JP7386036B2 - bonded structure - Google Patents

Description

The present invention relates to a bonded structure.

BACKGROUND ART Conventionally, techniques for joining concrete columns and beams that constitute a building have been proposed. Such technology includes, for example, a steel plate frame formed with a rectangular cross section, a reinforcing steel plate integrally formed within the steel plate frame, and a plurality of connecting rods passing through the steel plate frame laterally, each of which has a rectangular cross section. A technique (for example, see Patent Document 1) has been disclosed in which the protruding end of a connecting rod from a steel plate frame is connected to a beam main reinforcement via a coupler. Further, the outer diameter of the concrete column is set larger than the outer diameter of the steel plate frame.

Japanese Patent Application Publication No. 10-110471

Here, in the above conventional technology, as described above, the outer diameter of the concrete column is set larger than the outer diameter of the steel plate frame. If the outside diameter is smaller than the outside diameter, when placing the concrete column, it is necessary to pour additional concrete so that the outside diameter of the concrete pillar is larger than the outside diameter of the steel plate frame, which reduces the construction cost. There was a risk that the amount would become excessive. Therefore, there was room for improvement from the perspective of construction costs.

The present invention has been made in view of the above, and an object of the present invention is to provide a joined structure that can reduce construction costs.

In order to solve the above-mentioned problem and achieve the object, a joined structure according to claim 1 is a joined structure that joins concrete columns and beams that constitute a building, and is a joined structure that connects a concrete column and a beam that constitute a building, and that is a joined structure that connects a concrete column and a beam that constitute a building, and that comprises a steel cylindrical body. a joint section for joining the concrete column and the beam; a beam joining means for joining the beam to the cylindrical body; and a joint section for joining the beam to the cylindrical body; a mounting part provided in a part inserted into the tubular body, the mounting part for attaching the hanging fitting to the beam joining means, and the mounting part is provided in a part inserted into the tubular body, and the mounting part is configured to match the planar shape of the inner edge of the tubular body and the outer edge of the concrete column. The planar shape is a substantially same rectangular shape having each side along the left-right direction and the front-back direction, and the cylindrical body is a cylindrical body having a predetermined thickness, and the vertical direction of the cylindrical body is and the vertical axis of the concrete column coincide with each other, and the gap between the inner edge of the cylindrical body and the outer edge of the concrete column in plan view is The length of the gap is set to a length that can suppress leakage of concrete poured into the cylindrical body, and the length of the gap in plan view is set to be 1/1000 or less of the floor height of the concrete column. , the outer diameter of the cylindrical body is larger than the outer diameter of the concrete column, and the length of the cylindrical body in the left-right direction is four times the length of the concrete column in the left-right direction as the gap in plan view. The length of the cylindrical body in the front-rear direction was made longer than the length of the concrete column in the front-rear direction by four times the gap in plan view.

The joined structure according to claim 2 is the joined structure according to claim 1, wherein the planar shape of the outer edge of the cylindrical body and the planar shape of the outer edge of the concrete column are substantially the same rectangular shape, and The corner of the cylindrical body is formed into a rounded shape, the corner of the concrete column is formed into a chamfered shape, and the radius of the corner of the cylindrical body is four times the thickness of the cylindrical body. It was increased by about 10 times.

According to the bonded structure according to claim 1, the length of the gap in plan view is set to a length that can suppress leakage of concrete poured into the cylindrical body, so that it is possible to prevent concrete from leaking inside the cylindrical body. It is possible to suppress leakage of concrete from gaps in plan view during pouring. Therefore, compared to the conventional technology (technique in which the outer diameter of the concrete column is made larger than the outer diameter of the steel plate frame), it is possible to omit additional casting of concrete columns, and it is possible to suppress construction costs.
In addition, since the length of the gap in plan view is set to 1/1000 or less of the floor height of the concrete column, the length of the gap in plan view can be set in consideration of the construction accuracy of the concrete column. It is possible to suppress leakage of concrete from gaps in plan view while ensuring this.

According to the joint structure according to claim 2 , the outer diameter of the cylindrical body is made larger than the outer diameter of the concrete column, and the planar shape of the outer edge of the cylindrical body and the planar shape of the outer edge of the concrete column are approximately the same. They are made into the same rectangular shape, and the diameter of the radius at the corner of the cylindrical body is approximately 4 to 10 times the thickness of the cylindrical body, so the planar shape of the cylindrical body and the planar shape of the column are approximately the same. In the case where the cylindrical body has a rectangular shape, the rounded corners of the cylindrical body can give the joint part a sharp appearance. In addition, the required strength of the cylindrical body is ensured compared to when the diameter of the radius of the corner of the cylindrical body is less than 4 times the plate thickness of the cylindrical body or more than 10 times the plate thickness of the cylindrical body. At the same time, it becomes easier to achieve uniformity between the appearance of the corner of the cylindrical body and the appearance of the chamfered part of the concrete column.

