DE10211429C1 - Ionization device to compensate for electrostatic charging in paper and textiles has direct current source inverter and multiplier to feed electrode system - Google Patents

Abstract

An ionization device to at least partly compensate for electrostatic charging comprises a multi-kilovolt high-voltage source fed from a dc source via an inverter (2) and multiplier circuit (3) to produce a bipolar dc voltage which is fed (10,11) to the arrangement of electrodes.

Description

The invention relates to an ionization device for at least partial compensation for electrostatic charge gen, with a high voltage source, the output side for example, delivers several kilovolts of high voltage and connected to one or more electrode arrangements is.

Ionization devices serve as discharge systems for the La compensation of electrostatic charges, for example Papers, foils, textiles and other materials at Her position and processing can occur.

The high available at the ionization device voltage balances the charge in the immediate vicinity. An application example for such ionization devices are Sheetfed offset presses.

Ionization devices are known as prior art, at an alternating high voltage on the one hand to the electrodes arrangement with one or more electrodes and on the other Mass, for example a machine frame or the like  chen is connected. The AC voltage is, for example 5 kV to 10 kV. This high voltage is usually associated with a high-voltage transformer from the AC mains voltage generated.

The disadvantage here is that - due to, for example, si nus-shaped course of the AC voltage - at the zero crossing no ions are produced and therefore no constant ions production rate is present. Also kick in the Zulei cable to the electrode arrangement reactive power losses on.

Due to these reactive power losses within the usual several meters long supply cable must be used High voltage transformer has a corresponding output performance are available to compensate for these losses Ren. Such a high voltage transformer is comparative wise expensive. In addition, when using a high chip on the primary side also a protective circuit is required in the event of a secondary short circuit responds. This causes additional costs.

Because of the cable-side electromagnetic radiation With such ionization devices, EMC aspects are also intensified (electromagnetic compatibility).

From DE 29 02 425 A1 is one with AC voltage working ionization device known. There is one Phase shift between a first and a second Electrification element provided so that compared to the The aforementioned ionization devices a little there is more uniform ion production rate that However, the disadvantages described above are also present here. The same applies to the device of US Pat. No. 3,711,743 shaped, oscillating voltage pulses works and thus also with AC voltage.  

From US 4,423,461 a device for corona Pretreatment of materials known to use an AC voltage delivering power supply unit with a Has high voltage transformer. With this device can target the surface of the material being treated attacked, for example, better To achieve color adhesion properties. To get rid of This device is not electrostatic charges intended.

CH 345 698 describes an apparatus for derivation electrostatic charges. It will be vibrant High voltage worked, so an AC voltage to their Generation of a high voltage transformer is provided. Also here the disadvantages described above are present.

An ionization device is also known, the one Has power supply device, at the output equal voltage pending. This is a high voltage transformer used, at the high-voltage output a high-voltage Rectifier circuit is connected. This ionisati too ons device causes comparatively high costs. Finally, one knows from US 5 930 105 Ionization device that has a bipolar DC voltage supplies. Two inverters are used for this, the a high-voltage transformer on the output side exhibit. This means a comparatively high effort.

The object of the present invention is to provide an ionization direction of the type mentioned above to create the cost is favorable, a practically constant ion production rate points and connectable to a compact electrode arrangement is.  

To solve this problem, the invention suggested that the high voltage source be a power supplier has a supply device that to a DC voltage closed inverter for generating an alternating high voltage has and that to the inverter a multiplier circuit for Rectification, voltage multiplication and generation a bipolar DC voltage is connected to the output is connected on the side to the electrode arrangement.

One equipped with such a power supply device Ionizer has one with a high chip voltage transformer equipped a significant cost part. The one provided for the electrode assembly High DC voltage results in a largely constant ion pro production.

In the ionization device according to the invention, using of the inverter into a DC input voltage into an AC Formed tension. A downstream multiplier stage then acts that this AC output voltage of the inverter raised to the necessary high voltage, rectified and a bipolar DC voltage is generated. Then it is on Output a bipolar DC voltage with single voltages of for example some kV available.

In this ionization device, the secondary side can gear current can be kept much smaller because of the the  Supply lines to the electrode arrangement no longer exist reactive power losses. One exit is sufficient current, which is only about 1/5 of the previously required Output current is. Accordingly, the power supply can be direction to be smaller and more compact. In addition, the DC voltage is not an electromagnetic one Radiation available.

In order to improve the constancy of the ion production even more the multiplier circuit for generating related to ground unequal (asymmetrical) individual voltages are designed, especially to generate a versus negative one individual positive higher voltage.

With the output DC voltage asymmetrical to the zero potential generates a negative voltage that is less than that positive tension. This will result in the same single voltages greater ion production at the negative peak com pens, resulting in an equal ion production rate on both types of electrodes of the electrode arrangement.

In connection with that of the electricity supplier according to the invention supply device generated, bipolar DC high voltage the use is preferably asymmetrical single voltages one connected to the output of the multiplier circuit Electrode arrangement with electrodes for a positive potential and counter electrodes for a negative potential partial because this makes both a particularly effective levy of negative as well as positive ions when using a bipolar DC voltage is possible.

