JP2022054706A - Column connection structure of building unit - Google Patents

Abstract

To provide a column connection structure of a building unit capable of setting any position of the column to achieve a high design freedom and reassuring a structural resistance of the column.SOLUTION: In a column connection structure of a building unit, a center column 40 comprises upper and lower end plates 41 fastened to a roof girder 10 and a floor girder by a bolt 101 and a nut 102. Each end plate 41 comprises a thick plate part 411 welded to the center column 40 and a plate part for fastening 412 welded to the thick plate part 411. The plate part for fastening 412 comprises a base plate part 412a fastened to a lower flange 11 and an upper flange by the bolt 101 and the nut 102 and a lateral plate part 412b formed integrally with the base plate part 412a and provided along a web 12 of a lateral surface of each girder 10.SELECTED DRAWING: Figure 5

Description

The present disclosure relates to a column connection structure of a building unit.

Conventionally, the building unit that constructs a unit building is known to have four steel columns arranged upright at the four corners of a rectangle, with the upper ends and lower ends joined together by welding steel beams. (See, for example, Patent Document 1). In this prior art, in the connection between a column and a beam, it is common to connect the beam to the side surfaces of the upper end and the lower end of the column, that is, a so-called column-winning connection.

Japanese Unexamined Patent Publication No. 2018-031220

However, in the above-mentioned conventional technique, the positions of the pillars are generally set to the four corners of the building unit, and the degree of freedom in design is low. In addition, when the position of the pillar is arbitrarily set according to the arrangement of the living room, the length and shape of the beam will be different from the one in which the pillar is arranged at the four corners, and a beam of a certain size and shape is used. Compared to the case, it requires labor and cost for manufacturing. Further, in the case of a so-called beam-winning structure in which columns are set at arbitrary positions between the upper and lower beams, it is difficult to secure the structural strength of the columns as compared with the conventional technique of the so-called column-winning structure.

Therefore, it is an object of the present disclosure to provide a column connection structure of a building unit capable of setting the position of columns arbitrarily to have a high degree of freedom in design and ensuring the structural strength of columns. ..

The column connection structure of the building unit of the present disclosure is formed by connecting columns to the vertically facing facing surfaces of the girder, and the column is an end fastened to the girder by a fastener at at least one of the upper and lower end portions. Equipped with a plate. The end plate includes a plate portion joined to the pillar by welding and a fastening plate portion joined to the plate portion by welding and fastened to the girder by a fastener. The thick plate portion has the required rigidity and has a thicker plate thickness than the fastening plate portion. The fastening plate portion abuts on the facing surface of the girder to be coupled, and abuts on the facing surface at a portion where the dimension in the direction along each girder is larger than that of the thick plate portion. It is provided with a base plate portion fastened by the above and a side plate portion formed integrally with the base plate portion and provided along the side surface of the girder.

In the column connection structure of the building unit of the present disclosure, the position of the column can be arbitrarily set to obtain a high degree of freedom in design, and it is possible to secure the structural strength of the column.

It is a perspective view which shows the outline of the building unit U1 of embodiment. It is a perspective view which shows the outline of the building unit U2 of embodiment. It is a perspective view which shows the outline of the building unit U3 of embodiment. It is a side view which shows the pillar structure of a building unit U1. It is a figure which shows the connection structure of the upper end part of the central pillar 40 of a building unit U1, (a) is a side view seen from the short side direction of a unit, (b) is a side view seen from the long side direction of a unit. It is a figure which shows the connection structure of the lower end part of the middle pillar 40 of a building unit U1, (a) is a side view seen from the short side direction of a unit, (b) is a side view seen from the long side direction of a unit. It is an arrow view seen from the direction of the arrow S7-S7 of FIG. It is an arrow view seen from the direction of the arrow S8-S8 of FIG. It is an arrow view seen from the direction of the arrow S9-S9 of FIG. It is an arrow view seen from the direction of the arrow S10-S10 of FIG. It is a side view which shows the connection structure of a column 340. It is a figure which shows the connection structure of the upper end part of a pillar 340, (a) is a side view seen from the short side direction of a unit, (b) is a side view seen from the long side direction of a unit. It is a figure which shows the connection structure of the lower end part of a pillar 340, (a) is a side view seen from the short side direction of a unit, (b) is a side view seen from the long side direction of a unit.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.
(Embodiment)
The column connection structure of the building unit of the embodiment is applied to the building units U1, U2, and U3 shown in FIGS. 1 to 3.

