DE4216423A1 - Printing unit washing device for printing machines - Google Patents

Description

The invention relates to a printing unit washing device for printing presses according to the preamble of claim 1.

The printing unit washing device is used to apply Washing liquid, e.g. B. water, on printing unit parts such as for example blanket cylinders, plate cylinders, Printing cylinders, ink transfer rollers or on a Washing cloth for the mechanical cleaning of such printing Cylinders and printing unit rollers. The printing press can in particular an offset printing machine.

A Printing machine washing device of this type is from the German patent DE 28 26 135 C2 known. they contains a nozzle bar with which washing liquid can be sprayed onto a cloth with which a Blanket cylinder of a printing machine is cleaned.  

The nozzle bar is in shape via a buffer a cross line and check valves, which in Open towards the buffer and in the opposite direction close, connected to liquid supply lines, which each have a washing liquid through a dosing pump can be supplied. The dosing pumps are from controlled valves operated. The one of the Dosing pumps during a conveying process in the The amount of liquid pumped is from the Depending on the opening time of your controlled valve thereby adjustable. The one saved in the clipboard dosed amount of liquid is then through a Compressed air column ejected through the nozzle bar and sprayed with it.

If with the known washing device Washer fluid can be fed to several nozzle bars then there are different lengths of line sections from Buffer to the nozzle bar or one of the number number of dosing pumps per nozzle bar Liquid type necessary. When starting up for the first time such a washing device, the different lengths Has lines, the washing liquid becomes the nozzle bar the shorter lines already reach when the longer liquid lines only partially Liquid filled and the nozzle bars are still empty. This will not remove all of the washcloths during the first Cleaning cycles with liquid and moistened it there is insufficient cleaning and thus one poor print quality. There is also at Liquid lines of more than one meter in length Danger that the compressed air of the compressed air column in the Pipes mixed with water, so that the No more pure water jet is sprayed, but a mixture of water and air, or just air is sprayed. This leads to an uneven spray pattern  and a bad wash result. If you are for the Supply of several nozzle bars of uneven length and too want to avoid long liquid lines, then one for each nozzle bar for each liquid type own dosing pump needed, so that for example two nozzle bars, each with two different Liquids must be supplied, four metering pumps required are. One print for each printing unit machine, at least one nozzle bar is required. A printing machine in which such a wash device can be used, for example, shows the German patent application DE 40 13 465 A1.

The object of the invention is to solve a problem Washing device for printing units of printing machines too create one or more buffers can be filled with liquid more quickly without high fluid pressures for long periods of time are necessary and without any leakage problems high liquid pressures arise. Furthermore, by the Invention the printing unit washing device designed so be that for fluid supply to several Nozzle bar only one dosing pump per liquid type is needed, and the fluid pathways from the intermediate save to their nozzle bars with all nozzle bars can be the same length. For ejecting the Liquid from the buffer stores by means of a Compressed air column should the intermediate storage and the downstream lines so narrow Have wire cross-sections and be so short  that an adverse mixing of the air column with of the liquid in the intermediate stores and in the Fluid paths is avoided. The wash should device be designed so that it automatically works controlled and the liquid discharge quantities and Liquid ejection times of the nozzle units individually can be set and controlled automatically. The Applications of the washing device should not on moistening washcloths to damp Cleaning of blanket cylinders may be limited, but the washing device is also intended for wet cleaning from other printing press parts such as Plate cylinders, ink transfer rollers and for cleaning of blanket cylinders without interposing one Cleaning element such as a washcloth own.

This object is achieved according to the invention by characterizing features of claim 1 solved.

Further features of the invention are in the sub claims included.

The invention is described below with reference to the drawing Solutions based on preferred embodiments as a case games described. In the drawings shows

Fig. 1 shows schematically a printing unit washing device according to the invention, in particular for offset printing machines,

Fig. 2 is a schematic representation of a further embodiment of a printing unit washing device according to the invention.

The printing unit washing device shown in Fig. 1 of the drawings is suitable for wet cleaning of printing press parts such as, for example, rubber blanket cylinders, plate cylinders, printing cylinders, ink transfer rollers, etc., of printing presses, in particular offset printing presses. In this case, liquid can either be sprayed directly onto these printing machine parts or onto a cleaning element, in particular a washing cloth, with which these machine parts are cleaned mechanically, preferably automatically.

