JP2017179852A - Junction structure between foundation and reinforced concrete column, and building structure provided with the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a junction structure between a foundation and a reinforced concrete column that effectively resists bending moment, along with a building structure provided with the junction structure.SOLUTION: A junction structure 1 is for connecting between a foundation 2 and a reinforced concrete column 3. With the junction structure 1 between the foundation 2 and the reinforced concrete column 3, a bottom end 3a of the column 3 narrows down so that cross-section area gradually becomes smaller downward. A bottom end 10a of a reinforcing bar 10 of the column 3 terminates before reaching the foundation 2. A bottom end 5a of a structural steel 5 of the column 3 contacts or comes close to the foundation 2. An axial-direction reinforcing bar 12 is provided between the foundation 2 and the column 3 in a vertical direction, for connecting the foundation and the column. The axial-direction reinforcing bar 12 is positioned on an inner side of the reinforcing bar 10 and an outer side of the structural steel 5 when seen on a horizontal cross-section, and resists inclination of the column 3 by tensile force at a time of earthquake.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a joint structure between a foundation and a steel reinforced concrete column and a building structure including the joint structure.

  In general, building structures using columns made of steel reinforced concrete (hereinafter referred to as SRC) are widely used.

  With respect to such a building structure, in order to improve the seismic performance, a structure that absorbs seismic energy in the entire building structure by pin-joining the column base and the foundation has been proposed.

  Patent Document 1 discloses a column base pin structure as shown in FIG. The bottom end of the core steel frame 102 in the SRC column 101 is fixed to the foundation 104 by the anchor bolt 105, and the covering concrete 103 in the column 101 is provided with a slight dimension away from the foundation 104 to thereby form the covering concrete 103. A shear bar 106 is arranged so as to straddle between the lower part and the foundation 104, and an elastic material 107 is interposed between them, and the horizontal displacement of the column 101 with respect to the foundation 104 is determined as the shear strength of the shear bar 106. And the relative rotation in the vertical plane of the column 101 with respect to the foundation 104 is allowed by the elastic deformation performance of the elastic member 107 in the thickness direction. A core steel frame 102 is installed at the center in the width direction of the column 101 as a wall column, and shear bars 106 are arranged between the lower part of the covering concrete 103 and the foundation 104 at positions on both sides of the core steel frame 102, and an elastic material. A hard rubber sheet 107 is interposed. As a result, the joint type of the column base to the foundation 104 is a substantial pin joint that does not transmit bending force structurally.

JP 2013-221334 A

  In the pin joint structure disclosed in Patent Document 1, the reinforcing bar straddling between the column 101 and the foundation 104 is a shearing bar 106 for the purpose of countering a shearing force. That is, it is not necessarily fixed to the concrete 103 and the foundation 104 so that it can sufficiently resist the tensile force acting in the vertical direction. Therefore, for example, when a large force that lifts the column base 101a on the column 101 acts on the column 101 at the time of an earthquake, this cannot be countered, and in particular, there is a possibility that the shear muscle 106 located on the left side will come off the column 101 or the foundation 104. is there.

  In the structure of Patent Document 1, the lower end of the core steel frame 102 is fixed by an anchor bolt 105. However, when a force that lifts the column base left side 101a as described above is applied, the column 101 rotates with the lower end of the core steel frame 102 as a fulcrum, so the anchor bolt 105 disposed in the vicinity of the fulcrum has this force. Can't fully compete with.

  That is, in the structure of Patent Document 1, there is a possibility that the bending moment acting on the column 101 cannot be effectively countered when a large seismic force is applied.

  The problem to be solved by the present invention is to provide a joint structure between a foundation and a steel reinforced concrete column and a building structure including the joint structure, which can effectively counter a bending moment.

