JPH022574A - Toner for electrophotography - Google Patents

Abstract

PURPOSE:To easily adjust the electrostatic charging quantity of toner without causing any other trouble by dispersing a conductive coloring agent which colors the toner, an electrostatic charging control agent which gives electrostatic charges, and conductive fiber in a binder resin agent which integrates respective materials constituting the toner. CONSTITUTION:In the binder resin agent which integrate the respective materials constituting the toner, the conductive coloring agent which colors the toner, the electrostatic charging agent which gives electrostatic charges, and conductive fiber are dispersed. The metallic fiber binds particles of the conductive coloring agent in the toner to lower the resistance value of the toner. The amount of the metallic fiber is adjusted so that the electrostatic charging quantity of the toner can be adjusted. Consequently, the electrostatic charging quantity of the toner is set uniformly to a desired value without causing any other trouble.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an electrophotographic toner used in electrophotographic apparatuses such as electrostatic transfer copying machines and laser printers.

[Conventional technology]

Conventional electrophotographic toner (hereinafter referred to as toner) consists of a styrene/acrylic binder resin that integrates the various materials that make up the toner, and a conductive colorant such as a carbon blank that imparts color to the toner. and a charge control agent that imparts chargeability to the toner. Then, these materials are mixed, melt-kneaded and dispersed appropriately, and the resulting kneaded material is ground into fine powder with a particle size of about 1 to 30 μm, and then classified into particles with a predetermined particle size. be done.

The amount of charge of the toner produced as described above is mainly determined by the amount of the charge control agent and the colorant, and is set by appropriately adjusting the amount of at least one of them.

[Problem to be solved by the invention]

However, although the amount of charge of the toner can be adjusted as described above, it is not possible to freely set the amount of carbon black as a charge control agent or colorant in order to obtain a desired amount of charge.

That is, when the amount of charge is adjusted by the amount of carbon blank, if the amount of carbon blank is too large, image fogging will occur, while if it is too small, the image density will be low, making it impossible to obtain an image with appropriate density.

On the other hand, even when the amount of charge is adjusted by the amount of charge control agent, if the amount of charge control agent is too large, for example, the charge control agent may migrate onto the carrier surface, causing so-called spent, where normal chargeability is lost. On the one hand, if there are too few,
Appropriate chargeability cannot be uniformly imparted to each toner. That is, uniform chargeability cannot be obtained, and the chargeability distribution becomes wide. For this reason, the conventional toner described above has a problem in that it is difficult to easily obtain appropriate chargeability.

[Means to solve the problem]

In order to solve the above-mentioned problems, the electrophotographic toner according to the present invention has a binder resin that integrates each material constituting the toner, and when imparting color, a colorant that is n-electrostatic and a chargeable colorant. This is a structure in which a charge control agent that imparts a charge and a conductive fiber are present.

[For production]

According to the above configuration, since the conductive fiber is present in the binder resin together with the colorant and the charge control agent, the amount of charge can be easily adjusted.

That is, the metal fibers connect particles of the conductive colorant in the toner and serve to lower the resistance value of the toner. Therefore, by adjusting the amount of metal fibers, the amount of charge on the toner can be adjusted. As a result, the amount of charge of each toner can be uniformly set to a desired value without causing other problems.

Incidentally, as the conductive fiber in letter L, carbon fiber, metal fiber, conductive coated glass fiber, etc. can be used. Also, the amount of conductive fiber added is 0.1% by weight based on the weight of the toner.
It is appropriate to set it to 10%.

[Example 1] An embodiment of the present invention will be described below.

Toner for electrophotography according to the present invention (hereinafter referred to as toner)
The toner consists of a binder resin that integrates the various materials that make up the toner, a conductive colorant that gives color to the toner, a positive charge control agent that gives the toner positive chargeability, and a toner that It is composed of a release agent that prevents offset caused by adhesion to the surface of the fixing roller of an electrophotographic device, and conductive fibers.

The above binder resin is styrene/acrylic resin (hereinafter S
t/Ac resin), carbon blank as a coloring agent, nigrosine as a positive charge control agent, polypropylene as a mold release agent, and metallic fiber as a conductive fiber. The blending ratio of each material used is 1ffl as shown in Table 1.

Table 1 A method for manufacturing the present toner having the above structure will be described below.

First, the materials shown in Table 1 above were mixed, and the mixture obtained by this mixing step was melted, kneaded, and integrated. After that, the integrated kneaded material is pulverized into particles,
By classifying the obtained particles, the average particle size is approximately 10μ.
m toner was obtained.

Next, as a toner for comparison with the toner according to the above-described example, a toner not containing metal fibers was produced in a similar manner. When the charge amount of this comparative toner and the toner according to this example was compared, the charge amount of the comparative toner was +20 μc/g, while the charge amount of the toner according to this example was +20 μc/g. +10 μ (7 g).

As is clear from the above results, since the toner according to this example contains 1 part by weight of metal fibers as conductive fibers, the charge amount is higher than that of the comparative toner that does not contain metal fibers. is reduced by 10 μc/g. As a result, by adding an appropriate amount of metal fiber, it is possible to easily set the toner charge to an appropriate value without causing the disadvantages of adjusting the charge amount by adjusting the amount of charge control agent or carbon blank. I know what I'm getting.

[Example 2] Other embodiments of the invention will be described below.

The toner according to this embodiment uses carbon fiber as the conductive fiber, and the other configurations are the same as the toner according to the first embodiment.

The blending ratio of each material used is as shown in Table 2.

Similarly, a toner having an average particle size of about 11 μm was obtained through the following steps: mixing, melting, kneading, crushing, and classification.

When the charge amount of the above toner was examined, it was found to be +9 μc/g. [Example 3] Another example of the present invention will be described below.

The toner according to this embodiment uses a conductive coated glass fiber as the conductive fiber, and the other configurations are the same as the toner according to the first embodiment. The blending ratio of each material used is as shown in Table 3.

(Left below) In the above configuration, each material shown in Table 2 is
Therefore, by adjusting the amount of metal fibers, the amount of charge on the toner can be easily adjusted without any other adverse effects. Thereby, the amount of charge of each toner can be uniformly set to a desired value. Therefore, by using the toner of the present invention, it is possible to obtain images with good image quality.

In the above configuration, toners having an average particle size of about 10 μm were obtained in the same manner using each +A material shown in Table 3.

When the charge amount of this toner was examined, it was found to be +11 μC/g. [Effects of the Invention] As described above, the electrophotographic toner of the present invention has a binder resin that integrates each material constituting the toner. It has a structure in which a conductive colorant that imparts color, a charge control agent that imparts chargeability, and conductive fibers are interspersed.

Claims (1)

[Claims] 1. A conductive coloring agent that imparts color, a charge control agent that imparts chargeability, and conductive fibers are interspersed in the binder resin agent that integrates each material constituting the toner. An electrophotographic toner featuring: