This invention relates generally to the field of cylindrical can decorating or printing equipment, and more particularly relates to inker assemblies utilized in such can decorating equipment.
Decorating equipment that apply ink to cans or similarly shaped articles using offset printing techniques are known. Ink of a particular color is transferred from an ink fountain assembly to a plate cylinder and printing blanket by an inker assembly comprising a number of rotating rolls or drums, the ink. Certain rolls known as transfer rolls are typically ceramic coated, while other rolls known as doctor rolls, distributor rolls and form rolls are coated with a closed cell polymer. In known designs the transfer rolls are axially oscillated relative to the other rolls to preclude “ghosting”, the unwanted retention and transfer of a printing plate image on the rollers where the ink has been removed and not reapplied or smoothed by the oscillating rolls. This creates problems in that the oscillating transfer rolls are composed of steel, are water cooled and gear driven, which requires significant energy to operate and will produce vibration in the system from the inertia resulting from the rapid axial movement. Significant heat is generated in the transfer rolls, which results in frequent shaft seal failure and leaking oil. Gear driven systems also require water cooling of the oil in the gearbox, which often results in oil leaks near the printing plates and blankets. The gear driven systems do not provide for independent adjustment of the oscillating frequency during operation. Furthermore, current designs are not easily disassembled, such that removal of the inker assembly for cleaning or replacement is time and labor intensive. Current designs have other problems in addition to those listed above, and it is an object of this invention to address a number of problems inherent in the current designs.
In general, the invention in various embodiments is, in a basic embodiment, a cylindrical can decorator inker assembly, said inker assembly conveying ink from an ink fountain assembly to a plate cylinder, wherein said ink fountain assembly comprises a fountain well, a fountain roll and a ductor roll, and wherein said plate cylinder rotates an image plate against a blanket roll, said inker assembly comprising a non-oscillating first transfer roll intermittently contacted by said ductor roll of said ink fountain assembly; a non-oscillating second transfer roll; and a non-oscillating third transfer roll. In a more complex embodiment, the invention is a cylindrical can decorator inker assembly, said inker assembly conveying ink from an ink fountain assembly to a plate cylinder, wherein said ink fountain assembly comprises a fountain well, a fountain roll and a ductor roll, and wherein said plate cylinder rotates an image plate against a blanket roll, said inker assembly comprising a non-oscillating first transfer roll intermittently contacted by said ductor roll of said ink fountain assembly; a non-oscillating distributor roll in contact with said first transfer roll; a non-oscillating second transfer roll in contact with said non-oscillating distributor roll; a first and second axially oscillating distributor roll both in contact with said second transfer roll; a non-oscillating third transfer roll in contact with said first and second axially oscillating distributor rolls; a first non-oscillating form roll and a second non-oscillating form roll, both in contact with said third transfer roll and with said plate cylinder; and a first axially oscillating ghost chaser roll in contact with said first non-oscillating form roll and a second axially oscillating ghost chaser roll in contact with said second non-oscillating form roll.
In possible embodiments, said first, second and third transfer rolls are driven independently from said plate cylinder and are driven by at least one timing belt. In possible embodiments, the inker assembly comprises an oscillator drive assembly, said oscillator drive assembly oscillating said first and second axially oscillating distributor rolls and said first and second axially oscillating ghost chaser rolls, the oscillator drive assembly in possible embodiments comprising a variable speed motor such that the rate of oscillation of said first and second axially oscillating distributor rolls and said first and second axially oscillating ghost chaser rolls can be varied. In possible embodiments said oscillator drive assembly further comprises a timing belt driving an oscillating mechanism comprising cams and drive rods, said drive rods contacting plungers in said first and second axially oscillating distributor rolls and said first and second axially oscillating ghost chaser rolls.
In possible embodiments, the inker assembly further comprises a first set of front and rear pivoting plates and a second set of front and rear pivoting plates, said first set and second set of pivoting plates each pivoting about the axis of said third transfer roll, wherein said first form roll and said first axially oscillating ghost chaser roll are mounted to said first set of pivoting plates and wherein said second form roll and said second axially oscillating ghost chaser roll are mounted to said second set of pivoting plates, whereby said first and second form rolls are pivotable out of contact with said plate cylinder while remaining in contact with said third transfer roll.
In possible embodiments said first and second axially oscillating distributor rolls and said first and second axially oscillating ghost chaser rolls are mounted in quick release brackets.
In possible embodiments, said first and second axially oscillating distributor rolls and said first and second axially oscillating ghost chaser rolls are mounted onto an outer sleeve coaxially mounted onto a fixed inner shaft, wherein said outer sleeve is axially movable relative to said inner shaft, said inner shaft having an axial bore open on one end, said axial bore retaining a return spring and a plunger rod extending from and axially movable relative to said inner shaft, wherein said outer sleeve is connected to said plunger rod by a mechanical member extending through a pair of slots in said inner shaft, such that axial movement of said plunger rod causes axial movement of said outer sleeve relative to said inner shaft.
