JP5946948B1 - Method for removing steel slab and concrete layer of steel slab - Google Patents

Abstract

To provide a steel slab capable of peeling and removing a concrete layer from a steel plate more reliably and easily without destroying everything with a concrete breaker. A steel floor slab 1 is formed of a deck plate 2 formed of a steel plate, a coating layer 4 formed of an epoxy resin primer to which thermally expandable microcapsules are added, and an epoxy resin adhesive. An adhesive layer 5, a fiber reinforced concrete layer 6, and an asphalt surface layer 7. The deck plate 2 is heated by the IH heating device arranged on the asphalt surface layer 7 to heat the coating layer 4, and the coating layer 4 is broken by the action of the thermally expandable microcapsules. Since the adhesive force of the fiber reinforced concrete layer 6 by the adhesive layer 5 to the deck plate 2 is reduced, the fiber reinforced concrete layer 6 is easily peeled from the deck plate 2. [Selection] Figure 1

Description

  The present invention relates to a steel deck having a concrete layer on a steel plate and a method for removing the concrete layer of the steel deck.

  Conventionally, a steel floor slab used for a road bridge is formed by arranging a pavement composed of a base layer made of goose asphalt and a surface layer made of dense grain asphalt on a deck plate made of steel plate. Many structures are adopted. This type of steel deck is relatively low in the rigidity of the deck plate. Therefore, when the load of the vehicle repeatedly acts on the deck plate, the welded portion between the U-rib that reinforces the deck plate and the deck plate, etc. There is a disadvantage that fatigue damage is likely to occur.

  As a structure of a steel floor slab that eliminates such inconvenience, there is a so-called SFRC (Steel Fiber Reinforced Concrete) pavement in which steel fiber reinforced concrete is arranged on a deck plate (for example, non-patent literature). 1). In SFRC pavement, the upper surface of the deck plate is polished by blasting if necessary, and then an epoxy adhesive is applied, followed by placing steel fiber reinforced concrete, and the asphalt material is placed on the steel fiber reinforced concrete. It is formed by laying a surface layer. This SFRC pavement prevents the deck plate from being damaged due to the load of the vehicle by joining the upper surface of the deck plate with steel fiber reinforced concrete, which has a relatively high strength, with an adhesive to reinforce the deck plate. Yes.

Takayoshi Kodama and 4 others, “Measures to improve fatigue durability of steel slabs by SFRC pavement”, Japan Society of Civil Engineers, August 2009, 12th Symposium on Steel Structures and Bridges, p. 83-96

  The steel slab provided with the SFRC pavement as described above needs to remove the steel fiber reinforced concrete from the steel slab when repairing or removing the road bridge. When removing a general concrete structure, a method of destroying and removing concrete with a concrete breaker is widely used. However, since steel fiber reinforced concrete with high strength is difficult to be destroyed by a concrete breaker, if all the steel fiber reinforced concrete is to be destroyed by a concrete breaker, there is a problem that a large amount of labor is required and noise is generated over a long period of time. Further, since the steel fiber reinforced concrete is firmly fixed to the deck plate with an adhesive, there is a problem that it is difficult to reliably peel the steel fiber reinforced concrete without remaining on the deck plate.

  Therefore, the object of the present invention is to provide a steel slab that can peel and remove the concrete layer from the steel plate more reliably and easily without destroying everything with the concrete breaker, and a method for removing the concrete layer from the steel slab. It is to provide.

In order to solve the above problems, the steel slab of the present invention comprises a steel plate,
Containing a thermally expandable microcapsule and covering the steel sheet;
An adhesive layer disposed on the covering layer;
And a concrete layer disposed on the adhesive layer.

  According to the said structure, the steel plate and the concrete layer are being fixed with the coating layer which coat | covers a steel plate, and the contact bonding layer arrange | positioned on this coating layer. Since the coating layer contains thermally expandable microcapsules, the adhesive force between the steel sheet and the adhesive layer can be reduced by heating the coating layer. Therefore, the concrete layer can be easily peeled off from the steel plate and removed.

  In the steel deck according to one embodiment, the concrete layer is made of fiber reinforced concrete.

  According to the above embodiment, the concrete layer is formed of fiber reinforced concrete containing reinforcing fibers, and has a higher strength than that of general concrete. Therefore, the concrete layer is destroyed by a concrete breaker or the like. Is difficult. Here, by heating the coating layer containing the thermally expandable capsule, the adhesive force between the adhesive layer and the steel plate that fixes the concrete layer to the steel plate can be reduced, so that the entire concrete layer does not have to be destroyed by a concrete breaker or the like. Can be easily peeled off from the steel sheet. Therefore, the concrete layer formed of fiber reinforced concrete can be removed from the steel deck with less effort and noise. Here, examples of the fiber contained in the fiber-reinforced concrete include metal fibers formed of steel or the like, organic fibers formed of nylon, vinylon, polypropylene, or the like, carbon fibers, and glass fibers.

