The present exemplary embodiments relate to the construction arts. They find particular application in conjunction with exterior insulation and finish systems (EIFS), and to a hand tool for use therewith, and will be described with particular reference thereto. However, it is to be appreciated that the present exemplary embodiments are also amenable to other like applications.
Basic drainage type exterior insulation and finish systems (EIFS) and construction techniques therefor are well known in the art. In the general case, as shown in
Using a paint roller, an adhesive and seal layer 14 is applied onto the first layer 12 of sheathing. Preferably, the adhesive is water based and fast drying and, once dried, is flexible so as to bridge normal movement in the first layer 12. The adhesive and seal layer 14 forms a weather proof seal for the first layer 12.
After drying, an insulation board 16 is adhered to the first layer 12 by the adhesive and seal layer 14. In the prior art system illustrated, the insulation board 16 is special in that it includes a plurality of grooves 18 provided for purposes of conducting fluid which may accumulate between the insulation board 16 and the first layer 12.
An initial base coat 20 is then applied to the surface of the insulation board 16 opposite the surface which is secured to the substrate layer 12 by the adhesive and seal layer 14. The initial base coat may be applied over the insulation board with spray equipment or a trowel to a uniform thickness. Next, a mesh layer 22 is immediately embedded in the wet base coat 20 by troweling or using other techniques. An additional base coat 24 may be applied over the surface of the mesh material 22 as needed and, lastly, a finish coat 26 is applied to the base coat 24 by spraying or troweling, depending on the specific finish desired.
Although drainage type EIFS of the type described above have been very successful, some limitations in application have been encountered. More particularly, the insulation board 16 must either be provided with a plurality of grooves 18, or have some other means in order for the system to properly conduct fluid. Also, during installation, the grooved insulation board 16 must be oriented in the proper direction with the grooves 18 oriented vertically and facing the sheathing substrate 12 of the structure. Still further, although the system described above functions to conduct fluid, care is required in order to position ends of insulation boards 16 so that the grooves 18 formed are in alignment to provide a continuous fluid evacuation conduit. Also, a delay is necessary to allow the seal coating to fully cure prior to adhering the insulation board. Such a delay is usually a minimum of 24 hours and can result in additional costs to the contractor both in delays as well as costs of providing weather protection for the additional time cause by the delay.
Lastly, if construction workers are impatient or for other reasons apply the insulation board 16 onto the sheathing 12 before the adhesive layer 14 is adequately cured, the adhesive layer material could migrate into the grooves 18 formed in the board 16 and thereby obstruct the fluid path.
Accordingly, there is a need for an improved method and tool for installing exterior insulation and finish systems which overcomes the above limitations and others and provides an inexpensive and convenient solution thereto.
In accordance with one aspect of a first present exemplary embodiment, a drainage type exterior insulation and finish system for a building is provided. The system is applied over a sheathing substrate and includes an insulation board, a single adhesive and sealing layer, a base coat, a mesh layer, and a finish layer. The sheathing substrate is adapted for attachment to a frame of an associated building or other structure. The single adhesive and sealing layer adhesively secures the insulation board to the sheathing substrate. The layer is disposed between the sheathing substrate and the insulation board and defines at least one via adapted to conduct fluid such as water for example. The base coat is applied onto the insulation board, followed by a mesh layer, and then a finish layer. In its preferred form, the sheathing substrate has a flat front face and the insulation board has opposite flat front and rear faces. The flat rear face of the insulation board is oriented toward the flat front face of the sheathing substrate with the at least one via being defined by the single adhesive and sealing layer and disposed between the sheathing substrate and the insulation board. In another form, a plurality of viae are defined in the single adhesive and sealing layer to conduct fluid therethrough.
In accordance with an aspect of a second exemplary embodiment, an exterior insulation and finish system for use with associated insulation and substrate layers of a building is provided: The exterior insulation and finish system includes primary and secondary water resistive barriers. The primary water resistive barrier is disposed on a first surface of the associated insulation layer. The secondary water resistive barrier is disposed on a second surface of the associated insulation layer. The secondary water resistive barrier includes a single adhesive and sealing layer defining at least one channel and adhesively securing the second surface of the associated insulation layer to the associated substrate layer. In one form, the single adhesive and sealing layer defines a plurality of channels, each being adapted to conduct fluid therethrough. The channels are formed between the second surface of the insulation layer and a surface of a groove provided in the single adhesive and sealing layer.
In accordance with an aspect of another exemplary embodiment, an exterior insulation and finish system for a building is provided. The system is applied over a sheathing substrate for attachment to a frame of an associated building, and includes first and second insulation boards, a single adhesive and sealing layer securing the insulation boards to the sheathing substrate and defining at least one via adapted to conduct fluid, a base coat, a mesh layer, and a finish layer. The at least one via defined by the single adhesive and sealing layer extends from a first location disposed between the sheathing substrate and the first insulation board to a second location disposed between the sheathing substrate and the second insulation board. In that way, at least one via is provided between the insulation boards and the sheathing substrate and extending between the first and second insulation boards. In another form, the at least one via extends uninterrupted from the first location to the second location. Still further, a plurality of viae are provided. They are defined by the single adhesive and sealing layer and extend uninterrupted from the first location to the second location.
