DE2810854A1 - Reverse development of inductively chargeable toner image - using high absolute charge to attract toner particles to image background - Google Patents

Abstract

A method of developing an electrostatic image on a support operates by applying inductively charged toner particles onto the support to produce "reverse development". The image on the support is composed of first regions possessing a relatively higher electrostatic charge and second regions possessing a relatively lower electrostatic charge, i.e., representing the background of the image. The support is conveyed on an electrically conducting backing sheet and a "brush" of toner particles is formed on an electrically conducting surfaces; a voltage difference is applied across the conducting surface and conducting backing sheet with the same polarity as the first charged regions, in order to maintain the polarity of the charge of toner particles the same as the polarity of the charge in these first charge regions; this causes the toner particles to adhere to the second, less charged regions. Pref. the applied voltage difference is not less than that between the first charged regions and the backing sheet. The method is used to produce a reverse development process utilising an inductively chargeable magnetic toner.

Description

DESCRIPTION

The invention relates to a method of reversal development, according to which a magnetic one-component toner, i.e. an inductively chargeable one Toner, can be adhered to the parts of the latent image that have a lower electrostatic charge. With an electrostatic development system is usually an electrostatic latent image on a carrier element or a photoconductor mapped. The latent image is created by the photoconductor, for example as non-crystalline selenium or the like, uniformly positive or negative is charged by then the uniformly charged photoconductor with a The image to be reproduced is exposed, reducing the charge on the exposed part reduced and essentially retained as such on the unexposed part remain. Another known possibility is an electrostatic image to be generated by clicking on a matt or film with high resistance such as an electrostatic one Registration sheet, a charge is applied.

With regard to the development of the latent image, the The term normal development "refers to a process in which colored powder, the Toner is called, in places with a higher absolute value, the unexposed Correspond to locations of the electrostatic latent image produced in this way, adheres. In contrast, the term "reverse development" refers to a process in which the toner adheres to places with a lower potential in absolute terms, where the lower charged areas correspond to the exposed areas.

More recently, there has been an increased need for reversal development revealed for use for example with microfilm printers, tasimiles and laser beam printers. In one method of developing prints by Microfilm printer uses toner to develop the latent image, which is based on a photoconductive Paper formed through a negative film with exposure to a pattern of light has been. Since the negative film is transparent characters on an opaque background the latent image formed on the paper contains discharged areas, corresponding to the characters and charged areas corresponding to the background. When developing the latent image, it is necessary that the toner be applied to the discharged Areas so that a positive visible image results. It is the same known in some cases from the development of facsimiles and laser beam printers, that the toner on the discharged areas of a carrier for the electrostatic latent image should adhere.

One such reversal development is disclosed in U.S. Patent 3,888 666 known. There it is described that a photoconductor as an electrode opposite the the photoconductor containing the latent image can be used. The one as an electrode Photo conductor used consists of the same material as the photoconductor for the latent image and contains the same charge as the original photoconductor was charged for the latent image. The latent image is developed negatively by a developing powder dispersed in an insulating liquid, which is previously charged with the same polarity as the latent image.

Furthermore, a method for normal development has recently been used in which a toner containing magnetic particles instead of one conventional developers, such as liquid developers and two-component developers, containing toner and carrier is used.

The newly developed toner, the so-called magnetic one-component toner, which is inductively chargeable has proven popular because it allows for mixing of conventional toner and carrier particles is eliminated. It leads to a simplification the previously complicated structure of the developing device.

Such a method for normal development is, for example, in U.S. Patents 3,909,258 and 3,816,840. In this procedure Only toner particles without carrier particles are used for development. The toner particles containing ferromagnetic particles are under absorption on an electrically conductive shell that contains a permanent magnet with it a magnetic brush is formed at least at the development point, on this Development position promoted. There will be electrically conductive circles between the Toner particles and the electrically conductive shell formed, and the electrically conductive Shell is grounded to the frame of the duplicator, making an electrical Charge with reverse polarity due to the electric field created by the electrostatic Charge is caused on the support for the electrostatic latent image the toner brush is induced. lit other words when the toner is on the magnetic Brush is grounded, where the latent image on the carrier becomes a negative Contains charge on which toner induces a positive charge. However, it is very difficult to obtain reversal development with the inductively chargeable toner adheres to the lower charged areas of the electrostatic image. There the so-called one-component toner by an external electric field inductive As the toner is charged, the toner tends to stick to the more highly charged areas of the picture than of the less loaded areas of the image to cling to.

The object of the invention is to provide a reversal development method under Using an inductively chargeable magnetic toner to create.

