JP2006273700A - Flowability improving method of super-quick hardening concrete and flowability improving agent for super-quick hardening concrete - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a flowability improving method of super-quick hardening concrete which has strength developability in a short time in the super-quick hardening concrete, has high flowability at the time of construction, even more than that at the time of construction under a high temperature atmosphere, and can assure an excellent construction property, and a flowability improving agent for the super-quick hardening concrete. <P>SOLUTION: A setting retarder and sodium gluconate are blended with the super-quick hardening concrete to improve the flowability of the super-quick hardening concrete. The blending comprises adding 8 to 38 parts by mass sodium gluconate to 100 parts by mass setting retarder. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a fluidity improving method for ultrafast hard concrete and a fluidity improving agent for ultrafast concrete, and more particularly, a fluidity improving method for ultrafast concrete in a high temperature atmosphere in which a setting retarder is added and the fluidity improving method. The present invention relates to a fluidity improver for ultra-high-speed hard concrete used in the field.

Conventionally, super-hard hard concrete can be developed in a short time, and thus has been used for various purposes such as repairs such as road works.
Specifically, for example, many of the ultrafast cement used for ultrafast concrete is designed to develop the required strength after 3 hours even when the outside air temperature is about 5 ° C. Below, its strength develops in a shorter time.
As described above, since the conventional ultra-high-speed hard concrete has a short setting time, usually, an appropriate amount of various setting retarders is added. By adding an amount suitable for the outside air temperature and the material temperature, a wide temperature range can be obtained. It is used by adjusting the setting time of super-hard hard concrete so that it can be used in.
Here, normal concrete manufactured in a raw concrete plant or the like is a concrete having a predetermined slump by adjusting the admixture addition rate in response to a change in temperature in the season.
In addition, because a large amount of concrete is shipped at a stationary plant, it is possible to immediately ship concrete with a predetermined slump by adjusting the admixture addition rate by making use of experience, etc. for temperature changes during the day. It is said.

However, as described above, ultra-high speed hard concrete uses ultra-high speed hard cement that is designed based on the premise that an amount of setting retarder is added according to the ambient temperature, so if the setting rate of setting retarder is changed In particular, when the addition rate is increased at high temperatures, the increase in the viscosity of the concrete becomes remarkable.
In order to increase the fluidity of the ultrafast cement composition, there is a method of adding a fluidizing agent such as naphthalene sulfonic acid, triazine, or lignin, but even if these fluidizing agents are used in ultrafast concrete, Compared with the case where it is added to ordinary ordinary Portland cement, the fluidizing action is small and the expected fluidity cannot be obtained.

That is, the slump value of the ultra-high-speed hard concrete fluctuates depending on the addition rate of the retarder added to obtain the pot life corresponding to the temperature change in addition to the fluctuation of the slump value due to the temperature change.
It is very difficult and troublesome to adjust this by the admixture addition rate such as a high-performance water reducing agent and ship it as concrete having a predetermined slump value.

  Furthermore, in the ultra-fast hard concrete to which the setting retarder is added, for example, at a relatively high atmospheric temperature exceeding 25 ° C., it becomes difficult to ensure fluidity, as in the case of concrete using Portland cement, etc. There exists a problem that the addition amount of the setting retarder for ensuring the usable time of super-hard-hardened concrete will increase.

Here, the addition of a setting retarder increases the viscosity of the super fast hard concrete, but if the operating ambient temperature is from low temperature to normal temperature, the addition of the setting retarder necessary to obtain the specified usable time The amount does not have to be large, and the increase in viscosity is not so great.
However, in the case of a high-temperature atmosphere in which the use atmosphere temperature exceeds 25 ° C., the increase in viscosity due to the increase in the addition rate of the setting retarder becomes large, resulting in a problem that the workability is impaired.

Super-hard hard concrete is generally manufactured in a mobile plant.
Mobile plants are affected by vibrations during movement, so they are configured with the simplest system possible. Emergency construction (predicting ambient temperature in advance is difficult) and night construction (atmospheric temperature changes during construction are significant) Therefore, it may be difficult to adjust the admixture addition rate such as a high-performance water reducing agent in accordance with the change in the ambient temperature each time.
In such a case, the method of adjusting the slump by adjusting the amount of kneaded water is also used, but this will change the mix of the concrete and may affect the physical properties of the hardened concrete. Unfavorable

  In view of such problems, JP-A-10-7446 discloses a polyoxyalkylene compound having a specific structure, a copolymer containing maleic anhydride as an essential component, and a water reducing agent containing the copolymer and the like. It is described that an additive combining a retarder containing oxycarboxylic acid, phosphonic acid and derivatives thereof is added to cement to improve fluidity.