To simplify the description, it is assumed that the printing press has, for example, three printing units 1 , 2 and 3 , and that each printing unit has a nozzle bar 6 , 7 and 8 for spraying one of at least two different liquids onto a printing unit part of these printing units which is to be damp-cleaned or on a washcloth for cleaning printing unit parts is assigned to these printing units 1 , 2 and 3 . In a modified embodiment, a larger number of printing units or only two printing units can also be provided; one, two or more nozzle bars 6 , 7 and 8 can be assigned to each printing unit; and more than the two liquid reservoirs shown can be connected to each nozzle unit 6 , 7 and 8 . The nozzle bars 6 , 7 and 8 are preferably tubes which are provided with nozzles or nozzle openings 80 .

Water, liquid detergent or water-enriched detergent or another liquid can be used as the liquid. In the embodiment shown in Fig. 1, two liquid reservoirs 11 and 12 are provided. There is liquid detergent in one and water in the other. A metering pump 14 is provided for each liquid reservoir. Its suction side 15 contains a check valve 16 opening in the suction direction and sucks a predetermined amount of liquid from the liquid reservoir 11 via a fine filter 17 and a diving lance 18 connected upstream to it with a filter 19 at the upstream lance end when the metering pump 14 carries out a suction stroke. This predetermined amount of liquid is stored in the metering pump 14 . The metering pump 14 is preferably a piston pump. It is shown in Fig. 1 in its rest position, in which a delivery piston 21 and a drive piston 22 of this pump 14 are in a rest position, which is the starting position at the beginning of a suction stroke. The feed piston 21 and the drive piston 22 are mechanically connected to one another via a rod 23 , so that they each move together in their cylinders in the longitudinal direction of the cylinder. A compressed air source 26 can alternatively be connected via a pressure reducer 27 and a controllable changeover valve 28 on one side or on the other side of the drive piston 22 to its cylinder space 29 . In the illustrated starting position, the compressed air source 26 is connected in terms of flow to the part of the cylinder space 29 located below the drive piston 22 . At the same time, the part of the cylinder chamber 29 located above the drive piston 22 is vented via the same controllable valve 28 and a silencer 30 provided on the pump 14 . When switching of the controllable valve 28 to its other possible switching position, the compressed air source 26 of the cylinder space 29 fluidly connected to the located in Fig. 1 above the driving piston 22 part and the location below the drive piston 22, part of the cylinder space 29 is via the controllable valve 28 and the same silencer 30 vented. The controllable valve 28 is controlled by an electrical control device 33 , preferably depending on a specific operating program. The control device 33 preferably contains a microcomputer for the operating program.

During the intake stroke the drive piston upper position shown 1 22 moves together with the conveyor piston 21 from that in Fig. In a lower position. The delivery plunger 21 sucks a certain amount of liquid from the liquid reservoir 11 into the part of its delivery plunger cylinder space 35 located above it. This amount of liquid is so large that it is certainly sufficient for a single liquid spraying operation on all nozzle bars 6 , 7 and 8 . The amount can be, for example, 200 ml. On the pump 14 along the axial path of movement of the drive piston 22 signal transmitters 37 , 38 and 39 are arranged which, depending on the axial position of the drive piston 22, provide the control device 33 with signals which indicate the axial position of the drive piston 22 in each case . It can thus be determined how much liquid is still in the pump 14 during the delivery stroke. Furthermore, in contrast to the incompressibility of liquid, the compressibility of air can be used to determine whether there is air or only liquid in the line part connected to the pressure side 40 of the pump 14 . If the line part connected to the pressure side 40 is closed and the drive piston 22 is acted upon in the direction of a delivery stroke, in FIG. 1 from below, with compressed air from the compressed air source 26 , then the drive piston 22 can only move upwards when on the Pressure side 40 of the pump is air, but not when the pressure side 40 and the line part connected to it are completely filled with liquid. Such a functional test is particularly important if the immersion lance 18 is removed from the reservoir 11 and inserted into the liquid of another reservoir 11 , for example if the first reservoir 11 no longer contains sufficient liquid.

