DE1246409B - Xerographic developing machine - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

G03g

German KL: 57 e- 15/08

Number: 1 246 409

File number: R 27913 IX a / 57 e

Filing date: May 6, 1960

Opened on August 3, 1967

The invention relates to a xerographic developing machine having an on a surface with toner particles to be loaded dispenser, which is close to an electrostatic latent to be developed Image-bearing surface is to be brought.

In the known xerographic development process, the electrostatic latent images uses electrostatically charged, non-conductive developer particles that attracted to the image area to be developed by its oppositely charged area parts will. The forces of attraction that arise are therefore in a direct relationship to the charges of the latent image. For example, in the Kakadierungsverfahren, in which the developer is cascaded over the image area to be developed, relatively large carrier particles for the developer used, which on their surface with finely divided, pigmented non-conductive toner particles connected by electrostatic adhesion. These toner particles separate during the development process from the carrier particles as they are attracted to the charges of the latent electrostatic image will. Their deposition on the image surface makes the latent image visible.

Other development facilities work with a non-conductive or conductive dusty or liquid dye which is brought up to the image area to be developed in an air suspension will. As with the cascading process, dust particles or droplets of this developer material are produced attracted by the charges in the latent image, making it visible.

Furthermore, development devices are known which have a non-conductive located on a brush Developer, with a magnetic developer that forms a magnetic brush with its particles, or with a non-conductive layer on a donor sheet or tape applied developer work. The dispenser carrying the developer is supposed to be the feeder allow a constant amount of developer to be applied to the image area to be developed.

With the last-mentioned development devices, it is true that the developer material is fed evenly to the image area to be developed is possible, but the transition in the developer material existing toner particles on the image area, ζ. Β. to regulate the image contrast, not influenced will. Therefore, the avoidance of background deposits has also been a priority in these facilities not perfect.

Xerographic developing machine

Applicant:

Rank-Xerox Limited, London

Representative:

Dipl.-Ing. F. Weickmann,

Dr.-Ing. A. Weickmann,

and Dip.-Ing. H. Weickmann, patent attorneys.

Munich 27, Möhlstr. 22nd

Named as inventor:
Robert William Gundlach,
Spencerport, NY (V. St. A.)

Claimed priority:

V. St. v. America May 7, 1959 (811610)

A well-known developing method using a dispenser is used as a developer a mixture of magnetic carrier particles and non-conductive toner particles, which in one by the Donor generated magnetic field is brought into contact with the image area to be developed. Of the magnetic dispenser is also electrically conductive and serves as an electrode for generating an electrical Constant field between magnet and picture surface, with its direction and strength the transition of the Toner particles on the latent image is controllable.

All of the development processes considered here work with non-conductive toner particles that are electrostatic are charged. This charge is carried out within the supply of toner powder mechanical movement when mixing with the respective carrier particles used by the triboelectric Effect achieved by friction. As a result of the irregularities inherent in these processes there is also an unequal charging of the toner particles with one another, so that even with one Arrangement of the type described last on an exact control of the transition of the image powder. the

709 619/559

latent image as well as the deposition clearly corresponding to the image is not yet possible. Besides This facility requires a magnetic dispenser and magnetic carrier particles, which makes the Selection of the substances to be used is severely restricted and there are further irregularities result from the inhomogeneity of the magnetic field.

The object of the invention is now to provide for a developing device of the type mentioned at the beginning those indicated above in connection with the supply of the developer and its pretreatment to avoid the disadvantages caused, so that an exact and precisely defined control of the electrostatic forces between the toner particles and the charges of the latent image is possible.

This object is achieved according to the invention in that the surface of the dispenser is non-magnetic and has a specific electrical resistance of less than ΙΟ ⁹ Ω cm, that carrier-free toner particles are used which also have a specific electrical resistance of less than ΙΟ ⁹ Ω cm and that the electrical resistivity of the surface bearing the electrostatic latent image to be developed is at least two orders of magnitude greater.

In practicing the teachings of the invention, the surface of the dispenser and the toner particles are conductive enough to make the toner particles virtually instantly upon application to the dispenser assume its surface potential. As a result, the toner particles are only reduced by the small ones van der Wals' forces kept on the donor, so that when transitioning to the to be developed The picture surface does not have to overcome any binding forces of electrostatic or magnetic origin are, as is the case with the known development processes. The toner particles are preserved when approaching the electrostatic latent image to be developed, an image corresponding to that image Image charge: The opposite polar charge corresponding to this image charge flows off through the donor. As a result, the transfer of the toner particles to the latent image is essentially only due to the charge ' distribution in the latent image is determined, but not by a previous charging of the toner particles or by magnetic forces.

