DE2253431A1 - DIAPOSITIVE - Google Patents

Description

DR. ING, B. HOFFMANN · DIPL, ING. W. SITLB · I> R. REH, NAT, K. HOFFMANN PATENT LAWYERS ' D-8000 MÖNCHEN 81ARABELIASTRASSE 4 TELEPHONE (08.11) 911087

XEROX CORPORATION,
Rochester, NY / USA

Slide "

The invention relates to xerographic reproduction and specifically to transparencies suitable for use in xerographic reproduction processes.

Slides are very suitable products for visual education, since an image on a slide with the necessary Magnification level can be projected onto a screen where it can be viewed by a large number of people can be. Slides have heretofore been made by photographic reproduction of the desired image. To the Manufacturing has therefore required the specialist knowledge of a person who is familiar with the complex photographic reproduction processes is familiar. Photographic reproduction of slides also requires a long period of time and of a lot of money and is therefore inexpedient. It continues to have an easy and simple method for Production of slides has been sought after which slides can be imaged simply and economically and then can be used indefinitely in visual education programs.

309818/1097

Xerography and electrostatic copying are known from US Pat. No. 2,297,691. This procedure has proven to be a very successful procedure for reproduction with the accompanying advantages in terms of speed and proven to be reliable. With the usual xerographic vision Processes an electrostatic image of an object is used, which has been formed on a receiving member such as a xerographic plate or drum. the xerographic plate can have a layer of a photoconductive Material, for example made of selenium, comprise on a conductive metal base. The latent electrostatic Image formed on the photoconductive material is developed into a powder image which is then applied to a sheet of paper is transferred and is fixed thereon with the formation of a permanent pressure.

The xerographic process has so far proven to be simple and proven reliable procedure for the production of transparencies. Slides obtained by a xerographic process are formed by forming an electrostatic image of the desired object, this is developed and then transferred to a transparent sheet of material with the image permanent thereon is fixed or melted by either allowing heat to act or treating it with a solvent vapor will. In either case, the toner that is used to develop the powder image is carried through on the sheet material a melting technique is coalesced to form a permanent image thereon. Appropriate melting techniques for transparent Materials by xerographic processes are described, for example, in U.S. patents 3,049,810 and 3,148,078.

Although the xerographic reproduction process is an obvious one The solution to the problem of the economical and effective production of transparencies is, however, at

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The production of transparencies in this way poses further problems. One of the most pronounced problems with The production of transparencies by an electrostatic copying process consists of powdered or developed Image to make it look good on the transparent Film material adheres before the image is permanently fixed by melting. If that goal is not achieved, then partial or cracked images are obtained. Another · problem that arises is achieving the correct and uniform density of the image after fixing or melting without resulting damage to the transparent Film material takes place either in the melting process or in the transmission system used in the machine. the end for this reason there are already different coatings and combinations with various types of transparent sheet materials have been proposed to overcome some of these disadvantages. Examples of this are various single-component polymer coatings, such as those described in US Pat. No. 3,539,334-0, 3,539 3 ^ 1 and 3,535 112 are described.

The aforesaid coatings, although an improvement contribute to the adhesion of the developed electrostatic image to the transparent film material, nevertheless not yet fully suitable when slides are made by a multicolored xerographic imaging process will. The difficulties encountered with multicolored imaging processes and transparencies produced in this way are partly due to the multi-component pigment developers which are required for multicolored imaging processes, as well as their varying degrees of attraction to the transparent sheet material. Another problem is the correct degree of coalescence of the toner particles in the Obtaining a permanent image is an even more difficult matter with multicolored images than with development a monochrome image. This increased criticality is

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attributed to the fact that monochrome transparent images are only completely opaque or non-opaque of varying degrees to produce a slide that has images suitable for projection.

On the other hand, multicolored slides have to be for everyone Color or combination of colors in the image allow a certain degree of color density which is sufficient and uniform is that a uniform and true color tone is allowed to be projected. This therefore requires a different and unique combination of materials to be used, with more critical controls on the transparent materials must be exercised, which are used in a multicolor xerographic imaging process to achieve the desired Degree of attraction of the toner to the translucent sheet as well as the correct coalescence of the toner particles for good Preserve color density.

