JP5974157B1 - Reinforced structure of reinforced concrete structure - Google Patents

Abstract

To provide a reinforcing structure for a reinforced concrete structure that satisfies both strength and toughness at the same time. The entire surface of a reinforced concrete column with a slab is covered with a column grout material, and a column reinforcing rod is embedded in the column grout material along the longitudinal direction of the reinforced concrete column. A reinforcing sheet 24 is disposed so as to cover the grout material 22 for columns, and the lower portions of the concrete beams 25a, 25b, 25c, 25d connecting the reinforced concrete columns and the reinforced concrete columns are covered with the beam grout material 26, and the beams A beam reinforcing rod 27 is embedded in the grout material 26 along the longitudinal direction of the concrete beams 25a, 25b, 25c, 25d, and a reinforcing sheet 29 is disposed so as to cover the beam grout material 26. [Selection] Figure 5

Description

  The present invention relates to a reinforcing structure for reinforcing an existing reinforced concrete structure.

  Reinforced concrete columns such as building structures may deteriorate over time, resulting in a lack of seismic strength, or may already lack seismic strength at the time of new construction. In such a case, reinforcement of reinforced concrete is required. As a reinforcement structure for that purpose, Patent Document 1 discloses a structure shown in FIG.

  This conventional reinforced concrete reinforcing structure reinforces a reinforced concrete column 61 having a square cross-sectional shape in a direction perpendicular to the longitudinal direction. That is, a pair of surrounding steel plates 62 and 62 are provided, and the surrounding steel plates 62 and 62 are formed so as to form a rectangular column having a hollow inside by abutting each abutting portion 63a and 63b. The square columns made of these enclosed steel plates 62 and 62 maintain a dimensional relationship that is slightly thicker than the reinforced concrete columns 61.

  In order to reinforce the reinforced concrete column 61 using the pair of surrounding steel plates 62 and 62 as described above, the following is performed. First, the periphery of the reinforced concrete column 61 is surrounded by a pair of surrounding steel plates 62 and 62, and the butted portions 63a and 63b are butted. The butted portions 63a and 63b are welded to bond the surrounding steel plates 62 and 62 to each other. Reference symbols y and y are welds.

  If the enclosure steel plates 62 and 62 are welded and bonded together as described above, the square column formed thereby becomes thicker than the reinforced concrete column 61, so that the enclosure steel plates 62 and 62 and the reinforced concrete column 61 are between them. An interval h is formed. Then, a grout material is filled in the interval h, the surrounding steel plates 62 and 62 are brought into close contact with the reinforced concrete column 61, and the reinforced concrete column 61 is reinforced.

Japanese Patent No. 3860791

  Current seismic reinforcement technology for buildings is roughly divided into strength type and toughness type. The strength form is realized, for example, by incorporating a seismic wall in a building. Further, the toughness shape is realized mainly by a reinforced concrete column. The criteria for seismic performance is evaluated by a numerical value obtained by multiplying an index representing strength and toughness, and it is ideal to balance strength and toughness.

  However, in an existing building, if it is going to realize strength form with the above-mentioned seismic wall, it will be necessary to build a new wall surface in the existing building, which is practically impossible, and the strength of the reinforced concrete column To achieve both strength and toughness.

  However, in the conventional reinforced concrete column reinforcement structure shown in FIG. 10, the existing reinforced concrete column 61 is surrounded by the surrounding steel plates 62 and 62, and the butted portions 63a and 63b are welded. Although it could be maintained, there was a problem that the reliability of field welding was inferior. In addition, if the strength is to be increased with this conventional reinforcing structure, the thickness of the surrounding steel plates 62 and 62 must be increased. However, as the thickness of the surrounding steel plates 62 and 62 is increased, the cost is increased correspondingly, and there is a problem that the weight is increased by the increased thickness and workability is deteriorated. Because of these problems, it was a reality that the reinforcement of reinforced concrete columns alone did not provide sufficient strength to cover the functions of the above-mentioned seismic walls.

  Thus, none of the conventional reinforced concrete reinforcing structures satisfy both the strength and the toughness at the same time. Accordingly, an object of the present invention is to provide a reinforcing structure for a reinforced concrete structure that satisfies both strength and toughness at the same time.

