The present invention relates generally to printing presses, and more particularly to ink and dampening fluid metering devices for printing presses.
Printing processes, such as the lithographic web offset process, commonly use an arrangement of rollers called an inker to accept ink from an ink metering device and deliver it to a printing plate. A goal of the inker is to supply the plate with a thin, uniform film of ink. An inker may contain as many as twenty rollers to achieve this goal.
One reason for the large number of rollers in an inker is that the ink feed from prior art ink metering devices, such as ink fountains, ductors, and metering rolls, is intermittent. Typically the ink is supplied by the ink metering device in the form of stripes or spots spaced about two or more inches apart in the circumferential direction on the first inker roll. An inker contains extra rollers to filter out these spots or stripes so that the plate receives a uniform ink film and the spots or stripes do not appear in the print.
To produce a high quality printed product, most ink metering devices allow the feed rate of ink into the inker to be varied laterally across the web or sheet. Typically the metering device is divided into separate lateral zones about one or two inches in width, with the ink feed in each zone being separately controllable.
Printing processes, such as the lithographic web offset process, commonly use an arrangement of rollers called a dampener. The goal of the dampener is to deliver a thin, uniform film of dampening fluid to a printing plate. Typical prior art dampeners are of two basic types, generally called spray dampeners and pan-roll dampeners. Spray dampeners typically have the dampening fluid sprayed onto the first dampener rollers. Pan-roll dampeners typically transfer the dampening fluid onto the first dampener rollers from a pan-roller which is partially submerged in a pan containing dampening fluid.
To transfer more or less dampening fluid on a localized lateral area of the lithographic printing plate, the typical pan-roll dampeners has only roller-squeeze and roller-skew for coarse adjustments. The typical spray dampener accomplishes lateral control for localized areas by varying the fluid flow rate through laterally spaced spray nozzles. The typical spray dampeners also have over-spray issues and rely on the sprayed fluid to adhere to the dampener rollers.
Printing processes, such as the flexographic printing process, commonly use an engraved anilox roller to deliver a quantity of ink from an ink chamber to a flexographic printing plate. The raised image sections of the flexographic printing plate then transfer a portion of the ink delivered by the anilox roll to the substrate being printed.
The goal of the anilox roller is to supply the flexographic printing plate a quantity of ink proportional to the volume of the engraved anilox cells. The goal of the flexographic printing plate is to selectively transfer a portion of the ink delivered by the anilox roll to the printing substrate.
To transfer more or less ink on a localized lateral area of the substrate being printed, typically the flexographic printing plate is replaced by another flexographic printing plate having a larger or smaller image transfer areas.
To transfer more or less ink laterally uniform across the substrate being printed, typically the engraved anilox roller is replaced by another engraved anilox roller having a larger or smaller engraved anilox cell volume.
A roll for distributing printing liquid in a printing press is provided. The roll includes a roll core having at least a first and a second axial zone, a first liquid feed for feeding liquid to the first axial zone, a second liquid feed for feeding the liquid to the second axial zone independent of the first axial zone and a porous shell covering the first and second axial zones.
A printing press is also provided. The printing press includes a plate cylinder, a printing liquid supply roll and at least one printing liquid pump. The printing liquid supply roll forms a nip with the plate cylinder and includes an interior region and a porous layer surrounding the interior region. The at least one printing liquid pump is adapted to pump printing liquid into the interior region and through the porous layer. The printing liquid supply roll is adapted to transfer the printing liquid to the plate cylinder at the nip.
A method for providing printing liquid through a porous shell of a printing liquid supply roll to a cylinder of a printing press is also provided. The method includes the steps of rotating the printing liquid supply roll; supplying the printing liquid into the inside of the printing liquid supply roll; feeding the printing liquid from the inside of the printing liquid supply roll through the porous shell; and transferring the printing liquid from the printing liquid supply roll to the cylinder.
An inking apparatus for a printing press is also provided. The inking apparatus includes an anilox roll and at least one ink pump. The anilox roll includes an interior region, a porous layer surrounding the interior region and an outer surface of engraved cells surrounding the porous layer. The at least one ink pump is adapted to pump ink into the interior region and through the porous coating to the outer surface of engraved cells.
A method for providing ink to an anilox roll is also provided. The method includes the steps of rotating the anilox roll; filling engraved cells of the anilox roll with ink from outside of the anilox roll; removing any excess ink from the anilox roll with a doctor blade; and providing additional ink to the engraved cells from the inside of the anilox roll.
The present invention is described below by reference to the following drawings, in which:
a shows a schematic view of an axial cross-section of a porous roll according to another embodiment of the present invention;
b shows a schematic view of a cross section of porous roll shown in
c shows the cross section of the porous roll shown in
a shows a schematic view of an axial cross-section of a porous roll according to another embodiment of the present invention;
b shows a schematic view of a cross section of the porous roll shown in
Porous shell 12 is supported by an outer race 38 of bearing 28 near edge 36 of roll core 14. Porous shell 12 may be supported by one or more additional bearings on roll core 14. Porous shell 12 is free to rotate around a center axis CA1.
