JP2011241679A - Filler - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance the handleability of a filler by reducing the adhesion of the filler to be used for filling a void portion such as a cavity.SOLUTION: The filler to be used for filling the void portion such as the cavity comprises water, cement, fly ash, incombustible lightweight aggregate, and a thickening material. In such a constitution, two-part VISCOTOP (R) is used as the thickening material. Perlite of a component composition can be easily ion-bound with the VISCOTOP (R). Thus, the filler can obtain required viscosity and reduced adhesion by adding the VISCOTOP (R) to composition components except the perlite, kneading the mixture, subsequently, adding the perlite to the resultant mixture, and then kneading together.

Description

  The present invention relates to a technique for filling a cavity such as a cavity, and is particularly effective when applied to filling a back cavity of a tunnel.

  In excavation work for mountain tunnels, holes are drilled in the rocks that make up the natural ground. On the inner peripheral surface side of the hole, a cavity is easily generated due to a small-scale collapse, and the cavity is filled with a grout of filler to stabilize the natural ground.

  Moreover, when excavating a tunnel using a shield excavator or the like, a lining body such as a segment is provided in conjunction with excavation of a hole. A grout material is injected into a gap between the outer peripheral surface of the covering body and the inner peripheral surface of the hole.

  In this way, the backside cavities of railways, roads, and waterway tunnels constructed by the mountain tunnel method cannot be expected to have sufficient ground reaction force from the backside of the lining when the tunnel is subjected to plastic pressure or partial pressure. In addition to being in a disadvantageous state, it also causes loosening of the natural ground, so that the gap on the back side is filled with a filler.

  As such a filling method, for example, a plastic grout method is known. A cementitious material having plasticity (the injection material itself does not have fluidity but easily flows under pressure) is injected into the back cavity. Such a plastic grout method is less prone to cracks in the natural ground, deviation from the cavities on the lining surface, and limited injection is possible.

  As a material used for such a plastic grout method, for example, Patent Document 1 discloses a composition having water, hydraulic cement, pearlite as a lightweight aggregate, a polycarboxylic acid-based water reducing agent, and a thickener. Fillers have been proposed. It is described that the proposed filler is excellent in lightness, injectability, handleability, and reduction in construction cost.

JP 2005-163526 A

  Certainly, the use of a polycarboxylic acid-based attenuating agent in the filler improved the injectability and handleability, but the present inventor believes that further improvement in injectability and handleability is necessary from the construction viewpoint. It was.

  From the viewpoint of improving the handleability including the pouring property, the present inventor has paid attention to the adhesiveness when adjusting the viscosity of the filler. In the conventional filler, when the viscosity is adjusted to a predetermined viscosity by adding a thickener, the adhesion of the filler to the vessel wall and the like is also increased. For this reason, it has been a general tendency that the resulting filler adheres to the wall of the equipment used during manufacture or filling, and its handling becomes worse.

  Therefore, the present inventor considered that a configuration of a filler that can secure a predetermined viscosity as the filler and does not increase the adhesion so much is necessary.

  An object of the present invention is to improve the handleability by reducing the adhesion of a filler used to fill a void such as a cavity.

  The above and other objects and novel features of the present invention will be apparent from the description of this specification and the accompanying drawings.

  Of the inventions disclosed in the present application, the outline of typical ones will be briefly described as follows.

  That is, the present invention is a filler used to fill a void such as a cavity, the filler has water, cement, fly ash, lightweight aggregate, and thickener, Adhesiveness is smaller than that of a filler containing a polycarboxylic acid-based water reducing agent having a hydraulic cement, pearlite, and a polycarboxylic acid-based water reducing agent. Alternatively, the cement as a component of the filler is encapsulated in a thickener added by the particles. Alternatively, the filler has water, cement, fly ash, noncombustible lightweight aggregate, and thickener, and the water is 339 parts by weight or more and 412 parts by weight or less, and the cement is 214 parts by weight or more and 236 parts by weight or less, the fly ash is 641 parts by weight or more and 709 parts by weight or less, the lightweight aggregate is 14 parts by weight or more and 16 parts by weight or less, and the thickener is 7.6 parts by weight. It is characterized by being not less than 8.4 parts by weight and not more than 8.4 parts by weight. In this configuration, pearlite having a particle size of 0.6 mm or more and 2.5 mm or less and a water absorption of 15% or less is used for the lightweight aggregate.

