DE3631080A1 - Method for producing a printed image of high resolution on an information carrier by thermography or thermal transfer printing, and device for this purpose - Google Patents

Abstract

The invention relates to a method for producing a printed image on an information carrier by thermography or thermal transfer printing by means of a printing board which has electrically actuable, thermally sensitive printing points arranged along a line for parallel printing of an image line. A non-printing gap is produced between two adjacent printing points, the number of printing points constituting at most half of the number of image points required for an image line and, to fill in the image line between the image points of two printing points, the printing board at least once carrying out a translatory movement by the width of the printing point from a starting position into an end position with the information carrier remaining in the same position, and one and the same printing point thus producing at least two image points of the image line. The printing board has a number of printing points constituting at most half of the number of image points required for one image line, the printing board being mounted so that it can carry out a translatory movement to fill in the image line between the image points of two printing points, and the smallest length of the movement of the printing board for printing two adjacent image points being at least equal to the width of one printing point. <IMAGE>

Description

The invention relates to a method for producing a high-quality printed image Resolution on an information carrier in thermal printing or Thermal transfer printing according to the preamble of claim 1; the invention also relates to a device for carrying out the Procedure.

Thermal printing boards are used in a variety of printers today Thermal transfer printing or thermal printing for various purposes used because such printers due to their non-impact Printing technology are extremely quiet. The former method requires one Foil, which carries the dye to be transferred, when heated locally melts, using plain paper in this process can; the second requires the use of thermal paper.

Such thermal printing boards, which preferably print in parallel, have electrically heatable pressure points or resistors that normally are arranged in a line parallel to the longitudinal axis of the printing plate, the peculiarity is that all pressure points are parallel or can be energized in groups of a line.

Known thermal printing boards in thin film technology can today up to 16 Have pressure points per millimeter in the line of the pressure points. The Manufacturing elements using thin-film technology is complex and expensive, which is why if possible manufactured in thick film technology Thermal printing boards are used, but less Pressure points per millimeter can be achieved.

The density of the individual pressure points of a pressure line to achieve a brilliant print image, as it is especially in the graphics or automatic character recognition is necessary today costly, on the other hand in the printing width due to the application known methods limited. As described above, however, are the Limits on increasing the density of pressure points.

The invention is therefore based on the object of a method of to create the type mentioned at the beginning, with which the density of the individual pixels to be printed on the information carrier up to high Resolution - related to different types of printing boards too variable - can be increased so that on the one hand a pin sharp Print image is the result and on the other hand, despite the high resolution Line up several printing boards to achieve large ones Print widths is possible.  

According to the invention, this object is achieved in the process of Claim 1. An apparatus for performing the method is according to the invention in claim 8, a thermal printing board for use characterized in the device in claim 9. Other configurations the invention are characterized in the remaining claims.

The inventive method has the salient advantage that with this a print image of extremely high resolution in Thermal transfer printing or thermal printing can be generated, whereby a highly brilliant print image is achieved, which is especially for the Graphic printing, for printing characters for automatic character recognition and is suitable for printing at a relatively high writing speed. A The disadvantage of the method and the device according to the invention could compared to a printing board that has all the printing dots in the printing line has, theoretically, be seen in the fact that such a printing plate is slower. This theoretical advantage of known printing boards can however practically in the known boards for thermal reasons and are not used for reasons of circuit design, which is why the Pressure points of such printing boards with high resolution of the state of the Technology can be controlled in groups. Therefore, the invention Print board connected at least as quickly as known print boards but with the decisive advantage that the invention Printing board with considerably less control electronics and is cheaper to manufacture.

