JP2010132862A - New polyion complex - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a useful polyion complex using a cellulosic polymer with predetermined structure. <P>SOLUTION: The polyion complex is obtained as a precipitate by mixing an aqueous solution of a cationic cellulose polymer having a predetermined repeating unit and a predetermined molecular weight with an aqueous solution of an anionic cellulose polymer having a predetermined repeating unit and a predetermined molecular weight, in an aqueous medium under pH conditions in which both materials become a dissociative state, to produce a heterogeneous solution, and by continuously mixing the resulting heterogeneous solution. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a polyion complex using a cellulosic polymer as a starting material. Furthermore, the present invention relates to a strength enhancing composition for a hydraulic composition containing such a polyion complex, a cement hydraulic composition containing the strength enhancing composition, and a frozen hydraulic composition formed by freezing the cement hydraulic composition. Related to things. In addition, the present invention relates to a water absorption enhancing composition for a hydraulic composition containing such a polyion complex, and a plaster hydraulic composition containing the water absorption enhancing composition.

A polyion complex is a complex in which a polyanion and a polycation are bonded by electrostatic interaction, and exhibits a unique action having a hydrophilic region and a hydrophobic region. Various types of polyion complexes have been proposed.
For example, Patent Document 1 below uses hydroxyethyl cellulose hydroxypropyltrimethylammonium chloride ether (hereinafter referred to as the former in this paragraph number) as a polyanion and carboxymethyl cellulose (hereinafter referred to as the latter in this paragraph number) as a polycation in Example 13. ) To produce a fine-grained polyion complex. According to Example 13 of Patent Document 1, the former hydrochloric acid solution and the latter aqueous solution are mixed to obtain a transparent compatible solution, and from this transparent compatible solution, after treatment such as pH fluctuation, A fine-grained polyion complex is obtained. That is, in this known production method, “formation of a compatible solution” and “pH variation of the formed compatible solution” are essential requirements.

  However, since the known complex is in the form of fine particles, for example, when it is added to cement as a hydraulic composition, it should be scattered as a small lump without becoming a lump even when swollen in contact with water. Therefore, there is a problem that the strength of the cement is lowered.

JP 2005-36190 A

  In view of the above problems, an object of the present invention is to provide a useful polyion complex using a cellulose-based polymer having a predetermined structure.

〔式中、Ｒ₁〜Ｒ₃は、同じまたは異なってもよく炭素数１〜３のアルキル基であり、Ｘはハロゲン原子である。〕
で示される反復単位および分子量１万〜１０万を有するカチオン性セルロースポリマーと、式（II）：

〔式中、Ｙは水素またはアルカリ金属原子である。〕
で示される反復単位および分子量５０万〜１００万を有するアニオン性セルロースポリマーとを、水性溶媒中、これら両物質が解離状態となるｐＨ条件下に、混合することによって不均一性溶液を得、得られた不均一性溶液の混合を継続することによって沈殿物として得られることを特徴とするポリイオンコンプレックスを提供する。
さらに本発明は、その第２の態様として、本発明のポリイオンコンプレックスを含む水硬性組成物用の強度増強組成物を提供し、その第３の態様として、本発明の強度増強組成
物を含むセメント水硬性組成物を提供し、その第４の態様として、セメント水硬性組成物（第３態様）を凍結させてなる冷凍水硬性組成物を提供し、その第５の態様として、本発明のポリイオンコンプレックスを含む水硬性組成物用の吸水性増強組成物を提供し、その第６の態様として、本発明の吸水性増強組成物を含む漆喰水硬性組成物を提供する。 As a result of intensive studies to solve the above problems, the present inventors have mixed a cationic cellulose polymer having a predetermined structure and an anionic cellulose polymer under pH conditions where both substances are in a dissociated state. The complex was obtained as a precipitate, and for example, it was found that it was useful for increasing the strength of cement and could solve the above-mentioned problems. Based on this finding, the present invention has been completed.
That is, the present invention relates to the formula (I):

[In formula, R < ₁ > -R < ₃ > may be the same or different and is a C1-C3 alkyl group, and X is a halogen atom. ]
A cationic cellulose polymer having a repeating unit represented by formula (1) and a molecular weight of 10,000 to 100,000, and a formula (II):