  In any one of the above configurations, the specific gravity of the filler is 1.1 or more and 1.5 or less, and the fluidity of the filler is a flow value after standing at a flow value of 80 mm or more and 150 mm or less when left standing. Is 100 mm or less, the flow value at the time of impact is 130 mm or more and 205 mm or less, and the flow value after 60 minutes is 170 mm or less. In any one of the configurations described above, a two-component Visco Top (registered trademark) is used for the thickening material. In any one of the configurations described above, the filler is used for repair work of a tunnel used after construction.

  Among the inventions disclosed in the present application, effects obtained by typical ones will be briefly described as follows.

  In this invention, while ensuring the desired viscosity of the filler used in order to fill void parts, such as a cavity, handleability etc. can be improved more by reducing adhesiveness.

  In the present invention, by adding pearlite as a component of the filler after mixing with the thickener, it is possible to suppress the bonding between the pearlite and the thickener and to secure a desired viscosity.

It is a flowchart which shows an example of the manufacturing method of the filler of this invention. It is a flowchart which shows an example of the manufacturing method of the past filler. It is a flowchart which shows an example of the manufacturing method of the filler of this invention. It is explanatory drawing which shows the composition of the filler of this invention in a table | surface form. (A) is explanatory drawing which shows typically the filling system which is filling the tunnel back surface cavity part of the one side in use using the filler of this invention, (b) is the mode inside a tunnel. It is explanatory drawing which shows a mode that it looked from the upper surface of this. It is explanatory drawing which shows the flow value of the filler shown in one Example of this invention in a table | surface form. It is explanatory drawing which shows the specification of the flow value of the filler in the road tunnel of Japan Highway Public Corporation in a tabular form. It is explanatory drawing which shows typically the filling system using the filler which concerns on this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  The present invention is a technique related to a filler used for filling a void such as a cavity. The filler of the present invention can basically be used for filling the gaps of any kind, but is particularly suitable for filling cavities formed on the back of mountain tunnels. . In other words, it is effective when applied to repair work for tunnels in use.

  Such a filler of the present invention has water, cement, fly ash, lightweight aggregate, and thickener as its components. In particular, when applied to a tunnel such as a mountain tunnel, a lightweight aggregate may be made nonflammable such as pearlite as necessary.

  In the present invention, in order to further improve the handleability of the filler and the like, even if a thickener that adjusts the filler to a predetermined viscosity is added, it adheres to the walls of equipment used in manufacturing or filling operations, etc. A thickener having a property capable of suppressing the property is selected and used.

  As such a thickening material, for example, Visco Top (registered trademark) manufactured by Kao Corporation can be used. A two-component thickening material using Viscotop (registered trademark) A which is an alkyl allyl sulfonate and Viscotop (registered trademark) B which is an alkylammonium salt may be used.

  In such a filler, when pearlite is used as the non-combustible lightweight aggregate, it is necessary to employ a special mixing procedure because pearlite itself forms an ionic bond with the above-mentioned Viscotop (registered trademark). It has now been clarified that the desired viscosity cannot be generated in the filler when manufactured without employing such a mixing procedure.

  Since pearlite is lightweight and nonflammable, it is required to be used as a fire countermeasure in tunnels where several major fire accidents have occurred before.

  The present inventor is a polycarboxylic acid having a hydraulic cement, pearlite, and a polycarboxylic acid-based water reducing agent as a filler excellent in lightness, injectability, handleability, construction cost reduction, etc. A water reducing agent-containing filler was proposed. Such a filler may be a thickener such as Metroze manufactured by Shin-Etsu Chemical Co., Ltd., for example.

  However, although the handleability has been improved, when considering the workability, it was considered necessary to improve the handleability as described above. Therefore, a thickening material was selected by paying attention to adhesion. The inventors searched for a thickening material that can impart a desired viscosity but can suppress adhesion. Various commercially available thickeners were tried.

  Under such circumstances, the above-mentioned Visco Top (registered trademark) A and B have been focused on as being capable of obtaining a thickening effect while suppressing adhesion. However, while trying various lightweight aggregates, it was found that sufficient viscosity did not occur when pearlite was used. Among several lightweight aggregates, pearlite was an aggregate that should be used as a lightweight aggregate with excellent nonflammability.

  Therefore, the present inventor has sought why the desired viscosity is less likely to occur when such pearlite is used. As a result, since perlite easily reacts with Viscotop (registered trademark) B, it was found that the reaction of Viscotop (registered trademark) A and B hardly occurs.