  Japanese Patent Application Laid-Open No. 6-183812 discloses ultra-high speed cement, 0.2 to 1.00% by weight of a high-performance water reducing agent, 0.20 to 1.20% by weight of a lignin retarder and an oxycarboxylic acid retarder. A high-flowing ultrafast cement composition containing 0.01 to 0.30% by weight of an agent is disclosed.

However, even in these cement compositions, for example, at a relatively high atmospheric temperature exceeding 25 ° C., the amount of additive such as a setting modifier increases, and the expected fluidity is achieved. It may be difficult to obtain.
Therefore, it has both high fluidity and quick hardening, and is insufficient to realize highly efficient workability.
Japanese Patent Laid-Open No. 10-7446 JP-A-6-183812

The object of the present invention is to solve the above-mentioned problems, and has high fluidity even during construction, particularly in a high-temperature atmosphere, while exhibiting strength development in a short time in super-hard hard concrete. Another object of the present invention is to provide a method for improving the fluidity of super fast hard concrete, which can ensure excellent workability.
Another object of the present invention is to improve the fluidity of super-hard cemented concrete, which can obtain almost the same fresh properties that are sufficiently excellent in workability from a low temperature atmosphere to a high temperature atmosphere, that is, almost the same fluidity. Is to provide a method.
Another object of the present invention is to provide a method for improving the fluidity of super fast hard concrete according to the present invention, which is useful for imparting high fluidity even in a wide temperature range, particularly in a high temperature atmosphere. It is to provide an improving agent.

  According to the present invention, by adding sodium gluconate at a constant rate according to the rate of increase in the setting rate of the setting modifier added to the ultra-high speed hard concrete, almost the same fresh properties from a low temperature atmosphere to a high temperature atmosphere, that is, construction It has been achieved by finding that a sufficiently high fluidity can be obtained.

In the method for improving fluidity of super fast hard concrete according to the present invention, a setting retarder and sodium gluconate are blended with super fast hard concrete, and the blend is 8 to 38 parts by weight of sodium gluconate with respect to 100 parts by weight of the set retarder. It is characterized by being added.
Preferably, in the method for improving fluidity of super-hard hard concrete according to the present invention, 0.05 to 1.5% by mass of a setting retarder is added to the super-fast hard cement contained in the super-hard hard concrete. More preferably, in the method for improving the flowability of super fast hard concrete according to the present invention, the setting retarder is citric acid and / or sodium citrate.

Moreover, the fluidity improver for super-hard hard concrete of the present invention is a combination of a setting retarder and sodium gluconate, and is formed by blending 8-38 parts by mass of sodium gluconate with 100 parts by mass of the setting retarder. It is characterized by this.
Preferably, in the fluidity improver for ultra-high speed hard concrete of the present invention, the setting modifier is:
Citric acid and / or sodium citrate.

The method for improving the fluidity of super fast hard concrete according to the present invention ensures a substantially constant high fluidity without depending on the ambient temperature even when the environmental temperature changes when placing super fast hard concrete. It becomes possible to supply concrete having a predetermined slump value.
Therefore, at the time of casting using ultra-high speed hard concrete, it is excellent in workability, and thereafter, strength can be expressed in a short time.
In addition, the super fast hard concrete fluidity improving agent of the present invention can be effectively used in the fluidity improving method of the super fast hard concrete of the present invention, and the unit water amount can be reduced even in a high temperature atmosphere of 25 ° C. or higher. The fluidity is ensured without increasing, and the slump loss is reduced. Therefore, a substantially constant high fluidity can be imparted to the super-hard cemented concrete at a wide range of atmospheric temperatures.

The present invention is illustrated by the following preferred examples, but is not limited thereto.
In the method for improving the fluidity of super fast hard concrete of the present invention, a setting retarder and sodium gluconate are blended with super fast hard concrete.
In this way, by adding sodium gluconate at a constant rate according to the increasing rate of the setting retarder added to the ultra-high speed hard concrete, almost the same fresh properties from a low temperature atmosphere to a high temperature atmosphere are obtained. It can be granted.

