JP2007270402A - Newsprint paper for offset printing - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain newsprint paper for offset printing, which has high opacity after printing, printability and internal bonding strength and surface strength. <P>SOLUTION: The newsprint paper comprises a porous filler having a silicon-containing particle formed from silicon dioxide and/or a silicate and 0.1-40 mass% of an alkali-resistant microparticle based on 100 mass% of the silicon-containing particle, a pore volume of 3.0-5.0 mL/g, and a specific surface area of 70-250 m<SP>2</SP>/g, in an amount of 0.5-10.0 mass% based on 100 mass% of pulp. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

An object of the present invention is to provide a newsprint for offset printing having low post-printing opacity, high post-print opacity, printability and internal bond strength, and surface strength.

  Offset printing is the mainstream of recent commercial printing methods, including newspaper printing. Offset printing is a method in which a printing plate, usually called a PS plate, is prepared and dampening water and ink are supplied to the printing plate for printing. The printing plate is a lithographic plate, and the image area on the printing plate is treated to have an oleophilic surface, and the non-image area is treated to have a hydrophilic surface. When dampening water and ink are supplied to the printing plate, ink is attached to the image area and water is attached to the non-image area, and the ink is transferred from the printing plate to the paper through the blanket for printing. To do.

  In this offset printing, since ink with relatively strong tack is used, the paper is required to have high internal bond strength and surface strength. In addition, when dampening water adheres to the paper surface, if paper with low internal bond strength or surface strength is used, paper dust accumulates on the blanket or mixes with ink, so-called blurring occurs on the printing surface. In addition to troubles, paper out troubles may occur.

  In addition, in recent years, there has been a demand for weight reduction in newsprint paper, and accordingly, there is an increasing demand for paper that can maintain high opacity after printing. In order to increase the opacity of paper, white carbon, Inorganic pigments such as calcium carbonate, titanium oxide, and talc have been widely used as fillers for papermaking. These inorganic pigments inhibit the bonding force between fibers and cause a decrease in internal bonding force and surface strength. In addition, DIP (deinked waste paper pulp), which is regarded as important in terms of the environment, is formulated with a high rate of DIP, compared to mechanical pulp such as GP, RGP, and TMP. It is extremely difficult to achieve both high rate blending.

  Various proposals have been made to improve the above-mentioned problems. For example, by using a starch composition for paper coating in which a high-viscosity starch and a low-viscosity starch are blended as a surface treatment agent, surface strength and paper strength are improved. And a method for improving the affinity with a filler (see Patent Document 1) has been proposed. However, the proposed method does not have the effect of increasing ink fillability and opacity after printing, and the effect of suppressing blanket piling is not sufficient. Furthermore, there is almost no effect of preventing water breakage and there is a problem in printing workability.

  A method for suppressing surface strength and elution rate with respect to a dampening aqueous solution by using a surface sizing agent composition for printing paper comprising amylopectin content of 95% by weight or more and a water-resistant agent. (See Patent Document 2). However, in this composition, since the penetration of the fountain solution into the base material cannot be sufficiently suppressed, there is almost no effect of preventing water breakage. In addition, although the elution of amylopectin can be suppressed, the slight swelling of the amylopectin component, which is the main factor of the Nepali phenomenon, cannot be suppressed, so that the effect of improving the Nepali phenomenon is insufficient. Furthermore, in any of the above methods, the surface of the newsprint is low in hydrophobicity, so that the adhesion of the ink component is inferior, and it is difficult to obtain a high ink density on the paper. In addition, since the coating agent is highly hydrophilic and has no ink absorbability, there is no improvement in opacity after printing.

  Furthermore, as a means for improving ink fillability and opacity after printing, a method of applying various pigments has been proposed. Satin white, hydrated silicic acid, and hollow organic pigments can be applied to improve whiteness, opacity, and post-print opacity with a small amount of coating, but the bonding strength with the adhesive is weak and blanket piling is not possible. Since it deteriorates, it is necessary to increase the adhesive ratio, and as a result, the effect on opacity is reduced, which is not preferable in terms of cost (see Patent Documents 3, 4, and 5).

As described above, the opacity after printing is remarkably improved, the surface strength can be further increased, piling can be prevented, and the high internal bond strength is limited by the conventional method, and the target high level of quality. It was difficult to get.
Japanese Patent Laid-Open No. 5-195490 Japanese Unexamined Patent Publication No. 9-78495 JP 2000-34694 A JP 2001-164494 A JP 2000-314097 JP

An object of the present invention is to provide a newsprint for offset printing that has high post-printing opacity, printability, internal bond strength, and surface strength while being low basis weight.

In the present invention, in order to achieve both weight reduction, opacity after printing, and paper strength, the present invention of the present application has been made by intensive studies on fillers in the base paper.
The present invention includes the following inventions.
(1) It contains silicon-containing particles formed from silicon dioxide and / or silicate, and 0.1 to 40% by mass of alkali-resistant microparticles with respect to 100% by mass of the silicon-containing particles, and has a pore volume of Newsprint paper for offset printing containing 0.5 to 10.0% by mass of a porous filler having a specific surface area of 70 to 250 m ² / g with respect to 100% by mass of pulp.
(2) The newspaper for offset printing according to (1), wherein the porous filler has an average particle size of 10 to 40 μm or less.
(3) Newsprint paper for offset printing according to (1) or (2), wherein the internal bond strength (J.TAPPI No. 18-2) is 190 J / m ² or more.
(4) Newsprint paper for offset printing according to any one of (1) to (3), wherein the basis weight is 45 g / m ² or less and the opacity after printing is 91% or more.
(5) Newsprint paper for offset printing according to any one of (1) to (4), wherein 50% by mass or more of deinked waste paper pulp is contained in 100% by mass of the pulp.

