Configuration implementing waterproofing under a concrete surface coat of a concrete floor
A barrier to fluid passage is embedded within, instead of atop, porous material to retain the durability of the surface of the porous material. In one embodiment, a thin set mortar is applied to a concrete slab. A pleated metal foil is pressed into the wet mortar and a bond is established. The mortar is allowed to set and a top, or finish, section of concrete is then poured over the foil and finished conventionally. Provisions are made for sealing expansion joints in concrete slab floors and at the juncture of floor and wall. The foil may be provided in multiple layers to provide a mechanical bond via mortar oozing through perforations or along pleats in each of the top and bottoms layers, while providing a solid layer through which a fluid will not pass, at least in one direction.
This application is a division of U.S. patent application Ser. No. 11/368,473, Method of Implementing Waterproofing under a Concrete Surface Coat of a Concrete Floor, by McInerney et al., filed Mar. 7, 2006 which is, in turn, a division of U.S. patent application Ser. No. 10/715,430, Embedded Barrier to Fluid Flow, by McInerney et al., filed Nov. 19, 2003, both of which are incorporated herein by reference.
STATEMENT OF GOVERNMENT INTERESTUnder paragraph 1(a) of Executive Order 10096, the conditions under which this invention was made entitle the Government of the United States, as represented by the Secretary of the Army, to the entire right, title and interest therein of any patent granted thereon by the United States. This patent and related ones are available for licensing. Contact Bea Shahin at 217 373-7234 or Phillip Stewart at 610 634-4113.
BACKGROUNDU.S. Pat. No. 6,286,279, Method for Attaching Fabric and Floor Covering Materials to Concrete, to Bean et al., Sep. 11, 2001, and incorporated herein by reference, teaches bonding a thin metal plate or metal foil to a concrete surface to effect a barrier to water vapor transfer. The configuration of the '279 patent improves the maintenance of the bond between a concrete surface and various types of floor coverings. The '279 patent teaches two systems for implementing the barrier: one uses a single-layered thin metal plate or metal foil that is folded to produce recesses much like corrugated sheet metal. One side of the foil is attached to the concrete surface using a Portland cement-based thin set grout. A second embodiment employs a two-part thin metal plate or foil. A first lower part is perforated (or slit and expanded) and attached to a second solid upper part. The lower perforated part is embedded in a layer of thin set mortar on the concrete to anchor it to the concrete. The thin set mortar that oozes through the perforations also serves as a mechanical bond, a “cementitious rivet,” supplementing the chemical bond made along the contact surface.
A preferred embodiment of the present invention is an improvement on the '279 patent in that it allows the thin metal plate or metal foil to be embedded just below the surface of the underlayment, concrete in the case of a “poured slab,” so that there is a layer, e.g., concrete, both above and below the thin metal plate or metal foil. That is, a robust “finish” surface, e.g., concrete, is placed above the thin metal plate or metal foil, thus presenting a durable surface of conventional appearance. One advantage of this design is the ability of the surface to resist moisture flow from without while accommodating typical use, e.g., that of hard-wheeled vehicles that would otherwise damage vinyl or carpet floor coverings.
SUMMARYA fluid, or vapor, barrier is encapsulated within a durable structure to preclude passage of fluid in at least one direction while retaining the durability of a surface of a structure that conventionally does not contain such a barrier.
A first preferred embodiment of the present invention employs a two-part folded thin metal (or composite) plate or metal (or composite) solid (un-perforated) foil such as provided in the '279 patent, but embedded just below the top surface of a durable surface such as an underlayment, typically a concrete “slab” or floor.
Alternatively, a second preferred embodiment of the present invention employs a two-part thin metal plate or metal foil differing from that of the '279 patent in that the second or top layer of metal is a perforated thin plate or metal foil. The perforations on the top side of the second (top) layer serve to facilitate the formation of a mechanical bond via the concrete oozing through the perforations and acting as a “cementitious rivet” between the top side of the second layer and the bottom side of the surface of the underlayment above this second (top) layer. This mechanical bond acts in addition to any chemical bond formed between the bottom side of the underlayment surface and the remainder of the upper surface of this second (top) perforated layer. This second preferred embodiment must employ a solid thin metal plate or metal foil as a first (bottom) layer to block passage of moisture through the path provided by the underlayment material, typically concrete, that, upon installation, oozed through the perforations in the second (top) layer of perforated thin metal plate or metal foil. That is, if a perforated second (top) layer of a two-part thin metal plate or metal foil is used to achieve a better bond, then the first (bottom) layer must be solid, and conversely, if a perforated first (bottom) layer is used, then the second (top) layer must be solid.