In each liquid reservoir 11 , 12 there is a level switch 42 , which generates an optical, acoustic or electrical alarm signal by an alarm system 44 when the liquid level in the liquid reservoir has dropped to a certain lower level. When this lower level 46 is reached , the liquid reservoir 11 , 12 must be refilled or replaced by a completely different liquid reservoir. The particular advantage of the washing device is that the liquid reservoirs 11 , 12 can be commercially available canisters.

The metering pump 14 has on its pressure side 40 a check valve 48 that opens in the pressure direction and closes in the suction direction of the metering pump 14 . The upstream beginning 50 of a liquid distribution line 52 is connected to this check valve 48 .

At the downstream end 14 , 14/2 of the distributor line 52 , a return line 55 is connected via a back pressure valve 54 , which is a controllable on-off valve 54 , the outlet end 49 of which opens into the upper part of the liquid reservoir 11 of this metering pump 14 .

Between the upstream beginning 50 and the downstream end 53 , as many liquid supply lines 56 , 57 , 58 , 59 are each connected to the distribution line 52 via a controllable on-off valve 62 , 63 , 64 and 65 , for example 4 pieces, such as nozzle bar 6 , 7 , 8 , etc. are to be supplied with liquid from the same liquid reservoir 11 . The downstream ends of the liquid supply lines 56 , 57 , 58 and 59 are each via a check valve 66 , 67 and 68 which opens in the pressure direction of the pump 14 to an intermediate store 72 , 73 , 74 for which it is supplied by the pump 14 via one of the liquid supply lines 56 , 57 , 58 metered amount of liquid supplied connected.

Each buffer store 72 , 73 , 74 is formed by a pipe or a hose with a narrow pipe duct or hose duct, the diameter and length of which form the maximum storage capacity of the buffer store. The channel is so narrow that liquid stored in it is pushed through a compressed air column with a small amount of air and sprayed from the associated nozzle bar without the air mixing with the liquid.

The back pressure valve 54 , 54/2 of each manifold 52 , 52/2 serves several purposes. When a new liquid reservoir 11 , 12 is started up, it serves, after a suction stroke and subsequent delivery stroke of the metering pump 14 , 14/2, for venting and thus completely and air-free filling of the distribution line 52 , 52/2 with liquid. After the distributor line 52 , 52/2 has been filled, the back pressure valve 54 , 54/2 closes this distributor line and the metering pump generates a specific liquid metering pressure in it. After the metered amount of liquid has been sprayed onto the nozzle bar 6 , 7 and 8 , the relevant back pressure valve 54 and / or 54/2 is opened, so that the distributor line 52 or 52/2 is depressurized again.

The metered amount of liquid which is conveyed from the metering pump 11 , 12 via the distributor line 52 , 52/2 into the intermediate store 72 , 73 or 74 is dependent on that from the metering pump 14 or 14/2 in its distributor line 52 or 52 / 2 generated liquid metering pressure and the opening period of the relevant controllable valve 62 , 63 , 64 or 65 , which is closed in the idle state and is opened for the supply of the liquid to the relevant intermediate store 72 , 73 or 74 for a certain metering period. For the supply of liquid from the liquid reservoir 11 through the metering pump 14 to the intermediate store 72 , the controllable valve 62 for the intermediate store 72 is opened, while all other controllable valves 63 , 64 and 65 and 54 are closed; to supply liquid to the intermediate store 73 , the valve 63 is opened for a certain period of time, while all the other valves 62 , 64 , 65 and 54 are closed; to supply liquid to the intermediate store 74 , the valve 64 is opened for a certain period of time, while all the other valves 62 , 63 , 65 and 54 are closed; etc. The nozzle bars 6 , 7 and 8 each have a plurality of nozzles 80 which , for example, against the printing unit assigned to them or against a specific press part to be moistened. B. are directed a washcloth. The nozzle bars 6 , 7 and 8 each preferably extend over the entire width of the printing unit, and they contain a channel 76 , 77 , 78 which extends essentially over the same width for supplying all nozzles 80 with liquid.