The object of the invention is therefore to provide a slide available on which a multicolored xerographic image with uniform and consistent color reproduction and Density can be permanently fixed. Furthermore, according to the invention, a slide is to be made available, which is permanent in terms of its nature and which has the necessary sheet strength to withstand repeated use for visual educational purposes. Furthermore, a color slide is to be produced by means of a xerographic multicolored imaging process be available, in which the skill of a technician can be dispensed with, the reproductive photographic Procedure is practiced.

It has now been found that the general goal of making a slide that is permanently true and consistent multicolored xerographic ^ holds can best be achieved by using a transparent, thermoplastic film sheet

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used like a polysulfone or polycarbonate sheet material, on which before the xerographic imaging process a coating with a mixture of a vinyl chloride-acetate copolymer resin, an acrylic resin such as poly-n-alkyl methacrylate and a Wetting agent such as a quaternary ammonium salt or a fatty acid amide is applied. It has been shown that just This coating composition ensures that all colored pigments are required for a multicolored reproduction process through which transparent sheets are suitably attracted during unmolding and sheet transition and held thereon so that on the transparent sheet then a permanent image with uniform and accurate color densities can be fused. This coating overcomes the manufacturing difficulties noted above a slide made by a multicolored electrostatic copying process. Examples of these difficulties are the poor adhesion of the developed xerographic image to the transparent film as well as the difficulty in finding one to ensure consistent and true color density in the development of the colored, original image, whichever suitable for projection or enlargement on a screen is. As already pointed out, these problems, although they are also in a single color xerographic Imaging processes are present - much more pronounced when a multicolored xerographic process is used.

It was further found that when the coating mixture also contains a particulate material which is relatively Is inert, e.g. asbestos, silicon dioxide, colloidal silicon dioxide and the like., the coated slide by a extraordinary reduction of the static properties is characterized by an easy handling of the slide through the machine's rubbing paper handling system, as well as allowing many sheets to go into the machine can be inserted without crushing

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or sticking takes place. Sheets coated with a mixture containing an effective amount of the particulate material, in order to reduce the static properties of the sheet, also contribute to the toner transfer to the sheet during development, since if a high level of static builds up on the sheet due to the friction from the handling system, it will be the degree of attraction for the electroscopic Can reduce toner particles which are used to develop the image. Indeed, in one In such a case, the toner particles will even be repelled, thereby preventing the development of the image. The coating, which also contains a particulate material contributes to one by virtue of its reduction in static charges Toner transfer to transparent films.

The process of multicolor xerographic reproduction uses a subtractive color-to-color reproduction technique, to develop images formed on the photoconductive layer. Furthermore, multicolored xerographic The imaging process also involves multiple scanning of the colored original at different wavelengths of light used to create multiple images that correspond to each primary color in the original. These primary color images can then be used to form a single multicolored Image can be recombined to match the original by using a subtractive color-to-color reproduction process a multi-component or multi-color toner is used. This subtractive color-to-color reproduction method is described, for example, in US Pat. No. 3,057,720.

Toners used in multicolor xerography, use subtractive primary colors, yellow, cyan (teal), and magenta. These are in turn used to create a reproduce wide gamut of colors normally found in the colored original. As an illustration

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it can be said that by subtractively blending the yellow and cyan colorants, green tones are obtained. In a similar way Way, mixing magenta and yellow colorants in varying amounts results in red hues, while a Combination of cyan with magenta leads to the reproduction of shades of blue. Mixtures of equal amounts of each toner result naturally a black picture.

