DE1549911B1 - PRINTING DEVICE WITH INDIVIDUALLY CONTROLLED PRESSURE ELEMENTS ARRANGED IN A MATRIX-WAY ON A ROTATING DRUM - Google Patents

Description

In a known printing device, the one for controlling the input of the lagging time As indicated, the printing elements consist of data inputted to one another in the memory array electrically conductive electrodes, which are arranged in this way.

are net that by energizing appropriate electrical In the printing device according to the invention

the digits 0 to 9 on a tension-sensitive, the input of the data can be generated on a single borrowed piece of paper. The 15 slip ring to generate. The control circuits and the electrode groups storage arrangement used in the drum, which are accommodated in the drum and run in rows and columns on the drum, ensure that the drum is brought up. The control of the individual print data then to the intended print element groups takes place via slip rings, each of which is long. The printing elements can be excited in such a way that corresponding electrodes of the printing element groups ao are connected to one another in the corresponding columns in a column. If a first digit of different types is to be recorded on different lines, they will be generated. So even if the transfer of the corresponding electrodes of a printing element character to the recording material ratio group is applied, which at the same time takes a moderately long time, electrodes of all printing element groups can be used with high printing speed, since a larger drum pen in a column over the slip rings at tension speed by a larger wrap around. In this way, however, the pressure elements of all angles of movement of the recording material around the groups of a column can be compensated again in the same way, ie towards the drum, so that generation of the same digit is excited. The required contact time between the printing material may therefore only be brought into contact with the element group of a line containing the printing elements and the recording medium. The printing formed according to the invention, otherwise the same in several lines at the same time
Digit would be recorded. Since the process of creating the recording on the recording material takes a certain amount of time, 35
linger the drum in the place where
the contact of the printing elements with the recording material takes place. The printing device must
therefore necessarily work slowly; this is at

the known device also thereby takes into account many sliding contacts reliably, Sights that the drum drive is a slow one. An embodiment of the invention is in the

Stepper is used.

Further, in the known printing apparatus, the number corresponds to that used in each column Slip rings the number of printing elements that make up a matrix. If one more differentiated representation of the characters to be printed is sought, the number of slip rings per Matrix and thus per column can be increased considerably. Of course, this also applies to an enlargement the number of characters printed per line. There is an increase in the number of slip rings without changing the character width and the character spacing is only possible to a very limited extent, are also

the application of the known printing device to 55 mix printing elements of FIG. 4, the printing of any characters narrow limits. The known printing apparatus is therefore only processing of the heating circuit of the thermal print elements for recording a few characters, on beispiels- _V F i g. 4 and

wise the ten digits in a line suitable, they F i g. 7 is a schematic representation of the logical

but cannot easily print long 60 lines and create another output line in terms of circuitry from any number of different characters guiding form of the printing device used according to the invention will. manure.

The aim of the invention is to provide a thermal. According to the drawings

Printing device of the type specified above, the printing device 10 from a cylindrical drum a very small number of slip rings the 65 mel 12 that print on a rotating shaft 14 is brought to a large number of different types. The shaft and the drum will be Characters embodied in long lines at high operating speed by suitable motor 16 age made possible. Facilities at a set speed

device is therefore ideally suited for high-speed printers, such as those used as output devices in Data processing systems are used.

Although only a few data and clock slip rings are required in the printing device according to the invention long lines of any characters can be printed. The device is accordingly versatile and by avoidance

Drawing shown; it shows

F i g. 1 is a perspective view of a printing device according to the invention,

FIG. 2 is a simplified illustration of a cross section along the line 2-2 of FIG. 1,

F i g. 3 is a schematic representation of the logic and circuit structure of the printing device of Fig. 1,

F i g. 4 shows a simplified perspective illustration of thermal printing elements arranged like a matrix, as they are in the printing device from F i g. 1 can be used, Fig. 5 shows a simplified section through the thermal

turned. As shown in Figure 2, a piece of heat sensitive paper 18 is wrapped around the cylinder 12 guided around during its rotation and stands with the surface of the circumference over a Sector area of about 180 ° in contact. The paper 18 can either consist of a continuous Paper web or series of sheets are made which are handled by suitable known means will.