(Outline of building unit)
These building units U1 to U3 are used to construct a unit building (not shown). That is, a unit building (not shown) can be constructed by arbitrarily connecting these building units U1 to U3 and other building units (not shown) in the horizontal direction or the vertical direction.

Here, first, the building unit U1 shown in FIG. 1 will be described. The building unit U1 includes a roof girder 10, a floor girder 20, a pillar 30, and a middle pillar 40. In the figure, the direction along the horizontal long side of the building unit U1 which is the direction of the arrow LS is the unit long side direction, and the direction along the horizontal short side of the building unit U1 which is the direction of the arrow SS is the unit short. The side direction, the direction of the arrow UP is upward, and the direction of the arrow DN is downward.

The roof girder 10 and the floor girder 20 are formed of C-shaped steel having a substantially U-shaped cross section. That is, as shown in FIG. 5B, the roof girder 10 is formed in a substantially U-shaped cross-sectional shape in which the lower flange 11 and the upper flange 13 are provided above and below the web 12. Further, as shown in FIG. 6B, the floor girder 20 is also formed in a substantially U-shaped cross-sectional shape in which the lower flange 21 and the upper flange 23 are provided above and below the web 22.

Further, the pillar 30 is formed of a square cylindrical steel plate. The structures of both girders 10, 20 and columns 30 are the same as those described in Patent Document 1. That is, the columns 30 are arranged at the four corners of the building unit U1, and the upper and lower ends of the columns 30 and the girders 10 and 20 are joined by welding with the reinforcing plates 31 interposed therebetween.

In the building unit U1, a plurality of ceiling joists 51 are bridged and connected to a pair of roof joists 10 and 10 located on the long side and facing each other. Further, a plurality of floor beam 52s are bridged and connected to a pair of floor beams 20 and 20 located on the long side side of the building unit U1 and facing each other.

(Connected structure of middle pillar)
Next, the connection structure between the upper end and the lower end of the middle pillar 40 and the roof girder 10 and the floor girder 20 of the building unit U1 will be described.

The center pillar 40 is located in the middle of one of the pair of long sides of the building unit U1 and is provided in an upright state between the roof girder 10 and the floor girder 20 in a so-called “beam win” state. It is a pillar that was made. Therefore, it can be installed at an arbitrary position between the girders 10 and 20. It should be noted that such a central pillar 40 can be used, for example, when a photovoltaic power generation panel is installed on the roof or when it is additionally set for reinforcement such as when it is installed in an area with a lot of snow.

The middle pillar 40 is formed of a thin square pipe made of steel plate, and as shown in FIGS. 7 and 8, the middle pillar 40 is formed in a cylindrical shape having a substantially rectangular cross section, and the short side is in the unit long side direction (arrow LS). It is arranged along the direction along). Further, the length on the long side of the middle pillar 40 is larger than the width dimension of each of the girders 10 and 20, and the one having a smaller cross section than the pillar 30 is used.

The middle column 40 is provided with a function (structural strength) of bearing not only a vertical load but also a horizontal load (seismic force, wind pressure). The middle pillar 40 includes upper and lower end plates 41, 42 and upper and lower stiffeners 60, 70, which will be described later, in order to impart such structural strength. Below, these upper and lower end plates 41, 42 and upper and lower stiffeners 60, 70 will be described.

<End plate configuration>
First, the upper end plate 41 and the lower end plate 42 will be described with reference to FIGS. 4 to 6.

(Structure of upper end plate)
As shown in FIG. 4, the upper end plate 41 is provided at the upper end portion of the middle pillar 40, and the lower end plate 42 is provided at the lower end portion of the middle pillar 40.

As shown in FIG. 5, the upper end plate 41 includes a thick plate portion 411 and a fastening plate portion 412 from the lower side. The thick plate portion 411 and the fastening plate portion 412 are joined to each other by welding, and the thick plate portion 411 is welded to the middle pillar 40.

The thick plate portion 411 is formed of a rectangular steel plate having a plate thickness (for example, about 9 mm) twice that of the fastening plate portion 412, and is joined to the upper end of the middle column 40 by welding. As shown in FIG. 5A, the thick plate portion 411 has a larger dimension in the unit long side direction than the dimension in the unit long side direction of the middle pillar 40, and a pair of upper stiffeners 60 described later. The vertical plate 62 is formed to have a size larger than the size of the distance in the unit long side direction. The plank portion 411 is formed so that the dimension in the unit short side direction is slightly larger than the dimension in the unit short side direction of the middle pillar 40, as shown in FIG. 5 (b).