Roll core 14 has an outer surface 40 supporting an inner race 42 of bearing 28 and seals 16, 18, 20. Seals 16, 18, 20 form the axial boundaries of axial zones 44, 46, 48. Axial zones 44, 46, 48 have holes 50, 52, 54, respectively, extending from outer surface 40 to an inner radius RI of roll core 14. Holes 50, 52, 54 contain fittings 22, 24, 26 attached to interior tubes 30, 32, 34, respectively. Interior tubes 30, 32, 34 extend through a hole 56 at edge 36 and are coupled to liquid pumps 13, 15, 17, respectively. Interior tubes 30, 32, 34 may act as liquid feeds to axial zones 44, 46, 48. The liquid may be conveyed in interior tubes 30, 32, 34 or roll core 14 may be solid and liquid may be conveyed in channels machined directly into roll core 14, for example as channels 116, 118, 120 of
During operation of porous roll 10, liquid is pumped at controlled liquid flow rates Q1, Q2, Q3 through respective interior tubes 30, 32, 34 and into respective axial zones 44, 46, 48. In each axial zone 44, 46, 48, the liquid may fill respective interior regions 58, 60, 62 between an outer radius R2 of roll core 14, and an inner radius R3 of porous shell 12. Seals 16, 18, 20 prevent liquid from flowing axially between axial zones 44, 46, 48. Liquid flows radially from interior regions 58, 60, 62 through porous shell 12 to an outer surface 64 of porous shell 12 at an outer radius R4. Liquid transfers from outer surface 64 to an adjacent inker roll or dampener roll, at a region of contact, or contacting nip, formed between outer surface 64 and the adjacent roll.
By constructing porous roll 10 with porous shell 12, liquid transfer from porous roll 10 to an adjacent roll is quasi-continuous. Porous roll 10 can advantageously improve the uniformity of liquid supplied to the printing plate and allows the number of rollers in an inker or dampener to be reduced.
Liquid delivered by porous roll 10 into an inker or dampener is pre-metered by liquid pumps 13, 15, 17 coupled to respective interior tubes 30, 32, 34. At steady state operation, a flowrate of liquid out of outer surface 64 and to an adjacent roll in axial zones 44, 46, 48 is equal to liquid flowrates Q1, Q2, Q3, respectively. Porous roll 10 thus advantageously can reduce or eliminate the intermittent liquid feed.
While
In the embodiment in
Roll core 84 has an outer surface 100 supporting an inner race 102 of bearing 92 and seals 86, 88, 90. Seals 86, 88, 90 form the axial boundaries of axial zones 104, 106, 108. An outer race 110 of bearing 92 is supported by bearing hanger 94.
Porous shell 82, roll core 84, seals 86, 88, 90, inner race 102 of bearing 92, and an inner race 112 of rotary union 96 are free to rotate about a center axis CA2. Outer race 110 of bearing 92, an outer race 114 of rotary union 96, and bearing hanger 94 are not free to rotate about center axis CA2.
Roll core 84 has channels 116, 118, 120 extending in the axial direction from axial edge 98 to axial zones 104, 106, 108. Channels 116, 118, 120 act as liquid feeds for respective axial zones 104, 106, 108 and are machined into roll core 84. Roll core 84 also has holes 122, 124, 126 extending in the radial direction to connect outer surface 100 with respective channels 116, 118, 120.
Rotary union 96 allows liquid to be pumped from a non-rotating liquid pump into channels 116, 118, 120 of roll core 84 as roll core 84 is rotating about center axis CA2. For illustration purposes, rotary union 96 is shown detached from roll core 84 in
During operation of porous roll 80, liquid is pumped at controlled liquid flowrates Q4, Q5, Q6 through holes 122, 124, 126 and into axial zones 104, 106, 108. In each axial zone, the liquid may fill regions 156, 158, 160 between an outer radius R7 of roll core 84, and an inner radius R8 of porous shell 82. Seals 86, 88, 90 prevent liquid from flowing axially between axial zones 104, 106, 108. Liquid flows radially from regions 156, 158, 160 through porous shell 82 to an outer surface 162 of porous shell 82 at an outer radius R9. Liquid transfers from outer surface 162 to an adjacent inker roll or dampener roll at a region of contact, or contacting nip, formed between outer surface 162 and the adjacent roll.
By constructing porous roll 80 with porous shell 82, liquid transfer from porous roll 80 to the adjacent roll is quasi-continuous. Porous roll 80 may advantageously improve the uniformity of liquid supplied to the printing plate and may allow the number of rollers in an inker or dampener to be reduced.