Each buffer 72 , 73 , 74 has an upstream end 92 and a downstream end 93 . The liquid supply lines 56 , 57 , 58 are each connected via a check valve 66 , 67 , 68 in a flow to the intermediate stores 72 , 73 , 74 at a point located between the two ends 92 and 93 . The metered, stored amount of liquid can thus be pushed from the intermediate store into the nozzle unit 6 , 7 or 8 assigned to it by a compressed air column at the upstream end 92 in the intermediate store 72 , 73 , 74 and from there onto a washcloth or another printing unit part to be moistened Printing unit 1 , 2 or 3 can be sprayed. For this purpose, at the upstream end 92 of each buffer store 72 , 73 , 74 each via a check valve 96 , 97 , 98 opening in the compressed air direction towards it and closing in the opposite direction and upstream connected compressed air lines 102 , 103 and 104 , in which there is a controllable compressed air open valve 106 , 107 , 108 , the compressed air source 26 is connected. The controllable compressed air valves 106 , 107 and 108 can contain pressure reducers, or a pressure reducer 110 can be arranged in a compressed air supply line 109 between the compressed air source 26 and these compressed air valves. The pressure reducer 110 can be used to set the pressure of the air with which the metered amount of liquid is expelled from the relevant intermediate store 72 , 73 , 74 through the associated nozzle bar 6 , 7 and / or 8 . If instead of a common pressure reducer 110 each individual compressed air line 102 , 103 and 104 contains a pressure reducer, the air pressure can be set individually for each nozzle unit 6 , 7 and 8 .

The second liquid reservoir 12 contains, for example, water as the washing liquid. This second liquid reservoir 12 is controlled in the same way as the first liquid reservoir 11 by an immersion lance 18/2 , a metering pump 14/2 , a distributor line 52/2 , valves 62/2 , 63/2 , 64/2 , 65/2 , connected liquid supply lines 56/2 , 57/2 , 58/2 , 59/2 etc., and at the ends of each via a check valve 66/2 , 67/2 each a metered amount of liquid in the intermediate storage 72 , 73 , 74th promoted. These metered amounts of liquid of the further liquid keitsreservoirs 12 can in the same way as described above by compressed air from the compressed air source 26 via the check valves 96 , 97 , 98 in the form of liquid spray jets from the intermediate stores 72 , 73 , 74 individually, in groups or together through the nozzle units 6 , 7 , 8 are expelled in order to moisten 12 parts of the printing units 1 , 2 and / or 3 with the liquid of the further liquid reservoir. The downstream end 53/2 of the distribution line 52/2 is optionally closed by a controllable back pressure valve 54/2 , so that a metered quantity of liquid is conveyed from the metering pump 14/2 into one or all of the intermediate stores 72 , 73 , 74 , or is opened , so that the distribution line 52/2 is vented into the second liquid reservoir 12 or liquid is emptied from it. Insofar as the parts required for conveying liquid from the second reservoir 12 are structurally and functionally identical to parts for conveying the liquid of the first liquid reservoir 11 , they are provided with the same reference numbers and with an additional identification number "2" and their function becomes not described here again. The second metering pump 14/2 is controlled by the same electrical control device 33 by means of a computer program via a changeover valve 28/2 , which is the same as the changeover valve 28 of the first pump 14 .

The washing device has the advantage that only one pump 14 , 14/2 is required for each liquid, that is to say for each liquid reservoir 11 and 12 , regardless of how many nozzle bars 6 , 7 , 8 are supplied with the liquid from a liquid reservoir. A further advantage is that the routes over which a metered amount of liquid to the nozzle beams 6, 7, 8 is conveyed, in all nozzle beams 6, 7, 8 is of equal length. These distances are also shorter than 1 m, so that water is sprayed on all nozzle bars 6 , 7 and 8 without air mixing and the same spray patterns are generated.

In the further embodiment, which is shown in Fig. 2, Fig. 1 functionally corresponding parts are provided with the same reference numerals, and they will not be described again in detail. In the off guide die according to Fig. 2, the manifolds 52 and 52/2 each designed as a ring line 52/3 for a liquid reservoir 11, and as a ring line 52/4 for the other liquid reservoir 12, and they extend from the pressure side 40 of the Metering pump 14 and 14/2 each along all nozzle bars 6 , 7 , 8 , and in parallel to all nozzle bars 6 , 7 , 8 over back to the controlled back pressure valve 54 or 54/2 in the vicinity of the associated liquid keitsreservoirs 11th or 12 . The return lines 55 and 55/2 of these back pressure valves open into the reservoir 11 or 12 assigned to them.