The fastening plate portion 412 is made of a steel plate having a plate thickness (for example, 4.5 mm) of about 1/2 that of the thick plate portion 411, and has a base plate portion 412a and a side plate portion 412b as shown in FIG. 5 (b). Is formed into a substantially L-shaped cross-sectional shape. Then, in the fastening plate portion 412, the lower surface of the base plate portion 412a is joined to the lower surface of the thick plate portion 411 by welding.

Further, in the fastening plate portion 412, at least the dimension of the base plate portion 412a in the unit long side direction is larger than the dimension of the middle pillar 40 in the unit long side direction as shown in FIG. 5A, and The lower stiffener 70 is formed to have substantially the same dimensions as the unit long side direction of the attachment plate 71, which will be described later. In the present embodiment, the unit long side dimension of the side plate portion 412b is also formed to be the same as that of the base plate portion 412a, but the dimension is different from that of the base plate portion 412a depending on the required toughness described later. Can be formed.

On the other hand, the fastening plate portion 412 is formed so that the dimension in the unit short side direction is slightly larger than the dimension in the unit short side direction of the middle pillar 40, as shown in FIG. 5 (b). The side plate portion 412b of the fastening plate portion 412 is formed so that its vertical dimension is about 1/3 of the height of the web 12.

Further, the fastening plate portion 412 is formed with a pair of insertion holes 413 for inserting bolts 101 as fasteners for fastening the middle pillar 40 to the roof girder 10.

The sum of the plate thickness of the thick plate portion 411 and the plate thickness of the base plate portion 412a of the fastening plate portion 412 is formed so as not to be lower than the height of the ceiling CE shown in FIG. 5 (a). Has been done. That is, the plate thickness of the base plate portion 412a and the plate thickness of the thick plate portion 411 are set so that the position of the lower surface of the thick plate portion 411 is located higher than the position of the lower surface of the ceiling joist 51. There is.

(Structure of lower end plate)
As shown in FIG. 6, the lower end plate 42 includes a thick plate portion 421 and a fastening plate portion 422. The lower end plate 42 is formed symmetrically with the upper end plate 41 in the vertical direction. The thick plate portion 421 and the fastening plate portion 422 of the lower end plate 42 are formed of the same steel plates as the thick plate portion 411 and the fastening plate portion 412 of the upper end plate 41, and are joined to each other by welding to have a thickness. The plate portion 421 is joined to the middle pillar 40 by welding.

Further, the fastening plate portion 422 is formed by a base plate portion 422a and a side plate portion 422b. An insertion hole 423 for inserting the bolt 101 is formed in the base plate portion 422a of the fastening plate portion 422.

The sum of the thickness of the thick plate portion 421 and the plate thickness of the base plate portion 422a of the fastening plate portion 422 is formed so as not to be higher than the height of the floor FL shown in FIG. 6A. Has been done. That is, the plate thickness of the base plate portion 422a and the plate thickness of the thick plate portion 421 are set so that the position of the upper surface of the thick plate portion 421 is located lower than the position of the upper surface of the floor beam 52. ing.

<Composition of upper and lower stiffeners>
As shown in FIG. 4, an upper stiffener 60 and a lower stiffener 70 are provided inside the roof girder 10 and the floor girder 20 to which the upper end plate 41 and the lower end plate 42 of the middle pillar 40 are connected.

The configurations of the upper stiffener 60 and the lower stiffener 70 will be described below.

As shown in FIG. 5, the upper stiffener 60 includes a supplementary plate 61 and vertical plates 62 and 62.

The splicing plate 61 is formed of a steel plate having a plate thickness thicker than that of the thick plate portion 411 of the upper end plate 41 (for example, about 14 mm), and is joined to the upper surface of the lower flange 11 of the roof girder 10 by welding. As shown in FIG. 5A, the attachment plate 61 has substantially the same dimensions as the fastening plate portion 412 of the upper end plate 41, and the dimensions in the unit short side direction are the same. As shown in FIG. 5B, the floor girder 20 is formed to have a size of about 4/5.

