JP2013035701A - Foam mortar kneaded product and infilling method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a foam mortar kneaded product excellent in flowability and stability, capable of setting widely the range of a contained air quantity and obtaining continuous foam, and having gas permeability and water permeability, even when using a general surfactant or an animal protein-based foaming agent without using a special surfactant as a foaming agent.SOLUTION: This foam mortar kneaded product is a kneaded product formed by kneading an ordinary portland cement, a fine particle admixture, water and a forming agent, together with an additive, if necessary, wherein the fine particle admixture contains limestone powder and cellulose powder at the ratio of 1:0.0005-0.002, and the weight ratio of the cement to the fine particle admixture is 1:0.3-2.5, and the air amount is 40-75 vol%. In the kneaded product, an ordinary portland cement is used as the cement, and limestone powder and cellulose powder are used jointly as the admixture.

Description

  The present invention is used in the case of shielding work and tunnel tunnels, when filling the backside of the concrete lining or filling the gap between the primary lining and the secondary lining (steel pipe, FRPM pipe, etc.). The present invention relates to a foamed mortar kneaded material used as a filler excellent in air permeability and water permeability by a construction method and excellent in long-distance pumpability and an injection method thereof.

  Conventionally, in the backfill injection method and the backfilling method for the back side of concrete lining of shield tunnels and tunnels, foam mortar kneaded materials in which bubbles are mixed into cement slurry, fine particle slurry and mortar kneaded material have been used. ing. The foamed mortar kneaded product can be set to a specific gravity or compressive strength according to the purpose by adjusting the amount of solidified material, admixture and mixed bubbles in the materials to be used, and a predetermined air mortar can be obtained. . Therefore, it is often used for civil engineering work such as lightweight embankment, backfill injection on the backside of tunnel lining concrete, filling filling of gaps around secondary lining materials, closing of waste pipes and filling of cavities such as old mines and air defense walls. Yes. However, in the construction of tunnels and the like, when the foam mortar kneaded material is injected, long distance pump pumping is required in the pumping pipe after kneading and manufacturing at the square near the wellhead. Due to troubles such as separation of bleeding (bleeding), quality problems such as blockage of the pressure feeding tube, poor physical properties and poor filling of the foamed mortar solidified body are likely to occur and are unstable, and the result depends on the skill level of the worker Often.

  In order to eliminate such troubles, the present inventor has proposed a solidification method using a foam mortar kneaded material using an admixture containing 30% by weight or more of calcium carbonate, as shown in Patent Document 1. On the other hand, Patent Document 2 discloses a combination of a fine powder aggregate (for example, limestone fine powder) and a special surfactant (amine oxide type nonionic surfactant), and the air permeability coefficient, strength and specific gravity of the cured foam mortar. It shows how to control.

  Patent Document 3 discloses a foam mortar composition that has good fluidity and is difficult to separate even when pumped, and uses fine sand of ferronickel slag as a fine aggregate. A composition with bentonite is shown. In Patent Document 4, polycarboxylate and calcium lignin sulfonate are added to the filling material mainly composed of cement and bentonite to ensure fluidity and sufficient working time (pot life). A filling material to which metallic aluminum which is a post-foaming type is added as an agent is shown.

  As described above, in order to obtain a foam mortar kneaded material that has good fluidity and does not separate in the pumping pipeline, can be pumped over a long distance, and is preferably applied to shield construction and tunnel construction, etc. It is known to use limestone fine powder containing calcium carbonate as a component or bentonite having high swellability. However, a foamed mortar kneaded product using calcium carbonate fine powder as one method when installing steel pipes for gas pipes in tunnels such as shields and tunnels and filling the gaps on the back of steel pipes. In order to ensure a larger amount of air (bubble amount), a special nonionic surfactant is used (see Patent Document 2). Then, bentonite, a clay mineral that is highly swellable and has a stable cement slurry as a suspension, is preferably used in combination with ferronickel slag (Patent Document 3) or in combination with a special additive (Patent Document 4). )doing.

Japanese Patent Laid-Open No. 7-3771 (Japanese Patent No. 2514576) JP 2009-11024 A (Patent No. 4550103) JP 9-249441 A (Patent No. 3706670) JP 2007-169974 A

  The problem of the present invention is that, without using a special surfactant as a foaming agent, even if a general surfactant or animal protein-based foaming agent is used, the fluidity in long-distance pumping, An object of the present invention is to provide a foam mortar kneaded product that is excellent in stability, can be set in a wide range of air content, has open cells, and has air permeability and water permeability.

