DE3137872C2 - Method for magnetic recording of images on a recording medium - Google Patents

Abstract

In an image recording method, a non-magnetic sheet is placed over a magnetic recording part, then a magnetic latent image is formed on the magnetic recording part either directly or through the non-magnetic sheet by means of perpendicular magnetization before or after the non-magnetic sheet is placed over the magnetic recording part, then the magnetic latent image is developed with magnetic toner from above the non-magnetic sheet placed above the magnetic recording member to form a toner image on the non-magnetic sheet, then the toner image is developed on the non-magnetic sheet, disposed on the magnetic recording member is fixed, and after the fixing step, the non-magnetic sheet is separated from the magnetic recording member.

Description

2. The method according to claim 1, characterized in that a magnetic intermediate image carrier of a supporting substrate and a magnetic recording layer with perpendicular magnetization characteristic is used.

3. The method according to claim 1, characterized in that the toner image at a temperature is heat-set, which is above the temperature value at which the magnetic, latent image the magnetic intermediate image carrier is erased.

4. The method according to claim 3, characterized in that in the production of a plurality of toner images of a single magnetic, latent image only the last toner image at one temperature is heat-set, in which the latent, magnetic image on the intermediate image carrier is erased while the remaining toner image carriers are heat-set at a temperature below the extinguishing temperature is.

50

The invention relates to a method of magnetically recording images on one Record carrier according to the preamble of claim 1. Such a method is from the FR-OS 94 118 known.

In the known method, first of all on an endless, rotating magnetic intermediate image carrier a magnetic, latent image of the original is generated by means of a recording head. Subsequently this magnetic, latent image becomes an intermediate image by means of a magnetizable toner developed, which is then electrostatically transferred to a web-shaped recording medium b5 is transferred and fixed in a fixing device to form a permanent image of the original. After Removing the toner from the magnetic intermediate image carrier, this is demagnetized and the on Any remaining toner particles are wiped off by a cleaning blade.

This method has several disadvantages. The magnetic intermediate image carrier must after each Kopisrvorgang be cleaned to remove the toner residues from it to remove. A separate cleaning device is required for this. Nevertheless, experience shows that it works not to make the intermediate image carrier absolutely free of toner, so that the subsequently manufactured Copies show unwanted toner traces. Furthermore, a device for electrically charging the recording medium, d. H. of the copy paper required to transfer the toner image onto it and onto it the way to the fuser. Furthermore, an unloading device is required behind the fixing station. For the demagnetization of the intermediate image carrier, there is also a corresponding demagnetization device assigned. Seen overall, the known method requires you to do so complicated apparatus-like structure.

Another, quite significant disadvantage of the known method is that the development and the cleaning device comes into direct contact with the magnetic intermediate image carrier. this leads to wear of the intermediate image carrier, which is only caused by relatively low feed speeds can be kept within tolerable limits. The wear and tear leads to a reduction in the quality of the copies. The magnetic intermediate image carrier must therefore be replaced relatively frequently.

The invention is intended to eliminate the aforementioned disadvantages of the known method. You are the one The object is to design this method so that a longer life of the intermediate image carrier is achieved, can be operated at high speed, an improved copy quality is achieved and the outlay on equipment can be reduced.

This object is achieved by the characterizing feature of claim 1. Beneficial Further developments of the invention are the subject of the subclaims.

In the method according to the invention, no toner image at all is formed on the magnetic intermediate image carrier generated. Rather, the toner image is directly on the recording medium, i. H. generated from the copy paper, which is located on the intermediate image carrier and thus covers it. In this state will The toner image is fixed as soon as an electrostatic device is used to transfer and hold the toner on the recording medium is not required. By properly controlling the temperature at Fixing the intermediate image carrier can be magnetically neutralized at the same time, so that a dedicated demagnetization device is dispensable. The contact between the intermediate image carrier and the recording medium poses a negligible problem in practice because these two elements move at the same speed move and therefore any mechanical frictional forces are only small. The intermediate image carrier stays clean, a cleaning device for him is not necessary.

