JP2008199906A - Method for producing saccharides, and papermaking filler from papermaking process reject - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To propose a method for economically utilizing wastes using a simple process, by taking advantage of the characteristics of the places where the wastes are produced. <P>SOLUTION: A method for producing saccharides and a papermaking filler directly collects the rejects, generated during the making of paper consisting essentially of chemical pulp derived from lignocellulose from a papermaking process, adding cellulase thereto, hydrolyzing the rejects, thereby producing the saccharides and simultaneously converting residues after collecting the saccharides into the papermaking filler. As the tails of the rejects, in a dust removing step prior to paper machine are, preferably rejects, and wastewater containing the rejects is preferably collecteddirectly, without mixing with other normal wastewater, directly hydrolyzed, or after dehydration of solids, the resultant solids are preferably hydrolyzed. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a technique for producing saccharides as raw materials for fermentation production by microorganisms such as ethanol and lactic acid from biomass, and effectively using the residues after the saccharide production as papermaking raw materials.

  In order to prevent global warming, efforts to reduce carbon dioxide, one of the global warming gases, have been widely carried out. As part of this, replacement of petroleum products using biomass, which is carbon neutral, as a raw material The production of goods is being considered. Among them, many studies have been conducted on the production of useful substances starting from saccharides such as glucose obtained by hydrolyzing polysaccharides. (For example, see Non-Patent Document 1)

  One method for obtaining a saccharide from a polysaccharide is a hydrolysis method using an acid. For example, in the method using concentrated sulfuric acid, hemicellulose is separated and recovered by a prehydrolysis treatment using steam at 185 ° C., and then main hydrolysis is performed using 80% sulfuric acid. Thereafter, glucose is obtained by post-hydrolysis using about 5 to 10% dilute sulfuric acid. However, since this method causes secondary decomposition of glucose, the yield of glucose is low, and an acid-resistant reaction vessel is required to use acid under high pressure. In addition, there are problems such as an increase in cost for collecting sulfuric acid.

  Another method for obtaining a saccharide from a polysaccharide is a hydrolysis method using an enzyme. Among them, a method using cellulase is particularly studied. This method is a method in which cellulose is hydrolyzed with cellulase, but since the secondary decomposition of glucose does not occur, the yield as the theoretical value is obtained. Since the reaction conditions are mild, no acid-resistant pressure-resistant reaction vessel is required. In addition, there is an advantage that there is no concern about environmental pollution. (For example, refer nonpatent literature 2) Cellulase is a general term of the enzyme which hydrolyzes the β-1,4 glycosidic bond of cellulose, and endoglucanase (EC 3.2.1.4), cellobiohydrolase (EC 3). 2.1.91) and beta glucosidase (EC 3.2.2.11). In addition, the microorganisms that produce cellulase are widespread such as bacteria and filamentous fungi. (For example, see Non-Patent Document 2)

  As described above, the enzymatic hydrolysis method has advantages over the acid hydrolysis method, but further reduction in production cost is required, and therefore, an inexpensive raw material is required. Moreover, this raw material has a low lignin content, and in addition, a raw material having a high decomposition rate from cellulose to glucose is required. The reason why a raw material having a low lignin content is preferable is that lignin coats cellulose and reduces the reactivity of cellulase, and if the lignin content is high, a pretreatment step for removing lignin is required. . (For example, refer nonpatent literature 2) Moreover, it is for raising the productivity of saccharides as a reason for the raw material with the high decomposition rate of a cellulose being calculated | required. For example, if the decomposition rate of cellulose in the raw material is low, the input energy (reaction time, number of reactions, reaction vessel, etc.) must be increased, which is not preferable because the cost increases.

  As raw materials with low lignin content and high cellulose degradation rate, there are papers derived from chemical pulp. Among them, waste paper is suitable as a raw material, and research on saccharification and fermentation using waste paper as a raw material is being conducted. (For example, Patent Document 1 and Patent Document 2). However, since used paper is often reused as a raw material for paper, it is not preferable to use it as a raw material for saccharification. For this reason, the raw material which does not compete with the recycling | reuse as paper with the cellulose resource with few lignins is desired.

