JPH01113779A - Magnetic printer - Google Patents

Abstract

PURPOSE:To obtain a superior safety and sanitary property and durability and to facilitate maintenance management by using a magnetic drum in which an 'Alumite(R)' magnetic coat is formed as a recording medium. CONSTITUTION:The magnetic drum 30 is a cylindrical one made of aluminum, and the 'Alumite(R)' magnetic coat 32 is formed on the surface. The coat 32 is the one in which iron that is magnetic metal is filled in the pore 36 of an 'Alumite(R)' coat 34. On a uniform magnetizing unit 38 provided at one side part of the drum 30, two permanent magnets 38a and 38b are provided opposite ly, and the permanent magnet 38b on one side is arranged in the drum 30. A patterning unit 40 is provided at the downstream side of the drum 30 in a rotational direction, and demagnetization is performed by heating the non- pattern part of the coat 32 over a Curie point by performing scan by a laser beam, and the laser beam is turned ON and OFF corresponding to the pattern of an original. After that, developing is performed in a developing unit 42 by a magnetic brush developing method.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application J] The present invention relates to printing devices such as copying machines, printers, and facsimiles that utilize magnetism.

"Prior Art" Conventionally, a copying machine having the structure shown in FIG. 3 has been widely used as a printing device.

This copying machine uses photoconductive phenomena to form an electrostatic charge image (latent image) on a recording medium, and then attaches colored charged fine particles (toner) to the latent image using electrostatic attraction to create a visible image. With the device,
A photoconductor drum I, which is a recording medium, and a corona charger 3,
It is composed of a photoimage exposure unit 5, a developing unit 7, a transfer section 9, a static elimination lamp 11, a cleaner 13, and an optical static elimination unit 15.

Next, the operation of this copying machine will be explained.

First, the surface of the photoconductor drum 1 is uniformly charged by the corona charger 3. Then, the photoimage exposure unit 5 irradiates light so that an electrostatic latent image 17 corresponding to the design of the document remains on the surface of the photoconductor drum l. Next, in the developing unit 7, toner is attached to the electrostatic latent image 17, and a toner image 19 is formed on the surface of the photoconductor drum l. This toner image 19 is electrostatically transferred onto the recording paper 21 by the transfer section 9. A fixing device 23 applies heat, pressure, etc. to the toner transferred onto the recording paper 21 by the transfer unit 9, and the toner image 19 is fused to the recording paper 21.

``The residual toner on the photoconductor drum I is removed by the cleaner I3, and at this time the surface potential of the drum I is lowered to near zero potential by the static eliminating lamp 11 to help the cleaning effect. Further, the surface potential of the entire photoconductor drum 1 is lowered by a photostatic charge eliminating section 15 provided immediately before the corona charger 3.

"Problems to be Solved by the Invention" Such conventional printing apparatuses have the following problems.

■ Since corona is used to uniformly charge the photoconductor drum l, harmful ozone is generated.

(2) Since the strength of the photoconductive layer forming the surface of the photoconductor drum I is weak, the life of the drum I is short.

For example, a photoconductive layer made of Se-Te has a printing durability of about 50,000 sheets, and a photoconductive layer made of an organic photoconductor (OPC) has a printing durability of about 20,000 to 30,000 sheets.

It is possible to improve the printing durability of the drum l by forming the photoconductive layer with amorphous silicon, but in this case, C
The process of film formation, doping, etc. by the VD method is complicated and requires a lot of equipment, leading to a problem of rising manufacturing costs.

"Means for Solving the Problems" The magnetic printing device of the first invention uses a magnetic drum in which a recording medium is provided with an alumite magnetic film.

The magnetic drum constituting the printing device of the first invention may be made entirely of aluminum; however,
It can also be constructed by fitting a cylindrical aluminum material to the outer periphery of a core material made of another material. In this case, it is desirable to use a material with excellent heat resistance or good heat conductivity as the material forming the core material. Further, although this magnetic drum may have a solid cylindrical shape, it is preferable that it has a hollow cylindrical shape in order to reduce the weight.

The alumite magnetic film formed on the surface of this magnetic drum is made by filling the bores of a porous film made of aluminum oxide with magnetic material, so by controlling the diameter and depth of the bores, the coercive force and magnetic flux can be increased. Magnetic properties such as density can be controlled arbitrarily.

The magnetic material filled in the bore of the alumite film includes iron,
Cobalt, nickel, and alloys thereof are preferably used. Among these, iron is most preferable because it has a large saturation magnetization.

