DE2636675A1 - Printing unit using electrosensitive paper - has two groups of electrodes in single or two parallel rows across direction of paper movement - Google Patents

Abstract

Printing unit for electrosensitive esp metallised recording paper has two groups of electrodes arranged in a single row or in two parallel rows arranged at right angles to the direction of paper movement. A control unit is used to regulate alternately the electrode groups. The control input for isolating all the electrodes of one group and the input for the second group are controlled in common via an inverter. The analogue signal corresponding to the information to be recorded is fed over an input contact to the a-d converter. For 2n-electrode groups, n-outputs are required from the a-d converter.

Description

State of the art

The invention is based on a recording device according to Genre of the main claim. Such a recording device is already out the DT-OS 2 410 569 known, in which, however, only a single group of individual, is provided in a row arranged writing electrodes. The possibility that To increase resolution in this arrangement by the electrodes and the electrode spacing are made smaller and smaller, is particularly limited by the fact that at to close arrangement (more than two electrodes per millimeter) problems in the supply lines and connections. Since each electrode is assigned an amplifier and this one Amplifier, and possibly other parts of the electronics, on a die.Elektrode Plate are arranged, also result if the electrode arrangement is too close Space problems. In addition, it is difficult with an electrode group that To arrange electrodes overlapping.

Advantages of the invention The device according to the invention with the characterizing Features of the main claim has the advantage that any good Resolution achievable through a corresponding number of rows of electrode groups is. Electrode groups with larger electrode spacing can be used, which represents a significant reduction in price compared to very fine electrode groups, as these are very expensive to manufacture as precision work. In addition arise no problems with the placement of the electrode amplifier and the others Electronics.

The measures listed in the subclaims are advantageous Further training and improvements in the main claim specified Recording device possible. A control device is particularly advantageous to be provided through which the electrode groups can be controlled alternately. this supports the good resolution of the image information or a typeface.

DRAWING Two exemplary embodiments of the invention for the electrode arrangement and an embodiment of the invention for the circuit configuration are shown in the drawing and explained in more detail in the description below. 1 shows, as a first exemplary embodiment, the arrangement of two electrode groups in a row, FIG. 2, as a second exemplary embodiment, the arrangement of two electrode groups in two rows and Figure 3 an embodiment of a circuit arrangement for Control of two groups of electrodes.

Description of the invention In the first shown in FIG Embodiment form five electrodes arranged parallel to one another in a row 10 a first group of electrodes, which is designed as a so-called electrode comb. A second electrode comb consists of five electrodes II. The electrodes of both Electrode combs 10, 11 form a certain angle to one another and are arranged in such a way that that the electrodes come to lie on one line. The electrodes are like this interlocked that each one electrode of an electrode group next to an electrode the other electrode group comes to rest. These writing electrodes 10, 11 press preferably resiliently on an electrosensitive paper 12, the direction of movement is indicated relative to the writing electrodes 10, 11 by an arrow. This electrosensitive paper 12, preferably a registration metal paper, consists usually from a carrier paper on which a black varnish and above a thin metal layer is brought. The electrode comb slides over this with ground bonded metal layer. If one of these electrodes 10, 11 is activated, as in FIG Figure 3 is explained in more detail, a current flows through this writing electrode into the metal layer on the electrosensitive paper 12. At the relevant point evaporates the metal layer and lays the underlying black lacquer layer as dark point free.

Instead of the straight electrodes 10, 11 shown, curved electrodes can also be used Electrodes are used so that the ends of electrodes of both electrode groups get to lie parallel to each other on the paper 12. The opposite The ends of both electrode groups are then again offset by an angle.

In the second embodiment shown in Figure 2 form both electrode groups 10, 11 again at an angle to one another, but their Endpoints on the paper no longer on one line, but on two, preferably parallel offset lines. This arrangement is then of Advantage if the distance between the electrodes is too small around the two electrode combs 10, 11 to be able to interlock with one another. Across the recording direction of the Paper 12 is of course again an alternating sequence of electrodes of the given one and the other comb.

For the two electrode combs shown in FIGS. 1 and 2 Further electrode combs can be added to the previous ones form a certain angle.

The circuit example shown in Figure 3 for controlling two The basic structure of the electrode combs 10, 11 corresponds to the circuit in FIG DT-OS 2 410 569. The analog one containing the information to be recorded The input signal is sent to an analog-digital converter 14 (A-D converter) via an input terminal 13. fed. In the cycle of a clock frequency, which via a second input terminal 15 to the A-D converter 14 is supplied, which converts the respective applied analog voltage into binary values converted, which are present at the binary number outputs 20 to 26 of the A-D converter. The output 20 is directly connected to a release input G1 of an electrode carrier plate 16 connected, on which the electrodes 10 are arranged and on the other hand via a Inverter 17 to a release input G1 of a further electrode carrier plate 18 connected to which the electrodes 11 are attached. The binary number outputs 2 to 2 Lt of the A-D converter 14 are at demultiplex inputs A-D of both electrode carrier plates 16 and 18 connected.

