EP1230039A2 - Method of applying a powder coating to a non-metallic substrate - Google Patents

Abstract

A method of applying a powder coating to a non-metallic substrate such as a length of a lignocellulosic material, e.g a length of wood, is disclosed. The substrate is impregnated or has applied to the surface thereof, a composition containing a pre-accelerated, unsaturated polyester resin containing a latent catalyst therefor, either dissolved in a suitable non-aqueous solvent or mixed or dispersed in water. Thereafter the non-aqueous solvent or water is removed, and the substrate is placed in an electrostatic field or in a fluidised bed and a powder coating composition is applied thereto. The substrate is then subjected to an elevated temperature to polymerise and/or cross-link the polyester resin in or on the substrate and to cure the powder coating composition to form the powder coating. The result is a product with a decorative powder coating which may be used for many purposes.

Description

I

METHOD OF APPLYING A POWDER COATING TO A NON-METALLIC SUBSTRATE

BACKGROUND OF THE INVENTION

This invention relates to a method of applying a powder coating to a non-metallic substrate, such as for example cement bound particle board

Powder coating is the term given to the application of a decorative coating principally to metallic articles The coating is applied to the article in an electrostatic field by propelling dry pigmented particles from a special gun, which is friction or electrostatically activated, towards the article the particles being attracted to the article by electrostatic forces The particles adhere to the surface of the article, and depending upon the force of the electrostatic field, successive particles adhere until the required build up is achieved whereafter any surplus powder falls from the article and may be recovered The article is then moved through a suitable oven at elevated temperatures usually in the range of 140°C, to 185°C, or at lower temperatures in the presence of ultra violet light, to cause the powder particles to melt, flow, coalesce and cure to form a coating

The advantages of powder coating are that a wide variety of textures and surface finishes may be achieved, the coatings are very tough and resistant to wear and in exterior grades resistant to weathering In addition, the powder coating method is solventless and because the powder can be recovered for reuse, wastage is virtually nil The thickness of the coating on the article may be very accurately controlled Further, the method is of particular application to articles of complex shape Powder coatings are further characterised by their flexibility and adhesion so that, after powder coating, an article such as a flat sheet may be post formed over curves or edges

One powder coating technique requires that the article to be coated must be able to sustain an electrostatic field for the particles of the powder coating composition to adhere thereto It is possible that an article which does not retain an electrostatic field could be dampened or wetted in order for the particles of the powder coating composition to adhere to the article However oven heating of the article may lead to the commencement of decomposition or to "blowing' as gasses escape through the coalescing powder film from the heated article The alternative is fusion coating wherein the article is preheated before applying the powder coating, such as in a fluidized bed

PCT Patent Application No PCT/GB 97/01464 (WO 97/45591 ) to Windsor Technologies Limited teaches a method of applying a powder coating to a length of a lignoceliulosic material The method includes the steps of impregnating the material with an impregnating composition comprising either a dicarboxylic anhydride or a tπcarboxylic anhydride dissolved in a suitable non-aqueous solvent or an isocyanate thermosetting resin dissolved in a suitable non-aqueous solvent or a combination of the two, if necessary removing from the impregnated length of material any excess of the impregnating composition removing the non-aqueous solvent or solvents, placing the impregnated length of lignoceliulosic material in an electrostatic field or in a fluidised bed and applying a powder coating composition thereto so that the powder coating composition adheres thereto and then subjecting the length of lignoceliulosic material to elevated temperatures to polymerise and/or cross-link the resin or resins in the length of lignoceliulosic material and to cure the powder coating composition to form the powder coating

This method can suffer the disadvantage of carbon dioxide emission as a by-product of the chemical reaction between an isocyanate thermosetting resin and either water or the celluloses

UK Patent No 1 ,348,272 teaches the powder coating of a length of paper while still damp with abrasion resistant particles, such as quartz or corundum, in which the electrostatic attraction is achieved by the presence of water This however necessitates the drying of the material before the curing of the either pre- or post- applied thermosetting resin

European Patent Application No 636669 to DSM N V teaches a radiation curable binder composition for powder paint formulations The binder composition comprises a polymer having a degree of unsaturation between 300 and 1800 grams per mole of unsaturated group (WPU), having a molecular weight n between 800 and 6800 and a viscosity between 1 dPas and 800 dPas, and a cross-linking agent having vinyl ether, vinyl ester or (meth)acrylate functional groups The polymer is preferably an unsaturated polyester and/or an unsaturated polyacrylate The binder composition can be used in the preparation of powder paint formulations which can be applied to heat-sensitive substrates such as wood and plastic and which can be cured with UV or electron beam radiation

