Techniboard
quartz surfaces patent
Stone-like laminate
Abstract
The present invention relates to a stone like laminate that comprises a
support layer made from a cementious matrix board and a surface layer.
The surface layer comprises a high percentage of particles from an
inorganic material such as stone particles and a low percentage of a
resin, such as a polyester resin. The stone like laminate of the present
invention can be produced at low cost and provides a aesthetic laminate
that is highly resistant to heat, water and pressure.
| Inventors: |
Rochette; Michel; (Ste-Foy, CA)
|
| Correspondence Name and Address:
|
Fronz Bonsang;C/o Protections Equinox Int'l.
224-4480 Cote-de-liesse
Montreal
QC
H4N 2R1
CA
|
| Assignee Name and Adress: |
SURFACES TECHNIBOARD INC.
Lac Beauport
CA
|
| Serial No.:
|
568864 |
| Series Code:
|
10
|
| Filed:
|
August 17, 2004 |
| PCT Filed:
|
August 17, 2004 |
| PCT NO:
|
PCT/CA04/01520 |
| 371 Date:
|
February 21, 2006 |
| U.S. Current Class: |
428/703; 427/180; 427/256; 427/355 |
| U.S. Class at Publication: |
428/703; 427/256; 427/180; 427/355 |
| Intern'l Class: |
B32B 13/00 20060101 B32B013/00; B05D 3/12 20060101 B05D003/12; B05D 5/00 20060101 B05D005/00 |
Foreign Application Data
| Date | Code | Application Number |
|---|
| Aug 28, 2003 | US | 10/604,967 |
| Sep 11, 2003 | CA | 2,441,494 |
Claims
1. A stone-like laminate comprising a support layer and at least one
surface layer disposed over said support layer, said support layer
comprising a pre-cured heat-absorbing cementious matrix board, said
surface layer comprising at least eighty percent particles of an
inorganic material and at most twenty percent of a resin, said resin
being effective to ensure adhesion of said surface layer on said support
layer and to cause said surface layer to form an integral structure.
2. Stone-like laminate according to claim 1, wherein said support layer is
a perforated, scarified or chemically treated pre-cured heat-absorbing
cement board.
3. Stone-like laminate according to claim 1, wherein said surface layer
further comprises heat-conducting particles adapted for enhancing
transfer of heat from said surface layer to said support layer.
4. Stone-like laminate according to claim 1, wherein said surface layer
has a thickness ranging from 0.7 to 10 mm and wherein said support layer
has a thickness ranging between 4 and 40 mm.
5. A stone-like laminate comprising a support layer and at least one
surface layer disposed over said support layer, wherein said support
layer comprises a perforated, scarified or chemically treated pre-cured
heat-absorbing cementious matrix board, wherein said surface layer
comprises at least eighty percent of particles of an inorganic material,
at most twenty percent of a resin and at least one heat-conducting
material in particulate form in an amount effective to enhance transfer
of heat from said surface layer to said support layer, wherein said resin
is effective to ensure adhesion of said surface layer on said support
layer and to cause said surface layer to form an integral structure.
6. Stone-like laminate according to claim 5, wherein said surface layer
has a thickness ranging from 0.7 to 10 mm and wherein said support layer
has a thickness ranging between 4 and 25 mm.
7. A method for producing a stone-like laminate comprising a support layer
and a surface layer disposed over said support layer, which comprises:
providing a support layer having pores or surface irregularities thereon,
said support layer comprising a heat-absorbing cementious matrix board;
applying a thin layer of a resin on at least one surface of said support
layer under conditions to cause said resin to penetrate into the pores or
surface irregularities of said support layer and to form a thin resin
layer; applying a mixture layer comprising at least eighty percent of
particles of an inorganic material and at most twenty percent of
additional said resin on said thin resin layer; compacting said mixture
layer over said support layer; allowing said resin to polymerize to form
said surface layer, and said surface layer to become an integral
structure comprising said thin resin layer and said mixture layer,
8. Method according to claim 7, wherein said support layer is a
perforated, scarified or chemically treated pre-cured heat-absorbing
cementious matrix board.
