U.S. patent application number 11/111726 was filed with the patent office on 2005-08-25 for process for manufacturing a multi-layer film-type laminate for packaging materials.
Invention is credited to Bonsch, Fabian, Frey, Juerg, Nageli, Hans-Rudolf, Rosenberger, Karolina.
Application Number | 20050183830 11/111726 |
Document ID | / |
Family ID | 32011057 |
Filed Date | 2005-08-25 |
United States Patent
Application |
20050183830 |
Kind Code |
A1 |
Rosenberger, Karolina ; et
al. |
August 25, 2005 |
Process for manufacturing a multi-layer film-type laminate for
packaging materials
Abstract
A production device (10) for manufacturing a multi-layer
film-type laminate. The production device (10) includes a
continuous feed production line for film-type materials with an
uncoiling and coiling system for uncoiling and coiling the films or
film-type laminates in question present in roll form. The
production device (10) also contains one laminating (1) and/or
extrusion station for manufacturing a multi-layer film-type
laminate, at least one printing station (2) and at least one
sealing layer station (4). The individual stations are arranged
in-line as integral modules of the production device (10). Thereby,
the printing station (2) and the sealing layer station (4) contain
apparatus for coating the film or film-type laminate using an
electrostatic coating process.
Inventors: |
Rosenberger, Karolina;
(Osterfingen, CH) ; Bonsch, Fabian; (Neuhausen,
CH) ; Nageli, Hans-Rudolf; (Neuhausen, CH) ;
Frey, Juerg; (St. Gallen, CH) |
Correspondence
Address: |
FISHER, CHRISTEN & SABOL
1725 K STREET, N.W.
SUITE 1108
WASHINGTON
DC
20006
US
|
Family ID: |
32011057 |
Appl. No.: |
11/111726 |
Filed: |
April 22, 2005 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
11111726 |
Apr 22, 2005 |
|
|
|
10674001 |
Sep 30, 2003 |
|
|
|
Current U.S.
Class: |
156/384 ;
156/237; 156/277 |
Current CPC
Class: |
B32B 2553/00 20130101;
B32B 15/08 20130101; B32B 37/00 20130101; B32B 38/14 20130101; B32B
39/00 20130101; B32B 38/145 20130101 |
Class at
Publication: |
156/384 ;
156/237; 156/277 |
International
Class: |
B41M 001/00 |
Foreign Application Data
Date |
Code |
Application Number |
Oct 7, 2002 |
EP |
02405866.1 |
Claims
1-14. (canceled)
15. A production device (10) for manufacturing a multi-layer
film-type laminate, the production device (10) comprises a
continuous feed production line for film-type materials with an
uncoiling and coiling system for uncoiling and coiling films or
film-type laminates in question present in roll form, the
production device (10) contains one laminating (1) and/or extrusion
station for manufacturing a multi-layer film-type laminate, at
least one printing station (2) and at least one sealing layer
station (4), and the individual stations are arranged in-line as
integral modules of the production device (10), whereby the
printing station (2) and the sealing layer station (4) contain
means for coating the film or film-type laminate using an
electrostatic coating process.
16. The device according to claim 15, wherein the production device
contains a laminating station (1) and the laminating station (1)
has means for coating the film using an electrostatic coating
process.
17. The device according to claim 16, wherein the means for
electrostatic coating contains means for electrostatic charging
coating particles and means for transferring the electrostatically
charged coating particles to the film surface that is to be
coated.
18. The device according to claim 17, wherein the means for
transferring the electrostatically charged coating particles
contain a transfer roll or transfer belt on which the
electrostatically charged coating particles are deposited by
electrostatic forces, and means for applying an electric field to
transfer the electrostatically charged coating particles from the
transfer roll or transfer belt to the film surface to be
coated.
19. The device according to claim 18, wherein the laminating
station (1), the printing station (2), the print overlayer station
(3) and/or the sealing layer station (4) have means for electronic
data processing appointed to them for the purpose of specific
deposition and control of partial layer deposition and/or
controlling the thickness of the layers.
20. The device according to claim 19, wherein the coating particles
at the printing station (2) are of a solid or liquid toner, and the
printing station (2) has appointed to it means for image processing
and means for specific, localized deposition of the toner in the
form of an image for printing.
21. The device according to claim 20, wherein the print overlayer
station (3) and/or the sealing layer station (4) have/has appointed
to them/it means for image processing and means for specific,
localized deposition of coating particles.
