CH621421A5 - Magnetographic dry copying process and device for carrying it out - Google Patents

Description

The invention relates to a magnetographic copying method for the dry printing of data, a magnetic image being produced on an image base and then the magnetic image being provided with ferromagnetic toner particles which are then electrostatically transferred to a dielectric copy base and fixed there.

Xerographic and magnetographic printing processes are already known. In a xerographic process, an electrostatic charge is generated on a photoconductive material, such as selenium, and the photoconductive material is exposed for imaging, with the exposed areas losing their charge. Subsequently, a finely divided, electrically charged powder provided with color pigment is applied, which is attracted and held by the electrostatic image. The charged toner image is then transferred to the copy paper either by means of an opposing electrostatic charge or by pressure.

Magnetographic imaging processes produce a magnetic image and become ferromagnetic particles

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applied to it, which adhere to the magnetic image areas. The particles are then transferred to copy paper either by pressure or magnetically. In the case of transmission by pressure, disadvantageous wear occurs on the imaging element and a film can also build up on the imaging element, which causes smearing.

In the case of magnetic transfer, it has proven difficult to carry out the toner transition without erasing the latent magnetic image on the imaging element. ] 0

It is an object of the invention to provide a method and to provide an apparatus for carrying out the method, with which the difficulty in magnetic image transmission can be mastered.

The object is achieved by the invention specified in the patent claims.

The specified process involves the production of a latent magnetic image, the application of an uncharged ferromagnetic toner to the latent magnetic image and the subsequent transfer of the toner electrostatically to a substrate in such a way that difficulties that arise from the action of pressure or magnetic transmission , are overcome and using electrostatic neutralizers such as AC corona discharge to neutralize electrostatic charges on such toner particles that would otherwise produce a blurry image on the final copy and unwanted background marks.

An uncharged toner is understood to mean a toner which has not been intentionally charged by, for example, a corona discharge or frictional electricity, but which may, however, contain small frictional electricity charges of any polarity.

The drawings show:

1 is a schematic side view of a printer which is used in carrying out the method according to the invention;

2 shows a side view of another embodiment of a printer for carrying out the method according to the invention, 40

3 shows the exposure of the magnetic imaging element by means of radiation energy,

4 shows the latent magnetic image,

5 is an illustration of the magnetic image provided with toner, which lies next to the copy paper, 45

Fig. 6 is an illustration of the copy paper that has been provided with the transferred image and

Fig. 7 is an illustration of the finished copy with the melted image.

3 to 7 show the gradual production of the 50 latent magnetic image and the application of toner thereon, as well as the transfer of the toner to the copy paper and the connection of the toner to the copy paper.

FIG. 8a shows a schematic representation of the unwound surface of the drum 15 according to FIG. 1 and shows the result 55 of a magnetographic copying process without using the electrostatic neutralizing devices according to the invention, while

FIG. 8b shows a schematic illustration similar to FIG. 8a, which shows the use of the AC corona discharges according to the invention.

An aluminum-coated polyester film is provided with a layer of periodically magnetized chromium dioxide particles which are attached in a binder adhering to the film surface and which serve as a copying device. 65 The arrangement is exposed to uniform illumination according to FIG. 3. As can be seen from Fig. 3, the print job on the translucent original prevents the

Illumination reaches the magnetized chromium dioxide particles so that they remain in the magnetized state in the areas under the print job. On the other hand, those areas of the original to be copied that do not have a print job do not prevent the light rays from reaching the magnetized chromium dioxide particles, so that they are heated above their Curie temperature of about 116 ° C. and thereby demagnetized. The latent magnetic image shown in FIG. 4 is produced in this way. Ferromagnetic toner particles are applied to the latent magnetic image to give a developed magnetic image. 5 is placed on the magnetic image. A corona discharge device then charges the back of the paper electrostatically. A sufficiently large electrostatic force is generated to overcome the magnetic attraction between the previously uncharged toner particles and the latent magnetic image, so that the toner particles are transferred to the copy paper with surprisingly good efficiency and adhere there according to FIG. 6. The electrostatic transmission does not affect the latent magnetic image, which can be used again and again. In this regard, reference is made to the patent (Ges.-Nr. 3 702/77). The transferred toner particles are then fused to the copy paper by heat as shown in FIG. 7.