For example, a comb-like electrode arrangement with at least a series of electro spaced apart the and counter electrodes each between adjacent electrical the, preferably approximately in the middle between adjacent electrodes, is particularly advantageous for this.  

Additional embodiments of the invention are in the others Subclaims listed. The invention is as follows of embodiments with reference to the drawings explained here.

Show it:

Fig. Onsvorrichtung 1 is a block diagram of an ionisation according to the invention,

Fig. 2 is a partially sectional side view ei ner bipolar electrode assembly for direct voltage,

Fig. 3 is an end view and

FIG. 4 is a top view of the electrode arrangement shown in FIG. 2.

A block diagram shown in FIG. 1 shows the construction of a high voltage source with a power supply device 1 as part of an ionization device according to the invention. This power supply device 1 is used to generate a bipolar DC voltage of a few kilovolts.

Essentially, the power supply device 1 has an inverter 2 and a multiplier circuit 3 connected downstream thereof.

To the inverter 2 a higher AC voltage is generated from a DC voltage, and the multiplier circuit 3 is used for voltage multiplication, for rectifying and for the generation supply of the bipolar DC voltage that is the supplied to the Fig. 2 to 4 shown electrode assembly 12.

The inverter 2 , which can include an LC oscillator with a converter transformer, is preceded by a voltage regulator 4 , which ensures that the inverter 2 is supplied with a stabilized DC voltage. The input voltage of, for example, 24 volts DC voltage is supplied to the voltage regulator 4 via an input filter 5 and a relay switch 6 .

The input filter 5 is used on the one hand to buffer the input voltage and thus any high-frequency interference is filtered.

With the help of the relay switch 6 , a fault message can be output by the function block 7 when the output voltage of the inverter drops to a certain threshold value, for example 15 V, due to short circuit, overcurrent or overtemperature. The function block 8 for overcurrent detection is connected on the aisle side to the inverter and, on the other hand, for control with the relay switchover 6 .

The inverter 2 supplies an AC voltage on the output side, which is connected to the multiplier circuit 3, which is formed as a double multiplier to generate a bipolar DC voltage. The multiplier circuit 3 is used to generate two individual voltages based on ground, namely a ne negative and a positive individual voltage. A special feature is that the individual voltages are unequal in relation to ground, whereby the positive individual voltage can be +6 kV and the negative individual voltage can be -4.5 kV. It is thereby achieved that the electrodes connected to the positive potential and the counter electrodes connected to the negative potential of an electrode arrangement have approximately the same ion production rates.

The multiplier circuit 3 is designed for both the positive and for the negative branch in a multi-cascade fashion, in particular as a Greinacher circuit. The number of cascades of the multiplier circuit 3 for the positive single voltage is greater than the number of cascades for the negative single voltage. Practical tests have shown that the different number of cascades for the individual voltages is appropriately dimensioned in such a way that the positive individual voltage is about 20 to 40 percent higher.

At the high-voltage output of the multiplier circuit 3 , a current limit 9 is also provided, which has in series or parallel to the output terminals of the high-voltage output, high-impedance resistors. In addition to the current limitation, these also serve as discharge resistors for the capacitors of the multiplier circuit 3 .

The inverter 2 has a converter transformer operating, for example, with an inverter frequency of 40 kHz. Since no ground is required as counter potential for the operation of the ionization, the secondary circuit of this converter transformer normally remains floating and is connected to ground via a resistor. Only when the differential voltage across this resistor exceeds about 90 V, for example, does a surge arrester connected in parallel with this resistor ignite and ground this line. This serves to protect the converter transformer, since it would otherwise be raised to an impermissibly high potential.

In the connecting line between inverter 2 and voltage multiplier circuit. 3, a current flow display device, not shown here, can be provided, in particular in the form of two light-emitting diodes connected in parallel. The light intensity of these LEDs is a measure of the load current.

The bipolar electrode arrangement 12 shown in FIGS. 2 to 4 can be connected to the output terminals 10 and 11 of the power supply device 1 .

This electrode arrangement 12 has because of the bipolar output DC voltage from the power supply device 1 both electrodes 13 for a positive potential and counter-electrodes 14 for a negative potential.

As can be seen well in FIG. 4, a straight row in the exemplary embodiment of side by side spaced apart Elect roden 13 are provided, are in each case arranged approximately centrally counter electrodes 14 between adjacent electrodes 13. The individual electrodes 13 , 14 are each part of a base part 15 in the form of an elongated conductor. As can be seen in FIG. 2, the electrodes 13 , 14 have tips 13 a, 14 a. The electrode tips 13 a, 14 a are arranged approximately in line with each other and connected to the strip-shaped, laterally spaced base parts 15 via bends 16 . Overall, the strip-shaped base part 15 , the associated electrodes 13 , 14 and the bends 16 are made in one piece from a cross-section approximately Z-shaped sheet metal part, as can be seen well in FIG. 3.

