JP2016069923A - Reinforced concrete structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reinforced concrete structure capable of obtaining sufficient strength without increasing the amount of reinforcement.SOLUTION: An inner reinforcement material 22 of a box culvert 1 comprises: both end parts 22b with yield point or 0.2% proof stress corresponding to a normal strength part specified by JISG3112; and a central part 22a corresponding to a high strength part, which is placed between these end parts 22b, and the inner reinforcement material is made by partly hardening a piece of normal reinforcing bar. The central part 22a corresponding to the high strength part is arranged to respond to the part with preset bending moment value ranging from the maximum value to 0.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a simple support slab, a box culvert, and other reinforced concrete structures.

Simple support slabs and box culverts are known as reinforced concrete structures.
The box culvert is formed in a rectangular tube shape by an upper wall, a bottom wall, a left side wall, and a right side wall. There is a conventional example in which reinforcing bars are arranged on each of the upper wall, the bottom wall, the left side wall, and the right side wall (Patent Document 1).
In general, box culverts and other reinforced concrete structures use reinforcing bars having the same strength from one end to the other. A reinforced concrete structure is designed by selecting the diameter and number of the reinforcing bars according to the bending moment.

JP 2009-243139 A

In simple support slabs, box culverts, and other reinforced concrete structures, the magnitude of the bending moment generated in each part varies depending on the manner in which the load is applied.
However, in Patent Document 1 and other conventional examples, since the reinforcing bars used generally have the same strength from one end to the other, they are not configured to cope with the bending moment. If the amount of reinforcing bars is calculated at a location where is large, reinforcing bars will be placed excessively at locations where the bending moment is small.
Here, in order to calculate the amount of reinforcing bars at locations where the bending moment is small and partially increase the strength at locations where the bending moment of the reinforced concrete structure is large, add the number of reinforcing bars to the portion where the strength of the reinforced concrete structure is small However, it is necessary to increase the thickness of the reinforced concrete structure. In addition, simply adding the amount of reinforcing bars only results in overcrowding.

  An object of the present invention is to provide a reinforced concrete structure capable of obtaining sufficient strength without increasing the amount of reinforcing bars.

  The reinforced concrete structure of the present invention includes a reinforcing bar material and plate-like concrete provided on the reinforcing bar material, and the reinforcing bar material has a normal strength portion whose yield point or 0.2% proof stress is defined by JIS G3112, and A high strength portion having a yield point or 0.2% proof stress set larger than that of the normal strength portion, and the high strength portion is partially quenched by one ordinary reinforcing bar having the same strength as the normal strength portion. The high-strength portion is arranged corresponding to a portion where the value of the preset bending moment is from a maximum value to a small value, and the normal strength is corresponding to a portion from the small value to 0 The portion is arranged.

In the present invention having this configuration, when designing a simple support slab having a structure in which plate-like concrete is provided on a reinforcing bar, a bending moment is obtained in advance by a method similar to the conventional method. Then, a high-strength portion is arranged corresponding to a portion where the value of the bending moment is from the maximum value to a small value, and a normal strength portion is arranged in a portion where the value of the bending moment is 0 from a small value.
Since a portion with a large bending moment is a portion to which a large load is applied, by placing a high-strength portion at that portion, it is possible to withstand a large load. Since the load applied to the portion with a small bending moment is small, it is sufficient to arrange a normal strength portion having a lower strength than the high strength portion.
Therefore, in the present invention, a reinforcing effect can be obtained by disposing a high-strength portion in a portion requiring high strength in the simple support slab.
And since it was set as the structure which has a high intensity | strength part and a normal intensity | strength part in one rebar material, it is not necessary to increase the amount of reinforcement for reinforcement. Since the high-strength portion is formed by partially quenching one ordinary reinforcing bar, the manufacturing cost of the reinforcing bar material can be reduced as compared with the case where all the ordinary reinforcing bars are quenched to obtain high strength.

