DE1097456B - Method and device for electrographic recording - Google Patents

Description

Method and device for electrographic recording The invention relates to an electrographic recording method and an apparatus to carry out the process and, in particular, to improve the process and the device for producing electrically charged areas on a one Charge retentive surface of a recording medium.

The electrographic recording process involves three stages. the The first stage consists in the production or printing of electrically charged ones Areas on selected locations of a recording medium, these areas Represent information. The second stage consists in developing the charged areas on the recording medium, for example by making them visible. The third stage, which is optional, consists in fixing or making it permanent of the developed areas. Find in the electrographic recording process these: take place three stages one after the other and are at locally separated from each other Bodies executed.

The creation of an electrically charged area on a recording medium in the printing station was previously caused by a sufficiently strong electrical Field is generated between a pressure electrode and the counter electrode, between which the recording means is arranged to ensure that one or several charged particles through field electron emission into the gap between the Electrodes are inserted. These particles trigger the cumulative ionization of the Gas molecules in the gap, and an avalanche of charged particles spreads out the pressure electrode towards the counter electrode until the avalanche hits the recording medium and creates a charged area on it.

The strength of the electric field that is required to make the cumulative Supporting ionization or a Townsend discharge is considerably less than that which is required to move charged particles through the field effect into the Introduce gap. Also the exact voltage at which charged particles pass through the field effect introduced into the gap exhibits any change on. In addition, the point in time at which the charged particles are generated changes hence the strength of the electric field in the gap. The size of the loaded areas or the printed dots on the charge-retaining surface -des Recording medium generated is a function of the strength of the electrical Field in the gap at the point in time when the cumulative ionization begins. Consequently heretofore lacked the size of the charged ones made on the recording medium Areas the evenness.

It has been found that by increasing the amount of water vapor that in that existing between the pressure electrode and the surface of the recording medium surrounding atmosphere is present, the voltage at which the Field electron emission of the charged particles occurs from the printing electrode, and that Ida's presence of an electronegative gas in the gap increases the size of the on: the Recording medium produced charged area and also changes the size between the printed dots.

The invention therefore relates to an improved device and a method for producing electrically charged areas on a recording medium.

Another object of the invention is an improved method and a device for initiating a continuous discharge in a gas the pressure and temperature of the surrounding atmosphere.

Another object of the invention is a printing station for an electrographic printer which does not require a special one Create atmosphere to control the size of the printed latent images.

Yet another aspect of the invention is a method and an apparatus for electrographic data recording in which the The amplitude of the pressure paths än the pressure and counter electrodes is reduced.

The invention also provides a method and a device for initiating a continuous discharge in the printing station an electrographic record that prints reliably and evenly and in which the contamination of the printing electrodes has no harmful effects.

The invention also relates to an electrographic Recording method and an apparatus for carrying out .the method improvements the printing station, the reliable electrostatic latent images of more consistent Quality produced at significantly lower compressive stresses without the need to manufacture a modified atmosphere. is required.

The invention relates to an electrographic recording method, in which an area on a recording medium is electrically charged Particle is charged on the recording medium by an electric field which passes substantially across the recording medium. The distinguishing feature of the process is that the maximum strength of the field is less than the limit for introducing the charged particles by the field effect is required that the charged particles enter the field a location remote from the recording medium and @ that -the The strength of the field between, this point and the recording medium is sufficient, to aid cumulative ionization.

The invention also relates to an electrographic recording device for carrying out the method with a part carrying a recording medium or a counter electrode and at least one pressure electrode spaced from the part and the recording medium. The device is characterized by at least one trigger electrode, which is immediately next to, but at a distance from, the Pressure electrode lies, by means of which: the pressure electrode a first unidirectional electromotive force brings about to effect a field generate which crosses the recording medium and which is insufficient to the ionization of the atmosphere in the space between the pressure electrode and the recording medium trigger, which is enough to cause the cumulative ionization of the atmosphere to support in this space, and .by an institution; those on the trigger electrode brings about a second electromotive force of such magnitude that one Spark discharge is generated between the trigger electrode and the pressure electrode; to trigger the ionization of the atmosphere in this field.

