PL228131B1 - Spatial structure of the surface of anilox roller intended to transfer paint onto the painting roller, based on the regular pentagon figure - Google Patents

Description

The subject of the invention is the spatial structure of the surface of a printing anilox cylinder intended to be transferred with lacquer to a varnish roller, based on the figure of a regular pentagon.

The spatial structures of the surface of anilox printing cylinders for transferring the varnish are known, consisting of three-dimensional ink tubes with spatial thresholds between them. In the known solutions, the structure of the rollers causes the formation of high pressure under the leveling strip (which is used to remove excess varnish from the cylinder surface) during the process of applying the varnish, as a result of which - as a result of the difficulty in escaping the varnish from the fillets and moving between them - the strip (normally adjacent to cylinder) rises. This, in turn, contributes to problems related to the uncontrolled leakage (splashing) of varnish and the appearance of streaks on the print. It is also known from the Polish patent application No. P.405855, filed for the Applicant of the present invention, the spatial structure of the surface of an anilox printing cylinder, however, based on polygons, with a large degree of irregularities, the basis of which are completely different functions.

In the solution according to the invention, the spatial structure of the surface of the printing anilox cylinder consists of ink boxes arranged on the plan of a regular pentagon. There are also squares and equilateral triangles between the inkwells with wall lengths identical to the length of the regular pentagon wall. The inkwells are positioned in relation to each other according to the following relationships: on the walls of each regular pentagon, on the plan of which the inkwells are arranged, and which is the basic unit of the structure, there are 5 squares with equilateral triangles between them. The larger unit of the structure created in this way, built around the base pentagon, consists of squares and equilateral triangles, creating a regular decagon (decagon). On the faces of each regular decagon, in turn, there are successive regular pentagons with ink bubbles. This is how another, even larger unit of the structure was created, forms an icosagon with twenty equal sides, each angle measuring 108 ° and the sum of the angles being 2160 °. These 20sons form the basis of the mesh structure on the roller surface and are spaced as closely as possible to each other in regular sequences. The spaces between the individual icosagons are properly completed with equilateral triangles and squares with faces of the same length. The bottom of the ink tubes preferably has the shape of at least one wedge. Such inkwells can take various forms, in particular single-shaped, three-shaped, six-shaped, nine-shaped, twelve-shaped or fifteen-shaped.

The bottom of the inkwells may advantageously be flat in shape and the inkwells are prisms.

Printing cylinders are used to evenly transfer the varnish of a strictly defined and uniform thickness to the roller, which is in direct contact with the surface of the printed carrier. In the process of varnishing, the ink tubes that make up the cylinder structure are filled with varnish under pressure. Then the aligning bar removes the excess varnish from the cylinder surface, which makes contact with the surface of the varnish roller. The device in question can be used for printing on an offset printing machine equipped with a varnishing unit, a cylinder system, and also for other printing techniques capable of adapting this technology.

Inkwaves are arranged in a specific, but unique way.

The new ink tube structure is able to meet the highest quality requirements. It guarantees full use of the possibilities of currently used printing machines. It enables exceptionally good reproduction, especially in the process of varnishing, demanding and difficult surfaces with non-absorbent or poorly absorbent character, such as IML and BOPP foils.

The significant advantages of the new surface structure compared to the solutions used so far include in particular:

- increasing the precision of the anilox roller operation,

- much more efficient paint transfer and increased process stability.

The solution according to the invention also ensures that there is a lower pressure on the cylinder surface (under the equalizing bar) and facilitates the release of the varnish from the flasks, thanks to which it is possible to achieve the desired density with the use of a higher ruling than in the case of known solutions. The use of the solution according to the invention also minimizes the troublesome phenomenon of microfoam caused by varnish residues not absorbed by the printed surface.