In the following, the invention on the basis of preferred embodiments with reference to the Drawings explained in detail. It shows

F i g. 1 is a schematic view of a device for the practical implementation of a first Aiisl'üh-

Rung form of the invention for creating and developing a 'atentcn image and for fixing the same from the top of the drawing medium (paper sheet) seen here;

F i g. Figure 2 is a schematic view of the magnetic recording station of the device shown in Figure 1;

F i g. 3 is a schematic view of a modification of the FIG. ! Manufactured facility;

F i g. Fig. 4 is an enlarged view of the magnetic recording part and the non-magnetic one Sheet in the in F i g. 3 device shown, which bear against one another;

F i g. 5 is a schematic view of a further modification of the FIG. 1 shown device;

F i g. 6 is a schematic view of a device for practicing the second embodiment according to the invention, in which the formation of a latent image is not carried out from above or from the top of the sheet, but only the developing and fixing from above b / w. be carried out from the top of the sheet;

F i g. 7 is a schematic view of a modification of the one shown in FIG. 6 device shown;

F i g. 8 is a schematic view of a further modification of the FIG. 6 device shown;

9 is a schematic view of a device for practicing a third embodiment of the invention in which a demagnetization of the magnetic recording part in the thermal Fuser can be carried out, and

Fig. 10 is a schematic view of a modification the in F i g. 9 device shown.

Preferred embodiments are described below with reference to the drawings, in which the same or corresponding parts are denoted by the same reference numerals. In Fig. 1 is a visual view of a device for practicing an embodiment of the invention is shown. Here, a magnetic intermediate image carrier 1 in the form of a belt is guided over rollers R 1 and R 2 and is driven in an arrow direction PX by a drive device (not shown). The intermediate image carrier consists of a flexible carrier M (Fig. 2) made of polyester resin, vinyl chloride resin, synthetic rubber, fluororesin or other plastics in tape form or of stainless steel or other material in tape form and one on the carrier XA formed, magnetic recording /. Recognition layer XB (Fig. 2) made of a magnetic material that has perpendicular magnetization characteristics.

The magnetic material that has the perpendicular magnetization characteristics can be selected from the following group: FeÜ2, Fe2U3, FejO4, CrO ₂ . Fe-Ni-Co alloy. MnBi, Mn-Al- Ge alloy Yj · Gai „1 · Fe3-9 · O12 · Tb · FeOa, GdI · G, CoP ₁ Sm ₁ ,.? · Er _o -i · FeO ₃₁ GdFe andTbFe.

The magnetic recording layer 10 can be formed on the support XA by mixing one of the magnetic materials in powder form with a synthetic resinous binder and kneading the mixture into a coatable form, which is applied to the surface of the support XA and b5 dried, to provide the magnetic recording layer \ B. One of the magnetic materials can also be applied directly to the carrier XA as a magnetic recording layer by vapor deposition or vapor deposition in vacuo or by sputtering, by a molecular epitaxy method, by a liquid phase epitaxy method and so on. If the magnetic material is suitable, a chemical vapor deposition process can also be used.

In a perpendicular magnetization system in which a magnetic latent image is formed by selectively polarizing parts of the magnetic recording layer Iß formed by a magnetic material having the perpendicular magnetization characteristics in the direction of its thickness (perpendicular direction) corresponding to the signals to be stored, a external magnetic field has a very sharply sloping shape due to the magnetized part of the layer Xb. For example, if a small point-like area of a square, as seen above the magnetic recording layer XB , is magnetized, the external magnetic field formed by the magnetized points is distributed in the form of a square "pillar", so that the distribution of the magnetic field that extends in a plane parallel to the magnetic recording layer XB , still has the shape of a square even if this plane is arranged at a certain distance from the surface of the magnetic recording layer XB . Thus, when a sheet of non-magnetic material is placed over the magnetic recording layer I3, the external magnetic field on the surface of the sheet of non-magnetic material has a distribution in a plane which does not differ greatly from the distribution in a plane of the external magnetic field with respect to a plane counterpart on the magnetic recording layer differs from Iß.

