DE1090007B - Method and device for recording characters or numbers on a surface - Google Patents

Description

GERMAN

The invention relates to a method and an apparatus for recording characters or numerals on a surface, and it is her job based on enabling the recordings to be carried out so quickly that, for example, to keep up with the extraordinarily fast pace of work of electronic calculating machines able.

It is known to generate images electrostatically. For this purpose a photoconductive Layer, d. H. So a layer that "becomes conductive when exposed to light" and that is on top of you conductive support is provided with an electrical charge, whereupon the photoconductive layer is exposed to the image to be recorded. The layer becomes conductive in the light areas of this picture, so that the charge can flow off to the wearer there, while the dark areas remain charged. You get such an invisible charge image that can be made visible by dusting powder. The powder can be fixed on the surface where it is by heating.

If copies are to be made of such an image, the surfaces are fixed with the Powder loaded, dusted with new powder and then brought into contact with paper. Charges \ verden not transferred, but there is only a transfer of the powder to the contact surface instead of.

Such a method works for the recording of characters or numerals in connection with z. B. still too slow with the operation of electronic calculating machines. Therefore, for the ver method and apparatus
for recording characters or numbers on a surface

Applicant:

Battelle Development Corporation,
Columbus, Ohio (V. St. A.)

Representative: Dipl.-Ing. E. Prinz, patent attorney,
Munich-Pasing, Bodenseestr. 3 a

Claimed priority:
V. St. v. America August 29, 1952

Chester Floyd Carlson, Fairport, NY (V. St. Α.),
has been named as the inventor

the purpose of the production process described of electrostatic images modified according to the invention in such a way that electrically conductive writing of the Numbers are brought close to each other on an insulating surface and between the end face an electrical charge shift is brought about on the characters and the insulating surface, by creating a strong electric field between the opposing surfaces and thereby creating an electrostatic image on the insulating surface that corresponds to the shape of the characters or numbers.

An example embodiment of the subject matter of the invention shows the drawing, namely is

Fig. 1 is a partially schematic side view of the cooperating parts of an inventive electrostatic recording device and a diagram of the associated circuits,

Fig. 2 is a section along line 2-2 in Fig. 1 perpendicular to the rotor shaft, wherein the recording wheel or the Recording drum from above and the strip that receives the electrostatic image, as well as the stationary ones Signal electrodes are visible in section,

3 is a perspective view of one of the characters on the recording wheel;

Fig. 4 is a view in which one looks through the strip at the character-bearing wheel and the the process of sequentially applying electrostatic images to the continuously moving strip explained, and

Fig. 5 is a partial view showing an embodiment of a powder developing mechanism.

Referring to Fig. 1, the electrostatic recording apparatus has a framework 10, which consists of a pair of vertical side plates with rods and Support parts, between these. Plates can consist. On the plates or rods od. The like. Are the cooperating Elements attached. A shaft 11 at the top of the frame carries a supply roll 12 for the supply of flat insulating material, which is in the form of a strip 13 from the roll 12 is deducted. The strip moves substantially straight down to the lower part of the Device, where it travels under a drum 14 into a melting device, and then again upwards and over a conveyor roller 16 and finally between this and a non-driven one To run through roll 17. The strip is provided with an adjustable tension by a brake plate 18.

009 609/218

Splits. The plate 18 rests on top of the supply roll 12 and its pressure can be adjusted by adjustment of the lever weight 19 can be changed.

The flat insulating material in the form of the strip 13 can be made of a plastic film, e.g. B. polystyrene. Cellulose acetate, ethyl cellulose or a similar material with good insulating properties and useful consist of a thickness of 0.025 or 0.05 mm. Paper can also be used as an insulating material use that on the work surface with one of the mentioned plastic substances or with a wax is covered. In certain cases completely dry paper or cellulose film can also be used will.