FIG. 1 is a perspective view conceptually showing a joining structure according to an embodiment of the present invention. 2 is a cross-sectional view taken along the line AA in FIG. 1. FIG. FIG. 3 is an enlarged view of a peripheral region of a corner of the bonded structure shown in FIG. 2;

Embodiments of a joining structure according to the present invention will be described in detail below with reference to the accompanying drawings. First, [I] the basic concept of the embodiment will be explained, then [II] the specific contents of the embodiment will be explained, and finally [III] modifications to the embodiment will be explained. However, the present invention is not limited to the embodiments.

[I] Basic Concept of Embodiment First, the basic concept of the embodiment will be explained. Embodiments generally relate to a joint structure that joins concrete columns and beams that constitute a building.

Here, the specific structure and type of "building" is arbitrary, and the concept includes, for example, single-family houses, housing complexes such as apartments and condominiums, office buildings, buildings such as commercial facilities, etc. Here, the explanation will be given as a multi-level parking lot with multiple floors. Moreover, "joining a concrete column and a beam" means directly or indirectly connecting a concrete column and a joint structure, and also connecting a beam and a joint structure directly or indirectly.

[II] Specific contents of the embodiment Next, specific contents of the embodiment will be described.

(composition)
First, the configuration of the bonded structure 50 according to the embodiment and the configuration of the building 1 in which this bonded structure 50 is installed will be described.

(Composition - Building)
First, the configuration of the building 1 will be explained. FIG. 1 is a perspective view conceptually showing a bonded structure 50 according to an embodiment of the present invention (partial illustration is omitted). In the following explanation, the X direction in FIG. 1 is the left-right direction of building 1 (-X direction is the left direction of building 1, the +X direction is the right direction of building 1), and the Y direction in FIG. 1 is the front-back direction of building 1 (+Y The direction is the front of the building 1, the -Y direction is the back of the building 1), the Z direction in Figure 1 is the vertical direction of the building 1 (the +Z direction is the top of the building 1, the -Z direction is the bottom of the building 1) It is called.

The building 1 is, for example, a reinforced concrete building, which is located within a predetermined site, and includes a floor (not shown), walls (not shown), columns 10, and beams 20, as shown in FIG. There is.

(Composition - Building - Floor)
The floor is a member that constitutes the building 1, and is a member that constitutes the floors of the building 1. This floor is constructed using, for example, a known flooring material (for example, a concrete floor panel material), and a plurality of floors are arranged vertically in parallel at intervals from each other.

(Composition - Building - Wall)
The wall is a member constituting the building 1 and is a member for partitioning floors from each other. This wall is constructed using, for example, a known wall material (for example, a concrete wall material), and a plurality of walls are provided between the floors.

(Composition - Building - Pillar)
The pillar 10 is a member that constitutes the building 1 and is a member that supports the floor. The pillar 10 is constructed using, for example, a known elongated concrete pillar material (for example, a reinforced concrete pillar material or a prestressed concrete pillar material), and is arranged between the floors (i.e., between the floors of the building 1). A plurality of them are provided in each layer (space). Note that the pillar 10 will be referred to as a "concrete pillar 10" in the following description.

Furthermore, although the specific shape and length of the concrete pillar 10 are arbitrary, they are set as follows in the embodiment. That is, as shown in FIG. 1, the planar shape of the concrete pillar 10 is set to be approximately rectangular (specifically, square shape), and specifically, the corner of the concrete pillar 10 is chamfered. (Note that this chamfered portion is referred to as a "chamfered portion"). However, the shape is not limited to this, and may be set to other polygonal shapes such as a triangular shape, a circular shape, an elliptical shape, or the like. Further, the length of the concrete pillar 10 in the left-right direction is set shorter than the length of the floor portion in the left-right direction. However, the length is not limited to this, and may be set to be longer than or equal to the length of the floor in the left-right direction, for example. Further, the length of the concrete pillar 10 in the front-rear direction is set shorter than the length of the floor section in the front-rear direction. However, the length is not limited to this, and may be set to be longer than or equal to the length of the floor in the front-rear direction, for example. Further, the length of the concrete pillar 10 in the vertical direction is set shorter than the length in the vertical direction of the floor on which the concrete pillar 10 is installed.

