Embossing is sometimes used to create raised images and designs in printed paper or other printed media. Embossing is normally performed as a post printing process on dedicated embossing machinery. Embossing machines typically involve the design and manufacture of a two piece die. The embossing machines place a portion of the media between the two pieces and then press the two pieces of the die together. This mechanically deforms the media to create the embossed image. These embossing techniques may have a number of disadvantages, including the delay in manufacturing the die, the cost of purchasing/maintaining separate embossing machines, and the significant amount of effort involved in the separate post-printing embossing run.
The accompanying drawings illustrate various examples of the principles described herein and are a part of the specification. The illustrated examples are merely examples and do not limit the scope of the claims.
Throughout the drawings, identical reference numbers designate similar, but not necessarily identical, elements.
Embossing is sometimes used to create raised images and designs in printed paper or other printed media. These raised images provide texture, emphasis, and visual effects to the media. The embossed images can include a variety of additional characteristics, including printed images, gloss, lamination, or security features.
In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the present systems and methods. It will be apparent, however, to one skilled in the art that the present apparatus, systems and methods may be practiced without these specific details. Reference in the specification to “an example” or similar language means that a particular feature, structure, or characteristic described in connection with the example is included in at least that one example, but not necessarily in other examples.
The examples and methods described below provide for embossing of a wide range printable media. In one illustrative example, printed relief patterns are used to form the embossing die. The printed relief pattern can be formed using a variety of printing processes and, in some examples, can be printed by the same printer that forms ink images on the media. The media is pressed against the printed relief patterns to form the embossed image in the media. This process is integrated into the normal printing flow within the printer. This eliminates delay, handling, and overhead of traditional embossing systems.
As used in the specification and appended claims, the term “printed relief pattern” refers to ink structures having a thickness or height sufficient to emboss a media pressed against the printed relief pattern. For example, a typical printed relief pattern may have a height of between approximately 0.1 millimeters and 2 millimeters or more. In some examples, the printed relief pattern may be formed from multiple layers of ink. Factors which may influence the height of printed relief pattern include: the desired height of the embossed image, the capacity of the printing technique in depositing ink layers, and the structural characteristics of the cured ink.
In some examples the printed relief patterns are created using digital printing processes. Digital printing processes transform digital data into a printed image in fractions of a second. Additionally, digital printing allows for successive images to change without slowing or reconfiguring the printer. Thus, the ink layers which make up the printed relief patterns can be rapidly formed in any pattern described by the digital data. The cost of printed relief patterns correlates to the cost of operating the printing press for tens of seconds and the amount of ink contained in the printed relief pattern. This can be a significant cost savings over designing a brass, bronze or copper embossing die, sending out the die for machining, waiting to receive the die from the machinist, installing the die in a dedicated embossing machine, and managing the post-printing embossing run. Consequently, the use of printed relief patterns as embossing die can enable low cost, rapid embossing runs which occur during the normal printing work flow. As used in the specification and appended claims, the term “ink” refers broadly to material deposited onto a surface by a printer or press. For example, the term “ink” includes liquid toners, dry toners, UV cured inks, thermally cured inks, inkjet inks, pigment inks, dye based inks, solutions without colorant, solvent based inks, water based inks, plastisols, or other appropriate solutions.
The digital embossing technique can be performed using a number of printing technologies, including Liquid Electro Photographic (LEP) printing, xerography and inkjet printers. The term “Liquid Electro Photographic” or “LEP” refers to a process of printing in which a liquid toner is applied through an electric field onto a surface to form an electrostatic pattern. In most LEP processes, this pattern is then transferred to at least one intermediate surface, and then to a print medium. During the operation of a digital LEP system, ink images are formed on the surface of a photo-imaging cylinder. These ink images are transferred to a heated blanket cylinder and then to a print medium. The photo-imaging cylinder continues to rotate, passing through various stations to form the next image.
The term “nip” refers to a region between two rollers where the rollers are in closest proximity. When a media sheet or other material passes through the nip, the distance between the two rollers can be adjusted to produce pressure on the media.
According to one illustrative example, an image is formed on the photo-imaging cylinder (105) by rotating a clean, bare segment of the photo-imaging cylinder (105) under the photo charging unit (110). The photo charging unit (110) includes a charging device such as corona wire, charge roller, or other charging device and a laser imaging portion. A uniform static charge is deposited on the photo-imaging cylinder (105) by the photo charging unit (110). As the photo-imaging cylinder (105) continues to rotate, it passes the laser imaging portion of the photo charging unit (110) that dissipates the static charges in selected portions of the image area to leave an invisible electrostatic charge pattern that represents the image to be printed.