  A reinforced concrete structure according to the present invention is a reinforced concrete structure having a top wall portion, a bottom wall portion, and left and right side wall portions, which are formed in a rectangular tube shape and provided with concrete in a reinforced steel material, A normal strength portion whose point or 0.2% proof stress is defined in JISG3112, and a high strength portion whose yield point or 0.2% proof strength is set larger than the normal strength portion, and the high strength The portion is formed by partially quenching one ordinary reinforcing bar having the same strength as the normal strength portion, and the high strength portion is arranged corresponding to a portion where a preset bending moment value is from a maximum value to zero. And the said normal intensity | strength part is arrange | positioned corresponding to the part from which the value of the said bending moment becomes 0, It is characterized by the above-mentioned.

In the present invention having this configuration, when designing a box culvert having a top tube portion, a bottom wall portion, and left and right side wall portions and formed in a rectangular tube shape, a bending moment is obtained in advance by a method similar to the conventional method. Keep it. Then, a high-strength portion is disposed in a portion where the value of the bending moment is large, and a normal-strength portion is disposed in a portion where the value of the bending moment is zero.
In the present invention, in the box culvert, a reinforcing effect can be obtained by disposing a high-strength portion in a portion requiring high strength.
Moreover, since a single reinforcing bar material has a high-strength portion and a normal strength portion, it is not necessary to increase the amount of reinforcing bars, and the high-strength portion is formed by partially quenching one normal reinforcing bar. Therefore, the manufacturing cost of a reinforcing bar material can be held down.

In the present invention, the reinforcing bar material is arranged to extend horizontally and has a central portion corresponding to the high-strength portion and end portions corresponding to the normal strength portion provided on both sides of the central portion. A configuration is preferred.
In simple support slabs and box culverts, a high-strength portion is arranged at the central portion where the bending moment is large, and a normal-strength portion is arranged at the small end portion. Therefore, sufficient strength can be obtained without increasing the amount of reinforcing bars by realizing the arrangement of reinforcing bars suitable for the bending moment of simple support slabs and box culverts.

In the present invention, the reinforcing bar member includes an inner reinforcing bar member disposed on the center side and an outer reinforcing bar member disposed on the outer side away from the center, and the inner reinforcing bar member is disposed to extend horizontally. A central portion corresponding to the high-strength portion, and end portions corresponding to the normal-strength portion provided on both sides of the central portion, and the outer reinforcing bars extending horizontally to be disposed on the normal-strength portion. It is preferable to have a configuration in which a corresponding central portion and curved portions corresponding to the high-strength portions are provided on both sides of the central portion, and the curved portion is curved so as to follow the box culvert corner portion.
The bending moment of the upper and bottom wall portions of the box culvert is greatest at the central portion where the value is located at the intermediate portion between the one end portion and the other end portion. It becomes 0 on the way to each, and further reverses toward one end and the other end, and takes a maximum value at one end and the other end.
In the present invention, in the inner reinforcing bar material, a high strength portion corresponding to a region where the value of the bending moment becomes 0 toward the one end portion and the other end portion from the maximum value of the center portion is positioned on both sides of the center portion. By making the end portion to be a normal strength portion, a sufficient strength can be obtained without increasing the amount of reinforcing bars.
Moreover, since the bending moment takes a maximum value of a predetermined size at one end and the other end, the curved portion of the outer reinforcing bar material is made a high-strength portion corresponding to these maximum values, and between these curved portions. A sufficient strength can be obtained without increasing the amount of reinforcing bars by making the central portion of the steel plate a normal strength portion.
That is, in the present invention, two types of inner reinforcing bar material and outer reinforcing bar material are prepared so as to correspond to the region where the bending moment takes the maximum value at the central portion and the region where the bending moment takes the maximum value, respectively. By differentiating the positions of the high-strength portion and the normal-strength portion in the reinforcing bar material, it is possible to obtain a large reinforcing effect by appropriately corresponding to a complicated bending moment.

In the present invention, the ratio of the allowable bending moment between the normal strength portion and the high strength portion is preferably set based on the ratio between the strength of the normal strength portion and the strength of the high strength portion.
In this configuration, the lengths of the normal strength portion and the high strength portion can be set rationally corresponding to the allowable bending moment between the normal strength portion and the high strength portion.