The present invention employs the following means in order to solve the above problems. That is, in the joint structure of the foundation and the steel reinforced concrete column according to the present invention, the lower end portion of the column is narrowed so that the cross-sectional area decreases downward, and the lower end of the reinforcing bar of the column is Ended before reaching the foundation, the lower end of the steel frame of the column is in contact with or close to the foundation, and is provided in the vertical direction between the foundation and the column, and includes an axial streak joining the two The axial streak is located on the inner side of the reinforcing bar and on the outer side of the steel frame in a horizontal sectional view, and resists the inclination of the column during an earthquake with a tensile force.
According to such a configuration, when a large lateral force acts on the column, the lower end of the column steel frame is in contact with or close to the foundation, so that one column leg is lifted and The column tries to rotate and tilt around the lower end of the steel frame so that the column base on the side sinks into the foundation.
Here, an axial streak is provided between the foundation and the column in the vertical direction and joins the two. As is well known, when an object to be rotated is stopped, it can be effectively stopped as the force for stopping the rotation is applied to a place far from the center of rotation. Similarly, in this case, since the installation position of the axial streak is provided outside the steel frame as a fulcrum in the horizontal sectional view, it is possible to resist the inclination of the column at the time of the earthquake with a tensile force. . At the same time, the position of the axial rebar is set in the horizontal cross-sectional view, inside the column rebar located near the outer periphery, that is, at a position close to the steel frame as the fulcrum. Since the column ends far from the steel frame, the column reinforcement farther away from the steel frame extends downward and is anchored to the foundation. Can be allowed to lift.
Furthermore, the lower end of the column is narrowed so that the cross-sectional area decreases downward, and the joint surface between the column and the foundation is made smaller, so the column on the opposite side moves so as to sink into the foundation. Does not interfere with leg movement.
Due to the various factors described above, the column and the foundation are semi-rigidly joined, which makes it possible to realize a joint structure that can absorb seismic energy and effectively resist bending moments. Become.

In one aspect of the present invention, a steel plate is joined to the lower end of the steel frame, and the upper end of the axial streak is joined to the steel plate.
According to such a configuration, even when a stronger tensile force is applied, a semi-rigid joint can be realized that opposes it.

In one aspect of the present invention, the width at the lower end of the steel frame is shorter than the width at the top.
According to such a configuration, it is possible to eliminate interference with the axial streak arranged near the steel frame while ensuring the rigidity of the steel frame in the upper part.

In one aspect of the present invention, the pillar located inside the building structure in the horizontal sectional view is joined to the foundation by the joint structure of the foundation and the steel reinforced concrete pillar as described above.
According to such a configuration, when a building structure is constructed, when a large lateral force acts on the column, the column outside the building structure where a large tensile force acts on the column base is used as a foundation. It is possible to realize a structure that is rigidly connected and has a structure in which the inner column whose tensile force is smaller than that of the outer column is made semi-rigid as described above, and can effectively resist bending moment. It becomes.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the joining structure of the foundation and the column made from a steel reinforced concrete which can counter effectively a bending moment.

BRIEF DESCRIPTION OF THE DRAWINGS (a) of the joining structure of the foundation shown as embodiment of this invention and the column made from a steel frame reinforced concrete is a sectional side view, (b)-(d) is a plane sectional view. It is explanatory drawing which shows the behavior at the time of the earthquake of the joining structure of the foundation shown as embodiment of this invention, and the column made from steel reinforced concrete. BRIEF DESCRIPTION OF THE DRAWINGS (a) of a 1st modification of the joining structure of the foundation shown as embodiment of this invention and the column made from steel-framed reinforced concrete is a sectional side view, (b)-(d) is a plane sectional view. (A) is a sectional side view, (b)-(d) is a plane sectional view of the 2nd modification of the joining structure of the foundation shown as an embodiment of the present invention, and the column made of steel reinforced concrete. It is a sectional side view of the 3rd modification of the junction structure of the foundation shown as embodiment of this invention and the column made from steel frame reinforced concrete. It is a sectional side view of the 4th modification of the junction structure of the foundation shown as embodiment of this invention, and the column made from steel frame reinforced concrete. It is a sectional side view of the 5th modification of the joining structure of the foundation shown as embodiment of this invention and the column made from steel-framed reinforced concrete. It is explanatory drawing of the conventional pin joint.

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

  FIG. 1A is a side sectional view of a joint structure 1 between a foundation 2 and a steel reinforced concrete column 3 shown as an embodiment of the present invention, and FIGS. 1B, 1C, and 1D are respectively It is AA 'sectional drawing, BB' sectional drawing, and CC 'sectional drawing of Fig.1 (a).

  This embodiment is an example when the present invention is applied to a lowermost pillar of a low-rise building structure such as a stadium, a gymnasium, or a warehouse. In this embodiment, the pillar located outside in the horizontal sectional view of the building structure is rigidly joined to the foundation, and the pillar 3 located inside realizes the semi-rigid joint shown in FIG. It is joined to the foundation 2 by a joining structure 1. The semi-rigid joint is a joint in which the rigidity of the joint portion is lower than that of a so-called rigid joint in which the reinforcement of a column having a foundation and a constant cross-sectional area is penetrated and embedded in concrete.