The production of a multicolored copy from the colored original can suitably by any multicolored xerographic imaging processes are carried out. It is not intended that this invention be subject to particular variations of the multicolor xerographic imaging process is limited with the apparatus used in this process be performed. By way of illustration it should be said that a suitable method for color imaging with the correct recognition of the color composition of the original object and its inclusion begins. This can suitably be done by successive optical scanning of the Color originals are made over a number of points in time to formulate a sequence of electrostatic latent images, which correspond to the primary colors in the original. This is accomplished through a photograph, which is through a suitable color filter is run so that the latent image is actually separated by color according to the different primary colors is. In theory, the latent image formed by passing the light image through a green filter should be require that the magentas (the complementary color) areas are relatively high charge density on the drum surface, while the green tones (the separate color) should produce a depressed density value. The magenta tones are then made visible by applying a green-absorbing magenta toner to an image-bearing part. On similar ones A blue separation is developed with a cyan toner. The three developed color separations are then

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together in registration on the end sheet of the carrier material brought to make a multicolored facsimile of the original colored document "

This multi-colored developer system, which is in the subtractive Color-to-color reproduction process is used brings about countless problems with it, for example when a color slide is to be produced which is to reproduce the color densities with a uniform and precise consistency, which correspond to the colored originals.

In the manufacture of transparencies by a multicolor xerographic imaging process according to the present invention a transparent thermoplastic film sheet material is selected as the support material on which the multicolored xerographic image can be developed aoll. Although the leaf

material can be any suitable thermoplastic film material that has the necessary clarity, strength, and heat resistance for repeated projections, particularly preferred materials include thermoplastic films, made from thermoplastic resins such as polysulfones or polycarbonates.

Thermoplastic sheet materials useful in the invention Polysulfone sheet materials such as the commercial products of Rowland Products Inc., Kensington, Connecticut, and Instar Supply Co., Inc., New York, with the trademark Folacron PSN, and polycarbonate sheets commercially available from General Electric Corp., Waterford, N.Y., under the trademark Lexan SL 1007, available. These materials can be selected from any desired strength range, although in the selection of film thickness, the films should be strong enough that they have the necessary strength. she on the other hand, they should also be thin enough that they

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remain flexible for continuous use. A suitable thickness of films suitable for xerographic imaging is generally 76.2 to 203.2 / u (3 to 8 mils).

The thermoplastic film material is then mixed with a Polymer-containing composition coated, which enables the adhesion of a multicolored xerographic image to a slide significantly improved during the xerographic development process, while at the same time during the BildaufSchmelzung provides an accurate reproduction of the fiber density the slide is allowed. It has been shown that the coating provides permanent fixation or melting in this regard the developed image on the slide supported either by solvent vapor or heat melting techniques, although as a fusing method for slides made according to the present invention, the ■ Solvent vapor melting is preferred.

According to a preferred embodiment of the invention it has also been found that if the coating is a relatively inert, contains particulate material, a slide obtained which is characterized by a significant reduction in static properties, making the lighter one Handling as well as the multiple sheet feeding through the Paper handling system is permitted without addition problems from the paper feed trough.

The coating provided herein comprises a mixture of a vinyl chloride-acetate copolymer resin, an acrylic resin such as a poly-n-alkyl methacrylate and a wetting agent such as one quaternary ammonium salt or a fatty acid amide, according to In a preferred embodiment, the incorporation of a relatively inert, particulate material is provided. This Coating mixture is usually applied to the transparent film material in the form of a solution. Because of this

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ι.

One circumstance is the choice of solvent to make the solution
obtained, important with regard to the coating composition, since there is no clouding or change in the film material
may and because at the same time there should be sufficient dissolving power for the coating composition to produce a clear, uniform coating on the slide without any signs of
to give insolubility of a component. If a coating mixture is used which contains a relatively inert, particulate material, the latter is usually insoluble and is in suspension in the solution of the other
Component of the coating mixture.

The solvent composition that is suitable for use with the existing composition and for its application to
Slides produced therewith have proven suitable, is a mixture of 2-ethoxyethanol and a ketone, preferably methyl isobutyl ketone. The mixture of these solvents which is used to dissolve the coating composition of the present invention preferably comprises between about
2.5 to 3.0 parts of 2-ethoxyethanol per 1 part of ketone, although
Variations in the amount of these solvents can be made depending on the specific materials used.

