[0001] The present invention relates to security documents such as banknotes, currency,
identification documents, passports, cheques, visas, certificates and the like, and
methods for their manufacture. In particular, the invention relates to security documents
incorporating security devices in the form of optically variable effect generating
relief structures such as holograms and/or diffraction gratings. The disclosed methods
are particularly well adapted for integral formation of such security devices on a
security document having a polymeric substrate, such as a polymer banknote.
[0002] Optically variable effect generating relief structures such as holograms and diffraction
gratings have been used widely over the last few years to impart security to documents
of value such as banknotes, credit cards, passports and the like. Conventionally,
the structure is provided on a transfer foil and then hot stamped from the transfer
foil onto the final document substrate. An early example of this approach is described
in
US-A-4728377. Such techniques work well with traditional security documents having substrates
formed of paper, for example. However, it can prove difficult to adhere such articles
to other types of substrate, such as polymer substrates. For instance, polymer-based
banknotes typically comprise a substrate of polypropylene, which can withstand temperatures
up to around 80 degrees C. Hot stamping methods commonly operate at higher temperatures,
e.g. around 250 to 300 degrees C, which would cause damage to such substrates. Meanwhile,
the use of cold adhesives has generally proved unsuccessful since the bond between
polymer and security device is often not sufficiently robust.
[0003] In order to avoid such problems, alternative methods have been employed including
the use of "cast-cure" resins. A curable material is applied to the polymer substrate
and embossed with a desired relief structure. Simultaneously or subsequently, the
material is cured, e.g. by exposure to UV radiation, in order to fix the relief structure.
A metallic ink is then applied to the relief to provide a reflective layer, in order
to render the optically variable effect visible. An example of such a method is disclosed
in
WO-A-2008/031170.
[0004] Whilst this technique results in strong adhesion between the substrate and security
device, due to bonding between the polymeric substrate and curable resin, the quality
of the resulting security device is typically not optimal. One reason for this is
the use of a metallic ink to enhance the optically variable replay, which does not
give rise to as bright and clear an optical effect as is achievable in traditional
transfer foil type devices which use a metal or high refractive index layer as the
reflective material. This is because the reflective particles making up a metallic
ink cannot conform to the relief structure to the same degree that can be achieved
where a metal or HRI layer is applied to the relief. However, the use of metal or
HRI layers is problematic since the methods required for deposition of such materials
typically involve heating the substrate, which leads to warping. This gives rise to
loss of registration between the curable resin region and the metallised area and/or
between the curable resin region and coating layers or printed graphics on the document.
[0005] Document
WO 2011/017749 A1 discloses a method according to the preamble of claim 1.
[0006] In accordance with the present invention, a method of manufacturing a security document
comprises:
- (a) providing a polymeric substrate having first and second surfaces;
then performing the following steps (b), (c) and (d) in any order:
(b) applying a curable material to a first region of the substrate on its first surface;
(c) forming the curable material such that its surface distal from the substrate follows
the contours of an optically variable effect generating relief structure and curing
the curable material such that the relief structure is retained by the cured material;
(d) applying one or more coating layers to the first and/or second surface(s) of the
substrate to define a viewing region, the coating layer(s) being absent at least on
the first surface across all or part of the first region;
then:
(e) applying a masking substance to the first surface of the substrate, excluding
at least a second region which includes at least part of the first region, the overlapping
portions of the first and second regions defining a third region;
(f) depositing a reflection enhancing material onto the first surface of the substrate
such that, in the third region, the reflection enhancing material is deposited onto
the cured material and follows the contours of the relief structure; wherein the masking
substance impedes the retention (e.g. deposition and/or adhesion) of the reflection
enhancing material such that the reflection enhancing material is retained only in
areas to which the masking substance was not applied.
[0007] By "viewing region" it is meant a gap in the coating layer(s) applied in step (d),
within which the relief structure will be viewed in the end product. The viewing region
could have the same opacity as its surroundings such that it is not distinguishable
in transmitted light. However, in preferred examples the viewing region comprises
a window region, i.e. a region of lower opacity than its surroundings.
[0008] By applying both coating layer(s) which define the viewing region and curable material
(forming a security device) and then using a masking substance to define those parts
of the substrate in which the reflection enhancing material will be retained, the
result is that the coating layer(s), curable material and reflection enhancing material
can all be applied in register with one another, whilst still enabling the use of
a metal or HRI layer as the reflection enhancing material. As such, the optical quality
of the security device formed in the third region by the cured material and reflection
enhancing material in combination can be comparable to those of traditional foil-based
devices. High registration is achievable because all of the steps which define the
end locations of the curable material, reflection enhancing material and viewing region
in the coating layer(s) are performed before the step of depositing the reflection
enhancing material (during which heating typically takes place), and hence before
any warping or distortion or stretch of the substrate occurs.
[0009] It is therefore preferable that in steps (b), (d) and (e), the respective curable
material, coating layers and masking substance are applied in register with one another
and advantageously in register with the relief structure formed in step (c).
[0010] Moreover, as discussed further below, the use of a masking substance in this way
has the benefit that each of the steps defining the end locations of the viewing region
in the coating layer(s), the curable material and the reflection enhancing material
can be performed using similar or the same type of application techniques (e.g. printing
or coating), and hence all can be performed in a continuous, in-line process. This
further enhances the achievable registration and simplifies the manufacturing process
since all of these application steps can be completed before the deposition step (e.g.
metallisation), which may take place separately, e.g. as part of a separate process
and potentially on separate apparatus. This may be the final step in the manufacturing
process with no need for further application steps, hence reducing the manufacturing
process to two key stages.
[0011] The viewing region could take a number of different forms, including an interruption
in only the coating layer(s) applied to the first or second side of the substrate
to reveal the security device, whilst the other side may ultimately be fully coated
with opaque material, in which case the viewing region will not be visible in transmission.
However, as noted above, in preferred examples, the viewing region defined by the
coating layer(s) laid down in step (d) is a window region. This may ultimately be
a full window (i.e. no coating layer is provided on either side of the substrate in
the window region) or a half window (i.e. coating layer(s) of less than 100% opacity
are applied to only one side of the substrate in the window region).
[0012] The coating layer(s) which are laid down in step (d) are the layer(s) which define
the location, shape and size of the viewing region by means of a gap in those layer(s).
