JP6512908B2 - Construction method of floor slab structure - Google Patents

Description

  The present invention relates to a method of installing a floor slab structure having improved durability of the floor slab.

  Conventionally, a new concrete floor slab is finished by pumping relatively soft concrete with a slump of 10 to 15 cm by a pump car or the like and compacting the same compounded concrete in one layer using a vibrating vibrator or the like. In addition, in order to improve the durability of existing concrete floor slabs and steel floor slabs, concrete floor slab structures and steel floors that use high-strength fiber reinforced concrete in which fibers are mixed into concrete on floor slabs as the main component material Plate structures are known. For example, Patent Document 1 proposes a steel bridge floor slab mainly composed of high-strength fiber-reinforced concrete in which silica fume, an expansive agent, and steel fibers are mixed in concrete. These are also compacted and finished with the same compounded concrete layer.

JP, 2009-7925, A

  In recent years, the simultaneous deterioration of social infrastructure has become a social problem, and the most expensive of which is the maintenance cost is the bridge. Among them, in concrete floor slabs, rainwater and snow melting agents that intrude from the pavement edge of the upper surface and construction joints penetrate into concrete floor slabs, rusting of reinforcing bars due to frost damage, alkali silica reaction, salt damage, etc. The fatigue effect causes horizontal cracking, gravelization, etc., and there are many cases where the durability of the floor slab is significantly impaired. Although various measures such as high performance waterproofing and drainage are taken as measures against this, penetration of water can not be prevented, and improvement of the durability of the floor slab has become a major issue. On the other hand, in order to cope with such a problem, the movement of constructing highly durable concrete in consideration of durability as well as raising the concrete strength is spreading. However, such concrete is expensive and difficult to be adopted compared to conventional concrete. In addition, as a practical problem in construction, since the concrete casting method inserts vibration in the vertical direction by inserting a rod-like vibrator for a floor slab thickness of about 20 cm, the durability is inferior to the upper surface of the concrete floor slab It can be said that a fragile bleeding layer is likely to be formed.

  On the other hand, as a pavement structure such as a bridge, there is a structure in which asphalt pavement is formed after a waterproof layer is formed on a floor slab. In such a structure, replacement repair of asphalt pavement is required after about 10 years of service. At that time, there is an example in which the upper surface of the existing concrete floor slab is damaged.

  There is also a method of forming a steel fiber reinforced concrete layer on a concrete floor slab or a steel floor slab and forming asphalt pavement on the upper surface thereof to improve floor slab durability and waterproofness. However, due to long-term service, steel fibers are exposed from the cut surface of the steel fiber reinforced concrete layer at the time of cutting by later repair, and there is a problem that adhesion with asphalt pavement is impaired.

  Furthermore, there is a top surface thickening method in which a steel fiber reinforced concrete layer is formed on the existing concrete floor slab to increase the punching shear resistance of the floor slab. However, even if the interface between the existing concrete and the old and new concrete surfaces is adhered well after being treated by cleaning, many examples of delamination at the interface between the existing floor slab and the steel fiber reinforced concrete layer in long-term service have been reported There is. The above problems are all problems in the upper surface of the concrete to be constructed, and are solved by enhancing the durability of only the upper surface of the concrete.

  This invention is made in view of the said problem, and an object of this invention is to provide the construction method of the floor slab structure which can improve durability of a floor slab and can construct economically.

In order to achieve the above object, a method of installing a floor slab structure according to a first aspect of the present invention,
A method of constructing a floor slab structure comprising a high durability material for improving the durability of the concrete floor slab on a concrete floor slab and forming a high durability layer comprising concrete or mortar,
A first screed for laying out the concrete forming the concrete floor slab;
And a second screed for laying out the concrete or mortar forming the high durability layer.
It installs using the device which has installed the nail | claw and the anti-vibration rubber behind the said 1st screed,
The concrete or mortar forming the high durability layer is supplied between the first screed and the second screed using a supply device,
In addition to laying out the concrete forming the concrete floor slab, laying out the concrete or mortar forming the high durability layer on the concrete , placing both of them simultaneously .
The claws whose screed vibration is blocked by the anti-vibration rubber interferes with the concrete forming the concrete floor slab and swings to the left and right with respect to the traveling direction, so that the upper surface of the concrete slab is spread. It is characterized in that it is roughened .

