JP2021155281A - Cold resistant inorganic anchor material and fixing method of anchor member using the anchor material - Google Patents

Abstract

To provide a cold resistant inorganic anchor material that can secure a proper usable life even an environment below a freezing point, has excellent workability with little sagging property, is excellent in adhesiveness with an anchor member and can suitably maintain the strength, and a fixing method of the anchor material using the anchor material.SOLUTION: A cold resistant inorganic anchoring material contains ultrafast hardening binder and nitrite, and contains 10 to 50 mass% of CA and 3 to 40 mass% of C2AS as an ultra fast hardening mineral in the ultrafast hardening binder, and C12A7 is not substantially contained, nitrite is contained in the range of 3 to 13 mass% relative to 100 pts.mass of the ultrafast hardening binder.SELECTED DRAWING: None

Description

The present invention relates to a cold-resistant inorganic anchor material and a method of fixing an anchor member using the anchor material, and a cold-resistant injection-type inorganic post-installed anchor material that can be effectively used even in an environment of low temperature, for example, below freezing point. The present invention relates to a method of fixing an anchor member using an anchor material.

Anchor bars are housed in holes formed at a predetermined depth from the surface of structures such as buildings and paved roads, and a filler is filled between the anchor bars and the holes to form the anchor bars. There is a known method of fixing to.
The anchor material to be injected into the hole provided in the concrete structure which is such a building / civil engineering structure can be roughly classified into an inorganic type and an organic type, and the construction form includes a capsule type and an injection type. be.

The inorganic anchor material contains cement as a main component, is kneaded with water, is filled between the pores and the anchor streaks, and then hardened to form a hardened layer. Then, when the hardened layer is combined with the structure and the anchor muscle and a force is applied to the anchor muscle in the direction of pulling out from the hole, the anchor muscle is maintained so as not to be pulled out by having high adhesion performance. Is desired.

For example, in building structures, it is generally used for installation of handrails, signs, etc., seismic reinforcement work such as breath construction method, and in civil engineering structures, it is generally used for bridge collapse prevention, installation of equipment in tunnels, fixing, etc. be.

Normally, when cement-based materials such as concrete and mortar are used below freezing in cold regions, the water used for kneading freezes, resulting in initial frost damage, and the durability and watertightness are significantly inferior. It is known.
Therefore, in winter construction, especially in a sub-zero environment, antifreeze agents such as nitrite, nitrate, urea, and ethylene glycol are added to lower the freezing point of the kneaded water to prevent freezing. ..
Inorganic anchor materials are also concerned that when they are below freezing point, they are damaged by initial frost and have a great influence on the adhesion performance with anchor muscles.

As an adhesion-retaining material for cement materials at low temperatures, Patent No. 5740909 (Patent Document 1) states that cement used in an environment with a temperature of 5 ° C. or lower as a base treatment material for repairing a concrete structure with a cement-based material. It is an adhesion-retaining material for materials, and is characterized by being an aqueous solution in which a substance selected from the group consisting of sodium nitrite, lithium nitrite, calcium nitrate, and calcium nitrite is dissolved at a solid content concentration of 5 to 50% by mass. The adhesion-retaining material for cement materials is described.

Further, in Japanese Patent Application Laid-Open No. 62-235239 (Patent Document 2), a cementy substance and an alkali metal nitrate, an alkaline earth metal nitrate, an alkali metal nitrite, and an alkaline earth metal nitrite selected from the group 1 a fixing composition of elements as a main component and seeds above, cementitious material was Portland cement, alumina cement, slag cement and Ca0-Al ₂ 0 ₃ based compounds in these cements were mixed Things are disclosed.
Further, Japanese Patent Application Laid-Open No. 2018-080092 (Patent Document 3) describes a hydraulic composition for cold regions that cures at a working temperature of up to 10 ° C. and / or an ambient temperature upon contact with water, and is Portland cement. , Alumina cement, a hydraulic component containing a quick-setting agent, a strength enhancer containing kaolin as a main component, a fluidizing agent, and a coagulation adjuster, and 20 to 40 parts by mass of the Portland cement. 30 to 50 parts by mass of alumina cement, 10 to 30 parts by mass of the quick-setting agent, 1 to 10 parts by mass of the kaolin, 0.1 to 1 part by mass of the coagulation adjuster, 0.1 part by mass of the fluidizing agent. A hydraulic composition having up to 1 part by mass is disclosed.