  In the joint structure 1, the pillar 3 is erected on the foundation 2. The column 3 is made of SRC and includes a steel frame 5 and a reinforcing bar 10 extending in the length direction, that is, the height direction Z in FIG.

  The steel frame 5 includes a lower steel frame 6 positioned in the vicinity of the lower end 3 a of the column 3 and an upper steel frame 7 positioned above the lower steel frame 6. As shown in FIG. 1C, the lower steel frame 6 includes a single web 6b and two flanges 6c joined to both sides of the web 6b perpendicularly to the web 6b. As shown in FIG. 1B, the upper steel frame 7 has a cross-sectional shape, for example, in a cross shape when viewed in a plane. That is, the upper steel frame 7 includes two webs 7b orthogonal to each other in a plan view, and a total of four flanges 7c joined to the webs 7b on both sides of each web 7b. .

  Between the upper end of the lower steel frame 6 and the lower end of the upper steel frame 7, a bonded steel plate 8 is interposed perpendicularly to the webs 6 b and 7 b and the flanges 6 c and 7 c of both the steel frames 6 and 7, that is, horizontally. Has been provided. The lower steel frame 6, the upper steel frame 7, and the joining steel plate 8 are joined by welding. The joining steel plate 8 has a rectangular shape with sides larger than the respective widths of the web 7b of the upper steel frame 7 and the web 6b of the lower steel frame 6.

  The lower steel frame 6 and the upper steel frame 7 are positioned so that their central axes are at the same position in plan view. Further, the width of the web 6 b of the lower steel frame 6 is formed to be shorter than the width of the web 7 b of the upper steel frame 7. Thereby, the width | variety in the lower end 5a of the steel frame 5, ie, the width | variety of the lower end 6a of the lower side steel frame 6, is shorter than the width | variety in upper part, ie, the width | variety of the upper side steel frame 7.

  A steel plate 9 is joined to the lower end 5a of the steel frame 5, that is, the lower end 6a of the lower steel frame 6 by welding so as to be perpendicular to the web 6b and the flange 6c. As shown in FIG. 1 (d), the steel plate 9 has a rectangular shape having sides larger than the width of the web 6 b of the lower steel frame 6. The steel frame 5 is provided on the foundation 2 so that the grout layer 13 and the steel plate 9 are in contact with each other on the grout layer 13 formed to have an area substantially equal to that of the steel plate 9. Thereby, the lower end 5 a of the steel frame 5 of the column 3 is provided close to the foundation 2.

  The reinforcing bars 10 are provided so as to extend in the vertical direction around the steel frame 5 and in the vicinity of the outer periphery of the column 3. The lower end 10 a of the reinforcing bar 10 of the column 3 is terminated before reaching the foundation 2, that is, above the foundation 2.

  A plurality of hoop bars 11 are provided outside the steel frame 5 and the reinforcing bar 10 so as to surround them.

  Concrete is cast to form the concrete portion 4 so as to embed each member such as the steel frame 5, the reinforcing bar 10, and the hoop bar 11 as described above. In the present embodiment, the pillar 3, that is, the concrete portion 4 has a rectangular cross section.

  The lower surface 4a of the concrete portion 4 includes an inclined portion 4b formed so as to gradually incline upward from a certain position toward the outside from the outer surface 4d of the concrete portion 4. On the outer side of the inclined portion 4b, an outer horizontal portion 4c extending horizontally between the outer edge of the inclined portion 4b and the outer surface 4d of the concrete portion 4 is formed.

  Since the lower surface 4a of the concrete part 4 has the shape as described above, the lower end part 3a of the column 3 is narrowed so that the cross-sectional area decreases downward, and the column 3 is placed on the foundation 2 with the lower end. When the portion 3a is provided downward, a gap 14 is formed between the upper surface 2a of the foundation 2 and the inclined portion 4b and the outer horizontal portion 4c of the concrete portion 4.

  The joint structure 1 further includes an axial stripe 12. The axial streak 12 is provided between the foundation 2 and the pillar 3 in the vertical direction, and is fixed to the concrete forming the concrete portion 4 of the pillar 3 on the upper side and to the concrete forming the foundation 2 on the lower side. Both 2 and 3 are joined. As shown in FIGS. 1C and 1D, the axial reinforcement 12 is located on the inner side of the reinforcing bar 10 and on the outer side of the lower steel frame 6 in the horizontal sectional view.

