DE4327421A1 - Device for dyeing structured flat items - Google Patents

Abstract

A device for the at least single-sided dyeing of flat items (1) has a transporting apparatus for transporting the parts (1). In the machine frame of the device, there is arranged a cylindrical dye application roller (12) which is designed as a brush roller and is dyed by means of a transfer roller (13) and a metering roller (14). The transfer of the quantity of dye is controlled with the aid of the gap between the metering roller (14) and the transfer roller (13). In the flow direction following the dye application roller (12) there is an evening-out station (4) which evens out the dye applied using two rollers (75, 76) likewise designed as brush rollers. <IMAGE>

Description

The invention relates to a device for at least one side coloring of flat parts with pressure sensitive structured surface.

When it comes to such parts fully automatically on egg One side is usually sprayed spray technology applied. Here, the color is fine Droplets dissolved, which then settled on the part should hit. It extends from the paint mist generated drafts to remove some of the aerosol from ver to carry relatively large distances, so that the paint mist in unwanted places outside the front direction. It must therefore be considerable Effort to be driven to a too big vagabondie avoid the color aerosol to a large extent. Still leaves contamination occurs immediately in the vicinity of the Do not completely avoid the machine due to paint mist.

Based on this, it is an object of the invention to provide a direction to create at least one machine parts dyed all over the page.

This object is achieved with a device solved with the features of claim 1.

The use of the paint roller with elastic outside circumferential surface ensures a full, flawless contact with the part to be colored, the counter pressure device prevents the possibly thin part from dodging. Because of the elastic outer peripheral surface can with the new device especially parts with textured ter surface, even if the surface is sensitive to pressure. An example of a such material is half corrugated cardboard, with one too great pressure to squeeze the grooves and thus leading to a loss of structure. On the other hand, must the inking roller also the valleys in the corrugated cardboard len to achieve a homogeneous coloring.

The ink transfer device enables a uniform Applying the ink to the inking roller, yours the color on the part to be colored is leveled.

Particularly low pressure forces and an even adaptation Solution to the structured surface is achieved when the Ink roller is a brush roller, and the elasti cal outer peripheral surface formed by the brush bristles is.

A particularly good leveling of the color on the surface to be colored is applied by a paint roller achieved, which, based on the passing part, rotates in the opposite direction because they are surplus Color pushes ahead. At the same time  a particularly economical application of paint is guaranteed.

Flinging away of color does not occur when the um catch speed of the inking roller between in / sec and m / sec.

The ink applied to the inking roller can be regulate the quantity well, if a cylindrical one Transfer roller is used, which is rotatably driven and which touches the inking roller in the opposite direction. By doing the transfer roller simultaneously moves in the direction pa is given parallel to its longitudinal axis, is equal moderate application of the ink to the inking roller guaranteed.

The transfer roller has a smooth outer peripheral surface, and that from a material that each through processing paint is wettable.

The transfer is in turn by means of a metering roller roller dyed, using a gap between the amount of ink can be regulated on both rollers. For this is the storage of the transfer and / or metering roller designed such that the gap between the rollers is adjustable.

Another equalization of the color transfer to the Ink application roller can be reached if the transfer roller and the inking roller with different speeds are driven.

It is particularly advantageous if the actual color carrier station added a color equalization station tet, which in turn expediently ent two rollers holds that is similar to the inking roller with elastic Outer peripheral surface are formed. Here too the  Outer peripheral surface through the brush bristles of a brush roller are generated.

Particularly good color uniformity is achieved if, based on the transport direction of the concerned part to be inked, the upstream roller in the Synchronism and the downstream roller in the opposite direction is working. Excess paint is so between the whale zen managed, but on the other hand, the space between the rollers because of the downstream counter-rotating Only roll in an equalized form on the surface of the leave the relevant part.

The length of the bristles naturally depends on the Height difference on the textured surface that is to be colored. Conveniently, the bristles about twice as long as the height difference on the struk turured surface. It is also an advantage if the brush bristles are in tufts, so one as dense and compact outer surface of the paint application roller or the leveling rollers comes about. The diameter of the individual brush bristles must be in Ab Dependency on the bristle material can be chosen so a sufficient return force is generated to also the Flank the structures in the structured surface to be able to color well. Finally, the self-elastic tity of the brush bristles also prevent that by the adhesive effect of the wet paint the effective through knife of the inking roller is reduced, which is why fur-like coating is only suitable to a limited extent.

