DE3243737A1 - Device for the electrostatic deflection of discontinuously produced, contrasting fluid droplets for an ink jet printer - Google Patents

Abstract

The invention relates to a deflection device for ink jet printers whose primary objective is to compensate the influence of the path covered by print fluid droplets after the deflection pulse has occurred on the deflection of said droplets and to utilise the by far the greatest part of the image droplets for the formation of characters in order to achieve a high printing frequency. The invention is therefore based on the object of developing a deflection device in which a droplet-by-droplet digitisation facility of each droplet position is provided using the line-drawing method and the resulting droplet deflection is dependent merely on the deflection voltage and the deflection pulse duration, but not on the location at which the printing fluid droplet is located at the time of the pulse effect. According to the invention, for this purpose the deflection electrode plates are arranged obliquely with respect to one another, their spacing decreasing from the side of the droplet inlet to that of the droplet outlet and being proportional with respect to the remaining length of trajectory. The application of the invention is expedient in non-mechanical typing and printing technology. <IMAGE>

Description

Title of the invention

Device for electrostatic deflection generated discontinuously contrasting fluid droplets for an inkjet printer field of application of the Invention The invention relates to a device for electrostatic deflection discontinuously generated contrasting fluid droplets for an inkjet printer, by means of which the electrically charged writing fluid (ink) droplets for generating a directly readable character on a suitable recording medium can be put together in a mosaic according to a predetermined grid, their application in non-mechanical writing and printing technology1 in particular in writing or similar office machines useful, but also with other labeling devices, such as those used for printing electronic components, cans and tubes provided is possible.

Characteristics of the known technical solutions There are already a number of non-mechanical writing and printing devices based on the principle an inkjet writer based, known in the case of a droplet-forming Nozzle equally spaced contrasting writing fluid droplets of the same Size generated by means of a charging electrode with a constant electrical charge and then in one by one or more pairs of deflection electrodes formed electrostatic deflection field are influenced in their trajectory in such a way, that this is immediate. after they hit a suitable recording medium through their mosaic-shaped stringing together, depict an immediately legible symbol. The solutions known so far for the electrostatic deflection of electrically charged writing fluid droplets generally take into account the fact that that at the required frequency of the transmission of such writing fluid droplets there is no possibility of a discrete deflection of each individual droplet, because the time required for the electric field to act on the writing fluid droplets is greater than the period of droplet generation. Aim accordingly the known devices for electrostatic deflection on a serial line by line Deflection of the writing fluid droplets and the fading out or suppression of the droplets not needed to form a mark, but what in the end leads to a significant reduction in the theoretically possible write frequency, because the majority of the writing fluid droplets generated are not used for character formation is required and is therefore hidden or suppressed. Proves to be disadvantageous also that in a homogeneous electrical generated by the deflection electrodes Field no- ne compensation of the influence of the writing fluid droplets After the success of the deflection pulse, the web covered on its deflection is possible is, so that with the serial deflection there is also no drop-by-drop detection of the positions can take place in a grid with equal intervals.

For example, DE-AS 2 327 930 describes an inkjet printer which a stream of equally spaced and equally charged ink drops generates the to form a raster-shaped composite character by two Two-dimensional deflection electrode pairs arranged at right angles to one another, d. H. in horizontal and vertical directions, is deflectable, and where the for pressure of the character, unnecessary ink drops are suppressed. The one used to generate a raster line caused different deflection of the individual ink droplets results from the variation of the time period in which each ink drop within the cyclically changing electrical deflection field of the deflection electrodes, the first pair of which has a length equal to the length of one Ink droplet jet is whose ink well for writing the maximum length in one direction of the deflected beam it is sufficient. This means, that for the rasterization of the columns and lines, the ink droplets through the between the deflection electrodes acting homogeneous electric field for different time intervals be influenced, at which the ink droplets reach a lateral speed, which is proportional to the time integral of the effect of the electric field, da the individual ink droplets have a constant speed that is proportional to the distance integral of the electric field from the position of an ink drop at the time the electric field to the end is the same.