In some cases, this will include all of the coating layers which are planned to be
applied to the security document. However, in other cases there may be additional
coating layer(s) which do not contribute to the definition of the viewing region and
in this case such additional layer(s) could be applied during step (d) or at any later
stage, including after step (e) or after step (f). For example, where the viewing
region is a half window type structure (translucent or non-translucent), the coating
layer(s) applied to one side of the substrate may extend all over the substrate and
these could be applied later since no registration between such all-over layer(s)
and any other feature is necessary. However in general it is preferable to apply all
of the coating layers before step (f) so that all the printing / coating steps are
complete before application of the reflection enhancing material. In this way the
substrate web does not have to be returned to printing/coating apparatus after reflection
enhancing material deposition.
[0013] It should also be noted that whilst the coating layer(s) applied in step (d) will
generally be applied outside the first region containing the curable material, those
coating layer(s) may also overlap that first region, provided that on the first surface,
at least part of the first region is left uncovered at the end of step (d) so that
it is available for receipt of reflection enhancing material in step (f). Hence, on
the first surface of the substrate, the coating layer(s) applied in step (d) will
not fully overlap the curable material, but on the second surface of the substrate
the coating layer(s) applied in step (d) may extend across the whole first region,
e.g. if the viewing region is to be a half-window. In preference, the coating layer(s)
define either a window or a "half-window" structure (translucent or non-translucent)
on the substrate within which at least part of the curable material is located.
[0014] The relief structure could be configured to exhibit any type of optically variable
effect, which means that its appearance is different at different viewing angles.
In particularly preferred embodiments, the optically variable effect generating relief
structure is one which gives rise to a diffractive optical effect, such as a hologram
or a diffraction grating. However, it should be appreciated that in other embodiments
the relief structure may be a non-holographic optical structure, such as a prismatic
structure.
[0015] The masking substance could operate according to various different mechanisms, including
inhibiting adhesion of the reflection enhancing material to the substrate and/or obstructing
deposition of the reflection enhancing material onto the substrate in the first place.
Depending on the type of masking substance used, no further steps beyond deposition
may be necessary to achieve the desired result. For instance, the masking substance
may repel the reflection enhancing material such that no deposition of the reflection
enhancing material occurs in the areas to which the masking substance has been applied.
In other cases, there may be some deposition of the reflection enhancing material
in these areas. This may become detached subsequently without any positive intervention,
but in preferred implementations, the method further comprises, after step (f):
(f1) washing the substrate to remove any residual reflection enhancing material in
areas to which the masking substance was applied.
The washing may be performed using a liquid (e.g. water) or gaseous (e.g. air jet)
substance. Where a liquid is used, preferably the liquid has the capacity to dissolve
the print mask (e.g. the mask is soluble within the washing liquid).
[0016] In one preferred implementation the masking substance comprises an oil mask adapted
such that application of the reflection enhancing material thereto causes degassing
of the oil mask, thereby impeding adhesion of the reflection enhancing material to
the substrate. Such substances have the benefit that a subsequent removal step (e.g.
step (f1)) is typically not required. Examples of suitable oil masks include low molecular
weight oils, including silicones, which will boil off in a vacuum environment.
US-A-3935334 mentions oil masks in the content of metallised resin films for condenser elements.
[0017] In other preferred embodiments, the masking substance comprises a soluble mask, such
as soluble ink (comprised of an appropriate binder and pigment combination), which
does not adhere strongly to the substrate or can be dissolved by application of a
solvent (aqueous or otherwise), thereby impeding adhesion of the reflection enhancing
material applied thereto to the substrate. In this case a washing step may be required.
Examples of a suitable soluble mask in the form of a heavily pigmented ink are described
in
WO-A-9913157. Various mechanisms may be adopted but in one example, the soluble mask is configured
such that, when coated with a thin deposited layer of reflection enhancing material
(e.g. metal) the masking substance creates small holes or discontinuities in the metal
film by virtue of the fact that the metal film (typically 15 to 30nm thick) is not
thick enough to continuously over coat the pigment grains in the mask. When immersed
in a suitable solvent (preferably water) the solvent enters through these holes, dissolving
the pigment such that the overlying metal layer disbands. In order for this mechanism
to operate effectively, the pigment grain dimensions are preferably greater than the
thickness of the reflection enhancing film. For instance, preferred pigment grain
sizes may be in the range of greater than or equal to about 100 nm, and less than
500 nm. The upper limit on this range takes into account that in typical designs the
minimum line with of a reflective region will be of the order of 500 nm, and the grain
size should be less than this in order to permit adequate resolution of the desired
pattern. Other examples of suitable soluble masks are disclosed in
US-A-5142383,
EP-A-1023499 and
US-A-3935334.
[0018] The use of a soluble mask will be preferred over an oil mask in many cases, since
such oils (e.g. low molecular weight oils) will tend to offset, transfer or smear
if the substrate web is wound into a roll after printing. As such, the use of oil
masks is more suited to processes in which in-line metalisation takes place after
the printing or other application steps (i.e. there is no rewind process between printing
and metalisation). In contrast, the use of a print soluble mask applied does not impose
such limitations. In addition, the vapours produced by degassing of an oil mask can
in some circumstances lead to contamination of the optical structure.
[0019] The curable material, coating layer(s) and masking substance can be laid down using
any appropriate method which enables selective application of the materials to the
desired regions of the substrate. In preferred embodiments, in steps (b), (d) and/or
(e), the respective curable material, coating layers and/or masking substance are
applied using one or more printing technique(s), such as gravure printing, flexographic
printing or slotted die coating. Printing techniques are preferred since the materials
can be laid down in a precisely controllable manner. Different printing techniques
may be used for each of the steps as appropriate for the material in question. However,
in particularly preferred embodiments, the same printing technique is used for steps
(b), (d) and (e), which simplifies the manufacturing process and apparatus.
[0020] As mentioned above, it is especially preferred that at least steps (b), (c), (d)
and (e) are performed in a continuous, in-line process. For example, these steps may
be carried out at stations along one continuous manufacturing line such that the relative
location of the substrate is known between one station and the next. This approach
allows particularly high registration to be achieved and also delimits all the printing/application
steps from subsequent metallisation (or other deposition) processes.