In the drawing is an embodiment of the subject of the invention. Show it:  

Fig. 1, the device according to the invention in a schematic side view tisierten,

Fig. 2 is a schematic stretched top view of the arrangement of brush roller, transfer roller and metering roller and

Fig. 3 is a schematic plan view of the Farbega lization station with the mutually movable union rollers.

In Fig. 1 is a highly schematic a device for one-sided coloring structured parts, such as open on one side or half of corrugated cardboard, is illustrated. In the figures, only those machine parts are illustrated that are necessary for the understanding of the structure and function. All other parts such as frame, foundation and. The like are omitted for the sake of clarity.

According to Fig. 1 comprises, based on the passage of the einzu coloring parts or products 1, the apparatus comprises a feed station 2, a inking station 3, a Egalisie assurance station 4, a transfer station 5, and a drying station 6.

The feed station 2 contains two rotatably driven rollers 7 , 8 , which are mounted axially parallel in a machine frame not shown ge and push the products 1 supplied from a separation station, also not shown, into the inking station 3 , the run of the products 1 from a light barrier 9 is being watched over.

The inking station 3 comprises a counter-pressure roller 11 which is also rotatably mounted in the machine frame and which is arranged such that the products 1 come from the supply station 2 , pass through the inking station 3 without a difference in height.

Opposite the platen roller 11 is an inking roller 12, turn roller axially parallel to the back pressure aligned. 11 The inking roller 12 is arranged on the side on which the surface of the product 1 is to be colored.

The ink supply roller 12 is supplied with ink by a transfer roller 13 with which a metering roller 14 cooperates.

The mounting and the drive of the parallel rollers 12 , 13 , 14 result from FIG. 2, the section being kinked at the height of the axis of the application roller 13 and the axis of rotation of the ink application axis 12 .

According to Fig. 2 are in the non-illustrated Maschi nengestell two mutually parallel bearing flanges 15, 16 spaced from each other. The two bearing flanges 15 , 16 are changeable in the machine frame and mirror-symmetrical to one another, which is why the same reference numerals are used for components on the two bearing flanges 15 , 16 and the parts connected to them.

The two bearing flanges 15 , 16 each contain a pair of bores 17 aligned with one another and a further pair of bores 18 aligned with one another. The axes of the bores 17 , 18 lie parallel to the axis of the counterpressure roller 11 and thus at right angles to the continuous movement of the products 1 through the inking station 3 . In addition, the axes of these pairs of bores 17 , 18 are at the same height.

In the bore 17 is a collar sleeve 21 provided with an eccentric surface 19 , which contains a cylindrical bearing bore 22 . A corresponding further Bundbüch se 21 is in corresponding holes in the bearing flange 16 th The two collar bushes 21 are used to support a shaft 23 on which the metering roller 14 sits in a rotationally fixed manner. The metering roller 14 is a smooth steel cylinder, the outer circumferential surface of which is coaxial with the axis of rotation of the shaft 23 .

On both ends, a truncated cone 24 is formed on the steel cylinder forming the metering roller 14 , the smaller diameter end of which points away from the bearing flange 15 , 16 in question . These two truncated cones 24 sit without a gap on the metering roller 14 representing steel cylinders.

In order to drive the metering roller 14 , a spur gear 26 is secured in a rotationally fixed manner on the shaft stub 23 of the shaft 23 with reference to FIG. 2 by means of a parallel key 25 .

The, based on the transport direction of the products 1 upstream holes 18 each contain an externally inserted collar sleeve 27 , which, as the figure shows, with its cylindrical part clearly Lich inwardly over the two bearing flanges 15 , 16 in question . On this protruding section from the two collar bushings 27 each have a movable bearing flange 28 or 29 , which is pivotable with respect to the collar bushing 27 . In addition, the collar sleeve 27 is used to support the metering roller 13 , which is also formed as a smooth-walled steel cylinder on the outside, which is arranged on a shaft 31 for rotation therewith. The ends of this shaft 31 are rotatably seated in the mutually cursing bores of the two collar bushings 27 .