These and other features and advantages of the invention will emerge from the description. In the drawing, FIG. 1 shows an enlarged schematic Side view of part of the printing station of an electrographic recording device, 2 shows an enlarged view of the print side of a known matrix print head, Figure 3 is a greatly enlarged perspective view illustrating how the Printing is carried out in a known electrographic recording apparatus Fig. 4 is an enlarged view of the print side of a print head with additional trigger electrodes, Fig. 5 Meine-särk enlarged perspective view of the printing station, which the How the print head works with additional trigger electrodes Figure 6 is a graph of the voltages applied to the push and release electrodes according to FIG. 5 come into effect, and FIG. 7 shows an example of a matrix print head generated electrographic record. To the invention and the advantages! to show the known method and apparatus for making charged Areas written on a recording medium. In Figs. 2 and 3 is the Formation of a known print head shown. Fig. 1 shows two elements the printing station 10, namely the print head 12 and the counter electrode 14. The print side 16 of the printhead 12 is essentially flat and is in the. even spacing from the support surface 17 of the counter electrode 14 by any conventional means, z. B. the holder 19 held. The recording medium 18 is in the space between the print head 12 and the counter electrode 14 arranged. The recording means 18 consists of a carrier layer 20 and one applied to one side of the same dielectric layer 22. The carrier layer 20 is a relatively good conductor of electricity, and the dielectric layer 22 has a very high specific resistance on or is a very poor conductor of electricity. The usual setup for Movement of the recording medium 18 through, the printing station 10 through the The direction indicated by the arrows is not shown. The Carrier layer 20 in contact with support surface 17 of counter electrode 14.

Figure 2 is an enlarged view of the print side 16 of the stencil print head 12. The ends of the pressure or pin electrodes 24 are with the pressure side 16 Indian same level. The electrodes 24 bind on the pressure side 16 at the same distance from each other and arranged in five columns and seven rows. A printhead with pin electrodes arranged on the printing side, as shown in Fig. 2, is also known as the 5.7 die print head. By energizing selected pressure electrodes 24 can read symbols of letters on the recording medium in a known manner or digits can be printed. An example is shown in FIG.

In Fig. 3, a single pressure electrode 24a is illustrated. the Other electrodes and the structure of the head 12 are omitted for the sake of illustration and to simplify the description of the printing process. The Eiode of the Pressure Electrode 24a is at the distance from the counter electrode or anvil 14. The space between the anvil 14 and the pressure electrode 24a define a gap 26. The recording medium 118 is arranged within the gap, with the carrier layer 20 being the support surface 17 of the counter electrode 14 touches.

In order to reduce the amplitude r of the compressive stress pulse and one greater degree of uniformity in the size of the electrically charged areas Achieve, which is generated on the exposed surface of the dielectric layer 22 the atmosphere in gap 26 is changed. The pump 28, which at a preferred embodiment is electrically driven, presses the surrounding air through a layer of water 30 in container 32. The air then passes through a layer of an electronegative former Fabric 34, such as. B. trichlorethylene, blown in the container 36. The modified air is then passed through the nozzle 38 in the space between the printing side 16 and the dielectric layer 22 of the recording medium 18 brought.

The counter electrode 14 can be held at reference potential with a Point or to be connected to earth. The pressure electrode 24a can be replaced by a (not shown) direct current source on a substantially constant rest voltage can be kept at -600 V, for example. If on the recording medium 18 below the electrode 24 a is to be produced an electrically charged area, is on the electrode 24a a pressure voltage pulse of: for example -f-1100 V for Effect brought so that the potential difference between the electrodes 24 a and 14 increases to -1700V. The source of the pulse is: a common pulse generator circuit, which is not shown.

A potential difference of 1700 V under these conditions is common more than the limit at which electrons are emitted from the pressure electrode 24a if this is negative: The potential difference between the electrodes 24a and 14 take a short but still limited time to reach their maximum To achieve value. As a result, the exact voltage at gap 26 at the time in: which electrons are emitted from the pressure electrode 24a, not a constant and changes with the material of the electrode 24a, if it is assumed that .that all other factors remain unchanged. The time that a never-ending discharge needs to spread across the gap 26 and the charged area 40 on of the dielectric layer 22 is 10-9 seconds or less. in the In comparison with this, the rise time of the compressive stress pulse is quite long. From it there is any change in the strength of the electric field, if charged particles are first emitted from the electrode 24a, and the sizes of the printed dots 40 generated by each compressive voltage pulse are not necessary evenly. Each of the dots 40 printed by the electrode 24a becomes, for example substantially circular - and the center of point 40 will be at its Formation below the center or on the extended longitudinal axis of the pin electrode 24a lie.