The appropriate amounts of the coating compound are then added to the aforementioned solvent mixture and dissolved.
The preferred amounts of the materials used in the coating composition of the present invention comprise a ratio of the acrylic resin to the vinyl chloride-acetate copolymer resin of between about 6: 4 to 7: 3 by weight
of the mixture. When the ratio of these two components
falls above this range, then undesirable tackiness takes place in the coating. On the other hand, if the ratio falls below this range, then it results
poor image adhesion. The wetting agent is in
an amount of between 2.5 to 25% by weight of the mixture of

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Coating mass before. This area expressed as a percentage increases toner transfer to the film substrate and results in a more uniform, consistent, and brilliantly colored image.

In the preferred embodiment of the present invention is a particulate material in the coating composition in an amount of between about 1 and 20 percent by weight of the polymer Components of the mixture, i.e. the acrylic and vinyl chloride-acetate copolymer resin, locked in. This particular percentage range has been shown to be very effective at reducing the static Charging on the transparent sheet by the paper handling system of the machine under varying conditions of relative humidity. Naturally, since the Degree of static electricity depends somewhat on the relative humidity of the environment, the percentage of the particulate Materials can be varied over a wide range, depending on the amount that is needed to remove the static charge to be reduced to an acceptable level without any adverse effect on the transparency of the plate.

The particulate material added to the coating to reduce the static charge of the transparent plate under the handling conditions is added, contributes a degree of bulk to the coating »Because of its protrusion through the Coating it contributes to a certain degree of roughness or texture of the slide surface, even if this texturing is not only visible to the naked eye is. This texturing or roughness is to that effect successfully eliminates the static charge on the slide surface is reduced by frictional contact during handling by reducing the surface area of the sheet which is in contact with other friction surfaces in the sheet handling system of the machine, since contact with the sheet surfaces is only through the particulate Material takes place. This minimal surface contact

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gives a sheet that shows little static electricity during handling, development and delivery and that is a light one Machine input permitted,

It is therefore the right combination of these components that is essential for proper fixation and adhesion of the multicolored xerographic Image on which the slide is critical. It is also this combination of ingredients that enables correct reproduction the color density in the molten image, as well as obtaining a strength of the film which is suitable for requires sheet transition during copying and continuous use of the slide after formation is. The ingredients must also match the multicomponent toners used for the subtractive color reproduction process will be compatible and, accordingly, precipitation or separation of the toner as individual, recognizable particles Avoid in the finished developed image, as opposed to a coalescence and formation of a uniform and consistent one Toner film. If the toner is deposited as recognizable and discrete particles, then an image is created with a looks dirty or blotchy, and the color density thus becomes erroneous. The coating materials must therefore be compatible with the toner materials used for it to develop the multicolor images, at the same time being transparent and yet firm enough to allow normal handling of the slides.

The vinyl chloride-acetate copolymer resin material which can be used for the coating composition of the present invention can be in any commercially available form of this material. For example, the copolymer material of Union Carbide Corp. suitable with inclusion of Bakelite VMCH. The vinyl chloride-acetate copolymer resin material imparts to the film the necessary toughness. It gives the image formed on it the necessary scratch resistance and also avoids one

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excessive curling of the transparency after successive Melting techniques.

The acrylic resin is added and improves the adhesion and fixation of the toner. The material can be suitably selected from the various poly-n-alkyl acrylic resins such as the polymerized n-alkyl methacrylates commercially available from EIduPont de Nemours and Co under the trademark Lucite. Although various alkylated methacrylates are suitable for use in the invention, the butyl methacrylates such as Lucite 4A, 45 and 46 are preferred for use in the coating compositions of the invention, _x

A wetting agent is used in the coating compositions of the invention added to improve the flow of the colored toner and to improve coalescence across the coating during the subsequent steam melting process. This material also helps wet the toner particles so that they are more uniform, more brilliant, and more consistent Coloring in addition to an improvement in the color density in the slide result. The addition of the wetting agent is improved also the surface properties of the slide itself and contributes to a reduction in the static properties, at least under the conditions of high humidity, in order to prevent the slides from sticking together either or to avoid after imaging. Materials that are particularly preferred as wetting agents in the present invention are the quaternary ammonium salts and the fatty acid amides, as sold by Armor Industrial Chemical Co., Chicago, Illinois under the trademark Arquad 2 HT-75 Armid O, Armid C or Armostat 310 are available.

