Abstract: An ink jet recording method is provided in which an ink jet head having a first nozzle array and a second nozzle array which is arranged along the first nozzle array, in which the distance between the first nozzle array and the second nozzle array is 15 mm or greater and a nozzle density of the first nozzle array and a nozzle density of the second nozzle array are 600 dpi or greater is used, and while varying the relative position of the ink jet head in a direction intersecting an array direction of the first nozzle array and the second nozzle array with respect to a recording medium, an ink composition is adhered to the recording medium by performing a scanning which discharges the ink composition at a frequency of 12 kHz or greater from nozzles in the first nozzle array and the second nozzle array.

Abstract: A liquid ejecting head includes: a head casing including a plurality of block-shaped portions and a plurality of plate-shaped portions, the plate-shaped portions including a first plate-shaped portion and a second plate-shaped portion which are staggered, the first plate-shaped portion arranged next to both the first and second block-shaped portions, the second plate-shaped portion arranged next to both the first and second block-shaped portions; a plurality of flow channel units, each of which is fixed on a surface of corresponding one of the block-shaped portions, the flow channel units including: a first flow channel unit that includes a first nozzle plate; and a second flow channel unit that includes a second nozzle plate, the first and second nozzle plates which are staggered; and a plurality of drive units configured to eject liquid from the flow channel units.

Abstract: A method of manufacturing a printhead includes providing a substrate and a filter membrane structure. A first portion of the substrate defines a plurality of nozzles and a second portion of the substrate defines a plurality of liquid chambers. Each liquid chamber of the plurality of liquid chambers is in fluid communication with a respective one of the plurality of nozzles. The filter membrane structure is adhered, for example, laminated, to the second portion of the substrate. Each liquid chamber of the plurality of liquid chambers is in fluid communication with a distinct portion of the filter membrane structure. Pores are formed in the filter membrane structure using a photo-lithography process.

Abstract: The disclosure relates to a method and apparatus for preventing oxidation or contamination during a circuit printing operation. The circuit printing operation can be directed to OLED-type printing. In an exemplary embodiment, the printing process is conducted at a load-locked printer housing having one or more of chambers. Each chamber is partitioned from the other chambers by physical gates or fluidic curtains. A controller coordinates transportation of a substrate through the system and purges the system by timely opening appropriate gates. The controller may also control the printing operation by energizing the print-head at a time when the substrate is positioned substantially thereunder.

Abstract: In an inkjet head which has nozzle rows having nozzles each of which ejects curable inks cured by imparted activation energy and which are arranged in a first direction at a pitch P, the nozzle rows being N (N?5) nozzle rows of every color which eject, respectively, thick inks of four colors including cyan, magenta, yellow and black, and at least one light ink among light inks similar in color tone to the thick inks, the nozzles in each of the nozzle rows are arranged so as to be shifted by P/N from each other in a first direction, a nozzle of an ink with lowest cure sensitivity is arranged on the most upstream side in a direction of relative movement of a recording medium in the first direction, and further the nozzle of light ink is arranged in between the nozzles of two different thick inks.

Abstract: (Problem to be Solved) To appropriately restrain occurrence of striped variation and to appropriately enhance image quality of a printed result. (Solution) An inkjet printer in which multi-gradation printing is performed in an inkjet method includes an ejection control section for controlling ejection of ink droplets by supplying an ejection control signal to a nozzle for controlling ejection of the ink droplets from the nozzle of an inkjet head. The inkjet head forms lines of ink dots juxtaposed in a line direction so that the lines are juxtaposed in a direction perpendicular to the line direction. In a case that a nozzle which forms a line is the abnormal nozzle, an ejection control signal corresponding to an ink dot size which is different from a case of the normal nozzle is supplied as the ejection control signal corresponding to a part of the dots juxtaposed in the line, thereby an average value in the line of ejection errors is brought close to zero.

Abstract: An alignment method includes: disposing an alignment mark provided to a positioned member and a reference mark provided to a surface of an alignment mask so that the alignment mark and the reference mark can face each other; capturing an image from the other surface side of the alignment mask, which is the opposite surface of the alignment mask from the surface where the reference mark is disposed, the image concurrently showing the alignment mark and the reference mark; performing a surface treatment on at least a region of the positioned member side of the alignment mask, which is captured as the image, rather than on the reference mark side thereof, the surface treatment providing a high contrast ratio to each alignment mark and reference mark on the captured image; and thereafter aligning the alignment mark with the reference mark, while checking the image.