  The axial direction stripe | line | muscle 12 is joined by the intensity | strength which can resist the inclination of the pillar 3 at the time of an earthquake with a tensile force. That is, when an earthquake occurs and the column 3 is about to tilt, the concrete portion 4 of the column 3 is long enough so that the axial streak 12 does not come off from the concrete portion 4 or the foundation 2 of the column 3. And has been established in Foundation 2. Further, the material and the position of the axial streak 12 from the steel frame 5 are determined so as to allow a certain amount of inclination of the column 3 and temporarily elastically deform and extend when the column 3 is inclined. ing.

  Next, the construction method of the above-described joint structure 1 will be described.

  First, the foundation 2 is constructed. At this time, the lower side of the axial streak 12 is embedded in the foundation 2 in advance.

  Thereafter, the lower steel frame 6, the upper steel frame 7, the joined steel plate 8 and the steel plate 9 are welded in a ground yard or the like to manufacture the steel frame 5, and the reinforcing bars 10 and the hoop bars 11 are arranged around the steel frame 5. The member manufactured here is erected at a predetermined position. At this time, the building is constructed such that the upper side of the axial reinforcement 12 protruding upward from the foundation 2 is positioned outside the lower steel frame 6 and inside the reinforcement 10 and the hoop reinforcement 11. The grout is filled between the steel plate 9 and the upper surface 2a of the foundation 2 to form the grout layer 13.

  Furthermore, a formwork is arranged around the erected steel frames 5 and reinforcing bars 10. At this time, the shape of the gap 14 shown in FIG. 1A, that is, the inclined portion 4 b of the concrete portion 4, the outer horizontal portion 4 c, the upper surface 2 a of the foundation 2, and the outer surface 4 d down to the upper surface 2 a of the foundation 2. A plate material having the same cross-sectional shape as the trapezoidal shape formed by the extended virtual line, for example, a cross-sectional trapezoidal shape formed by foamed polystyrene or the like, is installed on the upper surface 2a of the foundation 2 at a place where the gap 14 is formed. To do.

  After that, concrete is placed in the mold, and after curing and curing, the concrete part 4 is manufactured. In the present embodiment shown in FIG. 1, the trapezoidal cross-section plate material used to form the gap 14 is removed, but it may be left without being removed.

  Next, the operation and effect of the joint structure 1 between the foundation 2 and the steel reinforced concrete column 3 shown as the above embodiment will be described with reference to FIGS. FIG. 2 is an explanatory diagram showing the behavior of the joint structure 1 during an earthquake. In FIG. 2, the reinforcing bars 10 and the hoop bars 11 shown in FIG. 1 are omitted.

  Consider a case where an earthquake occurs and a large force in the lateral direction, for example, the right direction X, acts on the joint structure 1 shown in FIG. In such a case, since the lower end 5a of the steel frame 5 of the column 3 is close to the foundation 2, as shown in FIG. 2, one column base, in this case, the left column located on the left side in the figure. The column 3 rotates and tilts clockwise around the lower end 5a of the steel frame 5 so that the leg 3b is lifted and the opposite column base, that is, the right column base 3c located on the right side in the figure is recessed into the foundation 2. And

  Here, the axial streak 12 that extends in the vertical direction between the foundation 2 and the pillar 3 and joins the two has a certain amount of inclination of the pillar 3 when the pillar 3 is inclined as described above. The material and the position from the steel frame 5 are determined so as to allow and temporarily elastically deform and extend.

  As is well known, when an object to be rotated is stopped, it can be effectively stopped as the force for stopping the rotation is applied to a place far from the center of rotation. That is, particularly with respect to the installation position of the axial streak 12, the axial streak 12 is provided outside the steel frame 5 serving as a fulcrum in a horizontal sectional view, and therefore resists the inclination of the column 3 at the time of an earthquake with a tensile force. It is possible.

  At the same time, the axial streak 12 is provided on the inner side of the reinforcing bar 10 located in the vicinity of the outer periphery of the column 3 in a horizontal sectional view, that is, at a position closer to the steel frame 5 serving as a fulcrum, as shown in FIG. As described above, the lower end 10 a of the reinforcing bar 10 of the column 3 is terminated before reaching the foundation 2. For this reason, the column 3 is fixed to the foundation 2 as strongly as the reinforcing rod 10 positioned farther away from the steel frame 5 extends downward and is fixed to the foundation 2 and the column 3 is rigidly joined to the foundation 2. Not. Thereby, the axial streak 12 can be elastically deformed to allow the left column base 3b to be lifted up a certain amount. In FIG. 2, a portion of the axial streak 12 that has been elastically deformed and extended is illustrated as an elastic deformation portion 12 a.