Ink is transferred onto the photo-imaging cylinder (105) by Binary Ink Developer (BID) units (115). There is one BID unit (115) for each ink color. During printing, the appropriate BID unit is engaged with the photo-imaging cylinder (105). The engaged BID unit presents a uniform film of ink to the photo-imaging cylinder (105). The ink contains electrically charged pigment particles which are attracted to the opposing electrical fields on the image areas of the photo-imaging cylinder (105). The ink is repelled from the uncharged, non-image areas. The photo-imaging cylinder (105) now has a single color ink image on its surface.
The photo-imaging cylinder (105) continues to rotate and transfers the ink image to a blanket cylinder (120). The blanket cylinder transfers the image to a sheet of media wrapped around the impression cylinder (130). As will be further described below, this process may be repeated for each of the colored ink layers to be included in the final image.
The print medium (140) enters the printing system (100) from the right, passes over a feed tray (125), and is wrapped onto the impression cylinder (130). As the print medium (140) contacts the blanket cylinder (120), the single color ink image is transferred to the print medium (140). The creation, transfer, and cleaning of the photo-imaging cylinder (105) is a continuous process, with hundreds of images being created and transferred per minute.
To form a single color image (such as a black and white image), one pass of the print medium (140) through the impression cylinder (130) and the blanket cylinder (120) completes the desired image. For a color image, the print medium (140) is retained on the impression cylinder (130) and makes multiple contacts with the blanket cylinder (120) as it passes through the nip (127). At each contact, an additional color plane may be placed on the print medium (140).
For example, to generate a four color image, the photo charging unit (110) forms a second pattern on the photo-imaging cylinder (105) which receives the second ink color from a second BID unit (115). As described above, this second ink pattern is transferred to the blanket cylinder (120) and impressed onto the print medium (140) as it continues to rotate with the impression cylinder (130). This continues until the desired image with all four color planes is formed on the print medium. Following the complete formation of the desired image on the print medium (140), the print medium (140) can exit the machine or be duplexed to create a second image on the opposite surface of the print medium (140). Because the printing system is digital, the operator can change the image being printed at any time and without manual reconfiguration.
According to one illustrative example, the digital offset LEP system (100) can be adapted to perform embossing in addition to printing. The impression cylinder (130) is covered by an impression layer (132). This impression layer (132) absorbs and captures excess ink to minimize maintenance and image quality issues. For example, when a paper jam occurs, ink intended for the absent paper may be instead deposited on the impression layer (132). As part of the jam clearing process, the operator may replace the impression layer (132) before restarting the printing operation. The printer design facilitates the rapid and convenient replacement of the impression layer (132).
To perform embossing with the digital offset LEP system, the media feeding through the press (100) is temporarily stopped. Ink images are repeatedly deposited on the impression layer (132) to accumulate and build up a two or three dimensional relief ink image which serves as the embossing die. The ink deposition process occurs as described above, with an electrostatic image being created on the photo-imaging cylinder (105) and the photo-imaging cylinder (105) receiving ink from a BID unit (115) to form an ink image on the photo-imaging cylinder (105). The image is transferred to the surface of the resilient layer (122) on the blanket cylinder (120) and then to the impression layer (132). The ink image is cured on the impression layer (132). This process is repeated to deposit multiple layers of cured ink and forms the printed relief pattern that serves as an embossing die. In some implementations, the process may pause after the deposition of one or more ink layers or may incorporate null printing cycles where no ink is deposited.
The description of embossing using printed relief patterns created on a LEP printer is only an illustrative example. A variety of other printing methods and systems could be used to create printed relief patterns and emboss media. Additional illustrative examples are described below.
The ink used to form the structures (210, 215) may be any color or may have no color at all. The ink is selected so that its mechanical properties facilitate the formation of a printed relief pattern. For example, the ink may be selected for its adhesive or structural characteristics. In some implementations, different inks may be used in different layers of the structures. For example, an adhesive ink may be used as a first layer to securely bind the structures to the impression layer. The other layers may be built using inks which have more structural properties and are designed to withstand repeated compression during the embossing process. A top layer may be selected so that it does not stick to the media that is being embossed.
The diagram shown in
After the embossing die is formed, the media is again fed into the printer and attached over the embossing die on the impression cylinder (block 320). A wide variety of media can be used. For example, cellulose based media ranging from 60 grams per meter square to 350 grams per meter square have been used. Other types and weights of media can also be used. As each sheet of media passes though the nip, it is pressed against the embossing die at the nip between the blanket cylinder and the impression cylinder (block 325). As discussed above, this embosses the media by pressing it over and into the ink structures which make up the embossing die. If desired, an ink image could be simultaneously printed on the media.