Abstract: There is provided a discharge head including: a tubular member that includes a flat portion with an oblate shape where a cross-section of a tube path extends in a first direction, the tubular member being formed so that the flat portion includes a first wall that is flat and has an actuator attached to an outside thereof and the flat portion becomes a cavity with an internal volume thereof varying due to displacement of the first wall; and a nozzle opening that is provided at one end of the tubular member and discharges a liquid substance due to variation in the internal volume of the cavity.

Abstract: A process for producing a chip in which plural ejection orifice arrays are arranged including conducting reduction projection exposure plural times to a wafer having a substrate and a photosensitive resin layer formed thereon while relatively moving positions of the wafer and a reticle to form ejection orifice array patterns in the resin layer, developing the patterns to form ejection orifice arrays in the resin layer, and dividing the wafer to form plural chips in which the plural ejection orifice arrays are arranged. The exposure is conducted once to form in the resin layer a first ejection orifice array pattern corresponding to partial ejection orifice arrays in an arranging direction thereof in one chip, a second ejection orifice array pattern corresponding to all ejection orifice arrays in one chip and a third ejection orifice array pattern corresponding to partial ejection orifice arrays in an arranging direction thereof in one chip.

Abstract: A fluid discharge head semiconductor device, comprising a terminal unit including first pad group including a plurality of pads, a processing unit configured to process input information from the first pad group, a printing unit including a plurality of printing elements configured to discharge a printing material in accordance with a result of the processing, and an inspection output unit including second pad group including at least one pad and an output buffer unit, wherein the processing unit outputs information on an inspection of an operation to the inspection output unit, and the inspection output unit drives the output buffer unit to output the information to the second pad group when performing an inspection, and suppresses the driving of the output buffer unit when performing printing.

Abstract: An ink jet printing apparatus, for each level, employs a plurality of density patterns to prevent cancellation of a granularity reduction effect that has been provided by an increase in resolution. Specifically, when determining an arrangement of dot-on areas in the density pattern, the dot-on areas is not located in the areas of a first row of the each of the plurality of density patterns. Thereby, whitish areas appear with the same cycle as a use cycle of the density patterns in a longitudinal direction and thus the whitish areas is not unevenly located. As a result, granularity is prevented from increasing.

Abstract: According to one embodiment, an inkjet head includes a substrate, a nozzle plate which includes nozzle lines, each of which includes nozzles, the nozzles which are included in one of the nozzle lines and the nozzles which are included in another of the nozzle lines alternating with each other, and forming one imaginary nozzle line, piezoelectric members which are opposed to the respective nozzle lines, and groove parts which are provided in each of the piezoelectric members, the groove parts corresponding to the nozzles to eject ink from the nozzles and being processed by cutting edges, one of the groove parts which corresponds to one of the nozzles in the imaginary nozzle line and another of the groove parts which corresponds to another nozzle adjacent to the nozzle in the imaginary nozzle line being processed by the cutting edges which are independent of each other.

Abstract: Provided is a method for manufacturing a liquid discharge head, the liquid discharge head includes a substrate provided on a surface with a first energy generating part and a second energy generating part for generating energy utilized for discharging a liquid; a first discharge port provided corresponding to the first energy generating part so as to face the surface; a second discharge port provided corresponding to the second energy generating part so as to face the surface; a first wall member which has a wall of a first liquid flow path which communicates with the first discharge port; and a second wall member which has a wall of a second liquid flow path which communicates the second discharge port, wherein a distance between the second energy generating part and the second discharge port is greater than a distance between the first energy generating part and the first discharge port.

Abstract: In a head chip, a cover plate includes a positioning reference provided at a position facing at least one of nozzle holes through at least one liquid jet channel. The positioning reference can be detected from underneath the nozzle plate through the nozzle hole and the liquid jet channel. A method of manufacturing the head chip includes a positioning step for positioning the nozzle plate by detecting the positioning reference provided in the cover plate.

Abstract: A method for adjusting a head module of an inkjet head in which a plurality of head modules having nozzles capable of ejecting droplets are connected and linked together is disclosed. The inkjet head has an overlapping region in which an arrangement sequence of the head modules corresponding to the ejected droplets is alternate between adjacent head modules. The method includes the steps of: obtaining, among intervals between the droplet ejected by one of the head modules and the droplet ejected by another one of the head modules in the overlapping region, a largest interval between the droplets in a direction of alignment of the head modules based upon movement of the droplets caused by a landing interference; and adjusting the adjacent head modules in a direction to decrease the largest interval between the droplets.