  That is, the reaction of Viscotop (registered trademark) A and B occurs by ionic bond, but since pearlite has a positive charge on the particle surface, it forms an ionic bond with anionic Viscotop (registered trademark) B. It has been found. For this reason, Viscotop (registered trademark) B becomes difficult to react with Viscotop (registered trademark) A, and as a result, it has been clarified that a desired viscosity cannot be obtained.

  The binding property between such pearlite and Viscotop (registered trademark) B is such that as the specific surface area of pearlite increases, the charge of the surface area increases. It becomes easier. For this reason, it has been confirmed for the first time that when pearlite and Viscotop (registered trademark) B are mixed, it becomes easier to react with Viscotop (registered trademark) B as pearlite is crushed and finer during mixing.

  Therefore, in order to suppress the reaction with Viscotop (registered trademark) B, it is possible to mix pearlite after sufficiently reacting Viscotop (registered trademark) A and Viscotop (registered trademark) B. I noticed that it was preferable.

  Furthermore, it has been found that the pearlite used is more preferable if the particle size is set to 0.6 mm or more and 2.5 mm or less, for example. If the particle size is less than 0.6mm, there is a problem of being adsorbed to the thickener B because it is a fine powder, and if the particle size is larger than 2.5mm, it cannot enter into cracks during lining. There may be a problem that the filling cannot be performed well. Therefore, the particle size is preferably 0.6 mm or more and 2.5 mm or less.

  FIG. 1 shows a flowchart of the manufacturing method of the present invention. That is, in step S10, water, cement, fly ash, and Viscotop (registered trademark) B as the thickener B are kneaded together with a grout mixer. Thereafter, in step S20, Visco Top (registered trademark) A as the thickener A is added and kneaded. Finally, in step S30, a predetermined amount of perlite is added and mixed. What is necessary is just to perform the process of this step S20, S30 with a mortar mixer.

  As shown in FIG. 1, in the production method of the present invention, after adding Viscotop (registered trademark) A and B and kneading, adding pearlite and mixing, pearlite and Viscotop (registered trademark) B and This reaction is sufficiently suppressed. By doing in this way, the desired thickening effect is acquired with the suppressed adhesiveness.

  In step S10, mixing is performed for 3 minutes, in step S20, mixing is performed for 2 minutes, and in step S30, mixing is performed for 30 seconds. The pearlite may be added in the final stage after kneading the thickener and other composition components in this way, and lightly mixed in a short time.

  On the other hand, in the manufacturing method shown in FIG. 2 which the present inventor tried, in step S1, water, cement, fly ash, Visco Top (registered trademark) B as a thickener B, and pearlite are grouted. Knead all at once with a mixer. Then, transfer to a ready-mix car etc., add Viscotop (registered trademark) A as thickener A, and knead in a ready-mix car for 3 minutes.

  In such a method, pearlite is pulverized by high-speed rotation of a grout mixer, and the pulverized fine powder of pearlite reacts with Viscotop (registered trademark) B to form ionic bonds. Therefore, Visco Top (registered trademark) B does not easily react with Visco Top (registered trademark) A, and as a result, the desired thickening effect cannot be exhibited.

  As shown in the flow chart shown in FIG. 1, the inventor adds pearlite after mixing and kneading Viscotop (registered trademark) A and B, so that pearlite and Viscotop (registered trademark) B are mixed. They have found a production method that can sufficiently suppress the reaction.

  Further, the present inventor has found that the kneading time can be shortened by further reviewing the step S10 shown in FIG. That is, as shown in FIG. 3, in step S101, water and Visco Top (registered trademark) B as the thickening material B are kneaded for 10 seconds, for example. Thereafter, fly ash is added in step S102 and kneaded for 1 minute. Thereafter, in step S103, cement is further added and mixed for 30 seconds.

  As described above, by dividing Step S10 of FIG. 1 which has been kneaded at once into steps S101, S102 and S103 of FIG. 3, the time required for kneading could be reduced to only 1 minute 40 seconds.

  After step S103, pearlite may be added and kneaded after addition and kneading of Viscotop (registered trademark) A as the thickener A, similarly to steps S20 and S30 and the method shown in FIG.

  Moreover, since the pearlite used in the present invention cannot be expected to be crushed during kneading as shown in FIGS. 1 and 3 above, it is preferable to set the particle size in advance. It should be set to 0.6mm or more and 2.5mm or less.

  In the configuration shown in FIGS. 1 and 3, pearlite, which is a nonflammable lightweight aggregate, is added after the reaction of Viscotop (registered trademark) A and B as thickeners. However, lightweight aggregates other than pearlite are added. When the reaction with the thickening material can be suppressed by using, it is not necessary to take the production method as shown in FIGS.

