JPH11206611A - Hydrolytic tissue - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain hydrolytic tissues that are strong even when they are dry or wet due to a certain amount of water and disperse easily when they contact a large amount of water. SOLUTION: The hydrolytic tissues contain water dispersible fibers and fine fibrous cellulose mixed together. It is preferred that water dispersible fibers contain pulp and rayon and the content of the fine fibrous cellulose is 5 to 30 wt.%. The hydrolytic tissues excel in dry strength and wet strength when they are wet due to a certain amount of water. Those hydrolytic tissues do not lose much of their strength as wet tissues even if they are stored for a long period of time.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a water-disintegrable tissue which is easily dispersed by a large amount of water. More particularly, the present invention relates to a water-disintegrable tissue used as toilet paper or for cleaning or cleaning.

[0002]

2. Description of the Related Art A water-disintegrable tissue is used as toilet paper for wiping the buttocks of a human or as a cleaning sheet around the toilet. When this water-disintegrable tissue is thrown away in a toilet or the like, it must be dispersed in a septic tank, so high water-disintegration is required. As a result, the wet strength when wet with a small amount of water was extremely low.

However, in recent years, flush toilets with a washing device have become widespread. In this cleaning device, after washing the buttocks with water, the moisture remaining in the buttocks is dried by warm air.
However, it takes too much time to obtain a completely dry state with short-time hot-air drying, and the act of wiping off moisture with toilet paper after washing is performed. As described above, toilet paper has a low wet strength when containing a small amount of water, and easily dissolves when touching a small amount of water. Therefore, when wiping the wet buttocks, the toilet paper is easily torn.

In this regard, Japanese Patent Application Laid-Open No. 8-56868 discloses a toilet paper for a flush toilet with a washing device, which contains a cationic aldehyde-modified polyacrylamide copolymer. However, in order to achieve high wet strength in this toilet paper, the amount of the copolymer must be increased,
Water disintegration becomes extremely poor.

[0005] On the other hand, similarly, a water-disintegrable wet tissue as a textile product is used for cleaning around a toilet, wiping a baby's ass, and the like. These must maintain their strength even in a wet state containing water, and must be easily decomposed when thrown away in a toilet. For this purpose, a water-soluble binder and an electrolyte are included. For example, JP-A-2-149237 discloses a water-disintegrable cleaning article containing carboxymethylcellulose and an alkaline earth metal, and JP-A-9-170193 discloses a water-disintegrable sheet containing methylcellulose and an electrolyte. I have. However, alkaline earth metals and metal salts of electrolytes may have a bad effect on the human body depending on their types.

SUMMARY OF THE INVENTION An object of the present invention is to provide a water-disintegrable tissue which easily disintegrates when exposed to a large amount of water, and has high strength when dried and high strength when wet when contacted with a small amount of water. .

It is another object of the present invention to provide a water-disintegrable tissue that is safe for the human body.

[0008]

The above objects and advantages of the present invention are attained by a water-disintegrable tissue characterized in that water-dispersible fibers and microfibrous cellulose are mixed.

As the fiber of the present invention, a fiber having good dispersibility in water is used. Here, the dispersibility in water means
It has the same meaning as water disintegration, and is a property that is subdivided by contact with a large amount of water.

The fibers used in the present invention include:
Either synthetic fiber or natural fiber or both fibers can be used. Examples of the chemical fiber include rayon and acetate as regenerated fibers and polypropylene as a synthetic fiber, and examples of natural fibers include wood pulp such as softwood pulp and hardwood pulp, Manila hemp, Linder pulp, bamboo pulp, and kenaf. Among them, softwood pulp is preferred as a natural fiber because both strength and water dispersibility are easily achieved. Softwood bleached kraft pulp can be exemplified as the softwood pulp. Preferred C for softwood pulp
The FS is 500 cc. As a fiber other than pulp, rayon is preferable because it has good water dispersibility and can give a soft feeling to the tissue. The preferred fiber length of rayon is 10 mm or less, and the preferred denier is 7 denier or less. In addition, softwood pulp and rayon can be mixed and used. In addition, natural fibers such as cotton mainly containing water-dispersible fibers, synthetic fibers such as polypropylene, polyvinyl alcohol, polyester or polyacrylonitrile, and nylon, synthetic fibers made of polyethylene and the like, and inorganic fibers such as glass wool are contained. You can also.