Alternatively, a third preferred embodiment of the present invention employs a three-part thin metal plate or metal foil differing from that of the '279 patent in that a solid center foil or thin metal plate has an expanded metal foil or thin metal plate, e.g., pleated foil, applied to both sides. Application of the top and bottom pleated foils or thin pleated metal plates may be by way of spot welding in one embodiment. This results in a three-layered system that provides opportunity for the adhesive, e.g., thin-set mortar, to infiltrate slots in the lower foil (or thin metal plate) positioned over the adhesive immediately applied to an existing slab, while the expanded foil (or thin metal plate) attached to the top of this three-layer version establishes a similar mechanical and chemical bond to the overlaid concrete that forms a surface, e.g., concrete flooring. This particular embodiment also aids in resisting “curling” of an overlaid concrete layer that provides a durable surface for use by hard-wheeled vehicles.
A preferred method of applying a first preferred embodiment of the present invention to an existing porous surface, such as cured concrete, comprises:
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- applying a layer of adhesive, such as thin set mortar, to the existing surface;
- placing a folded or pleated thin metal plate or folded or pleated metal foil on the layer of adhesive, e.g., thin set mortar;
- embedding the bottom of the thin metal plate or metal foil into the adhesive, e.g., thin set mortar;
- covering the top of the folded or pleated thin metal plate or folded or pleated metal foil with a thin layer of durable material, such as concrete;
- permitting the adhesive to cure; and
- finishing and curing the thin layer of durable material, e.g., concrete, as needed.
Note that if concrete is used as a finish layer, consolidation of this covering concrete must be done with care to avoid loosening the foil bonded to the adhesive, e.g., thin set mortar.
As an alternative, seams between the pieces (sheets) of the folded or pleated thin metal plate or folded or pleated metal foil may be sealed with flexible commercially available room temperature vulcanizing (RTV) products appropriate for use in alkaline environments. As a further alternative, employing accordion-style pleats at edges of the thin metal plate or metal foil accommodates panel movement while avoiding tearing or breaking the folded thin metal plate or folded metal foil should the installed surface move under load. Of course, this method is not limited to existing installations but may be employed upon initial installation of an underlayment or wall.
In installing a second preferred embodiment, the above method of installation may be applied using a two-part thin metal plate or metal foil having a first (bottom) layer and a second (top) layer, instead of a single folded thin metal plate or folded metal foil.
In another method of installing the second preferred embodiment a two-part thin metal plate or two-part metal foil is used in which the second (top) layer incorporates perforations and the first (bottom) layer is solid.
In yet another method of installing the second preferred embodiment, the immediately above method of installation may be applied using a two-part thin metal plate or two-part metal foil in which the first (bottom) layer incorporates perforations and the second (top) layer is solid.
Finally, the above method of installation may be applied using the third preferred embodiment, a three-layer sandwich comprising top and bottom layers of perforated, folded or pleated foil or thin metal covering a solid middle layer of foil or thin metal. The top and bottom layers may be joined to the solid center layer by any of a number of suitable processes, e.g., tack welding.
Embodiments of the present invention are not limited to underlayments but may be used on vertical or slanted surfaces where protection from fluid intrusion is desired. Further, a “one-way” vapor barrier may be installed to prevent intrusion of fluids while permitting expulsion of the same fluids or vapors. Instead of a metal foil or thin metal plate, a special “breathing” material such as those marketed under the trademark GORETEX® (liquid impermeable, moisture vapor transmissive material) may be used in place of metal. This would have particular application in below grade applications such as basement floors or walls and in environments of high humidity such as kitchens or bathroom floors or walls that otherwise “sweat.” In addition to embedding the GORETEX® (liquid impermeable, moisture vapor transmissive material) lining in concrete on a slab, it could be embedded just beneath a porous outer stucco or similar coating to achieve the same effect as the metal barrier does in the underlayment while also permitting “out gassing” of vapors from within the room.
