DE10001590A1 - Device for dusting a printed product moved past by a conveyor - Google Patents

Abstract

A device (1) is used for dusting a printed product (2) which is moved past by means of a conveying device. It comprises a powder nozzle arrangement (5) which emits at least one powder / air mixture jet (8). In addition, it has an air nozzle arrangement (20) which emits air jets (11, 12). The powder / air mixture jet (8) and the air jets (11, 12) meet in inflow regions (10, 18, 19) which extend transversely to the conveying direction (3) essentially over the width of the printed product (2) . The nozzle arrangements (5, 20) are designed and directed so that the powder / air mixture jet (8) and the air jets (11, 12) are adjacent to one another along the course of the powder / air mixture jet (8). However, the powder / air mixture jet (8) and the air jets (11, 12) do not penetrate until they strike the printed product (2). This leads to the formation of good flow properties for a powder / air mixture jet (8) which is as laminar as possible, without this being swirled by the air jets (11, 12) until it hits the printed product (2).

Description

The invention relates to a device for dusting one moved by a conveyor Printed product with at least one powder / air mixed-jet dispensing powder nozzle arrangement and one at least one air jet emitting air jet arrangement, where the powder / air mixture jet and the air jet in inflow areas that are transverse to the conveying direction essentially across the width of the printed product stretch to meet this.

Such pollination devices are from DE 197 51 383 A1 and known from US 5 868 326 A. The Air nozzle arrangements in these pollinators form air curtains that block the powder / air mixture from external influences, e.g. B. Air turbulence caused by the conveyor should. At the same time should prevent air curtains be changed that powder is not released to the printed product is, but unwanted leaks. The order the nozzle arrangements in the known pollination device but is such that the air jets and the Powder / air mixture jet along its flow path touch or penetrate each other to the printed product. This leads to several disadvantages: On the one hand, in In this case, powder can hardly be prevented in the Air jets flow path and through swirls Unwanted transport in the air jets to the outside what is to be prevented On the other hand they lead each other on their flow path to  Print product penetrating rays to an increased Air pressure above the printed product, what it the powder difficult to get to the printed product. On irregular powder application and increased powder loss can be the result.

Another known pollination device of the beginning mentioned type is described in DE 197 07 157 A1. There is an additional suction chamber the unwanted Prevent powder from being released into the environment. Providing such a suction device is expensive and leads to additional adjustment problems of pollination direction, because B. there is a risk that if too strong Vacuum the powder in too little amount on the pressure pro product sticks. Is the vacuum in the suction chamber on the other hand, the unwanted powder release is too low not sufficiently prevented from the outside.

It is therefore the object of the present invention a pollination device of the type mentioned to develop such that a more efficient powder is guaranteed on the printed product, the additional not essential from disturbing air turbulence being affected.

This object is achieved in that the nozzle arrangements are designed and directed that the powder / air mixture jet and the air jet along the course of the powder / air mixture jet who are neighboring, however, until they meet do not penetrate the printed product.

The interaction of the air jet with the powder / air mixed jet on the way from the nozzle assemblies towards the printed product is based on the specification of  favorable flow boundary conditions for the formation of a possible laminar powder / air mixture jet the neighboring air jet or jets above the Flow areas separated from the powder / air mixture jet Form "air curtains" limited. Because the rays do not penetrate on the way to the printed product, there is no desired powder discharge by powder that is whirled in the air jet. Because the min at least an air jet a certain distance from the powder / Air mixture jet has interference that affect in the air jet due to turbulence e.g. B. by passing components of the conveyor are generated the powder / air mixture jet practically not. Also problems with powder application caused by one of the Air jet caused increased air pressure above the Powder inflow areas are generated at a such configuration and alignment of the nozzle arrangement reduced.

The nozzle arrangements can be designed and directed in this way be that at least one inflow area for the Powder / air mixture jet upstream and downstream the flow direction at least one inflow area is adjacent for the air jet. That way both an undesirable powder discharge in both directions prevent along the conveyor path as well as the Powder / air mixture jet in these two directions protected against turbulence.

The nozzles of the air nozzle arrangement can be compared to the Nozzles of the powder nozzle arrangement can be arranged such that the main directions of neighboring rays are at an angle include that of the sum of half the opening angle these rays measured in a plane that is essentially lichen perpendicular to the dusted section of the printed product  stands and is parallel to the direction of conveyance, corresponds. Such a choice of the main directions of the rays as a function of their opening angles ensures that the adjacent boundary areas of the rays along the flow path from the Nozzle arrangements towards the printed product essentially one have a constant distance from each other. This improves again the flow boundary conditions for the formation of a Powder / air mixture jet as laminar as possible.

