JP2008050377A - Thickener comprising water-dispersible cellulose and polysaccharide - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a thickener for producing viscosity even with a small amount by including a water-dispersible cellulose being a fine fibrous cellulose and a polysaccharide. <P>SOLUTION: The thickener comprises: a water-dispersible cellulose which is a fine fibrous cellulose composed of plant cell walls as a raw material, contains &ge;30 mass% of a component (major axis: 0.5-30 &mu;m, minor axis: 2-600 nm and the ratio of major axis/minor axis: 20-400) stably suspending in water and has a dissipation factor of &lt;1 when made into 0.5 mass% water dispersion; and a polysaccharide and produces viscosity with a small amount. <P>COPYRIGHT: (C)2008,JPO&amp;INPIT

Description

  The present invention relates to a thickener comprising water-dispersible cellulose, which is fine fibrous cellulose, and at least one polysaccharide, which can impart viscosity with a small amount.

  Conventionally, polysaccharides such as tamarind seed gum and pectin are generally used as thickeners for thickening products such as foods and cosmetics. In general, the amount of thickener that can be added to foods, cosmetics and the like is limited to the upper limit of product design. Therefore, a thickener that can exhibit the desired viscosity in as little amount as possible is desired.

As the fine fibrous cellulose made from plant cell walls, microfibrous cellulose, cellulose nanofibrils, and the like are known. While these fine fibrous celluloses can be expected to have a high thickening effect to a certain extent, they are expensive in comparison with general polysaccharides, so that it is difficult to use them alone. In addition, since the “miniaturization” described later is insufficient, the cellulose fibers are rough, the food texture and the touch feel uncomfortable, and the use that can be used as a thickener is very limited.
Patent Documents 1 to 3 and the like are known as thickeners containing fine fibrous cellulose and polysaccharides. The effects shown in these are “mamako prevention”, “intestinal regulation” and the like, and it is not described that the amount of thickener added can be reduced by using in combination with a specific polysaccharide.

In Patent Documents 4 and 5, there is a disclosure relating to a composition in which cellulose nanofibrils obtained from cells having a primary wall of about 80% or more and other additives are blended. This is an improvement in the properties of cellulose nanofibril itself, such as an improvement in the redispersibility of the dried product.
Patent Document 6 describes a gel-forming composition containing a water-dispersible dry composition and a polysaccharide, but this polysaccharide is limited to glucomannan, galactomannan, and sodium alginate, and is used in the present invention. It is different from polysaccharides. In addition, it is said that an intrinsic gel (True gel) is formed when a water-dispersible dry composition and a gel-forming composition containing a polysaccharide of Patent Document 6 are added and the aqueous dispersion is allowed to stand. On the other hand, the thickener of the present invention is different in that it is not gelled, that is, the fluidity of the aqueous dispersion or liquid composition to which the thickener is added is maintained and a true gel is not formed. When gelled, the fluidity is lost and the form is no longer liquid, so the function and physical properties of the aqueous dispersion and liquid composition are lost, and the function as a thickener is not manifested. is there.

Japanese Patent No. 1731182 JP 60-260517 A Japanese Patent No. 1850006 Special table 2001-520180 gazette Japanese Patent No. 3247391 JP 2004-411119 A

  An object of this invention is to provide the thickener which can provide viscosity with a small amount by containing the water-dispersible cellulose which is fine fibrous cellulose, and a polysaccharide.

  The present inventor has solved the problems and made the present invention by containing water-dispersible cellulose, which is fine fibrous cellulose made from plant cell walls, and polysaccharides. That is, the present invention is as follows.

(1) Fine fibrous cellulose made from plant cell walls as a raw material, and stably suspended in water (major axis: 0.5 to 30 μm, minor axis: 2 to 600 nm, major axis / minor axis ratio: 20 to 400) containing 30% by mass or more and having a loss tangent of less than 1 when the aqueous dispersion is 0.5% by mass, tamarind seed gum, pectin, Contains at least one polysaccharide selected from carrageenan, gellan gum, sodium carboxymethyl cellulose, soybean water-soluble polysaccharide, xanthan gum, karaya gum, psyllium seed gum, pullulan, gum arabic, tragacanth gum, gaddy gum, arabinogalactan, curdlan A water-dispersible cellulose: polysaccharide = 1: 9 to 9: 1 mass ratio. Thickeners.

(2) A water-dispersible dry composition comprising 50 to 95% by mass of the water-dispersible cellulose described in (1) and 5 to 50% by mass of a water-soluble polymer and / or a hydrophilic substance, and (1) A composition comprising at least one polysaccharide selected from polysaccharides, wherein the composition comprises a water-dispersible dry composition: polysaccharide = 1: 9 to 9: 1 in a mass ratio. Sticky.
(3) A water-dispersible dry composition comprising 50 to 95% by weight of the water-dispersible cellulose described in (1), 1 to 49% by weight of a water-soluble polymer, and 1 to 49% by weight of a hydrophilic substance, and at least A composition containing one kind of polysaccharide, wherein the polysaccharide is selected from the group consisting of tamarind seed gum, pectin, carrageenan, sodium carboxymethylcellulose, soybean water-soluble polysaccharide, and karaya gum. The thickener according to (2).
(4) A liquid composition formulated by adding the thickener according to any one of (1) to (3).

  A thickener comprising water-dispersible cellulose, which is fine fibrous cellulose, and at least one polysaccharide, and capable of imparting viscosity in a small amount can be provided.

Hereinafter, the present invention will be specifically described focusing on its preferred form. The water-dispersible cellulose of the present invention is made from plant cell walls. Specifically, materials that can be stably obtained at low cost and can be used industrially are preferable, such as wood (conifers, hardwoods), cotton linters, kenaf, Manila hemp (Abaca), sisal hemp Pulp mainly composed of natural cellulose such as jute, survivorgrass, esparto grass, bagasse, rice straw, straw, straw and bamboo is used. Cotton, papyrus grass, beet, ridges, honey, and ganpi can also be used, but reasons such as difficulty in securing stable raw materials, high content of components other than cellulose, and difficulty in handling May not be preferable. When regenerated cellulose is used as a raw material, sufficient performance is not exhibited, so regenerated cellulose is not included as a raw material of the present invention.
Specific examples of preferable raw materials are wood pulp, cotton linter pulp, bagasse pulp, wheat straw pulp, rice straw pulp, bamboo pulp and the like. Particularly preferred are cellulosic substances originating from the cell walls of gramineous plants, specifically bagasse pulp, wheat straw pulp, rice straw pulp and bamboo pulp.

The crystallinity of the fine fibrous cellulose used in the present invention is not particularly defined, but the crystallinity as measured by the X-ray diffraction method (Segal method) is preferably greater than 50%. 55% or more is more preferable. The water-dispersible dry composition used in the present invention contains components other than cellulose, but these components are amorphous and are counted as amorphous.
The cellulose used in the present invention is “fine fibrous”. In the present specification, “fine fibrous” refers to a length (major axis) of about 0.5 μm to 1 mm and a width (minor axis) of 2 nm to as observed and measured with an optical microscope and an electron microscope. It means that the ratio of length to width (major axis / minor axis) is about 5 to 400, about 60 μm.

  The water-dispersible cellulose or water-dispersible dry composition of the present invention contains a component that is stably suspended in water. Specifically, it is a component having the property of being stably suspended in water without settling even when it is centrifuged at 1000 G for 5 minutes in the form of a 0.1% by weight aqueous dispersion. The length (major axis) observed and measured with a high-resolution scanning electron microscope (SEM) is 0.5 to 30 μm, the width (minor axis) is 2 to 600 nm, and the ratio of length to width (major axis) / Minor axis ratio) is composed of fibrous cellulose having a ratio of 20 to 400. Preferably, the width is 100 nm or less, more preferably 50 nm.

The water-dispersed cellulose or water-dispersible dry composition used as a constituent of the thickener of the present invention contains 30% by mass or more of this “component that is stably suspended in water”. When the content of this component is less than 30% by mass, the above-described function is not sufficiently exhibited. The content of “a component that is stably suspended in water” is preferably as high as possible, but is preferably 50% or more. Unless otherwise specified, the content of this component represents the abundance ratio in the total cellulose, and is measured and calculated so that it is not included even if a water-soluble component is included. .
The water-dispersible cellulose or water-dispersible dry composition used as a constituent of the thickener of the present invention is measured under the conditions of a strain of 10% and a frequency of 10 rad / s in an aqueous dispersion having a concentration of 0.5% by mass. The loss tangent (tan δ) is less than 1, preferably less than 0.6. If it is less than 0.6, the performance is further improved. When the loss tangent is 1 or more, the viscosity amplification function described later cannot be sufficiently exhibited.