The electrode arrangement 12 has a carrier part 17 made of electrically insulating material for receiving the electrode parts. Overall, the electrode support part 17 is formed in the form of a rod and, as can be seen in FIG. 3, has a slot-like opening 18 running in the longitudinal direction, in which the electrodes 13 and the counter electrodes 14 with their associated parts are each arranged. The carrier part 17 has half of the opening 18 a longitudinal support projection 19 for the electrode tips 13 a, 14 a. Slits 20 are provided on both sides of the support projection 19 , which is approximately rectangular in cross section. The sheet metal parts of the electrode arrangement which are approximately Z-shaped in cross section are arranged on the side flanks and on the outside 21 of the support projection 19 and each engage with one of the two slots 20 with their strip-shaped base parts 15 .

In Fig. 3 it can still be clearly seen that the carrier part 17 we at least has a longitudinal gas channel 22 , which is arranged here within the support projection 19 . In Fig. 3 and 4 are connected to this gas channel 22 and adjacent to the electrode tips 13 a, 14 a which open outflow channels 23 of clearly. The mouths 24 are arranged on both sides near the respective electrode tip 13 a, 14 a. The blow-out direction can also be directed obliquely against the electrode tips. The range of action of the discharge device is increased by the support, preferably by air.

The electrode parts are expediently cast into the insulating material 25 except for the electrode tips 13 a, 14 a within the electrode support part 17 .

The base part 15, which is designed as a sheet metal strip, is connected to the series of high-voltage connecting cables with the output terminals 10 and 11 of the power supply device 1 for supplying the bipolar DC voltage. The electrode arrangement 12 shown in FIGS. 2 to 4 is matched with its bi-polar electrode arrangement to the power supply device shown in FIG. 1. This provides a suitable, bipolar DC voltage, which is applied to the DC voltage electrode of the electrode arrangement 12 .

For the electrical function it is in this constellation not necessary to bring up a separate mass. The Elect The tiller assembly can be attached electrically insulated.

Claims (11)

1. Ionization device for at least partial compensation of electrostatic charges, with a high-voltage source that supplies, for example, several kilovolts of high voltage on the output side and is connected to one or more electrode arrangements, characterized in that the high-voltage source has a power supply device ( 1 ) that a printer connected to a DC voltage inverter (2) for He generating an AC high voltage, and in that a multiplier circuit (3) processing the In verter (2) for rectifying, is connected to the voltage multiplier and for generating a bipolar DC voltage output side is connected to the electrode arrangement ( 12 ). 2. Ionization device according to claim 1, characterized in that the multiplier circuit ( 3 ) is designed for the generation of unequal (unsymmetrical) individual voltages based on ground, in particular for generating a positive individual voltage which is higher than the negative individual voltage. That a mehrkaskadige multiplier circuit (3), in particular a Greinacher circuit is provided 3. ionization apparatus according to claim 1 or 2, characterized in that a multiplier circuit (3). 4. Ionization device according to claim 3, characterized in that the number of cascades of the multiplier circuit ( 3 ) for the positive single voltage is greater than the number of cascades for the negative single voltage and in particular for a by about 20% to about 40% higher positive single voltage is dimensioned. 5. Ionization device according to one of claims 1 to 4, characterized in that an error detection and before preferably an error protection circuit for overtemperature and / or for short circuit and / or for overcurrent of the output circle and / or for incorrect polarity of the input voltage are provided. 6. Ionization device according to one of claims 1 to 5, characterized in that in a connecting line between the inverter ( 2 ) and multiplier circuit ( 3 ), a current flow display device is connected, in particular two antiparallel connected light-emitting diodes. 7. Ionization device according to one of claims 1 to 6, characterized in that the electrode arrangement ( 12 ) connected to the output of the multiplier circuit ( 3 ) has at least one electrode ( 13 ) for a positive potential and at least one counter electrode ( 14 ). for a negative potential. 8. Ionization device according to claim 7, characterized in that the electrode arrangement ( 12 ) has at least one row of spaced apart electrodes ( 13 ) and that counter-electrodes ( 14 ) each between adjacent electrodes ( 13 ), preferably approximately in the middle between adjacent electrodes ( 13 ) are arranged. 9. Ionization device according to claim 7 or 8, characterized in that the electrode arrangement ( 12 ) has a Trä gerteil ( 17 ) made of electrically insulating material for receiving the electrodes ( 13 , 14 ) and the like. 10. Ionization device according to claim 9, characterized in that the carrier part ( 17 ) has at least one longitudinal gas channel ( 22 ), which is preferably arranged within a support projection ( 19 ) and at or between the preferably as electrode tips ( 13th a, 14 a) formed electrodes ( 13 , 14 ) opening outflow channels ( 23 ). 11. Ionization device according to claim 10, characterized in that the mouths of the outflow channels are arranged on both sides near the electrode tips ( 13 a, 14 a) and that the blow-out direction of the outflow channels ( 23 ) is preferably obliquely against the electrode tips ( 13 a, 14 a) is directed.