SE535722C2 - Method and rotogravure printing device for printing by the ESA method - Google Patents

Description

5 35 535 722 generate an electric field in the area of the nip between the printing and engraving cylinders when ink transfer takes place. The ink is electrostatically drawn by the field to the substrate. Depending on the dielectrophoresis (movement of neutral material which is caused by polarizing effects in a non-uniform electric field) fl the ink moves towards areas with denser field lines found in the edges of the ink cell. Consequently, no lifting force acts on the ink in the center of the ink cell and it results in a monk-shaped ink lift.

SUMMARY OF THE INVENTION The object of the present invention is to overcome or at least minimize at least some of the disadvantages and disadvantages of the thickening method described above.

This can be achieved with a rotogravure printing device according to claim 1.

Thanks to this invention, a lifting force acts on the ink even in the middle of the cell, which gives a smoother print, a better shade value and a reduction of the ink consumption.

According to one aspect of the invention, the bottom of the ink cells has at least a protruding portion which acts as a gravitational force for field lines and as a consequence a lifting force acts on the ink also in the middle and the ink lifts more uniformly out of the cell and the resulting pressure points are whole points. hole in the middle.

Most preferably, the wall portion of the cell extends substantially vertically. In this way, the ink line is faster, because the concentration of fold lines is greater at the edges than if the walls are sloping.

According to yet another aspect of the invention, the protruding portion has a height equal to or less than the height of the wall portions.

According to yet another aspect of the invention, the base width of the protruding portion is at least a quarter of the size of the cell width so that no areas with sparse lines occur.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail with reference to the appended figures, of which: l0 20 25 30 35 Fig. 1 Fig. 2 Fig. 3 Fig. 4 Fig. 5 Fig. 6 Fig. 7 Fig. 8 Fig. 9 535 722 A) and B) show the sequential method of ink transfer in rotogravure printing according to the prior art, constitute a cross-sectional view of a laser etched, U-shaped ink cell 1 according to the prior art such as that used in Fig. 1 B, constitute a cross-sectional view of a mechanically engraved V-shaped ink cell according to the prior art such as that used in Fig. 1A, shows a top view of a section of an engraving device with ink cells according to the invention, shows a cross-sectional view, along the line CC in Fig. 4, of an ink cell according to the invention, shows a top view of a section of an engraving device provided with alternative ink cells according to the invention, constitutes a cross-sectional view, along the line DD in Fig. 6, of an alternative ink cell according to the invention, constitutes a cross-sectional view of yet another alternative embodiment of a ink cell according to the invention, and constitutes a cross-sectional view of the sleeve an alternative embodiment of an ink cell according to the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS The following description and examples therein are provided for the purpose of describing and illustrating certain embodiments of the invention only and are not intended to limit the scope of the invention in any way.

Fig. 1 A) and B) show the sequential method of ink transfer by rotor engraving printing according to the prior art by means of an engraving cylinder 4 with many immersed microscopic depressions 2 (Fig. A) and 1 (Fig. B), so-called cells. The amount of ink available for placement on a substrate is controlled by the size and depth of the cells 1, 2. The engraving cylinder 4 is mounted for rotation about a horizontal axis and provided with high fluidity inks. A doctor blade (not shown) removes ink from those portions of its peripheral surface which do not contain the cells, the cells containing ink until it is deposited on the surface of the substrate. This is accomplished by allowing the substrate to pass between the engraving cylinder 4 and a printing cylinder (not shown) having a resilient coating which presses the bottom surface of the substrate against the engraving cylinder 4 so that ink 5 in cells 1, 2 can be deposited on that surface. The transfer of ink 5 from the engraving cells 1, 2 to the substrate is increased by the application of an electric field between the engraving and printing cylinders which pass through the ink 5 due to dielectrophoresis.

Fig. 1 shows sequentially the method of transferring ink 5 by means of the very lowest part a) showing it before contact with the nip, in an intermediate part b) showing the phase of ink lifting and in the very upper part c) the contact surface in nypet. As can be noted, a monk-shaped ink lift is obtained, which means that not all the ink 5 is deposited from all the cells 1, 2, which results in incomplete points which lead to reduced quality and sometimes consequently incorrect prints.

Fig. 2 is a cross-sectional view of a laser etched, U-shaped ink cell according to the prior art, such as that used in Fig. 1B. These cells 1 are in the form of circular engravings with substantially vertical edges 11, 12 and a substantially horizontal bottom 14.

The concentration of field lines 10 is greater in the edges 11, 12 of the cell 1 than in the middle 13 of the cell 1.

This means that no lifting force acts on the ink in the middle 13 of the ink cell 1 and the result is a monk-shaped ink lift as shown in Fig. 1 B.