The perspective view which fractured | ruptured a part which shows the whole structure of 1st Embodiment of this invention. Sectional drawing which shows the whole structure of 1st Embodiment. Schematic which shows the bending moment of 1st Embodiment. (A) is a front view which shows an outer side reinforcement material, (B) is a front view which shows an inner side reinforcement material. Sectional drawing which shows 2nd Embodiment of this invention. Schematic which shows the bending moment of 2nd Embodiment. (A) is a front view which shows an outer side reinforcement material, (B) is a front view which shows an inner side reinforcement material. (A) is the schematic which shows the bending moment of 3rd Embodiment of this invention, (B) is sectional drawing which shows the principal part of 3rd Embodiment, (C) is an intensity distribution figure which shows intensity distribution of a reinforcing bar material.

[First Embodiment]
A first embodiment of the present invention will be described with reference to FIGS.
The whole structure of the reinforced concrete structure concerning 1st Embodiment is shown by FIG.1 and FIG.2. In the first embodiment, the reinforced concrete structure is a box culvert 1 that is formed in a rectangular tube shape including an upper wall part 11, a bottom wall part 12, a left side wall part 13, and a right side wall part 14.
In the box culvert 1, a space is continuously formed along the direction of the square tube axis.
In the box culvert 1, a concrete body 100 is provided on the reinforcing bar 2. In FIGS. 1 and 2, hatching indicating a cross section of the concrete body 100 is omitted.

A plurality of reinforcing bars 2 are arranged side by side along the direction of the rectangular tube axis of the box culvert 1. A connecting reinforcing bar 20 that connects these reinforcing bars 2 is arranged extending in the direction of the rectangular tube axis. The connecting reinforcing bars 20 are disposed on the upper wall portion 11, the bottom wall portion 12, and the side wall portions 13 and 14, respectively.
The reinforcing bar 2 is arranged to extend horizontally to the outer reinforcing member 21 and the upper wall part 11 and the bottom wall part 12 respectively, which are arranged with the center part extending horizontally to the upper wall part 11 and the bottom wall part 12 respectively. Inner reinforcing bars 22, normal reinforcing bars 23 and 24 arranged on the left and right side wall parts 13 and 14, and reinforcing reinforcing bars 25 arranged at box culvert corners, respectively.

The outer reinforcing bars 21 are arranged on the outer side opposite to the center of the box culvert 1 and are arranged in a pair in the vertical direction.
The outer reinforcing steel member 21 has a deformed shape having a central portion 21A that extends horizontally, a curved portion 21B that is provided on each side of the central portion 21A, and a distal end portion 21C that is provided at the end of the curved portion 21B. It is a reinforcing bar.
The curved portion 21B is formed to be curved along the box culvert corner. 21 C of front-end | tip parts from the middle of the curved part 21B are arrange | positioned at the side wall part 13 and the side wall part 14, respectively.

The upper outer rebar member 21 and the lower outer rebar member 21 are in contact with each other at their tips 21C, and these contacts are joined together by welding. A joint may be used instead of joining the end portions of the tip end portion 21C by welding, or the tip end portion 21C of the upper outer rebar member 21 and the tip end portion 21C of the lower outer rebar member 21 are connected. It is also possible to partially overlap each other and connect the overlapped portions.
In the present embodiment, the distal end portion 21C may be omitted from the outer reinforcing material 21, and the outer reinforcing material 21 may be configured from the central portion 21A and the curved portion 21B. In this case, it is good also as a structure which connects the lower end of the curved part 21B of the upper side outer reinforcement material 21 and the upper end of the curved part 21B of the lower side outer reinforcement material 21 with a normal reinforcement.

A pair of upper and lower inner reinforcing bars 22 are arranged on the center side of the box culvert 1. The inner reinforcing bar material 22 is a deformed reinforcing bar having a central portion 22a and end portions 22b provided on both sides of the central portion 22a.
The normal reinforcing bar 23 arranged on the left side wall 13 is a deformed reinforcing bar whose yield point or 0.2% proof stress is a value specified by JISG3112, for example, 295 MPa (N / mm ² ) or more and 490 MPa (N / mm ² ) or less.
The upper and lower ends of the normal reinforcing bar 23 intersect with the inner reinforcing bar material 22, respectively.
The normal reinforcing bars 24 arranged on the right side wall portion 14 are deformed reinforcing bars made of the same material as the normal reinforcing bars 23, and the upper and lower ends thereof intersect the inner reinforcing bar material 22.

