DE2549189B2 - Copy table for electrostatically holding a large number of sheets of paper lying on top of one another - Google Patents

Description

The invention relates to an ICopier table described in the preamble of claim 1, known from US-PS 33 59 469 type.

With the known copier table, di; s Charge applicator charges of the same name are applied to the foils, which are opposite to that of the Generator applied to the plate are DC charge. Get on repeated charge but finally so much charges on the front surface of the copy plate that its surface has ground potential assumes d. H. the DC voltage on the lower side of the generator. As a result, the copy films do not adhere during subsequent fastening processes. This means that essentially all of the DC voltage is applied to the insulating plate of the copy table while there is practically no voltage applied to the foils.

To remedy this deficiency, the mentioned US-PS separated the DC voltage supplied to the rear surface of the insulating plate from the generator and the back surface connected to ground. By switching the previously generated by the generator to the The high voltage applied to the back surface at ground potential reduces the surface of the insulating plate as a result the polarity on the insulating material that is opposite to the original polarity. As a result, the foils Adhere again to the surface of the insulating plate when new charges are applied with the charge applicator the outer surfaces of the foils are applied with polarity opposite to that originally applied Area additional measures are taken to hold the foils until they no longer turn be liable. If the foils no longer adhere to the copier table lying on ground s, the high DC voltage is applied again according to the above-mentioned US Pat by connecting the high voltage side of the generator to the insulating plate and the process through Switching of the operating modes is repeated.

ίο When applying multiple layers of foils on the surface of the insulating plate, if so several Negatives are laminated one on top of the other on a photosensitive layer, essentially the equal conditions. That is, after a

If the number of layers has been applied, the Charge applicator applied enough charges that the top surface of the top sheet is applied Ground potential is and the next film no longer adheres. When attaching multiple copies, it is but difficult to determine the switching because of the amount of charge applied during each attachment from the polarizing and dielectric Properties not only of the material of the insulating plate itself but also of the foils to be attached For example, if the switch is delayed for so long, it is possible that some foils will not charge enough to properly attach until too many layers are applied. On the other hand, if the switchover is carried out too early, so not enough charges accumulate in the

Copy plate and on the already applied Layers to get sufficient after switching To achieve attachment of additional layers. The in the characterizing part of claim 1

The invention described is therefore based on the object of designing the copier table of the generic type in such a way that any number of foils can be used safely can be held on top of each other, With the Kop.enisch according to the invention arises on

-to the individual foils an arbitrary charge distribution, which enables an effective electrostatic attachment multiple slides guaranteed. This also increases the strength of the acting on the operator Reduced impacts if this touches the foils directly.

-ν, Furthermore, due to the random distribution of the positive and negative charges, the electrostatic sparks occurring between the foils and / or the surface holding the foils are reduced when the foils are removed from the copying table;

vi thereby preventing infoige on photosensitive Fiimen electrostatic discharges fog occur.

On the copy table according to the invention, photosensitive foils, laminated films, sheets or

v <the like can be held securely.

Preferred developments and refinements of the copying table according to the invention are the subject matter of claims 2 to 4. Based on the execution shown in the drawing

w) approximately example the invention is explained in more detail, It shows

F i g. 1 is a perspective and partially schematic view of a partially broken away copying table; F i g. 2A, 2B and 2C are cross sections to explain the

*> ■ "> Basics of the invention and those resulting from the application of the various layers Charge distribution. Fig. I shows an electrostatic copy table

Holding a photosensitive film P and at least one negative film N. Both are attached to one another on the copying table before the photosensitive film is exposed by means of light rays passing through each of the negatives. The copier table contains an insulating plate A, a high DC voltage generator B and a charge applicator C connected to a terminal of the high voltage generator, which can be guided over the outer surfaces of the photosensitive film P and each negative N when these are successively placed on the front surface of the insulating plate , and an automatic switch D, through the closing and opening of which alternately the potential of one or the other output terminal of the direct current generator B reaches the rear surface of the insulating plate

The copying table can be constructed in different ways, for example according to US-PS 33 59 469, 34 48 356, 34 73 097 and 35 49 963. For example, the insulating plate A can consist of transparent Ghs if exposure is to be carried out from below; in this case a row of lamps 12 is arranged in a cabinet 14. The entire lower surface 16 of the insulating plate A is then coated with an electrically conductive film; For example, a layer of gold, silver, copper or the like is vapor-deposited on the lower surface 16. This forms a transparent electrode 18, the thickness of which is in the range of the wavelength of the light. In the embodiment described above, first the negative (s) N and finally the light-sensitive film P are placed on the upper surface 20 of the insulating plate. If the exposure is from above, the lamp or lamps 12 are located above the copying table; the insulating plate A then consists of a suitable opaque dielectric, for example phenolic resin, and the electrode 18 consists of a copper plate.

In any case, the electrode 18 is connected to the DC voltage generator B via a line 21 and a current limiting resistor 22, with which positive or negative DC voltages between approximately 1.5 and 25 kV can be fed to the surface 16 of the insulating plate A. The DC voltage generator B consists of a known electrostatic DC voltage source, which is shown in FIG. 1 is shown in block form. The DC voltage generator B generates an output voltage which is negative with respect to ground at a resistor 24 when the switch 26 located in the control panel is closed. The output voltage of the generator can be changed within the control range by means of a regulating transformer 28, which is also located on the control panel.

The charge applicator C can also be constructed in different forms, for example from a roller, brush or a wiper, which can be moved over the copier table and rest against the surface 20 of the insulating plate A or the film already placed on it . The charge applicator is connected to the second terminal of the DC voltage generator B , which can be connected to ground. The charge applicator C can also consist of a direct or alternating current ionizer, not shown, which does not need to touch the foils P or N , but in which a conductive connection is formed by the ions emitted by the ionizing devices (see e.g. US Pat 469 or 38 44 657).

