PHOTOGRAPHIC PRINTS
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to photographic prints and their production. By a "photographic print" is meant a developed photographic image carried on a photographic support.
2. Background Prior Art
Paper is the most widely used photographic support material. Normally the paper is coated, either with baryta or with a polymeric layer applied by extrusion. Wholly polymeric sheet materials are also used as photographic supports, but generally only for specialised end uses where their high cost can be justified. Such sheet materials may for example be of white-pigmented polyester or triacetate polymer.
The use of paper as a photographic support has the drawback that the paper tends to be adversely affected by photo-senεitizing solutions and by processing solutions used to produce the final photographic image. This problem is lessened if the paper carries a polymer coating, but processing solutions may still penetrate the paper at the edges of the support- where the polymer coating is not present to provide a barrier. These problems may be minimised, but not eliminated, by the incorporation of speciality chemicals during production of the paper, but this naturally adds to its costs, particularly as the choice of chemical is greatly restricted by the requirement that the chemical must not react adversely with, the subsequently-applied photosensitive coating cr with the processing chemicals.
The use of polymeric sheet material as a photographic support avoids the above-described disadvantages, but such"
sheet material tends to lack the rigidity or stiffness necessary to permit the finished print to be readily handled, unless the sheet material is so thick as to be uneconomic. In effect, the cost of paper-based supports imposes a ceiling on the acceptable cost of potentially competing materials such as polymeric sheet materials (except for certain speciality end uses where the additional cost is acceptable).
European Patent No.7048 B (equivalent to US Patents Nos.4296198 and 4355099) discloses a process in which photosensitive material on a thin transparent polymeric support is first exposed and developed to produce a positive transparency, and the surface of the transparency carrying the image is then laminated to a main support, e.g. of paper. The main support is of greater thickness than the transparent support. A pigmented reflective layer is provided between the main support and the image, so that the image may be viewed through the transparent support against the background of the pigmented reflective layer. The pigmented reflective layer is preferably provided by means of a gelatin coating over the photosensitive material, but may alternatively be present as a coating on the main support. Alternatively the adhesive used to cement the main and transparent supports together may be pigmented so as to constitute a reflective layer.
The arrangement just described has the advantage that the main paper support is not contacted at any stage with photosensitizing or photographic processing solutions, and thus that the above-described disadvantages of- paper are avoided. A further advantage is that after lamination, the image is protected from damage by the transparent support. Nevertheless, the pigmented reflective layer can give rise to problems. In the preferred arrangement in which this layer is a pigmented gelatin layer, the photographic image in the final product is backed by a gelatine layer and a cement layer τ and these would be expected to lessen the
brightness and sharpness of the image obtained. Furthermore the use of an opacifying agent in the gelatin layer would be a radical and hence unattractive step for companies specialising in photosensitization. Even if this pigment-coating operation could be satisfactorily carried out, the thinness of the resulting reflective layer would tend to give only limited opacity and hence .poor optical characteristics in the finished product. Much the same drawbacks would apply to the use of a pigmented cement or a pigmented coating on the main support.
It is an object of the present invention to permit the technical benefits associated with polymeric sheet material supports to be obtained at acceptable cost whilst at the same time avoiding the above-described drawbacks associated v.'ith the use of transparent polymeric sheet materials and pigmented reflective layers.
SUMMARY OF THE INVENTION
According to the present invention, there is provided a process for the production of photographic prints,, comprising the steps of:-
a) photographically processing an exposed photosensitized thin flexible polymeric sheet material to produce a positive photographic image on the sheet material; and
b) bonding said polymeric sheet material to a stiff backing substrate;
characterized in that:
c) the thin polymeric sheet material is opaque and is bonded on its unsensitized surface to said substrate.
The invention also resides i- photographic prints produced
by the process.
