JP6802568B2 - Concrete inducer, concrete placement method, and method of determining suitability for use of concrete inducer - Google Patents

Description

The present invention relates to a concrete inducer, a method for placing concrete, and a method for determining the suitability of using a concrete inducer.

When placing ready-mixed concrete at a civil engineering or construction site, ready-mixed concrete (hereinafter, may be abbreviated as "ready-mixed concrete") is a concrete pump truck from an agitator vehicle (also called a mixer truck, ready-mixed concrete truck, truck mixer, etc.). It is put into the hopper of the concrete truck and pumped to the place where it is placed through a pipe such as a rubber hose or a steel pipe. At that time, if only the ready-mixed concrete is pumped, the cement content contained in the ready-mixed pipe slows down due to the friction on the pipe surface or remains on the pipe surface, and as a result, the aggregate (gravel, etc.) is contained in the ready-mixed pipe. Increases the proportion of gravel and tends to cause obstruction in the pipe. This is brought about by arching, i.e. arched locks caused by collisions and friction between aggregates in the pipe.

Conventionally, in order to prevent pipe blockage during pumping of ready-mixed concrete, first, a leading material called a leading mortar or a leading mortar is put into the pump car into the hopper of the concrete pump car, and then the ready-mixed concrete is put into the hopper of the concrete pump car. It is common to pump the leading mortar in front of the ready-mixed concrete by feeding it. For example, Patent Document 1 describes a method of pumping a postponed mortar.

Japanese Unexamined Patent Publication No. 8-1643

The preceding mortar is used in an amount of about 0.5 to ² m ³ . This amount is small compared to the loading capacity of a normal agitator vehicle. On the other hand, since the preceding mortar cannot guarantee the strength required for the ready-made mortar to be placed (contrary to the JIS standard), it is not allowed to place the preceding mortar together with the ready-made mortar. From these things, the following problems arise.

The ready-mixed mortar company needs to arrange the preceding mortar separately from the ready-made mortar, but the amount is small compared to the loading capacity of the normal agitator car, so the operating rate of the agitator car is poor. Delivery of leading mortar results in a deficit because leading mortar is cheaper than ready-made mortar. These things can induce mixed delivery, that is, loading and delivering the preceding mortar in the same agitator vehicle as the ready-mixed mortar. As described above, mixed delivery produces ready-mixed mortar mixed with preceding mortar, and if such ready-mixed mortar is placed, results outside the JIS standard will occur. In this way, mixed delivery is essentially unacceptable.

Since the amount of the preceding mortar used, which is about 0.5 to ² m ³ , is too large for the preceding mortar to be piped, the preceding mortar is usually charged in the hopper. Since the ready-made mortar is also put into the hopper, the preceding mortar and the ready-made mortar are inevitably easy to mix. As mentioned above, ready-mixed mortar mixed with preceding mortar cannot be placed, so it must be treated as industrial waste. Although the amount of leading mortar used is small compared to the loading capacity of agitator vehicles, it is by no means small in absolute quantity, and therefore the industrial waste generated when such amount of leading mortar is used. The amount tends to be large.

Although pre-used mortar and ready-mixed mortar mixed with pre-mortar are treated as industrial waste, they cannot be disposed of on-site, so it is unavoidable that there is a cost disadvantage and a risk of compliance risk.

The present invention has been made in view of the above problems, and is a concrete inducer capable of preventing pipe blockage with a smaller amount than that of the preceding mortar, a concrete placing method using the same, and determination of suitability for use thereof. The purpose is to provide a method.

The present inventors have found that the above problems can be solved by using a specific granular material in combination with at least one of a fiber and a fiber structure, and have completed the present invention.

(1) A concrete inducer containing granules and at least one of fibers and fiber structures.
The granular material is a concrete inducer containing at least one of ready-mixed concrete sludge and its processed product, blast furnace slag fine powder, fly ash, and silica fume.

(2) A concrete inducer containing granules and at least one of fibers and fiber structures.
The granular material is a concrete inducer containing fine particles having an average particle diameter of 0.1 μm to 1 mm and a brain specific surface area of 1500 cm ² / g or more.

(3) The fibrous material according to (1) or (2), wherein at least one of the fiber and the fiber structure has a liquid absorbing property and a liquid retaining property and exhibits a liquid-removing property when pressurized. Concrete inducer.

(4) The concrete inducer according to (1) or (2), wherein at least one of the fiber and the fiber structure contains a cellulosic fiber or a plant-derived fiber.

(5) (i) The water-cement ratio is less than 41 unit mass (kg / m ³ )%.
(Ii) The water-concrete ratio is 41 unit mass (kg / m ³ )% or more and less than 60 unit mass (kg / m ³ )%, and the fluidity is represented by a slump value, or (iii) water-concrete ratio. Is 60 unit mass (kg / m ³ )% or more and 65 unit mass (kg / m ³ )% or less, and the S / a value is 47 unit volume (L / m ³ )% or more. The concrete inducer according to any one of (1) to (4) used for concrete.

(6) In the piping, the step of pumping the ready-mixed concrete and the dispersion medium dispersion liquid of the concrete inducer according to any one of (1) to (5) is included, and in the pumping step, the dispersion liquid is fed. A method for placing at least a part of concrete by pumping it while being located on the downstream side of the ready-mixed concrete.

