CA2241695A1

CA2241695A1 - Insulating compositions

Info

Publication number: CA2241695A1
Application number: CA 2241695
Authority: CA
Inventors: Brian Boudreau
Original assignee: SPECIALTY COATINGS LTD.
Current assignee: SPECIALTY COATINGS Ltd
Priority date: 1998-06-24
Filing date: 1998-06-24
Publication date: 1999-12-24

Abstract

An insulating composition and method is disclosed. The insulating composition comprises an admixture of heat expanded polystyrene (EPS) beads in a liquid, solvent-free binder, comprising an aromatic isocyanate cured with a polyol resin. The ratio of EPS to binder is about 50:1 by volume. The composition is applied to a surface coat of the binder and finished with a top coat of the binder. A reinforcing fabric layer is optimal.

Description

INSULATING COMPOSITIONS
FIELD OF THE INVENTION
The present invention relates to an insulating composition.
BACKGROUND OF THE INVENTION
Insulating compositions which contain expanded polystyrene (EPS) particles bound means of a polymeric binder matrix are well known. As well, it is well known to use polyurethane foam as a spray-on insulating coating. Both of these prior art techniques have disadvantages which limit their applications.
Insulating compositions which use EPS beads and polymeric binders are typically about 80% EPS by volume and utilize aqueous based binding agents because of the susceptibility of EPS to many solvents such as aromatic hydrocarbons, ketones, aldehydes or polyester resins. Suitable binding agents disclosed in the prior art include synthetic resin latex or acrylic resins: see U.S. Patent No. 4,379,857 issued to Hansen et al.
However, such resins are expensive and must be used in ratios of up to 60% by volume of the insulating composition. In contrast, the EPS is very inexpensive and is the primary insulating component in the composition. The resin is non-insulating, therefore, minimizing the binder agent may increase insulating effectiveness as well as reducing expense.
Spray-on polyurethane foam using carbon dioxide as the foaming gas is well known. However, the carbon dioxide leaks out over time and is replaced by oxygen and nitrogen, which are poorer insulators than carbon dioxide. It is also susceptible to consumption by rodents.
The use of EPS foam admixed with a latex resin binder as a roofing material is described in U.S. Patent No. 4,413,026 to Sherno. As disclosed therein, such a composition may be advantageous in comparison to asphalt based roof coating compositions which require a good deal of maintenance and are poor insulators. However, the insulating composition disclosed in this patent still has the disadvantages stated above.
Therefore, there is a need in the art for an insulating composition which maximizes insulation value and cost-effectiveness by minimizing the quantity of the binding agent while avoiding the drawbacks of the prior art. It would be further advantageous if such an insulating composition to moisture proof, rigid and light-weight while providing a structurally strong and permanent base for various applications and roofing applications in particular.
SUMMARY OF INVENTION
In one aspect of the invention and in general terms, the invention comprises an insulating composition comprising a plurality of expanded polyurethane foam particles bond on a solvent-free binder.
In another aspect of the invention, the invention comprises a layered implementing system comprising:
(a) a primer coat layer applied to the substrate to enhance adhesion of an insulating layer to the substrate;
(b) an insulating layer applied over the primer coat layer comprising a plurality of expanded polystyrene particles dispersed in a solvent free polyurethane rubber binder; and (c) a surface finish layer comprising a fabric mesh and at least one sealing coat of the solvent free polyurethane rubber.

DETAILED DESCRIPTION OF THE INVENTION
The insulating composition of the present invention comprises an admixture of heat expanded plastic granules or beads in a liquid, solvent free binder. The heat expanded granules are preferably expanded polystyrene (EPS) granules or beads which are preferably dispersed in the liquid binder. Alternatively, heat expanded materials such as vermiculite or perlite may be used if treated to eliminate or reduce their moisture absorption characteristics.
The EPS beads used are preferably about 5mm in diameter although the actual size of the beads is not critical to this invention. EPS beads or ground EPS particles are well known in the art and are readily commercially available.
The liquid binder is solvent free and is preferably a two component polyurethane rubber comprised of an aromatic isocyanate, preferably diphenylmethane diisocyanate, cured with a suitable polyol resin. The polyol resin comprises polyether polyol and chain extenders consisting of low molecular weight diols, below about 200 grams per mole. The chain extenders preferably comprise about 15% of the polyol resin but may vary from about 5% to about 25%. The polyol resins employed in the present invention are blended in accordance with well-known paint manufacturing processes.
Preferably, the polyol resin is mixed with the isocyanate in a 2:1 to 1:1 ratio by volume.
The polyol resin may optionally contain additives such as pigments, surfactants, catalysts and/or fire retardants. Titanium dioxide may be used as a white pigment. There are many known catalysts which accelerate the curing process such as dibutyl tin.
A fire retardant additive such as a phosphate ester is also optional.
The insulating composition is then prepared by combining the EPS beads with the polyurethane binder at a ratio of approximately 5:3 (resin to EPS) by weight. This is equivalent to a ratio of approximately 1:50 (resin to EPS) by volume. The composition may then be applied to the substrate and allowed to cure. Before the composition is finally cured, it may be levelled, sloped or contoured with relative ease.