  Furthermore, the lower end portion 3a of the column 3 is narrowed so that the cross-sectional area decreases downward, and since the joint surface between the column 3 and the foundation 2 is made smaller, it moves so as to be embedded in the foundation 2. The movement of the opposite column base, that is, the right column base 3c is not hindered.

  Friction force acting between the right column base 3c and the foundation 2 indented into the foundation 2 when the pillar 3 once rotates and moves with the lower end 5a of the steel frame 5 as a fulcrum and shifts to the state shown in FIG. The axial streak 12 that is elastically deformed due to the tensile force due to the inclination of the column 3, particularly the shear resistance at the elastically deforming portion 12 a, counteracts the shearing force that tries to move in the lateral direction of the column 3.

  As described above, since the axial streak 12 is elastically deformed when the column 3 is inclined, after the earthquake is stopped, the column 3 returns to the position before the earthquake and returns to the original length. Transforms into

  As described above, due to the above-mentioned various factors, the column 3 and the foundation 2 are semi-rigidly joined. As a result, the joint structure 1 absorbs seismic energy and is effective in bending moment. It is a structure that can compete with each other.

  In particular, since the lower end 5a of the steel frame 5 is located close to the foundation 2, the position of the steel frame 5 clearly becomes the center of the column 3, that is, the fulcrum, and the fulcrum is shifted in the horizontal direction during the rotational movement of the column 3. To prevent. This makes it possible to counter the bending moment more effectively.

  In the present embodiment, the pillar 3 located on the inner side in the horizontal sectional view of the building structure is joined to the foundation 2 by the joining structure 1. That is, when a building structure is constructed, when a large lateral force is applied above the column 3, the column 3 outside the building structure on which a large tensile force acts on the column base is rigidly connected to the foundation 2. By making the inner column 3 having a smaller tensile force than the outer column a semi-rigid joint as described above, it is possible to more effectively counter the bending moment.

  Moreover, since the width | variety in the lower end 5a of the steel frame 5 is shorter than the width | variety in an upper part, interference with the axial direction stripe | line | wire 12 distribute | arranged near the steel frame 5 can be eliminated, ensuring the rigidity of the steel frame 5 in the upper part. .

  Furthermore, the steel frame 5 of the pillar 3 extends downward and does not penetrate into the foundation 2, and the lower end 5 a of the steel frame 5 is located close to the foundation 2. It is possible to manufacture the reinforced concrete members in the manner of construction without considering the connection.

  Due to these factors, construction can be easily performed.

(First Modification of Embodiment)
Next, a first modification of the joint structure 1 shown as the embodiment will be described with reference to FIG. 3A is a side sectional view of the joining structure 20 in the first modification, and FIGS. 3B, 3C, and 3D are DD ′ sectional views of FIG. It is EE 'sectional drawing and FF' sectional drawing. The joining structure 20 in the first modification is different from the joining structure 1 in that the upper end 22a of the axial streak 22 is joined to the steel plate 21.

  More specifically, in the first modification, the lower side of the axial streak 22 is fixed to the concrete forming the foundation 2, and the upper end 22 a protrudes from the upper surface 2 a of the foundation 2. The steel plate 21 joined to the lower end 6a of the lower steel frame 6 is provided with a hole 21a at a position outside the lower steel frame 6, and the upper end 22a of the axial bar 22 is inserted into the hole 21a from below. The nut 23 is screwed.

  The joint structure 20 can be basically constructed in the same manner as the joint structure 1. In the joining structure 1 shown in FIG. 1, the steel frame 5 is positioned so that the upper side of the axial reinforcement 12 protruding upward from the foundation 2 is outside the lower steel frame 6 and inside the reinforcement 10 and the hoop 11. Was built. In the joint structure 20, instead, the upper end 22 a of the axial bar 22 passes through the hole 21 a of the steel plate 21 at a position outside the lower steel frame 6 and inside the reinforcing bar 10 and the hoop bar 11. The nut 23 is screwed after being positioned.