  In order to make the loss tangent of the water-dispersible cellulose or water-dispersible dry composition used as a constituent of the thickener of the present invention less than 1, it is necessary to take out microfibrils derived from plant cell walls without cutting them short. There is. However, with the current technology, it is not possible to perform only “miniaturization” without “short fiber” at all. (In this case, “short fiber” means that the fiber is cut short, or the state of the shortened fiber. Also, “miniaturization” means that the fiber is made thin by giving an action such as tearing, or In other words, in order to make the loss tangent less than 1, it is important to advance the “miniaturization” while minimizing the “short fiber” of the cellulose fiber. Although the preferable method for that is shown below, it is not limited to these methods at all.

The cellulosic substance originating from the plant cell wall selected as a raw material in order to advance the “miniaturization” while minimizing the “short fiber” of the cellulose fiber has an average degree of polymerization of 400 to 12000, and α -The cellulose content (%) is preferably 60 to 100% by mass, more preferably 60 to 85% by mass.
A high-pressure homogenizer is preferable as an apparatus used for advancing “miniaturization” while minimizing “shortening” of cellulose fibers. Specific examples of the high-pressure homogenizer include emulflex (made by AVETIN Inc.), optimizer system (made by Sugino Machine Co., Ltd.), nanomizer system (made by Nanomizer Co., Ltd.), microfluidizer (made by MFIC Corp.), valve Type homogenizers (manufactured by Sanwa Machine Co., Ltd., manufactured by Invesys APV, manufactured by Niro Soavi, manufactured by Izumi Food Machinery Co., Ltd.), and the like. The processing pressure of the high-pressure homogenizer is preferably 30 MPa or more, more preferably 60 to 414 MPa.

  Polysaccharides used in the present invention are tamarind seed gum, pectin, carrageenan, gellan gum, sodium carboxymethyl cellulose, soybean water-soluble polysaccharide, xanthan gum, karaya gum, psyllium seed gum, pullulan, gum arabic, tragacanth gum, gaddy gum, arabinogalactan, At least one selected from the group consisting of curdlan, preferably from the group consisting of tamarind seed gum, pectin, carrageenan, sodium carboxymethyl cellulose, soybean water-soluble polysaccharide, and karaya gum. More preferably, the type of carrageenan is lambda-carrageenan.

The tamarind seed gum used in the present invention is xyloglucan having a main chain of glucose and xylose in the side chain.
The pectin used in the present invention has α-D-galacturonic acid linked to α-1,4 in the main chain and is partially esterified with methanol. The molecule is twisted by β-L-rhamnose entering the main chain of galacturonic acid. In addition, there are cases where neutral araban, galactan, xylan, and the like are bonded as side chains and in some cases. Galacturonic acid constituting pectin exists in two forms, a methyl ester form and an acid form. The proportion of galacturonic acid present in the form of the ester is called the degree of esterification, and those having a degree of esterification of 50% or more are called HM pectin and those having less than 50% are called LM pectin.
The carrageenan used in the present invention has a structure in which β-1,4 bonds and α-1,3 bonds of β-D-galactose and α-D-galactose are alternately repeated and galactose units are bonded. .

Gellan gum used in the present invention is one in which four sugars, glucose, glucuronic acid, glucose and L-rhamnose, are linked in a straight chain by repeating units. Native gellan gum has a 3-5% acetyl group bonded to the C-6 position of this glucose and a glyceryl group bonded to the C-2 position. Deacetylated gellan gum is obtained by deacetylating native gellan gum and purifying it.
The sodium carboxymethylcellulose used in the present invention is obtained by etherifying a hydroxyl group of cellulose with monochloroacetic acid or monochloroacetic acid sodium salt, and has a linear structure in which D-glucose is linked by β-1,4. .
The soybean water-soluble polysaccharide used in the present invention is composed of sugars such as galactose, arabinose, galacturonic acid, rhamnose, xylose, glucose, etc. Yes.

  The xanthan gum used in the present invention has a structure in which the main chain has a β-1,4-bonded D-glucose, and is composed of D-mannose, D-glucuronic acid, and D-mannose on the main chain anhydroglucose. The side chain is attached. The 6-position of D-mannose attached to the main chain is acetylated and has a highly branched structure in which the terminal D-mannose is acetal-bonded to pyruvic acid.

Karaya gum used in the present invention is a partially acetylated branched polysaccharide containing about 40% uronic acid and not more than 8% acetyl groups. There are rhamnose and galacturonic acid in the main chain, and glucuronic acid is presumed to be in the side chain.
The psyllium seed gum used in the present invention has a highly branched structure with xylan as the main chain, and the side chain is composed of arabinose, xylose, galacturonic acid, and rhamnose. This sugar composition is estimated to be about 64% D-xylose, about 20% L-arabinose, about 6.4% L-rhamnose, and about 9.4% D-galacturonic acid.
The pullulan used in the present invention has a linear structure in which maltotriose repeats α-1,6-glycosidic bonds.

Although the molecular structure of gum arabic used in the present invention has not been clarified, its constituent sugars are 36% D-galactose, 31% L-arabinose, 13% L-rhamnose, 18% D-glucuronic acid, Protein 2% is reported.
The tragacanth gum used in the present invention is obtained from the sap of legume tragacanth and is said to contain 70% tragacantic acid and 10% arabinogalactan.
The gaddy gum used in the present invention is composed of D-glucuronic acid, L-arabinose, D-galactose, D-mannose and D-xylose, and the D-galactose residue constitutes the main chain.

The arabinogalactan used in the present invention has D-galactose as the main chain, and the ratio of the side chain to L-arabinose is about 5 to 6: 1. From the β1 → 3 linked galactan backbone, short side chains of β1 → 6 linked galactose and β1 → 3 linked arabinose emerge.
The curdlan used in the present invention is a linear glucan in which glucose is β-1,3-glucoside-bonded.

The viscosity amplifying function of the present invention means that the viscosity of the aqueous dispersion or liquid composition of the thickener of the present invention at a rotational speed of 6 to 60 rpm is an aqueous dispersion or liquid composition of a polysaccharide contained in the thickener. The function to make it larger than the viscosity of is shown. That means
η6α: viscosity of an aqueous dispersion or liquid composition of the present invention at 6 rpm η30α: viscosity of an aqueous dispersion or liquid composition of the present invention at 30 rpm η60α: thickener of the present invention Viscosity of aqueous dispersion or liquid composition at 60 rpm η6β: viscosity of polysaccharide contained in the thickener of the present invention used for adjusting viscosity η6β at 6 rpm of aqueous dispersion or liquid composition η30β: viscosity η30α The viscosity of the polysaccharide contained in the thickener of the present invention used for adjusting the viscosity of the aqueous dispersion or liquid composition at 30 rpm η60β: of the polysaccharide contained in the thickener of the present invention used for adjusting the viscosity η60α When placed at 60 rpm viscosity of an aqueous dispersion or liquid composition,
When the relational expressions “viscosity η6α> viscosity η6β”, “viscosity η30α> viscosity η30β”, and “viscosity η60α> viscosity η60β” are satisfied, it is determined that the viscosity amplification function is provided.

In addition to the thickener, the thickener of the present invention includes starches, fats and oils, proteins, peptides, amino acids, salt, various salts such as phosphates, surfactants, emulsifiers, preservatives, shelf life. Components such as improvers, acidulants, sweeteners, fragrances, pigments, pH adjusters, antifoaming agents, minerals, dietary fibers, seasonings, acids, alkalis, alcohols and the like may be appropriately blended.
The water-dispersible dry composition used as a constituent of the thickener of the present invention comprises 50-95% by mass of water-dispersible cellulose and 5-50% by mass of a water-soluble polymer and / or a hydrophilic substance. Preferably, the water-dispersible cellulose: water-soluble polymer: hydrophilic substance is in the range of 50 to 95: 1 to 49: 1 to 49 mass%, more preferably 60 to 75: 5 to 20:15 to 25 mass. % Is a dry matter composed of a range of%. This composition takes the form of granules, granules, powders, scales, pieces, and sheets. This composition is characterized in that when it is put into water and given mechanical shearing force, the particles are disintegrated and fine fibrous cellulose is dispersed in water. When the water-dispersible cellulose is less than 50% by mass, the cellulose ratio is lowered and the effect is not exhibited.