  In the steel deck according to one embodiment, the covering layer is formed of an adhesive primer that forms the adhesive layer.

  According to the above embodiment, by forming a coating layer with an adhesive primer that forms the adhesive layer, and by including thermally expandable microcapsules in the coating layer, the adhesive strength of the adhesive layer to the steel sheet at room temperature before heating Can be secured sufficiently, while the adhesive force of the adhesive layer to the steel sheet can be effectively reduced by heating. Here, it is preferable that the primer is sufficiently adhered to the steel plate to form a film and has a high affinity with the adhesive forming the adhesive layer.

  In one embodiment, the coating layer is formed of an epoxy resin-based primer, and the adhesive layer is formed of an epoxy resin-based adhesive.

  According to the said embodiment, a concrete layer is firmly fixed to a steel plate by the coating layer formed with the epoxy resin-type primer and the adhesive layer formed with the epoxy resin-type adhesive at normal temperature before heating. On the other hand, the adhesive force of the adhesive layer to the steel sheet can be effectively reduced by heating the coating layer.

  In one embodiment, the thermally expandable microcapsule includes an outer shell formed of a polymer and a volatile expansion agent encapsulated in the outer shell.

  According to the above embodiment, when the thermally expandable microcapsule reaches a predetermined temperature, the liquid expander is vaporized, thereby expanding the outer shell and increasing the volume of the thermally expandable microcapsule. By heating the coating layer containing such thermally expandable microcapsules, the coating layer is damaged by the action of the thermally expandable microcapsules, and the adhesive force of the adhesive layer to the steel sheet can be effectively reduced. Here, the outer shell of the thermally expandable microcapsule is preferably formed of a thermoplastic polymer, and as such a polymer, a polymerization component containing a nitrile monomer, a non-nitrile monomer, and a crosslinking agent is used. It is preferable to use the formed one. The volatile swelling agent is a substance that becomes gaseous at a temperature below the softening point of the polymer forming the outer shell, and it is preferable to use a low-boiling organic solvent.

  Examples of the nitrile monomer include acrylonitrile, methacrylonitrile, α-chloroacrylonitrile, α-ethoxyacrylonitrile, and fumaronitrile. These may be used alone or in combination of two or more. Examples of the non-nitrile monomer include acrylic acid esters such as methyl acrylate, ethyl acrylate, butyl acrylate, and dicyclopentenyl acrylate, and methacrylic acid such as methyl methacrylate, ethyl methacrylate, butyl methacrylate, and isobornyl methacrylate. Examples include esters. These may be used alone or in combination of two or more. Examples of volatile swelling agents include low molecular weight carbonization such as ethane, ethylene, propane, propene, n-butane, isobutane, butene, isobutene, n-pentane, isopentane, neopentane, n-hexane, heptane, petroleum ether, and the like. Examples include hydrogen; chlorofluorocarbons such as CCl3F, CCl2F2, CClF3, and CClF2-CClF2; tetraalkylsilanes such as tetramethylsilane, trimethylethylsilane, trimethylisopropylsilane, and trimethyl-n-propylsilane. These may be used alone or in combination of two or more.

  The average particle size of the thermally expandable microcapsules is preferably 1 to 100 μm, and more preferably 5 to 70 μm. If the particle size of the thermally expandable microcapsules is too small, the effect of reducing the adhesive force between the steel sheet and the adhesive layer will not be sufficiently exhibited when the coating layer containing the thermally expandable microcapsules is heated. On the other hand, if the particle size of the thermally expandable microcapsules is too large, the adhesive force between the steel sheet and the adhesive layer cannot be sufficiently exhibited at room temperature. Here, the average particle diameter of the thermally expandable microcapsule in the present specification is a value measured by a laser diffraction scattering method.

  In the steel slab of one embodiment, the content of the heat-expandable microcapsules in the coating layer is a ratio of 33 to 70% with respect to the total mass of the material of the coating layer.

  According to the above embodiment, the concrete layer is fixed to the steel plate with sufficient strength at normal temperature before heating by containing the heat-expandable microcapsules in a ratio of 33 to 70% with respect to the total mass of the material of the coating layer. On the other hand, the adhesive force of the adhesive layer to the steel sheet can be effectively reduced by heating. Here, if the content of the thermally expandable microcapsule is less than 33%, the effect of reducing the adhesive force when the coating layer is heated may be insufficient. On the other hand, when the content of the heat-expandable microcapsule is larger than 70%, the viscosity of the material of the coating layer becomes excessive, and there is a possibility that abnormal application occurs when the material of the coating layer is applied on the steel plate. . In particular, the heat-expandable microcapsules are preferably in a proportion of 41 to 63% with respect to the total mass of the material of the coating layer. Here, the total mass of the material of the coating layer is the total of the mass of the thermally expandable microcapsule and the mass of the cured product of the resin that forms the coating layer. Does not include solvent mass. In addition to the substances derived from the resin main agent and the curing agent, the resin cured product may include a substance added as a resin material such as a filler.