The air nozzle arrangement is preferably designed such that the main direction of the air jet with the pollinated Section of the printed product encloses an angle, which is less than 90 °. In this way a de Finished outflow behavior of the air jet after the Guaranteed impact on the printed product since after the impact of the air jet on the printed product a total pulse component of the air jet parallel to flowed section of the printed product remains.

The air nozzle arrangement can be designed that the air jet has a total pulse component, which is directed away from the powder / air mixture jet. At this embodiment will penetrate the beam len even after hitting the printed product in the essentially prevented because the air jets after the Impact on the printed product from the powder / air mixture Flowing away jet.

In a preferred embodiment of the invention the air nozzle assembly is part of a main pipe that communicates with a compressed air source and off which the at least one air jet with to the peripheral surface of the main pipe vertical main direction occurs. A such an arrangement allows easy specification of the  Main direction of the air jets, the main pipe can be manufactured in a simple manner.

The main pipe can have a wall thickness that is larger than 10 mm, the air nozzles being the air nozzles arrangement formed by holes in the main tube are. Such a configuration of the air nozzles is inexpensive.

The distance between the powder nozzles and the powder nozzles is preferred arrangement to the printed product less than that of Air nozzles to the printed product. The powder / air mixture jet is then immediately after leaving the Powder nozzles from a stable air jet to specify the Current boundary conditions surround. This also promotes the formation of a laminar powder / air mixture jet.

The powder nozzle assembly can be a plurality of powder nozzles Carriers include and the air nozzle assembly can Have a plurality of air nozzles that are transverse to the conveying direction tion to the powder nozzle carriers so offset are that at least one assigned to an air nozzle Single air jet between two neighboring powders can flow through nozzle carriers. This allows one simple design of the nozzle arrangements in the Usually be fed from separate sources. The nozzles Orders are not in the way of each other. Additional Liche through channels are therefore not necessary. Overall, a relatively compact arrangement of the Realize pollination device.

The nozzles can be designed so that the opening win angle of the rays is in the range of 20 °. A derar opening angle leads in connection with the white other operating parameters relevant for pollination  (e.g. powder density, flow velocity) to a good one Flow behavior of the jets.

The delivery speed of the air jet can be double be as large as that of the powder / air mixture jet. Such a speed ratio between the Blasting leads to an additional improvement the formation of the flow boundary conditions for the Powder / air mixture jet.

Embodiments of the invention are as follows explained in more detail with reference to the drawing; show it:

Fig. 1: a dusting device for a printing product vorbeibeweg tes in a side view parallel to the conveying direction;

FIG. 2 shows a detail of a view along line II-II of FIG. 1;

FIG. 3 shows a view according to line III-III of Figure 1 on a reduced scale;. and

FIG. 4: a view similar to FIG. 1 of an old native pollination device.

A generally provided with the reference numeral 1 pollinating device is used for pollinating a freshly printed printed product 2 shown only schematically in the drawing, so that printed products lying on top of one another in the later course of the processing do not stick together. The printed product 2 is moved past the pollination device 1 in the direction of arrow 3 by means of a conveyor device (not shown) and then stacked (not shown).

The pollination device 1 has a basic housing 4 , which is held in a manner not shown by a support frame. The basic housing 4 is connected to a powder source and a compressed air source, which are also not shown.

For powder dusting of the printed product 2 , the dusting device 1 has a powder nozzle arrangement 5 . As shown in particular in Fig. 2, the powder nozzle assembly 5 has a plurality of powder nozzle carriers 6 , which are placed on one end of the base housing 4 and are connected via the latter with the powder and the compressed air source. Transversely to the conveying direction 3 , that is to say perpendicular to the plane of the drawing in FIG. 1, the powder nozzle carriers have a width of approximately 20 mm and a distance from one another of approximately 100 mm (drawing not to scale). Each powder nozzle holder 6 has two powder nozzles 7 arranged side by side in the conveying direction 3 . These are shaped so that when pollinating them, a powder / air mixture jet 8 (see FIG. 1) emerges from individual jet cones, which are assigned to the powder nozzles 7 , and which has an opening angle α of approximately 20 ° has.

Due to the opening angle α and the distance of the printing product 2 from the powder nozzles 7 in the direction of a powder jet main direction 9 , the individual jet cones 7 of the powder / air mixture jet 8 associated with the individual powder nozzles 7 combine on the printed product 2 to form a total rectangular powder inflow region 10 (cf. FIG. 3) which extends essentially over the entire width of the printed product 2 .

The powder / air mixture jet 8 is surrounded by powder-free air jets 11 , 12 both upstream and downstream of the conveying direction 3 . The air jets 11 , 12 are emitted by an air nozzle arrangement 20 with air nozzles 13 (see FIG. 2), which are designed as bores in the peripheral wall of a compressed air main pipe 14 . The peripheral wall has a thickness that is greater than 10 mm.