The newspaper for offset printing according to the present invention has high post-printing opacity despite its low basis weight, high internal bond strength and surface strength, and excellent printability.

The present invention contains silicon-containing particles formed from silicon dioxide and / or silicate, and 0.1 to 40% by mass of anti-alkali microparticles with respect to 100 parts by mass of the silicon-containing particles. By using a porous filler having a volume of 3.0 to 5.0 mL / g and a specific surface area of 70 to 250 m ² / g, it is possible to maintain high ink absorption during printing and to improve opacity after printing. It is something that can be done.

Here, the silicate forming the silicon-containing particles is a compound represented by the general formula xM ₂ O · ySiO ₂ , xMO · ySiO ₂ , xM ₂ O ₃ · ySiO ₂ , wherein M is Al, Fe , Ca, Mg, Na, K, Ti, Zn (x and y are arbitrary positive numerical values).

Examples of the alkali-resistant fine particles include kaolin, calcined kaolin, calcium carbonate, barium sulfate, titanium dioxide, talc, alumina, magnesium carbonate, magnesium oxide, and magnesium hydroxide. Among these, calcium carbonate, kaolin, and talc are preferable because of cost advantage. Moreover, it is preferable that the particle diameter of an alkali-resistant microparticle is 0.2-7.0 micrometers which is excellent in the dispersibility in a reaction tank.

  The content of the alkali-resistant fine particles is 0.1 to 40 parts by mass with respect to 100 parts by mass of the silicon-containing particles. Due to the content of the alkali-resistant fine particles being in the above range, it is suitable for the bulkiness of paper and the prevention of crushing due to the fan pump from the preparation of pulp slurry to the sheet, the shearing force by stirring, the pressure by pressing, calendering, etc A porous filler having a narrow particle size distribution and an appropriate average particle size. When the content of the alkali-resistant fine particles is less than 0.1 parts by mass, a narrow particle size distribution cannot be obtained, and the surface strength and internal bond strength of the paper become insufficient. On the other hand, when the amount exceeds 40 parts by mass, a narrow particle size distribution cannot be obtained, the oil absorbability becomes insufficient, the transparency of the porous filler is improved, and the opacity is lowered when internally added to paper. The content of the alkali-resistant fine particles is obtained by tableting a powder sample of the porous filler and then measuring the amount of oxide of each element using a fluorescent X-ray analyzer.

Moreover, it is preferable that the pore volume of a porous filler is 3.0-5.0 mL / g, and a specific surface area is 70-250 m < ² > / g, Furthermore, 70-150 m < ² > / g. Here, the pore volume is the volume of all pores assuming that the pore shape is a geometric cylinder using a pore sizer 9230 (manufactured by Shimadzu Corporation). It is a value obtained from the relationship of the amount of mercury released. The specific surface area is the surface area of all pores assuming that the pore shape is a geometric cylinder using a pore sizer 9230 (manufactured by Shimadzu Corporation). It is a value obtained from the relationship of quantity.

When the maximum volume is less than 3.0 mL / g, the oil absorption decreases and high opacity after printing cannot be obtained when blended with paper, and when it exceeds 5.0 mL / g, the cohesive strength of the aggregate structure is weak. Therefore, it is easily crushed by the shearing force, press pressure, and calendar treatment pressure during pulp slurry preparation, and the oil absorption is insufficient.
When the specific surface area is less than 70 m ² / g, the particle size distribution is deteriorated, fine particles and coarse particles are increased, and the internal strength and the surface strength are lowered. If it exceeds 250 m ² / g, the cohesive strength of the aggregated structure will be weak, it will be easily crushed by the shearing force, pressing pressure, and calendering pressure at the time of pulp slurry preparation, and not only will the oil absorption be insufficient, but also dry shrinkage. This is not preferable because of the large percentage. In addition, as described above, the porous filler of the present invention needs to satisfy both a pore volume of 3.0 to 5.0 mL / g and a specific surface area of 70 to 250 m ² / g. This is because even if the pore volume is in the above desired range, if the specific surface area exceeds 250, the pore volume becomes small when blended into paper, which tends to be crushed with various shares. You cannot get opacity after printing. When the specific surface area is less than 70, the particle size distribution becomes poor even with the target pore volume, the fine particles and coarse particles increase, and the internal strength and the surface strength decrease.
Even if the specific surface area is 70 to 250 m ² / g, if the pore volume is less than 3.0, the post-printing opacity when blended in paper cannot be obtained. When the pore volume exceeds 5.0, the cohesive strength of the aggregated structure is weakened, and is easily crushed by the shearing force, the pressing pressure, and the calendering pressure at the time of pulp slurry preparation, and the oil absorption is insufficient.