Embodiments of the present invention may be used in any application where it is necessary to prevent the movement of fluids (liquid or gas) through porous material, such as concrete. Specifically, embodiments may be used to block the movement of water vapor and will be equally effective in preventing the movement of stable gases, such as radon, through porous material, such as concrete.
The “embedded barrier” of the present invention, in all of its preferred embodiments, is unique in its implementation. For example, conventionally, a concrete slab has been “sealed” by pre-placing a polymer membrane under the slab prior to placing the new concrete. Once the concrete slab had been installed, the slab could be further sealed only at its top surface. This sealing of the top surface has been accomplished conventionally by using epoxy, fiberglass or combinations of fiberglass and epoxy, leaving a surface that was less durable than a concrete surface.
To summarize some of the salient advantages of preferred embodiments of the present invention:
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- it permits modifying existing installations, e.g., addition of concrete above the metal barrier on existing slabs;
- it allows a trafficked surface above a vapor barrier to be made of durable castable material such as concrete or asphalt concrete;
- it provides a continuous sheet of metal foil that also serves to reinforce an underlayment, such as a concrete slab;
- it reduces the opportunity for cracking that occurs on one side of a structure to propagate to the other side;
- it reduces the opportunity for fractures that exist in the lower part of an underlayment, e.g., a concrete slab, to widen or propagate laterally;
- in a preferred embodiment it prevents curling of a top surface of concrete that has been applied to an existing concrete slab; and
- in an alternative embodiment, it accommodates joints between panels of structure, such as an underlayment, by employing a pleated barrier joining section thus permitting movement without compromising the integrity of the barrier.
Further advantages of the present invention will be apparent from the description below with reference to the accompanying drawings, in which like numbers indicate like elements.
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- at least one layer of adhesive 312 applied to a top surface of the porous material comprising a base 311, e.g., thin set mortar applied to a concrete slab;
- panels 100 of non-porous material having edges 102 suitable for overlapping, e.g., pleated edges, as shown at 701 of
FIG. 7 , affixed to a topmost layer of adhesive 312 so as to completely cover the adhesive 312, a flexible sealant as shown at 702 ofFIG. 7 applied between the overlapping edges as shown at 701 ofFIG. 7 ; and - the topmost section 313 emplaced upon the panels 100 so as to completely cover all said panels 100, the topmost section 313 incorporating the top surface suitable for routine use by wheeled traffic.
In a preferred embodiment of the configuration, the barrier is a vapor barrier embedded, i.e., completely enclosed, in porous material. The non-porous material used for the panels 100 may be selected from: a metal, a metal alloy, a steel alloy, a stainless steel, a composite material, a composite material containing at least some metal, and combinations thereof.
In a preferred embodiment of the configuration, the non-porous material comprises at least one metal and the porous material comprises at least some concrete. Further, the adhesive 312 may be a thin set mortar applied to a thickness of about 6 mm (¼ inch). In a preferred embodiment of the configuration in which the porous material at least partially comprises concrete, the topmost section may comprise concrete applied to a thickness of about 2.5 cm (1 inch) or more.
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A preferred method of implementing an embedded barrier comprises:
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- applying at least one layer 312 of adhesive, such as a thin set mortar, to an entire first surface of the porous material of the base 311, e.g., a concrete slab, prior to emplacing the topmost section 313, e.g., a finish layer of concrete;
- placing panels 100 of non-porous material, such as a metal or composite plate or metal or composite foil, upon a topmost layer 312 of adhesive (if more than one layer of adhesive is used), overlapping edges 102 of each panel 100 with edges of any panels 100 placed adjacent thereto in the same plane along the topmost layer 312 of adhesive such as shown at 701 in
FIG. 7 , and completely covering the topmost adhesive layer 312 with the overlapping panels 100; - establishing a seal 702 as shown in
FIG. 7 between all the overlapped panel edges 701; and - emplacing at least one layer of material comprising a topmost section 313 upon the panels 100 such that each panel 100 is confined below the topmost section 313 and above a topmost layer 312 of adhesive.