Microfibrous cellulose (Microfib)
“Rilated Cellulose” is obtained by crushing hydrogen bonds of cellulose and beaten the cellulose to a state close to microfibrils. As a main production method, pulp is used as a raw material, and it is mechanically subjected to a special treatment in a state of an aqueous suspension, and is severely beaten while suppressing cutting in the fiber axis direction. The shape is an elongated fibrous shape, the fiber length is several tens to several hundreds μm, and the fiber diameter is submicron to 0.01 μm, which is close to a so-called microfibril. Microfibrous cellulose is also insoluble in water.

A water-disintegrable tissue is obtained by blending the above-mentioned water-dispersible fibers with microfibrous cellulose and making paper. The method for producing the water-disintegrable tissue is not particularly limited, and a conventionally known method can be used. Generally, a wet papermaking method is used.

In this paper-made water-disintegrable tissue, the microfibrous cellulose mixed in the water-disintegrable tissue is finely divided, so that the number of hydrogen bonding sites of the cellulose is increased as compared with a normal tissue. Therefore,
Since the microfibrous cellulose functions as a paper-strengthening agent, this water-decomposable tissue exhibits sufficient strength even when impregnated with a small amount of water, but when exposed to a large amount of water, hydrogen bonds are broken. And can be easily disintegrated.

However, the amount of the hydrogen-bonding site of the microfibrous cellulose varies depending on the miniaturization conditions during production. When the amount of the hydrogen bondable portion increases, the water retention increases. Therefore, if microfibrous cellulose having a high water retention is used, a water-disintegrable tissue with high strength can be obtained even if the amount of the microfibrous cellulose is small. When using microfibrous cellulose having a low water retention, it is preferable to add a certain amount.

In the present invention, according to the test method of JAPAN TAPPI paper pulp No. It is preferable to use microfibrous cellulose having a water retention of 250% or more at 26. In this case, the mixing ratio of the water-dispersible fiber and the microfibrous cellulose is such that the water-dispersible fiber is 70 to 95%.
5% by weight and 5-30% by weight of microfibrous cellulose
Preferably, In this mixing ratio, the water-disintegrable tissue of the present invention is excellent in water-solubility required for toilet paper, strength when dried, and further strength when wet with a small amount of water.

In addition, JAPAN TAPPI paper pulp test method No. In the case of using microfibrous cellulose having a water retention of about 361% in 26, if the blending amount of the microfibrous cellulose is 1% or more, a higher wet strength than conventional toilet paper can be obtained. For example, when using microfibrous cellulose having a water retention of 350%, the compounding amount of microfibrous cellulose is 3%.
As described above, for example, when using microfibrous cellulose having a water retention of 250%, the compounding amount of microfibrous cellulose is 5%.
% Or more, a wet strength higher than that of toilet paper can be obtained. As described above, the higher the water retention of the microfibrous cellulose, the smaller the amount of the microfibrous cellulose compounded. Therefore, it is preferable to use microfibrous cellulose having a high water retention in terms of cost.

In the present invention, the basis weight (basis weight) of the water-disintegrable tissue is preferably 12 to 50 g / m ² . When the grammage is smaller than the lower limit, necessary strength cannot be obtained when used as toilet paper. When the basis weight is larger than the above upper limit, the flexibility as toilet paper is lacking, and the fibers are difficult to disperse in water, resulting in poor water dissolvability. When the water-disintegrable tissue of the present invention is used as a wiping sheet for cleaning or cleaning, it is preferable that the basis weight be larger than that used as toilet paper. For example, the basis weight of the fiber is preferably 15 to 30 g / m ² in terms of the strength of the wiping sheet, the effect of wiping off dirt, and the soft feeling when touched.

The water-disintegrable tissue thus obtained preferably has a water-disintegrable property of 100 seconds or less. When used as toilet paper, the generally required water disintegration is 100 seconds or less. The water disintegration at this time is the water disintegration measured according to the JIS P4501 toilet paper loosen test.

The water-disintegrable tissue of the present invention has a wet strength enough to withstand wiping work even when it contains a certain amount of water, for example, 1 to 2.5 times the weight of the water-disintegrable tissue.