The porous filler of the present invention preferably has an average particle size in the range of 10 μm to 40 μm. Furthermore, it is preferable that it is 10-30 micrometers. If it is less than 10 μm, the internal bond strength may be reduced, and if it exceeds 40 μm, the particle size distribution is deteriorated, resulting in an increase in coarse particles and a decrease in surface strength.
The average particle diameter in the present invention is a value that is 50% in volume integration as measured by a laser diffraction method using SALD2000J (manufactured by Shimadzu Corporation). Further, as the particle size distribution of the porous filler, the standard deviation (σ) is preferably 0.35 or less, and more preferably 0.30 or less. With such a particle size distribution, both coarse particles and fine particles are reduced, and better internal bond strength and surface strength can be obtained. Furthermore, the paper layer is not easily crushed and bulky when the surface treatment is performed with a calendar. In addition, the paper surface is less rough due to coarse particles and has good smoothness. In the present invention, the porous filler is contained in an amount of 0.5 to 10% by mass with respect to 100% by mass of the pulp. If the amount is less than 0.5% by mass, the above-described effects cannot be exhibited.

The porous filler according to the present invention contains a silicon-containing solution by adding a mineral-resistant solution and / or a metal salt solution of a mineral acid after adding alkali-resistant fine particles to the alkali-silicate aqueous solution, and neutralizing the alkali-silicate aqueous solution. What was manufactured by the method of depositing particle | grains in presence of a fixed electrolyte is preferable.
Here, the alkali silicate aqueous solution is not particularly limited, but a sodium silicate aqueous solution or a potassium silicate aqueous solution is preferable. The concentration of the alkali silicate aqueous solution is preferably 3 to 15% because the porous filler can be produced efficiently. When the alkali silicate aqueous solution is a sodium silicate aqueous solution, the SiO ₂ / Na ₂ O mole The ratio is preferably 2.0 to 3.4.

  The addition amount of the alkali-resistant microparticles is 0.1 to 40% by mass, preferably 0.5 to 30% by mass with respect to 100 parts by mass of the silicon-containing particles to be produced. When the addition amount of the alkali-resistant fine particles is within the above range, a porous filler having a suitable average particle diameter and narrow particle size distribution can be obtained, which is suitable for increasing the bulk of the paper and imparting opacity. Presence of alkali-resistant microparticles when depositing silicon-containing particles is considered to cause precipitation of silicon-containing particles while including alkali-resistant microparticles. The silicon-containing particles including alkali-resistant fine particles are considered to have a small particle size and form a narrow particle size distribution by stirring during precipitation. When the addition amount of the alkali-resistant microparticles is less than 0.1% by mass, it does not sufficiently function as the nucleus of the silicon-containing particles during precipitation, and when it exceeds 40 parts by mass, the bulkiness of the silicon-containing particles is impaired.

The alkali-resistant microparticles are preferably added to the alkali silicate aqueous solution while the alkali silicate aqueous solution is stirred while the alkali-resistant microparticles are added to the aqueous solution of the alkali-resistant microparticles. An aqueous solution can be added.
In addition, the alkali-resistant fine particles may be added all at once to the alkali silicate aqueous solution before the addition of the mineral acid solution and / or the metal salt solution of the mineral acid, or may be added in multiple portions. Good.

  In the mineral acid solution and / or the metal salt solution of the mineral acid, examples of the mineral acid include hydrochloric acid, sulfuric acid, nitric acid and the like, and examples of the metal salt of the mineral acid include sodium salt, potassium salt of the mineral acid, A calcium salt, an aluminum salt, etc. are mentioned. Among these, sulfuric acid and aluminum sulfate are preferable from the viewpoint of cost and handling, and an aqueous solution is preferable.

  The addition amount of the mineral acid solution and / or the metal salt solution of the mineral acid is in the range of 95 to 150% of the theoretically required neutralization amount, and the pH of the resulting slurry is adjusted to a range of more than 2.5 and 10 or less. An amount is preferred. When the addition amount of the mineral acid solution and / or the metal salt solution of the mineral acid is less than 95% of the theoretically required neutralization amount or the pH of the resulting slurry exceeds 10, the alkaline silicate aqueous solution as the raw material There is a lot of waste. On the other hand, if it exceeds 150% of the theoretically necessary neutralization amount or the pH of the resulting slurry is 2.5 or less, the filtrate pH generated when concentrating the porous filler becomes too low and difficult to handle. Become.

At the time of precipitation of the silicon-containing particles, it is preferable to stir at a speed of 5 to 15 m / sec with a stirring device. Here, the peripheral speed is an index of the shearing force, and the shearing force increases as the peripheral speed increases. When the peripheral speed is less than 5 m / sec, the shear force is too small, and it may be difficult to obtain an appropriate average particle size and narrow particle size distribution even if alkali-resistant fine particles are included.
On the other hand, when the peripheral speed at the time of precipitation exceeds 15 m / sec, the shearing force becomes too large, the particle size of the porous filler becomes small, and the internal bond strength may be lowered when blended in paper. In addition, the load power increases and the equipment costs increase.
As the stirring device, an agitator, a homomixer, a pipeline mixer or the like is preferable. Although it is possible to use a pulverizer such as a ball mill or a sand grinder, it is not preferable because problems such as an increase in fine particles and a thickening of the slurry tend to occur.

The mineral acid solution and / or the metal salt solution of the mineral acid may be added to the alkali silicate aqueous solution all at once, but since it has a better particle size distribution, it is divided into two or more stages. It is preferable to add.
When adding the mineral acid solution and / or the metal salt solution of the mineral acid in two or more stages, since the particle size distribution is particularly good, the temperature of the first stage alkali silicate aqueous solution is set to 20 to 70 ° C., In the second and subsequent stages, it is preferable to set the temperature to 70 ° C. or higher. In the first stage, it is preferable that the addition amount of the mineral acid solution and / or the metal salt solution of the mineral acid is in the range of 10 to 50% of the theoretically required neutralization amount.