In the simplest case, the conductive carrier of the latent electrostatic image and the conductive carrier Donor equal potential, e.g. B. Earth potential. If the latent image is e.g. B, formed from positive charges, thus they influence negative charges in the toner particles that are brought close to them. The these corresponding positive charges are discharged via the donor. The negatively charged toner particles are attracted by the image charges and remain on the image surface or a possibly inserted one Image sheet adhere.

By influencing charges in the toner particles are the forces that cause the transition evoke the picture surface to be developed, proportional to the square of the prevailing electrical power Field strength. This results in a contrast and significantly improved compared to known methods better area coverage for area-toned images. Background deposits come in handy completely avoided. Only toner powder without carrier particles is used as the developer, as these would disrupt or prevent the influencing effect described. The conductivity of the toner determines the speed of the induction process, so that if good conductors are used, a faster one Development can be achieved than was previously possible.

In a further development of the invention As is known per se, the developing device is the surface carrying the electrostatic latent image the surface of a conductive pad

ίο located photoconductive or dielectric Layer, and between the conductive surface of the dispenser and the conductive backing is a voltage source switched. By adjusting the voltage, the surface potential of the Set the dispenser as required in terms of strength and sign in relation to the charge of the latent image, so that the electrostatic forces between the toner particles and the image charges are accurate are controllable.

Further advantageous configurations of the developing device according to the invention emerge from the following description of the exemplary embodiments shown in the figures.
Fig. 2 shows an embodiment of a developing device which works with a dispenser in the form of an endless belt;

F i g. Fig. 2 shows an embodiment of a developing device with a dispenser in the form a rotating brush works, and

Fig. 3 shows an embodiment of a developing device in which between the dispenser and Image plate an image recording tape is guided.

In Fig. Fig. 1 is an automatic xerographic developing machine constructed in accordance with the invention shown. It contains a xerographic plate 11 in the form of a cylindrical drum, which has a photoconductive, insulating layer 12 on a conductive substrate 13. These drums wear a layer of amorphous selenium as a photoconductive insulating material. Optionally, the photoconductive insulating layer 12 also includes any known photoconductive insulating material, e.g. B. Anthracene or sulfur, phosphorus, but also suspended in a binder, photoconductive material,

z. B. zinc oxide in acrylic resin. Like. Have. The drum 11 rotates in the direction indicated by the arrow Direction, and the carrier 13 is grounded. As it rotates, the drum 11 passes an awareness station 15, an exposure station 16, a development station 17, an image transfer station 18 and a cleaning station 20.

At the sensitization station 15, the drum 11 is charged by uniform electrostatic charging of the photoconductive insulating material layer 12 is sensitized. This can be due to a corona discharge done as described, for example, in US Pat. No. 2,777,957. But it can also find other methods of charging use, for example radioactive charge, induction charge od. Like. After the sensitization, the drum 11 arrives at the exposure station 16, in which the The photoconductive insulating material layer 12 is selectively charged by exposure to a radiation image is balanced against that of the photoconductive

C5 layer is sensitive. For example, the photoconductive Layer exposed to a light image by projecting the latter onto the surface of the drum 11 be, with a slot scanner or the like.

as is done on Haloid Xerox Inc.'s Copyflo machine. Slides can also be used placed against the surface of the drum 11 and moved with it, with a light source behind the slide is used to expose the photoconductive insulating layer 12. It is also possible to use the Exposing drum 11 to an image pattern of X-rays or other types of energy which the photoconductive insulating plate 12 reacts by equalizing charges. After the exposure on the station 16 moves the drum 11 to the development station 17, where the over the surface of the Layer 12 now developed distributed charge patterns into a visible image of developer material will. Following this process stage, the drum 11 arrives at the transfer station 18, where the image developed on the surface of the drum 11 onto a transfer member, e.g. B. a paper web, is transmitted. The image can then be permanently fixed on the transfer element, by exposing it to a heat source or a steam atmosphere, the developer and a binder for this material flow together on the transfer element. However, it can developed image on the surface of the drum 11 can also be processed or used in other ways, whereby the transmission station may be omitted under certain circumstances. The drum 11 moves finally to the cleaning station 20, where remaining developer material from the surface of the Drum is removed. Also an additional treatment can be done to the drum for the next one Prepare the cycle that starts at the awareness station and continues through to cleaning station 20.

