RU2169666C1 - Method for jet printing and printer for its realization - Google Patents

Abstract

FIELD: printing arts. SUBSTANCE: the method consists in transfer of drops of printing ink from the plate to the medium, directing simultaneously two radiating pulses - a powerful clock pulse and a weak control pulse to each preset point of the ink layer. A luminous hydraulic effect arises only due to the energy of both pulses in these points, causing a powerful acoustic pulse and ejection of ink drops from the preset points to the medium. Effect of radiating pulses on the preset points of the ink layer is possible in the following combinations: clock and control pulses - pulses of coherent radiation, clock and control pulses-pulses of non-coherent radiation. The printer used for realization of the given method of printing has a printing plate made of material that is transparent for investigation of preset length of the wave moving synchrously with the information-carrying medium, and generators radiating the clock and control pulses. At an action on all the points of the ink layer equally spaced on the plate surface on the same straight line by clock pulses simultaneously with control pulses in those of them, from which it is necessary to eject drops of ink, powerful acoustic pulses and transfer of ink on information-carrying medium arise in the mentioned points. Then, the plate and the medium displace by a step, and this process repeats up to the transfer of the programmed image to the medium. EFFECT: enhanced printing speeds at a minimum power consumption for ejection of ink drops irrespective of the printing speed and the width of the medium tape. 13 cl

Description

 The invention relates to printing devices. More specifically, the invention relates to means for printing, in which the transfer of droplets of ink from a form onto a carrier is effected by pulses of laser radiation.

 There is a method of inkjet printing, which consists in placing the information carrier opposite the printing form with a smooth smooth surface, applying a continuous uniform layer of paint on this surface, exposing the given points of the ink layer to light pulses, generating a light-hydraulic effect at the indicated points of the ink layer to transfer drops from them paints on a carrier (RF patent N 2096183, class 6 B 41 J 2/015).

 In the known method, the dropping of droplets of paint from a mold onto a carrier is effected by the energy of a light pulse, which, although significantly less than when dropping droplets due to the thermal effect, is still excessively large in order to either transfer droplets of paint from all given points of one line, or provide scanning of lines with high speed. An increase in printing speed to that achieved by mechanical printing devices leads to an increase in the power of light sources to a value that is difficult not only to create, but also to realize.

 The printing device, implemented according to the aforementioned patent, comprises a printing form placed opposite the carrier, means for applying ink to the form, means for generating radiation pulses, and means for focusing these pulses on predetermined points of the ink layer on the form to eject ink droplets from them. The means for generating pulses provided in this device is a laser, the power of which should be the greater, the higher the printing speed and the line width of the medium. Therefore, the known device can be used only at low printing speeds, and it can not compete with mechanical printing devices in printing speed.

 The basis of the invention is the creation of such a method and a printing device that would allow for high printing speeds with minimal energy consumption for the emission of droplets of ink, regardless of the printing speed and width of the media.

 The problem is solved in that in the method of inkjet printing, which consists in placing the information carrier opposite to the printing form with a smooth smooth surface, applying a continuous uniform paint layer to this surface, exposing the given points of the paint layer to light pulses, exciting the light-hydraulic layer at the indicated points of the paint effect for transferring droplets of paint onto the carrier from them, in accordance with the invention, the light-hydraulic effect at each given point is excited from several their pulsed radiation sources, for which radiation from these sources is sent simultaneously to the same point.

 With this printing method, the energy necessary to eject droplets of ink from predetermined points is divided between several radiation sources, which allows limiting the power of each of them without compromising the printing speed.

 It is advisable that a powerful clock and weak control pulses of radiation from various sources are directed to each given point of the paint layer and that the photoelectric effect at the given point of the paint layer is caused only by the combined action of these pulses.

 With this printing method, it is possible to minimize the energy that must be added to the energy of the clock pulse in order to cause a photohydraulic effect at a given point.

 It is advisable that all points located in a straight line with the same pitch are simultaneously affected by powerful clock pulses of radiation, and those of these points at which it is necessary to cause a light-hydraulic effect are simultaneously affected by control pulses of radiation.

