EP2059394A1

EP2059394A1 - Ink dosing device of a printing group, and method for controlling said ink dosing device

Info

Publication number: EP2059394A1
Application number: EP07802549A
Authority: EP
Inventors: Detlef Alfons BÜCHNER
Original assignee: Koenig and Bauer AG
Current assignee: Koenig and Bauer AG
Priority date: 2006-09-06
Filing date: 2007-08-09
Publication date: 2009-05-20
Anticipated expiration: 2027-08-09
Also published as: ATE468224T1; US20090320702A1; US8001896B2; EP2059394B2; CN101460310A; EP2059394B1; CN101460310B; DE102006041881B4; DE102006041881A1; DE502007003880D1; WO2008028744A1

Abstract

The invention relates to an ink dosing device (04) of a printing group (01) comprising a printing group cylinder (02) that is embodied as a plate cylinder (02) as well as an inking unit. The ink dosing device (04) has a number (m) of physical zones (ZP,i) which are arranged next to each other in the longitudinal direction and can be individually adjusted by means of dosing elements (Di) in order to individually adjust, section by section, an amount of ink that is to be applied. A control station (07) is provided with a number (n) of operator elements (Bj) which are assigned to virtual zones (ZV,,j) of a printed page and are used for triggering dosing elements (Di). The segmentation of the zones (ZV,,j) of the ink dosing device (04) in relation to the width of the printed page differs in the number and/or position of the zones (ZV,,j) of the ink dosing device (04) across the width (bS) of the printed page (S) from the segmentation of the zones (ZV,,j) in the control station (07) in relation to the width of the printed page with respect to the number and/or position of the zones (ZV,,j) in said control station (07) across the width (bS) of a printed page. At least two dosing elements (Di) are allocated using computing means to at least one of the operator elements (Bj) with respect to the relevance of the latter for the adjustment process following the selection of said operator element (Bj).

Description

description

Ink metering device of a printing unit and method for controlling the ink metering device

The invention relates to a paint metering device of a printing unit and to a method for controlling the ink metering device according to the features of claims 1 and 10, respectively.

DE 198 56 675 A1 discloses a control device for controlling the printing of webs, wherein an analysis table with a group of buttons for individually controlling the opening and closing of ink fountain screws is provided. The spacing of the keys corresponds to the physical distance of the respective fountain pen screws.

In DE 42 16 440 B4, an actuator is placed below a sheet inspected by the printer to a position corresponding to a printed image strip to be corrected. An automatic detection system adjusts the ink fountain key of that zone and adjacent zones.

DE 10 2004 018 743 A1 discloses a device for the visualization of color metering element settings with a number of display devices corresponding to the number of color metering elements.

From DE 10 2004 022 700 B3 a Farbdosiereinrichtung is known, wherein a lying between two single pages panoramic color zone is assigned to a display screen both a display bar of a print page, as well as a display bar of the other printed page. In order to avoid a conflicting points with one and the same control element, an average value for the two values desired by the operating personnel is formed and at the common actuating means considered.

DE 10 2004 054 599 A1 discloses a forme cylinder of a printing machine, which carries several printing forms side by side in the axial direction.

The invention has the object of developing a Farbdosiereinrichtung a printing unit and a method for controlling the Farbdosiereinrichtung to the effect that a standardization for different machine widths is made possible.

The object is achieved by the features of claim 1 and 10, respectively.

The advantages that can be achieved with the invention are, in particular, that a cost-effective and standardisable solution for the inking units on newspaper printing presses is created. The hitherto high cost of conventional small series production of each ink fountain and the corresponding dosing specifically for a variety of machine or product formats can - be significantly reduced - at least in large areas or series of adjacent formats.

By adapting the displacements resulting from the unified metering elements to the operating conditions via calculation algorithms-in particular a computer-aided software solution-the operation can take place in the usual way without recognizable expenditure for the printer.

Embodiments of the invention are illustrated in the drawings and will be described in more detail below.

