DE2112199A1 - Copier with a heat-sensitive recording medium - Google Patents

Description

IBM Germany International Office Ma * & inen Getelltchaft mbH

Boeblingen, March 9, 1971 km-sk

Applicant: International Business Machines

Corporation, Armonk, N.Y. 10

Official file number: New registration File number of the registration: Docket YO 969 062

Copier with a heat-sensitive recording medium

The invention relates to a copier with a heat-sensitive Data carriers for making copies of documents, pictures or electrically or magnetically stored information.

It is known to use a heat-sensitive recording medium for the production of copies of documents or pictures to be used with a photoconductive or photodielectric layer (e.g. USA patent 3 368 892). If a recording medium coated in this way is exposed with the image of an object to be copied, takes place in accordance with the incident Light quantity is a local change in the conductivity in the photoconductive layer or the dielectric constant in the photo-dielectric layer. Is essentially simultaneous with the coating

109841/1642

Docket YO 969 062

the exposed area is heated by the action of high frequency, which results in the heat-sensitive recording medium sets a heat distribution that corresponds to the object to be copied and that creates a visible image this object leaves behind. These known arrangements have the disadvantage that the incidence of light is relatively intense must be in order to produce a good copy quality. It also has the photoconductive or photo-dielectric Layer no sustainable storage property for the conductivity changes generated in it by exposure or changes in the dielectric constant. The heat fixation must therefore almost simultaneously with the Exposure take place, whereby the structural design option is considerably restricted and a deletion exposure before fixation is not possible.

The object of the present invention is to provide a copier of the type mentioned, in which a smaller Light intensity is used to produce good copies and the aforementioned restrictions do not exist. According to the invention, this is achieved in that the recording medium with a type of field effect influenceable semiconductor layer is provided, which is used to receive and store a charge image of the object to be copied is used, and that for local heating of the semiconductor a heat source is provided, through the action of which a heat source corresponding to the charge pattern is provided visible image is generated in the recording medium.

The charge pattern established in the semiconductor layer can be kept indefinitely. The fixation of the image in the record carrier can therefore to a later

109841/1642

Time and in a different place. "Because everyone The elementary area of the semiconductor layer can be regarded as a power amplifier is that for image formation The energy required in the semiconductor layer, e.g. light intensity, is much smaller than with the known ones Arrangements, the heat-sensitive recording media use.

Various advantageous embodiments of the invention are evident from the claims. Several exemplary embodiments of the invention are shown below with reference to FIG Drawings explained. Show it:

Fig.Ia-Ie a series of simplified representations to explain the mode of operation of a preferred embodiment according to the invention, which uses a magnetic layer as a recording medium

2 shows another advantageous embodiment of the copier according to the invention, where the recording medium is a heat-sensitive one Paper serves and

Fig.3 shows a further embodiment of the invention, the recording on a Layered structure is made, which is made up of a layer of heat-sensitive material, composed of a semiconductor layer and an insulating layer

109841/1642

In Fig.la an electrically insulating support 2 is shown, which can preferably consist of glass, ceramic or the like and which has a thin magnetic layer 4 is coated. The layer 4 consists preferably of europium oxide (EuO), the direction of the magnetic field through Curie point switching can be changed. Such europium oxide is usually at a temperature which is below its Curie temperature. On the layer 4 there is a thin semiconductor layer 6 made of zinc oxide (ZnO).

In order to carry out a magnetic recording on an arrangement as shown in Fig.la, the first step is to use Step a magnetic field M is applied, which magnetizes the entire europium oxide layer 4 in one direction, which lies parallel to the plane of the magnetic layer (Fig.Ib). This direction of magnetization is retained, when the magnetic field M is removed. The surface of the zinc oxide layer 6 is covered by a corona device 8 evenly negatively charged, the entire arrangement being kept in a darkened environment (Fig.Ic). In order to allow the dissipation of excess negative charges within the zinc oxide layer 6, the magnetic layer is 4 connected to earth potential. The zinc oxide layer 6 is then temporarily exposed by taking an image of an object S is mapped onto it (Fig.Id).

By doing this on the surface of the zinc oxide layer 6 resulting light distribution is locally discharged this layer, so that a charge image on the surface of the Layer 6 remains. The properties of zinc oxide, which enable the retention of negative charges and their decomposition

109841/1642

- EZ - *.