The presence of water vapor in the gap 26 reduces the maximum Voltage at which the field electron emission takes place. The effect of the electronegative Material (in the gap 26 is to increase the field strength that is used to support cumulative ionization is required. This way the dimensions the avalanche decreased, reducing the size of the surface of the charge retaining layer 22 of the recording medium 18 produced or printed electrically charged area 40 is reduced.

Fig. 4 is a fig. 2 similar view showing the print side 42 of printhead 44 shows. The print head 44 is a 5.7 die print head in which a trigger electrode 46 is provided for each of the pressure electrodes 48. The ends the print and trigger electrodes lie with the print side 42 of the print head 44 in the same plane. The pressure electrodes 48 are equidistant from one another and are arranged in five columns and seven rows. In a preferred embodiment each of the electrodes 46, 48 has a diameter of 0.0762 mm, the distance between the axes of the pressure electrodes 48 is 0.3464 mm, and the distance between one Pressure electrode 48a and a trigger electrode 46a is approximately 0.0635 mm.

Prop. Fig. 5 is a greatly enlarged schematic view of a part the printing station 10, the printhead 12 being replaced by the printhead 44, and only a single print electrode 48a and the associated trigger electrode 46a of the print head 44 are illustrated. The structure of the print head 44 is omitted for illustration and description of the improved method and apparatus for manufacturing to simplify electrically charged areas on the recording medium 18. the Counter electrode 14 is arranged so that the support surface 17, its surface at least is as large or larger than the diameter of the pressure electrode 48 a or the trigger electrode 46a, from the print side 42 of the print head 44 in a substantially uniform manner Distance is and is maintained.

A compressive voltage pulse can be applied to the pressure electrode 48a by the Pressure pulse generator circuit 54 of low impedance are brought into effect, which is shown schematically. In a preferred embodiment, the amplitude of the compressive voltage pulse 56 approximately 500 V and the width approximately 500 ms. The presence of the compressive voltage pulse 56 produces a unidirectional one diverging electric field between the pressure electrode 48a and the plane Surface 17: of the counter electrode 14 or within the gap 58. The electrode 48a can be viewed comparatively as a point source or a point electrode will. However, the maximum strength of this field at the electrode 48a is not sufficient to cause the emission of charged particles by the field effect. the The strength of the field is just big enough to keep the cumulative ionization within of the gap 58 as soon as electrically charged particles enter the same are introduced. To introduce charged particles into gap 58, a trigger pulse is used 60 to the trigger electrode 46 a through the trigger pulse generator circuit 62 of brought into effect relatively high impedance, which is shown schematically is. The amplitude of the trigger pulse 60 can be approximately -1000 V and its width be about 50 ms, so that: ß it is significantly less than the width of the Compressive stress pulse: The strength of the electric field between the trigger electrode 46a and the counter electrode 14 is below the limit value at which the charged Particles are generated by the field effect.

Referring to Figure 6, the relative polarities, amplitudes, and dates of compressive voltage pulse 56 and trigger pulse 60 are shown. If a trigger pulse 60 is applied to the trigger electrode 46a and a pressure tension pulse 56 is simultaneously applied to the pressure electrode 48a, the voltage between them is sufficiently high to immediately trigger a spark or a spark discharge. The duration of the spark discharge is very short, 10-9 seconds or less. So that the printing can take place with the new head, the pressure voltage and release pulses must be brought into effect simultaneously on an associated pair of pressure and release electrodes. The widths of the two pulses can therefore be made the same, or the trigger pulse can be wider than the pressure pulse. Although it is not shown in FIG. 5, the electrodes 46 a and 48 a are isolated from one another by a material having a high resistance, such as, for. B. the epoxy resin, from which the greater part of the head 44 is made. As a result, the spark discharge between the ends of the electrodes 46a, 48a takes place essentially in the plane of the pressure side 42 of the head 44.