  In the steel floor slab of one embodiment, the thermally expandable microcapsule has a foaming start temperature of 70 to 140 ° C and a maximum foaming temperature of 100 to 160 ° C.

  According to the above-described embodiment, the adhesive layer can be stably fixed to the steel plate by the adhesive layer because the adhesive layer is not capable of reducing the adhesive force due to the thermally expandable microcapsules of the coating layer at room temperature before heating. High rigidity can be maintained. In particular, even when the temperature of the steel slab reaches about 60 ° C. due to, for example, summer sunshine, sufficient adhesion between the steel plate and the adhesive layer can be ensured. On the other hand, when the concrete layer is removed from the steel slab, the heating temperature of the coating layer can be made 160 ° C. or lower, so the temperature of the steel plate covered by the coating layer can be made 160 ° C. or lower, Damage to the provided coating film can be effectively prevented. When the expansion start temperature of the thermally expandable microcapsule is lower than 70 ° C., the adhesive force of the concrete layer to the steel sheet may become insufficient due to the action of the thermally expandable microcapsule in summer. On the other hand, if the foaming start temperature of the thermally expandable microcapsule is higher than 140 ° C., the temperature of the steel sheet when heating the coating layer becomes excessive, and the coating film provided on the steel sheet may be damaged. Further, if the maximum foaming temperature of the thermally expandable microcapsule is lower than 100 ° C., the adhesive force of the concrete layer to the steel sheet may be insufficient due to the action of the thermally expandable microcapsule in summer. On the other hand, if the maximum foaming temperature of the thermally expandable microcapsule is higher than 160 ° C., the temperature of the steel sheet when heating the coating layer becomes excessive, and the coating film provided on the steel sheet may be damaged.

  In the steel floor slab of one embodiment, the amount of the primer applied is 5 to 50% of the amount of the adhesive applied.

  According to the said embodiment, the application amount of the primer containing a thermally expansible microcapsule is a ratio of 5 to 50% with respect to the application amount of the adhesive, so that the adhesive layer to the steel sheet at normal temperature before heating. While the adhesive force can be secured stably, the adhesive force of the adhesive layer to the steel plate can be effectively reduced by heating. Here, the thickness of the coating layer formed of the primer may be 5 to 50% with respect to the thickness of the adhesive layer. If the amount of primer applied is too small relative to the amount of adhesive applied, there is a possibility that the effect of reducing the adhesive force by the thermally expandable microcapsule cannot be obtained. On the other hand, if the amount of primer applied is too large relative to the amount of adhesive applied, the adhesion of the concrete layer to the steel sheet may be insufficient. In particular, the primer application amount is preferably 10 to 25% of the adhesive application amount.

The method for removing the concrete layer of the steel slab of the present invention is a method for removing the concrete layer of the steel slab,
Applying a magnetic field to the steel plate from above the concrete layer to heat the steel plate;
A step of heating the coating layer by heat generation of the steel plate to reduce an adhesive force between the steel plate and the adhesive layer.

  According to the above configuration, the steel plate, the thermal expansion microcapsule, the coating layer covering the steel plate, the adhesive layer disposed on the coating layer, and the concrete disposed on the adhesive layer About a steel slab provided with a layer, a magnetic field is applied to the steel plate from above a concrete layer, and the steel plate is heated. By heating the coating layer by the heat generation of the steel plate, the adhesive force between the steel plate and the adhesive layer is reduced by the action of the thermally expandable microcapsules. As a result, the concrete layer can be easily peeled off from the steel plate and removed.

  In the method for removing the concrete layer of the steel deck according to one embodiment, the heating temperature of the coating layer is 100 to 160 ° C.

  According to the above embodiment, when the coating layer is heated by the steel plate heated by applying a magnetic field from above the concrete layer, the heating temperature of the coating layer is 100 to 160 ° C. It is possible to effectively prevent damage to the coating film provided on the side opposite to the coating layer of the steel sheet while reducing the adhesive force between them.

It is sectional drawing which shows the steel deck of embodiment of this invention. It is sectional drawing which shows a 1st test body typically. It is sectional drawing which shows a 2nd test body typically. It is a top view which shows a 3rd test body typically. It is sectional drawing which shows a 3rd test body typically.

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

  FIG. 1 is a cross-sectional view showing a steel deck according to an embodiment of the present invention. The steel slab 1 is supported by a main girder and a horizontal girder and constitutes a superstructure of a road bridge. The superstructure including the steel deck 1 is supported by a steel or concrete pier. The steel slab 1 includes a deck plate 2 formed of a steel plate and a steel U trough 3 disposed on the lower surface of the deck plate 2. The U trough 3 is a vertical rib extending in the bridge axis direction, and is fixed to the lower surface of the deck plate 2 by welding. A coating film for preventing rust is provided on the lower surface of the deck plate 2 other than the portion covered with the member such as the U trough 3 and the outer surface of the U trough 3. In addition to the U trough 3, other vertical ribs such as a valve plate may be provided on the lower surface of the deck plate 2. Further, a transverse rib extending in a direction perpendicular to the bridge axis is provided on the lower surface of the deck plate 2. The steel deck 1 is supported by a main girder extending in the bridge axis direction and a horizontal girder extending in a direction perpendicular to the bridge axis. The main girder, the cross girder, the horizontal rib and the vertical rib are made of steel, and these members are fixed to the lower surface of the deck plate 2 by welding.