(7) The method for determining the suitability of using the concrete inducer according to any one of (1) to (5).
(I) The water-cement ratio of the ready-mixed concrete used exceeds the absolute allowable upper limit.
(Ii) The water-cement ratio of the ready-mixed concrete is equal to or less than the absolute allowable upper limit value and equal to or more than the voluntary allowable value, and the S / a value of the ready-mixed concrete is less than a predetermined value, or (iii) The water-cement ratio of the ready-mixed concrete. Is less than the arbitrary allowable value and equal to or more than the absolute allowable lower limit value, and the fluidity of the ready-mixed concrete is represented by the slump flow value.
A method for determining that the concrete inducer is unsuitable for use when the above applies.

(8) The method for determining the suitability of using the concrete inducer according to any one of (1) to (5).
(I) The water-cement ratio of the ready-mixed concrete used is less than the absolute lower limit.
(Ii) The water-cement ratio of the ready-mixed concrete is equal to or more than the lower limit of the absolute value and less than an arbitrary value, and the fluidity of the ready-mixed concrete is represented by a slump value, or (iii) The water-cement ratio of the ready-mixed concrete is arbitrary. The value is equal to or greater than the absolute upper limit, and the S / a value of the ready-mixed concrete is greater than or equal to the predetermined value.
A method for determining that the concrete inducer is appropriate for use when the above applies.

(9) The method according to (7) or (8), wherein the absolute allowable upper limit value is 64 to 66 unit mass (kg / m ³ )%.

(10) The method according to any one of (7) to (9), wherein the absolute lower limit value is 40 to 42 unit mass (kg / m ³ )%.

(11) The method according to any one of (7) to (10), wherein the arbitrary permissible value is 57 to 62 unit mass (kg / m ³ )%.

(12) The method according to any one of (7) to (11), wherein the predetermined value is 46 to 48% by mass.

According to the present invention, it is possible to provide a concrete inducer capable of preventing pipe blockage with a smaller amount as compared with the preceding mortar, and a method for placing concrete using the same. As a result, according to one aspect of the present invention, the following effects can also be expected.

Since the amount of the concrete inducer according to the present invention is small, it can be put into a pipe. As a result, since it is not necessary to charge the hopper, it is possible to reduce the chance that the concrete inducer and the ready-mixed concrete are mixed as in the case of charging the hopper.
At the head (downstream side) of the ready-mixed concrete being pumped, the cement and water covering the aggregate form a film in the pipe and exhibit lubricity (that is, most of the lubricating film in the pipe is cement derived from ready-mixed cement. And water, or cement paste.). The highly liquid concrete inducer is difficult to mix with the ready-mixed concrete in this state.
Eventually, as cement and water are taken away by the pipe film, the coefficient of friction between the aggregates of the ready-mixed concrete and between the aggregate and the pipe increases, causing arching, and gaps between the aggregates and between the aggregate and the pipe are likely to be formed. Become. On the other hand, the concrete inducer is located on the downstream side of the ready-mixed concrete, the fiber or fiber structure absorbs the dispersion medium, and the granular material maintains the dispersion between the dispersion medium and the fiber or fiber structure. It is in a state. As described above, the highly liquid concrete inducer quickly enters the gap, the dispersion medium is released from the fiber or fiber structure to which the force is applied, and the granules are formed between the aggregates and between the aggregate and the pipe. It works with the sand in the ready-mixed concrete to produce a ball bearing effect. It is considered that the combination of these actions reduces the coefficient of friction between the aggregates and between the aggregates and the pipes, and suppresses arching.
That is, the concrete inducer penetrates unevenly around the aggregate that is about to be arched, and exerts an action effect of suppressing arching through the ball bearing effect in the gap between the aggregates and the aggregate and the pipe. Therefore, unlike the type of concrete inducer that forms a lubricating film on the entire inner wall of the pipe, the amount of the concrete inducer used in the present invention is extremely small, but it is important to determine the suitability for use according to the properties of the ready-mixed concrete. Is high.

In addition, since the concrete inducer is highly liquid, it is difficult to mix with the ready-mixed concrete in the pipe unless the aggregate of the ready-mixed concrete is arching, and even if it is mixed, the amount of the concrete inducer used. The amount of the mixture of the concrete inducer and ready-mixed concrete is extremely small. Therefore, even when the mixture is discarded, the amount thereof can be suppressed to an extremely small amount, and even when the mixture is cast, the influence of the concrete inducer can be considerably limited. ..

Since the amount of the concrete inducer according to the present invention is small, it is not necessary to load and deliver it on an agitator vehicle, unlike the case of the preceding mortar. For example, it is sufficient to deliver a relatively small container containing the concrete inducer to the site, and it is not necessary to prepare an agitator vehicle. By using the vacant agitator vehicle for the original delivery of ready-made products, the operating rate of the agitator vehicle can be improved. As a result, the occurrence of a deficit can be prevented.

Hereinafter, embodiments of the present invention will be described, but the present invention is not limited thereto.

<Concrete inducer>
In the first embodiment, the concrete inducer according to the present invention contains granules and at least one of fibers and fiber structures, and the granules are ready-mixed concrete sludge and its processed product, blast furnace slag fine. Contains at least one of powder, fly ash and silica fume. In the second embodiment, the concrete inducer according to the present invention contains granules and at least one of fibers and fiber structures, and the granules have an average particle diameter of 0.1 μm to 1 mm. , Contains fine particles having a brain specific surface area of 1500 cm ² / g or more. In both the first and second embodiments, when the dispersion medium dispersion liquid of the concrete inducer and the ready-mixed concrete pass through the pipe, at least a part of the dispersion liquid precedes the ready-mixed concrete. The concrete inducer according to the present invention is used so as to pass through the pipe.

