DE1293165B - Electrostatic printing system - Google Patents

Description

1 2

The invention relates to a device for elec- The device according to the invention contains no

trostatic printing of flat objects, and they have all kinds of cumbersome mechanical devices, such as consists of a container filled with colored powder, brushes, which are normally necessary for this the on an outer surface an electrically conductive screen color powder through the screen printing stencil to overprint stencil who also bear a counter-5. In addition, the invention in their overlaying plate over a power source for the creation of various execution forms a thorough create an electrostatic field between the sieve, mixing and circulating the color powder and the printing stencil and plate is connected. Carrier particles safe, so that uniform pressure

It is an electrostatic printing process that produces results and improved image contrast knows, in which powder particles are io through an image form.

electrode through an air gap, in which the invention is illustrated below with reference to the drawing electrostatic field has been generated, described on a voltage. It shows

Image pickup electrode or on an object F i g. 1 to facilitate understanding of the invention

be transferred, the. between the two diagrammatic view of an electrostatic .Electrodes are located. The two electrodes consist of the known printing device mentioned at the beginning from parallel electrically conductive surfaces, which in different ways,

different electrical voltages are held, Fig. 2 a diagrammatic view of the invention

so that these electrodes have an essentially identical design, delimit a shaped electrostatic field. F i g. 3 the view of an arrangement for the mechanical

The image shape electrode can be a thin current- so frilly operation of the printing device, and conductive component, for example a grid or sieve F i g. 4 is one with electromagnetic drive

be in which all surfaces, with the exception of the provided arrangement for operating the device; desired printing areas, covered or masked. Figs. 5, 6 and 7 are other designs, at

Printing is effected by using charged magnets facing each other Pigment particles through the image shape openings of the 25, and

Grid or sieve through into the electro- F i g. 8 and 9 are a front view and a

static field can be brought. The particles are side view of a modification to achieve a along pressure lines that are perpendicular to the plane of the image. run, move and generate an image of the For a better understanding of the present invention

Pattern of the openings present in the sieve on 3 ° formation is first made with reference to FIG. 1 one the receiving electrode. or on the item, electrostatic printing device, described that that has been pushed between the electrodes. corresponds to the state of the art. This Vorrich-Die Charged powder particles are placed on top of a container 10 with a bottom part surface on which they have been deposited, so long in the form of a screen printing stencil 12, in the following held until the image by the action of heat 35 called screen stencil, on in which a to be printed or by solvent vapors or by another letter or number. The sieve means that of the composition of the partial image template 12 preferably consists of a stream depend, is fixed. conductive or conductive sieve. The container 10 ent-Zum Forcing the pigment powder through holds pigment powder particles so large that they are the sieve openings had to use a brush or a 40 through the open mesh of the existing one another device can be used, which pass through the screen template. Between a conductive powder particle pushes into the electrostatic field. capable plate 16 and the conductive screen template Although the powder particles are smaller than the opening 12, connection to a voltage source 14 gen, the powder particles do not run freely and at the same time an electrostatic field is generated. The sieve and the moderately through the openings. An around 45 plate thus serve as an opposing plate running brush is for pushing through the partial distance set electrodes to generate this Chen, although well suited, must soon be replaced by an electrostatic field.

as the brushes wear out quickly. The container 10 contains a pigment powder, its

With the invention, a novel arrangement of particles is now intended by a rotating brush 18 against the tion in an electrostatic printing system to the conveyor 50 screen stencil, so that the powder of pigment powder through the particles in the printing screen into the between the screen stencil 12 and Existing openings are created through the back plate 16 existing electrostatic field whereby the pigment powder particles pass through the at elek-. On a between screen template 12 and static printing systems used stencil plate 16 inserted object, e.g. B. on one sieves are moved through in such a way that the sheets of paper 20 become the pigment powder distribution pressures of the powder particles scattered through the stencils, which corresponds to the one on the sieve stencil 12 The brush previously used is no longer required and resembles the existing pattern. The sheet of paper 20 is borrowed. is then pulled out. The powder particles adhere