Such blending is a ratio of 8 to 38 parts by mass of sodium gluconate with respect to 100 parts by mass of the setting retarder.
When this amount is less than 8 parts by mass, the slump at the time of kneading becomes smaller as the atmosphere becomes higher, and exceeds the allowable range of the slump (± 2.5 cm).
On the other hand, if it exceeds 38 parts by mass, the effect of sodium gluconate becomes too great, and conversely, the slump at the time of kneading at a high temperature becomes large.
Preferably, sodium gluconate is preferably 15 to 33 parts by mass with respect to 100 parts by mass of the setting retarder.

As the setting retarder used in the method for improving the fluidity of the ultrafast hard concrete of the present invention, any material can be used as long as the required usable time can be secured without losing the fastness of the ultrafast concrete. Examples thereof include citric acid, tartaric acid, malic acid, boric acid, heptonic acid, and salts thereof.
These setting retarders may be used alone or in combination of two or more.

The setting retarder is added in an amount of 0.05 to 1.5% by mass with respect to the ultrafast cement contained in the ultrafast cement.
The setting modifier is premised on adjusting the amount of addition according to the ambient temperature due to the properties of ultrafast hard concrete.

The super fast hard concrete that can be used in the fluidity improving method of the present invention can be obtained by blending a known hydraulic super fast hard cement with fine aggregate, coarse aggregate and water.
For example, some super-hard setting cements are mainly composed of 11CaO · 7Al ₂ O ₃ · CaX ₂ (where X represents a halogen element). In the combination with the setting retarder and sodium gluconate, the effect of the present invention can be expressed more satisfactorily.

Further, such ultrarapid hardening cement, the _{SO 3} / _Al 2 _O 3 (molar ratio) is 0.6 to 1.3, preferably preferably from 0.9 to 1.25, this _SO 3 / Al _{When the 2} O ₃ (molar ratio) is within the above range, the initial strength development, particularly the strength development after 3 hours after kneading, will be excellent.

Moreover, as a fine aggregate, if it is a fine aggregate used for concrete, it can be used.
Furthermore, as the coarse aggregate, any coarse aggregate used for concrete can be used.

  In addition, for ultra-high speed hard concrete, other additives such as AE agent, antifoaming agent, drying shrinkage reducing agent, rust preventive agent, foaming agent, expansion agent, etc., and to improve material separation resistance These thickeners and reinforcing agents such as carbon fibers and steel fibers can be used within a range that does not substantially impair the object of the present invention.

  In addition, the order of adding the setting retarder and sodium gluconate to the ultra-high speed hard concrete of the present invention is not particularly limited as long as it is uniformly mixed, and the fluidity improver in which the setting retarder and sodium gluconate are mixed in advance. The fluidity improver is mixed with ultrafast hard concrete, the fluidity improver prepared in advance in the process of producing ultrafast concrete is added, or the setting retarder and sodium gluconate May be added to the ultrafast hard concrete, or a setting retarder and sodium gluconate may be added in the process of producing the ultrafast hard concrete.

Thus, there are no limitations on the mixing conditions, the type of mixer, etc., and the respective materials may be mixed and used at the time of construction, or some or all of them may be mixed in advance.
As the mixing device, any existing device can be used. For example, a known type of mixer such as a pan-type forced mixer, a biaxial forced kneading mixer, an omni mixer, a Henschel mixer, a night mixer, a tilting mixer, or a continuous kneading mixer may be used. it can.
In general, the mixing ratio of water to the cement during kneading can be changed depending on the type and mixing of the materials used, so it is not uniquely determined, but the water / cement (W / C) ratio. 30 to 45 mass% is preferable from the viewpoint of short-term strength development.

The present invention will be illustrated by the following examples and comparative examples, but is not limited thereto.
Materials used The materials shown in Table 1 below were used in Examples and Comparative Examples.

Examples 1-4, Comparative Examples 1-2
In Examples 1 to 4 and Comparative Examples 1 and 2, using the ultrafast cement, fine aggregate, coarse aggregate, steel fiber, water reducing agent and water materials shown in Table 1, the blending ratio shown in Table 2 Each material was blended and kneaded to prepare super fast hard concrete.

表２中、Ｓ／ａは細骨材率を示し、具体的には、コンクリート中の全骨材量に対する細骨材の絶対容積比を百分率で表した値である。

In Table 2, S / a indicates the fine aggregate ratio, and specifically is a value representing the absolute volume ratio of the fine aggregate with respect to the total aggregate amount in the concrete as a percentage.