Here, when the amount of water impregnated with respect to the weight of the fibers and microfibrous cellulose is 1.0 times, M
It is preferable that the wet strength in the D (Machine Direction) direction is 50 g / 25 mm or more.
This wet strength is higher than the wet strength of commercially available toilet paper, and can withstand the wiping operation even in a slightly wet state. In addition, the breaking strength at the time of moistening (hereinafter referred to as wet strength) is 25 mm wide and 150 mm long.
A predetermined amount of water is impregnated into a water-disintegrable tissue cut to a thickness of 100 mm, and a chuck interval of 100 m is used with a Tensilon tester.
m, strength at break (gf) measured at a tensile speed of 100 mm / min. This is merely a measure based on this measurement method, and any shape having substantially the same strength as the wet strength may be used.

The weight of the water-disintegrable tissue is 1.
It is sufficient to wipe the wet buttocks after washing in a flush toilet equipped with a washing device if the wet strength is sufficient to withstand the wiping operation in a state of containing 0 times the water content. Therefore,
The obtained water-disintegrable tissue has the necessary strength and water disintegration properties as a toilet paper for a flush toilet with a washing device, and also as a fiber sheet used for wiping operations such as cleaning the body and wiping the baby's ass. It can be.

In particular, for cleaning around the toilet, the water-disintegrable tissue of the present invention can be flushed to the toilet after use, which is extremely convenient. In this case, the toilet paper can be used by impregnating the toilet paper with a cleaning liquid containing a surfactant or the like at the time of cleaning.

Therefore, it can be packaged and sold as a wet tissue in a wet state pre-moistened. The cleaning liquid to be impregnated in the water-disintegrable tissue may be, if necessary, a surfactant, a bactericide, a preservative, alcohol,
Perfumes and the like can be contained.

The water-disintegrable tissue of the present invention may contain a water-soluble or water-swellable binder to increase the strength. In particular, when used strongly for cleaning or wiping work for cleaning, if the fibers are strongly wiped, the fibers may fall off from the surface that is the wiping surface. In such a case, the surface of the water-disintegrable tissue is coated or contained with a water-soluble binder, so that the tissue can be more easily used for wiping.

However, since this water-disintegrable tissue does not contain a binder and has a high wet strength, the amount of the binder is much smaller than that of a conventional cleaning sheet. For example, it may be applied only to the surface for the purpose of increasing the surface strength.

Examples of the water-soluble binder include carboxymethyl cellulose, alkyl cellulose, polyvinyl alcohol, and modified polyvinyl alcohol. Water-soluble or water-swellable carboxymethyl cellulose can be used. Examples of the alkylcellulose include methylcellulose, ethylcellulose, and benzylcellulose in which a hydroxyl group in a glucose ring unit of cellulose is substituted with an alkyl group. The modified polyvinyl alcohol is a vinyl alcohol-based polymer containing a predetermined amount of a sulfonic acid group or a carboxyl group. In order to include the binder on the surface of the water-disintegrable tissue, there is a method in which a water-soluble binder is applied using, for example, a silk screen.

When the above binder is used, an electrolyte can be contained in order to enhance the function of the binder. However, depending on the type of the metal salt of the electrolyte, a smaller content is preferable for the human body. However, as described above, in the water-disintegrable tissue of the present invention, the binder may be contained in a small amount, so that the following electrolyte does not need to be contained in a large amount. When carboxymethylcellulose is used as the binder, a divalent salt is preferable from the viewpoint of increasing the strength of the water-disintegrable nonwoven fabric. When alkyl cellulose is used as the binder, a monovalent salt is preferred. When polyvinyl alcohol or modified polyvinyl alcohol is used as the binder, it is preferable to use a monovalent salt. As the electrolyte, one or both of an inorganic salt and an organic salt can be used. As inorganic salts, sodium sulfate, potassium sulfate, sodium chloride,
Examples include magnesium sulfate, potassium chloride, sodium carbonate, sodium hydrogen carbonate and the like. Examples of the organic salt include sodium citrate, potassium citrate, sodium tartrate, potassium tartrate, sodium lactate, sodium succinate, calcium lactate and the like.

When alkylcellulose is used as a binder, to increase the strength of the water-disintegratable nonwoven fabric,
For example, a copolymer of a polymerizable compound that is an acid anhydride such as a (meth) acrylic acid maleic acid-based resin, a (meth) acrylic acid fumaric acid-based resin, and a compound copolymerizable therewith, or trimethylglycine And other amino acid derivatives.

In addition, the water-disintegrable tissue of the present invention may contain other substances as long as the effects of the present invention are not impaired.