The particular embodiment of the printhead described is capable of printing lines of alphanumeric characters. This is carried out with fifty thermal print heads P ₁ to P ₅₀ , which are distributed along the drum and at equal intervals over the circumference of the drum. Each of the fifty print heads P ₁ to P ₅₀ comprises one hundred and twenty matrices of alphanumeric characters C ₁ to C ₁₂₀ (see Fig. 3), and each of the matrices of the characters consists in turn of twenty-five individually controllable point heat sources 20. In the schematic representation of the logical structure according to FIG. 3 are the matrices of the characters C ₁ to C _{20 of} the print head P ₁ with P ₁ C ₁ to P ₁ C ₁₂₀ , the matrices of the characters of the print head P ₂ with P ₂ C ₁ to P ₂ C ₁₂ O ^and the matrices of the Character "of the print head P ₅₀ is denoted by P ₅₀ C ₁ to P ₅₀ C _120. Thus, each of the print heads P ₁ to P _{50 has} three thousand individually controllable point heat sources 20.

Each point-shaped heat source 20 can consist of a body of semiconductor material 54 (see FIG. 5) which is coated with a layer 57 of silicon carbide. The silicon carbide surface layer 57 is in direct contact with the paper 18 and represents a surface which is very resistant to wear. Each of the point-shaped heat sources 20 is heated by a heating circuit 56 according to FIG. 6, the individual components of which are built up within the semiconductor body 54 by diffusion or other conventional techniques. The heating circuit 56 consists of transistors 58 and 60, collector resistors 62 and 64, which are connected to one another in a known manner, as shown. The base 66 of the transistor 58 is the control input of the heating circuit. If a logical "0", ie 0.0 volts, is applied to the base 66 , the heating circuit is switched off. When a positive voltage, represented by a logical "1", is applied to the base 66 ^ the transistors 58 and 60 are conductive and the current flowing through the transistors and the collector resistors heats the entire semiconductor body 54 and the overlying silicon carbide layer 57 on. The lines connecting the transistors and resistors of the heating circuit 56 as well as the input lines and the voltage supply lines for the various heating circuits of the matrix can be formed on oxide layers 70 and 74 in the form of layers 68 and 72 representing first and second lines. Layers representing third and fourth lines can of course be used if necessary. This structure described so far is on a ceramic support 76 by means of a suitable binder, for. B. an epoxy resin, attached. The lines of the various heating circuits 56 can then over the edges of the ceramic carrier 76 down, as in FIG. 4 denoted by the reference numeral 80, run. The respective adjacent matrices of the characters, e.g. B. the dies P ₁ C ₁ and P ₁ C ₂ can be separated from one another by profile strips 82 consisting of semiconductor bodies 84 and coated with silicon carbide layers 57. The in the F i g. 4, 5 and 6 can be manufactured in such a way that depressions are first etched into the surface of a semiconductor body in order to produce mesas corresponding to the semiconductor bodies 54 and 84. This can be done with the help of the usual photolithographic etching technique. The silicon carbide layer 57 is then applied over the surface of the mesas and the depressions. This can be done in that, for. B. the vapors of toluene (C ₇ H ₈ ) and silicon tetrachloride (SiCl ₄ ) with gaseous hydrogen is used as a carrier. These gases, in a typical mixture of about 0.87 mole percent silicon carbide, 0.18 mole percent toluene and the remaining percentage hydrogen, are passed over the carrier, which is placed in a suitable heating furnace and maintained at a temperature of about 1080 ° C . A hydrogen reduction, ζ. B. of silicon tetrachloride, a layer of polycrystalline or amorphous silicon is deposited over the surface of the silicon carbide layer. This layer is not shown in the drawing since it is only used to increase the strength of the structural structure during the manufacturing process and is then removed again. The surface of the semiconductor starting material on the side opposite the body 54 is then removed again from the silicon carbide layer 57 previously formed in the depressions by lapping and polishing. As a result, the semiconductor bodies 54, which consist of a single crystal, are obtained as islands on a surface of the amorphous silicon body. The silicon islands are isolated from the amorphous silicon body by the silicon carbide layer 57. The silicon carbide layer 57 serves on the one hand to limit the depth during lapping and polishing and on the other hand ensures that the semiconductor bodies 54 are of the same thickness and thus ensure a uniform heating and cooling rate for all point heat sources.

