WO2004091914A1

WO2004091914A1 - Ink dosing device for variable widths of fabric to be printed

Info

Publication number: WO2004091914A1
Application number: PCT/DE2003/004240
Authority: WO
Inventors: Volker Gerold Rauh; Roland Pfister
Original assignee: Koenig & Bauer Aktiengesellschaft
Priority date: 2003-04-04
Filing date: 2003-12-22
Publication date: 2004-10-28
Also published as: EP1610952A1; WO2004091914B1; DE10315444B4; AU2003293290A1; DE10315444A1

Abstract

The invention relates to an ink dosing device (01) for variable widths of fabric to be printed. Said ink dosing device comprises an ink duct (02) having an integrated ink reservoir, an ink ductor (04) feeding ink (03) from the ink duct and a transfer roller (06) feeding the ink transferred by the ink ductor to a roller system of an inking system. At least one doctor blade (07, 08) is disposed on the transfer roller to rest against it. Said doctor blade is used to remove the ink which is present on the transfer roller outside the width of fabric. The ink duct can be adapted to different widths of fabric to be printed by means of at least one ink duct divisor (11, 12). The ink duct receives the removed ink in a separate, outer edge area (13, 14).

Description

description

COLOR DOSING DEVICE FOR VARIABLE PRINT WIDTHS

The invention relates to a color metering device according to the preamble of claim 1 or 2.

An important component of an inking unit is the ink metering system for ink quantity regulation both during presetting, for automatic remote control during production, and for manually regulating the ink flow. The ink metering system stores the printing ink in an ink fountain or in an ink tray. From this stock, the ink metering system has the task of using a ductor or an immersion roller and an ink knife bar or ink slide to continuously, evenly and without fluctuation adjust the inking unit with an ink quantity to be adapted to the printing work or to feed it to the roller system.

A large number of different color metering systems are known in practice. In the roller inking units that are still predominant today, the ink metering system consists of the ink fountain itself, as well as a periodically, but usually permanently, rotating ink fountain. It is driven separately by a motor to set different speeds. Sometimes it is also referred to as a scoop or dip roller.

Depending on the design of the ink metering system, ink knife blades, ink slides or ink knife bars act against the ductor for zonal metering of the ink quantity. Depending on the desired amount of ink, more or less ink is let through or doctored between the ductor and the ink knife blade.

Ink metering systems are also known in which the ink reservoir in the ink fountain is divided by at least one ink fountain divider. The color box can do so different web widths can be adjusted.

A disadvantage of the known ink metering systems with ink fountain dividers, however, is that there is very heavy contamination in the area of the ink ductor or the transfer roller. When using smaller web widths, the ink fountain can be adapted to the smaller web format using ink fountain dividers. This ensures that the ink duct is only covered with paint in the area that corresponds to the current web width. When the ink travels between the distribution cylinder and the inking roller, it happens that the edge areas of the rollers that are not coated with ink are also coated with ink. The ink drops carried out from the inside of the roller collect at the edge area of the inking rollers and are thrown out in an uncontrolled manner by the rotation of the transfer roller. This leads to very heavy soiling in the area of the inking unit. To make matters worse, it is very laborious to remove the paint from the individual machine parts during cleaning or maintenance work, since these places are sometimes very difficult to access.

DE 196 24 536 A1 and DE 3326 916 C2 disclose inking units in which a squeegee scrapes off excess ink lying outside the printing substrate. In one embodiment, the doctored paint is fed back into the paint box containing fresh paint.

The invention has for its object to provide an easy to maintain ink metering device for variable web widths.

The object is achieved by the features of claim 1 or 2.

The invention relates to an ink metering device for variable substrate widths, in particular web widths, in the case of the transfer roller at least one doctor blade can be brought into contact with which the ink, which is located outside the web width on the transfer roller, can be doctored off. This reliably prevents the paint from being thrown out in an uncontrolled manner using simple means.

However, it proves to be particularly advantageous if two doctor blades are arranged on the transfer roller, in each case at the two end regions of the transfer roller.