  The foam mortar kneaded product of the present invention is a kneaded product obtained by adding foam prepared with a foaming agent diluent and compressed air to a cement fine particle slurry produced by kneading ordinary Portland cement, a fine particle admixture, and water. The fine particle admixture uses limestone powder and cellulose powder, the weight ratio of limestone powder and cellulose powder is 1: 0.0005 to 0.002, and the weight ratio of cement to the fine particle admixture is 1: 0. .3 to 2.5, and the amount of air is 40% to 75% by volume. This kneaded product is characterized in that ordinary Portland cement is used as cement and limestone powder and cellulose powder are used in combination as fine particle admixture.

  Moreover, it is preferable to add a polycarboxylic acid type high performance water reducing agent, a melamine sulfonic acid type retarder and a metal aluminum powder as additives to the foam mortar kneaded product.

  Furthermore, a filling method for filling the inside of a tunnel is provided, characterized in that the above-mentioned foamed mortar kneaded material is pumped and filled at a predetermined location in a shield construction or a tunnel.

The foamed mortar kneaded material of the present invention is excellent in fluidity and stability even when the amount of air is 40% by volume or more, and during the long distance pumping in the tunnel filling method etc., the bubbles are reduced and the kneaded material is separated. And stable filling and consolidation. The foamed mortar solidified body becomes open-celled, and has air permeability and water permeability, and a value of 1 × 10 ⁻¹ cm / sec or more is obtained as the air permeability coefficient. When used, even if a gas leak occurs, the leaked gas can be detected quickly.

  The present invention has been found that by using limestone powder and cellulose powder in combination as fine particle admixture, the characteristics of limestone powder having excellent characteristics as an admixture for a foam mortar kneaded product can be further exhibited. . That is, even if a general-purpose foaming agent is used without using a special surfactant as a foaming agent, due to the interaction between limestone powder and cellulose powder, moderate hydrophilic affinity is obtained when kneaded with water. It becomes a suspension that exhibits the viscosity of the kneaded product, and in the state of the kneaded product by introduction of the bubble group, it maintains moderate bubble stability.After the cement hydrates and solidifies, the foam mortar solidified with open cells is solidified. It becomes a ligation, and good air permeability and water permeability can also be obtained.

  In addition, this development can provide the characteristics that the electro-coating action that adversely affects the painting of steel pipes is difficult to occur by using ordinary Portland cement as the solidifying material.

  As described above, the combined use of limestone powder and cellulosic powder ensures the fluidity and stability of the kneaded product, so the settings such as the air volume and water powder ratio can be adjusted in a wide range. The physical properties of the consolidated body can also be set widely. Therefore, it is easy to re-excavate shields and tunnels filled with air mortar by reducing the specific gravity of the consolidated body to make it a lightweight mortar consolidated body or adjusting the strength of the consolidated body. Can be constructed.

  Furthermore, by adding a polycarboxylic acid-based high-performance water reducing agent, a melamine sulfonic acid-based retarder, and a metal aluminum powder as additives, the metal aluminum acts as a foaming agent after adjusting the fluidity of the kneaded product, adjusting the pot life. Due to the presence of the powder, stable fluidity and air bubble filling can be achieved, workability can be maintained, pumping can be performed over a longer distance, and the quality of the kneaded product after filling and consolidation can be stabilized.

  In addition, since the solidified body of the foam mortar kneaded product of the present invention also has high water permeability, when the back gap or underground cavity of the existing water channel structure is filled and closed with this air mortar, the groundwater level rises abnormally. Even if it is a water-permeable air mortar layer, intrusion water can be allowed to pass through and the back water pressure can be reduced. In this case, impregnation of water passing through the bubbles of the mortar solidified body by mixing natural porous minerals such as zeolite, activated carbon, porous sintered ceramics, etc. as adsorbents in this mortar kneaded product. Objects can be removed by adsorption to purify water.

It is a manufacturing plant of a bubble mortar kneaded material. It is a recording chart of the pumping pressure and injection | pouring speed | velocity | rate in the long distance pumping test of bubble mortar kneaded material.

  The production of the foam mortar kneaded product of the present invention can be carried out in the same process as the production of a normal foam mortar kneaded product. That is, cement, fine particle admixture, cellulose powder, water and additives are kneaded with a mixer to form a slurry, and foam produced by merging foaming agent diluted with water and compressed air is passed through a blender. It is mixed and mixed with the slurry to make a foam mortar kneaded product. Alternatively, cement, an admixture, cellulose powder, water and additives may be added to the foamed foam and kneaded and stirred with a grout mixer.

  The foamed mortar kneaded material produced in this way is pumped to the injection point by a pipeline and filled in the target point in the case of a shield work or a tunnel in a tunnel. Since the foamed mortar kneaded product of the present invention is excellent in fluidity and stability, even when the distance between the production place of the kneaded product and the injection site is as long as 3000 m or more, it is stably pumped and injected and filled. Can do. In the case of a long distance such that the pumping distance is L = 3000 m or more, the slurry kneading step and the bubble kneading step are separated, the slurry is produced and pumped in advance, and a bubble group is introduced at a location near the injection point. May be employed to further reduce the amount of bubbles and further reduce the separation of the kneaded material.

