Abstract:
A laminated curtain wall panel is prepared by continuously disposing foam boards onto adhesively coated gypsum sheathing followed by a third layer consisting of a reinforcing mesh and a cementitious binder, as the product progresses on a conveyor. The laminated product is erected by screws which are forced through the panel by a screw gun which disposes the screw head firmly against the gypsum sheathing.

Description:
This invention relates to a laminated curtain wall panel including a gypsum board, foam board, reinforcing mesh and a cement binder, to the method of making the panel and to the method of erecting a curtain wall using the panel. 
     BACKGROUND OF THE INVENTION 
     Several board and panel products have been used or proposed for use in the construction of insulating curtain walls. U.S. Pat. No. 3,389,518 discloses constructing a curtain wall by adhering a plastic foam board layer to a supporting wall, adhering a reinforcing layer, consisting of a cemetitious material and glass fabric, over the foam board layer, and finally applying a finish coating of a mixture of a mineral aggregate and a binder. A less labor intensive method would be advantageous, with respect to this prior method. 
     SUMMARY OF THE INVENTION 
     The present invention consists of a laminated panel, produced on a continuous conveyor, which includes a gypsum sheathing board, a plastic foam board and a third layer including reinforcing mesh and a cement binder. 
     The product is formed by continuously disposing plastic foam board on top of gypsum sheathing on which an adhesive material was continuously deposited, following which the third layer of a reinforcing mesh and a cementitious binder is continuously deposited on the foam board. 
     The laminated panels are erected to form the base for a curtain wall by affixing the panels to nonload-bearing metal studs. The panels are affixed to the studs either immediately prior to erecting the studs or after the studs are affixed in their normal spaced parallel vertical positions. The panels are affixed to the studs by self drilling, self tapping drywall screws which are forced through all layers of the panel and into the metal stud by a powered screw gun having a screw depth guide which stops the advance of the screw when the guide contacts the fabric reinforced layer of the panel, which is also when the screw head has finished passing through the foam board layer and is contacting and firmly holding the gypsum board layer against the metal stud. 
     It is an object of the present invention to provide a novel advantageous, laminated product for use in constructing building curtain walls. 
     It is a further object to provide a novel method for making laminated curtain wall panels. 
     It is a still further object to provide a novel method of affixing laminated curtain wall panels to building framing members. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     These and other objects and advantages will be more readily apparent when considered in relation to the preferred embodiments, as set forth in the specification, and shown in the drawings, in which: 
     FIG. 1 is an isometric end view of the curtain wall panel of the present invention. 
     FIG. 2 is a diagrammatic side view of the apparatus and process for making the panel of FIG. 1. 
     FIG. 3 is a cross sectional side view of the panel of FIG. 1 being affixed to a metal stud. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring to FIG. 1, there is shown a laminated panel 10 consisting of a gypsum sheating board 12, a plastic foam insulation board 14, and a third layer 16 consisting of a web of fiber glass mesh 18 embedded in a latex-modified Portland cement mortar 20. 
     In the preferred embodiment, gypsum sheathing boards 12, typically 4&#39;×8&#39;×1/2&#34;, are continuously laid on a conveyor 22, end to end, as the conveyor moves forward, passing the boards 12 under a roll coater 24 which applies a continuous coat 26 of polyvinyl alcohol adhesive onto the top face of the boards 12. Immediately following the application of the adhesive coat 26, plastic foam boards 14, typically 4&#39;×8&#39; polystyrene bead boards having a thickness of between about 1/2&#34; to 3&#34;, are continuously alined with and laid on each gypsum board 12 adhered thereto. 
     As the conveyor continues to move forward with the laminated gypsum boards 12 and foam boards 14, a continuous web of fiber glass mesh 18 is fed from a roll 28 onto the upper face of the foam board 14 and disposed to cover the entire width of the foam board 14 and advance with the foam board 14 as they pass under a hopper of latex-modified Portland cement mortar 20. 
     The web of fiber glass mesh 18 is preferably an open mesh scrim having about 36 openings per square inch and a thickness of about 0.012 inch. Immediately after the fiber glass mesh 18 is laid on the top of the foam boards 14, a layer of mortar 20, about 0.016 inch thick, is deposited on the top of the foam boards 14, surrounding and embedding the mesh 18 within the mortar 20, bonding the mesh 18 to the top of the foam boards 14. 
     In the preferred form, the foam boards 14 have a shallow wide tapered edge 30 along each side, on the surface, to which the fiber glass mesh 18 and the mortar 20 conform, producing a similar tapered edge 32 on the mortar surface. The tapered edges 30 and 32 may have a width of about one and a half inches and a taper depth of about 3/32 inch. 
     The 0.016 inch thick layer of mortar 20 is made reasonably smooth by a light screeding which maintains the desired thickness of mortar across the width of the laminated panels 10 and improves the adhesion of the mortar to the foam board 14. After forming the mortar and mesh third layer 16, the mesh 18 is cut at the abutting ends of foam boards 14, and the mortar 20 is also severed, forming the individual panels 10, with settable mortar 20 in the third layer 16. 
     The panels 10, with the settable mortar 20, are then conveyed through a drying oven 34 to partially dry the mortar and accelerate the setting of the mortar to an extent that makes the panels capable of being handled and removed from the conveyor. 
     The mortar composition is of a formula approximately as follows: 
     
