DE7342772U - PRINT PAPER FOR ELECTROPHOTOGRAPHY - Google Patents

Description

The invention relates to transfer papers for electrography or electrophotography.

In electrophotography becomes an electrostatic developed latent image with a liquid developer and the image so produced to obtain a Transferring the copy onto a proof or copy paper (transfer or printing material). According to the invention print papers are now provided, which are particularly useful for electrophotography, with the transferred images developed to a liquid developer by electrophoresis in the presence of a liquid carrier will.

The electrophotographic processes are numerous

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such as the Carlson process, photo-voltage process, Aerosol printing processes, the permanent polarization process, electrolytic electrophotography, the "Canon NP process ", electrophoretic electrophotography and the like are known, and those skilled in the art know that the images generated by the above method are transferred or subtracted or that the initially formed electrostatic latent image visualized with a liquid developer and then permanent to achieve "Printed" copies are transferred to a print or copy paper.

In general, the latent image is wet developed using a liquid developer made visible, which is produced by dispersing a toner in an insulating liquid, and that image so developed is then transferred within extremely short times by electrophoresis by one Brings carrier liquid film on the photosensitive plate with the print or copy paper in contact. if creates a visible image in a liquid film as in electrophoretic electrophotography is, the image transport by electrophoresis takes place within a very short time, during which the The film of liquid is in contact with the print or copy paper.

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If now conventional papers are used as printing papers, the carrier liquid is during the short contact time is absorbed by the paper and the carrier film cannot be maintained. This prevents electrophoresis of the toner and increases the efficiency of image transfer reduced, with the result that the transferred image is "destroyed" or extremely poor.

With a lot of carrier liquid, m corresponding to the remains much on the photosensitive plate, the transferability of the toner image is increased, however, the printing paper is moistened unnecessary, so that undesirably long times are required for drying. In some cases, large amounts of carrier vapors are generated, which is undesirable for health reasons.

Furthermore, when the carrier liquid is strongly absorbed by the paper, the wettability becomes less or moisture of the photosensitive plate or electrode is reduced and thereby the cleaning of the same made more difficult and sometimes even damaged.

Accordingly, there is a reduction in oil absorbency of the proof paper as well as an improvement

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its resistance or repellency to reduce the absorption of carrier liquid and Maintenance of the carrier filra during the contact time is required in which the printing paper is in contact with the photosensitive plate or electrode.

A typical process of making paper oil-resistant or - to make it repellent and to reduce the oil absorption by the same 7.U consists in the formation of an oil-repellent i.e. highly hydrophilic polymer film on the surface of the paper or in the impregnation of the Paper with such a polymer. Polyvinyl alcohol, cellulose derivatives, salts of polymers with hydrophilic Groups, water-soluble natural polymers and the like are used for coating, impregnation and compounding.

Although now the oil resistance of the paper is improved by using the above polymers and the absorption capacity of the same for oil is reduced, the paper produced in this way is not completely satisfactory, because it is used in the paper machine or coating machine as a result of its high (water) reforming properties such polymers is insufficiently dried. Furthermore, the paper produced in this way proves to be disadvantageous because it tends to "curl" or curl up and the

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The resisrente film easily tears or breaks when satinizing. The paper is also moisture-sensitive and there due to its highly hydrophilic properties the bonding strength between the paper and the developer is weak, the formed image is poorly picked up.

The aim of the invention is therefore print or copy papers that do not have the above deficiencies and a highly effective image transmission with the achievement of clearer (non-cloudy) and clearer resp. enable sharper images. Furthermore, the papers should have the best possible fixability of the transferred toner image own. In addition, a consistently flat quality of something that does not tend to roll up is achieved Aimed at paper. Another object of the invention is a hygienically desirable paper that does not exhibit excessive absorption of carrier liquid and thus does not generate large amounts of carrier vapors leads to dry fixation.

The print or copy paper for electrophotography according to the invention developed for this purpose is characterized in that it contains copolymers which are composed of one or more monomers of the general Formula (I):

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A I

CH ₀ = C (I)

² I.

COOB

in which A is hydrogen or CH, and B is an alkyl radical and at least one monomer from the group of unsaturated carboxylic acids and acrylonitrile are made «

According to the invention, the above copolymers can be used by being neutralized or partially be neutralized.

Further, the above copolymers such as water-soluble acrylic resins can be used in combination with various Types of synthetic resin emulsions can be applied.

Acrylic or acrylic or methacrylic esters show depending on the type of alcoholic residue and the ratio of alcohol to acrylic acid or methacrylic acid differ Properties. Furthermore, the properties of the copolymer as a treatment liquid or coating for Paper such as viscosity, drying properties, water retention, adhesiveness and the like partial incorporation of carboxylic acid groups, partially or completely neutralized carboxylic acid groups or Nitrile groups in the copolymers or by changing the proportions thereof can be easily changed. in the

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the rest can be hardness, adhesiveness, roll-up properties, Moisture sensitivity, oil resistance, ability to fix the developer and the like of the formed paper or the surface thereof can be changed appropriately. You knew by using other synthetic resins be achieved, but it has been found that the properties required for the printing papers according to the invention most satisfactorily by using acrylic resins can be achieved, which are prepared from the monomers as indicated above.