  This steel slab 1 includes a coating layer 4 provided on the upper surface of the deck plate 2, an adhesive layer 5 provided on the coating layer 4, and a fiber-reinforced concrete layer 6 provided on the adhesive layer 5. The asphalt surface layer 7 disposed on the fiber reinforced concrete layer 6 is provided.

  The covering layer 4 is provided so as to cover the upper surface of the deck plate 2 and is formed using an epoxy resin-based primer. The epoxy resin-based primer preferably uses a main component of bisphenol A type epoxy or bisphenol F type epoxy and a polyamine type or mercaptan type curing agent. The epoxy resin-based primer may include a coupling agent, a viscosity modifier, a curing accelerator, and the like in addition to the main agent and the curing agent. As such an epoxy resin-based primer, KS Primer II manufactured by Kashima Road Co., Ltd. can be used.

  This coating layer 4 is formed including thermally expandable microcapsules. The thermally expandable microcapsule is formed to include an outer shell formed of a polymer and a volatile expansion agent encapsulated in the outer shell. The outer shell polymer is preferably formed of a polymerization component containing a nitrile monomer, a non-nitrile monomer, and a crosslinking agent. As the volatile swelling agent, those formed with a low-boiling organic solvent are preferable. The thermally expandable microcapsule preferably has an average particle diameter of 1 to 100 μm, particularly an average particle diameter of 5 to 70 μm. The thermally expandable microcapsule preferably has a foaming start temperature of 70 to 140 ° C and a maximum foaming temperature of 100 to 160 ° C. As such thermally expandable microcapsules, Matsumoto Microsphere F, FN series manufactured by Matsumoto Yushi Seiyaku Co., Ltd. can be used.

  The content of the heat-expandable microcapsules in the coating layer 4 is preferably set to a ratio of 33 to 70%, particularly preferably 41 to 63% with respect to the total mass of the material of the coating layer 4.

  The adhesive layer 5 is provided on the coating layer 4 and is formed using an epoxy resin adhesive. The epoxy resin adhesive preferably uses a bisphenol A type epoxy or bisphenol F type epoxy main agent and a polyamine type or mercaptan type curing agent. The epoxy resin adhesive may include a coupling agent, a viscosity modifier, a curing accelerator, and the like in addition to the main agent and the curing agent. As such an epoxy resin adhesive, KS bond manufactured by Kashima Road Co., Ltd. can be used.

The application amount of the primer forming the coating layer 4 is set to 0.1 to 0.4 kg / m ² and the application amount of the adhesive forming the adhesive layer 5 is 1.0 to 2.0 kg / m ^2. m ² can be set. In particular, the coating amount of the primer is preferably 0.15~0.3kg / ^{m 2,} the coating amount of the adhesive is preferably 1.2~1.6kg / ^{m 2.} Here, the ratio of the primer coating amount is preferably 5 to 50%, particularly preferably 10 to 25%, based on the adhesive coating amount.

  The fiber reinforced concrete layer 6 is formed of fiber reinforced concrete that is reinforced with fibers. The fiber reinforced concrete layer 6 is formed including at least cement, fiber, and aggregate, and contains an admixture as necessary. Cement is not particularly limited, but portland cement such as ordinary Portland cement, early-strength Portland cement, ultra-high-strength Portland cement and low heat Portland cement, mixed cement such as blast furnace cement and silica cement, low heat generation cement and ultrafast cement Special cement such as cement can be used. Although it does not specifically limit as a fiber, The metal fiber formed with steel etc., the organic fiber formed with nylon, vinylon, polypropylene, etc., carbon fiber, glass fiber, etc. can be mentioned. The aggregate is not particularly limited, and river sand, mountain sand, land sand, sea sand, crushed sand, reclaimed sand, and the like can be used. The particle size of the aggregate preferably includes coarse aggregate and fine aggregate. The maximum particle size of the coarse aggregate is preferably 15 mm or less. As the admixture, water reducing agents, high performance water reducing agents, AE agents, setting retarders, swelling agents, and the like can be used.

  The fiber reinforced concrete layer 6 is preferably formed of steel fiber reinforced concrete (SFRC) using early-strength Portland cement or super-hard cement and steel fiber. In this case, the fiber reinforced concrete layer 6 is SFRC paved. Configure.

