DE102005061332B4 - Device for contactless elimination of an electrostatic charge double layer - Google Patents

Abstract

A device (10; 20) for the non-contact removal of an electrostatic charge double layer from a conveyed planar, electrically substantially insulating material (11; 21), comprising a conductive element (14; 23) arranged adjacent to the material in a first contact region for forming a near-field electric field and contactless compensation means (16-19; 26-29) for supplying charge carriers to the material in the region of the first conductive element for at least partial compensation of the charges at least in a layer plane of the charge double layer, and with the sheet material (11; 21) in FIG a second contact area adjacent second conductive element (13; 24) for forming a near electric field and the second contact area associated field strength measuring means (15; 25) for detecting the field strength of the near field, wherein the compensation means (16-19; 26-29) on the input side with the fieldst connected to the metering device and is designed for the controlled supply of charge carriers to the material in response to the detection result, wherein the compensation means (16-19; 26-29) is adapted to selectively supply positive or negative charge carriers to the field strength measurement device in response to the detection result, wherein the second contact region (24) is located downstream of the first contact region (23) such that control of the charge carrier control acts as a control ; and wherein said compensating means (16-19; 26-29) has a charging electrode (19; 29) connected to a high voltage source (18; 28) opposite said first conductive member with respect to said material and adapted to provide said material with positive or to supply negative charges.

Description

The invention relates to a device for removing an electrostatic charge double layer from a conveyed flat, electrically substantially insulating material. A flat material should be understood as meaning both a quasi-endless web of material and individual sheets, and essentially insulating materials are those which act as an insulator over at least the greater part of their surface, such as printing or packaging papers, plastic films, film-laminated papers, plastic-laminated metal foils or the like.

Charge bilayers are known and feared as electrostatic charging phenomena in various industries, particularly handling high speed insulating materials. By this is meant electrostatic charging of one side of an insulating material combined with opposite polarity electrostatic charging of the opposite side. Charge bilayers often occur on highly insulating, thin and high-speed webs or sheets and often lead to serious and costly process disturbances. They may even result in destruction of the material by spark discharges therethrough.

For eliminating electrostatic charges of conveyed materials of the type mentioned above, contactless discharge electrodes are known and commercially available and have proven useful in many applications; see. at www.eltex.de "FAQs for Discharge / Charging".

These known discharge systems / electrodes utilize the electric field for charge equalization emanating from the charged material to the (neutral) ground by supplying gas ions and free electrons into the electric field. Due to the force effect of the electric field, these are attracted to opposite polarity charges on the charged material and there cause a neutralization (compensation) of the charge. Their efficiency is particularly high at high field strengths. Since, with a constant charge quantity Q in a charging region, the electric field strength E increases in accordance with the relationship E ~ Q / C with decreasing capacity, the known unloading devices are specifically positioned in regions of small capacity of the arrangement, that is for example as far as possible from guide rollers.

The known discharge systems, however, largely fail in the removal of charge bilayers. This is due in large part to the fact that no electric far field emanates from charge bilayers, although large amounts of charge can be stored in them. Namely, the electrostatic field emanating from the positive charges on one side of the material is superimposed by the field of negative sign originating from the negative charges on the other material side.

The publication US 2004/0085705 A1 relates to a method for electrostatic charge neutralization, in which method grooved rolling surface patterns are used. In this connection, the document teaches to use two pairs of electrodes. A pair of electrodes is intended to apply negative charge to a surface of a moving sheet. The other electrode pair brings in the course positive charges on the moving surface element.

The publication EP 0762 810 A1 relates to a charge removal device for a moving surface element, wherein the charge removal device comprises two voltage application elements with discharge electrodes, which are arranged at equal intervals. The state of charge on the sheet is measured at two locations, first upstream of a first state of charge meter, and then downstream of a second state of charge meter.

The invention is therefore an object of the invention to provide an effective and contactless device of the type mentioned above, which in particular in arrangements for rapid transport and for the rapid processing of materials of o. G. Art can be used.

This object is achieved by a device having the features of claim 1. Advantageous developments of the inventive concept are the subject of the dependent claims.

The invention is based on the finding that materials which carry charge double layers, in one-sided contact with an electrically conductive and earthed or grounded surface emanating from the side facing away from this top emanating, measurable electric field (hereinafter also referred to as near field) , The invention includes the essential idea of utilizing this field for at least partial neutralization or compensation of the charge double layer by supplying charge carriers of suitable polarity to the material in its region.

According to the invention, said near field is measured in a measuring step and for controlling a compensation step (at a point spaced from the measuring point). A device according to this embodiment is characterized by a second conductive element adjacent to the sheet material in a second contact region for forming a near-field electric field and a field strength measuring device assigned to the second contact region for detecting the field strength of the near field. In this case, the compensation device is connected on the input side to the field strength measuring device and designed for the controlled supply of charge carriers in response to the detection result.

In this device, the second contact region is arranged downstream of the first contact region such that the control of the supply of the charge carrier acts as a control. Alternatively, but not covered by the patented invention, the second contact region can be arranged upstream of the first contact region, so that therefore the measurement of the near field of the charge double layer takes place before the compensation step. It is then a controlled compensation. The control or regulation is characterized in particular by the fact that the compensation device is designed to selectively supply positive or negative charge carriers in response to the detection result of the field strength measuring device, and optionally to adjust their quantity appropriately.

The proposed solution also makes it possible to easily convey or process charge-critical materials, such as plastic films or paper webs, in high-speed systems.