The main disadvantage of this inkjet printer is first of all based on that due to the proposed serial deflection of the ink droplets no drop-by-drop digitization possibility of every drop position within of the given character grid (dot matrix) is given, which is not least the The result is that the deflected ink droplets on the recording medium to be printed are merely arranged in such a way that only an approximately linear grid of lines is generated Will. This solution also completely ignores the fact that that the deflection of the ink droplets is also proportional to the travel time of the ink droplets after their acceleration is. In addition, to limit the effect of the Air resistance, the free flight length of the ink droplets can be kept to a minimum, so that the aspect ratio between the flight length from entering the deflection field up to the recording medium on the one hand and the flight length from the exit from the deflection field on the other hand, up to the recording medium can in no way be neglected. It also proves to be disadvantageous that there are always so many color droplets on the deflection electrodes must go through as required to map a full character height.

With the additional patent application disclosed in DE-AS 2 445 2o7 the inkjet printer learns according to DE-AS 2 327 930 a further advantageous Design in the orphan that the deflection electrodes are only half as long as one are the groups of ink droplets required to produce a maximum raster line and acted upon by a square wave signal, the length of which corresponds to the time, the one predetermined group of ink droplets for passing through the deflection electrodes needed, with this divided into three equal sections is, the successive positive potential, zero potential and negative potential have despite the advantageous embodiment of the described in DE-AS 2,327,980 Inkjet printer adheres to this.

but the serious disadvantage that the resulting Distraction of the ink droplets to a decisive extent from the place and time at which or to which they are exposed to the action of the deflection voltage pulse is. In this way, as before, only an approximately linear grid of lines can be achieved which means that even this solution has no possibility of a drop by drop digitization every drop position in a linear grid. In addition, the Suppression of the ink droplets not required for character formation at a substantial level Reduction of the theoretically possible writing frequency by DE-AS 2 353 340 an inkjet printer has also become known in which only the character-forming, d. H. the ink droplets intended for writing a character, a discrete one and equally spaced ink drop sequence by means of a charging electrode with one constant electrical potential and then an electrostatic Deflection device pass, which the charged ink droplets wanrend their running time between the deflection electrodes proportional to the associated time integral of a sawtooth-shaped periodic deflection voltage perpendicular to the line direction deflects, while the not required ink drops are hidden, the period of the deflection voltage is twice as long as the travel time of the ink droplets between the deflection electrodes, those at the end of each period during a transit time between the deflection electrodes ver running ink droplets will disappear and the number the writing points are larger than the number of those generated by the nozzle in one run time Ink droplets.

Again, this solution has the fundamental disadvantage, that the scrielle line by line deflection of the jet of ink droplets and the fading out of the ink droplets not required for character formation at the expense of the theoretical possible write frequency goes. Also here is: a possibility for a discreet Distraction given to each droplet. Furthermore, the deflection device turns out to be to the extent that it is disadvantageous that certain conditions must be met, such as the setting of the times at which the ink droplets used for printing occur within a row of points or that is the time it takes for a row of points is required, e.g.

the time between the occurrence of the first drop in the space between the main deflection electrodes and the exit of the last drop from the space between the main deflection electrodes, to the tilting period of the main deflection voltage is.

Finally, DE-OS 3 005 543 describes an ink pen with controlled ink supply, in which the charged by means of a charging electrode Ink droplets as a function of their weight, charge and deflection voltage when passing a deflection field generated by a pair of deflection electrodes by one corresponding angle are electrostatically deflected, which is also in their Size of differing droplets can experience a distraction, though whose charge is varied in proportion to their weight. Under these conditions a uniform acceleration of the ink droplets can also be achieved.

With the proposed ink pen this is done by stringing them together individual ink droplets tessellated characters simply by the line-by-line writing of the character grid, which means that there is no possibility of that according to the. predetermined character grid characters to be formed according to the so-called To write "stylus method". So this solution is still adhering to the basic one Disadvantage that when writing the grid line by line, one for each grid point Timing must be provided regardless of 00 for this one ink drop is needed or not. As a rule, however, only a relatively small amount Part of the halftone dots is covered with an ink droplet as a result only a fraction of that corresponding to the frequency of formation of the ink droplets per Time cycle generated droplets are used for the formation of characters, which ultimately in turn at the expense of the theoretically possible write frequency. In addition, it is capable of Even this ink does not write a linear character grid in the manner described to create.