  In order to solve the above-mentioned problems, the present invention covers the entire surface of a reinforced concrete column with a wall or a slab with a grout material for a column, and a reinforcing rod is placed along the longitudinal direction of the reinforced concrete column in the column grout material. The reinforcing sheet is placed so as to cover the above-mentioned grout material, and the lower part of the concrete beam connecting the reinforced concrete column and the reinforced concrete column is covered with the beam grout material, and is reinforced in the beam grout material. A rod is embedded along the longitudinal direction of the concrete beam, and a reinforcing sheet is disposed so as to cover the beam grout material.

  Since the strength increases as the number of reinforcing sheets increases, it is preferable to adopt a multilayer structure in which a plurality of reinforcing sheets are stacked. Moreover, when a reinforcement sheet consists of a multilayer structure, it is preferable that the arrangement direction of the reinforcement sheet of each layer differs. And it is especially preferable that the arrangement | positioning direction of the reinforcement sheet of each layer differs 90 degrees (perpendicular).

  The reinforcing rod and the reinforcing sheet are preferably made of aramid fibers.

The reinforcing rod embedded in the beam grout material preferably penetrates into the reinforced concrete column. When the diameter of the reinforcing rod is D, it is preferable that the reinforcing rod embedded in the beam grout material penetrates the reinforced concrete column by a length of at least 4D.
When the reinforced concrete column has a square cross section and the length of one side of the square is L, the reinforcing rod embedded in the beam grout material has a length of at least L × 0.1 in the reinforced concrete column. It is preferable to invade only. When a reinforced concrete column has a rectangular cross section, the long side of the rectangle is M and the short side is N, the reinforcing rod embedded in the grouting material for the beam is placed in the reinforced concrete column. It is preferable to penetrate by a length of at least M × 0.1 and N × 0.1. In this way, the reinforcing rod embedded in the beam grout material penetrates into the reinforced concrete column at least four times the diameter of the reinforcing rod, or from each side of the square section of the reinforced concrete column, respectively. The reinforcing rod embedded in the grout material for the beam penetrates the column by 0.1 times the length of one side of the square, or from each side of the rectangular cross section of the reinforced concrete column, In addition, it is preferable that the reinforcing rod embedded in the beam grout material penetrates by a length of 0.1 times the length of one side of the rectangle.

  ADVANTAGE OF THE INVENTION According to this invention, the reinforcement structure of the reinforced concrete structure which can satisfy intensity | strength and toughness simultaneously can be provided.

FIG. 1 is a front view showing an example of a braid made of an aramid fiber that is a material of a reinforcing rod of the present invention. FIG. 2 is a schematic view showing a method for producing a resin-impregnated braid when a sanding step is added. FIG. 3 is a schematic view showing a resin-impregnated braid which is an example of the reinforcing rod of the present invention. 4 (a) to 4 (c) are photographs showing the appearance of examples of the reinforcing sheet of the present invention. Fig.5 (a)-(f) is the schematic which contains the cross section of the reinforcement structure of the reinforced concrete structure of this invention, Fig.5 (a) is a figure which shows the cross section of a horizontal direction of the reinforced concrete pillar with a slab, FIG. (B) is a front view including a longitudinal section of a reinforced concrete column with a slab, FIG. 5 (c) is a sectional view taken along the line CC of FIG. 5 (a), and FIG. 5 (d) is a sectional view of FIG. 5D is a cross-sectional view taken along the arrow D-D, FIG. 5E is a cross-sectional view taken along the line E-E in FIG. 5B, and FIG. 5F is a cross-sectional view taken along the line F-F in FIG. FIG. 6 (a) is a perspective view of a part of a reinforced concrete column of the present invention, and FIG. 6 (b) is a part of a reinforcing sheet covering a concrete beam and slab and embedded in a grout material for a beam. It is a perspective view which shows a part of reinforcement rod. 7 (a) to 7 (e) are cross-sectional views showing various reinforcing structures of the reinforced concrete structure. FIG. 8A is a diagram for explaining a bending test method, and FIG. 8B is a diagram for explaining a method for obtaining the relationship between the load and the displacement shown in FIG. FIG. 9 is a diagram illustrating a relationship between a load and a displacement amount in a bending test of various reinforcing structures of a reinforced concrete structure. FIG. 10 is a perspective view of a conventional reinforced concrete reinforcing structure.

