U.S. patent application number 09/147813 was filed with the patent office on 2001-11-15 for plastic glazing, in particular for motor car and method for making same.
Invention is credited to BRAVET, JEAN-LOUIS, MAURER, MARC.
Application Number | 20010041251 09/147813 |
Document ID | / |
Family ID | 9509212 |
Filed Date | 2001-11-15 |
United States Patent
Application |
20010041251 |
Kind Code |
A1 |
BRAVET, JEAN-LOUIS ; et
al. |
November 15, 2001 |
PLASTIC GLAZING, IN PARTICULAR FOR MOTOR CAR AND METHOD FOR MAKING
SAME
Abstract
The invention relates to a product which is at least partly
transparent and of high optical quality, equivalent to that of a
glass window, which can be approved as a motor-vehicle window
according to the various standards in force, and having a plastic
core coated with a skin comprising at least one plastic film coated
with a scratch-resistant layer; it also relates to a process for
manufacturing this product and to the application of the latter as
a body element, part of which forms a window, for example for motor
vehicles.
Inventors: |
BRAVET, JEAN-LOUIS;
(THOUROTTE, FR) ; MAURER, MARC; (VERVIERS,
BE) |
Correspondence
Address: |
OBLON SPIVAK MCCLELLAND
MAIER & NEUSTADT
1755 JEFFERSON DAVIS HIGHWAY
FOURTH FLOOR
ARLINGTON
VA
22202
|
Family ID: |
9509212 |
Appl. No.: |
09/147813 |
Filed: |
August 31, 1999 |
PCT Filed: |
July 10, 1998 |
PCT NO: |
PCT/FR98/01513 |
Current U.S.
Class: |
428/213 ;
156/104; 156/105; 156/272.6; 156/99; 428/215; 428/216; 428/412;
428/425.5 |
Current CPC
Class: |
B32B 2307/584 20130101;
B32B 27/08 20130101; Y10T 428/31678 20150401; Y10T 428/24967
20150115; Y10T 428/31935 20150401; B29K 2995/0087 20130101; B29C
2045/14737 20130101; B29K 2995/002 20130101; Y10T 428/31598
20150401; C08J 5/00 20130101; Y10T 428/31938 20150401; B32B
17/10009 20130101; B32B 2309/105 20130101; B29K 2995/0093 20130101;
Y10T 428/31855 20150401; Y10T 428/31507 20150401; Y10T 428/24975
20150115; B29K 2715/006 20130101; Y10T 428/2495 20150115; B29C
45/14811 20130101; Y10T 428/31786 20150401; Y10T 428/3154 20150401;
B29L 2009/00 20130101; B29L 2031/7782 20130101; B32B 2605/006
20130101 |
Class at
Publication: |
428/213 ;
428/215; 428/216; 428/425.5; 428/412; 156/99; 156/104; 156/105;
156/272.6 |
International
Class: |
B32B 027/08; B29C
041/20; B29C 045/14 |
Foreign Application Data
Date |
Code |
Application Number |
Jul 15, 1997 |
FR |
97/08934 |
Claims
1. Product, which is at least partly transparent and of optical
quality equivalent to that of a window, characterized in that it
comprises a plastic core coated with a skin comprising at least one
plastic film supporting a scratch-resistant layer.
2. Product according to claim 1, characterized in that the
thickness of the skin is at most equal to 500 .mu.m, preferably
between 10 and 100 .mu.m, and in that the skin consists of one or
more transparent thermoformable plastic films, especially made of
polycarbonate, polypropylene, poly(methyl methacrylate) an
ethylene/vinyl acetate copolymer, poly(ethylene terephthalate),
polyurethane, polyvinyl butyral or a cycloolefin copolymer, between
which is interposed, or on which is deposited, at least one
functional layer, it being possible moreover for at least one of
these films itself to constitute one such functional layer.
3. Product according to claim 1 or 2, characterized in that the
thickness of the scratch-resistant layer is between 1 and 10 .mu.m
and in that this scratch-resistant layer is essentially inorganic,
especially consisting of polysiloxanes and/or based on silica
and/or on alumina, or essentially consists of networks of entangled
inorganic and organic molecular chains linked to each other by
means of silicon-carbon bonds.