Abstract: An ink jet printing device (1) for printing multicolored images has an essentially horizontally extending conveyor mechanism (2) for moving items to be printed (3) lying on it in a forward feed direction (4), and a print head arrangement (5) disposed above the conveyor mechanism (2) which is disposed stationary relative to the conveyor mechanism (2) during the printing process. The print head arrangement (5) is made up of several print heads (6) each with several nozzles disposed in a nozzle row (26), and the nozzle rows (22) have a printing range width (24) as measured perpendicular to the forward feed direction (4) which forms a total printing range width (27) of the print head arrangement (5) corresponding to the number of print heads (6). The print head arrangement (5) is disposed so that it can be displaced vertically on a guide (10) and a nozzle rinsing device (14) is provided which can be positioned underneath the print head arrangement (5) as and when necessary.

Abstract: A printing head configured to apply white light-blocking ink, specialty gloss ink, and color ink is controlled, and the inks are applied so that the color ink, the specialty gloss ink, and the white light-blocking ink are formed in this order onto a printing medium having light-transmissive properties. When the printing medium is viewed from the surface on which ink has not been formed, a white ink layer is formed behind the color ink layer and the metallic ink layer, and light-blocking properties can be ensured. Because the amount of the metallic ink can be reduced, adequate expression of the color ink can be ensured.

Abstract: An inkjet ink set containing a first pigment ink and a second pigment ink. The first pigment ink includes an anionic self-emulsification ether polyurethane, and the second pigment ink includes a styrene acrylic resin emulsion.

Abstract: The liquid ejection head capable of securing a high performance of supplying liquid through supply ports while reducing the size of the substrate is provided. The liquid ejecting apparatus using such a liquid ejection head are also provided. The third supply ports situated between the first ejection port array and the second ejection port array include a portion of a large dimension and a portion of a small dimension.

Abstract: A pattern film formation method includes: discharging liquid from at least one first nozzle toward a first pattern film formation region on a substrate; and discharging liquid from a plurality of second nozzles toward a second pattern film formation region that is narrower than the first pattern film formation region. A number of the second nozzles is greater than a number of the at least one first nozzle.

Abstract: An image forming apparatus includes: a transport section including a first transport section configured to transport the recording medium in a first direction having a component of a downward direction in a vertical direction, a second transport section configured to transport the recording medium in a second direction having a component of an upward direction in the vertical direction, and a third transport section configured to connect the first transport section and the second transport section; a first head provided to face the first transport section and includes a plurality of first nozzles formed in different positions in the vertical direction; a second head provided to face the second transport section and includes a plurality of second nozzles formed in different positions in the vertical direction; and a control device configured to control the transport section, the first head, and the second head.

Abstract: A printing apparatus is provided in which a position of a joint of a first yellow nozzle group and a second yellow nozzle group in a predetermined direction is offset from a position of a joint of a first magenta nozzle group and a second magenta nozzle group in a predetermined position and a position of a joint of a first cyan nozzle group and a second cyan nozzle group in the predetermined position, and the position of the joint of the first magenta nozzle group and the second magenta nozzle group in the predetermined position is the same as the position of the joint of the first cyan nozzle group and the second cyan nozzle group in the predetermined direction.

Abstract: There is provided an inkjet print head, including: a first pressure chamber connected to a first channel and including a first nozzle formed therein; and a second pressure chamber connected to a second channel and including a second nozzle formed therein, the second nozzle being connected to the first pressure chamber.

Abstract: A controller includes an information transferring unit in a main control unit. A mechanical controller transmits device state information at predetermined time intervals. The information transferring unit performs some processing on the device state information received from the mechanical controller as necessary and stores the information in a second storage unit. Upon receiving a device state acquisition command from a host control unit, the information transferring unit transmits device state information read out from the second storage unit to the host control unit as a response to the device state acquisition command.

Abstract: An image recording apparatus has low intensity ink ejection parts for ejecting low intensity ink, and a high intensity ink ejection part for ejecting high intensity ink. With respect to a direction orthogonal to a moving direction of printing paper, a pitch of outlets in the high intensity ink ejection part is larger than that in the low intensity ink ejection part. Thus, manufacturing cost of the apparatus is reduced. With respect to each gray level in a middle grayscale range, if a tint image is recorded with the high intensity ink, a spatial frequency of this tint image is lower than that of a tint image recorded with the low intensity ink. By the above image recording control, even if the high intensity ink ejection part includes an abnormal outlet where a flight direction of droplet is abnormal, streak unevenness in a color halftone image can be suppressed.