22. The device according to claim 21, wherein the image processing
means contains means for electronic data processing for the purpose
of producing an image and/or drawing in the form of a printer's
copy, whereby the data for the printer's copy are present in
digital form and the coating stations (2, 3, 4) contain means for
coating the film or film-type laminate using an electrophotographic
process.
23. The device according to claim 22, wherein the laminating
station (1), the printing station (2), the print overlayer station
(3) and/or the sealing layer station (4) each contains a heating
unit for melting the coating.
24. The device according to claim 23, wherein the laminating
station (1), the printing station (2), the print overlayer station
(3) and/or the sealing layer station (4) each contains a curing
unit for hardening the coating.
25. The device according to claim 23, wherein the production device
(10) contains a common curing station (5) situated downstream of
the coating stations (1, 2, 3, 4).
26. The device according to claim 25, wherein the curing station
(5) or curing units operate with UV or EB radiation.
27. A process of utilizing a film-type laminate (7) produced
according to the device of claim 14, for manufacturing sealable
forms of packaging such as flat pouches, flat bottom bags, standing
pouches, small bags, cushion-type packs, bags, sacks, supports for
goods, boxes, base parts for push-through packs, blister packs, lid
materials for containers or supports for goods.
28. The device according to claim 22, wherein the means for
electronic data processing is image and/or text processing
programs.
Description
[0001] The present invention relates to a process for manufacturing
a packaging material from a flexible multi-layer film-type
laminate, comprising the following process steps: manufacturing the
film-type laminate from a plurality of films or layers by means of
a laminating and/or extrusion process, printing on the film or
film-type laminate and coating at least one of the free surfaces of
the film-type laminate with a sealing lacquer. The invention also
relates to a device for manufacturing the film-type laminate and
the use of the film-type laminate.
[0002] The production of film-type laminates with printing and
sealing layers is normally carried out today using a plurality of
process steps and devices which are separate from each other.
[0003] The films are e.g. brought together in a laminating facility
and combined to give a film-type laminate. As a rule, the adhesive
is deposited on the films by means of rolls and the films
subsequently combined to give a film-type laminate. In a subsequent
process step the film-type laminate is printed on. The printing of
the laminate is carried out e.g. by means of intaglio or offset
printing. If the laminate contains a counter-print image, then the
films are provided with a counter-print image in a printing unit
before the laminating step.
[0004] The printed film-type laminate is subsequently provided with
lacquer coatings in a coating unit; these may e.g. be overprinting
lacquers or sealing layers. The coating of lacquer is normally
deposited by roll coating, immersion coating or spray coating.
[0005] For coating purposes, the films are fed individually from
coils of film material and, on completion of this step, again
re-wound and taken away for further processing. In some cases, in
order to carry out the above mentioned process steps, the films
have to be unwound and rewound from the coils and taken away and
stored for interim periods for subsequent process steps.
[0006] The production of a printed and lacquer-coated film-type
laminate in individual process steps using various coating or
deposition methods is very complicated and time consuming.
[0007] The object of the present invention is therefore to propose
a manufacturing process and device by means of which the above
mentioned disadvantages can be avoided.
[0008] That objective is achieved by way of the invention in that
the lamination process and/or extrusion process, the printing and
coating with a sealant lacquer take place in-line at individual
stations in a common production facility, and the printing and the
coating with a sealing lacquer take place at coating stations using
an electrostatic coating process in which coating particles are
electrostatically charged and deposited on the film surface to be
coated using transfer means by applying an electric field, and
melting and/or hardening the same to give a coating film.
[0009] The film-type laminate is preferably made from two or more
films, whereby at least two films are laminated together and the
lamination takes place at a lamination station in the production
facility using an electrostatic coating process in which coating
particles are electrostatically charged and are deposited on the
film surface to be coated using transfer means by applying an
electric field and melting and/or hardening the same to give a
coating film in the form of an adhesive layer.
[0010] The coating of sealing lacquer is a cold-sealing lacquer or,
especially preferred, a hot-sealing lacquer.
[0011] The hardening or curing of the coating is important in the
case of chemically cross-linking coating systems. In the case of
coating materials in the form of thermoplastic materials (e.g.
melting adhesives, hot-melts) conventional curing is not necessary.
When employing curing-type coating systems, the curing of the
adhesive layer/layers, the singular or multiple printing, the
deposition of the print-covering layer of lacquer and/or the
sealing layer of lacquer may take place in curing units in the
respective coating stations.