The water-soluble polymer that is a component of the water-dispersible dry composition used in the present invention has an action of preventing keratinization of celluloses during drying. Specifically, gum arabic and arabi Nogalactan, alginic acid and its salts, curdlan, gati gum, carrageenan, caraya gum, agar, xanthan gum, guar gum, enzymatically degraded guar gum, quince seed gum, gellan gum, gelatin, tamarind seed gum, indigestible dextrin, tragacanth gum, farsellan One or two or more substances selected from pullulan, pectin, locust bean gum, water-soluble soybean polysaccharide, sodium carboxymethylcellulose, methylcellulose, sodium polyacrylate and the like are used.
Of these, sodium carboxymethylcellulose is preferable. As this carboxymethylcellulose sodium, the substitution degree of the carboxymethyl group is 0.5 to 1.5, preferably 0.5 to 1.0, more preferably 0.6 to 0.8. The viscosity of the 1% by mass aqueous solution is about 5 to 9000 mPa · s, preferably about 1000 to 8000 mPa · s, and more preferably about 2000 to 6000 mPa · s.

  The hydrophilic substance, which is a component of the water-dispersible dry composition used in the present invention, is a substance that is highly soluble in cold water, hardly causes viscosity, and is a solid substance at room temperature, dextrins, water-soluble saccharides (Glucose, fructose, sucrose, lactose, isomerized sugar, oligosaccharide, xylose, trehalose, coupling sugar, palatinose, sorbose, reduced starch saccharified starch, maltose, lactulose, fructooligosaccharide, galactooligosaccharide, etc.), sugar alcohols (xylitol , Maltitol, mannitol, sorbitol, etc.), or one or more substances selected from them. As described above, the water-soluble polymer has an effect of preventing the keratinization of cellulose, but depending on the substance, the water permeability to the inside of the dry composition is inferior, so it is necessary to provide a strong mechanical shear force in water for a long time. May occur. The hydrophilic substance mainly has a function of enhancing the water conductivity, and specifically promotes water disintegration of the dry composition. Of these, dextrins and trehalose are preferable, and dextrins are more preferable.

The dextrins used in the present invention are partial decomposition products generated by hydrolyzing starch with acid, enzyme, and heat, and glucose residues are mainly α-1,4 bonds and α-1,6. It consists of a bond, and a DE (dextrose equivalent) of about 2 to 42, preferably about 20 to 42 is used. Branched dextrin from which glucose and low-molecular oligosaccharides have been removed can also be used.
Trehalose used in the present invention is a disaccharide in which two D-glucose molecules are bound, and this bond is usually an α, α (1 → 1) bond.

In addition to water-dispersible cellulose, water-soluble polymer, and hydrophilic substance, the water-dispersible dry composition of the present invention includes starches, fats and oils, proteins, salt, various phosphates and other salts, emulsifiers, and acidulants. Ingredients such as sweeteners, fragrances, pigments, pH adjusters, antifoaming agents, foaming agents, preservatives, shelf life improvers, surfactants, antibacterial agents, and disintegrants may be appropriately blended.
As described above, when the water-dispersible dry composition of the present invention is introduced into water and given a mechanical shearing force, the structural unit (particles) is disintegrated and fine fibrous cellulose is dispersed in water. It becomes like this. At this time, the “mechanical shearing force” means that a 0.5 mass% aqueous dispersion is dispersed with a rotary homogenizer at a maximum of 15 000 rpm for 15 minutes, and the temperature is 80 ° C. or less. Means that.

  The aqueous dispersion thus obtained has a state before drying, that is, “a component that is stably suspended in water” in an amount of 30% by mass or more based on the total cellulose content. The loss contact at 0.5% by mass of this aqueous dispersion is less than 1. The measurement conditions for the content of the “component stably suspended in water” in the water-dispersible cellulose and the loss tangent will be described later. As described above, the water-dispersible cellulose has a major axis of 0.5 to 30 μm and a minor axis of 2 to 600 nm. The major axis / minor axis ratio is 20 to 400. Preferably, the width is 100 nm or less, more preferably 50 nm.

The mass ratio of the water-dispersible cellulose and the polysaccharide constituting the stabilizer of the present invention is water-dispersible cellulose: polysaccharide = 1: 9 to 9: 1 as a solid content, preferably 2: 8 to 8: 1. : 2, more preferably 3: 7 to 7: 3. Similarly, the mass ratio of the water-dispersible dry composition to the polysaccharide is, as a solid content, water-dispersible dry composition: polysaccharide = 1: 9 to 9: 1, preferably 2: 8 to 8: 2. More preferably, it is 3: 7-7: 3.
The liquid composition of the present invention takes a liquid or paste form at room temperature, and includes liquid food compositions, liquid cosmetic compositions, liquid pharmaceutical and medical compositions, liquid industrial compositions, and the like. These liquid compositions are also included in the present invention even if they have different forms or processing methods at the time of use, such as sprays, Chua packs, retort foods, frozen foods, foods for microwave ovens, and the like.

  Examples of liquid food compositions include “tea, coffee, black tea, Japanese tea, oolong tea, barley tea, etc., green tea, cocoa, juice, juice, soy milk, soy milk, etc.”, “raw milk, processed milk, fermented food Milk beverages containing dairy ingredients such as milk beverages and lactic acid bacteria beverages, “fermented milk”, “Zenzai”, “various beverages including nutrition-enriched beverages such as calcium-fortified beverages and dietary fiber-containing beverages”, “coffee whitener, Dairy products such as whipping cream, custard cream, soft cream, etc., soups, stews, seasonings such as sauces, sauces, dressings, etc. ”,“ Fruit processed products represented by fruit sauce, fruit preparation, jam ”,“ Food food such as tube liquid food ”,“ Liquid or pasty health food ” And such "liquid or pasty pet food acids" and the like, retort food, frozen food, as food such as microwave, even with different processing techniques or in the form at the time of use preparations are included in the present invention. Since the liquid food composition is usually supplied at a pH of 3 to 8 and a salt concentration of 0.001 to 20%, it is required to exhibit an effect under such conditions. Examples of pharmaceutical / medical product compositions include “oral medicines such as syrups, vitamins, and tonics”, “nasal medicines such as hormones”, “infusions / antitumor drugs, chemotherapeutics, etc.” `` Tube medicines '', `` liquid foods such as tube liquid foods classified into pharmaceuticals '', `` ointments such as skin drugs '', `` medicine cosmetics, vitamin-containing health agents, hair preparations, medicated toothpastes, bath preparations '' , Quasi-drugs such as insecticides / insecticides, odor control agents, mouth fresheners, ”“ biomaterials such as artificial cartilage and bioadhesives ”, patching agents, coating agents and the like. Examples of liquid cosmetic compositions include: “skin lotion, emulsion, serum, pack, moisture cream, massage cream, cold cream, cleansing cream, face wash, vanishing cream, emollient cream, hand cream, sunscreen cosmetics, etc. Cosmetics for skin "," Finishing cosmetics such as foundation, funny, lipstick, lip balm, cheek red, sunscreen cosmetics, eyelash cosmetics such as eyebrows and mascara, and nail polishes such as nail polish and light removal liquid " , "Shampoos, hair rinses, hair tonics, hair treatments, pomades, tics, hair creams, balms, hair styling agents, hair styling agents, hair sprays, hair dyes, hair cosmetics such as hair restorers and hair nourishing agents" and even hand cleaners Cleaning agents, bath cosmetics, shavings Cosmetics, fragrances, toothpaste, ointments, plasters and the like. Examples of liquid industrial compositions include pigments, paints, inks, deodorants / fragrances, antibacterial / antifungal agents, adhesives, coating agents, surfactants, hygiene materials, culture materials, detergents, liquid soaps, etc. Can be given.