Advantageously, the printing plate for printing between two adjacent printing dots - and thus with respect to the information carrier for printing two immediately adjacent pixels for filling the image line - is moved translationally in the direction of the line of the printing dots. The smallest length of movement of the printing plate, based on the width of a pixel in the image line, is a maximum of the width w of a printing dot in the direction of the line. The movement of the printing plate can now take place step by step or continuously, because the energization of a pressure point can only be a fraction of the movement time of the printing plate. If the movement takes place continuously, the smallest length of the movement of the printing plate is understood to mean the smallest displacement which has to be covered for printing two immediately successive image points, which usually corresponds to the width w of a pressure point. If the movement takes place step by step, the smallest length of the movement of the printing plate is just a step length of the width w of a pressure point.

The width v of the non-printing space between two adjacent pressure points is z. B. equal to three times the width w of a printing point, so that the printing plate for printing the space between one printing point to the next must be moved by a total of four smallest lengths or four steps in the direction of the line, the rest position of the printing plate being counted as the first step.

According to the invention, two movements are thus advantageous superimposed, namely the movement of the printing plate and that of Information carrier for which a common or a separate one Drive is present. Both movements are synchronized with each other or can be set independently of one another in speed. Each after coordinating the two movements, all can be Master printing modes: graphic printing and fine writing or Correspondence and design printing. Advantageously, with the Invention the width and / or the height of a printed image, for example a letter, can be varied arbitrarily, the height of which over the Control of the feed increments by means of a variable feed is varied. The printer according to the invention can thus between one high print speed with low print quality and lower Continuously adjustable print speed with high-resolution print image will. A certain quality of the printed image is therefore a certain one Dissolution and / or a certain feed or both at the same time assigned. The high speed is u. a. a consequence of the fact that can be printed while the information carrier is being fed, the printer can also be operated in start-stop mode.

Another advantage of the invention is that now such Printing boards can be lined up in a row, which at Printing boards with high resolution of the prior art are not possible is. Since there is a non-printing space between two pressure points is present can be abutting, inventive Printing boards are easily manufactured and adjusted so that between the last pressure point of the previous printing plate and the first Print point of the following just the distance of the non-printing Space is maintained.

If one looks together at the level of the printing plate and the level of the information carrier, the printing point together with the non-printing space spans a matrix of fields to be printed up to the next printing point. Thus, each print point within the line creates a majority of pixels within the image line corresponding to the number of steps on the print board. This majority is generally formed by the quotient of the (center) distance between two pressure points divided by the width of a pressure point in the direction of the line. If the printing plate moves translationally from the first to the nth position and if one or the same pressure point is energized after or with each step, all the pixels falling in the non-printing space between two adjacent pressure points, including the first pixel of the pressure point, are shown in the same image line generated in the initial position of the printing plate.

When the printing plate moves translationally back and forth from the first to the nth step and vice versa, preferably with pulsed energization of the printing point, the printing plate is thus related to the information carrier which is advanced by a feed increment or a fraction thereof for printing the next image line , moved in the form of a small meander. With regard to the information carrier, a meandering fine line is printed as the print image of one and the same printing point, which leads to complete printing of the information carrier. The pixels of successive image lines are thus printed in opposite directions.

It is also possible to print the printed circuit board after a continuous or gradual translational movement from the initial position to the End position and preferably continuous pulsed energization the pressure point without performing an intermediate pressure from the End position to move back to the start position to the Print the next image line after feeding the Information carrier in turn in the same direction to move the end position and so on. Regarding the Information carriers are printed as one and the same Pressure point fine consecutive lines in the same direction printed, which also leads to a complete printing of the Information carrier leads.

Advantageously, the smallest length of movement of the Printing board or the stride length of the same and the feed length of the Information carrier to be coordinated with each other so that the Pixels by a fraction of the width and / or by a fraction of the Overlap length of pressure point.  

The inventive device for performing the method with There are a number of printing boards located within a printing station of pressure points, which advantageously at most half of the required pixels for a picture line, whereby between each two adjacent pressure points with a non-printing space at least the width of a pressure point in the direction of the line of the Pressure points is arranged and to fill the image line between the Pixels of two adjacent pressure points the printing board in the direction its longitudinal axis or the line of the pressure points can be moved in translation is held, the smallest length of movement of the printing plate for printing two immediately adjacent pixels at least is equal to the width of a pressure point in the direction of the line.