This object is achieved by, for example, a permanent magnet is built into an electrically conductive sheath, a carrier with a electrostatic latent image on a conductive substrate in the area of the electrically conductive sheath is held, a toner brush made of inductively chargeable toner between the conductive sheath and the electrostatic image through the magnetic Attractive force of the permanent magnet is formed, and an electrical bias is applied between the conductive sheath and the substrate, which causes that an electric current flows through the toner brush and thereby the particles attached to the less charged parts of the latent image. The potential of the less charged parts is essential in its absolute value lower than that of the other parts of the latent image. The bias is not less than that between the latent image and the substrate and has the same Polarity like the latent image.

In the following the invention in connection with the appended Drawing described. On this is or

Fig. 1 shows a schematic sectional view of a conventional one Electrostatic image developing machine, Fig. 2 is a schematic sectional view an electrostatic image developing machine according to the invention, Fig. 3 shows the tension relationship between the longitudinal relative position (X) of the advancing electrostatic image and the potential (V) of the photoconductor plate in the embodiment FIGS. 2, 4 show an electrical equivalent circuit diagram for the embodiment of FIG Figs. 2 and 3.

A conventional electrostatic latent development method Images will now be described with reference to Figure 1 which is a schematic sectional view of a conventional electrostatic image developing machine. A one-component, i.e., inductively chargeable magnetic toner 4 is produced by the rotation of an in an element 3 built-in permanent magnets 1 from a toner container (not shown) conveyed to a photoconductor plate 5 which has an electrostatic latent image wearing. The element 3 is usually as an electrically conductive shell with a curved Surface, at least as far as part of it is concerned, developed and exists made of aluminum or the like. The toner 4 is, as shown in the figure, through the electrostatic charge on portions a1, a2, of the electrostatic latent The image is inductively polarized and the toner adheres to these portions. The photoconductor plate 5 is supported by an electrically conductive pad 6, which is connected to a grounded .-Current path is connected. According to the conventional method, therefore, a charge becomes opposite polarity to that of the latent image by the effect of the charge of the latent image, so that the toner inevitably hits the sections a1, a2, adheres, but cannot adhere to the background or the discharged part. Accordingly, no reversal development can be achieved.

In the following the invention will now be described with reference to an in the FIGS. 2 and 3 shown embodiment shown. Corresponding parts to Fig. 1 have the same reference numerals in FIG. 2. The one on an electrically conductive one Tray 3 transported toner 4 is lightly with the surface of the electrostatic brought latent image on the photoconductor plate 5 in contact. The senior Shell is preferably piled on an insulating part 2 to keep it from earth to isolate. Sections a1, a2, ... of the electrostatic latent image on the For example, photoconductor plates 5 are charged to about -500 V while the background b1 is charged to a potential of approximately +10 volts. One between bias voltage applied to the electrically conductive base 6 and the conductive shell 3 81 is brought to a value of approximately -550 V in this example.

Fig. 3 shows the relationship between the relative position (x) in the longitudinal direction the advancing photoconductor plate 5 and the potentials (V) of the photoconductor plate.

The toner 4 to be used was prepared by mixing 50 parts by weight Magnetite, 5 parts by weight of carbon black, 40 parts by weight of polyethylene vinyl acetate and 5 parts by weight Made of wax and had an electrical resistance of 108 ohm-cm. When performing reverse development using a commercially available ZnO-coated one Film or web as photoconductor plate 5 resulted in a clearly visible image with an image density of 1.98 for the background and 0.12 for the image.

The phenomenon of reversal development, as stated above, is called Transfer of charged toner particles from one formed on the conductive shell Brush the toner on the less charged areas of that formed on the photoconductive sheet described latent image. By rotating the conductive shell 3 or the Permanent magnet 1 is inductively chargeable toner to a place in the area exercise of the photoconductor 5 promoted. The toner 4 forms due to the permanent magnets 1 receding magnetic flux lines place a toner brush on the tray 3.

When the photoconductor 5 is driven from left to right as in FIG becomes, the toner brush formed on the cup approaches the latent image on the photoconductor while moving in the same direction. Although the Tips of the brush. are exposed to the negative electric field created by the Charging caused on the charged portions a1, a2 is caused by the large voltage maintain a negative charge in the tips between shell and base 6. The negatively charged peaks are caused by the essentially large negative charge repelled on the latent image, i.e. the toner will not be charged on the higher one Section transferred, but the negatively charged toner is carried by an electrical one Field between the base and the shell on the less charged section b1 transfer.