The toner particles preferably consist of magnetic pigment particles encapsulated in a thermoplastic binder. Generally, the toner particles have an average particle size between 10 and 30 microns, with the preferred particle size between 15 and 20 microns. Spherical particles, such as those obtained by spray drying, are preferred because of their superior flow behavior, which can be increased by adding small amounts of a flow agent, such as silicon dioxide. A further description of the preparation of the toner particles can be seen in US Pat. No. 3,627,682. When using the device described, the toner particles should have a low electrical conductivity. If the particles have a high conductivity, they get back and forth between the drum and the paper, causing an out of focus image and a low transfer efficiency. In general, the electrical conductivity of the powdered toner is less than 1X10 "13 S / cm.

1, the original to be copied is applied to the tray 11 and moved against the inlet 12. The copier is then actuated to raise the inlet 12 and bring the lower feed roller 13 into abutment with the original. The conveyor roller 13 brings the original into the gap between the endless conveyor belt 14 and the drum 15. The endless conveyor belt 14 consists of a transparent film, for example a polyethylene terephthalate film with a thickness of about 0.05 to 0.18 mm. The rollers 16, 17 and 18 serve to drive and guide the endless conveyor belt 14. The surface of the drum 15 preferably consists of a polyethylene terephthalate film with a thickness of approximately 0.13 mm. The convex surface of this film is covered with a conductive layer, for example with an aluminum layer with a specific surface resistance of 1 to 1000 ohms. The aluminum layer is preferably grounded. The conductive carrier can also consist of plastic, for example of a polyoxymethylene sleeve which is coated or produced with aluminum, nickel, copper or another conductive material. The carrier can also consist of the conductive metal itself. The surface of the aluminum is provided with a layer of ferromagnetic material, for example with acicular chromium dioxide in an alkyd or other suitable binder. In general, the layer of needle-shaped chromium dioxide has a thickness of between 0.001 and 0.012 mm and contains between 40 and 85% by weight of needle-shaped

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chromium dioxide and between 15 and 60% by weight of an alkyd binder or another resin binder. The acicular chromium dioxide can be prepared according to US Pat. No. 2,956,955, however preferred acicular chromium dioxide particles are obtained by the processes according to US Pat. Nos. 5,923,683 and 3,512,930.

The drum 15 rotates counterclockwise. The ferromagnetic coating on the drum is magnetized by a biasing device 19 which records a periodic pattern. A number of methods are known for carrying out this magnetic structuring.

This results in a working range between 12 and 40 magnetic reversals per mm on the magnetizable surface and preferably between about 15 and 24 magnetic reversals per mm. 15

According to an alternative embodiment, a foil structured by grooves can be used for the surface of the drum 15, which contains needle-shaped chromium dioxide, in which case a simple DC magnet can serve as a biasing device 19. 20 generally 7.5 to 12 grooves per mm drum extension are provided, with 15 to 24 magnetic reversals per mm being obtained.

The magnetized drum surface which is in contact with the original is then guided past an exposure station shown at 20. The exposure station consists of a lamp 21 and a reflector 22. A xenon flash lamp, which has a color temperature corresponding to 6000 ° C., is suitable as lamp 21. The surface of the drum 15 is gradually exposed until the entire original is recorded as a latent magnetic image on the surface of the drum 15. The chromium dioxide used has a Curie temperature of approximately 116 ° C. The data of the copied original, for example pencil lines, an imprint or the like, give a shadow in the exposure in the regions of the chromium dioxide 35 above which these data lie, as a result of which is prevented,

that these areas reach the Curie temperature. After exposure, the surface of the drum thus has magnetized chromium dioxide regions which correspond to the regions of the translucent copied original provided with data.

After exposure, the copied original falls into the collection container 23.

The imagewise magnetized drum 15 is rotated past a toner application device which contains a trough 24 which is provided with a rapidly rotating roller 25 and a rod 26. The device 62 'removes any static charges on the toner particles exiting the toner applicator. A vacuum squeegee 41 is used 50 to remove toner particles that have inadvertently remained on the demagnetized areas of the chromium dioxide on the surface of the drum 15.