[Wherein Y is hydrogen or an alkali metal atom. ]
A heterogeneous solution is obtained by mixing an anionic cellulose polymer having a repeating unit represented by the formula (1) and a molecular weight of 500,000 to 1,000,000 in an aqueous solvent under a pH condition in which both of these substances are dissociated. Provided is a polyion complex obtained as a precipitate by continuing to mix the produced heterogeneous solution.
Furthermore, the present invention provides a strength enhancing composition for a hydraulic composition containing the polyion complex of the present invention as a second aspect thereof, and a cement containing the strength enhancing composition of the present invention as a third aspect thereof. A hydraulic composition is provided, and as a fourth aspect thereof, a frozen hydraulic composition obtained by freezing a cement hydraulic composition (third aspect) is provided, and as a fifth aspect, the polyion of the present invention is provided. A water absorption enhancing composition for a hydraulic composition containing a complex is provided, and as a sixth aspect thereof, a stucco hydraulic composition containing the water absorption enhancing composition of the present invention is provided.

  According to the polyion complex of the present invention, a useful massive polyion complex can be obtained through a heterogeneous solution by mixing under pH conditions where both substances of cationic cellulose / anionic cellulose are dissociated. There are technical effects. For example, when the polyion complex of the present invention is added to a cement, an organic structure is formed between the inorganic structure of the cement, which is an inorganic material, and the organic structure of the cationic cellulose polymer / anionic cellulose polymer (an entangled structure of cellulose). A strong network was built and a significant increase in strength was obtained.

It is a graph which shows the relationship between intensity | strength and a density | concentration regarding the cement hydraulic composition of this invention, and a comparative example (water cement ratio 40%). It is a graph which shows the relationship between intensity | strength and a density | concentration regarding the cement hydraulic composition of this invention and a comparative example (60% of water cement ratio). It is a graph which shows the strength comparison with a freezing comparative example and a non-freezing control regarding the cement hydraulic composition of a comparative example. It is a graph which shows the strength comparison with a freezing example and non-freezing control regarding the cement hydraulic composition of this invention. It is a graph which shows the relationship between a measurement period and the weight of a plaster hydraulic composition regarding the plaster hydraulic composition and comparative example of this invention. It is a graph which shows the relationship between IPEC 1 addition rate (slaked lime reference | standard) and the amount of water absorption regarding the plaster hydraulic composition and comparative example of this invention.

-Polyion complex-
As described above, the present invention comprises a cationic cellulose polymer having a repeating unit represented by the formula (I) and a molecular weight of 10,000 to 100,000, a repeating unit represented by the formula (II) and a molecular weight of 500,000 to 1,000,000. By mixing the anionic cellulose polymer with an anionic cellulose polymer in an aqueous solvent under a pH condition where both of these substances are dissociated to obtain a heterogeneous solution, and by continuing mixing of the obtained heterogeneous solution Provided is a polyion compressor characterized in that it is obtained as a precipitate.

式（Ｉ）において、Ｒ₁〜Ｒ₃は、同じまたは異なってもよく、炭素数１〜３のアルキル基であってメチル、エチル、プロピルまたはイソプロピル基である。また、Ｘはハロゲン原子であって、クロル、ブロム原子を例示することができる。また、カチオン性セルロースの平均分子量は、１万〜１０万、好適には３万〜７万、有利には１万〜３.５万、３万〜６万、５万〜１０万である。
現時点で好適なカチオン性セルロースは、Ｒ₁〜Ｒ₃が同じであってメチル基で、Ｘがクロル原子である式（Ｉ）の反復単位を有する。 <Cationic cellulose / Anionic cellulose>
The cationic cellulose polymer (hereinafter also simply referred to as cationic cellulose) that is a starting material of the present invention has a repeating unit represented by the following formula (I).

In the formula (I), R _{1 to} R ₃ may be the same or different and each represents an alkyl group having 1 to 3 carbon atoms and is a methyl, ethyl, propyl or isopropyl group. X is a halogen atom, and examples thereof include chloro and bromo atoms. The average molecular weight of the cationic cellulose is 10,000 to 100,000, preferably 30,000 to 70,000, preferably 10,000 to 35,000, 30,000 to 60,000, and 50,000 to 100,000.
The presently preferred cationic cellulose has recurring units of the formula (I) in which R _{1 to} R ₃ are the same and are methyl groups and X is a chloro atom.