Since the liquid food composition is usually supplied at a pH of 3 to 8 and a salt concentration of 0.001 to 20%, it is required to exhibit an effect under such conditions.
The addition amount of the thickener of the present invention to the liquid composition is not particularly limited, but is preferably 0.001% by mass or more and less than 1% by mass, more preferably about 0.05 to 0.7% by mass. It is.
The gelation of the present invention is a function of forming a gel such as jelly or pudding, that is, a true gel when the aqueous dispersion or liquid composition is allowed to stand. Judge at 24 hours. Gelled aqueous dispersions and liquid compositions do not have fluidity.

Next, the present invention will be described in more detail with reference to examples. The evaluation of various physical properties of the substance according to the present invention was based on the following method.
<Average degree of polymerization of cellulosic material>
ASTM Designation: D 1795-90 “Standard Test Method for Intrinsic Visibility of Cellulose”.
<Α-cellulose content of cellulosic material>
It is performed according to JIS P 8101-1976 (“dissolving pulp test method” 5.5 α cellulose).

<Crystallinity of cellulosic material>
It is calculated by the Segal method from the diffraction intensity value of the X-ray diffraction diagram obtained by the X-ray diffraction apparatus prescribed in JIS K 0131-1996 (“General Rules for X-ray Diffraction Analysis”) and is defined by the following equation: .
Crystallinity (%) = {(Ic−Ia) / Ic} × 100
Here, Ic is the diffraction intensity at the diffraction angle 2θ = 22.5 degrees in the X-ray diffraction diagram, and Ia is the baseline intensity (minimum value intensity) around the diffraction angle 2θ = 18.5 degrees.

<Shape of cellulose fiber (particle) (major axis, minor axis, major axis / minor axis ratio)>
Since the range of the size of cellulose fibers (particles) is wide, it is impossible to observe all with one kind of microscope. Therefore, an optical microscope and a scanning microscope (medium resolution SEM, high resolution SEM) are appropriately selected according to the size of the fibers (particles), and observed and measured.
When using an optical microscope, the sample and pure water are weighed out so as to obtain an aqueous dispersion having a solid content concentration of 0.25% by mass, and “Excel Auto Homogenizer” (manufactured by Nippon Seiki Co., Ltd.) is used. The one dispersed for a minute is adjusted to an appropriate concentration, placed on a slide glass, and further covered with a cover glass and observed.
In addition, when using a medium resolution SEM (manufactured by JEOL Ltd., “JSM-5510LV”), a sample aqueous dispersion is placed on a sample stage and air-dried, and then Pt—Pd is deposited by about 3 nm and observed.
When using a high-resolution SEM (manufactured by Hitachi Science Systems, Inc., “S-5000”), place the sample aqueous dispersion on the sample stage, air dry, and then deposit Pt—Pd by about 1.5 nm for observation. .
The major axis, minor axis, and major axis / minor axis ratio of the cellulose fibers (particles) were measured by selecting 15 (pieces) or more from the photographed photographs. Some fibers were almost straight and curved like hair, but never round like lint. The minor axis (thickness) was varied among single fibers, but an average value was adopted. The high-resolution SEM was used when observing a fiber having a minor axis of several nm to 200 nm, but one fiber was too long to fit in one field of view. Therefore, photography was repeated while moving the field of view, and then the pictures were synthesized and analyzed.

<Content of “component that is stably suspended in water”>
It calculates | requires from the following (1)-(5) and (3 ')-(5').
(1) The sample and pure water are weighed out so that the cellulose concentration is 0.1% by mass and dispersed with an ace homogenizer (manufactured by Nippon Seiki Co., Ltd., AM-T type) at 15000 rpm for 15 minutes.
(2) Put 20 g of sample solution into a centrifuge tube and centrifuge at 1000 G for 5 minutes in a centrifuge.
(3) The upper liquid portion is removed and the mass (a) of the sediment component is measured.
(4) Next, the sedimentation component is absolutely dried, and the mass (b) of the solid content is measured.
(5) The content (c) of the “component that is stably suspended in water” is calculated using the following formula.
c = 5000 × (k1 + k2) [mass%]

However, k1 and k2 are calculated using the following formula and used. (Where k1: amount of “fine fibrous cellulose” contained in the upper liquid portion, k2: amount of “fine fibrous cellulose” contained in the precipitation component, and w1: contained in the upper liquid portion. (W2: amount of water contained in the precipitation component, s2: amount of “water-soluble polymer + hydrophilic substance” contained in the precipitation component.)
k1 = 0.02−b + s2
k2 = k1 × w2 / w1
(Water-soluble polymer + hydrophilic substance) / cellulose = d / f [Blending ratio]
w1 = 19.98−a + b−0.02 × d / f
w2 = a−b
s2 = 0.02 × d × w2 / {f × (w1 + w2)}
When the content of “a component that is stably suspended in water” is very large, the weight of the sediment component becomes a small value, so that the measurement accuracy is lowered by the above method. In that case, the procedure after (3) is performed as follows.

(3 ′) The upper liquid portion is obtained and the mass (a ′) is measured.
(4 ′) Next, the upper layer component is completely dried, and the mass (b ′) of the solid content is measured.
(5 ′) The content (c) of “a component that is stably suspended in water” is calculated using the following formula.
c = 5000 × (k1 + k2) [mass%]
However, k1 and k2 are calculated using the following formula and used. (Where k1: amount of “fine fibrous cellulose” contained in the upper liquid portion, k2: amount of “fine fibrous cellulose” contained in the precipitation component, and w1: contained in the upper liquid portion. (W2: amount of water contained in the precipitation component, s2: amount of “water-soluble polymer + hydrophilic substance” contained in the precipitation component.)
k1 = b′−s2 × w1 / w2
k2 = k1 × w2 / w1
(Water-soluble polymer + hydrophilic substance) / cellulose = d / f [Blending ratio]
w1 = a′−b ′
w2 = 19.98−a ′ + b′−0.02 × d / f
s2 = 0.02 × d × w2 / {f × (w1 + w2)}
If the boundary between the liquid portion of the upper layer and the sediment component is not clear in the operation (3) and separation is difficult, the operation is performed with the cellulose concentration lowered appropriately.

<Loss tangent (= loss elastic modulus / storage elastic modulus)>
It calculates | requires in the procedure of the following (1)-(3).
(1) The sample and pure water are weighed so as to obtain an aqueous dispersion having a solid content concentration of 0.5% by mass, and dispersed with “Excel Auto Homogenizer” (manufactured by Nippon Seiki Co., Ltd.) at 15000 rpm for 15 minutes.
(2) Leave in an atmosphere at 25 ° C. for 3 hours.
(3) After putting the sample liquid into the dynamic viscoelasticity measuring apparatus, the sample is allowed to stand for 5 minutes, and then measured under the following conditions to determine a loss tangent (tan δ) at a frequency of 10 rad / s.
Apparatus: “ARES” (Rheometric Scientific, Inc., 100FRTN1 type)
Geometry: Double Wall Couette
Temperature: 25 ° C
Distortion: 10% (fixed)
Frequency: 1 → 100 rad / s (Raise over about 170 seconds)

<Preparation of 0.4% mass concentration aqueous dispersion, confirmation of gelation state, viscosity measurement>
First, a sample and water are weighed so that the solid content becomes an aqueous dispersion having a mass of 1% by mass, and dispersed using TK homomixer (manufactured by Tokushu Kika Kogyo Co., Ltd.) at 8000 rpm for 10 minutes. Further, this 1% by mass sample aqueous dispersion: water was mixed at a ratio of 4: 6, and further dispersed for 5 minutes to prepare a 0.4% by mass sample aqueous solution. The temperature at this time is not particularly specified, but a temperature suitable for the dispersion of the sample is selected. Further, if there is a substance (for example, an ionic substance such as calcium chloride or sodium chloride, a saccharide, etc.) indispensable for the expression of the function of the polysaccharide constituting the thickener, it may be added as appropriate.