The paper 32 on which the copy is to be made

is fed from a supply roller 33 via idling rollers 34, 35 55 and 36 to the conveyor rollers 37 and 38. A counter roller 39 cooperates with a roller 40 equipped with cutting edges 41. The rollers 39 and 40 are actuated by a device (not shown) in order to cut the paper 32 to a length corresponding to the original to be copied. The paper is then brought into contact with the surface of the drum 15 by the conveyor rollers 42 and 43. The paper 32 lying on the drum surface is guided past a corona discharge device 44, which is preferably designed as a device known as a corotron and has a corona wire which is approximately 17.5 mm from the paper, and a mechanical shield which surrounds about 75% of the corona wire and one

Leave a 90 ° opening around the wire facing the paper. The metallic shield is insulated from the corona wire and is kept at earth potential. Generally, the corona wire has a diameter between 0.025 and 0.25 mm and is maintained at 3000 to 10,000 volts. The wire can have either a negative or a positive potential, with the negative potential being preferred. Corotron 44 electrostatically charges the back of paper 32. As a result, the paper is placed slightly against the drum and, when the paper is separated from the drum, an image-wise transfer of toner particles onto the paper 32 takes place in accordance with the original endless vacuum belt 50 loosens, the toner particles remain image-wise connected to the paper 32. It has been found that the Corotron 44 should lie over the arc area of the close contact between the paper and the drum to achieve the beneficial result. If the corotron 44 is in a different position or there are forces which prevent the paper 32 from forming a close, arch-shaped contact, the image obtained becomes blurred. There is only a slight pressure between the paper 32 and the surface of the drum 15, which is only sufficient to hold these two parts together. The pressure between the paper 32 and the drum 15 is generated substantially entirely by the electrical attraction provided by the corona discharger 44. Nonetheless, the efficiency of the transfer is surprisingly high and is 100% higher for toners with a non-sticky surface and low conductivity. The paper 32 is then removed from the surface of the drum 15 by the action of the endless vacuum belt 50 in cooperation with a cushion 45 which presses the paper against the surface of the endless vacuum belt 50 which is driven by rollers 51 and 52. The endless vacuum belt 50 guides the paper 32 past infrared lamps 53, 54 and 55, which heat the thermoplastic resin used to encapsulate the magnetic material in the toner so that the toner particles melt and bond to the paper 32. The paper 32 provided with the transferred image is then discharged into the hopper 56.

If multiple copies of the same original are desired, a control, not shown, is actuated such that the drum 15 rotates continuously without switching on the demagnetizing device 60, the suction device 61, the magnetizing device 19 or the lamp 21, since the electrostatic transmission of the Toner particles do not affect the magnetic state in the chromium dioxide layer on the surface of the drum 15. Many copies can be made using a single exposure at a feed rate of up to 91.5 m per minute. For demonstration purposes, more than 10,000 copies were made from a single magnetic image.

Untransferred toner particles can be electrostatically charged in the transfer zone adjacent to the corona discharge device 44 itself. Because of the nature of the toner, these charges do not flow to earth. Subsequently, these particles electrostatically pick up other particles in the application device 24 and finally transfer them, whereby undesirable markings arise. To prevent this, a static charge extinguishing device 62 is used, which consists of an alternating current discharge rod, but for which any static compensation device can be used, as is known, for example, in the form of nuclear rods. It has been found that a Simco unit operating at 60 Hz and 7000 volts works satisfactorily for this purpose.

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A fraction of the toner particles are not transferred to image areas. Particles in the image areas that are still charged as they pass through the applicator 24 pick up electrostatic toner particles that are held so tightly that the vacuum squeegee 31 cannot remove them, thereby causing the image to “bloom” or grow, and a blurred outline with repeated copying. The static charge eraser 62 prevents this undesirable phenomenon.

Some toner particles are also sparsely distributed over non-image areas that are not transferred to the paper and that are electrostatically charged in the transfer zone. These particles also attract electrostatically toner in the application device 24, which cannot then be completely removed by the vacuum doctor blade 31, as a result of which an undesired background drawing occurs on the finished copies. The static charge eraser 62 also prevents this undesirable phenomenon.