Further, a pair of insertion holes 611 and 111 for inserting the bolt 101 are formed in the attachment plate 61 and the lower flange 11. The insertion holes 413 formed in the fastening plate portion 412 are arranged coaxially with the insertion holes 611 and 111 formed in the attachment plate 61 and the lower flange 11.

The pair of vertical plates 62 and 62 are formed of steel plates, respectively, and are welded to the upper surface of the splicing plate 61, the inner surface of the web 12 of the roof girder 10, and the lower surface of the upper flange 13 with the front and back surfaces facing toward the long side of the unit. It is joined by. Further, as shown in FIG. 5A, the distance between the vertical plates 62 and 62 in the unit long side direction is set to be slightly smaller than the dimension of the thick plate portion 411 of the upper end plate 41 in the same direction. ing.

As shown in FIG. 6, at the place where the middle pillar 40 is installed, the ceiling joist 51 is arranged between the vertical plate 62 and the vertical plate 62 of the upper stiffener 60 and thrusts into the web 12 of the roof girder 10. It is fixed to the roof girder 10 in the state of being hit.

The lower stiffener 70 includes a supplementary plate 71 and a pair of vertical plates 72, 72, similarly to the upper stiffener 60.

As shown in FIG. 6, the splicing plate 71 is joined to the lower surface of the upper flange 23 of the floor girder 20 by welding. A pair of insertion holes 711,231 for inserting the bolt 101 are formed in the attachment plate 71 and the upper flange 23. The insertion holes 423 formed in the fastening plate portion 422 are arranged coaxially with the insertion holes 711 and 231 formed in the attachment plate 71 and the upper flange 23.

The pair of vertical plates 72, 72 are joined to the lower surface of the side plate 71, the inner side surface of the web 22 of the floor girder 20, and the upper surface of the lower flange 21 by welding. Then, as shown in FIG. 6A, the distance between the pair of vertical plates 72, 72 in the unit long side direction is slightly smaller than the dimension of the thick plate portion 421 of the lower end plate 42 in the same direction. It is set. The vertical plate 72 is formed so that the vertical dimension thereof is shorter than the vertical dimension of the vertical plate 62 of the upper stiffener 60 according to the difference in the vertical dimension between the roof girder 10 and the floor girder 20. ing.

Further, as shown in FIGS. 6A and 6B, the floor girder 52 is arranged between the vertical plates 72 and 72 in the unit long side direction, and both ends in the longitudinal direction are welded to the floor girder 20. It is bonded to the fixing bracket 53 fixed by welding.

(Connected structure of middle pillar)
The above-mentioned middle column 40 is fixed by fastening the upper end plate 41 and the lower end plate 42 to the lower flange 11 of the roof girder 10 and the upper flange 23 of the floor girder 20 by bolts 101 and nuts 102.

That is, as shown in FIGS. 5A and 5B, the upper end plate 41 is in contact with the lower surface of the lower flange 11 of the roof girder 10, and the bolt 101 is attached from below the fastening plate portion 412. , The lower flange 11 and the insertion hole of the attachment plate 61 of the stiffener 60 are inserted, and the nut 102 is fastened to the bolt 101 from above the attachment plate 61 to be fixed.

On the other hand, as shown in FIGS. 6A and 6B, the lower end plate 42 is in contact with the upper surface of the upper flange 23 of the floor girder 20, and the bolt 101 is attached from above the fastening plate portion 422. , The upper flange 23 and the lower stiffener 70 are inserted into the insertion holes of the auxiliary plate 71, and the nut 102 is fastened to the bolt 101 from below the auxiliary plate 71 to be fixed.

(Action of the middle pillar)
The central pillar 40 provided in the building unit U1 can bear not only a vertical load but also a horizontal load (seismic force, wind pressure). That is, the middle column 40 has an upper and lower end portions via an upper end plate 41 and a lower end plate 42 including thick plate portions 411 and 421 formed of thick steel plates with respect to the roof girder 10 and the floor girder 20. Is combined. Further, the roof girder 10 and the floor girder 20 are provided with an upper stiffener 60 and a lower stiffener 70 provided with attachment plates 61 and 71 at a portion where the middle pillar 40 is connected. In addition, the fastening plate portions 421 and 422 of the end plates 41 and 42 are formed in an L-shaped cross-sectional shape and are joined to the webs 12 and 22 of the roof girder 10 and the floor girder 20.