9. Method according to claim 7, which comprises forming said surface layer
with a thickness ranging from 0.7 to 10 mm and wherein said support layer
has a thickness ranging between 4 and 40 mm.
10. Method according to claim 7, wherein said mixture layer further
comprises heat-conducting particles adapted for enhancing the transfer of
heat from said surface layer to said support layer.
Description
TECHNICAL FIELD
[0001] The present invention generally relates to a stone-like laminate
comprising a support layer made from a pre-cured cementious matrix board
and a surface layer comprising a resin and particles of an inorganic
material.
BACKGROUND ART
[0002] Sheets of polished stone, such as marble or granite, have become
prestigious material in the manufacture of countertops or decorative
panels, especially for their aesthetic characteristics. However, natural
stone sheets are very expensive, mainly due to the cost involved in
shaping and polishing raw stones. In addition, the raw material is
usually obtained from remote regions and therefore, the cost associated
with transportation contributes to increase the already elevated cost of
stone panels. Other drawbacks associated with natural stone panels
include stone imperfections that cause cracking and general fragility of
the sheets and staining and bacteria growth in porosities.
[0003] In the past years, may attempts were made to develop panel products
having the appearance of natural polished stone, while being
substantially more affordable and avoiding problems related to heaviness,
transportation and installation. These engineered stone products are, for
most of them, produced following a so-called "Brenton-Stone" technology,
disclosed in U.S. Pat. No. 4,698,010 to Toncelli. Briefly, this
technology consists in blending a low percentage of a polyester resin
with inorganic particles, such as stone particles to obtain a relatively
dry mass of mixed material. The mixed material is then cured to obtain a
slab, which becomes rigid after polymerization of the resin material.
Such engineered stone products are commercialized under trade names that
include Cambria.RTM., CeasarStone.RTM., Silestones.RTM., Technistone.RTM.
and Zodiaq.RTM..
[0004] Several drawback are however associated with these engineered stone
panels. For example, to prevent bending of large surface panels and
breaking of panels during the polishing process, the slabs must be thick,
being most of the time thicker than 3/4 inch (2 cm). Therefore, the
resulting panels are heavy, difficult to transport and to handle, require
very strong panel supporting structures and cannot be stacked onto one
another. In fact, typical marketed engineered stone products weigh the
same as natural granite, which increases the handling and installation
costs.
[0005] To reduce the thickness or the weight of the engineered stone
material while preserving rigidity and solidity, the prior art discloses
lamination of the engineered stone material on a base layer of wood,
plastic or metal. When unpolymerized material is poured and cured onto
such a layer, shrinkage of polyester resin during polymerization causes a
tension over the layer, which responds by forming a convex shape, a
characteristic that is not a desirable for a panel.
[0006] Other approaches rely on multi-step laminating. Briefly, this
process consists in curing the stone like product, removing it from the
mold and gluing it on a support layer made from wood, metal or plastic
with a special adhesive once it is polymerized. A disadvantage of the
multiple step laminating procedure is that the decorative part is very
thin and therefore fragile to polish. In addition, the decorative layer
being glued to the base layer, small air pocket may be formed between the
support and the decorative layer, creating zones that will eventually
crack under small impact or a heat source. Delamination of the surface
material is also often observed.
[0007] Considering the state of the prior art, it would be highly
desirable to be provided with a laminate panel having the appearance of
natural polished stone, while being light, easy to handle and to
transport, producible at low cost and resistant to bending, delamination
and heat.
DISCLOSURE OF THE INVENTION
[0008] One object of the present invention is to provide a stone-like
laminate comprising a support layer and at least one surface layer
disposed over the support layer. The support layer comprises a pre-cured
heat-absorbing cementious matrix board and the surface layer comprises at
least eighty percent of particles of an inorganic material and at most
twenty percent of a resin. The resin is effective to ensure adhesion of
the surface layer on the support layer and to cause the surface layer to
form an integral structure.