At the development station 17, an endless dispenser belt 9 is provided, which runs over rollers 8 and 7. In this embodiment, the roller 7 is electrically conductive and connected via a line 6 to a potentiometer 5 which is connected to a battery 4. Powder particles 3 are deposited on the surface of the belt 9 by a device 10 for generating a powder cloud. Particles that are not deposited on the surface of the belt 9 are sucked off under a hood 63 by a vacuum pump 2. The belt 9 runs in the direction of the arrow drawn, passes through a charging zone within the hood 63 and then reaches the surface of the photoconductive insulating layer 12 of the drum 11. The belt 9 consists, compared with the photoconductive insulating layer 12, of a relatively conductive material. In general, the material of the insulating layer 12 has a specific resistance of at least ΙΟ ¹² Ω cm, the belt 9 should be at least two orders of magnitude more conductive than the photoconductive insulating layer 12, preferably by three orders of magnitude, that is, its specific resistance should be less than 10 ^{! l} Ω cm. Developing according to the present invention is more effective when a more conductive layer is used. The best results have been achieved with conductive foils or metals with a resistance in the order of magnitude of 10 ~ ⁴ Ωαη for the band 9. The outer surface of the band 9 is preferably regular and uniform. It can be smooth, but it can also be evenly grained. Uniformity of the surface is desirable in order to ensure a uniform application of the powder particles, whereby a uniformly large amount of powder on the surface of the belt 9 can be transferred to the photoconductive insulating layer 12 of the drum 11 during development.

Like the web 9, the developing material should be at least two orders of magnitude more conductive than the photoconductive insulating material layer 12, preferably it is more conductive by at least three orders of magnitude. The developer material can be conductive in the usual sense, for example made of conductive metals or the like exist.

The figure shows a preferred way of loading the belt 9. The particles are through a or several fine tubes, the exit end of which is directed towards the surface of the belt, blown against the belt in a turbulent flow. Lots of the particles hitting the surface remain attached to the tape, and since the particles and tape are relatively conductive, charges, which were generated during the passage through the fine tubes, balanced; the particles However, they remain in their place due to van der Waals forces or similar force effects the tape 9 adhere. As already mentioned, another type of loading is that of the developer cascaded onto the surface of the belt 9, as is customary in xerographic technology. Charging with a liquid has also been attempted, but with less success because Developer particles that have been applied to the belt in this way move away during development do not easily peel off on the surface of the drum 11. It should be emphasized that during the figure shows a device for loading the strip 9, also one that has already been loaded Railway can be used. Such a track must be changed from time to time. Of course the belt 9 can also be replaced by the surface of the roller 7.

According to the illustrated embodiment of the invention, the band 9 is with a low tension biased by electrical connection to the battery 4 via roller 7, line 6 and potentiometer 5. As a result, the developer particles on the belt 9 in one of the charge image on the Drum layer 12 induces corresponding distribution charges, the polarity of which is that of the Drum charge is opposite. A strong field is created between the particles and the charged surface elements on the surface of the photoconductive insulating layer 12, and if that The belt 9 and the drum 11 separate from one another, leaving particles with induced charges adhere along the surface of the photoconductive insulating layer 12 in an imagewise distribution. It should be noted that the development according to the present invention not, as with practically all known xerographic Development systems, is polarity dependent. With the usual xerographic development A positively charged particle is moved to a negative surface charge and a negatively charged particle Particle to a positive surface charge. When developing the charged surface elements according to The present invention - be these elements positive or negative - occurs when the earth potential is applied or a potential substantially corresponding to this induction on the particulate material opposite charges on the particle

material on, so that the latter of the charged surface elements on the surface to be developed is attracted. This is advantageous in that it always develops charged surface elements is not required, the developer material or the bias applied to it to change regardless of whether the charge polarity is positive or negative.

According to the present invention, it is also possible to develop uncharged surface elements. this is achieved if one applies a bias voltage to the development material 3, which is essentially is equal to the voltage on the surface to be developed and has its polarity. Is z. B. a positive polarized image of 200 volts on the surface of drum 11 then applies of 200 volts positive to the roller 7, a particle deposition on the non-charged surface elements on the surface of the photoconductive insulating layer 12. In this case, a field exists on the uncharged surface elements and this causes a migration of the charge into the carrier part 13 in a distribution corresponding to the uncharged surface elements. Such induced charges form strong fields that cause particle movement from the surface of the belt 9 and thus a Image development on the surface of the photoconductive insulating layer 12 in the non-charged surface elements cause. This type of development is shown in FIG. 2 shown. . '.