The construction method of the floor slab structure according to the second aspect of the present invention is
Floor structure with high durability layer consisting of concrete or mortar, on steel floor or reinforced concrete floor, including fiber reinforced concrete layer and high durability material to improve durability of steel floor or reinforced concrete floor The construction method of the body,
A concrete forming the fiber reinforced concrete layer is spread, and a concrete or a mortar forming the high durability layer is spread on the concrete, and both are cast simultaneously.

  A first screed for laying out the concrete forming the fiber reinforced concrete layer;
  And a second screed for laying out the concrete or mortar forming the high-durability layer.
  Preferably, the concrete or mortar forming the high-durability layer is supplied between the first screed and the second screed using a supply device.

  The claws and the anti-vibration rubber are installed behind the first screed, and the claws whose screed vibration is cut off by the anti-vibration rubber interfere with the concrete forming the fiber reinforced concrete layer and spread in the traveling direction. It is preferable to finish the upper surface of the concrete which forms the said fiber reinforced concrete layer spread by roughening on the other hand by roughening to the left and right.

  It is preferable to use, as the high-durability material, one containing at least one of fly ash, ground fine blast furnace slag, short fibers, an expanding material and a polymer.

  ADVANTAGE OF THE INVENTION According to this invention, the construction method of the floor slab structure which can improve durability of a floor slab can be provided.

It is a figure which shows an example of the floor slab structure constructed by the construction method of the floor slab structure of the 1st Embodiment of this invention. It is a figure which shows an example of the floor slab structure constructed by the construction method of the floor slab structure of the 2nd Embodiment of this invention. It is a figure which shows the structure of the principal part of a concrete finishing apparatus. It is a figure which shows the structure of the principal part of a concrete finishing apparatus. It is a figure which shows the structure of the principal part of a concrete finishing apparatus. It is a figure which shows the total salt amount measurement result of a test object.

  Hereinafter, the construction method of the floor slab structure of the present invention will be described with reference to the drawings.

First Embodiment
FIG. 1: is a figure which shows an example of the floor slab structure 1 constructed by the construction method of the floor slab structure of the 1st Embodiment of this invention. First, the floor slab structure 1 of the present embodiment will be briefly described.

  As shown in FIG. 1, in the floor slab structure 1, a high durability layer 12 is formed on a concrete floor slab 11.

  Examples of the concrete floor slab 11 used in the present invention include concrete floor slabs generally used for bridges, expressways and the like.

  The high durability layer 12 used in the present invention contains a high durability material, and is formed of concrete or mortar. For example, the high durability layer 12 is formed on the concrete floor slab 11 by coating a concrete (mortar) containing cement, aggregate (sand), high durability material and water on the concrete floor slab 11 Can.

  As the cement used in the present invention, commonly used cements, for example, cements such as pneumatic cement and hydraulic cement can be used. In particular, generally used cements such as portland cement, alumina cement, jet cement, mixed cement and the like can be used.

  The aggregates used in the present invention include fine aggregates and coarse aggregates. As fine aggregate, natural sand such as river sand and mountain sand, and artificial sand such as crushed sand and blast furnace slag fine aggregate can be used. Gravel and crushed stone can be used as the coarse aggregate.

  As the high durability material used in the present invention, the durability such as waterproofness, water tightness, frost damage resistance, salt permeation resistance, alkali silica reaction resistance etc. of the floor slab structure 1 to be constructed is better than concrete or mortar An excellent material is also preferable, and it is preferable to contain, for example, at least one of ground granulated blast furnace slag, fly ash, short fibers, an expansive agent, and a polymer.

  For example, by adding 1.0 to 20% by mass of ground granulated blast furnace slag as a high-durability material, the air hole diameter after hardening becomes small and dense. Thereby, waterproofness, water tightness, resistance to salt permeation and resistance to alkali silica reaction are improved.