式（II）において、Ｙは水素またはアルカリ金属原子であり、ナトリウム、カリウムを例示することができる。また、アニオン性セルロースの平均分子量は、５０万〜１００万、好適には６０万〜９０万、より好適には７０万〜８０万、有利には、例えば、５０万〜６５万、６０万〜７５万、７０万〜８５万、８０万〜９５万、８５万〜１００万である。現時点で好適なアニオン性セルロースは、Ｙがナトリウムである式（ＩＩ）の反復単位を有する。
カチオン性セルロース／アニオン性セルロースの平均分子量に関し、一方の平均分子量が比較的大きい場合には、他方の平均分子量は比較的小さいことが好適であることが現時点で判明している。したがって、両者の平均分子量の合計は、好適には１１０万以下、より好適には９５万以下、特に好適には８５万以下である。 The anionic cellulose polymer (hereinafter also simply referred to as anionic cellulose), which is a starting material of the present invention, has a repeating unit represented by the following formula (II).

In the formula (II), Y is hydrogen or an alkali metal atom, and examples thereof include sodium and potassium. The average molecular weight of the anionic cellulose is 500,000 to 1,000,000, preferably 600,000 to 900,000, more preferably 700,000 to 800,000, and advantageously 500,000 to 650,000, 600,000 to 600,000, for example. 750,000, 700,000-850,000, 800,000-950,000, 850,000-1 million. The presently preferred anionic cellulose has a repeating unit of formula (II) where Y is sodium.
With regard to the average molecular weight of the cationic cellulose / anionic cellulose, it has now been found that when one average molecular weight is relatively large, the other average molecular weight is preferably relatively small. Accordingly, the sum of the average molecular weights of both is preferably 1.1 million or less, more preferably 950,000 or less, and particularly preferably 850,000 or less.

<Mixing in aqueous solvent>
Cationic cellulose and anionic cellulose are mixed in an aqueous solvent, and if necessary, an aqueous solvent containing a small amount of a surfactant, preferably in an aqueous solution. An aqueous solvent is prepared in advance, and cationic cellulose and anionic cellulose may be added to the aqueous solvent. Preferably, an aqueous solution of cationic cellulose and an aqueous solution of anionic cellulose are mixed. . Particularly preferably, either one of the solutions can be dropped little by little.
The aqueous solution concentration of the cationic and anionic celluloses depends on the amount (viscosity) of these celluloses, and at least one of the aqueous solutions has an aqueous solution concentration that provides a droppable viscosity.

