DE2361418A1 - METHOD AND DEVICE FOR DEVELOPING AN ELECTROSTATIC LATENT IMAGE - Google Patents

Description

Applicant: Oce-van der Grinten NV , po box ΙΟΙ, Venlo / Holland, St. Urbanusweg 102

Process and apparatus for developing
an electrostatic latent image

The invention relates to a method and apparatus for developing an electrostatic latent image thereon insulating surface.

A number of such methods are already known
which are developed with the help of a cascade, a magnetic brush, a liquid and an electron donor.
In the usual processes, a developer is used which consists of a mixture of insulating toner particles and a carrier material in which the toner particles adhere by friction
be charged to the carrier material. In such systems, however, there is the problem that the mixture of toner particles and carrier material must be kept homogeneous, that a constant ratio of toner particles to carrier material and a
constant particle size must be present so that good development is guaranteed.

• A well-known process in which such a system
with two components is not required, there is the

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transferring a layer of insulating toner particles to a suitable surface from which the toner particles are charged a corona discharge, or with the aid of an electric field, from the transfer of the charged toner particles to a donor surface with the help of an electric field, after which the toner particles on the donor surface become latent electrostatic Image to be exposed. However, this known process (US Pat. No. 2,839,400) has the disadvantage that the process is not suitable for a continuous and rapid way of working. Therefore, the invention is intended to provide a method and a Device are created, so that the difficulties mentioned can be largely avoided.

This object is achieved in a method of developing an electrostatic latent image on an insulating Surface solved in that

a) a brush-like layer of magnetically attractable, fusible Toner particles with a resistivity between 10 and 10 ohm · cm by a magnetic system in the direction a transfer zone existing between the magnetic system and a conductive donor surface is;

b) the toner particles during their transport through a potential difference charging generated between the magnetic system and the conductive donor surface;

c) the emerging from the magnetic system magnetic field in the vicinity of the transfer zone is changed in such a way that the Forces of attraction that hold the toner particles on the magnetic system through which forces of attraction are overcome, which are due to the potential difference, so that a part of the toner particles electrostatically from the magnetic system transferred to the conductive donor surface;

d) the transferred part of the charged toner particles with the conductive donor surface in the direction of a developer zone insulating surface bearing the electrostatic latent image, and

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e) the portion of the charged toner particles in the developer zone contacted with the electrostatic latent image to imagewise remove toner particles from the conductive donor surface to the surface bearing the latent image under the influence of electrostatic attractive forces, which proceed from the latent image.

An apparatus for the continuous implementation of this process is characterized according to the invention in that

a) a magnetic brush consisting of a magnetic element in a circulating member that has a conductive surface that is endless in the path of circulation, which is conductive Surface made of magnetically attractable fusible toner particles with a specific resistance between 10 and 10 Ohm - cm have;

b) a donor member with a circulating conductive surface, which is endless in the path of circulation, is placed a short distance from the magnetic brush to form a transfer zone? *

c) a voltage source for generating an electric field between 3000 and 10000 volts per cm in the transmission zone between the circulating surfaces of the magnetic brush and the donor member is provided; and

d) a movable electrostatic image bearing member is provided adjacent the donor member to provide a second transfer zone to build. .

The toner particles can be removed from the magnetic brush by one Feed hopper or by passing the brush in a storage container are fed.

The magnetic devices are expediently in place The magnetic brush consists of a rotating conductive cylinder or an endless belt and a magnetic element that is bipolar or multipolar, and can have a surface texture

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Rotate speed, which is different from the surface speed of the surrounding rotating conductive cylinder or endless belt is different, or can be stationary with a pole in the Direction of the transfer zone between the magnetic brush and the Donor be arranged. With such a magnetic element, there are attractive forces that the toner particles exert the magnetic device and the magnetic or cohesive forces may be considerable in the transfer zone decreased.

