Not applicable to this application.
Example embodiments in general relate to a membrane-lined wall.
Any discussion of the related art throughout the specification should in no way be considered as an admission that such related art is widely known or forms part of common general knowledge in the field.
Levees have been in use for many years, and levee repair systems and methods for just about as long. Cutoff walls are one way to reinforce and prevent leakage in levees, but permeability of materials used (such as concrete) and soil contamination of the concrete during the curing process can reduce the integrity and strength of the cutoff wall. Further, without reinforcement, cutoff walls may be susceptible to seismic and other forces.
An example embodiment is directed to a membrane-lined wall. The membrane-lined wall is formed in-place in a trench, typically a narrow, deep trench, formed by excavating the trench, typically along the top of a levee, although the wall system and the method for constructing it is particularly suitable for forming membrane-lined walls on the slope of a levee, as needed for localized problem areas.
In addition to levee reinforcement, the membrane-lined wall is also useful for stopping or preventing levees from leaking, for preventing pollution due to the migration of water or liquid contaminants, such as around the perimeter of waste disposal sites, coal slurry impoundments, and any other sites where groundwater movement should be stopped to prevent water contamination.
The membrane-lined wall comprises cementitious material, such as concrete, that fills the trench. The membrane-lined wall is formed by excavating a trench in the earth, the trench having two sides, a bottom, and a length. Next, a liner, which may be a low-permeability geomembrane, is installed in the trench along the length of the trench, the liner forming a continuous barrier between the two sides and the bottom of the trench and an interior portion of the liner in at least one dimension. After the liner is installed, a reinforcement mat is also installed within the interior portion of the liner, the reinforcement mat having a length aligned with the length of the trench, and having a height aligned with the two sides of the trench. As an example, the reinforcement mat may be a galvanized steel mesh, such as grade 40 galvanized wire mesh with rectangular openings. Other types of reinforcement, or reinforcement in addition to the mesh, may also be used.
The next step comprises filling at least part of the interior portion of the liner with a cementitious material that surrounds the reinforcement mat within the interior portion of the liner, wherein the weight of the cementitious material forces the liner into close contact with the sides of the trench, and then allowing the cementitious material to harden. The cementitious material, or concrete, can surround the reinforcement mat on three sides (such as both vertical sides and the bottom), or on all sides.
To add structural integrity, the reinforcement mat may come in sections, which are then joined together once they are in place in the trench to form a substantially continuous structure. In such an embodiment, the mat sections are joined together at a vertical edge between sections, so that the resulting reinforcement is aligned linearly along the length of the trench. For deeper trenches, multiple vertical sections of reinforcement mat may be required, and in such case, the sections may also be joined along the horizontal edges between them. The sides of the trench may be vertical in some example embodiments.
In an example embodiment, vibration, such as by an internal vibrator, may be applied to the cementitious material before it hardens. The vibration during the hardening process can remove air in the cementitious material and prevent honeycombing, which can weaken the wall.
In an example embodiment, the geomembrane liner comprises two layers of the low-permeability membrane, an inner layer adjacent to the interior portion of the liner, and an outer layer adjacent to the sides and the bottom of the trench. The inner layer of the liner may comprise multiple sections, wherein each section forms an overlap with an adjacent section along a first edge. Such multiple sections may also have an adhesive layer or coating applied at their edges between each adjacent section of the inner layer of the liner.
Further, the outer layer of the liner may comprise multiple sections, wherein each section of the outer layer forms an overlap with an adjacent section of the outer layer along a second edge. In such an embodiment, each overlap of the inner layer may be spaced apart from each overlap of the outer layer in a direction along the length of the trench.
In an example embodiment, forming the membrane-lined wall may further comprise positioning a roll of liner material over one side of the trench, positioning and clamping a lengthwise edge of the liner material over a side of the trench opposite the roll of liner material, and lowering a weight into the trench along the length of the trench to cause the liner material to unroll from the roll of liner material and extend into the trench. In using this method, the liner may then be cut from the roll, lengthwise, so that both edges of the liner (either one or two layers) are at the top of the trench, with a “pocket” of the liner extending down into the trench.
In addition to the preceding method of installing a liner, an example embodiment may further comprise positioning a second roll of second liner material over one side of the trench, and positioning and clamping a lengthwise edge of the second liner material over a side of the trench opposite the second roll of second liner material, and lowering a lengthwise weight into the trench to cause the liner material and the second liner material to unroll and extend into the trench. As with previous embodiments, the cementitious material may comprise concrete.
In another example embodiment, the liner of the membrane-lined wall comprises two layers of a low-permeability membrane, an inner layer adjacent to the interior portion of the liner, and an outer layer adjacent to the sides and the bottom of the trench.
Other example embodiments include a method of excavating the trench that provides for forcing the sides of the trench away from the interior portion of the trench, which can compress the soil of the sides and reduce the tendency of the sides to collapse. The method includes excavating a first depth of the trench extending from a surface of the ground to a first distance; applying an outward force from the interior portion against the two sides along the first depth of the trench; and excavating a second depth of the trench below the first depth such that the two sides extend to a second distance.