Fig. 3 is a cross-sectional view of a mechanically engraved V-shaped ink cell 2 according to the prior art, such as that used in Fig. 1 A. The volume of the cell 2 forms an upside-down pyramid with four surfaces, seen from above, the cell 2 resembling a diamond. The cell 2 has inclined edges 21, 22 which meet in the middle 23 of the cell 2. The concentration of fold lines 10 is greater in the edges 21, 22 of the cell 2 than in the middle 23 of the cell 2. The consequence of this is that no lifting force fi acts on the ink in the ink cell 2 middle 23 and the result is a donut-shaped ink shelter fi as can be seen in Fig. 1 A.

It has been found that the shape of the ink cell 1, 2 affects the efficiency of the ink transfer. The ink lift from an ink cell with U-shape 1 (laser etched) is faster than from an ink cell with V-shape 2 (mechanically engraved). Considering the field lines 10, 20 in Figs. 2 and 3, the concentration of field lines 10 at the edges 11, 12 of the U-shaped ink cell 1 is greater than in the case of a V-shaped ink cell 2. For both cell types 1, 2, the field lines 10 are , 20 sparse in the middle 13, 23 of the ink cell 1, 2. ).

Fig. 4 is a top view of a section of an engraving device 4, e.g. an engraving cylinder, provided with ink cells 3 according to a preferred embodiment of the invention.

As can be noted, each cell 3 is formed by a circular outer wall 31 and a projecting apex 34 in the center 35 of the cell 3.

Fig. 5 shows a cross-sectional view of an ink cell 3, shown in Fig. 4, along the line CC in Fig. 4. The ink cell 3 has substantially vertical walls 31 and a substantially horizontal bottom 33 with a height h of the walls 31 and a width w on the bottom 33 due to raster and hue. In the middle 35 of the bottom 33, a further top 34 protrudes vertically, i.e. preferably usually parallel to the walls 31. The top 34 is cone-shaped with its thickest part in the bottom 33. The width W of the thickest part of the top 34 is in the range 0.05w - 0.5w, i.e. 0.05w <W <0.5w, preferably 0.1w <W <0.4w. The height H at the top 34 is between 0.1h and 0.9h, i.e. 0.1h <H <0.9h, preferably 0.5h <H <0.8h. This additional peak 34 in the center 35 of the ink cell 3 acts as a traction force for additional felt lines 10 and the consequence of this is that a lifting crane acts on the ink also in the center 35 of the ink cell 3. In this way the ink can be lifted more uniformly from the cell 3 and the resulting pressure points. form whole points without any hole in the middle.

The shape of the points is the result of different cooperating forces, e.g. electric forces that lift the ink out of the ink cell 3 at the edges 3 of the cell 31 / walls. These lifting forces are transmitted to the ink surface in the middle 35 of the ink cell 3 by means of surface tension. The amount of ink follows the ink surface depending on cohesive forces. In these interactions, however, the transfer of the ink slide from the edges to the center by surface tension is very sensitive, which means that there is some unpredictability regarding the result (the exact point size and point shape), which leads to unpredictability regarding point size and shape in macroscopic scale. and evenness in the printed result. Thanks to the use of the protruding part 34, the lightning force now works in principle over the entire ink cell 3. In addition, the new arrangement can offer a more uniform pattern for the field lines 10 and the ink lifting process is made more uniform, resulting in more predictable hue values, which in turn can result in minor proofreading. It can also offer smoother printing and - as a consequence of better ink coverage - a reduction in ink consumption. According to another aspect, the protruding portion 34 may have other shapes that create opportunities for arranging different patterns for field lines 10, which provides an opportunity to control the print in the macroscopic scale.

Fig. 6 is a top view of a section of an engraving device 4, e.g. an engraving cylinder, provided with an alternative embodiment of ink cells 6 according to the invention.

As can be noted, each cell 6 is formed by a hexagonal outer wall 61 and a projecting top 64 in the center 65 of the cell 6.

Fig. 7 shows a cross-sectional view of an ink cell 6, as shown in Fig. 6, along the line D-D.

The ink cell 6 has substantially vertical walls 61 and a substantially horizontal bottom 63 with a height h on the walls 61 and a width w on the bottom 63 which depends on the grid and hue. In the middle 65 of the bottom 63, a further top 64 protrudes vertically, i.e. preferably usually parallel to the walls 61. This further top 64 is in the form of a hexagonal, cut-off cone with a base width W in the range 0.08 - 0.8w, i.e. 0.08w <W <0.8w, preferably 0.1w <W <0.6w. The height H of the peak 64 is between 0.1h and 0.9h, i.e. 0.1h <H <0.9h, preferably 0.5h <H <0.8h. The hexagonal defoaming cone 64 in the center 65 of the ink cell 6 acts as a traction fi for additional field lines 10 and the consequence of this is that a lifting force fi acts on the ink also in the center of the ink cell 6. In this way the ink can be lifted more uniformly out of the cell 6 and the resulting pressure points form whole points without any hole in the middle.