  The asphalt surface layer 7 is formed of an asphalt mixture. As the asphalt mixture, a dense particle size asphalt mixture, an open particle size asphalt mixture, a porous asphalt mixture, or the like can be used. Note that the steel slab may be provided with a concrete pavement in which the thickness of the fiber-reinforced concrete layer 6 is increased and the upper surface thereof is a pavement surface without providing the asphalt surface layer 7.

The coating layer 4 containing the thermally expandable microcapsule used for the steel deck 1 of this embodiment was tested to confirm the effect of reducing the adhesive strength by heating. In the test, as shown in FIG. 2, a coating layer 14 formed of a primer containing thermally expandable microcapsules and an adhesive layer 15 formed of an adhesive are arranged between two steel plates 11 and 11. The first test body 10 was used. In the first test body 10, four examples (Examples 1 to 4) in which the amount of thermally expandable microcapsules added to the coating layer 14 were set were set. Further, as Comparative Example 1, as shown in FIG. 3, the second test in which only the adhesive layer 25 containing the thermally expandable microcapsules was provided between the two steel plates 11, 11 without providing the coating layer. The test was performed using the body 13. For the first specimen 10, the coating layer 14, primer 0.3 kg / ^{m 2} coating to form a layer thickness of 0.2 mm, the adhesive layer 15, the adhesive 1.4 kg / ^{m 2} applied to The layer thickness was 1 mm. About the 2nd test body 13, the contact bonding layer 15 apply | coated 1.4 kg / m < ² > of adhesive agents, and formed it in the layer thickness of 1 mm. In each of the test bodies 10 and 13, KS primer II manufactured by Kashima Road Co., Ltd. was used as a primer, and KS bond manufactured by Kashima Road Co., Ltd. was used as an adhesive. Moreover, Matsumoto Microsphere F-30 manufactured by Matsumoto Yushi Seiyaku Co., Ltd. was used as the thermally expandable microcapsule. About these Examples and the comparative examples, after heating the test bodies 10 and 11 to 130 degreeC with a heating furnace, it was confirmed whether the two steel plates 11 and 11 were separable. Table 1 is a table | surface which shows the content rate of the thermally expansible microcapsule in an Example and a comparative example, and a test result. The test results are indicated by ◯ when the two steel plates 11, 11 can be separated, and by x when the separation is not possible. When the separation of the two steel plates 11 and 11 is impossible, the distance between the steel plates 11 and 11 changes, that is, the thickness of the coating layer 14 and the adhesive layer 15 existing between the steel plates 11 and 11. Or the change of the thickness of the contact bonding layer 15 was described by the increase rate with respect to the thickness before a test.

したがって、被覆層１４における熱膨張性マイクロカプセルの含有割合は、混合前のプライマーの材料、すなわち、フィラーを含む主剤と硬化剤の混合前の合計質量に対して、２５〜４５質量％であるのが特に好ましい。なお、他の実験により、混合前のプライマーの材料に対する熱膨張性マイクロカプセルの含有割合が２０〜５３質量％であってもよいことが確認された。ここで、熱膨張性マイクロカプセルの含有割合が２０質量％よりも小さいと、被覆層を加熱した時の接着力の低減効果が不十分になり、鋼板１１と鋼板１１を分離することができなかった。一方、熱膨張性マイクロカプセルの含有割合が５３質量％よりも大きいと、主剤と硬化剤と熱膨張性マイクロカプセルを混合した直後の材料の粘度が過大になり、この材料を鋼板１１上に塗布すると、材料が連続せずに途切れて、均一な膜が形成できなかった。 As can be seen from Table 1, the adhesive force between the steel plate 11 and the adhesive layer 15 can be reduced by containing thermally expandable microcapsules in the coating layer 14. Here, in Table 1, the content ratios of the heat-expandable microcapsules with respect to the coating layer 14 and the adhesive layer 15 are those in the stage before mixing the main component and the curing agent of the resin material forming the coating layer 14 or the adhesive layer 15. The content ratio of the thermally expandable microcapsule with respect to the total mass of That is, the primer forming the coating layer 14 is the total mass of the main agent and the curing agent including the filler before mixing, and the content ratio of the thermally expandable microcapsule with respect to the total mass of the material before the solvent evaporates. is there. The content ratio of the heat-expandable microcapsule with respect to the material containing the solvent before mixing of the primer and the content ratio of the heat-expandable microcapsule with respect to the material not containing the solvent after curing of the primer correspond as shown in Table 2 below. .

Therefore, the content ratio of the heat-expandable microcapsules in the coating layer 14 is 25 to 45% by mass with respect to the material of the primer before mixing, that is, the total mass before mixing of the main agent and the curing agent including the filler. Is particularly preferred. In addition, it was confirmed by other experiments that the content ratio of the thermally expandable microcapsule with respect to the material of the primer before mixing may be 20 to 53 mass%. Here, when the content ratio of the thermally expandable microcapsule is smaller than 20% by mass, the effect of reducing the adhesive force when the coating layer is heated becomes insufficient, and the steel plate 11 and the steel plate 11 cannot be separated. It was. On the other hand, when the content ratio of the heat-expandable microcapsule is larger than 53% by mass, the viscosity of the material immediately after mixing the main agent, the curing agent, and the heat-expandable microcapsule becomes excessive, and this material is applied onto the steel plate 11. As a result, the material was not continuous and a uniform film could not be formed.