Abstract: An inkjet recording head substrate having an electrothermal transducer for generating thermal energy used to discharge ink and a drive element for driving the electrothermal transducer mounted thereon includes a first circuit portion for outputting selection signals for selecting the electrothermal transducer to be driven at a amplitude level of a second voltage higher than a first voltage based on an input signal of the amplitude level of the first voltage, a second circuit portion for inputting the selection signals from the first circuit portion and controlling the drive element corresponding to the electrothermal transducer to be driven based on the selection signals subject to the second voltage, and a plurality of signal lines for transmitting the selection signals between the first and second circuit portions.

Abstract: Provided is a liquid ejecting method, including: ejecting a liquid from a liquid ejecting head, wherein the viscosity of the liquid is in a range from 6 mPa·s to 20 mPa·s, wherein the liquid ejecting head includes: nozzles which eject the liquid; a pressure chamber which applies a pressure variation to the liquid in order to eject the liquid from the nozzles; and a supply unit which communicates with the pressure chamber and supplies the liquid to the pressure chamber, and wherein the opening area of the nozzles on the side in which the liquid is ejected is 1/10 or less of the opening area of the opening of the supply unit on the pressure chamber side.

Abstract: A printhead and a method of ejecting liquid droplets are provided. The method includes providing a printhead operable to eject liquid drops having a plurality of drop volumes Vi, for i equal to 1 through n, where n?2, with Vj>Vi when j>i. One of the plurality of drop volumes is a minimum drop volume Vmin, and a difference in drop volumes between successively larger drops equals (Vk+1?Vk) which is less than Vmin, for k equal to 1 through n?1. The method also includes ejecting liquid drops through the printhead.

Abstract: An ink-jet head includes: a first nozzle group; a second nozzle group; a first common ink chamber; and a second common ink chamber. With respect to a first direction, nozzles constituting the first nozzle group and nozzles constituting the second nozzle group are arranged alternately to complement each other, the first nozzle group includes a first nozzle and a second nozzle which deviates from the first nozzle with respect to a second direction perpendicular to the first direction, the second nozzle group includes a third nozzle arranged adjacent to the first nozzle with respect to the first direction and a fourth nozzle arranged adjacent to the second nozzle with respect to the first direction, and with respect to the second direction, the fourth nozzle deviates from the third nozzle in a direction opposite to a direction in which the second nozzle deviates from the first nozzle.

Abstract: A printhead comprises a first member and a second member, formed separately from the first member. The second member is nested within a first space defined by the first member. A plurality of fluidic transmission channels is formed between the first and second members to convey ink to an outer surface of the first and second members.

Abstract: Inkjet print head dies are directly seated upon an exterior of a tubular member so as to face different directions.

Abstract: Printing methods and systems that provide both a secure value label printing mode of operation and a non-secure mode of operation that allows generic printing of non-value items without compromising the security feature of the secure printing mode are described. If the printing system determines the image is a non-secure image such as an address label or other non-value graphic, the printing system utilizes the non-secure mode and disables the use certain printhead elements. In such a system, the enforced print disabled white bands are enforced in non-secure mode such as by actually disabling the print drive mechanism that allows a row to be printed or by populating certain regions of the print buffer with zero values.

Abstract: In an example this disclosure relates to printhead modules arranged to move with respect to each other.

Abstract: The printing device for carrying out printing on a translucent printing medium includes: a print head having a first applying portion for applying a first color material onto the printing medium, a second applying portion for applying a second color material, and a third applying portion for applying an opaque specialty ink; a conveying portion for conveying the printing medium relative to the print head; and a printing control portion configured to execute printing according to a printing mode in which a first color-producing layer of the first color material is formed on the conveying printing medium using the first applying portion, an opaque light-blocking layer of the specialty ink is formed using the third applying portion, and a second color-producing layer of the second color material is formed over the light-blocking layer using the second applying portion after the light-blocking layer is formed.