Next, the beaker (or viscometer adapter) is filled with this 0.4 mass% sample aqueous solution. After the 0.4% by mass sample aqueous solution filled in the beaker is allowed to stand in an atmosphere at 25 ° C. for 24 hours, if the beaker is tilted and the 0.4% by mass sample aqueous solution is fluidized and spills, the fluidity is reduced. It was maintained and it was judged that it was not gelled. However, this operation may be omitted for samples that do not require confirmation of the gelation state.
In addition, a 0.4 mass% sample aqueous solution filled in another beaker (or viscometer adapter) was allowed to stand in an atmosphere at 25 ° C. for 3 hours, and then allowed to stand still in a rotating state (B-type viscometer, east Machine Industry Co., Ltd., “TV-10 type”) was set, and the viscosity (η6) after 60 seconds at a rotor rotational speed of 6 rpm was read. By the same method, the viscosity at 30 rpm (η30) and the viscosity at 60 rpm (η60) were measured. The rotor and adapter were appropriately changed depending on the viscosity.

<Confirmation of gelation state of liquid composition, viscosity measurement>
The beaker was filled with the liquid composition prepared by the Example mentioned later. After the liquid composition filled in the beaker was allowed to stand for 24 hours, the beaker was tilted. If the liquid composition fluidized and spilled, the fluidity was maintained, and it was judged that the liquid composition was not gelled. However, this operation may be omitted for samples that do not require confirmation of the gelation state.
In addition, the liquid composition filled in another beaker (or viscometer adapter) was allowed to stand for 3 hours, and then allowed to stand still, and a rotational viscometer (B-type viscometer, manufactured by Toki Sangyo Co., Ltd., “TV-10”) ) Was set, and the viscosity (η6) after 60 seconds at a rotor speed of 6 rpm was read. By the same method, the viscosity at 30 rpm (η30) and the viscosity at 60 rpm (η60) were measured. The rotor and adapter were appropriately changed depending on the viscosity.

<Determination of viscosity amplification function>
When the viscosities determined above satisfy the relational expressions of “viscosity η6α> viscosity η6β”, “viscosity η30α> viscosity η30β”, and “viscosity η60α> viscosity η60β”, it was determined that there is a viscosity amplification function.
<PH>
The pH was measured with a pH meter (“HM-50G type” manufactured by Toa DKK Corporation).

  EXAMPLES Hereinafter, although an Example and a comparative example are shown and this invention is demonstrated concretely, this invention is not limited to these at all. The water dispersible cellulose, water dispersible dry composition, pectin, xanthan gum, tamarind seed gum, karaya gum, and carboxymethylcellulose sodium used in the examples are shown in the following (1) to (8).

(1) Preparation of water-dispersible cellulose A: commercially available straw pulp (average polymerization degree = 930, α-cellulose content = 68% by mass) is cut into a 6 × 12 mm square to be 4% by mass. Water was added and stirred for 5 minutes with a home mixer. This was dispersed for 1 hour with a high-speed rotation type homogenizer (Yamato Scientific, “ULTRA-DISPERSER”).
This aqueous dispersion was treated with a grindstone rotary grinder (grinder rotation speed: 1800 rpm). The number of treatments was 2, and the grinder clearance was changed from 60 to 40 μm.
Next, the obtained aqueous dispersion was diluted with water to 2% by mass, and subjected to 8 passes with a high-pressure homogenizer (treatment pressure: 175 MPa) to obtain a water-dispersible cellulose B slurry. The crystallinity was 74%. When observed with an optical microscope, fine fibrous cellulose having a major axis of 10 to 700 μm, a minor axis of 1 to 30 μm, and a major axis / minor axis ratio of 10 to 150 was observed. The loss tangent was 0.43. The content of “a component that is stably suspended in water” was 89% by mass. When observed with a high-resolution SEM, very fine fibrous cellulose having a major axis of 1 to 20 μm, a minor axis of 6 to 300 nm, and a major axis / minor axis ratio of 30 to 350 was observed.

(2) Preparation of water-dispersible dry composition B: To the water-dispersible cellulose A obtained in (1), the water-dispersible cellulose and carboxymethylcellulose sodium have a mass ratio of 85:15 as a solid content. Sodium carboxymethylcellulose was added, and the mixture was stirred and mixed for 15 minutes with a stirring homogenizer. Subsequently, it dried with the drum dryer and scraped off with the scraper. This was pulverized with a cutter mill (manufactured by Fuji Powder Co., Ltd.) so that the sieve having an opening of 1 mm was almost completely passed through to obtain a water-dispersible dry composition B.
The crystallinity of the water-dispersible dry composition B was 68% or more, the loss tangent was 0.51, and the content of “component stably suspended in water” was 75% by mass. When this was observed with a high-resolution SEM, very fine fibrous cellulose having a major axis of 1 to 20 μm, a minor axis of 10 to 300 nm, and a major axis / minor axis ratio of 30 to 350 was observed.

(3) Preparation of water-dispersible dry composition C: Commercial bagasse pulp (average polymerization degree = 1320, α-cellulose content = 77%) was cut into a 6 × 16 mm square and the solid content concentration was 77% by mass. Water was added so that This was passed once through a cutter mill (cutting head / horizontal blade gap: 2.03 mm, impeller rotation speed: 3600 rpm), taking care not to separate water and pulp chips as much as possible. Cutter mill processed product, carboxymethylcellulose sodium (1 mass% aqueous solution viscosity: about 3400 mPa · s) and water are weighed out so that the cellulose concentration is 2 mass% and the concentration of carboxymethylcellulose sodium is 0.118 mass%. The mixture was stirred until the fibers were tangled.
The obtained aqueous dispersion was directly subjected to 9 passes with a high-pressure homogenizer (treatment pressure 90 MPa) to obtain a water-dispersible cellulose C slurry. When observed with an optical microscope and medium resolution SEM, fine fibrous cellulose having a major axis of 10 to 500 μm, a minor axis of 1 to 25 μm, and a major axis / minor axis ratio of 5 to 190 was observed. The loss tangent was 0.32. The “component stably suspended in water” was 99% by mass. When the “component that is stably suspended in water” was observed with a high-resolution SEM, a very fine fibrous cellulose having a major axis of 1 to 20 μm, a minor axis of 10 to 400 nm, and a major axis / minor axis ratio of 20 to 300 was obtained. Observed.

Water-dispersible cellulose C: carboxymethylcellulose sodium: dextrin: soybean oil = 63: 15: 21.5: 0.5 (parts by mass) Water-dispersible cellulose C slurry with carboxymethylcellulose sodium (1 mass) % Aqueous solution viscosity: about 3400 mPa · s) and dextrin (DE: about 28) were added, and 15 kg was stirred at 8000 rpm with a stirring type homogenizer (manufactured by Tokushu Kika Kogyo KK, “TK AUTO HOMO MIXER”). After stirring and mixing for a minute, 20 MPa and one pass treatment were performed with the above-described high-pressure homogenizer to obtain a water-dispersible cellulose C ′ slurry.
The water-dispersible cellulose C ′ slurry is dried with a drum dryer and scraped off with a scraper. Furthermore, the water-dispersible dry composition C was obtained by sieving with a standard sieve having an opening of 425 μm after pulverization with an impact pulverizer. The crystallinity of the water-dispersible dry composition C was 58% or more, the loss tangent was 0.58, and the “component stably suspended in water” was 99% by mass. Observation of the “component that is stably suspended in water” with a high-resolution SEM revealed that a very fine fibrous cellulose having a major axis of 1 to 12 μm, a minor axis of 10 to 330 nm, and a major axis / minor axis ratio of 20 to 220 was obtained. Observed.

(4) Carboxymethylcellulose sodium (Daiichi Kogyo Seiyaku Co., Ltd., Degree of substitution of carboxymethyl group: 0.78)
(5) Pectin (CP Kelco, LM pectin)
(6) Xanthan gum (Dainippon Pharmaceutical Co., Ltd.)
(7) Tamarind seed gum (Dainippon Pharmaceutical Co., Ltd.)
(8) Karaya gum (manufactured by Sanei Pharmaceutical Trading Co., Ltd.)