(Composition - Building - Beam)
The beam 20 is a member that constitutes the building 1 and is a member that supports the floor. The beams 20 are constructed using, for example, known long steel beams (for example, steel or stainless steel beams), and a plurality of beams 20 are provided so as to be in contact with the lower surface of each floor. ing.

Furthermore, although the specific shape and length of the beam 20 are arbitrary, they are set as follows in the embodiment. That is, as shown in FIG. 1, the cross-sectional shape of the cross section perpendicular to the longitudinal direction of the beam 20 is set to be substantially I-shaped. However, the shape is not limited to this, and may be set in an L-shape, a straight line, etc., for example. Further, the length of the beam 20 in the longitudinal direction is set longer than the length of the concrete column 10 in the left-right direction or front-back direction. However, the length is not limited to this, and may be set to be longer than or equal to the length of the floor in the left-right direction, for example. Further, the length of the beam 20 in the width direction is set shorter than the length of the concrete column 10 in the left-right direction or the front-back direction. However, the length is not limited to this, and may be set to be longer than or equal to the length of the floor in the left-right direction, for example. Further, the length of the beam 20 in the vertical direction is set shorter than the length of the concrete column 10 in the vertical direction.

(Configuration - joined structure)
Next, the configuration of the bonded structure 50 will be explained. FIG. 2 is a sectional view taken along the line AA in FIG. 1 (partially not shown). The joint structure 50 is for joining the concrete column 10 and the beam 20. As shown in FIGS. 1 and 2, this joint structure 50 includes a concrete column 10 (specifically, the upper end of the concrete column 10) and a plurality of beams 20 (specifically, the longitudinal direction of each beam 20). The joint section 60, the first beam joint section 70, and the second beam joint section 80 are provided between the joint section 60, the end section of the beam joint section 70, and the second beam joint section 80. Note that the building 1 according to the embodiment is provided with joint structures 50 between each concrete column 10 and each beam 20, but since these can be configured in the same way, illustrations and detailed descriptions will not be provided. will be omitted, and the following description will focus on only one bonded structure 50. In addition, below, among the plurality of beams 20 connected to the joint structure 50, the beam 21 located on the left side is referred to as the "left side beam 21", and the beam 22 located on the right side is referred to as the "right side beam 22", The beam 23 located on the front side is referred to as the "front side beam 23", and the beam 24 located on the rear side is referred to as the "rear side beam 24".

(Configuration - joint structure - joint part)
Returning to FIG. 1, the joint part 60 is the basic structure of the joint structure 50, and as shown in FIGS. 1 and 2, a cylindrical body 61, a filling body 63, a first insertion hole (not shown), and a second insertion hole (not shown).

(Configuration - joint structure - joint part - cylindrical body)
Returning to FIG. 1, the cylindrical body 61 is the basic structure of the joint section 60. This cylindrical body 61 is constructed using, for example, a steel cylindrical body whose upper and lower ends are open, and is erected at the upper end of the concrete column 10 as shown in FIG. ing.

Moreover, although the specific shape and length of the cylindrical body 61 are arbitrary, they are set as follows in the embodiment. That is, as shown in FIGS. 1 and 2, the planar shape of the cylindrical body 61 is such that the planar shape of the outer edge of the cylindrical body 61 and the planar shape of the outer edge of the concrete column 10 are approximately the same rectangular shape. Specifically, it is set to have a substantially rectangular annular shape (square annular shape in FIG. 2), and each corner thereof is formed into a rounded shape. Further, the length of the cylindrical body 61 in the left-right direction and the front-back direction is set so that the outer diameter of the cylindrical body 61 is larger than the outer diameter of the concrete column 10. Specifically, the length of the cylindrical body 61 in the left-right direction is set longer than the length of the concrete column 10 in the left-right direction, and the length of the cylindrical body 61 in the front-rear direction is set to be longer than the length of the concrete column 10 in the left-right direction. It is set longer than the length in the front and rear direction of No. 10. Further, the length of the cylindrical body 61 in the vertical direction is set shorter than the length of the concrete column 10 in the vertical direction. In addition, below, among the side pieces 62 (hereinafter referred to as "tube side piece 62") that constitute the cylindrical body 61, the cylinder side piece 62a located on the left side will be referred to as the "left side cylinder side piece 62a", and the right side piece 62a will be referred to as the "left side cylinder side piece 62a". The cylinder side piece 62b located at 62d of cylinder side pieces.

(Configuration - joint structure - joint part - filling body)
Returning to FIG. 1, the filling body 63 is a reinforcing means for reinforcing the cylindrical body 61, and is a connecting means for connecting the concrete column 10 and the cylindrical body 61. The filler 63 is made of, for example, a known concrete filler, and is filled inside the cylindrical body 61 as shown in FIGS. It is connected to the concrete column 10 via a plurality of reinforcing bars (not shown, or steel plates, etc.) that protrude upward from the section.

