DE9004745U1 - Coating unit for a printing press - Google Patents

Description

Coating unit for a printing press

The invention relates to a coating unit for a printing machine according to the features specified in the preamble of claim 1.

Such a coating unit is described in DE 36 41 213 A1. An arranged coating unit or a coating unit integrated into a printing unit enables the printing material to be refined inline by giving the print additional optical properties that cannot be achieved with single-color printing or overprinting. In addition, the coated coating has abrasion resistance, prevents blocking in the stack and enables immediate further processing.

As a result of the high printing quality, the printing machine is required by the coating plant to ensure reliability and processing quality, at least at the level of the other process steps. For the printing machine used, this requirement means uniform processing properties. The coating sizes must be constant and adjusted to the specific processing case.

As a mixture of certain components, the paint has different evaporating proportions. It is therefore necessary to control the flow properties of the paint and to intervene if the viscosity changes in a disruptive way, for example due to drying. This can impair the film transfer of the paint using the application roller and also change the conveying behavior of the paint, which can affect the equipment in the paint shop.

The paint supply system is to be considered open from the paint feed side to the paint box, in which the scoop roller rotates. In addition to drying out due to the accompanying phenomenon of evaporation or vaporization, viscosity-changing contaminants can also enter the paint system.

In the paint shop according to DE 36 41 213 Al, the paint circulating to the paint box is in a thermostated tank, which is equipped with a viscometer that acts on a valve that regulates the thinner supply. If the paint has a thickened consistency, thinning liquid flows in, which is mixed with the

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The paint, which has been adjusted to the viscosity, is then pumped into the paint tank. A return line from the paint tank and a circuit designed to return excess paint to the tank open into the tank.

The viscometer is shown as a single measuring device that is immersed in the vessel from above. It ^therefore obviously works according to a measuring principle that is common in laboratory devices, especially in falling ball viscometers or rotational viscometers.

The disadvantage here is that the measurement of the viscosity of the paint only relates to the paint at a specific point in the tank. If this point, which is not homogeneously connected to other points containing paint, reports insufficient viscosity, the viscosity setting will fail. The task is therefore to arrange a viscometer on the device receiving the paint that is insensitive and representative of the entire amount of paint used.

This problem is solved by applying the measures specified in claim 1.

The solution enables viscosity measurement in a closed system, so that exposed paint surfaces are avoided and measurement errors resulting from them cannot occur. The closed system offers favorable temperature distribution due to its compact design, because temperature gradients caused by air flow and air heat transfer are eliminated. In terms of equipment, the viscosity measuring part can be either permanently integrated or adapted as an additional part, because it can be actively connected in series to the pipe or conveyor system or as a passive component. As a passive component, it functions like a sampling device, from which small quantities sufficient for measurement purposes can be returned or discharged.

The viscosity of the paint is usually based on experience gained from the practical use of the measuring cup. In the manual method with a measuring cup, the flow time is determined and conclusions are drawn from this as to whether the paint should be thinned or thickened. Based on the practical method with a measuring cup,

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The measured values from the viscometric measuring device in the paint shop are related to the measuring cup run-out times to make it easier for the operating personnel to orientate themselves. The measured and displayed values are therefore not absolute values with regard to the dynamic or kinematic viscosity, but consist of relative values that enable viscosity control. The measured value exists as a reference or substitute value for the viscosity.

The viscosity is adjusted using predetermined amounts of paint as a high-viscosity component and thinner as a low-viscosity component. The respective amount of paint supplied is the result of the volume or filling quantity of the metering pumps used, one being the paint pump and the other being the thinner pump.

The dosing volume is preferably uniform from feed step to feed step, but it can just as easily refer to quantities that vary from time to time. The dosing volumes are adjusted to the total amount of paint in the paint system, so that there is enough scope to regulate the viscosity. The most favorable design is that too small dosing quantities make the adjustment process long, whereas too high dosing quantities can immediately lead to an incorrect adjustment that cannot be reversed.

The viscometric measuring device consists of a measuring pump with which the paint liquid to be checked is pumped into or through a defined flow element. For example, the piston of a piston pump, which is subjected to a constant or variable force, moves in a certain distance-time relationship, while the paint as the measuring liquid is pushed through the pump outlet. The pump outlet can be represented as a capillary tube. The piston of the piston pump can be seen as a forced conveying element. The forced conveying element can also be the blade of a rotary pump or the blade of a diaphragm pump.

The measuring pump can run both continuously, obtaining continuous measured values, and discontinuously, obtaining measured values obtained individually at time intervals. In the bypass system, the measuring pump works in a secondary branch; when connected to a line in the line system, the measuring pump works directly in the flow, which is set up between the inlet to the paint tank and the outlet from the paint tank.

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The desired viscosity can also be achieved using a multi-way valve, whereby the quantities of paint or thinner supplied are determined by the angle position of the multi-way mixer.

In the following, an embodiment of the invention is described with reference to the drawing.

The paint shop A with its "sifting technology" facilities is assigned to the supply ^section B for the provision of processable paint. The paint is stored in paint tank 1. Next to it is a thinner container 2. The paint liquid to be used is in the mixing container 3.

According to the operation of the printing machine with the start and end of varnishing during the print run, a specific functional sequence is set up in the supply part B, which is divided into three phases. Phase 1 concerns the filling of the mixing container 3. For this purpose, varnish is pumped from the varnish tank 1 into the mixing container 3 by means of a pump 4. To ensure the best possible mixing in the mixing container 3, a stirrer 5 is arranged, which rotates due to the recoil when the varnish flows in inside the mixing container 3. A level control 6 is arranged on the mixing container 3. During the filling phase of the mixing container 3, the lower level is controlled. This means that there is still a reserve for later addition of quantities, which is used to adjust the viscosity.