The individual jet cones of the air jets 11 , 12 assigned to the air nozzles 13 have an opening angle β with a size of approximately 20 °, which corresponds to the opening angle α of the powder / air mixture jet 8 .

The compressed air main pipe 14 is mounted in a manner not shown above the side of the powder nozzle arrangement 5 facing away from the powder nozzles 7 , so that the distance between the air nozzles 13 and the printed product 2 is greater than the distance between the powder nozzles 7 and the printed product 2 , and extends transversely to conveying direction 3 . As shown in Fig. 2, the air nozzles 13 are offset transversely to the conveying direction 3 to the powder nozzles 7 are arranged such that three pairs respectively are seen in projection on a plane parallel to the printed product 2 from air nozzles 13 of adjacent between the powder nozzles 7 powder nozzle carrier 6. In this way, three pairs, each with two air nozzles 13 lying next to one another in the conveying direction 3, are arranged between two adjacent powder nozzle carriers 6 .

The compressed air main pipe 14 is connected to a compressed air source, not shown. The air jets 11 , 12 have main air jet directions 15 , 16 which are perpendicular to the peripheral surface 17 of the compressed air main pipe 14 .

The main air jet directions 15 , 16 form an angle α / 2 + β / 2 with the main powder jet direction 9 such that the mutually facing boundary surfaces of the powder / air mixture jet 8 and the air jets 11 , 12 are parallel to one another. A distance d remains between these adjacent parallel boundary surfaces of the powder / air mixture jet 8 and the air jets 11 , 12 (cf. FIG. 1). Because of this distance d there is no penetration of the powder / air mixture jet 8 and the air jets 11 , 12 on the way from the respective nozzles 7 , 13 to the printed product 2 .

The assigned to the individual air nozzles 13 single jet cone unite on the way to Druckpro product 2 to "air curtains" and meet in substantially rectangular inflow areas 18 , 19 on the printed product 2 , the surface area with the powder-Anströmbe rich 10 comparable is (see Fig. 3).

After the inflow of the printed product 2 in the powder inflow region 10 and the air inflow regions 18 , 19 , the upstream air jet 11 has a total pulse component opposite to the conveying direction 3 and the downstream air jet 12 has a total impulse component in the conveying direction 3 .

The air jets 11 , 12 have a flow rate that is approximately twice as high as that of the powder / air mixture jet 8 .

The pollination device 1 works as follows:

The moving in the conveying direction 3 printed product 2 is sprayed with the powder / air mixture jet 8 and the air 11 , 12 . Through the conveyor device, not shown, and the gripper for the printed product moving below the nozzles 7 , 13 . 2 (not shown), air swirls as the printed product 2 moves past (conveying speeds in the range of a few m / s). The air jets 11 , 12 shield the powder / air mixture jet 8 against these eddy currents, so that it can pressurize the Druckpro product 2 essentially undisturbed. The air jets 11, 12 penetrate thereby along the flow path toward the printed product 2 not in the powder / air mixture 8 is a beam, so that there is no Puderverwirbelung by the air jets 11, 12th

Due to the attachment of the air nozzles 13 above the powder nozzles 7 and the higher flow velocity of the air jets 11 , 12 , the portions of the air jets 11 , 12 adjacent to the powder / air mixture jet 8 generate flow boundary conditions which result in an essentially laminar flow of the printed product through the Allow powder / air mixture jet 8 . After impinging on the printed product 2 , the air jets 11 , 12 flow away from the powder / air mixture jet 8 due to their upstream or downstream total impulse components, without interacting appreciably with it. This prevents unwanted powder discharge to the outside in wesent union.

An alternative embodiment of a pollination device is shown in Fig. 4. Components that correspond to those that have been described in connection with FIGS. 1 to 3 bear with reference numerals increased by 100 and are not explained again in an individual. The angle or size designations remain unchanged.

The air nozzle arrangement 121 is formed in this embodiment in an air nozzle compressed air bar 122 which, similar to the compressed air main pipe 14 , extends transversely to the conveying direction 103 above the powder nozzle arrangement 105 . The air nozzle compressed air bar 122 is fastened to the base housing 104 of the pollination device 101 .

The air nozzles of the air nozzle arrangement 121 , which, like the air nozzles 13 of the air nozzle arrangement 20 , which was described in conjunction with FIGS. 1 to 3, are arranged offset with respect to the conveying direction 103 with respect to the powder nozzles, are wall sections 123 , 124 facing the printed product 102 the air nozzle compressed air bar 122 is formed. From the side view of FIG. 4 it can be seen that the wall sections 123 , 124 are arranged in a V-shape with respect to one another in such a way that the air jets 111 , 112 emerging perpendicularly from them have the same main air jet directions 115 , 116 as in the context of FIGS Fig. 1 to 3 described embodiment of the pollination device.

