JPH03213591A - Production of pulp by microorganism - Google Patents

Abstract

PURPOSE:To obtain pulp inexpensively and industrially with saved energy without adding a nutrition source and cellulose decomposition inhibitor by treating wood chip with microorganisms. CONSTITUTION:Wood chip or pulp prepared by refining wood chip is treated with a microorganism without substantially adding a nutrition source and a cellulose decomposition inhibitor. NK-1148 strain (FERM BP-1859) may be cited as the microorganism.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a method for producing pulp by pulping or bleaching by microbial treatment.

More particularly, the present invention relates to a method for producing pulp by pulping or bleaching by microbial treatment without substantially adding nutrients or cellulolysis inhibitors.

In the present invention, by using microorganisms with extremely excellent lignin decomposition activity and high selectivity, pulping or bleaching can be carried out without substantially adding nutrients or cellulose decomposition inhibitors such as glucose during the pulp manufacturing process. This enabled an extremely energy-saving and low-cost industrial pulp production method to be provided.

(Prior Art and Problems) In general, many studies have been conducted for a long time regarding pulping or bleaching in the production of pulp using microorganisms.

JP-A-50-46903 proposes a method for producing cellulose pulp by decomposing lignin using microorganisms capable of producing lignin-degrading enzymes under conditions that substantially decompose lignin.

However, in this method, the lignin decomposition activity of the microorganisms used is extremely weak and the lignin decomposition rate is low, and sugars and nitrogen compounds are added to suppress the microorganisms from assimilating cellulose. It has not yet reached industrial implementation.

Also, Phanerochaete chrysosp.
Bleaching of pulp by orium has been reported (Bj,
otechnol Lett,, 1347-353 (
(1979)), but the lignin decomposition activity is weak and a large amount of cellulose decomposition inhibitor is used, so it has not been implemented industrially.

Furthermore, bleaching by Coriolus versicolor was reported (May 1989 Tappi
Journal 217-220), but this method also has a high ability to assimilate cellulose, consumes a considerable amount of cellulose, and requires the addition of a large amount of bacterial culture using a nitrogen source and glucose. It has not yet been implemented industrially.

(Means for Solving the Problems) The present inventors have discovered that cellulose is not consumed in pulping or bleaching by microbial treatment, and
As a result of intensive research in search of a treatment method without adding nutrients or cellulose decomposition inhibitors, we were able to achieve this objective with the present invention.

That is, in the present invention, if microorganisms that grow well in a medium containing lignin as the sole carbon source are used, wood chips, pulp after refining, and unbleached pulp can be used as a substantial nutrient source or cellulose decomposition inhibitor. This makes it possible to perform pulping and/or bleaching in an extremely energy-saving and inexpensive manner without adding any additives.

As a medium, lignin is used as the only carbon source] ~10
%, preferably 2 to 4%, is prepared.

If an isolated source collected from nature is dispersed in this medium at an appropriate concentration and cultured at 25 to 35°C, and a colony showing good growth is collected, this becomes an effective microorganism for use in the present invention.

The present inventors have already developed the NK-1148 strain (FERM BP
-1859) and NX-729v strain (FBI (M BP-
1860), etc., and these are extremely effective microorganisms in the present invention.

The mycological properties of the NK-1148 strain (FERM BP-1859) are as follows.

(1) Growth status in medium Note-1 Medium pH: 5. o (before autoclave sterilization) Note-
2 Culture conditions = 28°C x 7 days Note - 3 Growth status: weak: + moderate 20 vigorous: +++ (2) Physiological and ecological properties■ Growth pH range (potato/glucose agar medium,
(Culture at 28°C for 4 days) It grows around pH 3 to 9 and does not grow at pH 2 and 10. The optimum pH is around 4-6.

■ Temperature range for growth (potato/glucose agar medium,
p115.4-day culture) Grows at around 10-45°C and does not grow at 50°C.

The optimum temperature is around 28-37°C.

■ Phenol oxidase reaction (cultured at 28°C for 4 days) Shows weak or negative results.

■ Characteristics of bacterial flora (potato/glucose agar medium, pH
5. Cultured at 28°C for 4 days) It is white and felt-like.

In addition, NK-729W strain (FERN BP-1860)
The mycological properties of this species are as follows.