  On the other hand, in the paper manufacturing industry, paper is manufactured through processes such as pulping, preparation, paper making, and coating. Wastewater generated in these processes is used as pulp fiber, which is a raw material for papermaking, organic substances mainly composed of adhesives such as starch and synthetic adhesives, internal fillers and coating pigments. It contains inorganic substances mainly composed of white inorganic particles, lignin washed out in the pulping process, fine fibers, fillers for papermaking derived from waste paper, printing ink adhering thereto, and the like. Moreover, in general, these wastewaters contain a lot of sand and dust in addition to the above organic and inorganic substances on a route sent to a wastewater treatment facility installed immediately before being discharged from the boundary of the factory.

  Paper sludge separated and recovered from waste water using wastewater treatment equipment such as clarifiers using precipitation or levitation is used to burn organic matter in paper sludge in incinerators such as fluidized bed furnaces and stoker furnaces. At the same time as recovering energy, the volume of sludge is reduced, and then landfilled as industrial waste. Reduction of industrial waste is urgent due to the need for environmental conservation, and from the viewpoint of effective use of resources, recyclability of waste is required. At present, some incineration ash is considered to be used as cement, soil conditioner, compost, and white inorganic particles for papermaking. (For example, Patent Document 3 and Patent Document 4)

Here, the following is performed especially in the discharge and recovery of water in the papermaking process.
Paper stock prepared by blending, beating, adding chemicals, fillers, dyes, etc. to various pulps such as kraft pulp, used paper pulp, and mechanical pulp produced in various pulping processes is usually 2.5 to 3.0. Is sent to the papermaking process at a concentration of 1%.
This high-concentration paper stock is diluted to about 0.4 to 1.0% depending on the type of paper and operating conditions. The diluted paper stock is finally removed before the head box. As a dust removing device, a vortex cleaner is mainly used for removing foreign matters heavier than pulp fibers, and a sealed screen is mainly used for removing foreign matters larger than pulp fibers. The dust removal process is divided into accept pulp and reject. The reject of the cleaner and screen is a system that makes the maximum use as paper material by repeating the cleaner and screen processing again. The final rejection of the cleaner is called a tail, but this tail is not used as paper stock but is discharged as papermaking sludge. The tail immediately after coming out of the cleaner is almost free of foreign matter such as fiber lump, dust and sand particles by a screen device such as a pulping process, and has less foreign matter than the wastewater near the wastewater treatment facility.

  The accept pulp is jetted onto the wire through the head box. Since the concentration of wet paper leaving the wire part is about 20%, a large amount of water is discharged through the wire. This waste water has a fiber content at about half the headbox concentration, and this type of pulp suspension water is generally called white water. White water is circulated and used in accordance with the place where it is discharged, such as the dilution of the high-concentration paper stock and the pulping process.

For wire parts and press parts, wire trims, wet broke generated by couch rolls and press rolls when paper is cut, and dryers, calenders and reels that occur when paper is cut after dry parts, finishes such as stripped paper, winders and cutters at the edge of the frame There is a loss of paper called drive roke that occurs in machines. The broke is roughly disaggregated by a wet broke pulper and a drive roul pulper provided below the paper machine, then processed by a broke disintegrator or broke beating machine in the preparation process, and reused as a raw material.
As described above, in a paper mill, even if it is sent to a paper machine as a stock, there is a large amount that is rejected without staying on the paper machine, but it is used by being circulated in the paper mill.

  In general, in order to improve optical properties such as whiteness and opacity of paper, smoothness, and the like, paper making is usually performed by adding white inorganic particles as a filler for internal addition to a paper stock mainly composed of pulp. In addition, for the purpose of improving printability, a pigment coating layer mainly composed of white inorganic particles and an adhesive is also provided on paper. Examples of white inorganic particles for papermaking used for such internal addition or coating include kaolin, calcium carbonate, zinc oxide, aluminum hydroxide, zinc sulfide, titanium dioxide, calcium sulfate, calcium sulfite, and sulfuric acid. Mainly composed of barium, satin white, talc, silica, and the like, and one or more organic pigments called plastic pigments are appropriately mixed and used as necessary. For this reason, the rejection in a papermaking process and the tail of rejection have the characteristics that many said white inorganic particles are contained other than a pulp fiber.