The alkyl radical of the acrylic esters or methacrylic esters used to prepare the acrylic resins according to the invention is preferably low molecular weight (with a carbon number less than 10) and just like Methyl, ethyl, butyl, hexyl, octyl, 2-ethylhexyl and the like. The mixing ratio of the ^ ster including that of acrylic ester to methacrylic ester should be accordingly the properties of the alcohols forming the individual esters are determined; is preferred the use of esters of the soft and hard type, taking into account strength, hardness, adhesiveness, Rolling properties, fixability of the developer and the like of the formed resin film or the film-formability, Viscosity or the like of the acrylic resin.

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In particular, in the case of printing papers, the film-forming ability, film-forming temperature and glass transition temperature of the synthetic resin are related to blocking, double-access and sticking, and thus glass transition temperatures of the resin below 20 C are not preferred. However, temperatures at higher glass transition · occur an undesirable curling of paper, tearing d ^ r coating during smoothing in the calender and similar defects, so that the glass transition temperature should be below 50 ^0C.

The carboxylic acid content of the Ac ^ JJa ^ r s is important since he is the balance between hydro ^ aile and oleophilic Properties of the present resin determined. That is, if the carboxylic acid content is too low, the hydrophilic properties of the resin poor and its QT resistance poor and further in the case of Production of water-soluble resin cannot be made water-soluble because of the carboxylic acid content on the other If it exceeds 35 mol%, the oil resistance is improved, but the resin becomes brittle, hard, very hygroscopic and strongly adherent or sticky, so that the ability to fix the toner is impaired. The paper made using such resin is therefore insufficient as a printing or copying paper. To the-

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in accordance with a carboxylic acid content in the range from 5 to 35 mol%? "■ any case of water-soluble resin," Mikrosol "or colloidal solution or emulsion are preferred. The above discussion is based on findings on the basis of data as shown in the following Table 1 .

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Table 1: Influence of the carboxylic acid content

Sample no. 1 2 60 4th 5 - respective paper n-
id 0.0 Acrylic resin composition
(Mol%) - - 50 Ethyl acrylate 50 75 20th 45 - - 0.5 Butyl acrylate - 5 20th - 100 - 95
0 Methyl methacrylate 20th - - 15th - - Acrylic acid 30th - sodium
hydroxide 40 Natriu
hydrox - Methacrylic acid - 20th what s.
Sol. - water
Sol. - Neutralizing agent - ammonia sodium
hydroxide Fc rm emulsion Emul
sion 4.0 what s.
Sol. 2.0 Features of the trigger
paper 400 220 oil resistance (s) 3.0 4.0 1.1 3.0 0.9 Air permeability (s) 300 380 75
4th 310 55
15th optical image density 1.2 1.1 0.9 Fixability of the Ent
winder (%)
Ripple or roll rig. (Mm) VO
Ul ul 80
6th 60
13th

Comment:

(1) 4 g / m 2 (solids) of a press size coating liquid with ^ u parts of the above acrylic resin «30 parts Polyvinyl alcohol and 30 parts of clay or kaolin (each stated as a solid) are one on both sides high-quality paper of 60 g / m is applied with a table size press.

(2) "Ordinary paper" is high quality

2 paper for offset printing from 64 & / ΐη.

(3) Ais "air permeability" becomes the galley air permeability designated.

(4) "Optical image density" is taken to mean the optical density of solid black parts of the image on a printing paper (measured with a reflection densitometer).

(5) As the "rolling property ^'1 the height (in mm) of the Kantenaufbiegung is referred to a round paper of 100 mm diameter, for 24 hours at 20 ⁰ C and

65 % relative humidity had been stored.

(6) The "fixability" of the transferred image becomes measured as follows: One with a transferred image

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provided and dried take-off or. Copy paper is placed on a plate having a horizontal surface in such a manner that the image side faces outward. To ⁿ ie aspect soft papers 8 are cm square with a coarse surface coated and further brought out an aluminum block. The load is about 12 g / cm. The rough-surfaced papers and the aluminum lock thereon were set so as to prevent them from moving horizontally, and the proof paper was then drawn away at a speed of about 7 m / s, which was repeated five times. The resulting image density thereafter was measured and the ratio thereof to the initial image density is given in % .