(1) Growth status in medium Note-1 Medium pH: 5. o (before autoclave sterilization) Note-
2 Culture conditions = 28℃ x 7 daysNote-3 Growth status: Weak: Moderate: ++ Vigorous: +++ (2) Physiological and ecological properties■ Growth pH range (potato/glucose agar medium,
28°C, culture for 4 days) 8 [) Grows around H3-7, does not grow at ρ+12 and 8. The optimum pH is around 4-5.

■ Temperature range for growth (potato/glucose agar medium,
(pH 5, culture for 4 days) It grows at around 10-32°C and does not grow at 37°C.

The optimum temperature is around 20-30°C.

■ Phenol oxidase reaction (28°C, cultured for 4 days) Shows positive.

■ Shape of bacterial flora (potato/glucose agar medium, pH
5.28°C, 4 days of culture) White and hairy.

■ Shape and size of fruiting body: Diameter 2-5 mm ・Shape: Inverted bowl shape (nose shape) ・Edge and surface: The rim is curled inward, and the surface is yellowish brown with brown hairs all over.

・Tube surface: Pale grayish white, concave in the shape of an inverted dish, and the pores are small.

・Meat quality: Flexible, leathery and almost white in color.

■　Spore shape It is colorless and smooth with a sausage shape of about 3 to 4 x 1 μm.

The microorganism used in the present invention is NK
-1148 strain or NK-729W strain, but it is better to use selected isolates that grow well using lignin as the sole carbon source without mutagenic treatment or mutagenic treatment, or to use basidiomycetes isolated from nature. But that's fine.

In the present invention, a microorganism that grows well using lignin as the sole carbon source is, for example, a microorganism that can be used to bleach unbleached kraft pulp without reducing its strength, and has a whiteness of 45% or more, preferably 50% or more, and more preferably refers to microorganisms that can bleach 60% or more.

The microorganisms used in the present invention can be cultured in any of a medium containing lignin as the sole carbon source, a normal lignin-free medium for basidiomycetes and molds, or a medium containing wood flour, wood chips, and pulp. I can do it.

On the other hand, the types of pulp are roughly classified into the following three types.

■ Mechanical pulp made by mechanically treating wood as it is to make it into a fibrous form ■ Semi-chemical pulp made by combining chemical and mechanical treatment ■ Chemical pulp made by removing most of the lignin through chemical treatment It can be applied to the production of pulp.

In mechanical pulping, chips are mechanically refined into pulp. In the present invention, wood chips and/or lightly refined pulp can be used, which is extremely energy efficient compared to conventional methods.
Moreover, it is possible to produce pulp with high strength.

In semi-chemical pulp, chips are treated with chemicals in advance and then mechanically refined to produce pulp.

In the present invention, wood chips or refined pulp obtained by lightly refining wood chips can be used.

Additionally, wood chips that have been lightly treated with chemicals or pulp obtained by refining wood chips that have been lightly treated with chemicals can be used. Note that there is no problem in performing appropriate refining and/or chemical treatment after microbial treatment.

Microbial treatment requires only minor refining and chemical treatments, resulting in significant energy and chemical savings.

In addition, in chemical pulp, lignin is highly decomposed by chemical treatment under high temperature and high pressure to produce unbleached chemical pulp. In the present invention, wood chips or pulp obtained by lightly refining wood chips can be used. It is also possible to use wood chips that have been lightly treated with chemicals or pulp obtained by refining wood chips that have been lightly treated with chemicals. As in the case of semi-chemical pulp, there is no problem in performing appropriate refining and/or chemical treatment after microbial treatment.

Microbial treatment results in significant savings in cooking energy and chemicals.

Note that strongly colored lignin remains in unbleached chemical and semi-chemical pulps, so in order to use them for paper applications that require high whiteness, a process that removes the residual lignin and imparts whiteness ( Bleaching) is required.

In the present invention, microorganisms can also be added to unbleached pulp to cause bleaching.

Unbleached pulp treated with microorganisms is considerably bleached, requiring only a light chemical treatment for subsequent bleaching, which also helps prevent pollution.

During pulping and/or bleaching, microbial cultures are added to the chips or various pulps in an amount of about 1/10,000 to 10/100 of the pulp or pulp without adding any nutrients or cellulose decomposition inhibitors. 2
The treatment can be carried out by culturing at about 0 to 35°C for 3 to 90 days.

Next, examples of the present invention will be shown.

Example 1 A medium prepared by adding 1.0 g of beech wood flour (60 to 80 mesh) and 2.5 mQ of water to a 50 mQ king square flask was heat sterilized at 120°C for 15 minutes, and then NK-1148 strain (FERM
BP-1859) and cultured at 28°C for one week,
The obtained bacterial cells are suspended in water.