The pressure points can be equidistant from each other, whereby the non-printing space between two neighboring ones Pressure points at least one time the width of the pressure point in Direction of the line is. The non-printing space between two adjacent pressure points can be a whole multiple of the width of the Pressure point in the direction of the line of the pressure points or reduced by be a fraction of the width of the pressure point.

The width of the non-printing space between two neighboring pressure points may be smaller than the width of the pressure point be, whereby the generated from one and the same pressure point adjacent pixels overlap. Likewise, the Stride length of the crotch of the printing board smaller than the width of one Pressure point in the direction of the line, whereby the of one and the same pressure point created side by side Pixels also overlap.

In an advantageous manner, the distance between two pressure points from one another can also be approximately smaller than a whole multiple of the width w of a pressure point. If the printing plate is then moved in translation with the step length of the width w of the printing point, the pixels overlap, which ensures complete blackening of the space between two pixels. The mathematical relationship for the length v of the non-printing space is:

v = w · (n - Δ )

where n is the number of steps of the printing plate, w is the width of the pressure point and Δ is a fraction of the width w of the pressure point.

Or the step length per step of the printing plate is less than the width w of a printing dot, which also results in an overlap of the pixels within the non-printing space between two printing dots.

The interaction of the different levels of the printing plate and the information carrier is shown in the following example, the length of the non-printing space between two printing points being three times the width w of a printing point and thus the printing plate in four steps of the step length of the width w of a printing point in the direction of Line is moved to print all the pixels of the same image line between two adjacent printing dots. To print the next line, after the information carrier has been fed by one feed increment or one feed step thereof, the printing plate is moved back in the direction of the line in four steps of the step length of the width w of a printing point in order to print all the pixels of the following line.

This printing process is explained using the matrix shown below:

For example, the entire lines a and b should be printed:

The information carrier is in the starting position, feed p = 1, image line 1:

Heating pressure points 1 , 2 , 3 . . . m :
- Movement of the printing plate step 1: fields a 1, a 5, a 9,. . . a (m) printed - step 2: fields a 2, a 6, a 10,. . . a (m +1) printed - step 3: fields a 3, a 7, a 11,. . . a (m +2) printed - step 4: fields a 4, a 8, a 12,. . . a (m +3) printed

The entire line a is thus printed.

The information carrier is moved by a feed increment, feed p = 2, image line 2:

Heating the pressure points 1 , 2 , 3 ,. . . m :
- Step 4: fields b 4, b 8, b 12,. . . b (m +3) printed - step 3: fields b 3, b 7, b 11,. . . b (m +2) printed - step 2: fields b 2, b 6, b 10,. . . b (m +1) printed - step 1: fields b 1, b 5, b 9,. . . b (m) printed

When all the steps of the printing board are carried out between each feed , the matrix is continuously printed in opposite directions.  

Will the print board be printed after printing an image line and feeding the Information carrier from its end position without printing in the Initial position moved back and then translationally back into the End position and so on and thus the pixels are consecutive Image lines of the same pressure point in the same direction in Small rows abutting or superimposed on each other printed, the printing process is explained using the following matrix:

For example, the entire lines a and b should be printed out again:

The information carrier is in the starting position, feed p = 1, image line 1:

Heating pressure points 1 , 2 , 3 . . . m :
- Movement of the printing plate step 1: fields a 1, a 5, a 9,. . . a (m) printed - step 2: fields a 2, a 6, a 10,. . . a (m +1) printed - step 3: fields a 3, a 7, a 11,. . . a (m +2) printed - step 4: fields a 4, a 8, a 12,. . . a (m +3) printed

The entire line a is thus printed.