In the preferred embodiment of the invention that can particulate material which gives the coating a texture

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ication of the surface of the slide is added, from a group of relatively inert, particulate materials which includes asbestos, silicon dioxide or colloidal silicon dioxide. The material can suitably be the Coating can be added during the dissolution of the polymeric material ion. As already stated, there is a

preferred addition range between about 1 to 20% by weight of the mixture of the polymeric components that make up the vinyl chloride-acetate copolymer resin and which include acrylic resins. This addition range allows a sufficient reduction in the static Charging of the sheet under varying relative humidity conditions, making it easy to handle and easy to use multiple sheet addition is permitted without adverse effects on the clarity or transparency of the thermoplastic film will. It should be noted, however, that the particulate material may also fall outside the specified range depending on the Environmental conditions of the sheet can be used provided there is an acceptable reduction in the static properties of the Sheet takes place without affecting the transparency of the film sheet. Transmission measurements over a range of wavelengths of active light made on transparencies containing the particulate material show that essentially the same transmission for the uncoated sheet as for the coated sheet containing the particulate Contains material is obtained.

The coating compound is after dissolving in the appropriate Solvent mixture applied to the transparent, thermoplastic film by the known techniques of paper coating. Various techniques that are suitable, for example, for applying the coating, work with a roller, an air knife or other uniform application device, how they are used in paper coating. For example, the coating can simply be by a Funnel are added, which the coating mass

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contains in liquid form. This is provided with a squeegee. One can also proceed by applying the coating using multiple precise coating devices such as engraving presses. Preferably, a coating between about 2.54 and 17.8 Ai (0.1 to 0.7 mils) is applied to the transparent thermoplastic film sheet after a solvent has been evaporated or the dissolved polymeric materials solidified. Since the polymeric coating on the plate is an extremely thin film in nature, its presence does not result in any significant deterioration in the transparency of the sheet itself to be satisfactory for visual educational purposes.

The invention is illustrated in the examples.

Example 1 ■

A transparent, thermoplastic film material with the dimensions 8 1/2 11 inches (8 1/2 11 inches) consisting of 8 1/2 11 inches made of a transparent polysulfone sheet with a 127 / U (5 mils) thick was used as a substrate for a coating composition used, "which was prepared by adding a solution of 45 parts of 2-ethoxyethanol and 15 parts of methyl isobutyl ketone was formed, to which the following was given:

7 g of n * -butyl methacrylate

3 g vinyl chloride acetate copolymer resin (8.6% Vinyl chloride, 13% vinyl acetate)

0.5 g dialkyl quaternary ammonium chloride (Arquad 2 HT-75, Armor Industrial Chemical Co.)

This was mixed until a clear solution was obtained was. The coating was then applied to a polysulfone sheet with a # 20 Mayer rod. Then it became coated sheet dried with warm air. After leaving

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dampening of the solvents used to apply the coating A coating thickness of about 7.6 / U (0.3 mils) was obtained.

The coated, transparent sheet material became a multicolored xerographic imaging process with a resulting Subjected to steam melting of the adherent, multi-colored image. It was observed that both before and after superior image adhesion occurred to steam fusing and that greater toner transfer while forming a highly uniform one and accurate colored image was obtained. The colors reproduced were uniform, with consistent color density and with no evidence of toner staining. In addition, the multicolored slides showed low friction and friction static properties compared to non-coated transparencies.

Example 2

The procedure of Example 1 was repeated with the exception that the following mixture was added to the solution of 45 parts of 2-ethoxyethanol and 15 parts of methyl isobutyl ketone:

7 g of n-butyl methacrylate

3 g vinyl chloride acetate copolymer resin (8696 Vinyl chloride, 13% vinyl acetate)

0.5 g fatty acid amide (Armid 0, Armor Industrial Chemical Co.)