  When pearlite is used as the lightweight aggregate and the thickener Bisco Top (registered trademark) is used, the composition of the filler can be as follows. That is, the composition of the filler may be composed of water, cement, fly ash, pearlite as a non-combustible lightweight aggregate, and Visco Top (registered trademark) as a thickener.

  In such a filler composition, water (sometimes abbreviated as W) is 339 to 412 parts by weight, cement (sometimes abbreviated as C) is 214 to 236 parts by weight, and fly ash ( F (sometimes abbreviated as F) is 641 parts by weight or more and 709 parts by weight or less, and pearlite (sometimes abbreviated as P) is 14 parts by weight or more and 16 parts by weight or less, and is a thickener (may be abbreviated as Z). It has been confirmed by experiments that Viscotop (registered trademark) is preferably 7.6 parts by weight or more and 8.4 parts by weight or less. The particle size of pearlite used as such a lightweight aggregate may be set to 0.6 mm or more and 2.5 mm or less, for example.

  When the composition ratio is not satisfied, the specific gravity and fluidity of the obtained filler may be outside the specifications shown below.

  Also, if the binder (may be abbreviated as B) = C + F + P, the amount of water (W) used is 37% by weight or more in the binder ratio (W / (C + F + P)) 45% by weight or less, and most preferably 43% by weight. It was confirmed that the use amount of the thickener is preferably 2% by weight or more and 3% by weight or less (Z / W) with respect to the weight of water.

  As for the specific gravity immediately after kneading, since a thickener is added, some air (about 5.0%) is mixed in the filler, and the specific gravity immediately after kneading is approximately 1.289, which reduces the weight. It was confirmed that it was within the range of 1.2 ± 0.1 even when considering variations during mixing.

  The filler having such a composition is obtained by mixing the above-described composition components within the composition range of each component composition, so that the specific gravity is 1.1 or more and 1.5 or less, and the flowability when standing is 80 mm or more and 150 mm or less for 60 minutes. The subsequent flow value can be 100 mm or less, the flow value at impact can be 130 mm or more and 205 mm or less, and the flow value after 60 minutes can be 170 mm or less.

  Since it can have such specific gravity and fluidity within the range of the above composition, for example, for filling repair work such as the hollow part of the common tunnel of the public corporation where the property value standard of the filler used is set Can also be used.

  As described above, the present inventor searches for a thickener that can adjust the viscosity within a predetermined range to improve the handleability of the filler, but does not increase the adhesion so much. In various tests, a Visco Top (registered trademark) manufactured by Kao Corporation was found.

  In the case of using such Viscotop (registered trademark), it was confirmed that the cement particles as components were surrounded by a substance in which Viscotop (registered trademark) A and B reacted and ionically bonded. By generating such a structure, the filler can obtain a predetermined viscosity based on the fluidity indicated by the flow value at the time of standing and the flow value at the time of impact, but the adhesion is at least the polycarboxylic acid described above. It is presumed to be suppressed from the filler containing the water reducing agent.

  For example, the mountain of fillers proposed so far, including hydraulic cement, pearlite as a lightweight aggregate, polycarboxylic acid-based water reducing agent, thickener (Metrouse manufactured by Shin-Etsu Chemical Co., Ltd.) Compared with the tunnel backside cavity filler, in the above range, the viscosity based on fluidity is the above range, the filler of the present invention has clearly lower adhesion, and the filler related to the previous application is more than the case of the filler of the present invention. It can be seen that it is obviously high.

  A comparison of the magnitude of the adhesion is, for example, that in the JHS flow test, the filler according to the present invention (Visco Top (registered trademark) is used as the thickening material) is more smoothly removed from the cylindrical container of φ80 mm. The polycarboxylic acid-based water reducing agent-containing filler (Metrouse is used as a thickening material) adheres to the inner surface of a cylindrical container with a diameter of 80 mm and cannot be removed unless it is slowly raised. Although it is simple, it can be easily confirmed by comparing the time required for dropout in the flow test and the state of standing still after dropout.

  In the filler of the present invention, the desired viscosity can be ensured and the adhesion can be kept low in this way, so that it does not adhere to equipment, containers, etc. used at the time of manufacture, filling, etc. In addition, handling properties such as workability are very good.

  In this example, the filler of the present invention described in the above embodiment and the manufacturing method thereof will be described with specific examples.

  As described above, the materials used in the filler according to the present invention are water, cement, fly ash, pearlite, and a thickener.

