Abstract: A source of actinic radiation for curing printing plates. The source includes a base with a heat sink and has a length greater than its width. One or more circuit boards mounted on the base provide a plurality of light emitting diodes (LEDs) distributed over the length of the base. A transparent or translucent cover together with the base defines an enclosure for the plurality of LEDs. The source provides the radiation at an emission angle greater than the emission angles of a single LED in a plane perpendicular to the axis of the base, in a plane containing the axis of the base or parallel to the axis of the base and perpendicular to the target illumination plane, or a combination thereof. The source may be configured to replace a fluorescent bulb. Methods and systems for bank exposure of printing plates using such sources are also described.

Abstract: Apparatus, method, and system for exposing a photosensitive printing plate to radiation, including a plurality of LED point sources configured to emit UV light. The plurality of LED point sources in at least one of a front side set or back side set are controllable in subsets smaller than an entirety of the collective irradiation field corresponding to the respective set. A holder receives the printing plate in a stationary position to receive incident radiation and a controller is configured to control the plurality of LED source subsets. A first LED point source subset is configured to be controlled at a first intensity differing by a factor relative to a second intensity of a second LED point source subset to give the radiation emitted by the respective set an intended degree of homogeneity.

Abstract: A photosensitive flexographic printing form, and process for manufacturing the same. The printing form includes a base, a first series of relief patterns having a first elevation with respect to the base in an image area of the base, and a second series of relief patterns having one or more elevations lower than the first elevation and located outside of the image area.

Abstract: A system for preparing a photopolymer printing plate includes exposure unit comprising a plurality of UV light emitting diodes (UV LEDs), a holder comprising a UV translucent material configured to receive the printing plate, and a controller configured to activate the plurality of UV LEDs. The UV LEDs include a plurality of stationary back UV LEDs configured to emit UV radiation toward the non-printing back side of the printing plate through the holder with the printing plate disposed in a stationary position on the holder, the plurality of stationary back UV LED sources together defining at least one back array having a collective irradiation field covering an area at least coextensive with the lateral length and lateral width of the plate.

Abstract: A combined radiation and functional layer application system includes one or more radiation sources and a commonly located functional layer application unit configured to dispose a functional layer over the surface of a fixed target ahead of the radiation sources during relative motion between the target and the radiation sources/application unit. System and method embodiments include those in which the target is stationary or moving, and embodiments in which the functional layer is applied as a liquid or as a solid laminate. Embodiments relate to application of an oxygen-blocking layer of a printing plate prior to exposure to actinic radiation. Certain solid laminate embodiments include a two-roll system for positioning the laminate for cutting adjacent a trailing edge of the plate.

Abstract: A method and system for creating a printing plate from a vector format image file having image and non-image areas. A boundary in vector coordinates is identified via a user interface that defines each image area corresponding to an image patch. The image file is raster image processed (RIPped) to create RIPped image information associated with the vector coordinates corresponding to the image patches. The RIPped image information and associated vector coordinates are processed to create RIPped image patches, register marks attached to each RIPped image patch, and the RIPped image patches with register marks and corresponding vector coordinates stored in a processing file. The system includes a computer memory, an interface for providing the image file, a user interface, and a computer processor configured to perform the method.

Abstract: The overall mechanism for creating the exposure may comprise a table having an outer frame 1110 that holds a transparent (e.g. glass) inner portion 1112. The upper 1120 and lower 1122 linear radiation sources (e.g. banks of LED point sources, optionally mounted inside a reflective housing) are mounted on a gantry system or carriage 1130. The radiation sources are connected to a power source, such as an electrical power cord having sufficient slack to extend the full range of motion of the carriage. Tracks (not shown) disposed on the outer frame portion provide a defined path for the gantry system or carriage to traverse. The carriage may be moved on the tracks by any drive mechanism known in the art (also coupled to the power supply and the controller), including a chain drive, a spindle drive, gear drive, or the like. The drive mechanism for the carriage may comprise one or more components mounted within the carriage, one or more components fixed to the table, or a combination thereof.

