DE2147536A1 - DEVICE FOR PRODUCING IMAGES - Google Patents

Description

Device for producing images.

The invention relates to a method and a device for production of images, with information either from an original document or from a electronic receipt applied to paper or another suitable recording medium will. In the case of the invention, this is done essentially with the aid of a control element or of control elements that control an electrical adjacent to the recording medium Create field; the receiving elements or the receiving element are in a Immersed in liquid.

Processes and techniques for producing visible images of an electrical input have been known for a number of years. facsimile Recording and copying machines using special paper are widely used common. Here the image is either made by the electrolytic Developing a color or by using an X e ett-i tric discharge produced for vaporizing or blowing a topping.

Furthermore, a method is known in which a spray discharge is carried out a thin pin is created, which is a short distance above an insulating surface stands - in general a paper, the surface of which is covered with an insulating thermoplastic Film is covered. This inclusion process is described, for example, in U.S. Patents 2,894,799; 3,064.2 @@@ 3,068,481; 3,131,256; 3,208,076; 3,217,330; 3,289,209; 3,383,697; 3,384,898; 3,409,899; 3,417,404; 3,434,157; 3,417,861.

Another method of producing images is in the US Pat. No. 3,121,375 describes a fundamental difference between the known The method and the present invention is the presence of a liquid when recording pen in the method and in the device according to the invention.

A number of devices are described below, wherein by using a liquid medium instead of air between the electrodes and the recording medium, there are several significant advantages, such as: 1) Realizing a much higher resolution than that using a electrical air discharge is possible; 2) a significant increase in the recording speed due to the speed with which the output from the pen forms the image (higher Modulation rate of the potential associated with the dispensing pen); 3) the recording and the development process take place simultaneously or almost simultaneously, whereby the Device for performing the recording method according to the invention simplified will.

Further important features of the invention emerge from the following Figure description. 1 shows a schematic view of a recording device; Fig. 2 is a partial view of a modified receiving pin; 3 shows the partial view a variant shape, partially cut, with a plurality of receiving pins is used; Fig. 4 is a plan view of a recording medium that is used by the device goes to Fig. 3; Fig. 5 is a modification showing a computer output represents operated copier; 6 shows a further modification with a row optical inputs; 7 to 9 further embodiments, FIG. 7 being a side view, 8 shows a view of the left half of the embodiment according to FIGS. 7 and 9 represents a diagram of the line arrangements; 10 schematically shows a further embodiment and FIG. 11 shows a further embodiment with a high take-up speed for electrical Entrances.

Corresponding parts have been crossed out in the figures Position numbers are used (e.g. position 12 in Fig. 1, 12 'in Fig. 10 and 12 "in Fig. 11).

Example 1 This example is illustrated by comparison with FIG clear.

The recording device according to FIG. 1 has a recording sheet serving as a medium 10 on which the image is made.

The recording sheet can be a plastic sheet or a be any type of paper. The receiving sheet 10 is rolled 16 through a tub 12 out, which contains a liquid developer 14. The recording sheet 10 can guided through the tub 12 by conventional means, not shown further will. The paper web can pass through the device continuously or intermittently be performed, e.g. if only a single image is desired. With A roller squeegee 18 removes the superfluous developer from the paper. on The remaining developer residues on the paper web are removed in a hot air arrangement 20 away. A receiving pen 22 has a pen tip 24, which consists of a coarse Wire tapered to a width of 2 to 3 mils (1 mil 1/1000 inch), is made; the tip can also be spherical and have a radius of approx. 5 to 20 mils. The receiving pin is over the surface of the receiving sheet or -blattes guided, the pen tip the surface of the sheet with a electromechanical drive 26 touches. A modulated voltage source 30 provides an electric field between the pin 22 and a conductive counter electrode 28 here.

The electromechanical drive that holds the pen on the recording sheet positioned, can be any known drive, for example an X-Y recorder with servo drive, where the pin is positioned in two directions or one High speed pen motor, or other suitable device.

It became a developer by grinding charcoal in a petroleum solution ("isobar G" manufactured by Humble Oil and Refining Company). The developer was diluted with the solution until the solid content was 0.5 percent by weight cheat. Other developers such as that described in U.S. Patent 3,259,581 proved to be effective.