The form for implementing this invention is demonstrated below.
《Aramid fiber》
The material for the reinforcing rod and the reinforcing sheet in the present invention is preferably an aramid fiber. Aramid fibers are extremely useful engineering plastics that are characterized by high strength and light weight, high durability, excellent shock absorption, non-conductivity and non-magnetic properties. The aramid fiber is a para-aramid fiber or a meta-aramid fiber. Examples of para-aramid fibers include polyparaphenylene terephthalamide (trade name “Kevlar” manufactured by Toray DuPont) and copolyparaphenylene-3,4′-diphenyl ether terephthalamide (trade name “Technola” manufactured by Teijin Techno Products). ) Etc. Examples of meta-aramid fibers include polymetaphenylene isophthalamide (trade name “NOMEX” manufactured by DuPont).

  As the aramid fiber, para-aramid fiber excellent in high strength, high elastic modulus, and heat resistance is preferable, and polyparaphenylene terephthalamide (hereinafter referred to as “PPTA”) excellent in cut resistance is particularly preferable. PPTA is a polymer obtained by polycondensation of terephthalic acid and paraphenylenediamine, and a copolymer obtained by copolymerizing a small amount of dicarboxylic acid and diamine can also be used.

  The single yarn fineness in the aramid fiber is 3.5 to 10 dtex, preferably 4.0 to 8.0 dtex. When the single yarn fineness is less than 3.5 dtex, the single yarn strength is weak, and it is not preferable because the single yarn breakage is likely to be caused by the frictional resistance received from the roll or guide in the process before applying the oil agent. On the other hand, when the single yarn fineness exceeds 10 dtex, the desulfurization efficiency at the time of spinning is remarkably lowered, and this is not preferable because the productivity is remarkably lowered.

  The total fineness of the aramid fiber of the present invention is in the range of 10 to 100 dtex, preferably 20 to 100 dtex, more preferably 30 to 100 dtex. When the total fineness is less than 10 dtex, the amount of polymer discharged during spinning becomes excessively small and it becomes difficult to maintain a stable discharge state, so that it is difficult to stably produce aramid fibers. On the other hand, when the total fineness exceeds 100 dtex, the contact area with the roll guide increases and the coefficient of friction increases, so that fluff and single yarn breakage are likely to occur.

  The number of filaments constituting the aramid fiber is 2 to 28. For example, by bundling about 20 5 dtex single yarns, the total fineness becomes 100 dtex.

  The tensile strength of the single yarn of aramid fiber is preferably 15 cN / dtex or more, more preferably 18 cN / dtex or more, and particularly preferably 21 cN / dtex or more. This is because if it is 15 cN / dtex or more, the function as a high-strength fiber can be sufficiently exhibited. From this point, a para-aramid fiber is desirable.

《Reinforcement sheet》
The reinforcing sheet is made of a woven fabric or a knitted fabric of constituent fibers. The constituent fiber is preferably an aramid fiber. For example, in order to obtain a reinforcing sheet made of a woven fabric, as a method of weaving single yarns of constituent fibers, “weaving method in which warp yarns and weft yarns are regularly and alternately disclosed” is used. If there is no crossing and there is one tolerance, then there is a 1x2 weaving and then 1x3 weaving, and a 1x3 weaving one more, and so on. Only weaving is a weave with a lot of luster that appears to be on the surface. "Shuko weaving", "Weaving based on other weaving methods such as plain weaving and satin weaving, on top of which we put the color yarn we want to be the background `` A certain '' solid weave, `` It is the best weaving method for expressing fine patterns and characters, and by using special yarn or increasing the yarn density, you can reproduce fine patterns and characters that can not be expressed with normal weaving method High density weaving, which is a weaving method, and a weaving method that is resistant to shrinkage and distortion. "Non-shrinking weave", "Weaving with a dull look like a pear surface" pear texture and "Impact weaving without entangled texture" be able to.

  Further, as a reinforcing sheet made of a knitted fabric, a unidirectional sheet (FIG. 4A) knitted so that the constituent fibers are arranged in one direction, and knitted so that the constituent fibers are arranged in two directions intersecting at right angles. Examples thereof include a bi-directional sheet (FIG. 4B), a mesh sheet obtained by knitting constituent fibers into a mesh shape (FIG. 4C), and the like.