The collar of the collar bushes 27 is located outside the fixed bearing flanges 15 , 16 , while the movable bearing flanges 28 and 29 are arranged on the inside thereof. So that the arrangement does not slide apart, a groove 32 is still inserted into the end of the collar bushings 27 projecting from the movable bearing flanges 28 , 29 , in which a corresponding external detonating ring 33 is seated.

In the same way as in the metering roller 14 , a truncated cone-like extension 34 is also provided in the transfer roller 13 at its two front ends, the smaller surface of the transfer roller 13 facing it. Both truncated cone-like extensions 24 and 34 are used to collect running paint over the end of the two rollers 13 , 14 and to guide them via interposed scrapers 35 into a paint container 36 which is sensitive to the two rollers 13 , 14 .

In order to set the transfer roller 13 in revolutions, a spur gear 37 is arranged on the shaft end projecting from the left collar sleeve 27 of the shaft 31 , which is aligned with the spur gear 26 , with which it is coupled by gear shears, not shown.

On the side of the spur gear 37 remote from the fixed bearing flange 15, a toothed belt collar disk 38 is finally attached, which is likewise connected in a rotationally fixed manner to the shaft 31 via a feather key 39 . With the aid of a toothed belt 41 , which is set in motion by a drive motor 42 , the toothed belt pulley 38 is driven and subsequently the gear wheel 36 via the gear shears . In this way, the metering roller and the transfer roller 14 , 13 run at the same speed, in such a way that their peripheral speed, at the point where their circumferences are most adjacent, move in the same direction as in FIG. 1 corresponding arrows are indicated. In other words, the transfer roller 13 moves counterclockwise in Fig. 1, while the metering roller 14 rotates clockwise.

The two bearing flanges 28 , 29 are provided at their end remote from the collar bushing 27 with a further bore 44 , namely the bores 44 are coaxial to one another and axially parallel to the bores 18 . In each of the two bores 44 there is an eccentric bushing 45 provided with a collar. Of which the eccentric bushing 45 , which is in the bearing flange 29 , a cylindrical bolt 46 which is axially secured by means of a clamping screw 47 . In the face of the other bearing flange 28 facing the cylinder bolt 46 contains a cylindrical blind bore 48 , which serves as La gerbohrung for a corresponding stub shaft 49 of the inking roller 12 . On the other end, the inking roller 12 is provided with a further shaft stub 51 , the tion 52 in a cylindrical Sackboh is inserted. This cylindrical blind bore 52 is located in an end face of a driver or drive shaft 53 which is rotatably mounted in the eccentric bush 45 of the bearing flange 28 . On its free, outwardly from the eccentric 45 protruding stub shaft rotatably seated as a toothed pulley toothed pulley 54th A toothed pulley 54 on the endless timing belt 55 connects the on-lying Zahnrie menscheibe 54 with a drive motor 56th As a result, the inking roller 12 can be rotated independently of the speed of the transfer roller 13 and the metering roller 14 . In addition, the ink transfer roller 12 runs with the same rotation as the transfer roller 13, ie, where the ink transfer roller 13 and the inking roller touching 12, enters supply on an opposite BEWE.

It should be noted that Fig. 2 also contains a highly schematic representation and that in particular those parts are omitted in particular, which hold the flanges 15 and 16 and which ensure that the two movable bearing flanges 28 and 29 only in the same direction on the Collar bushings 27 are to be pivoted so that the alignment between the bores 44 is not lost. In addition to the said coupling means is omitted from the figures for reasons of clarity, which ensures that the two eccentric bushings 21 can only be adjusted in the same direction, so that bushings in each setting of the eccentric 21, the misalignment of their bearing bores 22 is not lost. The same applies to a coupling device provided in the eccentric bushes 45 , which also has the task of ensuring that the adjustment is in the same direction.