Show it:

Fig. 1 is a schematic representation of a printing unit and a control station of a first machine width;

Fig. 2 is a schematic representation of a printing unit of a second

Machine width with an inking unit with a lower zonal division than the control desk;

3 shows a schematic representation of a printing unit with an inking unit with a higher zonal division than the control station;

An only schematically indicated printing unit 01 a printing press, in particular a newspaper printing unit 01 a newspaper printing machine, has at least one printing cylinder 02, z. B. forme cylinder 02 and a forme cylinder 02 inking inking unit with at least one roller 03 and one with the roller 03 for the purpose of coloring cooperating Farbdosiereinrichtung 04 on. By the printing unit 01 is a substrate 06, in particular a paper web 06, can be printed. Preferably, the printing unit 01 is formed as an offset printing unit for newspaper printing and has between form cylinder 02 and paper web 02 on a transfer cylinder, not shown. As a substrate in newspaper printing in contrast to the high-quality commercial or sheetfed offset printing uncoated or only slightly coated paper z. B. to 20 g / m ² , in particular up to at most 10 g / m ² printed. Between roller 03 and forme cylinder 02, one or more further rollers can be arranged depending on the type of inking unit and the roller z. B. as a ductor roller of a film inking unit, as a ductor roller of a pumping inking unit or as an anilox roller of an anilox or short inking unit. The forme cylinder 02 has on its circumference z. B. in the axial direction next to each other depending on the web width more, z. B. two, four or six not shown releasable printing plates.

A machine width M1, ie an effective width of the printing cylinder 02, is usually matched to the zuuckoende maximum printing material or web width and corresponds in newspaper printing z. B. substantially more than an integral multiple of a newspaper page width of the desired maximum product size or the width of the total on the forme cylinder 02 side by side arranged printing forms. Newsprint machines of different machine widths are thus designed and delivered by the machine manufacturer for different publishing houses or these printing presses.

The printed images to be applied to the printing material 06 require i.d.R. Depending on the print image, a color quantity varying over the print image width to achieve the desired color density and thus coloration.

In order to ensure individual coloring over the entire printing width, the ink metering device 04 has in the axial direction next to each other a plurality of individually adjustable metering elements D ₁ (i = 1 .... m, with me N), by means of which in each case in a corresponding zone Z _{P] I} (i = 1 .... m, the ink feed can be controlled with me N, index P for "physical") The ink metering device 04 having a multiplicity of adjustable zones Z _{P] I} can be formed in different ways In the figures, the ink metering device 04 is embodied by a multiplicity of metering elements D ₁ designed as so-called inking knives D ₁ (stripping elements ₎ , which are individually adjustable by their drives not shown in their distance to the lateral surface of the roller 03. Depending on the gap width of this distance remains during stripping through the ink knife D ₁ a stronger or less strong ink film on the previously brought into contact with a paint reservoir roll surface. So in order to ensure an individual color over the print width or the color box 04 - z. B. using the drives not shown for the individual dosing D ₁ - the gap between roller 03 and metering D ₁ per zone Z _P ,, set.

In an unillustrated embodiment can be used as dosing D ₁ and a plurality of pumps D ₁ or a plurality of outlet openings D ₁ , each in the Zuführweg arranged, be provided with respect to the flow adjustable valves. In the following, the ink metering device 04 and the method for controlling by way of example on a paint reservoir (ink fountain) and the plurality of ink blades D ₁ having so-called ink fountain 04 will be explained. The principle explained with reference to the colorimeter D ₁ is to be transferred to any other embodiment of dosing elements D ₁ forming physical zones Z _P ,,.