[0012] In a preferred version the curing of the above mentioned
coatings takes place in-line in a common curing station of the
production facility downstream of the coating stations.
[0013] The coating particles or the coatings may be coating systems
hardened e.g. by radiation, in particular UV-radiation (ultraviolet
radiation) or EB-radiation (electron-beam radiation). The use of UV
or EB curing coatings in electrostatic coating processes makes it
possible to employ solvent-free coating systems.
[0014] In the case of the radiation-curing coating systems
according to the invention the sometimes necessary melting and
formation of the coating particles on the substrate is uncoupled
from the actual curing process, this in contrast to thermally
curing coating systems.
[0015] The radiation-curing coating systems, such as UV-curing or
EB-curing coating systems contain so-called initiators e.g.
photo-initiators in UV-curing coating particles, which are
activated under the influence of energy applied e.g. using UV or EB
radiation and effect immediate polymerisation of the coating.
[0016] In a preferred version of the invention, after deposition on
the substrate (plastic film), the coating particles are heated e.g.
to 70-80.degree. C. and melted in a so-called heating unit e.g. by
means of IR (infra-red) radiation or NIR (near infra-red)
radiation, in particular by means of heated rolls. A fine, uniform
film which adheres to the substrate is formed as a result of the
melting. In each case the heating unit for this purpose is situated
at the individual coating station.
[0017] After depositing the coating particles and if desired after
heating and melting the coating into the form of a fine film, there
follows the fixing of the melt product on the substrate by means of
a radiation-curing system in a subsequent curing station. The
cross-linking reactions effected by the curing process are, as
already mentioned initiated preferably by means of ultraviolet or
electron beam radiation.
[0018] The coating particles or the coatings, in particular
hot-sealing lacquer coatings, printing or adhesive coatings, may
however be based on thermoplastics, whereby curing as such no
longer takes place. After transfer from the transfer medium to the
substrate, the coating particles are rather--as described
above--melted to give a coating film and solidified on cooling.
[0019] The production device contains preferred means for
electronic data processing which control specific, partial-area
i.e. localised deposition in the form of printing, the deposition
of a layer of lacquer over the printing or a layer of sealing
lacquer. The localised deposition results in the creation of a
printed image.
[0020] The production device may also contain means for electronic
data processing which enable the thickness of the layer to be
deposited at the individual coating stations to be supervised
and/or controlled. The said means are preferably employed at the
following stations, if present, viz., the lamination station, the
print overlayer station and/or the sealing lacquer station. The
control of the thickness of layer to be deposited or the localised
deposition is achieved preferably using digital printing
techniques.
[0021] The coating particles for the laminate or adhesive layer may
be liquid or dry particles. They are preferably in dry form e.g. as
a powder. The coating particles may be e.g. part of a two-component
development system with a carrier. The coating particles may also
be part of a single component development system. The coating
preferably covers the whole surface area.
[0022] The coating particles at the printing station are preferably
dry or liquid toner particles. The toner may e.g. be a
two-component dry-toner or a two-component development system with
a carrier. The toner may also be a single-component toner.
[0023] The printed image comprises usefully of pictures and/or
drawn patterns which e.g. contain sequences, reproductions,
patterns, lines, random patterns. The pictures and/or drawn
patterns may e.g. be coloured, black, white or in grey tones.
[0024] The pictures and/or drawn patterns are usefully based on a
printer's copy. The data for the printer's copy are preferably
available in digital form and are e.g. created or re-worked by
means of desktop-publishing i.e. employing programmes for
processing images and texts or the like using equipment for
electronic data processing (EDP).
[0025] The data may be e.g. stored on a magnetic, magneto-optical
or optical storage medium. It is also possible to take printer's
copies in the form of analogue data--using appropriate means such
as EDP-units and data-processing programmes (e.g. scanners)--to
capture and to transform and process this further into digital
signals by means of an analogue-digital transformer. The data of
the printer's copy in digital form are usefully reproduced on the
packaging materials by way of an electro-photographic process.
[0026] Coloured images and/or drawn patterns are usefully created
in a series of printing steps one after the other in different
printing units in the printing station, whereby e.g. an appropriate
toner with a specific colour pigment is employed at each step.
[0027] Further, two or more printer's copies may be applied e.g.
using EDP via text and/or image processing programmes to yield a
complete image and/or drawn pattern. Apart from a printer's copy,
it is possible to copy in another continuous printer's copy which
changes for each area to be printed or changes in another sequence,
whereby by "copy in" or "copy" is to be understood the reproduction
of an image to be reproduced usefully present in electronic data
form. This makes it possible to prepare e.g. serial numbers,
patterns or colour-differing packaging materials for individual
packs and the like in one process step. A printer's copy may be
reproduced singly or a number of times.