However, in the conventional inorganic anchor material, when the above antifreeze is used, the compressive strength can be improved, but the addition of the antifreeze deteriorates the fluidity and increases the shrinkage rate, so that the anchor material can be used. The desired construction performance (sagging property during upward construction) and mechanical properties (compressive strength and tensile strength) are reduced.

Therefore, a cold-resistant inorganic anchor material that can secure the pot life even in a sub-zero environment, has good construction performance with little sagging property, has excellent adhesion performance to an anchor member, and has sufficient compressive strength is desired. ing.

Japanese Patent No. 5740909 Japanese Unexamined Patent Publication No. 62-235239 JP-A-2018-080092

An object of the present invention is to solve the above problems, secure an appropriate pot life even in a sub-zero environment, have good construction performance with little sagging, and have excellent adhesion performance to anchor members such as anchor bars. It is an object of the present invention to provide an inorganic anchor material for cold resistance, particularly a post-installed anchor material, which can maintain good adhesion strength between the anchor material and a concrete structure.
Another object of the present invention is to provide a method for fixing an anchor member, which can easily and effectively fix the anchor member even in a cold environment by using the cold-resistant inorganic anchor material of the present invention. That is.

The present invention has been found to solve the above problems by including a specific cement and a specific antifreeze agent even under sub-zero conditions and specifying the content of the antifreeze agent, and has arrived at the present invention.

The cold-resistant inorganic anchor material according to claim 1 contains an ultrafast-hardening binder and a nitrite, and the ultrafast-hardening binder contains _{10 to 50% by mass of CA (CaO · Al 2} O ₃ ) as an ultrafast-hardening mineral and C2AS (C2AS). _{2CaO · Al 2 O 3 · SiO} 2) and contains 3 to 40 _{wt%, C12A7 (12CaO · 7Al 2} O 3) is not substantially contained, nitrite, 3 with respect to 100 parts by weight of ultra-fast curing binder It is a cold-resistant inorganic anchor material, which is contained in an amount of 13 parts by mass.

The cold-resistant inorganic anchor material according to claim 2 is the above-mentioned cold-resistant inorganic anchor material, wherein the nitrite is at least one selected from the group consisting of lithium nitrite, calcium nitrite and sodium nitrite. It is a characteristic cold-resistant inorganic anchor material.

The cold-resistant inorganic anchor material according to claim 3 has a compressive strength at −10 ° C. measured in accordance with JIS A 1108 “Concrete Compressive Strength Test” in any of the above cold-resistant inorganic anchor materials. 29.4 N / mm ² or more, and the adhesive strength of the anchor member at −10 ° C. is 10.9 N / mm ² or more as measured in accordance with JCAA's “Post-installed Anchor Test Method”. It is an inorganic anchor material for cold resistance.

The method for fixing the anchor member according to claim 4 is to enclose any of the above-mentioned cold-resistant inorganic anchor materials in a cartridge, attach the cartridge to an injection gun, and attach the cold-resistant inorganic anchor material to a concrete structure. It is a method of fixing an anchor member, which comprises filling a hole and hardening the anchor member to fix the anchor member.