OBJECT OF THE INVENTION The aim of the invention is to provide the known technical Solutions to eliminate inherent disadvantages, but especially a distraction of the writing liquid droplets in multiple directions with only a single deflection voltage and the simplest point-by-point storage of the character on the basis of a predetermined grid allow the influence of the writing fluid droplets after the success of the deflection pulse compensated for the distance traveled on their deflection and depending on the character shape and the character grid used, by far greatest Part of the imageable writing fluid droplets used for character formation and as a result, a high writing frequency is made possible.

Statement of the essence of the invention The object of the invention is to be found based on a device for the electrostatic deflection of discontinuously generated equally spaced, contrasting writing fluid droplets of the same size, To develop charge and speed when using the so-called "Stylus notation" for character formation a droplet-wise digitization option every droplet position is given even with group-wise droplet deflection and in which the generated droplet deflection depends only on the deflection voltage and the Pulse duration, but not from the location within the electrostatic deflection field the drop of writing fluid at the time of the action of the deflection voltage pulse is located, is dependent.

The device according to the invention is characterized in that the Deflection electrode plates of the provided deflection electrode pairs so inclined to one another are arranged so that their distance from the side of the droplet entrance to the of the droplet exit decreases and proportional to the remaining flight length of the Is writing fluid droplets, which are in the imaginary extension of the Deflection electrode plates on the recording medium forming cutting lines at the same time the; <represent the coordinate axes of the character grid, their common point of intersection as the zero point of the character grid roughly with the point of impact of the undeflected Droplet collapses. The deflection electrode plates point on the side of the droplet exit of the deflection electrode pairs after the deflection device according to the invention for the additional one or more other such pairs of deflection electrodes can be provided, so-called corrections, in the form of abbreviations or non-planar deformations are formed.

According to the invention by the arrangement of the inclined to each other Deflection electrode plates when a deflection voltage pulse is applied between them an inhomogeneous electrostatic deflection field is generated, the field strength of which is reversed is proportional to the remaining flight path of the writing fluid droplets and as a result, the droplets when passing the deflecting electrode pairs such Experienced distraction, which is only dependent on the deflection voltage and the deflection pulse duration, but not from the location at which the droplets are at the time of the host Deflection voltage pulse are dependent. The undesirable inhoi: oogeneities ground on the side of the droplet exit of the deflection electrode pairs by means of the compensated for corrections provided on the deflection electrode plates. By the arrangement a further pair of deflecting electrodes or several further pairs of deflecting electrodes it is easily possible to have a deflection in several independent directions, for example to generate different grids or to compensate for the relative movement between the recording medium and the nozzle as they move continuously.

EXEMPLARY EMBODIMENT The invention is based on an exemplary embodiment are explained in more detail. Show in the accompanying drawing Fig. 1 is a simplified diagram limited to the most essential parts Representation of an inkjet printer with the deflection device according to the invention, Fig. 2 a with the erfindungsge: wet deflection device generated lettering Example of a given drawing grid of 7 x 11 grid points.

The embodiment of the invention is as shown According to Figure 1 of the drawing is based on an inkjet printer for generating a discontinuous sequence of equally spaced contrasting writing fluid (Ink) droplets of the same size and speed from a droplet-forming one Dus.e l consists in a known manner via a first pulse generator with a Central control is connected to the input side as well as an input unit a character generator are connected, this also from the output side is connected to the central control.

A charging electrode 2 is arranged in front of the nozzle 1, by means of which the ink droplets generated by the nozzle 1 with a constant electrical Charge can be provided. For this purpose, the charging electrode 2 has a charging voltage Ut generating voltage source connected to the nozzle 1 via the same way the first pulse generator can be acted upon. Between the charging electrode 2 and a recording medium 4 suitable for mapping a character 3 is shown in FIG Direction of flight of the ink droplets provided a deflection device with the The nozzle 1 and the charging electrode 2 can be moved along the stationary recording medium 4 is arranged. The deflection device according to the embodiment of the invention is formed by two pairs of deflection electrodes 5 and 6, the- first horizontally arranged deflection electrode pair 5 for a droplet deflection in the Y-direction and the second vertically arranged pair of deflection electrodes 6 for deflecting the Ink droplets is provided in the X direction, but can also be used without the inventive concept to change, from only one pair of deflection electrodes to deflect the ink droplets in only one direction or from several such pairs of deflection electrodes exist, causing a deflection of the ink droplets in several independent directions, for example to compensate for the transverse movement between the recording medium 4 and the nozzle 1 with their continuous movement or to realize various Character grid, such as a square or triangle grid, can be done. According to the invention are the deflection electrode plates 5a and 5b of the deflection electrode pair 5 and the Deflection electrode plates 6a and Ab of the deflection electrode pair 6 so at an angle to one another placed so that their distance from the side of the droplet occurs to that of the Droplet exit decreases and proportional to the remaining flight length of the ink droplets is. The deflection electrode plates 5a form in their graphic extension and 5b or 6a and 6b in their horizontal and vertical lines of intersection on the Recording medium 4 at the same time the lloordinatenachsen of the character grid, whose common point of intersection as the zero point or origin of the character grid roughly coincides with the point of impact of the undeflected ink droplet.