  In Comparative Example 1 in which the adhesive layer 15 contains thermally expandable microcapsules, the viscosity of the adhesive increases with the addition of the thermally expandable microcapsules, so 27 mass% is the substantial upper limit of the content ratio. It was. In Comparative Example 1, although the thickness of the adhesive layer 15 increased by 24.2% by heating, the adhesive force was not reduced and the steel plates 11 could not be separated.

Next, the tensile test which measures the adhesive strength of the coating layer 4 used for the steel deck 1 of this embodiment and the contact bonding layer 5 was done using the 3rd test body. The adhesive strength was measured using a Kenken-type adhesive strength tester. For the standard value of adhesive strength, edited by the Public Works Research Institute and 3 other companies, “Joint Research on Fatigue Durability Improvement Technology for Steel Floor Bridges (Part 2, 3, 4) Report-Existing Steel Floor by SFRC Pavement” The design and construction manual (draft) on plate reinforcement, which conforms to the 4.5.6 adhesive application method, passed the average strength of 3 points of the third test specimen of 1.0 N / mm ² or more. It was. FIG. 4 is a plan view schematically showing the third test body, and FIG. 5 is a cross-sectional view schematically showing the third test body. The 3rd test body 20 was produced as follows. First, four circular through-holes with a diameter of about 110 mm are formed on the bottom plate of the other end of the steel box-shaped mold 21 having an inner dimension of 300 mm in width, 300 mm in depth, and 50 mm in height and opened at one end. To do. A steel loading jig 26 having a diameter of 100 mm is inserted into each of the four through-holes, and the bonding surface of the loading jig 26 is positioned so as to be flush with the bottom surface of the box-shaped mold 21. The seal material 23 is used to seal between the through hole and the loading jig 26. A primer containing thermally expandable microcapsules and an adhesive are applied to the bottom surface of the box-shaped form 21 and the bonding surface of the loading jig 26. Thereby, the coating layer 24 and the adhesive layer 25 are formed on the bottom surface of the box-shaped form 21 and the adhesive surface of the loading jig 26. Fiber reinforced concrete is cast inside the box-shaped form 21 to form a fiber reinforced concrete layer 22. When a predetermined age elapses after placement of the fiber reinforced concrete, the opening of the box-shaped formwork 21 is arranged vertically downward, and the connecting portion 27 provided on the side opposite to the bonding surface of the loading jig 26 is vertically upward. Turn to. A Kenken-type adhesive strength tester was connected to the connection portion 27 of the loading jig 26, and a tensile force was loaded on the loading jig 26 at a rate of 0.1 MPa / sec. The tensile force was loaded until one of the layers broke. The tensile test was performed at normal temperature before heating and after heating at 130 ° C. Heating was performed by putting the entire third specimen 20 into a heating furnace. Among the four loading jigs 26 of the third test body 20, one loading jig 26 performed a tensile test at normal temperature before heating, and the remaining three loading jigs 26 performed a tensile test after heating. .

セメントは太平洋セメント株式会社製のスーパージェットセメント、混練水は水道水、鋼繊維は神鋼建材工業株式会社製のシンコーファイバー・ドライミックス、細骨材は大阪府高槻市産の砕砂、粗骨材は大阪府高槻市産の硬質砂岩の砕石を用いた。また、減水剤として、花王株式会社製の高性能減水剤マイティ１５０と、凝結遅延剤として、小野田ケミコ株式会社製のジェットセッターを用いた。被覆層２４の塗布量と、被覆層２４が含有する熱膨張性マイクロカプセルの含有割合と、接着層２５の塗布量は、表４に示すとおりである。熱膨張性マイクロカプセルの含有割合は、主剤と硬化剤の混合前の合計質量に対する割合である。 Six examples (Examples 5 to 10) in which the coating amount of the coating layer 24, that is, the layer thickness, and the amount of thermally expandable microcapsules added to the coating layer 24 are different in the tensile test using the third test body 20. Set. The primer used was KS Primer II manufactured by Kashima Road Co., Ltd., and the adhesive used was KS Bond manufactured by Kashima Road Co., Ltd. As the fiber reinforced concrete forming the fiber reinforced concrete layer 22, the ones shown in Table 3 were used.