The method may further comprise maintaining the outward force against the two sides while excavating the second depth. For example, the second depth may be excavated using an excavator having a boom that extends under an apparatus (such as an air-lift cushion or plates with hydraulic rams between them) that applies the outward force from a position beyond the apparatus along the length of the trench. The excavation method may further comprise applying a force against the two sides along the second depth—that is, below the first depth of the trench.
Once the trench has been excavated, using any method, the membrane-lined wall may be formed as described herein. In addition, a moisture detector can be inserted in the wall, such as in the interior portion, so that if moisture penetrates the membrane, a signal can be produced and sent alerting users to that fact. For example, the moisture detector can be placed proximate the bottom of the trench, inside the liner, and as a further example, it may be a wired sensor that is placed prior to applying cementitious material to the trench. Of course, more than one sensor can be used, and for efficient processing, sensors can be embedded in the reinforcing material or in the liner itself. Once placed, the moisture sensors may be electrically connected to a control unit, which may be actively monitored or which may send radio or cellular signals indicating the presence of moisture detected by the sensor.
There has thus been outlined, rather broadly, some of the embodiments of the membrane-lined wall in order that the detailed description thereof may be better understood, and in order that the present contribution to the art may be better appreciated. There are additional embodiments of the membrane-lined wall that will be described hereinafter and that will form the subject matter of the claims appended hereto. In this respect, before explaining at least one embodiment of the membrane-lined wall in detail, it is to be understood that the membrane-lined wall is not limited in its application to the details of construction or to the arrangements of the components set forth in the following description or illustrated in the drawings. The membrane-lined wall system is capable of other embodiments and of being practiced and carried out in various ways. 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.
Example embodiments will become more fully understood from the detailed description given herein below and the accompanying drawings, wherein like elements are represented by like reference characters, which are given by way of illustration only and thus are not limitative of the example embodiments herein.
A. Overview.
An example membrane-lined wall generally comprises a reinforced, protected concrete wall 80 that is formed in place in a trench excavated in the desired location in the earth 10, such as the berm of a levee or the perimeter of a waste disposal site, as just two examples. The wall 80 can be formed anywhere it is needed, such as at the top, generally level portion of a levee berm, or it can be formed on a sloped portion of the berm, to strengthen, reinforce, or prevent leakage in a levee or other site in localized areas, as needed. Further, the methods described herein can be used anywhere a reinforced, waterproof in-ground wall is needed—not just for levees.
To form the wall 80 where it is needed, a location for trench 14 is first determined. This determination will include the location on the levee, waste disposal site, etc., as well as the needed depth and width. The trench, once formed, will comprise sidewalls 18 and bottom 16, and may be substantially rectangular, with a bottom 16 being horizontal or substantially horizontal, and the sidewalls 18 being vertical, or substantially vertical.
Wall 80 may generally comprise cementitious material 82, such as concrete. The wall 80 may also include a reinforcing mat or layer 84, which may be substantially parallel to the sides 18 of the trench 14. The reinforcing mat 84 may be, for example, made of galvanized steel. Further, multiple sections or pieces of reinforcing mat 84 may be installed in the trench 14 and held within the concrete or cementitious material 82, especially where the depth or length of the trench requires. For example, if the trench 14 is too deep or too long for a single piece of reinforcing material, multiple sections or pieces of reinforcing mat 84 will be needed. Such multiple sections may be joined together for added strength, either in multiple horizontal sections, multiple vertical sections (one section atop another), or both horizontal and vertical sections.
The wall 80 may be protected by, for example, one or two layers of a low-permeability liner 62, such as HDPE geomembrane. Such liners are anti-aging, UV resistant, and are impermeable. Accordingly, by installing liners 62 in a trench before concrete or other cementitious material 82 is added, the liners will not only make the wall 80 substantially impermeable (which will make it last longer and be a more effective barrier against erosion, etc.), but the liner 62 will prevent soil, and any substances in the soil, from contaminating the concrete or cementitious material during curing. This will result in a better concrete wall 80.
B. Trench Excavation.
As shown in
The trench, once excavated, will typically have sidewalls 18 and a bottom 16, as shown generally in the figures. As mentioned, the trench may be excavated on a slope, as shown in
In an example embodiment, the trench 14 may be dug deep enough to extend into undisturbed, native soil 19, as shown in
If the soil to be excavated is not sufficiently firm, techniques and apparatus may be used to hold or press the sidewalls of the trench in place, such as air bladders or plates forced apart by hydraulic cylinders, for example.
One such method and apparatus is best illustrated in
If necessary (e.g., depending on soil conditions or other factors), rigid plates 106 may be used in addition to air bladders to compress the soil. Further, instead of air bladders, hydraulic cylinders 108 may be used to apply force to plates 106, as shown in
In creating a deeper trench, the trench may first be excavated to a given depth, for example, the depth shown in
Once the desired depth has been reached, the air-lift cushions 100 may be deflated and pulled out of the trench, so that the liner 62 and reinforcement layer 84 can be installed into the open trench as described herein. Notably, and again depending on soil conditions as observed during excavation/compression, it may not be necessary to immediately install the liner 62 and pour concrete for the wall, because it is possible that, once compressed, the sides of the trench may not quickly collapse even after the bladders 100 or plates 106 and cylinders 108 are removed.