Among such materials, ordinary Portland cement defined in JIS R5201 was used as the cement. In addition, fly ash having a JIS standard type II with a specific surface area of 2500 cm ² / g or more and a specific gravity of 1.95 or more was used. Perlite was used as a nonflammable lightweight aggregate. Such pearlite has a specific gravity of 0.26 g / cm ³ or less, a water absorption of 15% or less, and a particle size of 0.6 to 2.5 mm. Most preferred is 1.2 to 2.5 mm.

  As shown in FIG. 4, the composition ratio is 390 parts by weight of water, 225 parts by weight of cement, 675 parts by weight of fly ash, 15 parts by weight of pearlite, and viscotop as a thickener. (Registered trademark) A and B were 8 parts by weight in total.

  In such a composition, the amount of water used was 42.6% by weight as a binder ratio. The specific gravity at the time of kneading is that the specific gravity immediately after the mixing is added with a thickener, so some air (about 5.0%) is mixed in the filler, and the specific gravity immediately after kneading is 1.283. It was confirmed that

  In addition, the filler is first blended with the composition shown in FIG. 4 using a grout mixer. As shown in the flow chart of FIG. 3, Visco Top (registered trademark) of water and a two-component thickener in step S101 is used. ) Add B and knead for 10 seconds. Next, in step S102, fly ash is added and mixed for about 1 minute. In step S103, cement is added and mixed for about 30 seconds.

  Assuming that such a situation is used, for example, for filling and repairing a cavity at the back of a tunnel of a road tunnel, FIG. 5 (a) schematically shows the filling system. Steps S101 to S103 may be performed by a grout mixer 10 installed at a location away from the actual construction site, as shown in FIG.

  Thereafter, the mixture kneaded by the grout mixer 10 is dropped into the agitator tank 20 and stirred, and the necessary amount is put into the ready-mixed car 40 by the mortar pump 30.

  The ready-mix vehicle 40 moves to the on-site tunnel 100 where the injection is actually performed, and inputs a predetermined amount of the material mixed into the mortar mixer 50. Then, the remaining Visco Top (registered trademark) A as a thickening material is added in an amount corresponding to the predetermined amount of material, and is mixed for about 2 minutes. After that, pearlite with a particle size of 1.2-2.5mm and water absorption of 15% or less is added in an amount suitable for the specified amount of material, and mixed for about 30 seconds to produce the filler of the present invention (also referred to as a backing material). To do.

  The fluidity of the filler thus manufactured is as shown in FIG. In the flow test of JHS A313-1992 using a cylinder with a diameter of 80mm and a height of 80mm, as shown in Fig. 6, the static flow when the elapsed time is 0 minutes is 108mm, the flow when hitting is 179mm, 60 minutes The flow value at the time of standing after the lapse was 93 mm, and the flow value at the time of impact was 165 mm.

  As described above, in the filler according to the present invention, the flow down in 60 minutes after mixing is small, so that high injectability can be maintained when pumping with a pump. In addition, the filler has a specific gravity of 1.2 ± 0.1 and is light in weight, and has a lower adhesion than the case of using the polycarboxylic acid-based water reducing agent developed for its good handleability. Is very good. Further, when kneading is performed along the flow shown in FIG. 3, the construction time can be kept short, and the manufacturing cost can be reduced.

  Such filler has the fluidity as described above, and the quality of the back cavity filling material described in Japan Road Public Corporation “Back sheet cavity injection material design guideline for construction of Yaita tunnel, 2002.10” shown in FIG. It can be seen that the standard value for the fluidity of the standard is satisfied. The regulations shown in Fig. 7 are the standard values for the fillers for repairing road tunnels of the Japan Highway Public Corporation, but the standards for fillers for such tunnel cavities are generally not prepared and are currently the strictest standard values. If this standard value is satisfied, it can be applied to other tunnels.

  The filler having such properties produced by the mortar mixer 50 in this manner is sent to the pressure feeding tube 71 via the hopper 60 and the grout pump 70, for example. In the aerial work vehicle 80, the filling material may be injected with the filling nozzle of the pressure feeding tube 71 directed into the cavity 200 on the back surface of the tunnel.

As shown in Fig. 5 (b), such a filling system can be used when a large amount (30m ³ / day) is injected in a road tunnel with two or more lanes. It is a system that can be adopted. A large amount of filler is manufactured at the ready control plant, transported to the site tunnel using the ready control vehicle, received by the hopper 60 installed at the site, pumped by the grout pump 70, and injected into the cavity 200 at the back of the predetermined tunnel. Good. That is, it can be said that this system is effective when a large amount of filler is manufactured and manufacturing is not possible at the filling site.