[Example 1]
The thickener uses water-dispersible cellulose A slurry (2% by mass concentration) and contains water-dispersible cellulose A: carboxymethylcellulose sodium (hereinafter referred to as CMC-Na) at a mass ratio of 8: 2. Selected.
First, weigh out the above sample and water so that a 0.4% by mass sample aqueous dispersion becomes an aqueous dispersion having a solid content of 1% by mass, and “TK homomixer” (manufactured by Tokushu Kika Kogyo Co., Ltd.) Was dispersed at 30 ° C. and 8000 rpm for 10 minutes. This 1% by mass sample aqueous dispersion: water was mixed at a ratio of 4: 6 and dispersed for 5 minutes to prepare a 0.4% by mass sample aqueous solution and filled in a beaker. The 0.4 mass% sample aqueous dispersion filled in one beaker was allowed to stand in an atmosphere at 25 ° C. for 24 hours and then tilted. As a result, it fluidized and spilled from the beaker and did not gel.
A 0.4 mass% sample aqueous solution filled in another container (beaker or viscometer adapter) was allowed to stand in an atmosphere at 25 ° C. for 3 hours. A rotational viscometer (B-type viscometer, manufactured by Toki Sangyo Co., Ltd., “TV-10”) was set in a stationary state, and the rotor rotation speed was 6 rpm and the viscosity after 60 seconds was read. The viscosity at 30 rpm and 60 rpm was read in the same manner. The rotor and adapter were appropriately changed depending on the viscosity.

As a result, the viscosity (η6α1) at a rotor rotational speed of 6 rpm was measured with a 0.4% by mass thickener aqueous dispersion, and found to be 202 mPa · s, and the viscosity at 30 rpm (η30α1) was measured to be 91 mPa · s. The viscosity (η60α1) at 60 rpm was measured and found to be 63 mPa · s.
A 0.4 mass% CMC-Na aqueous solution prepared by the same method as described above was placed in an adapter and allowed to stand in an atmosphere at 25 ° C. for 3 hours, and the viscosity (η6β1) at a rotor rotational speed of 6 rpm was measured. The viscosity (η30β1) at 30 rpm was measured to be 12 mPa · s, and the viscosity (η60β1) at 60 rpm was measured to be 14 mPa · s.
From the above, the relational expressions of “viscosity η6α1> viscosity η6β1”, “viscosity η30α1> viscosity η30β1”, and “viscosity η60α1> viscosity η60β1” were established, and it was found that this thickener has a viscosity amplification function.

[Example 2]
As the thickener, one containing a water-dispersible dry composition B: pectin in a ratio of 6: 4 was selected. A 0.4 mass% thickener aqueous dispersion was prepared and evaluated in the same manner as in Example 1. However, the dispersion temperature was 80 ° C., and 100 mg of calcium chloride per gram of the thickener was added to the thickener aqueous dispersion.
The 0.4 mass% thickener aqueous dispersion was evaluated in the same manner as in Example 1. This 0.4 mass% thickener aqueous dispersion maintained fluidity and was not gelled.
Furthermore, when the viscosity (η6α2) at a rotor rotational speed of 6 rpm was measured with a 0.4 mass% thickener aqueous dispersion, it was 380 mPa · s, and the viscosity at 30 rpm (η30α2) was measured and was 122 mPa · s, 60 rpm The viscosity (η60α2) was measured and found to be 96 mPa · s.
A 0.4 mass% pectin aqueous solution prepared in the same manner as above was placed in an adapter and allowed to stand in an atmosphere at 25 ° C. for 3 hours, and the viscosity (η6β2) at a rotor rotational speed of 6 rpm was measured. The viscosity (η30β2) at 30 rpm was 7 mPa · s, and the viscosity at 60 rpm (η60β2) was 7 mPa · s. However, 100 mg of calcium chloride was added per 1 g of pectin when the 0.4 mass% pectin aqueous solution was prepared.
From the above, the relational expressions of “viscosity η6α2> viscosity η6β2”, “viscosity η30α2> viscosity η30β2”, and “viscosity η60α2> viscosity η60β2” were established, and it was found that this thickener has a viscosity amplification function.

[Example 3]
The thickener was selected to contain a water-dispersible dry composition C: pectin in a mass ratio of 8: 2.
A 0.4 mass% thickener aqueous dispersion was prepared in the same manner as in Example 2, and evaluated in the same manner as in Example 1. This 0.4 mass% thickener aqueous dispersion maintained fluidity and was not gelled.
Furthermore, when the viscosity (η6α3) at a rotor rotational speed of 6 rpm was measured with a 0.4 mass% thickener aqueous dispersion, it was 670 mPa · s, and when the viscosity at 30 rpm (η30α3) was measured, it was 263 mPa · s, and 60 rpm The viscosity (η60α3) was measured and found to be 159 mPa · s.
When the viscosity (η6β3) at a rotation speed of 6% by mass of a 0.4 mass% pectin aqueous rotor was measured by the same method as in Example 1, it was not measurable (less than 10 mPa · s), and the viscosity at 30 rpm (η30β3) was measured. The viscosity (η60β3) at 60 rpm was measured and found to be 7 mPa · s.
From the above, the relational expressions of “viscosity η6α3> viscosity η6β3”, “viscosity η30α3> viscosity η30β3”, and “viscosity η60α3> viscosity η60β3” were established, and it was found that this thickener has a viscosity amplification function.

[Example 4]
As the thickener, one containing a water-dispersible dry composition C: pectin in a mass ratio of 5: 5 was selected.
A 0.4 mass% thickener aqueous dispersion was prepared in the same manner as in Example 2, and evaluated in the same manner as in Example 1. This 0.4 mass% thickener aqueous dispersion maintained fluidity, was not gelled, and had good liquidity.
Furthermore, when the viscosity (η6α4) at a rotor rotational speed of 6 rpm was measured with a 0.4% by weight thickener aqueous dispersion, it was 452 mPa · s, and when the viscosity at 30 rpm (η30α4) was measured, it was 153 mPa · s and 60 rpm. The viscosity (η60α4) was measured to be 105 mPa · s.
When the viscosity (η6β4) at a rotation speed of 6 rpm of a 0.4 mass% pectin aqueous solution rotor obtained by the same method as in Example 1 was measured, it was not measurable (less than 10 mPa · s), and the viscosity at 30 rpm (η30β4) was measured. However, it was 7 mPa · s, and the viscosity (η60β4) at 60 rpm was measured to be 7 mPa · s.
From the above, the relational expressions of “viscosity η6α4> viscosity η6β4”, “viscosity η30α4> viscosity η30β4”, and “viscosity η60α4> viscosity η60β4” were established, and it was found that this thickener has a viscosity amplification function.

[Example 5]
The thickener was selected to contain a water dispersible dry composition C: tamarind seed gum in a ratio of 7: 3. A 0.4 mass% thickener aqueous dispersion was prepared and evaluated in the same manner as in Example 1. However, the dispersion temperature was 80 ° C. This 0.4 mass% thickener aqueous dispersion maintained fluidity and was not gelled.
Furthermore, when the viscosity (η6α5) at a rotor rotational speed of 6 rpm was measured with a 0.4 mass% thickener aqueous dispersion, it was 1360 mPa · s, and when the viscosity at 30 rpm (η30α5) was measured, it was 880 mPa · s, and 60 rpm The viscosity (η60α5) was measured and found to be 210 mPa · s.
0.4 mass% tamarind seed gum aqueous solution obtained by the same method as in Example 1 When the viscosity (η6β5) at a rotor rotational speed of 6 rpm was measured, it was not measurable (less than 10 mPa · s), and the viscosity at 30 rpm (η30β5) was The measured value was 9 mPa · s, and the viscosity (η60β5) at 60 rpm was measured and found to be 9 mPa · s.
From the above, the relational expressions of “viscosity η6α5> viscosity η6β5”, “viscosity η30α5> viscosity η30β5”, and “viscosity η60α5> viscosity η60β5” were established, and it was found that this thickener has a viscosity amplification function.

[Example 6]
The thickener was selected to contain a water dispersible dry composition C: tamarind seed gum in a ratio of 3: 7. A 0.4 mass% thickener aqueous dispersion was prepared and evaluated in the same manner as in Example 1. However, the dispersion temperature was 80 ° C. This 0.4 mass% thickener aqueous dispersion maintained fluidity and was not gelled.
Furthermore, when the viscosity (η6α6) at a rotor rotational speed of 6 rpm was measured with a 0.4 mass% thickener aqueous dispersion, it was 28 mPa · s, and the viscosity at 30 rpm (η30α6) was measured and was 26 mPa · s, 60 rpm The viscosity (η60α6) was measured and found to be 23 mPa · s.
In the same manner as in Example 1, when the viscosity (η6β6) at a rotor rotation speed of 6 rpm was measured by a 0.4 mass% tamarind seed gum aqueous solution, it was not measurable (less than 10 mPa · s) and the viscosity at 30 rpm (η30β6) was measured As a result, it was 9 mPa · s, and the viscosity (η60β6) at 60 rpm was measured to be 9 mPa · s.
From the above, the relational expressions “viscosity η6α6> viscosity η6β6”, “viscosity η30α6> viscosity η30β6”, and “viscosity η60α6> viscosity η60β6” were established, and it was found that this thickener has a viscosity amplification function.

