DE1797213A1 - Method for electrically charging a chargeable device - Google Patents

Description

Method for electrical charging can be charged Facility

The invention relates to a method of electrical charging a rechargeable device with the help of a corona source and an ICorona charging device for performing the method .

Today, corona charging processes are used almost exclusively to sensitize electrophotographic recording surfaces used. A large ion flux is generated by the corona discharge of a wire or wire, hereinafter referred to as a corona wire Wire row electrode generated near the electrophotographic Aufzsichnuz \ ga surface arranged on a high 'Potential is held. The oo generated by the corona wire Ions cause the electrophotographic recording surface to be charged and sensitize them for a subsequent

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Exposure or similar imaging of an electrophotographic process. In addition to the ions, the corona wire also generates electronic radiation, some of which is visible. Although the intensity of the electromagnetic radiation appears only small to the human eye, the main emission occurs in the ultraviolet spectral range, which lies outside of visible light. Since the sensitivity of electrophotographic selenium plates in the ultraviolet spectral range is quite high, even a relatively weak electromagnetic radiation from the corona discharge tends to discharge the plate again. It has been found that the electromagnetic radiation emitted by the corona wire is not insignificant and may be sufficiently strong to reduce the effectiveness of the corona charging of the plate. As a result of the discharge caused by electromagnetic radiation, the charging efficiency is reduced by approximately 10 f> in the case of positive corona charging. This 10 # can also be exceeded if special photosensitive combinations are used that are more sensitive than selenium. The electromagnetic radiation from a negative corona discharge is approximately five times stronger than the radiation from a positive discharge under similar conditions. The disadvantageous effect of the electromagnetic radiation of a negative corona discharge on similarly sensitive photoconductors must therefore be considered more strongly than in the case of a positive corona discharge. In addition, it makes itself

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the discharge problem caused by the corona radiation. always more noticeable, the more sensitive the photoconductor for use in machines operating at higher speeds to be developed.

The previously known methods and devices for Corona charging does not achieve the desired efficiency corona charging, and there are considerable difficulties in charging more sensitive photoconductors. These Difficulties arise from the fact that the electromagnetic radiation generated by the corona wire reduces the effectiveness of this Corona charge decreases again, a fact the meaning of which has not yet been properly devised.

The object of the invention is therefore to provide a new method to provide a device for carrying out the method, which the disadvantages of the previously known devices and Proceedings no longer exhibit. So we want a new corona charging device be created whose charging efficiency is larger and with that after a new recharge procedure sensitive · photoconductors can be charged with corona discharge at high speed.

This object is achieved according to the invention in a method for electrically charging a chargeable device solved that the chargeable device compared to the

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electromagnetic generated by the corona charge source Radiation is shielded and that the charge is directed to the rechargeable device.

According to a development of the invention, a corona charging device created, which is a corona charge source, an optical shielding of a chargeable device against electromagnetic generated by the corona charge source Radiation and transport facilities around Transport of the charge from the coronary charge source to the chargeable device.

By shielding the chargeable Hnrloixtung from those generated by the corona charge source and undesirable electromagnetic radiation is a · caused by this Avoid discharging the charged device. Thus the one generated and desired by the corona charge source Charge as much as possible despite the optical shielding of the device completely on the surface of the facility, are special transport devices for the corona * » Ladun £ 3quelle provided ions emitted »these around the Guide the optical shield around directly onto the surface of the chargeable device. This Tranoporteinrichtunjen can be suitable electrostatic fields according to various embodiments of the invention, which the ion flow in deflect the direction you want or you can

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Ion-driving gas streams or an insulating intermediate material that is charged directly by the corona charge source, after covering a certain path and contacting the chargeable device a charge to theee gives up

The invention is illustrated with reference to the drawing Embodiments of the corona charging device designed according to the invention for carrying out the method according to the invention are explained in more detail.