The transistors and resistors can then be placed on the exposed surface of the semiconductor body 54 can be manufactured using any standardized fabrication techniques. The same applies to the various line structures which are in one or more layers on the surface of the carrier. This assembly is then turned over and placed on the ceramic support 76 using a connection or. Adhesive layer 78 mounted. The amorphous silicon layer is then broken through by the silicon carbide layer Etching removed, for which a mixture of hydrofluoric acid, nitric acid and acetylic acid are used can. During this process step, the silicon carbide layer 57 serves as an etching barrier for Protect the underlying silicon body 54 and allow the amorphous silicon out of the recesses is etched away between the various point heat sources.

According to FIG. 3, fifty shift registers DSR ₁ to DSR _{50 are provided} for the fifty print heads P ₁ to P ₅₀ . In the interests of maximum

Slip ring 26 applied clock pulses synchronized. This means that the data signal is either a logical "0" or a logical "1" during each the three thousand clock pulses depending on 5 the applied binary value. The successive Bits of a data signal are applied to and through one end of the shift register the remaining positions of the register moved. After the three thousandth clock pulse it is up to everyone

transform characters in such a way that the limited number of characters is generated.

The shift registers DSR ₁ to DSR _S0 are preferably located in the vicinity of the print heads P ₁ to P _{50 in} accordance with the procedure shown in FIG. 2 arranged manner shown. The shift registers DSR ₁ to DSR ₅₀ can be manufactured as integrated circuits that have approximately the same volume as the print heads

Versatility, each shift register has a storage capacity of three thousand bits, with each bit
with one of the point heat sources 20 to
whose control is connected. The shift registers
represent serial-parallel converters for the data,
in the form that three thousand bits of binary data are in
Series can be fed into each register.
The three thousand bits of data are stored in the shift registers and in three thousand parallel
Outputs for the control of corresponding point-like- io the three thousand places of the shift register are formed by an entger heat source. As long as only alpha-speaking output signal, and this output numerical information through the device 10 signals are to be printed in parallel to the control of the three thousand, punctiform heat sources have to be emitted through each matrix, the characters only thirty or forty characters until a new data signal is in the Shift register can be printed one character. In this case the 15 can be fed.

Number of bits in the shift registers DSR for each The electrical power for the circuits is

Characters from twenty-five to approximately fed through slip rings 30 and 32. It's self six be reduced if an appropriate understandable that in place of the two slip rings Decryption circuitry is provided to use any number of such rings six-digit binary code to control the point-ao can be found if this is due to the different shaped heat sources of the matrix of the font required voltage levels is required.

Two discs 34 and 36 for timing control are provided on the shaft 14 to the position and the Speed of the in F i g. 1 drum 12 shown to be scanned. Around the circumference of the disk 34 fifty permanent magnets are distributed, the fifty pulses in the scanning head 38 during one revolution the drum 12 generate. The magnets are preferably arranged in such a way that their position

Take P ₁ to P ₅₀ . However, it should be noted that the respective position of the print heads P ₁ to P ₅₀ corresponds to the fact that within the drum for the sliding die, ring counters and control gates are excited by the disk 34 in the scanning head 38, there is more volume of Ifl kd Shi

lumen can be consumed if necessary is.