(7) The "oil resistance" was determined with a device as shown in the attached drawing: an injector 1 with a needle 2 (H5 according to JIS-T 3101) contains a carrier liquid 3 C'lsopar G "from Esso); in a spacer frame U is a paper 5, which is to be measured oil resistance. a drop of the carrier liquid (about 0.004 mL) is dropped on the paper 5 and the surface 6 observed. the permeation of Isopar G in paper makes the paper permeable. the Drops penetrate part of the paper (pinholes) and then penetrate the entire extent of the

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dripped area (about 10 to 15 mm in diameter). The length of time between the arrival of Isopar G on the paper 5 and the point in time when the permeation of the entirety of the dripped area 6 is complete is measured in units of 0.1 seconds with a stop watch . This measurement is carried out ten times at different points on the same paper and the mean value from the 10 tests is determined as "oil resistance". For the printing paper, "oil resistance" within the range of 1.0 to 10.0 seconds is preferred.

Unsaturated carboxylic acids, as used here, are preferably acrylic acid, methacrylic acid, Itaconic acid, maleic anhydride and the like.

By introducing acrylonitrile into the acrylic resin according to the invention, the image properties of the Printing paper is improved, and thus uniform images free from white spots can be obtained. However, the introduction of a large amount of acrylonitrile, as can be seen from Table 2, brings no additional good results, rather there is then rather the risk of impairing the heat resistance of the acrylic resin. The effect of the introduction Acrylonitrile is believed to be achievable in amounts less than 10 mol%.

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Table 2 Influence of acrylonitrile

Sample no. 1 2 3 4th Acrylic resin together
settlement (mol%) Ethyl acrylate 55 55 53 50 Methyl methacrylate 30th 30th 27 25th Acrylic acid 15th 12th 13th 15th Acrylonitrile 0 3 7th 10 Neutralizing
middle sodium
hydroxide dto. dto. dto. shape water
Sol. dto. dto. dto. Properties of the
Deduction paper optical image
density 1.1 1.1 1.2 1.2 Fixability of the
Developer (%) 75 80 7S 75 Uniformity of
dignified black
Areas of the image 6.0 8.5 9.0 9.5

Note:

(l) The printing paper was made in the same manner

as in table 1.

K. λ η

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(2) As "uniformity of the solid black areas of the image", fixability of the developer is used marked on the solid black areas of the image on the print paper (complete fixation means 10).

(3) The smoothness of the print paper corresponds to 120 seconds according to the Bekk advertisement.

About the neutralizing agents as used here include caustic soda, ammonia, organic amines, etc. When using ammonia or organic Amines, crosslinking is achieved through the simultaneous use of a third component, as the end group becomes reactive with ammonia or organic amines. The moisture sensitivity and adhesiveness can be so improved grazing. It should be noted that the neutralizing agent selected taking into account the pot life of the treatment liquid and the crosslinking effect should be. In the case of aqueous solutions, the degree of neutralization varies depending on the amount of carboxylic acid, however, higher degrees of neutralization are preferred. In the case of microsols and emulsions neutralization is not absolutely necessary.

In the production of the deduction according to the invention

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Papers can such as acrylic resin alone or in combination with water-soluble high molecular compounds an adhesive or glue can be used. The water-soluble high molecular compound can be any known one Be a compound with high oil resistance that is capable of film formation. Of the well-known water-soluble high molecular compounds must be selected those with the acrylic resin according to the invention are easily miscible and act as a protective colloid for the emulsion. This means that polyvinyl alcohol, carboxyl » Methyl and ethyl cellulose, starch, starch derivatives, casein, Styrene-maleic anhydride copolymer salts, vinyl acetate-maleic anhydride copolymer salts and the like used. When the acrylic resin of the invention is used together with the above resins, the defects of the latter avoided and it can thus be a high quality Proof paper can be obtained.

As other ϊ synthetic resin emulsions like them used here in combination with the water-soluble acrylic resin according to the invention can be any Emulsions can be used which are based on cellulose ". That is, emulsions based on of vinyl acetate, styrene / butadiene, acrylonitrile / acrylonitrile / butadiene, Ethylene / vinyl acetate and vinylidene chloride can be used.

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above - 17th - . ' /
j
21 I like ι ACT established the water · 'Iöslic; ii yl resins bcvorz ugly under the confusion of

5 to 35 mol% of carboxylic acid as an additional hydrophilic group to acrylate and / or methacrylate and the like. Or also made by using acrylonitrile (less than 10 mol%). It is preferred that the neutralization of acrylic resin to make it water-soluble by using inorganic alkalis or organic ones Amines is carried out.

The introduction of the water-soluble resin in emulsions improves their stability considerably. as Protective colloids for emulsions are known which are individually suitable for the emulsions. For example polyvinyl alcohol is considered suitable for a vinyl acetate-based emulsion and polysodium acrylate for an acrylonitrile based emulsion, casein for a styrene / butadiene based emulsion, etc. It was however, it is very difficult to meet the requirements for printing papers while maintaining the properties unchanged of the protective colloid satisfactorily. This problem has now been solved by using the water soluble Acrylic resin dissolved according to the invention. The influence of the acrylic resin on the emulsion stability is shown in Table and the influence of the mixing ratio of acrylic resin to emulsion is shown in Table 4.