The compressed air supply line 109 of the compressed air source 26 also extends along all the nozzle bars 6 , 7 and 8 .

At the upstream end 92 of the buffer 72 of the first nozzle bar 6 , the controllable compressed air on-valve 106 instead of the check valve 96 is closed; to the upstream end 92 of the intermediate store 73 of the second nozzle bar 7 , the controllable compressed air open valve 107 is connected instead of the check valve 97 ; to the upstream end 92 of the third buffer 74 , the controllable compressed air-on-valve 108 is connected instead of the check valve 98 ; and the upstream inlets of these controllable valves 106 , 107 and 108 are each connected directly or through very short compressed air lines 102 , 103 and 104 to the compressed air supply line 109 of the compressed air source 26 provided with a pressure reducer 110 . The controllable liquid-open valves instead of the liquid check valves are connected to the intermediate stores 72 , 73 and 74 between their two ends 92 and 93 . The controllable liquid-on-to valve 62 is connected to the buffer 72 instead of the check valve 66 ; the controllable liquid-on-valve 63 is connected to the intermediate store 73 instead of the check valve 67 ; the controllable liquid-on-to-valve 64 is connected to the intermediate store 74 instead of the check valve 68 ; and the pressure sides of these controllable valves 62 , 63 , 64 are each connected directly or via short liquid supply lines 56 , 57 , 58 to the distributor line 52/3 , which is designed as a ring line, at locations which lie between the pressure side 40 of the metering pump 14 and the controllable back pressure valve 54 . As a result, the ring line 52/3 and all parts connected to it can be depressurized by opening the back pressure valve 54 .

Similarly, 14/2 the controllable fluid on-off valve instead of the check valve 62/2 66/2 connected to the latch 72 for the second liquid reservoir 12 and the metering pump; the controllable valve 63/2 is connected to the buffer store 73 instead of the check valve 67/2 ; the controllable valve 64/2 is connected to the latch 74 instead of the check valve 68/2; and all of these controllable valves 62/2 63/2 and 64/2 are connected with their pressure side either directly or via only short liquid supply lines 56/2 , 57/2 or 58/2 to the ring line 52/4 at locations which lie between the pressure side 40 of their metering pump 14/2 and their back pressure valve 54/2 . By opening the back pressure valves 54 and 54/2 , the entire system is vented and depressurized. Leakage of liquids is thus avoided. When the washing device is started up for the first time, air inclusions in the line system can be avoided in a simple manner, possibly with a few repeated suction strokes and pressure strokes of the metering pumps 14 and 14/2 .

The washing device according to FIG. 2 has the advantage over that of FIG. 1 that a large part of the line network is depressurized simply by opening the back pressure valve 54 or 54/2 , and that no additional non-return valves to the intermediate store 72 , 73 , 74 are required are.

In contrast, Fig. 1 has the advantage that all controllable valves in a cabinet according to functional groups can be arranged centrally ge.

Both embodiments of FIGS. 1 and 2 have the additional advantage that any number of nozzle bars 6 , 7 , 8 from a liquid reservoir 11 or 12 can be supplied with liquid in metered quantities with a single metering pump. At the same time, there is the option of optionally supplying each nozzle bar 6 , 7 , 8 with any number of different liquids, with only a single pump being required for each additional liquid, regardless of the number of nozzle bars. A particular difficulty with such washing devices is that relatively small amounts of liquid of, for example, only 10 ml over the long lengths of, for example, 1.6 m, the nozzle bars 6 , 7 , 8 have to be uniformly distributed and evenly sprayed from them. Only such a uniform distribution of small amounts of liquid over large areas ensures uniform cleaning of all parts across the entire printing unit width and thus also uniform printing quality across the entire printing press width.

The controllable liquid valves and compressed air valves can be set to the same or different opening times in both embodiments according to FIGS. 1 and 2. This makes it possible to moisten several printing unit parts or washcloths simultaneously, in groups or in succession with the same washing device if they require different amounts of liquid, at the same time or at different times. To spray the metered amount of liquid, the back pressure valve 54 or 54/2 must be closed so that a back pressure is created in the pipe system.