<Mixing under pH condition to be dissociated>
Cationic cellulose and anionic cellulose are under pH conditions where these substances are in a dissociated state, preferably under conditions of pH 5.5 to pH 8.5, such as pH 5.5 to pH 6.5, pH 6.0 to pH 7. 0, pH 6.5 to 7.5, pH 7.0 to 8.0, pH 7.5 to 8.5, more preferably pH 6.0 to 8.0, and particularly preferably pH 6.0. Mix under conditions of 5 to pH 7.5. Similarly to the above, if these upper and lower limits are deviated, a heterogeneous solution cannot be formed. When mixed under such pH conditions, a heterogeneous solution such as an opaque solution can be obtained.
<Mixing ratio of two polymers>
Cationic cellulose and anionic cellulose can be mixed at any mixing ratio as long as a heterogeneous mixed solution is obtained. In order to determine a suitable mixing ratio, when mixing with one aqueous solution while changing the addition amount of the other aqueous solution, first, the mixed solution increases in viscosity and shows a maximum value, and near this maximum value. The turbidity of the mixed solution is observed [Step I above]. Furthermore, when the addition amount is increased, the mixed solution shows an increase in turbidity and formation of a precipitate in the lower part of the mixed solution and a maximum value of the precipitation amount, and the viscosity of the mixed solution decreases and the precipitation amount decreases. A minimum value is shown near the maximum value of, and the upper phase of the mixed solution becomes transparent [step II above]. In addition, when the amount added is increased, the turbidity of the mixed solution increases again, the amount of precipitation decreases, and the solution viscosity increases [step III above].
From the above experimental results, the preferred mixing ratio is the ratio in the II stage where the viscosity of the mixed solution is minimal.
In particular, when a suitable mixing ratio is defined by weight ratio, the weight ratio of (cationic cellulose polymer) to (anionic cellulose polymer) varies depending on the former degree of cationization as well as the latter degree of anionization. , (2.5 to 3.5) to 1, preferably (2.7 to 3.3) to 1. Deviating from these upper and lower limits makes it difficult to form a heterogeneous solution.
<Mixing of heterogeneous solution>
The heterogeneous solution suitably continues to be mixed while maintaining the pH in the same state (eg, within the range of ± 1.0, preferably within ± 0.5) to obtain a precipitate. The time required for mixing depends on the kind of the cationic cellulose / anionic cellulose, the concentration of the aqueous solution, the blending ratio, etc., but is preferably about 10 minutes to about 60 minutes, more preferably about 30 minutes to about 50. Minutes. In addition, it is suitable for the formation of a precipitate if it is allowed to stand at room temperature for about 1 day after the completion of mixing. After the formation of the precipitate, the polyion complex is obtained by removing the supernatant and separating the precipitate in the aqueous medium. The obtained polyion complex can be preferably obtained as a powder by washing the separated precipitate with water, drying, and further pulverizing.

-Strength enhancing composition / water absorption enhancing composition for hydraulic composition-
The strength enhancing composition for a hydraulic composition of the present invention contains the polyion complex of the present invention as an essential component, and optionally includes calcium sulfoaluminate or quicklime used as a surfactant or swelling agent used as a shrinkage reducing agent. Furthermore, usual additives such as blast furnace slag and silica fume used as an admixture can be included. As described above, when the polyion complex of the present invention is added to cement as a hydraulic composition, the inorganic structure of the cement, which is an inorganic material, and the organic structure of the cationic cellulose polymer / anionic cellulose polymer are interposed. An organic network is built and a significant increase in strength is obtained.
Further, the water absorption enhancing composition for a hydraulic composition of the present invention similarly contains the polyion complex of the present invention as an essential component, and can optionally contain various additives.
The strength or water absorption enhancing composition of the present invention can be preferably produced by adding and mixing a powdered polyion complex with the aforementioned additives, preferably a powdered additive.

-Hydraulic composition-
The hydraulic composition of the present invention contains, as an essential component, either a strength enhancing composition for the hydraulic composition of the present invention or a water absorption enhancing composition for the hydraulic composition. The hydraulic composition includes a cement hydraulic composition and a plaster hydraulic composition as a composition that can be cured by a hydration reaction in the presence of moisture, and examples of the former include, for example, ordinary portland cement, moderately heated cement , Cement containing high strength cement, super high strength cement, high belite content cement, blast furnace cement fly ash cement, alumina cement, silica fume cement, and optionally containing aggregates such as sand and gravel (mortar, concrete ). The latter plaster hydraulic composition contains slaked lime, and optionally contains hemp fibers, herbs or seaweed-derived adhesives.
<Strength / addition ratio of water absorption enhancing composition>
The hydraulic composition of the present invention can contain the strength / water absorption enhancing composition of the present invention at an arbitrary addition ratio. Regarding the cement hydraulic composition, a suitable addition ratio is such that the polyion complex is 10 g to 70 g, more preferably 12 g to 50 g, and particularly preferably 15 to 35 g with respect to 1000 g of cement in the composition. To do. Regarding a plaster hydraulic composition, a suitable addition ratio can be contained such that the polyion complex is 1 g to 20 g, more preferably 3 to 10 g with respect to 200 g of slaked lime in the composition.
The strength / water absorption enhancing composition may be added in a powdered or lump-like state during kneading of the hydraulic composition, but is preferably added in a swollen state by adding water in advance. it can.
<Unwater-separable hydraulic composition>
In the cement hydraulic composition of the present invention, the strength enhancing composition as an essential component exhibits strong adhesiveness, and the strength enhancing action in water has been experimentally proven. Useful as a composition.