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CO IN9

Tabel

Improvement of the thermal and mechanical resistance of emulsions by Addition of water-soluble acrylic resin

Emulsions Acrylic Styrene Vinyl- Polyvinyl emulsion Butadiene acetate emulsion alcohol emulsion emulsion Emulsion alone Amount of coarse particles 6th 12th 11th 11th Stability index 1.15 1.42 1.33 1.33 pH 7.1 8.0 6.4 • Emulsion with water Polyvinyl alcohol soluble acrylic resin Amount of coarse particles 1 2 2 1 Stability index 1.00 1.02 1.05 1.02 pH 7.9 8.0 7.0 7.0

Comment:

Conditions for Stability Measurement: A solution containing 10% solids is heated to 60 ⁰ C and stirred for 15 minutes with a "homomixer" at 6000 rpm.

(1) The "amount of coarse particles" becomes that amount which remains after passing through a sieve with a mesh size of 0.105 mm (in mg / g).

(2) The "stability index ¹ " is the ratio of the concentrations in the lower part to that in the upper part of emulsions after standing for 36 hours.

(3) As the water-soluble acrylic resin, the same as in Example 6 was used.

The mixing ratio of the water-soluble acrylic resin is 50% by weight.

(5) The acrylic emulsion, styrene / butadiene emulsion and vinyl acetate emulsion are the same as in FIG Examples 6, 8 and 7.

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Table 4
Influence of the addition ratio of water-soluble

Admixture ratio O Amount coarse Stability index of water soluble IC Particle Acrylic resin 2 C (mg / g) 30th 12th 1.17 50 2 1.02 2 1.01 2 1.00 1 1.00 1 * 00

Comment:

(1) The stability measuring conditions are the same as in Table 3.

(2) The emulsion used is an acrylic resin emulsion.

As follows from the above description, the disadvantages of emulsions according to the invention are exerted eliminates the water-soluble acrylic resin that allows the full benefits of the same, while at the same time eliminating the disadvantages and advantages of the water-soluble acrylic resin itself

-Ή. ? S

of the same come into their own.

That is, the water-soluble acrylic resins have high oil resistance and the solution or coating properties are those of conventional natural, synthetic, and semi-synthetic polymers Connections very similar. However, the water-soluble acrylic resin has oleophilic properties that They cannot be found in conventional compounds and, moreover, they can have oleophilic properties to be controlled. In this way, the shortcomings of conventional natural synthetic and semi-synthetic can be remedied high polymer compounds with regard to moisture sensitivity, film hardness, curling or Curling properties, film breakage and the like are essential be reduced.

The printing paper according to the invention can thus be compared with a conventional paper by use the acrylic resin in the form of an emulsion or the water-soluble acrylic resin alone or in coordination significant with conventional natural synthetic and semi-synthetic polymeric compounds be improved. However, if a mixture of the emulsions and conventional natural, synthetic or semi-synthetic resins are used, one meets

to problems with the stability of the emulsions, even if Adhäsivc- or glues are used as protective colloids serve for the emulsions, can be used at the same time and furthermore the disadvantages of conventional glues cannot be adequately eliminated. When using the water-soluble acrylic resin together with conventional Gluing can reduce the deficiencies of conventional glues can be reduced, but there is an improvement in the coating properties not sufficient as both are water soluble.

On the other hand, when the water-soluble acrylic resin is used together with the emulsions, the disadvantages are avoided altogether and the favorable properties of both are brought to the fore. I.e. » the problem of the stability of the emulsion can be completely eliminated and the ability to retain water and the "lubricity" or applicability of the coating solutions are improved and thus they can can be used satisfactorily with a speed sizing press or coating apparatus. The lack of usual technology, especially with regard to the rolling properties, temperature dependency and fixability of the developer are noticeably weakened.

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The treatment or coating liquid according to the invention can contain pigments. The addition of such pigments is for improving the Smoothness of the release paper, ease of writing, evenness of the image, dryability of the paper after image transfer and preventing stickiness; nd blocking effective, as opposed to one Worsening of the oil resistance. Thus, pigment should be used appropriately. Dispersants, Lubricants and anti-foaming agents are of course used along with the use of pigment and other glues applied, but the advantages of the invention through the use of such agents are not detrimental to be influenced.

Since the printing papers are excellent according to the invention in terms of oil resistance and affinity to the developer, they can be used as a substrate when applied organic solvents can be used. That is, the paper is excellent in ability to withhold coating paints based on organic solvents and it has adequate Affinity and thus processed paper can be obtained that has little repellency of colors and shows little coating unevenness.

