JPS6210757Y2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a device for removing toner firmly adhered to a magnetic recording medium in a magnetic printing device, and particularly to a device having an improved cleaning blade.

In the field of conventional electrostatic copying machines, this type of cleaning device uses a rotating brush made of rabbit hair, viscose, etc.
-25237 JP-A-50-500043 Rubbers such as those proposed in JP-A-50-14892 and JP-A-50-17130, etc.
Methods using elastic blades made of synthetic resin, etc. have been put into practical use, but in magnetic printing devices, these methods cannot completely remove residual toner firmly attached to the magnetic recording medium, so the recording head has to be removed. Contamination caused recording unevenness and the inability to record. Further, when the circumferential speed of the magnetic recording medium is about 1 to m/sec, knife edges made of rubber, synthetic resin, etc. lack strength and become unusable.

In an electrostatic copying machine, after toner is transferred from a photoreceptor drum to a recording paper, the entire surface of the photoreceptor drum is irradiated with light to erase an electrostatic latent image on the photoreceptor drum, and then cleaning is performed. That is, due to erasing, the electrostatic attraction force between the toner and the photosensitive drum is almost nonexistent or extremely small. Therefore, the toner could be easily removed using the method described above. However, the situation is completely different when attempting to make multiple copies without erasing the magnetic latent image in a magnetic printing device. To make multiple copies, the processes of development, transfer, and cleaning are repeated without erasing the magnetic latent image once recorded.

That is, during cleaning, the toner is strongly attracted to the magnetic latent image on the magnetic recording medium (printing drum) by magnetic attraction. The toner is transferred to the recording paper because the electrostatic attraction of the transfer roller overcomes the magnetic attraction of the magnetic recording medium, but even so, only toner groups located relatively far from the magnetic recording medium are transferred. The toner in the surface layer portion of the magnetic recording medium that is in close contact with the magnetic recording medium remains untransferred. This residual toner is not easy to remove because it is strongly attracted to the magnetic latent image on the magnetic recording medium. If even a small amount of toner remains, it will adhere to the abutting gap of the magnetic head that is in contact with or in close proximity to the magnetic recording medium, creating bridges, making magnetic recording impossible or significantly reducing recording efficiency. Furthermore, the residual toner increases the gap between the magnetic recording medium and the magnetic head, making magnetic recording impossible or significantly reducing recording efficiency. The magnetic head has a holder portion around the magnetic core that is considerably larger than the magnetic core, but even if the holder portion rides on residual toner, the gap between the magnetic core and the magnetic recording medium increases.

That is, magnetic printing devices require extremely thorough cleaning, and this has been one of the major obstacles preventing magnetography technology from being put to practical use.

The cleaning device according to the present invention was devised against this background, and enables complete cleaning without erasing the magnetic latent image.

A detailed explanation will be given below with reference to the drawings.

FIG. 1 shows an embodiment of a magnetic printing apparatus equipped with the present invention, in which 1 indicates Co-Ni, Co-Ni-P, Co-P
A magnetic latent image recorded on the printing drum 1 by the recording head 15 using a magnetic recording medium plated with a metal magnetic thin film (hereinafter referred to as a printing drum when formed on a drum) is developed by the developer 2. The image is formed into an image, transferred onto a transfer paper 5 by a transfer roller 3, and fixed by a fixing device 4. Printing drum 1 without being transferred
The toner remaining on the surface is scraped off by a cleaning blade 13 made of a thin plate of brass, phosphor bronze, or the like. The toner accumulated at the tip of the cleaning blade 13 is vacuum-suctioned by the vacuum box 7 and collected by the filter 6. As shown in FIGS. 1 and 3, the cleaning blade 13 is sandwiched between the cleaning blade press plate 10 and the cleaning support rod 12, and is firmly fixed to the cleaning support rod 12 with screws 30. The cleaning blade support rod 12 is rotatably held at both ends, and is configured so that the contact pressure and contact angle between the printing drum 1 and the cleaning blade 13 can be optimally set by adjusting screws 11. When the printing drum 1 rotates in the direction of the arrow as shown in FIG. 2, the angle θ formed between the cleaning blade 13 and the printing drum 1 depends on the metal material used, the plate thickness, and the length l of the blade. It varies but must be set at an acute angle. As an example, when a brass plate with a thickness of 0.05 mm and l=9 mm is used, θ is 15° to 25°.