Abstract: A system for preparing a photopolymer printing plate includes an imager, a plate unloader configured to automatically unload the plate from the imager and deliver the plate to an exposure unit comprising a plurality of UV LEDs, and a controller configured to operate the imager, the plate unloader, and the exposure unit. The imager has a rotatable drum configured to rotate while laser beams ablate portions of an ablatable layer of the printing plate in accordance with imaging data. The UV LEDs include a back array and a front array configured to expose the front of the UV-curable plate, at least one of which is configured to emit UV radiation toward the plate during relative motion between the plate and the array.

Abstract: Apparatus and method for directly curing photopolymer printing plates, such as with UV radiation. Printing plates are cured directly by radiation, such as emitted from a high power UV laser beam. No LAMS layer or film bearing the image information is required on top of the polymer plate. The laser beam may be split into several individually-modulated beams by means of an Acousto Optical Deflector. Each individual beam is capable of curing pixels of the image that are to be transferred to the printing plate. Support shoulders for the printing details, formed by the pixels are determined by the caustic of the UV beam propagation.

Abstract: A method and system for creating a printing plate from a vector format image file having image and non-image areas. A boundary in vector coordinates is identified via a user interface that defines each image area corresponding to an image patch. The image file is raster image processed (RIPped) to create RIPped image information associated with the vector coordinates corresponding to the image patches. The RIPped image information and associated vector coordinates are processed to create RIPped image patches, register marks attached to each RIPped image patch, and the RIPped image patches with register marks and corresponding vector coordinates stored in a processing file. The system includes a computer memory, an interface for providing the image file, a user interface, and a computer processor configured to perform the method.

Abstract: A plate handling system (500, 600) for transporting printing plates between workstations in a process workflow. A plurality of vacuum gripper end effectors (512) configured to grip the printing plates are mounted to a computer-controlled transporter (514) configured to translate in at least three orthogonal directions and to rotate about at least one rotational axis. At least one sensor (560) detects orientation of the plate relative to a staging location and a controller (630) causes the transporter to move based upon programmed instructions in accordance with information provided by the sensor. A mobile preparation table (1000) may be provided in the staging location. A thickness measurement system (1090) may be included in some embodiments.

Abstract: Apparatus and method for exposing a printing plate having a photosensitive polymer to curing radiation. A plurality of light-emitting diodes (LEDs) are arranged in an array of columns and rows, including at least two, and more preferably at least three, different species, each species having a different center emission wavelength, preferably in the UV spectrum. The LEDs species are disposed adjacent one another in a repeating sequence. A controller connected to the array is configured to activate the array and to independently control each of the species to cause them to emit radiation towards the printing plate simultaneously with emissions patterns of adjacent members overlapping one another on the plate. A linear or planar source may comprise a plurality of independently controllable arrays.

Abstract: Systems and methods for exposing photopolymer printing plate material located within a target area having first and second dimensions. A light source having LEDs arrayed coextensive with the first dimension moves relative to the second dimension, and emits different light intensities over the target area in at least one of the first dimension or the second dimension. The systems and methods may be used to determine exposure parameters for curing a selected plate by causing different sample units to receive different amounts of total energy exposure, exposure energy per exposure step, or a combination thereof, and visually evaluating each sample unit against a reference plate of the same type and thickness. The sample unit embodying a minimum acceptable total exposure energy and a maximum acceptable exposure energy per exposure step is then identified.

Abstract: A process for constructing a printing plate by successively depositing a plurality of n layers of photopolymer on a substrate, curing each layer 1 through (n?m) using a wide area radiation source, and selectively curing layers (n?m+1) to layer n using a small area radiation source modulated in accordance with a desired image to be printed by the printing plate. Non-cured polymer is removed from layers (n?m+1) to n, and all of the layers are further cured with a detacking area radiation source. Also disclosed is a system for constructing a printing plate by additive manufacturing, including a printing assembly and means for providing relative motion between the substrate and the printing assembly. The assembly comprises one or more ink jet print heads, at least one wide area radiation source, and the small area radiation source.