Therefore, the rigidity of each of the end plates 41 and 42 can be ensured by the thick plate portions 411 and 421, and the toughness (deformability) can be ensured by the L-shaped fastening plate portions 421 and 422. That is, the middle column 40 can transmit a vertical load from the end plates 41, 42 provided with the thick plate portions 411,421 to the girders 10,20. Further, the toughness that allows horizontal deformation can be ensured by the fastening plate portions 421 and 422 having an L-shaped cross-sectional shape of each of the end plates 41 and 42.

Further, both the stiffeners 60 and 70 can transmit the structural stress from the middle column 40 to the entire girders 10 and 20 having an open cross-sectional shape (C-shaped steel) by the vertical plates 62 and 72. Then, both stiffeners 60 and 70 reinforce the lower flange 11 and the upper flange 23 of the girders 10 and 20 having an open cross-sectional shape (C-shaped steel) by the thick plate supplement plates 61 and 71, and form the joint portion of the middle column 40. It can be strengthened and bear the load in the horizontal direction.

Therefore, although the middle column 40 has a structure in which both girders 10 and 20 are connected to each other without using welding, toughness (deformability) can be ensured while ensuring rigidity in a limited space.

(Effect of embodiment)
The effects of the embodiments are listed below.
(1) The pillar connection structure of the building unit of the embodiment is a pillar connection structure of the building unit U1 formed by connecting the middle pillar 40 to the facing surfaces of the upper and lower roof girders 10 and the floor girder 20 facing in the vertical direction. Is. The middle column 40 includes upper and lower end plates 41 and 42 fastened to the roof girder 10 and the floor girder 20 by bolts 101 and nuts 102.

The end plates 41 and 42 are joined to the thick plate portions 411 and 421 by welding to the middle column 40 and to the thick plate portions 411 and 421 by welding and fastened to the girders 10 and 20 by bolts 101 and nuts 102. The fastening plate portions 421 and 422 are provided. The thick plate portions 411 and 421 have the required rigidity and have a plate thickness thicker than that of the fastening plate portions 421 and 422. The fastening plate portions 421 and 422 abut on the lower flange 11 and the upper flange 23 having facing surfaces of the girders 10 and 20 to be connected, and are in the direction along the girders 10 and 20 from the thick plate portions 411 and 421. The base plate portions 412a and 422a and the base plate portions 412a and 422a fastened to the lower flange 11 and the upper flange 23 by the bolt 101 and the nut 102 in the portion where the dimensions are formed to be large are integrally formed, and the girders 10 and 20 are respectively formed. It is provided with side plate portions 412b and 422b provided along the webs 12 and 22 on the side surface of the above.

Therefore, the middle column 40 can be installed at an arbitrary position between the two girders 10 and 20 of the building unit U1 by fastening the upper and lower end plates 41 and 42 to the girders 10 and 20 with bolts 101 and nuts 102. .. Therefore, a high degree of freedom in design can be obtained.

The end plates 41 and 42 can secure the rigidity of the middle pillar 40 by the thick plate portions 411 and 421. Further, since the fastening plate portions 421 and 422 have an L-shaped cross section and are provided along the facing surfaces (lower surface and upper surface) of the flanges 11 and 23 and the side surfaces of the webs 12 and 22, the horizontal load due to an earthquake or wind pressure can be resisted. It is possible to secure the deformation ability (toughness) and bear these horizontal loads. Therefore, the structural strength required for the center pillar 40 can be secured.

(2) In the column connection structure of the building unit of the embodiment, the stress applied to the input from the center column 40 to the flanges 11 and 23 is applied to the inside of the columns 10 and 20 at the positions where the center columns 40 are connected. The upper and lower stiffeners 60 and 70 that transmit to the whole of 20 are attached.

Therefore, at the installation location of the middle pillar 40 in each of the girders 10 and 20, the stress of each girder 10 and 20 with respect to the input from the middle pillar 40 can be improved and high rigidity can be ensured.

(3) In the column connection structure of the building unit of the embodiment, the upper and lower stiffeners 60 and 70 are plate-shaped directly or indirectly connected to the upper flanges 13 and 23, the lower flanges 11 and 21 and the webs 12 and 22. A plurality of vertical plates 62, 62, 72, 72 are provided.