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The invention is explained in more detail below with the aid of examples.

example 1

100 parts of fine CdS crystals and 20 parts of a
30% strength solution of vinyl chloride-vinyl acetate copolymers in toluene were mixed and toluene was added to the mixture in order to set a viscosity suitable for the coating. The dispersion made in this way was applied to an aluminum support with the formation of a hO μ thick film (in the dry state)
and dried. On the thus obtained photoconductive
On the 2nd layer, a polyethylene terephthalate film (thickness: 30 / a) was stuck on with an epoxy resin-based adhesive to produce a three-layer photosensitive assembly.

On the photoeirpfindlichen arrangement was a
electrostatic latent image formed by the electrophotographic method disclosed in Japanese Patent Publication No. 23910/1967,

The following ingredients were completely mixed together with a "homomixer" for about 2 hours:

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Carbon black 6 g

Cyclized gum 40 g (20 ThiKe solution in xylene;

Low molecular weight polyethylene with a molecular weight of 1000 (20% solution in xylene) 5 g

Coumarone resin

(20% solution in xylene) 30 g "Isopar G" (from Esso) 120 g

20 ml of the resulting dispersion were added to 2 liters of "Isopar G" with AO ml of lecithin with stirring for making a liquid developer. With this, the electrostatic latent image was developed with the achievement of a sharply defined image on the photosensitive assembly.

To a starting material of 20 parts of a bleached to a "freeness" of 300 ml Kraft paper pulp from coniferous wood (N.BKP) and 8C parts of a bleached kraft paper pulp made from leaves or Hardwood (L.BKP) 0.3 parts of rosin glue, 1.5 parts of alum and 8 parts of talc were added, this is then put into a Fourdrinier machine to produce a paper with a material content of 60 g / m 2 became. A press sizing solution having the following composition was applied to the produced paper in a Quantity of 3 g / m (solid) with a sizing or

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Oummierpress applied, creating a proof paper with an air permeability of 5500 seconds, one Roll height of 7 mm and an oil resistance (hold out) of 10 seconds was obtained.

Emulsion of a copolymer of 50 mol% ethyl acrylate, 20 mole percent methyl methacrylate and 30 mole percent acrylic acid 70 parts

Methyl cellulose ("Metholose 658H" from Shinetsu Kagaku) 0.5 parts

Coating clay or kaolin ... 30 parts

Melamine resin ("Sumirez 613" from Shumitomo Kagaku) 0.5 parts

Antifoam agent (silicone) 0.1 part

Dispersant ("Primal 850" from Nippon Akuriro Kagaku) 0.02 part

Water _u 100 parts

The above developed image was transferred onto the printing paper by a corona transport process and air-dried, whereby a clearly drawn image with excellent fixability was obtained. The image density was 1.2, the fixability was 95 %, and the image evenness was 9.0.

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- 27 -

Example 2

The same copying operation as in Example 1 was carried out using the following paper.

To a starting material consisting of 100 parts of a "freeness" of 440 ml battered L.BKP 0.6 parts of rosin size, 2.0 parts of alum, and 15 parts of talc were added and the pulp for making paper with a Flächenge ^"r A pressing solution of 50 parts of oxidized starch, 50 parts of coating clay and 500 parts of water was applied in an amount of 6 g / m "" (solid) to paper with a size press applied. a paint mi t the following composition was provided with an air knife coater on both sides of the coated paper in Pressleimungslösung

applied at an amount of 4 g / m 2 per 1 side, whereby a release paper with a galley air permeability of 4000 seconds, an oil resistance of 8 seconds and a roll height of 5 mm was obtained.

Emulsion of the ammonium salt of a copolymer of 75 mol% ethyl acrylate, 5 mol% butyl acrylate and 20 mol% Methacrylic acid 19 parts

Polyvinyl alcohol ("PVA 107 ·" from Kurare)

5 parts

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oxidized strength 4 parts

Coating clay or kaolin 72 parts

Antifoam agents (silicone) ..,. 0.1 part

Sodium pyrophosphate, 0.5 part

Potassium pyrophosphate 0.5 parts

Water * 400 parts

The image density was 1.2, the fixability was 95%, and the uniformity of the image was 10.0.

Example 3

Selenium (with a purity greater than 99.99%) was made Vaporized in a vacuum onto an aluminum substrate to a thickness of about 60 μm to produce a photoconductive one Layer. The entire surface of the photoconductive layer was corona discharge uniformly charged at +6 kV and then imagewise exposed to form an electrostatic latent image. The electrostatic latent image formed sn was developed with the liquid developer of Example 1 ur * d obtained a clearly drawn picture in this way.

To a starting material from ICO parts of to a "freeness" of 350 ml of crushed L.BKP

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C., 3 parts of rosin glue, 0.5 parts of alum and 8 parts of talc were added and the paper pulp for the production of Parier was placed in a Fourdrinier machine with a weight of 60 g / m 2. A press size solution with the following composition was applied to the paper produced in this way in an amount of 2.0 g / m 2 (solids) and thus a paper with a galley air permeability of 1500 seconds, an oil resistance of 5 seconds and a roll height of 8 mm received.