Referring to FIG. 1, each of the two movable Lagerflan cal 28, 29 provided with an upwardly upstanding protrusion 57, engages the a double-acting pneumatic cylinder 58. Whose piston rod 59 is connected to an extension 61 which radially protrudes from the relevant eccentric bush 45 outside the movable bearing flange 28 or 29 . As a result, the two eccentric bushes 45 can be adjusted in the same direction by actuating the two pneumatic cylinders 58 , whereby the distance that the inking roller 12 has from the transfer roller 13 is varied.

In order to also be able to change the distance of the ink transfer roller 12 from the counter-pressure roller 11 , each of the two movable bearing flanges 28 , 29 is also provided with an extension 62 which extends from the bearing flange 28 or 29 approximately in the direction parallel to the web, along which it extends move the products 1 , stands out. 63 at the free end of this extension 61 engages a piston rod of a pneumatic cylinder 64 in order by extending the Kol benstange 63, the inking roller 12 roller of the counter-pressure lift. 11 Conversely, when the piston rod 63 is retracted, the inking roller 12 is lowered in the direction of the counter-pressure roller 11 .

Although only one side of the device is shown in FIG. 1, it is clear that the side remote from the viewer is provided in the same way with a corresponding pneumatic cylinder 64 and a corresponding extension 62 .

While the metering roller 14 and the transfer roller 13 are rigid rollers with a smooth cylindrical outer peripheral surface, the inking roller 12 has an elastic, also cylindrical outer peripheral surface. This elastic outer peripheral surface is achieved in that the inking roller 12 consists of egg nem rigid core 66 with a cylindrical outer contour, in the individual tufts of bristles 67 are inserted in corresponding blind holes. The bristle tufts 67 consist of polypropylene bristles with a diameter of 0.2 mm and they have a free length, measured from the cylindrical outer peripheral surface of the core 66, of approximately 12 mm. This creates a resilient and ink-absorbing surface or layer for the inking roller 12 , which can adapt to the grooves 67 of the open corrugated cardboard that forms the product 1 .

The paint to be applied to the products 1 comes from an ink reservoir 69 , from which an outlet of the tube 71 is formed . In the tube 71 there is a Do sierventil 72 , which is adjustable by means of a pneumatic cylinder 73 , the adjustment range of the Dosierven valve 72 includes the complete shut-off. The tube 71 ends above the valley or interstice between rule the metering roller 14 and the transfer roller 13 , so that the color flowing out of the tube 71 in the loading area between the two rollers 13 , 14 runs a. The distance between the metering roller 14 and the transfer roller 13 by means of the eccentric bushes 21 is set so that a is formed between their outer circumferential surfaces over the entire length of the two rolls 13, 14 through narrow gap, which in Fig. 1 by a corresponding double line at the arrow 74 is indicated. The setting and functioning of this gap 74 is explained in detail below.

The downstream of the inking station 3 leveling station 4 has two counter-rotating leveling rollers 75 , 76 , which are designed in the same way as the inking roller 12 as brush rollers. Accordingly, they have a rigid solid core: 77 , in which, as before, bristle tufts 78 are inserted at a small distance from one another, with which the entire upper surface of the two leveling rollers 75 , 76 is formed by the tight brush bristles.

The storage and drive of the two equalizing rollers 75 , 76 results from FIG. 3. Thereafter, two spaced apart bearing flanges 79 are present in the machine frame, not shown, which contain mutually aligned bores 81 , 82 and 83 . A shaft 84 on which the leveling roller 75 is arranged between the bearing flanges 79 in a rotationally fixed manner leads through the mutually aligned bores 81 . Another drive shaft 85 is rotatably seated in the mutually aligned bores 82 and serves to support and drive the leveling roller 78 . The bores 83 serve Lich the movable mounting of the flanges 79 , and in these bores 83 are sleeve-like extensions 86 of frame-fixed brackets 87 .