The demultiplex inputs A to D are not shown connected to corresponding inputs of demultiplexers 19. By the used 4-bit information can be operated per 16 outputs of each demultiplexer 19. To simplify matters, there are only five demultiplexer outputs with five writing electrodes each tied together. Each demultiplexer output is through an amplifier 20 with one. Writing electrode 10, 11 connected. Transistors are preferably used as the amplifier 20, whose Bases can be controlled by the demultiplexer outputs. The switching path of a such transistor connects a write electrode 30 to one in the drawing Burnout voltage source not shown in detail. The binary 6 number outputs 25 and 26 of the A-D converter 14 are connected to binary number inputs A, D of a further demultiplexer tied together.

The three outputs of the demultiplexer 21 are each with Release inputs G 2 of the demultiplexer 19 in both electrode support plates 16 and 18 are connected. Through the 2-bit information at the input of the demultiplexer 21 can per electrode carrier plate four demultiplexers 19 are controlled. For the sake of simplicity, only three are shown.

The terms O-Signal and 1 signal can be introduced. A 0 signal has a potential that is approximately ground potential corresponds to and a 1-signal has a potential that is in the order of magnitude of Supply voltage is present.

After each clock pulse at terminal 15, as already described, the analog signal applied to terminal 13 at the output of the A-D converter 14 converted to a binary word. This binary word gives three pieces of information. Of the Alternatively, output 20 selects one of the two electrode carrier plates. Is on Output 20 has a 1-signal, this 1-signal blocks all of them via the release input G1 Electrodes or demultiplexer 19, the electrode carrier plate 16. Simultaneously lies Via the inverter 17, a zero signal at the release input G1, which the electrode carrier plates 18 receptive to input signals. If the signal at output 20 changes to one Zero signal, the situation is reversed. Through this reciprocal control a very fine resolution is achieved due to the offset electrode combs.

Through the outputs 25 and 26 of the A / D converter 14, on each electrode support plate 16, 18 one demultiplexer 19 enabled, the others disabled. So there is the Selection of a demultiplexer that can output a signal, provided that the input G1 the corresponding electrode carrier plate at the same time has a release signal.

Which special electrode of the selected demultiplexer 19 now The demultiplexer is informed by the outputs 21 that it is actually to be operated to 24 of the A-D converter 14. With each clock pulse at terminal 15, a Electrode controlled, namely alternately one electrode of one electrode carrier plate 16 and the other electrode carrier plate 18.

If the burning time of an individual electrode is to be limited, then in a manner known per se, the output 20 of the A-D converter 14 also has a timing element be connected downstream.

If the two electrode combs 10, 11 are offset from one another, as in FIG Figure 2 is described, a compensation for this offset must be found, if the analog signal at input 13 relates to a writing line. Possible Devices for this purpose are known. So either can input any of those Electrode plate, which is arranged set back with respect to the writing direction, a time delay element can be connected upstream, which the information about the Delays the time it takes for the writing paper to move from an electrode Kanim to return to the next electrode comb. Preferably for this time Delay also a shift register can be used, in which the output information of the A-D converter 14 read in parallel and then shifted with a clock frequency can be. After a certain number of bars corresponding to the time, which the writing paper needs to cover the distance between the two electrode combs 10, 11, the information is back in parallel to the relocated Electrode carrier plate read out.

If the number of electrode carrier plates increases, so must increase the number of outputs of the D / A converter 14, which are used to select the electrode support plates are provided. Outputs are required for Zn electrode groups. the mutual Control of the electrode carrier plates or

the electrode comb is especially required when contiguous Lines should be written across the direction of movement of the paper.

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Claims (9)

Claims 1. Device for recording image information using electrosensitive paper, in particular on metal recording paper a group of individual writing electrodes arranged in a row that electrically are isolated from each other and controlled via controllable switches, thereby characterized in that at least one further group (11) of arranged in a row Writing electrodes of the first group (10) is assigned, the writing electrode groups (lo, 11) are arranged offset from one another perpendicular to the recording direction, so that electrodes of one group are effective at electrode intervals of the other group will. 2. Device according to As claim 1, characterized in that all electrode groups (10, 11) are arranged in a row. 3. Apparatus according to claim 1, characterized in that each Electrode group (10, 11) forms its own row. 4. Apparatus according to claim 3, characterized in that electronic Means are provided through which the signals for the relative to the recording direction set back electrode rows (10) are delayed. 5. Apparatus according to claim 4, characterized in that this electronic means are time delay elements. 6. Apparatus according to claim 4, characterized in that this Electronic means are storage devices, in particular shift registers. 7. Device according to one of the preceding claims, characterized in that that a control device (17) is provided through which the electrode group reciprocally are controllable. 8. Apparatus according to claim 7, characterized in that at two Electrode groups (10, l1) the control input (G1) for blocking all electrodes one group (10) directly and the corresponding control input (Gl) the second Group (II) can be controlled jointly via an inverter (17). 9. Apparatus according to claim 7 or 8, characterized in that when controlling 2n electrode groups by an analog-digital converter (14) n-Bit (outputs) of the A-D converter (14) for alternating control of the electrode groups are provided.