The length of the deflection electrode pairs 5 and 6 is according to the for the formation of a character 3 predetermined character raster dimensioned, d. H. at a character grid of the basic form 2n + 1 x 2m + 1 these are dimensioned so that between the deflection electrode plates 5a and 5b a maximum of 1 ink droplet and between the deflection electrode plates 6a and Ab can be a maximum of n ink droplets.

Thus, the deflecting electrode plates are 5a and 5b and 6a and 6b, respectively almost half as long as one used to represent a maximum horizontal resp. vertical character grid line required ink droplet group. On the exit sides of the deflection electrode pairs 5 and 6, since particularly large field strengths occur here, So-called corrections 5c or 6c are provided, as shortenings and / or non-level Deformations were formed at the ends of the deflection electrode plates 5a and 5b and 6a and Gb, respectively to compensate for the inhomogeneities that are undesirable for the deflection of the ink droplets to serve. The deflection electrode plates 5a and 5b or 6a and 6b are also over each a pulse generator connected to a common deflection voltage source, the the required deflection voltage I Yes for the deflection electrode pairs 5 and 6 is generated and depending on the droplet deflection to be effected either positive potential, Has zero potential or negative potential. Each of these for the deflection electrode pairs 5 and 6 provided pulse generators is with a corresponding delay element coupled, which in turn have a clock output on the input side as well as with are connected to the central control. The clock is also on one Central control input connected.

The operation of the deflection device according to the invention, which follows are represented by means of a lettering to be formed by the word "INK" is as follows: According to the embodiment of the invention, for the formation of the lettering consisting of the place "INK" according to FIG. 2 of the Drawing a rough drawing grid of the basic form 2n + 1 x 2.9 + 1, where n = 3 and n = 5, provided, the distance of the square to each other arranged grid points, of the character grid consisting of 7 x 11 grid points, Should be 0.4 mm. To generate the characters that are stored on a suitable recording medium 4 according to the principle of the so-called stylus notation, similar to the Writing tells a writing implement through the characters in one or more strokes the juxtaposition of a number of corresponding to the character to be formed Writing fluid droplets are put together in a mosaic, according to the Input of the character 3 to be written via the character generator, the central control and the first pulse generator acts on the droplet-forming nozzle 1 in a known manner and retrieve the ink droplets required for the appropriate character formation. The ink droplets generated in this way, equally spaced from one another per cycle, the also have the same size and speed, have a mass of around 10 kg and a flight speed of around 1 ms-1, with their formation frequency should be 1 kHz in the selected example. When passing in front of the droplet-forming Nozzle 1 arranged charging electrode 2 are the ink droplets by the voltage source provided with a constant electrical charge of about 10 As, due to which they on their further flight path when passing through the deflection device according to the invention generated electrostatic deflection field for character formation on the recording medium 4 experience a corresponding deflection from their original trajectory. It must however, the deflection of each ink droplet in each direction is the sum that can be digitized Allow deflection pulses to be shown, taking into account that there are two consecutive Distinguish droplets in their resulting deflection only by means of the deflection impulses, the one before your entry of the second droplet and after the exit of the first droplet from the deflection electrode pairs 5 and 6 determine the deflection field.