Employing this method, i.e., providing one or more adhesive layers 312 upon a surface of a base 311 of porous material, placing “barrier” panels 100 of one or more layers such as layers depicted at 210, 220, 600, 610 upon the topmost layer 312 of adhesive, establishing a seal 702 between the overlapped edges 701 of the panels 100 and emplacing a topmost section 313 to encapsulate the panels 100, implements a fluid barrier within porous material, preferably durable porous material such as concrete.
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The method of emplacing a fluid barrier within porous material extends to establishing a vapor barrier in porous material. The vapor barrier may be a one-way barrier such that the configuration is permitted to “breathe” or “outgas” in one direction while establishing and maintaining a fluid barrier in the opposite direction.
In a preferred embodiment of a method of implementation of the present invention, the method employs non-porous material comprising at least one metal and the porous material comprises at least some concrete. Further, the topmost adhesive layer 312 may be a thin set mortar applied to a thickness of about 6 mm (0.25 inch). In a preferred embodiment in which the porous material at least partially comprises concrete, the topmost section may comprise concrete applied to a thickness of about 2.5 cm (1.0 inch) or more.
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In yet another alternate preferred configuration, the panels 100 comprise a first perforated foil 210 as a first layer 321 of a two-layer foil 321, 322, the second layer 322 being a solid foil 220. Each of the first and second foil layers 321, 322 has a total thickness of less than about 2 mm (80 mils), and more preferably less than about 0.76 mm (30 mils), and most preferably about 0.25 mm to 0.76 mm (10-30 mils). In a preferred embodiment, the first perforated foil 210 is placed immediately adjacent the bottom side of the topmost section 313 as shown at 321.
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The abstract of the disclosure is provided to comply with the rules requiring an abstract that will allow a searcher to quickly ascertain the subject matter of the technical disclosure of any patent issued from this disclosure. 37 CFR § 1.72(b). Any advantages and benefits described may not apply to all embodiments of the invention.
While the invention has been described in terms of its preferred embodiments, those skilled in the art will recognize that the invention can be practiced with modifications within the spirit and scope of the appended claims. For example, although the configuration is described in specific examples related to concrete structure, it may be adapted to other porous construction materials, such as drywall, chipboard, wood, tile, composites, and combinations thereof. Thus, it is intended that all matter contained in the foregoing description or shown in the accompanying drawings shall be interpreted as illustrative rather than limiting, and the invention should be defined only in accordance with the following claims and their equivalents.
Claims
1. A configuration preventing fluid passage in discrete structures in at least one direction, comprising: wherein if more than one said panels are required, all edges of each said panels are overlapped with any adjacent said panels and sealed continuously along each said overlapped edge; and wherein said second porous material is similar in composition and method of emplacement to said first porous material such that said second porous material hardens upon curing, and wherein placement of said second section establishes a durable surface and affixes said configuration in place.
- at least a topmost layer of adhesive material applied to a topmost surface of a first section of first porous material comprising a flowable mixture that hardens upon curing, said first porous material provided as an underlayment in said discrete structures;
- at least one panel of non-porous material having a top side and a bottom side, said bottom side affixed to said topmost layer of adhesive material so as to completely cover said topmost surface of said first section,
- a second section of second porous material emplaced such that said second porous material flows over said at least one panel in a contiguous mass that completely covers said at least one panel,
2. The configuration of claim 1 in which said panel comprises non-porous material selected from the group consisting essentially of: a metal, a metal alloy, a steel alloy, a stainless steel, a composite material, a composite material containing at least some metal, and combinations thereof.
3. The configuration of claim 1 in which said non-porous material comprises at least in part at least one metal.
4. The configuration of claim 1 in which said first porous material and said second porous material comprise at least in part concrete.
5. The configuration of claim 1 in which said adhesive material comprises at least in part a thin set mortar applied at a thickness of about at least 6 mm.
6. The configuration of claim 1 in which said first porous material comprises at least in part concrete applied at a thickness of about at least 2.5 cm.