Both ends of the reinforcing reinforcing bar 25 are connected to the curved portion 21 </ b> B of the outer reinforcing bar material 21, and the material thereof is the same as that of the normal reinforcing bar 24.
The connecting reinforcing bars 20 are arranged in two rows inside and outside, and are arranged so as to intersect the outer reinforcing bar material 21, the inner reinforcing bar material 22, and the normal reinforcing bars 23 and 24, respectively. These reinforcing bars and the connecting reinforcing bars 20 are connected as necessary. The connecting reinforcing bar 20 is a deformed reinforcing bar made of the same material as the normal reinforcing bar 23.

FIG. 3 shows an outline of the bending moment used when designing the box culvert 1.
The bending moment includes a bending moment M11 corresponding to the upper wall portion 11, a bending moment M12 corresponding to the bottom wall portion 12, a bending moment M13 corresponding to the left side wall portion 13, and a bending moment corresponding to the right side wall portion 14. A moment M14. The bending moment is a constant (self-weight) load moment plus an external force moment. The design bending moment is obtained by a normal design method.

A region Ma where the bending moment M11 becomes maximum at the center point of the upper wall portion 11 (intermediate point between the adjacent side wall portions 13 and 14), decreases toward the side wall portions 13 and 14, and becomes 0 at a predetermined position. And a region Mb which is reversed from the position where the value becomes 0 and becomes maximum at both ends (side wall portions 13 and 14).
The bending moment M12 is opposite in sign to the bending moment M11. In general, the bottom wall portion 12 has a larger bending moment at both ends and the center portion than the upper wall portion 11.
The values of the bending moments M13 and 14 are 0 at the intermediate height between the side wall portions 13 and 14, and the maximum at the upper end or the lower end. In general, the bending moment at the lower end is larger than that at the upper end.

In the present embodiment, the structures of the outer reinforcing bar member 21 and the inner reinforcing bar member 22 are set based on the bending moments M11 and M12.
That is, the outer reinforcing steel member 21 has a high-strength portion and a normal-strength portion set in order to correspond to the region Mb among the bending moments M11 and M12. Specifically, both end portions 22b corresponding to the high-strength portions are respectively disposed corresponding to the regions Mb, and a central portion 22a corresponding to the normal strength portion is disposed between these regions Mb.
The inner reinforcing steel member 22 has a high-strength portion and a normal-strength portion set in order to correspond to the region Ma in the bending moments M11 and M12. Specifically, the central portion 22a corresponding to the high strength portion is disposed corresponding to the region Ma, and the end portions 22b corresponding to the normal strength portion are disposed on both sides of the region Ma.

In FIG. 4 (A), the outer rebar material 21 is shown enlarged, and in FIG. 4 (B), the inner rebar material 22 is shown enlarged.
In FIG. 4A, the outer reinforcing steel member 21 has a central portion 21A and a half of the curved portion 21B formed in a straight line. The curved portion 21B is bent at a right angle with the central portion as a boundary. The remaining half of the curved portion 21B and the tip portion 21C are formed in a straight line.
The length of the central portion 21A is LA, the length of half of the curved portion 21B is LB1, and the length of the other half is LB2.
The central portion 21A and the tip portion 21C are normal strength portions, respectively, and the yield point or 0.2% proof stress is a value defined by JIS G3112, for example, 295 MPa (N / mm ² ) or more and 490 MPa (N / mm ² ). It is as follows.

The curved portion 21B is a high-strength portion in which the yield point or 0.2% yield strength is set larger than that of the normal strength portion, and the yield point or 0.2% yield strength exceeds 490 MPa (N / mm ² ) and is 1000 MPa. (N / mm ² ) or less.
The outer rebar member 21 forms a curved portion 21B which is a high strength portion by partially quenching one ordinary rebar having the same yield point or 0.2% proof stress as the normal strength portion, and the unquenched portion is the center. A part 21A and a tip part 21C are formed.
The lengths of LB1 and LB2 constituting the high-strength portion of the outer reinforcing steel member 21 are set so that the allowable bending moment calculated based on the strength of the central portion 21A exceeds the bending moment distribution. The

In FIG. 4 (B), as for the inner side reinforcement material 22, the center part 22a and the edge part 22b are formed in linear form.
The length dimension of the central portion 22a is La, and the length dimension of the end portion 22b is Lb.
Central portion 22a is a high strength part, its yield point or 0.2% proof stress is greater than ^{490MPa (N / mm 2) 1000MPa} (N / mm 2) or less.
The end portion 22b is a normal strength portion, and its yield point or 0.2% proof stress is a value specified by JIS G3112, for example, 295 MPa (N / mm ² ) or more and 490 MPa (N / mm ² ) or less.
The inner reinforcing bar material 22 is formed by quenching the central portion of one normal reinforcing bar having the same yield point or 0.2% proof stress as that of the normal strength portion to form a central portion 22a of the high strength portion. It becomes the end 22b.