The shafts 84 and 85 project laterally over one of the bearing flanges 79 and they each carry a toothed belt pulley 68 and 89 in the vicinity of the bearing flange 79 in question. In addition, there is another toothed belt pulley 91 on a shaft 92 which are rotatably and axially immovable in the sleeve-like extensions 86 . Around the toothed belt pulleys 88 , 89 and 91 there is a toothed belt 93 , which is provided with teeth on the front and on the rear, and is also held at a distance in the region of one of its strands by a loose roller 94 which can be seen in FIG. 1. As a result of the guidance of the toothed belt 93 shown in FIG. 1, the upstream leveling roller 75 runs clockwise and thus in synchronization with the incoming products 1 , while the downstream leveling roller 76 rotates counterclockwise and thus rotates in the opposite direction to the passing products 1 . The drive comes via the shaft 92 which, in addition to the pulley 91, also carries a further pulley 95 , just in case it is fixed against rotation, and thus connects the shaft 92 with a drive motor 97 by means of a toothed belt 96 .

The two Egalisierungswalzen 75, 76 perform during their rotation around the plane defined by the shafts 84, 85 axis of rotation at the same time still a movement in the longitudinal direction by from the waves 84., 85 In order to produce this longitudinal movement, the end of the drive shaft 92 protruding from the pulley 95 carries a worm 97 which meshes with a worm wheel 98 . The worm wheel 98 is rotatably mounted and is provided on the end facing the viewer with a crank pin 99 which is axially parallel to the axis of rotation of the worm wheel 98 . The crank pin 99 interacts with a two-armed lever 101 , which is pivotally mounted at 102 on the frame. This bearing point 102 lies between the two shafts 84 and 85 and it bears in the same distance from the frame-fixed pivot point 102 to this axis parallel pins 103 and 104th The end of the lever 101 which extends beyond the pin 104 is forked and the mouth 105 formed by the fork overlaps the crank pin 99 .

In order to convert the movement of the lever 101 into the desired longitudinal movement of the two equalizing rollers 75 , 76 , a grooved washer 106 or 107 is placed on each, the circumferential groove 108 or 109 of which acts as a backdrop for the pin 103 or 104 works.

As soon as the shaft 92 is rotated by the drive motor 97 via the toothed belt 96 , the worm wheel 98 also rotates about an axis which is perpendicular to the axis of rotation of the shaft 92 . The thereby eccentrically around the rotational axis of the worm wheel pin 98 rotating crank 98 109 issued a periodi cal reciprocating pivoting movement about the axis of its pivot point 102 to the two-armed lever. During the pivoting movement of the lever 101 , the two equalizing rollers 75 , 76 are each longitudinally displaced by the same amount in the opposite direction without the rotation movement being interrupted in between. The toothed belt pulleys 88 and 89 are therefore made wide enough so that the toothed belt 93 remains in engagement with the two toothed belt pulleys 88 and 89 in each axial position of the two leveling rollers 75 and 76 .

By means of the further transport station 5 , which is formed from two rollers 111 and 112 rotating in synchronism, the product 1 in question is made in the downstream drying station 6 , which comprises a chamber 113 sent with hot air. The warm air exits from this chamber 113 in order to dry the colored top of the product 1 .

The device described so far works as follows:  

From the feed station upstream Vereinze processing station, which can be designed for example in the manner of the known sheet feeder, individual corrugated cardboard blanks, which form the products 1 , are pulled off and pushed in the direction of the inking station 3 before. The product 1 then passes between the counter-pressure roller 11 and the inking roller 12 , the side to be dyed from the blank, that is the grooved side of the open corrugated cardboard, of the inking roller 12 facing. Their bristles are transferred in a counter-current process to the product 1 by the transfer roller 13 on genom mene color. Counter-rotation here means that the bristles of the inking roller 12 run in the contact area with the product 1 against its feed movement. This results in a relatively high relative movement between the product 1 and the bristles of the ink application roller 12 is achieved despite the low speed of the ink application roller, whereby the paint is brushed onto the product 1 as it were. During the application of paint, the bristles penetrate into the valleys of the corrugated cardboard, so that a uniform coloring takes place without disturbing the structure of the corrugated cardboard.