With the above developer, dense lines became dense at a pen voltage absorbed by over 200V; here the pen 22 was with respect to the counter electrode 28 negative. The width of the lines can be varied from 1/4 mil to 10 mils, namely depending on the geometry of the pen tip and less depending on the given voltage. Dense lines were drawn through the. elelitrome chanis chen Drive achieved the highest speed, namely 5 (), 8 cm / sec (200 inch / sec), achieved. The optical density of the line increased to the maximum applied Voltage of 1200V.

Fig. 2 shows in a partial view a modified pin, wherein no larger container with developer liquid is required. Because of here The modification described is a device for quickly changing the developer provided, which means, for example, developers of different colors are quickly close at hand of the recording pen can be brought to change the color of the image. In In FIG. 2, the receiving sheet 10 is in turn held by a conductive counter-electrode 28.

The receiving pin 22 'is arranged in a cylindrical tube 32, which is open at the bottom and closed at the top. The hose-pin arrangement is positioned by the electromechanical drive 26. The modulated voltage source 30 gives off tension. The inner surface of a cylinder 32 contains the developing solution 14, which are circulated through an inlet hose 34 to an outlet hose 36 will. The liquid developer is added continuously through a container, namely through a. Solenoid valve with pump, not shown in detail. Through the It is possible to use electrically operated solenoid valves within a Less than a second from one developer of one color to one Change developer of a different color. Thus, not only the density of the Figure but also the color determined by the power source 30 at will will.

Example 2 The device outlined in FIG. 3 constitutes an apparatus for the inclusion of alphanumeric or other symbolic information. Here In contrast to the single pin of FIG. 1, seven pins 22 are used. By the timing of the pulses to the pens will be alphanumeric Characters (at a height of seven elements) formed. Fig. 4 is a schematic Top view of the recording system, with the recording film or paper 10 and the pins 22 are designated by letters a to g. The pens are in one Mounted recording head 40, which is used for scanning film or paper on an electromechanical Converter can be attached. The pulse generators and the logic for the pins are in an electronic package 42. The tips of the pens are in the not shown receiving liquid immersed.

The operation of this recording device is best suited to the game 4 will be explained. In this figure the sheet of film or paper is moving quickly from left to right.

The formation of the letter "h" is shown here.

If the characters are relatively large (e.g. of such a size that the signs can still be seen with the natural eye can be arranged in a vertical row. in this case the Letter "A" formed by energizing electrodes c, d, e, f and g one after the other, by giving impulses to bd, ad, bd and then to cdef and g. The time interval between each impulse characterizes the speed of the movement of the paper web and the distance between each letter in the direction of movement of the paper web. The pins shown in Fig. 3 and 4 are arranged one above the other so that the The distance between each adjacent pin increases by the distance that exists one would arrange the pins in a vertical row. This will make the Copy effect wiping the pens kept the possibility as small as possible a disturbance in the tension between the pins and the attachment eliminated and alignment of the pins simplified. These benefits are important when using pens with small dimensions are desired, e.g. alphanumeric characters in a Overall size of 10 mils or less. If the pins are unbalanced on top of each other suitable known electronic logic must be used, so that the time delays necessary for the formation of the lit characters can be adhered to.

It goes without saying that, if desired, the pens will continue can be, across the entire paper web in orthogonal or inclined Direction of path movement. An arrangement must be provided for the respective Select printing or writing pens from the large number of available pens.

Example 3 The device according to FIGS. 3 and 4 can be modified so that that it produces alphanumeric characters at a very high speed, from a computer output. An example of one from a computer outlet operated microfilm device is shown schematically in Fig. 5, where a plastic transparent plate 10 'in the form of a track, a counter electrode 28' and a scanning wheel 44 are shown. In the face of the scanning wheel 44 are four pin arrangements at a distance of 900 attached along the periphery. Each pin arrangement consists of seven superimposed pins of the type shown in Figs.

The modified device can be compared with those currently available on the market A computer output can be used on microfilm devices that use cathode ray tubes or a laser diode matrix are provided as an optical link. So is the film 10 is a 16-mm film and the recording is on a width of 12.7 mm (1/2 inch) of the film. The characters on the film are scaled down, like this that they can be seen normally at 26x magnification. The characters on of the film are 3 mils high and 4 mils wide.