(Configuration - Joint structure - Joint part - First insertion hole)
The first insertion hole is an insertion hole (through hole) for inserting the first beam joint portion 70 into the cylindrical body 61. This first insertion hole is formed to have substantially the same cross-sectional shape as the first beam joint portion 70 along the YZ plane, and is provided in the left cylinder side piece 62a and the right cylinder side piece 62b, respectively. ing.

(Configuration - joint structure - joint part - second insertion hole)
The second insertion hole is an insertion hole (through hole) for inserting the second beam joint portion 80 into the cylindrical body 61. This second insertion hole is formed to have substantially the same cross-sectional shape as the second beam joint portion 80 along the XZ plane, and is provided in the front cylinder side piece 62c and the rear cylinder side piece 62d, respectively. It is being Note that the details of the configuration of the joint section 60 will be described later.

(Configuration - Jointed structure - First beam joint)
Returning to FIG. 1, the first beam joining section 70 is a beam joining means that joins the left beam 21 and the right beam 22 to the cylindrical body 61. The first beam joint 70 is constructed using, for example, a known steel beam material, and is provided so as to be inserted into the cylindrical body 61 through the first insertion hole. Each of the beams 22 is connected to each other by a fixture or the like via a joint member (not shown).

Moreover, although the specific shape and length of the first beam joint 70 are arbitrary, they are set as follows in the embodiment. That is, as shown in FIGS. 1 and 2, the cross-sectional shape of the first beam joint 70 along the YZ plane is the same as the cross-sectional shape of the left beam 21 (or right beam 22) along the YZ plane. For example, it is set to be approximately I-shaped. Further, the length of the first beam joint 70 in the left-right direction is set longer than the length of the concrete column 10 in the left-right direction. Further, the length of the first beam joint 70 in the front-rear direction is set shorter than the length of the concrete column 10 in the front-rear direction. Further, the length of the first beam joint 70 in the vertical direction is set shorter than the length of the concrete column 10 in the vertical direction.

Further, although the specific configuration of the first beam joint portion 70 is arbitrary, in the embodiment, a mounting portion (not shown) having a mounting hole (not shown) for attaching a hanging fitting (for example, an eye bolt) is used. By providing this, the assembled joint structure 50 (excluding the filling body 63) may be transported by a crane or the like using a hanging fitting attached to the mounting hole. Although the installation position of this attachment part is arbitrary, for example, by installing the attachment part so that it is accommodated inside the cylindrical body 61 when the joint structure 50 is assembled, the attachment part can be installed at any position. may be prevented from being exposed to the outside. Moreover, this attachment part may be provided in the second beam joint part 80, for example.

(Configuration - Joint structure - Second beam joint)
Returning to FIG. 1, the second beam joining section 80 is a beam joining means that joins the front beam 23 and the rear beam 24 to the cylindrical body 61. The second beam joint 80 is constructed using, for example, a known steel beam material, and is inserted into a cylindrical shape through an insertion hole (not shown) formed in the first beam joint 70 and a second insertion hole. It is provided so as to pass through the body 61, and is connected to each of the front side beam 23 and the rear side beam 24 by a fixture or the like via a joint member (not shown).

Furthermore, although the specific shape and length of the second beam joint portion 80 are arbitrary, they are set as follows in the embodiment. That is, as shown in FIGS. 1 and 2, the cross-sectional shape of the second beam joint 80 along the X-Z plane is the same as the cross-sectional shape of the front beam 23 (or rear beam 24) along the X-Z plane. The shape is set to be approximately the same as the shape, for example, approximately I-shaped. Further, the length of the second beam joint portion 80 in the left-right direction is set shorter than the length of the concrete column 10 in the left-right direction. Further, the length of the second beam joint 80 in the front-rear direction is set longer than the length of the concrete column 10 in the front-rear direction. Further, the length of the second beam joint 80 in the vertical direction is set shorter than the length of the concrete column 10 in the vertical direction.

With such a configuration of the joint structure 50, it is possible to connect the joint part 60 and the concrete column 10, and also connect the first beam joint part 70 and the second beam joint part 80 to the plurality of beams 20. be able to.

(Details of composition - joint structure - joint part composition)
Next, details of the configuration of the joint section 60 will be explained. FIG. 3 is an enlarged view of a region around a corner of the joining structure 50 of FIG. 2. As shown in FIG. In the embodiment, the features of the structure of the cylindrical body 61 of the joint portion 60 are as shown below.