4. Product according to claim 3, characterized in that the external
surface of the skin is hydrophobic/oleophobic and in that the
external layer of which the skin is composed contains a
hydrophobic/oleophobic agent, especially of the fluorinated
polysilane type, the said external layer consisting of the said
scratch-resistant layer in which the said hydrophobic/oleophobic
agent is incorporated, or of a thin layer, having a thickness of
between 2 and 50 nm, essentially consisting of the said
hydrophobic/oleophobic agent, such a thin layer being obtained by
grafting, or else of a layer of the said hydrophobic/oleophobic
agent, this layer being supported on a film of the poly(vinyl
fluoride) or poly(vinylidene fluoride) type.
5. Product according to one of claims 1 to 4, characterized in that
the said skin includes at least one decorative and/or masking layer
covering all or part of the surface of the product, this layer
being preferably positioned directly under the film supporting the
scratch-resistant layer.
6. Product according to one of claims 1 to 5, characterized in that
the said skin includes at least one adhesion layer constituting, in
particular, the internal surface of the skin intended to come
directly into contact with the core of the product.
7. Product according to one of claims 1 to 6, characterized in that
the said skin includes one or more optically selective layers, for
example thin metal layers, especially based on silver, having
thicknesses of between 2 and 35 nm and separated from each other,
as well as from other adjacent layers or films, by dielectric
layers.
8. Product according to one of claims 1 to 7, characterized in that
the said core consists of a thermoplastic such as polycarbonate,
poly(methylmethacrylate), an ethylene/vinyl acetate copolymer,
poly(ethylene terephthalate), polyurethane or a cycloolefin
copolymer, or of an ionomer resin or of a thermosetting or
thermally crosslinkable material of the polyurethane, unsaturated
polyester, ethylene/vinyl acetate copolymer type, or else of a
combination of several thicknesses of the same one or several of
these plastics, given that the core thus formed is chemically
compatible with the said skin and is capable of giving the assembly
the required mechanical properties.
9. Product according to one of the preceding claims, characterized
in that it is bent and in that it forms a motor-vehicle window
having, in particular, the regulation optical properties.
10. Product according to one of the preceding claims, characterized
in that the scratch-resistant layer finally has a surface
appearance without any crazing.
11. Process for manufacturing a product according to one of claims
1 to 10, which consists: firstly, in assembling the constituent
elements of a skin by laying them approximately flat, or by
supplying them from a device of developable shape, especially by
screen printing, flexography, ink-jet printing, laser printing, dip
coating or spraying, these being optionally combined with vacuum
deposition techniques of the sputtering or evaporation type, and,
where appropriate, in subjecting the constituent elements of the
skin to an operation whose purpose is to consolidate them to a
greater or lesser extent, then, secondly, in subjecting the skin to
a heat treatment, preferably at a temperature of between 100 and
300.degree. C., the skin being supported completely or partly by a
mould surface, an auxiliary means for shaping at least part of the
skin to the said mould surface, especially by blowing or by
suction, being optionally provided so as to relax the stresses in
the skin, and in crosslinking certain constituent elements thereof
and thirdly, in joining the skin to a plastic core by hot pressing
in a form, or by thermoplastic injection moulding or reactive
injection moulding of the material of the core, the skin having
been positioned in the bottom of the mould in such a way that its
constituent scratch-resistant layer and/or hydrophobic/oleophobic
layer is in direct contact with the mould.
12. Process for manufacturing a product according to one of claims
1 to 10, comprising the steps: of depositing the constituent
elements of a scratch-resistant layer on a substantially flat
plastic film and of shaping this film bearing the elements of the
scratch-resistant layer into a shape which is the same as or at
least similar to the ultimate shape of the end-product, at least in
certain parts, while at the same time at least partly crosslinking
this scratch-resistant layer.
13. Process according to claim 12, characterized in that the
crosslinking and simultaneous shaping involve a heat treatment at a
temperature of between 100 and 300.degree. C., and more precisely
between 140 and 240.degree. C.
14. Process according to either of claims 12 and 13, characterized
in that the shaping is carried out by supporting the film coated
with the scratch-resistant layer, or the elements intended to
constitute this layer, at least on part of its surface, by a
mould.
15. Process according to claim 14, characterized in that the mould
carrying the film is a frame open at its centre.
16. Process according to one of claims 11 to 15, characterized in
that the film coated with the scratch-resistant layer or elements
constituting this layer is combined, before shaping, with one or
more other films which themselves fulfil functions or carry means,
such as screen-printed decorations or layers, carrying out these
functions other than the scratch-resistance function.
17. Application of a product according to one of claims 1 to 10 as
a body element, a transparent part of which forms a window,
especially for motor vehicles.