  Moreover, by adding 1.0 to 20% by mass of fly ash as a highly durable material to concrete (mortar), the air hole diameter after hardening becomes small and it becomes compact. Thereby, waterproofness, water tightness, resistance to salt permeation and resistance to alkali silica reaction are improved.

  Furthermore, as a highly durable material, a mixture of ground granulated blast furnace slag and fly ash in a ratio of 1.5 to 2.5: 1 is hardened by adding 1.0 to 25% by mass of concrete (mortar) The air hole diameter after that becomes smaller and denser. Thereby, waterproofness, water tightness, resistance to salt permeation and resistance to alkali silica reaction are improved.

  Furthermore, by adding 0.1% to 2.0% by mass of a short fiber (concrete (mortar)) as a high-durability material, it becomes strong in tensile force, and cracking due to tensile force can be suppressed. This prevents the infiltration of moisture and salt from cracks, and improves waterproofness and resistance to salt penetration. Examples of short fibers include steel fibers, glass fibers, organic fibers, carbon fibers and the like.

  Moreover, tensile strength becomes strong by adding a polymer (1.0 to 20 mass% of a concrete (mortar)) as a highly durable material, and the crack by tensile force can be suppressed. This prevents the infiltration of moisture and salt from cracks, and improves waterproofness and resistance to salt penetration. As a polymer, SBR, EVA, PAE etc. are mentioned, for example.

  Furthermore, by adding 0.1 to 15% by mass of an expansive material as a highly durable material to concrete (mortar), the tensile force becomes strong, and cracking due to the tensile force can be suppressed. This prevents the infiltration of moisture and salt from cracks, and improves waterproofness, water tightness, resistance to frost damage, and resistance to salt permeation. Examples of the expansive material include quick lime-gypsum-based expansive material, gypsum-based expansive material, calcium sulfoaluminate-based expansive material, and the like.

  The high durability layer 12 is formed to a thickness of 1 mm to 50 mm, and constructs the surface layer of the floor slab structure 1 that improves the durability. When the thickness of the high durability layer 12 is less than 1 mm, it is difficult to improve the durability of the floor slab structure 1, and when the thickness of the high durability layer 12 is greater than 50 mm, the concrete floor slab 11 is simultaneously struck It is because it becomes difficult to set.

  Moreover, it is preferable that the drying shrinkage of the high durability layer 12 does not differ greatly from the drying shrinkage of the concrete floor slab 11. If the drying shrinkage rate of the high durability layer 12 and the drying shrinkage rate of the concrete floor slab 11 are largely different, the difference in the shrinkage rates may cause cracking.

  Thus, the floor deck structure is provided by imparting durability such as waterproofness, water tightness, frost damage resistance, salt permeation resistance, alkali silica reaction resistance, etc. to the high durability layer 12 and by constructing it on the surface. The durability of 1 can be improved.

  Next, the construction method of the floor slab structure of the present embodiment will be described.

  First, in the case of new construction, concrete for constructing a general concrete floor slab 11 is manufactured by kneading cement, aggregate, water and the like at a predetermined stirring speed and stirring time in a stationary concrete plant. Furthermore, high durability is achieved by kneading cement, aggregate (sand) water and highly durable materials at a predetermined stirring speed and stirring time using a similar installation type concrete plant or a mobile concrete manufacturing apparatus. Manufacture concrete (or mortar) for applying the layer 12.

  Next, using a concrete finisher, the concrete for laying the manufactured concrete floor slab 11 is spread at a predetermined position, and the high durability layer 12 produced is spread on the spread concrete. The concrete (or) mortar to do is spread so that the thickness becomes 1 mm-50 mm.

  In the case of construction on an existing concrete floor slab, high durability is achieved by kneading cement, aggregate (sand) water, high durability material, etc. at a predetermined stirring speed and stirring time using a mobile concrete manufacturing apparatus The concrete (or mortar) for applying the quality layer 12 is manufactured. Cut the upper surface of the existing concrete floor slab, apply an adhesive to the cut surface, and use concrete finishing equipment to apply the concrete layer (or mortar) to apply the manufactured high durability layer 12 Spread it so that it will be 1 mm to 50 mm.