The cold-resistant inorganic anchor material of the present invention has an appropriate pot life even in a sub-zero environment by combining an ultrafast-hardening binder and a nitrite, and has excellent workability such as sagging property. Can be effectively used, has high compressive strength, and can maintain excellent adhesion strength with the anchor member.
Further, the method for fixing the anchor member of the present invention can be efficiently and easily applied even in a cold environment without the inorganic anchor material filled in the holes of the concrete structure dripping.
In particular, by using an injection container such as an anchor cartridge, it is possible to perform the stirring and mixing work and the filling work of the cold-resistant inorganic anchor material in the same container, and the generation of dust during the stirring and mixing work is almost zero. It is suppressed, and it becomes possible to easily perform filling in the hole, particularly upward filling.

It is the schematic of the flow test for evaluating the sagging property of an inorganic anchor material. It is a schematic diagram of the tensile strength test for evaluating the adhesion performance between an inorganic anchor material and an anchor member.

The present invention will be described in the following form, but the present invention is not limited thereto.
The cold-resistant inorganic anchor material of the present invention contains an ultrafast-hardening binder and a nitrite, and the ultrafast-hardening binder contains 10 to 50% by mass of CA as an ultrafast-hardening mineral, 3 to 40% by mass of C2AS, and C12A7. Nitrite is a cold-resistant inorganic anchor material that is substantially free and is contained in an amount of 3 to 13 parts by mass with respect to 100 parts by mass of the ultrafast-hardening binder.

Usually, CA, C2AS and C12A7 correspond to the ultrafast-hardening mineral, but in the present invention, CA and C2AS are contained in the ultrafast-hardening binder, and C12A7 is substantially not contained. The contents of CA and C2AS contained in the ultrafast-hardening binder are 10 to 50% by mass for CA and 3 to 40% by mass for C2AS.
By containing CA and C2AS in such a range and substantially not containing C12A7, the above-mentioned effect of the present invention can be effectively exhibited.
Here, the fact that C12A7 is substantially not contained means that even if it is contained, it is less than 1% by mass, and is preferably 0%.
If C12A7 is contained in an amount of 1% by mass or more, an appropriate pot life cannot be secured, and workability may not be sufficient, which is not desirable.

Further, the ultrafast-hardening binder contains 10 to 50% by mass of CA and 3 to 40% by mass of C2AS. If it deviates from such a content range, the adhesiveness to the concrete structure in the environment below the freezing point is inferior, the appropriate pot life cannot be obtained, and the workability is inferior.

As such an ultrafast-hardening binder, if an ultrafast-hardening binder containing 10 to 50% by mass of CA and 3 to 40% by mass of C2AS and substantially not containing C12A7 can be obtained, ultrafast-hardening cement is contained as the ultrafast-hardening binder. You can also do it.

Anchor materials using conventional Portland cement as an example have a long setting time, and especially when filling sideways or upward holes, the anchor material may hang down from the holes or shift to the next process over time. Although the time has been long, in the present invention, such a problem does not occur because an appropriate pot life is secured even in a sub-zero environment and the sagging property is excellent.

Further, the cold-resistant inorganic anchor material of the present invention contains nitrite as an essential component in combination with the ultrafast-hardening binder.
The nitrite used in the cold-resistant inorganic anchor material of the present invention is not particularly limited and may contain any nitrite, but is preferably from the group consisting of lithium nitrite, calcium nitrite and sodium nitrite. It is desirable to use at least one selected nitrite in order to more effectively exhibit the above-mentioned effects of the present invention.
The particle size of the nitrite is not particularly limited, and the blending amount thereof is 3 to 13 parts by mass, preferably 3.5 to 12.5 parts by mass with respect to 100 parts by mass of the ultrafast-hardening binder.
By using the ultrafast-hardening binder and the nitrite in combination within such a range, it is possible to have excellent workability even in an environment below freezing point, and to maintain good compressive strength and adhesion (tensile) strength.
It is desirable that the nitrite is previously mixed and dissolved in kneading water.

Conventionally, urea, ethylene glycol, calcium nitrate and the like have been used as the antifreeze agent, but in the present invention, these antifreeze agents are not included.