-Frozen hydraulic composition-
In general, when a hydraulic composition is cooled in an uncured state even in the presence of moisture, its curing rate decreases. Furthermore, when the frozen state is reached, the curing rate is remarkably reduced. On the other hand, if the hydraulic composition that has reached the frozen state is thawed and then cured again, it is also common that the strength is significantly reduced compared to the case where it is not frozen. Was known and was a problem. Therefore, even when the hydraulic composition to which the strength enhancing composition of the present invention was added was frozen and thawed, it was found that the strength reduction was remarkably small, and this problem could be solved. This fact has been experimentally proven. That is, the present invention provides a frozen hydraulic composition in a frozen state. The frozen hydraulic composition of the present invention is very useful because it can be used as an ordinary hydraulic composition by thawing to room temperature.
In order to produce the frozen hydraulic composition of the present invention, for example, the hydraulic composition of the present invention is kneaded with water according to a conventional method to form an uncured kneaded product, and this uncured kneaded product is brick-like. And poured into a mold having a desired shape and size, such as a concrete block shape, to a temperature that can be frozen while containing water, for example, −198 to 0 ° C., preferably −100 to −20 ° C. It can be carried out by cooling and freezing.
The frozen hydraulic composition produced as described above is taken out of the mold after freezing, and is preferably packaged with a water-impermeable film and kept at a low temperature below the temperature at which the frozen state can be maintained, for example, -198 to 0 Store at -100 ° C, preferably at -100 to -20 ° C, and use the frozen hydraulic composition in a frozen state at room temperature or if necessary, thaw and use it in the same way as a normal kneaded product can do.
-Other uses of the polyion complex of the present invention-
The polyion complex obtained as described above is expected to be used as an adhesive in addition to its use as a strength-enhancing composition and a water-absorbing enhancing composition for hydraulic compositions.

-Example-
Next, although an Example, a comparative example, a preparation example, and a test example are given and this invention is demonstrated in more detail, this invention is not restrict | limited to these Examples. In Examples and the like, “%” means wt% unless otherwise specified.
<Preparation Example 1: Preparation of aqueous cellulose polymer solution>
Cationic cellulose polymer having a repeating unit represented by the following formula (Ia) and an average molecular weight of 51000 (manufactured by Daicel Chemical Industries, Ltd., trade name: Gelner QH-200) was dissolved in 1 L of water, An aqueous solution was prepared. The prepared aqueous solution has a pH of 7.6.

Further, 20 g of an anionic cellulose polymer having a repeating unit represented by the following formula (IIa) and an average molecular weight of 750,000 (manufactured by Daicel Chemical Industries, Ltd., trade name: CMC1350) is dissolved in 1 L of water, and an aqueous solution of anionic cellulose is obtained. Prepared. The prepared aqueous solution has a pH of 6.0.

<Example 1: Polyion complex>
To 1 L of the anionic cellulose aqueous solution prepared in Preparation Example 1, 1.5 L of the cationic cellulose aqueous solution prepared in Preparation Example 1 was added dropwise at room temperature. After completion of the addition, the solution was stirred for 40 minutes at room temperature. The homogenous solution was left at room temperature for 24 hours. The pH of the supernatant of the heterogeneous solution is 7.6. Next, the supernatant was removed, and the resulting precipitate was washed with 0.5 L of water three times and dried at 50 ° C. in a dryer. This was pulverized with a mixer to obtain 64 g of a polyion complex. With respect to the resulting polyion complex, the weight ratio of (cationic cellulose polymer) to (anionic cellulose polymer) is 3: 1.
<Example 2: Strength / water absorption enhancing composition for hydraulic composition>
The powdery polyion complex produced in Example 1 was used as a strength / water absorption enhancing composition in the raw state, and this strength / water absorption enhancing composition is hereinafter referred to as “IPEC 1”.