A magnetic printing device according to a second invention includes the magnetic drum according to the first invention, a uniform magnetization unit that uniformly magnetizes the alumite magnetic coating of the magnetic drum, and a uniformly magnetized portion of the alumite magnetic coating. a patterning unit that forms a latent image on the
A developing unit brings magnetic toner into contact with an alumite magnetic film and causes the toner to adhere to the latent image area.

The above-mentioned - type magnetization unit uniformly magnetizes the alumite magnetic coating of the magnetic drum. The magnetization by the −-like magnetization unit may be performed using an in-plane magnetization method, but a perpendicular magnetization method that can increase the recording density is preferably used.

In the case of the perpendicular magnetization method, a magnetic field is applied to the alumite magnetic film in the vertical direction of the film by a uniform magnetization unit. As a uniform magnetization unit for perpendicular magnetization, a magnetic head for perpendicular magnetic recording can be used, but two permanent magnets are provided inside and outside a magnetic drum so that the north and south poles face each other. Also good.

The above-mentioned patterning unit forms a magnetically charged image (latent image) corresponding to the design of the document on the alumite magnetic film of the magnetic drum.The patterning unit forms a magnetically charged image (latent image) corresponding to the design of the document on the alumite magnetic film of the magnetic drum. ) is demagnetized to form a latent image. Demagnetizing the non-patterned portions of the alumite magnetic film can be carried out using a demagnetizing head, but it can also be done by means of heating the non-patterned portions to a temperature higher than the Curie point.

When demagnetizing by heating in this way; when iron is used as the magnetic material forming the alumite magnetic film, 77
1131 when cobalt is used above 0℃
358 °C or higher and when nickel is used.
Heat the non-patterned part of the alumite magnetic coating to a temperature above ℃.

Demagnetization by heating is preferably performed by scanning a laser beam. By focusing the laser beam on a small spot, a small area of the magnetic drum is instantaneously heated and immediately cooled, so the thermal effect on the drum as a whole can be reduced. In alumite magnetic coating, extremely thin cylindrical blocks of magnetic material are embedded in aluminum oxide (alumite), which is a thermally stable ceramic, and are distributed at a high density of hundreds of millions per mm'. Therefore, when a small spot laser beam is scanned over the alumite magnetic film, blocks of magnetic material are individually demagnetized to form a highly accurate latent image.

The developing unit causes toner to adhere to the magnetic drum on which the latent image is formed as described above. In this printing device, toner is attracted to the latent image portion of the magnetic drum by magnetic force. For this reason, it is preferable to use a toner in which magnetic powder is mixed or a toner in which magnetism is imparted to the toner itself. The developing unit of this printing device has
Known mechanisms such as a fur brush development method and a pressure development method can be used, and among them, a magnetic brush development method using magnetic powder as carrier particles is preferably used.

The toner thus attached to the latent image portion forms a toner image. This toner image is then attached to the recording paper and then fixed onto the recording paper.

Excess toner remaining on the magnetic drum after the toner image has been transferred is removed by a cleaning section.

The cleaning section may be provided between the transfer section and the uniform magnetization unit, but may also be provided between the negative magnetization unit and the developing unit. When a cleaning section is provided between the transfer section and the uniformly magnetized unit, a demagnetization mechanism is attached as necessary. As the demagnetization mechanism, a mechanism for heating the alumite magnetic film to a temperature above the Curie point or a demagnetization head can be used.

In a printing device with such a configuration, the alumite magnetic coating on the magnetic drum is uniformly magnetized by the uniform magnetization unit, and then the non-patterned portion is demagnetized by the patterning unit, so that the image of the document is formed on the drum surface. A corresponding latent image is formed. Then, toner is magnetically attached to this latent image portion by a developing unit provided at the next stage, thereby forming a toner image. This toner image is transferred to recording paper and printing is completed.

"Embodiment" Next, an embodiment of the magnetic printing apparatus of the first and second inventions will be described in detail with reference to FIGS. 1 and 2.

Reference numeral 30 in the figure is a magnetic drum. This magnetic drum 3
0 is a cylindrical one made of aluminum, and an alumite magnetic film 32 is formed on its surface as shown in FIG. This alumite magnetic film 32 is formed by filling the pores 36 of the alumite film 34 with iron, which is a magnetic metal.