Studies have been made on the utilization of pulp fibers contained in paper sludge as a saccharide raw material in a method for producing saccharides using enzymes (for example, Patent Document 5, Non-Patent Document 3, and Non-Patent Document 4). Here, when papermaking sludge is used as a saccharide raw material, it is easy to recover and use the concentrate recovered using a solid content separation device such as a clarifier using precipitation or levitation. Is common. However, as described above, there are many foreign substances in the papermaking sludge after passing through the wastewater treatment facility, and when producing sugars using these papermaking sludges as raw materials, these foreign substances are removed from the sugar before or after saccharification. An operation to remove is necessary.
Techniques for producing a papermaking filler from papermaking sludge have also been studied as described above. (For example, patent document 3, patent document 6) Here, the papermaking filler manufactures white inorganic particles from the incinerated ash reduced by incineration of papermaking sludge, and the manufacturing method differs from the patent of this application. To do.

JP-A-2005-278602 JP-A-2002-238590 JP-A-2002-308619 Japanese Patent Laid-Open No. 2004-182538 JP 2004-89177 A Japanese Patent Laid-Open No. 2000-178024 Biomass energy characteristics and energy conversion and utilization technologies (2002, NTS Corporation) Encyclopedia of cellulose (2000, Asakura Shoten, Cellulose Society), pp.300-316, p.404-408. Evaluation of paper sludge for amenability to enzymatic hydrolysis and conversion to ethanol. Lee R. Lynd et al., P. 50, Tappi Journal, 2001. Conversion of paper sludge to ethanol in a semicontinuous solids-fed reactor., Zhiliang Fan et.al, 26, pp. 93-101, Bioprocess Biosyst. Eng., 2003. Methods for measuring cellulase activities, Thomas M. Wood and K. Mahalingeshwara Bhat, vol. 160, p.92, Methods in Enzymology.

  The conventional various methods described above are only methods that require incineration when obtaining an inorganic substance from sludge, and require complicated separation when obtaining an organic substance. Therefore, an object of the present invention is to propose a method of utilizing waste economically by a simple process, taking advantage of the characteristics of the place where the waste is generated.

As a result of intensive studies based on the above problems, the present inventors have reached the present invention. That is, the present invention employs the following configurations (1) to (4).
(1) Rejections generated during the papermaking process of paper mainly composed of lignocellulose-derived chemical pulp are collected directly from the papermaking process, and after the saccharides are collected at the same time as the saccharides are produced by hydrolysis with cellulase added thereto. And a method for producing a papermaking filler, wherein the residue is used as a papermaking filler.
(2) A method for producing a saccharide and a papermaking filler, wherein the rejection described in (1) above is a tail of a rejection in a dust removal step before the paper machine.
(3) The saccharide according to (2) above, wherein the wastewater containing reject is directly collected without mixing with other general wastewater, and hydrolyzed as it is or after dehydrating the solid content, And a method for producing a filler for papermaking.
(4) The above characterized in that the wastewater containing the reject is directly collected without mixing with other general wastewater and not subjected to the coagulating sedimentation treatment, and is subjected to hydrolysis as it is or after collecting the solid content by a filter. (2) The manufacturing method of the saccharide | sugar as described in (3), and the filler for paper manufacture.

  According to the present invention, saccharides that can be stably supplied from unused resources as a saccharification raw material and have few impurities can be produced at low cost. Moreover, the residue after saccharification can be reused as a papermaking raw material.

  As the lignocellulose used in the present invention, any material may be used as long as it is a raw material of pulp, and any of wood, kenaf, manila hemp, bamboo, bagasse, straw, cotton linter, reed, flax, cocoon, and sardine is used. be able to. Moreover, these materials may be used independently or may use several types. For example, wood includes conifers such as pine, cedar, fir, spruce, Douglas fir, and radiatapine, and broadleaf trees such as beech, hippopotamus, alder, maple, eucalyptus, poplar, acacia, lawan, aspen, and rubber.