Next, the fluidity improvers for super-high-speed hard concrete were prepared at the blending ratios shown in Table 3, respectively, and the fluidity improvers for super-high-speed hard concrete were added to and mixed with the prepared ultra-fast hard concrete.
The amount of the fluidity improver for each ultra-high-speed hard concrete added to the ultra-high-speed hard concrete is constant for each ambient temperature in each of Examples 1 to 4 and Comparative Examples 1 and 2, and the setting retarder addition rate is shown in Table 4. Shown in
In addition, the addition rate of the setting retarding agent shown in Table 4 was adjusted so that the work usable time would be about 45 minutes when each of the above-mentioned flow improvers for super fast hard concrete was added to super fast hard concrete. It is a ratio.

Table 5 shows the results of measuring the slump value at each ambient temperature shown in Table 4 of the ultrafast hard concrete obtained by adding the super fast hard concrete fluidity improver shown in Table 3 at each addition rate shown in Table 4. Show.
The slump value is a value measured by “JIS A 1101 Concrete Slump Test Method”.

但し、表５中のスランプ差は、（３５℃におけるスランプ値）−（２０℃におけるスランプ値）の差を示したものである。

However, the slump difference in Table 5 indicates a difference of (slump value at 35 ° C.) − (Slump value at 20 ° C.).

Examples 5-8, Comparative Examples 3-4
The amount of addition of the flow improver for super fast hard concrete shown in Table 3 to the super fast hard concrete is shown as a setting retarder addition rate in Examples 5 to 8 and Comparative Examples 3 to 4 with each atmosphere temperature constant. Prepared in the same manner as in Example 1 except for showing in 6.
However, the addition rate of the setting retarding agent shown in Table 6 was adjusted so that the workable time was about 60 minutes when each of the above-mentioned flow improvers for super high-speed hard concrete was added to super high-speed hard concrete. It is a ratio.

Table 7 shows the results of measuring the slump value at each ambient temperature shown in Table 6 above for the ultra-fast hard concrete obtained by adding the super fast hard concrete fluidity improver shown in Table 3 at each addition rate shown in Table 6. Show.
The slump value is a value measured by the same method as in Example 1 above.

但し、表７中のスランプ差は、（３５℃におけるスランプ値）−（２０℃におけるスランプ値）の差を示したものである。

However, the slump difference in Table 7 indicates a difference of (slump value at 35 ° C.) − (Slump value at 20 ° C.).

From the above Tables 5 and 7, it can be seen that in Comparative Example 1 in which sodium gluconate was not added, the slump value decreased as the ambient temperature increased, and the fluidity was not improved.
On the other hand, in Comparative Example 2 in which the blending amount of sodium gluconate is large, the addition rate of sodium gluconate is excessive at high temperatures, so that the slump value is excessively increased in the high temperature region, contrary to Comparative Example 1.
On the other hand, in Examples 1-4 and Examples 5-8, the slump difference is within 2.5 cm, which satisfies the allowable range of the slump value (± 2.5 cm in the case of 8 cm). This indicates that substantially constant fluidity is ensured even when the use atmosphere temperature changes.

The method for improving the fluidity of super fast hard concrete according to the present invention can be effectively applied when the environmental temperature is high, such as in the summer season, and is appropriately used for emergency works in the civil engineering and construction fields.
The fluidity improver for super-fast hard concrete of the present invention is expected to be added to super-fast hard concrete to ensure fluidity, but is not limited to concrete, and is also applied to cement paste and mortar having fast-hardness. It is something that can be done.

Claims (5)

Super fast-hardened concrete is characterized in that a setting retarder and sodium gluconate are blended with ultrafast concrete, and the blend is obtained by adding 8 to 38 parts by weight of sodium gluconate to 100 parts by weight of the set retarder. Fluidity improvement method. In the ultrafast hard concrete fluidity improving method according to claim 1, 0.05 to 1.5 mass% of a setting retarder is added to the ultrafast hard cement contained in the ultrafast hard concrete. Super fast hard concrete fluidity improvement method. 3. The method for improving flow properties of super-hard hard concrete according to claim 1 or 2, wherein the setting retarder is citric acid and / or sodium citrate. A fluidity improver for super-hard-hard concrete, comprising a combination of a setting retarder and sodium gluconate, wherein 8 to 38 parts by mass of sodium gluconate is blended with 100 parts by mass of the setting retarder. 5. The fluidity improver for ultrafast hard concrete according to claim 4, wherein the setting adjuster is citric acid and / or sodium citrate.