Therefore, each of the girders 10 and 20 from the middle column 40 can transmit the vertical load input to the girders 10 and 20 from the plurality of vertical plates 62, 62, 72, 72 to each of the girders 10 and 20, and can bear the rigidity against the vertical load. Can be secured.

(4) In the column connection structure of the building unit of the embodiment, the upper and lower stiffeners 60 and 70 are welded to the back side of the lower flange 11 and the upper flange 23 as the joint surface of the upper and lower end plates 41 and 42, and each end plate 41. , 42 is provided with a flange plate 61, 71 through which a bolt 101 for fastening the 42 is inserted, and the vertical plates 62, 72 are welded to the flange plate 61, 71.

Therefore, the rigidity of the joint portion of the middle column 40 in each of the girders 10 and 20 can be ensured by the auxiliary plates 61 and 71, and the upper and lower stiffeners 60 and 70 can bear not only the vertical load but also the horizontal load from the middle column 40. Become.

(Explanation of building unit U2)
Next, the building unit U2 shown in FIG. 2 will be described.
In the building unit U2, all the columns 240 connected to the two girders 10 and 20 have the same structure as the central column 40 shown in the building unit U1, but the central columns 40 are some. Has differences. The differences will be described below.

The pillar 240 has the directions of the long side and the short side in the cross section of the thin square pipe different from the middle pillar 40 shown by the building unit U1 by 90 degrees. That is, each of the columns 240 is installed so that the long side is oriented along the extending direction of each of the girders 10 and 20. Therefore, the column 240 has a dimension that fits within the width of each beam 10 and 20 in the unit internal and external direction which is a direction orthogonal to the extending direction of each beam 10 and 20 in the horizontal plane. Therefore, even in the upper and lower end plates 41 and 42, the width dimensions of the thick plate portions 411 and 421 and the base plate portions 412a and 422a in the unit internal and external directions are the widths of the lower flange 11 and the upper flange 23 of the girders 10 and 20, respectively. It is formed to fit within the dimensions.

Therefore, when a wall straddling the upper and lower girders 10 and 20, the pillar shape of the pillar 240 can be prevented from protruding further.

In the roof girder 10 and the floor girder 20 of the building unit U2, the upper and lower stiffeners 60.70 provided at the joints of the columns 240 are the same as the upper and lower stiffeners 60 and 70 of the building unit U1.

Further, in the building unit U2, the roof girder 10 and the floor girder 20 are provided with an opening of the C-shaped steel facing the outside of the unit. Therefore, the ceiling joists 51 and the floor joists 52 are directly joined to the webs 12 and 22 of the girders 10 and 20 by welding.

The effects of (1) to (4) above can also be obtained in this building unit U2.

(Explanation of a modified example of Stifuna)
Next, a modification of the upper and lower stiffeners 60 and 70 will be described. In both stiffeners 60 and 70, the installation of the attachment plates 61 and 71 can be omitted where the pillar does not need to bear the horizontal load.

In FIGS. 11, 12, and 13, the upper stiffeners 360 and the lower stiffeners 370 provided at the installation positions of the columns 340 in the girders 10 and 20, omitting the side plates 61 and 71, and a pair of vertical plates 362 and 362 and vertical plates. An example using the one formed by the plates 372 and 372 is shown. The vertical plate 362 is joined to the inner side surfaces of the lower flange 11, the web 12, and the upper flange 13 of the roof girder 10 by welding. Further, the vertical plate 372 is joined to the inner side surfaces of the lower flange 21, the web 22, and the upper flange 23 of the floor girder 20 by welding.

In this way, when the pillar 340 does not bear the horizontal load, the configuration of both stiffeners 360 and 370 can be simplified, and the number of parts, the labor of manufacturing, and the weight can be reduced.

(Explanation of building unit U3)
Next, the building unit U3 shown in FIG. 3 will be described. The inside of this building unit U3 is divided into a living room RM and a garage GA.

Therefore, the floor girders 320 and 320 are formed so that the dimension in the long side direction of the unit is about half of the total length in the same direction of the building unit U3. The floor beams 321 are connected to the tip portions of the floor beams 320, 320 on the cutting side.

Further, an intermediate beam 310 spanning the roof beams 10 and 10 on the long side is provided at a position directly above the floor beam 321. Therefore, an intermediate wall (not shown) can be provided straddling the intermediate beam 310 and the floor beam 321. It is also possible to provide a pillar 240 inside the intermediate wall.