The device according to the invention for electrical on the paper sheet and can by means of a heat static Printing is characterized in that 60 treatment or by spraying with a one a multitude of magnetizable glaze-forming agents in the colored powder for permanent use on the sheet of paper Contains carrier particles that are larger than the Ma- are attached. Is the object itself sufficient opening of the screen printing stencil, and that conductive, so that an electrostatic field between a magnet acting along the plate to the object and the conductive screen is generated pulling the carrier particles in the direction of the sieve 65 can be, then the plate 16 is not necessary, printing template is provided. The magnet is a print or deposit of pigment powder parallel to that of the conductive screen printing stencil takes place essentially on the conductive object Movable level. borrowed in the same way as when using the

3 4

Plate 16. Although only the magnet 36 can be used in the manner shown in FIG. 2 refers to a back plate, but this posed way of being moved back and forth by hand should not be interpreted as a limitation, since the back. If several magnets 40 A to 40 F can be omitted on a plate, if a counter-band 42 is attached, which stood by two cylinders 44, which is rotatably supported by such a large conductivity 5 and 46, these two will have, that it works as an electrode in creating spaced cylinders from an electrostatic field motor. (not shown) rotated so that the magnets

Move the pigment powders present in the container 10 one after the other along the plate 30. The particles do not flow voluntarily and at the same time through magnetic particles are consequently alternating the uncovered meshes through, even if the io is lifted to the screen template and then fall back into Powder particles are smaller than the mesh openings. the container back. When moving to the sieve-es A device must be available to carry this template, the magnetic particles powder-powder particles through these openings and push these powder particles through the in stores. One of the uncovered openings located in the effective screen template used for this purpose Devices is a brush that passes through the 15 gene in between the sieve template and Grinds along openings. The powder particles must be present on the opposite electrode the brush will be poured, which will then box the powder comfortably. The magnets will be 40 ^ 4 to 4OF pushes through the openings. always moved over the plate 30 when a

Reference will now be made to electrostatic printing.
F i g. 2 shows an electrostatic printing device according to FIG. 2. 4, which described the present invention. In this the device according to FIG. 3 corresponds to the embodiment according to the invention, no brush magnets are not used mechanically on the plate, but the container 22 is moved past with a 30, but several adjacent mixtures of pigment particles 24 and a soft, mutually arranged electromagnets are used, the magnetizable Material, e.g. B. iron filings 26, 25 are turned on one after the other. A simple filled. The iron filings are larger in diameter. Such an arrangement uses a magnet 48 (FIG. 4), which is present in the screen template 28 and which has the shape of the field openings. The conductive back plate 30 is in a structure of an electric motor. This magnet 48 is arranged at a distance from the screen template. One has a yoke 48 A and several poles 48 B, the voltage source 32 creates an electrostatic field 3 ° from the yoke to the conductive screen stencil between the plate 30 and the screen stencil 28. stretch. The yoke and the poles consist of several of the only partially shown Gereren lamellae of suitable material to be printed and object 34 has been pulled out in order to show the pattern the same dimensions as the conductive plate 30. 28 α . A magnet 36 is placed along the plate.

30 moved back and forth, around the iron filings against 35 separate windings 50 A to 50 E wound. One of the screen stencils and in particular the pattern 28 α end of each independent winding is to be lifted with one. In the illustration, the terminal of the voltage source 52 is connected from the container side. The one part that has been broken out to show the other end of each winding is to show a special way of using the iron filings. The Eisenfeil contact clamp 54/4 to 54 E connected. A chip 26 is lifted by the force of attraction of the magnet 40 contact slide 56 is connected to the other clamp 36, the pigment powder being connected to the voltage source 52. The movement of the openings in the pattern 28 'of the slide 56 from contact 54 ^ 4 to contact 54 E is pressed. The pigment powder gets into the electro- switched one after the other by the windings and static field and is consequently transferred to the counter- the magnet 48 successive stand 34, on which the pattern simulated 45 magnets one. As a result, those are supposed to be evaluated. container 22 located, with the powder particles

The conductive plate 30 consists of a material, mixed magnetic particles drawn to the screen template that does not form a magnetic shield. As and take with them the powder particles that pass through Material such as aluminum can be used for the openings in the screen template. 50 must be pushed through. The one shown in FIG