On the other hand, when the amount of filler used is small, filling may be performed with a filling system as schematically shown in FIG. For example, as shown in FIG. 8, when the working time can be secured only about 3 hours at night in a railway single-track tunnel, and the injection amount is about 1 m ³ / day, the filler according to the present invention is used locally. It may be manufactured and processed in a plaza near the tunnel pit.

  As shown in FIG. 8, a small, fully-automatic kneading plant is installed in the vicinity of the tunnel wellhead, and a generator, water truck, water tank, material, and the like are also prepared. In such a small fully-automatic plant, necessary materials are automatically charged in the order of steps S101, S102, and S103 shown in FIG. As shown in FIG. 8, the kneaded mixture is put into a tank 91 of a rail car 90 and transported to a filling site in the tunnel.

  At the site, the contents are transferred from the tank 91 of the track-and-rail vehicle 90 to the mortar mixer 50 provided in another track-and-ground vehicle 90 by the pump 92. Furthermore, Viscotop (registered trademark) A is added and kneaded for a predetermined time, and then pearlite is added and kneaded for a predetermined time to produce a filler. Such a filler is sent to the pressure feeding tube 71 via a hopper 60 and a grout pump 70 provided in another rail car 90, and the filling nozzle of the pressure feeding tube 71 is directed toward the inside of the cavity 200 at the back of the tunnel by the rolling tower 81. The filler may be injected.

  As mentioned above, the invention made by the present inventor has been specifically described based on the embodiment. However, the present invention is not limited to the embodiment, and various modifications can be made without departing from the scope of the invention. Needless to say.

  In the above-described embodiments and examples, a two-component viscotop (registered trademark) has been described as an example of a thickener, but as a thickener used, in addition to viscotop (registered trademark), Needless to say, any material can be used as long as it has a lower adhesion than a polycarboxylic acid-based water reducing agent-containing filler and can provide a viscosity based on the fluidity of the standard.

  Furthermore, when the pearlite and the components of the thickener react with such a thickener, the production method of the present invention can be applied.

  INDUSTRIAL APPLICABILITY The present invention can be effectively used in the field of civil engineering that fills voids such as cavities such as mountain tunnels.

DESCRIPTION OF SYMBOLS 10 Grout mixer 20 Agitator tank 30 Mortar pump 40 Ready-mix vehicle 50 Mortar mixer 60 Hopper 70 Grout pump 71 Pressure feed tube 80 Aerial work vehicle 81 Rolling tower 90 Railroad vehicle 91 Tank 92 Pump 100 Tunnel 200 Cavity

Claims (7)

A filler used to fill a void such as a cavity,
The filler has water, cement, fly ash, lightweight aggregate, and thickener.
A filler characterized by having lower adhesion than a polycarboxylic acid-based water reducing agent-containing filler having hydraulic cement, pearlite, and a polycarboxylic acid-based water reducing agent. A filler used to fill a void such as a cavity,
The cement, which is a component of the filler, is encapsulated in a thickener added by the particles. A filler used to fill a void such as a cavity,
The filler has water, cement, fly ash, non-combustible lightweight aggregate, and thickener.
The water is 339 parts by weight or more, 412 parts by weight or less,
The cement is 214 parts by weight or more, 236 parts by weight or less,
The fly ash is 641 parts by weight or more, 709 parts by weight or less,
The lightweight aggregate is 14 parts by weight or more and 16 parts by weight or less The filler is characterized in that the thickener is 7.6 parts by weight or more and 8.4 parts by weight or less. The filler according to claim 3,
The lightweight aggregate is made of pearlite having a particle size of 0.6 mm or more and 2.5 mm or less and a water absorption of 15% or less. In the filler according to any one of claims 1 to 4,
The specific gravity of the filler is 1.1 or more, 1.5 or less,
The flowability of the filler is such that the flow value after standing is 80 mm or more and 150 mm or less, the flow value after 60 minutes is 100 mm or less, and the flow value upon impact is 130 mm or more and 205 mm or less, after 60 minutes. The filler has a flow value of 170 mm or less. In the filler according to any one of claims 1 to 5,
The thickener is made of a two-component Bisco Top (registered trademark). In the filler according to any one of claims 1 to 6,
The said filler is used for the repair work of the tunnel currently used after construction, The filler characterized by the above-mentioned.

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