Description
[0001] The present invention relates to at least partly transparent
products made of plastic, especially products of high optical
quality, equivalent to that of a glass window. It is conceivable to
replace glass sheets with plastic sheets in the construction of
windows, for example for buildings or transport vehicles.
[0002] Compared with glass, plastics are lower in weight, which is
a key advantage in the case of electrically driven town vehicles,
in so far as an increase in their range is crucial. In such
vehicles, it could even be envisaged producing, from plastic, in a
single unit, entire doors or even complete sides of the body,
including the windows, and, optionally, painting a lower part
thereof. In general, the low weight of the transparent surfaces is
relatively advantageous in the case of modern transport vehicles in
so far as technical progress is going hand in hand with integration
into windows of still more numerous functions (heated rear window,
radio antenna, windscreen de-icing, colouration in order to prevent
the passenger compartment heating up in strong sunlight,
incorporation of electrochromic compounds, display of information
on the windscreen, etc) and with ever increasing amounts of glazed
surfaces. This results in a general increase in the vehicle weight,
to the detriment of its energy consumption.
[0003] Moreover, compared with glass, plastics are capable of
providing improved safety conditions and superior anti-theft
protection because of their greater toughness.
[0004] A not insignificant advantage of plastics compared with
glass resides in their superior ability to be easily converted into
complex shapes.
[0005] Finally, the ability of plastic sheets to be deformed
substantially reversibly makes it possible to envisage ways of
fitting them into considerably simplified body openings by a
snap-fastening mechanism, from the inside just as from the outside
of the vehicle.
[0006] According to a first approach, flat plastic sheets are
formed by extrusion, a component is cut to the required dimensions
and fastened to a thermoforming device, a contact thermoforming
operation is carried out with at least one solid mould surface and,
optionally, with the aid of compressed air or suction. The optical
properties of a sheet thus extruded are not satisfactory.
[0007] Furthermore, the scratchability of plastics, mentioned
previously, is such that, in their optical applications or as
transparent elements, it is necessary to coat the shaped components
with a hard varnish. This operation is accompanied, as is well
known to those skilled in the art, by problems of the varnish
flaking, these problems being more acute in the case of surfaces of
complex shapes. In addition, it has only been envisaged forming the
hard varnish at a temperature below the deformation temperature or
softening point of the plastic, the shape of which is thus entirely
preserved during this operation. Such conditions of forming the
varnish are excessively restrictive and have resulted in
considerable effort being expended to produce varnishes which form
at sufficiently low temperatures and, at the same time,
thermoplastics with high softening points. There therefore remained
the need for a plastic which is transparent or intended for optical
applications, in which the poor optical quality inherent in the
extrusion technique and the problem of the varnish flaking would be
avoided and in which many varnishes could be employed in
combination with many plastics under satisfactory compatability
conditions.
[0008] This product should be capable of being obtained by an
inexpensive, reliable and simple process.
[0009] These objectives are presently achieved by the invention,
the subject of which is a product which is at least partly
transparent and of high optical quality. More particularly, the
invention resides in the fact that this product comprises a plastic
core integral with a skin comprising at least one plastic film
supporting a scratch-resistant layer.
[0010] This is because the property by which the scratch-resistant
layer is supported on a plastic film guarantees easy and reliable
procurement of an end-product of lasting high optical quality, as
will become apparent in the rest of the description. It makes it
possible to produce such an end-product on the basis of the
scratch-resistant layer on its support film in a physical and
chemical state which will not be modified consequently, or only
very slightly, by combining it with the core especially by
injection moulding the plastic of which it is composed. The use of
certain scratch-resistant varnishes forming at relatively high
temperatures optionally requires choosing a material for the
support film which is sophisticated but in a low quantity.
[0011] The expression "high optical quality or optical quality
equivalent to that of a window" is understood to mean, in the sense
of the invention, "optical quality equivalent to that of a glass
window, which can be approved as a motor-vehicle window according
to the various standards in force, especially the R 43 standard in
use in France".
[0012] Whatever the material of the core, the injection-moulding
temperatures should not, of course, affect the other constituents
of the product. This material may be chosen from many plastics; it
may be a conventional inexpensive thermoplastic having a relatively
low softening point. According to the invention, the plastic of the
core is capable of interacting with the skin for the purpose of
obtaining high optical quality, while at the same time having the
desired mechanical properties, in particular flexural strength and
impact strength.