Liquid delivered by porous roll 80 into an inker or dampener is pre-metered by the one or more liquid pumps connected to holes 128, 130, 132. At steady state operation, a flowrate of liquid out of outer surface 162 and to the adjacent roll in axial zones 104, 106, 108 is equal to liquid flowrates Q4, Q5, Q6, respectively. Porous roll 80 thus advantageously can reduce or eliminate the intermittent liquid feed.
While
a shows a schematic view of an axial cross-section of a porous roll 170 according to another embodiment of the present invention. Porous roll 170 is similar to porous roll 10 shown in
Flow into distribution ring 801 may be regulated by one or more pressure relief or check valves 803. Pressure relief valves 803 require liquid to exceed a pre-determined pressure value before the valves 803 will open. By proper selection of this value, liquid can be fully distributed axially and circumferentially in the axial zone before the one of more valves 803 open. Multiple valves 803 may be employed (
b shows a schematic view of a cross section of porous roll 170 along AA of
c shows the cross section of porous roll 170 shown in
a shows a schematic view of an axial cross-section of a porous roll 180 according to another embodiment of the present invention. Porous roll 180 is similar to porous roll 10 shown in
b shows a schematic view of a cross section of porous roll 180 along BB of
Porous shell 212 is supported by the outer race of bearings 222, 224 at the edges of roll core 214. Porous shell 212 may be supported by one or more additional bearings on roll core 214. Porous shell 212 is free to rotate around a center axis CA3.
Roll core 214 has an outer surface supporting the inner race of bearings 222, 224 and seals 216, 218, 220. Seals 216, 218, 220 form the axial boundaries of zones 230, 232. Zone 242 has a channel 228 internal to roll core 214, extending from outer surface of roll core 214, under bearing 224 and under seal 220, to the outer surface of roll core 214, out-board of bearing 224, delivering liquid to an interior region 232. Similarly, zone 240 has a channel 226 internal to roll core 214, extending from outer surface of roll core 214, under bearing 224 and under seals 218, 220 to the outer surface of roll core 214, out-board of bearing 224, delivering liquid to an interior region 230. Channels 226, 228 extend through roll core 214, out-board of bearing 224 and are coupled to liquid feed pumps 160, 162. Channels 226, 228 act as liquid feeds to axial zones 240, 242 respectively.
During operation of porous roll 210, liquid is pumped at controlled flowrates Q7, Q8 through channels 226, 228 and into regions 230, 232. In each zone 240, 242, the liquid may fill interior regions 230, 232 between an outer radius R10 of roll core 214, and an inner radius R11 of porous shell 212. Seal 218 prevents liquid from flowing axially between zones 240, 242. Seals 216, 220 prevent ink from flowing axially outward from zones 240, 242. Liquid essentially flows radially from regions 230, 232 through porous shell 212 to an outer surface 234 of porous shell 212 at an outer radius R12. Liquid transfers from outer surface 234 to an adjacent roller at a region of contact, or nip, formed between outer surface 234 and the adjacent roller.
By constructing porous roll 210 with porous shell 212, liquid transfer from porous roll 210 to an adjacent roller is quasi-continuous. Porous roll 210 can advantageously improve the uniformity of liquid supplied to the printing plate and allows the number of rollers to be reduced.
Liquid delivered by porous roll 210 is pre-metered by the liquid feed pumps 160, 162 coupled to channels 226, 228. At steady state operation, a flowrate of liquid out of outer surface 234 and to an adjacent roll in ink zones 240, 242 is equal to ink flowrates Q7, Q8, respectively. Porous roll 10 thus advantageously can reduce or eliminate intermittent ink feed.
While
During operation of porous roll 210, liquid is pumped through channel 226 and into region 230. In each zone, the liquid may fill region 230 between roll core 214, and porous shell 212. Liquid flows radially from region 230 through porous shell 212 to an outer surface 234 of porous shell 212. Liquid transfers from outer surface 234 to an adjacent roller at a region of contact, or nip, formed between outer surface 234 and the adjacent roller 236. Region 230 between the roll core 214 and the porous shell 212 may contain one or more components to aid in liquid distribution such as a secondary porous material, a material with channels, a void region, check valves, or any combination thereof. These one or more components may include, for example, one or more components of distribution ring 801 shown in
In one preferred embodiment, anilox roll 310 is similar to porous roll 210 shown in
Interior region 332 between the roll core 314 and the porous layer 312 may contain one or more components to aid in liquid distribution such as a secondary porous material, a material with channels, a void region, check valves, or any combination thereof. These one or more components may include, for example, one or more components of distribution ring 801 shown in
Porous shells 12, 82, 212 and porous layer 312 may be constructed of a matrix material, for example, a sintered plastic, metal or ceramic material, or may alternatively be constructed by machining pores into an originally solid shell.
In the preceding specification, the invention has been described with reference to specific exemplary embodiments and examples thereof. It will, however, be evident that various modifications and changes may be made thereto without departing from the broader spirit and scope of invention as set forth in the claims that follow. The specification and drawings are accordingly to be regarded in an illustrative manner rather than a restrictive sense.