[0021] The deposition of the reflection enhancing material can be achieved using any appropriate
deposition technique but generally a non-selective deposition technique will be preferred
for simplicity. That is, the technique will result in the deposition of a contiguous
layer of the reflection enhancing material across the entire area of the substrate
which is exposed to the deposition process. In many cases, this will be the entire
first surface of the substrate (although this is not essential). Preferably, the reflection
enhancing material is deposited by vacuum deposition, suitable techniques including
electron beam vapour deposition, vapour deposition from a resistively heated source
(e.g. a boat source), pulsed laser vapour deposition, evaporative vapour deposition
and sputtering, as well as chemical vapour deposition methods. Evaporative vapour
deposition techniques from resistively heated or electron beam sources are generally
preferred.
[0022] Preferably, the reflection enhancing material is a metal or alloy, or a material
with a refractive index which differs from that of the cured material by at least
0.3, more preferably 0.5 (known as "high refractive index (HRI)" materials). That
is, the reflection enhancing material is laid down as a contiguous layer of the selected
material (or as multiple spaced portions each having such a contiguous layer). This
should be contrasted with materials such as metallic inks, which comprise a dispersion
of reflective particles in a binder, the reflective (particle) material itself therefore
not forming a contiguous layer. Examples of suitable metals or alloys include aluminium,
copper, nickel, chrome, aluminium-copper allows, silver, gold, etc. By "high refractive
index" (HRI) materials, we mean materials having an index of refraction which exceeds
that of the transparent base layer by a numerical value of preferably 0.5 or more.
Since the refractive index of the base layer will typically fall in the range of 1.45
- 1.55, then a high refractive index material will be one with an index of preferably
2.0 or more. In practice high refractive index materials with good visual transparency
will have an index in the range 2.0 to 2.5. Examples of suitable HRI materials include
zirconium dioxide and zinc sulphide and titanium dioxide
[0023] In particularly preferred embodiments, the curable material is a transparent curable
material. This enables the optical effect generated by the relief structure to be
observed through the substrate and hence, if the opposite side of the relief structure
is also visible and both sides of the reflection enhancing material conform to the
relief, the optical effect is exhibited by both sides of the device. This results
in a security device with a strong visual impact and hence increased security level.
[0024] The curable transparent material may be of a type which can be cured by the application
of any form of energy, such as heat. However, in most preferred embodiments, the curable
transparent material is radiation-curable, preferably UV-curable, and in step (c)
the curing comprises exposing the formed curable material to curing radiation, preferably
UV radiation. The application of radiation can generally be more accurately controlled
than that of heat, e.g. through the use of appropriately directed radiation sources
and/or masks. Additionally the cross-linking action is generally much more rapid in
UV curable systems compared to thermal cure systems leading to a more accurate relief
forming process. Finally it is often very desirable to limit or strongly minimise
thermal distortion of the substrate and in such cases a UV cure may be the only suitable
cross-linking approach. It should be noted that radiation wavelengths other than UV
may be used. However, it is preferred that the substrate is at least semi-transparent
to the curing energy (e.g. to the relevant radiation wavelength(s)), so that the energy
can be applied to the curable material through the substrate. Polypropylene, for example,
is generally transparent to UV wavelengths.
[0025] As mentioned above, the curable material is preferably at least visually semi-transparent
(i.e. transmits wavelengths in the visible range) such that the optical effect of
the device can be viewed through the material. However, the material need not transmit
all visible wavelengths equally and in preferred examples, the material further comprises
an optically effective substance, preferably a visible colourant, a luminescent, phosphorescent
or fluorescent material. This further enhances the security level of the device and
can be used to cause the optically variable effect to be seen in a different colour
when viewed from one side of the device (through the curable material) as opposed
to the other. Such optically effective substances could additionally or alternatively
be disposed in any of the other layers of the device, including the substrate and/or
the reflection enhancing layer.
[0026] In many implementations, a single type of curable material will be applied in the
first region. However, in some preferred embodiments, step (b) comprises applying
two or more curable materials to the first region of the substrate in a pattern, one
or more of the curable materials comprising an optically effective substance such
that the two or more curable materials have different optical characteristics, preferably
visibly different under at least visible or non-visible illumination. By providing
a pattern which is detectable either to the naked eye or to a machine in this layer,
the security level of the device is further increased. If two or more curable materials
are provided it is preferred that they are each adapted to be cured by the same type
of curing energy and most advantageously at the same rate as one another, so that
both are cured simultaneously in step (c).
[0027] In step (c) the partially cured transparent material and the layer of reflection
enhancing material can be formed by any appropriate method but preferably the layers
are embossed with a die carrying the relief structure, wherein the die advantageously
forms part of an embossing roller. If multiple devices are to be formed on a substrate
web (later to be divided into individual security documents each carrying one of the
devices), the embossing roller may preferably carry the relief structure in the form
of a repeating pattern. The repeat periodicity is preferably matched to that of the
document repeat length and/or width.
[0028] In step (c), the curable material may be cured simultaneously with and/or subsequently
to forming of the relief structure in the surface of the curable material. For example,
if the embossing roller is opaque (e.g. metal), curing can occur at the point of impression
with radiation being transmitted through the substrate, for instance using a transparent
quartz nip roller opposing the embossing roller. Alternatively curing can take place
just after the resin leaves the impressing nip, in which case the radiation can be
applied through the substrate or from the opposite side.
[0029] Preferably, the one or more coating layers applied in step (d) comprises one or more
opacifying layers. This step is particularly relevant where the substrate is to become
the substrate of a polymer banknote. The coating may be applied to one or both sides
of the substrate and as mentioned above, is preferably omitted across the (third)
region in which the security device is formed on both sides, although in some cases
it may be applied across all of some of the region on the side of the substrate opposite
from that to which the curable material is applied. This can lead to the appearance
of a "half window" effect and/or conceal one or more portions of the device when viewed
through the substrate. Opacifying layers typically comprise a binder containing a
white (or other coloured) pigment.