(Configuration - Joint structure - Details of the structure of the joint part - First feature)
First, regarding the first feature of the cylindrical body 61, as shown in FIG. 2 and FIG. The length (referred to as "FS") is set to a length that can suppress leakage of the concrete placed in the cylindrical body 61 (specifically, the concrete for forming the filling body 63). There is. Note that "the gap between the cylindrical body 61 and the concrete column 10 in plan view" refers to the gap between the end of the cylindrical body 61 on the concrete column 10 side and the cylindrical shape of the concrete column 10 when seen from the plane direction. It means the space between the end on the body 61 side, and in the embodiment, it corresponds to the space between the inner edge of the cylindrical body 61 and the outer edge of the concrete column 10.

Specifically, the length of the gap FS in plan view is set to be equal to or less than 1/1000 of the floor height (length in the vertical direction) of the concrete pillar 10. For example, when the floor height of the concrete column 10 is 6000 mm, the gap FS in plan view may be set to be equal to or less than 6 mm (floor height of the concrete column 10 x 1/1000 = 6000 x 1/1000). Here, the reason for setting the length to be ``1/1000 or less of the floor height of the concrete column 10'' is that the length of the concrete column 10 is generally required to absorb construction errors. By setting the length to 1/1000 of the height as a standard, it is possible to ensure the construction accuracy of the concrete pillar 10 and to avoid leakage of concrete from the gap FS in plan view when pouring concrete. This is to do so.

Further, as shown in FIG. 2, the cylindrical body 61 is configured such that a gap FS in plan view is formed around the entire concrete column 10 when viewed from the planar direction. More specifically, the length of the cylindrical body 61 in the left-right direction is set to be longer than the length of the concrete column 10 in the left-right direction by twice the gap FS in plan view, and The length in the front-rear direction is set to be longer than the length of the concrete column 10 in the front-rear direction by twice the length of the gap FS in plan view. The cylindrical body 61 is arranged such that the vertical axis of the cylindrical body 61 and the vertical axis of the concrete column 10 coincide with each other.

With such a first feature, when concrete is placed inside the cylindrical body 61, leakage of concrete from the gap FS in plan view can be suppressed. Therefore, compared to the conventional technique (technique in which the outer diameter of the concrete column 10 is made larger than the outer diameter of the steel plate frame), additional casting of the concrete column 10 can be omitted, and construction costs can be suppressed. In addition, since the length of the gap FS in plan view is set to be less than or equal to the floor height of the concrete column 10, the length of the gap FS in plan view can be set in consideration of the construction accuracy of the concrete column 10. It becomes possible to suppress leakage of concrete from the gap FS in plan view while ensuring construction accuracy.

(Configuration - Joint structure - Details of the structure of the joint part - Second feature)
Next, regarding the second feature of the cylindrical body 61, as described above, the outer diameter of the cylindrical body 61 is set larger than the outer diameter of the concrete column 10, and the planar shape of the outer edge of the cylindrical body 61 is The planar shape of the outer edge of the concrete column 10 is set to approximately the same rectangular shape, and the corner of the cylindrical body 61 is formed in a rounded shape (the rounded portion and the corner of the concrete column 10 are formed in a chamfered shape). In addition, as shown in FIG. 3, the radius R of the corner of the cylindrical body 61 is set to be approximately 4 to 10 times the thickness t of the cylindrical body 61.

For example, when the width W of the chamfered part of the concrete column 10 is 15 mm, and the plate thickness t of the cylindrical body 61 is 6 mm, the diameter R of the radius of the corner of the cylindrical body 61 is the thickness of the cylindrical body 61. By setting it to about four times t (that is, 6 mm x 4 = 24 mm), the ratio of the radius R of the corner of the cylindrical body 61 and the width W of the chamfered part of the concrete column 10 = 24 mm / 15 mm. = may be set to about 1.6. Based on this example, if the radius R of the corner of the cylindrical body 61 is set to about 4 to 10 times the thickness t of the cylindrical body 61, the above ratio should be set to 1. Since the required strength of the cylindrical body 61 can be set to about 6 to 4 times, the required strength of the cylindrical body 61 can be set to about 6 to 4 times. While ensuring uniformity in appearance of the corner portion of the cylindrical body 61 and the appearance of the chamfered portion of the concrete column 10, it becomes easy to achieve consistency.

Due to such a second feature, when the planar shape of the cylindrical body 61 and the planar shape of the column are substantially the same rectangular shape, the corners of the cylindrical body 61 are rounded, so that the joint part 60 can be given a sharp appearance. Moreover, compared to the case where the radius R of the corner of the cylindrical body 61 is less than 4 times the plate thickness t of the cylindrical body 61 or more than 10 times the plate thickness t of the cylindrical body 61, the cylindrical While ensuring the necessary strength of the body 61, it becomes easier to achieve uniformity in the appearance of the corner portion of the cylindrical body 61 and the appearance of the chamfered portion of the concrete column 10.