[0013] Preferably, the skin has a thickness at most equal to 500
.mu.m, particularly preferably between 10 and 100 .mu.m, and
comprises one or more transparent thermoformable plastic films, for
example made of polycarbonate (PC), polypropylene (PP), poly(methyl
methacrylate) (PMMA), an ethylene/vinyl acetate copolymer (EVA),
poly(ethylene terephthalate) (PET), polyurethane (PU), polyvinyl
butyral (PVB) or a cycloolefin copolymer (COC), i.e. an
ethylene/norbornene copolymer or an ethylene/cyclopentadiene
copolymer. One or more functions may be assigned to some of these
thermoformable plastic films by the incorporation of suitable
agents. Depending on its thickness and its nature, the skin is
capable of contributing to a greater or lesser extent to the
mechanical properties of the product.
[0014] Moreover, a functional layer may be deposited on a
thermoformable plastic film of the skin, this being, in particular,
the case with the scratch-resistant layer. Finally, a functional
layer may be sandwiched, autonomously, between two thermoformable
plastic films.
[0015] Advantageously, the scratch-resistant layer has a thickness
of between 1 and 10 .mu.m; generally, it forms the external surface
of the product of the invention. It may essentially be inorganic
and especially consist of polysiloxanes and/or of derivatives of
silica and/or alumina, or a hybrid, such as consisting of networks
of entangled inorganic and organic molecular chains linked to each
other by means of silicon-carbon bonds. Such a hybrid layer
exhibits excellent transparency, adhesion and scratch-resistance
properties. It appears that the inorganic network gives the coating
its hardness and its scratch resistance while the organic network
gives it its elasticity and its toughness. Such varnishes are well
known and have been described in the published applications
EF-A1-0,524,417 and EP-A1-0,718,348, the teaching of which is
incorporated here by way of reference; some of these varnishes are
especially denoted by the registered trademark "Ormocer" which is
an abbreviation for "Organically Modified Ceramic". It is worth
pointing out that the firing temperature of Ormocers is easily
adaptable by varying the relative amounts of the organic polymer
fraction and the inorganic fraction. With regard to the plastic of
the support film, it may be useful, or indeed necessary, to adapt
its composition so as to make it compatible with the method and
temperature of deposition of the scratch-resistant layer.
[0016] Other functionalities may be incorporated into the skin.
[0017] According to one particular embodiment, the external layer
of the skin, in contact with the environment, contains a
hydrophobic/oleophobic agent which therefore imparts this property
to the external surface of the product. As hydrophobic/oleophobic
agent, fluorinated polysilanes are well known, especially those
obtained from precursors having a hydrolysable alkoxy- or halogeno-
type functional group at one end, this functional group serving for
chemical bonding to the substrate, and a perfluorinated carbon
chain at the other end, this chain being intended to constitute the
external surface of the product.
[0018] The hydrophobic/oleophobic agent is, in decreasing order of
preference, incorporated into the scratch-resistant layer, which
has a chemical structure close to its own, or with which it is at
the very least chemically compatible, or grafted in the form of a
thin layer having a thickness of between 2 and 50 nm, preferably
onto the scratch-resistant layer, or alternatively self-supported
on a plastic film, such as a poly(vinyl fluoride) (PVF) or a
poly(vinylidene fluoride) (PVDF), to be advantageously applied
directly to the scratch-resistant layer.
[0019] According to a variant, at least one decorative and/or
masking layer, covering all or part of the surface of the product,
is positioned in the skin, preferably directly under the support
film of the scratch-resistant layer.
[0020] This layer may, for example, replace the screen-printed
decoration often deposited around the periphery of the internal
face of windows, especially for motor vehicles, for the purpose of
masking, in the case of an observer outside the vehicle, the body
elements forming the frame of the opening and the adhesive bead
which is thus protected from degradation by ultraviolet radiation.
This layer may include opaque or transparent coloured decorative
elements, making it possible to produce coloured elements matching
the body or the internal fittings, logos, etc.
[0021] The skin may be provided with an adhesion layer, in
particular on its internal face for fastening to the core, but also
between two films or layers of the skin. Standard adhesives are
polyvinyl butyral or polyurethane.
[0022] Finally, among the main constituents of the skin are the
optically selective layers which are stacked, for example beneath
the decorative and/or masking layer. These layers are distinguished
by a high transmission in the visible range (wavelengths from 400
to 800 nm) and a high absorption and/or reflection in the
ultraviolet range (<400 nm) and infrared range (>800 nm).
