Electro-photography printing forms an image on a substrate by selectively charging or discharging a photoconductive drum corresponding to an image to be printed. A colorant is applied to the charged drum and subsequently transferred to the substrate.
Liquid electro-photography (‘LEP’) uses inks as the colorants. An LEP printing device typically comprises a binary ink developer that applies the ink to a photoconductor.
The photoconductor subsequently transfers the ink to an Intermediate Transfer Member (‘ITM’) which is responsible for printing the image onto the substrate.
In between each duty cycle, LEP printing devices are cleaned with a view to maintaining high image quality unadulterated by the previous printing cycles. Ineffective cleaning can adversely affect print quality.
Example implementations of the present disclosure will now be described by way of example, with references to the accompanying drawings, in which:
Examples of the present disclosure provide a printing apparatus and method where an intermediate transfer member (‘ITM’), such as a belt or a drum, has a grounded potential. The grounded potential of the ITM removes the need to isolate the ITM. The grounded potential may also increase productivity when printing onto conductive substrates. Furthermore, the grounded ITM may aid in cleaning a photoconductor which may increase its lifespan and may also reduce the static electricity on the substrate resulting in improved substrate handling.
Referring to
The printing apparatus 100 comprises an intermediate transfer member (‘ITM’) 120 and an impression member or roller 130. The ITM 120 is provided for receiving an image formed on a photoconductor 145 and transferring the image to a web substrate 110 which is brought into contact with the ITM 120 by the impression roller or cylinder 130. The photoconductor 145 may be a photo receptor sheet attached to a photo imaging plate (‘PIP’) in the form of a drum 140 on which the image is formed. The photoconductor 145 may receive charge from a charge roller 160, which in turn electrostatically attracts ink from a binary ink developer 150. The ITM 120 may have a transfer blanket 125 wrapped around an outer surface for receiving and transferring the image. The impression roller 130 may be moveable between an engaged position, in which the web substrate 110 is brought into contact with the ITM 120, and a disengaged position in which the web substrate 110 is not contacting or is free from the ITM 120.
The charge roller 160 has a large negative potential in turn charging the photoconductor 145. The PIP 140 may have a negative potential of at least −400V, such as −600V. The charge roller 160 may have a negative potential of at least −1500V, such as −1700V. Other suitable potentials may be used. The charge roller 160 charges the photoconductor 145 prior to a digitized discharge unit 170 which selectively discharges the selected parts of the photoconductor 145 to the potential of the PIP 140, forming an electrostatic charge pattern representative of an image. The digitized discharge unit 170 may be a laser writing head. For example, after exposure by the digitized discharge unit 170, areas where there may be a positive image, i.e. areas ink may be placed will have a lower potential; for example between −500V and −800V, such as −650V than areas where there will be no ink where the potential will be at least −1300V, such as −1500V. Other suitable potentials may be used.
After exposure by the digitized discharge unit 170, the photoconductor 145 moves with respect to the binary ink developer 150. The binary ink developer 150 is arranged such that ink is transferred to the photoconductor 145 in areas which have been discharged by the digitized discharge unit 170. As the photoconductor 145 moves with respect to the binary ink developer 150, the respective charges are such that the ink migrates from the binary ink developer 150 onto the areas of the surface of photoconductor 145 discharged by the digitized discharge unit 170. The ink will have a potential such that the potential of the areas of the surface of the photoconductor 145 where ink can be attracted may be modified. Following the binary ink developer, the discharged portions of the photoconductor 145, representative of the image will have a potential of between −1000V and −1100V, such as −1050V. Other suitable potentials may be used and other colorants may be used such as toner.
After receiving ink from the binary ink developer 150, but before transferring the ink to the ITM 120, a charging unit 180, which may comprise a light emitter such as a plurality of light emitting diodes, may be arranged to perform a pre-transfer erase (‘PTE’) on the photoconductor 145. The PTE removes any additional charge on the photoconductor 145 such that the potential of the photoconductor 145 generally matches the potential of the PIP 140. Charging unit 180 may be arranged to charge or discharge the photoconductor 145 to a uniform potential. When performing the PTE, the charging unit 180 discharges a portion of the photoconductor 145, such that the photoconductor 145 has the same substantially uniform electrostatic charge, for example at least −400V, such as −600V. This ensures a clean transfer of the image and avoids background charges from sparking to the ITM 120 or the transfer blanket 125 and prevents damage to the image. Other suitable potentials may be used.
Following the charging unit 180, a first transfer occurs where the image on the photoconductor 145 can be transferred onto the ITM 120 or the transfer blanket 125 surrounding the ITM 120. The transfer of the ink representing the image may be aided by the electrostatic force caused by a potential difference existing between the photoconductor 145 and the ITM 120. For example, the potential difference will be uniform electric field with a potential of at least 400V, such as 600V, from the photoconductor 145 to the ITM 120. This potential difference exists because of the grounded potential of the ITM 120 and the photoconductor 145 having a potential of at least −400V, such as −600V. The photoconductor 145 may be any other suitable voltage.
As the ITM 120 rotates, the ITM 120 surface, or the transfer blanket 125, comes into contact with the substrate 110. The substrate 110 can be pressed against the outer surface of the ITM 120 or the transfer blanket 125 by the impression roller 130. The impression roller 130 may also have a grounded potential. As a result, the ink image on the outer surface of the ITM 120 or the transfer blanket 125 can be transferred to the substrate 110.