Aqueous amine salt solution of a copolymer of 50 Mo1% ethyl acrylate, 35 Mo1% methyl methacrylate, 10 Mo 1% acrylic acid and 5 mol? 6 methacrylic acid

100 parts

Citric acid 1.0 part Antifoam agent (silicone) 0.5 parts Water 2000 parts

The image formed was transferred to the printing paper by a corona transport process and then dried by hot air, and a copy with a printing image density of 1.2, a fixability of 75 % and a smoothness of the image of 9 »0 was thus obtained.

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Example 4

Photoconductive zinc oxide 100 g

Styrene-butadiene copolymer 120 g

(50% solution in toluene)

n-butyl methacrylate 40 g

(50% solution in toluene)

Toluene 120 g

"Bengal pink" 4 ml

(1% methanolic solution)

The above compounds were mixed in a ceramic ball mill for 6 hours to prepare a dispersion. This dispersion was applied to a 0.05 mm thick aluminum plate with a wire bail or a doctor blade to form a 40 µm thick film (when dry) and dried in hot air to evaporate the solvent, thereby obtaining a zinc oxide-based photosensitive plate.

On the other hand, the following ingredients were placed in a ceramic ball mill for about 20 hours mixed together to produce a dispersion.

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nc

Carbon black 4 g

Cyclized gum 60 g

(20% solution in xylene)

Manganese naphthate 5 g

(20% solution in xylene)

"Isopar G" (from Esso) 120 g

20 ml of the dispersion obtained in this way were dissolved or diluted in 2 liters of "Isopar G" with stirring to achieve this a liquid developer. The above zinc oxide based photosensitive plate was made charged in total by -6 kV corona discharge and then to form an electrostatic latent image imagewise exposed. The electrostatic latent image was created with the liquid developer (for preparation see above) and in this way obtain a visible image ■

To a starting material made from 100 parts of an L.BKP crushed to a "freeness" of 420 ml 0.5 part rosin glue, 1.0 part alum and 8 parts talc were added. The mixture was used for manufacture of a paper with a basis weight of 60 g / m 2 is placed in a Fourdrinier machine. One Press size solution with the following composition was with a size press in an amount of 3.5 g / m

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applied to the paper. In this way a Panier with a galley air permeability of 1200 seconds, an oil resistance of 5 seconds and a roll height of 4 mm.

80% sodium neutralized copolymer of 50 mol% butyl acrylate, 30 mol% methyl acrylate, 5 mol% Acrylonitrile and 15 Molyt methacrylic acid (aqueous solution)

50 parts

Polyvinyl alcohol ("N-300" from Nippon Gosei Kagaku)

20 parts

Coating calcium carbonate 30 parts

Antifoam agent (silicone) 0.5 parts

Water 900 parts

The above developed image was transferred onto the thus prepared paper and dried with hot air to obtain a pie with a print image density of 1.1, a fixability of 70 % and an image evenness of 9.0.

P. : i game 5

To 100 g of a 10% solution of poly-N-vinylcarbazole in benzene were 2 ml of a 10% solution of "Bengal-Rora" Added in ethanol. The mixture was up

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stirred completely to become homogeneous. The homogeneous solution thus obtained was coated on an aluminum plate 0.05 mm thick to form a 10 nm thick (dry) film and dried with hot air to form a photosensitive assembly.

The photosensitive plate thus obtained was fully charged by corona discharge of + 6kV and imagewise exposed to form an electrostatic latent image. The electrostatic latent image was developed with the liquid developer of Example 1 to give a clearly drawn image.

To 100 parts of a "freeness" of 440 ml L.BKP was added 0.5 part rosin glue, 1.0 part of alum and 8 parts of talc were added. This mixture was used to make paper with a

ρ
Weight of 60 g / m 2 put into a Fourdrinier machine. With a size press, a size solution with the following composition was applied to both sides of the paper produced in this way in an amount of 4.0 g / m (solid) »

Thus, a printing paper having an air permeability of 440 seconds, an oil resistance was obtained of 4 seconds and a roll height of 5 mm.

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- 3h -

Emulsion of a copolymer of 50 mol% ethyl acrylate, 20 mol # methyl methacrylate, 25 mol% acrylic acid and 5 mole percent acrylonitrile, 33 parts

Polyvinyl alcohol 33 parts

Coating tone 33 parts

Antifoam 0.5 parts

Water 900 parts

The above developed image was transferred to the printing paper thus obtained and dried with hot air and in this way a copy with a print density of 1.1, a fixability (or liquid strength) of 90% and an image evenness of 8.5.