It will be appreciated that the present process has the advantage of permitting photosensitization and photographic processing by the methods currently practised, and that the opacity of the polymeric sheet material will give rise to a. photographic print having excellent optical qualities (clarity, brightness, resolution etc.), since the photographic image is viewed against the background of the opaque sheet material. Such pigmented polymeric sheet materials are readily available. They may for example be of white opaque polyester e.g. a "Melinex" opaque polyester sheet material as supplied by ICI.
The thickness of the opaque sheet material may vary within wide limits, although use of an excessively thick sheet material will lead to cost penalties. Typically the thickness of the polymeric sheet material may be in the range of about 30 to about 100 um, although thinner sheet materials are in principle usable, e.g. down to about 5 μm. As sheet material thickness of about 50 μm is currently thought preferable for most end uses.
The nature of the stiff backing substrate to which the opaque polymeric sheet material is bonded may vary widely, depending on the nature of the photographic print to be produced. For most purposes, the backing substrate is preferably of paper although other materials may be used, for example plastics sheet material, metal foil, fabric, and display laiminates. When paper .is used, it can be designed to impart maximum rigidity for its thickness.
Since the substrate does not come into contact .. with photosensitive material or photographic processing solutions, the usual concerns over photosensitivity do not apply. A relatively inexpensive white card proαuct may therefore be used. The substance of such a product would typically be about 150 to about 200 -2 for most types of
photographic print, although substances outside this range could be used. Speciality applications may require special backing substrates. For example, prints which have to be mounted for display or exhibition may require a heavier weight backing substrate, for example of a substance of up to about 500 gm-2.
The total thickness of the finished prints, i.e. of the sheet material and the backing substrate is preferably of the order of 200 to 250 μm. Its stiffness, as measured by a Lorenzen & Wettres stiffness tester, is preferably of the order of 100 to 150.
Bonding of the opaque polymeric sheet material to the stiff substrate may conveniently be carried out on-line as a part of the photographic processing operation, normally just prior to the cutting operation to produce individual photographic prints. Conveniently, bonding is achieved by the provision of a self-adhesive coating on the surface of the stiff substrate prior to the processing operation, or by applying an adhesive coating as part of the processing operation.
The opaque polymeric sheet material may have any of the surface characteristics conventional in the photographic support field, for example it may have a glossy, matt or embossed finish. Embossing may if desired be carried out after photographic processing and bonding of the polymeric sheet material to the substrate.
The opaque sheet material and/or the substrate may if necessary be treated in conventional manner to prevent build up of static charges or to facilitate writing on the reverse of the print.
In order to enable the invention to be more readily understood, reference will now be made to the accompanying drawings, which illustrate diagrammatically and by way of
example an embodiment thereof.
DETAILED DESCRIPTION
In the drawings:
FIGURE 1 is a diagrammatic side view of a production line for the production of photographic prints;, and
FIGURE 2 is a side view on an enlarged scale of one such photographic print.
Referring to Figure 1, an opaque polymeric sheet material 1 carrying developed photographic images on its upper surface 2 is shown emerging from a photographic processing station indicated as 3. A roll 4 of stiff backing substrate material carrying a self-adhesive coating and a releasable protective covering over the adhesive coating is positioned downstream of the processing station 3 and opposite a support roll 5, such that the sheet material 1 passes between and in contact with the rolls 4 and 5. The roll 4 is arranged to unwind at the same peripheral speed as the speed of the sheet material 1. The releasable protective covering is separated from the adhesive coating as the roll 4 unwinds, and the used protective covering is reeled up into a roll 6. A pair of opposed nip rolls 7 is positioned downstream of the rolls 4 and 5 so as to press the sheet material 1 into firm contact with the adhesive coating on the backing substrate and to form a laminate (the backing substrate is shown as 8 when in the unwound condition) . A guillotine 9 is positioned downstream of the nip rolls 7 and 8 so as to chop the laminate into individual prints.
Referring now to Figure 2, the photographic print comprises a developed photographic image 10 on an opaque polymeric sheet material 11. A conventional protective gelatin layer (not shown) may be present over the photographic image. The sheet material 11 is bonded by an adhesive layer 12 to a stiff backing substrate 13.