As mentioned above, in newspaper printing, ie in inking units of newspaper printing machines, different machine widths M1; M2 offered for different maximum product formats. Conventionally, for these different machine widths M1; M2 but then also in each case to this machine width M1; M2 specially adapted inking units used, wherein the division of the physical zones Z _Pιl based on a width b _s or page width b _s a print page S is always an integer (eg, zp = 8 number) selected. So far, for example, for a newspaper printing press with wider product format an inking unit with a certain number, z. 8) of wider metering elements D ₁ or zones Zp, ₁ , and for a newspaper printing machine with a narrower product format, an inking unit with the same (eg, eight) or other integer number of metering elements D ₁ or zones Z _P ,, a smaller physical zone width b _P used, so that in sum an even number of zones Z _P , _m corresponds to the print page width. The number of adjustable physical zones Z _P ,,, is usually reflected in the number of operating elements B _j (j = 1 .... n, with ne N) with the corresponding virtual zones Z _Vj (j = 1 .... n with ne N) at a control desk 07 again. In Fig. 1, each pressure side S to be placed on the control station 07 is a number (eg, virtual zone number zv = 8) of z. B. controls designed as a button B _j (or pairs of controls, each marked with + and -), available, by means of which the printer, the metering D ₁ and thus the column at the physical zones Z _P, can control. For example, by pressing "+" the color flow is increased (increasing the gap or increasing the pump power), by "-" z. B. decreased (reducing the gap or lowering the Pump power). The numbers of segments in the virtual and physical zones Z _PY at the control station 07 in this case corresponds to (Fig. 1) and the numerical number of segments in the physical spatial zones Z _{P] I} am inking unit. In the presence of a presetting system 08, the required area coverage or color densities can also be converted into the positioning of this integer number of metering elements D ₁ or zones Z _{P] I} from the product definition in the editorial office, via the prepress stage to the presetting system 08. In Fig. 1 a newspaper double-side with their lateral width b _s and the associated control elements is schematically B _j or virtual zones Z _PY with the virtual zone widths b _v shown in the lower image area. In this case, the virtual zone widths b _v applicable to the pages placed on the desk correspond to the physical zone width b _P at the inking unit and the number of virtual zones Z _Vj per printed page S to the number of effective physical zones Z _Pιl . An effective, effective width b _{e of} the ink metering device 04, that is, for the present machine width M1; M2 required area with dosing D ₁ corresponds essentially to the machine width M1; M2 or the maximum web width.

A disadvantage of the machine-width-specific design of the ink metering device 04, in particular the metering D ₁ , is the high design complexity and the usual disadvantages known for "very small series".

The concept described below is based on the idea no longer for each specific machine width M1; M2 of a printing unit 01 in the newspaper printing specifically formed Farbdosiereinrichtungen 04, in particular the metering D ₁ , to use, but for different machine widths M1; M2 - at least within certain limits - at least the same metering D ₁ , advantageously even the same Farbdosiereinrichtungen 04 to use.

FIG. 2 schematically shows a printing unit 01 and a control station 07 with a smaller product format compared to the machine from FIG. 1 and a smaller machine width M2 shown. Here, on the forme cylinder 02, for example, several, compared to the machine of Fig. 1 narrower printing forms arranged side by side. The support surface on the control desk 07 and the width of the group of controls B _j or the entirety of the virtual zones Z _Vj is also smaller or narrower according to the product. .. For example, for a machine width M1 of FIG constructed 1 - - ink fountain 04 shown, in which case the number of relevant at the control station 07 for the print pages S _Vj virtual zones Z z in Figure 2 is a. B. is the same as that of the machine of Fig. 1, but with virtual zones Z _PY smaller zone width b _v. The ink fountain 04, however, has metering D ₁ and physical zones Z _P ,, with a to the zone width b _v of the virtual zones Z _PY different, larger here zone width b _P of the physical zones Z _Pιl or the dosing elements D _1. On the pressure side width (or the machine width M1; M2) related virtual number of segments in the zones Z _Vj (at the control station 07 or the prepress) is different from that on the pressure side width (or the machine width M1; M2) related physical number of segments in the zones Z _Pιl to the Farbdosiereinrichtung 04. While the virtual division in each case is an integer, a virtual, on the print page width or effective width b _e related divisor may also differ from an integer -. As in Fig. 2 about 6.3 per printed page S. Here, under of segments in the quotient of the number of considered adjacently arranged pressure faces S and the number of b _s projected assigned zones Z _PY, Z _P, (this width eg in Fig. 2: virtual division 8/1 or 16/2 etc. and physical division 6,3 / 1 or 12,6 / 2 etc.). The difference of divisions of the physical and virtual zones Z _P, Z _Vj can also be in a different spatial position with respect to the printing side S. In the present case, the differences in the number of parts in terms of the number and location of the zones Z _P , "Z _Vj .