In possible embodiments, said first, second and third transfer rolls are mounted onto water-cooled shafts retained within bearings such that said water-cooled shafts are able to rotate, said transfer rolls comprising a water-receiving internal cavity, each end of said transfer rolls comprising a first annular recess having a first depth and a first outer diameter, a pair of bolt-receiving bores, and a second annular recess having a second depth and a second outer diameter, wherein said first depth is lesser than said second depth and said second diameter is lesser than said first diameter; said inker assembly further comprising mounting flanges, mounting bolts and O-rings; wherein said transfer rolls are mounted to said water-cooled shafts by a pair of said mounting flanges, said mounting flanges comprising a collet portion adapted to encircle said water-cooled shafts, a radially-extending flange portion received by said first annular recess, a pair of bolt-receiving bores disposed in said flange portion, and an annular shoulder extending inwardly from said flange portion, wherein said annular shoulder is received within said second annular recess; wherein with said O-rings encircling said water-cooled shafts and disposed within said second annular recesses, and with mounting bolts inserted into said bolt-receiving bores of said mounting flanges and said transfer rolls, tightening of said mounting bolts causes said annular shoulders to compress said O-rings against said water-cooled shafts.
The invention comprises in general an inker assembly for a can decorator, or more broadly a can decorator comprising the described inker assembly and the methodology of decorating cans using the inker assembly. With reference to the drawings, the invention will be described in detail with regard for the best mode and the preferred embodiments. The term “axially oscillating” or variations thereof shall be taken herein to define back-and-forth reciprocal movement in the axial direction, and the term “non-oscillating” or variations thereof shall be taken herein to define non-movement in the axial direction. When the terms describe a roll, the roll is able to rotate about the axis whether it is an axially oscillating roll or a non-oscillating roll.
As seen best in
The inker assembly comprises a plurality of drums or rolls that define an ink conveyance pathway such that contact between the rotating rolls results in the ink being passed from one roll or rolls to the next roll or rolls in the pathway. As shown, the inker assembly comprises in combination a non-oscillating first transfer roll 11, a non-oscillating second transfer roll 13 and a non-oscillating third transfer roll 14. More completely, the inker assembly comprises a non-oscillating first transfer roll 11 intermittently contacted by the ductor roll 93 of the ink fountain assembly, a non-oscillating distributor roll 12 in contact with the first transfer roll 11, a non-oscillating second transfer roll 13 in contact with the non-oscillating distributor roll 12, at least one distributor roll but preferably a first axially oscillating distributor roll 21 and a second axially oscillating distributor roll 22, both in contact with the second transfer roll 13, a non-oscillating third transfer roll 14 in contact with said first and second axially oscillating distributor rolls 21 and 22, at least one form roll but preferably a first non-oscillating form roll 15 and a second non-oscillating form roll 16, both in contact with the third transfer roll 14 and with the plate cylinder 94; and at least one ghost chaser but preferably a first axially oscillating ghost chaser roll 23 in contact with said first non-oscillating form roll 15 and a second axially oscillating ghost chaser roll 24 in contact with said second non-oscillating form roll 16. The axes of the various rolls are aligned in parallel. As is known in the art, the first transfer roll 11, the second transfer roll 13 and the third transfer roll 14 may and will likely have ceramic-coated cylindrical surfaces, while the remaining rolls may and will likely have cylindrical surfaces coated with a closed cell polymer or similar resilient material.
In inker assemblies having multiple rolls, a problem known as ghosting, the undesired retention of ink on the rolls which results in misprints or overprints on the cylindrical cans, must be addressed. In more basic systems, correction of the ghosting problem may require redesign of the label being printed or attempting difficult timing adjustments. The solution to this problem is to axially oscillate certain of the rolls, while other rolls in the inker assembly remain fixed in the axial direction. In the inker assembly as described herein, the first, second and third transfer rolls 11, 13 and 14 are non-oscillating.
The first, second and third transfer rolls 11, 13 and 14 of the inker assembly are powered, while the remaining rolls of the inker assembly are friction driven from contact with the powered rolls. Preferably, the first, second and third transfer rolls 11, 13 and 14 are driven by a single, clutched drive source, the clutch allowing the instantaneous stoppage of the inker roll train, with a first timing belt connecting the drive source to the second transfer roll 13 and either the first or third transfer rolls 11 and 14, and a second transfer belt that connects the second transfer roll 13 to the other of the first or third transfer rolls 11 and 14, and to an idler pulley or tensioner device. The first, second and third transfer rolls 11, 13 and 14 require relatively complex mounting mechanisms, shafts and power connections, are significantly heavier than the other rolls in the inker assembly and must be water cooled during operation to prevent excessive heat build-up. Therefore, the ghosting problem is addressed by making the first, second and third transfer rolls 11, 13 and 14, the distributor roll 12 and the first and second form rolls 15 and 16 of the inker assembly non-oscillating in the axial direction, while the first and second distributor rolls 21 and 22 and the first and second ghost chaser rolls 23 and 24 are axially oscillating rolls. By oscillating the lighter first and second distributor rolls 21 and 22 and the lighter first and second ghost chaser rolls 23 and 24, less power is required and less vibration is directed to the inker assembly.