The reciprocating movement of the magnet 36 device achieves essentially the same results the plate 30, the magnetic particles results as in FIG. 3 device shown, lifted from the leading pole and the magnets in FIG. 3 generated magnevon repelled the following pole, so that the table field is weaker than that by the Powder mixture is shaken in an advantageous manner 55 electromagnets produced in Fig. 4 individual and the clumps and clumps of magnetic fields. With the in F i g. 4 shown loosen and new powder reaches the sieve template 28. However, the device will still be an adequate one The powder flow is very smooth. The magnetic attraction and shaking effect achieved so that the Particles move from the leading pole to magnetic particles in the successive one Sieve stencil is lifted and a short distance 60 is magnetized by these electromagnets a new one shifted along this. As a result of the friction of the powder charge to the screen stencil can promote to Particles on the stencil remain the particles to work completely satisfactorily, until the trailing pole of the magnet is aimed.

opposite this particle lies, which then from this For reasons of simplification it can be desired

Pole are repelled and be returned to the container, the container with the conductive screen above fall. The leading pole always lifts new ones to arrange the backplate. Such an arrangement material so that the gap on the screen template is shown in FIG. A better hold on the shake Mass is constantly replenished. effect of the magnetic particles in the powder

is achieved when the magnetic particles in the pigment powder mass are drawn up and towards and away from the stencil to which the particles have been drawn by the magnet 60. The magnet 60 is reciprocated on the opposite side of the conductive plate 30 in the same manner as that for the magnet 36 in FIG. 2 has been described. Two magnets 62 and 64 used in connection with the magnet 60, which are separated by a non-magnetic web 66, lift the magnetic material from the screen template located at the bottom of the container 22 before and after the magnetic material generated by the magnet 60 is removed from them one magnet is on one side of the container and the other magnet is on the side of the conductive plate. The magnet on the side of the plate 30 can, if necessary, be connected to a voltage source whose voltage is higher than the voltage of the current source 74, so that a stronger current flows through the winding and consequently a stronger field than that produced by the magnet 70 is produced Field.

An arrangement of this type is shown in FIG. 7 shown. The magnet 70 creates a weak field that the Magnetic particles present in the container 22 are attracted to the top of the container. When printing the switch 70 is closed, so that a Spani kl 8 l Di

g g g g p

Field these particles down to the screen ^{template 1} S voltage source 78 is placed on a winding 80. the

Wikl 8 fid ih f i 8

pulled. The magnets 62 and 64 are much weaker than the magnet 60, because the magnets 62 and 64 are closer to the magnetic particles than the magnet 60. The fields formed by the magnets 62 and 64 should also be kept so weak that they the desired effects of the field generated by magnet 60 do not overtake. The distance of the magnet 62 from the magnet 64 and the strength of these magnets is chosen so that the magnet 60, despite the presence of the magnets 62 ^a 5 and 64, pulls the magnetic particles safely down against the screen template.

Instead of two magnets 62,64 that run in synchronism be moved with the magnet 60 (FIG. 5), k b h ii M

gq g gg

Winding 80 is located on a magnet 82 of the type shown in FIG. 4 illustrated type. A strong current flows through the winding 80, so that a strong magnetic field is generated, the fast Causes acceleration of the magnetic particles present in the container 22 to the screen template, the powder particles carried by the magnetic particles through those in the screen template Openings in the existing between the screen stencil and the plate 30 electrostatic Field to be bumped. If switch 75 is opened when switch 76 is closed, and vice versa, then the magnetic fields are generated alternately. This increases the amount of electricity E d Mf

g (g) g, g g

but a single magnet 70 can also be used 3 ° reduced to generate the magnetic field when which is similar to solenoid 48 and requires printing.

ki Figs. 8 and 9 show a front view and a front view, respectively.

a side view of an electrostatic printing pre

direction in which the magnetic particles move quickly

which has a winding72 between two pole pieces wrapped around the yoke of the magnet. A current source 74 is connected to the winding 72.