 With this printing method, only one clock pulse is needed to transfer all drops of one line from the form to the carrier, which minimizes the power of its radiation source. At the same time, minimizing the energy of the control pulses also allows the use of low-power radiation sources for this purpose.

 It is advisable that the pulses of coherent radiation are used as clock and control pulses.

 With this printing method, it is possible to remove clock and control pulses from the printed form of radiation sources and supply them to predetermined points of the form by means of optical communication lines.

 It is advisable that as the clock and control pulses are used, respectively, pulses of incoherent and coherent radiation.

 With this printing method, it is possible to use cheap radiation sources of clock pulses.

 It is advisable that pulses of incoherent radiation are used as clock and control pulses.

 With this printing method, it is possible to use cheap radiation sources of clock and control pulses.

 It is advisable that the spot of the radiation pulse focused on a given point is larger than the focus of the radiation of the control pulse focused on the same point.

 With this method of printing a clock pulse, an ink layer is activated in the area of the corresponding points, thus prepared for the action of control pulses.

 The problem is also solved by the fact that in a printing device containing a printing form located opposite the information carrier, means for generating radiation pulses and means for focusing these pulses at predetermined points of the ink layer on the form for ejecting paint droplets from them, in accordance with the invention, means for The generation of radiation pulses contains several generators, the radiation of which is focused simultaneously on given points.

 With this embodiment of the printing device, the power of each of the sources of pulsed radiation can be drastically reduced.

 It is advisable that in the printing device one of the generators of the means for generating radiation pulses generates powerful clock pulses focused on all points of the ink layer, located in a straight line with the same pitch between them, and the remaining generators emit control pulses focused on those points of this series, of which it is necessary to eject droplets of paint onto the carrier.

 With such a design of the printing device, the necessary radiation power of the control pulses can be so reduced that the generators of these pulses can be combined into a line of emitters, which in turn will lead to a sharp increase in the printing speed.

 It is advisable that in the printing device, the means for focusing radiation pulses contains focusing devices for clock and control pulses of radiation and that focusing devices for clock pulses are configured to focus radiation at a given point on the surface of the ink layer into a spot of a larger diameter than focusing devices of control pulses.

 This embodiment of the printing device will most effectively use the interaction of the emitters of clock and control pulses.

 It is advisable that in the printing device the clock and control pulse generators are made in the form of coherent radiation generators, while the clock pulse generator is connected via optical fibers to all points of the printing form located at the same pitch on one straight line perpendicular to its direction of movement, and the number of control generators corresponds to the number of points on the form to which the ends of the optical fibers are connected, these generators are assembled on a common basis and form a line of emit oil.

 This embodiment of the printing device will significantly reduce its dimensions, since the clock emitter will be removed from the printing form and connected with it only by means of optical fibers.

 It is advisable that in the printing device, the clock and control pulse generators are respectively made in the form of incoherent and coherent radiation generators, their number corresponds to the number of dots on the form placed with the same pitch on one straight line, perpendicular to the direction of its movement, and each of these generators forms a pair, acting by its radiation on the corresponding point of the form.

 This embodiment of the printing device will reduce its cost by using inexpensive emitters for the formation of clock pulses.

 It is advisable that in the printing device the clock and control pulse generators are made in the form of incoherent radiation generators, their number corresponds to the number of dots on the form placed with the same pitch on one straight line, perpendicular to the direction of its movement, and each of these generators form a pair acting by its radiation to the corresponding point on the form.

 This embodiment of the printing device allows to simplify its design through the use of simple and inexpensive emitters of clock and control pulses.

The invention is further illustrated by the description of specific, but not limiting, embodiments of the invention and the accompanying drawings, in which:
FIG. 1 - the proposed method of inkjet printing;
FIG. 2 is a section II in FIG. 1;
FIG. 3 - the same, when scanning the radiation of the control pulse;
FIG. 4 is a general view of a printing device;
FIG. 5 is a section II-II in FIG. 4.

 The best embodiments of the invention.

 The proposed method of inkjet printing is as follows.

 The storage medium A is placed opposite the printing plate B (Fig. 1) with a smooth smooth surface C. A paint layer D is applied to the form. Ray E from a pulsed radiation source F and beam H from a pulsed radiation source K are directed to a predetermined point of the paint layer on the surface of the form B, transparent for rays E and H.