[0030]

EXAMPLES Hereinafter, the present invention will be described in more detail with reference to Examples, but the present invention is not limited to these Examples. [Example A] Softwood bleached kraft pulp (Canadian Standard 9 Freeness (CS
F) = 570 ml. It is shown as NBKP below the table. )
Microfibrous cellulose (manufactured by Daicel Chemical Industries, Ltd., J
APAN TAPPI No. 26 has a water retention of 361)
Weighing 40 g / m ² by wet paper making method
Water-disintegrable tissue (base paper). The blending ratio is 90% by weight of softwood bleached kraft pulp and 10% by weight of microfibrous cellulose. The obtained water-disintegrable tissue was measured for water-disintegration and dry strength.
Further, 150 g of ion-exchanged water was impregnated with 100 g of the obtained water-disintegrable tissue by spraying. The wet strength of the obtained wet water-disintegrable tissue was measured. Each measurement method is described below.

The water disintegration test was carried out in accordance with the JIS P4501 toilet paper looseness test. To be more specific, a water-disintegrable tissue is 10 cm long and 10 cm wide.
Was cut into a 300 ml beaker containing 300 ml of ion-exchanged water, and stirred using a rotor. The rotation speed is 600 rpm. At this time, the dispersion state of the water-disintegrable tissue was observed over time, and the time until fine dispersion was measured (in the following table, the unit is seconds).

The dry strength and wet strength of the water-disintegrable tissue obtained by the above method were 25 mm in width and 150 in length.
mm was used as a sample, and using a Tensilon tester, the chuck interval was 100 mm and the pulling speed was 10 mm.
It was measured at 0 mm / min. Measurements were taken in the machine direction (MD:
Machine direction) and cross direction of the paper (CD: Cross Direction). The strength at break (gf) at that time was taken as the value of the test result of the wet strength (units in the following table are g / 25 m).
m).

As Comparative Example 1, a paper made of softwood pulp by hand-making by wet papermaking method, and as Comparative Example 2, wet papermaking by adding 0.1% of polyamide epowrolhydrin resin to 100% softwood pulp and handmaking. Water disintegration, dry strength and wet strength tests were performed on the paper produced by the method in the same manner as in the examples.

Table 1 shows the results. Further, the breaking lengths obtained from the obtained values of the dry strength and the wet strength are calculated and shown in Table 1. Here, the breaking length is a value obtained by eliminating the difference in value due to the difference in basis weight in the measurement of strength,
Calculated based on the tensile strength test method of paper and paperboard of JIS P8113. The formula used is as follows. Breaking length (m) = ｛tensile strength (g / 25 mm) × 100
0｝ ÷ ｛Basic weight of test piece (g / m ² ) × width of test piece (m
m)｝

[0035]

[Table 1]

Example B A paper was made from the water-disintegrable tissue of the present invention using a machine. Using the same softwood pulp and microfibrous cellulose as in Example A, with the formulation shown in Table 2,
Paper was made using a circular net-Yankee machine in a wet system.
The papermaking speed was 150m / min for dryer and 1 for winding.
A water-disintegrable tissue manufactured at 32 m / min and having a crepe ratio adjusted to 12% was obtained.

The obtained water-disintegrable tissue was measured for water-disintegrability in the same manner as in Example A. Further, 100 g of ion-exchanged water was used for 100 g of the obtained water-disintegrable tissue.
Was impregnated with a spray. The wet strength of the obtained wet water-disintegrable tissue was measured in the MD and CD directions. The measuring method is the same as in Example A. As a comparative example, a commercially available toilet paper and a commercially available tissue paper were tested for water degradability and wet strength in the same manner as in the examples. Table 2 shows the results.

[0038]

[Table 2]

[Example C] Using the same softwood bleached kraft pulp as in Example A and the same microfibrous cellulose as in Example A as the raw material fiber, the wet disintegration by hand was carried out by wet papermaking at a weight of 40 g / m ² . Tissue (water disintegration paper) was manufactured. The mixing ratios are as shown in Table 2. Example A of this water-disintegrable tissue (water-disintegrated paper)
Water dissolvability, dry strength, and bristles were measured in the same manner as described above. The rigidity was measured based on the cantilever method of JIS L1096. Further, 100 g of ion-exchanged water was impregnated with 100 g of the obtained water-disintegrable tissue (water-disintegrated paper) by spraying. The wet strength of the obtained wet water-disintegrable tissue (water-disintegrated paper) was measured. The measuring method is the same as in Example A. As a comparative example, a test for water disintegration, dry strength, wet strength, and bending resistance was performed on a tissue containing no microfibrous cellulose in the same manner as in the example. Table 3 shows the results.