On the transport path of the strip between the supply roll 12 and the one conveying the strip Roll 16 the following devices are arranged: a loading device 20 for the strip, which the Has the task of bringing the strip surface into a state of uniform electrostatic charge, an electrostatic imaging drum or wheel 21 and associated circuitry and electrodes for applying electrostatic charge images to digits. Letters or other symbols on the strip, a device 22 for visualizing the electrostatic images with the help of finely pulverized material or if necessary also with the help of liquids and finally a device 15 for permanent fixation of the Images on the strip by melting the resins added to the powder. These elements are described in more detail in connection with the operation of the device.

In operation, the motor 23 is attached to the shaft 34 of which the image wheel 21 is attached. fed so that he went with runs at an exactly predetermined speed. The speed control is done by a synchronization circuit known design. The motor rotates the wheel 21. The switching devices accommodated in the housing 24 and photoelectric time switch and also a pulley 25 which in turn has the roller 16 driving the strip over belt 26 and one located on the axis of roller 16 Pulley 27 sets in motion. The roller 16 conveys the strip 13 with each revolution of the wheel 21 each with a line spacing. When the wheel has 21 digits about 3 mm high and an alistand of also about 3 mm between the lines is desired, the strip becomes with each revolution of the wheel moves forward by about 6 mm.

When the strip leaves the supply roll 12. it first wanders through the loading device 20. which has a chamber with an electrode plate 28. The electrode plate is radioactive with a Layer that emits ionizing particles, such as. B. with a polonium layer, which the Surface of the strip is facing. On the other hand, the plate 28 is one with the adjustable contact Potentiometer 29 connected, which is grounded in the middle and at its ends to the opposite Poles of a battery 30 with a potential of 100 to several 100 volts is connected. One Grounded metal plate: 31 is at the level of the charging device 20 on the back of the strip, see above that when changing the potentiometer setting between of the electrode 28 and the strip a field of positive or negative polarity and controllable Strength can be generated.

«Particles and other ionizing particles emitted by the radioactive layer an ionization of the air in the chamber of the device 20 so that negative and positive ions develop. These ions migrate in opposite directions depending on their polarity electric field formed between the electrode 28 and the plate 31. Because the ions of one polarity their charge to the plate 28, which give the other polarity to the strip 13, so the field is through the charge of the strip changed until

ίο a state of equilibrium is established in which the potential of the strip surface is equal to that transmitted to the electrode 28 by the potentiometer Potential is. It is useful to give the strip a small positive potential by adding the Poteiitiometerkcntakt is adjusted from the ground connection on the positive side, as this is from Fig. 1 can be seen. If necessary, however, the electrode 28 can also be at the earth or ground potential be held, in which case the device only serves to remove random electrostatic charges removed from the strip prior to transferring the electrostatic images. The purpose of the negative Part of the potentiometer will be described later will.

As the strip moves downward out of the loading device, it passes a straight rod 32 of insulating material and is then curved or drawn into an approximately cylindrical shape by a circular insulating segment plate 33. The plate 33 is arranged at a small distance above the wheel 21 and parallel to it. In order to achieve the same recording position on the strip 13 for all points 35 of the image wheel 21, the shaft 34 of the alotors 23 is pivoted with its axis somewhat out of the vertical position. As a result, the upper end of the shaft according to FIG. 1 for the observer, as shown in FIG. 1, is to be seen inclined backwards. Thus, the wheel 21 and accordingly the segment plate 33 is pivoted relative to the horizontal by a corresponding amount, whereby a point on the 'circumference of the wheel 21 initially appears to the viewer, as shown in FIG. 1, for example, about 3 mm higher than the same Point after one revolution of the wheel 180 ^c .

To bring the strip into a curved fen, at which all points of the width extension of the strip from the edge of the pivoted wheel 21 are equidistant, the strip is given the shape of a cylindrical arc, the axis of which is around the is pivoted the same amount as the shaft 34. This is achieved by the arrangement of the spindle 11, the axis of which is slightly offset from the axis of the drum 14 of the melting device. Consequently is the end of the spindle 11, which is closest to the viewer in Fig. 1, further left than the opposite end. The device 20 and rod 32 are similarly inclined employed. The axis of the drum 14 of the melting device runs a little obliquely in the opposite direction Direction. This makes it possible to draw the strip exactly into a curve, which is the curved one Side of the plate 33 corresponds and over the width of the strip at all points equal distance from the edge of the wheel 21, as can be seen from FIG. the a section perpendicular to the axis of the Shaft 34 represents. The wheel 21 can consist of a light metal disc, the cylindrical edge of which, for example is about 6 mm thick. A series of raised metal characters 35 representing the \ 'order page of types similar to (Fig. 3), is on part of the

Perimeter of the wheel 21 spaced apart. For example, the digits 1 to 0 equally spaced on half of the perimeter, while the other half is smooth. Dynamic balancing is ensured by loading this other half. the Shaft 34 is supported in bearings 38.