  The chemical pulp used in the present invention may be manufactured by any method as long as it is a chemical delignification method. For example, “Paper Pulp Manufacturing Technology Series (1) Kraft Pulp” (Paper Pulp Technology) The alkali pulp method, the sulfite pulp method, the kraft pulp method, etc. described in the association edition) can be used. In addition, for example, oxygen, ozone, chlorine, chlorine dioxide, alkali extraction, hypochlorous acid, peroxide, sulfurous acid, hydrosulfite described in “Pulp Cleaning / Selection / Bleaching” (edited by the Paper Pulp Technology Association) are used. Conventional bleaching steps can be used. As the paper making process of the paper using chemical pulp, chemical pulp alone or a mixture of used paper pulp or mechanical pulp can be used. However, mechanical pulp such as thermomechanical pulp and mechanical pulp, and waste paper pulp containing mechanical pulp are not preferable as a raw material for saccharide production because they contain lignin. Therefore, it is preferable that chemical pulp is the main component. The proportion of chemical pulp is 50% or more, preferably 80% or more, more preferably 100%.

The rejection of the papermaking process in the present invention is typically discharged from the process of separating into a foreign material that is preferable as a paper material and the object that is not preferable in the dust removal process before the papermaking machine. In addition, the paper discharged on the paper machine as white water or broke is not included as paper. As an example, white water (including fibers and fillers) that overflows and is discarded in the circulation, or a mixture of this and overflowed paint waste is included.
The dust removal process before the paper machine will be described in detail. In this process, for example, a process of removing using a difference in shape, specific gravity, hardness, and the like. The apparatus used in the dust removal process may be any apparatus that separates high-quality paper and foreign substances, such as a vortex cleaner, an open-type low-vibration rotary screen, and a sealed pressure-type screen. . These screens and cleaners can also be used in screening systems such as those described in “Papermaking” (edited by the Paper and Pulp Technology Association).

The reject tail in the present invention refers to a reject that occurs at the end of the process when dust is removed by combining a plurality of screens or cleaners. The reject tail is recovered by simple precipitation or coagulation precipitation in the wastewater treatment process. This sludge is usually called sludge.
The reject of the present invention refers to rejects from individual devices such as cleaners and screens during the paper making process, and reject tails. In the present invention, by using the reject and the tail of the reject directly without going through the waste water treatment step, it is possible to avoid mixing of various foreign matters contained in the papermaking sludge.

  The reject in the present invention is collected directly from the outlet and used for the saccharification reaction. In addition, the collected reject can be used for the saccharification reaction as it is, or dehydrated and used for the saccharification reaction. Moreover, since the density | concentration of the sugar produced at the time of the cellulase reaction in this invention is high, since the density | concentration of sugar produced becomes high, any density | concentration may be sufficient as long as it can stir in a saccharification tank. Generally, 20% or less is preferable, but continuous saccharification can be performed at a higher concentration.

  The reaction vessel in which cellulase is added to the reject for hydrolysis is preferably one that can be maintained at a pH and temperature suitable for the optimum conditions of the enzyme used, and is preferably equipped with a stirring device. It is desirable that the reaction vessel has a reject adding device and a device capable of recovering the solution containing the saccharide after the reaction. In addition, there is an apparatus in which the reaction vessel has an ultrafiltration membrane, and by processing the reaction solution with the ultrafiltration membrane, the cellulase can be continuously collected outside the reaction vessel while maintaining the cellulase in the reaction system. Can be used.

The solvent added to dilute the reject in the present invention to a desired concentration should not interfere with the cellulase reaction or contain a large amount of organic components other than inorganic components and pulp that make purification after the reaction difficult. Anything can be used. Cellulase may be contained in the solvent.
Any method may be used for adding the reject to the saccharification reaction vessel in the present invention, but the solution in which the reject is dispersed can be added continuously or discontinuously. In addition, dried or dehydrated rejects can be added continuously or discontinuously.