Every spark discharge carries a large number of charged particles into the gap 58, in particular into that part of the gap between the electrode 46a, the electrode 48 a and the counter electrode 14, where the strength of the electric field is close to the maximum value. As soon as charged particles are introduced into the gap 58 -is the field between the pressure electrode 48a and the counter electrode 14 as a result the presence of the pressure voltage pulse on the pressure electrode 48 a sufficient strong to the propagation of an avalanche of charged particles across gap 58 and forming a charged region 64 on the surface of the dielectric Effect layer 22. The printed dot 64 produced is essentially circular. However, the center of the point produced does not come immediately below the pressure electrode 48a, but between the axes of the electrodes 46 a and 48a, or, in other words, the origin of the avalanche is likely along the path of the spark discharge between the trigger electrode 46a and the pressure electrode 48a. The polarity of the charged area is the same as that of the pressure electrode 48 a. If the pulses have the polarity indicated in Figure 5, the charge is of the printed point 64 positive.

For example, an explanation of how a negative charge spreads across the gap 26 of FIG. 3 is relatively easy to understand because it is on the acceleration of the electrons caused by the electric field ., which are emitted by the field effect from the electrode 24a, so that the electrons have enough energy to ionize the gas molecules in the gap 26. The ionization process of the gases in the gap generates further electrons, which in turn accelerated to generate even more electrons, etc. However, if on the Pressure electrode 48 c>; a positive compressive stress is brought into effect the explanation is not so simple, since the strength of the field in the gap 58 of FIG between the electrode 48 a and the counter electrode 14 is not sufficient to .die im Gap 58 to accelerate existing positively charged ions so that they the further Cause ionization.

An explanation of how a positively charged area 64 is made or is printed, is inferring: The presence of the through, the spark discharge .in positive ions introduced into gap 58 distorts the electric field in the gap 58 to such an extent that electrons from in front of the bulk of the positive ions lying gas molecules, lie beyond the limits of the avalanche. As a result, more positive ions are formed, and since the emitted electrodes move rapidly to the pressure electrode 48a, the charge on the ions will not be neutralized. The additional positive ions cause a further distortion of the field and create a new limit. The process continues until the avalanche crosses has spread to the gap and hits the recording medium 18. This statement the propagation of the ppstive ions across slit 58 is similar to that of the Townsend avalanche, which is generated when the pressure electro @, de is negative.

Due to the high impedance of the trigger pulse generator 62, the spark discharge is between the electrodes 46 a, 48 a of very short duration. The time constant ides de circuit containing trigger electrode 46a and the time during which the compressive voltage pulse 56 and the trigger pulse 60 simultaneously to the relevant Electrodes are present, determine whether every time the pressure electrode 48a and the trigger electrode 46a are excited at the same time, more than one spark discharge can be generated. Every spark discharge triggers an avalanche of charged particles the end. Each additional avalanche causes an increase in the charge density of the printed matter Point 64 and a slight increase in its size. To a high degree of evenness To achieve this, it is desirable that each printed dot be substantially of nm generated by the same number of avalanches. This is done by regulating the latitudes and .the duration of the impulses as well as the impedance, the circuit of the trigger electrode achieved.

One of the advantages, a spark discharge between the trigger electrode 46a and the pressure electrode 48a for introducing charged particles into the gap 58 is to use @ that the strength of the unidirectional field between the pressure electrode 48a and the counter electrode 50 is established at the time and has a substantially fixed value in which these charged particles are introduced into the gap by the spark discharge. Because the strength of the electric Field is essentially constant and known, so is the size of the through a such combination of pressure and trigger pulses produced or printed charged area 64 be substantially constant. Furthermore, since the discharge is not by (the field effect is triggered, it is not necessary to touch the pressure electrodes To bring pressure pulses of very high voltage to effect. As a result, is a Device that supplies modified air to the printing station is no longer required.

Another problem that arises when using the known printheads results is that the presence of certain substances or impurities the voltage increases at which, the charged particles are emitted by the field effect will. In some cases, the presence of impurities in the The minimum value of the voltage is increased to a value which is greater than that by the Impulse generator brought into effect value, so that no charged particles are emitted and the printhead does not print. It was observed that the spark discharge a self-cleaning effect between the trigger electrode and the pressure electrode has so that the printing electrodes are no longer rendered ineffective by impurities can be.

When the printhead shown in FIG. 4 is in the printing station 10 is located, with each of the pressure electrodes 48 a pressure pulse generator and with each of the trigger electrodes 46 is connected to a trigger pulse generator. Whenever a loaded one Area, for example, below id the pressure electrode 48b and the trigger electrode 46 b is to be produced, must be on the electrodes concerned at the same time a compressive voltage and a trigger pulse can be brought into effect. To a one If you add letters or characters representing a number, they will be Pressure- and trigger electrodes for printing the character on the recording medium must be excited, excited by conventional control circuits, which are not shown are because they are known and produce the record illustrated in FIG.