A preferred embodiment in conventional production systems provides that the first and / or second conductive element is designed as a conductive surface of a drive and / or guide element of a conveyor contacting the material web. Specifically, it is provided here that the first and / or second conductive (especially grounded) element is formed as the surface of a deflection roller.

The compensation device itself has a charging electrode connected to a high voltage source facing the first conductive element with respect to the material and supplying gas ions and free electrons to the material.

Remaining unipolar charges (virtually the uncompensated layer plane of the charge double layer or parts thereof) can be eliminated by a compensating device in the material running direction following conventional discharge device in a conventional manner. Such an unloading device then comprises at least one known as such discharge electrode, as they u. a. is available from the applicant.

Advantages and expediencies of the invention will become apparent from the dependent claims and the following description of two embodiments with reference to FIGS. From these show:

1 a schematic representation of a first embodiment of the invention and

2 a schematic representation of a second embodiment of the invention.

1 shows a schematic diagram of a compensation device 10 to compensate for double charge on one in one direction 12 quickly conveyed material web 11 , The material web is in this embodiment via a first and second guide roller 13 . 14 Z-shaped deflected. The guide rollers 13 . 14 have a good conductive surface which is grounded through a low resistance connection.

At the first guide roller 13 forms due to a on the insulating material 11 trained electrostatic double layer of an electric near field, which by a field strength measuring device 15 is detected. The measuring device 15 is a measuring amplifier 16 downstream, whose output with an input of a control device 17 connected is. The control device 17 wins from the conditioned field strength measurement signal a manipulated variable, the control input of a high voltage power supply unit 18 is supplied.

The generated by this, controlled in response to the field strength measurement signal high voltage is a charging electrode 19 supplied, which, based on the material web 11 , opposite the second guide roller 14 is arranged. That between the charging electrode 19 and the second guide roller 14 formed electric field ionizes gas molecules of the atmosphere and generates and accelerates (depending on polarity and magnitude of the provided high voltage) charge carriers on the material web 11 towards an at least substantial compensation of the charge double layer present there. Any remaining charges on the material web are tolerated in this example, which describes a controlled compensation of the charge double layer.

In 2 is a further embodiment, a further compensation device 20 in one 1 shown in the illustration. Functionally identical or similar components are with 1 designated reference numerals.

An insulating material web 21 here has two guide rollers 23 . 24 in one direction 22 a U-shaped section of a walkway. In this embodiment, with respect to the second conductive deflecting roller 24 a field strength measuring device 25 arranged, the measurement signal in a processing and control device 26 is fed to the output of a manipulated variable for a controllable high voltage power supply 28 provided. This power supply 28 is with a charging electrode acting in the same manner as in the first embodiment 29 opposite the first conductive deflecting roller 23 connected.

In the present embodiment, the loop is that of the web 21 via the charging or compensation electrode 29 supplied charge adjusted so that by the field strength measuring device 25 measured field strength of the near field at the deflection roller 24 Becomes zero. The design of the compensation process as a control thus already gives an improved compensation effect compared to the first embodiment. In addition, downstream of the second guide roller 24 conventional discharge electrodes 31 , each with associated power supply 32 to eliminate any remaining unipolar charges on the two surfaces of the web 21 intended.

The embodiment of the invention is not limited to the examples described above, but also in a variety of modifications are possible, which are within the scope of technical action. In particular, combinations of the various aspects of the dependent claims, in any combination with one another, are to be included within the scope of the invention.

Claims (5)

Contraption ( 10 ; 20 ) for the contactless removal of an electrostatic charge double layer from a conveyed flat, electrically substantially insulating material ( 11 ; 21 ), with a conductive element disposed adjacent to the material in a first contact region (US Pat. 14 ; 23 ) for forming a near-field electric field and a contactless compensation device ( 16 - 19 ; 26 - 29 ) for supplying charge carriers to the material in the region of the first conductive element for at least partial compensation of the charges at least in a layer plane of the charge double layer, and with a flat material ( 11 ; 21 ) in a second contact region adjacent second conductive element ( 13 ; 24 ) for forming an electric near field and a field strength measuring device assigned to the second contact area ( 15 ; 25 ) for detecting the field strength of the near field, wherein the compensation device ( 16 - 19 ; 26 - 29 ) is connected on the input side to the field strength measuring device and is designed for the controlled supply of charge carriers to the material in response to the detection result, the compensation device ( 16 - 19 ; 26 - 29 ) is adapted to selectively supply positive or negative charge carriers to the field strength measuring device in response to the detection result, wherein the second contact region ( 24 ) downstream of the first contact area ( 23 ) is arranged such that the control of the supply of the charge carrier acts as a control; and wherein the compensation device ( 16 - 19 ; 26 - 29 ) one with a high voltage source ( 18 ; 28 ) connected charging electrode ( 19 ; 29 ) which faces the first conductive element with respect to the material and is adapted to supply positive or negative charges to the material. Device according to claim 1, wherein the first and / or second conductive element ( 13 . 14 ; 23 . 24 ) is formed as a conductive surface of the material web contacting drive and / or guide element of a conveyor. Apparatus according to claim 2, wherein the first and / or second conductive element as a surface of a deflection roller ( 13 . 14 ; 23 . 24 ) is trained. Device according to one of the preceding claims, wherein the first and / or second conductive element is grounded. Device according to one of the preceding claims, wherein downstream of the compensation device ( 26 - 29 ) an unloading device ( 31 . 32 ) for removing remaining unipolar charges from the material ( 21 ) is provided.

Images