The transfer of the toner can take place when the electrostatic Attractive force between the charged toner and the substrate is greater than that magnetic attraction due to the permanent magnet, even if the tip of the toner brush does not touch the surface of the photoconductor. Preferred the tip of the toner brush touches the surface so that the attractive force is effective gets bigger. So development current flows from the lower charged section through the toner brush to the bowl. The amount of the less charged sections Adhered toner can be determined by Anãe m.q of the applied bias steer. The excess of the adhered toner tends to have opposite polarity so that it can be removed through the tips of the toner brush.

An equivalent circuit diagram for the embodiment of FIGS. 2 and 3 is shown in fig. VM corresponds to the bias voltage applied to the conductive shell 3 and is therefore -550 V. Vp is a potential of -500 V at charged portions a1, a2, ... of the electrostatic latent image. Vp 'is a potential on +10 V for the background sections or less charged sections b1. RA and RB are the respective electrical resistances of those lying on the toner layer Toner brush extending from the conductive shell 3 to the photoconductor 5 on the charged and background sections, as will be explained below. The transfer of toner particles from the toner brush to the photoconductor 5 means that the charge on the toner is transferred to the photoconductor, so that an electric current flows through it. In such a case, that corresponds Potential at the root of A Non toner brush on sections a1, a2, ... of the electrostatic latent image apparently that at root B of toner brush on background portions b1. On the other hand, the resistances RA and RB of the toner are expected to be substantially are the same. However, since the voltage difference between the ends of RA is 50V and the one between the ends of RB 560 V, the current through RB is evident larger, so that a reverse development can be achieved. When the voltage drop Vg in resistor RB is smaller than VM - Vp t, a large current flows in similar Wise through RA so that reversal development cannot be achieved. It is obviously that iVBI equals to effect a stable reversal development IVM - Vp'I should be.

Although in the case of the above embodiment, the higher charged sections have an opposite polarity to that of the less charged sections it is also possible to achieve reverse development when the less charged sections have the same polarity as the more highly charged sections. For example is it is suitable when using non-crystalline selenium as a photoconductor, VM y + 1200 V, Vp 2 + 800 V and Vp - + 200 V.

From the above examples it is clear that the process according to the invention then works if the voltage difference, taken in absolute terms, between the first charged areas and the second less charged areas is sufficient for Ensure contrast in the latent image.

The above embodiments have been described as if the first and second areas each have a uniform potential. However, this only happened to Ease of understanding and it should be noted that the waste of toner depending on the voltage difference between the relevant area of the photoconductor and the conductive shell varies.

In summary, it can be said that it will be an inverse development process executed with an inductively chargeable magnetic toner. One on a photoreceptor or photoconductor formed electrostatic latent image with first charged Areas and second less charged areas will develop negatively by a one-component, d. i.e., inductively chargeable magnetic Toner formed on a conductive shell containing a permanent magnet is, between the conductive shell and a support supporting the photoreceptor an electrical voltage is applied, which have the same polarity as the first charged areas of the latent image and not smaller than is the voltage between the latent image and the substrate, creating a development current through the toner brush between the conductive shell and the less charged areas of the latent image flows and the toner particles on the less charged areas be brought to attachment.

Claims (5)

Inverse development process using an inductively chargeable Toners PATENT CLAIMS Process for developing an existing on a carrier electrostatic image with inductively chargeable toner particles, the image is in the form of first charged areas and second less charged areas and the potential of the first charged areas in its absolute value is substantially higher than that of the second charged areas, g e k e n n z e i c h n e t by transporting the carrier onto an electrically conductive one Pad, the formation of a brush from toner particles on an electrically conductive one Surface, the impression of a voltage difference between the conductive surface and the conductive pad with the polarity of the first charged areas to the To keep the polarity of the charge of the toner particles the same as the polarity of the charge the first charged areas, and the adherence of the toner particles to the second less charged areas. 2. The method according to claim 1, characterized in that g e k e n n -z e i c h n e t that the applied voltage difference is not less than that between the first charged areas and the substrate. 3. The method according to claim 2, characterized in that g e k e n n -z e i c h n e t that the applied voltage difference is substantially equal to that between the first charged areas and the substrate. 4. The method according to claim 2, characterized in that g e k e n n -z e i c h n e t that the brush with the charged areas of the carrier being transported substantially is in touch. 5. The method according to claim 2, characterized in that g e k e n n -z e i c h n e t that the polarity of the first charged areas is opposite to that the second loaded area is selected. 6, the method according to claim 2, characterized in that it is indicated that the polarity of the first charged areas is the same as that of the second loaded areas is selected.