         ______________________________________                Pounds______________________________________Sand                   72Acrylic Latex Emulsion (50% solids)                  15Thickener              0.5Defoamer               0.25Ammonia                0.1Preservative           0.02Water                  13Type I Portland Cement 100______________________________________ 
    
     The sand is a Martin Marietta Corporation 420 grade fine sand. The acrylic latex emulsion may be Rhom &amp; Haas Co. latex E 330 or Rhoplex AC-64. The thickener is Rohm &amp; Haas Co. Acrysol TT 615 acrylic acid thickener. The defoamer is Drew Chemical Corp. 483 L. The preservative is Merck &amp; Co., Inc. Tektamer 38 AD. 
     When the mortar 20 has reached substantially full set strength, the panels 10 may be shipped for use in constructing the curtain walls of building. It is contemplated that the panels 10 be screw attached to screwable sheet metal drywall studs 36, as shown in FIG. 3. The panels may be attached to the studs either just prior to erection of the studs, or at any time subsequent to the erection of the studs. 
     The panels 10 are affixed to the studs by a modified power operated screw gun 38, having a special elongated screw driver attachment 40. Attachment 40 has an end for receiving and holding screws 42. Attachment 40 is essentially a screw driver shaft having a diameter substantially equal to the diameter of the head of the screw 42 and a length equal to the total thickness of the foam board 14 and the third layer 16, whereby screw gun 38 is able to drive a screw completely through panel 10 and the abutting flange 44 of the screw stud 36, with the head 46 of the screw 42 engaging and holding the gypsum sheating board 12, having passed completely through the foam board 14 and the third layer 16. 
     The attachment of panel 10 to the stud 16 is substantially stronger by having the screw head engaging the gypsum sheathing board layer, as opposed to having a longer screw with the screw head engaging the third layer. Heat transmission through the full thickness of the panel is avoided by using the shorter screws as compared to long screws engaging the third layer. 
     To make certain that the screw head firmly engages the gypsum sheathing board layer without penetrating through the surface of the gypsum board, a depth guide 48 is affixed to the special attachment 40. Depth guide 48 is mounted a fixed distance from the end of attachment 40 such that engagement of guide 48 against the surface of the third layer 16 occurs simultaneously with the screw head 46 engaging the gypsum sheathing board 12. 
     After the studs 36 are in their mounted vertical position and the panels 10 are all affixed thereto, the joints are covered with a reinforcement, prior to the application of a finish veneer stucco over the entire surface. The reinforcing includes a narrow tape of fiber glass leno weave mesh. Preferably the tape is one and a half inches wide, 0.008 inch thick and about 10×10 per inch mesh. 
     The tape is applied, centered over each joint, with a joint compound as follows: 
     
         ______________________________________               Pounds______________________________________Ground Silica         10Type I Portland Cement                 10Acrylic Latex Emulsion (50% solids)                  1Water                 Sufficient to                 trowel______________________________________ 
    
     The ground silica is #270 grade from Ottawa Industrial Sand Co. 
     When the joint concealing treatment is finished, veneer stucco finish is applied over the mesh-mortar surface and the joint treatment surface. The finish material may be a mixture of latex and sand applied in a thickness of 1/32&#34; (about 1/2 lb of wet material/ft 2 ) or a sand-latex-portland cement mixture. 
     The sand-latex mixture works well when applied in thin thicknesses, however if thicker coatings, for improved impact resistance, are required, the sand-latex-cement-mixture will allow application of thicker coatings 1/2-2 lb/ft 2  without check cracking the surface during the drying and setting stage. 
     An example of a sand-latex finish coat is as follows: 
     
         ______________________________________                Pounds______________________________________Fine Sand              450.0Coarse Sand            150.0Acrylic Latex Emulsion (50% solids)                  230.0Thickener              2.0Defoamer               2.5Ammonia                0.5Ethylene Glycol        20.0Attapulgite Clay       8.5Coalescent             3.5Mildew Preventative    3.0Dispersant             0.25Wetting Agent          0.25Water                  67.0Water added on-site up to                  10.0______________________________________ 
    
     Except for the on-site water, these ingredients may be factory mixed, packaged and stored, prior to use. 
     The coalescent is Eastman Chemical Products Inc. Texanol. The mildew preventive is Rohm &amp; Haas Co. Super Ad-it Mildew-aid. The dispersant is R. T. Vanderbilt Co. Darvan aryl alkyl sulfonate. The wetting agent is Rohm &amp; Haas Co. Triton CF 10. 
     An example of a sand-latex-cement finish coat is as follows: 
     
         ______________________________________            Pounds______________________________________Fine Sand          65.6Dry Latex          2.15Defoamer           .40Methylcellulose    .10White Portland Cement              28.0Hydrated Type S Lime              3.75Water added on-site              20.0______________________________________ 
    
     Except for the on-side water, these ingredients may be factory mixed, packaged and stored, prior to use. 
     The dry latex is Air Products &amp; Chemicals Inc. RP 246 ethylene vinyl acetate. The methylcellulose is Henkel Corp. Culminol 20000 PFR. 
     Upon drying and hardening of the finish material, a completed exterior surface of a very permanent nature is produced, having good insulating properties and highly acceptable aesthetic properties. 
     Having completed a detailed disclosure of the preferred embodiment of our invention so that those skilled in the art may practice the same, we contemplate that variations may b made without departing from the essence of the invention or the scope of the appended claims.