There is a need for a method by which a non-metallic substrate can be powder coated

SUMMARY OF THE INVENTION

According to the invention there is provided a method of applying a powder coating to a non-metallic substrate which includes the steps of

(a) impregnating the substrate or applying to the surface of the substrate a composition containing a polyester resin which is selected from (i) a pre-accelerated, unsaturated polyester resm containing a latent catalyst therefor, dissolved in a suitable non-aqueous solvent, and

(n) a pre-accelerated , unsaturated polyester resm containing a latent catalyst therefor mixed or dispersed in water

(b) removing the non-aqueous solvent or water,

(c) placing the substrate from step (b) in an electrostatic field or in a fluidised bed and applying a powder coating composition to the substrate so that the powder coating composition adheres to the substrate, and

(d) then subjecting the substrate of step (c) to an elevated temperature to polymerise and/or cross-link the polyester resm in or on the substrate and to cure the powder coating composition to form the powder coating

The non-metallic substrate may be for example a length of a lignoceliulosic material, e g a length of paper or cardboard or wood, a length of a fibre board such as medium density fibre board, high density fibre board, or a fibre reinforced phenolic composite, a cementitious product such as a fibre cement or cement bound particle board, or a cement expanded mineral composite product, or the like

The method of the invention may include various optional steps

(e) after step (b) and before step (c) pre-heating the substrate or

(f) after step (b) and before step (c) subjecting the substrate to a vacuum or

(g) after step (b) and before step (c) pre-heating the substrate and then subjecting the substrate to a vacuum

In step (a) the composition may include a dicarboxylic anhydride or a tπcarboxylic anhydride dissolved in a suitable solvent such as a non-aqueous solvent which may be the same as or compatible with the non-aqueous solvent for the polyester resm, or such as water

In step (a) the composition may also include a styrene polymer dissolved in a suitable non-aqueous solvent which may be the same as or compatible with a non- aqueous solvent for the polyester resm DESCRIPTION OF EMBODIMENTS

The crux of the invention is that a non-metallic substrate is either impregnated or surface coated with a polyester resm and in this way is modified so that it induces an electrostatic attraction that the surface of the substrate is stabilised, hardened and strengthened, that the polyester resm in the treated substrate forms a chemical linkage to the applied powder coating, and that the chemical reactions involved do not emit a gas, which all contribute to the successful powder coating of the substrate

Step (a) of the method of the invention is to impregnate the substrate or to apply to the surface of the substrate a composition comprising a pre-accelerated polyester resin containing a latent catalyst therefor either dissolved in a suitable non-aqueous solvent or mixed or dispersed in water

The polyester resin may be any suitable unsaturated polyester resm An example of a suitable resin is an isophtha c neopentyl glycol unsaturated polyester resm, developed for applications where good chemical and water resistance are essential A specific example is NCS Ultraset 993 by NCS Resins of South Africa which is especially designed for filament winding, marine swimming pools and PVC laminate applications This resm has the following properties

Good stain and thermal shock resistance,

Good heat and chemical resistance to a wide range of aggressive environments, including alkaline conditions

TYPICAL LIQUID PROPERTIES

PROPERTY SPECIFICATION NCS

TEST

METHOD

Viscosity @ 25°C mPa s 540-800 5,3

Acid value, mg KOH/g 10-16 13

Geltime @ 25°C, 2 phr^* CATALYST M and 4 i phr^*

ACCELERATOR ULTRACURE AC9 minutes 7-1 1 8

Liquid appearance Clear pale yellow 2

Stability in the dark @ 25°C months 5 minimum 4 1

^* = parts per hundred resm, by mass Another option is to combine a rigid polyester resin such as NCS 33410 which is a rigid isophthalic resm with an adipic acid modified unsaturated polyester resin, particularly the isophthalics such as 8130 by NCS Resins of South Africa, added in an amount of up 50% by weight of the rigid polyester resin, so as to render the resin more flexible The properties of cured 8130 are

*Fιltered resm, void-free casting

The unsaturated polyester resin must be pre-accelerated The resm is pre- accelerated typically with a cobalt naphthanate or a cobalt octoate in white spirits, in an amount of from 0,25% to 1 ,5% inclusive by weight on the weight of the resin The resin is thereafter catalysed with a latent catalyst which will decompose and trigger polymerisation at temperatures in the region of 60°C upwards, more typically above 80°C Examples of suitable latent catalysts are a di-tertiary-butyl peroxy 3,3,5-trι- methyl cyclohexane in tπ-butyl phthalate such as Tπganox 29B 240 or Tπganox 29B 50 by Akzo Chemie and benzoyl peroxide formulations such as tert-butyl perbenzoate, sold by Interox under the codes TBTB and others