  Needless to say, the first modified example acts in the same manner as in the above embodiment during an earthquake and has the same effects as in the above embodiment. In particular, since the upper end 22a of the axial streak 22 is fastened to the steel frame 5 via the steel plate 21, the joint structure 20 in the first modification acts on the axial streak 22 by the inclination of the column 3 during an earthquake. It is possible to counter strongly by the tensile force.

(Second Modification of Embodiment)
Next, a second modification of the bonding structure 1 shown as the embodiment will be described with reference to FIG. 4A is a side cross-sectional view of the bonding structure 30 in the second modification, and FIGS. 4B, 4C, and 4D are cross-sectional views taken along line GG ′ in FIG. It is HH 'sectional drawing and II' sectional drawing. The joining structure 30 in the second modification is a combination of the joining structure 1 described above and the joining structure 20 in the first modification.

  That is, the joint structure 30 includes two types of axial streaks 12 and 22, an outer axial streak 12 and an inner axial streak 22. The outer axial streak 12 is vertically provided between the foundation 2 and the column 3, and is fixed to the concrete forming the concrete portion 4 of the column 3 on the upper side and to the concrete forming the foundation 2 on the lower side. Thus, both 2 and 3 are joined.

  The inner axial stripe 22 is provided inside the outer axial stripe 12 and outside the lower steel frame 6. The lower side of the inner axial streak 22 is fixed to the concrete forming the foundation 2, and the upper end 22 a protrudes from the upper surface 2 a of the foundation 2. The steel plate 21 joined to the lower end 6a of the lower steel frame 6 is provided with a hole 21a at a position outside the lower steel frame 6, and the upper end 22a of the axial bar 22 is inserted into the hole 21a from below. The nut 23 is screwed.

  Needless to say, the second modified example acts in the same manner as in the above embodiment during an earthquake and has the same effects as in the above embodiment. In particular, in the joint structure 30 in the second modification example, the foundation 2 and the column 3 are joined by two types of axial streaks 12, 22 of the outer axial streak 12 and the inner axial streak 22. It is possible to strongly counteract by the tensile force acting on the axial streaks 12, 22 by the inclination of the column 3 at the time of earthquake.

(Third Modification of Embodiment)
Next, a third modification of the bonding structure 1 shown as the embodiment will be described with reference to FIG. FIG. 5 is a side sectional view of the joint structure 40 in the third modification. The joint structure 40 in the third modified example is different from the joint structure 1 described above in that the width at the lower end of the steel frame is not shorter than the width at the upper part and is equivalent.

  That is, the steel frame 5 in the above embodiment has a configuration in which two steel frames 6 and 7 having different widths are connected via the bonded steel plate 8 as shown in FIG. The steel frame 5 in the modified example includes a single steel frame 41 and has substantially the same width over the length direction. The width of the steel frame 41 does not interfere with the axial streak 12 and is larger than that which can hold the axial force when the steel frame 41 is constructed.

  The joint structure 40 in the third modified example has a width at which the steel frame 41 does not interfere with the axial streak 12 at the lower end portion 3 a, and the width is an axial force when the steel frame 41 is built over the entire column 3. It is applicable when the size is larger than the size that can hold That is, it goes without saying that the third modified example acts in the same manner as in the above embodiment during an earthquake and has the same effect as in the above embodiment. In particular, unlike the above-described embodiment, it is not necessary to join two types of steel frames to each other, so that the construction is further facilitated.

(Fourth Modification of Embodiment)
Next, the 4th modification of the joining structure 1 shown as the said embodiment is demonstrated using FIG. FIG. 6 is a side sectional view of the joint structure 50 in the fourth modified example, and shows only the concrete portion 4 and the steel frame 5. The joint structure 50 in the fourth modification is different from the joint structure 1 described above in that the lower end 5a of the steel frame 5 is in contact with the foundation 2 via the steel plate 9.

  That is, in the fourth modified example, the grout layer 13 as shown in FIG. 1 is not provided under the steel plate 9, and the steel plate 9 constituting the steel frame 5 is formed on the upper surface 2 a of the foundation 2. Are provided in direct contact.

  It goes without saying that the fourth modified example acts in the same manner as the above embodiment during an earthquake and has the same effect as the above embodiment.