PL 228 131 B1

Additional beneficial effects occur in the variant of the solution in which the bottom of the inkwells is wedge-shaped. This shape strengthens the walls of the inkwell and facilitates the transfer of the varnish to the outside of the inkwell. The transfer of the varnish is carried out as a result of the centrifugal force during the rotation of the cylinder during operation and the change in the surface tension of the varnish.

The subject of the invention is shown in the embodiment on the drawing, in which the individual figures show:

- fig. 1: general view (flat) of a section of the cylinder surface structure, with a schematic marking of individual modules,

- fig. 2: general view (flat) of a section of the structure of the cylinder surface, with an example of the arrangement of different types of tubes,

- fig. 3: specification of the 6 types of different-shaped inkwells occurring in the structure,

- fig. 4: general three-dimensional view of a fragment of the structure with different types of a booklet, where the top, well and wedge are visible,

- fig. 5: general (flat) view of the structure of a wedge-shaped cone with a mono-shape base,

- fig. 6: general (flat) view of the structure of the wedge-shaped cone with a tri-shape base,

- fig. 7: general (flat) view of the structure of the hexagonal wedge-shaped cone,

- fig. 8: general (flat) view of the 9-shaped wedge-cone structure,

- fig. 9: general (flat) view of the twelve-shaped wedge-cone structure,

- fig. 10: a general (planar) view of the structure of a wedge-shaped cone with a fifteen-shape base.

For the production of the cylinder surface, high-quality ceramic material with the unique structure of the spiral spherical cone cones is used, which creates a coating with a hardness of 1320 ° on the Vickers scale (it is called HV). The surface of the shell covers the cylinder throughout its cylindrical space and has dimensions of 1000 mm (length) x 707 mm (diameter). The described exemplary spatial structure of a cylinder is a fragment of the structure with dimensions of 50 gm x 60 gm and consists of 6 spatial inkpots 1 - understood as the number of whole different inkpots 1 which are arranged in such a configuration that each of them is surrounded by inkpots and the other kind. In the case of the ink-box 1 marked X1 (single-shape) based on the figure of a circle, the remaining ink-boxes 1 surrounding it take the designations X3 (three-shaped), X6 (six-shaped), X9 (nine-shaped), X12 (twelve-shaped), X15 (fifteen-shaped) and they differ shape of the base and the degree of rotation around its axis, assuming that they have a common shape of the top constituting the bottom of the ink-tube.

In the exemplary structure, inkpots 1 take the designations X1 to X15, starting with the middle inkpot 1 labeled X1, and ending with the inkpots 1 surrounding it labeled X3 to X15. Each of the inkwells 1 fulfills the assumptions of the structure and has its own specific characteristics, as indicated below.

Description of the function of rotation of the ink bottle 1:

akn = 360 / n + k akn - angle of rotation of a given ink cartridge 1 n - number of shapes in the base of a ink cartridge 1 k - another ink cartridge 1 appearing in the structure where k e {1, ..., 360 / n}

Kałamarzyk 1 marked X1:

- construction based on a cone with a wedge-shaped apex in the shape of a circle (the base of the apex differs from the directly adjacent ink boxes 1)

- the angle of rotation around its own axis (each of the existing inkwells 1 of the same type differs from the next rotation angle determined on the basis of the function described above)

For the 1 X1 ink cartridge we take n = 1, i.e. ke {1, ..., 360}, therefore we take the value k = 4 for example - it means that we calculate the angle for the fourth ink cartridge appearing in the structure pattern ak = 4, n = 1 = 360/1 + 4 and k = 4, n = 1 = 364 °

PL 228 131 B1

Kałamarzyk 1 marked X3:

- construction based on a cone with a wedge-shaped apex on the plan of a three-shape figure (the base of the apex differs from the directly adjacent ink boxes 1)

- the angle of rotation around its own axis (each of the existing inkwells 1 of the same type differs from the next rotation angle determined on the basis of the function described above)