Abstract: The disclosure relates to a method and apparatus for preventing oxidation or contamination during a circuit printing operation. The circuit printing operation can be directed to OLED-type printing. In an exemplary embodiment, the printing process is conducted at a load-locked printer housing having one or more of chambers. Each chamber is partitioned from the other chambers by physical gates or fluidic curtains. A controller coordinates transportation of a substrate through the system and purges the system by timely opening appropriate gates. The controller may also control the printing operation by energizing the print-head at a time when the substrate is positioned substantially thereunder.

Abstract: An inkjet printhead includes a printhead die including: a first nozzle array that is configured to be fed with ink by a first ink feed; and a second nozzle array that is configured to be fed with ink by a second ink feed; and a mounting substrate including: a surface to which the printhead die is attached; a first layer including a first ink channel having an opening disposed at the surface; a second layer including a second ink channel having an opening disposed at the surface; and a third layer disposed between the first layer and the second layer, wherein the printhead die is attached to the first layer, the second layer and the third layer, and wherein the first ink channel opening is fluidically connected to the first ink feed, and the second ink channel opening is fluidically connected to the second ink feed.

Abstract: A liquid ejection head includes a plurality of pressure chambers, respectively communicating with a plurality of ejection orifices for ejecting a liquid, for storing the liquid to be ejected from the plurality of ejection orifices. At least a part of a wall portion forming each of the plurality of pressure chambers is formed of a piezoelectric member, and the plurality of pressure chambers causes the plurality of ejection orifices to eject the liquid by deformation of the piezoelectric member. A plurality of space portions is arranged in parallel to the plurality of pressure chambers at intervals, with some of the plurality of space portions being decompressable. A gas permeable member is provided between the pressure chambers and the decompressable space portions so that a gas inside the pressure chambers is exhausted via the decompressable space portions.

Abstract: An inkjet printer is configured to acquire gap variation information related to a variation of a gap between a specific portion of an ink discharging surface and a recording sheet as a function of an inkjet head position, the specific portion located within a usage nozzle disposed area where usage nozzle rows to be actually used are disposed, determine representative gap variation information related to a variation, as a function of the inkjet head position, of a representative gap representing actual gaps between the usage nozzle rows and the recording sheet, by multiplying the gap variation information by a correction coefficient dependent on a width of the usage nozzle disposed area in a head moving direction and a wavelength of a wave shape of the recording sheet, and determine ink discharging timing based on the representative gap variation information, assuming that the actual gaps are equal to the representative gap.

Abstract: The liquid ejection head capable of securing a high performance of supplying liquid through supply ports while reducing the size of the substrate is provided. The liquid ejecting apparatus using such a liquid ejection head are also provided. The third supply ports situated between the first ejection port array and the second ejection port array include a portion of a large dimension and a portion of a small dimension.

Abstract: An inkjet printing system includes a print head in fluid communication with an ink reservoir and having a plurality of orifices and a corresponding plurality of associated ejection chambers. The print head includes a substrate and a barrier layer disposed on the substrate. The barrier layer defines in part a plurality of fluid channels and the plurality of ejection chambers. The barrier layer includes a material selected from epoxy-based photo resist materials and methyl methacrylate-based photo resist materials. An orifice plate is disposed over the substrate. The orifice plate includes the plurality of orifices in fluid communication with the ejection chambers. The system includes a reservoir containing an organic solvent-based ink composition, wherein the ink composition includes an organic solvent selected from C1-C4 alcohols, C3-C6 ketones, C3-C6 esters, C4-C8 ethers, and mixtures thereof, in an amount 60% or more by weight of the ink composition.

Abstract: The liquid jet head of the present invention includes a laminate structure obtained by laminating a cover plate, an actuator substrate, and a nozzle plate. The actuator substrate includes a groove array formed by alternately arraying an ejection groove (a first or second ejection groove) and a dummy groove (a first or second dummy groove), and a common chamber communicating with one end of the ejection groove. The cover plate includes one chamber communicating with the common chamber and another chamber (a first or second chamber) communicating with another end of the ejection groove and is provided on a top surface of the actuator substrate so as to cover the groove array. The nozzle plate includes a nozzle communicating with the ejection groove and is provide on a bottom surface of the actuator substrate so as to cover the groove array.

Abstract: In an image processing apparatus, a data amount of printing data generated for each different size of dot is reduced. Specifically, in quantization to obtain data for each printing head, printing data for a large dot is set as data in which a bit number per pixel is two bits, and printing data for a medium or small dot is set as data in which a bit number per pixel is one bit. Thereby, a data amount per pixel can be reduced compared with data in which all bit numbers per pixel for the large, medium and small dots are equally two bits.