[Example 7]
As the thickener, one containing a water-dispersible dry composition C: Karaya gum in a ratio of 4: 6 was selected. A 0.4 mass% thickener aqueous dispersion was prepared and evaluated in the same manner as in Example 1. However, the dispersion temperature was 60 ° C. This 0.4 mass% thickener aqueous dispersion maintained fluidity and was not gelled.
Furthermore, when the viscosity (η6α7) at a rotor rotational speed of 6 rpm was measured with a 0.4 mass% thickener aqueous dispersion, it was 682 mPa · s, and the viscosity at 30 rpm (η30α7) was measured to be 221 mPa · s, 60 rpm. The viscosity (η60α7) was measured and found to be 141 mPa · s.
The viscosity (η6β7) of a 0.4 mass% Karaya gum aqueous solution measured at a rotor rotational speed of 6 rpm was 110 mPa · s and the viscosity at 30 rpm (η30β7) was measured at 96 mPa · s in the same manner as in Example 1. Yes, the viscosity (η60β7) at 60 rpm was measured and found to be 82 mPa · s.
From the above, the relational expressions of “viscosity η6α7> viscosity η6β7”, “viscosity η30α7> viscosity η30β7”, and “viscosity η60α7> viscosity η60β7” were established, and it was found that this thickener has a viscosity amplification function.

[Example 8]
Fermented milk drink A was prepared and evaluated in the following manner.
In a beaker, put 39% by mass of water at 80 ° C. and 60% by mass fructose-glucose liquid sugar (manufactured by Oji Cornstarch Co., Ltd., “F-55”). While stirring, 1% by mass of the water-dispersible dry product C was added, and the mixture was stirred at 8000 rpm for 10 minutes while maintaining the temperature. (Hereinafter referred to as a1 liquid)
In another beaker, 99% by mass of 80 ° C. water was added, 1% by mass of pectin was added, and the mixture was stirred under the same conditions. (Hereinafter referred to as a2 liquid)
While stirring with a propeller stirring blade, 20% by weight blueberry puree (thawed frozen blueberry, thawed and sterilized by lining), the following stirred yogurt 50% by weight, 20% by weight a1 solution, 10% by weight a2 solution were added. For 2 minutes at 400 rpm. A solution obtained by homogenizing this solution at a processing pressure of 10 MPa using a high-pressure homogenizer was designated as fermented milk drink A.
At this time, the content of the thickener (water-dispersible dry composition C: pectin = 6.7: 3.3) in the fermented milk A was 0.3% by mass.
Fermented milk drink A was filled into a beaker, and one beaker was allowed to stand at 5 ° C. for 23 hours, and further allowed to stand at 25 ° C. for 1 hour. When this beaker was tilted, the fermented milk drink A was fluidized and spilled, and was not gelled.
The viscosity (η6α8) at 6 rpm was 941 mPa · s and the viscosity at 30 rpm (η30α8) was 500 mPa, measured using the fermented milk beverage A filled in the remaining beakers, after standing at 25 ° C. for 3 hours. -The viscosity ((eta) 60 (alpha) 8) in s and rotation speed 60rpm was 221 mPa * s, and pH was 3.9.

The manufacturing method of the stirring yogurt used here is as follows.
21.7% by mass of water and 75% by mass of milk (manufactured by Southern Japan Dairy Kyodo Co., Ltd., milk fat content 3.5% or more, non-fat milk solid content 8.3%) are poured into a stainless steel beaker and stirred with a propeller While stirring at 200 rpm at 25 ° C. using a blade, 3.3% by mass of skim milk powder (manufactured by Snow Brand Milk Products Co., Ltd.) was added, and stirring was continued for 10 minutes.
The solution was homogenized at a processing pressure of 15 MPa using a high-pressure homogenizer, and further stirred for 30 minutes at 80 ° C. and 200 rpm using a propeller stirring blade to sterilize the solution. Furthermore, it cooled to 30 degreeC in 20 minutes, stirring at 200 rpm in a clean bench. A starter (manufactured by Danisco Carter, “MSK-Mix AB N 1-45 Visbybac DIP”) as an aqueous solution of 0.01% by mass was added to this solution in an external ratio of 0.32% by mass, stirred with a spatula, and fermented. The container was filled. This was transferred to an incubator and fermented at 42 ° C. for 12 hours. After fermentation, the mixture was transferred to a refrigerator at 5 ° C. and passed for 3 days to obtain a stirring yogurt (non-fat milk solid content of 9.4% or more).

[Example 9]
Water dispersible dry composition C: Tamarind seed gum = 2.5: 7.5 A thickener powder-mixed at a mass ratio (hereinafter referred to as “thickener b”) is used to remove grated B in the following procedure. Prepared and evaluated.
20 masses of 60 ° C. fructose glucose liquid sugar (manufactured by Oji Cornstarch Co., Ltd., “F-55”) while stirring with “TK homomixer” (manufactured by Tokushu Kika Kogyo Co., Ltd.) in water at 60 ° C. %, 0.4% by mass of the above thickener a and 5% by mass of granulated sugar (manufactured by Daiichi Sugar Industry Co., Ltd.), dispersed at 8000 rpm for 10 minutes, and further replaced with a propeller stirring blade Soy sauce 30% by mass (Kikkoman Co., Ltd., salt concentration 16%), 5% by mass of sodium chloride (Salt Business Center), Asahi taste 1% by mass (Japan Tobacco Inc.), 5% by mass of apple vinegar (Mitsukan Co., Ltd., acidity 5.0%), radish grated 5% by mass, grated garlic 1% by mass and blended to a total of 100% by mass. Further, stirring was continued at 400 rpm, and stirring was continued until 3 minutes had elapsed after the liquid temperature reached 80 ° C., and the sterilized one was designated as grated B. Grain dripping B was filled into four beakers, and after one beaker was allowed to stand at 25 ° C. for 24 hours, when the beaker was tilted, it fluidized and spilled from the beaker and did not gel.
The viscosity (η6α9) at a rotational speed of 6 rpm after standing for 3 hours at 25 ° C. measured by using the grater B filled in the remaining three beakers was 240 mPa · s, and the viscosity (η30α9) at a rotational speed of 30 rpm was 124 mPa. -The viscosity ((eta) 60 (alpha) 9) in s and rotation speed 60rpm was 90 mPa * s. The pH was 4.1 and the salt concentration was 10%.

[Example 10]
Water dispersible dry composition C: Tamarind seed gum = Thickener b of Example 9 using a thickener (hereinafter referred to as thickener c) powder-mixed at a mass ratio of 7.5: 2.5 Grated weeping C was prepared and evaluated in the same procedure as in Example 9, using thickener c instead of.
After grater dripping C was filled into four beakers and one beaker was allowed to stand at 25 ° C. for 24 hours, when the beaker was tilted, it fluidized and spilled from the beaker and did not gel.
Viscosity (η6α10) at a rotational speed of 6 rpm after standing at 25 ° C. for 3 hours, measured using a grater C filled in the remaining three beakers, was 1160 mPa · s, and a viscosity at a rotational speed of 30 rpm (η30α10) was 421 mPa. -The viscosity ((eta) 60 (alpha) 10) in s and rotation speed 60rpm was 261 mPa * s. The pH was 4.1 and the salt concentration was 10%.