An essential feature of the invention can be seen in the automatic switch D , which contains break contacts 32 located on the low voltage side. These are controlled by means of a cam 34 driven by a synchronous motor 36 in such a way that the DC voltage generator B is regularly and periodically switched on and off. It has been found that an optimal fastening effect occurs when for about ¹ U to 5 seconds at a time

ίο a connection to the DC voltage output is established; this matches the speed at which the charge applicator C is normally passed by an operator over the outer surfaces of the copies. The period for each switchover is preferably approximately 1 second. The cam 34 is designed so that it closes the breaker contacts 32 during half of its rotation and opens during the other half of its rotation. The synchronous motor 36 running at a speed of 30 rpm drives the cam 34 such that the breaker contacts 32 during every- Cycle closed for 1 second and held open for 1 additional second. When the interrupter coruacts are open, the copier table is automatically connected to ground via the current limiting resistor 22 and the load resistor 24.

In the following, the function of the copy table will be explained with reference to FIG. 2 explained in more detail at opposite mass negative output voltage of the equal voltage

: o generator B is supplied with a negative voltage during the closing time of conicals 32 of electrode 18. Negative film N is placed on surface 20 of insulating plate A , while charge applicator C as shown in FIG. 2A left to right across

j:> the outer surface of the film N is pulled, it is positively charged. If, on the other hand, the interrupter contacts 32 are open, then the electrode 18 of the insulating plate A is at ground potential, and no charge is applied to the vegativfolic / V

To close the contacts 32 and with a further wiping movement of the charge applicator C over the outer surface of the film N, a negative voltage is again supplied to the electrode 18, so that positive charges are applied to the corresponding zone of the negative film N

• h are applied. In the zone furthest to the right in FIG. 2A, ground potential is applied to the insulating plate A because of the again closed interrupter contacts 32, so that no charge is placed on the part of the negative film N above it

ι »is applied.

In the following description it is assumed that a maximum charge transfer from the charge applicator J; always takes place when it touches a film N or P. Furthermore, the foils N and P are ideal

Yi insulators from which no charges can escape. Under these idealized conditions, according to the laws of influence, the positive and negative charges applied in each zone always have the same size, so that the sum of all charges on

no of all foils lying on top of one another is always zero

In FIG. 2B, a second negative film N is applied to the first negative film N, which is in contact with the copying table, over the outer surface of the charge ap

t) "> Multiplier C is pulled. The second negative layer N, while the charge applicator C is connected to ground potential, negatively charged in the touched by him zones where the underlying Negativfo-

let N have a positive charge. The second negative layer N is not charged in those areas which the charge applicator C touches during the opening time of the contacts and in which the negative film N underneath is not charged. When the switch D is switched on, the second layer is charged in the areas touched by the charge applicator C if the negative film / V underneath is not charged, and not charged if the negative film N underneath is positively charged.

2C, in which a photosensitive film P is placed on the laminate of two negatives already attached to the surface 20 of the insulating plate A , shows the charge distribution in the three layers. When the switch D of the charge applicator C brings positive charges on the third layer (sheet P), namely in those of her touched areas in which one of the underlying negative films N positi / and the other is negatively charged, or where no both negative foils N is charged. In those areas in which one of the films below is positive but the other is not charged, no charges are applied.

When the switch D is switched off, the charge applicator C applies negative charges to the third layer P in those areas in which one of the films underneath is positively charged and the other is not charged. However, no charges are applied if both of the underlying foils N are not charged or if one of the two foils is positively charged and the other negatively charged. As a result, randomly> positive and negative charge areas are formed in the various layers, with the charge applicator C randomly or accidentally touching different parts of the successive layers when the switch D is switched off or on.

The above description assumes ideal relationships in advance. In practice, however, it is the contact of the charge applicator C with the various surfaces at best incomplete and variable; in addition, the insulating properties of the foils are often not good

'> ideal and differ from each other. In practice different charge levels are therefore applied and maintained so that the successive Layers show a pattern of positive and negative charges that are not ideal

As a result, there are deviations from the degiziisand in terms of size and sometimes also polarity. This deviation from the ideal state increases the charge distribution in the various layers N and Pin

- '"> accidental or arbitrary. This phenomenon contributes to the desired effect in that several copy layers on one another and on the surface 20 of the Copies adhere and are effectively and approximately evenly attached.

1 sheet of drawings

Claims (4)

Claims; 1. Copying table for electrostatically holding a multitude of foils lying on top of one another, with an insulating plate that is electrically conductive on its underside, with a charge applicator that can be moved across a sheet that is on top of the insulating plate or on at least one sheet that is already lying on it , and generating a high voltage DC generator, the output terminals are connectable to the charge applicator or to the conductive bottom of the insulating plate, characterized by a during movement of the Ladungsapplikators (Qqutr over a sheet (N, P), several times through a switching drive (34 36) cyclically operated switch (D), which alternately connects the conductive underside (16) of the insulating plate (A) to one of the output terminals of the direct current generator (iy 2. Kupier table according to claim 1, characterized in that one of the output terminals of the generator (B) is at ground potential and that a charge applicator (C) is connected to the output terminal of the generator (113) at ground potential 3. Copying table according to claim 1 or 2, characterized in that the switching drive consists of one there is a cam (34) driven by an electric motor (36) 4. Kopierti '--h according to claim 3, characterized in that the speed of the * cam is chosen is that each switching interval lasts a quarter of a second to five seconds.