DE2515578A1 - Electrographic printing unit with controlled gas discharge - primary direct current discharge path comprising nitrogen at atmospheric pressure in chamber - Google Patents

Abstract

The electrographic printing unit with a controlled gas discharge has a primary direct current gas discharge path-preferably nitrogen at atmospheric pressure-contained within a practically enclosed chamber with only a narrow outlet in the container wall which is formed as an anode. The primary anode (3) which belongs incommon to the two discharge paths (2-3 and 3-12) has a line of several very small holes (11). The associated electrodes which is divided into various individual elements (7, 8, 9, 10) is positioned like a control grid of a triode spaced very little distance from the cathode (2) on the one side and th anode (12) at the other. The electrode is loaded with the image point voltage signals. Teh design eliminates the need for relatively high control voltages corresponding to high image signals.

Description

Electrographic writing device with controlled gas discharge The invention relates to an electrographic writing device with a primary dc gas discharge path, preferably in nitrogen at atmospheric pressure, within a practically closed Chamber with only a narrow outlet slot, opening, or the like in the as Anode formed vessel wall to which a controlled useful discharge path is directly attached in a normal atmosphere connects in such a way that the one with the outlet opening (Control opening) provided primary anode as cathode and one of the counterelectrodes Puritz number corresponding multiplicity, arranged along a line, galvanically separated Individual elements serve as the end anode, preferably leading and supporting the paper web, to which the image voltage signals are applied, preferably via a shift register.

In the proposed writing device described takes place in In contrast to the previously known plasma lines, the relevant controlled gas discharge not within a closed tubular flask, but rather with a normal one atmospheric pressure in at least one outlet opening, slot the container connected to the outside air. The gas discharge burns between one electrode placed at a high negative potential of approx. -30 kV and one grounded housing surrounding this electrode. A part the gas discharge passes through an exit slot in the housing to the outside of the discharge space and there can be drawn on a number of pins if these are on some + 100 volts. The paper from a paper roll is pulled over the row of pens. By varying the tensions on the pins, a more or less large Draw part of the gas discharge stream onto the paper so that a charge image appears on it arises, which is fixed in the usual way with the help of a suitable toner. This means that semitones can also be represented by this measure.

In addition to noble gases, one in particular has proven useful for gas discharge normal nitrogen atmosphere, because this atmosphere is responsible for the discharge needed electrons less to the existing ones. Attach molecules than this at Oxygen is the case.

The high operating voltage is unfavorable in the device described of some 10,000 V as well as the high suction voltage required to control the Pens. The arrangement thus ultimately corresponds to a triode with the pins as an anode, which, however, differs from the usual control via the anode voltage will.

The object of the present invention includes, inter alia, the to avoid the disadvantages indicated, namely the requirement for high operating voltages, especially after relatively high control voltages, correspondingly high image signals to bypass. In addition, however, its main goal is to increase the throughput of full gas such as nitrogen, extremely low, i.e. to be made extremely economical, once in terms of cost and on the other hand, so that the Device can also be used in normal workrooms without the presence and activity of persons in it would be endangered.

This is achieved with an electrographic one described in the first paragraph Writing device with a primary dc gas discharge path according to the invention in that that the primary anode belonging to the two discharge paths along one Line has a large number of very small holes and in the useful discharge path the assigned electrode divided into individual elements in the manner of a control grid a triode at a very short distance from the one with very small passage openings provided cathode arranged on one side and the anode on the other side and is supplied with the pixel voltage signals.

Because of the large number arranged along a line in the cathode fine holes and the individual elements of the grid arranged very close in front of them a triode functioning electrode there is a leakage of nitrogen at practically the same normal atmospheric pressure only by diffusion, i.e. at a very low level Lot.

The control of the useful discharge takes place in accordance with a grid control with relatively low control voltages, i.e. low image signals.

In this case, there is advantageously the discharge vessel of the primary dc path from a closed, in one area a slot-like opening or a multitude box with very small holes arranged along a line as an anode, inside it a further box, however open on one side, at a distance is arranged as the cathode so that the discharge to the slot or bundles towards the fine exit openings.

In an advantageous further development, the low Electrode spacing through a thin insulating film provided with appropriate holes realized on both sides of the relevant electrodes of the useful discharge path, namely cathode and control electrode are arranged as metal coatings.