The whole was mixed well with the solvents until one clear solution was obtained. Then, as in Example 1, it was applied to a polysulfone sheet. The resulting coating had a thickness of 7.6 / U (0.1 mils) after drying,

This coated, transparent sheet material was subjected to a multicolor xerographic imaging process. As well as before and after steam melting to fix the

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Image became superior image adhesion to the transparent one Sheet received. Furthermore, the toner transfer was excellent to the sheet with a resulting improvement in the equal, shape of the colored image and its density. That Illustrated slides also showed less friction and a decrease in static properties. The picture on it corresponded well to the original in terms of color.

Example 5

The procedure of Example 1 was repeated with the _t would take off that was added to the solution of 45 parts of 2-ethoxyethanol and 15 parts of methyl isobutyl ketone, the following mixture;

7 g of n-butyl methacrylate

3 g vinyl chloride acetate copolymer resin (86% vinyl chloride, 13% vinyl acetate)

2.0g dialkyl quaternary ammonium chloride (Arquad 2 HT-75, Armor Chemical Co.)

The whole was mixed well with the solvent mixture until a clear solution was obtained, which was as in Example 1 was applied to the polysulfone sheet material. The resulting After drying, the coating had a thickness of 7 »6 / rev (0.3 mils).

When this coated, transparent sheet material was subjected to a multicolor xerographic imaging process, superior image adhesion resulted both before and after the fusing used to fix the image. Furthermore, what good where de ^f & Originals corresponded, ein'guter toner transition occurred in good and uniform colors on.

Example 4

Three transparent polysulfone sheet materials as in Example 1 were coated according to the procedure of Example 1 and

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referred to as sheets A, B and C. The designations corresponded to the following formulations used for the production of the coatings of the individual sheets were used.

Sample A

8 g of n-butyl methacrylate

2 g vinyl chloride-acetate copolymer resin (86% vinyl chloride, 13% vinyl acetate)

dissolved in a mixture of 45 parts of 2-ethoxyethanol and 15 parts of methyl isobutyl ketone

Sample B

5 g of n-butyl methacrylate

5 g vinyl chloride-acetate copolymer resin (86% vinyl chloride, 13% vinyl acetate)

dissolved in a mixture of 45 parts of 2-ethoxyethanol and 15 parts of methyl isobutyl ketone

Sample C

2 g n-butyl methacrylate

8 g vinyl chloride acetate copolymer resin (86% vinyl chloride, 13% vinyl acetate)

dissolved in a mixture of 45 parts of 2-ethoxyethanol and 15 parts of methyl isobutyl ketone.

Each sheet was subjected to a multicolor xerographic imaging process subjected to examining the quality of the image on the transparent sheet material.

It was found that Sample A had good image quality with good color density and uniformity, although the coating possessed undesirable stickiness.

It was also found that Samples B and C had good image quality with good color density and uniformity, although the adhesion of the image before and after the steam fusing was low.

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Example. 5 :

It has a series of six transparent thermoplastic film sheets with approximate dimensions of 20.3 cm 1.27 cm χ χ 27.9 cm (8 1/2 χ 11 inches) were prepared _t which each consist of a polysulfone and passed a- thickness of 127 / ü (5 mils) had. These sheets were used as substrates for the following six coating compositions. All of the latter were prepared by forming a solution of 45 parts of 2-ethoxyethanol and 15 parts of methyl isobutyl ketone. The following mixtures were dissolved or dispersed in the solvent mixture and then applied to the respective polysulfone sheets with a Nr * Mayer rod * The coated sheets were dried with a stream of warm air of about 7.6 / u (0.3 mils). The coated sheets were named as follows, depending on the mixtures used:

Sheet 1 ■ / "'-"',''

7 g of n-butyl methacrylate

3g vinyl chloride acetate copolymer resin (86% ■. Vinyl chloride, 13% vinyl acetate)

1 g wetting agent (Armostat 310, Armöur Industrial Chemical Co.)