These layers may consist of thin metal layers, for example based on
silver, having thicknesses of between 2 and 35 nm, separated from
each other, as well as from other adjacent layers or films, by
dielectric layers of oxides or nitrides of indium, tin, silicon,
zinc, titanium, tungsten, tantalum, niobium, aluminium, zirconium,
etc., generally having thicknesses of between 10 and 150 nm. These
layers may include at least one bulk-coloured layer.
[0023] The combination of these layers may be electrically
conductive; it may belong to the family of solar-protection stacks
used for limiting the influx of heat by solar radiation into closed
spaces or to that of low-emissivity stacks used, on the contrary,
to limit the loss of heat from closed spaces, this loss being
mainly due to transmission of infrared radiation through the
window. Such stacks are described in Patents FR 2,708,926 and EP
0,678,484.
[0024] The core of the product of the invention consists of a
thermoplastic such as polycarbonate, poly(methyl methacrylate), an
ethylene/vinyl acetate copolymer, poly(ethylene terephthalate), a
cycloolefin copolymer (for example, an ethylene/norbornene or
ethylene/cyclopentadiene copolymer), or of an ionomer resin (an
ethylene/methacrylic acid copolymer or an ethylene/acrylic acid
copolymer neutralized with a polyamine, etc.), or of a
thermosetting or thermally crosslinkable material (polyurethane,
unsaturated polyester, ethylene/vinyl acetate copolymer) or else of
a combination of several thicknesses of the same one or several of
these plastics, on condition that the core is chemically compatible
with the skin of the product according to the invention and gives
the assembly the required mechanical properties.
[0025] The subject of the invention is also a process for
manufacturing the product described above.
[0026] In a first phase of this process, the constituents of the
skin are assembled, this being in the form of a ply or developed,
optionally plane.
[0027] The scratch-resistant layer, when it is made of
polysiloxanes, is advantageously formed cold on its support film
and/or by plasma-enhanced deposition, such as plasma CVD (Chemical
Vapour Deposition). Insofar as polysiloxanes formed in this way are
no longer reactive, having already completely reacted, it is
necessary to choose the composition of the scratch-resistant layer
so that it can be bent, in order to avoid subsequent flaking
problems.
[0028] When the scratch-resistant layer consists of Ormocers, these
are applied flat in the form of liquid precursors to the support
film, using the conventional techniques of flow coating, dip
coating, especially in a bath of small volume for the sake of
economizing, liquid spraying or curtain spraying. The precursor
consists, for example, of colloidal dispersions in solvents of
several hybrid compounds, that is to say compounds which are both
organic and inorganic, or of low-molecular-weight polymers
functionalized by SiOR groups in a mixture with tetraethoxysilane.
The scratch-resistant layer is then cured using a sol-gel process
in which the precursor is firstly dried, passing through the
intermediate state of a gel, by moderate radiation or heating,
especially, in the latter case, at less than 50.degree. C. The
support film is then always held substantially flat; the curing of
the Ormocer is completed during the second phase of the process,
described below, which consists in thermoforming the said skin by
ultraviolet radiation and/or heating to temperatures of 100 to
300.degree. C., and more specifically 140-240.degree. C.
[0029] In either case, the layers, in particular the
scratch-resistant layer on the assembled and bent end-product, meet
the required properties for its use, especially the regulation
optical properties when it is to be used as glazing or as an
element comprising a window for a transport vehicle, especially a
motor vehicle.
[0030] The often complex shapes of motor-vehicle windows mean that
the scratch-resistant layer in particular must be able to be bent
without flaking and without cracking. Thus, advantageously, the
scratch-resistant layer is only fully cured after its support has
been shaped and, preferably, it only starts to cure and crosslink
at the same time as its support is being shaped, so as finally to
have a surface appearance without crazing or flaking.
[0031] The deposition and formation techniques which have just been
described may also be used for incorporating the
hydrophobic/oleophobic function, whether the corresponding agent
forms an integral part of the scratch-resistant layer or is
supported on a plastic film; when it is grafted on as a thin layer,
it is also preferably formed by depositing it in liquid form by
spraying, if it consists of silanes, or by evaporation using
techniques such as plasma CVD, optionally under vacuum.
[0032] The decorative and masking layer or layers are provided on
support films, especially made of plastic, according to the
techniques used in printing: screen printing, flexography, ink-jet
printing, laser printing, etc.
[0033] The adhesion layer is usually provided in the form of an
integral thermoplastic film.