In both the first and second stages, the mineral acid solution and / or the metal salt solution of the mineral acid can be added all at once or continuously to the alkali silicate aqueous solution.
After completion of the addition of the mineral acid solution and / or the metal salt solution of the mineral acid, an aging step of stirring while maintaining the temperature at the time of addition may be included as necessary.

  When adding the mineral acid solution and / or the metal salt solution of the mineral acid in one stage, the temperature of the alkali silicate aqueous solution is preferably 60 ° C. to the boiling point of the solution, and 75 ° C. to the boiling point of the solution. More preferably. The mineral acid solution and / or the metal salt solution of the mineral acid can be added to the alkali silicate aqueous solution all at once or continuously.

In the present invention, chemical pulp (NBKP, LBKP, etc.), mechanical pulp (GP, CGP, RGP, PGW, TMP, etc.), deinked waste paper pulp (DIP, etc.), etc. are used alone or mixed in any ratio as raw material pulp However, when the deinked waste paper pulp is contained in an amount of 50% by mass or more in the total pulp, the effect of the porous filler used in the present application is large, which is preferable. It is preferable to contain 0.5 to 10.0% by mass of the porous filler with respect to 100% by mass of the pulp. Addition of a porous filler with a good particle size distribution reduces the decrease in internal strength and surface strength. In addition, the paper layer is not easily crushed when the surface treatment is performed with a calender, and is bulky. The paper surface roughness is small and has good smoothness. However, if the content in the paper is less than 0.5%, the above-mentioned effects cannot be exhibited.
Further, it is possible to add paper fillers such as white carbon, clay, amorphous silica, talc, titanium oxide, calcium carbonate, etc., so long as they do not affect paper strength such as internal bond strength and surface strength. . Further, if necessary, papermaking chemicals such as an internal sizing agent, a fixing agent, a paper strength enhancer, a yield improver, a water resistance agent, and an ultraviolet absorber are appropriately added, and the paper machine is not limited. There are no particular limitations on the papermaking conditions of the base paper. As the paper machine, for example, a commercial paper machine such as a long paper machine, a gap former paper machine, a circular paper machine, or a short paper machine can be selected and used as appropriate according to the purpose. .

  The newspaper for offset printing of the present invention has a blue or purple dye or colored pigment, fluorescent dye, thickener, water retention agent, antioxidant, antioxidant, as long as the effect of the present invention is not hindered. Various auxiliary agents such as a conductive treatment agent, an antifoaming agent, an ultraviolet absorber, a dispersant, a pH adjuster, a mold release agent, a water-resistant agent, and a water repellent agent can be appropriately blended.

  In the present invention, a surface treating agent can be applied to improve the surface strength. There is no particular limitation on the surface treatment agent, and starch, starch derivatives, water-soluble resins, water-dispersible resins, etc. can be used as an adhesive. For example, starch such as corn, potato, tapioca, wheat, rice, etc. and oxidation of the above starch Examples thereof include starch derivatives such as starch, dialdehyde starch, phosphoric acid-modified starch and cationized starch, synthetic water-soluble binders such as polyacrylamide resins and polyvinyl alcohol, and copolymer latexes such as styrene-butadiene copolymers. The polyacrylamide resin has a molecular weight of about tens of thousands to 2,000,000, and is a polymer of acrylamide, a polymer of methacrylamide, a copolymer of acrylamide and methacrylamide, or a polymer or copolymer of these. Examples thereof include a polymer obtained by partially hydrolyzing and partially methylolizing the coalescence. Among them, a polyacrylamide resin is preferably used because it has good Nepari property and is inexpensive and has a starch or starch derivative and good surface strength.

  Addition of a surface sizing agent such as a styrene-acrylic acid copolymer or a styrene-maleic acid copolymer to the above adhesive in an amount of 5 to 50% by mass is also appropriately performed for the purpose of improving the size of the surface. For the purpose of improving opacity, it is also effective to add pigments such as calcium carbonate, kaolin, white carbon, amorphous silica, titanium oxide, and plastic pigment at a ratio of 200% by mass or less based on the adhesive. In addition, the range of 30-100 mass% is preferable for the adhesive agent chosen from starch, a starch derivative, or a polyacrylamide type resin with respect to the surface treatment agent total solid.

The surface treatment agent thus obtained is applied on the base paper of printing newsprint in a solid content concentration range of 2% to 15%, but the coating amount is generally 0.05 to 2 g / side. m ^2, preferably applied in the range of 0.1 to 1 g / ^{m 2.} Hardly sufficient surface strength can not be obtained if the coating amount is less than ^{0.05g / m 2, 2g / m} 2 increase exceeds the Neppari strength and undesirably to cause sticking problems in the blanket.

  The coating apparatus for applying the surface treating agent composition to the newsprint base paper is not particularly limited. For example, an ink line or a vertical two-roll size press, a blade metalling size press, a rod metalling size press. Roll coater such as gate roll coater, trailing, flexible, roll application, fountain application, bevel type and vent type blade coater such as short dwell, rod blade coater, bar coater, air knife coater, curtain coater, spray coater, gravure A publicly known apparatus such as a coater is appropriately used. In addition, as a method of drying the wet coating layer after apply | coating a surface treating agent composition, various systems, such as vapor | steam drying, gas heater drying, electric heater drying, infrared heater drying, are employable, for example.