The cement is Super Jet Cement manufactured by Taiheiyo Cement Co., Ltd., the kneaded water is tap water, the steel fiber is Shinko Fiber Dry Mix manufactured by Shinko Construction Materials Co., Ltd., the fine aggregate is crushed sand and coarse aggregate from Takatsuki City, Osaka Prefecture Hard sandstone crushed stone from Takatsuki City, Osaka Prefecture was used. Moreover, the high performance water reducing agent Mighty 150 made from Kao Corporation was used as the water reducing agent, and the jet setter made by Onoda Chemico Co., Ltd. was used as the setting retarder. Table 4 shows the coating amount of the coating layer 24, the content ratio of the thermally expandable microcapsules contained in the coating layer 24, and the coating amount of the adhesive layer 25. The content rate of a thermally expansible microcapsule is a ratio with respect to the total mass before mixing of a main ingredient and a hardening | curing agent.

As test results, Table 4 shows the pass / fail of the tensile test before and after heating, and the position where the fracture occurred by the tensile test. The acceptance / rejection of the tensile test was evaluated as ○ when the tensile strength at break was 1.0 N / mm ² or more, and x when the tensile strength at break was less than 1.0 N / mm ² . As for the fracture position, “SFRC layer” indicates the fiber-reinforced concrete layer 22, and “coating layer / jig” indicates the interface between the coating layer 24 and the bonding surface of the loading jig 26.

As can be seen from Table 4, each of Examples 5 to 10 had a tensile strength greater than 1.0 N / mm ² at room temperature before heating, and was broken by the fiber-reinforced concrete layer 22. Therefore, the covering layer 24 and the adhesive layer 25 can exhibit a sufficient adhesive force between the fiber reinforced concrete layer 22 and the steel loading jig 26. In addition, in all of Examples 5 to 10, after heating to 130 ° C., immediately after loading of the tensile force, it was broken at the interface between the coating layer 24 and the bonding surface of the loading jig 26, and the tensile strength at this time was substantially It was zero. Therefore, it can be said that the adhesive force between the steel loading jig 26 and the fiber reinforced concrete layer 22 can be effectively reduced by heating the coating layer 24 to 130 ° C. in any of Examples 5 to 10.

  The steel deck 1 of this embodiment is constructed as follows. First, an epoxy resin-based primer containing thermally expandable microcapsules is applied to the upper surface of the deck plate 2 to form the coating layer 4. Subsequently, an epoxy resin adhesive is applied to the upper surface of the coating layer 4 to form the adhesive layer 5. Subsequently, fiber reinforced concrete is cast on the upper surface of the adhesive layer 5 to form the fiber reinforced concrete layer 6. The covering layer 4, the adhesive layer 5, and the fiber reinforced concrete layer 6 are preferably formed with a relatively short time. As a result, the curing of the primer forming the covering layer 4, the curing of the adhesive forming the adhesive layer 5, and the curing of the fiber reinforced concrete forming the fiber reinforced concrete layer 6 proceed substantially simultaneously, The covering layer 4, the adhesive layer 5, and the fiber reinforced concrete layer 6 are effectively attached. As a result, the deck plate 2 and the fiber reinforced concrete layer 6 can be effectively integrated. Subsequently, after the fiber reinforced concrete forming the fiber reinforced concrete layer 6 is cured to a certain degree, an asphalt mixture 7 is laid on the upper surface of the fiber reinforced concrete layer 6 to form the asphalt surface layer 7.

  The steel floor slab 1 thus constructed may be a reinforced steel floor slab of an existing road bridge. That is, the deck plate 2, the ribs and girders on the lower surface of the deck plate 2, and the substructure such as the bridge pier that supports them may be existing ones. Further, the steel deck 1 may constitute a newly constructed road bridge. That is, the entire structure including the substructure and the superstructure including the steel deck 1 may be newly constructed.

  In the road bridge having the steel slab 1 of the above embodiment, the fiber reinforced concrete layer 6 and the asphalt surface layer 7 are removed from the steel slab 1 during repair or removal. Removal of the fiber reinforced concrete layer 6 and the asphalt surface layer 7 is performed as follows. First, a cutting line is formed by a concrete cutter so that the fiber-reinforced concrete layer 6 and the asphalt surface layer 7 are divided into sizes that can be easily transported. The cutting line is formed at a depth reaching the vicinity of the lower surface of the fiber-reinforced concrete layer 6. Subsequently, an IH (Induction Heating) type heating device is installed on the asphalt surface layer 7. The IH heating device includes an electromagnetic induction coil and a power supply device that supplies electric power to the electromagnetic induction coil, and is configured to be movable by human power or a vehicle. Next, the IH heating device is operated, and a varying magnetic field is applied from above the asphalt surface layer 7 to the deck plate 2 by an electromagnetic induction coil. Thereby, an eddy current is generated in the deck plate 2, and the deck plate 2 is heated by the Joule heat of the eddy current. The heating temperature of the deck plate 2 by the IH heating device corresponds to the maximum foaming temperature of the thermally expandable microcapsule of the coating layer 4 and is set to 100 to 160 ° C. When the deck plate 2 generates heat, the coating layer 4 is heated by this heat, and the thermally expandable microcapsules contained in the coating layer 4 are heated. The coating layer 4 is damaged by the action of the heat-expandable microcapsule heated to the maximum foaming temperature, thereby reducing the adhesive force of the fiber-reinforced concrete layer 6 by the adhesive layer 5 to the deck plate 2. Thereafter, a scraper, a heavy machinery shovel or the like is inserted into the dividing line, and the vicinity of the dividing line between the fiber reinforced concrete layer 6 and the asphalt surface layer 7 is lifted. Thereby, the fiber reinforced concrete layer 6 is peeled from the deck plate 2, and the fiber reinforced concrete layer 6 and the asphalt surface layer 7 are divided along the dividing line. The divided fiber reinforced concrete layer 6 and the asphalt surface layer 7 are transported by a heavy machine or the like and removed from the steel deck 1.