Example 6

100 parts of fine CdS crystals and 20 parts of a 30 # solution of a vinyl chloride-vinyl acetate copolymer in toluene were mixed and the viscosity of the resulting mixture was adjusted to a viscosity suitable for the application by adding toluene. The dispersion solution prepared in this way was applied to an aluminum support to form a hQ μ thick film (in the dry state) and dried. A polyethylene terephthalate film (thickness: 30 / u) was applied

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the photoconductive layer thus obtained is adhered with an epoxy resin-based adhesive for manufacture a three-layer photosensitive plate.

Using this three-layer photosensitive plate, an electrostatic latent image was formed produced by the electrophotographic method disclosed in Japanese Patent Publication No. 23910/1967.

The following ingredients were mixed together with a mixer for 2 hours to produce a dispersion solution:

Carbon black 6 g

Cyclized gum A0 g

(20 % ± ge solution in xylene)

low molecular weight polyethylene with

an average molecular weight

from 1000 (20% solution in xylene) 5 g

Coumarone resin (20% solution in 30 g Xylene)

"Isopar G" (from Esso) 120 g

20 ml of the above dispersion were in 2 1 "Isopar G" dissolved or diluted with 40 ml of lecithin while stirring for making a liquid developer. That

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electrostatic latent image was made liquid with this Developer designed to get a clear image on the optical plate.

On a paper of 90 parts of a bleached hardwood kraft paper pulp (L.BKP), 10 parts of clay resp. Kaolin, 0.6 parts resin glue and 2.0 parts alum with a basis weight of 60 g / m 2 was treated with a The size press applied the following "paint" or coating (see below). In this way it became a printing paper with an oil resistance or oil repellency (measured by dropping 0.04 ral "Isopar G") of 3.0 seconds, a galley air permeability of 260 seconds and a smoothness of 120 seconds.

Emulsion of 50 ΜοΓ% ethyl acrylate, 20 Mo1% Methyl methacrylate and 30 mol% acrylic acid

25 parts

80% NaOH-neutralized aqueous solution of Resin of 50 Moltf butyl acrylate, 30 mol% methyl methacrylate, 5 mol% acrylonitrile and 15 mol% methacrylic acid 25 parts

Polyvinyl alcohol (PVA 117 ¹¹ "by Kurashiki Rayon), 25 parts of

Coating calcium carbonate AO parts

Antifoam agent ("Nopco 1407") 0.1 part

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(The above proportions of the components relate to solids contents).

The above developed image was transferred onto the printing paper by a Corcna conveying process and dried with hot air to obtain a clearly drawn image with excellent fixability. The image density was 1.2, the fixability was 90 %, the smoothness of the image was 9.0, and the roll height was 5 mm.

When using 30 parts of acrylic emulsion and 30 parts of polyvinyl alcohol excluding the water-soluble acrylic resin occurred in this example a resinification or gumming ("gum-up") on the The size press was open and a coating over a longer period of time was not possible.

Example 7

A by vacuum deposition of selenium (purity: more than 99.99%) on an aluminum substrate in a thickness of about 6C μ prepared photoleiter.de layer was fully charged by corona discharge of +6 kV and then imagewise to form an electrostatic latent image illuminated. The electrostatic latent image thus formed was developed with a liquid developer as in Example 1 to give a clear "printed out" image.

On the other hand, the following has been given "Paint" on the same paper as in Example 1 with a size press in an amount of 4.0 g / m applied. This produced a release paper with an "Isopar G" rejection of 2.5 seconds and a smoothness of 110 seconds.

Vinyl acetate emulsion ("Kurare OM" by Kuraray Co. Ltd.) 30 parts

Polyvinyl alcohol ("NH-18" from Nippon Gosei Kagaku) 15 parts

water-soluble acrylic resin of Example 1 .. 25 parts of coating parts 30 parts

Calcium stearate (from Nippon Yushi Karushium Suteareito) 0.5 parts

The above developed image was transferred to the release paper and dried with hot air and printed on thus a copy with a print image density of 1.1, a fixability of 85%, an image uniformity of 9.0 and a roll height of 6 mm.

Example 8

Photoconductive zinc oxide 100 g

Styrene-butadiene copolymer 120 g

(50% solution in toluene)

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n-butyl methacrylate (50% solution

in toluene) 40 g

Toluene 120 g

"Bengal Pink" (1% methanolic

Solution) 4 ml

The above compounds were dispersed in a ball mill for 6 hours. The obtained dispersion was coated on a 0.05 mm thick aluminum plate with a wire hanger or a doctor blade to form a film of 40 µm thick (when dry), and dried with hot air to evaporate the solvent, thereby obtaining a zinc oxide-based photosensitive plate.

On the other hand \ the ingredients indicated below earthen about 20 hours in a porcelain ball mill were mixed together and 20 ml of the resulting dispersion with stirring in 2 1 "Isopar G" were added to form a liquid developer.