In developing a xerographic plate, the belt 9 is generally preferably pretensioned to a slightly increased tension. Usually, when developing a xerographic plate, a little residual voltage remains in the background areas, and it is preferred that a voltage approximately equal to the residual voltage and having the polarity thereof is applied to the belt 9 through the potentiometer 5. This has the effect that the residual stress area is the earth potential area between the particle layer and the drum surface which is developing. Generally the applied voltage will be on the order of 5 to 20 Volts. When developing a surface on which the charge is imagewise distributed over the surface elements or a plate which has no residual charge and no background charges; a bias to earth potential results in a background-free development.

F i g. Figure 2 shows another embodiment of a developing device constructed in accordance with the invention. This is about development a xerographic plate 21 having a photoconductive insulating material layer 23 over a conductive support layer 22 has. The photoconductive layer 23 can, however, also be formed by other dielectric image material layers be replaced. The carrier 22 is connected to ground potential via a line 27. The arrow behind the xerographic plate 21 indicates its direction of rotation. From the plate 21 is shown in FIG. 2 only a section shown. It can be a xerographic, cylindrical drum, as in Fig. 1, or just one Cylinder segment or the like. On the surface of the photoconductive insulating layer 23 of the plate 21 there are positive charges 25 in an imagewise distribution. The plate moves up, its surface area above the processor has the Development zone already happens while the area under the development device enters this zone has not yet occurred.

A brush-like dispenser element 33 is arranged at the development zone and extends from a cylinder 57 protruding bristles 35 is formed. The axis 43 of the element 33 is through a Belt 40 is connected to a motor 38 and is driven by this in the direction of the inside of the Cylinder 37 shown arrow driven. At his

ίο rotation moves the dispenser element 33 into contact past a loading cylinder 44; this consists of a housing 46 with a compression spring 45 pressing a feed member 47 against a developer block 42; the latter is due to the Brush 33 on, so that their bristles 35 pick up developer powder as they pass the cylinder 44. This developer powder adhering to the bristles is brought to the image area to be developed, d. H. to the photoconductive insulating material layer 23 of the xerographic plate 21.

The dispenser element 33 is opened via the line 31 and the wiper 32 of a potentiometer 30 a bias voltage supplied by a battery 28 is maintained. In the position shown, the leads Wiper 32 has a positive voltage. As already explained, the developer element 33 and the developer powder are 42 each by at least two, preferably three orders of magnitude more conductive than that Photoconductive layer to be developed 23. As a result of the conductivity of the powder in the bristles 35 acts the bias applied to the donor element 33 also at a point closest to that to be developed Image area. As a result, the uncharged surface elements are developed while the charged ones Surface elements are not developed, The voltage applied to the donor element is approximately the same and of the same polarity as the highest voltage on the image surface to be developed. This creates electric force fields between the developer and the uncharged surface elements of the image area and essentially no field between the powder and the charged ones Surface elements. As shown for the portion of plate 21 above the developer device, powder 26 becomes deposited on non-charged surface elements, while on the charged surface elements 25 no deposit takes place. The development of the charged surfaces can be monitored with the device of FIG. 2 in the reference to FIG. 1 explained way by biasing the donor element 33 with ground potential can be achieved.

The rotational speed of the dispenser element 35 of FIG. 2 or the band 9 of FIG. 1 depends on the conductivity of the material used for the brushes 35, the cylinder 37 and the developer 42. This is due to the fact that when using poor conductors sufficient Time must elapse for the induction of the charge in the particles. If you use a good ladder it works the induction very quickly in front of it and the brush 33 can then rotate quickly.

Wherever particles are deposited, they remain, as there is no movement of charge between the electrically conductive particles and the insulating image surface take place, electrostatically bound in place, and the deposition of new particles continues until charge neutralization is achieved. The full Neutralization is not the norm; H.,

Particle deposition takes place close to the point of neutralization, without complete neutralization to reach. This amount of particle deposition is what is common and yields in xerography Sufficient image sharpness and density.

While the dispenser element 33 is designed to be cylindrical in the example shown, there are also other designs possible. For example, the cylinder 37 can be made by a flexible, endless Band with bristles 35 or the like. Be replaced. Such variants that are familiar to the person skilled in the art become also encompassed by the basic idea of the invention.

The bristles 35 of the dispenser element 33 can consist of various conductors known per se, so made of thin metal wires, natural and synthetic furs, treated fiber materials, Carbon wool and the like. It is preferred to use wire bristles if the one to be developed Screen should not be used repeatedly. In the other case, i. H. when the screen repeats is used, treated fiber materials are preferred as the bristles.