[0009] It is also an object of the present invention to provide a
stone-like laminate comprising a support layer and at least one surface
layer disposed over the support layer, wherein the support layer
comprises a perforated, scarified or chemically treated pre-cured
heat-absorbing cementious matrix board. The surface layer comprises at
least eighty percent of particles of an inorganic material, at most
twenty percent of a resin and at least one heat-conducting material in
particulate form in an amount effective to enhance transfer of heat from
the surface layer to the support layer. The resin of the surface layer is
effective to ensure adhesion of the surface layer on the support layer
and to cause the surface layer to form an integral structure.
[0010] A further object of the present invention is to provide a method
for producing a stone-like laminate comprising a support layer and a
surface layer disposed over said support layer. This method comprises:
[0011] providing a support layer having pores or surface irregularities
thereon, and which consists of a heat-absorbing cementious matrix board;
[0012] applying a thin layer of a resin on at least one surface of the
support layer under conditions to cause it to penetrate into the pores or
surface irregularities of the support layer and to form a thin resin
layer;
[0013] applying a mixture layer comprising at least eighty percent of
particles of an inorganic material and at most twenty percent of
additional resin on the thin resin layer,
[0014] compacting the mixture layer over the support layer;
[0015] allowing the resin to polymerize to form the surface layer, and the
surface layer to become an integral structure comprising the thin resin
layer and the mixture layer.
[0016] For the purpose of the present invention, the term "cementious
matrix board" is intended to mean any a board, panel or the like made
from a cementious material and includes but is not limited to cement
boards, fiber cement boards, light concrete boards cement bonded particle
board, calcium silicate board, other cement base panel product and the
like.
BRIEF DESCRIPTION OF DRAWINGS
[0017] Reference will now be made to the accompanying drawings, showing by
way of illustration, a preferred embodiment thereof, and in which:
[0018] FIG. 1 is a cross-section view of a stone-like laminate according
to one embodiment of the present invention.
[0019] FIG. 2a to 2f are cross-section views of stone-like laminates
according to other embodiments of the present invention.
MODES OF CARRYING OUT THE INVENTION
[0020] The present invention relates to a stone-like laminate comprising a
support layer on which is applied a decorative layer (FIG. 1). The stone
like-laminate of the present invention is a panel, a slab or a sheet
having predetermined dimensions and designed to be used as kitchen
countertops, bathroom vanity tops, shower wall cladding, flooring, table
tops or any other decorative panels The stone like-laminate of the
present invention can be produced as a slab and further cut according to
particular needs. For example, the stone-like laminate of the present
invention can be produced in the same dimensions as other engineered
stone like products known in the art, such as 3/4 inch (2 cm) thick, 10
feet (304.8 cm) long, and 53 inches wide (134 cm). The panel of the
present invention is however preferably 10 mm thick including a 6
mm-thick perforated support layer and a 4 mm-thick surface layer. Since
the panel of the present invention uses resin and other materials more
wisely than other panels known in the art, as it will be described in
more details hereinafter, the stone-like laminate of the present
invention is significantly lighter than the other known products while
maintaining the same strength properties, for predetermined
specifications. Since the high cost involved in the production of
engineered stone products is largely due to the cost of polymer resins,
the present invention proposes a low cost versus strength ratio panel.
The strength properties of the stone-like laminate makes it more
resistant to bending and pressure and renders possible the use of
machinery traditionally used for the processing and polishing of natural
or engineered stone products. This step is generally performed with an
industrial multi-head polisher, which requires a pressure as high as over
100 metric tons, polishing fluids and heat. The stone-like laminate of
the present invention is pressure resistant, highly wet resistant and
highly heat resistant, without encountering any deformation or
dimensional variation.