By developing the magnetic latent image on the intermediate image carrier 1 by means of a magnetic toner which is applied from above to a recording medium 2 made of non-magnetic material covering the intermediate image carrier 1, a sharp image can consequently be produced on the recording medium. Since the external magnetic field generated by the perpendicular magnetization sharply increases, the developed image has a high resolution and hence data can be stored at a high density. If the recording medium 2 is to be brought into full contact with the intermediate image carrier 1 by the electrostatic force as a result of the charge by means of a corona discharge to be described below, this should advantageously be grounded. ".. That is, if a material with a relatively low electrical resistance or a material having an electrical resistivity of less than about 10 ⁸ ncm of any of the above-mentioned magnetic materials with perpendicular magnetic magnetization characteristics is used to form the magnetic recording layer I3, it should be grounded. For example, a conductive material layer is formed on the flexible substrate XA , and the magnetic recording layer Iβ is formed on the conductive material layer which is grounded.

The recording medium, which will later be referred to as "sheet", is fed as a band-shaped non-magnetic material from a sheet feed station 9 and moved in the direction of the arrow P1 ,

which it is arranged on the intermediate image carrier 1. The web material is cut into sheets of the desired size by means of a cutting device 10. The sheet 2 can be either paper, plastic, non-magnetic metal, etc. as long as the sheet 2 is only non-magnetic. If a contact-making device, in which the electrostatic force is used, which has been generated by charging by means of a corona discharge to be described below, is used, the sheet 2 is preferably made of a material with a specific resistance of more than 10 ^ι0 Ω cm, to make loading possible. In Fig. 2 shows an embodiment of a magnetic recording station for subjecting the magnetic recording layer I3 of the intermediate image carrier 1 to perpendicular magnetization in accordance with signals to be stored. In Fig. 1 and 2, the magnetic recording station 3 is provided with a plurality of magnetic recording heads each having a magnetic core 3/4 of a small thickness formed by pressing in a predetermined shape and a magnetizing coil 33 wound around the core 3A. The magnetic recording heads 3, the number of which is equal to the number of recording dots necessary to form an image, are arranged broadly across the sheet 2 close to each other. Each magnetic core 3Λ has a recording pole 3C, the front end of which has an area which can change depending on the size of the pattern of the information to be recorded or which is in the range between 0.1 and 0.01 square. The magnetic core 3a also has a magnetic flux closing pole 3D. the surface of which is located opposite to the sheet 2 and which has a much larger surface area than the recording pole 3C. As a result, the magnetic flux passing through the pole 3D has a lower flux density, so that the magnetization of the magnetic recording layer I3 of the intermediate image carrier 1 can be minimized when it is below the pole 3D which closes the magnetic flux

lllllUU! Ui _e > .. ll.

A magnetic shunt 4 is formed from a magnetic material which extends over the sheet 2 is arranged opposite the magnetic core 3/4. The magnetic one Shunt 4 has a non-magnetic layer 4Λ, which deflects the magnetic flux Layer is to a magnetic flux, which between the magnetic core 3.4 and the magnetic shunt 4 is generated by an electrical signal applied to the magnetizing coil 3ß, in a perpendicular in the magnetic recording layer I3 of the intermediate image carrier 1 bring.

In a developing station 5, a dry developer with a magnetic brush system, a cascade system, a powder-cloud system, etc. can be used. The toner used in the dry development method comprises powder of a magnetic material such as CrO>, FC2O3, Fe3O4. The magnetic toner having a desired particle size can be obtained by mixing 0.1 to i0 μπι toner with a synthetic resin material such as acrylic resin, vinyl resin, etc. in an appropriate solvent such as toluene, methyl ethyl ketone, ethyl acetate, etc. and the Mixture is then kneaded before it is pulverized by a drying centrifuge. In a fixing station 6, the TonerL.ld is fixed in the usual way. Furthermore, a demagnetizing head 7 is provided in order to demagnetize the magnetic latent image on the magnetic recording layer I3 of the intermediate image carrier 1. A device 8 which establishes a very good contact has a corona charger SA and a high-voltage power supply 8β in order to apply a voltage to the corona charger SA ; The device 8 serves to bring the magnetic recording layer 1 3 of the intermediate image carrier 1 into full contact with the non-magnetic sheet 2 by the electrostatic force created by a corona discharge.