Allow light scattering are given in Article ¹¹ A Review of Electrofax Behavior "by JAAmick, RCA Review, December 1969, Volume XX, No. 4, page 753. After the exposure, successive areas of the magnetic layer 4 and the zinc oxide layer 6 exposed to a high-frequency field in that the carrier 2 with the layers 4 and 6 is moved past high-frequency electrodes 12. (Fig.Ie) At the same time, a magnetic field M ¹ , which has the opposite direction to the magnetic field M, is applied to the europium oxide layer 6. Corresponding to the charge image that was produced in layer 6 during exposure according to FIG in an article "Image Storage Panels Based on Field-Effect Control of Conductivity" by B. Kazan et al, PROC. OF THE IEEE, 1968, No. 56 , Pages 285-295. The high-frequency field causes a local flow of current in the zinc oxide layer 6 at the points where it is conductive (discharged), which causes these parts of the layer to be heated. This heating is transferred to the immediately adjacent parts of the europium oxide layer, which are thereby brought to a temperature which is above their Curie temperature, so that, after subsequent cooling, the relevant areas of the europium oxide are magnetized in the direction of the field Maintain M ¹ that is opposite to its initial direction of magnetization. An image is therefore recorded in layer 4 which corresponds to the charge image previously stored in layer 6.

109841/1642

The frequency of the high-frequency energy supplied to the electrodes 12 is selected so that the generation of heat is mainly limited to the zinc oxide layer 6. If the recording is to be made on a magnetic layer, as in the case shown, it is advisable to use a doped zinc oxide material with a correspondingly large conductivity range. For example, a material doped with excess zinc can be used for this purpose. Since as little heat as possible should be generated in the magnetic layer 4, Wf should have a very low conductivity.

In the case of europium oxide, for example, the specific resistance of this material is 10 Ohm c compared to the resistance range of zinc oxide of

6 9
10-10 ohm cm, so that a preferred heating of the zinc oxide over the europium oxide is obtained.

To expose the zinc oxide layer 6, a grid-like exposure can also be used instead of a projection of the object image by scanning with a laser beam or an incoherent intensity-modulated light beam for use come. If a laser beam is used, a very short exposure time of the beam on each is sufficient Raster point of the layer 6 in order to generate the charge image, since a laser beam has a very high light intensity. A significantly higher scanning speed is possible here than when a Str.ahl uses incoherent light will. The main advantage of the reproduction method described above, however, is that storage of the charge image is obtained, which can be kept in this state for a long time and which also allows deletion. The conversion to a magnetically recorded image can be any Point in time after the creation of the charge image. An erasure of the magnetic record

109841/1642

■ Mt "7 ·»

takes place in that a sufficiently uniform magnetic field M is applied to the europium oxide layer 4 and a new recording process is started.

Although the recording explained above was explained in successive steps, is easy to see that the composition of layers 2, 4 and 6 in a light-tight housing such as a camera, and one after the other at a magnetization station, a corona charging station, an exposure station and a high frequency station Can be moved past that are located at successive places of the transport route Structure.

The Fig.2 shows a schematic representation of a such arrangement. A heat-sensitive paper is provided with a zinc oxide layer 6 and serves as a Recording media. The coated paper 14 is in the form of a long movable strip which extends in a camera 16 is located and can be exposed by operating a camera shutter, not shown. The exposure takes place via a lens system 20, which creates an image of a focused object by means of light beams 18 18 is projected onto a part of the layer 6, which is below the open camera shutter, not shown is located. Before this part of the layer reaches the area of the closure, it becomes effective exposed to a corona station where it becomes negatively charged. A grounding of a conductive pulley r allows excess charges to be dissipated from the zinc oxide layer 6 through the low-conductivity paper

109841/1642

The exposure of the zinc oxide layer 6 to the light rays 10 causes a charge image on the surface of this layer / which generates a corresponding conductivity pattern in the zinc oxide layer. This conductivity pattern remains unlimited after its formation
exist until deliberate deletion takes place. That
Any further transported paper then reaches a
High-frequency heating station 22, which has electrodes 12 arranged in the vicinity of layer 6 / which
cause local heating of the layer 6 and the paper 14. The thermosensitive paper 14 may, for example, be of the type whose reddish yellow
Color changes to dark blue when heated above 100 ° C. One type of paper of this type is referred to as thermofax paper. Since the heat generated in the zinc oxide layer 6 by the high-frequency field occurs in a distribution that corresponds to the stored conductivity pattern, this pattern is reproduced in the paper 14. Since the zinc oxide layer 6 is / is / is the discoloration pattern generated in the paper 14 after
visible outside.