[0040]

[Table 3]

Example D The same softwood bleached kraft pulp and rayon as in Example A (fiber length 5 m)
m, 1.5 denier) and the same microfibrous cellulose as in Example A, and a water-disintegrable tissue weighing 40 g / m ² was manufactured by hand-making using a wet papermaking method. The mixing ratios are as shown in Table 2. With respect to this water-disintegrable tissue, the water-disintegrability, dry strength, and bending resistance were measured in the same manner as in Example A. The bending resistance was measured in the same manner as in Example B. Also, 100 g of ion-exchanged water was impregnated with 100 g of the obtained water-disintegrable tissue by spraying. The wet strength of the obtained wet water-disintegrable tissue was measured. The measuring method is the same as in Example A. As a comparative example, a test for water disintegration, dry strength, wet strength, and bending resistance was performed on a tissue containing no microfibrous cellulose in the same manner as in the example. Table 4 shows the results
Shown in

[0042]

[Table 4]

Example E 100 g of the same water-disintegrable tissue as in Example A was impregnated with 200 g of ion-exchanged water by spraying. The obtained wet water-disintegrable tissue was stored in a plastic container at room temperature, and the wet strength after 0, 24, and 144 hours was measured. The measuring method is the same as in Example A. Table 5 shows the results.

[0044]

[Table 5]

Example F The same softwood bleached kraft pulp as in Example A was used as the raw material fiber.
I No. Using a microfibrous cellulose having a water retention of 26 and a wet papermaking method by hand, weighing 40 g / m2
² water-disintegrable tissues (base paper) were manufactured. The water retention of each microfibrous cellulose is as shown in Table 4. The obtained water-disintegrable tissue was measured for water-disintegration, dry strength and wet strength in the same manner as in Example A. Table 6 shows the results.

[0046]

[Table 6]

[0047]

The water-disintegrable tissue to which the microfibrous cellulose of the present invention is blended has good water-disintegration properties and contains a certain amount of water, for example, 1 to 2.5 times the weight of the water-disintegrable tissue. Has a wet strength enough to withstand the wiping operation. Therefore, the obtained water-disintegrable tissue is necessary as a toilet tissue suitable for use in a flush toilet with a washing device, and as a wet tissue used for wiping operations such as body cleaning such as wiping a baby's ass and cleaning. It has strength and water disintegration.

Further, the water-disintegrable tissue of the present invention does not cause a decrease in strength even when stored for a long time in a wet state containing water. Therefore, it can be used as a wet tissue pre-wetted for cleaning or cleaning.

The microfibrous cellulose used in the present invention is edible.
Further, a water-disintegrable tissue having a strength that can be used can be obtained without using a metal salt such as an electrolyte or the like used in a conventional water-disintegratable fiber sheet or using a small amount. Therefore, the water-disintegrable tissue of the present invention is highly safe for the human body.

Claims (9)

[Claims] 1. A water-disintegrable tissue comprising a mixture of water-dispersible fibers and microfibrous cellulose. 2. The water-dispersible fiber is pulp.
The water-disintegrable tissue described. 3. The water-disintegrable tissue according to claim 1, wherein the water-dispersible fibers include pulp and rayon. 4. The content of microfibrous cellulose is 5 to 3
The water-disintegrable tissue according to claim 1, which is 0% by weight. 5. Japan T of microfibrous cellulose
APPI Paper Pulp Test Method No. 5. The water-disintegrable tissue according to claim 1, wherein the water retention degree according to No. 28 is 250% or more. 6. The water-disintegrable tissue according to claim 1, which is used in a wet state impregnated with water. 7. The water-disintegrable tissue according to claim 6, wherein the amount of water to be impregnated is 1 to 2.5 times the sum of the weights of the fibers and the microfibrous cellulose. 8. The method according to claim 6, wherein the wet strength (MD) when the amount of impregnated water is 1.0 times the weight of the fibers and the microfibrous cellulose is 50 g / 25 mm or more. Water dissolvable tissue. 9. The water-disintegrable tissue according to claim 6, wherein the surface contains a water-soluble binder and an electrolyte.