The length (La) of the central portion 22a constituting the high-strength portion of the inner reinforcing bar 22 is set so that the bending moment allowable value calculated based on the strength of the end portion 22b exceeds the bending moment. Is set.
The allowable value of the bending moment is roughly represented by a strength ratio. For example, the strength of the central portion 22a is 685 MPa (N / mm ² ), and the strength of the end portion 22b is 490 MPa (N / mm ² ). Then, the value obtained by multiplying this ratio (490/685) by the bending moment of the central portion 22a where the bending moment is the maximum is equal to a position where the bending moment distribution is equal or greater.

Therefore, in the first embodiment, the following effects can be achieved.
(1) The inner reinforcing bar 22 of the box culvert 1 is disposed between these end portions 22b and the end portions 22b on both sides corresponding to the normal strength portion whose yield point or 0.2% proof stress is defined by JISG3112. And a central portion 22a corresponding to the high strength portion, and the high strength portion was formed by partially quenching one ordinary reinforcing bar. A central portion 22a corresponding to the high-strength portion is arranged corresponding to the portion where the preset value of the bending moment M reaches 0 from the maximum value. Therefore, in the box culvert 1, a reinforcing effect can be obtained by making the central portion 22a that requires a large strength a high strength portion. And since it was set as the structure which has a high intensity | strength part and a normal intensity | strength part in one rebar material, it is not necessary to increase the amount of reinforcing bars. Therefore, the manufacturing cost of a reinforcing bar material can be suppressed.

(2) The outer reinforcing steel member 21 has a central portion 21A corresponding to a normal strength portion and curved portions 21B provided on both sides of the central portion 21A and corresponding to a high strength portion, and the curved portion 21B has a box culvert angle. A curve was formed along the part. Since the bending moment M takes a maximum value of a predetermined magnitude at each of the one end and the other end, the bending portion 21B of the outer rebar 21 is made a high-strength portion corresponding to these maximum values. A sufficient strength can be obtained without increasing the amount of reinforcing bars by setting the central portion 21A in the middle as the normal strength portion.

(3) Since the ratio of the bending moment between the normal strength portion and the high strength portion can be roughly set based on the ratio between the strength of the normal strength portion and the strength of the high strength portion, Can be reasonably set.

[Second Embodiment]
A second embodiment of the present invention will be described with reference to FIGS.
The reinforced concrete structure of the second embodiment is a simple support slab 3 having both ends supported by the concrete body 30. In the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.
The simple support slab 3 has a structure in which a reinforcing concrete member 4 is provided with a plate-like concrete body 40.
In addition, in FIG. 5, the hatching which shows the cross section of the concrete body 30 or the plate-shaped concrete body 40 is abbreviate | omitting illustration.

A plurality of reinforcing bars 4 are arranged side by side in the paper penetration direction in FIG. 5, and these reinforcing bars 4 are connected by a connecting reinforcing bar (not shown).
The reinforcing bar member 4 includes an upper reinforcing bar member 41 that extends horizontally, and a lower reinforcing bar member 42 that is disposed below the upper reinforcing bar member 41.
The upper reinforcing bar material 41 is a deformed reinforcing bar having a central portion 41A that extends horizontally and curved portions 41B provided on both sides of the central portion 41A. The curved portion 41B is formed toward the lower side, and the distal end portion thereof is parallel to the central portion 41A.
The lower reinforcing bar member 42 is a deformed reinforcing bar having a central portion 42a that extends horizontally and curved portions 42b provided on both sides of the central portion 42a. The curved portion 42b is formed toward the upper side, and the distal end portion thereof is parallel to the central portion 42a.