  The reject in the present invention may contain organic and inorganic components other than pulp fibers. For example, chemicals / fillers added in the cooking step, bleaching step, and preparation step, and lignocellulose as a raw material. A derived component, a reaction product of lignocellulose as a raw material and a chemical may be contained. However, when the residue remaining in the reaction vessel is added to the papermaking raw material, impurities that become foreign matter simplify the fractionation means required for removing the impurity and the process of removing the impurity from the solution after the reaction. In order to reduce the cost for the reduction, it is preferable to reduce the cost. The amount of impurities can be measured, for example, by filtering the solution after the reaction using filter paper and then measuring the size and number of impurities according to the Tappi method (T213-om85).

  The cellulase used in the present invention is not particularly limited, but it is preferable to select a cellulase that operates under conditions suitable for each pH and temperature condition according to the state of rejection. For example, when the reaction solution is in the acidic range of pH 4 to 5, cellulase preparations derived from the genus Trichoderma, the genus Acremonium, the genus Aspergillus, the genus Phanerochaete and the genus Trametes In the neutral range of pH 6 to 7, cellulase derived from the genus Humicola etc. can be used, and in the alkaline range of pH 8 or higher, the cellulase preparation derived from the genus Bacillus etc. Can be used. The type of cellulase used for the reaction of the reject or the reject tail is not particularly limited, and a cellulase obtained by culturing a normal microorganism or a commercially available cellulase can be used. An appropriate amount of cellulase is added in consideration of the characteristics of the enzyme used for a desired time. For example, in the case of a commercially available enzyme derived from the genus Trichoderma, 0.01 to 300 units of cellulase are added for filter paper disintegration activity, and saccharification is performed at 50 ° C., and glucose generated by hydrolysis is separated and collected. Cellulase may also contain polyethylene glycol, hexylene glycol, polyvinyl pyrrolidone, tetrahydrofuryl alcohol, glycerin and water. Further, it may contain an enzyme or a metabolite produced when the microorganism is cultured, for example, a hemicellulase other than cellulase, an enzyme such as lignin degrading enzyme, a protein, or an organic acid.

  The pH at the time of the reaction in the present invention may be any pH as long as the cellulase to be used acts and the range does not chemically change the inorganic substance contained in the reject tail. If an acid is used, the pH can be adjusted to a desired pH by adding, for example, sulfuric acid, phosphoric acid, hydrochloric acid, carbonic acid, and an organic acid. In the case of using an alkali, it can be used after adjusting to a desired pH by adding sodium hydroxide, calcium hydroxide, potassium hydroxide or the like. Moreover, it can adjust to desired pH by using a buffer solution.

The reaction temperature in the present invention may be any temperature as long as the cellulase used acts, but is preferably 5 to 80 ° C.
The reaction time in the present invention depends on conditions such as the type of cellulase used in the reaction, pH, reaction temperature, reject concentration, etc., but until the saccharification rate at a certain point does not increase even if the reaction is further performed, It is desirable to do. For example, a cellulase derived from Trichoderma, which is a commercially available cellulase, was reacted with stirring at 50% by mass, pH 5.0, reaction temperature 50 ° C., and reject concentration 3% by mass with respect to the dry weight of the reject. 95% saccharified.

  The solution after the reaction in the present invention can be used without removing impurities other than the saccharide, but the solution after the reaction can be purified to produce a saccharide with higher purity. As an apparatus that can be used for the purification of the reaction solution, the apparatuses used in the above-described pulp refining process can be used alone or in combination. For example, a vibrating screen, a hermetically pressurized screen, a centrifugal screen, and a vortex cleaner can be used. Further, these screens and cleaners can be used in combination in the above-described multistage system, multiplex system, and cascade system. Moreover, the saccharide | sugar after reaction can be refine | purified using methods, such as centrifugation, ion exchange, ultrafiltration, and a reverse osmosis membrane.

Under the conditions described above, the saccharification reaction was performed using the reject tail as a raw material, and compared with the saccharification reaction of papermaking sludge. Using the reject tail as a raw material has fewer impurities and is better as a raw material for saccharification. It became clear that
In addition, after the saccharification reaction, the sugar solution and the residue can be separated by a filter according to a conventional method. The residue contains white inorganic particles and unreacted pulp, but there are very few foreign matters and binding fibers, and there is no problem in using the paper as it is or after dehydration. The addition amount can be an amount equivalent to the amount of ash necessary for producing the target paper. For example, in order to produce a paper with a target ash content of 15%, when a hand-made paper is prepared according to JIS P 8222 using pulp into which a residue after saccharification reaction corresponding to an ash content of 25% is added, Instead, the same paper quality was obtained when 25% calcium carbonate was added and handmade paper was prepared in the same manner.