  Thus, in the steel floor slab 1 of this embodiment, the coating layer 4 containing thermally expandable microcapsules is provided between the deck plate 2 and the adhesive layer 5 to which the fiber-reinforced concrete layer 6 is bonded. By heating the deck plate 2, the adhesive force by the adhesive layer 5 can be effectively reduced. Therefore, the fiber reinforced concrete layer 6 can be easily peeled from the deck plate 2 and removed from the steel deck 1. In addition, since it is not necessary to destroy the high-strength fiber reinforced concrete layer 6 with the concrete breaker attached to the deck plate 2, the fiber can be produced with little effort and without generating noise over a long period of time. The reinforced concrete layer 6 can be removed. Moreover, when the steel slab 1 of this embodiment removes the fiber reinforced concrete layer 6, the exothermic temperature of the deck plate 2 corresponds to the maximum foaming temperature of the thermally expandable microcapsule of the coating layer 4 to 100 to Since it is set to 160 ° C., it is possible to prevent inconvenience that the coating film on the lower surface of the steel deck 1 is damaged.

  In this embodiment, the deck plate 2 of the steel slab 1 has a bolt head at the abutting portion, and a stud for enhancing the integration with the fiber-reinforced concrete layer 6 may be protruded. . In this case, a primer containing thermally expandable microcapsules is also applied to the surface of the bolt head or stud to form the coating layer 4, and an adhesive is applied thereon to form the adhesive layer 5. A reinforced concrete layer 6 is formed. Thereby, when removing the fiber reinforced concrete layer 6, the adhesive force of the adhesive layer 5 to the bolt head and stud can be effectively reduced by heating the bolt head and stud together with the deck plate 2.

  In the said embodiment, although the steel deck 1 was provided with the fiber reinforced concrete layer 6, you may provide the concrete layer formed with the concrete which does not contain a reinforcement fiber. For example, a deck plate formed of a steel plate, a reinforcing bar disposed on the deck plate, a concrete layer provided to include the reinforcing bar on the deck plate, and an asphalt layer provided on the concrete layer The present invention can be applied to a concrete synthetic steel slab having In this case, a coating layer containing thermally expandable microcapsules is formed on the upper surface of the deck plate, an adhesive layer is formed on the coating layer, and a concrete layer is formed on the adhesive layer. Thereby, when repairing or removing the concrete composite steel slab, the concrete layer can be easily separated from the deck plate by heating the coating layer by heating the deck plate with an IH heating device or the like.

DESCRIPTION OF SYMBOLS 1 Steel deck 2 Deck plate 3 U trough 4 Coating layer 5 Adhesion layer 6 Fiber reinforced concrete layer 7 Asphalt surface layer

Claims (8)

Steel sheet,
Formed with an epoxy resin-based primer, containing thermally expandable microcapsules, and a coating layer covering the steel sheet;
An adhesive layer formed of an epoxy resin adhesive and disposed on the covering layer;
A steel floor slab comprising a concrete layer disposed on the adhesive layer and formed of cement . In the steel deck according to claim 1,
The steel floor slab, wherein the concrete layer is formed of fiber reinforced concrete. In the steel deck according to claim 1,
The thermally expandable microcapsule includes a shell formed of a polymer and a volatile swelling agent encapsulated in the shell. In the steel deck according to claim 1,
The steel floor slab, wherein the content of the thermally expandable microcapsules in the coating layer is a ratio of 33 to 70% with respect to the total mass of the material of the coating layer. In the steel deck according to claim 1,
The thermally expandable microcapsule has a foaming start temperature of 70 to 140 ° C and a maximum foaming temperature of 100 to 160 ° C. In the steel deck according to claim 1 ,
The steel floor slab, wherein the amount of the primer applied is 5 to 50% of the amount of the adhesive applied. A method for removing a concrete layer of a steel slab according to claim 1,
Applying a magnetic field to the steel plate from above the concrete layer to heat the steel plate;
A method for removing a concrete layer of a steel slab, comprising: heating the coating layer by heat generation of the steel plate to reduce an adhesive force between the steel plate and the adhesive layer. In the removal method of the concrete layer of the steel deck according to claim 7 ,
The method for removing a concrete layer from a steel slab, wherein the heating temperature of the coating layer is 100 to 160 ° C.

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