JPH03294589A - Treatment of unclassified waste information-recording paper - Google Patents

Abstract

PURPOSE:To effectively decolor unclassified waste information-recording paper, especially back-carbon paper, to a state reusable as a paper-making material without classification by using an oxidation bleaching agent in bleaching step. CONSTITUTION:In the treating process of unclassified waste information- recording paper comprising a maceration step, a kneading step, a flotation step, a washing step and a bleaching step, an oxidation bleaching agent is used in the bleaching step to effectively decolor a back carbon paper (blue ink). Preferably, the paper bleached with the oxidation bleaching agent is subsequently further bleached with a dithionite.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a processing method for reusing waste information recording paper as a raw material for papermaking without sorting it into each recording paper, and in particular This invention relates to a method for recovering pulp that can also be used as a raw material for paper.

[Conventional technology]

In recent years, from the perspective of resource and environmental protection and urban waste countermeasures,
There is a growing momentum to promote the use of recycled paper. A particular problem here is waste information recording paper discarded from offices and the like. This kind of waste paper is
It consists of toner prints from electrophotographic copiers and one-way printers, carbonless copy paper, facsimile thermal paper, carbon-backed copy paper, etc.

Among these information recording waste papers, carbonless paper is used.

Thermal paper and carbon-backed paper are considered contraindicated because if they are mixed with general waste paper, the recovered pulp will be colored or colored spots will appear. Further, toner-printed waste paper is extremely insufficiently deinked by a general deinking method consisting of IW solution, flotation, and washing.

In this way, it can be said that all information recording paper is waste paper that is difficult to remove ink.

For the above-mentioned types of waste information recording paper, individual processing methods are known.

Regarding toner-printed waste paper, for example, as described in Paper and Pulp Technology Times, 31(8), 25 (1988), by adding a process of kneading disintegrated waste paper at a high concentration, toner printing can be performed. Efficient separation and removal of dust is possible.

Regarding the treatment method of carbonless waste paper,
3991, JP-A-60-231889. Japanese Unexamined Patent Publication No. 55-
98990.

It is disclosed in JP-A-55-6580, JP-A-54-138605, and Tappi, 62(7), 27 (1979). What these have in common is that they include disintegration, flotation, and bleaching steps. Regarding the types of bleaching agents used in the bleaching process, it is said that sodium hypochlorite, sodium dithionite, chlorine, or hydrogen peroxide, each singly or in combination, are effective.

At present, no effective processing technology has been established for waste paper such as thermal paper and carbon-backed paper.

[Problems to be Solved by the Invention] As described above, methods for individually processing specific waste information recording papers are known to a certain extent. However, waste information recording paper generated from offices and the like is a mixture of various materials, and sorting it is difficult and requires a great deal of effort. Therefore, there is a need for a method for collecting and processing the unsorted materials, but the reality is that no attempt has been made to reuse them yet.

The inventors of the present invention have conducted intensive studies on methods for disposing of unsorted waste information recording paper, and have found that back carbon paper (blue ink) is particularly problematic. That is, if even a small amount of this is mixed in, the entire pulp will be colored blue, and it is difficult to remove it using normal deinking methods. When using carbon-backed paper alone, the ink can be removed relatively easily by flotation sorting after difficult separation, but when mixed with electrophotographic copying paper or used carbonless paper, the entire surface becomes dyed, making it extremely difficult to remove the ink. I found that it becomes difficult.

Therefore, the present inventors researched a method for bleaching this color, and as a result found that bleaching was possible by using an oxidizing bleach, and completed the present invention. That is, the purpose of the present invention is to provide a method for processing waste information recording paper generated from offices, etc., as it is without sorting it, and recovering pulp with high whiteness and low impurities that can be used as raw material for high-grade paper. This is what we provide.

[Means to solve the problem]

The present invention is a treatment method including the steps of disintegration, kneading, flotation sorting, washing and bleaching, and particularly the bleaching method is the key point.

In the disintegration step, various high-concentration or low-concentration pulpers commonly used for disintegrating waste paper raw materials can be used. It is customary to use caustic soda, sodium silicate, hydrogen peroxide, surfactants, etc. as additive chemicals, but some chemicals may be omitted depending on the used paper raw material. After disintegration, cleaner and screen treatments are generally performed to remove coarse foreign matter from the pulp.