 A light-hydraulic effect occurs at the interface between the paint and the surface of the mold under the action of energy released simultaneously by radiation pulses from sources F and K. This effect is characterized by the release of tremendous energy in an insignificant volume of paint adjacent to the surface of the mold, resulting in tremendous pressure, up to hundreds of atmospheres. The powerful acoustic impulse caused by this pressure will tear off a drop L from the paint layer D and transfer it to carrier A. The energy emitted by the pulse of any of the radiation sources F or K is not enough to produce a light-hydraulic effect. This effect will occur only with the simultaneous action of both radiation sources. Only then will their total energy be sufficient for the appearance of an acoustic impulse.

 It is advisable that the radiation energy of one of the sources is an insignificant part of the energy necessary for the occurrence of an acoustic pulse. In this case, a powerful pulse E will be clocked and will act from one radiation source at the same time on all points located at the same pitch on one direct printing plate, and a weak pulse H will be the control pulse and will affect those points on this straight line from which it is necessary drop droplets of paint. Moreover, the control pulses can act either each on its own point from independent sources (Fig. 2), the number of which corresponds to the number of points located with the same pitch on one straight line on the surface of the form, or alternately on each point on this straight line when scanning radiation from one source (Fig. 3). In this case, during the action of the clock pulse, the control pulses must have time to interact with all points on this line.

 In all embodiments of the proposed method, it is advisable that the spot of the radiation of the clock pulse focused on a given point is larger than the focus of the radiation of the control pulse focused on the same spot of the radiation.

 The proposed method can be implemented both in the case when the clock and control pulses emit sources of coherent radiation, and in those cases when these pulses emit sources of incoherent and coherent radiation, respectively, and when these pulses emit sources of incoherent radiation.

 From the above description of the proposed method, it is obvious that for the concentration at a given point of the paint layer of energy necessary to create an acoustic pulse at this point and eject a drop of paint from it, the total value of this energy can be obtained by adding radiation pulses directed from different sources, which allows you to minimize primarily the energy of the control pulses and reduce the power of the clock source by reducing the frequency of the pulses.

 To implement the proposed method of inkjet printing, it is necessary to ensure the concentration at a given point of the ink layer on the form of energy from different radiation sources, sufficient to create an acoustic pulse at this point.

 The proposed printing device comprises a printing form 2 located opposite the information carrier 1, a means 3 for applying ink to a form 2, a means 4 for generating radiation pulses and a means 5 for focusing these pulses on predetermined points of the ink layer on the form for ejecting paint droplets 6 from them. The printing form 2 can be made in the form of an endless ribbon 7 (Fig. 4) from a material transparent to radiation pulses of a given wavelength. The means 3 for applying paint to the mold contains rotating rollers 8 and 9, transferring the paint from the container 10 to the surface 11 of the mold 2. The drives for rotating the rollers 8 and 9, the endless belt 7 and the carrier movement are not shown.

 The means 4 for generating radiation pulses contains two generators 12 and 13, one of which, 13, generates radiation clock pulses that follow one another with the frequency of the lines of the carrier when it moves relative to the line on which the radiation from all generators focuses, and 12 - control impulses.

 If the generators 12 and 13 generate pulses of coherent radiation, then the clock pulses from the generator 13 (laser) simultaneously enter the optical fibers 14 and are fed to the corresponding points located at the same pitch on one straight line, perpendicular to the direction of movement of the tape 7 of form 3. To the same points from the respective generators 12 (low-power lasers) through the focusing device 15 receives control pulses. In this case, the control pulse generators can be assembled together with focusing devices in a compact line of lasers. If the clock generator generates pulses of incoherent radiation, then it can be made, for example, from powerful IR LEDs, the radiation of which is focused in a line of the required length with a width of 50-100 microns. If the generators of not only clock but also control pulses emit incoherent radiation, then powerful LEDs can also be used as these generators, the focused radiation of which is directed to predetermined points of the paint layer for joint action with the radiation of clock pulses.

 The proposed printing device operates as follows.