The electromagnet 70 is kept so weak that 35 are advanced to the screen stencil to through the magnet 60, on the opposite side, the uncovered openings of the screen template Pigder conductive plate 30 is reciprocated, l i lkih ld

the effect of the magnetic field of the electro-0 i T

magnet 70 overcomes and the magnetic Teilh di i T h 2

g g

to bring ment powder into the electrostatic field, whereupon the magnetic particles are magnetically released

g of the sieve template can be moved away. A container

against the front in the lower part of the container 22 90 has a front wall 92, which is a template for existing screen template pulls. This magnetic example contains the letter "A". the

Back plate 94 is spaced from the template. The object 95 on which the imprint will be made d k

Particles are then made by the action of the weak magnetic generated by the electromagnet 70 Field withdrawn into the powder mass. Ghfll i Shl 5 R

G
is between the front wall 92 and the back plate 94

gg p

If desired, a switch 75 can be inserted in series with 45. A voltage source 96 generates a of the power source 74 and the winding 72, an electrostatic field is connected between the front wall 92 before a reciprocating movement of the and the back plate 94.

Magnet 60 is opened and closed to Several electromagnets 98, 100, 102 are close

while being pressed by the field of the meander so arranged that the container between gneten a maximum tensile effect on the pole faces of the magnets in the container 5o. Everyone who is electrical exercise magnetic particles. magnet has a winding, e.g. B. winding 104

i H (Fig. 8). The winding has two terminals 106 resp.

K d i K

The magnet 60 works in its reciprocating motion; i.e., a magnetic field is generated sequentially moved over the screen stencil in order to successively move the magnetic particles to the screen stencil pull so that the powder particles pass through the screen stencil into the electrostatic field be pressed. But it is also possible to have an immediately existing magnetic field over the entire Surface of the sieve template. If this magnetic field is generated quickly due to the sudden acceleration of the magnetic particles through a larger amount of powder pushed through the openings of the screen template. Also, contrary to what is described successive printing a simultaneous printing over the entire sample area. Two magnets are used for this purpose,

(g) g

108. All of the terminals 106 are connected to one terminal of the voltage source 110. The selector switch 112 connects one of the terminals 108 one after the other to the voltage source 110. If the Selector switch 112 rapidly from right to left as seen in FIG. 9, moved, then the magnets 98, 100 and 102 turned on one after the other, so that the magnetic particles one after the other to the front wall 92 are drawn and applied to the. Front wall 92, the powder particles through the in The openings located on the stencil are introduced into the electrostatic field and then onto the Item 95 are placed on which the letter "A" is to be printed. When turning back With the selector switch to its "off" position, the magnetic particles are removed from the front wall 92

withdrawn, shaking the powder particles so that a large amount of powder between the Front wall 92 and where the magnetic particles are located.

With several devices according to FIG. 8 and 9, a printing device can be made which has 90 different letter openings in the front wall 92 of each container. The one to be printed Letter is selected and is then selected by pressing the associated selector switch 112 printed.

Thus, a novel and improved electrostatic printing device has been created in which the Transport of the powder particles through the conductive screen template into the electrostatic field is effected in a magnetic manner.

Claims (4)

Patent claims: 1. Device for electrostatic printing of flat objects, consisting of a Container filled with colored powder, with an electrically conductive screen printing stencil on one of its outer surfaces carries, which is also connected to an opposing plate via a power source Generating an electrostatic field between the screen printing stencil and the plate is connected, characterized in that a plurality of magnetizable carrier particles in the colored powder is included, which are larger than the mesh opening of the screen printing stencil (28), and that a along the plate (30) acting magnet (36) to attract the carrier particles in the direction is provided on the screen printing stencil (28). 2. Device according to claim 1, characterized in that the magnet (36.40 Λ-F, 60) is movable parallel to the plane formed by the conductive screen printing stencil (28). 3. Apparatus according to claim 1, characterized in that a second magnet (62,64) the side of the container (22) opposite to the first magnet (60) is arranged and a second, weaker magnetic field than the first. 4. Apparatus according to claim 3, characterized by a switch device (75, 76), which permits the selective energization of the first and second magnets. 1 sheet of drawings 909 517/68