The operation of the device shown in Fig. 1 will now be described. When the intermediate image carrier 1 is moved by a drive device (not shown), the sheet 2 is applied to its magnetic recording layer 1 3 and brought into abutment therewith by the contact-making device 8. The sheet material to be cut into sheets is withdrawn from the feed section 9 and cut by the cutter 10 onto a sheet 2 of a predetermined size before it is placed on the magnetic recording layer I3. The sheet 2, which is snugly against the magnetic recording layer I3, passes between the magnetic recording heads 3 and the magnetic shunt 4. At this time, a current is sent to the magnetizing coil 33 of the magnetic head 3, and a closed magnetic field is generated between the magnetic core 3A and the magnetic bypass 4 as shown by broken lines in Fig. 2 to magnetize the magnetic recording layer. If no current is sent to the magnetizing coil 33, the magnetic field indicated by the broken lines will not be generated and the magnetic recording layer I3 will not be magnetized. Since the current sent to the magnetizing coil 33 is controlled by signals corresponding to the information to be recorded, a magnetic latent image of the information can be recorded on the magnetic recording layer I3 through the sheet 2 sandwiched between the magnetic recording layer I3 and the magnetic head 3 is arranged.

In Fig. 1 is a side view of the device for practicing an embodiment of the Invention shown. In reality, a number of magnetic recording heads 3 are across the width of the Intermediate image carrier and the sheet 2 arranged.

As a result, the signals pass through the magnetizing coils one after the other 3ß in synchronism with the displacement of the intermediate image carrier and the recording sheet 2. Thus, the number of magnetic recording heads 3 can be set at a predetermined angle with respect to the direction of movement of the intermediate image carrier 1, its speed of movement and the time interval corresponds with which the signal successively passes through the magnetizing windings 3ß of the heads 3, to be ordered.

The intermediate image carrier 1 which has the magnetic latent image on its magnetic recording layer Iß, and the sheet 2 arranged on it reach the development station 5, in which the magnetic latent image on the recording layer I3 from above or from the top of the sheet 2 is developed with a magnetic toner. That is, there becomes a toner image of the latent image on the Sheet 2 formed. After the toner image on the

Sheet 2 has been fixed in the fixing station 6, the sheet 2 is from the recording layer 1ß of the intermediate image carrier 1 separated.

As soon as the sheet 2 is separated from the intermediate image carrier 1, the magnetic latent image recorded on the recording layer I3 is erased by means of the demagnetizing head 7 arranged in the vicinity of the roller R 2 to restore the recording member 1 to its original state. The above-described steps are repeated one after another to copy information points. If the degaussing head 7 is turned off for a predetermined time or moved away from the developing station 5 so as not to demagnetize the magnetic recording layer I3 and thereby erase the magnetic latent image, the information can be copied on as many sheets as possible.

The facility making the contact is not essential and can be dispensed with if none There is a risk that the sheet will be displaced with respect to the intermediate image carrier 1, for example when the non-magnetic sheet is strongly adhesive.

According to the invention, no toner is applied directly to the intermediate image carrier 1, so that the There is no need to clean it. As a result, there is no wear and tear of the magnetic recording layer so that it does not deteriorate even after a long use The sheet, like a copy paper, is separated from the magnetic recording layer I3, first after the toner image formed thereon is fixed so that there is no fear of magnetic toner scattering or moved when the sheet is separated. This is then a contamination of the sheet and the device with toner excluded, so that a fresh, sharply defined image is always produced can be.

In Fig. 3 is a schematic view of a device shown, which is a modification of the in F i g. 1 reproduced facility is. In the one shown in FIG The device is the intermediate image carrier shown in FIG 1 in the form of a drum, and the magnetic shunt 4 is accordingly also designed in the form of a drum, so that the intermediate image carrier 1 and thus the magnetic The recording layer can be rotated.