FIG. 6 shows an outline of the bending moment M2 used when the simple support slab 3 is designed.
The bending moment M2 is a region in which the value becomes maximum at the center point of the simple support slab 3 (intermediate point of the adjacent concrete body 30), decreases toward the both ends, and becomes 0 at the support point C.
In the present embodiment, the structure of the lower rebar 42 is set based on the bending moment M2.
That is, the lower reinforcing steel member 42 is set with a high strength portion and a normal strength portion in order to correspond to the bending moment M2. Specifically, the high strength portion is the central portion 42a, and the normal strength portion is the curved portion 42b. The length of the central portion 42a where the high-strength portion is set may be all of the dimensions between the two support points C, or may be a portion as shown in FIG.

FIG. 7A shows the upper rebar member 41 in an enlarged manner, and FIG. 7B shows the lower rebar member 42 in an enlarged manner.
In FIG. 7A, the upper reinforcing steel member 41 has a central portion 41A formed in a straight line, and curved portions 41B are integrally formed at both ends thereof.
The upper reinforcing steel member 41 is a normal strength portion, and its yield point or 0.2% proof stress is a value defined by JIS G3112, for example, 295 MPa (N / mm ² ) or more and 490 MPa (N / mm ² ) or less.

In FIG. 7 (B), the lower reinforcing steel member 42 has a central portion 42a formed in a straight line, and curved portions 42b are integrally formed at both ends thereof. In FIG. 7B, a part of the central part 42a is a high-strength part, and the remaining part of the central part 42a and the curved part 42b are normal-strength parts.
Of the central portion 42a, the length of the high strength portion is La, and the length of the normal strength portion is Lb.
Yield point or 0.2% proof stress of the high strength portion is less 490MPa (N / mm ²⁾ beyond 1000MPa (N / mm ^2).

The yield point or 0.2% proof stress of the normal strength portion is a value defined by JIS G3112, for example, not less than 295 MPa (N / mm ² ) and not more than 490 MPa (N / mm ² ).
The lower reinforcing steel member 42 hardens the central portion of one normal reinforcing bar having the same yield point or 0.2% proof stress as the normal strength portion to form a high strength portion of the central portion 42a. The unquenched part forms a normal strength part.

The length Lb of the normal strength portion of the lower rebar member 42 and the length of the high strength portion are set from the bending moment distribution based on the ratio between the strength of the normal strength portion and the strength of the high strength portion.
For example, when the strength of the high strength portion of the central portion 42a is 685 MPa (N / mm ² ) and the strength of the other normal strength portions is 490 MPa (N / mm ² ), this ratio (490/685) The value obtained by multiplying the bending moment at the center where the bending moment is the maximum is equal to the position where the bending moment distribution is equal to or greater.

Therefore, in 2nd Embodiment, there can exist the following effect other than the same effect as (3) of 1st Embodiment.
(4) The lower rebar member 42 of the simple support slab 3 is formed between the curved portions 42b on both sides corresponding to the normal strength portion where the yield point or 0.2% proof stress is defined by JIS G3112, and between these curved portions 42b. And a central portion 42a corresponding to the high strength portion, and the high strength portion was formed by partially quenching one ordinary reinforcing bar. Since the central portion 42a corresponding to the high-strength portion corresponding to the portion where the preset bending moment M2 reaches 0 from the maximum value is provided, a reinforcing effect can be obtained and the amount of reinforcing bars is increased. I don't need it.

(5) Since the conventionally used reinforcing steel can be used as the upper reinforcing steel 41, the manufacturing cost of the reinforcing steel 2 can be suppressed.

[Third Embodiment]
A third embodiment of the present invention will be described with reference to FIG.
The third embodiment is different from the first embodiment in the configuration of the outer reinforcement member 21 and the inner reinforcement member 22, and the other configuration is the same as that of the first embodiment. In the description of the third embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.
In the third embodiment, the strength of the outer reinforcing steel member 21 is shifted from the normal strength portion to the high strength portion between the central portion 21A where the normal strength portion is arranged and the curved portion 21B where the high strength portion is arranged. The strength transition portion 21D is different from that of the first embodiment, and other configurations are the same as those of the first embodiment.