The unsaturated polyester resin may be dissolved in a suitable non-aqueous solvent The choice of solvent is dictated by cost toxicity evaporative rate and compatibility with the other components of the composition Examples of suitable non-aqueous solvents are dichloromethane and acetone

In the alternative, the unsaturated polyester resin may be one which is dispersible or miscible in water, in which case water may oe used as the carrier

The composition preferably contains the polyester resin in an amount of from 15% to 40% inclusive of the polyester resin by weight of the composition The remainder of the composition is made up of the non-aqueous solvent or water, optionally an additional component such as an anhydride or a styrene polymer as is discussed in more detail below, the pre-accelerator, and the catalyst The catalyst is preferably present in an amount of from 0 2% to 0,8% by weight of the composition

The composition may also include a dicarboxylic anhydride selected from the group consisting of maleic anhydride, phthalic anhydride succmic anhydride and tetrahydrophthahc anhydride or a tπcarboxylic anhydride such as tπmellitic anhydride Preferably the anhydride is maleic anhydride

The anhydride is dissolved in a suitable solvent which must be compatible with the solvent for the resin, or water Preferably, the anhydride is dissolved in the same solvent as the resm, for example dichloromethane or acetone

The purpose of the anhydride is to maximise the electrostatic attraction of the treated non-metallic substrate It is also chosen for compatibility with the polyester resm The preferred anhydride is maleic anhydride which has a di-electπc loss factor of 0,97 in dichloromethane

The anhydride is preferably present in an amount of from 1 % to 6%, more preferably from 1 to 4%, by weight of the composition

The composition may also include a styrene polymer, e g a styrene homopolymer, copolymer or terpolymer

Thus, the styrene polymer may be a homopolymer, e g polystyrene, or a copolymer such as styrene acrylonitπle or styrene polybutadiene, or a terpolymer such as acrylonitnle polybutadiene styrene or a blend between them

The use of a styrene polymer imposes resistance to water uptake and to water ingress on the treated material minimises dimensional change, particularly shrinkage on drying, improves hardness In addition, styrene polymers have high resistance to chemicals

The homopolymer polystyrene itself is very hard Polystyrene has a specific gravity of 1 ,05 to 1 ,07 and a percentage water absorption after 24 hours of immersion of between 0,04 and 0,06% The copolymerisation of styrene with another monomer imposes special properties such as toughness Again, the styrene polymer may be dissolved in any suitable non-aqueous solvent which may be the same as, or compatible with, the solvent used for the polyester resin Thus, the styrene polymer may be dissolved in dichloromethane or acetone, or may be dissolved in toluene to render it compatible with the polyester resin composition

The styrene polymer is preferably present in an amount of from 1 % to 5% by weight of the composition

The substrate may be impregnated with the composition in any suitable manner Examples of methods of impregnation are to be found in PCT/GB 97/00440 (WO 97/32074) and PCT/GB 97/01464 (WO 97/44591 ) both of which are incorporated herein by reference

For example, the impregnation may be carried out by irrigating the substrate with the composition or by immersing the substrate in the composition

Alternatively, the substrate may simply be surface coated with the composition, again in any suitable manner, such as for example by spraying

After step (a), if necessary there may be removed from the impregnated or coated substrate any excess of the composition

In step (b), the non-aqueous solvent or the water is removed This may be achieved using electronically induced heat such as infrared induced heat, or any other suitable method When the solvent is a non-aqueous solvent it may be recaptured for reuse

After step (b) and before step (c) the treated substrate may be pre-heated or may be subjected to a vacuum or may be pre-heated and then subjected to a vacuum, the purpose being to de-gas and de-humidify the substrate to minimise gassing during the powder coating step

In step (c) of the method of the invention the substrate is placed in an electrostatic field or in a fluidised bed and a powder coating composition is applied thereto Generally, the powder coating composition, in the form of a finely divided pre- formulated dry powder, is propelled towards the surface of the substrate from a suitably charged applicator gun, either friction or electrostatic, such that the particles of the powder coating composition adhere to the surface of the substrate Electrostatic charged guns are preferred such as the Super Carona by Gema Any particles of the powder coating composition that do not adhere to the surface of the substrate, fall from the substrate and may be recovered