Next, the pulp is concentrated to a concentration of about 20 to 35% and transferred to a cross-mixing process. The purpose of this process is to micronize toner ink derived from toner-printed waste paper to a size that can be separated in the subsequent flotation sorting process.

As an apparatus for this purpose, a solid mixer such as a kneader, disperser or mixer is used. Note that, if necessary, chemical addition and/or steam injection can be performed immediately before the fixed mixer.

After the cross-mixing process, the pulp is usually subjected to an aging process in which it is retained in a tower or the like at a high concentration in order to promote the swelling of the fibers due to alkali. Further, a crossing step may be provided after ripening.

After the above treatment, the pulp is diluted to a concentration of about 1% and sent to a flotation process to separate the ink.

Various types of floatators used in general waste paper deinking processing can be used as the flotation sorting device. Note that a kneading step can also be provided after the flotation sorting.

After flotation, the pulp is washed. In this step, trace amounts of remaining toner ink are removed, and coloring substances such as dyes and pigments are also removed.

As cleaning equipment, various extractor deckers, thickeners, and press-type concentrators can be used. Coloring substances originating from back carbon paper, carbonless paper, thermal paper, etc. remain in the pulp after washing, and especially when some types of back carbon paper (blue ink) are mixed, the pulp takes on a blue color.

Therefore, a bleaching treatment is performed to decolorize the colored substance. Oxidizing bleaches were found to be effective as bleaching agents, and hydrogen peroxide, oxygen 9-hypochlorite, chlorine, and chlorine dioxide were particularly effective.

As conditions for bleaching with these oxidizing agents, conditions employed in ordinary pulp bleaching can be applied. Note that sodium hypochlorite or calcium hypochlorite is usually used as the primary hypochlorite.

This bleaching removes the coloring of the back carbon paper that originates from the blue ink. However, some dyes contained in carbonless paper, thermal paper, etc. may remain in the pulp after bleaching. For such pulps, dithionite bleaching is preferably carried out as the next bleaching step. As the dithionite salt, sodium dithionite is usually used. As the bleaching conditions, the conditions employed in general pulp bleaching can be applied.

Further, in the present invention, oxygen (O) and chlorine (C).

Alkali (E) 9 Hypochlorite (H), Chlorine dioxide (D
), hydrogen peroxide, etc. may be combined to perform multi-stage bleaching similar to general chemical pulp.

0CEHD, CEHD, CEHED, etc. are suitable. Such multi-step bleaching makes it possible to remove both the blue ink and the dye.

〔Example〕

Hereinafter, the present invention will be explained by examples.

The following mixture was used as unsorted information recording paper waste paper.

(a) 204 copies of electrophotographic copy paper (as air-dried paper, the same applies hereinafter) Printed matter by Xerox 5990, toner adhesion amount 0.5
6% by weight (b) 176 copies of carbonless copy paper, 1 sheet each of top paper, middle paper, and bottom paper, black 9 color development area ratio 20% (c) 35 copies of thermal recording paper for facsimile, black 9 color development area ratio 20 % (d) 20 copies of back carbon copy paper Courier slip, blue, mixed waste paper of unused or better quality with 1.0% caustic soda (absolutely dry paper,
The same applies below), 2.0% of sodium silicate (No. 3), 0.5% of hydrogen peroxide, and 0.3% of Lipotol Ll (-200, a deinking agent manufactured by NICCA Chemical Co., Ltd.), Using a high-concentration pulp disintegrator (5 L volume) manufactured by Kumagai Riki Kogyo Co., Ltd., the pulp was disintegrated for 24 minutes at a raw material concentration of 15% and a temperature of 50°C.