Abstract: Systems and methods for making a flexo plate, and plates, machines, readers, and computer readable media for use therewith. In the system, a plurality of processing machines, each configured to perform one or more process steps in a workflow, includes a controller, a variable operating parameter controlled by the controller, and a reader configured to read machine-readable indicia on the flexo plate. The machine-readable indicia (e.g. bar code, RFID tag, text) is configured for persistent readability downstream of washing (and cutting) steps, without printing in the printing step. The indicia may embody information including at least a plate identifier and instructions corresponding to the at least one variable operating parameter for each of the processing machines or information corresponding to an address in computer storage where the information resides.

Abstract: A method for mounting one or more printing plate segments on a carrier sheet. The method comprises importing a file into a computer associated with a mounting unit. For each printing plate segment, the file includes a printing plate segment identifier, information regarding alignment of registration marks relative to the carrier sheet; and image data corresponding to a characteristic pattern associated with each printing plate segment. A composite image depicting the image data corresponding to the characteristic patterns is then displayed on a display in the predetermined arrangement of one or more printing plate segment locations and orientations. A mounting unit and a printing system and computer readable media programmed with instructions for performing the method are also described.

Abstract: A process for mounting a printing plate on a carrier sheet, including disposing registration indicia on the plate, placing the carrier sheet on a cutting table of a cutting system, mounting the plate to the carrier sheet, detecting absolute coordinates of the registration indicia; and cutting the carrier sheet along a cut line having absolute coordinates generated based upon the detected absolute coordinates. A related system includes the cutting system with the cutting table, a camera for detecting the registration indicia, a processor, a cutter, a controller, and a computer memory programmed with instructions for instructing the controller to detect the indicia, calculate the absolute coordinates for the cut line based upon the detected absolute coordinates and stored relative coordinates for the cut line, and cutting the carrier sheet along the cut line. Computer readable media containing such programmed instructions is also disclosed.

Abstract: Apparatus and method for directly curing photopolymer printing plates, such as with UV radiation. Printing plates are cured directly by radiation, such as emitted from a high power UV laser beam. No LAMS layer or film bearing the image information is required on top of the polymer plate. The laser beam may be split into several individually-modulated beams by means of an Acousto Optical Deflector. Each individual beam is capable of curing pixels of the image that are to be transferred to the printing plate. Support shoulders for the printing details, formed by the pixels are determined by the caustic of the UV beam propagation.

Abstract: A system for preparing a photopolymer printing plate includes an imager, a plate unloader configured to automatically unload the plate from the imager and deliver the plate to an exposure unit comprising a plurality of UV LEDs, and a controller configured to operate the imager, the plate unloader, and the exposure unit. The imager has a rotatable drum configured to rotate while laser beams ablate portions of an ablatable layer of the printing plate in accordance with imaging data. The UV LEDs include a back array and a front array configured to expose the front of the UV-curable plate, at least one of which is configured to emit UV radiation toward the plate during relative motion between the plate and the array.

Abstract: A process for mounting a printing plate on a carrier sheet, including disposing registration indicia on the plate, placing the carrier sheet on a cutting table of a cutting system, mounting the plate to the carrier sheet, detecting absolute coordinates of the registration indicia; and cutting the carrier sheet along a cut line having absolute coordinates generated based upon the detected absolute coordinates. A related system includes the cutting system with the cutting table, a camera for detecting the registration indicia, a processor, a cutter, a controller, and a computer memory programmed with instructions for instructing the controller to detect the indicia, calculate the absolute coordinates for the cut line based upon the detected absolute coordinates and stored relative coordinates for the cut line, and cutting the carrier sheet along the cut line. Computer readable media containing such programmed instructions is also disclosed.