In the preferred method of applying the insulating composition, the solvent free polyurethane binder is used as a primer coat layer on the substrate to ensure good adhesion of the insulating composition to the substrate. In the preferred method, one coat of the binder is applied to about a 5 mil thickness.
If the substrate surface temperature could potentially exceed the melting temperature of polystyrene, it may be necessary to provide a heat shielding layer to prevent melting of the EPS component in the insulating composition. It has been found that a layer of ceramic microspheres bound with a polymeric binder is sufficient for most applications.
Z-lightTM spheres from 3M are suitable for this application. Although any latex or polyurethane binder may be used for the ceramic microspheres, it is preferable to use the solvent free polyurethane of the preferred embodiment herein.
In the preferred embodiment, a reinforcing fabric surface finish layer is applied over the insulating EPS layer once the EPS layer has cured. The fabric should preferably exhibit good tensile strength and a tight weave. Preferably, spunbonded polyester, fibreglass mesh, polyester or high density polyester mesh fabric are used. The fabric layer is applied over the EPS layer and at least one coat of the solvent free polyurethane is applied to seal the fabric surface. Preferably, an additional coat or two to provide a top coat of about 30 mil thickness are applied to reinforce the surface. Optionally, prior to the surface finish, a layer of expanded polystyrene board or other suitable roofing board may be applied over the EPS
layer to provide additional insulation and some additional structural strength.
The solvent free polyurethane cured with an aromatic isocyanate such as diphenylmethane diisocyanate is not stable when exposed to ultraviolet light and will discolor or potentially degrade if exposed to UV light. Therefore, if the insulating composition is used in outdoor applications such as a roofing material, then it is preferable to provide an additional top coat which is UV light resistant such as acrylic latex or a two component solvent free polyurethane employing an aliphatic isocyanate in place of the aromatic isocyanate of the preferred embodiment.

As will be apparent to those skilled in the art, various modifications, adaptations and variations of the foregoing specific disclosure can be made without departing from the teachings of the present invention.

Claims

1. An insulating composition comprising in combination:
(a) a plurality of expanded polystyrene foam particles; and (b) a solvent free binder.

2. The insulating composition of claim 1 wherein the binder is comprised of a two-component polyurethane rubber.

3. The insulating composition of claim 2 wherein the polyurethane rubber is comprised of an aromatic isocyanate cured with a suitable polyol resin.

4. The insulating composition of claim 3 wherein the aromatic isocyanate is diphenylmethane diisocyanate.

5. The insulating composition of claim 3 wherein the polyol resin is comprised of polyester polyol and chain extenders comprising low molecular weight diols.

6. The insulating composition of claim 4 wherein the polyol resin further comprises one or more additives chosen from the following group: pigments, surfactants, catalysts and/or fire retardants.

7. The insulating composition of claim 1 wherein the binder is combined with the expanded polystyrene particles at a ratio of about 5:3 by weight.

8. The insulating composition of claim 1 wherein the binder is combined with an expanded polystyrene particles at a ratio of about 1:50 by volume.

9. A layered insulating system applied to a substrate comprising:
(a) a primer coat layer applied to the substrate to enhance adhesion of an insulating layer to the substrate;
(b) an insulating layer applied over the primer coat layer comprising a plurality of expanded polystyrene particles dispersed in a solvent free polyurethane rubber binder; and (c) a surface finish layer comprising a fabric mesh and at least one sealing coat of the solvent free polyurethane rubber.

10. The layered insulating system of claim 9 further comprising a heat shield layer disposed between the primer coat layer and the insulating layer wherein the heat shield layer comprises a plurality of ceramic microspheres dispersed within a suitable binding agent.

11. The layered insulating system of claim 9 further comprising a board layer disposed between the insulating layer and the surface finish layer.

12. The layered insulating system of claim 11 wherein the board layer is comprised of expanded polystyrene board.

13. The layered insulating system of claim 11 further comprising a heat shield layer disposed between the primer coat layer and the insulating layer wherein the heat shield layer comprises a plurality of ceramic microspheres dispersed within a suitable binding agent.

14. The layered insulating system of claim 9 wherein the polyurethane rubber is comprised of an aromatic isocyanate cured with a suitable polyol resin.

15. The layered insulating system of claim 14 wherein the aromatic isocyanate is diphenylmethane diisocyanate.

16. The layered insulating system of claim 15 wherein the polyol resin is comprised of polyester polyol and chain extenders comprising low molecular weight diols.

17. The layered insulating system of claim 16 wherein the polyol resin further comprises one or more additives chosen from the following group: pigments, surfactants, catalysts and/or fibre retardants.

18. The layered insulating system of claim 9 wherein the binder is combined with the expanded polystyrene particles at a ratio of about 5:3 by weight.

19. The layered insulating system of claim 9 wherein the binder is combined with the expanded polystyrene particles at a ratio of about 1:50 by volume.