As can be seen from Fig. 4, the characters are arranged on the jacket of the image wheel on a helical line, the slope of which, for example, is about 6 mm. As a result of the pivoting of the wheel axle, however, there are all characters which facing the strip, at each instant on a line perpendicular to the edges of the strip runs, as can be seen from FIG. Since the strip moves downwards when the wheel is turned, the elevation of the characters on the wheel keeps pace with the progress of the strip. In For example, FIG. 4 shows a point 36 on the strip opposite the number "1" on the Wheel lies. If the point on the strip had moved to position 37, so would wheel 21 Twisted so far that the number "7" is opposite the corresponding column in which the "1" was previously. The "7" is, however, in a lower position of the picture wheel jacket, so that the "7" is now is opposite to the same point on the strip opposite which the "1" was previously. This arrangement enables horizontal rows of images to appear the continuously moving strips can be applied.

The front sides of the characters 35 are ground in such a way that they are in one around the shaft 34 concentric cylinder surface are located, while the shaft is supported by rigid bearings 38 so precisely that that the front sides of all characters are at the same distance from the surface of the strip 13, if they are turned past this one.

As can be seen from FIG. 2, a series of conductive electrodes 39, separated by insulating layers 34, 40, 41 and 42 arranged on the back of the strip 13, namely where the strip 13 is cylindrical Has shape and the wheel 21 and the plate 33 is opposite. The front of these electrodes are on a cylindrical surface whose distance from the front of the characters of the Thickness of the strip plus a short air gap that is approximately 0.025 or 0.05 mm or can also be a little larger. For each column of electrostatic character images displayed on the If strips are to be accommodated, an electrode is provided. In the illustrated embodiment, there are thus four columns of character images four electrodes available.

The electrostatic images are applied to the strip by means of the characters 35 by between a character and an electrode, e.g. B. the electrode 40, a strong electrical Field of short duration is generated as soon as the desired character is opposite on the wheel 21 the electrode of the desired column comes to rest. The field removes electrons from the Front of the metallic character pulled out, so that a silent discharge arises, which as Field emission is known. The electron flow, whichever has the shape of the front of the character in its cross-section, moves on a straight line Line through the short air gap to the strip area where the charge is released and an electrostatic one Image of the character is generated on the strip. That way they became vigorous electrostatic images on cellulose acetate film 0.025 mm thick across an air gap of 0.05 to 0.075 mm produced using an ordinary steel impact letter, which has not been specially cleaned or prepared for emission, as well as under application a potential difference of about 750 volts between the face of the character and the electrode on the back of the strip. However, it is possible to lower the necessary voltage by using the Emission properties of the front sides of the characters can be improved. Means of implementation such an improvement are known. One method is to remove the front of the character to be covered with colloidal graphite, followed by a layer of magnesium oxide.

Fig. 1 shows a circuit which is used to supply the recording potentials in accordance with the from result collection circuits of a calculating machine, a signal receiving circuit, a keyboard or others Orders received signals or the like. Can serve. It should be noted, however, that the illustrated Circuit is shown by way of example only and that other circuit arrangements can be used in conjunction with the described recording system can be used.