 When the endless tape 7 is moved with a paint layer applied to its surface and the carrier 1 is synchronized with it, the clock pulse generator simultaneously emits clock pulses directed to all points of the paint layer, placed on the same line with the same pitch, and the control pulse generator to those points in this line, from which it is necessary to throw out drops of paint. The light-hydraulic effect that has arisen at these points as a result of a simultaneous joint action of clock and control pulses on the paint causes powerful acoustic pulses that transfer paint droplets from predetermined points of the paint layer to the medium. Then the tape 7 of the form 2 and the carrier 1 are moved to a step, and the described process is repeated. This continues until the image specified in the program is applied to the medium.

 The inkjet printing method and the printing device are intended for visual display with high resolution and speed of text and graphic information on any type of media with minimal energy costs for transferring ink droplets from the form to the medium and the minimum power of pulsed radiation sources.

Claims (13)

 1. The method of inkjet printing, which consists in placing the information carrier opposite the printing form with a smooth smooth surface, applying a continuous uniform paint layer to this surface, applying light pulses to the given points of the ink layer, exciting the light-hydraulic effect at these points in the ink layer to transfer it from them drops of paint on the carrier, characterized in that the photoelectric effect at each given point is excited from several pulsed radiation sources, for which teaching from these sources is sent simultaneously to the same point.  2. The method according to claim 1, characterized in that a powerful clock and weak control pulses of radiation from various sources are directed to each given point of the paint layer, and that the light-hydraulic effect at a given point of the paint layer is caused only by the combined action of these pulses.  3. The method according to claim 1 or 2, characterized in that all points located in a straight line with the same pitch are simultaneously affected by powerful clock pulses of radiation, and those of these points at which it is necessary to cause a light-hydraulic effect are simultaneously controlled by control pulses of radiation.  4. The method according to any one of claims 1 to 3, characterized in that the pulses of coherent radiation are used as clock and control pulses.  5. The method according to any one of claims 1 to 3, characterized in that the pulses of incoherent and coherent radiation are used respectively as clock and control pulses.  6. The method according to any one of claims 1 to 3, characterized in that the pulses of incoherent radiation are used as clock and control pulses.  7. The method according to any one of claims 1 to 7, characterized in that the spot of the radiation of the clock pulse focused on a given point is larger than the focus of the radiation of the control pulse focused on the same point.  8. A printing device comprising a printing form located opposite the information carrier, means for applying ink to the form, means for generating radiation pulses, and means for focusing these pulses on predetermined points of the ink layer on the form for ejecting paint droplets from them, characterized in that the means To generate radiation pulses, it contains several generators whose radiation is focused simultaneously on given points.  9. The printing device according to claim 8, characterized in that one of the generators of the means for generating radiation pulses generates powerful clock pulses focused on all points of the ink layer, located in a straight line with the same pitch between them, and the remaining generators emit control pulses, focused on those points in this series from which it is necessary to eject droplets of paint onto the substrate.  10. The printing device according to claim 8 or 9, characterized in that the means for focusing radiation pulses contains focusing devices for clock and control pulses of radiation, and that the focusing devices of clock pulses are configured to focus radiation at a given point on the surface of the paint layer in the spot larger diameter than the focusing device control pulses.  11. The printing device according to any one of claims 8 to 10, characterized in that the clock and control pulse generators are made in the form of coherent radiation generators, while the clock pulse generator is connected via optical fibers to all points of the printing form located at the same pitch on one straight, perpendicular to its direction of motion, and the number of control generators corresponds to the number of points on the form, to which the ends of the optical fibers are connected, these generators are assembled on a common basis and Name a line of emitters.  12. A printing device according to any one of claims 8 to 10, characterized in that the clock and control pulse generators are made respectively in the form of incoherent and coherent radiation generators, their number corresponds to the number of dots on the form placed with the same pitch on one straight line, perpendicular to the direction its movement, and each of these generators forms a pair, acting with its radiation on the corresponding point in the form.  13. A printing device according to any one of claims 8 to 10, characterized in that the clock and control pulse generators are made in the form of incoherent radiation generators, their number corresponds to the number of dots on the form placed with the same pitch on one straight line, perpendicular to the direction of its movement, and each of these generators forms a pair, acting by its radiation on the corresponding point in the form.

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