《Reinforcing rod》
The reinforcing rod can be obtained, for example, by impregnating a braid made of aramid fiber with a binder resin and curing it. This resin-impregnated braid can be manufactured, for example, by a method as shown in FIG. In FIG. 2, 1 is a feeding roller, 2 is a tension roller, 3 is a binder resin tank, 4 is a braid of raw materials, 5 is a heating furnace, 6 is a heating furnace, 7 is a resin impregnation process, 8 is a sanding process, 9 is Curing step, 10 is a cutting step, 11 is a resin-impregnated braid, and 12 is a take-up roller. That is, the braid 4 (see FIG. 1) not impregnated with resin is fed from the feed roller 1 and passed through the binder resin tank 3 so that the braid 4 is impregnated with binder resin (epoxy resin), and the braid 4 is tensioned. In order to improve the adhesion (adhesiveness) in the sanding step 8, sand, silica fume and other granular materials are adhered to the braid 4 in order to improve the adhesion (adhesiveness) in the heating furnace 5 through the tension roller 2 that gives The resin-impregnated braid 11 (see FIG. 3) can be obtained by curing the resin in the heating furnace 6 and cutting it into an appropriate length through the take-off roller 12 in the cutting step 10. As the assembly pitch p and the diameter d of the resin-impregnated braid 11 that can be obtained in this manner, an appropriate one can be adopted depending on the application.

  Since the resin-impregnated braid manufactured as described above can loosen the structure of the braid, there is no problem that the binder resin is difficult to be impregnated into the braid, it is lightweight, and adheres to concrete or grout material. (Strength, heat resistance, etc.) Since the resin-impregnated braid manufactured as described above does not use iron, it is excellent in rust prevention. The resin-impregnated braid manufactured as described above is particularly useful in the field of civil engineering and construction as a substitute for reinforcing bars because of its characteristics.

A resin-impregnated braid obtained by impregnating a binder resin made of aramid fiber with a binder resin and curing is commercially available. For example, product number RA15 (diameter: 15.7 mm, yield strength: 225 kN, Young's modulus, manufactured by Fivex Corporation) 68.6 kN / mm ² ) or product number TF-15R (diameter: 15.7 mm, yield strength: 225 kN, Young's modulus: 68.6 kN / mm ² ) manufactured by Takeiri Seisakusho Co., Ltd. can be used as the reinforcing rod of the present invention.

《Reinforcement method for reinforced concrete columns》
As an example of the reinforcement method of the reinforced concrete pillar by this invention, it can carry out in the following process order.
(1) Groundwork inspection A reinforced concrete column is subjected to a percussion inspection, and if there are floating parts (such as gaps or spaces) as judged from the detected sound, the floating parts are removed and special polymer cement or thermosetting is removed. The floating part is repaired with a resin added with necessary additives (hereinafter also referred to as repair material). Moreover, a hole is made in the surface of the reinforced concrete column so as to communicate with the floating portion, and the repair material is injected into the floating portion from the hole. Furthermore, if there is a crack on the surface of the reinforced concrete column, the repair material is injected into the crack.

(2) Foundation adjustment The surface of the reinforced concrete column is polished with a polishing machine such as an electric filer (sander) to remove protrusions on the surface.

(3) Attaching the reinforcing rod Drill a hole in the underground foundation or underground beam, insert the reinforcing rod into the drilled hole, and fix the reinforcing rod to the reinforced concrete column with the mounting bracket. Drill holes in the slabs and ceiling slabs on the ground, insert the reinforcing rods into the holes, and fix the reinforcing rods to the reinforced concrete columns with known fittings. And each reinforcement rod from the reinforcement rod inserted in the drilling hole of the underground foundation or the underground beam to the uppermost reinforcement rod is connected. Grouting material is filled into the drilling holes of the foundation foundation or underground beam, and the slabs on each level of the ground and the slabs on the ceiling side. The uppermost reinforcing rod is fixed to the ceiling side slab with a known mounting bracket. As the grout material, cement (mortar), glass, synthetic resin, or the like can be used.

(4) Primer application Apply an appropriate primer to the surface of a reinforced concrete column.
(5) Formwork material installation Formwork material is installed around the reinforced concrete pillars with a predetermined interval, and the intermediate part in the height direction is used to prevent the formwork material from bending as required. Install anti-bending material.
(6) Filling the grout material Fill the gap between the reinforced concrete column and the formwork material with the grout material. The formwork is removed after the grout is dried.

