DE4022974A1 - ERASABLE OPTICAL RECORD CARRIER FOR COLORED INFORMATION - Google Patents

Abstract

The recording medium disclosed comprises a substrate carrying a heat-sensitive film which can be converted into different optical states under the influence of temperature (e.g. opaque and transparent). These states are permanent at normal ambient temperature (e.g. room temperature) and reversible by heating to specific temperatures. The recording medium is designed such that four dots (F) are combined in groups of four to form zones (B), each of the dots (F) having a different primary colour (e.g. red, yellow, blue or black). If the heat-sensitive film over a dot (F) in a zone (B) is converted by appropriate warming to the transparent state, the dot lying under the film becomes visible. This makes it possible to record coloured data, either on a recording medium in the form of a sheet or in the form of a continuous strip from a display device.

Description

The invention relates to an erasable optical Record carrier consisting of a carrier and a heat-sensitive layer attached to it with influenceable by different temperatures optical conditions (e.g. opaque and transparent rent), the states in the normal environment temperature (e.g. room temperature) permanently and rever by heating to certain temperatures are sibel.

Such a record carrier is already be knows. This is how it is in European patent specifications EP-PS 00 00 868 and 00 14 826 a body with rever flexible and temperature-changeable  Light extinctions are described, which can be deleted Record carrier consisting of a pair of substances is formed, which for example when heating from the state of maximum light absorbance to one below a transition temperature temperature and then cooling and under one lower temperature value a decreasing Lichtex tinktion with increasing heating temperature.

The recording and erasing process can be arbitrary Repeat, recording using fine bundled heat or light radiation or also through Contact heat can take place. The well-known record The carrier is therefore suitable for erasable opening drawing of numbers, letters, pictures, patterns, etc., the records can be both transpa rent in opaque surroundings as well as opaque in transparent Environment.

The object of the invention is now that to train known recording media that this also for recording colored information is suitable.

This object is achieved in that on the carrier a matrix on the side facing the layer shaped grid of colored, punctiform or appropriately shaped surfaces is attached.

The color recording takes place in that in Area of the respective area with the desired one Color the overlying heat sensitive layer is heated so that the transparent State occupies while the rest of the area Layer remains in the opaque state, in which they uniform before the start of the recording process has been brought.  

A further development of the invention consists of three point-shaped surfaces are combined into one area, each of the punctiform surfaces have a different basic color (for example red-yellow-blue).

A further development of the invention also consists in that four point-shaped areas each to an area are summarized, each of the punctiform Surfaces have a different basic color (e.g. shows red-yellow-blue-black).

This measure makes it possible to reproduce colored information in all colors. The size of a punctiform surface depends on the intended use. When reproducing colored images on sheet-like information carriers in the common paper formats, the size of such an area is smaller than, for example, the impact area of a needle of a dot matrix printer. This could correspond to an area, for example. If the recording medium according to the invention is used for large display areas, the individual areas can assume orders of magnitude of one or more mm ² .

Now only three basic colors or four Basic colors without the color black for each Surfaces are used, then the one set at the beginning Task solved in that the carrier on the Layer facing side is colored black on the side of the layer facing away from the carrier Matrix-shaped grid of colored, punctiform or appropriately shaped surfaces is attached, and that on the first layer a second heat sensitive one Layer is attached, the temperatures to Change in the optical properties of the two Layers are different.  

In this version of the record carrier is the first under the punctiform surfaces Only then layer from opaque to transparent Condition transferred when as fourth or fifth color Black is needed.

Further advantageous designs according to the invention result from the subclaims.

The invention is based on exemplary embodiments explained in more detail, which is shown in the drawing are.

It shows:

Fig. 1 is the graph showing the two states of the layer depending on different temperatures union,

Fig. 2 shows the structure of the recording medium with a temperature sensitive layer,

Fig. 3 shows the structure of the recording medium having two temperature-sensitive layers,

Fig. 4 shows the structure of a region with three point-shaped surfaces,

Fig. 5 shows the structure of an area with four punctiform surfaces and

FIG. 6 shows the graphical representation of the two states of the two layers of the recording medium according to FIG. 3 as a function of different temperatures.