The visible image formed in the heat-sensitive paper 14 is fixed when the image area reaches the station 22
leaves. In contrast to the magnetic recording according to Fig.Ia-Ie, the image cannot be erased. It is within the scope of the present invention that the heat-sensitive paper can be replaced with other suitable heat-sensitive materials if so desired. Such materials are, for example, cholesteric / liquid crystals, which change their color when heated.

109841/1642

Although images produced in such crystals by changes in temperature are only for a certain period of time such layers can be preserved in connection with a field effect layer like the zinc oxide layer 6 find use for image generation in dynamic display devices.

3 shows an embodiment of the invention, wherein the recording medium 4 can be a magnetic layer, a heat-sensitive paper or a heat-sensitive crystal. The zinc oxide layer is replaced here by a thin layer of semiconductor material 34 and an electrical insulating layer 36. The insulating layer 36 can for example consist of SiO ₂ or CaF ₂ and the semiconductor material 34 can be for example GdSe, CdS or tellurium and is preferably a semiconductor material that is light can be produced as a thin layer. In contrast to zinc oxide, such semiconductors cannot store the charge image without the presence of an insulating layer 34.

By an arrangement of needles 38, of which in Fig.3 only one is shown and which extend close to or in contact with the surface of the layer 36 stand, the insulating layer 36 individual voltages V_ are supplied, which correspond to the input

output signals are modulated when the structure consisting of the layers 32, 34 and 36 past the needles 36 is moved. In this way, a charge image can be generated on the insulating layer 36. Suppose that the layer structure of recording medium 32, semiconductor layer 34 and insulating layer 36 is corresponding is moved in the direction of the arrow by the roller r.

109841/1642

During this movement, the area of the charge image is exposed to the action of the high-frequency electrodes 12, as a result of which local heating takes place in the semiconductor layer 34. This warming takes place in accordance with the conductivity pattern held in the semiconductor layer 34 by the stored charge image is produced. The local heating is then transferred to the heat-sensitive recording medium 32, where it leaves either a permanent or an erasable record. In the embodiment of 3 it has been assumed that the recording medium 32 is electrically conductive to a small extent and via the Roller r is grounded, thereby removing excess negative charges from semiconductor layer 34 during corona charging derive. The grounded role r also serves to transport the layer structure.

109841/1642

■ · *

Claims (10)

Claims Copier with a heat-sensitive recording medium, characterized in that the recording medium (14) can be influenced with a field effect type Semiconductor layer (6) is provided for receiving and storing a charge image of an object to be copied is used, and that a heat source (12) is used for local heating of the semiconductor layer is provided.? through their action a charge image corresponding visible image is generated in the recording medium. 2. Copier according to claim 1, characterized in that that the semiconductor layer (6) is an optical system (20) for generating an object image is opposite, which corresponds to the light distribution contained in it leads to the formation of a charge image in the semiconductor layer, and that a transport device (r) is provided for the recording medium, through which the stored charge image is in the vicinity a heat source (12) which converts it into a visible image. 3. Copier according to claim 1 and 2, characterized / that the optical system consists of a lens arrangement (20), which from an object (18) projects an image onto the semiconductor layer (6). 109841 / 1B42 4. Copier according to claim 1 and 2, characterized / that the optical system consists of a grid-shaped There is a light beam guided over the semiconductor layer (6) which depends on the The intensity of the image is modulated. 5. Copier according to claim 1 and 2, characterized in that instead of the optical system several needle-shaped electrodes (38) reach close to the semiconductor layer (34), corresponding to those supplied to the image to be recorded modulated voltages will. 6. Copier according to one of claims 1 to 3, characterized characterized in that the semiconductor layer (6 or 34) consists of zinc oxide. 7. Copier according to one of claims 1 to 6, characterized in that the recording medium (4, 14 or 32) consists of europium oxide. 8. Copier according to one of claims 1 to 5, characterized in that the semiconductor layer (34) with an electrical insulating layer (36) is covered. 9. Copier according to one of claims 1 to 8, characterized in that along the transport path of the recording medium (14) a charging device (8) is stationed, which the semiconductor layer (6) in unexposed state with a negative charge provides that in the transport direction following an exposure station (10, 20) is arranged, in which an image of the object to be copied onto the surface the semiconductor layer is brought, and that on the 109841/1842 Exposure station followed by a heating station (12), to which the charge image generated in the semiconductor layer is exposed and which this image into the recording medium (14) transmits. 10. Copier according to one of claims 1 to 9, characterized characterized in that the recording medium is a pre-magnetized magnetic layer (4) which is used for recording a magnetic recording image corresponding to the charge image in the semiconductor layer (6) Curie point switching is used while the semiconductor layer is exposed to the heat source (12). 109841/1642 Blank page