  In each of the above-described embodiments, a reinforcing bar material in which a high-strength portion is formed adjacent to the normal-strength portion is used. However, in consideration of the manufacturing process, between the normal-strength portion and the high-strength portion, It can be assumed that there is an intermediate part of the strength of. That is, it is conceivable that the heat treatment is performed by feeding one normal reinforcing bar to the heating device for a predetermined length and then heating the portion corresponding to the high strength portion. However, in this heat treatment, a strength transition portion in which the strength continuously transitions from the normal strength portion to the high strength portion is generated between the normal strength portion and the high strength portion. , How to handle is a problem.

In FIG. 8, the bending moment distribution is shown in (A), a partially enlarged view of FIG. 2 is shown in (B), and the bending moment strength distribution is shown in (C).
The bending moment distribution shown in FIG. 8A is maximum at the right end. The right end of FIG. 8A corresponds to an intermediate position between the adjacent side wall portions 13 and 14 (the side wall portion 14 is omitted in FIG. 8). The bending moment becomes smaller toward the side wall portion 13, becomes 0 in the middle, then reverses the direction, and becomes maximum on the inner side surface of the side wall portion 13.
In the present embodiment, the design position Q is the level of the allowable stress level at the same time that the reinforcing bar material or the concrete material reaches the limit of the allowable stress level at the base R of the outer reinforcing bar material 21 at the time of the earthquake, that is, the position of the inner surface of the side wall portion 13. A position designed to reach the limit. At the same time, the most reasonable design is when the limit of the allowable stress level is reached.
In order to reach the limit of the allowable stress level at the base R at the same time that the reinforcing bar reaches the limit of the allowable stress level at the design position Q, that is, to effectively utilize the curved portion 21B that is a high strength portion, at the base R It is desirable that the allowable stress limit of the high strength part has been reached. However, the root R may be located in the middle of the strength transition portion 21D. Even in this case, there is no problem if the strength is sufficient with respect to the bending moment of the root R.

In the third embodiment, the boundary P between the curved portion 21B, which is a high-strength portion, and the strength transition portion 21D is separated from the root R by the dimension T, and the root R is positioned in the middle of the strength transition portion 21D.
The boundary between the strength transition portion 21D and the central portion 21A that is the normal strength portion is a design position Q, and the design position Q is located at a position separated from the base R by the dimension S.
The strength is set so that the allowable bending moment of the root R in the strength transition portion 21D is equal to or greater than the bending moment at the root R position obtained from the moment distribution during earthquake.

In FIG. 8C, the strength distribution of the outer reinforcing bar 21 is indicated by a solid line, and the required strength distribution of the reinforcing bar obtained by back-calculating from the bending moment distribution of FIG. Is shown by a one-dot chain line.
As shown in FIG. 8C, the strength of the outer reinforcing steel member 21 includes the strength TH in the curved portion 21B that is a high strength portion, the strength TL in the central portion 21A that is a normal strength portion, and the strength in the strength transition portion 21D. NL. The strength NL is indicated by a line segment connecting ends of the strength TL and the strength TH.
The strength TH is also required at the base R. It is a curve L connecting the required strength at the base R and the required strength at the design position Q, and the strength value at the position of the boundary P between the strength transition portion 21D and the curved portion 21B is required in the high strength portion in this embodiment. Required strength TH ′. The strength of the outer reinforcing bar 21 is set so that the gradient of the strength NL between the design position Q and the boundary P is larger than the gradient (indicated by a two-dot chain line) obtained from the curve L. In addition, also in the inside reinforcing bar material 22, when using a reinforcing bar in which a strength transition portion is provided between the high strength portion and the normal strength portion, similarly to the outside reinforcing material 21, the strength is designed by the same method as described above. It is possible.

Therefore, in the third embodiment, in addition to the effects of the first embodiment, the following effects can be achieved.
(6) The outer reinforcing steel member 21 is configured such that the strength transition portion 21D is disposed between the central portion 21A of the normal strength portion and the curved portion 21B of the high strength portion, and the high strength portion is formed by the upper wall portion 11 and the side wall portion 13. The design position Q designed to reach the allowable stress limit at the base R of the reinforcing bar joint at the same time as an earthquake at the same time as the normal strength portion and strength The boundary between the transition portion and the boundary between the high-strength portion and the strength transition portion is positioned inside the joint, and the root R is positioned at the strength transition portion 21D, and the strength of the root R at the strength transition portion is distributed as a bending moment distribution. Was set to a value equal to or higher than the required strength TH ′ obtained by back calculation. Therefore, by making the gradient of strength larger than the gradient of moment during an earthquake, even if the strength transition portion 21D is long, it can be used for a building having an earthquake resistant structure.