A preferred embodiment of the oscillator drive assembly is shown best in
Rotation of the ghost roll drive pulleys 35 and the distributor roll drive pulleys 36 operates the oscillating mechanisms such that the ghost chaser rolls 23 and 24 and the distributor rolls 21 and 22 reciprocate or oscillate in the axial direction. A preferred embodiment of the oscillating mechanisms is shown in more detail in
The use of a variable speed motor 31 is preferable to allow for adjustment of the oscillation rate. In current inking systems, the oscillation rate is constant, such that correction of the ghosting problem may require redesign of the label or difficult timing adjustments of the rolls. With a variable speed motor 31, the oscillating rate is initially set to be relatively slow. If ghosting occurs on the cans, the oscillation rate is increased until the ghosting disappears. When labels are changed, the process can be easily repeated to determine the optimum rate of oscillation.
A preferred embodiment for the axially oscillating rolls is shown in
The axially oscillating rolls are mounted such that the outer ends of the actuator rods 61 abut the outer ends of oscillating plunger rods 46, the return spring 59 providing a bias against the actuator rods 61 relative to the fixed shafts 53 such that the actuator rods 61 are extended away from the fixed shafts 53 unless moved by the oscillating plunger rods 46. In this manner, when the plunger rods 46 are individually extended by the oscillator drive assembly, return springs 59 are compressed, as seen in
The oscillating rolls of the inker assembly are preferably mounted in quick release brackets, as shown in
The relatively heavy transfer rolls 11, 13 and 14 rotate at high speed, and high temperature build-up is a problem that must be addressed. Typically, this problem is addressed by providing a water cooling system, the water being routed through the roll shafts and into and out of the interior of the rolls to reduce the temperature through heat transfer. O-rings are utilized to provide seals between the rolls and the shafts. In current designs the O-rings are often damaged during insertion of the shaft into the roll because of shearing forces. A preferred embodiment for the transfer rolls 11, 13 and 14 is shown in
To improve the mounting mechanism and seal between the roll 71 and the shaft 73, the transfer roll 71 comprises a pair of annular transfer roll mounting flanges 85, the mounting flanges 85 each comprising a collet portion 86 pressed onto the shaft 73 by a clamp collar 84, a radially extending flange portion 87 that abuts the ends of the roll 71, and an inwardly-facing annular shoulder portion 89. Bolt receiving bores 88 are provided in the radially extending flange portions 87. The ends of the transfer roll 71 is provided with a first annular recess 96 corresponding in size and dimensions with the radially extending flange portion 87 and a second annular recess 98 that substantially corresponds with the size and dimensions of the annular shoulder portion 89, the second annular recess being deeper than the length of the annular shoulder portion 89 such that a gap is created to receive the O-ring 90. Bolt receiving bores 97 are correspondingly positioned in the ends of roll 71 to align with the bolt receiving bores 88. With this structure, the roll 71 is slid onto the shaft 73 and the O-rings are positioned in the second annular recesses 98 of each end. The transfer roll mounting flanges 85 are then slid onto the shaft 73 to abut the ends of the roll 71, the radially extending flange portion 87 seating within the first annular recess 96 and the annular shoulder portions 89 seating within the second annular recess 98, the ends of the annular shoulder portions 89 abutting the O-rings 90. Bolts are inserted into the aligned bolt receiving bores 88 and 97 and tightened, which forces the roll mounting flanges 85 axially inward to secure the roll 71 and to compress the O-rings 90. This lateral compression of the O-rings 90 causes them to expand in the radial direction against the shaft 73, thereby creating the required seal to retain the water within the internal cavity 72 of the transfer roll 71. The collet portions 86 of the mounting flanges 85 are then secured to the shaft 73 by clamp collars 85.
In the inker assembly as shown in
To provide easier access to the various rolls of the inker assembly, a preferred inker assembly mount is provided as shown in
It is contemplated that equivalents and substitutions for certain elements set forth above may be obvious to those of ordinary in the art, and therefore the true scope and definition of the invention is to be as set forth in the following claims.
Number | Name | Date | Kind |
---|---|---|---|
1995701 | Buttner | Mar 1935 | A |
4741266 | Stirbis et al. | May 1988 | A |
5062362 | Kemp | Nov 1991 | A |
5249524 | Morris | Oct 1993 | A |
5823109 | Hummel et al. | Oct 1998 | A |
7380498 | Domotor | Jun 2008 | B2 |
20120272846 | Fleischer et al. | Nov 2012 | A1 |
Number | Date | Country | |
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20130174753 A1 | Jul 2013 | US |