  Fig. 3 shows the structure of the main part of the concrete finisher. For example, as shown in FIG. 3, the concrete 111 for constructing the supplied concrete floor slab 11 is spread by the lower layer screed 31 of the concrete finishing device 3, and the supplied high durability layer 12 is constructed. Concrete (or mortar) 121 is laid by the upper layer screed 32 of the concrete finisher 3. Thereby, the concrete (or mortar) 121 for constructing the high durability layer 12 is laid on the concrete 111 for constructing the concrete floor slab 11.

  Subsequently, by applying high frequency vibration by the upper layer screed 32 of the concrete finishing device 3, concrete 111 for constructing the concrete floor plate 11 and concrete (or mortar) 121 for constructing the high durability layer 12 are used. At the same time it will be driven (compacted). The concrete (or mortar) 121 for applying the high durability layer 12 is supplied onto the concrete 111 spread between the lower layer screed 31 and the upper layer screed 32 using a supply device.

  As described above, after placing the concrete floor slab 11, both can be integrated by placing the high durability layer 12 without putting time, so the durability of the floor slab structure 1 is improved. be able to. Further, the high-durability layer 12 capable of improving the durability can be economically provided as a thin layer.

  As shown in FIG. 4, it is preferable that a claw 41 be installed behind the lower layer screed 31 so as to interfere with the upper surface of the concrete 111 and swing the claw 41 laterally in the direction of travel. Thereby, the surface of the concrete floor slab 11 is finished to be rough, and the adhesiveness with the high durability layer 12 can be improved. Further, by installing the anti-vibration rubber 42 on the claws 41, it is possible to prevent the vibration of the lower layer screed 31 from being transmitted to the claws 41 and the roughened surface of the concrete 111 becoming smooth.

The depth at which the claws 41 interfere with the concrete 111 is preferably 10 to 30 mm from the surface of the concrete 111.
Further, as shown in FIG. 4, it is preferable to provide a finishing screed for finishing the concrete (or mortar) 121 for applying the high durability layer 12 lined in the rear of the upper layer screed 32.

  As the supply device, it is preferable to use a concrete hopper 43 as shown in FIG. 4 or to use a belt conveyor 44 as shown in FIG. Using these, concrete is supplied from a concrete carrier or mobile concrete manufacturing apparatus.

Second Embodiment
FIG. 2: is a figure which shows an example of the floor slab structure 2 constructed by the construction method of the floor slab structure of the 1st Embodiment of this invention. First, the floor slab structure 2 of the present embodiment will be briefly described.

  As shown in FIG. 2, in the floor slab structure 2, a fiber reinforced concrete layer 22, a high durability layer 23, and an asphalt mixture layer 24 are formed on the floor slab 21.

  The floor slab 21 used in the present invention includes reinforced concrete floor slabs (RC floor slabs) and steel floor slabs used for bridges, expressways and the like.

  The fiber reinforced concrete layer 22 used in the present invention can be formed by kneading concrete containing cement, aggregate, fibers and water at a predetermined stirring speed and stirring time. Then, the fiber reinforced concrete layer 22 can be formed on the floor plate 21 by coating the fiber reinforced concrete on the floor plate 21.

As the cement used in the present invention, commonly used cements, for example, cements such as pneumatic cement and hydraulic cement can be used. In particular, generally used cements such as portland cement, alumina cement, jet cement, mixed cement and the like can be used.
The aggregates used in the present invention include fine aggregates and coarse aggregates. As fine aggregate, natural sand such as river sand and mountain sand, and artificial sand such as crushed sand and blast furnace slag fine aggregate can be used. Gravel and crushed stone can be used as the coarse aggregate.
The fibers used in the present invention include steel fibers, glass fibers, organic fibers, carbon fibers and the like.

  The high durability layer 23 used in the present invention contains a high durability material, and is formed of concrete or mortar. For example, the high durability layer 23 is formed on the fiber reinforced concrete layer 22 by coating concrete (mortar) containing cement, aggregate (sand), high durability material and water on the fiber reinforced concrete layer 22. can do. The cement and aggregate used in the high durability layer 23 are the same as the cement and aggregate used in the high durability layer 12 of the first embodiment.