The wheel 21 and the characters on it lie on that of the frame of the machine educated crowd. Each of the electrodes 39 and 40, 41 and 42 is connected to a separate control circuit Mistake. All of these circuits can be designed similarly. In the drawing is the circuit for the electrode 40 shown as an example. The electrode 40 rests on the adjustable slide of the Potentiometer 44, which connects the poles of the battery 45, the negative pole of which via the resistor

46 is connected to earth or ground. This can be applied to the electrode 40 by moving the potentiometer tap applied positive potential can be adjusted so that between the characters and the strip electric field is created, which is just below the potential threshold at which a Field emission discharge can begin. A triode

47 is connected with its cathode to the resistor 46 and via a capacitor 48 to the electrode 40. The anode, on the other hand, is connected to the ground or earth via the anode battery 49. If the triode 47 becomes conductive, the potential of the battery 49 occurs at the resistor 46, whereby the Potential drop is added to the fixed potential coming from the battery 45 at the electrode 40. In this way, the potential of the electrode 40 rises above the emission threshold, so that from that character which is located opposite the electrode 40 when the tube becomes conductive, a discharge takes place. As when unloading charges are applied to the surface of the strip 13 by electrons or ions, the electric field on the strip changes. The discharge stops when the electrostatic Image is built up. The anode current in the triode 47 is only allowed for a short period of time flow so that by the movement of the wheel 21 during the duration of a recording pulse no blurring of the image occurs.

The grid of the triode 47 is connected to the blocking potential supplied by the battery 50 via the resistor 51. A pulse circuit 52 is from a signal storage circuit of a calculating machine or a

controlled by another signal source. For each electrode corresponding to electrode 40 there is such a control circuit provided, which ensures the appropriate arrangement of the characters 35 on the wheel 21. A such a circuit, which corresponds to the number "1" on the Wheel 21 is part of the drawing. Each flow circuit contains a capacitor 53. To At the beginning of every run of the wheel 21, this capacitor is charged if the number "1" is in the column of the electrode 40 is to be recorded. The condenser however, remains uncharged if the number "1" is not to be recorded. Intended to Another digit is recorded, it finds the charge of a similar capacitor in one other of the circuits 52 instead. But there is always only one capacitor per electrode in a given one Working cycle loaded.

A switching arm 54, which is mounted on the shaft 34, rotates synchronously with the wheel 21 and successively touches the contacts 55 to which the corresponding circuits 52, which are assigned to an electrode (40, 41, 42), are brought up. The arm 54 closes such a contact when the character corresponding to the circuit 52 of this contact comes to rest on the wheel 21 opposite the electrode 40. The (jitter of the triode 47 is connected to the arm 54 through a photocell 56, so that one of the capacitors 53 is connected in parallel with the grid circuit as soon as the switching arm 54 is on the associated contact 55 and the photocell becomes conductive 56 is excited by a light beam from the lamp 57. The light beam is controlled by a disc 58 which is also arranged on the shaft 34 and revolves with it and which has a number of light transmission slits 59 which ensure that the light only passes through the photocell is reached at the moment in which the character is in the middle position exactly opposite the electrode connected to the circuit, such as e.g. opposite electrode 40. If the associated capacitor 53 has a ¹ charge, the grid becomes the Triode emits a positive pulse, which makes the triode conductive for the short period of time required to run on the strip e to create an electrostatic image. The constants of the circuit are chosen so that the triode returns to its non-conductive state before a blurring of the image can occur as a result of the movement of the wheel 21. A If the wheel 21 is rotated at 1000 revolutions per minute or more, the duration of the recording pulse should only be a few microseconds.

A second circumferential disk 60 with a single light slit 61 controls the application a second photocell 62 in a control circuit 63. The slit 61 passes a light pulse in the direction of the photocell 62 immediately after the switching arm 54 has completely traversed the row of contacts 55. so as to transfer a initiate a new series of charge pulses through circuits 52, creating selected capacitors 53 according to the control of the calculating machine by electronic storage circuits or other results or signals supplying sources are charged with charges. The charge on the capacitors 53 therefore takes place during the period in which the part of the wheel 21 that does not have any signs passes the arguing and the strip continues its downward movement around the line space. In this way, as shown in FIG. 4, one character line after the transferred to others.