However, if the deflection of the ink droplets is the sum of the deflection pulses should be shown, in addition to defining the duration and tension of the Deflection pulses, which must be dimensioned accordingly, also the influence of the path of the ink droplets between the effect of the deflection pulse on the one hand and its impact on the other hand, are compensated on the recording medium 4. Since every deflection voltage, ungsimpuls- a change in the tangent of the angle between the paths of a deflected and of an undeflected drop would be in the case of a homogeneous deflection field the resulting droplet deflection proportional to the remaining flight length.

This compensation is achieved through a targeted inhomogeneity of the electrical Deflection field achieved, which in a first approximation by the idea of the invention corresponding Arrangement of the deflection electrode plates 5a and 5b or 6a and 6b is possible, the electric field strengths of the deflection electrode pairs 5 and 6 generated electrostatic deflection fields are formed such that these are inversely proportional to the remaining flight path of the ink droplets. Because of the shape of the electrostatic deflection field is approximately circular Course of the field lines between the deflection electrode plates 5a and Sb and 6a and 6b assumed, with the undesired Inhomogeneities are largely compensated for by means of corrections 5c and 6c. Via the central control, the clock generator is used for the Deflection device provided pulse generators a signal via the deflection electrode pairs 5 and 6 deflection voltage to be applied (+ Ua, Ua or 0) as well as via the tripping one Ink droplets ejected. At the same time, the the flight of the droplet caused a phase shift between the droplet formation and its entry into the deflection device formed by the deflection electrode pairs 5 and 6, what can be done, for example, by means of known shift registers, is taken into account. Accordingly, the deflection voltages by means of the delay elements for the pair of deflection electrodes 5 causing the vertical deflection and for the horizontal deflection generating deflection electrode pair 6 each up to the entry of the associated droplet into the respective deflection electrode.

pairS or 6 out of phase. When applying a deflection voltage of The electric field strength is 80 V at each of the deflection electrode pairs 5 and 6 between the deflection electrode plates 5a and 5 or 6a and 6b under consideration their mean plate spacing averaging -1 -1 about 23 V mm or 47 V mm. According to the equation F = QE = ma where F is the force, Q is the charge, E is the electric field strength, m denotes the mass and a denotes the acceleration, results for the exemplary embodiment an average acceleration of the ink droplets of about 23 ms for the deflection electrode pair s or from 47 ms-2 for the pair of deflection electrodes 5. From the remaining free Flight length of the ink droplets accelerated when passing through the deflector after leaving the deflection field, the corresponding results are obtained up to the recording medium 4 the specified character grid ximal distractions of 1.2 mm in the X direction and 2 mm in the Y direction from the center of the character grid, so-called ROM memory circuits, for example, for storing the characters can be provided. Tables 1 through 5 below show for the selected Example the programming to represent what is to be formed by the word "INK" Lettering. The necessary distractions are shown in columns 1 and 2 of each ink droplet in both directions, i.e. in the X-direction and Y-direction shown, which they have to experience for the corresponding character formation. In the Columns 3 and 4 show the sequence of deflection pulses for the respective droplet indicated in the X and Y directions, while in columns 5 and 6 the per time cycle and deflection electrode pair 5 (Y? or .6 (X) polarity of the deflection voltage to be applied (+ Ua, Ua or 0) and in column 7 the signal for the emission of an ink droplet is shown.