In accordance with a still further aspect of another exemplary embodiment, an exterior insulation and finish system is provided for use with associated first and second insulation panels applied over an associated substrate layer of a building. The system includes primary and secondary water resistive barriers. The primary water resistive barrier is disposed on a first surface of the associated first and second insulation panels. The secondary water resistive barrier is disposed on a second surface of the associate first and second insulation panels. The secondary water resistive barrier includes a single adhesive and sealing layer defining at least one channel and adhesively securing the second surface of the associated first and second insulation panels to the associated substrate layer with at least one edge of each of the first and second insulation panels being in substantial abutment. The at least one channel extends from the first insulation panel to the second insulation panel and is adapted to conduct fluid therethrough.
Still further, in accordance with yet another aspect of an exemplary embodiment, a hand tool is provided for working an adhesive and sealing layer in an exterior insulation and finish system. The hand tool includes a flat inflexible rectangular plate connected with a handle. At least a first one of the longer edges of the inflexible rectangular plate is upwardly curved and includes a plurality of spaced apart teeth. In use, the plurality of teeth form grooves defining the viae and channels described above for conducting fluid between the sheathing substrate and the insulation board. Preferably, the plurality of spaced apart teeth are defined by a plurality of notches formed in the longer edge of the rectangular plate of the hand tool. In their preferred form, the plurality of notches include an elongate first section having a substantially uniform predefined width terminating at a rounded bight having a diameter substantially conforming to the uniform predefined width of the first section of the notches.
The invention may take form in certain components, structures, and steps, the preferred embodiments of which will be illustrated in the accompanying drawings.
a is an enlarged view of portion A from
The exemplary embodiment has been described with reference to the preferred embodiments. Obviously, modifications and alterations will occur to others upon reading and understanding the preceding detailed description. It is intended that the exemplary embodiment be construed as including all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.
With reference to the drawings in general, and to
The exterior insulation and finish system includes an adhesive and sealing layer 34 that is applied to the sheathing or other outer layer 32 of the associated building using a hand tool, the details and use of which will be described in greater detail below. Preferably, the adhesive is 100% water based and fast drying so as to decrease installation time. Preferably, the adhesive and sealing layer 34 is a polymer modified cementitious material available from Dryvit Systems, Inc. Once dried, the adhesive and sealing layer is preferably sufficiently flexible so as to permit normal movement and bridge across gaps in the sheathing layer 32. The adhesive and sealing layer 34 forms a water resistant seal for the sheathing layer 32. More particularly, as illustrated, the adhesive and sealing layer 34 is applied onto the outer layer 32 of the associated building (not shown) in a manner to result in a first portion 38 of material having a substantially uniform thickness to completely cover the substrate 32, and a second portion 40 having a non-uniform thickness to provide at least one via 42 for conducting fluids therethrough.
Immediately following the application of the adhesive and sealing layer 34 of the present EIFS, an insulation board 44 element of the EIFS having a flat front face 46 is adhered to the first sheathing layer 32 by the adhesive and seal layer 34. Simple hand pressure is applied over the entire insulation board surface to ensure a complete bond. It is to be appreciated that many types of insulation boards can be used equivalently including polisocyanurate board and others.
A further element of the EIFS includes an initial base coat 50. The initial base coat is applied to the flat outer surface 48 of the insulation board 44 which is secured to the substrate layer 32 by the adhesive and seal layer 34. The base coat 50 is applied over the insulation board using spray equipment, a trowel, or the like, to realize a uniform thickness of approximately 1/16 of an inch.
Another component of the EIFS includes a mesh layer 52. The mesh layer is embedded into the base coat 50 while it is wet by troweling from the center of the mesh toward the outer edges. In some cases, additional base coat material 54 may be applied over the surface of the mesh material 52 in order to ensure that the mesh is completely embedded into the base coat 50.
Lastly, a further component of the EIFS includes a finish coat 56 of an acrylic base or silicone enhanced textured wall coating applied onto the base coat 54. The finish coat 56 is applied by spraying, rolling, troweling, or the like, depending on the specific finish desired.
In
With continued reference to
With continued reference to
The subject exterior insulation and finish system 30 is installed onto the substrate 32 of the associated building using a hand tool 100, preferably the trowel 102 described above, by dragging the trowel across an adhesive and sealing layer 34 applied onto the sheathing layer 32. The trowel both “plows” through and “floats” on a thick layer 130 of adhesive and sealing material as shown in
More particularly, with reference next to
The invention has been described with reference to the preferred embodiments. Obviously, modifications and alterations will occur to others upon reading and understanding the preceding detailed description. It is intended that the invention be construed as including all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.
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Number | Date | Country | |
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20070011986 A1 | Jan 2007 | US |