  In the production of newsprint for offset printing according to the present invention, after the formation of the coating layer of the surface treatment agent composition, smoothing treatment is performed in various calendar devices. Commonly used calendar devices such as a render, a soft calendar, a gloss calendar, a compact calendar, a mat super calendar, and a mat calendar can be used as appropriate. As the calender finishing conditions, the temperature of the rigid roll, the calender pressure, the number of nips, the roll speed, the paper moisture before the calender, and the like are appropriately selected according to the required quality. Furthermore, the calendar device includes an off type that is different from the coater and an on type that is integrated with the coater, but can be used in either case. The material of the calendar apparatus to be used is a roll which is mirror-finished with a metal or a hard chrome plating on the surface of a rigid roll. As the elastic roll, a roll obtained by molding a resin roll such as urethane resin, epoxy resin, polyamide resin, phenol resin, or polyacrylate resin, cotton, nylon, asbestos, aramid fiber, or the like is appropriately used. It should be noted that it is of course possible to use a suitable combination of a water coating device, an electrostatic humidifying device, a steam humidifying device, etc., for humidity control and humidification of the coated paper after finishing with a calendar.

The offset printing newsprint of the present invention can have a post-printing opacity as high as 91% or more, even if the basis weight is 45 g / m ² or less, due to the effect of the embedded porous filler. The internal bond strength (J.TAPPI No18-2) is 190J / ^{m 2,} preferably at least because it is 200 J / ^{m 2} or greater, there is no possibility of causing such blurred or out of paper.

  EXAMPLES The present invention will be specifically described below with reference to examples, but the present invention is not limited to these examples. In addition, unless otherwise indicated, the part and% in an example show a mass part and the mass%, respectively. Further, the average particle diameter, specific surface area, pore volume, content of alkali-resistant microparticles in the porous filler used in Examples and Comparative Examples, and the opacity after printing, surface strength, The density, ash content in the paper, white paper opacity, and internal bond strength were measured by the following methods.

(Average particle size and particle size distribution)
The average particle diameter is a value that is 50% in volume integration as measured by a laser diffraction method using SALD2000J (manufactured by Shimadzu Corporation).
The particle size distribution of the porous filler is indicated by the standard deviation (σ) value.
(Pore volume and specific surface area)
It measured using the pore sizer 9230 (made by Shimadzu Corp.).
(Content of alkali-resistant fine particles in the porous filler)
It is the value measured using a fluorescent X-ray analyzer (Spectris PW2404).

(Opacity after printing)
JAPAN TAPPI No. 45. In addition, on the basis of the real rice floor of Example 1, a sample of different rice floor was corrected to 0.6% / US square foot 1 g / m ² .

(Surface strength)
Create a sample mount with the newspaper for offset printing obtained in each of the examples and comparative examples attached, and print ink (paper test SD50 Red BT & K TOKA Co., Ltd.) with an RI printing tester (Meiji Seisakusho). Printing was performed using 0.4 cc, and the degree of picking on the printed surface was visually evaluated. Evaluation was performed by the following five-step evaluation.
5: The strength is very high, there is no practical problem, and the quality is excellent.
4: High strength, practically satisfactory, and excellent quality.
3: The strength is high and there is no practical problem.
2: The strength is slightly inferior and there is a problem in practical use.
1: The strength is remarkably inferior, it is a problem in practical use, and the quality is remarkably inferior.

(ash)
Ashing was performed at 525 ° C. based on JIS P 8251.
(Opacity)
Measured according to JIS P 8149.
(Internal bond strength)
J. et al. TAPPI No. It measured according to 18-2.

(Manufacture of porous filler A)
161 g of 5% sodium sulfate aqueous solution was added to 831 g of tap water, and 330 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Expressed as “charcoal cal A” in the table.) 100 g (10 parts with respect to 100 parts of silicon-containing particles) was added at a temperature of 50 ° C. while stirring with a three-one motor (using pitched turbine blades). Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / second, 74 g of sulfuric acid (concentration 20%) was added in 15 minutes to neutralize the first stage, and then the temperature was increased to 90 ° C. at the peripheral speed. Warm up. Subsequently, 200 g of sulfuric acid was added over 40 minutes at this temperature, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 5.0.
When the obtained porous filler was measured with the laser diffraction particle size distribution analyzer, the 50% mass integrated particle size was 14.3 μm, and the standard deviation was 0.259.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 4.1 cc / g, and the specific surface area was 132 m ² / g. The content of alkali-resistant fine particles was 8.5 parts with respect to 100 parts of silicon-containing particles.

(Manufacture of porous filler B)
After adding 754 g of 5% sodium sulfate aqueous solution to 263 g of tap water, 330 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Expressed as “charcoal cal A” in the table.) 100 g (10 parts with respect to 100 parts of silicon-containing particles) was added at a temperature of 50 ° C. while stirring with a three-one motor (using pitched turbine blades). Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / second, 74 g of sulfuric acid (concentration 20%) was added in 15 minutes to neutralize the first stage, and then the temperature was increased to 90 ° C. at the peripheral speed. Warm up. Subsequently, 200 g of sulfuric acid was added over 40 minutes at this temperature, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 5.0.
When the obtained porous filler was measured with the laser diffraction particle size distribution analyzer, the 50% mass cumulative value was 21.1 μm and the standard deviation was 0.288.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 3.8 cc / g, and the specific surface area was 96 m ² / g. The content of alkali-resistant fine particles was 8.3 parts with respect to 100 parts of silicon-containing particles.