After the trench 14 has been excavated, one or more sensors 110 may be installed at various locations within the interior portion 64 of the trench or liner 62, as shown in
For greater efficiency, it is possible to place or embed multiple sensors, of different types if desired, within the liner 62 or reinforcement layer 84. Further, the sensors 110 may be placed at different locations within the interior portion 64 of the trench or liner 62. For example, for moisture or vibration sensors 110, placement at or near the bottom of the trench 14 may be desirable, although any location in the trench/wall is possible. The placement of sensors 110 within the wall is possible and improved by the controlled, “dry” process of forming walls described herein.
C. Liner.
As best shown in
In addition to making the finished wall 80 more resistant to water flow and increased mitigation of internal water migration, the liner 62 also serves to prevent soil contamination in the concrete pour, ensuring competent concrete core integrity. In addition, the weight of the concrete tends to force the liner into close contact with the sides 18 of the trench, resulting in a tight seal to the sides 18 of the trench 14.
As shown in
In addition, if desired, an adhesive layer 66 may be added to further seal the layers of liner 62 together. In addition to an inner layer, the liner 62 may also comprise a second, outer layer, as shown in
Installed as shown in
D. Reinforcement Mat.
As best shown in
E. Liner Installation Sled.
As best shown in
As also shown, the sled 40 may have provision for mounting one or more large rolls 60 of geomembrane liner material, in position above and to one side of the trench 14. As shown in
As shown, the liner installation sled 40 is designed to hold one or more layers of liner 62 in position over the trench. Initially, the liner 62 extends over the trench 14 between the positioning roller 42 and the liner end clamp 44. Once so positioned, a user may activate winch 50 (which may be a power winch or a manual winch) to lower a weight 54, such as a lead pipe weight 54, into the trench. Lowering the weight will cause the liner roll 60, or both the upper and lower liner rolls 60 (
F. Operation of Preferred Embodiment.
In use, the desired location of a trench 14 may be determined, where a wall can best reinforce or prevent leakage in a levee, or wherever such a wall is needed to prevent water migration, contain pollution, etc. In just one example use, a membrane-lined wall 80 can be formed along the top of a levee, as best shown in
Once the trench has been dug, the liner installation sled 40 is used to hold the layer or layers of liner 62 in position over the trench and the sled and winch 50 are used as discussed above to lower a weight 54 into the trench, causing the liner roll or rolls 60 to unroll and the liner 62 to drop into the trench 14, creating an interior portion 64 or pocket, as shown, to create an impermeable barrier between the interior portion 64 and the sides 18 and bottom 16 of the trench 14.
In an example embodiment, the trench 14 may be deep enough to extend into undisturbed, native soil 19, as shown in
The liner 62 may, in an example embodiment, be lowered into trench 14 in a predetermined way, so that any overlapping portions of liner will resemble the overlap patterns shown in
Once the liner 62 is in place within the trench, reinforcement mat 84 is installed within the interior portion 64 created by the liner. Typically, the reinforcement mat 84 will have a length aligned with the length of the trench, and a height aligned with the two sides of the trench. The mat will typically be positioned within the trench in the position shown in
Next, concrete or other cementitious material 82 can be poured into the trench 14. For example, the material 82 can be poured from one end of the trench and allowed to flow into the trench in one direction, indicated by the arrows in
After the concrete or other material 82 is poured, but before it cures, an internal vibrator 90 may be used to effect a good cure, by removing or minimizing air within the concrete mixture. As is known, typically an internal vibrator may be repeatedly inserted (as shown in position in
Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Although methods and materials similar to or equivalent to those described herein can be used in the practice or testing of the membrane-lined wall, suitable methods and materials are described above. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety to the extent allowed by applicable law and regulations. The membrane-lined wall may be embodied in other specific forms without departing from the spirit or essential attributes thereof, and it is therefore desired that the present embodiment be considered in all respects as illustrative and not restrictive. Any headings utilized within the description are for convenience only and have no legal or limiting effect.
The present application is a continuation of U.S. application Ser. No. 16/537,928 filed on Aug. 12, 2019 which issues as U.S. Pat. No. 10,753,061 on Aug. 25, 2020, which claims priority to U.S. application Ser. No. 16/220,139 filed Dec. 14, 2018. Each of the aforementioned patent applications, and any applications related thereto, is herein incorporated by reference in their entirety.
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Entry |
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U.S. Non-Final Rejection Issued from USPTO for U.S. Published Application US2020/0277749 A1; dated Dec. 24, 2020. |
Number | Date | Country | |
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20200385950 A1 | Dec 2020 | US |
Number | Date | Country | |
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Parent | 16537928 | Aug 2019 | US |
Child | 17000984 | US |
Number | Date | Country | |
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Parent | 16220139 | Dec 2018 | US |
Child | 16537928 | US |