(Construction method of bonded structure)
Next, a method for constructing the bonded structure 50 according to the embodiment will be described. The construction method of the bonded structure 50 according to the embodiment includes a concrete column forming process, an assembly process, a placement process, a filling process, and a beam joining process.

(Construction method of jointed structure - concrete column formation process)
First, the concrete column forming process will be explained. The concrete column forming process is a process for forming the concrete column 10.

Specifically, inside the building 1, formwork is installed around where the concrete pillars 10 are installed. Next, after placing multiple reinforcing bars in the formwork, concrete is poured and placed. Note that the plurality of reinforcing bars are arranged so as to protrude above the formwork. After the poured concrete has hardened for a predetermined period of time, the formwork is removed. In this case, the specific shape and size of the formwork is such that it can be formed into the shape and size of the concrete column 10 without taking into account additional concrete pouring, and It is configured in such a shape that it is possible to form a concrete column 10 having a chamfered portion by simply installing the concrete pillar 10. Thereby, the concrete pillar 10 can be made compact, and the concrete pillar 10 can be formed efficiently.

(Construction method of bonded structure - assembly process)
Next, the assembly process will be explained. The assembly process is a process for assembling the joint structure 50 (excluding the filling body 63) after the concrete column forming process (or before the concrete column forming process).

Specifically, at a position near the concrete column 10 (or in a factory), after inserting the first beam joint 70 into the cylindrical body 61 through the first insertion hole, the second beam joint 80 is inserted into the first beam It is assembled by inserting it into the cylindrical body 61 through the insertion hole of the joint part 70 and the second insertion hole.

(Construction method of bonded structure - placement process)
Next, the arrangement process will be explained. The placement process is a process after the assembly process, in which the joint structure 50 assembled in the assembly process is placed on the concrete column 10.

Specifically, after attaching a hanging tool to the mounting portion of the joint structure 50, the joint structure 50 is lifted using a crane, thereby placing the joint structure 50 at the upper end of the concrete column 10. More specifically, the cylindrical body 61 is arranged so that a gap FS in plan view is formed around the entire circumference of the concrete column 10 when viewed from the plane direction, and a plurality of reinforcing bars protruding upward from the concrete column 10 are arranged. It is arranged so as to be located inside the joining structure 50.

(Construction method of bonded structure - filling process)
Next, the filling process will be explained. The filling process is a process for filling the inside of the joint part 60 with the filling body 63 after the arrangement process.

Specifically, concrete is poured and cast into the inside of the cylindrical body 61 placed in the placement step, and then the poured concrete is solidified for a predetermined period of time, thereby filling. Thereby, the cylindrical body 61 and the concrete column 10 can be joined via the plurality of reinforcing bars protruding upward. Further, although a gap FS in plan view is formed between the cylindrical body 61 and the concrete column 10, leakage of concrete from the gap FS in plan view is suppressed, so that concrete cannot be placed inside the cylindrical body 61. The filling body 63 can be reliably filled into the cylindrical body 61. However, the present invention is not limited to this, and for example, leakage of concrete from the planar gap FS may be avoided by further closing the lower end of the planar gap FS with a known backup material.

(Construction method of jointed structure - beam joining process)
Next, the beam joining process will be explained. The beam joining process is a process for joining the plurality of beams 20 and the joining structure 50 after the filling process.

Specifically, while the left beam 21 (or right beam 22) is suspended using a crane or the like, the left beam 21 (or right beam 22) and the first beam joint 70 are connected via a joint member. and connect with fixtures etc. Similarly, with the front beam 23 (or rear beam 24) suspended using a crane or the like, the front beam 23 (or rear beam 24) and the second beam joint 80 are connected. Connect with a fixture or the like via a joint member.

By the construction method of the bonded structure 50 as described above, compared to the conventional technology (technique in which the outer diameter of the concrete column 10 is made larger than the outer diameter of the steel plate frame), the additional pouring work of the concrete column 10 can be omitted, and the construction It becomes possible to suppress costs. Further, since the placement process is performed after the assembly process, the bonded structure 50 (excluding the filler 63) can be installed efficiently and safely, and the workability of the bonded structure 50 can be improved.