Would the printer z. B. want to make a correction to the control B ₃ for its virtual zone Z _{v, 3} and the operation as usual in newspaper printing without consideration of the different zone widths b _P ; b _v and / or situations on the Actuate the dosing D ₃ act, it would be faulty (see Fig. 2). Order for different machine widths M1; M2 inking units of the same physical zone width b _P to be able to use is now a calculation algorithm A, in short: algorithm, provided which the deviations between the virtual and physical zones Z _Vj , Z _P ,, in number and / or position and / or width considered and converted accordingly.

As shown in FIG. 2, the inking unit or the metering device 04 can have more than the number of absolutely necessary metering elements D ₁ or only as many metering elements D _m as required for complete coverage of the effective width b _e , ie the present machine width M2 (in this case, Fig. 2 is seven per side of the edge, since six is insufficient). In the former case, for different machine widths M1; M2 the same metering 04 are used, in the second case for different widths of the metering 04 at least the same metering D ₁ .

If the printer corrects, for example by means of the control elements B _3, the virtual zone Z _v , _{3 associated with} a pressure side strip, then the algorithm A converts such that the drive of the dosing element D ₄ is activated. With regard to the size of the actuating signal, it is advantageous to take into account the size of the overlap or overlap between the position and width of the virtual and physical zones Z _v , ₃ and Z _P , ₄ . Since the physical zone Z _{P] 4} here is wider than the associated virtual zone Z _v , ₃ , the required real change of the gap width is smaller than the virtually requested change. As shown in FIG. 2 for the virtual zone Z _v, ₂ more physical zones Z _P ,, (here, Z _P, Z ₄ and _P ₃₎ are relevant, the conversion is performed such that multiple metering elements D ₁ (here, the Both D ₄ and D ₃ ) - advantageously taking into account their coverage - positioned accordingly or their drives are controlled accordingly. The same principle of the conversion lies with the or an algorithm of a presetting system 08 (or the Pre-printing) on which the presetting values for the physical zones Z _{P] I} are to be formed from the otherwise standardized standardized integer-coordinated zones. However, it is advantageous if, in the presetting system 08 or the actual physical zones Z _{P] I} already taken into account in the prepressure calculation, the required areal coverage or color densities are taken into account and kept there in the corresponding programs.

In another embodiment of the principle explained in FIGS. 1 and 2, a metering device 04 is shown in FIG. 3, wherein the width b _{P of} the physical zones Z _{P] I} here is smaller than the width b _{v of} the virtual zones Z _Vj am Control desk 07 or in the standard settings of the pre-adjustment system. The explained to the figures 1 and 2 is here to apply in the same way. Virtual and physical (actual) number of segments in the zones Z _PY, Z _Pιl are again different from each other. The algorithm A again ensures that when selecting a particular virtual zone Z _PY an appropriate transfer to the relevant metering D, or to the respective dosing elements D ₁ (or its drive / drives) takes place. By way of example, the physical division here is an integer, in this case nine, but could also differ from an integer-based on the printing page width or the effective width b _{e of} the ink metering device 04. The virtual number of segments in (number of zones Z _PY or controls B _j for each printing page S) is an integer and here amounts to eight.