[Granular matter]
In the first embodiment of the concrete inducer according to the present invention, the granules include at least one of ready-mixed concrete sludge and its processed product, blast furnace slag fine powder, fly ash, and silica fume. Since the granules contain at least one of ready-mixed concrete sludge and its processed product, blast furnace slag fine powder, fly ash, and silica fume, the concrete inducer according to the present invention causes pipe blockage in a smaller amount than that of the preceding mortar. Can be prevented. These may be used alone or in combination of two or more. Among them, blast furnace slag fine powder, fly ash, and silica fume have the property of hardening over time due to latent hydraulic lime or pozzolan reaction even if they are mixed in the cast ready-mixed concrete (note that they harden in the pipe during pumping). It cannot be as fast as this), which is advantageous in that the mixture with the ready-mixed slag does not necessarily have to be discarded.

The ready-mixed concrete sludge includes, for example, solid content contained in the cleaning waste liquid of the agitator vehicle; return concrete (ready-mixed concrete that was not used without being unloaded from the agitator vehicle) or residual concrete (after being unloaded from the agitator vehicle). Examples include solid content contained in the treatment waste liquid of (fresh concrete) that has not been used. Examples of the components of the ready-mixed concrete sludge include unreacted cement particles, cement hydrated products, aggregate fine particles and the like. Examples of the treated product include a dried product of raw consludge, a solid-liquid separated solid product, a crushed product, and the like.

In the second embodiment of the concrete inducer according to the present invention, the granules include fine particles having an average particle diameter of 0.1 μm to 1 mm and a brain specific surface area of 1500 cm ² / g or more. In the above fine particles, the average particle diameter is 0.1 μm to 1 mm, the specific surface area of the brain is 1500 cm ² / g or more, and particularly when the granular material is ready-mixed concrete sludge, the average particle size is 2000 cm ² / g or more or 3000 cm ² / g or more. Therefore, the concrete inducer according to the present invention can prevent pipe blockage in a smaller amount than that of the preceding mortar. The fine particles may be used alone or in combination of two or more.

The lower limit of the average particle size is 0.1 μm, and from the viewpoint of more effectively preventing pipe blockage, 0.2 μm, 0.3 μm, 0.5 μm, 0.7 μm, 1 μm, 2 μm, 3 μm, 5 μm, It may be 7 μm, 10 μm, 20 μm, 30 μm, 50 μm, 70 μm, 100 μm, 200 μm, 300 μm, 500 μm, 700 μm, or the like.

The upper limit of the average particle size is 1 mm, and from the viewpoint of more effectively preventing pipe blockage, 700 μm, 500 μm, 300 μm, 200 μm, 100 μm, 70 μm, 50 μm, 30 μm, 20 μm, 10 μm, 7 μm, 5 μm, 3 μm, It may be 2 μm, 1 μm, 0.7 μm, 0.5 μm, 0.3 μm, 0.2 μm or the like.

The lower limit of the brain specific surface area is 2000 cm ² / g, for example, 3000 cm ² / g, and from the viewpoint of more effectively preventing pipe blockage, 5000 cm ² / g, 7000 cm ² / g, 10000 cm ² / g, 20000 cm. ² / g, 30000cm ² / g, 50000cm ² / g, 70000cm ² / g, 100,000cm ² / g, 200,000cm ² / g, 300,000cm ² / g, 500,000cm ² / g, 700,000cm ² / g, 1000000cm ² / g, 2000000cm ^It may be ² / g, 3000000 cm, ² / g or the like.

The upper limit of the Blaine specific surface area is not particularly limited, from the viewpoint of preventing a pipe clogging more ^{effectively, 5000000cm 2 / g, 3000000cm 2} / g, 2000000cm 2 / g, 1000000cm 2 / g, 700000cm 2 / g, 500,000 cm ² / g, 300,000 cm ² / g, 200,000 cm ² / g, 100,000 cm ² / g, 70000 cm ² / g, 50000 cm ² / g, 30000 cm ² / g, 20000 cm ² / g, 10000 cm ² / g, 7000 cm ² / g, It may be 5000 cm ² / g, 3000 cm ² / g or the like.

Specifically, Blaine specific surface area, blast furnace slag when fine powder 2750 cm ² / g or more 10000cm may be at ² / g or more or less, may be in the case of fly ash 1500 cm ² / g or more 5000 cm ² / g or less, In the case of silica fume, it may be 130,000 cm ² / g or more and 300,000 cm ² / g or less.

For each of the average particle size and the brain specific surface area, the combination of the lower limit and the upper limit may be any as long as the lower limit is lower than the upper limit. In addition, in this specification, an average particle diameter means a volume-based cumulative average particle diameter (D50) measured by a laser diffraction method. Further, in the present specification, the specific surface area of brain refers to the specific surface area measured by the brain air permeation method.

Examples of the fine particles in the second embodiment include a ready-mixed concrete sludge and a processed product thereof, an inorganic filler such as calcium carbonate (preferably a porous body) and a treated product thereof (for example, the inorganic filling). Examples include dried products of agents, solid-liquid separated solid products, crushed products, etc.). As the fine particles, a dried product, a solid-liquid separated solid product, a crushed product, or the like of the concrete inducer waste according to the present invention can be used as long as it satisfies the numerical ranges of the average particle size and the brain specific surface area. ..

In the first embodiment, the granules include the fine particles in the second embodiment, that is, fine particles having an average particle diameter of 0.1 μm to 1 mm and a brain specific surface area in the above range. May be good.