[0021] Since the stone-like laminate of the present invention is lighter
than other products derived from natural or engineered stones, it is
easier to handle and to install, and usual carpentry tools can be used to
work with. The stone-like laminate of the present invention is also
impact resistant, termite and vermin resistant, highly fire-resistant,
moisture resistant and it provides very good and economical structural
qualities to the final product. In addition, because the stone-like
laminate of the present invention requires a smaller amount of
petroleum-derived resin or polymeric material than other engineered
stone-like panels, the production of the present invention causes less
pollution.
[0022] Many properties of the present invention are conferred to the
stone-like laminate by the support layer That is made of a cementious
matrix, a fiber cement, a light concrete or the like, in the form of a
board, and is preferably a pre-cured board and even more preferably a
heat absorbent-type pre-cured cementious matrix board. The term
cementious matrix board, as used in the present invention, should
therefore be interpreted broadly rather than restrictively and includes,
but is not limited to boards or panels made from a cementious material
such as cement boards, fiber cement boards, light concrete boards, cement
bonded particle boards, calcium silicate boards, other cement base panel
products, or the like. The cemetious matrix board comprises aggregates
such as ground silica, amorphous silica, micro silica, diatomaceous
earth, coal combustion fly and bottom ashes, rice hull ash, blast furnace
slag, granulated slag, steel slag, mineral oxides, mineral hydroxides,
clays, magnesite or dolomite, metal oxides and hydroxides, polymeric
beads, and mixtures thereof, bound together by a binding agent such as
Portland cement, high alumina cement, lime, high phosphate cement, ground
granulated blast furnace slag cement, and mixtures thereof. The
cementious matrix board may further comprise mica, fiberglass, cellulose
fibers, natural fibers, synthetic fibers, calcium silicate, wood material
and mixtures thereof. The support layer has a thickness that preferably
ranges from 4 to 40 mm.
[0023] The nature of the support layer provides the stone-like laminate of
the present invention with a good resistance to pressure, heat and water.
For example, support layer provides the stone-like panel of the present
invention with high heat-resistance, being capable of absorbing heat over
400.degree. F. while avoiding any delamination. In addition, the support
layer should agree with the process for the production of the stone-like
laminate of the present invention, which implies high pressures (up to
100 tons), heat and humidity. In addition to those physical properties,
the cement board provides the stone-like laminate of the present
invention with an excellent resistance to delamination. Resistance to
delamination is mainly due to the nature of the cementious matrix board.
Indeed, the surface layer is bound to the support layer through the
polymer resin comprised within the surface layer, as it will be described
in more details hereinafter. It is however acknowledged in the art that
polyester or acrylic resins have poor adhesion capabilities, which can
result in the delamination of the filler resin when it is poured and
cured over an inappropriate material such as plastic, wood or some metal
substrate. The stone-like laminate of the present invention uses a
cementious matrix board as support layer which, contrarily to other
materials, has a great porosity and the capacity of heat absorption that
significantly contribute to the bonding process with the polymer part.
Porous type cementious matrix boards used as a backup layer provide a
good receptive layer for polymer resins since the resins penetrate the
pores and provide the stone-like laminate with an increased mechanical
binding.
[0024] The support layer of the present invention can be made integrally
of cement, fiber cement or can comprise further elements that enhance its
physical properties. For example, the support layer of the present
invention may comprise an integrated structure that enhances the strength
of the bond created between the cement board or fiber cement board, and
the decorative layer. Such integrated structure comprises, but is not
limited to, fibers, metals, wood, inorganic particles, fiber grids and
metal grids. Alternatively, the support layer can be processed so as to
increase adhesion with the decorative layer. Such processing of the
support layer includes mechanical perforation or scarification, chemical
treatment of the support layer or combinations thereof. Perforation and
scarification of the porous fiber cement board will act similarly as a
radiator that will take the heat of the decorative layer and will
transmit the energy to the ambient air. In addition, perforations,
scarifications or any other surface irregularities increase the
mechanical bound between the surface layer and the support layer. The
cement board may comprise a sealant or any other agent that will increase
its waterproofing or a metal or aluminium sheet, grid, structure or the
like to increase heat evacuations from the cement board. To minimize
post-curing convex bending of the laminate, which is attributable to
shrinkage of the decorative layer, the cementious matrix board can be
curved so as to obtain a concave shaped board prior to curing the surface
layer. Alternatively, agents such as thermoplastics can be added to the
cured decorative layer to prevent further shrinkage. Thermoplastics used
for that purpose are commonly referred to as low-profile additives (LPAs)
and include polymethyl methacrylates, vinyl chloride-vinyl acetate
copolymers, polyurethanes and styrene-butadiene. copolymers. The cement
board may also be processed to enhance the esthetical properties of the
stone like laminate. For example, cementious matrix board can be
embossed, engraved, painted or a combination thereof to give an
impression of color and depth.