Show in detail

. 1 is a front view of the lorona charge Torriohtuag together with a partially cut image of one

electrophotographic drum,, 2 a representation of the gate soaped in kg. 1

direction along the line 2-2, fig. 3 a sectional illustration of a different embodiment »-

shape of the device _r Pig, 4 a section dare division of another Atnimwaai $ 9 ~ ..

form of the device and Pig, p a representation of a fourth embodiment «· - ..

shape of the device.

A preferred embodiment of the invention is in Pig. I. shown. A corona charge source 10 is close above one arranged photoconductive drum 15, which is a photoconductive

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Has layer 12 with which a grounded (21) conductive base 14 is covered. The corona charge source XO has a corona wire 16 which is partially enclosed by a shield 18. An electrostatic ion deflection element 20 is provided in the shield 18. A suitably high voltage from a Q source 22 is connected to the ion deflector 20 and has the same polarity as the ions emitted by the corona wire 16. A suitable potential difference for the suction of the desired electrostatic ion deflection, which is based on the geometric shape of the shield 16 and the ion deflection element 20, is "as appropriate, brought about by a voltage divider 17, the ε.B. is formed from a Beihe of resistors 23, 241, 25 and 29 and one between the electrostatic ion variable Velemtmt 20 and the Corona wire 16 erupted. The electric low-pitched circle can as known to every pachmann, have many other components than the resistors 23, 24, 2 and 29, which are given as examples only, in order to bend the usual electrical potentials of the corona wire 16, the shield 18 and the deflecting element 20 ". XKLe electrostatic shield 18 can also be biased to pass additional ions through the outlet port ejects. J

By generating suitable potential differences with the help of

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from the ion and electron optics known devices, the base 14 _t, the electrostatic ion deflector 20, the shield 18 and the corona wire 16 can carry potentials that cause an ion flow around the electrostatic ion deflector 20 and onto the surface of the photoconductor or the electrophoto ^ raflachen Guide recording area 12. Due to its shape and its relative dimensions over the recording surface 12 and the coronal charge -. ^ Ual 10, the electrostatic ion blanking element 20 prevents the linearly propagating eictrouagnetic radiation from impinging on the photoconductor.

Ob.vohl in Pig. 2 a special form of electrostatic 1on baffle 20 shown may be any suitable Shaping in connection with certain dimensions and shapes the other arrangements are used, which the ^ • ev / switched on electrostatic deflection of the ion flow simultaneous shielding of the photoconductor from any electromagnetic radiation caused. The supplied potentials can be changed in polarity and strength to the desired To achieve electrostatic deflection for the particular energies, shapes and materials that have just been silted up. The deflector 20 does not even need to be in the electrical circuit in some arrangements and therefore does also not to consist of a conductive metal, but rather it can, for example, be made of wood or some other dielectric material

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be made. If the deflection element 20 is aue “in” dielectric Material made and not on the circuit connected, it builds up only charges that Λιroh die Corona discharge generated ions repel.

The structure and materials of the corona charge sources used here can be of the same type as they are described, for example, in TM ÜS-iPatentschriften 2 588 699, 2 777 957t 2 851 725, 2 885 556 and 2 922 "883 ·

During operation, the ions generated by the corona wire 16 are radiated evenly in all directions 18 can be blackened with a conductive layer 19, such as with colloidal graphite or platinum black, so that a large part of the otherwise reflected electromagnetic Radiation is not reflected. In addition, the P is direct radiation of the corona wire 16 by the electrostatic Ion deflection element 20 shielded, as an optical shielding and also as that generated by the corona wire 16 Ion flow onto the photoconductive · surface 12 conductive · deflection unit works.

Another embodiment of the corona charging device is in Pig. 3, v / o in addition to the shield 18 and the electrostatic deflection element 20, a Ctesstrom from Preßö'asflaochen 26 is provided int. The in Piij ;. 3 gas flow is double with two inlet openings 28 in the outlet

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shielding 18 provided. The gas flow is durch.den pneumatic pressure dea in the / tabs 26 dividing under pressure β Gas generates and carries the flow of ions from the corona wire 16 past the electrostatic deflector 20 " this around.