(Effects of embodiment)
As described above, according to the embodiment, the length of the gap FS in plan view is set to a length that can suppress leakage of the concrete placed inside the cylindrical body 61, so that the concrete is not placed inside the cylindrical body 61. It is possible to suppress leakage of concrete from the gap FS in plan view when pouring concrete. Therefore, compared to the conventional technique (technique in which the outer diameter of the concrete column 10 is made larger than the outer diameter of the steel plate frame), additional casting of the concrete column 10 can be omitted, and construction costs can be suppressed.

In addition, since the length of the gap FS in plan view is set to be equal to or less than 1/1000 of the floor height of the concrete column 10, the length of the gap FS in plan view can be set in consideration of the construction accuracy of the concrete column 10. It becomes possible to suppress leakage of concrete from the gap FS in plan view while ensuring construction accuracy of the pillar 10.

Further, the outer diameter of the cylindrical body 61 is made larger than the outer diameter of the concrete column 10, and the planar shape of the outer edge of the cylindrical body 61 and the planar shape of the outer edge of the concrete column 10 are made substantially the same rectangular shape. Since the diameter R of the corner radius of the shaped body 61 is set to about 4 to 10 times the plate thickness t of the cylindrical body 61, the planar shape of the cylindrical body 61 and the planar shape of the column are substantially the same rectangle. In the case where the corner portions of the cylindrical body 61 are rounded, the appearance of the joint portion 60 can be given a sharp finish. Moreover, compared to the case where the radius R of the corner of the cylindrical body 61 is less than 4 times the plate thickness t of the cylindrical body 61 or more than 10 times the plate thickness t of the cylindrical body 61, the cylindrical While ensuring the necessary strength of the body 61, it becomes easier to achieve uniformity in the appearance of the corner portion of the cylindrical body 61 and the appearance of the chamfered portion of the concrete column 10.

[III] Modifications to the Embodiments The embodiments of the present invention have been described above, but the specific configuration and means of the present invention are within the scope of the technical idea of each invention described in the claims. , can be modified and improved as desired. Hereinafter, such a modified example will be explained.

(About the problems to be solved and the effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above-mentioned contents, and the present invention can solve problems not described above or achieve effects not described above. In addition, it may solve only a part of the described problem or produce only a part of the described effect.

(About shape, numbers, structure, time series)
With respect to the components illustrated in the embodiments and drawings, the shape, numerical values, structure or chronological relationship of multiple components may be arbitrarily modified and improved within the scope of the technical idea of the present invention. I can do it.

(About beams)
In the above embodiment, it has been explained that the beam 20 is made of steel, but the beam 20 is not limited to this, and may be made of concrete, for example.

(About concrete pillars)
In the embodiment described above, it has been described that the corners of the concrete pillar 10 are formed in a chamfered shape, but the corner portions are not limited to this, and may not be formed in a chamfered shape, for example.

(About the bonded structure)
In the above embodiment, it has been explained that the planar shape of the outer edge of the cylindrical body 61 is set to be substantially the same rectangular planar shape as the planar shape of the outer edge of the concrete column 10. It may be set to a rectangular shape different from the planar shape of the outer edge of No. 10 or a shape other than the rectangular shape (for example, a circular shape, etc.).

Further, in the embodiment described above, it has been described that the corners of the cylindrical body 61 are formed in a rounded shape, but the corner portions are not limited to this, and may not be formed in a rounded shape, for example.

Further, in the above embodiment, it has been explained that the number of beams 20 to be joined to the joined structure 50 is four, but the number is not limited to this, for example, the number may be less than three, or it may be five. It may be more than that. In this case, the number of insertion holes corresponding to the number of beams 20 may be formed in the joint portion 60, and the number of beam joining means corresponding to the number of beams 20 may be provided.

(About the gap in plan view)
In the above embodiment, it has been explained that the length of the gap FS in plan view is set to be equal to or less than 1/1000 of the story height of the concrete column 10, but the length is not limited to this. For example, if concrete can be prevented from leaking when concrete is poured inside the cylindrical body 61 in the filling process of the construction method of the jointed structure 50, the story height (vertical length) of the concrete column 10 can be reduced. The length may be set to exceed 1/1000.

(About construction method of jointed structure)
Although in the embodiment described above, the arrangement process is performed after the assembly process, the present invention is not limited to this. For example, the placement process may be omitted by performing the assembly process at the upper end of the concrete column 10 using a crane or the like.

(Additional note)
The joint structure in Appendix 1 is a joint structure that joins concrete columns and beams constituting a building, and is a joint section having a steel cylindrical body, which connects the concrete columns and the beams. It is provided with a joint part for joining, and the length of the gap in plan view, which is the gap between the cylindrical body and the concrete column in plan view, is such that the concrete cast inside the cylindrical body does not leak. is set to a length that can be suppressed.