It is important to arrange the doctor blade in such a way that the contact zone between the doctor blade and the transfer roller is arranged above the gap between the ink fountain roller and the transfer roller. This ensures that the ink that is stripped off by the doctor blade lying on the transfer roller is directed back into the ink fountain via the ink duct.

The doctor blade can be in permanent contact with the transfer roller. Timed starting is also conceivable. This minimizes wear on the working edge of the squeegee.

The ink fountain is ideally provided with at least one ink fountain divider in order to ^" adapt the ink fountain to different web widths. The ink which is guided from the doctor blade onto the ink fountain pen and from there into the ink fountain is directed into the lateral area of the ink fountain separated from the main part The ink knife blades in this area are closed.

This prevents contamination from flying paint drops. In addition, the paint that is guided in the side parts of the paint box can be easily removed from the paint box from there. Longer cleaning work due to heavy contamination in the area of the transfer roller can thus be carried out be completely avoided.

The transfer roller is advantageously a ceramic-coated film roller. Since the ink roller and film roller rotate at very different speeds, the ink profile is permanently milled off by the film roller and transported into the roller system of the inking unit. To ensure this function, there is a gap of approximately 0.05 to 0.08 mm between the ink fountain roller and the film roller.

The ceramic coating of the film roller ensures a smooth and robust surface and ensures that the squeegee can come to rest on the film roller with a smooth surface. It has proven particularly advantageous to provide the film roll with a diamond pattern on its surface. This results in higher ink adhesion on the transfer roller.

The doctor blade itself is ideally arranged axially displaceably on the ink metering device. Different web widths or positions can be covered with one or more doctor blades.

In order to guarantee a secure seat of the rakia on the transfer roller, the squeegee is in a prestressed state. This state is achieved by means of spring force. The doctor blade can adapt to any unevenness of the transfer roller that may occur.

In order to detach the squeegee from its working position, it is particularly advantageous to mount the squeegee in an adjustable, in particular pivotable, position between the switched-on and switched-off positions. This ensures good access to the rollers quickly and easily during maintenance work or cleaning the rollers. In a particularly advantageous embodiment, the width of the doctor blade is adjustable. This means that a single doctor blade can be used to react to many different web widths.

An embodiment of the invention is shown in the drawings and will be described in more detail below.

Show it:

Figure 1 shows a color metering device in a side view.

Fig. 2 shows a detail of the ink metering device according to Fig. 1 in a schematic plan view.

1 shows a color metering device 01 in a side view. The ink fountain 02 is arranged in such a way that the ink duct 04 comes into contact with the ink fountain 02 filled with ink 03 in some areas. The ink 03 is removed from the ink fountain 02 by the ink fountain pen 04 by means of scooping action or by means of adhesion. The running direction of the ink duct 04 is designed in the opposite direction to the running direction of the transfer roller 06, here in the form of a film roller 06. The distance from the ink fountain roller 04 to the transfer roller 06 is usually approximately 0.05 to 0.08 mm. The desired distance can be precisely defined using an actuator 09.

In this ink metering device 02, the transfer roller 06 is arranged higher than the ink roller 04. This ensures that the contact zone between the doctor blade 07 and the transfer roller 06 is arranged above the gap between the ink roller 04 and the transfer roller 06. This guarantees that the ink 03, which is stripped from the transfer roller 06 by the doctor blade 07, on the peripheral surface of the Ink duct 04 and from there drips back into the separated area of the ink fountain 02.

The doctor blade 07 itself is pivotably arranged above the transfer roller 06 (shown in broken lines). The squeegee 07 is in a prestressed state via a spring element (not shown) and is thus pressed against the circumferential surface of the transfer roller 06 in its working position. If necessary, the doctor blade 07 can be removed from the transfer surface 06 by a pivoting movement. It is advisable to manufacture both the transfer roller 06 and the doctor blade 07 from a robust, stable material or, at least in some areas, to subject the contact areas to a special surface treatment. As a rule, however, the transfer roller 06 is provided with a ceramic coating.