That from the bottles 26 in the Abschiremg 18 in area dea corona wire 16 conducted 0 * s can be done in different ways selected foci in order to deal with the difficulties caused by the electromagnetic radiation in each case «! Keep conditions as low as possible »

Thus, a gas can be selected that has a spectrum outside of the range of conditions of the poto conductor. For example, oxygen, or neon, or a misetang aas you, can be used when the totoconductor 12 is eleven »lelenj? Latte. Exactly it is possible to use a fl * s which absorbs <| * s spectral ranges in which the optical radiation generated by the 4 corona discharge is strong, whereby the electromagnetic radiation is largely eliminated · ¥ 1 «which faohmann immediately detects the gas stream mm around passing the ions can consults to the baffle 20 alone throw "so that no potential must be applied to the optical shield and the baffle 20th However, suitable potentials can also be applied to the optical shield, so that this also acts as an electrostatic deflection element at the same time.

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Redirecting the ions around the optical shield the photoconductive recording surface 12 causes.

In summary, it can be said about the mode of operation of the arrangements described so far, namely the optical shielding combined with a gas flow in a variety of variations of arrangement and with a variety of different pressure, flow rates and special effects of the gas to the electromagnetic radiation can be applied to the optical radiation of the corona wire 16 effectively Aaran to prevent the photoconductive Aufaeichnungsfläohe 12 * u and still ensure that an appropriate amount is conducted by ions of the corona wire 16 onto the surface 12 to be charged.

In Figure 4 there is shown another embodiment of the invention which includes a small insulating bead 48 on a charge device using intermediate material. The small. nexi insulating beads 48 are located in a container 46 which feeds them to the lower part "Ines housing 52 of the $ oro" charging device 40 · A motor 60 drives a conveyor belt 45 around a pair of guide wheels 42 and Si, as a $ * ahl of cups 44 has. The arrangement is designed so that the cup 44 is immersed in the supply of small insulating beads 48 which are located in the lower ¹ ½ of the housing 52. The pearls are carried with the cups 44 near the eggs and on a carrier at the upper end of the guide wheel 42

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62 poured. As they roll and slide down the carrier 62, the beads 48 are secured by a corona wire 64- charged, which is arranged in a corona shield 66, which the ions of the corona wire 64 on the Carrier 62 "heads moving beads 48. The beads are not photoconductive and are therefore not used by the το »corona wire The emitted electromagnetic radiation affects «the pearls» move under the influence of gravity or «fcirch mechanical conveying continues and cascading over the photoconductive Recording surface 54 of an electrophotographic drum, for example, having a conductive pad 55 grounded. The drum is driven by a motor 56. In this way, the charge is applied to the photoconductive recording surface 54 of the Tronmel transferred.

The optical radiation of the corona wire € 4 reaches dl photoconductive surface 54 is not. By charging a large number of the small insulating beads 48, it is not necessary to that the corona wire 64 has an even load on » shows. Therefore, the entire corona discharge can be used to charge the pearls 48, the previously used «* selective procedural steps can be dispensed with, eo that dae Corona charging process, is simplified. The level above The device and its mode of operation bring a much greater degree of efficiency than the careful corona charging devices up to $ 90 of the corona current on the Abeohirainc is directed and thus is lost to a more uniform

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To achieve charging of the pot conductor. By using this technique it is possible even with negative charges to charge evenly »since the pearls tend to cascade and thus randomly move to distribute the charge. In contrast, the uniform charging with negative charges was previously due to the pinch effect a difficult-to-reach target that creates so-called hot zones along the corona wire, which is an uneven Require charging of a pot conductor if this is charged directly.

Although the pearls 48 have previously been referred to as small insulating pearls their dimensions and their composition can be varied over a relatively large range. Typical dimensions of the pearl are e.g. between 40 and 1000 microns. Usually, the smaller the bead size, the more uniform the charge. Typical materials for the insulating beads see B. Q-Ias and polystyrene.