A number of toner particles are charged with frictional electricity by contact with each other and with the various surfaces due to the action of the application device 24. These electrostatically charged particles are bound to the surface of the drum 15 by so-called “mirror images”. The nature of the toner does not allow the charge to flow to the grounded surface, as is the case with static charges directly on the surface of the drum 15. If these particles remained on the surface of the drum 15 in a random distribution, this would affect the purity of the background of the finished image on the copy paper. The vacuum squeegee 31 is extremely effective in removing these particles, but some of the particles, which are presumably charged higher than others or have a smaller size, are held sufficiently firmly on the drum surface that they cannot be removed by the vacuum squeegee 31. A second static charge erasing device 62 ′ is arranged after the image application device 24 and in front of the vacuum squeegee 31 in order to remove the electrostatic charge of these particles and thus to improve the effect of the vacuum squeegee 31. The static charge eraser 62 'is necessary for the repeated stable reproduction of the latent magnetic image and also for obtaining background areas with excellent purity. The two charge erasers work together to produce the highest quality magnetographic copies and to deliver a large number of copies from a single latent magnetic image.

If copies are to be made from another template, a demagnetizing device 60 is actuated, which in the case of a continuously coated film expediently consists of a direct current magnetic head and the chromium dioxide is magnetized uniformly. Any toner particles that may have remained on the previously magnetized areas of the chromium dioxide are removed by the suction device 61, which preferably works in conjunction with brushes. The chromium dioxide is then magnetized by the magnetizing device 19, a periodic magnetic structure being obtained and the described method being repeated.

Instead of paper, other substrates such as fabrics and dielectric foils can be used.

Fig. 2 shows an alternative embodiment of a printer having a magnetic printhead as described by W.H. Meiklejohn in A.I.P. Conference, Proc. (Pt. 2) 10, (1973) pages 1102 to 1114. 2, the magnetic print head 71 is used to produce the latent image on the magnetic surface of the drum 72, which has the same structure as the drum 15 described above. The magnetic printhead 71 is a multi-lane printhead developed for a stationary head per web slice. The web density is preferably approximately 80 magnets per cm, which is sufficient for a copying process with good resolution. In general, a multi-lane write head is actuated by drive devices which are activated by a generator with a read-only memory structure. This generator is responsive to a data storage device, such as a magnetic tape, which can be part of the printer or located away from the printer. In an alternative embodiment, the multi-lane write head is activated by a keyboard, the magnetic structuring being carried out by the magnetic write head. The drum 72 rotates counterclockwise and carries the latent image past a static charge eraser 107. The electrostatic charges carried by any particles on the surface of the drum 72 are neutralized by the charge eraser 107. Such particles can consist of unintentionally adhered particles or particles in an image area that have not been transferred. Such particles may be very highly charged after they have passed the corotron 96 and would attract oppositely charged toner particles in the toner application device 108 if they were not neutralized by the static charge eraser 107. The charge extinguishing device 107 can be constructed in a known manner. Corona discharge at 60 Hz and 7000 volts AC is preferred because as the drum 72 rotates, the latent image is passed past the toner applicator 108, which consists of a trough 73 equipped with high speed rollers 74 and a stationary rod 75, wherein the latent image is toned to give a developed magnetic image. The static charge eraser 107 'removes any charges of toner particles exiting the toner applicator 108. These charges are based on a charge from frictional electricity and cause particles to adhere to the drum 72. Thus, the vacuum doctor can

81 Eliminate any unwanted toner particles, i.e. Particles that are not in an image area.

The paper 82 on which the toner pattern is to be applied is guided by the roller 83 around the idling rollers 84, 85 and 86 to the conveyor rollers 87 and 88. A support roller 91 cooperates with a roller 92 provided with cutting edges 93. The rollers 91 and 92 are operated by a device, not shown, to cut the paper 82 to the desired length. The paper is then brought into contact with the surface of the drum 72 by the feed rollers. The paper 82 in contact with the drum surface passes the corona discharge device or the corotron 96, by means of which the toner particles are electrostatically transferred to the paper 82. The paper 82 is then removed from the surface of the drum 72 by the action of the pad 97 which presses the paper onto the surface of an endless vacuum belt 98 driven by rollers 99 and 100. The endless vacuum belt 98 transports the paper 82 past infrared lamps 101, 102 and 103, which heat the thermoplastic resin that surrounds the ferromagnetic material in the toner particles so that they melt and adhere to the paper

82 connect. The printed paper 82 then passes into a tray 104. The drum can be continuously driven to make a plurality of copies.