As a result of this intake, one or the many outlet openings are formed by bundling the gas discharge, a virtual cathode acts as an electron source is used for the subsequent charge discharge. In a further embodiment of the Device can be used as a control element, e.g. a linear CCD (charge coupled device) with a number of side contacts of the same pitch that is matched to the number of pixels serve so that the control electrode leads with regard to low capacitance can be trained extremely briefly.

Further details of the invention should be based on the in the drawings Purely schematically illustrated exemplary embodiments are explained. Are in it Parts that do not necessarily contribute to an understanding of the invention are not labeled or omitted.

While FIG. 1 shows a cross section through an overall perspective view reproduces the device, in Figure 2 is the device closing insulating film shown with the metal coverings and the fine outlet openings.

In the basic illustration of FIG. 1, 1 is the anode and 1 is the anode 2 the cathode of the primary dc discharge path 1 - 2. The anode consists of a closed slot (gap) in a surface 3 4 having box as a housing. Inside this housing (box) that with pure nitrogen or another suitable gas, e.g. noble gas, at atmospheric pressure is filled, is in each case at a distance from the individual walls of the outer Another box 2, which is open towards the anode surface 3, acts as a cathode.

The anode to the opposite to the grounded housing Cathode 2 applied voltage of approx. -5000 V burns inside the hollow cathode 2 dc gases! charge such that the gas exposure to the slot 4 according to the cross-section shown discharge paths 5 is bundled by the box-shaped selected in each case Formation of the electrodes and their mutual arrangement is achieved that in Compared to the device described at the beginning, even with a much smaller one Operating voltage, i.e. from -5000 instead of -30000 V a much larger electron flow is achieved. This measure creates within and along the gap 4 a virtual cathode, which is used for the subsequent (downstream) useful discharge path serves as an electron source.

For this useful discharge path located in normal atmospheric air the primary anode 1 also serves as the cathode, i.e. it is provided with the slot.

The anode surface 3 shown belongs to both discharge paths in common.

From the outside, the gap 4 is made of a very thin insulating strip e.g. Teflon, Kapton or the like (registered trademarks) 6 covered, i.e. roughly hermetically sealed. Lie on this insulating film strip approximately narrow, isolated metal strips that are spaced apart from one another and extend perpendicular to it 7, 8, 9, 10 (tongues) or are attached to it. You provide the individual elements the control electrode (trigger electrode) for the useful discharge path. Each this metal strip 7 to 10 has in common with the interposed insulating film strip a very fine hole 11 pointing (leading) to the center line of the gap each the discharge, in particular the electron flow, to the subsequent useful discharge path he follows. At a distance from the slot 4 of the housing 1 is a flat or strip-shaped anode, namely the end or main anode 12, over which the paper web 13 slides out of a paper roll. The end anode 12 carries the highest positive Potential, approx. + 5000 V.

On the individual elements of the control electrode 7 to 10 is opposite of the associated cathode 3.1 with an associated electrode spacing of approximately 50 μm a relatively low positive voltage chosen so that between them Electrodes 3, 1 and 7 to 10 have just not ignited a discharge. Only by the entry of electrons from the primary discharge path through the individual Control openings 11 become this discharge path as a result of the ionization that occurs as a result ignited and ignited immediately to the end anode 12. On the line by line by feed movable paper web creates a charge image line by line, which is created by a toner is fixed.

Due to the high gas pressure compared to normal atmosphere to other common gas discharges are, in accordance with the laws of similars, corresponding reduced distances, i.e. electrode distances required. These small gaps of course also allow a good resolution. by choosing very small distances laterally between the tongues 8 to 10 of the control electrode. Simultaneously have to for this purpose the control openings 11 in the individual elements of the control electrode 7 to 10 can be chosen so small that the difference in gas composition between the free atmosphere, i.e. the air and the nitrogen atmosphere in the discharge chamber can be easily maintained.

Characterized in that the housing 1 at its slot 4 through the insulating film 6 is practically hermetically sealed except for the fine control openings 11, the filling gas, e.g. nitrogen, can only escape from this chamber via the small control openings 11 take place in the manner of a diffusion. So it is enough a very small additional supply of pure nitrogen or the relevant filling gas.