In Fig. 4, enlarged parts of the magnetic recording drum and the sheet 2 of the device shown in Fig. 3 are shown. In FIG. 4, the magnetic recording drum 11 has a non-magnetic material layer HC on a magnetic carrier HA and a thin magnetic material layer 11 on the non-magnetic material layer UC. The non-magnetic material layer HC is preferably made of a non-thermally conductive material! manufactured, such as metal oxides AI2O3, S1O2, ZnOj, a resin based on urea or urethane with high heat resistance or a polymer therefrom with a resin based on vinyl. The carrier WA performs the function of the magnetic shunt 4, and the non-magnetic material layer HC plays the same role as the layer 4/4. With the magnetic recording drum 11 of the above embodiment, an image with high resolution can be formed because the magnetic field in the thin magnetic material layer 113 can have a good perpendicularity due to the magnetic flux-breaking effect of the non-magnetic material layer HC. Also, the magnetic field under the pole 3C of the recording head has a higher strength, and the external magnetic field generated by magnetization also has a larger strength and is made sharp.

FIG. 5 shows a modification of that shown in FIG Facility reproduced. In the in F i g. 5 is the dry developing device 15 and the heat fixing device 16 of the FIG. 3 by a liquid development device 25 and a controlled hot blast fixing device 26 replaced.

In Fig. 3 and 5, the sheet 2 lies on the outer peripheral surface of the magnetic recording drum

is 11 substantially in the shape of a horizontal U, and the contacting device 8, the magnetic recording head 3, the developing device 15 or 25 and the fixing device 16 and 26 are arranged in the area of the outer peripheral surface of the magnetic recording drum in which the sheet 2 rests against the drum. The devices shown in FIGS. 3 and 5 work in the same way as with reference to FIG. 1 is described. When the drum is rotated in the direction of the arrow P \ , a magnetic latent image is formed and developed in the specified order from above and from the top of the sheet 2, and the toner image is fixed. The sheet 2 is then separated from the drum by a separating device 12 and discharged into a tray 13.

In Fig. 6 is a schematic representation of an apparatus for practicing a second embodiment of the invention. In the devices shown in Figs. 1, 3 and 5, not only developing a magnetic latent image and fixing a toner image but also forming a magnetic latent image were carried out from above and from the top of the sheet 2, respectively. However, developing and fixing is to be carried out from above the sheet 2 in order to prevent the magnetic recording member 1 or 11 from coming into contact with the magnetic toner and being soiled, and to prevent the magnetic toner from spreading or moving. when the sheet is separated from the intermediate image carrier. In the in F i g. 6, the sheet 2, which has been withdrawn from the feed section 9, rests on the intermediate image carrier 1 only in the vicinity of the roller R 2 , and the magnetic recording heads 3 are with respect to the direction of movement of the intermediate image carrier in front of the contact point of the sheet 2 with the Intermediate image carrier 1 arranged. As a result, the sheet 2 is disposed over the intermediate image carrier 1 after a magnetic latent image is formed by the magnetic recording heads 3 immediately on the outer periphery thereof. In this respect the device shown in Fig. 6 differs from the device shown in Figs. 1, 3 and 5, in which the magnetic latent image is formed after the sheet 2 is placed over the intermediate image carrier 1, 11 . In the device shown in Fig. 6, the sheet 2 is brought into abutment with the outer magnetic recording surface of the roller Λ 2 and separated from the outer surface of the roller R 2 by means of two guide rollers R 3 and R 4; the contacting device 8, the developing device 5 and the fixing device 6 are mounted in the region of the recording roller R 2 in which the sheet 2

rests against the intermediate image carrier t.