On the other hand, birch milled lignin 2.0%, N114H2P
12 ml of medium containing 0.2% O and 1.6% agar.
After heat sterilizing at 0℃ for 15 minutes, place in a petri dish (
Dispense 2 On + Q into each tube (diameter 90 mm).

The bacterial cell suspension described above was added to the medium and cultured at 28°C for 2 weeks, and a bacterial strain that showed good growth was isolated and designated as isolate A. Isolated strain A was named strain NK-11,48-3, and has been deposited with the Institute of Fine Technology as FERM P-11182.

Example 2 The isolate NK-1148-3 obtained in Example 1 was mixed with 10 kg of pulp obtained by lightly refining beech chips and 25 kg of water.
A mixed and stirred medium with Q was sterilized at 120°C for 15 minutes, then inoculated and cultured with aeration at 28°C for 2 weeks to obtain a seed culture.

Example 3 In the production of mechanical pulp, pulp 1.0 obtained by mild primary refining of beech chips 5
kg and 25 Q of water were mixed, sterilized at 120°C for 15 minutes, and 1 kg of the seed culture obtained in Example 2 was added and mixed,
After aeration culture at 28° C. for one week, secondary refining was performed, and it was possible to obtain mechanical pulp with high strength in an extremely energy-saving manner. The properties of the obtained biomechanical pulp are shown in Table 1 below.

Daily Table 1 Biomechanical Pulp Example 4 Strain NK-1148 and Isolated Strain NK-1 Obtained in Example 1
148-3 strains were each mixed and stirred with 10 kg of unbleached kraft pulp (eucalyptus) and 25 Q of water.
After sterilization at ℃ for 15 minutes, it was inoculated and cultured with aeration at 28 ℃ for 2 weeks to obtain a seed culture.

Example 5 In bleaching chemical pulp, unbleached kraft pulp (
Eucalyptus) and 25Ω of water were mixed, sterilized at 120°C for 15 minutes, 1kg of each seed culture obtained in Example 4 was added separately, mixed, and sterilized at 28°C for 1 to 5 minutes.
After aeration culture for one day, bleached kraft pulp was obtained. The increase in whiteness during the treatment period of 1 to 5 days is shown in FIG.

[Brief explanation of drawings]

Figure 1 shows the whiteness (
%).

Claims (11)

[Claims] (1) A method for producing pulp obtained by microbial treatment without adding substantially any nutrients or cellulose decomposition inhibitors. (2) A method for producing pulp, which comprises microbially treating wood chips or pulp obtained by refining wood chips without substantially adding any nutrients or cellulose decomposition inhibitors. (3) A method for producing mechanical pulp, which comprises subjecting wood chips or pulp obtained by refining wood chips to microbial treatment without substantially adding any nutrients or cellulose decomposition inhibitors. (4) The method for producing mechanical pulp according to claim 3, which comprises performing appropriate refining and/or chemical treatment after microbial treatment. (5) A method for producing chemical and/or semi-chemical pulp, which comprises microbially treating wood chips or pulp obtained by refining wood chips without substantially adding any nutrients or cellulose decomposition inhibitors. (6) The method for producing chemical and/or semi-chemical pulp according to claim 5, which comprises performing appropriate refining and/or chemical treatment after microbial treatment. (7) Wood chips treated with chemicals or pulp obtained by refining wood chips treated with chemicals,
A method for producing pulp, characterized by microbial treatment without substantially adding nutrients or cellulolysis inhibitors. (8) Wood chips treated with chemicals or pulp obtained by refining wood chips treated with chemicals,
1. A method for producing chemical and/or semi-chemical pulp, characterized by microbial treatment without substantially adding nutrients or cellulolysis inhibitors. (9) The method for producing chemical and/or semi-chemical pulp according to claim 8, which comprises performing appropriate refining and/or chemical treatment after microbial treatment. (10) Unbleached (chemical and/or semi-chemical)
characterized in that the pulp is microbially treated without substantially adding nutrients or cellulolysis inhibitors (
(chemical and/or semi-chemical) pulp bleaching methods. (11) Claims 1 and 2, characterized in that microorganisms that grow well using lignin as the only carbon source are used.
The method for producing pulp according to item 1, item 3, item 4, item 5, item 6, item 7, item 8, item 9 or item 10.