A negative magnetization unit 38 is provided on one side of the magnetic drum 30 . This --like magnetization unit 38 is provided with two permanent magnets 38a and 38b facing each other, and one of the permanent magnets 38b is arranged inside the magnetic drum 30. Further, the tip of one permanent magnet 38b is formed thinner than the other permanent magnet 38a. On the downstream side in the rotational direction of the drum 30 (hereinafter abbreviated as downstream side) from the part where the --like magnetization unit 38 is provided,
A patterning unit 40 is provided. The patterning unit 40 scans a laser beam to heat the non-patterned portion of the alumite magnetic film 32 to a temperature above the Curie point to demagnetize it, and the laser beam is turned on and off in accordance with the pattern of the original.

A developing unit 42 is provided downstream of the patterning unit 40. This developing unit 42 uses a magnetic brush developing method, and contains magnetic toner made of two components: carrier particles made of magnetic powder and pigment.

On the downstream side of the developing unit 42, a transfer section 44 and a cleaning section 46 are sequentially provided. In addition, the transfer section 4
A fixing section 48 is provided on the side of 4.

In this printing apparatus, first, the alumite magnetic film 32 of the magnetic drum 30 is uniformly magnetized by the uniform magnetization unit 38, and then the non-pattern portion A is demagnetized by the patterning unit 40. As a result, a latent image B corresponding to the design of the document is formed on the surface of the drum 30.

Then, toner is applied to this latent image B by a developing unit 42 provided at the next stage. The attached toner forms a toner image C. This toner image C is transferred to the transfer section 44.
is transferred to recording paper. And the transferred toner image C
is fixed on the recording paper by means such as heating in the fixing section 48.

Toner remaining on the surface of the magnetic drum 30 that has passed through the transfer section 44 is removed by a cleaning section 46 . Then, the cleaned portions of the magnetic drum 30 are sequentially re-magnetized by the --like magnetization unit 38, and the above operation is repeated.

"Effects of the Invention" Since the magnetic printing device of the first invention uses a magnetic drum provided with an alumite magnetic film as a recording medium, there is no need to perform corona charging to form a latent image.

Therefore, no harmful ozone is generated, which is excellent in terms of safety and health.

In addition, the alumite magnetic coating of the magnetic drum provided in the magnetic printing device of the first invention has a high surface strength and excellent printing durability, so the magnetic printing device of the first invention has excellent durability. It is excellent and easy to maintain and manage.

Further, in the magnetic printing device of the first invention, if the magnetic drum is made of aluminum, the alumite magnetic film can be directly processed by alumite treatment on the surface, so it can be manufactured at a relatively low cost. .

Furthermore, in the magnetic printing apparatus of the first invention, since the latent image is formed by magnetic charges, if a -degree latent image is formed, toner can be attached to the latent image many times. Therefore,
If the magnetic printing device of the first invention forms a -degree latent image,
-By temporarily suspending the operation of the magnetizing unit, etc.,
Since it can print multiple sheets, it can also be used as a printing machine.

In addition, the alumite magnetic coating can obtain arbitrary magnetic properties by controlling the bore structure such as bore diameter and bore depth, and the type of filling metal, so according to the first invention, magnetic properties with desired performance can be obtained. It is easy to manufacture a type printing device.

Further, according to the magnetic printing device of the second invention, the same effects as those of the magnetic printing device of the first invention can be obtained, and there is an advantage that a latent image can be formed on the alumite magnetic film at high speed.

[Brief explanation of the drawing]

FIG. 1 is a schematic configuration diagram showing the configuration of an embodiment of the magnetic printing apparatus of the present invention, FIG. 2 is an enlarged view showing the alumite magnetic coating portion of the magnetic drum of the same embodiment, and FIG. 3 is a diagram of the conventional magnetic printing device. 1 is a schematic configuration diagram showing the structure of a copying machine as a printing device. 30... Magnetic drum, 32... Alumite magnetic film, 38... --like magnetizing unit, 40... Patterning unit, 42... Developing unit, A... Non-pattern portion, B...・Latent image.

Claims (3)

[Claims] (1) A magnetic printing device characterized in that a magnetic drum on which an alumite magnetic film is formed is used as a recording medium. (2) A magnetic drum on which an alumite magnetic film is formed;
A uniform magnetization unit that uniformly magnetizes the alumite magnetic coating of this magnetic drum, a patterning unit that demagnetizes a part of the uniformly magnetized portion of the alumite magnetic coating to form a latent image, and an alumite magnetic coating unit that uniformly magnetizes the alumite magnetic coating. A magnetic printing device comprising a developing unit that brings magnetic toner into contact with the film and adheres the toner to the latent image area. (3) A patent characterized in that the patterning unit demagnetizes a portion of the alumite magnetic film other than a portion where a latent image is to be formed by heating it to a temperature higher than the Curie point of the magnetic material constituting the alumite magnetic film. A magnetic printing device according to claim 2.