Fig. 1 shows the state transitions as a function of temperature for a possible heat-sensitive layer. From the diagram it is clear that, starting from a first temperature (ambient temperature), the non-transparent state (opaque) of the material up to the temperature T 0 and the transparent state up to the temperature T 2 are maintained, with T0 at about 35 degrees C and T 2 is around +73 degrees C. Starting from the opaque state and ambient temperature, the material can be switched continuously between T 0 and T 1 to a state of maximum transparency. Starting from the transparent state and ambient temperature, the changeover to the opaque state occurs suddenly at temperature T 2 . The temperature T 1 is about 64 degrees C. This characteristic also enables the generation of any levels between opaque and transparent by an appropriate dosage of the writing energy.

To write transparent symbols in an opaque environment, the record carrier must first be converted to the opaque state. This is done by an erasing process in which the thermosensitive layer is first heated to at least the temperature T 2 and then cooled to T 0 or less than T 0 .

If the layer is then heated to a temperature between T 1 and T 2 , which is, for example, between +64 and +73 degrees C, the layer becomes transparent and maintains this state even after cooling to the ambient temperature.

The record carrier according to Fig. 2 consists of a support material T, the areas B mounted thereon and the heat-sensitive layer S. The carrier mate rial T may be either of paper or plastic or impenetrable sichtigem also made of a transparent material. In the first case, a recording medium constructed in this way can be used to reproduce color information, for example in common paper formats or as a display device which is illuminated by daylight, while the recording medium consisting of a transparent carrier material is particularly suitable for display devices which can be illuminated. The light source sits on the side of the carrier T facing away from the layer S.

On the side X of the support facing the layer S. T areas B are applied, for example through a printing or a screen printing process.

In the structure of a region B of FIG. 4 it is assumed that this is composed by three dot-like or correspondingly shaped faces F with the colors blue (B), red (r), and yellow (g). The surfaces F are arranged in a matrix, in columns S 1 to Sn and rows Z.

In FIG. 5, the structure is a range B shown consisting of four point-shaped surfaces F which red, correspond to the primary colors (r) yellow (g) blue (b) and black (s). It is also possible that green is used instead of black. In this arrangement, too, the surfaces F are arranged in a matrix, namely in columns S 1 to Sn and in rows Z.

The recording process for information consists in the fact that the layer S (see FIG. 2 or 3) is converted from the opaque to the transparent state in the area which is above a punctiform surface F by a corresponding heating. The punctiform colored surface F located under the layer S is thus visible. Depending on the desired color tone, either only one colored area F or also several colored areas F can now be made visible in the manner described within an area B. The arrangement of four colored surfaces F within a region B has the advantage that the control of the layer S (see FIG. 2 or 3) at the relevant locations is easier than with an arrangement of the surfaces F according to FIG .. 4

For the presentation of information on the recording medium according to the invention forms the Area B is the smallest imaging unit that makes up composing the picture. This means that for example wise the area B of the area with a dot matrix printer corresponds to that markable by the single needle is. Depending on the desired resolution, this can mean that the areas F have very small dimensions need to have.

In the case of a large-area display device, the requirements for the resolving power may not be so great that the punctiform areas F can also assume larger dimensions, for example of the order of a few mm ² .

The action of heat to change the optical properties of layer S according to FIG. 2 or 3 can now take place either by bundled heat radiation or also by contact heat. If the resolution is very high, ie very small punctiform areas F, only bundled thermal radiation, for example a laser beam, will be considered, while for larger punctiform areas F heating via resistors is also conceivable.