As it moves downwards, the strip passes a behind the recording device Developing device 22 in which the invisible electrostatic images are made visible, by placing a finely divided substance on the strip, such as B. an ink mist or a pigmented resin powder, is deposited, which adheres to the negatively charged image area parts. L ~ m the development To promote, the particles are suitably positively charged by friction or other means. When a uniform positive charge has been applied to the strip by the charging device 20, the particles are repelled by all parts of the surface of the strip except for the negatively charged parts of the image. Most development processes involve the deposition of powder on the substrate base insignificant, and even then, Avemi them uncharged are. A suitable powder developing device is shown in FIG. Other Possible embodiments are described in U.S. Patents 2,357,809 and 2,573,881 shown while an apparatus for developing electrostatic images with the aid of an ink mist U.S. Patent 2,551,582.

The developed strip now travels through a melting device 15, in which it is below the drum 14 rotates and then moves back up to the conveyor roller 16. The melting device 15 consists, for example, of an oven heated to a sufficient temperature to melt the resin powder images. The drum 14 can also achieve the same result can be heated electrically. If the development is effected with the aid of liquid ink or the like, so the melting device serves only as a drying device for the ink. For strips made of plastic Plastics that are distorted by the heat, however, it is useful that the melting device consists of a chamber filled with air with the vapor of a solvent for the resin images, but is not saturated for the strip material. The solvent is absorbed by the powder, until it becomes sticky or semi-liquid. If the strip leaves the melting device, it evaporates Solvent, and it leaves a fixed resin image on the strip. When provided with a coating Paper can be used as a solvent for the plastic coating composition in which In case it is possible to use infusible electroscopic powders, since the powders are in the plastic or a coating consisting of wax that is embedded when passing through the Melting device is softened by heat or a solvent.

The powder developing device shown in FIG. 5 has a pair of rollers 64, 65 on. The roller 64 is ordered from a central axis 66 with two disks 67 spaced apart from one another, around the edges of which the strip runs. The strip is against a shift in the axial direction secured by flanges 68 on the outsides of the discs. After that the strip down and wandered around the roller 64, it moves back up and over a full roller 65 and from there down again into the melting device. In that of the strip as it circulates around the Role 64 formed channel is one of the development

Claims (16)