  As the high durability material used in the present invention, durability such as waterproofness, water tightness, frost damage resistance, salt permeation resistance, alkali silica reaction resistance etc. of the floor slab structure 2 to be constructed is better than concrete or mortar An excellent material is also preferable, and it is preferable to contain, for example, at least one of ground granulated blast furnace slag, fly ash, short fibers, an expansive agent, and a polymer.

  For example, by adding 1.0 to 20% by mass of ground granulated blast furnace slag as a high-durability material, the air hole diameter after hardening becomes small and dense. Thereby, waterproofness, water tightness, resistance to salt permeation and resistance to alkali silica reaction are improved.

  Moreover, by adding 1.0 to 20% by mass of fly ash as a highly durable material to concrete (mortar), the air hole diameter after hardening becomes small and it becomes compact. Thereby, waterproofness, water tightness, resistance to salt permeation and resistance to alkali silica reaction are improved.

  Furthermore, as a high durability material, hardened by adding 1.0 to 25 mass% of a mixture of ground granulated blast furnace slag and fly ash in a ratio of 1.5 to 2.5: 1 of concrete (mortar) The air hole diameter after that becomes smaller and denser. Thereby, waterproofness, water tightness, resistance to salt permeation and resistance to alkali silica reaction are improved.

  Furthermore, by adding 0.1% to 2.0% by mass of a short fiber (concrete (mortar)) as a high-durability material, it becomes strong in tensile force, and cracking due to tensile force can be suppressed. This prevents the infiltration of moisture and salt from cracks, and improves waterproofness and resistance to salt penetration. Examples of short fibers include steel fibers, glass fibers, organic fibers, carbon fibers and the like.

  Moreover, tensile strength becomes strong by adding a polymer (1.0 to 20 mass% of a concrete (mortar)) as a highly durable material, and the crack by tensile force can be suppressed. This prevents the infiltration of moisture and salt from cracks, and improves waterproofness and resistance to salt penetration. As a polymer, SBR, EVA, PAE etc. are mentioned, for example.

  Furthermore, by adding 0.1 to 15% by mass of an expansive material as a highly durable material to concrete (mortar), the tensile force becomes strong, and cracking due to the tensile force can be suppressed. This prevents the infiltration of moisture and salt from cracks, and improves waterproofness, water tightness, resistance to frost damage, and resistance to salt permeation. Examples of the expansive material include quick lime-gypsum-based expansive material, gypsum-based expansive material, calcium sulfoaluminate-based expansive material, and the like.

  The high durability layer 23 is formed to a thickness of 1 mm to 30 mm. When the thickness of the high durability layer 23 is less than 1 mm, it is difficult to improve the durability of the floor slab structure 2, and when the thickness of the high durability layer 23 is greater than 30 mm, the fiber reinforced concrete layer 22 is simultaneously used. It is because it becomes difficult to set.

  Moreover, it is preferable that the drying shrinkage of the high durability layer 23 does not differ greatly from the drying shrinkage of the fiber reinforced concrete layer 22. If the drying shrinkage of the high-durability layer 23 and the drying shrinkage of the fiber-reinforced concrete layer 22 are significantly different, the difference in the shrinkage may cause cracks.

  Thus, the floor deck structure is provided by imparting durability such as waterproofness, water tightness, frost damage resistance, salt permeation resistance, alkali silica reaction resistance and the like to the high durability layer 23 and constructing on the surface. The durability of 2 can be improved.

  The asphalt mixture layer 24 used in the present invention is formed by coating an asphalt mixture. Asphalt mixtures used in the present invention include asphalt mixtures commonly used, for example, various asphalt mixtures such as fine particle size asphalt mixture, fine particle size gap asphalt mixture, fine particle size gap asphalt mixture, porous asphalt mixture and the like.

  Next, the construction method of the floor slab structure of the present embodiment will be described.

  First, in the case of construction on a new steel floor slab, general fiber reinforced concrete by kneading cement, aggregate, fibers, water and the like at a predetermined stirring speed and stirring time using a mobile concrete manufacturing apparatus Produce concrete for construction of 22. In addition, concrete for construction of the high durability layer 23 by kneading cement, aggregate (sand) water, high durability material, etc. at a predetermined stirring speed and stirring time using a mobile concrete manufacturing apparatus Or manufacture mortar).