The pulp after disintegration was diluted to a concentration of 3%, and then dehydrated to a concentration of 25%. This pulp was processed using a test kneader (2-shaft type, 1.5 KV) made by Yamamoto Hyakuma Seisakusho at a rotational speed of 14 Orp.
It was treated once with m. The treated pulp was diluted to a concentration of 15% and aged at 55°C for 120 minutes. Next, dilute it to a concentration of 1% and use a test floatator (SL volume) manufactured by Kyokuto Shinko Co., Ltd.
Floating sorting was carried out for 10 minutes using a . The obtained pulp was dehydrated to a concentration of 20% and washed.

Example 1 The washed pulp was bleached with hydrogen peroxide under the following conditions.

Hydrogen peroxide addition amount 2%, caustic soda addition amount 0.6%, sodium silicate addition amount 3%, pulp concentration 10%, 70°C, 1
20 minutes Example 2 The washed pulp was placed in a horizontal autoclave equipped with a stirrer (1
(8L volume) was used for oxygen bleaching under the following conditions.

Charge amount 500g0D, oxygen addition amount 11%, caustic soda addition amount 1.5%, pulp concentration 14%, 103℃, 60
Example 3 The washed pulp was bleached with sodium hypochlorite under the following conditions.

Addition amount of sodium hypochlorite 2% (as available chlorine), addition amount of caustic soda 0.58%, pulp concentration 1O%, 50℃,
120 minutes Example 4 The washed pulp was chlorine bleached under the following conditions.

Chlorine addition amount: 2.1%, pulp concentration: 2.5%, 54°C.

60 minutes Example 5 The washed pulp was bleached with chlorine dioxide under the following conditions.

Added amount of chlorine dioxide: 2% (as available chlorine).

Pulp concentration: 10%, 68° C., 240 minutes Example 6 The hydrogen peroxide bleached pulp obtained in Example 1 was washed once and then bleached with sodium dithionite under the following conditions.

Sodium dithionite addition amount 2%, sodium tripolyphosphate addition amount 0.5%, initial pH 6.5, pulp concentration 5%, 7
0°C, 60 minutes Example 7 After washing the chlorine bleached pulp obtained in Example 4 once,
Alkali treatment, sodium hypochlorite bleaching and chlorine dioxide bleaching were carried out under the following conditions. One wash was performed between each bleach stage.

Alkali treatment: Caustic soda addition amount 1.2%, pulp concentration 10%, 44°C, 60 minutes Sodium hypochlorite bleaching: Sodium hypochlorite addition amount 0.6
%, caustic soda addition amount 0.17%, pulp concentration 10%,
Chlorine dioxide bleaching at 46°C for 60 minutes Added amount of chlorine dioxide: 0.84%.

Pulp concentration: 10%, 68° C., 240 minutes Comparative Example The washed pulp was bleached with sodium dithionite under the following conditions.

Sodium dithionite addition amount 2%, sodium tripolyphosphate addition amount 0.5%, initial pH 6.5, pulp concentration 5%, 7
After each pulp was bleached at 0° C. for 60 minutes or more, the pH was adjusted to 6.5 using sulfuric acid band, and handmade paper was prepared according to the JIS method. The hue of the handmade paper was measured using a spectrophotometer (Model CM-1000 manufactured by Minolta Camera Co., Ltd.), and the whiteness was measured using a Hunter reflectance meter (newly manufactured by Toyo Seiki Co., Ltd.).
Each was measured by

The results of these measurements are shown in the table below.

Margin below The blue color has completely disappeared.

The pulp after hydrogen peroxide bleaching was slightly reddish, but by subsequent bleaching with sodium dithionite, the reddish color completely disappeared and the whiteness increased. Further, by four-stage bleaching using CEHD, a pulp with no bluish tinge and high whiteness was obtained.

According to the present invention, it was possible to remove the blue color originating from the underside carbon paper, which is a problem when recovering pulp from unsorted waste information recording paper, and to obtain pulp with high whiteness.

〔Effect of the invention〕

Claims (1)

[Scope of Claims] 1. A method for treating unsorted information recording paper waste paper, which comprises using an oxidizing bleach in the bleaching step, in a treatment step consisting of a disintegrating step, a kneading step, a flotation step, a washing step, and a bleaching step. . 2. The method for treating unsorted information recording waste paper according to claim 1, wherein bleaching is performed with a dithionite salt following the oxidizing bleaching agent.