The Kaakadierunus arrangement can differ from that in Pig. 4 shown differ considerably, since it is only necessary to charge the beads 46 in such a way that no electromagnetic Corona discharge radiation directly-on the one to be charged Photoconductor falls and then the beads 48 can be cascaded across the surface of the photoconductor. In the The view shown in FIG. 4 is therefore only for the purpose of previewing one embodiment of the present invention, see above

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that many other designs for drum-shaped and Flat drawing surfaces are conceivable and can be used by any specialist are realizable. For example, a layer of insulating beads can be placed on a selenium or other photoconductive recording surface can be applied in order to induce an induction charge on the pot conductor by charging the holiday shift.

In operation, it is therefore only necessary to use a small number of insulating beads with an optically shielded one Charge the Eorona charge source and then the pearls with in contact with the photoconductive material to be charged bring. The charge can be transferred by contact or induction, depending on the particular arrangement used or procedure

Another Ausfüiirungsfona of the invention is in Eig. 5 shown. I) a3 working principle of this arrangement is essential the same as the arrangement shown in Fig. 4 · Anctelle of the small insulating beads 48, however, is a insulating tape 80 is used. This tape is through a Drive wheel 76 driven by a motor 73 is moved. That .Band 80 is corona discharge from a corona wire 74 charged from a photoconductive drum to a photoconductive layer 86 covering a conductor 65 optically shielded iat. The drum is powered by a motor 88 powered. The optical shielding of the Votoltiter 86 opposite the light generated by the corona wire 74 can

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by the arrangement of the insulating tape 80 shown in FIG. 5 and also by the shielding JZ and, if necessary, by additional diaphragms and stops 70. First, a charge is generated on the insulating belt 80 by the corona wire 74, then the belt 80 is moved over the rollers 82 and 84 which bring the charges into close contact with the photoconductive drum 86 so as to remove the charge from the insulating belt 80 to be transferred to the photoconductive layer 86.

So again, the i \ ix charging ichädliohe optical radiation insulated, shielded and prevents their impact on the photoconductive 3chioht. In addition, it is possible to Jetst a larger. Proportion of the drowned kerona charge for charging the band would otherwise be equivalent to direct charging of the potoconductor through the source of charge, whereby the efficiency is also improved. In the embodiment shown in FIG. all that is necessary is to isolate the tape CO au.fgii1.a4en and then to bring this tape into contact with the toto-conducting Sahioht, whereby Al * LaAung becomes on the * »i» l **% * r, while on the same side the lotolelter « β * the corona wire 74 generated electromagnetic radiation is "lated and shielded.

Of course, the present * information is not on

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Applications in which a photoconductor is charged, but can be used anywhere where a corona charging device is desired and used sensitive fetal ladders.

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Claims (1)

1787213 Tp at en , ttj ^ a -P .-. Y. ffi-.fiulmji p. 1, Iverfahren for electrically charging a rechargeable Xlnrichtung using a Koronaladungsquille _r characterized in that the rechargeable !! finishing of the corona charging s source-β (10) electromagnetic radiation generated is shielded (12) relative to the and daJ3 cash charge for on ladw Device (12) is directed, 2. The method according to claim 1, characterized by the method * steps* 1) Apply a supply voltage (22) to the ICorona charge source (10), 2) the shielding a auXladbexe ünrichtun "(12) forming the photoconductive Sohioht by fin · optieohe Abeohirmung (20) relative to the r <m the loronaladungequelle (10) elektroiaagnetieohen radiation generated and 3) Passing the raw corona charge source (10) Charge around the optical shield (SO) and towards the photoconductive base (12). 3. The method according to Aoepruoh 2, thereby kelenseieinet, AeJ Backing of the charge generated by the lorona charge source (10) around the optical Abaohirnung: (20) around to the photoconductive layer (12) by clocking an ioninflusaes around Al «shielding (20) around photoconductive layer (12) 109831/1117 ÖA ORIGINAL acts by applying an electrostatic deflection of the ionic flux generated by the corona charge source (10) to the optical shielding voltage (22) (20) is placed and the ion flow is directed to the photoconductive layer (12). 4. The method according to claim 5, characterized in that 4er ion flow around the optical shield (20 'with a Gaostrom supports v / ird, which is connected to the wire electrode (16) past the corona charge source (10). 5. The method as claimed in claim 2, characterized in that the charge is conducted around the optical shielding (62, 80) around on the photoconductive layer (54 * 06) by charging an insulating ZvrL schema te rial · (48, 62) and by touching the optically coated photoconductive to be charged «! Layer (54, 86) with this two-skin material (48, 62) causes will · 6. The method naoh claim 5, characterized in that a a large number of intermediate materials (48, 80) containing small insulating perlon (48) are used. 7 · Method according to claim 5 »characterized in that dad, ale Intermediate material (48, 80) an insulating tape (Θ0) is used that oh t (86) is brought into contact with the photoconductive base. 108631/1117 BATH ORIGINAL 8 »Driving according to one of claims 1 to 7, whereby · draws that as a corona charge source (10, 66, 72) a corona wire (16, 64, 74) is used. 9 »Corona charging device, in particular for carrying out the Method according to one of Claims 1 to 8, characterized through a corona charge source (10), through an optical one Shield (20) from a chargeable SLnriaktung (12) electromagnetic generated by the corona charge source (10) Radiation and duroh transport facilities (20, 22, 26, 28) for transporting the charge Ton of the coronary charge source (10) to the chargeable device (12). 10 · Corona charging device according to Anepruoh 9, marked duroh a corona wire (16), through a feed apparatus (22) for the corona wire (16), by means of a radiation-absorbing and deflecting electrostatic shield (18) of the corona wire (16), by an optical shield (20) to prevent direct interference with the chargeable device forming photoconductive 3chioht (12) duroh from that iCorona wire (16) generated electromagnetic radiation and by Traneporteinricatungeo. (20, 22, 26, 26) to lead out the charge around the optical shield (20) on the photoconductive layer <12). 11. KoronaadungßVorrichtung according to Anapruch 10, characterized in that the Traneporteinrichtung (20, 22, 26, 28) a 100831 / titf BATH ORIGINAL electrostatic ion deflector (20) which a voltage source (22) for supplying an electrostatic potential to the optical shield (20). 12 «corona charging device according to claim 10, characterized in that that the transport devices (20, 22, 26, 28) have a deflection device which is a pneumatic device (26, 28) for generating a gas flow guided past the corona wire (16) and around the optical shield (20) contains. 13. Corona charging device according to claim 10, characterized in that the transport devices (20, 22, 26 _f 28) have an electrostatic ion deflection device (20) and a pneumatic device (26, 28) generating a gas flow for guiding the ions around the optical shield (20) ) have around. 14 · Corona charging device according to claim 10, characterized in that that the port facilities (40, 48, 76, 80) an insulating intermediate material (48, 80) and further means (40, 80) for this intermediate material (48, 80) with the optically shielded photoconductive layer (34, 86) in contact. 15 · Corona charging device according to claim 14 »thereby enabled« indicates that the insulating intermediate material (48, 80) a · 109831/1817 ßAD ORIGINAL has a large number of small insulating beads (48) 16. ICorona charging device according to claim 14 _f, characterized in that the insulating intermediate material (48 _t 80) / consists of an insulating tape (00) "which is brought into contact with the photolytic layer (86). 17. Corona charging device according to claim 9 »characterized in that that the corona charge source (66) has a plurality of able to charge insulating small beads (48) and that a distribution device (40) for distributing the beads (48) is provided over the surface to be charged (54). 18. Koronaadun ^ 3 device according to claim 9 »characterized in that that the corona charge source (72) is capable of applying a charge to the moving insulating tape (80). (6) that a part of the belt (80) shields the surface to be charged / against the electro-magnetic radiation generated by the corona charge source (72) and that a drive device (76) is provided which moves the belt (80) in such a way that ee with the surface to be charged (86) comes into contact, the. Charge is transferred to the surface to be charged (86). 10 9 8 31/1817 Blank page