The cold-resistant inorganic anchor material of the present invention contains an aggregate, but the aggregate is not particularly limited, and a general fine aggregate used for concrete or mortar can be preferably used.
Examples of the fine aggregate include natural fine aggregates such as river sand, sea sand, mountain sand, and crushed sand, recycled fine aggregates, and artificial fine aggregates.
The blending ratio of the fine aggregate is not particularly limited and can be arbitrarily blended according to the desired requirements in the field, but preferably, it is preferably 30 to 30 parts by mass with respect to 100 parts by mass of the ultrafast-hardening binder. It is preferably 200 parts by mass, more preferably 40 to 100 parts by mass, and the maximum size of the fine aggregate is 1.2 mm.

Further, water is blended to obtain the cold-resistant inorganic anchor material of the present invention. Water is preferably 30 to 50, more preferably 35 to 45 in terms of water / ultrafast-hardening binder mass ratio. If it is less than 30, the binder powder and water become non-uniform and it becomes difficult to discharge from the nozzle, and if it exceeds 50, the filled material flows out from the pores, and the sagging property and the adhesion strength are lowered, which is not preferable.

For the cold-resistant inorganic anchor material of the present invention, if necessary, known admixtures and additives such as water reducing agents, retarding agents, polymers, rust preventives, coagulation retarding agents, etc. are used to impair the effects of the present invention. It can be added in a range that does not exist.

The cold-resistant inorganic anchor material of the present invention can also be produced by preliminarily blending an ultrafast-hardening binder and a powder such as nitrite, and then blending fine aggregate and water and kneading them uniformly. It is also possible to preferably manufacture by dissolving nitrite in kneading water in advance, blending an ultrafast-hardening binder, an aqueous solution of nitrite, and each material such as aggregate on site, and kneading them using an arbitrary mixer. The method is not limited as long as a uniform material can be prepared.

The cold-resistant inorganic anchor material of the present invention is used, for example, for fixing an anchor member to an existing concrete structure in a sub-zero environment.
Specifically, a concrete structure is perforated from the surface, the hole is filled with the cold-resistant inorganic anchor material of the present invention, an anchor streak is inserted, and the cold-resistant inorganic anchor material is cured to anchor. Fix the member.
The method for filling the holes with the cold-resistant inorganic anchor material is not particularly limited, and a known method can be applied. However, for ease of construction, for example, the cartridge is filled with the anchor material, and the cartridge is filled. A method of mounting the anchor material on a discharger called an injection gun and injecting the anchor material into the hole to cure the anchor material can be preferably used.
In addition, since the cold-resistant inorganic anchor material of the present invention is used as the anchor material, an appropriate pot life is maintained even in a sub-zero environment, and the injected anchor material does not drip and is quickly anchored. The member can be fixed.

Any known cartridge or injection gun can be used, and for example, a sealing gun or a caulking gun can be used as a cartridge gun for mounting a cartridge.

As described in the following test example, the cold-resistant inorganic anchor material of the present invention has a sagging property measured according to JASS15 M103 (quality standard test of self-leveling material) at a temperature below freezing point, for example, -10 ° C. The flow test value is 70 mm or less, the pot life is also appropriate as 31 to 80 minutes measured by the method of the following test example, and the compressive strength measured according to JIS A 1108 "Concrete compressive strength test" is is at 29.4N / mm ² or more, and it is possible that the tensile strength of the anchor muscle was measured according to "post-installed anchor test method" of JCAA is to 10.9N / mm ² or more.
The method for fixing an anchor member of the present invention has an appropriate pot life even in a sub-zero environment, has excellent workability without material sagging, exhibits strength without being subjected to initial frost damage, and adheres to the anchor member. Performance can be significantly improved.