The media may be retained on the impression cylinder for a number of revolutions. Each time the media passes through the nip, it is again pressed over the printed relief pattern. For example, the impression cylinder may rotate the media through the nip four times before releasing the media. This may have a number of advantages, including sharper embossed images and an opportunity to print an image on the media with four color layers. The number of passes through the nip can be adjusted according to the characteristics of a given print run.
The pressure and temperature of the blanket cylinder and the impression cylinder can be controlled to produce the desired embossed image. The pressure can be controlled by adjusting the distance between the two cylinders and/or adjusting the resiliency/thickness of the resilient layer. The temperature of the cylinders and resilient layer can be adjusted by controlling heat flux into and out of the cylinders. For example, the temperature may be increased using radiative, convective or conducted heat. The temperature may be lowered by reducing the input heat flux or increasing a cooling convective flow.
In some examples, the printer may also deposit ink on the media as it is performing the embossing. The deposition of ink on the media is performed as described above with respect to
This process is repeated by feeding the next sheet of media into the printer (block 320), pressing the media into the relief image (block 325) and removing the media (block 330). The process continues until the embossing run is complete. For example, the embossing die may be used to emboss runs that range from a single sheet of media to hundreds or thousands of sheets. Tests have shown that a single embossing die is sufficient to print at least 600 sheets of media. If the embossing die becomes damaged or worn, the media printing/embossing process can be momentarily stopped while the printer deposits additional layers on the embossing die to correct the embossing die. Alternatively, the impression layer can be replaced and the embossing die can be built over again. After the printing is complete, the impression layer is replaced and printing continues as usual with the next print job (block 335).
The illustrative systems and methods described above are only one example of embossing using a printed relief pattern as the embossing die. As used in the specification and appended claims, the term “embossing” is used broadly to include both raised areas and depressed areas formed in a media surface.
The printed media are then fed into the printer and pressed into the embossing die (450) at the nip between a second cylinder (465) and the first cylinder (440) (block 420). The second cylinder (465) is covered with a resilient surface which presses the media against the embossing die (450) such that embossed features corresponding to the embossing die (450) are formed in the media (435). As discussed above, the media (435) may make multiple passes through the nip. For example, the first cylinder (440) may rotate the media (435) through the nip four times before releasing the media (435). This creates an embossed image (455) in the printed media (435). As discussed above, in addition to embossing the image, the printer may simultaneously print images on exposed surfaces of the media.
In one example, the registration of the printed media with the printed relief pattern can be performed using systems which are already in place within the printer. The registration between the printed media and the relief image insures proper alignment between the printed image and the embossing produced by the printed relief pattern. For example, the printed relief pattern and the printed media can be aligned using systems which register different colors of ink images on a sheet or using systems which align duplex printed sheets to insure that images placed on a second side of a sheet are aligned with images already printed on the first side of the sheet.
After the desired embossed features/ink deposition has occurred, the media (435-1) is removed and the next sheet of media (435-2) is fed onto the impression layer (block 425). When all the media has been embossed, the impression layer (445) can be replaced with a new sheet (460) and printing can continue with the next print job (block 430).
In this illustrative method, an embossing die (540) is formed on an impression layer (535) using an offline process (block 505). For example, an inkjet printer that deposits UV cured polymer inks or thermally curable inks could be used. The ink layers created by UV cured polymer inks can be significantly thicker than ink layers deposited by the LEP printing process. Consequently, fewer ink layers may form the desired embossing die (540). The impression layer (535) may be formed from any of a number of materials, including film, plastic, KAPTON, or other material. In some instances, the embossing die (540) may be formed using techniques other than ink deposition. For example, the embossing die (540) may be created using a letter press.
To properly align the separately formed embossing die (540), an alignment image or images (555) can be printed on the impression layer (550) (block 510). The alignment image(s) can be used to align the embossing die (540) on the impression cylinder (545) (block 515). The embossing die (540) can be adhered to the impression cylinder (545) in a number of ways, including adhesive, vacuum suction, electrostatic forces, clamping or other techniques.
The media (560) is then fed into the printer and embossed (block 520). After the desired media is embossed, the impression layer (535) containing the embossing die (540) can be replaced and printing can continue with the next job (block 525).
In conclusion, the digital creation of a printed relief pattern for embossing is a very flexible technique for creating embossed images on media. A wide variety of printing technologies can be used to deposit layers of ink to create the printed relief pattern. The printed relief pattern is used inside a printer to perform embossing of the media. This eliminates the cost, time and space consumed by external embossing machines. In other examples, the relief image is formed by an offline process and used in a printer for inline embossing.
The preceding description has been presented only to illustrate and describe examples of the principles described. This description is not intended to be exhaustive or to limit these principles to any precise form disclosed. Many modifications and variations are possible in light of the above teaching.
Number | Date | Country | |
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Parent | 14116321 | Nov 2013 | US |
Child | 15076600 | US |