[0025] The surface of decorative layer of the present invention serves
mainly for aesthetic or decorative purposes since it confers the
appearance of a polished stone panel to the laminate of the present
invention, while being non-pourous and resistant to stain, heat and
scratches. The surface layer of the present invention is preferably 0.7
to 10 mm thick and more preferably 5 mm-thick to prevent the presence of
small air pockets and reduces the need of requiring the use of vacuum to
obtain resistant stone-like laminate. The surface layer comprises at
least eighty percent (80%) of an inorganic material and at most twenty
percent (20%) of a resin, but preferably comprises at least ninety
percent (90%) of an inorganic material and ten percent (10%) of a resin
and more preferably ninety-three percent (93%) of an inorganic material
and seven percent (7%) of a resin.
[0026] The particles of inorganic material of the decorative layer include
any inorganic material in the form of particles. The term particle as
used herein is intended to mean any particle, granule, pellet, chip,
fragment, grain, crumb or the like from any opaque or transparent
inorganic material suitably usable for the purpose of producing the
stone-like laminate of the present invention. The inorganic material is
however preferably includes a mineral, and more preferably stone, rock,
sandstone, limestone, boulder, pebble, calcite, feldspar, glass, marble,
mica, obsidian, sand, silica, wollastonite alumina trihydrate, calcium
carbonate, silica, alumina trihydrate, antimony oxide, onyx, talc,
titanium dioxide, calcined talc, magnetite, siderite, ilmenite, goethite,
galena, coal, pyrite, hematite, limonite, biotite, natural granite,
anhydrite, chalk, sandstone, or the like, in the form of particles or
powder, and more preferably quartz particles. The inorganic material of
the present invention may be obtained, for example, by crushing natural
stones or minerals to obtain a determined mesh. The inorganic material of
the present invention is preferably constituted by particles having a
size that ranges between 0.0001 and 20 mm and more preferably by a
combination of 6 mesh (1.7-5.6 mm), 10 mesh (0.6-3.35 mm), 24 mesh
(0.15-1.18 mm) and 325 mesh (less that 44 microns) inorganic particles. A
skilled artisan will understand that in addition to particles of
inorganic material, various filled or unfilled pigments or dyes,
insoluble chips of polymeric materials such as cellulose, polyethylene,
ethylene copolymers, cross linked polyacrylic polymers, polyesters,
polypropylenes, cross-linked polyvinyl chlorides, cross-linked acrylic
polymers, polyethylene, ethylene copolymers, phenolic resins,
urea/formaldehyde resins, colored chips, hydrated alumina, cross-linked
polyvinyl chloride and polyesters, polyacetals, pigments, dyes, colored.
rocks, colored glass, colored sand, wood products or ceramic particles
can be added to the decorative layer to increase its esthetical aspect.
The surface layer may further comprise heat-conducting particles adapted
for enhancing transfer of heat from the surface layer to the support
layer, such as, but not limited to, reflective flakes and metal
particles.
[0027] The resin that can be used in the context of the present invention
includes any resin capable to bind inorganic material particles together,
but is preferably a clear, transparent or translucent resin. Such resin
includes, but is not limited to polymer resins such as polyesters,
acrylics, epoxy, phenols, silicones, urethanes, siloxanes, silanes, and
combinations thereof. For example, wide variety of generally clear,
transparent or translucent thermosetting polyester resins are known in
the art and fall within the scope of the present invention. Such resins
include acrylic resins, vinyl ester resins, epoxy resins and the like.