  Next, using a concrete finisher, the concrete for laying the manufactured fiber reinforced concrete 22 is spread at a predetermined position on the floor plate 21 and the height is produced on the spread concrete. Concrete (or mortar) for applying the durable layer 23 is spread so as to have a thickness of 1 mm to 30 mm.

  In the case of construction on an existing concrete floor slab, the upper surface of the existing concrete floor slab is cut, an adhesive is applied, and it is manufactured at a predetermined position on the floor slab 21 using a concrete finishing device. The concrete for laying the fiber reinforced concrete 22 is laid, and the concrete (or mortar) for applying the manufactured high durability layer 23 on the laid concrete has a thickness of 1 mm to Spread it so that it will be 30 mm.

  Here, as in the first embodiment, concrete 111 for constructing the supplied fiber reinforced concrete 22 is spread by the lower layer screed 31 using the concrete finishing device 3 shown in FIG. A concrete (or mortar) 121 for applying the high durability layer 23 is laid by the upper layer screed 32.

  Subsequently, concrete 111 for applying fiber reinforced concrete 22 and concrete (or mortar) 121 for applying high durability layer 23 are provided by applying high frequency vibration by upper layer screed 32 of concrete finishing device 3. At the same time it is set and compacted. The concrete (or mortar) 121 for applying the high durability layer 12 is supplied onto the concrete 111 spread between the lower layer screed 31 and the upper layer screed 32 using a supply device.

  As in the first embodiment, it is preferable to use a concrete hopper 43 as shown in FIG. 4 or a belt conveyor 44 as shown in FIG. 5 as the supply device. Using these, concrete is supplied from a concrete carrier or mobile concrete manufacturing apparatus.

  As in the first embodiment, the claws 41 may be installed behind the lower layer screed 31 shown in FIG. 4 so as to interfere with the upper surface of the concrete 111 and swing the claws 41 laterally with respect to the traveling direction. preferable. Thereby, the surface of the fiber reinforced concrete 22 is finished to be rough, and the adhesiveness with the high durability layer 23 can be improved. Further, by installing the anti-vibration rubber 42 on the claws 41, it is possible to prevent the vibration of the lower layer screed 31 from being transmitted to the claws 41 and the roughened surface of the concrete 111 becoming smooth.

The depth at which the claws 41 interfere with the concrete 111 is preferably 10 to 30 mm from the surface of the concrete 111.
Further, as shown in FIG. 4, it is preferable to provide a finishing screed for finishing concrete (or mortar) 121 for applying the high-durability layer 12 laid on the rear side of the upper layer screed 32.

  Finally, by coating an asphalt mixture on the high durability layer 23 using an asphalt finisher, a floor in which the fiber reinforced concrete 22, the high durability layer 23 and the asphalt mixture layer 24 are formed on the floor plate 21 The plate structure 2 is constructed.

  As described above, after placing the fiber reinforced concrete 22, both can be integrated by placing the high durability layer 23 without putting time, so the durability of the floor slab structure 2 is improved. be able to. Further, the high-durability layer 23 capable of improving the durability can be economically provided as a thin layer.

  Further, at the time of pavement replacement, only the upper portion of the high durability layer 23 may be cut, and the fiber reinforced concrete layer 22 will not be cut.

  The present invention is not limited to the above embodiment, and various modifications and applications are possible. For example, in the above embodiment, for example, in the above embodiment, the present invention has been described by way of example of ground granulated blast furnace slag, fly ash, short fibers, expansive material, and polymer as high durability materials. Any material may be used as long as it is a material excellent in durability such as waterproofness, water tightness, frost damage resistance, salt permeation resistance, alkali silica reaction resistance and the like of the floor slab structure, and materials other than these may be used.

  The resistance to salt penetration of blast furnace slag powder and fly ash, which are highly durable materials, was verified. A 40 × 40 × 160 mm prismatic mortar specimen was prepared with the composition shown in Table 1. The five sides except the immersed side were epoxy-coated, placed vertically in a 3% aqueous NaCl solution, and allowed to permeate salt from the lower side for one year. The water level of the 3% NaCl aqueous solution was constant at 70 mm from the immersion surface. The powder was collected by grinding with a disc grinder every 1 mm until the surface layer 6 mm and thereafter every 3 mm, and the total salt amount was measured with a potentiometric titrator.