From the foregoing it is clear that the polarities of the pressure and trigger pulses can be interchanged. When a negative compressive voltage is applied to the printing electrode, negatively charged areas are produced on the recording medium, and when positive pressure pulses are applied to the printing electrode, positively charged areas are produced on the recording medium. The impedance of the pulse generator energizing an electrode determines the function of the electrode, using a high impedance pulse generator for a trigger electrode and a low impedance pulse generator for a pressure electrode. The function of the electrodes 46 a, 48 a can therefore be interchanged if their corresponding pulse generators are interchanged.

Although the push and release electrodes are shown as pin electrodes and are described, other physical arrangements, e.g. B. one to the pressure electrode concentric trigger electrode, can be used and lie within the frame the invention.

The explanation of the way in which the electrically charged areas printed or fabricated on a dielectric layer of a recording medium are the best explanations that have ever been given for these processes are. They are believed to be accurate, and they are: backed up by experimentation. However, they only provide the best theories to explain the results observed that are currently known to the inventor.

From the foregoing, the advantages of using Trigger electrodes for introducing charged particles into the gap between the Pressure electrode and the counter electrode to discharge the discharge at a predetermined Trigger field strength, increasing the usefulness of electrographic printing devices have been significantly improved.

Claims (11)

PATENT CLAIMS: 1. Electrographic recording method, at which is an area on a recording medium by electrically charged particles which is deposited on the recording medium by an electric field passing substantially across the recording medium, thereby indicated that the maximum strength of the field is less than the limit value, which is necessary for the introduction of the charged particles by the field effect, that the charged particles in the field at a distant from the recording medium Place and that the strength of the field between this place and the recording medium is sufficient to support the cumulative ionization. 2. The method according to claim 1, characterized in that the strength of the field on the recording medium is less than the maximum strength of the field and that the strength of the field at the point of introduction of the charged particles is greater than the strength of the field on the recording medium. 3. Procedure according to claim 1, characterized in that the field between one of a surface The substantially point-shaped electrode located at a distance from the recording medium and one substantially adjacent to the other surface of the recording medium flat electrode is made and that the electrically charged particles in abundance Amount introduced into a part of the field adjacent to the first-mentioned electrode will. 4. The method according to claim 3, characterized in that the loaded Particles through an electrical spark discharge between the punctiform electrode and a third electrode into the field. 5. The method according to claim 4, characterized in that the discharge between the first and the third Electrode occurs over a short distance and is short-lived. 6. Electrographic Recording device for carrying out the method according to one of the preceding Claims having a part carrying a recording medium or a counter electrode and having at least one pressure electrode spaced from the part and the recording medium is, -characterized by at least one trigger electrode, which is immediately next to, but at a distance from, the pressure electrode, by means of a device which a first unidirectional electromotive force to the pressure electrode Brings about effect to create a field which crosses the recording medium and which is insufficient to ionize the atmosphere in the space between trigger the pressure electrode and the recording medium, which is sufficient, however, to aid the cumulative ionization of the atmosphere in that space, and by means of a second electromotive on the trigger electrode Force of such magnitude acts as a spark discharge between the Trigger electrode and the pressure electrode is generated to the ionization of the atmosphere trigger in this field. 7. Apparatus according to claim 6, characterized in that that the means applying the first electromotive force to the pressure electrode brings about a pulse generator of low impedance: is and that the device, which brings the second electromotive force to effect on the release electrode, is a pulse generator of high impedance, the pulse generator with the pressure and trigger electrodes are connected. B. Device according to claim 6 or 7, at which the print electrode (s) is (are) arranged in a print head, the print side of which at the same distance from a part carrying the recording medium or a Counter electrode is, characterized in that the trigger electrode (s) in This printhead is (are) arranged, with each trigger electrode on the print side is close to an associated print electrode and within the print head from the pressure electrode: is separated by electrically insulating material. 9. Device according to Claim 8, characterized in that the ends of the trigger electrode (n) and the printing electrode (s) lie in the same plane with the printing side of the print head. 10. The device according to claim 6, 7, 8 or 9, characterized by several pairs of electrodes, each pair consisting of a pressure electrode and a release electrode, the Distance from one another is less than the distance between adjacent pairs of electrodes. 11. Device according to Claim 10, characterized by several rows of such pairs of electrodes.