[0028] Using digitalisation and appropriate data processing
programmes the images to be printed may be worked over and changed
in an almost unlimited manner.
[0029] The packaging material supplied in roll form to foil
processing equipment may also contain a pre-printed image or base
image using one of the above mentioned classical printing
methods.
[0030] The coating particles for creating a print overlayer and/or
lacquer sealing layer may be in the form of liquid or solid
particles. These are preferably in solid form e.g. in powder form
or as powder lacquer. Print overlayers, and in particular
hot-sealing lacquers, are preferably in the form of powder
lacquers, whereby the hot-sealing lacquer is in particular
preferably a thermoplastic which is capable of melting.
Cold-sealing lacquer is preferably deposited in the form of liquid
particles.
[0031] The coating particles may e.g. be part of a two-component
developer system with a carrier. The coating particles may also be
part of a single component developer system. The coating particles
are preferably pigment-free or pigmented in such a manner that the
layer produced using them is at least translucent and the
underlying print remains visible.
[0032] The film-type laminate may exhibit only a sealing coating or
both a print overlayer coating, also called protective lacquer
coating, and a sealing lacquer coating. The film-type laminate may
exhibit, e.g. on the side to be sealed, a sealing coating and
printing on the opposite, free side, and on top of this a print
overlayer coating. On the same free side, the film-type laminate
may exhibit in combination, both a localised sealing coating in the
region of the sealing areas and a localised print overlayer coating
in the region of the printed images. Further, the sealing layer may
also be provided on the free side of the print overlayer
coating.
[0033] The sealing layer is preferably deposited specifically on
the part of the surface in the region of the sealing area. The
print overlayer coating is preferably deposited specifically on the
part of the surface in the region of the printed image. The print
overlayer is usefully translucent or partly or completely
transparent. The thickness of the sealing coating or the print
overlayer coating may be 7-100 .mu.m, in particular 10-50
.mu.m.
[0034] The print overlayer and/or sealing coating are usefully
deposited by use of electronic data processing means, such as
image-processing means, forming an image pattern on part of the
film surface.
[0035] The image is usefully based on a printer's copy, the data
for which are preferably in digital form. The preparation,
processing and storage of the image may take place in a manner
similar to that of the image and drawn pattern of printer's copies
for printing purposes. The related above disclosure applies also to
images for areas on print overlayer and sealing type coatings. The
images for that purpose are likewise created preferably by means of
an electro-photo-graphic method.
[0036] Print overlayer coatings deposited on the basis of a
radiation-curing coating system, such as e.g. ultraviolet or
electron beam radiation, exhibit excellent adhesion to the
substrate and the print. The print overlayer can be re-melted
preferably at temperatures of 200.degree. C. and more and remains
stable when the packaging material is heated during hot sealing or
sterilisation, so that the underlying print is protected against
damage.
[0037] In carrying out the process at least two films or film-type
laminates are unwound from a coil and passed on to the laminating
station in the production device. In the laminating station one or
both of the free surfaces of the films or film-type laminates to be
bonded is/are coated with an adhesive using an electrostatic
coating process. In a heating unit immediately downstream of the
coating unit, the adhesive is then preferably melted to give an
adhesive and, if desired, cured. Following this, the films are
brought together and bonded to give a laminate, whereby the layer
of adhesive solidifies on cooling.
[0038] It is conceivable for the laminate produced in this manner
to be laminated with one or more additional films or film-type
laminates in one or more laminating stations. Instead of
lamination, it is also conceivable at an extrusion station for an
additional layer to be extruded onto a film or film-type laminate
previously unwound from a coil.
[0039] In a printing station following the lamination or extrusion
station the film-type laminate is printed in one or more colours on
one or both sides. The printing station may subdivided into
substations i.e. in individual printing units in which individual
colours are deposited in line one after the other and combined to
give a coloured image.
[0040] If the film-type laminate is to feature a counter image,
then the films or film-type laminates are provided with a
counter-print image in a printing station situated upstream of the
laminating or extrusion station.
[0041] The printed film-type laminate is subsequently coated in the
sealing coating station with a sealing layer on one side on part or
the whole surface area. The side that has been printed on, which is
preferably the side opposite the free side, may also be coated with
a print overlayer coating on part or the whole surface area. The
sealing station may also be situated upstream of the printing
station.