(7) Attaching the reinforcing sheet Remove the fragile layer from the surface of the grouting material by peeling or polishing it appropriately, scraping the corners in some cases, rounding them appropriately, and filling the recessed parts with putty etc. Correct a non-planar surface to a flat surface. After such a base treatment, a primer resin is applied to the surface of the grout material and dried. The primer is usually the same type as the resin impregnated in the reinforcing sheet. A primer is applied to the surface of the grout material, and after sufficient drying, an adhesion / impregnation resin is applied thereon. Immediately after application, a reinforcing sheet is applied, and the air that has entered between the grout material and the reinforcing sheet is removed using a roller or the like. Then, the reinforcing sheet is sufficiently impregnated with the resin. After confirming that the undercoat resin for adhesive bonding is sufficiently impregnated, the same resin is used for overcoating.

  Keep curing until the resin is completely cured. Depending on the degree of reinforcement, multiple layers of reinforcing sheets are applied. In that case, the above steps are repeated. In this case, it is not always necessary to wait for the resin to cure. When it is confirmed that the topmost reinforcing sheet has been pasted and the resin has been completely cured, finishing is applied as necessary to improve durability and fire resistance.

  The present invention will be described below with reference to examples, but various changes and modifications can be made without departing from the technical scope of the present invention, and it goes without saying that the present invention is not limited to the following examples. Yes.

[Example of Reinforcement Structure of Reinforced Concrete Structure of the Present Invention]
Fig.5 (a)-(f) is the schematic which contains the cross section of the reinforcement structure of the reinforced concrete structure of this invention, Fig.5 (a) is a figure which shows the cross section of a horizontal direction of the reinforced concrete pillar with a slab, FIG. (B) is a front view including a longitudinal section of a reinforced concrete column with a slab, FIG. 5 (c) is a sectional view taken along the line CC of FIG. 5 (a), and FIG. 5 (d) is a sectional view of FIG. 5D is a cross-sectional view taken along the arrow D-D, FIG. 5E is a cross-sectional view taken along the line E-E in FIG. 5B, and FIG. 5F is a cross-sectional view taken along the line F-F in FIG.

  In FIG. 5A, the entire periphery of the reinforced concrete column 21 is covered with a column grout material 22, and four column reinforcing rods 23 are provided in the column grout material 22 along the longitudinal direction of the reinforced concrete column 21. A reinforcing sheet 24 is disposed so as to be buried and cover the grout material 22 for pillars. The lower parts of the concrete beams 25a, 25b, 25c, 25d connecting the reinforced concrete columns and the reinforced concrete columns shown in FIG. 5 (a) are covered with the beam grout material 26 shown in FIG. 5 (c). Three beam reinforcing rods 27 are embedded in the beam grout material 26 for each concrete beam along the longitudinal direction of the concrete beams 25a, 25b, 25c, 25d. A reinforcing sheet 29 is arranged so as to cover each concrete beam, the beam grout material 26 and a part of the concrete slab 28.

  As shown in FIG. 5E, twelve reinforcing bars 30 are embedded in the reinforced concrete column 21 along the longitudinal direction of the concrete. Needless to say, the number of reinforcing bars and reinforcing rods can be variously changed according to the required conditions.

  As shown in FIG. 5 (a), the reinforcing rod 27 embedded in the beam grout material 26 penetrates into the reinforced concrete column 21. Now, assuming that the length of one side of the square of the reinforced concrete column 21 having a square cross section is L, it is preferable that the reinforcing rod 27 penetrates into the reinforced concrete column 21 by a length of at least 0.1 L. As the penetration length of the reinforcing rod 27 into the reinforced concrete column 21 increases, the strength of the reinforced concrete structure increases. However, since the allowance for strength improvement is saturated at the penetration length of 0.5 L, it is economically 0. An intrusion length of 5L is the upper limit.

  If the reinforced concrete column has a rectangular cross section, the length of the long side of the rectangle is M and the length of the short side is N, the reinforcing rod embedded in the beam grout material is a reinforced concrete column. It is preferable to penetrate at least M × 0.1 and N × 0.1. The longer the penetration length of the reinforcing rod into the reinforced concrete column, the higher the strength of the reinforced concrete structure. However, the strength improvement allowance is saturated at the penetration lengths of 0.5M and 0.5N. Intrusion lengths of .5M and 0.5N are upper limits.