When the cleaning blade 13 is made of known synthetic rubber or natural rubber, the cleaning blade not only rides on the toner firmly adhered to the magnetic recording medium, but also becomes useless for cleaning.
It has also been observed that the contact pressure of the cleaning blade causes the toner to be crushed on the recording medium, resulting in the opposite effect of strengthening the adhesion.
This difficulty could be overcome by using a cleaning blade made of a thin metal plate. However, since this metal blade has a strong toner removal force, it also exerts a strong sliding force on the magnetic recording medium, which may damage the magnetic recording medium. As a result of experiments, when a magnetic recording medium coated with γ-Fe ₂ O ₃ was used, the damage was severe and the life of the magnetic recording medium was significantly shortened. On the other hand, when using a magnetic recording medium plated with a metal magnetic thin film such as Co-Ni-P, or a protective plated metal non-magnetic thin film such as Ni-P or hard Cr, it is practically impossible. The material, shape, etc. of the cleaning blade could be selected so that damage could be ignored.

Optimal materials include brass, phosphor bronze, beryllium copper, stainless steel copper plate for springs, nickel silver, titanium plate, etc.
It has been experimentally confirmed that the optimal blade thickness is approximately 0.03 mm to 0.5 mm.

The thin metal plate serves as a blade with a sharp cut edge and as an elastic material, so it can be supported with a simple structure and is easy to manufacture. In addition, although the cleaning blade wears out at the part where it rubs against the magnetic recording medium, since it is a thin plate, it does not need to be resharpened and can be used as is, so it has a long life.

FIG. 4 shows another embodiment of the cleaning device of the present invention. If the cleaning blade 13 is kept in contact with the printing drum 1 during latent image recording, it acts as a friction brake and absorbs rotational fluctuations of the printing drum 1.

However, in magnetic printing devices, the circumferential speed of the printing drum 1 when recording latent images can reach as much as 20 m/s, so it is difficult to record latent images during such high-speed recording. By first reducing or reducing the contact pressure between the printing drum 1 and the cleaning blade 13 using the solenoid 17, the load on the motor (not shown) is reduced and high-speed recording is made possible.

FIG. 5 shows yet another embodiment. A metal block 31 is used as a cleaning blade and is supported via an elastic material 32. Although such a structure can also achieve the purpose of cleaning, the structure shown in FIGS. 1 to 4 is superior in terms of structure, difficulty in manufacturing, lifespan, etc.

As explained above, by using the cleaning device according to the present invention, toner does not accumulate on the printing drum, and even after repeated copying operations, a clear and uniform latent image can be recorded. .

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional view of a magnetic printing device equipped with a cleaning device of the present invention. FIG. 2 is a setting diagram for a magnetic recording medium of the cleaning device of the present invention. FIG. 3 is a plan view of the cleaning device of the present invention. Figures 4 and 5
The figure shows another embodiment of the cleaning device according to the present invention. 1...Magnetic recording medium, 2...Developer, 3...Transfer roller, 4...Fixer, 5...Transfer paper, 6...
Filter, 7...Vacuum box, 10...Cleaning blade holding plate, 11...Adjustment screw, 12...
Cleaning blade support rod, 13... Cleaning blade, 14... Erasing head, 15... Recording head, 16... Pressure spring, 17... Solenoid, 30... Holding screw, 31... Metal block,
32...Elastic material.

Claims (1)

[Claims for Utility Model Registration] (1) A metal blade that comes into contact with a magnetic recording medium to scrape off toner adhering to the recording medium, and a vacuum box that vacuum sucks the scraped toner. . A cleaning device for a magnetic printing device, wherein a tip of the blade protrudes from a suction port of the vacuum box. (2) Utility Model Registration In the apparatus according to claim (1), the magnetic recording medium has a surface made of metal, and the blade is a thin metal plate. cleaning equipment.