[At least one of fibers and fiber structures]
By containing at least one of the fiber and the fiber structure, the concrete inducer according to the present invention can prevent pipe blockage in a smaller amount than that of the preceding mortar. In the present specification, the fiber structure refers to a structure containing fibers, for example, a structure having a structure in which fibers are entangled, a structure having a structure in which fibers are woven, and a structure in which fibers are oriented with each other. Examples thereof include a structure and a structure having a structure in which fibers are dispersed in a matrix such as resin. Each of the fiber and the fiber structure may be used alone or in combination of two or more.

The fiber and the fiber structure are not particularly limited, and at least one of the fiber and the fiber structure has a liquid absorbing property and a liquid retaining property from the viewpoint of more effectively preventing pipe blockage. , It is preferable to contain a fibrous material that exhibits liquid-removing property when pressurized. Since such a fibrous substance has a liquid-absorbing property, it sufficiently absorbs the dispersion medium from the dispersion medium dispersion liquid of the concrete inducer according to the present invention and also has a liquid-retaining property. The resulting dispersion medium can be easily retained without loss. On the other hand, since the fibrous material exhibits deliquescent property at the time of pressurization, when the concrete is pumped, it enters the gaps between the aggregates formed by arching and the aggregate and the pipe and is pressurized. Since the dispersion medium is released and the ball bearing effect due to the granules and the sand in the ready-mixed concrete is promoted, it is easy to prevent the pipe blockage. Further, the fibrous material has a softness that can be deformed in response to an external force applied by pumping or the like based on the fibrous shape, and a toughness that is not easily cut or broken by the external force. It is presumed that when the ready-mixed concrete is pumped, it may enter between the aggregates to reduce the collision and friction between the aggregates.

At least one of the fibers and the fiber structure preferably contains cellulosic fibers or plant-derived fibers from the viewpoint of more effectively preventing pipe blockage. The cellulosic fiber is not particularly limited, and examples thereof include cellulose and its derivatives. Examples of the derivative include cellulose having at least one substituent such as an alkyl group and a carboxyl group, and specific examples thereof include methyl cellulose and carboxyl methyl cellulose. The plant-derived fiber is not particularly limited, and examples thereof include rice straw-derived fiber and rice bran-derived fiber.

Specific examples of the above fiber structure include paper sludge (for example, paper sludge derived from newspaper, paper sludge derived from toilet paper); rice straw; rice bran; and a fiber structure containing granules having a structure in which fibers are entangled (for example). , Patent No. 5931267) and the like.

Unlike conventional conventional mortars, the concrete inducer has a high content of dispersion medium and a low content of sand (not included in principle) at the time of use, and therefore has a low viscosity. This makes it easier for the concrete inducer to quickly enter the gaps in the aggregate formed by arching during pumping of ready-mixed concrete. The amount of the dispersion medium (for example, water) is not particularly limited, but may be 20 to 50% by mass (specifically, 25 to 40% by mass) of the inducer at the time of use. The content of sand is not particularly limited, but may be 5% by mass or less (specifically, 2.5% by mass or less, 1% by mass or less, 0% by mass) of the inducer at the time of use. The concrete inducer may or may not contain a dispersion medium at the distribution stage before use, and the latter is preferable in that it can be easily prepared in a short time at the time of use.

[Other ingredients]
The concrete inducer according to the present invention may contain other components as long as the effects of the present invention are not impaired. Examples of other components include pigments. When a pigment having a different color (particularly hue) from that of ready-mixed concrete (for example, pink) is added to the concrete inducer according to the present invention, the concrete inducer and ready-mixed concrete can be clearly distinguished based on the color. it can. As a result, it becomes easy to dispose of the concrete inducer that is pumped in advance at the outlet of the pipe at the time of placing concrete, and to cast only ready-mixed concrete that is pumped in later. When the preceding mortar is used, it is not easy to distinguish the preceding mortar from the ready-mixed concrete because the color difference from the ready-mixed concrete is not clear. As a result, even the excess ready-mixed concrete is easily discarded together with the preceding mortar, but the concrete inducer to which the above-mentioned pigment is added can effectively reduce the excess ready-mixed concrete to be discarded. The pigment is not an essential component, and especially when the granules are blast furnace slag fine powder, fly ash, or silica fume, there is no problem even if the ready-mixed concrete mixed with the concrete inducer is used for casting, and even if the pigment is not used. I do not care.

In the concrete inducer according to the present invention, the total amount of the granules and at least one of the fibers and the fiber structure is not particularly limited as long as the effects of the present invention are exhibited. The lower limit of the above amount is 1% by mass, 5% by mass, 10% by mass, 20% by mass, 30% by mass, 40% by mass, 50% by mass, 60% by mass, 70% by mass, 80% by mass, 90% by mass, It may be 95% by mass, 97% by mass, or 99% by mass. The upper limit of the above amount is 100% by mass, 99% by mass, 97% by mass, 95% by mass, 90% by mass, 80% by mass, 70% by mass, 60% by mass, 50% by mass, 40% by mass, 30% by mass, It may be 20% by mass, 10% by mass, or 5% by mass. The combination of the lower limit and the upper limit may be any combination as long as the lower limit is lower than the upper limit. Moreover, the total amount may be 100% by mass.