After phase 1 of the supply of paint from the paint tank 1 into the mixing container 3, phase 2 follows for the purpose of mixing the paint liquid in the mixing container 3. For this purpose, the paint liquid flows via a suction nozzle 7 arranged coaxially to the axis of the mixing container 3 to the suction side of the pump 4, which presses the circulated amount of paint liquid back into the mixing container 3 via an inlet nozzle 8. The inlet nozzle 8, which is also used for filling, is arranged coaxially to the axis of the mixing container 3, just like the suction nozzle 7. Stirrer 5, suction nozzle 7 and inlet nozzle 8 have one axis in a compact design.

Phase 3 concerns the operating state with which paint fluid is removed from the

Supply part B can be fed to the paint shop A. This operating state requires the correct setting of the viscosity or flow behavior of the paint liquid.

The correct viscosity is achieved by adding thinner from the thinner container 2 or, if the paint liquid is already too thin, by adding paint from the paint tank 1. Piston pumps are provided for the supply of thinner or paint, see the paint pump 10 feeding from a line from the paint tank 1 to a collector 9 and the thinner pump 11 feeding from the thinner container 2 to the collector 9.

The supply of thinner or varnish is decided on the basis of the viscosity measurement carried out with the measuring device 12.

In this case, the measuring pump 13 draws paint fluid from the collector 9 and pushes it back into the collector 9 through a capillary part 14. The measuring signal is formed using the time interval that the piston needs to cover a distance between two distance marks. This time interval represents the reference value for a certain viscosity. If the paint fluid is thinner, the ejection process and thus the time interval are shortened; if the paint fluid is thicker, the time interval is extended accordingly. The piston movement is generated, for example, by a servo motor subjected to constant pressure. The distance and time system can be adapted as required to the accuracy requirements.

In an analogous manner, the internal pressure in the measuring pump 13 can also be measured and

be evaluated if the piston of the measuring pump 13 has a constant speed is imposed.

The stirrer 5 is operated fluidically as described, which eliminates the need for explosion protection. Pump 4 is designed as a two-chamber diaphragm pump. To avoid

The mixing container 3 is provided with a lid which is additionally provided with a collar to form a good labyrinth seal This means that only a very thin annular gap is left between the lid and the wall of the

Mixing container 3 is present. The paint fluid is supplied from the supply part B to the paint shop A

pressure side, i.e. after the pump 4 by means of branching from the collector 9 or

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Branching directly on the pressure side of pump 4 (see dashed line).
The inlet and return lines from the painting unit A to the supply part B can each be closed by valves, which are preferably designed as ball valves. To overcome flow resistance, the painting unit A is assigned its own pumping station. This is preferably designed as a double-stage diaphragm pump with one stage for supplying and one stage for removing the paint from the paint tank. There is a filter 15 in the return line from the painting unit A to the supply part B.
The diaphragm pumps, on the paint shop side and pump 4, are pneumatically operated, for which a compressed air connection with oil and water separator is installed.

Paint, thinner and measuring pumps 10, 11 and 12 are of course valve-controlled. The clocking of the pumps 10, 11 and 12 required for repelling is carried out by a processor to which the other control functions such as the level control 6 are also connected. For operation and control, appropriate switching, display and control elements are attached to a console.

A display (not shown) provides the flow time related to the known measuring cup as a reference value for the viscosity control that can be carried out with the Viscomat.

Claims (4)

"STSi Protection Claims 1. Coating unit for a printing machine with a roller mill for film formation and application of varnish, with a varnish supply consisting of a container, pipe and conveyor system, to which a device for adjusting the viscosity with a measuring part and a feed part for thinner is assigned, characterized, that the measuring part (12, 13 14) is formed by a forced flow section (13, 14) integrated into the container, line and conveyor system (1, 2, 3, 4) of the painting unit (A) or supply part (B), through which a partial quantity belonging to the total amount of process paint, coming from supply, removal or circulation, can be forcibly conveyed, whereby a variable resulting from the forced conveyance within the forced flow section (e.g. a resulting time interval for a fixed path interval, a resulting piston path for a fixed time interval, an internal pressure value for a piston movement subjected to a constant speed) can be measured and evaluated directly or transmitted . 2. Coating unit according to claim 1, characterized in that that the container, line and conveyor system (A, B; 1,2, 3, 4) has a mixing container (3) which can be operated by means of a pump (4) to fill it with paint from a paint vessel (1), that the mixing container (3) can also be operated by means of the pump (4) to circulate the paint liquid via a suction nozzle (7) and inlet nozzle (8), that a flow branch between the suction nozzle (7) and inlet nozzle (8) has a collector (9) to which the thinner from a thinner container (2) and the paint from the paint vessel (1) can be fed, and that the measuring device (12) with a measuring pump (13) for measuring the viscosity can be assigned to the flow branch or the collector (9). It(I I I I f • t t ■ 3. Coating unit according to claims 1 and 2, characterized in that that the measurement of the viscosity is linked to a temperature measurement and that the mixing container (3) and/or the collector (9) can be thermostatted. 4. Coating unit according to claims 1 and 2,
characterized, that the partial quantity taken up in the suction stroke for the purpose of measurement can be pushed out again by the measuring pump (13) through a capillary part (14), whereby the partial quantity can be returned to the collector (9) or can be further transported within the space between the suction ports (7) and the inlet ports (S).