When it is started up for the first time, the metering pump 14 or 14/2 first sucks air out of the immersion lance 18 , 18/2 before liquid comes from the liquid reservoir 11 , 12 . To supply a precisely metered amount of liquid to the intermediate containers 72 , 73 , 74 , however, only liquid without air may be contained in the line system between the metering pumps and the intermediate stores 72 , 73 , 74 . During the suction stroke, the drive piston 22 and the delivery piston 21 go together into their lower position with reference to FIG. 1. All controllable valves 54 , 62 , 63 , 64 , 65 or 54/2 , 62/2 etc. connected to the distribution line 52 or 52/2 are closed. During the subsequent delivery stroke, the pistons 21 and 22 can only move upward from the lower position with reference to FIG. 1, which is the suction end position, if there are in the pump 14 or 14/2 and in the distributor line 52 or 52/2 and the connected line branches air, but not if this line system is only completely filled with liquid, because only air, but not liquid, is compressible. A possible axial movement of the drive piston 22 is measured by the sensors 37 , 38 , 39 by the electronic control device 33 . If the pistons can move upwards in the conveying direction by compressing air pockets, then this means that air pockets are present. In this case, the back pressure valve 54 or 54/2 is opened, the delivery stroke is completed and the distributor line 55 or 55/2 is thus vented into the liquid reservoir 11 or 12 . Then the back pressure valve 54 or 54/2 is closed and the pistons 21 and 22 are moved again in the suction direction in order to draw in liquid again from the liquid reservoir. These processes are repeated until the pistons 21 , 22 can no longer be moved upward from their lower suction end position in the conveying direction when the switchable valves are closed. This is then a sign that the distribution line 52 or 54/2 and the connected line branches are air-free and only filled with liquid. Thereafter, the metering pump 14 , 14/2 generates a certain liquid pressure in its liquid-filled distribution line 52 , 52/2 . Now, by opening one of the controllable liquid supply valves 62 , 63 , 64 , 65 and 62/2 , 63/2 , 64/2 from the metering pump 14 or 14/2, a metered quantity of liquid can be transferred to the intermediate store 72 , 73 assigned to it or 74 are funded. For each metered amount, the delivery piston 21 is moved by a distance corresponding to the desired amount of liquid in the delivery direction, with reference to FIG. 1 upwards. The higher the liquid pressure and the longer the liquid supply valve in question is open, the greater the amount of liquid delivered to the intermediate store. The opening times of the controllable supply valves are automatically adjustable on the electronic control device 33 by hand or by a program. The delivery pressure of the metering pumps 14 and 14/2 can be set on the pressure reducer 27 . If different air pressures are required in different lines, a corresponding number of pressure reducers are required for these lines.

In a modified embodiment of the invention, the controlled valves 62 , 62/2 , 63 , 63/2 , 64 , 64/2 for the liquids according to FIG. 2 can be arranged directly on the intermediate store 72 , 73 , 74 , while for the compressed air Check valve 96 , 97 , 98 according to FIG. 1 is arranged at the upstream end 92 of the intermediate store 72 , 73 , 74 .

A further modified embodiment of the invention can consist in that check valves 66 , 66/2 67 , 67/2 , 68 , 68/2 for the liquid according to FIG. 1 are arranged, but at the upstream end 92 of the intermediate store 72 , 73 , 74 a controlled valve 106 , 107 , 108 according to FIG. 2 is arranged as an inlet for compressed air instead of the check valves 96 , 97 , 98 .

Preferably, during the spraying of liquid from the nozzle bars 6 , 7 , 8, the compressed air supply to the intermediate stores 72 , 73 , 74 is switched off again immediately when the compressed air column reaches the nozzles 80 of the nozzle bars 6 , 7 , 8 , or when the start the compressed air column is upstream just before the nozzles 80 . This prevents the compressed air from disadvantageously mixing with the liquid before or after the nozzles 80 .

All of the latches 72, 73, 74 of Fig. 1 and Fig. 2 are of equal length and their ends 93 form the input to the associated nozzle beam 6, 7, 8.

In all embodiments, the on-off valves so-called two-position valves.  

According to yet another embodiment according to the invention, the intermediate stores 72 , 73 , 74 have no compressed air inlets 92 , 96 , 97 , 98 , but rather the metered amount of liquid stored in the intermediate store 72 , 73 , 74 is determined by a subsequent metered further amount of liquid from the Buffer in the associated nozzle bar 6 , 7 , 8 driven and sprayed out of the latter.