Table 1: Programming the letter gT XY #X #Y Including drops XY -3 +5 -3 +5 - | + 1 -2 +5 -2, 0 +5 - + 1 -1 +5 -1.20 +5 - +. l O +5 30 +5 0 + 1 0 | +3 | 30 | + 4, -1 | 0 | + | 1 0 +1 30 - + 3, -2 0 + 1 0 -1 30 + 2, -3 0 + 1 0 -3 30 + 1, -4 0 + 1 0 | -5 | 30 | -5 | 0 | - | 1 0 -4 30 -4, 0 0 - 1 0 | -2 | 30 | -3, 0, + 1 | 0 | - | 1 0 0 30 -2, 0, + 2 0 - 1 0 +2 30 -1. 0, + 3 0 - 1 0- +4 30 0, + 4 0 0 1 +1 +5 20, +1 +5 0 + 1 +2 +5 0, + 2 +5 0 + 1 +3 +5 +3 +5 + + 1 - - - - + + 0 - - - - + + 0 - - - - 0 + 0 Table 2: Programming the letter "I" XY #X #Y Including drops XY 0 -5 30 -5 0 - 1st 0 -4 30 -4, 0 0 - | 1 0 -3 30 -3.20 0 - 1 0 -2 30 -2; 30 0 - | 1 0 | -1 | 30 | -1.40 | 0 | - | 1 0 0 30 50 0 0.1 0 | +1 | 30 | 40, + 1 | 0 | 0 | 1 0 +2 30 30, + 2 0 0 1 0 +3 30 20, + 3 0 0 l O +4 30 0, + 4 0 0 | 1 0 +5 30 | + 5- 0 + 1 - - - - 0 + 0 - - - - 0 + 0 - - - - 0 + 0 - - - - 0 + 0 Table 3: Programming the letter "N" XY #X #Y Including drops XY -3 -5 -3 -5 - - 1 -3 -4 -3 -4, 0 - - 1 -3 -3 -3 -3.20 - - 1 -3 -2 -3 -2.30 - - 1 -3 -1 -3 -1.40 - - 1 -3 0 -3 50 - 0 1 -3 | +1 | -3 | 40, + 1 | - | 0 | 1 -3 +2 -3 30, + 2 - 0 1 -3 +3 -3 20, + 3- - 0 1 -3 +4 -3 0, + 4 - 0 1 -3 +5 -3 +5 - + 1 -2 +4 -2, 0 +4, 0 - + 1 -1 +3 -1.20 +3.20 - + 1 -1 +2 20, -1 +2.30 0 + 1 -1 +1 0, -1, 0 +1.40 0 + 1 0 | 0 | -1, 0, + 1 | 50 | - | 0 | 1 +1 -1 0, +1, -0 0 | 40, -t 0 0 1 +1 -2 +1.20 30, -2 + 0 1 +1 -3 20, +1 20, -3 0 0 | 1 +2 -4 0, + 2 0, -4 0 0 1 +3 | -5 | +3 | -5 | + | - | 1 +3 -4 +3 -4, 0 + - 1 +3 | -3 | +3 | -3.20 | + | - | 1 +3 -2 +3 -2.30 + - 1 +3. -1 +3 - -1.40 + - 1 +3 0 +3 50 + O 1 +3 +1 +3 40, + 1 + 0 1 +3 | +2 | +3 | 30, + 2 | + | 0 | 1 +3 +3 +3 - 20, + 3 + 0 1 +3 +4 +3 0, + 4 + 0 1 +3 +5 +3 +5 + + 1 - - - - + + 0 - - - - + + 0 - - - - 0 + 0 Table 4: Programming the letter "T" XY #X #Y Including drops XY -3 +5 -3 +5 - + 1 -2 +5 -2, 0 0 +5 - | + 1 -1 +5 -1.20 +5 - + 1 0 +5 30 +5 O + | 1 0 | +3 | 30 | + 4, -1 | 0 | + | 1 0 +1 30 + 3, -2 0 + 1 0 -1 30 + 2, -3 0 + 1 0 -3 30 + 1, -4 0 + 1 0 -5 | 30 -5 0 - 1 0 | -4 30 -4, 0 0 - | 1 0 | -2 | 30 | -3, 0, + 1 | 0 | - | 1 0 0 30 -2, 0, + 2 0 - | 1 0 +2 30 -1, 0, + 3 0 - | 1 0 | +4 30 0, + 4 0 0 1 +1 +5 20, +1 +5 0 + 1 +2 +5 0, + 2 +5 0 + 1 +3 +5 +3 +5 + + 1 - - - - + + 0 - - - - + + 0 - - - - 0 + 0 - - - - 0 + 0 Table 5: Programming the letter "E" XY #X #Y Including drops XY +3 -5 +3 -5 + - 1 +2 -5 +2, 0 -5 + - 1 +1 -5 +1.20 -5 + - 1 0 -5 30 -5 0 - 1st -1 -5 20, -1 -5 0 - 1 -2 -5 0, -2 -5 0 - 1 -3 -5 -3 -5 - - 1 -3 -4 -3 -4.0 | - | - | 1 -3 -3 -3 -3.20 - J '- 1 -3 -2 -3 -2.30 - - 1 -3 -1 -3 -1.40 - - 1 -3 0 -3 50 - | 0 | 1 -1 0 -2, +1 50 - 0 1 +1 | 0 | -1, + 2 | 50 | - | 0 | 1 +2 0 +2, 0 50 + 0 1 0 0 +1, 0, -1 50 + 0 1 -2 0 - 0, -2 50 | 0 0 1 -3 +1 -3 40, +1 - 0 1 -3 +2 -3 30, + 2 - 0 1 -3 +2 -3 20, + 3 - 0 1 -3 +4 -3 0, + 4 - O 1 -3 +5 -3 +5 - 1 -2 +5 -2, 0 +5 - + 1 -1 +5 -1.20 +5 - + 1 0 +5 30 +5 O + 1 +1 +5 20, +1 +5 0 + 1 +2 +5 0, + 2 +5 0 +1 +3 +5 +3 +5 + + 1 - - - - + + 0 - - - - + + 0 - - - - 0 + 0 As the illustrations show, the deflection voltages are each grounded in a phase-shifted manner until the associated ink droplet enters the corresponding deflection electrode pair 5 or 6. The deflection device does not need to remain limited to the arrangement of two deflection electrode pairs shown in the exemplary embodiment of the invention, but further deflection electrode pairs can also be used without affecting the concept of the invention, for example to compensate for the possibly continuous advance of the recording medium or to implement a other grid (for example a triangular grid), be provided.