<Example 3: Cement hydraulic composition>
Example 2 (powdered IPEC 1) was added to water at 1%, 2%, 5% and 10% with respect to water to form swollen IPEC 1. Separately, cement (ordinary Portland cement manufactured by Hitachi Cement Co., Ltd.) and sand are mixed, kneaded for 1 minute, subdivided into containers, IPEC 1 in a swollen state with water is added to each container, and a mixer is mixed for 40 minutes. A hydraulic composition was produced by stirring with AM-20 manufactured by Aikosha Seisakusho.
In addition, the hydraulic composition produced two types of compositions by changing the water cement ratio as follows, and formed a total of eight samples.
40% water cement ratio: 400 g cement + 800 g sand + 160 g water
60% water cement ratio: 400 g cement + 800 g sand + 240 g water
In addition, when the addition ratio of IPEC 1 with respect to the water described above is expressed as an addition ratio with respect to 1000 g of cement, the water cement ratio of 40% is 4 g, 8 g, 20 g, and 40 g, respectively, while the water cement ratio of 60%, In order are 2.4 g, 4.8 g, 12 g and 60 g.
<Comparative Examples 1-2: Cement hydraulic composition containing cellulose polymer alone>
In accordance with the same method as in Example 3, Comparative Examples 1 and 2 were formed. However, instead of IPEC 1, the cationic cellulose polymer (Comparative Example 1) or the anionic cellulose polymer (Comparative Example 2) was used alone with the same weight.

<Test Example 1: Compressive strength test of cement hydraulic composition>
A test piece was prepared as follows and subjected to a strength test.
Each hydraulic composition formed in Example 3 and Comparative Examples 1 and 2 was separately driven into three circular molds (Diai Reform Co., Ltd. Hit One: φ50 mm × 100 mm). The driving was divided into three layers and packed 20 times with a stick, the surface was leveled with a metal iron, covered and placed in a curing room (temperature about 20 ° C., humidity about 80%). After 2 days, the mold was removed, and curing was continued for another 28 days in the curing room. After curing, the compressive strength was measured using a universal testing machine (Shimadzu Corporation measurement control device UH-500KNI type).
<< Test results and discussion >>
The test result of 40% water cement ratio is shown in FIG. 1, and the test result of water cement ratio 60% is shown in FIG. In these figures, “-♦ -IPEC 1” indicates the experimental result of Example 3, “-■ -cation” indicates the experimental result of Comparative Example 1, and “-▲ -CMC” indicates that of Comparative Example 2. Experimental results are shown. In both drawings, the concentration of 0% means no addition in Example 1 or the like.
As can be seen from FIGS. 1 and 2, the strength is most enhanced when 5% of Example 3 (IPEC 1) is added to water in both cases of 40% water cement ratio and 60% water cement ratio. It was done.
Further, the water cement ratio of 40% (FIG. 1) shows an increase in strength not only in Example 3 (IPEC 1) of the present invention but also in Comparative Examples 1 and 2. On the other hand, at a water cement ratio of 60% (FIG. 2), the strength is reduced except for Example 3 (IPEC 1). That is, in Comparative Examples 1 and 2, the strength significantly decreased with an increase in the water-cement ratio. From this result, it is assumed that the water cement ratio adjusted before being poured into water increases due to the inflow of moisture from the outside. That is, in Comparative Examples 1 and 2, the strength decreases as the water cement ratio increases, whereas in Example 3 (IPEC 1), the strength does not decrease even when the water cement ratio increases. Based on this fact, it has been found that the hydraulic composition of the present invention is particularly suitable as a non-separable hydraulic composition for cement used in water. This is a unique technical effect resulting from the strength-increasing composition of the present invention (IPEC 1) added to the hydraulic composition.

<Comparative Example 3: Additive-free cement hydraulic composition>
According to the same method as in Example 3, a hydraulic composition was formed as Comparative Example 3. However, in Comparative Example 3, Example 2 (powdered IPEC 1) was not added.