Surrounded in an embodiment not shown the air inflow areas do not match the powder inflow area only on the downstream or upstream Sides, but also transversely to the conveying direction, so that the powder flow area completely closed by one whose air inflow area is surrounded.

Claims (11)

1. Device for dusting a printed product moved past by means of a conveying device with a powder nozzle arrangement emitting at least one powder / air mixture jet and an air nozzle arrangement emitting at least one air jet, the powder / air mixed jet and the air jet in inflow regions which are transverse to the conveying direction extend essentially over the width of the printed product, meet it, characterized in that the nozzle arrangements ( 5 , 20 ; 105 , 121 ) are designed and directed such that the powder / air mixture jet ( 8 ; 108 ) and the air jet ( 11 , 12 ; 111 , 112 ) are adjacent to one another along the course of the powder / air mixture jet ( 8 ; 108 ), but do not penetrate one another until they strike the printed product ( 2 ). 2. Device according to claim 1, characterized in that the nozzle arrangements ( 5 , 20 ; 105 , 121 ) are designed and directed so that the at least one inflow region ( 10 ; 110 ) for the powder / air mixture jet ( 8 ; 108 ) upstream and downstream of the conveying direction ( 3 ; 103 ) at least one inflow region ( 18 , 19 ; 118 , 119 ) for the air jet ( 11 , 12 ; 111 , 112 ) is adjacent. 3. Apparatus according to claim 1 or 2, characterized in that the nozzles ( 13 ) of the air nozzle arrangement ( 20 ; 121 ) relative to the nozzles ( 7 ) of the powder nozzle arrangement ( 5 ) are arranged so that the main directions ( 9 , 15 ; 9 , 16 ; 109 , 115 ; 109 , 116 ) of adjacent beams ( 8 , 11 ; 8 , 12 ; 108 , 111 ; 108 , 112 ) enclose an angle which is the sum of half the opening angle of these beams ( 8 , 11 , 12 ; 108 , 111 , 112 ) measured in a plane which is substantially perpendicular to the dusted section of the printed product ( 2 ; 102 ) and parallel to the conveying direction ( 3 ; 103 ). 4. Device according to one of claims 1 to 3, characterized in that the air nozzle arrangement ( 20 ; 121 ) is designed so that the main direction ( 15 , 16 ; 115 , 116 ) of the air jet ( 11 , 12 ; 111 , 112 ) forms an angle with the dusted section of the printed product ( 2 ; 102 ) which is less than 90 °. 5. The device according to claim 4, characterized in that the air nozzle arrangement ( 20 ; 121 ) is so designed that the air jet ( 11 , 12 ; 111 , 112 ) has a total pulse component, the powder / Luftge mixed jet ( 8th ; 108 ) is directed away. 6. Device according to one of the preceding claims, characterized in that the air nozzle arrangement ( 20 ) is part of a main tube ( 14 ) which is connected to a compressed air source and from which the at least one air jet ( 11 , 12 ) with the peripheral surface ( 17 ) of the main pipe ( 14 ) vertical main direction ( 15 , 16 ) emerges. 7. The device according to claim 6, characterized in that the main tube ( 14 ) has a wall thickness which is greater than 10 mm, wherein the air nozzles ( 13 ) of the air nozzle arrangement ( 20 ) are formed by bores in the main tube ( 14 ). 8. Device according to one of the preceding claims, characterized in that the distance between the powder nozzles ( 7 ; 107 ) of the powder nozzle arrangement ( 5 ; 105 ) to the printed product ( 2 ; 102 ) is less than that of the air nozzles ( 13 ) to the printed product ( 2 ; 102 ). 9. Device according to one of the preceding claims, characterized in that the powder nozzle arrangement ( 5 ; 105 ) comprises a plurality of powder nozzle carriers ( 6 ; 106 ) and the air nozzle arrangement ( 20 ; 121 ) has a plurality of air nozzles ( 13 ) which cross to the conveying direction ( 3 ; 103 ) to the powder nozzle carriers ( 6 ; 106 ) are arranged offset so that in each case at least one air jet ( 13 ) associated individual air jet can flow between two adjacent powder nozzle carriers ( 6 ; 106 ). 10. Device according to one of the preceding claims, characterized in that the nozzles ( 7 , 13 ) are designed such that the opening angle of the jets ( 8 , 11 , 12 ; 108 , 111 , 112 ) is in the range of 20 °. 11. Device according to one of the preceding claims, characterized in that the discharge speed of the air jet ( 11 , 12 ; 111 , 112 ) is twice as large as that of the powder / air mixture jet ( 8 ; 108 ).