[0042] The coating unit in the print overlayer and/or sealing
station is preferably situated downstream of a heating unit in
which, under the influence of heat, the coating--in particular the
powder lacquer coating--is melted to give a uniform lacquer film
that bonds to the film surface and is subsequently solidified or
cured.
[0043] The film-type laminate according to the invention may be
manufactured in the form of monofilms or multi-layer films or
film-type laminates. The films may be e.g. of metal (metal foils,
thin metal layers) paper, plastic or a combination thereof. The
film-type laminate may contain layers of paper, metal or plastic.
Examples of metal foils as packaging material are foils of iron,
steel, copper and, preferably, aluminium and its alloys.
[0044] Suitable plastics are e.g. polyvinylchloride (PVC),
polyvinylidenchloride (PVDC), polyesters, polycarbonates,
polyvinylacetates, polyolefins and in particular polyethylene (PE),
and also polypropylenes (PP) and polyamides (PA). Further plastics
not listed here are also conceivable.
[0045] The thickness of the packaging material may e.g. range from
5 .mu.m to 1000 .mu.m. Useful are thicknesses of 15 to 200 .mu.m.
The film or film-type laminate may also contain barrier layers e.g.
thin ceramic layers.
[0046] The invention also relates to a production device for
manufacturing a multi-layer film-type laminate. The production
device according to the invention contains a foil processing
equipment with an uncoiling and coiling system for uncoiling and
coiling the films present in roll form.
[0047] The production device according to the invention is
characterised in that it contains at least one laminating and/or
extrusion station for manufacturing a multi-layer film-type
laminate, at least one printing station and at least one sealing
coating station and the individual stations are arranged in line as
integral modules of the production device, whereby the printing
station and the sealing coating station contain means for coating
the films or film-type laminate using an electrostatic coating
process.
[0048] The means for electrostatic coating contain usefully means
for electrostatic charging the coating particles and means for
transferring the electrostatically charged coating particles to the
film surface (substrate) to be coated.
[0049] The means for transferring the electrostatically charged
coating particles comprise preferably a rotatable transfer roll or
transfer belt on which the electrostatically charged coating
particles are deposited by electrostatic forces and means for
applying an electric field to transfer the electrostatically
charged coating particles from the transfer roll or transfer belt
to the film surface to be coated.
[0050] The transfer of the coating particles to the film surface is
carried out preferably by means of a process employing so called
EMB-Technology (Electro-Magnetic Brush Technology) such as is
employed in particular in two-component developer systems. Here, a
so called carrier is employed in the form of ferromagnetic
particles, whereby the coating particles are attached to the
carrier by tribo-electrical forces. The developer system comprising
the carrier and the coating particles adhering to them is deposited
over a rotating magnet roll facing the transfer roll or transfer
belt. As a result of the magnetic forces acting between the magnet
roll and the carrier, the developer system is drawn in a chain-like
manner to the magnet roll and forms a brush-like arrangement, also
known as magnet brush. The magnet brush strokes the transfer roll
and creates a so called brush effect as a result of which the
coating particles are transferred, with the aid of electrostatic
forces, to the electrostatically charged surface of the transfer
roll.
[0051] In the transfer process itself the coating particles are
transferred e.g. by means of corona discharge, directly or
indirectly from the transfer roll to the substrate to be printed
on. The coating particles are then fixed to the substrate if
desired in the molten state. Depending on the coating system
employed the coating is hardened in a separate curing station or
curing unit.
[0052] In the coating stations and in particular in that coatings
station in which the film surface is coated in specific areas, an
electrophotographic coating process is employed by way of
preference. In this case the transfer roll is usefully a
photo-carrier, preferably in the form of a drum, roll or transfer
belt. The photo-carrier is coated on the surface with a
photo-conductor. At a corona discharging station the
photo-conducting surface layer of the photo-carrier uniformly
charged in darkness. The photo-conducting layer is exposed to a
light source which reproduces the image in light form, whereby the
illuminated part of the photo-conducting layer is discharged. A
charge-image corresponding to the print image is produced.
[0053] In the developing stage the electrostatically charged
coating particles are transferred to the charge-image, whereby the
coating particles--which are charged with a charge opposite that of
the photo-conducting layer--are drawn onto the charge-image on the
photo-carrier under the action of the electrostatic forces, thus
reproducing the print image. The coating particles are then
transferred via electrostatic attraction from the photo-carrier
directly or indirectly onto the substrate.