  The measurement results of total salt content of each sample are shown in FIG. It is confirmed that the sample 1 which is a common mortar penetrates saltiness to 21 mm from the surface in 3 months of immersion, 33 mm in 1 year of immersion, and more deeply in 2 years of immersion. On the other hand, it is confirmed that the penetration depth of chloride is shallower than 21 mm from the surface in 1 year of immersion and the penetration stops at 21 mm in 2 years of immersion, and the specimen 2 which blended the blast furnace slag fine powder is confirmed. It can be said that salt penetration resistance is higher than 1). In addition, it is confirmed that the penetration of the specimen 3 containing fly ash is stopped at 15 mm from the surface at 3 months of immersion and at 18 mm even after 1 year of immersion, indicating that the salt permeation resistance is superior to that of the specimen 1. Furthermore, it is confirmed that the penetration of the specimen 4 containing blast furnace slag fine powder and fly ash is stopped at 18 mm from the surface in 3 months of immersion and 18 mm even in 1 year of immersion, and the salt permeation resistance is superior to that of specimen 1 It could be confirmed.

  From the above, it was confirmed that ground granulated blast furnace slag and fly ash were effective as high durability materials.

  The present invention is suitable for a method of installing a floor slab structure having improved durability of the floor slab.

1, 2 floor slab structure 3 concrete finisher 11 concrete floor slab 12, 23 high durability layer 21 floor plate 22 fiber reinforced concrete layer 24 asphalt mixture layer 31 lower layer screed 32 upper layer screed 33 finish screed 41 claw 42 anti-vibration rubber 43 Concrete hopper 44 Belt conveyor

Claims (5)

A method of constructing a floor slab structure comprising a high durability material for improving the durability of the concrete floor slab on a concrete floor slab and forming a high durability layer comprising concrete or mortar,
A first screed for laying out the concrete forming the concrete floor slab;
And a second screed for laying out the concrete or mortar forming the high durability layer.
It installs using the device which has installed the nail | claw and the anti-vibration rubber behind the said 1st screed,
The concrete or mortar forming the high durability layer is supplied between the first screed and the second screed using a supply device,
In addition to laying out the concrete forming the concrete floor slab, laying out the concrete or mortar forming the high durability layer on the concrete , placing both of them simultaneously .
The claws whose screed vibration is blocked by the anti-vibration rubber interferes with the concrete forming the concrete floor slab and swings to the left and right with respect to the traveling direction, so that the upper surface of the concrete slab is spread. The construction method of the floor slab structure characterized by finishing to a rough surface . Floor structure with high durability layer consisting of concrete or mortar, on steel floor or reinforced concrete floor, including fiber reinforced concrete layer and high durability material to improve durability of steel floor or reinforced concrete floor The construction method of the body,
A floor slab structure characterized in that the concrete forming the fiber reinforced concrete layer is spread and the concrete or mortar forming the high durability layer is spread on the concrete and both are cast simultaneously. Construction method. A first screed leveling laid concrete to form a pre-Symbol fiber reinforced concrete layer,
And a second screed for laying out the concrete or mortar forming the high-durability layer.
The construction of the floor slab structure according to claim 2 , wherein the concrete or mortar forming the high-durability layer is supplied between a first screed and a second screed using a supply device. Method. Established the pawl and anti-vibration rubber to the rear of the first screed, pawl blocks the screed vibration by the vibration isolating rubber is advanced interfere with concrete to form a mat break was pre Symbol fiber reinforced concrete layer by swinging to the left and right with respect to the direction, finish the upper surface of the concrete to form a pre-Symbol fiber reinforced concrete layer leveling flooring roughened, construction of the floor plate structure according to claim 3, characterized in that Method.   The material according to any one of claims 1 to 4, wherein the high-durability material contains at least one of fly ash, ground fine blast furnace slag, short fibers, an expansive material and a polymer. Construction method of floor slab structure.