During operation of LEP printing devices, sparks can be caused due to static electricity of the substrate. Furthermore, problems arise when printing onto a conductive substrate due to the maintenance of the ITM at a high voltage. Maintaining the ITM at such high voltage involves components to ensure the ITM is isolated and can support high loads.
Referring to
The printing apparatus 200 comprises an intermediate transfer member (‘ITM’) 220 and an impression member or roller 230. The ITM can be provided for receiving an image formed on a photoconductor 245 and transferring the image to a main web substrate 210 which may be brought into contact with the ITM 220 by the impression roller or cylinder 230. The photoconductor 245 may be a photo receptor sheet attached to a photo imaging plate (TIP′) in the form of a drum 240 on which the image can be formed. The photoconductor 245 may receive charge from a charge roller 260, which in turn electrostatically attracts ink from a binary ink developer 250. The photoconductor 245 may also receive a further charge from a charging unit representative of a further charge rollers 280 to provide the photoconductor 245 with a substantially uniform electrostatic charge prior to transferring to the ITM 220. The ITM 220 may have a transfer blanket 225 wrapped around an outer surface for receiving and transferring the image. The impression roller 230 may be moveable between an engaged position, in which the web substrate 210 can be brought into contact with the ITM 220, and a disengaged position in which the web substrate 210 may not be contacting or may not be free from the ITM 220.
The charge roller 260 has a large negative potential in turn charging the outer surface of the photoconductor 245. The PIP 240 may have a grounded potential. For example, the charge roller may have a negative potential of −1100V. The voltage of the charge roller 260 may be another suitable potential.
The apparatus 200 of
Following the binary ink developer 250, the photoconductor 245 receives a potential from the further charge roller 280. To enable the colorant to be electrostatically attracted from the PIP 240 to the outer surface of the ITM 220 or transfer blanket 225 surrounding it, both which have a grounded potential, a substantially uniform electrostatic charge may be applied to the PIP 240. The further charge roller 280 may have a negative potential of at least −600V, such as −700V, but other suitable voltages may be used. As such, a uniform electric field with a potential difference of at least 600V, such as 700V, from the photoconductor 245 to the ITM 220 will exist causing the ink on the photoconductor 245 to be electrostatically attracted towards the ITM 220.
As the ITM 220 rotates, the ITM 220 surface, or the transfer blanket 225, comes into contact with the substrate 210. The substrate 210 can be pressed against the outer surface of the ITM 220 or the transfer blanket 225 by the impression roller 230. The impression roller 230 may also have a grounded potential. As a result, the ink image on the outer surface of the ITM 220 or the transfer blanket 225 may be transferred to the substrate 210.
In step 310, an electrostatic charge pattern representative of an image can be formed on a photoconductor 145, 245, such as a photo imaging plate (‘PIP’) in the form of a drum 140, 240 by a digitized discharge unit 170, 270. The digitized discharge unit 170, 270 selectively discharges portions of the photoconductor 145, 245 to the voltage of the PIP 140, 240 such that the electrostatic charge pattern representing the image may be formed on its surface. The PIP 140, 240 may have a negative potential such as described above in relation to
In step 320, the photoconductor 145, 245 moves with respect to the binary ink developer 150, 250, wherein ink can be electrostatically attracted to the areas representative of the image to be printed. The ink will have a potential such that the potential of the areas of the surface of the photoconductor 145. 245 where ink can be attracted may be modified. Other colorants may be used to form the image, such as toner.
In step 330, the photoconductor 145, 245 may be provided with a substantially uniform electrostatic charge by a charging unit so as to enable the ink to be electrostatically attracted to the ITM 120, 220 or the transfer blanket 125, 225 surrounding it which has a grounded potential. As described above in relation to
In step 340, the image can be transferred to the ITM 120, 220 or the transfer blanket 125, 225. The ITM 120, 220 and any surrounding transfer blanket 125, 225 may have a grounded potential. The grounded potential of the ITM 120, 220 or transfer blanket 125, 225 reduces the cost of the press by removing the need to use expensive components to isolate the ITM 120, 220 from the web press. It also increases the productivity when using conductive substrates, preventing the build-up of static electricity in the substrate and improving substrate handling. Additionally, the grounded potential of the ITM 120, 220 can aid in the cleaning of the photoconductor 145, 245 increasing its lifespan. The image may be transferred by the difference in the electrostatic charges between the ITM 120, 220 and the photoconductor 145, 245.
At step 350, the image can be transferred from the ITM 120, 220 or transfer blanket 125, 225, to the substrate 110, 210. This may be achieved by bringing the substrate 110, 210 into contact with the ITM by means of an impression roller 130, 230. The impression roller may also have a grounded potential. The impression roller 130, 230 may be moveable between an engaged position, in which the web substrate 110, 210 can be brought into contact with the ITM 120, 220, and a disengaged position in which the web substrate 110, 210 may not be contacting or free from the ITM 120, 220.
These and other variations, modifications, additions, and improvements may fall within the scope of the appended claims(s). As used in the description herein and throughout the claims that follow, “a”, “an”, and “the” includes plural references unless the context clearly dictates otherwise. Also, as used in the description herein and throughout the claims that follow, the meaning of “in” includes “in” and “on” unless the context clearly dictates otherwise. All of the features disclosed in this specification (including any accompanying claims, abstract and drawings), and/or all of the elements of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or elements are mutually exclusive.
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WO2017/016577 | 2/2/2017 | WO | A |
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