Abstract: A printhead is provided having an elongate support having a plurality of internal webs protruding from a base section to define a plurality of parallel fluid supply channels, a shim supported by the support and defining a plurality of rows of openings through which fluid from respective supply channels is supplied, and a plurality of elongate printhead modules supported serially on the shim. Each module defines a plurality of fluid supply passages through which fluid passes to fluid ejection nozzles from respective rows of the openings. Either end of each module defines complementary formations such that adjacent modules nest together.

Abstract: The invention describes an inkjet printer with a printing bed for displacing a print medium in a forward feed direction and a print head carriage disposed above the printing bed for displacing at least one print head unit in a transverse feed direction, a print head unit with at least one print head being provided for every color to be printed, each print head having at least one nozzle row oriented in the forward feed direction of the print medium. The nozzles of the at least one nozzle row of the print head unit are disposed offset from one another by a nozzle distance D by reference to the forward feed direction. Another print head unit is provided, which has nozzles in at least one nozzle row disposed offset from one another by a second nozzle distance d by reference to the forward feed direction of the print medium, the ratio derived from the nozzle distance D and the second nozzle distance d being a rational number and greater than 1.

Abstract: A wiring substrate unit is provided. The unit includes: first and second wiring substrates, first and second input portions respectively formed in marginal portions of the first and second wiring substrates, and first and second output contact points respectively formed on one surfaces of the first and second wiring substrates. A through hole is formed in the first wiring substrate to correspond to the second output contact point; a cutout is formed either at a position adjacent to the first input portion of the marginal portion of the first wiring substrate or at a position adjacent to the second input portion of the marginal portion of the second wiring substrate; and one of the first and second input portions is exposed from the cutout.

Abstract: An inkjet printhead includes a printhead die including: a mounting substrate on which the printhead die is mounted, the mounting substrate including: a base layer including a hole; an intermediate layer including: a first surface including a plurality of contact pads; a second surface opposite the first surface, the second surface being proximate the base layer; and a slot that is aligned with the hole in the base layer; and a face layer proximate the first surface of the intermediate layer, the face layer including a window, wherein the printhead die is disposed within the window such that an ink feed opening of the printhead die is in fluid communication with the slot in the intermediate layer of the mounting substrate; and a plurality of electrical interconnections connecting bond pads of the printhead die to the plurality of contact pads on the intermediate layer of the mounting substrate.

Abstract: A printhead module includes a plurality of rows of printhead nozzles, at least some of the rows including at least one displaced row portion, the displacement of the row portion including a component in a direction normal to that of a pagewidth to be printed, wherein the displaced row portions of at least some of the rows are different in length than the displaced row portions of at least some of the other rows.

Abstract: A liquid ejection head includes: a plate base material; and an actuator; wherein the plate base material has: ejection holes having recessed portions; and an ejection face having ejection openings. The recessed portions include pairs each constituted by two recessed portions located side by side and at least one of which has the ejection openings. A shortest line segment of a certain pair is equal to or shorter than that of another pair, an average value of lengths of the respective recessed portions constituting the certain pair is not larger than that of lengths of the respective recessed portions constituting another pair.

Abstract: A printing device includes a nozzle row for chromatic ink comprising K nozzles and a nozzle row for achromatic ink comprising (n·K) nozzles. In a color region, an image-forming operation is performed m times in which the movement direction of the nozzle rows switches alternately between forward and reverse directions, whereby a region of the image having a predetermined width is formed. The image-forming operation performed m times includes the image-forming operation performed once in which both of the nozzle rows for chromatic ink and for achromatic ink are used, and the image-forming operation performed (m?1) times in which only the nozzle row for chromatic ink is used. In a monochrome region, the image-forming operation is performed once in which only the nozzle row for achromatic ink is used, whereby a region of the image having a predetermined width is formed.

Abstract: The invention concerns a contactless numerical printing machine for products of average fluidity, such as varnish, glue, and conducting or scratchable ink, onto a substrate of variable thickness and dimensions. The machine includes a special device for printing without contact by projection. The projected materials are materials of average fluidity or composed of large-dimension molecules. The process used includes an electro-acoustic device for control of the projection, and a multiplicity of projection nozzles, each controlled individually. The machine also includes a production chain with different work stations, whose printing devices are controlled by a computer management system. The production chain allows printing with a certain precision in given zones located during the processing by an appropriate work station.