The information carrier is moved by a feed increment, the printing plate is quickly moved back to the starting position: feed p = 2, image line 2:

Heating pressure points 1 , 2 , 3 . . . m :
- Step 1: fields b 1, b 5, b 9,. . . b (m) printed - step 2: fields b 2, b 6, b 10,. . . b (m +1) printed - step 3: fields b 3, b 7, b 11,. . . b (m +2) printed - step 4: fields b 4, b 8, b 12,. . . b (m +3) printed

When all the steps of the printing board are carried out between each feed the matrix will be changed one after the other in the same row Direction printed.

An example of the design of the thermal printing board is in the drawing shown in enlargement a number of pressure points with the associated power supply and discharge lines and between two pressure points non-printing spaces lying along a line.

The thermal printing circuit board consists of a substrate 1 , to which pressure points 2 , 3 , 4 , 5 , 6 , 7 or resistors made of resistance material are applied along a straight line 8 using known technology, preferably thick film technology. The pressure points 2-7 are arranged at equidistant distances from one another and each have the width w , the distance between two adjacent pressure points being equal to the non-printing space v between two pressure points, which is a multiple of the width w of a pressure point in the direction of the line of the pressure points . This multiple is preferably a whole multiple of the width w of the pressure point; In the example shown, the length v of the non-printing space is three times the width w of the pressure point: v = 3 w .

The pressure points 2-7 each have a current feed line 9 , 11 , which are guided, for example, via control circuits 18 , 19 , 20 , 21 , such as integrated amplifiers, and a current feed line 10 , 12 , which either connects to a collecting line 13 or for the adjacent pressure point a manifold 14 are placed. The collecting lines 13 , 14 are connected to the mass 17 via electronic switches 15 , 16 . For example, one control circuit is assigned to two adjacent pressure points, which can be controlled together via the control circuit. The closing of one of the switches 15 or 16 then decides on the activation of one of two adjacent pressure points. The movement double arrow 22 indicates the back and forth movements of the thermal printing plate in the direction of the line 8 of the pressure points.

Relative to the information carrier level, the pressure point 2 supplies the printed images for the fields a , b , c , and d in four steps to the right when the thermal printing plate is energized and moved. For printing of the four fields, and thus the non-printing gap between each two adjacent pressure points, the pressure board has in the direction of the double arrow 22 and thus in the direction of line 8 of the pressure points 2 - are moved in four steps 7, wherein the step length of a step equal to the width w of the pressure point and the first step is to count the initial position of the pressure plate.

For printing, for example, an entire image line with simultaneous actuation of all the driver circuits is 18 to 21 when the switch 16 is first closed, the switch 15 and thereby all the fields of a pressure points 2, 4, 6,. . . printed in parallel, then the switch 15 is opened and the switch 16 is closed and all fields a of the pressure points 3 , 5 , 7 ,. . . printed in parallel. Now the thermal printing plate is moved one step further and, in the case of repetitive positions of the switches 15 , 16 , all fields b of the pressure points 2 , 4 , 6 ,. . . and then all fields b of pressure points 3 , 5 , 7 ,. . . parallel and so on.

• List of the reference numerals: 1 pressure board 2 , 3 , 4 , 5 , 6 , 7 pressure points 8 line of pressure points 9 , 11 current leads of pressure points 10 , 12 current leads of pressure points 13 , 14 busbars 15 , 16 switches 17 ground 18 , 19 , 20 , 21 control circuits 22 double arrow for movement of the printing plate

Claims (14)