(Fifth Modification of Embodiment)
Next, the 5th modification of the junction structure 1 shown as the said embodiment is demonstrated using FIG. FIG. 7 is a side sectional view of the joint structure 60 in the fifth modification, and shows only the concrete portion 4 and the steel frame 5. The joint structure 60 in the fifth modification is different from the joint structure 1 described above in that the column 61 is made of precast concrete, and the grout layer 63 is not only the lower side of the steel plate 9 of the steel frame 5 but also the lower surface of the concrete part 62. The difference is that it is formed in the entire region excluding the portion corresponding to the gap 14 of 62a.

  The lower surface 62a of the concrete portion 62 of the column 61 includes an inner horizontal portion 62e, an inclined portion 62b, and an outer horizontal portion 62c. The inner horizontal portion 62e is formed in a planar shape on the inner side from a certain position on the inner side from the outer surface 62d of the concrete portion 62. The inclined portion 62b is formed so as to be gradually inclined upward from the outer end of the inner horizontal portion 62e to the outer side. The outer horizontal portion 62 c is formed outside the inclined portion 62 b so as to extend between the outer end side of the inclined portion 62 b and the outer surface 62 d of the concrete portion 62.

  The grout layer 63 is formed over the entire area of the inner horizontal portion 62e on the lower surface 62a of the concrete portion 62, below the inner horizontal portion 62e.

  In the joining structure 1 shown in FIG. 1, at the time of construction, the lower steel frame 6, the upper steel frame 7, the joining steel plate 8 and the steel plate 9 are welded in a ground yard or the like to produce a steel frame 5, and a reinforcing bar is added thereto. A member in which 10 and the hoop reinforcement 11 are arranged is erected, and a grout layer 13 is formed by filling a grout between the steel plate 9 and the upper surface 2a of the foundation 2. In this joining structure 60, a grout layer 63 is formed under the inner horizontal part 62e, which is a part to be joined to the foundation 2, in order to build a pillar 61 manufactured as a precast concrete material at a factory.

  It goes without saying that the fifth modified example acts in the same manner as the above embodiment during an earthquake and has the same effect as the above embodiment.

  In addition, the joint structure between the foundation of the present invention and the column made of steel reinforced concrete and the building structure including the joint structure are not limited to the above-described embodiment and each modification described with reference to the drawings. Various other modifications are conceivable within the technical scope.

  For example, in the above embodiment, the cross-sectional shape of the column is rectangular, but other shapes such as a circle may be used. The shape of the steel plate joined to the lower end of the steel frame may also have other shapes along with the cross-sectional shape of the column.

  Moreover, in the said embodiment, although the width in the lower end part of a steel frame and the width in an upper part were made different by joining the steel frame from which two types of width differ through a joining steel plate, it is not restricted to this, For example, The shape may be such that the width of one steel frame gradually decreases as it goes downward.

  Other than this, as long as the gist of the present invention is not deviated, it is possible to select the configuration described in the above-described embodiment and each modification, or to appropriately change to another configuration.

DESCRIPTION OF SYMBOLS 1, 20, 30, 40, 50, 60 Joint structure 2 Foundation 3, 61 Column 3a Lower end part 4, 62 Concrete part 5, 41 Steel frame 5a Lower end 6 Lower steel frame 6a Lower end 7 Upper steel frame 8 Bonded steel sheet 9, 21 Steel sheet 10 Reinforcing bar 10a Lower end 12, 22 Axial reinforcing bar 22a Upper end 14 Gap

Claims (4)

It is a joint structure between a foundation and a steel reinforced concrete column,
The lower end portion of the column is narrowed so that the cross-sectional area decreases downward,
The lower end of the reinforcing bar of the column is terminated before reaching the foundation,
The lower end of the steel frame of the column is in contact with or close to the foundation,
Provided in the vertical direction between the foundation and the column, and provided with an axial streak joining the two, the axial streak is inside the rebar and on the outside of the steel frame in a horizontal sectional view A joint structure between a foundation and a steel reinforced concrete column that is located and resists the inclination of the column during an earthquake with a tensile force.   The joining structure of a foundation and a steel reinforced concrete column according to claim 1, wherein a steel plate is joined to a lower end of the steel frame, and an upper end of the axial reinforcement is joined to the steel plate.   The joint structure of a foundation and a steel reinforced concrete column according to claim 1 or 2, wherein a width at a lower end of the steel frame is shorter than a width at an upper portion.   The building structure in which the pillar located inside in the horizontal cross sectional view is joined to the foundation by the joining structure of the foundation according to any one of claims 1 to 3 and the pillar made of steel reinforced concrete.

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