Will the printer, for example, in Fig. 3 B ₁₂ correct the virtual, associated with a pressure side strip zone Z _v, i ₂ by means of the control elements, as is done by the algorithm A such a conversion, that the drive of the metering activated D ₁₄ and the metering D ₁₅ becomes. The size of each required changes to the gap can then again the degree of overlap or overlap between at relative position and width b _v ; b _{P of} the virtual and physical zones Z _Vj , Z _{P] I} considered. In general, the ink metering device 04 has such a number m of metering elements D ₁ that the widths b _{P of} the zones in total are greater than or equal to the machine width M1; M2 or maximum web width. The width of the ink metering device 04 is then executed accordingly. If, as in the case of the examples from FIGS. 2 and 3, metering elements D _{1 are} provided outside the effective width b _e in edge regions of the ink metering device, then it can be provided in algorithm A and / or in the machine or precontrol that these metering elements D _{1 are} generally open closed gap are controlled. In a variant which is advantageous with regard to FIGS. 2 and 3, it is provided that a varying overall width of the paint metering device 04 is permitted, but only in steps which are then used for different machine widths M1; M2 used the same dosing D ₁ . Ie. the ink metering device 04 then has such a number m of metering elements D ₁ that the widths b _{P of} the zones Z _Pιl total greater than or equal to the machine _width M1; M2 is, however, a (m + 1) th metering element D _{m + 1} completely outside the effective width b _e or outside the projection of the machine width M1; M2 would lie.

The control station 07 is thus continued as usual with an integer, advantageously even number n of (virtual) zones Z _Vj or with the corresponding number m of controls B _j (eg n pairs of buttons B _j ) executed while the Farbdosiereinrichtung 04 is formed with a different division of zones Z _{P] I} standardized width b _P and possibly different number m. The format and / or count and / or zone-width-dependent shifts between virtual and physical zones Z _PY, Z _{P] I} will be about the algorithm A - in particular computer-aided - converted and taken into account. For this purpose, corresponding computing means containing the algorithm are provided. The algorithm A may have a function among other things of the machine width M1 defined by the maximum web width; M2 and / or the number m of the physical zones Z _{P] I} or the dosing elements D _m and / or the number n of the virtual zones Z _Vj or the control elements B _j and / or a width b _{P of} the physical zones Z _{P |} , The algorithm A contains fixed rules for the conversion or consideration of the shifts or the difference in number and / or position of the zones Z _Vj ; Z _{P |} , Although these fixed rules and / or the above-mentioned input parameters (machine width, m, n, etc.) can be fixed, but can be stored by the operator changeable in the calculation means.

During presetting, the presettings of the dosing elements D ₁ can advantageously be related directly to the physical zone number m and physical zone width b _P with respect to the area coverage. However, it is also possible that the values for the presettings with respect to the area coverage initially related to the number of zones n on the control room 04, there converted via Algorithm A on the physical conditions in the above manner and the dosing of D ₁ and their drives are acted upon ,

For all examples (FIGS. 2 and 3) or operating modes in which the partiality of physical and virtual zones Z _PΛ Z _VJ related to the printing page width is different, at least one of the operating elements B _{j is} via the computing means or the algorithm implemented there A several, z. B. associated with at least two dosing D ₁ and with respect to standing relevant. In this case, one of the plurality of metering elements D ₁ can in turn be assigned to a plurality of, in particular two control elements B _j , due to the overlapping. The plurality of dosing elements D ₁ relevant to an operating element B _j are preferably positioned taking into account the degree of their covering with the operating element B _j .

It is also significant for the abovementioned examples according to FIGS. 2 and 3 that not only a dosing element D ₁ lying between two printed pages S is assigned two operating elements B _{j of} two adjacent printed pages S, but rather that a plurality of printed pages S assigned by means of the algorithm A Operating elements B _j and dosing elements D ₁ adaptation to the overlap takes place. It's on the Print side S thus related several zones with respect to their position shifted or different in terms of the number.

LIST OF REFERENCE NUMBERS

01 printing unit, newspaper printing unit

02 printing cylinder, form cylinder

03 roller

04 paint dosing device, ink fountain

05 -

06 substrate, paper web

07 Control room

08 presetting system

A calculation algorithm, algorithm

B _j Control element (control element pair) (j = 1 ... m) b _e Width, effective b _P Zone width, physical b _s Width, side width b _v Zone width, virtual

D ₁ dosing element, colorimeter, pump, outlet with valve (i = 1 ... m)

D _m Dosing element, colorimeter, pump, outlet with valve m Number (dosing elements, physical zones)

Mx machines width (x = 1 or 2) n number (controls, virtual zones)

S pressure side

Zp ,, zone, physical (i = 1, 2, 3 ...)