For the 1 X3 inkwell we take n = 3, i.e. ke {1, ..., 120}, therefore we take the value of k = 3 for example - it means that we calculate the angle for the third inkwell appearing in the structure pattern ak = 3, n = 3 = 360/3 + 3 and k = 3, n = 3 = 123 °

Kałamarzyk 1 marked X5:

- construction based on a cone with a wedge-shaped apex on the plan of a five-shaped figure (the base of the apex differs from the directly adjacent ink boxes 1)

- the angle of rotation around its own axis (each of the existing inkwells 1 of the same type differs from the next rotation angle determined on the basis of the function described above)

For the 1 X5 ink cartridge we take n = 5, i.e. ke {1, ..., 72}, therefore we take the value k = 6 for example - it means that we calculate the angle for the sixth ink cartridge appearing in the structure pattern ak = 6, n = 5 = 360/5 + 6 and k = 6, n = 5 = 78 °

Kałamarzyk 1 marked X9:

- construction based on a cone with a wedge-shaped apex on the plan of a nine-shaped figure (the base of the apex differs from the directly adjacent ink boxes 1)

- the angle of rotation around its own axis (each of the existing inkwells 1 of the same type differs from the next rotation angle determined on the basis of the function described above)

For a 1 × 9 ink cartridge, we take n = 9, i.e. ke {1, ..., 40}, so for example, we assume the value of k = 5 - it means that we calculate the angle for the fifth ink cartridge appearing in the structure pattern ak = 5, n = 9 = 360/9 + 5 and k = 5, n = 9 = 45 °

Kałamarzyk 1 marked X12:

- construction based on a cone with a wedge-shaped apex on the plan of a twelve-shaped figure (the base of the apex differs from the directly adjacent ink windows 1)

- the angle of rotation around its own axis (each of the existing inkwells 1 of the same type differs from the next rotation angle determined on the basis of the function described above)

For the 1 X12 inkwell we take n = 12, i.e. ke {1, ..., 30} so for example we take the value of k = 10 - it means that we calculate the angle for the tenth inkwell appearing in the structure pattern ak = 10, n = 12 = 360/12 + 10 and k = 10, n = 12 = 40 °

PL 228 131 B1

Kałamarzyk 1 marked X15:

- construction based on a cone with a wedge-shaped apex on the plan of a fifteen-shaped figure (the base of the apex differs from the directly adjacent ink boxes 1)

- the angle of rotation around its own axis (each of the existing inkwells 1 of the same type differs from the next rotation angle determined on the basis of the function described above)

For a 1 × 15 ink cartridge we take n = 15, i.e. ke {1, ..., 24}, so for example, we assume the value of k = 13 - it means that we calculate the angle for the thirteenth ink cartridge appearing in the structure pattern ak = 13, n = 15 = 360/15 + 13 ak = 13, n = 15 = 37

Claims (3)

1. The spatial structure of the surface of a polygraphic anilox cylinder for transferring the varnish to the varnish roller, consisting of three-dimensional ink-boxes with spatial thresholds between them, characterized in that the ink-tubes (1) are arranged on a regular pentagonal plan, which is the basic structure unit, with where between the ink windows (1) there are also squares and equilateral triangles with wall lengths identical to the length of the regular pentagon wall, and the dream faeces (1) are positioned in relation to each other according to the following relationships: - on the walls of each regular pentagon, on the plan of which there are inkwells (1), there are 5 squares with equilateral triangles between them, the larger unit of the structure thus created forms a regular decagon (decagon), - on the walls of each regular decagon there are successive regular pentagons with ink bubbles (1) - this is how the next, even larger unit of the structure forms an 20-sagon with twenty equal sides, each angle being 108 ° and the sum of the angles being 2160 °. 2. The structure according to claim 1 The method of claim 1, characterized in that the bottom (4) of the ink tubes (1) has the shape of at least one wedge. 3. The structure according to claim 1 The method of claim 1, characterized in that the bottom (4) of the inkwells (1) has a flat shape and the inkwells (1) are prisms.