[0034] The formation of optically selective stacks makes use of
successive deposition operations using sputtering, especially
sputtering assisted by a magnetic field, or the like. In this
regard, reference may again be made to Patents FR 2,706,926 and EP
0,678,484.
[0035] The first phase of the process of the invention for forming
the substantially flat skin may be concluded by an operation whose
purpose is to consolidate the constituents thereof to a greater or
lesser extent, especially by cold calendering or calendering at a
temperature slightly above room temperature.
[0036] As briefly mentioned above, the second phase of the process
consists in thermoforming the skin at a preferred temperature of
100-300.degree. C. into a shape, optionally non-developable,
identical to that of the end-product.
[0037] To do this, it is advantageous, in particular in order to
complete the curing and/or crosslinking of the scratch-resistant
layer, to allow it to come into contact with the ambient
atmosphere, that is to say without coming into contact with solid
elements; only the other face of the skin is then in contact with a
support whose purpose is to give it shape. Auxiliary means, for
example, blowing or suction means, may be used to shape at least
part of the skin to this support. Apart from completing the
crosslinking of certain constituents, the heat treatment carried
out in this second phase has the effect of relaxing the stresses in
the skin.
[0038] The third phase of the process of the invention consists in
joining the skin to a plastic core by hot pressing in a form or by
thermoplastic injection moulding or reactive injection moulding
(RIM) of the material of the core, the skin having been positioned
in the bottom of the mould, at the start of this third phase, in
such a way that its scratch-resistant layer and/or its
hydrophobic/oleophobic layer, which layer is fully cured and/or
crosslinked, i.e. virtually no longer reactive, is in direct
contact with the mould wall.
[0039] Another object of the invention is the application of the
product described above as a body element, a transparent part of
which forms a window, especially for motor vehicles.
[0040] The invention will now be illustrated by the following
example.
EXAMPLE
[0041] The scratch-resistant coating described in the example in
Patent Application EP-A-0,718,348 is deposited as a 20 .mu.m thick
liquid film on an 80 .mu.m thick film of standard polycarbonate
prepared from bisphenol A, sold by Bayer AG under the registered
trademark "Makrolon.RTM.", which has a glass transition temperature
T.sub.g equal to 145.degree. C., by flow coating.
[0042] The coated support film is then placed in the bottom of a
mould, the scratch-resistant layer being positioned on top; the
assembly is then subjected to a heat treatment of 155.degree. C.
for 30 min. A skin in the sense of the present invention is then
formed, this having its virtually final shape.
[0043] The skin is placed in the bottom of an injection mould so
that the scrath-resistant layer is in contact with the mould wall.
There then follows, in the manner described above, the
thermoplastic injection moulding, only two different specimens, of
a 5 mm thick layer, on the one hand, and a 10 mm thick layer, on
the other hand, of the same standard polycarbonate as that making
up the support film of the scratch-resistant layer.
[0044] The laminate obtained exhibits a transparency and an optical
quality which are amply sufficient for application as a window.
[0045] The process of the invention has the advantages inherent in
the injection-moulding technique. It is thus possible to form the
injection-moulded component with a peripheral bead in order to
increase its stiffness, or with a relief and/or extensions, such as
ribs, profiles, tabs or lugs, and/or to arrange one or more
inserts, especially metal inserts, in the plastic. This arrangement
is particularly useful for gripping or fastening the product of the
invention, as well as for fitting it in its intended final
position, such as in a body opening of a motor vehicle. In the
latter case, forming suitable peripheral profiles makes it possible
to envisage fitting the product from inside the vehicle, i.e. from
inside the passenger compartment. The adhesive bead is then placed
under the edge of the body opening and is not exposed to solar
radiation. Protecting the adhesive bead with a varnish formed
around the periphery of the internal face of the sheet becomes, of
course, superfluous.
[0046] The appendages formed around the periphery of the product
while it is being injection moulded may be preserved, or sawn off
completely or partly depending on their use. After such sawing, a
rubbing-down operation may be provided.
[0047] A peripheral profile with a geometry which is symmetrical
with respect to the plane of the product may be opportune, for
example in the case of transparent side surfaces of transport
vehicles, it being possible for one or other part of the profile to
be subsequently sawn off, depending on whether it is a left-hand or
right-hand transparent element.
[0048] Moreover, optional inserts may be associated with the
incorporation into the product of special functions, such as a stop
light in a rear window.
[0049] Finally, the process of the invention is economic, easy and
reliable and allows the use of many combinations of constituents
without the problem of their compatability, especially from the
standpoint of their processing temperatures, arising.
* * * * *