Preferably the magnetic device consists of a stationary multipolar magnetic element in one circulating conductive cylinder or an endless belt, there with such a device it is possible to transfer the charged toner particles from the lower part of the toner layer to the To move the surface of the layer and move the uncharged toner particles to the lower part of the layer, around the charging time to reduce. Therefore, the magnetic field can also be changed by moving toner particles through a stationary inhomogeneous magnetic field are moved. In this way, the toner particles are exposed to a changing magnetic field, although the field is stationary.

The specific resistance of the toner particles must be between 10 and 10 ohm · cm. With smaller resistances the toner particles quickly discharge onto the donor surface and get back to the magnetic brush, or do not get sufficient Charge sufficient for good transfer to the electrostatic latent image. At higher resistances development can only be carried out very slowly because the toner particles are charged very slowly. Toner particles with a uniform or nearly uniform particle size below 50 microns, preferably between 10 and 35 microns, are well suited. Preferably, each toner particle contains a magnetically attractable component and an insulating component from binding agent 1.

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Suitable magnetically attractable components are iron, Cobalt, nickel, alloys thereof. Alloys of other metals and oxides such as hematite and ferromagnetic ferrites.

The insulating binder may be any thermoplastic resin having a specific resistance greater than 10 Ohm · cm. Suitable thermoplastic resins are cellulose nitrate, cellulose acetate, ethyl cellulose, polyamides, polyvinyl acetate, Polyvinyl chloride, polyvinyl formal, novolak, melamine formaldehyde resins, Epoxy resin, polyester or silicone resin. When particles made of such a resin and a magnetically attractable material have a specific resistance of more than 10 ohm · cm, the resistivity can be increased by incorporating a conductive material such as carbon black in the particles or can be reduced by coating particles with such a conductive material.

The ratio of binder to magnetically attractable material can be within a relatively wide range although the toner particles preferably contain between 20 and 70 percent by weight magnetically attractable material.

The conductive donor surface is part of a rotating one Roller, drum, endless belt or the like and is made of a conductive material. Cylinders or foils made of copper or another metal, metallized plastic foils, metallized paper or conductive rubber materials can be used as such conductive materials. The donor surface becomes like this in close proximity to the magnetic brush arranged so that the toner particles on the brush and the donor surface do not come into contact with each other. Usually a slot up to 5mm is satisfactory, although slots with a width between 2 and 3 mm are preferred.

The conductive parts of the donor and the magnetic brush are connected to a voltage source through which a direct

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voltage between 600 and 50OO volts is applied to an electrical Field between 3000 and 10000 volts per cm in the transmission zone to create. An electric field of 3000 volts per cm is required to produce a toner with a specific resistance of 10 ohm · cm to charge and transfer, and a field strength of 10,000 volts per cm is required to use a toner

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a specific resistance of 10 0hm · cm and transferred to. The donor surface must be the positive electrode when the electrostatic latent image is positive and the negative electrode when the electrostatic latent image is negative.

The electrostatic latent image can be formed in various ways, for example, by electrophotographic processes, in which a uniformly charged photoconductive layer is charged in the dark and is imagewise exposed with a radiation _f to discharge the photoconductive layer in the exposed areas. The photoconductive layer can be formed in a manner known per se, optionally contain a binder, be suitable for an indirect or direct electrophotographic process and can consist of materials such as selenium, cadmium sulfide, zinc oxide or an organic photoconductive material and can be on a suitable conductive support such as Metal, conductive plastic or paper can be applied and can have the shape of a cylinder, an endless belt or a plate. The electrostatic latent image can also be formed by forming a charge pattern on an insulating surface by an electrode located near the insulating surface or by charging a pattern of insulating portions on a conductive surface, which is used, for example, for reproduction purposes.

The electrostatic latent image is positioned such a small distance from the donor surface that the Charge toner on the donor surface practically in contact with

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the picture stands. A bias can be applied between the donor surface and applied to the electrostatic latent image carrier to cause a transfer of charged toner to the to prevent parts that do not match the picture. The preload can be increased to such a value that a reverse electrostatic latent image is the result which to a negative image can be developed with an appropriate toner can.