  Furthermore, when the diameter of the reinforcing rod is D, it is preferable that the reinforcing rod embedded in the beam grout material penetrates into the reinforced concrete column by a length of at least 4D. The strength of the reinforced concrete structure increases as the penetration length of the reinforcing rod into the reinforced concrete column increases, but the strength improvement allowance is saturated at the penetration length of 20D. It is.

  FIG. 6 (a) is a perspective view of a part of a reinforced concrete column of the present invention, and FIG. 6 (b) is a part of a reinforcing sheet covering a concrete beam and slab and embedded in a grout material for a beam. It is a perspective view which shows a part of reinforcement rod. In FIG. 6A, 31 is a reinforcing bar that supports the reinforcing bar 30.

  7 (a) to 7 (e) are cross-sectional views showing various reinforcing structures of the reinforced concrete structure. 7A shows a reinforced concrete 41 having a square section with a side length of 150 mm, FIG. 7B shows a structure in which the reinforced concrete 41 is covered with a grout material 42 having a thickness of 30 mm, and FIG. A structure in which four reinforcing rods 43 obtained by impregnating and curing a braid made of four aramid fibers having a diameter of 5 mm in the grout material 42 along the longitudinal direction of the reinforced concrete 41, FIG. ) Is a reinforcing sheet 44a, 44b made of a unidirectional sheet (see FIG. 4B) knitted so that an aramid fiber having a thickness of 0.193 mm is arranged in one direction around the structure shown in FIG. When two layers are arranged in the horizontal direction so as to overlap each other, FIG. 7 (e) shows an aramid fiber having a thickness of 0.193mm around the structure shown in FIG. 7 (c). The reinforcing sheet 44c made of a unidirectional sheet knitted so as to be arranged in the vertical direction is arranged in the vertical direction, and the reinforcing sheet 44d made of a unidirectional sheet of aramid fibers is horizontally placed on the reinforcing sheet 44c arranged in the vertical direction. The case where it arranges in the direction is shown. In addition, the vertical direction and the horizontal direction mean that the arrangement direction is different by 90 ° (perpendicular). The reinforcing sheets 44a, 44b, 44c and 44d were attached according to the method described in paragraph 0032.

  FIG. 8A illustrates a bending test method. As shown in FIG. 8 (a), a test piece 51 having various reinforcing structures having cross sections in the lateral direction shown in FIGS. 7 (a) to 7 (e) is supported by two fulcrums 52 on the upper surface of the test piece. When the load P is applied, the displacement amount and load of the test piece 51 are measured by measuring the displacement amount with a known strain gauge displacement meter 53 (trade name SDP-50C manufactured by Tokyo Sokki Kenkyujo Co., Ltd.). Sought the relationship.

  As a result of performing a bending test shown in FIG. 8A on various reinforcing structures of a reinforced concrete structure having a transverse cross section shown in FIGS. 7A to 7E and having a length of 1300 mm, each reinforcing structure The numerical values shown in Table 1 below were obtained as the critical loads that lead to failure.

  FIG. 8B is a diagram for explaining a method for obtaining the relationship between the load and the displacement shown in FIG. As shown in FIG. 8 (b), after a load P from zero load to about 1/3 of the limit load is applied to the test piece 51 shown in FIG. 8 (a), the load is returned to zero. After the load P from zero to about 2/3 of the limit load is applied to the test piece 51 shown in FIG. 8A, the load is returned to zero. Finally, the load P from the load zero to the limit load is changed. After the test piece 51 shown in FIG. 8A is loaded, the load is returned to zero to obtain the relationship between the load and the displacement amount in the bending test of various reinforcing structures of the reinforced concrete structure as shown in FIG. It was.

  In FIG. 9, line A, line B, line C, line D, and line E are respectively shown in FIGS. 7 (a), 7 (b), 7 (c), 7 (d), and 7 (e). It corresponds to each reinforcement structure. That is, as shown in FIG. 9, as indicated by line A, as indicated by line C, “reinforcing structure in which a reinforcing rod is embedded along the longitudinal direction of the reinforced concrete column in the grout material covering the entire periphery of the reinforced concrete column” It can be seen that the strength can be greatly improved as compared with “the structure of the reinforced concrete column only” and “the reinforcing structure in which the entire surface of the reinforced concrete column is covered with the grout material” shown by the line B. Further, it can be seen that the total displacement amount of the line C is increased as compared with the total displacement amount of the line A or B, and the toughness is also improved.