Through the outputs of the fifty bits O ₁ to ₅₀
of a ring counter RC become fifty one after the other
Data gates DG ₁ to OG ₅₀ and fifty clock gates
CG ₁ to CG ₅₀ actuated. The ring counter RC will
controlled by a slow clock pulse train,
which to 40 determine the position of the drum 12 via the slip ring 22 on the shaft 14; is also performed, which in Fig. 1 and 3 with the same is identified by this pulse and the pulses from the reference number. The frequency of the gear 24 of the operation of the ring counter RC with the slow clock pulse train is equal to the number of the rotation of the drum synchronized. Thus, shift registers DSR times the rotational speed of the magnet and the scanning head can be attached to the drum 12. Thus, the slow clock 45 has to be such that a pulse is produced when the pulse train is at a speed of the drum of printing head P ₁ in the position shown in FIG. 2 position shown is fifty revolutions per second a frequency and thus z. B. indicates that bit b _{1 of} the ring of 2500 pulses per second. For the purpose of the counter should have a logical "1" as output, synchronization can make the output signal of the last to the gates DG ₁ and CG ₁ , as in the following with bits b _{50 of} the ring counter written in 50 via the slip ring 24, ready for operation to be fed. The output signals of the bits O ₁ to The printing device 10 is

b _{K0 of} the ring counter RC actuate the interlocking stage 42 adapted to the data source 44 one after the other. The input data gates DG ₁ to DG _S0 and the high data source can be any high speed clock gate CG ₁ to CG ₅₀ . memory, computer or other data

A high speed clock signal will be passed to the 55 processing system. The intermediate stage rotating drum and then at an input 42 converts the data from the data source 44 and via which each clock gate CG ₁ to CG ₅₀ brings them into a slip ring 26 for the operation of the printing device. The frequency of the high-level 10 suitable digital form. In addition, the speed clock signal is at least equal to the data from the intermediate stage with the operation is synchronized with the product of the total number of storage locations 60 of the printing device. The design in the fifty shift registers DSR ₁ to DSR ₅₀ and and the structure of the intermediate stage can be very different from the rotational speed of the drum 12 plus one and depend on the type of small marginal portion that controls the operation of the control data from the source to be delivered. Their logic, as will be described later, facilitates. The primary function consists in providing the input data to the inputs of the data 65 binary gates DG ₁ to DG ^ ₀ to be reproduced by the print heads via the slip ring 28 train data for the respective print head. The input data are binary as a serial sequence if this is arranged in the data input sector 50 (see FIG. 2) and is passed through with the over the. To this end, the intermediate stage

sired pulse sequence can be used either for synchronization or for the derivation of the clock pulses a low speed, the RC of the ring counter are used for the operation, ₅₀ 35th A single magnet may be provided on disk 36 to produce a single pulse in scanning head 40 during each revolution of drum 12. This pulse is used as a reference pulse to

control the rotation of the drum through a conduit 46 extending to the motor 16. In this way, the intermediate stage provides a data input signal in the form of three thousand bits that are serially ordered and synchronized with three thousand clock pulses within the desired interval. It also ensures that the operation of the ring counter is synchronized with the rotation of the drum so that the control gates DG _n and CG _{n are made operational} at the correct moment.

For the operation of the printing device 10 , the drum 12 rotates at a certain constant speed, e.g. B. at 50 revolutions per second. The ring counter RC then works at a speed of 2500 counts per second. The counting of the ring counter RC is synchronized with the position of the drum 12 , so that the output from bit b ₁ makes the gates DG ₁ and CG ₁ functional for a period of time during which the print head P ₁ passes through the data input sector 50, which is not greater than one fiftieth of a turn. Then, when the print heads P ₂ , P ₃ , etc. successively pass through the data input sector 50, the gates DG ₂ and CG ₂ , DG ₃ and CG ₃ , etc. are successively activated by the output signals of bits b _o , b ₃ , etc. of the ring counter RC made functional.