Sheet 2 · ■■■ - ■■ _ ■ ·

7g n-butyl methacrylate

3 g vinyl chloride acetate copolymer resin (86%. Vinyl chloride, 13% vinyl acetate)

1 g wetting agent (Armostat 310, Armor Industrial Chemical Co *)

0.1 g asbestos

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Sheet 3

Sheet 4

sheet 5

7 g of n-butyl methacrylate

3 g vinyl chloride acetate copolymer resin (86% vinyl chloride, 13% vinyl acetate)

1 g wetting agent (Armostat 310, Armor Industrial Chemical Co.)

0.5 g asbestos

7 g of n-butyl methacrylate

3 g vinyl chloride acetate copolymer resin (86% vinyl chloride, 13% vinyl acetate)

1 g wetting agent (Armostat 310, Armor Industrial Chemical Co.)

1 g of asbestos

7 g of n-butyl methacrylate

3 g vinyl chloride acetate copolymer resin (86% vinyl chloride, 13% vinyl acetate)

0.5 g wetting agent (Armostat 310, Armor Industrial Chemical Co.)

1 g asbestos'

7 g of n-butyl methacrylate

3 g vinyl chloride acetate copolymer resin (86% vinyl chloride, 13% vinyl acetate)

0.5 g wetting agent (Armostat 310, Armor Industrial Chemical Co.)

1 g colloidal silica (Cab-o-Sil, Cabot Corporation)

After coating and drying, the six coated sheets were multicolor electrostatic copier addition tests subject. The ability to feed into the machine was assessed. Furthermore, the static and kinetic coefficient of friction for the individual coated sheets against one another

Sheet 6

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other according to the ASTM standard D 1894-63 with your! Eitel standard, Method of Test for Coefficients of Friction of Plastic Film measured and compared to non-inspected police officers «and Polysulfone sheets compared. The static or starting « coefficient of friction is related to the force that is measured is used to control the movement of the surfaces of the two sheets to begin relative to one another »On the other hand, he is more kinetic or coefficient of friction, the coefficient of friction expressed in relation to the force »which is measured to maintain this movement» The transmission of certain blades » which contained asbestos and silicon dioxide "was likewise measured at different wavelengths of actinic LiGht and compared to uncoated sheets. The testers * results are summarized below *

300818/1097

Polysulfone polycarbonate

hlatt (not- sheet (not-

"coated) layers)

Control control

coated sheet

1. Machine infeed cannot be fed in. Feed characteristics poor moderate moderate good good

Well

2.

% Transmission
420 m / u
myu

87%

700 »Wed

Friction coefficient (static coefficient the friction / kinetic coefficient of friction)

92%

0.50 / 0.44 88%

89% 89%

89% 89%

0.43 / 0.44 0.48 / 0.64 / 0.72 / 0.31 / 0.40 /

0.48 0.59 0.66 0.27 0.45

From the values given it can be seen that those with the inventive compositions coated slides ,, the moreover contained a particulate material such as asbestos or silica, improved machine feed properties and exhibited better coefficients of friction than the coated sheets which were not particulate contained.

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Claims (1)