The width of each recorded sub-area, corresponding to a discharge of a single pen, is 0.4 mil. There are four pin arrays over a surface of 12.7 mm along the periphery, is the diameter of the receiving disc 16.272 mm (0.64 inch). 10000 lines of alphanumeric characters are generated per minute recorded or 166 lines per second. The peripheral speed of the scanning wheel 44 is approximately 211 cm / sec (83 inches / sec) with the disk rotating at one speed of 2500 UpN. The entire arrangement is of course in the example 1 described developer liquid immersed. There is room for 132 in each line Characters, corresponding to a packing density? of 102.4 characters / cm (260 characters on 1.0 inch). From the Voiricillunge 22,000 characters per Second produced. Since the spacing of the picture elements is approximately 0.4 mil, the maximum Pulse rate to the pen 220,000 pulses / sec.

Since it is a direct electronic recording, is it is unnecessary to use intermediate optical members to produce the image. The picture is recorded on inexpensive transparent film. Because the That is, the mounting pins in the mounting head are asymmetrically arranged one above the other Procedure complicated only in that there is additional logic in appropriate training alphanumeric characters is required.

In a further modification, the scanning wheel can be driven by the drive with a high-speed motor of a writing device / can be replaced. In this case the pin assembly is mounted on the tip of the spring connected to a motor. Many of these motorized pens have a mechanical leveling; so that the scanner straight rather than curved. Lie over a scanning distance of 12.7 mm the required 166 touches per second within conventional requirements.

Example 4 In this example, a recording system with an optical Input described. In some respects, Examples 4 and 5 are similar to US Pat Disclosures in U.S. Patent 3,121,375. The main difference is that the examples of the mentioned patent the duplication developer on the side of the recording medium and show opposite the control electrode.

(With the exception of the capillary control of the duplicator). In the The embodiment described here is the control electrode in the liquid Immersed developer and communicates with the receiving surface.

The device shown schematically in Fig. 6 has one in one Line running optical input for controlling the pin potential, whereby a visible image is created on the recording paper 10. Position 28 is one Counter electrode. The liquid developer surrounding the tips of the pens is not shown. The pick-up head assembly consists of a glass plate 50 which is a cylindrical Has opening near its upper surface. A photocathode layer 56 is on the Surface of the glass hole attached. The photocathode, possibly made of cesium anion has the appropriate thickness to be electrically conductive. An electrical one Connection is between the photocathode and a DC power source 60. One Number of pins are stored in the glass receiving head 50; the pens consist of "KOVAR pens" with a diameter of 5 mils and they are arranged in centers of 10 mils.

The distance determines the resolution in the direction across the paper; in in this case 39.3 lines / cm (100 lines / inch).

In the operating position, an original document is placed behind a 10 mil wide slot or gap out, at a speed that the corresponds with which the paper 10 is guided under the receiving pin 22 ″. A device, not shown, transfers the exposed original to the photocathode. Optical devices that can be used for this are shown in FIG. 1 U.S. Patent 3,121,375.

The copier of Fig. 6 operates with negatives. So if the Exposure reflected off a white surface of the original on the photocathode 56 hits, electrons are ejected and from one connected to the pin 22 " Electrode collected, reducing the voltage of the electrode in relation to the counter electrode 28 becomes negative. Tension remaining in paper 10 is due to developer particles that have accumulated there.

The effectiveness of this procedure is determined by the following calculations explained. The capacitance between a single pin and the counter electrode is 10 picofarads, assuming a paper thickness of 3 mils. A total charge of 58 L coulombs per element is transferred from the photocathode to the pen in order to increase the potential of the pins by 1000V. Since there are about 106 discrete picture elements per copy sheet, the total amount of the copy transferred is Coulomb (provided that the entire sheet is printed).

At a speed of 50.8 mm / sec (2 inches / sec) per copy sheet the copy is made in 5 seconds, with the maximum current at the Recording is 1 µA.

The current potential of a pick-up pen is 1 / CX / idt, where C is the capacity and i is the charging current. Because the charging current is independent of the voltage is, the charging time corresponds approximately to the product of the potential difference through which an electrode is charged and its capacity is shared with respect to the counter electrode by the charging current per pen. Since the charging current of a single pen during the Operation is almost 10 9A, the charging time is 5 milliseconds. Thus the maximum recording time at minimum current level during operation 200 elements per second. Since 39.3 elements / cm (100 / inch) are picked up, the maximum pick-up speed is at lowest exposure level 50.8 mm / sec (21 / sec).

At higher exposure levels, the recording speed can be proportional increased, since the charging current is proportional to the exposure.