1. A method for generating a high resolution print image on an information carrier in thermal printing or thermal transfer printing by means of a thermoelectric printing circuit board which has electrically controllable thermosensitive printing dots which are arranged along a line for parallel printing of an image line and the information carrier after printing of the image line transversely to the same is advanced, characterized in that between two adjacent pressure points ( 2 , 3 , 4 , 5 , 6 , 7 ) in the line ( 8 ) of the pressure points a non-printing space (v) is generated and the number of pressure points at most half of the required Pixels for an image line and for filling the image line between the pixels of two adjacent pressure points, the printing plate ( 1 ) translates from an initial position at least once by the width (w) of the pressure point in the direction of line ( 8 ) into an end position with the position of the I. Information carrier is moved and thus one and the same pressure point generates at least two pixels of the image line. 2. The method according to claim 1, characterized in that for printing the next image line after the information carrier has been fed, the printing plate ( 1 ) is translationally moved out of the end position reached in the previous image line to fill the image line back into the initial position and so on and so on thus the printing plate, in relation to the information carrier, is moved in a meandering manner and the pixels of successive image lines of one and the same printing point are printed in opposite directions in a small meander that abuts or overlaps in terms of pixels. 3. The method according to claim 1, characterized in that for printing the next image line after the information carrier has been fed, the printing plate ( 1 ) is moved back from the end position reached in the previous image line to the starting position and then again a translational movement of the printing plate along the line ( 8 ) into the end position and so on and thus the pixels of successive image lines of one and the same printing point are printed in the same direction in small rows abutting or superimposed on each other. 4. The method according to claim 1, characterized in that the printing plate ( 1 ) and / or the information carrier are moved stepwise or continuously or discontinuously and both movements are necessarily synchronously coupled to one another or are independent of one another. 5. The method according to claim 4, characterized in that a feed increment of the information carrier from a plurality of There are individual feed steps. 6. The method according to any one of the preceding claims, characterized in that the smallest length of the movement of the printing plate ( 1 ) or the step length of the same and the feed length of the information carrier are coordinated so that the lengths or steps and feeds and thus the pixels around overlap a fraction ( Δ w) of the width (w) and / or by a fraction ( Δ 1) of the length of the pressure point. 7. The method according to claims 4 and 5 or 4, 5 and 6, characterized, that the feed increment to the stride length of the printing plate such it is coordinated that those lying one above the other in the feed direction Pixels of two successive image lines around a specifiable one Number of individual feed steps are pulled apart. 8. Apparatus for carrying out the method according to claim 1 with a printed circuit board arranged within a printing station, which has contactable, electrically controllable thermosensitive printing dots along a line for parallel printing of an image line and with a feed device for moving the information carrier through the printing station, characterized in that the Printing board ( 1 ) has a number of printing dots ( 2 , 3 , 4 , 5 , 6 , 7 ), which is at most half of the required pixels for one image line and a non-printing space (v) with at least the width between two adjacent printing dots (w) a pressure point is arranged in the direction of the line ( 8 ) of the pressure points and for filling up the image line between the image points of two adjacent pressure points the printing plate ( 1 ) is held in a translationally movable manner in the direction of its longitudinal axis or the line, the smallest length of the Movement of the printing plate z to print two immediately adjacent pixels is at least equal to the width (w) of a print dot in the direction of the line. 9. thermal printing plate for use in the device according to claim 8, characterized in that the pressure points ( 2 , 3 , 4 , 5 , 6 , 7 ) along the line ( 8 ) have equidistant distances from one another, the non-printing space (v) between two adjacent pressure points is at least one time the width (w) of the pressure point in the direction of the line. 10. Thermal printing board according to claim 8, characterized in that the width of the non-printing space (v) between two adjacent printing points ( 2 , 3 , 4 , 5 , 6 , 7 ) is a whole multiple of the width (w) of the printing point in the direction of the line ( 8 ) the pressure points. 11. The device according to claim 8, characterized in that the printing plate and the information carrier each have a separate drive and the movements of the printing plate ( 1 ) and / or the information carrier are stepwise or continuously or discontinuously. 12. The device according to one or more of claims 8 to 11, characterized in that the printhead consists of a plurality of printing plates ( 1 ) arranged in series with one another according to claims 8 to 10. 13. The device according to one or more of claims 8 to 12, characterized, that the drives for the printing board / printing boards and the Information carriers gradually or continuously and / or digitally or are working analogously. 14. The device according to one or more of claims 8 to 12, characterized, that a common drive for the printing board / printing boards and the Information carrier is available.