  Hereinafter, the present invention will be described more specifically with reference to examples and comparative examples. However, the present invention is not limited to these examples. In the following examples and comparative examples, all “%” means “mass%”, and the amount of additive added to the pulp fiber slurry is expressed as “mass%” with respect to the mass of the dry paper stock.

<Example 1> Production of saccharides from reject tails In front of a paper machine in a factory that manufactures kraft pulp and manufactures paper using mixed hardwood chips consisting of 70% domestic hardwood chips and 30% eucalyptus wood From the dust removal process, the tail of the generated reject was collected. The water content, ash content, holocellulose content, cellulose content, and lignin content in the reject were measured by the following test methods. Table 1 shows the results. Weighed 159.2g with a tail of rejection equivalent to 25g of holocellulose dry weight. To this, 100 ml of 1M phosphate buffer (pH 7.0) and distilled water were added so that the final weight was 1000 g, and disaggregation was performed using a standard disaggregator (manufactured by Kumagai Riki Kogyo Co., Ltd.). It was. The reject solution after disaggregation was transferred to a 5-liter Erlenmeyer flask and preincubated at 50 ° C. and 110 rpm using a shaking incubator (manufactured by Takasaki Scientific Instruments Co., Ltd.). After 20 minutes, after confirming that the temperature of the reject solution had reached 50 ° C., 2.5 g of cellulase REX-35 (Meiji Seika Co., Ltd.) was added to initiate the reaction. Sampling was performed immediately after enzyme addition and after 12 and 24 hours. The Erlenmeyer flask was dispensed into 1 ml microtubes and boiled at 100 ° C. for 10 minutes to inactivate the enzyme. Thereafter, centrifugation was performed using a micro high-speed centrifuge MX-301 (Tomy Seiko Co., Ltd.) for 20 minutes at 13000 rpm, and the supernatant was measured using the phenol-sulfuric acid method described in Non-Patent Document 5. Went. Glucose was used for preparing the calibration curve. The change in the saccharification rate when the reject is reacted is shown in FIG. Here, the saccharification rate refers to the ratio of the generated sugar weight to the added holocellulose weight.

As a result, it was found that the holocellulose in the rejection was 91% hydrolyzed after 24 hours. The reaction solution in the Erlenmeyer flask after the reaction for 24 hours was used for the filter paper No. 1 whose dry weight was measured on the Buchner funnel in order to separate the reaction solution and the unreacted product. Suction filtration was performed using 5C (manufactured by Advantec). The filter paper after suction filtration was dried to a constant weight at 105 ° C., and the amount of residue was measured by measuring the weight. As a result, the amount of residue was 82.6 g, which was almost the same as the sum of the amount of ash contained in the charged reject and the amount of unreacted holocellulose. Moreover, the ash content in this residue was 93.8%. Moreover, the impurities in the residue were measured using the filter paper after the weight measurement. As a result, the amount of impurities was 1.3 mm ² / m ² . Table 2 shows the results of the amount of residue and the amount of impurities.

<Test method>
(1) Moisture: Japan Tappi Paper Pulp Test Method No. 56, and measured.
(2) Ash content: Measured according to the Tappi method (T211 om-85).
(3) Amount of holocellulose: Japan Tappi Paper Pulp Test Method No. Measured according to 65.
(4) Amount of cellulose: Japan Tappi Paper Pulp Test Method No. Measured according to 60.
(5) Japan Tappi Paper Pulp Test Method No. Measured according to 61.
(6) Contaminant amount: Measured according to the Tappi method (T213-om85).