In the explanation of the arrangement of the punctiform surfaces F according to FIG. 5, it was mentioned that the basic color black can be dispensed with. To about sätzlichen playback of that color in accordance with the Anord calculations in FIG. 4 and FIG. 5 of the record carrier can according to FIG. Be constructed corresponding to 3. On an opaque carrier, a first T wärmeemp-sensitive layer S 1 is mounted on the side facing layer S X, where heat-sensitive-T between the support and the first layer S 1 is a black layer in the region X is provided. On the side of the first layer S 1 facing away from the carrier T, the areas B are applied which are covered by a second heat-sensitive layer S 2 . The reproduction of the primary colors of an area B takes place in that the second layer S 2 is brought into the transparent state at the desired locations of the areas F (not shown in FIG. 4 or 5) of the area B so that the relevant color is visible close. If, instead of one of the basic colors, the color black is desired, the first layer S 1 is transferred from the opaque to the transparent state at the relevant points by heating, so that the black color applied to the carrier T becomes visible. With this construction, it can be expedient not to apply the colors of the area B in an opaque manner, but rather by means of shine, as is also the case when the support T is transparent.

It is in the process of recording information of particular importance that within each Area B, layer S above the desired one Surface F is brought into the transparent state, d. H. that the color information of an area B is accurate are reproduced. This presupposes that warming agents, for example bundled light beam or the resistance element exactly inside an area B is positioned, because at a  Postponement there is a risk that the Erwär wrong place either none at all colored area or a colored area with a unwanted color becomes visible. For exact Positioning is therefore the record carrier T for example on its side facing away from layer S. Mark the page with appropriate markings for example correspond to rows Z and columns S. By means of appropriate optical scanning devices, which on the back of the record carrier T, d. H. on the side of the Carrier T are effective, the exact positioning controlled by the action of heat on the layer S. will.

These markings can also be applied on the side of the layer S or S 2 facing away from the carrier T, specifically such that they are not visible, for example, when illuminated with normal light, for example colors fluorescent under UV light. This applies particularly to those recording media in which the carrier T (see FIG. 2 or 3) is transparent.

If the columns S (see FIG. 4 or 5) are in the direction of movement of the recording medium or the writing device, they can be marked, for example, as solid lines. The column of each punctiform surface F does not necessarily have to be marked, but every fifth, for example. The line markings can either be attached to the edge of the record carrier, although it is also not absolutely necessary to mark each line of the punctiform areas F.

The column marker is from an appropriate one Sensor device detected and the record carrier across the direction of movement by suitable means  positioned so that the not shown Writing device is located in an area B.

An exemplary temperature behavior of the two heat-sensitive layers of the recording medium according to FIG. 3 is shown in FIG. 6. If both layers S 1 and S 2 are in the opaque state at room temperature T 0 , layer S 2 begins to become more translucent in the area of temperature T 3 due to the increasing heating of the recording medium, while layer S 1 initially still fully maintains opaque condition. As soon as the temperature T 1 is reached, the layer S 2 changes to the transparent state, while the layer S 1 still remains almost in the opaque state. If the temperature is not increased above T 1 , but the recording medium is cooled again to room temperature T 0 , the transparent state of layer S 2 and the opaque state of layer S 1 are retained, as a result of which only the colored areas B become visible, which are highlighted in white by the layer S 1 which is in the opaque state.

On the other hand, a further heating of the Aufzeich drying carrier to the temperature T 2, the layer S is also located under the layer S 2 1 so goes into the transparent state. If the temperature above T 2 is not increased further, but the recording medium cools down to room temperature T 0 again, the transparent state is maintained in both layers S 1 and S 2 . The white background of the colored areas is no longer available, ie the colors, which are transparent in themselves, appear against a black background and are therefore perceived by the eye as the color black.

In order to delete the information applied, ie to convert layer S 1 or layer S 2 to the opaque state, the recording medium must be heated to at least the temperature T 4 , which is above the temperature T 2 . After subsequent cooling to room temperature T 0 , both layers S 1 and S 2 maintain the opaque state.