Fig. 8 is a cross-sectional view of the sleeve an alternative embodiment of an ink cell 7 according to the invention. The ink cell 7 has substantially vertical walls 71 and a substantially horizontal bottom 73 with a height h on the walls 71 and a width w on the bottom 73 which depends on the grid and hue. In the middle 75 of the bottom 73, a further top 74 protrudes vertically, i.e. preferably usually parallel to the walls 71. The top 74 has the shape of a pillar with a width W in the range 0.05w - 0.5w, i.e. 0.05w <W <0.5w, preferably 0.1w <W <0.4w. The height H of the column is between 0.1h and 0.9h, ie. 0.1h <H <0.9h, preferably 0.5h <H <0.8h. This additional peak 74 in the center 75 of the ink cell 7 acts as a traction force for additional field lines 10 and the consequence of this is that a lifting force acts over the center of the ink cell 7. In this way, the ink can be lifted more uniformly out of the cell 7 and the resulting pressure points form whole points without any hole in the middle.

Fig. 9 is a cross-sectional view of yet another alternative embodiment of an ink cell 9 according to the invention. The ink cell 9 is V-shaped with sloping edges 91, 92 with a height h, and the whole cell 9 has a width w, the height h and the width w depending on the grid and hue.

In the center 9 of the cell 9, a further peak 94 protrudes vertically. The apex 94 is cone-shaped with the thickest part at the bottom of the cell 9. The width W of the thickest part of the top 94 is in the range 0.05w - 0.5w, i.e. 0.05w <W <0.5w, preferably 0.1w <W <0.4w. The height H of the peak 94 is between 0.1h and 0.9h, i.e. 0.1h <H <0.9h, preferably 0.5h <H <0.8h. This additional peak 94 in the center 93 of the ink cell 9 acts as a traction force for additional tent lines 10 and the consequence of this is that a lifting force acts over the center of the ink cell 9. In this way, the ink can be lyne more uniformly out of the cell 9 and the resulting pressure points form whole points without any hole in the middle.

As will be appreciated by those skilled in the art, a number of changes and modifications may be made in the above-described and other embodiments of the present invention without departing from the scope as defined in the appended claims. The ink cells may, for example, have other forms of dehydration than those described above, e.g. the ink cells may have an octagonal outer wall and the walls may be slightly or strongly inclined.

The protruding part in the bottom can have other embodiments than those described above, the main thing being that the protruding part adds additional non-horizontal surfaces as contact points for further tent lines. Other possible embodiments may be, for example, a pyramid, an obelisk with e.g. three or four surfaces, a cut-off cone, etc. The protruding part may also be a hollow structure similar to a ring which is hollow in the middle or a ridge extending over part or all of the bottom of the ink cell or many short ridges. It is also possible to have more than one protruding part in the same ink cell. The various embodiments of the ink cells and the protruding portions described above can, of course, be combined in other ways than those described herein.

Those skilled in the art will also appreciate that the size, height and width of the ink cell may vary depending on what is intended to be printed.

Claims (9)

535 722 PATENT CLAIMS 1. A rotogravure printing apparatus, comprising a printing cylinder and an engraving cylinder; the surface of said engraving cylinder is provided with many ink cells (3), each of which has a wall portion (31) and a bottom portion (33), characterized in that at least a number of said cells (3) are provided in their bottom with at least one protruding part (34) and in that said rotogravure printing device comprises means arranged to generate by means of the ESA method an electric field in the area of a nip between said printing cylinder and said engraving cylinder. Rotogravure printing device according to claim 1, characterized in that said wall portion (31) extends substantially vertically, and preferably has a circular horizontal cross-section. A rotogravure printing device according to claim 1 or 2, characterized in that said projecting part (34) is located in the middle (35) of said cell (3). A rotogravure printing device according to claim 1, 2 or 3, characterized in that said projecting part (34) has a height (H) which is less than the height (h) of the wall portions (31) - Rotogravure printing device according to claim 4, characterized in that said projecting part (34) has a height (H) which is in the range 0.1h <H <0.9h, preferably 0.5h <H <0.8h. Rotogravure printing device according to one of Claims 1 to 5, characterized in that the base width (W) of the projecting part (34) is less than half the size of the width (w) of the cell (3). Rotogravure printing device according to claim 6, characterized in that said base width (W) is in the range 0.05w - 0.5w, i.e. 0.05w <W <0.5w, preferably 0.1w <W <0.4w. Rotogravure printing device according to any one of claims 1-7, characterized in that said protruding part (34) is cone-shaped. A method of controlling ink lift in rotogravure printing using the ESA method for generating field lines, comprising the steps of providing a surface with 535,722 many ink cells (3), each having a wall portion (31) and a bottom portion (33). ), characterized by arranging in the center of the ink cells (3) a centrally located, projecting part (34) which adds further field lines (10) in the middle of said ink cells (3) so that a lifting force fl acts on ink also in said ink cells (3) mitt.