[0030] Preferably the method further comprises, after step (d) or step (f), printing a graphics
layer onto the one or more coating layers. The graphics layer may include for example
background patterns such as those typically seen on banknotes, optionally incorporating
fine line patterns, guilloches and other security features, information such as denomination
and other standard document data, and/or printed features which uniquely identify
or personalise the document, such as a serial number in the case of a banknote or
details of the holder in the case of an identity document. Most preferably, such graphics
and other features will be printed onto the document after application of the reflective
material.
[0031] Advantageously, the method further comprises, prior to step (b) or step (d), treating
the surface of the substrate to increase adhesion between the substrate and the curable
material and/or the coating layer(s), preferably by the application of a primer substance
or corona treatment. This can for example raise the surface of the substrate making
it more receptive to the subsequent application of the curable material and/or the
coating layer(s). Similarly in preferred embodiments, the method further comprises,
after step (c), treating the formed surface of the cured material to increase adhesion
between the cured material and the reflection enhancing material, preferably by plasma
or corona treatment.
[0032] As already mentioned, the method can preferably be implemented as a web-based process
with multiple security devices (i.e. "third regions") being formed on a substrate
which is then divided such that each device is located on a separate piece of substrate.
Hence, preferably the method further comprises, after step (f), cutting the substrate
into individual security. Typically this would also take place after the optional
step of printing a graphics layer has been performed.
[0033] Preferably, the first, second and/or third regions define respective indicia such
as a character, letter, number, symbol, graphic element or the like, the respective
indicia preferably being different. This can be used to create a complex security
device with a correspondingly high security level. In other preferred embodiments,
the first and second regions, and hence the third region, are the same such that the
reflection enhancing material is retained across the whole of the region in which
the curable material is present. In yet further alternative preferred embodiments,
the third region is contained within the first region, such that the reflection enhancing
material is retained across less than the whole of the region in which the curable
material is present. The shape of the viewing region (preferably a window region)
may also or alternatively define such indicia.
[0034] Advantageously, the substrate is transparent and preferably comprises a polymer such
as polypropylene (PP), orientated polypropylene (OPP), biaxially orientated polypropylene
(BOPP) polyethylene teraphthalate (PET), polyethylene, polyamide, polycarbonate, or
polyethylene naphthalate (PEN).
[0035] Preferably, the security document is a banknote, a polymer banknote, a hybrid paper/polymer
banknote, an identity document, a passport, an identification card, a cheque, a visa,
a certificate, or a stamp.
[0036] The invention further provides a security document manufactured in accordance with
the above method, wherein the security document is preferably a banknote, a polymer
banknote, a hybrid paper/polymer banknote, an identity document, a passport, an identification
card, a cheque, a visa, a certificate, or a stamp.
[0037] Also disclosed and not claimed is a security document, comprising:
a polymeric substrate having first and second surfaces;
a cured material disposed in a first region of the substrate on its first surface,
the cured material having an optically variable effect generating relief structure
formed in its surface distal from the substrate;
a reflection enhancing material disposed on at least part of the cured material, the
reflection enhancing material following the contours of the relief structure, wherein
the reflection enhancing material is a metal or alloy, or a high refractive index
(HRI) material; and
one or more coating layers disposed on the first and/or second surface(s) of the substrate,
the coating layer(s) being absent on at least one of the first or second surfaces
across all or part of the first region to define a viewing region;
wherein the cured material, the reflection enhancing material and the viewing region
defined by the one or more coating layers are registered to one another.
[0038] For the reasons given above, in conventional devices on polymer-type security documents
it has not been possible to achieve registration between the material in which the
relief is formed, the reflection enhancing material and the viewing region (e.g. window
or half-window) in the coating layer(s). High registration is beneficial since each
document so produced will have a consistent construction and appearance, making counterfeit
documents readily identifiable. Preferably, the security document is manufactured
in accordance with the method described above, and can have any of the features resulting
from any of the method steps described above.
[0039] The security document is preferably a banknote, a polymer banknote, a hybrid paper/polymer
banknote, an identity document, a passport, an identification card, a cheque, a visa,
a certificate, or a stamp.
[0040] Also disclosed and not claimed is a plurality of such security documents, wherein
the cured material, reflection enhancing material and viewing region in the one or
more coating layers have substantially the same positions relative to one another
in each of the plurality of security documents.
[0041] Examples of security devices, security documents and methods for their manufacture
will now be described with reference to the accompanying drawings, in which:
Figure 1 is a schematic cross-section through a first embodiment of a security document
equipped with an exemplary security device;
Figure 2 is a plan view of the security document of Figure 1;
Figure 3 is a flowchart depicting selected steps of a first embodiment of a method
for manufacture of a security document;
Figures 4a, b, c, d, e and f depict components of a second embodiment of a security
document at various stages of manufacture;
Figures 5a and b schematically depict an embodiment of apparatus suitable for manufacture
of a security document;
Figure 6 is a schematic cross-section through a further embodiment of a security document
exhibiting a further embodiment of a security device;
Figure 7 is a plan view of the security document of Figure 6; and
Figures 8, 9 and 10 depict further embodiments of security documents in cross-sectional
views.
[0042] The present description will focus on security documents provided with integral security
devices having optically variable effect generating relief structures which give rise
to diffractive optical effects, such as holograms or diffraction gratings. However,
it should be appreciated that in other embodiments the relief structure may be a non-holographic
micro-optical structure, such as a prismatic structure. Examples of prismatic structures
suitable for the security devices of the sort presently disclosed include, but are
not limited to, a series of parallel linear prisms with planar facets arranged to
form a grooved surface, a ruled array of tetrahedral, an array of square pyramids,
an array of corner cube structures, and an array of hexagonal faced corner cubes.
Another preferred type of micro-optical structure is one which functions as a micro
lens, including those that refract light at a suitably curved surface of a homogeneous
material such as plano-convex lenslets, double-convex lenslets, plano-concave lenslets
and double-concave lenslets. Other suitable micro-optical structures include geometric
shapes based on domes, hemispheres, hexagons, squares, cones, stepped-structures,
cubes or combinations thereof.
[0043] Figure 1 depicts a first embodiment of a security document 1, such as a banknote,
cheque, visa, passport, identification card etc., which is provided with a security
device 10. The security document 1 is formed based on a transparent substrate 2, such
as a polymer film, which also forms a substrate of the security device 10. The security
device 10 is considered to be integrally formed with the security document 1. In the
case of Figure 1, the substrate 2 is typically formed of a visually transparent polymer
such as polypropylene, although other flexible polymeric films suitable include polyethylene
terephthalate PET), polyethylene, polyamide, polycarbonate, polyvinylchloride (PVC),
polyvinylidenechloride (PVdC), polymethyl methacrylate (PMMA), or polyethylene naphthalate
(PEN).