  Foaming agents used in the kneaded product are anionic surfactants such as alkyl sulfates, alkyl ether sulfates, higher fatty acids and the like, nonionic surfactants such as polyoxyethylene alkyl ether, and anionic nonionic mixed surfactants. Commonly used foaming agents such as synthetic surfactant foaming agents such as rosin, natural resin foaming agents such as rosin, and animal protein foaming agents can be used, and are not particularly limited.

  As a cement, when ordinary Portland cement is used as a filling material for shields and tunnels in combination with fine particle admixtures consisting of limestone powder and cellulose powder, the chemical resistance of the mortar consolidated body is good, and Since the electrocoating action that adversely affects the painted film is difficult to occur, it is preferable in terms of the resistance of the steel pipe.

In the present invention, the limestone powder used as the fine particle admixture is obtained by drying and pulverizing natural limestone, adjusting the particle size, and setting the specific surface area to 3000 to 8000 cm ² / g.
Similarly, as the cellulose powder, methyl cellulose, ethyl cellulose, or the like produced from natural pulp is preferably used.

  In the fine particle admixture, limestone powder and cellulose powder are added to the kneaded material in a weight ratio of 0.0005 to 0.002 of cellulose powder to limestone powder 1. The total amount of the fine particle admixture added is added in a weight ratio of 0.3 to 2.5 with respect to the cement 1. If the amount of cellulose powder relative to the limestone powder is less than the above range, the effect of adding cellulose powder is not seen, on the contrary, if too much, cellulose fouling occurs, resulting in defects in the mortar solidified body, Bubble defoaming may occur. And when the quantity with respect to the cement of an admixture is more than the said range, the intensity | strength of a mortar solidified body cannot be ensured, and when it is small, the effect of this invention is not seen.

  Further, the amount of water used for kneading is not particularly limited, but the fine particle admixture has a weight ratio of 0.35 to 0.90 with respect to water 1 as in a general foaming mortar kneaded product. It is preferable to set to. The amount of air is set in the range of 40% by volume to 75% by volume. When the amount of air is less than 40% by volume, the ratio of open cells is small in the bubbles of the mortar consolidated body, and the necessary air permeability coefficient cannot be ensured. When the amount of air exceeds 75% by volume, a reduction in bubbles may occur during the pumping of the bubble mortar kneaded product, and the flowability of the kneaded product may change. Therefore, in the foam mortar kneaded material of the present invention, it is necessary to set the air amount within this range.

  Furthermore, other additives can be added to the foamed mortar kneaded material as required. Additives include high-performance water reducing agents, separation reducing agents, and post-foaming agents. In the present invention, a polycarboxylic acid-based high-performance water reducing agent comprising a polymer compound having a carboxyl group in the side chain is preferably used as the high-performance water reducing agent. This polymer compound is adsorbed on the cement particle surface, exhibits an effect of dispersing the cement particles, and exhibits water reduction.

  As the foaming agent, metallic aluminum powder can also be added. This metal aluminum powder generates hydrogen by an alkaline reaction such as calcium hydroxide in the mortar and foams, contributing to the replenishment of air bubbles in the kneaded product, and improving the air permeability and water permeability of the mortar consolidated product. Show the effect.

  Examples will be shown below to describe the present invention more specifically. In these examples, a foamed mortar kneaded material was prepared using the materials shown below, fluidity and the like were tested, and the kneaded material was consolidated to examine the characteristics of the mortar consolidated body.

Materials used Cement
Ordinary Portland cement Fine particle admixture Limestone powder "MP grout" (manufactured by Kizaitect)
Specific gravity 2.7 Specific surface area 5000 cm ² / g
Cellulose powder Nonionic Water-soluble cellulose ether

Foaming agent Surfactant system "KF foam" (manufactured by Kizaitect)
Specific gravity 0.98 to 1.02 pH = 7.0

Table 1 shows formulation examples and characteristic values of Examples 1 and 2.

  In the foamed mortar kneaded plant shown in FIG. 1, each batch of water, cellulose powder, fine particle admixture (MP grout), ordinary Portland cement, each lightweighted based on the formulation of each example shown in Table 1, Are sequentially added to the grout mixer 1 to produce a slurry by stirring and kneading, and at the same time, a 25-fold diluted solution of the foaming agent (KF foam) is supplied to the foaming nozzle 3 by the plunger pump of the foaming system 2 and separately supplied to the compressor 4. Compressed air is supplied to the foaming nozzle 3 to create air bubbles, which are put into the grout mixer 1 and kneaded well with the slurry to produce an air bubble mortar kneaded product. The produced foamed mortar kneaded product is pumped by a hydraulic piston type grout pump 5 to fill and close a gap around a pipe installed in a shield work or a tunnel in a tunnel, and solidifies to perform filling.