Examples of suitable powders are polyurethanes or epoxy polyesters for interior use or pure polyesters for exterior use, in gloss, suede or matte, in textures, hammer tones, metallics, pearlescents, wrinkle finishes or multi colours Curing temperatures are from as low as 100°C in the presence of ultra violet light using photosensitive catalysis, or in the range of 140°C -185°C with a cure time of 5 to 15 minutes

In step (d) of the method of the invention, the substrate is subjected to an elevated temperature to polymerise and/or cross-link the polyester resin in or on the substrate and to cure the powder coating composition to form the powder coating

For example, the length of the substrate may be passed through a space heater in which the temperature of the substrate is raised to a level above 140^CC, more usually up to 185°C

A preferred form of heating is surface heating using infrared

At the conclusion of the heating step the powder coating composition is fully cured

An example of the invention will now be given

A typical formulation of a composition for impregnation or surface coating of a substrate is as follows Acetone 350

NCS Ultraset 993 accelerated with cobalt naphthanate 80

Tπganox 29B50 2

Maleic anhydride J2

Total 444

(All parts by weight)

A substrate such as a length of medium density fibre board is impregnated with the above composition and any excess of the composition is then removed

Thereafter, the acetone is removed by heating

Thereafter, the treated substrate is powder coated with a suitable powder coating composition and the polyester resm and powder coating are then set and cured

The result is a length of medium density fibre board with a decorative powder coating, which may be used for the formation of wall units or cupboards or the like

Other products that may be produced by the method of the invention include roof sheeting, architectural mouldings materials for use for lamination to other substrates, and the like

Claims

A method of applying a powder coating to a non-metallic substrate including the steps of

(a) impregnating the substrate or applying to the surface of the substrate a composition containing a polyester resin which is selected from

(i) a pre-accelerated unsaturated polyester resm containing a latent catalyst therefor, dissolved in a suitable non-aqueous solvent, and (n) a pre-accelerated, unsaturated polyester resm containing a latent catalyst therefor, mixed or dispersed in water

(b) removing the non-aqueous solvent or water,

(c) placing the substrate from step (b) in an electrostatic field or in a fluidised bed and applying a powder coating composition to the substrate so that the powder coating composition adheres to the substrate, and

(d) then subjecting the substrate of step (c) to an elevated temperature to polymerise and/or cross-link the polyester resm in or on the substrate and to cure the powder coating composition to form the powder coating

A method according to claim 1 wherein the non-metallic substrate is selected from the group consisting of a length of a lignoceliulosic material, a length of a fibre board, and a cementitious product

A method according to claim 1 or claim 2 which includes the step of

(e) after step (b) and before step (c) pre-heating the substrate

A method according to claim 1 or claim 2 which includes the step of

(f) after step (b) and before step (c) subjecting the substrate to a vacuum

A method according to claim 1 or claim 2 which includes the step of (g) after step (b) and before step (c) pre-heating the substrate and then subjecting the substrate to a vacuum A method according to any one of claims 1 to 5 wherein in step (a) (i) the non- aqueous solvent is selected from dichloromethane and acetone

A method according to any one of claims 1 to 6 wherein in step (a) the composition contains the polyester resm in an amount of from 15% to 40% inclusive of the resm by weight of the composition

A method according to claim 7 wherein in step (a) the composition contains the latent catalyst in an amount of from 0,2% to 0,8% inclusive of the latent catalyst by weight of the composition

A method according to any one of claims 1 to 8 wherein in step (a) the composition includes a dicarboxy c anhydride or a tπcarboxylic anhydride dissolved in a solvent

A method according to claim 9 wherein the solvent selected from a non- aqueous solvent which is the same as or compatible with the non-aqueous solvent for the polyester resin, and water

A method according to claim 9 or claim 10 wherein in step (a) the composition contains the dicarboxyhc anhydride or tπcarboxylic anhydride in an amount of from 1 % to 6% inclusive of the anhydride by weight of the composition

A method according to claim 11 wherein in step (a) the composition contains maleic anhydride in an amount of from 1% to 4% inclusive of the anhydride by weight of the composition

A method according to any one of claims 1 to 12 wherein in step (a) the composition includes a styrene polymer dissolved in a solvent

A method according to claim 13 wherein in step (a) the composition contains the styrene polymer in an amount of from 1 % to 5% inclusive of the styrene polymer by weight of the composition A method according to any one of claims 1 to 14 wherein in step (d) the substrate is subjected to an elevated temperature above 140°C for a time sufficient to polymerise and/or cross-link the polyester resin in or on the substrate and to cure the powder coating composition to form the powder coating