[0044] The substrate 2 carries one or more coating layers on one or both of its surfaces
which increases the document's opacity in the covered regions and/or provides a background
to printed graphics. In the present example, the substrate 2 is coated with opacifying
layers 3 and 4, which layers carry printed graphics 5a and 5b. In the present embodiment,
both layers 3 and 4 are provided on both sides of the security document 1, but in
other cases the layers may be provided on only one side or the other. Further, here
the coatings 3 and 4 are omitted on both sides of the documents to define a viewing
region 20 within which the security device 10 is located. In this case, the viewing
region 20 is a window region having a lower opacity than its surroundings, and will
therefore be referred to hereinafter as a "window", although this is not essential
as described below. The structure depicted in Figure 1 is a "full-window". In other
cases, the layers 3, 4 (and 5) may be omitted in the window region 20 only on one
side of the document, with one or more of the layers 3, 4 and 5 continuing over all
or part of the window 20 on the other side of the document. This can be used either
to create a so-called "half window" effect or to prevent viewing of the device through
the document, as discussed further below.
[0045] Inside the window 20, on the first surface 2a of substrate 2 (here the upper surface,
facing observer A) the security device 10 is disposed. A curable transparent material
11, such as a radiation curable resin or a thermoplastic material containing a curable
cross-linking agent is disposed on the substrate 2 across a first region R
1. The curable transparent material 11 carries a reflection enhancing material 12,
such as a metal film (e.g. aluminium or copper) or a HRI layer (e.g. zinc sulphide).
The curable transparent material 11 has been formed so as to follow the contours of
a surface relief 13 defining an optically variable effect generating structure, such
as a hologram or diffraction grating (as discussed further above), and the reflection
enhancing material 12 follows the contours of the relief. The reflection enhancing
material 12 is present across a second region R
2, which at least overlaps with the first region R
1 and in this case is the same as region R
1. The parts of the first and second region which overlap define the third region R
3, in which the reflection enhancing material is deposited on the formed curable material
to form security device 10. The curable material 11, reflection enhancing material
1 and window 20 defined by coating layers 3, 4 are substantially in register with
one another, such that their relative locations do not vary substantially between
one banknote and another of the same type. For instance, the position tolerance of
the curable material 11, reflection enhancing material 1 and coating layers 3, 4 may
be as low as +/- 100 to 200 microns or exceptionally less from one document to the
next.
[0046] In this example, the security document is completed by the application of a protective
varnish or lacquer 19 (also preferably transparent) which covers the security device
and, here, also a portion of the surrounding window region 20 and optionally coatings
3, 4 and 5. In some cases the whole first surface 2a of the security document 1 may
be covered with the protective coating 19. The coating 19 could be coloured or multicoloured
or contain a security substance, e.g. a fluorescent, luminescent or phosphorescent
material.
[0047] It will also be noted that, in this example, the transparent curable material 11
is not applied directly to the transparent substrate 2, but rather a primer layer
9 exists between the substrate 2 and the curable transparent material 11. The primer
layer 9 improves adhesion between the substrate 2 and the transparent curable material
11. However its use is optional. In further alternative embodiments, the substrate
2 may be corona treated in order to improve adhesion between it and curable material
11.
[0048] Figure 2 shows a plan view of the security document of Figure 1 as viewed by observer
A. As previously described, the document 1 carries graphic layer 5 across much of
its surface which (together with underlying coating layers 3 and 4) is omitted in
the region of window 20. Inside window 20, the security device 10 extends across the
region R
3 which here has the form of a sun-shaped symbol. In other cases, the region R
3 may define an alternative indicia such as a letter, number or graphic, and the region
R
3 could extend to cover the whole window 20 (although this is less preferred). The
optically variable effect generated by relief structure 13 is visible across the whole
of sun-shaped region R
3 (assuming the relief structure 13 itself extends across the whole of the region).
Outside the region R
3, the window 20 is transparent and optically invariable. It should be noted that in
this case when the security document is viewed from the opposite side of the substrate
(i.e. from the position of observer B depicted in Figure 1) its appearance will be
substantially identical as that shown in Figure 2 since here the same surface relief
13 in reflective layer 12 will be viewed through transparent curable material 11.
[0049] Figure 3 depicts steps in a first embodiment of a method suitable for forming a security
device of the sort described with respect to Figures 1 and 2. To illustrate exemplary
implementations of the steps, Figures 4(a) to (f) show another embodiment of a security
document at various stages during its manufacture.
[0050] As will be discussed below, the initial steps of the method may be carried out in
a different order from that shown in Figure 3.
[0051] In step S101, a curable material 11 is applied to the first surface 2a of substrate
2, e.g. using any appropriate coating or printing techniques, preferably gravure,
and the resulting structure is shown in Figure 4a. As described previously, in practice
the substrate may be treated prior to application to curable material 11, either by
applying a primer layer 9 or by corona treatment to raise the surface of the substrate
material, for example. The curable material is applied across a first region R
1 which may define indicia. The curable material could be a radiation curable resin
or a thermoplastic containing a curable hardening agent. For instance, a curable resin
may typically be one of two types: a) Free radical cure resins which are unsaturated
resins or monomers, prepolymers, oligomers etc. containing vinyl or acrylate unsaturation
for example and which cross-link through use of a photo initiator activated by the
radiation source employed e.g. UV; or b) Cationic cure resins in which ring opening
(e.g. epoxy types) is effected using photo initiators or catalysts which generate
ionic entities under the radiation source employed, e.g. UV. The ring opening is followed
by intermolecular cross-linking. The radiation used to effect curing will typically
be UV radiation but could comprise electron beam, visible, or even infra-red or higher
wavelength radiation, depending upon the material, its absorbance and the process
used. Alternative thermoplastic lacquers such as PMMA-based resins, acrylic resins
or vinyl/styrene copolymers could be used with added curing agent.