7 is a schematic view of a modification of the device shown in FIG. 6, the intermediate image carrier shown in FIG 1 is in the form of a magnetic recording drum and also has the magnetic shunt 4 has a drum shape so that the magnetic recording layer of the recording drum can turn. The sheet 2 fed from the feed section 9 is fed via the guide roller /? 3 pulled, which cooperates with a guide plate 14, and is with the outer surface of the magnetic Recording drum 11 brought into contact at one point, where the outer surface begins to rotate downwards before it passes through the one located under the drum 11 Separating device 12 is separated from the outer surface of the drum 11.

In Fig. 8 is a modification of that shown in FIG. 7 reproduced Device shown in which the dry developing device 15 and the fixing device 16, shown in FIG. 7 through a liquid developing device 25 and a controlled hot blast fixing device 26 are replaced. In this device, the sheet 2 is flush with the outer surface of the drum 11 brought into the lower part of the plant.

In the device shown and described above for performing the image development process According to the invention, the demagnetizing head 7 is exclusively for demagnetizing the Intermediate image carrier 1, 11 used to remove the magnetic latent image therefrom. The degaussing head 7 can be omitted if the heat fixing device 6, 16 or 26 is designed so that the magnetic recording layer 15 or 1 ß through the fixing device is heated to a temperature above the Curie point in order to demagnetize it of the magnetic recording layer.

In Fig. Referring now to Fig. 9, there is shown apparatus for practicing a third embodiment of the image developing method according to the invention which includes heat fusing means 36; in FIG. 10 is a modification of that in FIG. 9 shown device reproduced. In the in Fi g. 9, an intermediate image carrier 1 in the form of an endless belt is used, while in the device shown in FIG. 10, an intermediate image carrier in the form of a drum is provided. In FIG. 9, the band-shaped intermediate image carrier 1, which is guided over the rollers R 1 and R 2, has an upper run, which is a return run, and a lower run, which is a forward run. The sheet 2 is brought into contact with the intermediate image carrier 1 on the lower run thereof, and the contacting device 8, the developing device 5 and the heat fixing device 36 are arranged along the lower run which is in contact with the sheet 2. With the in F i g. 9 and 10, a demagnetizing head is not used because the heat fixing device 36 also serves as a demagnetizing device.

The heat fixing device 36 can serve as a heat source infrared lamp 36/4 for emitting a Have infrared radiation or a role that emits heat, a hollow metal tube coated with silicone rubber with one housed inside Has infrared lamp, and which is rotated and pressed against the recording sheet 2.

With the heat fixing device 36, the magnetic Toner image fixed by heat generated by the developing device 5 has been formed on the non-magnetic recording sheet 2 and it becomes the magnetic recording layer of the intermediate image carrier 1, 11 demagnetized to by heating the magnetic recording layer to a temperature higher than its Curie point, the magnetic latent Remove image.

The Curie points of the different magnetic materials from which the magnetic recording layer of the recording member 1, 11 is formed are as follows: MnBi, 18O ⁰ C; MnAIGe, 175 ° C; Y ₃ Gali_iFej _ <, Oi2. 120 ⁰ C; TbFeO ₃ , 400 ° C and TbFc, 130 ° C.

If the magnetic recording layer is thus formed from one of the magnetic materials mentioned above, the magnetization temperature is in the range between 100 and 400 ^° C., depending on the material selected. The fixing temperature of dry magnetic toner is mainly determined by the synthetic resin that forms the toner , and is generally in the range between 100 and 300 ^° C. By appropriately choosing a synthetic resin that is mixed with the magnetic toner, a magnetic toner can be used with an appropriate fixing temperature which is adapted to the demagnetization temperature of the magnetic material.

In addition 5 sheets of drawings

Claims (1)

Patent claims: 1. Method for the magnetic recording of images on a recording medium, at to the a) on a rotating, endless, web-shaped magnetic intermediate image carrier a magnetic, generated latent image of a template, b) the recording medium in contact with the intermediate image carrier with the magnetic, latent Figure brought c) a toner image is generated on the recording medium, and d) the toner image is fixed characterized in that 20th e) the toner image is generated on the surface of the recording medium which is from the intermediate image carrier is turned away, and that f) the toner image is fixed on the recording medium while the intermediate image carrier is moving located in attachment to the recording medium.