During the passage of the product 1 through the inking station 3 , the product 1 is colored on its upper side over the entire width and, apart from the restriction explained below, also over the entire length. The product 1 , which is then conveyed further from the coloring station 3 , arrives at the leveling station, in which the still moist color is leveled further in order to achieve an even smoother application of paint and an even more shadow-free coloring. Here, the upstream leveling roller 75 runs in synchronism with the product, while the roller 76 further downstream, as before, rotates the inking roller 12 in the opposite direction. Back pressure devices can also be provided in this leveling station 4 so that the corrugated cardboard or the product 1 is kept in full contact with the leveling rollers 75 and 76 . Since in this leveling station 4, the leveling rollers 75 and 76 also perform a translatory movement in the direction of their axis of rotation, the transverse movement, based on the running direction of the product 1 , also presses the bristles more strongly against the flanks of the corrugated cardboard grooves, also in effectively equalize the color in this area. In addition, the periodic reciprocation of equalizing 76 prevents rollers 75, that the profile of the semi-open corrugated board is transferred in time in a complementary manner on the bristles of the two rollers 75, 76th

After equalization of the paint application takes place in the following drying station 6, the drying of the until then still moist or at least residual moist paint, so that the products 1 leave the device in a state so far dry that color no longer rubs off the surface is to be feared.

The ink application is regulated with the aid of the two steel cylinders which form the metering roller 14 and the transfer roller 13 . In the gusset area between these two rollers 13 , 14 color container runs continuously from the dosing container 69 . This color can either leave the area between the two rollers 13 , 14 by running over the front ends and there in cooperation with the truncated cone-shaped sets 24 , 34 and with the stripper 35 in the drip pan 36 or passed through between the gap 74 set by the two rollers 13 , 14 . In this case, running the part of the color, which is located on the outer peripheral surface of the metering roller 14, after a revolution back to the region above and between the two rollers 13, 14 while the carrier roll on the outer peripheral surface of the over 13 color component located roller onto the inking 12 is passed. It thus run on the timing location Kon the transfer roller 14 and the inking roller 12 against each other, so that the transfer roller 14 almost their entire carrier roll paint on the bristles of the Farbauf 12 emits. Thus, the part of the outer peripheral surface of the transfer roller 13 lying between the inking roller 12 and the gusset area is practically free of ink and is only newly inked in the area of the gap 74 . At the same time it can be seen that the width of the gap 74 can be used to meter the amount of ink that is delivered to the inking roller 12 . The smaller the width of the gap 74 is set, the less ink is transferred to the inking roller 12 .

While the device is running, the gap width is adjusted by synchronously adjusting the two eccentrics in the form of the bushes 21 so that neither too little nor too much ink is transferred to the bristles of the inking roller 12 . At the same time, the metering valve 72 is regulated via the pneumatic cylinder 73 in such a way that as little paint as possible runs off the ends of the metering roller 14 and the transfer roller 13 , that is to say all the ink that is supplied from the ink reservoir 69 also only flows through the gap 74 .

Since the ink transfer roller 12 is practically constantly supplied with ink, it is expedient to ensure that the counter-pressure roller 11 is not contaminated by ink, because otherwise ink is also transferred to the back of the product 1 . To avoid this, two operating modes can be selected. According to one mode of operation, the products 1 are fed to the inking station 3 in a slightly shingled manner, ie a narrow strip extending across the width of the product 1 at the upstream edge is covered by the subsequent product 1 , thereby ensuring that between successive products 1 can under no circumstances create a gap through which the bristles of the inking roller 12 smear the counter-pressure roller 11 with ink. The other operating option is to detect the start and end of a respective product 1 with the aid of the reflex light barrier 9 and then in good time after the leading edge passes and also in good time before the trailing edge of the product 1 , controlled by the pneumatic cylinder raising 64, the bearing of the inking roller 12 so that the bristles of the inking roller 12 in any case the platen may contact 11 if there is no product 1 between the two rollers 11 is located, 12th In this case, too, certain safety areas must be observed, which lead to the fact that at the beginning and at the end of each product there are 1 insufficiently colored stripes or none at all.

So that in production breaks, for example, between local successive products 1 with gaps, there is no local overdyeing of the inking roller 12 , it is expedient, simultaneously with the lifting of the inking roller 12 , that is to say to lead away from the counterpressure roller 11 , and also the contact to the transfer roller 13 interrupt, because otherwise the ink roller 12 would gradually gradually saturate with color due to a lack of decrease in color, because over the contact with the transfer roller 13 , color would be continuously replenished. To this contact with the transfer roller 13 to interrup surfaces are the pneumatic cylinders actuated simultaneously 58 be, by 45, the two eccentric bushes so ver be, to the contact between the ink application roller 12 and the transfer roller 13 ceases.

