the bag is made, suitable polymer materials to fulfill this requirement include polyethylene, polypropylene, polystyrene, polyvinyl chloride, polyester inter alia. In certain circumstance, it may be necessary to use high end or high performance materials such as polyvinyl fluoride film.
In order to facilitate water passage and moisture passage, the flexible bag is preferably composed of mesh or otherwise perforated to facilitate or mimic the concept of having a mesh structure. Depending on the intended use of the container, the mesh size may vary substantially from 0.1 mm to 10 mm. As will be appreciated by the user, the mesh pore size will vary depending on the surrounding earth formation and ground hydrology, etc. has high water content or is otherwise exposed to a great deal of drainage, or extremely fine or coarse existing soils.
Generally speaking, the size and charging of the flexible bag will vary from one intended use to another. One possibility is to have a unit approximately 8 feet in overall length and approximately 2 feet in diameter.
As illustrated in
With reference to
Turning to
Although these examples have been shown with respect to
As referenced earlier in the specification, the arrangement as illustrated in
In this application, the size of the openings in the mesh container 10 may be varied from one side of the container to the other to prevent the ingress of moisture through the exposed surface 30 of each of the walls 26. In addition, the backfill within the containers 10 of
The non-biodegradable materials may be comprised of recycled plastics as well as virgin plastic and additionally may incorporate other suitable materials made from paper as well as polymeric materials or other suitable recycled composite materials. In terms of the shapes that have been presented for the fill, a specific strength and density of the material selected will, of course, depend on the intended use of the product.
With respect to the flexible bag, the material that will be employed will be subject to substantial variation and will be variable in terms of the tensile strength.
Although embodiments of the invention have been described above, it is not limited thereto and it will be apparent to those skilled in the art that numerous modifications form part of the present invention insofar as they do not depart from the spirit, nature and scope of the claimed and described invention.
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Number | Date | Country | |
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20040218986 A1 | Nov 2004 | US |