The present invention will be described with reference to the following examples, comparative examples and test examples.
(1) Raw materials In preparing the inorganic anchor material, the following raw materials were used.
・ Ultra-fast-hardening binder: Those having the ultra-fast-hardening mineral composition shown in Tables 1 and 2. ・ Ordinary Portland cement: manufactured by Sumitomo Osaka Cement Co., Ltd. ・ Early-strength Portland cement: manufactured by Sumitomo Osaka Cement Co., Ltd. ・ Antifreeze: nitrite Lithium (manufactured by Nissan Chemical Industry Co., Ltd.)
Potassium nitrite (manufactured by Kanto Chemical Co., Inc.)
Sodium nitrite (manufactured by Kanto Chemical Co., Inc.)
Urea: (manufactured by Kanto Chemical Co., Inc.)
Calcium nitrate: (manufactured by Kanto Chemical Co., Inc.)
-Fine aggregate (B): No. 6 sand-Kneading water (W): Tap water-Thickening agent: Methyl cellulose-based thickener (2% aqueous solution, viscosity: 4000 mPa · s) Himetro's 90: (Shin-Etsu Chemical Co., Ltd.) ) Made)

(2) Examples 1 to 15 and Comparative Examples 1 to 16
Using each of the above raw materials, each raw material was blended at the blending ratios shown in Tables 1 and 2, and each inorganic anchor material was prepared.
Specifically, each aqueous solution was prepared by dissolving each of the above antifreeze agents in kneaded water in advance.
The ultrafast-hardening binder shown in Tables 1 and 2, the aggregate, the thickener, and each of the prepared aqueous solutions are kneaded at the blending ratios shown in Tables 1 and 2 to prepare each inorganic anchor material. bottom.

(3) Test example The following tests were carried out under cold temperatures of -10 ° C, -5 ° C, and 0 ° C.
(Test Example 1) Workability / Dripping property Using each inorganic anchor material immediately after kneading obtained in each of the above Examples and Comparative Examples, according to JASS15 M103 “Quality standard test of self-leveling material”, FIG. It was evaluated by a φ50 mm × h51 mm flow test as shown in.
The results are shown in Tables 1 and 2.
The evaluation was based on the following evaluation criteria.
〇: 70 mm or less Δ: 71-75 mm
×: 76 mm or more

(Test Example 2) Workability / Potability Time A commercially available cartridge resin injector for a sealing gun (330 ml type:) using each inorganic anchor material immediately after kneading obtained in each of the above Examples and Comparative Examples. It was filled in ADY Co., Ltd., and an injection nozzle (φ12 mm) was attached to the cartridge, and the discharge possible time from the injector was evaluated.
The results are shown in Tables 1 and 2.
The evaluation was based on the following evaluation criteria.・
〇: 30-80 minutes (appropriate)
Δ: 20 minutes to less than 30 minutes ×: Less than 20 minutes or more than 80 minutes

(Test Example 3) Mechanical Strength / Compressive Strength A compressive strength test was carried out in accordance with JIS A 1108 “Concrete Compressive Strength Test”.
Specifically, each inorganic anchor material was molded into φ50 × 100 mm, cured at each of the above temperatures, and the compressive strength at the age of 28 days was measured.
The results are shown in Tables 1 and 2.
The evaluation was based on the following evaluation criteria.
〇: 29.4N / mm ² or more ×: 29.4N / mm less than ²

(Test Example 4) Mechanical strength / tensile strength (adhesion with anchor muscle)
A hole of φ16 mm is formed in the concrete placed in the steel pipe, each inorganic anchor material is injected, and all screw bolts M12 (material SNB7) are fixed, and according to JCAA's "Post-installed anchor test", A tensile (adhesion) strength test was carried out.
The conditions such as anchor muscles in the adhesion test are as follows.
・ Anchor muscle: M12
・ Type: SNB7
-Embedding length: 84 mm (7 da)
・ Anchor muscle diameter: 12 mm
・ Drilling diameter: φ16 mm
・ Base concrete: Steel pipe driven concrete (σB = 25N / mm ² )