7. The configuration of claim 1 in which said overlapping edges of said panels are sealed with a sealant that remains flexible upon curing.
8. The configuration of claim 7 in which said at least one sealant is a Room Temperature Vulcanizing (RTV) sealant.
9. The configuration of claim 1 in which said at least one panel comprises at least one plate of a total thickness less than about 6 mm.
10. The configuration of claim 9 in which said at least one plate comprises a first perforated section, having a top side and a bottom side, and a second solid section, having a top side and a bottom side, said top side of said first perforated section abutted to said bottom side of said second solid section, each said first and second sections being of a total thickness of less than about 3 mm.
11. The configuration of claim 10 in which said first perforated section and said second solid section are joined via means selected from the group consisting of:
- tack welding, soldering, gluing, heating, applying pressure, and combinations thereof.
12. The configuration of claim 9 in which said at least one plate comprises a first perforated section, having a top side and a bottom side, a second solid section, having a top side and a bottom side, and a third perforated section, having a top and bottom side, said top side of said first perforated section abutted to said bottom side of said second solid section, and said bottom side of said third perforated section abutted to said top side of said second solid section, each said first, second and third sections being of a total thickness of less than about 3 mm.
13. The configuration of claim 12 in which said first and third perforated sections are joined to said second solid section via means selected from the group consisting of: tack welding, soldering, gluing, heating, applying pressure, and combinations thereof.
14. The configuration of claim 1 in which said at least one panel comprises at least foil having at least one layer, said foil having a thickness less than about 1.0 mm.
15. The configuration of claim 14 in which said foil comprises a first perforated section, having a top side and a bottom side, and a second solid section, having a top side and a bottom side, said top side of said first perforated section abutting said bottom side of said second solid section, each said first and second sections being of a total thickness of between about 0.25 mm and about 0.76 mm.
16. The configuration of claim 15 in which said first perforated section and said second solid section are joined via means selected from the group consisting of:
- tack welding, soldering, gluing, heating, applying pressure, and combinations thereof.
17. The configuration of claim 15 in which said each said first perforated section and said second solid section is further configured with a pleated edge along at least one edge,
- wherein said at least one pleated edge facilitates flexion of said foil when under load thereby resisting breach of said foil via shear forces.
18. The configuration of claim 1 in which said first and second sections each incorporate at least one expansion joint and said configuration further comprises a non-porous expandable strip overlapping the entire length of said edges of any said panels that abut said expansion joint, each overlap of a width less than about 5.0 cm,
- wherein said strip is sealed along each longitudinal edge of said strip between said strip and said topmost portion of each said panel that abuts said expansion joint with a continuous bead of sealant along the entire length of said expansion joint, said sealant remaining flexible upon cure.
19. A configuration preventing fluid passage in at least one direction in discrete structures, comprising: wherein if more than one said means for inhibiting are required, all edges of each said means for inhibiting are overlapped with any adjacent said means for inhibiting and sealed continuously along each said overlapped edge; and wherein said means for covering is emplaced upon said means for inhibiting so a to completely cover said means for inhibiting, and wherein placement of said means for covering establishes a durable surface and affixes said configuration in place.
- means for adhering that comprises at least a topmost layer, said means for adhering applied to a topmost surface of a first section of said discrete structure;
- means for inhibiting fluid flow, said means for inhibiting affixed to said topmost layer of said means for adhering to completely cover said topmost surface,
- means for covering, said means for covering having a top side and a bottom side abutting said topmost layer of said means for adhering,
20. The configuration of claim 19 in which said first section of said discrete structure and said means for covering comprise at least in part concrete.
Type: Application
Filed: Apr 26, 2007
Publication Date: Jul 17, 2008
Inventors: Michael K. McInerney (Champaign, IL), Sean W. Morefield (Champaign, IL), Vincent F. Hock (Mahomet, IL), Philip G. Malone (Vicksburg, MS), Charles A. Weiss (Clinton, MS)
Application Number: 11/790,508
International Classification: E02D 31/00 (20060101); E04B 1/70 (20060101); E02D 31/02 (20060101);