(Manufacture of porous filler C)
After adding 238 g of 5% aqueous sodium sulfate solution to 746 g of tap water, 330 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Expressed as “charcoal cal A” in the table.) 100 g (10 parts with respect to 100 parts of silicon-containing particles) was added at a temperature of 50 ° C. while stirring with a three-one motor (using pitched turbine blades). Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / sec, 86 g of sulfuric acid (concentration 20%) was added for 15 minutes to neutralize the first stage, and then the temperature was increased to 90 ° C. at the above peripheral speed. Warm up. Subsequently, 188 g of sulfuric acid was added over 40 minutes at the same temperature, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 5.0.
When the obtained porous filler was measured by the laser diffraction particle size distribution analyzer, the particle diameter of the 50% mass integrated value was 19.4 μm, and the standard deviation was 0.222.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 4.9 cc / g, and the specific surface area was 240 m ² / g. The content of alkali-resistant fine particles was 8.4 parts with respect to 100 parts of silicon-containing particles.

(Manufacture of porous filler D)
After adding 451 g of 5% sodium sulfate aqueous solution to 501 g of tap water, 330 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Expressed as “charcoal cal A” in the table.) 100 g (10 parts relative to 100 parts of silicon-containing particles) was added at a temperature of 60 ° C. while stirring with a three-one motor (using pitched turbine blades). Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / second, 69 g of sulfuric acid (concentration 20%) was added in 15 minutes to neutralize the first stage, and then the temperature was increased to 90 ° C. at the peripheral speed. Warm up. Next, 204 g of sulfuric acid was added over 40 minutes at the same temperature, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 5.0.
When the obtained porous filler was measured with the laser diffraction particle size distribution analyzer, the particle diameter at 50% mass integrated value was 12.7 μm, and the standard deviation was 0.241.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 3.6 cc / g, and the specific surface area was 80 m ² / g. The content of alkali-resistant fine particles was 8.4 parts with respect to 100 parts of silicon-containing particles.

(Manufacture of porous filler E)
161 g of 5% sodium sulfate aqueous solution was added to 917 g of tap water, and 330 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Expressed as “charcoal cal A” in the table.) 5 g (0.5 part with respect to 100 parts of silicon-containing particles) was added at a temperature of 50 ° C. while stirring with a three-one motor (using pitched turbine blades). Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / second, 74 g of sulfuric acid (concentration 20%) was added in 15 minutes to neutralize the first stage, and then the temperature was increased to 90 ° C. at the peripheral speed. Warm up. Subsequently, 174 g of sulfuric acid was added over 40 minutes at this temperature, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 4.7.
When the obtained porous filler was measured with the laser diffraction particle size distribution analyzer, the particle diameter of the 50% mass integrated value was 11.1 μm, and the standard deviation was 0.266.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 4.0 cc / g, and the specific surface area was 92 m ² / g. The content of alkali-resistant fine particles was 0.4 parts with respect to 100 parts of silicon-containing particles.

(Manufacture of porous filler F)
After adding 161 g of 5% aqueous sodium sulfate solution to 558 g of tap water, 330 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Expressed as “charcoal cal A” in the table.) 400 g (40 parts with respect to 100 parts of silicon-containing particles) was added at a temperature of 50 ° C. while stirring with a three-one motor (using pitched turbine blades). Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / second, 74 g of sulfuric acid (concentration 20%) was added in 15 minutes to neutralize the first stage, and then the temperature was increased to 90 ° C. at the peripheral speed. Warm up. Subsequently, 280 g of sulfuric acid was added over 40 minutes at the same temperature, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 5.1.
When the obtained porous filler was measured with the laser diffraction particle size distribution analyzer, the particle diameter of the 50% mass integrated value was 15.9 μm, and the standard deviation was 0.285.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 4.3 cc / g, and the specific surface area was 198 m ² / g. The content of alkali-resistant fine particles was 34 parts with respect to 100 parts of silicon-containing particles.

(Manufacture of porous filler G)
After adding 875 g of 5% sodium sulfate aqueous solution to 45 g of tap water, 330 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Expressed as “charcoal cal A” in the table.) 200 g (20 parts with respect to 100 parts of silicon-containing particles) was added at a temperature of 50 ° C. while stirring with a three-one motor (using pitched turbine blades). Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / sec, 86 g of sulfuric acid (concentration 20%) was added for 15 minutes to neutralize the first stage, and then the temperature was increased to 90 ° C. at the above peripheral speed. Warm up. Subsequently, 214 g of sulfuric acid was added over 40 minutes at this temperature, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 5.2.
When the obtained porous filler was measured by the laser diffraction particle size distribution analyzer, the 50% mass integrated particle size was 41.3 μm, and the standard deviation was 0.388.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 4.0 cc / g, and the specific surface area was 158 m ² / g. The content of alkali-resistant fine particles was 18 parts with respect to 100 parts of silicon-containing particles.