[0052] In step S103, a relief structure 13 is formed into the surface of the curable material
11 so as to define an optically variable effect generating structure such as a hologram
or a diffraction grating. This may be achieved for example by impressing the curable
material using an embossing roller. The material is cured, for example by exposure
to an appropriate curing energy such as heat or radiation (preferably UV radiation)
in order to fix the relief structure in place such that the material cannot relax
or exhibit viscous flow. Any known cast-cure process can be used to perform step S103
and it should be noted that curing may take place simultaneously with and/or subsequently
to the casting of the relief into the material. Figure 4b shows the formed relief
13 in material 11 and irradiation of the material with curing energy E (e.g. UV radiation)
through substrate 2.
[0053] In step S105, one or more coating layers are applied to the substrate defining a
viewing region (e.g. a window region) containing all or part of the region in which
curable material 11 has been laid down. In the example depicted in Figure 4c, two
coating layers 3 and 4 in the form of opacifying layers have been laid down on the
first surface 2a of the substrate. In this example, both layers are provided only
outside the curable material region R
1, but in other cases there could be an overlap. Further, in this example both coating
layers 3, 4 are provided on the first surface 2a of the substrate 2. In other cases,
the coating layer(s) may alternatively or additionally be disposed on the opposite
surface 2b of the substrate. If coating layer(s) are to be provided on both sides
of the substrate, the coating layer(s) may be applied to each side simultaneously
or sequentially.
[0054] It will be appreciated that the same structure shown in Figure 4c can be obtained
in a number of different ways. In particular, as illustrated by the dashed line arrows
in Figure 3, step S105 in which the coating layer(s) are applied may be carried out
prior to the application of the curable material 11 (i.e. before step S101). Alternatively,
the coating layer(s) could be applied after the curable material 11 has been applied
but before it is formed and cured (i.e. between steps S101 and S103). It would also
be possible to apply various different coating layers at different stages during this
part of the process, for example a first opacifying layer 3 could be applied before
step S101 and a second opacifying layer 4 could be applied after step S103.
[0055] After the curable material 11 and coating layer(s) defining the viewing region have
been applied to the substrate, and the curable material has been formed and cured,
in step S107 a masking substance 15 is applied to the first surface 2a of the substrate,
as shown in Figure 4d. The masking substance 15 is laid down across areas of the substrate
in which the reflection enhancing material is ultimately not desired and, as such,
the masking substance 15 can comprise any material which impedes adhesion of the reflection
enhancing material 12 to the underlying substrate (and/or to any intervening layers,
such as layers 3 and 4 in this example). In one preferred embodiment, the masking
substance 15 comprises an oil mask which de-gases when a material is laid down on
top of it, thereby preventing its adhesion. In another preferred embodiment, the masking
substance 15 comprises a soluble mask, such as soluble ink. One exemplary type of
soluble ink is heavily pigmented ink as disclosed in
WO-A-99-13157. Mechanisms by which soluble masks operate vary but in one example, the pigment grains
in the mask are sufficiently large that when a layer of metal or other reflection
enhancing material is deposited on top of the ink, holes are formed through the deposited
layer. As such, during subsequent washing with a solvent, the fluid can pass through
the deposited layer, reaching and dissolving the pigment. This leads to detachment
of the reflection enhancing material from the substrate in the regions where the soluble
mask is present. Further examples of suitable soluble masks are given in
US-A-5142383,
US-A-3935334 and
EP-A-1023499.
[0056] In order that the reflection enhancing material 12 can be deposited onto and strongly
bond to at least part of the relief structure 13, the application of masking substance
15 excludes a second region R
2 of the substrate, which second region R
2 includes at least part of the first region R
1 in which the cured material 11 carrying the relief structure is present. In the example
depicted in Figure 4d, the second region R
2 is coincident with the first region R
1, but this is not essential.
[0057] With the masking substance 15 in place, in step S109, the reflection enhancing material
is deposited onto the first surface 2a of the substrate 2 to form a layer of reflection
enhancing material 12 which extends over the cured material 11 and neighboring regions
of the substrate, including portions covered by masking substance 15 as shown in Figure
4e. In practice, depending on the nature of masking substance 15, in fact the reflection
enhancing material 12 may not settle on the masking substance. For example, if the
masking substance de-gases upon deposit of the reflection enhancing material 12, the
deposition step S109 may result directly in the structure shown in Figure 4f, in which
the reflection enhancing material is present only on the cured material 11. In other
cases, some residual reflection enhancing material 12 may remain on the masking substance
15 in which case a removal step, such as washing step S111, may be performed. This
may involve for example washing the surface of substrate 2 with a liquid (e.g. water)
or a gas, such as an air jet. This causes detachment of the reflection enhancing material
12 from the substrate in the areas where masking substance 15 is present, resulting
in the same final structure shown in Figure 4f. The region of the cured material 11
to which the reflection enhancing material 12 is applied (i.e. the overlapping parts
of regions R
1 and R
2, termed the third region, R
3) exhibits the desired optically variable effect.
[0058] The reflection enhancing material 12 deposited in step S109 is preferably a contiguous
film of a suitable reflective material, such as a metal or alloy or an HRI material,
so as to achieve high quality optical replay. The material is preferably deposited
by a non-selective method, such as vapour or vacuum deposition, in which the whole
surface of the substrate that is exposed to the process will be coated with the material
(as opposed to a selective application process such as printing). For example, the
material may be deposited by a physical vapour deposition process such as evaporative
deposition or sputtering, or a chemical vapour deposition process.
[0059] In contrast, the previously laid down components (i.e. the curable material 11, coating
layers 3 and 4 and masking substance 15) are laid down at controlled locations using
preferably a printing technique such as gravure, intaglio, lithographic printing etc.,
so that the extent and position of each can be precisely controlled. Preferably, the
printing or other application techniques used in steps S101, S103, S105 and S107 are
performed in register with one another such that the curable material 11, coating
layers 3 and 4 and masking substance 15 (and therefore the ultimate position of reflection
enhancing material 12) are registered to one another. That is, on a series of like
documents produced in the same way, the relative locations of these components of
the documents will be substantially identical. Particularly high registration can
be achieved by performing steps S101, S103, S105 and S107 in an inline process with,
for example, substrate 2 travelling as a web between stations at which each of the
steps is carried out. In this way, the positioning of the substrate 2 relative to
each of the stations is known and can be controlled. For example, if the curable material
11, coating layers 3 and 4 and masking substance 15 are each applied by gravure, registration
tolerances of +/-100 to 200 microns are achievable.