The amount of the granules with respect to the sum of the granules and at least one of the fibers and the fiber structure is not particularly limited as long as the effects of the present invention are exhibited. The lower limit of the above amount is 1% by mass, 5% by mass, 10% by mass, 20% by mass, 30% by mass, 40% by mass, 50% by mass, 60% by mass, 70% by mass, 80% by mass, 90% by mass, It may be 95% by mass, 97% by mass, or 99% by mass. The upper limit of the above amount is 99% by mass, 97% by mass, 95% by mass, 90% by mass, 80% by mass, 70% by mass, 60% by mass, 50% by mass, 40% by mass, 30% by mass, 20% by mass, It may be 10% by mass, 5% by mass, and 1% by mass. The combination of the lower limit and the upper limit may be any combination as long as the lower limit is lower than the upper limit.

The concrete inducer of the present invention is not particularly limited, but is preferably used for the ready-mixed concrete below.
(1) The water-cement ratio is less than 41 unit mass (kg / m ³ )% (the lower limit is not particularly limited and is usually 30 unit mass (kg / m ³ )% or more).
(2) The water-cement ratio is 41 unit mass (kg / m ³ )% or more and less than 60 unit mass (kg / m ³ )%, and the fluidity is represented by a slump value, or (3) Water-cement ratio. Is 60 unit mass (kg / m ³ )% or more and 65 unit mass (kg / m ³ )% or less, and the S / a value is 47 unit volume (L / m 3)% or more.

When the water-cement ratio (ratio of water to cement) is less than 41 unit mass (kg / m ³ )%, the so-called paste (cement and water) in the ready-mixed concrete has sufficient viscosity or amount, so that it is around the aggregate. Cover with sand coexisting. Therefore, when the concrete inducer enters between the aggregates being arched and between the aggregates and the pipes, a ball bearing effect due to the cooperation between the sand and the granules can be produced, and the arching can be suppressed.

A ready-mixed concrete having a water-cement ratio of 41 unit mass (kg / m ³ )% or more and less than 60 unit mass (kg / m ³ )% often has a sufficient viscosity or amount of the paste contained therein, and thus the fluidity of the ready-mixed concrete. In the case of ordinary ready-mixed concrete represented by a slump value, arching can be suitably suppressed by the concrete inducer of the present invention as in the case of ready-mixed concrete having a mass of less than 41 unit mass (kg / m ³ )%. On the other hand, although the water-cement ratio is 41 unit mass (kg / m ³ )% or more and less than 60 unit mass (kg / m ³ )%, ready-mixed concrete whose fluidity is represented by a slump flow value is available. , A special admixture is expected to be used in combination, and the concrete inducer of the present invention may affect the function of this special admixture (for example, some component of the concrete inducer chemically makes the admixture. The dispersion medium of the concrete inducer can physically separate the admixture from the ready-mixed concrete). As a result, problems such as difficulty in sufficiently suppressing arching and changing the planned performance of the ready-mixed computer may occur.

The slump value is not particularly limited and may be, for example, 8 to 21 cm (specifically, 8 to 18 cm).

Since the viscosity or amount of the paste contained in the ready-mixed cement having a water-cement ratio of 60 unit mass (kg / m ³ )% or more and 65 unit mass (kg / m ³ )% or less is low, sand coexists around the aggregate. The ability to cover in the state is relatively weak. Therefore, the concrete inducer of the present invention has a S / a (amount of sand in ready-mixed concrete) value of 47% or more, which is correspondingly high, because a sufficient amount of sand is likely to coexist around the aggregate. It is preferably used. The lower limit of the S / a value may be 50% by volume, 55% by volume, or 60% by volume, and the upper limit may be 80% by volume, 70% by volume, 60% by volume, or 55% by volume of the body, although the upper limit is not particularly limited. ..

A ready-mixed concrete having a water-cement ratio of more than 65 unit mass (kg / m ³ )% has a low viscosity of the paste contained therein, and it is basically difficult for sand to coexist around the aggregate. Therefore, the use of the concrete inducer of the present invention is not always suitable (of course, it may be preferable).

<Concrete placement method>
The method for placing concrete according to the present invention includes a step of pumping ready-mixed concrete and a dispersion medium dispersion liquid of a concrete inducer according to the present invention in a pipe, and in the pumping step, at least a part of the dispersion liquid. Is pumped in a state of being located on the downstream side of the ready-mixed concrete.

Piping, ready-mixed concrete, pumping conditions, etc. may be the same as before. The dispersion medium is not particularly limited as long as the effects of the present invention are exhibited, and examples thereof include water and organic solvents (organic acids, alcohols, ethers, ketones, etc.), and water is used from the viewpoint of workability, safety, etc. Is preferable.

In the pumping step, in order to pump at least a part of the dispersion liquid in a state of being located on the downstream side of the ready-mixed concrete, for example, a T-shaped pipe is provided in the middle of the pumping path, and the dispersion liquid is fed from there. Examples thereof include a method of pumping ready-mixed concrete from the upstream of the T-shaped pipe while supplying it into a pipe, and a method of first charging the dispersion liquid into a hopper and then charging the ready-mixed concrete into a hopper. From the viewpoint of further reducing the mixture of the dispersion liquid and the ready-mixed concrete and reducing the amount of ready-mixed concrete to be discarded, the former method using piping input is preferable.

The amount of the dispersion liquid used is not particularly limited as long as the effect of the present invention is not impaired, and may be, for example, about 0.3 to 0.9 L with respect to a surface area of 1 m ² in the pipe, 0.45 to 0. It may be about .75L. More specifically, although the inner diameter of the pipe varies depending on the position on the path of the pipe, for example, when a pipe having an inner diameter converted to about 105 mm is used and pumping of about 100 m is performed, for example, about 10 to 30 L. It may be about 15 to 25 L.