(Manufacture of porous filler H)
To 994 g of tap water, 330 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Expressed as “charcoal cal A” in the table.) 100 g (10 parts with respect to 100 parts of silicon-containing particles) was added at a temperature of 50 ° C. while stirring with a three-one motor (using pitched turbine blades). Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / second, 67 g of sulfuric acid (concentration 20%) was added in 15 minutes to neutralize the first stage, and then the temperature was increased to 90 ° C. at the above peripheral speed. Warm up. Next, 207 g of sulfuric acid was added over 40 minutes at the same temperature, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 5.1.
When the obtained porous filler was measured by the laser diffraction particle size distribution analyzer, the particle diameter at 50% mass integrated value was 9.6 μm, and the standard deviation was 0.273.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 3.9 cc / g, and the specific surface area was 111 m ² / g. The content of alkali-resistant fine particles was 8.8 parts with respect to 100 parts of silicon-containing particles.

(Manufacture of porous filler I)
After adding 350 g of 5% aqueous sodium sulfate solution to 881 g of tap water, 174 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Expressed as “charcoal A” in the table.) 53 g (10 parts relative to 100 parts of silicon-containing particles) was added at a temperature of 50 ° C. while stirring with a three-one motor (using pitched turbine blades). Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / second, 46 g of sulfuric acid (concentration 20%) was added in 15 minutes to neutralize the first stage, and then the temperature was increased to 90 ° C. at the above peripheral speed. Warm up. Subsequently, 99 g of sulfuric acid was added over 40 minutes at this temperature, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 4.8.
When the obtained porous filler was measured by the laser diffraction particle size distribution analyzer, the 50% mass integrated particle size was 15.6 μm, and the standard deviation was 0.298.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 5.1 cc / g, and the specific surface area was 256 m ² / g. The content of alkali-resistant fine particles was 8.6 parts with respect to 100 parts of silicon-containing particles.

(Manufacture of porous filler J)
161 g of 5% sodium sulfate aqueous solution was added to 831 g of tap water, and 330 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Expressed as “charcoal cal A” in the table.) 100 g (10 parts relative to 100 parts of silicon-containing particles) was added at a temperature of 90 ° C. while stirring with a three-one motor (using pitched turbine blades). Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / sec, 74 g of sulfuric acid (concentration 20%) was added for 15 minutes to neutralize the first stage, and the temperature was maintained at the above peripheral speed. Then, 200 g of sulfuric acid was added over 40 minutes, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 5.0.
When the obtained porous filler was measured by the laser diffraction particle size distribution analyzer, the particle diameter of the 50% mass integrated value was 23.0 μm, and the standard deviation was 0.388.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 2.8 cc / g, and the specific surface area was 62 m ² / g. The content of alkali-resistant fine particles was 8.3 parts with respect to 100 parts of silicon-containing particles.

(Manufacture of porous filler K)
161 g of 5% sodium sulfate aqueous solution was added to 921 g of tap water, and 330 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Indicated as “charcoal cal A” in the table) 1.0 g (0.1 part with respect to 100 parts of silicon-containing particles) was added at a temperature of 50 ° C. while stirring with a three-one motor (using pitched turbine blades). did. Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / second, 74 g of sulfuric acid (concentration 20%) was added in 15 minutes to neutralize the first stage, and then the temperature was increased to 90 ° C. at the peripheral speed. Warm up. Subsequently, 174 g of sulfuric acid was added over 40 minutes at this temperature, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 5.0.
When the obtained porous filler was measured by the laser diffraction particle size distribution analyzer, the 50% mass integrated particle size was 10.3 μm, and the standard deviation was 0.355.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 3.9 cc / g, and the specific surface area was 80 m ² / g. The content of alkali-resistant microparticles was 0.08 parts with respect to 100 parts of silicon-containing particles.

(Manufacture of porous filler L)
161 g of 5% sodium sulfate aqueous solution was added to 467 g of tap water, and 330 g of a commercially available No. 3 sodium silicate aqueous solution (solid content concentration 38%) was added while stirring with a three-one motor. Further, as alkali-resistant fine particles, a dispersion A of calcium carbonate (TP-121 “spindle”, manufactured by Okutama Kogyo Co., Ltd., solid content concentration of 9.5, adjusted to have an average particle size of 0.6 μm with a sand grinder). %, Expressed as “charcoal cal A” in the table.) 500 g (50 parts with respect to 100 parts of silicon-containing particles) was added at a temperature of 50 ° C. while stirring with a three-one motor (using pitched turbine blades). Thereafter, the peripheral speed of the stirring blade was adjusted to 10 m / second, 74 g of sulfuric acid (concentration 20%) was added in 15 minutes to neutralize the first stage, and then the temperature was increased to 90 ° C. at the peripheral speed. Warm up. Subsequently, 306 g of sulfuric acid was added over 40 minutes at this temperature, and the second stage neutralization was performed to obtain a porous filler. The pH of the reaction solution was 5.0.
When the obtained porous filler was measured by the laser diffraction particle size distribution analyzer, the particle diameter of the 50% mass integrated value was 16.8 μm, and the standard deviation was 0.332.
A part of the cake after filtration and washing was dried at 105 ° C., and the specific surface area and pore diameter were measured, and the content of alkali-resistant fine particles was measured with a fluorescent X-ray analyzer.
The pore volume in the obtained porous filler was 4.3 cc / g, and the specific surface area was 220 m ² / g. The content of alkali-resistant fine particles was 42 parts with respect to 100 parts of silicon-containing particles.