If a copy is to be made on the basis of a further template, the image erasing device 105 is actuated in order to erase the latent magnetic image and the suction device

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device 106 is used to remove any toner particles that have adhered to the old latent magnetic image.

The method can also be used using either a thermal pen or an electrical pen to generate the latent magnetic image, the former operating by thermal conduction and the second by electrical resistance heating of the image layer. Each pen can demagnetize selected areas by heating previously heated magnetized material above the Curie temperature, or thermoremanently magnetize selected areas by cooling the heated imagery below the Curie temperature in the presence of a magnetic field. A field of 20 to 200 Oersted next to the pen has proven to be sufficient for thermo-permanent magnetization, while a considerably stronger field of at least 800 Oersted is required to magnetize unheated chromium dioxide sufficiently. It goes without saying that imaging with electromagnetic or thermal transducers on a continuous coating, the surface of which is magnetized with a direct current magnet, requires modulation in accordance with the required magnetic gradients in order to sufficiently attract the toner in the magnetized image areas.

FIG. 8a shows a developed view of the surface of the drum 15 according to FIG. 1, which schematically shows the use of the image application device 24, the vacuum doctor blade 31 and the corotron 44 used for transmission without AC corona arrangements (and without functional representations of the components used for the Explanation of the effect of the alternating current corona devices are necessary). A1 shows a sparsely applied print symbol which consists of the letter I for illustration purposes and which has not been completely transferred into the transfer zone and has been electrostatically charged. The sign of the charge is irrelevant. At a.1, an unintentionally stuck toner particle b1 (enlarged schematically) is shown, which is charged in a similar manner. After the surface of the drum 15 has passed the image application device 24 at a /, the letter I is magnetically provided with toner, but 40 also carries electrostatically adhering toner. At b /

shows electrostatically adhering toner particles on the previously inadvertently adhering toner particles which form a cluster. In addition, some are with

Particles charged with static electricity are randomly distributed on the conductive surface of the drum 15, which are represented here by three such particles Cj.

The vacuum squeegee 31 removes some of the relatively loosely adhering toner particles, but some toner particles remain at a / ', b; "and c /. As can be seen, a" blooming "of the character I has occurred. After passing through the transfer zone next to the Corotron 44 were most of the toner particles, whether desired or unwanted, are transferred, but some remain at a / ", b /" and c / '. The copy has some slightly blurred particles and an impure background Attention is drawn to the fact that in the next printing process, there are additional untransferred and charged toner particles at ai and bt, which will lead to an even stronger flowering of the image and an even less pure background as a result of the enlargement of the background particles Cj becomes a new starting point for unwanted background toner, so with each subsequent print the quality of the copy received is progressively poor.

Figure 8b shows the use of AC corona devices 62 and 62 '. a2 and b2 represent charged toner particles, where a2 denotes untransferred characters and b2 denotes unintended particles. After stepping past the AC corona device 62, a2 'and b2' remain, but are electrostatically neutralized. Thus, the characters are provided with an application without "blooming" according to a2 "and the unintentionally stuck particle b2" does not attract a cluster of toner particles. However, particles charged by frictional electricity may adhere to the surface of the drum 15 at c2. After passing the AC corona device 62 ', a2 "' and b2" 'remain as before, but the particles c2' are neutralized. Thus, when passing through the vacuum doctor blade 31, almost all toner particles are removed from the demagnetized image-free areas and only the applied letter a2IV, which has not been enlarged by flowering, remains, so that the toner image which is transferred to the paper located next to the Corotron 44 is clear and one has a pure background. Any untransferred toner located at a2v, for example, is also within the outline of the original characters and subsequent copies are also clear and are preserved with a plain background.