Carbon black 4 g

Cyclized gum 60 g

(20% solution in xylene)

Manganese naphthenate 5 g

(20 % solution in xylene)

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"Isopar G" (from Esso) 120 g

The above zinc oxide based photosensitive plate was completed by corona discharge of -6 kV and exposed to a pattern of light to form an electrostatic latent image. Since <= electrostatic latent image was mix developed with the liquid developer and thus obtain a clear print image.

Thereafter, the "paint" given below was applied to one side of the paper used in Example 1 with an air knife coater in an amount of 0.0 g / m 2 and so a release paper with an "Isopar G" repellency (oil resistance) of 6 _t 0 seconds, a galley air permeability of 2000 seconds, and a glow of 200 seconds.

Styrene butadiene latex ("ISR-0660")

20 parts

Polyvinyl alcohol ("Kurare PVA 105"). 5 parts

Amine salt solution of resin of 50 mol% ethyl acrylate, 35 Mo1% methyl acrylate, 10 Ho1% acrylic acid and 5 mole percent methacrylic acid 5 parts

Description tone 70 parts

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Antifoam Agent ("Nopco 1407") .... 0.1 part

Melamine resin ("Sumirez 613" from Sumitomo Kagaku) 0.5 parts

Sodium Pyrophosphate ("PT" from Taiheiyo Kagaku) 0.4 parts

The above developed image was transferred to the printing paper and dried with hot air to form a copy having a printing image density of 1.1, a fixability of 85 %, and an image uniformity of 8.5. The release paper was coated on only one side and the roll height was thus 13 mm.

For comparison, when the image was transferred to high quality offset printing paper of 64 g / m, the image density was 0.5, the fixability was 95%, and the image smoothness was 4.0.

Example 9

To a 20% solution of poly-N-vinylcarbazole in Benzene, 2 ml of a 1% solution of "Benzal" added in ethanol. The resulting mixture was

stirred until homogeneous.

The homogeneous solution was reduced to 0.05 mm

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- 42 - ψ

Aluminum plate and dried with hot air to produce a 10 μ thick layer (iirt Trcckenzustfinri), thereby obtaining a photosensitive plate.

The photosensitive plate thus formed was fully charged by corona discharge of +6 kV and forming an electrostatic latent image imagewise exposed. The latent image was developed with a developer according to Example 1 and thus a clear · preserved developed image.

Thereafter, the following coating liquid became on a paper as in Example 1 with a size press in an amount of 4.0 g / m (solids) applied. In this way, a release paper with an "Isopar G" repellency (oil resistance) of 2.5 seconds, a galley air permeability of 230 seconds and a smoothness of 1.15 seconds.

Ethylene-vinyl acetate emulsion ("OM-4000 ¹¹ by Kurashiki Rayon) 25 parts

aqueous sodium salt solution of a copolymer of 50 mol% butyl acrylate, 30 mol% methyl methacrylate, 15 mol% methacrylic acid and 5 mol% acrylonitrile

25 parts

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Polyvinyl alcohol (Kurashiki Rayon, "PVA-105") 25 parts

Coating tone -25 parts

Antifoam agent ("Nopco DF-122") 0.1 part "

Calcium stearate (Nippon Yushi Karushium Suteareito) 0.5 parts

The above developed image was transferred to the release paper and then mi . Hot air dried to obtain a copy having a print image density of 1.1, a fixability of 85%, an image evenness of 9.0 and a roll height of 4 mm.

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Claims (7)

1. Print paper for electrophotography, characterized in that the paper Copolymers λτιη one or more monomers of the general Formula: A I CH ₀ = C ^ I COOB in which A is hydrogen or CH, and B is alkyl and at least contains a monomer from the group of unsaturated carboxylic acids and / or acrylonitrile. 2. Abzugspapxer according to claim 1, characterized in that the unsaturated carboxylic acid 5 to 35
Forms mol% of the copolymer. 3 * print paper according to claim 1 or 2, characterized
characterized in that the unsaturated carboxylic acid from the group consisting of acrylic acid, methacrylic acid, itaconic acid and
Maleic anhydride is selected. 4. release paper according to claim 1, characterized in that the acrylonitrile is less than 10 mol% of the Copolymers forms. 7342772 11/27/75 5. print paper according to claim 1 and in particular 2, characterized in that the paper through complete or partial neutralization of copolymers of one or more monomers of the above formula of Contains water-soluble acrylic resins prepared according to claim 1 and unsaturated carboxylic acids. 6. Print paper according to claim 1. that the paper by complete or partial neutralization of copolymers from 55 to 95 mol% of one or more monomers of the above formula of claim 1 and 5 to 35 mol% of unsaturated carboxylic acids and less than 10 mole percent acrylonitrile produced water soluble Contains acrylic resins. 7. release paper according to claim 5 or 6, characterized in that the paper is mixtures of said water-soluble acrylic resins with synthetic resin emulsions or those after treatment with these Mixtures ve containing permanent components. 7342772 27.1175