Specifically, using a test device as shown in FIG. 2, the inorganic anchor materials obtained in the above Examples and Comparative Examples were injected into a hole having a diameter of 16 mm and fixed with the full screw bolt M12. Was placed in a constant temperature bath at each of the above temperatures for 28 days, and then a tensile strength test was carried out.
The maximum load A when the full-thread bolt M12, which is the anchor bar, was pulled out from the hole was measured.
Next, the tensile (adhesion) strength C was calculated from the maximum load A and the adhesion area B.
The adhesion area B and the tensile (adhesion) strength C were calculated by the following formulas (1) and (2).
Adhesion area B = Anchor muscle diameter D x π x anchoring length (embedding depth) L ... (1)
Tensile strength C = maximum load A / adhesion area B ... (2)
The results are shown in Tables 1 and 2.
In addition, the evaluation was made according to the following evaluation criteria.
〇: 10.9N / mm ² or more ×: 10.9N / mm Less than ²

(comprehensive evaluation)
Among the evaluations of Test Examples 1 to 4, those with all evaluations of 〇 are evaluated as overall evaluation 〇, those with at least one evaluation of × are evaluated as overall evaluation ×, and there is no evaluation of ×, but evaluation of △ is one. As for the other evaluation results, those with ◯ are designated as comprehensive evaluation Δ, and the results of the comprehensive evaluation are also shown in Tables 1 and 2.

From Tables 1 and 2 above, the inorganic anchor material of the embodiment of the present invention has good sagging property even in a sub-zero environment, has an appropriate pot life, and maintains good tensile strength and the like of the anchor muscle. It turns out that it is possible.
On the other hand, in Comparative Examples 1 to 5 in which the composition of the ultrafast-hardening mineral in the ultrafast-hardening binder contained in the inorganic anchor material is outside the scope of the present invention, is it possible to have an appropriate pot life in a sub-zero environment? It is clear that the mechanical strength is not sufficient.

Further, Comparative Examples 6 to 7 in which the content ratio of the nitrite is outside the range of the present invention, 8 to 13 containing an antifreeze agent other than the nitrite of the present invention, Comparative Example 14 not containing the antifreeze agent, and the ultrafast-hardening binder of the present invention. It is clear that the anchor materials of Comparative Examples 15 to 16 not containing the above-mentioned materials have poor workability or insufficient mechanical strength in a sub-freezing environment.

The cold-resistant inorganic anchor material of the present invention can firmly attach an anchor member such as an anchor bar to a hole provided in a concrete structure in the field of construction / civil engineering in a cold place, and has an appropriate pot life. Therefore, the work efficiency of construction is high, and it can be effectively applied to structures especially in cold regions.

Claims (4)

It contains an ultrafast-hardening binder and nitrite, and the ultrafast-hardening binder contains 10 to 50% by mass of CA as an ultrafast-hardening mineral and 3 to 40% by mass of C2AS, substantially free of C12A7, and nitrite. An inorganic anchor material for cold resistance, which is contained in an amount of 3 to 13 parts by mass with respect to 100 parts by mass of an ultrafast-hardening binder. In the cold-resistant inorganic anchor material according to claim 1, the nitrite is at least one selected from the group consisting of lithium nitrite, calcium nitrite and sodium nitrite. material. In the cold-resistant inorganic anchor material according to claim 1 or 2, the compressive strength at −10 ° C. is 29.4 N / mm ² or more as measured in accordance with the “concrete compressive strength test” of JIS A 1108. An inorganic anchor material for cold resistance, characterized in that the adhesive strength of the anchor member at 10 ° C. is 10.9 N / mm ^{2 or more as measured in accordance with JCAA's "Post-Concrete Anchor Test Method".} The cold-resistant inorganic anchor material according to any one of claims 1 to 3 is encapsulated in a cartridge, the cartridge is attached to an injection gun, and the cold-resistant inorganic anchor material is filled in a hole of a concrete structure. A method for fixing an anchor member, which comprises curing and fixing the anchor member.

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