Example 1
10 parts of softwood kraft pulp, 40 parts of thermomechanical pulp and 50 parts of deinked waste paper pulp were mixed and disaggregated. S. F. (Canadian Standard Freeness) pulp slurry prepared to 0.5% of cationized starch (P3Y, PIRAAB STARCH Co., Ltd.) per dry dry pulp, and porous filler A containing porous filler in paper was added such that the amount of 3% after adjusting for papermaking pH to 4.5 with aluminum sulfate, and paper making the resulting stock by on-top twin wire paper machine, basis weight 40 g / m ² newsprint base paper Got.
Next, 100 parts of oxidized corn starch (trade name; Oji Ace A, manufactured by Oji Corn Starch Co., Ltd.), an olefin-based sizing agent (trade name; OT-) are coated on both sides of the above-mentioned newsprint paper as a coating solution for the surface treating agent composition. 25, manufactured by Arakawa Chemical Co., Ltd.) Using a gate roll coater, a mixed aqueous solution having a solid content concentration of 8.8% consisting of 10 parts is 0.35 g / m ² per side after drying. Thus, after applying and drying, a soft calender finish comprising a resin roll / metal roll was performed to obtain an offset printing newsprint with an actual amount of 40.7 g / m ² .

Example 2
Newsprint paper for offset printing was obtained in the same manner as in Example 1 except that the porous filler B was used as the filler.

Example 3
Newsprint paper for offset printing was obtained in the same manner as in Example 1 except that the following porous filler C was used.

Example 4
Newsprint paper for offset printing was obtained in the same manner as in Example 1 except that the following porous filler D was used.

Example 5
Newsprint paper for offset printing was obtained in the same manner as in Example 1 except that the following porous filler E was used.

Example 6
Newsprint paper for offset printing was obtained in the same manner as in Example 1 except that the following porous filler F was used.

Example 7
Newsprint paper for offset printing was obtained in the same manner as in Example 1 except that the following porous filler G was used.

Example 8
Newsprint paper for offset printing was obtained in the same manner as in Example 1 except that the following porous filler H was used.

Example 9
Porous filler B was added so that the content of porous filler in the paper would be 1%, and after adjusting the papermaking pH to 4.5 with a sulfuric acid band, the resulting paper stock was made with an on-top twin-wire paper machine. and, except that to obtain newsprint base paper basis weight 40 g / m ² was obtained for offset printing newsprint of example 1 in the same manner as the actual amount 40.7 g / m ^2.

Example 10
Porous filler B was added so that the porous filler content in the paper would be 8%, and after adjusting the papermaking pH to 4.5 with a sulfuric acid band, the resulting paper stock was made with an on-top twin-wire paper machine. and, except that to obtain newsprint base paper basis weight 40 g / m ² was obtained for offset printing newsprint of example 1 in the same manner as the actual amount 40.7 g / m ^2.

Comparative Example 1
Newsprint paper for offset printing was obtained in the same manner as in Example 1 except that the following porous filler I was used.

Comparative Example 2
Newsprint paper for offset printing was obtained in the same manner as in Example 1 except that the following porous filler J was used.

Comparative Example 3
Newsprint paper for offset printing was obtained in the same manner as in Example 1 except that the following porous filler K was used.

Comparative Example 4
Newsprint paper for offset printing was obtained in the same manner as in Example 1 except that the following porous filler L was used.

Comparative Example 5
Porous filler A was added so that the porous filler content in the paper was 0.4%, and after adjusting the papermaking pH to 4.5 with a sulfuric acid band, the obtained paper stock was put on an on-top twin-wire paper machine. paper to obtain a basis weight 40 g / m ² newspaper offset printing newsprint other than to obtain a base paper in the same manner as in example 1 actual amount 40.7 g / m ^2.

Comparative Example 6
Porous filler A was added so that the content of the porous filler in the paper was 11%, and after adjusting the papermaking pH to 4.5 with a sulfuric acid band, the resulting stock was made with an on-top twin-wire paper machine. , except that to obtain newsprint base paper basis weight 40 g / m ² was obtained for offset printing newsprint of example 1 in the same manner as the actual amount 40.7 g / m ^2.

The conditions of Examples 1 to 10 and Comparative Examples 1 to 6 are summarized in Table 1.

Claims (5)

In newsprint for offset printing, containing silicon-containing particles formed from silicon dioxide and / or silicate, and 0.1 to 40% by mass of alkali-resistant fine particles with respect to 100% by mass of the silicon-containing particles, 0.5 to 10.0% by mass of a porous filler having a pore volume of 3.0 to 5.0 mL / g and a specific surface area of 70 to 250 m ² / g with respect to 100% by mass of pulp. Characteristic newsprint for offset printing. The newspaper for offset printing according to claim 1, wherein the porous filler has an average particle size of 10 to 40 µm. The newspaper for offset printing according to any one of claims 1 and 2, wherein the basis weight is 45 g / m ² or less and the opacity after printing is 91% or more. The newsprint for offset printing according to any one of claims 1 to 3, wherein an internal bond strength (J.TAPPI No. 18-2) is 190 J / m ² or more. The newsprint paper for offset printing according to any one of claims 1 to 4, wherein 50 mass% or more of deinked waste paper pulp is contained in 100 mass% of the pulp.