Since also in the area of the leveling station 4 there are not illustrated counterpressure means which, for example, consist of an endless conveyor belt, who also lifted the leveling rollers 75 , 76 when no product 1 faces the leveling rollers 75 , 76 . For this purpose, pneumatic cylinders 114 are easily seen which pivot the bearing flanges 79 upwards, pivoting away around the sleeve-like extensions 86 until the bristles are lifted off the counterpressure device. The movement is similar to that of the ink application roller 12 , in which the movable bearing flanges 28 , 29 pivot upward around the extensions of the collar bushings 27 .

In the embodiment shown, only the two equalizing rollers 75 , 76 perform a translatory movement in the direction of their axis of rotation, while the inking roller 12 is fixed axially and is rotated by the drive motor 56 via the toothed belt 55 and the coupling shaft 53 in revolutions, for which purpose Driver pin 115 engages in a corresponding groove in the adjacent end face of driver shaft 53 . However, it is also possible to give this inking roller 12 a reciprocating movement by using a mechanism as described in connection with the two leveling rollers 75 , 76 .

If the inking roller 12 cleaned or replaced who needs to, it is enough to loosen the locking screw 47 to retract the cylinder bolt 46 a little until the stub shafts 48 and 51 can come free to remove the inking roller 12 . After cleaning, the inking roller 12 or another inking roller is used in the opposite direction and the non-rotatable coupling with the driving shaft 53 is made via the driving pin 115 .

In addition, it is apparent from the exemplary embodiment Lich that other structured flat parts turned on can be colored, although of course it is useful if the main direction of the structures parallel to the trans port direction, as is the case with half-open corrugated cardboard the case is when the appropriate cuts like this be placed so that the grooves are parallel to the transport groove tung lie. Finally, the new device is suitable also for other pressure-sensitive flat parts, if no particularly pronounced surface structure available that is. In any case, there is a very economical use of color guaranteed and the environment is not at the entrance color the products also provided with color that the device escapes.

Claims (29)