<Comparative example 1> Manufacture of saccharides from paper sludge As the raw material, instead of the reject of Example 1, paper sludge obtained from a clarifier obtained by coagulating and precipitating the waste water of the factory that obtained the reject of Example 1 was used. It was. The same procedure as in Example 1 was performed except for the raw materials. A comparison of the components of Example 1 and Comparative Example 1 is shown in Table 1. The amount of lignin which is not preferable as a raw material was about 120 times higher. The change in the saccharification rate of the paper sludge is shown in FIG. Both Example 1 and Comparative Example 1 used the same weight of holocellulose for the reaction, but the saccharification rate of Comparative Example 1 was about 60% of the saccharification rate of Example 1. The amount of impurities was 1609 mm ² / m ^{2 as} shown in Table 2. This amount was about 1200 times higher than that of Example 1, which was not preferable as a raw material.

＊ 対絶乾リジェクト重量

* Anti-drying weight

＊ 対絶乾残渣重量

* Anti-dry residue weight

<Example 2> Reuse of residue after sugar production as papermaking raw material Using a Niagara beater for experiment, hardwood bleached kraft pulp and softwood bleached kraft pulp were mixed in a ratio of 9 to 1, and Canadian standard freeness (CSF) 455 ml Beaten mixed. To this pulp fiber slurry (pulp concentration 2.0%), cationized starch (trade name: Ace K100, manufactured by Oji Constarch) 0.6%, aluminum sulfate 0.6%, residue 27% after saccharification reaction prepared in Example 1 (25% as ash) %)), A yield improver (trade name: DR-1500, manufactured by Hymo Co., Ltd.) was added in the order described above to obtain a paper stock. Using this paper stock, a paper having a basis weight of 90 g / m ² was prepared by a laboratory square sheet machine, dehydrated by a press, and blown and dried indoors. The handsheet was conditioned for 24 hours under conditions of 23 ° C. and 50% RH, and then the quality was evaluated. Each physical property was measured according to the following method.

<Test method>
(1) Tensile strength: Measured according to JIS P 8113, and indicated by break length (km).
(2) Tear strength: measured in accordance with JIS P8116.
(3) Whiteness; measured according to JIS P 8148 (ISO 2470).
(4) Opacity: measured according to JIS P 8138.
(5) Beck smoothness: measured in accordance with JIS P 8119.
(6) Ash content measurement in paper: Measured according to JIS P 8128 (ISO 2144).

<Comparative example 2> Utilization of calcium carbonate as a papermaking raw material Instead of 25% residue after saccharification reaction in Example 2, 25% calcium carbonate (trade name: TP121, manufactured by Okutama Kogyo Co., Ltd.) was added and the same as in Example 2 Thus, a hand-sheet was prepared. The quality of the obtained paper was evaluated in the same manner as in Example 1.

The composition table in Example 2 and Comparative Example 2 is shown in Table 3, and the quality evaluation results are shown in Table 4.
From Table 4, paper of the same quality was obtained in Example 2 and Comparative Example 2. Therefore, the residue after the saccharification reaction could be used by directly charging it into the paper stock as an internal filler.

  It can be supplied inexpensively and stably, has low lignin content and low impurity content, and can reduce sugars with low impurities through the hydrolysis reaction of cellulase from rejects and reject tails that are normally generated from the papermaking process. Can be produced. Moreover, the residue after the saccharification reaction can be reused by being added to the papermaking pulp as an internal filler.

It is the figure which showed the change of the saccharification rate of Example 1 and Comparative Example 1.

Claims (4)

Rejects generated during the paper making process of papers mainly composed of lignocellulose-derived chemical pulp are collected directly from the paper making process, and at the same time as the production of sugars by hydrolysis with cellulase added to this, the residues after sugar collection are removed. A saccharide characterized by being used as a filler for papermaking, and a method for producing a filler for papermaking. A method for producing a sugar and a papermaking filler, wherein the reject according to claim 1 is a tail of a reject in a dust removal step before the paper machine. The sugar and the papermaking filler according to claim 2, wherein the wastewater containing the reject is directly collected without mixing with other general wastewater, and hydrolyzed as it is or after dehydrating the solid content. Manufacturing method. The waste water containing the reject is collected directly without mixing with other general waste water and without being subjected to the coagulation sedimentation treatment, and the hydrolysis is performed as it is or after the solid content is collected by a filter. 3. A method for producing the saccharide according to 3, and a filler for papermaking.

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