The present invention relates generally to a flexographic printing plate cleaner that can provide its cleaning function while the printing press is operating.
The present invention is an improvement over U.S. Pat. No. 5,519,914, which is hereby incorporated by reference.
It is an object of the present invention to provide a flexographic printing plate cleaner that can operate under three modes, namely, a wipe mode for removing debris on the printing plate while the press is operating, a spot clean mode for cleaning specific location on the printing plate while the printing press is operating, and a wash mode for rinsing the printing plates while the printing press is offline.
It is another object of the present invention to provide a flexographic printing plate cleaner that provides a dual surface cleaning pad, where one surface is used for wiping the printing plate and another surface for more aggressive plate cleaning.
It is another object of the present invention to provide a flexographic printing plate cleaner that adjusts the traversing speed of the cleaning head so that the same amount of contact between the cleaning pad and the printing plate is maintained regardless of the printing machine speed.
It is another object of the present invention to provide a flexographic printing plate cleaner that provides the scrubbing efficiency of a direct contact system but is able to precisely control contact pressure and liquid flow without compromising quality during the printing operation.
It still another object of the present invention to provide a flexographic printing plate cleaner that requires relatively little maintenance, such as daily replacement of a small roll of cloth and periodic refilling of water into the pressurized vessel that can be routinely completed by production personnel.
In summary, the present invention provides a flexographic printing plate cleaner, comprising a linear actuator operably mounted relative to a plate cylinder carrying a flexographic printing plate; a frame carried by the linear actuator for movement along a path parallel to an axis of rotation of the plate cylinder; and a double-acting three-position cylinder carried by the frame. The cylinder includes a first piston rod having a retracted position, a first extended position and a second extended position. A backing plate is secured to an exterior end of the first piston rod and movable therewith. A cleaning pad is disposed in front of the pressure plate and adjacent the flexographic printing plate such that the pad engages the printing plate at a first pressure when the first piston rod is at the first position, and at a second higher pressure when the first piston rod is at the second position.
The present invention also provides a flexographic printing plate cleaner, comprising a linear actuator operably mounted relative to a plate cylinder carrying a flexographic printing plate; a cleaning head carried by the linear actuator for movement along a path parallel to an axis of rotation of the plate cylinder; and a speed encoder operably associated with the plate cylinder and the actuator to control the traverse speed of the cleaning head across the length of the printing plate during cleaning. The cleaning head has a first position away from the printing plate and a second position in engagement against the printing plate to clean the printing plate while the plate cylinder is rotating.
The present invention further provides a flexographic printing plate cleaner, comprising a linear actuator operably mounted relative to a plate cylinder carrying a flexographic printing plate; and a cleaning head carried by the linear actuator for movement along a path parallel to an axis of rotation of the plate cylinder. The cleaning head includes a cleaning pad comprising a cloth and bristles protruding through the cloth. The cleaning pad has a first position away from the printing plate and a second position in engagement against the printing plate wherein the cloth and the bristles are in engagement with the printing plate for cleaning.
These and other objects of the present invention will become apparent from the following detailed description.
A flexographic printing plate cleaner made in accordance with the present invention is disclosed in
The cleaner 2 comprises a cleaning head 10 carried by a linear actuator 12 between the outer edges 14 of the printing plate 4 and to any position in-between. The actuator 12 includes an endless toothed belt 16 driven by a stepper motor 18 mated to a gear reducer 20.
A speed encoder 22 including an encoder wheel 24 provides rotational speed information to the motor 18 so that the traverse speed of the cleaning head 10 across the printing plate 4 may be adjusted automatically, depending on the rotational speed of the plate cylinder 6 so that the same amount of contact between the cleaning head 10 and the printing plate 4 is maintained regardless of the plate cylinder's speed. The encoder wheel 24 is mounted in a standard manner for rotational engagement with the plate cylinder 6 by means of a pivot arm 26 mounted to a bracket 28, as schematically shown in
Referring to
A base structure 36 is operably secured to the frame 30. A double-acting three-position cylinder 38 is attached to the base structure 36 in a standard manner, such as by bolts 40 shown in
A roll 54 of cloth 58 is carried by an unwind spindle 56. The cloth 58 is coursed from the roll 54 to underneath, in front and on top of the base structure 36 and wound around a rewind spindle 60 driven by a motor 62. A low cloth sensor 64 provides an alarm when the supply cloth roll 54 is nearly used up. The sensor 64 includes a pivoting arm 66 with one end in engagement with a used roll 68 and the other end being associated with a switch 70. As the used roll 68 increases in diameter, the arm 66 pivots radially, eventually activating the switch 70 to send an alarm to a controller when the used roll 68 reaches a certain diameter indicative of the cloth roll 54 being nearly used up. The low cloth sensor 64 is further described in U.S. Pat. No. 5,519,914. The cloth 58 is a highly absorbent “clean room” grade, 100% woven polyester linen available from Lymtech Scientific, Chicopee, Mass. under the designation Purity Wipes.