In the jointed structure according to Appendix 2, in the jointed structure according to Appendix 1, the length of the gap in plan view is set to be equal to or less than 1/1000 of the floor height of the concrete column.

The jointed structure according to Supplementary note 3 is the jointed structure according to Supplementary note 1 or 2, in which the outer diameter of the cylindrical body is larger than the outer diameter of the concrete column, and the outer edge of the cylindrical body has a planar shape. The planar shape of the outer edge of the concrete column is approximately the same rectangular shape, the corner of the cylindrical body is formed into a rounded shape, the corner of the concrete column is formed in a chamfered shape, and the corner of the cylindrical body is formed into a chamfered shape. The diameter of the corner radius was set to be about 4 to 10 times the thickness of the cylindrical body.

(Effect of appendix)
According to the bonded structure described in Appendix 1, the length of the gap in plan view is set to a length that can suppress leakage of concrete poured into the cylindrical body, so that it is possible to prevent concrete from being poured inside the cylindrical body. It is possible to suppress leakage of concrete from gaps in plan view during installation. Therefore, compared to the conventional technology (technique in which the outer diameter of the concrete column is made larger than the outer diameter of the steel plate frame), it is possible to omit additional casting of concrete columns, and it is possible to suppress construction costs.

According to the bonded structure described in Appendix 2, the length of the gap in plan view is set to be equal to or less than 1/1000 of the floor height of the concrete column, so the length of the gap in plan view is determined in consideration of the construction accuracy of the concrete column. This makes it possible to control the leakage of concrete from gaps in plan view while ensuring the accuracy of concrete pillar construction.

According to the bonded structure described in Appendix 3, the outer diameter of the cylindrical body is larger than the outer diameter of the concrete column, and the planar shape of the outer edge of the cylindrical body and the planar shape of the outer edge of the concrete column are approximately the same. The diameter of the corner radius of the cylindrical body is approximately 4 to 10 times the thickness of the cylindrical body, so that the planar shape of the cylindrical body and the planar shape of the column are approximately the same. In the case of a rectangular shape, the corner portions of the cylindrical body are rounded so that the appearance of the joint portion can be finished sharply. In addition, the required strength of the cylindrical body is ensured compared to when the diameter of the radius of the corner of the cylindrical body is less than 4 times the plate thickness of the cylindrical body or more than 10 times the plate thickness of the cylindrical body. At the same time, it becomes easier to achieve uniformity between the appearance of the corner of the cylindrical body and the appearance of the chamfered part of the concrete column.

1 Building 10 Concrete column 20 Beam 21 Left beam 22 Right beam 23 Front beam 24 Rear beam 50 Joint structure 60 Joint section 61 Cylindrical body 62 Cylinder piece 62a Left cylinder side piece 62b Right cylinder side piece 62c Front cylinder side Piece 62d Rear cylinder side piece 63 Filler 70 First beam joint 80 Second beam joint FS Planar view gap

Claims (2)

A joint structure that connects concrete columns and beams that make up a building,
a joint part having a cylindrical body made of steel, the joint part for joining the concrete column and the beam;
beam joining means for joining the beam to the cylindrical body;
an attachment part provided in a portion of the beam joining means that is inserted into the cylindrical body, the attachment part for attaching a hanging fitting to the beam joining means;
The planar shape of the inner edge of the cylindrical body and the planar shape of the outer edge of the concrete column are substantially the same rectangular shape having sides along the left-right direction and the front-back direction,
The cylindrical body is a cylindrical body having a predetermined thickness, and is arranged so that the vertical axis of the cylindrical body and the vertical axis of the concrete column coincide,
The length of the gap in plan view, which is the gap between the inner edge of the cylindrical body and the outer edge of the concrete column in plan view, is determined to be a length that can suppress leakage of concrete poured into the cylindrical body. Satoshi,
The length of the gap in plan view is equal to or less than 1/1000 of the floor height of the concrete column,
The outer diameter of the cylindrical body is made larger than the outer diameter of the concrete column,
The length of the cylindrical body in the left-right direction is made longer than the length of the concrete column in the left-right direction by four times the length of the gap in plan view,
The length of the cylindrical body in the front and back direction is longer than the length of the concrete column in the front and back direction by four times the length of the gap in plan view.
bonded structure. The planar shape of the outer edge of the cylindrical body and the planar shape of the outer edge of the concrete column are substantially the same rectangular shape,
The corners of the cylindrical body are formed into a rounded shape,
forming a corner of the concrete pillar into a chamfered shape;
The radius of the corner of the cylindrical body is approximately 4 to 10 times the thickness of the cylindrical body.
The joining structure according to claim 1.

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