  Table 1 shows the characteristic values of the foamed mortar kneaded product and the consolidated product produced together with the composition. As shown from these characteristic values, the foam mortar kneaded mixture of the present invention is excellent in fluidity, has no separation and sedimentation phenomenon in the middle of the pressure feeding pipe, does not adversely affect the steel pipe coating film as a filling material, It is a mortar solidified body having suitable air permeability.

  FIG. 2 shows a recording chart of the pumping pressure and the injection speed in the pumping test of the foamed mortar kneaded material of the present invention. This pumping test is a pumping test that extends to 3,700 m, and pumps up to a point of 3,500 m as a slurry. At this point, bubbles are introduced by a blender to form a bubble mortar kneaded product. Further, the pipe was further extended by 200 m, bubble bubbles were introduced at a point of 3,700 m, and the pressure feeding was further continued, and finally the bubble mortar kneaded product was pressure-fed to a point of 3,700 m. The blending as the foam mortar kneaded product is the same blending composition as in Example 1.

  As shown in the recording chart of FIG. 2, the slurry was pumped by 3,500 m from time 100 to time 105, and the foamed mortar kneaded material was introduced at a time of 105 to 0.8-1. The injection rate of 75 liters / min is maintained at a pressure of about 05 MPa, and the injection rate of 75 liters / min is maintained at a pressure of about 1.5 to 1.9 MPa even after the pumping pipe is extended by 200 m. It was confirmed that it was excellent.

The air permeability coefficient and water permeability coefficient of the solidified product of the foam mortar composition of Example 1 were measured. The air permeability coefficient was measured by applying an epoxy adhesive to the side surface of a test specimen consolidated in a cylindrical shape for testing, and allowing air to pass only in the axial direction of the cylinder. The air permeability was measured at each pressure of 0.5, 1, and 1.5 kPa to obtain the air permeability coefficient. The dimensions of the specimen and the obtained air permeability coefficient were as follows.
The permeability coefficient was measured by measuring the water permeability five times by a constant water level method using a water-permeable cylinder having an inner diameter of 4.99 cm and a length of 9.83 cm at a water level difference of 9.0 cm and a measurement time of 270 minutes. Asked.
Test sample Bubble mortar composition (Formulation composition Example 1)
Specimen dimensions, etc.
Diameter 4.99cm
Cross-sectional area 19.56cm ²
Length 9.83cm
Volume 192.24cm ³
Mass 69.19g
Wet density 0.360 g / cm ³
Test results
Air permeability coefficient 2.83cm / sec
Water permeability 2.13 × 10 ^-2 cm / sec

As the air permeability coefficient, a value that sufficiently cleared the air permeability coefficient 1 × 10 ⁻¹ cm / sec necessary for gas leak detection was obtained. In addition, the hydraulic conductivity was also able to reduce the back water pressure by allowing intrusion water to pass through.

1 Grout mixer 2 Foaming system 3 Foaming nozzle 4 Compressor 5 Grout pump 6 Raw material silo 7 Mortar hopper 8 Hydraulic unit 9 Water meter

A Injection speed curve B Pumping pressure curve

100 Slurry pressure start time 101 3,500 m pipe connection pressure start time 102 Injection speed 150 liters / min Adjustment time 103 Pressure pressure 0.65 MPa
104 Injection speed 120 liters / min Adjustment time point 105 Arrival at slurry 3,500 m point, bubble introduction start time 106 Pressure feed pipe 200 m addition time point 107 Arrival at slurry 3,700 m point, bubble reintroduction start time 108 Pressure feed test end point

Claims (3)

  A cellular mortar kneaded material obtained by kneading ordinary Portland cement, a fine particle admixture, water and a foaming agent, and if necessary, a fine particle admixture comprising a limestone powder and a cellulose powder in a weight ratio of 1: 0.0005-0. A foam mortar kneaded material containing 0.002 in a weight ratio of cement and fine particle admixture of 1: 0.3 to 2.5 and an air amount of 40 volume% to 75 volume%.   2. The foam mortar kneaded product according to claim 1, wherein a polycarboxylic acid-based high-performance water reducing agent, a retarder, and metallic aluminum powder are used as additives.   Filling and filling the foamed mortar kneaded product according to claim 1 or 2 into a predetermined place in a shield work and a tunnel, filling and filling in a shield work and a tunnel Construction method.

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