[Example 11]
Water-dispersible dry composition C: Soup D was prepared and evaluated in the following procedure using a thickener (hereinafter referred to as thickener d) powder-mixed at a mass ratio of Karaya gum = 3: 7. .
While stirring at 80 ° C. with “TK homomixer” (manufactured by Tokushu Kika Kogyo Co., Ltd.), 0.3% by mass of the above thickener d and granulated sugar (manufactured by Daiichi Sugar Industry Co., Ltd.) 2% by mass was added and dispersed at 6000 rpm for 10 minutes, and the dispersing device was replaced with a propeller stirring blade. Consomme granule 1.5% by mass (manufactured by Ike Corporation, salt concentration 53%), Asahi taste 1% by mass (Nippon Tobacco Sangyo Co., Ltd.) and 5% by mass of thawed mixed vegetable (Nichirei Co., Ltd.) are added to prepare a total of 100% by mass. Stirring was continued at 400 rpm, and stirring was continued until 3 minutes had elapsed after the liquid temperature reached 80 ° C., and then the soup D was obtained. After filling the soup D and allowing the beaker to stand at 25 ° C. for 24 hours, the beaker was tilted and fluidized and spilled from the beaker and did not gel.
After removing the mixed vegetable, the viscosity of the soup D filled in a beaker or BL adapter after standing at 25 ° C. for 3 hours was measured. The viscosity at 6 rpm (η6α11) was 98 mPa · s, the viscosity at 30 rpm (η30α11) was 55 mPa · s, and the viscosity at 60 rpm (η60α11) was 43 mPa · s. The pH was 5.2 and the salt concentration was 0.8%.

[Example 12]
Water-dispersible dry composition C: Thickener instead of thickener d in Example 11 using a thickener (hereinafter referred to as thickener e) powder-mixed at a mass ratio of Karaya gum = 7: 3 e was used to prepare and evaluate Soup E in the same procedure as Example 11.
The viscosity of Soup E after standing at 25 ° C. for 3 hours was measured. The viscosity at 6 rpm (η6α12) was 291 mPa · s, the viscosity at 30 rpm (η30α12) was 110 mPa · s, and the viscosity at 60 rpm (η60α12) was 73 mPa · s. The pH was 5.4 and the salt concentration was 0.8%.

Example 13
Water-dispersible dry composition C: Thickener instead of thickener d of Example 11 was increased by using a thickener (hereinafter referred to as thickener f) mixed in powder at a mass ratio of CMC-Na = 3: 7. Soup F was prepared and evaluated in the same procedure as in Example 11 using the sticking agent f.
The viscosity of Soup F after standing at 25 ° C. for 3 hours was measured. The viscosity (η6α13) at 6 rpm was 360 mPa · s, the viscosity (η30α13) at 30 rpm was 144 mPa · s, and the viscosity (η60α13) at 60 rpm was 101 mPa · s. The pH was 6.8 and the salt concentration was 0.8%.

[Comparative Example 1]
Instead of the thickener of Example 8, the same amount of pectin was blended to prepare a fermented milk drink G and evaluated.
After standing at the same conditions as in Example 8, the viscosity at 6 rpm (η6β14) is 90 mPa · s, the viscosity at 30 rpm (η30β14) is 64 mPa · s, and the viscosity at 60 rpm (η60β14) is 53 mPa · s. Compared to Example 8, the viscosity was inferior. The pH was 3.9.

[Comparative Example 2]
In place of the thickener b of Example 9, the same amount of tamarind seed gum was blended to prepare a grater H and evaluated.
After standing at the same conditions as in Example 9, the viscosity at 6 rpm (η6β15) is 41 mPa · s, the viscosity at 30 rpm (η30β15) is 40 mPa · s, and the viscosity at 60 rpm (η60β15) is 40 mPa · s. Compared with Example 9 and Example 10, the viscosity was inferior. The pH was 4.1.

[Comparative Example 3]
Instead of the thickener d of Example 11, soup I was prepared by blending the same amount of Karaya gum and evaluated.
After standing at the same conditions as in Example 11, the viscosity at 6 rpm (η6β16) was 56 mPa · s, the viscosity at 30 rpm (η30β16) was 42 mPa · s, and the viscosity at 60 rpm (η60β16) was 29 mPa · s. Compared with Example 11 and Example 12, the viscosity was inferior. The pH was 5.1 and the salt concentration was 0.8%.

[Comparative Example 4]
Instead of the thickener f in Example 13, soup J was prepared by blending the same amount of CMC-Na and evaluated.
After standing under the same conditions as in Example 13, the viscosity at 6 rpm (η6β17) is 230 mPa · s, the viscosity at 30 rpm (η30β17) is 112 mPa · s, and the viscosity at 60 rpm (η60β17) is 81 mPa · s. Compared with Example 13, the viscosity was inferior. The pH was 6.8 and the salt concentration was 0.8%.

[Comparative Example 5]
Preparation of dry cellulose composition D: After cutting a commercially available wood pulp (average polymerization degree = 1050, α-cellulose content = 97 mass%), it was hydrolyzed in 105% at 20 ° C. for 20 minutes in 7% hydrochloric acid. And washed with a filter to obtain a wet cake. To this wet cake, carboxymethylcellulose sodium (hereinafter referred to as CMC-Na) was blended so as to have a ratio of cellulose / carboxymethylcellulose sodium = 86/14, and kneaded and ground with a kneader. Next, it was loosened by hand, dried with hot air, and pulverized with a hammer mill to obtain a dried cellulose composition D. The degree of crystallinity of the dried cellulose composition D was 69% or more, the loss tangent was 2.5, and the content of the “component stably suspended in water” was 61% by mass. When it was observed with a high-resolution SEM, fine fibrous cellulose was hardly observed.
As the thickener, the one containing cellulose dry composition D: CMC-Na at a mass ratio of 5: 5 was selected.
Furthermore, when the viscosity (η6α18) at a rotor rotational speed of 6 rpm was measured with a 0.4% by weight thickener aqueous dispersion, the viscosity was less than 10 mPa · s, and when the viscosity at 30 rpm (η30α18) was measured, it was 9 mPa · s. The viscosity (η60α18) at 60 rpm was measured and found to be 9 mPa · s.
A 0.4 mass% CMC-Na aqueous solution prepared by the same method as above was placed in an adapter and allowed to stand in an atmosphere at 25 ° C. for 3 hours, and the viscosity (η6β18) at a rotor rotational speed of 6 rpm was measured. The viscosity (η30β18) at 30 rpm was measured to be 12 mPa · s, and the viscosity at 60 rpm (η60β18) was measured to be 14 mPa · s.
From the above, the relational expressions of “viscosity η6α18 <viscosity η6β18”, “viscosity η30α18 <viscosity η30β18”, and “viscosity η60α18 <viscosity η60β18” were established, and it was found that this thickener has no viscosity amplification function.

  Viscosity can be amplified by including water-dispersible cellulose, which is the fine fibrous cellulose of the present invention, and a polysaccharide. That is, it is possible to impart a greater viscosity with a small amount. This property can be used not only in the food field but also in applications such as pharmaceuticals and cosmetics.

Claims (4)

  A fine fibrous cellulose made from plant cell walls as a raw material, and stably suspended in water (major axis: 0.5 to 30 μm, minor axis: 2 to 600 nm, major axis / minor axis ratio: 20 to 400) ) 30% by weight or more, and the loss tangent when the water dispersion is 0.5% by weight is less than 1, water-dispersible cellulose, tamarind seed gum, pectin, carrageenan, gellan gum A composition containing at least one polysaccharide selected from sodium carboxymethyl cellulose, soybean water-soluble polysaccharide, xanthan gum, karaya gum, psyllium seed gum, pullulan, gum arabic, tragacanth gum, gaddy gum, arabinogalactan, curdlan It is characterized by containing water-dispersible cellulose: polysaccharide = 1: 9-9: 1 by mass ratio Thickener.   The water-dispersible dry composition comprising 50 to 95% by mass of the water-dispersible cellulose according to claim 1, 5 to 50% by mass of a water-soluble polymer and / or a hydrophilic substance, and the polysaccharide according to claim 1. A thickener comprising at least one selected polysaccharide, wherein the composition is a water-dispersible dry composition: polysaccharide = 1: 9 to 9: 1.   A water-dispersible dry composition comprising 50 to 95% by weight of the water-dispersible cellulose according to claim 1, 1 to 49% by weight of a water-soluble polymer, and 1 to 49% by weight of a hydrophilic substance, and at least one kind A composition comprising a polysaccharide, wherein the polysaccharide is selected from the group consisting of tamarind seed gum, pectin, carrageenan, sodium carboxymethylcellulose, soybean water-soluble polysaccharide, karaya gum. 2. Thickener according to 2.   The liquid composition mix | blended by adding the thickener in any one of Claims 1-3.