1. Device for at least one-sided coloring of flat parts ( 1 )
with a transport device ( 2 ) arranged in a machine frame for transporting the parts ( 1 ) along a path which is aligned parallel to the side to be colored,
with an externally cylindrical ink application roller ( 12 ) rotatably mounted in a frame, the outer peripheral surface of which is elastic, which can be set in rotation by means of a drive device ( 56 ) and which is arranged on the side of the path which points in the same direction, like the area to be colored,
with an ink transfer means (13,14) to (69) ink to the Farbauf from an ink reservoir support roller to transfer (12), and
with a counter pressure device ( 11 ) for pressing the part ( 1 ) onto the inking roller ( 12 ). 2. Apparatus according to claim 1, characterized in that the inking roller ( 12 ) is a brush roller and that the elastic outer peripheral surface is formed by brush bristles. 3. Apparatus according to claim 1, characterized in that the inking roller ( 12 ) rotates in the opposite direction with respect to the preceding part ( 1 ). 4. The device according to claim 1, characterized in that the peripheral speed between xxx m / sec and yyy m / sec lies. 5. The device according to claim 1, characterized in that the ink transfer device ( 13 , 14 ) has a rotatably mounted cylindrical transfer roller ( 13 ) which is rotatably driven, the axis of rotation of which is aligned parallel to the axis of rotation of the inking roller ( 12 ) and which with its outer surface touches the inking roller ( 12 ), and that the transfer roller ( 13 ) rotates opposite to the inking roller ( 12 ). 6. The device according to claim 1, characterized in that the transfer roller ( 13 ) has a smooth outer peripheral surface. 7. The device according to claim 1, characterized in that the transfer roller ( 13 ) is mounted displaceably in the longitudinal direction of its axis of rotation. 8. The device according to claim 1, characterized in that the transfer roller ( 13 ) is assigned a drive device ( 42 ) by means of which the transfer roller ( 13 ) is periodically moved back and forth parallel to its axis of rotation while it ro ro about its axis of rotation. 9. The device according to claim 1, characterized in that the ink transfer device ( 13 , 14 ) has a rotatably mounted cylindrical metering roller ( 14 ) which is rotatably driven and the axis of rotation of which is parallel to the axis of rotation of the transfer roller ( 13 ). 10. The device according to claim 1, characterized in that the metering roller ( 14 ) has a smooth outer peripheral surface. 11. The device according to claim 1, characterized in that between the metering roller ( 14 ) and the transfer roller ( 13 ) has a gap ( 74 ) and that the metering roller ( 14 ) rotates in the opposite direction as the transfer roller ( 13 ). 12. The apparatus according to claim 1, characterized in that the storage of the transfer and / or the metering roller ( 14 ) is designed such that the gap ( 74 ) between the metering roller ( 14 ) and the transfer roller ( 13 ) is adjustable. 13. The apparatus according to claim 1, characterized in that the distance between the inking roller ( 12 ) and the counter pressure device ( 11 ) is smaller than it corresponds to the thickness of the part to be inked ( 1 ). 14. The apparatus according to claim 1, characterized in that the counter pressure device has a with the Bahnge speed of the part ( 1 ) rotating roller ( 11 ). 15. The apparatus according to claim 1, characterized in that the inking roller ( 12 ) and / or the transfer roller ( 13 ) and / or the metering roller ( 14 ) and / or the back pressure device ( 11 ) wider than the part to be inked ( 1 ) are. 16. The apparatus according to claim 1, characterized in that the inking roller ( 12 ) runs at a different speed to Um as the transfer roller ( 13 ). 17. The apparatus according to claim 1, characterized in that it has a color equalization station ( 4 ), which is arranged in relation to the running direction of the part ( 1 ) stro mab of the inking roller ( 12 ) to the color transferred to the part ( 1 ) equalize. 18. The apparatus according to claim 1, characterized in that the color equalization station ( 4 ) has at least one roller ( 75 , 76 ) with an elastic outer peripheral surface. 19. The apparatus according to claim 1, characterized in that the color equalization roller ( 4 ) is a brush roller and that the elastic outer peripheral surface is formed by brush bristles. 20. The apparatus according to claim 1, characterized in that the color equalization station ( 4 ) has at least two rollers ( 75 , 76 ) with an elastic outer peripheral surface. 21. The apparatus according to claim 1, characterized in that both color equalization rollers ( 75 , 76 ) are brush rollers and that their elastic outer peripheral surfaces are formed by brush bristles. 22. The apparatus according to claim 1, characterized in that the upstream color equalization roller ( 75 ) with respect to the running direction of the part ( 1 ) in the same direction and the downstream color equalization roller ( 76 ) with respect to the direction of movement of the part ( 1 ) in the opposite direction rotates. 23. The device according to claim 1, characterized in that color equalization rollers ( 75 , 76 ) are mounted longitudinally displaceably with respect to their axes of rotation and are driven such that they simultaneously perform a reciprocating movement on the surface of the part to be inked ( 1 ) during their rotation . 24. The device according to claim 1, 19 or 21, characterized ge indicates that the brush roller on its outside brush bristles that are close to the circumferential surface, that cover the entire surface and that of the outer surface of the brush bristles is cylindrical is. 25. The device according to claim 1, characterized in that the brush bristles are arranged in tufts ( 67 , 78 ). 26. The device according to claim 1, characterized in that the brush bristles have a free length of between 3 mm and 15 mm. 27. The apparatus according to claim 1, characterized in that a drying station ( 6 ) is arranged downstream of the color equalization station ( 4 ). 28. The apparatus according to claim 1, characterized in that the distance between the axis of the transfer roller ( 13 ) from the axis of the inking roller ( 12 ) is adjustable. 29. The device according to claim 1, characterized in that the inking roller ( 12 ) is associated with an actuating device ( 64 ) through which the distance of the inking roller ( 12 ) from the counter pressure device ( 11 ) can be increased at least to the extent that the inking roller ( 12 ) does not touch the counter pressure device ( 11 ).