Simultaneously with the establishment of the operational readiness of the gates DG ₁ and CG ₁ , three thousand bits of sequentially ordered binary data are introduced via the slip rings 26 and 28 in the form of a data signal synchronized with three thousand clock pulses. The serially ordered data are then stored in the shift register DSR ₁ and converted into data arranged in parallel in order to simultaneously control the three thousand point heat sources 20 of the print head P ₁ and the desired character within the matrices of the one hundred and twenty characters P ₁ C ₁ to P ₁ C ₁₂₀ to build. With the continuous rotation of the drum 12 , the registers DSR ₂ to DSR ₅₀ are acted upon one after the other as they pass through the data input sector 50. During the period in which the individual printhead is rotated further from the data input sector 50 up to the contact with the paper 18, the excited point-shaped heat sources 20 have sufficient time to warm up, whereas the non-excited point-shaped heat sources can cool down during this time . The print heads P ₁ to P ₅₀ come into contact with the paper 18 one after the other and maintain contact with the specified positions on the paper for approximately a portion of rotation of the drum and the paper of 180 °. The process then repeats itself again.

It should be noted that using fifty printheads and one drum speed two thousand five hundred lines per second are printed at fifty revolutions per second, each line containing one hundred and twenty characters. Of course, these values can go through a change in the number of print heads or the rotational speed of the drum increases or can be reduced in size. The specific number of print heads and the specific speed of rotation of the Drum was only given as an example, and the ones needed to achieve this speed are also included prior art components described.

The speed with which the input data are fed to the various shift registers DSR ₁ to DSR ₅₀ is quite high and in the particular embodiment described is 7.5 million bits per second. Thus, the shift register DSR _{n has} to operate at a fairly high frequency. A modified embodiment of the invention, in which the frequency of the input data is lower, is shown in FIG. 7 and is provided with the reference symbol 100 . The printing device 100 is very similar to the printing device 10 and therefore corresponding parts are given corresponding reference numerals. The printing device 100 differs from the printing device 10 in that

that in principle five shift registers, each with a capacity of six hundred bits, are assigned to each of the fifty print heads instead of the one shift register with a capacity of three thousand bits. This controls the shift registers DSR _{1 a} to DSR ₁₀

the individual spot-shaped heat sources of the print head P _1, the shift register DSR DSR _2a to _2e, the individual spot-shaped heat sources of the print head P _2, etc. The shift registers DSR DSR _{ie la} to be "at the same time via the slip rings 102

to 106 and the data gates DG _la to DG ₁₀ acted upon when the data gates are brought into a functional state by an output signal from bit O _{1 of} the ring counter RC. In the same way, the shift registers DSR ₂₀ to DSR _{2e are} simultaneously via the

Gates DG ₂₀ to DG _2e activated when bit b _{2 of} the ring counter RC has a logical "1" as the output. The clock gate CG ₁ scans the clock pulse train of all five shift registers DSR _1n to DSR _le . In a corresponding manner, the clock gate CG ₂ scans the

Clock pulse train of the shift register D5i? _{2a to} D5i? _2e and so on.

The mode of operation of the printing device 100 is identical to that of the printing device 10 , except for the fact that the series-ordered

Input data for each of the five shift registers of each print head can be entered simultaneously, ie in parallel. This takes place via five separate slip rings and control gates, so that the speed at which the data is entered into the individual storage devices, and thus the speed at which the shift registers have to work, is reduced to a fifth. It will be apparent that the number of shift registers for each print head can be increased or decreased in order to correspondingly decrease or increase the speed at which the data is serially entered into each shift register. In the case of the printing device 100 , the data is

Speed of 1.5 million bits per second, in contrast to 7.5 million bits per second for the printing unit 10, entered.

Although the described embodiment of the invention is particularly applied to the printing of lines with one hundred and twenty alphanumeric characters can of course be of any type of data can be printed in accordance with the general applicability of the invention. So can e.g. B. represent the entire surface of the drum a single matrix of point heat sources. The matrix can conveniently be divided into two or more sections, each Section one or more shift registers assigned

109 549/433

can be net. The shift registers of the section by section subdivided matrix are applied successively during the part of the revolution while the sections assigned to the matrix do not touch the paper. In fact, a variety will 5 of shift registers used to control each section of a matrix, the shift register can be applied in parallel.