For the purpose of the present invention, unsaturated polyester resins
are preferred for reasons of cost, availability, clarity and ease of
handling. Depending on the nature of raw materials and on how the resin
is manufactured, polyester resins can be formulated to meet any one of a
wide range of special needs. Polyester resins are obtained by
copolymerization of styrene and unsaturated polyester formed by reacting
an alpha, beta-unsaturated dicarboxylic acid with glycol. Other
unsaturated polyester resins may be obtained by the polycondensation of
dicarboxylic acid, such as phthalic acid or isophthalic acid, with
dihydric alcohol such as ethylene glycol or propylene glycol.
[0028] The stone-like laminate of the present invention is obtained by
providing a pre-cured and heat absorbing cement board on which is poured
a mixture comprising the resin and the inorganic particle material. The
mixture is then compacted onto the cement board, using a pressure ranging
preferably from 100 pounds to 100 metric tons over the whole laminate and
more preferably a pressure of 3000 pounds per square foot. The compaction
step may further comprise vacuum treatment and vibration so that any gas
found within the surface layer will be removed and preferably comprises a
vibration step of sixty (60) seconds at 3500 vibrations per minute.
Further compaction enables the stone-like laminate to cure. The use of a
catalyst that will increase the resin polymerization rate during the
curing step is also preferred, and more particularly the use of 2% (v/w)
catalyst, such as a peroxide catalyst commonly used for the
polymerization of unsaturated polyester resins. Since the polymerization
rate at room temperature is not optimal, curing at high temperatures is
also preferred, especially with a surface layer comprising a polyester
resin. Curing temperatures up to 300.degree. F. can be used since the
cementious matrix board is heat-resistant, but a hot curing at
176.degree. F. for 30 minutes is preferred. Total curing of the
stone-like laminate can be performed for a period ranging from one (1) to
twenty-four (24) hours, but is preferably performed for a twenty-four
(24) hour period. After polymerization of the resin content, the
stone-like laminate is unmolded, gauged and calibrated. For further
calibration, the stone-like laminate of the present invention is polished
using a standard polisher.
[0029] To enhance the binding of the surface layer on the support layer, a
thin layer of resin is applied on the cement board prior to pouring the
mixture comprising the resin and the inorganic material. The thin resin
layer is then allowed to penetrate into the pores or irregularities of
the cement board. The mixture is applied over the thin resin layer while
the resin of both the mixture and the thin resin layer remains
unpolymerized. The mixture and the thin resin layer contact each other
and form an integral structure with the inorganic particle material.
Since the resin penetrates and polymerizes within the pores or
irregularities of the cementious matrix board, it increases the
mechanical bound with the surface layer. A skilled artisan will
understand that the stone-like laminate of the present invention is not
restricted to a structure comprising a surface layer perfectly
superposing a support layer. For example, the surface layer of the
present invention can cover a surface that is wider or narrower than the
support layer. Additionally, a skilled artisan will understand that the
surface layer, although generally planar, may comprise a lip that covers
at least one side face of the support layer, as illustrated in FIG. 2a to
FIG. 2e, which constitute an embodiment of the present invention.
Alternatively, the surface layer may cover two faces or the entirety of
the support layer (FIG. 2f). The laminate of the present invention can
also comprise tongue and groove structures on the lateral sides of the
panel so that multiple stone-like laminate panels can be fitted into one
another.
[0030] While the invention has been described in connection with specific
embodiments thereof, it will be understood that it is capable of further
modifications and this application is intended to cover any variations,
uses, or adaptations of the invention following, in general, the
principles of the invention and including such departures from the
present disclosure as come within known or customary practice within the
art to which the invention pertains and as may be applied to the
essential features hereinbefore set forth, and as follows with the scope
of the appended claims.