The rewind spindle 60 is driven by the motor 62 by conventional means such as belt 72, as shown in
Referring to
Referring to
The cylinder 38 comprises chambers 78 and 80 separated by a wall 82. A piston 84 with a piston rod 86 is disposed in the chamber 78. A piston 88 with its associated piston rod 90 are disposed within the chamber 80. The piston rod 86 extends through an opening in the wall 82 and engages the piston 88. The piston rod 90 extends through an opening through an end wall 92 and through an opening in a bottom wall 94 of the recess 44. A bolt 96 or other standard means secures the piston rod 90 to the backing plate 46. An end wall 98 encloses the chamber 78. Fluid inlet port 100 communicates with the chamber 78 and inlet ports 102 and 104 with the respective chamber 80, as best shown in
The cylinder 38 has a fully retracted position, as shown in
When pressurized fluid, such as compressed air, is supplied to fluid inlet port 100, the piston 84 moves to the wall 82, and pushes the piston 88 to an intermediate position within the chamber 80, thereby pushing the backing plate 46 partway toward the printing plate 4, causing the cloth 58 to make contact with the printing plate 4 with sufficient pressure to wipe the printing plate 4 as it turns with the plate cylinder 6. The sponge pad 48 is depressed to further wet the cloth 58. At this position, called the wipe mode, a very low air pressure, for example under 20 psi, allows the sponge pad 48 and the cloth 58 to float over the surface of the plate 4. The wipe mode allows the cloth to lightly collect the debris (hickies) from the plate surface, and allows a light continuous wiping of the plate, resulting in greatly improved printing quality without stopping the press to hand wide the plate. Control of fluid flow to the sponge pad 48 is such that the cleaning fluid does not disrupt the dispersal of ink from the plate to the board.
When pressurized fluid is supplied to the fluid inlet port 102, the piston 88 moves to the end wall 92, causing the backing plate 46 to move further towards the printing plate 4, thus further depressing the sponge pad 48 and causing the bristles 50 to protrude through the weave of the cloth 58 and make contact with the printing plate 4 to provide thorough scrubbing of the contoured surface of the printing plate. At this position, called the wash mode, more aggressive plate cleaning is provided by the bristles whenever the press is not in production. During the wash mode, a higher pressure, for example 30 psi, is supplied to the inlet port 102 to allow a greater force to be applied to the backing plate 46, forcing the bristles to make more forceful contact with the plate. A higher fluid flow rate is also provided to the sponge pad 48 to allow a more thorough washing of the printing plate, which is done offline when printing is not being performed. The wash mode thoroughly soaks the sponge pad to assist with the removal of dried ink from the surface of the printing plate 4.
Separate liquid control is provided for the wipe mode compared to the wash mode.
The various components of the cleaner 2 are controlled from a programmable controller 106. The inlet hose 52 for the cleaning fluid is connected to a solenoid valve 108 which in turn is connected to a liquid pressure vessel 110 with a level sensor 112 connected to the controller 106. The inlet fluid port 110 of the cylinder 38 is connected to a solenoid valve 114. The fluid inlet port 102 is connected to another solenoid valve 116, set at a higher pressure than the valve 114. The valves 114 and 116 are controlled from the controller 106. A compressor 118 supplies compressed air to the pressure vessel 110 and to the cylinder 38.
The operation of the cleaner 2 will now be described. Referring to
Under the wipe mode, the printing plate width is selected at 120 to control the traverse distance of the cleaning head 10. A liquid pulse time is selected at 122, which determines the amount of time the solenoid valve 108 is pulsed to inject the cleaning fluid to the sponge pad. The traverse speed for the cleaning head 10 across the printing plate is selected at 124. A cloth advance time is selected at 126 which determines the operation of the rewind motor 62 to draw a new, clean section of the cloth 58 over the sponge pad 48. After the cleaner 2 is started at 128, alarms are checked at 130 for “low cloth” from the sensor 64 or for a low liquid level from the sensor 112. The cleaning head 10 is then moved to the edge of the plate at 132, the cloth is advanced at the selected time at 134, the cloth is moistened at 136 by operating the valve 108 and the sponge pad is extended to the intermediate position at 138 by operating the valve 114 to provide compressed air into the chamber 78. The cleaning fluid is then pulsed at 140 by intermittently operating the valve 108, thereby injecting the cleaning fluid through the passageway 74 to the sponge pad 48. The cleaning head 10 then traverses the length of the printing plate at 142 while the traverse speed is adjusted based on the speed of the plate cylinder 6, as determined by the speed encoder 22. The cleaning head is then stopped at the end of the plate at 144. The cleaning head is then retracted at 146 by providing compressed air through the inlet port 104 into the chamber 80. The whole process may be repeated starting at 130 for as many times as desired until the operator exits at 148.
Under the spot clean mode, the steps are similar to the wipe mode except that cleaning is done for a specific location on the printing plate. The location is entered at 150. In addition, the cleaning head stays engaged with the printing plate for a preselected time at step 152. The cleaning head is retracted at 154, after which the operator can repeat the process for the same location at 156 or exit at 158.
The wash mode is similar to the wipe mode except that the cylinder 38 is extended to its fully extended position at 160. Each cycle can be repeated as many times as desired at 162 until the operator exits at 164.
While this invention has been described as having preferred design, it is understood that it is capable of further modification, uses and/or adaptations following in general the principle of the invention and including such departures from the present disclosure as come within known or customary practice in the art to which the invention pertains, and as may be applied to the essential features set forth, and fall within the scope of the invention or the limits of the appended claims.
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Number | Date | Country | |
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20040244618 A1 | Dec 2004 | US |