Z _{P m} zone, physically

Z _Vj zone, virtual (i = 1, 2, 3 ...)

Z _v , n zone, virtual

Claims

claims

1. Farbdosiereinrichtung (04) of a printing unit (01) with a forme cylinder (02) formed printing cylinder (02) and an inking unit, wherein the Farbdosiereinrichtung (04) in the longitudinal direction next to each other for partially individual adjustment of a quantity of ink to be entered a number (m) of each has physical zones (Z _{P |} ) which can be set via dosing elements (D ₁ ) and a control station (07) has a number (n) of virtual zones (Z _Vj ) of a pressure side associated control elements (B _j ) for controlling dosing (D ₁ ) wherein a related to the pressure side width of segments in the zones (Z _V,) of the ink metering device (04) with respect to a number and / or position of the zones (Z _V,) of the ink metering device (04) over the width (b _s) of a printed page (S) , is different to a related to the pressure side of segments in width of the zones (Z _V,) at the console (07) with respect to a number and / or position of the zones (Z _V,) at the control station (07) via di e width (b _s ) of a pressure side (S), and wherein at least one of the control elements (B _j ) is assigned via a computing means at least two metering elements (D ₁ ) in terms of relevance when setting as a result of the selection of this control element (B _j ) ,

2. Farbdosiereinrichtung according to claim 1, characterized in that physical zones (Z _{P |} ) of the Farbdosiereinrichtung (04) and virtual zones (Z _Vj ) of the control station (07) with a mutually different width (b _P , b _v ) are formed.

3. Ink metering device according to claim 1, characterized in that the juxtaposed physical zones (Z _{P |} ) in total have a greater width than a machine width defined by the maximum web width to be processed (M1, M2).

4. ink metering device according to claim 1, characterized in that on the width (b _s ) of a printed page (S) related number (np) of physical zones (Zp ₁ ) deviates from an integer.

5. The ink metering device according to claim 1, characterized in that a calculation means with an algorithm (A) is provided, which is adapted at the activation of the metering elements (D ₁₎ the difference of Teiligkeiten between virtual and physical zones (Z _PY Z _{P |} ) according to established rules.

6. Farbdosiereinrichtung according to claim 1, characterized in that the computing means in the signal path between the controls (B _j ) and drives the dosing (D ₁ ) is arranged.

7. ink metering device according to claim 1, characterized in that the ink metering device (04) cooperates with a roller (03) of an inking unit.

8. ink metering device according to claim 1, characterized in that the inked by the inking forme cylinder (02) carries on its circumference in the axial direction side by side a plurality of printing plates.

9. Farbdosiereinrichtung according to claim 1, characterized in that the control station (07) has an integer number (n) of virtual zones (Z _Vj ).

10. A method for controlling a Farbdosiereinrichtung (04) with a related to a print page width number (zp) individually via metering (D ₁ ) adjustable physical zones (Z _{P |} ) and with a related to a print page width number (zv) virtual zones (Z _Vj ) assigned control elements (B _j ) for controlling the dosing (D ₁ ), wherein the virtual and physical Zones (Z _Vj ; Z _{P |} ) differ in terms of number or position of a printed page width, and wherein a control of the dosing (D ₁ ) is performed by a calculation algorithm (A), the deviation in position and / or number between the virtual and physical zones (Z _{P |} ; Z _Vj ) according to established rules, and that upon activation of at least one of the controls (B _j ) by the algorithm (A) an activation of multiple dosing (D ₁ ) is caused.

A method according to claim 10, characterized in that the activation of the plurality of metering elements (D ₁₎ taking into account the overlaps between the relevant physical zones (Z _Pιl) with the virtual zone (Z _V,) of the activated control element (B _j) is carried out.