Fig. 2 shows the color metering device 01 in a schematic plan view. Above the transfer roller 06, the two doctor blades 07; 08 arranged. The ink duct 04 is located below the transfer roller 06. The ink duct 04 is arranged such that the doctor blades 07; 08 stripped paint 03 reaches the peripheral surface of the ink duct 04. To separate the ink fountain 02, two ink fountain dividers 11 and 12 are arranged on the ink fountain 02. The ink fountain 02 can be adapted to different web widths by means of these ink fountain dividers 11 and 12. Due to the opposite direction of travel of the ink duct 04 to the transfer roller 06, the ink 03 is conveyed back from the ink duct 04 into the designated outer edge areas 13 and 14 of the ink duct 02, which are separated from the ink duct 02. From there, the collected amount of paint can easily be removed by the operating personnel.

LIST OF REFERENCE NUMBERS

01 paint dosing device

02 ink fountain

03 color

04 color doctor

05 -

06 Transfer roller, film roller

07 squeegee

08 squeegee

09 control element

10 -

11 ink fountain dividers

12 color box dividers

13 edge area

14 edge area

Claims

Expectations

1. ink metering device (01) for variable substrate widths, consisting of an ink fountain (02) with an internal ink reservoir, an ink fountain pen (04) conveying the ink (03) from the ink fountain (02) and an ink transferred from the ink fountain pen (04) 03) transfer roller (06) which can be conveyed into a roller system of an inking unit, at least one doctor blade (07; 08) being arranged on the transfer roller (06), with which the ink (03) which is outside the printing material width on the transfer roller ( 06), can be doctored off from the transfer roller (06), characterized in that the ink fountain (02) can be adapted to different printing material widths by means of at least one ink fountain divider (11; 12) and that the ink fountain (02) the doctored ink (03) in a separated, outer edge area (13; 14).

2. Ink metering device (01) for variable printing material widths, consisting of an ink fountain (02) with an internal ink reservoir, an ink fountain pen (04) conveying the ink (03) from the ink fountain (02) and an ink transferred from the ink fountain pen (04) 03) transfer roller (06) which can be conveyed into a roller system of an inking unit, at least one doctor blade (07; 08) being arranged on the transfer roller (06), with which the ink (03) which is outside the printing material width on the transfer roller ( 06), can be doctored off the transfer roller (06), characterized in that the doctored ink (03) first reaches the ink duct (04) and then into the ink fountain (03).

3. Ink metering device according to claim 1 or 2, characterized in that two doctor blades (07; 08) are provided on the transfer roller (06), each of which abuts the ends of the transfer roller (06).

4. Ink metering device according to claim 1 or 2, characterized in that the contact zone between the doctor blade (07; 08) and transfer roller (06) is arranged above the gap between the ink ductor (04) and transfer roller (06).

5. Dosing device according to claim 1 or 2, characterized in that the transfer roller (06) is designed as a film roller (06).

6. ink metering device according to claim 1, 2 or 5, characterized in that it is in the transfer roller (06) is a ceramic-coated film roller (06).

7. Ink metering device according to claim 5 or 6, characterized in that the film roller (06) has a diamond pattern on its peripheral surface.

8. ink metering device according to claim 1 or 2, characterized in that the doctor blade (07; 08) is axially displaceably mounted.

9. ink metering device according to claim 1 or 2, characterized in that the doctor blade (07; 08) is in its pre-tensioned state by means of spring force in its working position.

10. ink metering device according to claim 1 or 2, characterized in that the doctor blade (07; 08) is adjustable in width.

11. Dosing device according to claim 1 or 2, characterized in that the doctor blade (07; 08) between the on and off position is adjustable, in particular pivotable, mounted.

12. Ink metering device according to claim 1 or 2, characterized in that the doctor blade (07; 08) is timed.

13. Ink metering device according to claim 1 or 2, characterized in that two ink fountain dividers (11; 12) are arranged which form two separate, outer edge regions in the ink fountain (02).

14. Ink metering device according to claim 1, characterized in that the doctored paint (03) first reaches the ink duct (04) and then into the ink fountain (03).