Based on the drawing, an embodiment of the invention is intended explained in more detail. The single figure shows a schematic representation of a continuously operating device according to the invention for developing electrostatic latent images.

The apparatus includes a magnetic brush 1, which consists of a layer of toner 2 on a copper cylinder 3 in the arrow direction at a surface speed of 10 m rotates per minute, as well as (not shown) of a stationary multi-polar electromagnet which is arranged in the copper cylinder. 3

14 The toner has a specific resistance of 10 ohms - cm and consists of iron carbonyl parts that are bonded with an epoxy resin (Epikote 1004), which material is coated with carbon- is coated with particles. The particles contain 1.5 percent by weight Resin: and 0.12 weight percent carbon per part iron carbonyl. The magnetic brush is supplied with toner from a storage container 4, on which a knife-shaped scraper 5 is provided to making a magnetic brush with a layer of toner more uniform Ensure thickness. The toner layer 2 is transported to the donor 6, which consists of a copper cylinder, which rotates at a surface speed of 3 m per minute, During transport, the toner is positively charged in the electric field created by a voltage of 2 kV is generated by the voltage source 7, the negative electrode with the donor 6 and the positive electrode with the conductive Copper cylinder 3 is connected. The charged toner is from

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the cylinder 3 is transported to the donor 6, which cylinder and donor form a slot 3mm high. The charged toner on the donor 6 becomes the negative latent one electrostatic image transported on the photoconductive coating 8 of the rotating conductive drum 9 and with the negative latent electrostatic image brought into contact - A voltage source 10 with a voltage of 400 volts is used for application a bias between donor 6 and conductive drum 9 to prevent transfer of toner to outside of the image to prevent lying areas of the photoconductive layer. The part of the toner particles that are not on the latent electrostatic Image transferred is removed from the donor surface by a knife II. A transfer of the powder image on ordinary paper and the fixing device is not shown, since this can be done in a manner known per se, for example by transmission in an electric field and by fixing with heating by infrared radiation.

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Claims (3)

Claims IJ Method of developing an electrostatic latent image ι on an insulating surface, characterized in that a) a layer of magnetically attractable fusible toner particles with a specific resistance between 10 and 10 ohms - cm through a magnetic system in the direction of a Transfer zone is transferred between the magnetic System and a conductive donor surface; b) the toner particles during their transport due to a potential difference charged applied between the magnetic system and the conductive donor surface; c) the magnetic field strength resulting from the magnetic system emerges, so changed in the vicinity of the transfer zone is that the forces of attraction by which the toner particles are held on the magnetic system by the forces of attraction be overcome, which are caused by the potential difference, so that a part of the toner particles electrostatic is transferred from the magnet system to the conductive donor surface ία) the transferred part of the charged toner particles with the conductive donor surface are transported in the direction of the developer zone of the insulating surface, which carries the electrostatic latent image; and e) this part of the charged toner particles in the developer zone contacted with the electrostatic latent image for imagewise transfer of toner particles from the senior. Donor surface to the latent image bearing surface under the influence of the electrostatic Carry out attractive forces that emanate from the latent image. 409825/1042 236U18 2. Device for the continuous implementation of the method according to claim 1, characterized by äj a magnetic brush (1) that has a magnetic element inside a rotating member (3) having a conductive surface which is endless along the direction of movement is, which conductive surface is a layer (2) of magnetically attractable fusible toner particles with a specific Resistance between 10. and carries 10 ohm · cm; b) a Danator member (6) with a rotating conductive surface, which is endless in the direction of movement and is arranged closely adjacent to the magnetic brush, forming a transfer zone is; c) a voltage source (7) for generating an electric field of 3000-10000 volts per cm in the transmission zone between the rotating surfaces of the magnetic brush (1) and the donor member (6); and d) a movable electrostatic image bearing member (9), which is arranged at a short distance from the donor member (6) is to form a second transfer zone. 3. Apparatus according to claim 2, characterized by a stationary multipolar magnetic element with one pole in the direction of the transfer zone between the magnetic brush and the donor member.