In the above detailed description of the invention, an extremely fast printer was used wrote. The printing device adapts to high speed data processing systems and can be used together with these as an output system. The printing device can also be used as a Reproducing apparatus can be used for high speed facsimile devices. The described Facility has z. B. a sufficiently high speed to the successive images one conventional television broadcast.

Claims (13)

Patent claims: 1. Printing device for making recordings on a recording material with a rotating drum with individually controllable pressure elements on its outer surface are attached like a matrix, dadujrch, that in the drum a storage arrangement rotating with this is housed, the inputs for the input of Data supplied one after the other and outputs permanently assigned to the individual printing elements comprises that the printing elements in accordance with the output signals of the memory arrangement are excitable, and that within the drum with this revolving control circuits for the control of the input of the data entered one after the other into the memory arrangement are housed. 2. Printing device according to claim 1, characterized in that the pressure elements are heating elements which interact with a heat-sensitive recording medium. 3. Printing device according to claim 1 or 2, characterized in that from the printing elements The matrices formed are subdivided into groups, so that each matrix group has a memory arrangement is assigned and that the control circuits are designed so that they the inputted data to the memory devices feed in sequence during a fraction of the rotation of the drum. 4. Printing device according to claim 3, characterized in that the matrices in parallel to Lines lying on the drum axis are arranged and that each group contains the matrices of one line includes. 5. Printing device according to claim 3 or 4, characterized in that each memory arrangement has an input for entering the data that a slip ring for the drum on the drum Input of the data is arranged and that the control circuits in the successive Fractions of the drum rotation each have the input of a storage arrangement with the Connect slip ring. 6. Printing device according to claim 3 or 4, characterized in that each memory arrangement is divided into several parallel partial memories, each of which has an input for input the data has so many slip rings on the drum for the parallel input of data are arranged as sub-memories are present in each memory array, and that the Control circuits in the successive fractions of the drum revolution in each case the Connect inputs of the partial memory of a memory arrangement in parallel with the slip rings. 7. Printing device according to claim 5 or 6, characterized in that the control circuits contain a gate for each memory input, the output of which with the corresponding Memory input and its signal input is connected to a slip ring, as well as a synchronization circuit, which has an output for each memory arrangement that connects to the control input of the gate or the control inputs all gates of the memory arrangement in question is connected, and that the synchronization circuit in successive fractions of the drum revolution at their outputs one after the other an opening signal for the Gates releases. 8. Printing device according to claim 7, characterized in that the synchronizing circuit is a ring counter, the number of stages is equal to the number of memory arrangements and the Progress input is connected to the output of a slow clock pulse generator, the delivers slow clock pulses with a repetition rate equal to the number of drum revolutions per second multiplied by the number of memory arrays. 9. Printing device according to claim 8, characterized in that a position pulse generator with the drum for the synchronization of the slow clock pulse generator is connected. 10. Printing device according to one of claims 3 to 9, characterized in that each memory arrangement or each partial memory is formed by a shift register and that a faster clock pulse generator is provided, which the incremental inputs of the shift register fast clock pulses with a repetition frequency at least equal to the frequency of the slow clock pulses multiplied by the number of stages of each shift register. 11. Printing device according to one of claims 7 to 9, and according to claim 10, characterized characterized in that a clock pulse gate is provided for each memory arrangement, the output of which with the incremental input of the memory arrangement or the incremental inputs of all Part of the memory of the memory arrangement is connected, the signal input of which is connected to the output of the fast clock pulse generator is connected and its control input with the relevant Output of the synchronization circuit is connected. 12. Printing device according to one of claims 3 to 11, characterized in that each storage arrangement for each print element matrix has as many outputs as print elements are present in the matrix, and that each memory output is connected to a printing element is. 13. Printing device according to one of claims 3 to 11, characterized in that each memory arrangement for each printing element matrix one for identifying the one to be reproduced Character has a sufficient number of outputs that match the inputs of a decryption circuit are connected, to whose outputs the pressure elements are connected. For this purpose 4 sheets of drawings