Serving powder or mixture 69 filled, which rolls on its surface as the strips circulate. The disks 67 hold the powder in the development space. During this process, the powder adheres to the image areas. The characters 35 are shown as raised types. However, they can also be encapsulated with an insulating compound in such a way that there are no longer any raised parts on the wheel circumference, with all these surfaces lying in the same cylinder plane, which is determined by the edge of the wheel 21. Furthermore, the character images surfaces can consist of a material of low conductivity, which are applied to a metallic wheel rim of high conductivity, so that a discharge takes place only from the image surfaces. Although it is convenient to make electrodes 39, 40, 41 and 42 positive with respect to the wheel, it has been found that the strip can be charged with positive charges by reversing the polarities. It is believed that this is the result of a Electron field emission from the film material forming the stripe. Accordingly, it is contemplated that the polarities can be reversed by reversing the terminals of the battery 45 and the anode and cathode connections of the triode. In this case the slide on the potentiometer 29 is moved from the grounding point to the negative side so as to give the strip a negative background charge. It is possible to provide two or more strips with independent circuits at spaced locations around a single character wheel which can record the same or a different signal or result at the same time. It is also possible to produce duplicate copies by arranging two or more rows of identical character images on the circumference of a wheel by providing additional electrodes 39 to 42, which are connected to the same pulse circuits and are arranged at an angular distance around the wheel that corresponds to the angular distance of identical character images is the same. In addition, two or more wheels can be operated synchronously and the corresponding electrodes 39 to 42 can be connected in parallel to the pulse circuits. The characters used can, in certain cases, be very small in size and the images can be recorded on a very narrow strip of transparent film material so that very little space is required to accommodate the recordings. Normal readable size copies can then be made by xerographic or photographic processes, or the images can be projected for viewing. Instead of fixing the powder images on the original strip, it is also possible to transfer the images to another strip or another surface, for example by means of an electrostatic transfer process. Furthermore, a method can be used in which the images to be transferred are pressed on rollers against a surface coated with an adhesive. In this way, the resin images can be transferred to offset paper and fixed thereon, whereupon they can be used for offset printing a large number of copies. Furthermore, the electrostatic images can be made in the form of mirror images and a developing powder can be used which contains an alcohol-soluble dye with a higher coloring power. Further copies can then be made by bringing paper moistened with alcohol into contact with the melted images, as in the case of the alcohol copying process. The examples described can be modified without departing from the scope of the invention. P A T E X T A X S P R C CII E: 1. A method for recording characters or numerals on a surface, characterized in that electrically conductive characters or numerals are brought into close proximity to an insulating surface and an electrical discharge is brought about between the end face of the characters and the insulating surface, so that a strong electric field is generated between the opposing surfaces, thereby creating an electrostatic image on the insulating material surface that corresponds to the shape of the text or number symbol. 2. The method according to claim 1, characterized in that the electric field is directed so that in the recording position electrons from the face of the character or number to the insulating material surface are driven. 3. The method according to claim 1 or 2, characterized in that characters or numerals are used which are formed raised on a conductive support and the strong electrical Field between the conductive support of the characters and the one behind the insulating layer conductive electrode is generated. 4. The method according to claim 2, characterized in that characters or numerals are used which are recessed on a conductive support. 5. The method according to claim 1 to 4, characterized in that the latent electrostatic Image is developed by applying a finely powdered material. 6. The method according to claim 5, characterized in that the finely powdered material on the Isolation material surface is fixed. 7. Device for recording a text or number image, characterized in that that the effective characters or numerals at a short distance and parallel to a counter electrode is brought, a layer of insulating material between the face of the character or number and the electrode is moved past and means for generating a strong electrical Field between the face of the character or number and the counter electrode are, which between the face of the font or number and the insulating layer a cause an electrical discharge so that an electrostatic image is formed on the insulating material layer, which corresponds to the shape of the characters or numerals. 8. Apparatus according to claim 7 for recording a plurality of different images, characterized by moving characters or numerals, with the help of which one of several different characters or numerals is to be brought into the recording position. 009 609/218 9. Apparatus according to claim 8, characterized in that that the insulating material is formed by a sheet or a strip attached to the Record position is moved forward, and that the strong electric field in the form of voltage pulses is created. 10. Apparatus according to claim 8 or 9, characterized in that the characters or numerals are applied to the circumference of a wheel that the insulating material between the wheel and the stationary electrode is moved past imd that the strong electric field is effective at the moment in which the recorded Characters or numerals appear opposite the counter electrode. 11. The device according to claim 10, characterized in that the characters or numerals on the wheel at a distance from one another at least on part of the order are arranged along a helical line and further arrangements are provided which give the insulating material an enva cylindrical shape which one portion comprises the wheel circumference with the recorded characters or numerals, the axis of the cylindrical surface of which extends concentrically in the wesentliehen to the rotational axis of the wheel and the \ ^T orschubmittel further promote the latter in a direction perpendicular to the helix direction with a speed of the layer of insulating material, such that the advance of the insulating material coincides with the slope of the helix, so that the selected writing or graphic symbols are recorded in lines on the insulating material when the writing or symbols with selected columns on the insulating layer come into congruence. 12. \ 'device according to one of claims 7 to Ii, characterized in that the electric field is directed so that in the recording position Electrons ve η the face of the font or number is driven towards the insulating surface will. 13. \ "device according to claim 7, characterized in that that the carrier of the font is made of a conductive material and the characters or symbols are raised and that the strong electric field between the conductive text or graphic symbol and the one behind the insulating material layer Electrode is generated. 14. Apparatus according to claim 12, characterized in that the carrier of the writing or Symbol consists of conductive material and the characters or symbols are arranged recessed in it is. 15. Device according to one of claims 7 to 14, characterized in that the or the electrostatic images developed by the application of finely powdered material or inks will. 16. The device according to claim 15, characterized in that that the applied material is subsequently fixed on the insulating material layer. Considered publications:
Journal of the Optical Society of America, VoI 38. No. December 12, 1948, pp. 991-998. 1 sheet of drawings © 009 609 218 9.60