The advantage of the deflection device according to the invention is particularly evident in that the corresponding to the frequency of formation of the ink droplets per unit of time producible droplets can also be used as far as possible for the formation of characters and so that at the same time a high writing frequency is made possible. In addition, it opens conditionally caused by the design of the deflection electrode pairs according to the invention inhonogeneous deflection field education the possibility of one from the place droplet deflection independent of the impact of the momentum, with each ink droplet which is subject to the same distraction impuis, regardless of where it is within of the deflection electrode pairs 5 and 6, the droplet at the time of the on-effect of the Deflection pulse is located, the same deflection up to its impact on the Record carrier experiences. This enables the deflection device according to the invention a character generation according to the principle of the "stylus notation" with point by point Digitization of the position of each writing fluid droplet, even in groups Deflection of the droplets.

List of the reference symbols used 1 nozzle 2 charging electrode 3 Character 4 recording medium 5 deflection electrode pair 5a deflection electrode plate 5b Deflection electrode plate 5c Corrections 6 Deflection electrode pair 6a Deflection electrode plate 6b deflection electrode plate 6c corrections

Claims (3)

Invention claim 1. Device for electrostatic deflection discontinuously generated contrasting fluid droplets for an inkjet printer, in which the writing fluid droplets that are equally spaced from one another are the same Size, charge and speed according to their resulting distraction Impingement on a suitable recording medium is an immediately readable character consisting of a pair of deflection electrodes serving for deflection in one direction or two pairs of deflection electrodes arranged at right angles to one another for the horizontal one and vertical deflection of the droplets with their deflection electrode plates approximating half as long as one to represent a maximum horizontal or vertical Raster line required writing fluid droplet group are and have a Deflection voltage source by means of a deflection signal generator with a deflection voltage signal can be acted upon, either negative potential, zero potential or positive Can assume potential, characterized in that the deflection electrode plates (5a; 5b; 6a; 6b) of the deflection electrode pairs (5; 6) are arranged at an angle to one another, their distance from one another from the side of the droplet entrance to that of the Droplet exit decreases and proportional to the remaining flight length of the writing liquid droplets is, so that in the imaginary extension of the deflection electrode plates (5a; Sb; or 6a; 6b) on the recording medium (4) forming horizontal or vertical cutting lines are also the coordinate axes of the drawing grid whose common point of intersection is the zero point of the character grid in eta with the point of impact of the undeflected droplet collapses. 2. Device according to point 1 of the invention claim, characterized in that in addition to the deflecting electrode pairs (5; 6) a further deflecting electrode pair or several further pairs of deflection electrodes are arranged or respectively. are. 3. Device according to points 1 and 2 of the invention claim, characterized in that the deflection electrode plates (5a; 5b; 6a; 6b) of the deflection electrode pairs (5; 6) on the side of the droplet exit with as shortenings or non-planes Deformations formed corrections (5c; 6c) are provided.