[0060] An example of apparatus suitable for manufacturing a security document of the sort
described above will now be described with reference to Figures 5a and 5b. It should
be noted that the exemplary apparatus depicted in Figure 5 is suitable for implementing
the method as a continuous web-based technique but in other (less preferred) examples,
the documents could be made using batch processing methods.
[0061] As mentioned above, the steps of applying the curable material, forming the relief
and curing, applying the one or more coating layers and applying the masking substance
are preferably carried out in an inline process, and Figure 5a shows an example of
suitable apparatus for such a process. Subsequent steps involving deposition of the
reflection enhancing material can be carried out as continuation of the process or
in a separate manufacturing line. Since all of the printing or other application type
steps for which accurate registration is desirable are carried out before the steps
involving deposition of the reflection enhancing material, the method lends itself
well to carrying out manufacture in two distinct phases and in this example these
are reflected by the division between Figures 5a and 5b.
[0062] Thus, Figure 5a depicts an exemplary apparatus 30 for carrying out steps S101 to
S107 of the method described with respect to Figures 3 and 4. The substrate 2, such
as a transparent polymer film, is supplied from a reel 31. At a first station 32,
a curable material 11 is applied to the substrate 2 preferably over discrete regions
R
1 (although in other cases the region R
1 may effectively cover the whole substrate 2). In this example, the curable material
11 is a radiation curable material. The station 32 may comprise for example a print
roller 32a and an opposing roller 32b. The substrate 2 is then conveyed to second
station 33 where a relief structure 13 is formed. Here, the station 33 comprises a
rotary embossing roller 33a carrying a repeating pattern of the desired relief structure
13, and opposing roller 33b such as a transparent quartz nip roller. The relief 13
is impressed into the curable material 11 which is simultaneously exposed to curing
energy E, such as UV radiation. In this example, the radiation source E is disposed
within the transparent nip roller 33b. As such, curing takes place at the point of
impression of the relief structure 13 into the curable material. However, in other
examples, radiation source E may be located just after the web leaves the impressing
nip, e.g. between rollers 33a and 33b.
[0063] The web, now carrying a series of cured regions 11 each having an impressed surface
relief 13, now passes to a third station 34 at which one or more coating layers (such
as 3 and 4 depicted in previous Figures) are applied to the substrate 2 to define
a viewing region within which at least part of the cured material is located, on one
or both sides of the substrate 2. Station 34 may comprise for example a print roller
34a and an opposing roller 34b. In practice, more than one such station may be provided
if multiple coating layers are to be applied.
[0064] At a fourth station 35, a masking substance 15 is applied to the first surface 2a
of the substrate 2, so as to mask off areas in which reflection enhancing material
is not desired. Thus, the area to which the masking substance 15 is applied excludes
a second region R
2 at least partially overlapping with the cured surface relief regions. The printing/application
steps S101 to S107 are thus complete and the intermediate product so-produced may
then be wound on to a reel 36 for onward processing at a later time or on a separate
apparatus. Alternatively, the web may continue directly to apparatus of the sort described
for example with respect to Figure 5b.
[0065] Thus, Figure 5b depicts exemplary apparatus for carrying out deposition of reflection
enhancing material and an optional washing step. Here, reel 41 supplies the substrate
2 in the form of the intermediate product resulting from the manufacturing stages
already described. The web is conveyed through a fifth processing station 42 which
in this example comprises a vapour deposition chamber 42a for depositing reflection
enhancing material such as metal or a HRI material on to the first surface 2a of the
substrate. Typically, the reflection enhancing material may be deposited across the
full width of the web as it passes through the chamber.
[0066] As discussed above, depending on the nature of the masking substance 15, no further
processing steps may be necessary. In other cases, a step of removing residual reflection
enhancing material from regions in which it is not desired is useful and in this case
the web may be conveyed through a sixth processing station 43, here comprising a washing
chamber 43a in which the first surface of the substrate is subjected to washing, e.g.
by passing the web through a fluid bath or directing air jets onto the surface of
the web. The completed web may then be collected on a reel 44.
[0067] Optional onward processing steps will depend on the nature of the security document
in question but may comprise for example one or more further printing steps (e.g.
application of further coating layer(s) and/or graphics layer 5) and/or cutting of
the web into individual security documents each carrying one security device manufactured
in the above described manner. The apparatus may also include additional stations
for carrying out optional steps such as surface treatment of the substrate 2 and/or
cured material 11. For example, a station may be provided upstream of station 32 for
treating the substrate 2 so as to improve adhesion of the curable material and/or
coating layers to its surface. This may be achieved for example by applying a print
receptive primer such as layer 9 shown in Figure 1 or carrying out corona treatment.
Similarly, a treatment station may be inserted at any stage downstream of station
33 for treating the surface of cured material 11 prior to application of the reflection
enhancing material, e.g. by plasma or corona treatment.
[0068] As mentioned above, the application of the curable material and the application of
the one or more coating layers defining the viewing region may be carried out in the
opposite order to that depicted in Figure 5a, in which case the relevant processing
stations will be rearranged as appropriate.
[0069] A further embodiment of a security document 1 comprising an integral security device
10' will now be described with reference to Figures 6 and 7. Here, the construction
of security document 1, including substrate 2, coating layers 3 and 4 and print 5
is the same as discussed with respect to Figures 1 and 2, and like features are identified
using the same reference numbers. The security device 10' is formed using the same
technique as described above. As such, a reflection enhancing material 12 is disposed
on cured material 11 and follows a surface relief 13 defining an optically variable
effect generating structure. In this example, reflection enhancing material 12 does
not cover the whole region R
1 in which the cured material 11 is present, but rather (as shown best in the plan
view seen by observer A, shown in Figure 7), only a portion thereof. Here, the cured
material 11 covers a region R
1 having the form of a six-pointed star shape whilst the reflection enhancing material
12 is provided only across an area R
2 within region R
1, having the shape of an arrow symbol. The region R
2 is that region omitted by the coverage of masking substance 15 during manufacture.