The described small openings and small distances require a microtechnology. Foils suitable as a building material for the insulators are therefore used, such as.

Mica or robust plastic sheets, e.g. made of Teflon, Kapton, etc. (registered trademarks) are used. The (strip-shaped) individual elements of the Control electrode 7 to 10 etc. can then, as shown in Figure 2, on the underside of the insulating film 6 as rings 17, 18, 19 and 20 with the associated Supply lines 7, 8, 9 and 10 are vapor-deposited. The counter electrode for the Control field 3 - 7, 8, 9, 10 or 3 - 17, 18, 19, 20, i.e. the anode surface 3 with a slot 4 of the housing 1 is on the top of the foil, which serves as a spacer, upset. This electrode 3, which is applied as a metallic coating, is shared with the Perforated foil as carrier; i.e. it has a multitude of very small holes 11, through which the passage of electrons from the primary gas discharge path 1 - 2 takes place. The individual elements of the control electrode 7, 8, 9, 10 or 17, 18, 19, 20th cannot informally init the relevant in your extension control element shown, e.g. a linear CCD (charge coupled device) will.

This control element in the form of a shift register is approximately in It is used in the following way: The sequential signal of each line is inserted into this Shift register inserted and then the individual positions are simultaneously via the very large number of output electrodes placed across the register emptied to the individual elements of the control electrodes 7 to 10 or 17 to 20. Of course In addition to the simultaneous control of an entire line, a serial Carry out control of each individual pixel. Suitable for this purpose There are already CCDts with 1600 points over a length of about 1 inch, which means a point spacing of about 15um results. It can thus be the two components, that is, the shift register and the printing device can be easily joined together, with of course, both components have the same pitch corresponding to an equal pitch need to have.

4 claims 2 figures

Claims (4)

Claims 1 4 leRtrographische writing device with a Primary DC gas discharge path, preferably in nitrogen at atmospheric pressure, within a practically closed chamber with only a narrow exit slit or opening or the like in the vessel designed as an anode, to which directly a controlled useful discharge path is connected in a normal atmosphere in such a way that deß the primary anode provided with the outlet opening (control opening) as Cathode and, as a counter electrode, a plurality corresponding to the number of points, roughly lengthways galvanically separated individual elements arranged in a line as, preferably the Paper web leading and supporting end anode is used to which the image voltage signals, are preferably placed via a shift register, d u r c h e k e n n -z e i c h n e t that the two discharge paths (2 - 3 and 3 - 12) belong together Primary anode (3) has a large number of very small holes (11) along a line and in the useful discharge path (3 - 12) the associated in Binzelelemente (7, 8, 9, 10 or 17, 18, 19, 20) split electrode like a control grid a triode at a very short distance from the one with the very small passage openings (11) provided cathode (2) on one side and the anode (12) on the other side is arranged and applied to the pixel voltage signals. 2. Electrographic writing device according to claim 1, d a it is indicated that the discharge vessel (1) is the primary DC discharge path (2 - 3) from a closed, in one surface a slot-like opening (4) or a plurality along a line arranged, very small holes (11) having a box as an anode (3), inside each at a distance another box, which is open on one side, is arranged as a cathode (2) in this way is that the discharge is concentrated towards the slot (4). 3. Electrographic writing device according to claim 1 or 2, d a d u r c h e k e n n n z e i c h -n e t, that as a metal covering the two Discharge paths (2 - 3 and 3 - 12) belonging together, with very fine openings (11) provided electrode (3) on one side of a very thin grid-cathode spacing (3 - 7, 8, 9, 10 or 17, 18, 19, 20) determining the useful discharge path (3 - 12) Insulating film (6) and on its rear side (outside) the separate control elements (7, 8, 9, 70) forming, enclosing the individual through holes (11) and metal rings (17, 18, 19, 20) provided with corresponding leads are. 4. Electrographic writing device according to one or more of the Claims 1 to 3, d a d u r c h g e n n n z e i c h n e t that the relevant Control element, e.g. a CCD, a number of side contacts adapted to the number of pixels has the same pitch and the leads to the control electrode elements (7 - 10 or 17 - 20) are short.