The sensitivity of a typical cesium antimony photocathode is 20jUA / lumen. In order to produce the required 1, A charging current, the photocathode 0.5 lumens required. Since the efficiency of the optical system is about 5 percent, the total light density of the scanned area on the original must be 1 lumen or amount more. The area of the 10 mil scanning bezel (215.9mm or 8 1/2 inch wide) is 0.0056 dm2 (0.0006 ft2). Therefore, the lighting level must be at the diaphragm 488 m Candela (1600fit) or more. Such illuminance levels can can easily be achieved with simple condenser lenses that use a tungsten halogen lamp map onto the aperture.

Example 5 Figures 7, 8 and 9 schematically illustrate a further modification , with the mapping concept described above an optical one Input can be controlled. In this embodiment, the voltage is the Pins modulated by a photoconductor. In Figs. 7 and 8, copy paper and

Copy film 10, counter electrode 28 and liquid developer 14 are arranged. A series of conductive elements and photoconductors are on a recording head arranged.

A pick-up head 60 consists of a glass or ceramic substrate 62, on which a series of conductive strips 64 are provided. Have these stripes 5 mils wide and are evenly and spaced at 10 mil centers arranged.

A single wide strip 66 of photoconductive material is arranged over the strip 64. The photoconductor may vary depending on the particular application to get voted. In a system of high sensitivity and low speed can be used to form the photoconductor cadmium sulfide or cadmium sulfoselenide will. In order to produce high recording speeds, a fast-reacting device must be used Photoconductors such as amorphous selenium can be used. The manufacture of such films and their characteristics are known (see R.Fotland in "Journal of Appied Physics, 31, 1158 (1960)). Two lead electrodes 68,69 are above the photoconductive one Film arranged, the electrode 69 must be semipermeable so that the incident Exposure can shine through the film while the second electrode 68 is semi-transparent or can be permeable. A power source 70 is between the two conductive strips tied together.

As can be seen from the circuit diagram of FIG. 9, the has Arrangement of a bridge, the two arms of which are formed by the photoconductor. After this one arm of the bridge is exposed, the potential at the recording electrode increases 64, and the image is formed on the recording paper.

Provided that the recording head is amorphous for the production of photociter is used, a lighting level similar to that described in l3ei £ s) iel 4 required, since the sensitivity of an amorphous soul layer is almost; zO1) A / lumen needed.

Example 6 This example describes an embodiment which has two significant advantages over the previous examples. The imaging system is shown in FIG. In contrast to the previously described embodiments, in which the image was developed directly on the die or film 10 it is formed here on the coated surface of a transfer roller 74. One Insulating layer 76 is uniform about 1 to 10 mils thick on the Role applied; the layer consists preferably of glass enamel, - because of it high strength, high abrasion resistance and easy cleaning.

Da.s by a control recording head 72, which is described above can correspond to the image attached to the surface is made by a transfer roller 78 transferred to the copy paper 10. In order to increase the effectiveness of this transfer can increase, or to ensure, between the rollers 74 and 78 a strong electrical Voltage prevail to cause the electrostatic transfer of the image from the roll to promote paper.

Residues of the image are removed by a cleaning brush 80 from the Insulating layer 76 removed.

One advantage of this approach is related to the reduction of the paper background. It has been shown that by direct immersion of the paper into the developer liquid when it is removed from the bath the liquid stick to the paper. When the liquid developer evaporates, solid particles remain on the paper, creating a low level of background arises.

This background level can be reduced by removing the copy paper placed in a bath with a solution before immersion in the liquid developer that does not contain any developer pigments.

The prebath allows pure solvent to penetrate the paper, which means the possibility of the uptake of solution-based pigments during the development process is decreased. In the embodiment of Fig. 10, the paper background is extraordinary clean, since only a small amount of solvent due to the hard insulating layer 76 is transmitted.

Another advantage of this embodiment is related with the problem of paper orientation (register) when producing full color Copies. By using color separation filters and three recording heads, this can Recording and imaging system described here for the production of color copies be used; for example, one such method is disclosed in U.S. Patent 3,121,375 described.

Any other known systems for producing colored Copies are used, it being sufficient if different recording heads and different color pigments can be used. With a three-color system there will be three separate recording heads required. These heads can be relatively close together be arranged along the copy paper; nevertheless, the recording heads are allowed to move but do not overlap, as the liquid developer is spatially along the paper web must remain separate. Provided a color image is produced by direct recording onto the paper the orientation of the image with respect to paper movement is dependent on the precision of the optical devices, the evenly successive ones Arrangement of the recording heads and the constant geometry of the paper movement through the three receiving stations. Because the paper stretches and in its dimensions changed, the alignment can be improved by the fact that the colored image with the arrangement of three recording heads spaced around the circumference of the transfer roller to be ordered. Due to the immutability of the roller surface, a precise alignment is achieved. The full color image can then be aligned on a copy paper can be transferred.