<Test Example 2: Strength test by freezing cement hydraulic composition>
A test piece was prepared as follows, and subjected to a strength test by freezing. In addition, in order to compare with the effect by freezing, the same sample was subjected to a strength test in an unfrozen state.
Example 3 (a composition in which powdered IPEC 1 was added to 10% with respect to water and having a water cement ratio of 40%) and Comparative Example 3 were separately placed in three circular molds. The driving was divided into three layers, packed 20 times with a stick, the surface was leveled with a metal iron, covered and put in a freezer (temperature: -18 ° C). After 2 days, the mold was removed. Curing was performed for 28 days in a curing room (temperature: about 20 ° C., humidity: about 80%) After completion of the curing, the compressive strength was measured using a universal testing machine.
In addition, as compared with the effect by freezing as described above, for Example 3 and Comparative Example 3, instead of storing for 2 days in the freezer, curing for 2 days in the curing room was used.
<< Test results and discussion >>
FIG. 4 shows the test result by freezing and the control test result by non-freezing regarding Example 3, and FIG. 3 shows the test result by freezing and the control test result by non-freezing method regarding Comparative Example 3. .
As can be seen from these figures, Comparative Example 3 shows a significant decrease in strength of 57.7% due to freezing (FIG. 3), while Example 3 shows only a 18.6% decrease in strength even after freezing. Not (Figure 4). Therefore, the hydraulic composition of the present invention exhibits long-term strength stability by freezing storage, and the frozen hydraulic composition of the present invention obtained by freezing such a hydraulic composition has strength even after long-term storage. The reduction was small and found to be useful.

<Example 4: Stucco hydraulic composition>
To each container containing 100 g of water, 1 g, 3 g and 10 g of Example 2 (powdered IPEC 1) were added to swell IPEC 1, and then 200 g of slaked lime was added to each container, and a mixer ( A hydraulic composition was produced by stirring with AM-20 manufactured by Aikosha Seisakusho. The addition rate of IPEC 1 is 0.5%, 0.15% and 5.0% based on slaked lime.

<Comparative Example 4: Additive-free stucco hydraulic composition>
According to the same method as in Example 4, a hydraulic composition was formed as Comparative Example 4. However, in Comparative Example 4, Example 2 (powdered IPEC 1) was not added.

<Test Example 3: Water absorption test of plaster hydraulic composition>
A test sample was prepared as follows and subjected to a water absorption test.
After each hydraulic composition formed in Example 4 and Comparative Example 4 was dried at 50 ° C. to have a constant weight, it was stored at 20 ° C. in a desiccator with water on the bottom, and the weight change thereof. Were examined daily for 6 days.
<< Test results and discussion >>
With respect to Example 4 and Comparative Example 4, the change over time in the substantial weight of the stucco hydraulic composition is shown in Table 1 below, and based on this table data, the change with respect to the measurement period is shown in FIG. The amount of water absorption (g) per gram of the stucco hydraulic composition after 6 days drying with respect to the addition rate (based on slaked lime) is shown in FIG.
As can be seen from FIG. 6, regarding the amount of water absorption, Comparative Example 4 absorbed only 0.011 g, whereas the 5% addition stucco composition of the present invention absorbed 0.035 g. The water-absorbing capacity of the plaster hydraulic composition of the present invention has increased about 3.5 times, and the usefulness of the present invention has been proved.

Claims (8)

Formula (I):

[In formula, R < ₁ > -R < ₃ > may be the same or different and is a C1-C3 alkyl group, and X is a halogen atom. ]
A cationic cellulose polymer having a repeating unit represented by formula (1) and a molecular weight of 10,000 to 100,000, and a formula (II):

[Wherein Y is hydrogen or an alkali metal atom. ]
A heterogeneous solution is obtained by mixing an anionic cellulose polymer having a repeating unit represented by the formula (1) and a molecular weight of 500,000 to 1,000,000 in an aqueous solvent under a pH condition in which both of these substances are dissociated. A polyion complex obtained as a precipitate by continuing mixing of the heterogeneous solution formed.   The polyion complex according to claim 1, wherein mixing of the obtained heterogeneous solution is continued while maintaining the pH at the same state.   A strength enhancing composition for a hydraulic composition, comprising the polyion complex according to claim 1.   A cement hydraulic composition comprising the strength enhancing composition according to claim 3.   The cement hydraulic composition according to claim 4, wherein the hydraulic composition is an underwater non-separable hydraulic composition.   A frozen hydraulic composition obtained by freezing the cement hydraulic composition according to claim 4.   A water absorption enhancing composition for a hydraulic composition comprising the polyion complex according to claim 1.   A stucco hydraulic composition comprising the water absorption enhancing composition according to claim 7.

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