[0054] Processes which by definition fall into the category of
electrophotographic processes include direct and indirect
electrophotographic processes such as e.g. xerography, whereby an
indirect electrophotographic process, in particular a xerographic
process, is employed by way of preference.
[0055] The coating stations preferably contain means for electronic
data processing for the purpose of monitoring and/or controlling
deposition of a layer over part of the surface area and for
monitoring and/or controlling layer thickness. In particular the
printing station usefully contains means for image processing and
means for specific deposition of the coating particles on parts of
the surface area.
[0056] The image processing means preferably comprise means for
electronic data processing (EDP) such as image and/or text
processing programmes for creating an image or drawn pattern in the
form of a printer's copy. The printer's copy is preferably in
digital form.
[0057] Further processing units may, according to specific needs,
be added to the production device. The production device may e.g.
include further downstream a cutting station or a device for
automatic packaging.
[0058] The film-type laminate manufactured according to the
invention is preferably employed for the production of sealable
forms of packaging, in particular pouch-type packaging such as flat
pouches, flat-bottom bags pouches, standing pouches, large and
small bags, cushion-type packs, sacks. Further, the film-type
laminate may also be employed to manufacture supports for goods,
boxes, base parts for push-through packs, blister packs or lid
materials for containers or supports for goods.
[0059] The invention is described in the following by way of
examples and with reference to the accompanying drawing which shows
in:
[0060] FIG. 1: a schematic representation of a production device
for manufacturing a packaging material;
[0061] FIG. 2: a cross-section through a packaging material
manufactured according to the invention.
[0062] The production device 10 contains an uncoiling device, a
laminating station 1, a printing station 2, a print overlay coating
station 3, a sealing coating station 4, a curing station 5 and
downstream of this a coiling station (se FIG. 1). The uncoiling
device contains two rolls 8a, 8b from which a first and a second
roll of strip-shaped film or film-type laminate 9a, 9b are unwound
and fed continuously into the laminating station 1. In the
laminating station 1 the first film 9a is coated with an adhesive
using an electrostatic, preferably electrophotographic process,
whereby after the adhesive has been deposited on the film, it is
melted to give an adhesive film and the two films 9a, 9b laminated
together.
[0063] The film-type laminate is then passed through a printing
station 2 in which one of the free surfaces of the film-type
laminate is printed on using an electrophotographic process. It is
possible to print on both sides of the film-type laminate. The
printing may take place in one or several steps using one or more
toners with different pigments. Depending on the number of printing
steps the printing station may contain one or more printing units
18.
[0064] The layers of toner deposited on the film are melted on in a
subsequent heating station (not shown here) forming a film that
adheres to the substrate film surface, then solidified.
[0065] After the printing, the film-type laminate is passed through
the print overlayer station 3 which follows on from printing
station 2. Here a print overlayer lacquer coating is deposited
either over the whole or only part of the printed surface of the
film-type laminate.
[0066] Following the print overlayer station 3 is the sealing layer
station 4 in which the free side, opposite that which has been
printed on, is coated either wholly or in part with a sealing-type
lacquer coating, in particular a hot-sealing lacquer coating.
[0067] The deposition of the lacquer coatings at both coating
stations 3, 4 is carried out using an electrostatic, preferably
electrophotographic process. Each coating station 3, 4 also has a
heating unit (not shown here) associated with it in which the
lacquer coating is melted to form a lacquer film that adheres to
the substrate film surface and subsequently solidified.
[0068] The layer of adhesive, the print and the print overlayer are
coatings that can be cured by UV or EB radiation and are cured in a
common curing station 5 by means of UV or EB radiation after the
coating steps.
[0069] The finished film-type laminate 7 is then wound onto a film
coiling roll 6 for further processing.
[0070] In a modified version of the example each coating station
can feature a curing unit instead of having a common curing station
5, so that each layer deposited can be cured individually by UV or
EB radiation.
[0071] A film-type laminate 11 in FIG. 2 manufactured using the
process according to the invention contains a first film 15 and a
second film 17 which are laminated together using an adhesive layer
16. The first free surface of the film-type laminate 11 exhibits
printing 12. A print overlayer coating 13 is present on top of the
printing 12.
[0072] Deposited on the free surface of the film-type laminate 11
opposite that bearing the printing 12 is a layer of sealing
lacquer. The coating of sealing lacquer 14 may cover the actual
sealing area in part or cover the whole of the film-type laminate
11.
* * * * *