  Further, as indicated by a line D, a reinforcing rod is embedded in the grout material covering the entire periphery of the reinforced concrete column along the longitudinal direction of the reinforced concrete column, and two layers of reinforcing sheets are laterally arranged so as to cover the grout material. According to the “reinforcing structure to be disposed on”, it is understood that the strength can be further improved and the toughness can be improved as compared with the reinforcing structure of the line C. And, as shown by the line E, “a reinforcing rod embedded in the grout material covering the entire periphery of the reinforced concrete column along the longitudinal direction of the reinforced concrete column and laterally arranged so as to cover the grout material. According to the “reinforcing structure in which the reinforcing sheet is arranged in the vertical direction”, the strength can be further improved and the toughness can be improved as compared with the reinforcing structure of the line D.

  The present invention is suitable as a reinforcing structure for a wall or a reinforced concrete column with a slab.

DESCRIPTION OF SYMBOLS 1 Feeding roller 2 Tension roller 3 Binder resin layer 4 Braid 5 Heating furnace 6 Heating furnace 7 Resin impregnation process 8 Sanding process 9 Curing process 10 Cutting process 11 Resin impregnation process 12 Pickup roller 21 Reinforced concrete pillar 22 Column grout material 23 Column Reinforcing rod 24 Reinforcing sheet 25a, 25b, 25c, 25d Concrete beam 26 Grouting material for beam 27 Reinforcing rod for beam 28 Concrete slab 29 Reinforcing sheet 30 Reinforcing bar 31 Reinforcing bar 41 Reinforced concrete 42 Grout material 43 Reinforcing rods 44a, 44b, 44c, 44d Reinforcement sheet 51 Test piece 52 Support point 53 Displacement meter 61 Reinforced concrete column 62 Enclosed steel plate 63a, 63b Butt portion h Interval y Welded portion

Claims (4)

Cover the entire surface of a reinforced concrete column with walls or slabs with a column grout material, and embed a reinforcing rod in the column grout material along the longitudinal direction of the reinforced concrete column so as to cover the column grout material. A reinforcing sheet is placed, the lower part of the concrete beam connecting the reinforced concrete column and the reinforced concrete column is covered with a grout material for the beam, and a reinforcing rod is embedded in the beam grout material along the longitudinal direction of the concrete beam. In the reinforcing structure of the reinforced concrete structure in which the reinforcing sheet is disposed so as to cover the beam grout material ,
When the reinforced concrete column has a square cross section and the length of one side of the square is L, the reinforcing rod embedded in the beam grout material has a length of at least L × 0.1 in the reinforced concrete column. Reinforced structure of reinforced concrete structure characterized by only intrusion . Cover the entire surface of a reinforced concrete column with walls or slabs with a column grout material, and embed a reinforcing rod in the column grout material along the longitudinal direction of the reinforced concrete column so as to cover the column grout material. A reinforcing sheet is placed, the lower part of the concrete beam connecting the reinforced concrete column and the reinforced concrete column is covered with a grout material for the beam, and a reinforcing rod is embedded in the beam grout material along the longitudinal direction of the concrete beam. In the reinforcing structure of the reinforced concrete structure in which the reinforcing sheet is disposed so as to cover the beam grout material,
When a reinforced concrete column has a rectangular cross section, the long side of the rectangle is M and the short side is N, the reinforcing rod embedded in the grouting material for the beam is placed in the reinforced concrete column. A reinforcing structure for a reinforced concrete structure, which penetrates at least a length of M × 0.1 and N × 0.1 . Cover the entire surface of a reinforced concrete column with walls or slabs with a column grout material, and embed a reinforcing rod in the column grout material along the longitudinal direction of the reinforced concrete column so as to cover the column grout material. A reinforcing sheet is placed, the lower part of the concrete beam connecting the reinforced concrete column and the reinforced concrete column is covered with a grout material for the beam, and a reinforcing rod is embedded in the beam grout material along the longitudinal direction of the concrete beam. In the reinforcing structure of the reinforced concrete structure in which the reinforcing sheet is disposed so as to cover the beam grout material,
A reinforcing structure for a reinforced concrete structure, wherein the diameter of the reinforcing rod is D, and the reinforcing rod embedded in the grouting material for a beam penetrates the reinforced concrete column by a length of at least 4D . The reinforcing structure for a reinforced concrete structure according to any one of claims 1 to 3, wherein the reinforcing rod and the reinforcing sheet are made of aramid fibers .