Claims (6)

I. Printing unit washing device for printing machines for applying washing liquid to printing unit parts such as, for example, blanket cylinders, plate cylinders, printing cylinders, ink transfer rollers or a washing cloth for machine cleaning of such printing unit cylinders and printing unit rollers, containing

• - At least one nozzle bar ( 6 , 7 , 8 ) for spraying liquid onto the relevant printing unit part ( 1 , 2 , 3 )
• - at least one intermediate store ( 72 , 73 , 74 ) per nozzle bar for intermediate storage of a metered amount of the liquid;
• - At least one metering pump ( 14 , 14/2 ) with a suction inlet ( 15 ) for removing the liquid from a liquid reservoir ( 11 , 12 ) and a pressure outlet ( 40 ) for supplying a metered amount of the liquid to the relevant one Intermediate store via at least one liquid supply valve ( 62 , 63 , 64 , 65 , 62/2 , 63/2 , 64/2 );
• Means for ejecting the amount of liquid dosed in the intermediate store into the nozzle bar and for spraying out of the nozzle bar, characterized )
• - That the supply valves ( 62 , 63 , 64 , 65 , 62/2 , 63/2 , 64/2 ) are manually or mechanically controllable on-to-valves;
• - That there is a distributor line ( 52 , 52/2 ) in the liquid connection between the metering pump ( 14 , 14/2 ) and the intermediate store (s) ( 72, 73, 74 ), the upstream beginning ( 50 ) of which is connected to the outlet ( 40 ) of the metering pump ( 14 , 14/2 ) is connected in terms of flow, the downstream end of which is provided with a counterpressure valve via which the distribution line is alternatively closed at this end or to a return line ( 55 , 55/2 ) into the associated liquid reservoir ( 11 , 12 ) can be opened, and the distributor line section located between their beginning ( 50 , 50/2 ) and their end ( 53 , 53/2 ) each via one of the supply valves ( 62 , 63 , 64 , 62/2 , 63/2 , 64/2 , 65/2 ) with the one or more intermediate stores ( 62 , 63 , 64 ) is connected in terms of flow, in such a way that when the back pressure valve is closed, a liquid pressure is generated in the distribution line by the metering pump, which the back pressure V entil counteracts, so that by opening one or more of the supply valves, liquid is conveyed from the distribution line into the relevant buffer ( 72 , 73 , 74 ), whereas against the pressure of the end of the distribution line into the liquid reservoir when the counter pressure valve is open becomes.

2. Printing unit washing device according to claim 1), characterized in that the metering pump ( 14 , 14/2 ) is a piston pump, through which with closed supply valves ( 62 , 63 ... 62/2 , 63/2 ... ) and at the same time closed back pressure valve ( 54 , 54/2 ) in the distribution line ( 52 , 52/2 ) a liquid pressure is generated which, when one of the supply valves opens, a sudden rapid delivery of liquid from the distribution line to the relevant buffer ( 72 , 73 , 74 ). 3. Printing unit washing device according to claim 1 or 2, characterized in that an electronic control device ( 33 ) is provided which contains a microcomputer and which the metering pump ( 14 , 14/2 ), the supply valves ( 62 , 63 . ., 62/2 , 63/2 ... ) And the back pressure valve ( 54 , 54/2 ) controls depending on a washing program. 4. Printing unit washing device according to one of claims 1 to 3, characterized in that the downstream end ( 93 ) of the pipeline-like elongate buffer ( 72 , 73 , 74 ) to the nozzle bar ( 6 , 7 , 8 ) are each directly connected. 5. Printing unit washing device according to one of claims 1 to 4, characterized in that the metered amount of liquid stored in the intermediate store ( 72 , 73 , 74 ) with closed supply valves ( 62 , 63 ... , 62/2 , 63 / 2 ...) Is driven through a compressed air column in the associated nozzle bar and is sprayed out of the nozzle bar ( 6 , 7 , 8 ) without the compressed air of the compressed air column mixing with the liquid before spraying. 6. Printing unit washing device according to one of claims 1 to 4, characterized in that the metered amount of liquid stored in the intermediate store ( 72 , 73 , 74 ) in each case by a subsequent new metered amount of liquid in the associated nozzle bar ( 6 , 7 , 8 ) driven and sprayed from the latter.