In the embodiment according to FIG. 3, in turn, a plate 21 is used, which is made of a photoconductive insulating material layer 23 on a conductive carrier 22 is made. The latter lies above that Line 27 at ground potential, the plate 21 rotates in the direction of the arrow. At the development station In this figure, the conductive dispenser tape 53 moves, the conductivity of which is the same as in the F i g. 1 and 2 corresponds to the arrangements shown and which the likewise conductive particles 57 carries, between a roller 54 and the plate 21 in the indicated arrow direction. The donor tape 53 is connected to earth potential via the roller 54, it can, as in connection with FIGS. 1 and 2 explained, also be connected to a variable potential, around a predetermined potential for the particles 57 on the tape 53 to be able to adjust. In the case shown, the particles 57 are at ground potential; therefore the charged surface elements are developed. Between the plate 21 and the Particle layer 57 is a band 50 made of relatively poorly conductive material. This tape can made of pre-dried paper, insulating plastic or the like. The band 50 should be sufficient be poorly conductive in order to prevent degradation of the fields between plate 21 and conductive tape 53 and thus to ensure good development on the belt 50. In general it should Tape 50 will have a resistivity greater than about 10 ° Ω cm. According to the movement of the particles on the surface of the belt 50 in an image-wise distribution of the particle deposits 51 are the latter fused by the action of heat or steam and so the image on the surface of the belt 50 permanently fixed. The tape can now be wound up or, if desired, cut into individual images will. It can also be used in other known ways.

A particular advantage of the device shown in this figure is that cleaning the surface of the xerographic drum is not required because no particles are deposited on it will. Rather, the deposition takes place on the belt 50, which is between the drum and the Donor belt 53 is running.

The developer particles used in connection with the present invention can come from iron powder, other powdered metals, and the like. powdered Carbon, including graphite and lamp soot, and preferably charcoal. The particle size should generally be less than 20 microns; an average particle size is preferable less than 10 microns. The choice of particles and the particle size depend to some extent on the image to be developed and the desired resolution. Shall, for example, surface tint images are developed, an average particle size is less than 5 microns and not more than about 10 microns is preferable. When developing line images, it is enough to get good results in terms of quality, the other area indicated above.

Claims (8)

Patent claims: 1. Xerographic developing device with a dispenser to be loaded on a surface with toner particles, which dispenser is to be brought close to a surface carrying an electrostatic latent image to be developed, characterized in that the surface of the dispenser (9; 35, 37; 53) is non-magnetic and a specific electrical resistance of less than ΙΟ ⁹ Ω cm, that carrier-free toner particles (3; 26; 51, 57) are used which also have a specific electrical resistance of less than 10 ° Ω cm and that the electrical specific resistance of the the electrostatic latent image-bearing surface to be developed is at least two orders of magnitude larger. 2. Apparatus according to claim 1, characterized in that - as known per se - the electrostatic latent image (25) bearing surface (12; 23) the surface of a conductive Support (13; 22) located photoconductive or dielectric layer is and between the conductive surface of the dispenser (9; 35, 37) and the conductive pad (13; 22) one Voltage source (4, 5; 28, 30, 32) is connected. 3. Apparatus according to claim 2, characterized in that - as known per se - the voltage source (4, 5; 28, 30, 32) with regard to the level and polarity of the voltage to be output by it is designed to be adjustable. 4. Device according to one of the preceding claims, characterized in that - as on known - the dispenser (9; 35, 37; 53) is movable and is subject to a drive and that a device (2, 63, 10; 44) for the ongoing loading of the dispenser (9; 35, 37; 53) with the Toner particles (3; 26; 51; 57) is provided. 5. Apparatus according to any of the preceding claims, characterized in that the dispenser (35, 37) has an electrically conductive carrier element (37) on which electrically conductive Bristles (35) are attached. 6. Apparatus according to claim 5, characterized in that - as known per se - the carrier element (37) is cylindrical. 7. Apparatus according to claim 6, characterized in that - as known per se - the ■ "^;'709 619/559 cylindrical carrier element (37) is subject to a rotary drive (38, 40). 8. Apparatus according to any of the preceding claims, characterized in that a web (50) made of non-conductive material between the upper surface carrying the latent electrostatic image (25) surface (23) and the toner particles (57) present on the dispenser (53). Documents considered: German Auslegeschrift No. 1 024 988. 1 sheet of drawings 709 619/559 7.67 © Bundesdruckerei Berlin