Pumping condition is not particularly limited, in terms of easily suppressing the pipe clogging, 5 to 15 m ³ / h approximately (specifically ^{8~12m 3 / h, 9~11m 3 /} h, at about ^{10 m} 3 / h Low pressure is preferable. This is because if the pressure of pumping is too high, the ready-mixed concrete overtakes the concrete inducer in the pipe, and it is difficult to supply a sufficient amount of the concrete inducer to the aggregate in the leading ready-mixed concrete where arching is most likely to occur.

The mixture of the concrete inducer and the ready-mixed concrete may be discarded without being used for casting, or may be used for casting. Generation quantity or amount of waste mixtures of the present invention is not particularly limited, sufficient in 0.4 m ³ or less, usually 0.1 m ³ or less, it may be at 0.05 m ³ or less. The unused mixture may be discarded, but the components may be separated and reused as a part material (typically, granular material) of the concrete inducer. The component separation is not particularly limited, but for example, the method described in Japanese Patent No. 4501098 may be used.

<Method of determining the suitability of using concrete inducers>
In one embodiment, the present invention is a method for determining suitability for using the concrete inducer.
(1) The water-cement ratio of the ready-mixed concrete used exceeds the absolute allowable upper limit.
(2) The water-cement ratio of the ready-mixed concrete is equal to or less than the absolute allowable upper limit value and equal to or more than the voluntary allowable value, and the S / a value of the ready-mixed concrete is less than a predetermined value, or (3) The water-cement ratio of the ready-mixed concrete. Is less than the arbitrary allowable value and equal to or more than the absolute allowable lower limit value, and the fluidity of the ready-mixed concrete is represented by the slump flow value.
If it corresponds to, it is a method of determining that it is unsuitable for the use of the concrete inducer.

In another embodiment, the present invention is a method for determining suitability for using the concrete inducer.
(1) The water-cement ratio of the ready-mixed concrete used is less than the absolute allowable lower limit.
(2) The water-cement ratio of the ready-mixed concrete is equal to or more than the lower limit of the absolute permissible value and less than the voluntary permissible value, and the fluidity of the ready-mixed concrete is represented by the slump value, or (3) The water-cement ratio of the ready-mixed concrete. Is equal to or greater than the arbitrary allowable value and equal to or less than the absolute allowable upper limit value, and the S / a value of the ready-mixed concrete is equal to or greater than the predetermined value.
Is a method for determining that the concrete inducer is suitable for use.

The absolute allowable upper limit value, the absolute allowable lower limit value, the arbitrary allowable value, and the predetermined value may be appropriately set according to the allowable range of the required pipe blockage risk. Although not particularly limited, the absolute allowable upper limit value may be, for example, 64 to 66 unit mass (kg / m ³ )%, and the absolute allowable lower limit value may be 40 to 42 unit mass (kg / m ³ )%. The arbitrary permissible value may be 57 to 62 unit mass (kg / m ³ )%, and the predetermined value may be 46 to 48 unit volume (L / m ³ )%.

In one aspect (particularly the aspect in which the voluntary tolerance is within the range described in the previous paragraph), when the water-cement ratio of the ready-mixed concrete is equal to or less than the absolute allowable upper limit and greater than or equal to the voluntary tolerance, the fluidity of the ready-mixed concrete is slump value or slump flow. It does not matter which of the values it represents. Since the viscosity of the paste contained in such ready-mixed concrete is relatively low by nature, even if the fluidity is expressed by the slump flow value, it is unlikely that a special admixture is used under narrow window conditions. This is because it cannot be said that it is unsuitable for the use of the concrete inducer of the present invention.

In one aspect (particularly, the arbitrary allowable value is in the range described in the paragraph before the previous paragraph), when the water-cement ratio of ready-mixed concrete is less than the arbitrary allowable value and equal to or more than the absolute allowable lower limit value, the S / a value of the ready-mixed concrete is predetermined. Whether it is less than the value is not important. This is because such a ready-mixed paste has a correspondingly high viscosity of the paste contained therein, and even if the S / a value is less than a predetermined value, a sufficient amount of sand can coexist around the aggregate.

The slump value is not particularly limited and may be, for example, 8 to 21 cm (specifically, 8 to 18 cm). Further, the slump flow value is not particularly limited, and may be, for example, 40 to 70 cm (specifically, 50 to 60 cm).

Hereinafter, the present invention will be described in more detail with reference to Examples, but the scope of the present invention is not limited to these Examples. The following experiments were carried out at Kawabata Kogyo Co., Ltd. using the equipment and other equipment of Kawabata Kogyo Co., Ltd.

[Preparation of concrete inducer]
(Example 1)
The following materials were mixed to prepare a concrete inducer.
Ready-mixed concrete sludge dried product 20 kg
Calcium carbonate 18kg
Paper sludge 15kg
Water 25L

The ready-mixed concrete sludge dried product has an average particle diameter of 18 μm and a brain specific surface area of 4000 cm ² / g. The calcium carbonate has an average particle size of 2 μm and a brain specific surface area of 11000 cm ² / g. The paper sludge is derived from newspaper.

(Examples 2-35)
The materials shown in Tables 1 to 4 were mixed to prepare a concrete inducer.