In this case the optically active region R
3 therefore shares the same bounds as R
2.
[0070] The regions R
1 and R
3 preferably define different indicia. If the cured material 11 is clear and colourless,
the star-shaped region R
1 will not be visible to the observer. However, in this embodiment the cured material
11 comprises an optically effective substance such as a colorant, making it visible
to observers A and B. The colorant will also have the effect of causing the device
to have different optically variable appearances from the point of view from observer
A and observer B, since observer A will see the optical effect through colourless
protective lacquer 19, meaning that the colour of the effect will be determined solely
by that of reflection enhancing material 12, whereas observer B will see the optically
variable effect through the cured material 11 which will therefore impose its colour
onto the optically variable effect.
[0071] The optically effective substance in the cured material 11 could comprise any visible
colorant and/or any non-visible but machine detectible substance and/or a substance
which only becomes visible under certain conditions, such as UV illumination. For
example, the optically effective substance could be a luminescent, fluorescent or
phosphorescent material.
[0072] The reflection enhancing material 12 and/or substrate 2 may also comprise an optically
effective substance such as these.
[0073] The security level of the document can be further increased by forming the layer
11 from two or more transparent curable materials, and this is the case in the embodiment
depicted in Figures 6 and 7, where one portion of region R
1 is formed of a first curable material 11a and another portion of the region is formed
with a second curable material 11b. The two or more curable materials preferably comprise
different optically effective substances so that a pattern formed by the two curable
materials is visible to a human observer and to a machine. It is preferred that where
two or more materials are provided in this way, they are each responsive to the same
form of curing energy so that both can be cured simultaneously in step S103.
[0074] Figures 8, 9 and 10 depict cross-sections through three further embodiments of security
documents illustrating further optional features.
[0075] In the embodiments described so far, the substrate 2 of the document is transparent
and this is preferred in order to provide document with features such as see-through
windows or translucent half-windows which have a high recognition value and thus increase
the security level of the document. However, this is not essential and the polymeric
substrate could be translucent or opaque and this is the case in the Figure 8 embodiment.
In this case, the security device 10" is only designed to be viewed from one side
(that of observer A) and thus the coating layers 3b, 4b and print 5b on the second
surface 2b of the substrate 2' may be continuous in the region of the security device
10". Here, the viewing region 20' has the same opacity as its surroundings and a similar
result could be achieved using a transparent or translucent substrate 20 in combination
with all-over coating layers 3b, 4b of sufficiently high opacity. The security device
10" is constructed in substantially the same manner as described above. In this example
however, the second region R
2 across which the masking substance 15 is omitted during manufacture extends beyond
the edges of the first region R
1 in which the curable material 11 is deposited. Thus, as shown in Figure 8 in the
resulting security document the reflection enhancing material 12 may extend beyond
the perimeter of the cured material 11 carrying the surface relief 13. In this case,
the optically active third region R
3 is equal to the first region R
1.
[0076] In the previous embodiments, all of the coating layers 3, 4 which are intended to
be applied to the security document are applied prior to deposition of the masking
substance and reflection enhancing material. However this is not essential since only
those coating layers which contribute to the definition of the viewing region 20 need
be applied at that time. Figure 9 shows an exemplary embodiment in which it is advantageous
to apply certain coating layers prior to application of the reflection enhancing material,
and others after. Here, the security document 1" is provided with a security device
10"' which is designed to be viewed only through the substrate 2 (which must therefore
be transparent), through viewing region 20" from the position of observer B. The curable
material 11 is also transparent and the optically variable effect generated by relief
structure 13 can thus be viewed through the curable material 11 and the transparent
substrate 2. In this case, the security device is manufactured using the same method
as described above but, in the process step corresponding to step S105 shown in Figure
3, only coating layers 3b and 4b are applied (to the second surface of the substrate
2), since it is only these layers which define viewing region 20". At this stage,
no coating layers are applied to the first surface of the substrate 2 which is to
carry curable material 11. Thus, the relief structure 13 remains available for deposition
of the reflection enhancing material 12. After the reflection enhancing material 12
has been applied to the desired region, further coating layers 3a, 4a are applied
all-over the first surface of the substrate, including over security device 10"'.
The coating layers 3a, 4a may or may not be of the same number and/or composition
as the coating layers 3b, 4b. If the coating layers 3a, 4a are translucent, the viewing
region 20" will act as a half-window, becoming distinguishable from its surroundings
when viewed in transmitted light. Alternatively, if the coating layers 3a, 4a are
sufficiently opaque (in combination), the viewing region may not have the characteristics
of a window, exhibiting the same opacity as its surroundings and hence not being distinguishable
in transmitted light.
[0077] In the Figure 9 example, since the coating layers 3a, 4a are continuous all over
the surface of the substrate, there is no need for accurate registration between those
layers and other features of the document, hence the ability to apply those layers
after deposition of the reflection enhancing material. The same would apply to any
other coating layers which do not contribute to the definition of the viewing region
20, e.g. partial coating layers which are only applied in areas sufficiently spaced
away from the viewing region. However in general it is preferred to apply as many
of the coating layers as possible prior to deposition of the reflection enhancing
material, and it is only those which ultimately cover the region(s) of the relief
structure 13 on the first side of the substrate 2 (such as layers 3a, 4a in Figure
9) for which this is not possible.
[0078] Figure 10 shows a further example of a security document 1"' in which the security
device 10 is identical to that discussed with respect to Figure 1. In this case, the
security device 10 is located in a "half window" region 20'" of the document, with
coating layers 3 and 4 on the first surface of the document being omitted across the
region in which the security device is present whilst the coating layers 3b and 4b
are continuous across the same region on the opposite side of the substrate. In this
way, the optical effect of security device 10 is only clearly visible from one side
of the document (that of observer A), but depending on the opacity of layers 3b and
4b, from the opposite side the half window region may be apparent as a relatively
light or translucent region, and the optical effect generated by relief 13 may also
be visible to an extent. To form this type of structure, the coating layers 3a, 4a
will be laid down prior to deposition of the reflection enhancing material, but the
coating layers 3b, 4b could be laid down at the same time or at a later stage. This
is because only coating layers 3a, 4a define the viewing region (half-window) 20'"
whilst layers 3b, 4b are all-over and so do not require accurate registration.