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Claims (12)

621 421 PATENT CLAIMS 1. Magnetographic dry copying process for repetitive reproduction of image information, characterized by the following process steps a) transferring ferromagnetic toner particles to an electrostatically chargeable copying pad by placing the copying pad on a pictorial arrangement of ferromagnetic toner particles magnetically on a grounded, electrically conductive image pad adhere, the ferromagnetic toner particles having an electrical conductivity of 10 less than 1X 10 ~ 13 S / cm and the resistivity of the material for the image base less than 1X10 + 9 Q • cm, and applying an electric field to the back of the copy base on the front of which the transferred pictorial arrangement of the ferromagnetic 15th There is toner particles by applying an electrostatic charge to the back of the pad, the individual ferromagnetic toner particles adhering to the pad; and b) reapplying ferromagnetic toner material to the magnetizable electrically conductive image base; c) repeating the method step described under a); d) neutralizing the electrostatic charge on the electroconductive image base and the ferromagnetic toner particles thereon by means of AC corona discharge devices or devices which emit weak radioactive radiation, either between the application of ferromagnetic toner particles to the electrostatically chargeable copy base and the renewed one Applying ferromagnetic toner material to the magnetizable electrically conductive image base or between the renewed application of ferromagnetic toner material to the magnetizable electrically conductive image base and the application of the electrostatically chargeable copy base to 35 the pictorial arrangement of ferromagnetic toner particles; and e) removing residual toner particles from the non-magnetized areas on the magnetizable electroconductive image base between reapplying 40 ferromagnetic toner material to the magnetizable electroconductive image base and transferring ferromagnetic toner particles to the electrostatically chargeable copy base. 2. The method according to claim 1, characterized in that the neutralization of the electrostatic charge on the image base and ferromagnetic toner particles located thereon is carried out after the re-application of ferromagnetic toner material on the image base and before the electrostatically chargeable copy base is placed on it. 3. The method according to claim 1, characterized in that the neutralization of the electrostatic charge on the image base and ferromagnetic toner particles thereon is carried out after the transfer of ferromagnetic toner particles onto the copy base and before the re-application of ferromagnetic toner material onto the image base. 4. The method of claim 1, characterized in that 60 neutralizing the electrostatic charge between reapplying ferromagnetic toner material to the image pad and transferring ferromagnetic toner particles to the copy pad and between transferring toner particles to the copy pad and 65 reapplying of ferromagnetic toner material is carried out on the image base. 5. The method according to claim 4, characterized in that the neutralization is carried out by means of AC corona discharge devices. 6. The method according to claim 5, characterized in that the electric field is generated by spraying the back of the copy base with ions. 7. The method according to claim 1, characterized in that the toner particles are fused to the copy base by applying heat. 8. Apparatus for carrying out the magnetographic method according to claim 1, characterized by a magnetizable electrically conductive image pad which is movable and has selectively magnetized ferromagnetic particles, the material of the image pad having a resistivity of less than 1X10 + 9 £ 2 • cm , drive means for moving the image base forward, means (24) for applying ferromagnetic toner particles to the image base, means (31) for removing ferromagnetic toner particles from regions of the layer which are not selectively magnetized, means (33-43), to place a copy pad on the image pad, a device to expose the back of the copy pad while it is superimposed on the image pad to an electric field, a device (45, 50) for removing the copy pad from the image pad and by a neutralizing device (62) e.g. Ur neutralization of electrostatic charge on particles that have adhered to the image pad after the copy pad has been separated from the image pad. 9. The device according to claim 8, characterized in that the neutralizing device (62) consists of an AC discharge device. 10. The device according to claim 9, characterized in that a second neutralizing device (62 ') between the device (24) for applying the ferromagnetic toner particles to the image base and the means (44) for generating an electric field to which the back of the copy base is exposed is arranged. 11. The device according to claim 10, characterized in that both neutralization devices are AC discharge devices. 12. The apparatus according to claim 11, characterized in that the device (44) for generating an electric field contains means for spraying ions onto the back of the copy base.