(Examples 36 to 41)
A concrete inducer was prepared under the same conditions as in Example 1 except that blast furnace slag fine powder, fly ash, and silica fume were used instead of the dried raw concrete sludge or calcium carbonate. Blast furnace slag has an average particle diameter of 2 [mu] m, Blaine specific surface area of 3000 cm ² / g (Example 36) or 9985cm ² / g (Example 37), fly ash average particle diameter of 2 [mu] m, Blaine specific surface area of 1520 cm ² / g ( Example 38) or 4950 cm ² / g (Example 39), the silica fume has an average particle size of 2 μm and a brain specific surface area of 130500 cm ² / g (Example 40) or 299500 cm ² / g (Example 41).

[Concrete pumping test]
(Examples 1-41)
A concrete pumping pipe was prepared by connecting 31 steel pipes having a length of 3 m and an inner diameter of about 107 mm with a flexible synthetic rubber hose (7 m in total). The surface area inside the pipe is about 34 m ² when the inner diameter of the pipe is converted to 107 mm. The concrete inducer 18L prepared in Example 1 was put into a pipe, and the ready-mixed concrete (water-cement ratio 50 unit mass (kg / m ³ )%, fluidity was represented by a slump value) from the upstream at a pumping speed of 10 m ³ / h. Will be pumped). The ready-mixed concrete could be pumped without blockage. The amount of ready-mixed concrete mixed with the concrete inducer was 0.043 m ³ . Similar results were obtained when the concrete inducer prepared in each of Examples 2 to 41 was used.

(Comparison example)
The ready-mixed concrete was pumped in the same manner as in the examples except that 0.5 m ³ of the preceding mortar was put into the hopper instead of putting the concrete inducer into the pipe. The ready-mixed concrete was closed at a position 48 m from the pipe entrance. Normally, 0.5 m ³ of the preceding mortar is mixed with 0.25 m ³ of ready-mixed concrete, so the amount of waste is 0.75 m ³ .

(Discussion)
As described above, the concrete inducer according to the present invention can prevent pipe blockage in a much smaller amount as compared with the preceding mortar, and can reduce the amount of the resulting mixture to nearly 1/20. did it.

[Usability test]
Under the same conditions, except that the ready-mixed concrete used in the concrete pumping test using the concrete inducers of Examples 6, 16-18, 23, 33-35, 36-41 was replaced with the one shown in Table 5. went.

As a result, no pipe blockage occurred in any of the examples for the ready-mixed pipes 1 to 4, 6 to 7, 9 to 10, and 12 to 13. On the other hand, in the ready-mixed pipe 5, the pipe was not blocked in any of the examples, but in some examples, the physical properties of the ready-mixed pipe after pumping deviated from the planned values. In the ready-mixed pipe 8, the pipe was blocked in some examples (however, the average value of the blocked portion is 87 m from the pipe inlet, which is ahead of the comparative example). In the ready-mixed pipes 11, 14 and 15, the pipes were blocked in some examples (however, the average value of the blocked parts was 83 m from the pipe inlet, which was earlier than the comparative example).

(Discussion)
From the above, the concrete inducer of the present invention
(1) The water-cement ratio is less than 41 unit mass (kg / m ³ )%.
(2) The water-cement ratio is 41 unit mass (kg / m ³ )% or more and less than 60 unit mass (kg / m ³ )%, and the fluidity is represented by a slump value, or (3) Water-cement ratio. Is 60 unit mass (kg / m ³ )% or more and 65 unit mass (kg / m ³ )% or less, and the S / a value is 47 unit volume (L / m ³ )% or more. It was confirmed that it is preferable to be used for concrete.

[Piping and ready-mixed condition confirmation test]
A concrete pumping pipe was produced by connecting nine steel pipes having a length of 1 m and an inner diameter of about 107 mm to the outlet side of eight steel pipes having a length of 3 m and an inner diameter of about 107 mm. The concrete inducer 34L prepared in the same manner as in Example 1 except that the pink pigment was included was put into the pipe, and ready-mixed concrete (water-cement ratio 50 unit mass (kg / kg / kg /)) was pumped from the upstream at a pumping speed of 10 m ³ / h. m ³ )%, fluidity is represented by a slump value) was pumped. When the ready-mixed concrete began to be discharged from the pipe outlet, pumping was temporarily stopped, and the pipes were removed from the first to ninth steel pipes from the pipe outlet to observe the internal condition.
The presence of the concrete inducer shown in pink was confirmed in the 1st to 5th pipes, but was hardly confirmed in the 6th to 9th pipes, and instead cement and water or cement paste covered the inner wall of the pipe. (A lubricating film was formed). Specifically, in the 1st and 2nd pipes, a mixture of the concrete inducer and ready-mixed concrete was generally confirmed, while in the 3rd to 5th pipes, the abundance of the concrete inducer was found from the center to the outside of the pipe cross section. Upon closer observation, it was confirmed that the aggregate that had lost cement and water was covered with a concrete inducer and intervened between the aggregates and in the gaps between the aggregates and the pipes.
Therefore, the pipe blockage suppressing effect of the concrete inducer of the present invention is not mainly due to the formation of a film on the inner wall of the pipe, and most of the lubricating film in the pipe is cement and water derived from ready-mixed concrete. It turned out.