Example 7 In Fig. 11, the record of electrical inputs shown at high speed with the copy sheet 10 under a pressure roller 82 runs through it, which also serves as a counter electrode. Development occurs in the lenticular space between the copy sheet 10 and a roller 84. The lower Half of the space is immersed in a container 12 "of liquid developer. The roller 84 rotates at a surface speed that is greater than that of the pressure roller 82 so that the liquid developer is continuously supplied to the lens will. A wire 86 with high flexural strength is used to scan the paper; on Conductive recording pinballs 88 are disposed on the wire. For the one described here The intended use is a stainless steel wire of 0.762 mm (30 gauge) Proven, the balls are made by soldering or welding on stainless steel balls 30 mil diameter to the wire. The wire runs over roller bearings 90. A roller bearing is driven by a high speed motor 92. One with a power source 94 matched pickup signal is between the conductive roller 82 and the take-up wire 86 are provided. The receiving balls touch the surface of the paper and are spaced 215.9 mm (8 1/2 inches) along the scan wire attached, In one embodiment of this device, four balls are underneath evenly spaced along a 34 inch (86.36 cm) endless loop of wire arranged. The drive rollers are 3 inches in diameter and the drive motor has a speed of 12,000 rpm. A ball can be a 86.36 cm (8 1/2 inch) wide copy sheet at one speed. of 457.2 Scan cm / sec (1800 inch / sec) and produce 225 scans or recordings. the Samples are located on 10 mil centers; thus the amount for the production time required for a copy 5 seconds. As it is desirable to have about 800 resolvable The collection rate is to have elements available distributed across the paper surface (bit rate) about 180000 bit / sec; the modulation bandwidth must therefore be around 100 kHz be.

This fast-working facsimile process has the advantage of being closed, faster operation and also allows the use of conventional paper.

In summary, mean the amendments that include inclusion pen and developer are on the side of the recording media and with the pen immersed in the developer is significant for a number of work areas Advantages. The input can be both optical and electrical. The procedure is relatively simple.

Line widths of less than 1/4 mil were achieved, reducing the Possibility of micro-imaging or recording can be envisaged. The writing speed on film is over 3 m / sec (120 inches / sec). The maximal modulation rate and the Writing speeds are still limited by currently available devices; not but the procedure itself.

Patent or protection claims

Claims (8)

Patent or protection claims> recording device, marked by at least one recording pin, a device for moving a recording medium (10) relative to the receiving pin (22), with which one end of the pin (22) in direct Is maintained in contact with the recording medium (10), the end of the pin (22) is immersed in a liquid developer (14), through 2 each side of the medium (10) arranged counter-electrode (28), which is in contact with the pin (10) Side is opposite, and by an arrangement with which the receiving pin (22) a signal is supplied which contains the information to be recorded. 2. Recording device according to claim 1, characterized in that the Developer liquid (14) is held in an area surrounding the pen (22). 3. Recording device according to claim 1, characterized in that a electrical voltage source (30) between the receiving pin (22) and the counter electrode (28) is provided. 4. Recording device according to claim 1, characterized in that one A plurality of recording pins (22) is arranged transversely to the recording medium (10). 5. Recording device according to claim 1, characterized in that the recording medium (10) is a tape. 6. Recording device according to claim 4, characterized in that the Locating pins (22) are a multitude of fine wires that are insulated into one Bracket are embedded. 7. Recording device, characterized by at least one receiving pin (72), a device for moving a rotating, conductive drum (74) with an insulating surface (76) relative to the receiving pin (72) having one end the receiving pin (72) is held in direct contact with the drum (74), which end is in a liquid developer (14) by an arrangement to feed a cife up. information to be recorded on the drum Signal between drum (74) and pen (72) and through a device for making contact of a recording medium (10) with the drum (74), the information path from the drum to the medium. 8. Recording device according to claim 3, characterized in that at least an electro-optic transducer is provided that controls the potential between the pickup pin (22) and the counter electrode (28) controls, and that optical devices are provided that map an optical signal on the electro-optical transducer.