Claims' '' 'ι ι ii j 1 ./ Slide for the subsequent formation of an adhesive electrostatic image, characterized by a thermoplastic film sheet, wherein at least one surface of the sheet is coated with a mixture which comprises an acrylic resin and a vinyl chloride-acetate copolymer resin in a weight ratio of between about 6: 4 and 7: 3, contains a wetting agent in an amount between about 2.5 to 25 percent by weight of the mixture with an effective amount of a particulate material in the mixture to reduce the static properties of the sheet. 2. Slide according to claim 1, characterized in that the particulate material in one Amount of between about 1 to 20 weight percent based on the resins is present. 3. Slide according to claim 1, characterized in that the particulate agent selected from the group Asbestos, silica and / or colloidal silica is selected. 4. Slide according to claim 1, characterized in that that the thermoplastic film sheet is selected from the group consisting of polysulfone and polycarbonate sheets, 5. Slide according to claim 1, characterized in that g e k e η η draws that the mixture is applied to the sheet to a strength after drying between about 2.54 and 17.8 / U (0.1 to 0.7 mils) is stacked. . 6. Slide for the subsequent formation of an adhesive multicolored electrostatic image, g e k e η η - - 25 309818/1097 characterized by a thermoplastic film sheet from which at least one surface is coated with a mixture, which is an acrylic resin and a vinyl chloride-acetate copolymer resin in a weight ratio of between about 6: 4 and 7 * 3 » a wetting agent in an amount of between about 2.5 to 25% by weight, based on the mixture, and a particulate Material in an amount of between about 1 to 20% by weight, based on the resins, to reduce the stat! see property of the sheet. 7t. Slide according to Claim 6, characterized in that the particulate agent is selected from the group Asbestos, silicon dioxide and / or colloidal oil silicon dioxide is selected. · 8. Slide according to claim 6, characterized in that the thermoplastic film sheet from the Group of polysulfone and polycarbonate sheets is selected. 9. Slide according to claim 6, characterized in that g e k e η η, that the mixture on the sheet to a strength after drying between about 2.54 and 17 »8 / ύ (0.1 to 0.7 mils) is stacked. 10. - Slide produced by forming an adhesive multicolored image by electrostatic copying on a surface of a sheet of thermoplastic film, thereby g e k e η η ζ e i c h η e t that at least one Surface to improve the adhesion of the image with a Mixture has been coated, which is an acrylic resin and a vinyl chloride-acetate copolymer resin in a weight ratio: '· between about 6: 4 and 7: 3 and a wetting agent in an amount of between about 2.5 to 25% by weight of the mixture contains. - ^ 26 309818/1097 11. Slide according to claim 10, characterized in that the mixture is applied to the sheet in a solution from about 2.5 to 3.0 parts of 2-ethoxyethanol and 1 part of ketone is coated. 12. Slide according to claim 11, characterized in that the ketone is methyl isobutyl ketone. 13. Slide according to claim 10, characterized in that the mixture is applied to the sheet to a strength after drying between about 2.5-4 to 17.8 / u (0.1 to 0.7 mils). 14. Slide according to claim 10, characterized in that g ek e η η draws that the acrylic resin is a poly-n-alkyl methacrylate is. 15. Slide according to claim 14, characterized in that the poly-n-alkyl methacrylate is butyl methacrylate is. 16. Slide according to claim 10, characterized in that the wetting agent from the group Alkyl quaternary ammonium salts and fatty acid amide. 17. Slide according to claim 10, characterized in that the thermoplastic film sheet from the Group of polysulfone and polycarbonate sheets is selected. 18. Slide made by electrostatic formation of a multicolored, permanently fixed image Copying and steam melting this image onto the surface of the sheet of thermoplastic film characterized in that at least one surface of the sheet to improve the adhesion of the image with a mixture - 27 -309818/1097 is layered, which is an acrylic resin and a vinyl chloride-acetate copolymer resin in a weight ratio of between about 6: 4 and 7 | 3 and a wetting agent in an amount between about 2.5 and 25% by weight, based on the mixture. 19. Slide according to claim 18, characterized in that the mixture is applied to the sheet in a solution from about 2.5 to 3.0 parts of 2-ethoxyethanol and 1 part of ketone is piled up. , 20. Slide according to claim 19, characterized in that that the ketone is methyl isobutyl ketone. 21. Slide according to claim 18, characterized in that the mixture is applied to the sheet to a strength after drying between about 2.54 and 17.8 / U (0.1 to 0.7 mils) is piled up. = 22. Slide according to claim 18, characterized in that the acrylic resin is a poly-n-alkyl methacrylate and that the wetting agent is selected from the group consisting of alkyl quaternary ammonium salts and Fatty acid amides is selected. 23. Slide according to claim 22, characterized in that the n-alkyl methacrylate is n-butyl methacrylate is. . 24. "Slide according to claim 18, characterized in that the thermoplastic film sheet is selected from the group consisting of polysulfone and polycarbonate film sheets. 3098 18/1097