Claims (12)

(1) The water-cement ratio is less than 41 unit mass (kg / m ³ )%.
(2) The water-concrete ratio is 41 unit mass (kg / m ³ )% or more and less than 60 unit mass (kg / m ³ )%, and the fluidity is represented by a slump value, or (3) Water-concrete ratio. Is 60 unit mass (kg / m ³ )% or more and 65 unit mass (kg / m ³ )% or less, and the S / a value is 47 unit volume (L / m ³ )% or more. A concrete inducer used for concrete
The concrete inducer contains granules and at least one of fibers and fibrous structures.
The granular material is a concrete inducer containing at least one of ready-mixed concrete sludge and its processed product, blast furnace slag fine powder, fly ash, and silica fume. (1) The water-cement ratio is less than 41 unit mass (kg / m ³ )%.
(2) The water-concrete ratio is 41 unit mass (kg / m ³ )% or more and less than 60 unit mass (kg / m ³ )%, and the fluidity is represented by a slump value, or (3) Water-concrete ratio. Is 60 unit mass (kg / m ³ )% or more and 65 unit mass (kg / m ³ )% or less, and the S / a value is 47 unit volume (L / m ³ )% or more. A concrete inducer used for concrete
The concrete inducer contains granules and at least one of fibers and fibrous structures.
The granular material is a concrete inducer containing fine particles having an average particle diameter of 0.1 μm to 1 mm and a brain specific surface area of 1500 cm ² / g or more. The concrete inducer according to claim 2, wherein the average particle size is 0.1 μm to 7 μm. The concrete inducer according to any one of claims 1 to 3 , wherein at least one of the fiber and the fiber structure has a liquid-absorbing property and a liquid-retaining property, and contains a fibrous substance that exhibits a liquid-retaining property when pressurized. .. The concrete inducer according to any one of claims 1 to 3 , wherein at least one of the fiber and the fiber structure contains a cellulosic fiber or a plant-derived fiber. In the pipe
(1) The water-cement ratio is less than 41 unit mass (kg / m ³ )%.
(2) The water-concrete ratio is 41 unit mass (kg / m ³ )% or more and less than 60 unit mass (kg / m ³ )%, and the fluidity is represented by a slump value, or (3) Water-concrete ratio. Is 60 unit mass (kg / m ³ )% or more and 65 unit mass (kg / m ³ )% or less, and the S / a value is 47 unit volume (L / m ³ )% or more. Including the step of pumping concrete and the dispersion medium dispersion liquid of the following concrete inducer 1 or 2, in the pumping step, at least a part of the dispersion liquid is pumped in a state of being located on the downstream side of the ready-mixed concrete. How to place concrete.
Concrete inducer 1:
A concrete inducer containing granules and at least one of fibers and fiber structures.
The granular material is a concrete inducer containing at least one of ready-mixed concrete sludge and its processed product, blast furnace slag fine powder, fly ash, and silica fume.
Concrete inducer 2:
A concrete inducer containing granules and at least one of fibers and fiber structures.
The granular material is a concrete inducer containing fine particles having an average particle diameter of 0.1 μm to 1 mm and a brain specific surface area of 1500 cm ² / g or more. The following method for determining the suitability of using the concrete inducer 1 or 2.
(1) The water-cement ratio of the ready-mixed concrete used exceeds the absolute allowable upper limit.
(2) The water-cement ratio of the ready-mixed concrete is equal to or less than the absolute allowable upper limit value and equal to or more than the voluntary allowable value, and the S / a value of the ready-mixed concrete is less than a predetermined value, or (3) The water-cement ratio of the ready-mixed concrete. Is less than the arbitrary allowable value and equal to or more than the absolute allowable lower limit value, and the fluidity of the ready-mixed concrete is represented by the slump flow value.
A method for determining that the concrete inducer is unsuitable for use when the above applies.
Concrete inducer 1:
A concrete inducer containing granules and at least one of fibers and fiber structures.
The granular material is a concrete inducer containing at least one of ready-mixed concrete sludge and its processed product, blast furnace slag fine powder, fly ash, and silica fume.
Concrete inducer 2:
A concrete inducer containing granules and at least one of fibers and fiber structures.
The granular material is a concrete inducer containing fine particles having an average particle diameter of 0.1 μm to 1 mm and a brain specific surface area of 1500 cm ² / g or more. The following method for determining the suitability of using the concrete inducer 1 or 2.
(1) The water-cement ratio of the ready-mixed concrete used is less than the absolute allowable lower limit.
(2) The water-cement ratio of the ready-mixed concrete is equal to or more than the lower limit of the absolute permissible value and less than the voluntary permissible value, and the fluidity of the ready-mixed concrete is represented by the slump value, or (3) The water-cement ratio of the ready-mixed concrete. Is equal to or greater than the arbitrary allowable value and equal to or less than the absolute allowable upper limit value, and the S / a value of the ready-mixed concrete is equal to or greater than the predetermined value.
A method for determining that the concrete inducer is appropriate for use when the above applies.
Concrete inducer 1:
A concrete inducer containing granules and at least one of fibers and fiber structures.
The granular material is a concrete inducer containing at least one of ready-mixed concrete sludge and its processed product, blast furnace slag fine powder, fly ash, and silica fume.
Concrete inducer 2:
A concrete inducer containing granules and at least one of fibers and fiber structures.
The granular material is a concrete inducer containing fine particles having an average particle diameter of 0.1 μm to 1 mm and a brain specific surface area of 1500 cm ² / g or more. The method according to claim 7 or 8, wherein the absolute allowable upper limit value is 64 to 66 unit mass (kg / m ³ )%. The method according to any one of claims 7 to 9, wherein the absolute lower limit is 40 to 42 unit mass (kg / m ³ )%. The method according to any one of claims 7 to 10, wherein the optional allowable value is 57 to 62 unit mass (kg / m ³ )%. The method according to any one of claims 7 to 11, wherein the predetermined value is 46 to 48 unit volume (L / m ³ )%.