Since the deletion of the recorded information, ie the conversion of both layers to the opaque state, does not have to take place independently of one another, the temperature at which both layers S 1 and S 2 are converted to the opaque state can be the same for both layers. The temperature behavior of layer S 1 and S 2 shown in FIG. 6 is only exemplary and can also be selected in a different form, it is only necessary to ensure that the transition temperature from the opaque to the transparent state for layer S 2 must be lower, than that of layer S 1 and the transition temperature from the transparent state to the opaque state of layer S 2 must be above the transition temperature from the opaque to the transparent state of layer S 1 . It must be ensured in any case that the layer S 1 can be transferred from the opaque to the transparent state without changing the transparent state of the layer S 2 to the opaque state. It is assumed that the recording of information follows that the layers S 1 and S 2 which are in the opaque state are located at those points which are above the punctiform surfaces F (see FIG. 4 or 5), be brought into the transparent state during the recording process.

A suitable device for recording information mations on the heat sensitivity described at the beginning Liche layer is described in PCT / DE90 / 00 482. On a recording device in which a  Record carrier with a heat sensitive Layer used is in PCT / DE90 / 00 484 received in detail, d. H. also that the recording medium according to the invention with the aid of recording device described there with Provide information and this according to there refined display device can be used.

Claims (10)

1. Erasable optical recording medium consisting of a carrier and a heat-sensitive layer attached thereon with optical states that can be influenced by different temperatures (for example opaque and transparent), the states being permanent in the normal ambient temperature (for example room temperature) and reversible by heating to certain temperatures, characterized in that a matrix-shaped grid of punctiform or correspondingly shaped surfaces (F) is attached to the support (T) on the side facing the layer (S). 2. Erasable optical recording medium consisting of a carrier and a heat-sensitive layer attached thereon with optical states that can be influenced by different temperatures (for example opaque and transparent), the states being permanent in the normal ambient temperature (for example room temperature) and being reversible by heating to certain temperatures, characterized in that the support (T) is colored black on the side facing the layer (S 1 ), in that on the side of the layer (S 1 ) facing away from the support (T) there is a matrix-shaped grid of transparent colored punctiform or correspondingly shaped surfaces (F) is attached and that a second heat-sensitive layer (S 2 ) is attached to the first layer (S 1 ), the temperatures for changing the optical properties of the two layers being different. 3. Erasable optical record carrier after Claim 1 or 2, characterized, that three point-shaped surfaces (F) to one Area (B) are summarized, each of the punctiform surfaces (F) a different Basic color (e.g. red, yellow, blue) having. 4. Erasable optical record carrier after Claim 1 or 2, characterized, that four point-shaped surfaces (F) to one Area (B) are summarized, each of the punctiform surfaces (F) a different  Basic color (e.g. red-yellow-blue-black) having. 5. Erasable record carrier according to claim 4, characterized, that the four punctiform surfaces (F) such are trained that alternate in one line two surfaces (F) with one each different basic color and in the alternate two areas with the adjacent line each with a different basic color are arranged, the basic colors of the surfaces (F) two adjacent rows of an area (B) are also different. 6. Erasable optical record carrier after one of claims 1, 3 to 5, characterized, that the carrier (T) itself is colored white or on the side (X) facing the layer (S) white is colored. 7. Erasable optical record carrier after one of claims 1, 3 to 5, characterized, that the carrier (T) is transparent or translucent is. 8. Erasable optical recording medium according to claim 2, characterized in that the temperature for changing the optical properties of the first layer is greater than the temperature for changing the optical properties of the second layer (S 2 ). 9. Erasable optical recording medium according to one of claims 1 to 8, characterized in that on the carrier (T) facing away from the layer (S, S 1 ) markings are attached, which the grid and the location of the colored punctiform surfaces (F ) and / or areas (B). 10. Erasable optical recording medium after Claim 3, characterized, that two punctiform surfaces (F) each Area (B) in a row next to each other and the third punctiform surface of this area in the adjacent line, in one of the two Split the other two punctiform surfaces (F) are arranged.