Of the pillars 240 and 440 provided at the four corners of the building unit U3, the pillars 240 are the same as those used for the building unit U2, and thus the description thereof will be omitted.

Also, the pillar 440 extends the legs downward and connects the lower end plate 542 to the foundation 200. The lower end plate 542 may be the same as that provided in the building units U1 and U2, or may be formed of one thick plate as shown in the figure. The other configurations of the pillar 440 are the same as those of the pillar 240.

Even in the pillars 240 and 440 of the building unit U3, as described above, it can be installed at an arbitrary position, and a high degree of freedom in design can be obtained. Further, the structural strength required for the columns 240 and 440 can be ensured by the end plates 41 and 42.

Further, by setting the stiffeners 60 and 70, the stress of the girders 10 and 20 with respect to the input from the middle pillar 40 can be improved and the coupling rigidity can be secured at the installation location of the columns 240 and 440 in the girders 10 and 20. The effect can be obtained.

Although the embodiment of the column connection structure of the building unit of the present disclosure has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment and does not deviate from the gist of the present invention. The design modification of is included in the present invention.

For example, the number and position of the pillars provided in the building unit are arbitrary, and are not limited to the number and position shown in the embodiment. Further, the thickness and dimensions of the thick plate portion of the end plate, the fastening plate portion, the auxiliary plate of each stiffener and the vertical plate are not limited to those shown in the embodiment, and may be arbitrarily set as necessary. can.

Further, in the embodiment, as shown in the building unit U3, the connection by the end plate provided with the thick plate portion and the fastening plate portion may be at least one of the upper and lower sides of the column. Further, as the girder, a floor girder and a roof girder are shown, but when applied to a building unit for constructing a multi-story building, a ceiling girder can be used as the upper girder. Further, in the embodiment, bolts and nuts are shown as fastening members, but the bolts and nuts are not limited as long as the end plate can be fixed by tightening the screws.

10 Roof girder 11 Lower flange 12 Web 13 Upper flange 20 Floor girder 21 Lower flange 22 Web 23 Upper flange 40 Middle pillar 41 Upper end plate 42 Lower end plate 60 Upper stiffener 61 Sub-plate 62 Vertical plate 70 Lower stiffener 71 Sub-plate 72 Vertical Plate 101 bolt (fastener)
102 Nut (fastener)
240 Pillar 320 Floor girder 340 Pillar 360 Upper stiffener 362 Vertical plate 370 Lower stiffener 372 Vertical plate 411 Thick plate 412 Fastening plate 412a Base plate 412b Side plate 413 Insertion hole 421 Thick plate 422 Fastening plate 422a Base plate Part 422b Side plate part 423 Insertion hole 111 Insertion hole 231 Insertion hole 611 Insertion hole 711 Insertion hole U1 Building unit U2 Building unit U3 Building unit

Claims (4)

It is a column connection structure of a building unit formed by connecting columns to the facing surfaces facing each other above and below the girders provided facing each other.
The pillar is provided with an end plate fastened to the girder by a fastener at least one of the upper and lower ends.
The end plate includes a plate portion joined to the pillar by welding and a fastening plate portion joined to the plate portion by welding and fastened to the girder by the fastener.
The thick plate portion has the required rigidity and has a thicker plate thickness than the fastening plate portion.
The fastening plate portion abuts on the facing surface of the girder to be coupled, and abuts on the facing surface at a portion where the dimension in the direction along each girder is larger than that of the thick plate portion. A column connection structure of a building unit including a base plate portion fastened by the above and a side plate portion integrally formed with the base plate portion and provided along the side surface of the girder. In the column connection structure of the building unit according to claim 1,
The girder is provided with an integral upper and lower flange at the top and bottom of the web.
A column connection structure of a building unit in which a stiffener for transmitting stress to an input from the column is attached to the inside of the girder at a position where the columns are connected to the entire girder. The building unit according to claim 2.
The stiffener is a column connection structure of a building unit including a plurality of plate-shaped vertical plates directly or indirectly connected to the upper flange, the lower flange, and the web. In the column connection structure of the building unit according to claim 3.
The stiffener is welded to the back side of the facing surface to which the end plate is bonded, and includes a sub-plate into which the fastener for fastening the end plate is inserted, and the vertical plate is welded to the sub-plate. Column connection structure of the building unit.

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