It should be noted that the present invention is not limited to the above-described embodiments, and modifications, improvements, and the like within the scope that can achieve the object of the present invention are included in the present invention.
For example, in the first embodiment and the third embodiment, the reinforcing bar material is configured from the outer reinforcing bar material 21 and the inner reinforcing bar material 22, and in the second embodiment, the reinforcing bar material is configured from the upper reinforcing bar material 41 and the lower reinforcing bar material 42. However, in the present invention, either one may be used, or a configuration in which another reinforcing bar material is added may be used.
Moreover, although the reinforced concrete structure was demonstrated as the box culvert 1 and the simple support slab 3 in this invention, another structure may be sufficient in this invention.

  The present invention can be used for box culverts, simple support slabs, and other reinforced concrete structures.

DESCRIPTION OF SYMBOLS 1 ... Box culvert (reinforced concrete structure), 2 ... Reinforcement material, 100 ... Concrete body, 11 ... Upper wall part, 12 ... Bottom wall part, 13, 14 ... Side wall part, 21 ... Outer reinforcement material, 22 ... Inner reinforcement material , 21A ... center part (normal strength part), 21B ... curved part (high strength part), 22a ... center part (high strength part), 22b ... end part (normal strength part), 3 ... simple support slab (reinforced concrete structure) 4) Reinforcing bar material, 40 ... Plate-like concrete body, 41 ... Upper rebar material, 42 ... Lower rebar material, 42a ... Center part (high strength part), 42b ... Curved part (normal strength part), M11, M12 , M2 ... Bending moment

Claims (5)

Reinforcement material and plate-like concrete provided in the reinforcement material,
The reinforcing bar material has a normal strength portion whose yield point or 0.2% yield strength is defined by JISG3112, and a high strength portion whose yield point or 0.2% yield strength is set larger than that of the normal strength portion. And the high-strength portion is formed by partially quenching one ordinary reinforcing bar having the same strength as the normal-strength portion,
The high-strength portion is arranged corresponding to the portion where the preset bending moment value reaches from the maximum value to the small value, and the normal-strength portion is arranged corresponding to the portion from the small value to zero. This is a reinforced concrete structure. A reinforced concrete structure comprising a top wall portion, a bottom wall portion, and left and right side wall portions, formed into a rectangular tube shape and provided with concrete in a reinforcing bar material,
The reinforcing bar material has a normal strength portion whose yield point or 0.2% yield strength is defined by JISG3112, and a high strength portion whose yield point or 0.2% yield strength is set larger than that of the normal strength portion. And the high-strength portion is formed by partially quenching one ordinary reinforcing bar having the same strength as the normal-strength portion,
The high-strength portion is arranged corresponding to the portion where the preset bending moment value reaches from the maximum value to zero, and the normal-strength portion is arranged corresponding to the portion where the bending moment value becomes zero. Reinforced concrete structure characterized by being made. In the reinforced concrete structure according to claim 1 or 2,
The reinforcing bar material is arranged to extend horizontally, and has a central portion corresponding to the high-strength portion and end portions corresponding to the normal strength portion provided on both sides of the central portion, respectively. Reinforced concrete structure. In the reinforced concrete structure according to claim 2,
The rebar material includes an inner rebar material disposed on the center side, and an outer rebar material disposed on the outer side away from the center,
The inner rebar material has a central portion that extends horizontally and corresponds to the high-strength portion, and an end portion that is provided on each side of the central portion and corresponds to the normal strength portion,
The outer reinforcing bar material has a central portion that extends horizontally and corresponds to the normal strength portion, and a curved portion that is provided on both sides of the central portion and corresponds to the high strength portion, A reinforced concrete structure characterized by being curved along the box culvert corner. In the reinforced concrete structure according to any one of claims 1 to 4,
The ratio of the allowable bending moment between the normal strength portion and the high strength portion is set based on the ratio between the strength of the normal strength portion and the strength of the high strength portion.

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