JP2015108242A - Frame structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a roof frame structure to which a brace may be connected without adversely affecting the appearance and floor plan.SOLUTION: A frame structure 1 comprises a steel pipe column 11, a ridge beam 17 connected to the steel pipe column 11, and a brace 25 spanned between the steel pipe column 11 and the ridge beam 17. A joint section 30 is formed between a side 11c of the steel pipe column 11 and a lower edge part 25b of the brace 25, and the width of the joint section 30 is smaller than the width W2 of the steel pipe column 11. Thus, the connecting part 30 does not cause the structure around the steel pipe column 11 to become wider than the width W2 of the steel pipe column 11. As a result, the brace 25 may be connected without causing the connecting section 30 to adversely affect the appearance and floor plan.

Description

  The present invention relates to a frame structure in a building such as a house.

  Conventionally, in order to resist horizontal force due to an earthquake, a structure in which braces are arranged on a frame structure composed of columns and beams is known. For example, Patent Document 1 discloses a structure in which an end of a brace is joined to a square steel pipe column having a closed cross section. In this structure, a joint plate that protrudes perpendicularly to the frame surface at the same angle as the brace mounting angle on one half-circumferential part including two side surfaces parallel to the frame surface of the square steel pipe column and one side surface perpendicular to the frame surface Are welded. The end portion of the brace is on the same plane as the end portion of the joining plate, and is mechanically joined by a bolt via an attachment plate.

JP 2001-65064 A

  In the structure described in Patent Document 1, the joining plate wraps around and is welded to the two side surfaces parallel to the frame surface of the square steel pipe column. For this reason, the structure around the square steel pipe column becomes larger than the column width due to the presence of the joining plate. When the joining plate appears outside the wall, the appearance deteriorates. On the other hand, if it is going to be stored in the wall together with the joint plate, the wall thickness increases, which adversely affects the floor plan.

  Then, this invention makes it a subject to provide the roof frame structure which can join a brace, without exerting a bad influence on appearance and a floor plan.

  In order to solve the above problems, a frame structure according to the present invention includes a steel column, a beam joined to the steel column, and a brace constructed between the steel column and the beam, A joint is formed over the lower end of the brace, and the width of the joint is smaller than the width of the steel column.

  In the frame structure of the present invention, since the width of the joint is smaller than the width of the steel column, it is avoided that the structure around the steel column becomes larger than the width of the steel column due to the presence of the joint. Can do. As a result, the braces can be joined without adversely affecting the appearance and the floor plan due to the presence of the joint.

  Further, the joint portion has a column side joint piece protruding from the side surface of the steel column, and a brace side joint piece attached to the lower end portion of the brace, and among the column side joint piece and the brace side joint piece, One joining piece is formed in a plate shape, and the other joining piece includes a first facing surface portion that faces one surface of the one joining piece, and a second facing surface portion that faces the other surface of the one joining piece. , May be included. In this case, since one of the plate-shaped joining pieces faces the first opposing surface portion and the second opposing surface portion of the other joining piece, the one joining piece is resistant to deformation in a direction perpendicular to the surface. It will be equally restrained from both sides. Therefore, it becomes possible to sufficiently resist the out-of-plane force from any direction.

  Moreover, one joining piece is a column side joining piece, the other joining piece is a brace side joining piece, and the column side joining piece is located at the center of the width direction of the side surface of the steel column at the axis of the steel column. You may include the joining board part extended up and down along. In this case, since the brace-side joining piece can be received at the position in the center in the width direction of the side surface of the steel column, there is no eccentricity in load transmission between the steel column and the brace.

  Further, the steel column has a column main body portion formed by a steel pipe having a closed cross section, and a column base portion having an open cross section formed at a lower end portion of the column main body portion, and the column side joining piece is a column main body portion. And the column base may be fixed by welding. In this case, since the column-side joining piece is welded and fixed to both the column main body portion and the column base portion, load transmission between the column side joining piece and the column is performed from the upper end portion to the lower end portion. Can do. In particular, since the column-side joining piece is also welded and fixed to the column base portion having an open cross section, load transmission to the column base portion can be ensured.

  Moreover, the column side joining piece contains the plate-shaped reinforcement part welded and fixed to the side surface of the column main-body part, and the joining plate part may be fixed to the reinforcement part. In this case, since the thickness of the load transmitting portion in the steel column is increased by the reinforcing portion, it is possible to suppress the stagnation of the steel column.

  Moreover, the brace has a brace body part and a beam joint part attached to the upper end part of the brace body part. The brace body part is formed of a steel pipe, and the brace side joining piece is welded to the lower end part of the steel pipe. It may be fixed. In this case, since the main body is formed of a steel pipe, it can resist not only tension but also compression. As a result, it becomes difficult to buckle as a whole, and the performance as a brace is improved.

  In addition, a pair of notches are formed at the lower end of the brace body in a position that is line-symmetric with respect to the axis of the brace body, and the brace-side joining piece is inserted into the pair of notches. It may be fixed by welding. In this case, since the brace-side joining piece is welded and fixed in the notched portion, the weld length of the brace-side joining piece can be ensured. As a result, it is possible to ensure the bonding strength between the main body portion of the brace and the brace-side joining piece, and to smoothly transfer the load between the main body portion and the brace-side joining piece.

  Moreover, the brace may be installed only in one place between the two steel columns. In this case, the cross section of the steel column and the beam can be designed to be smaller than that of the conventional rigid frame structure, and the degree of freedom of opening between the steel columns can be increased and The influence can also be suppressed.

  Moreover, the brace may be constructed between the steel column and the building beam. In this case, the frame structure according to the present invention can be used as a roof frame structure.

  ADVANTAGE OF THE INVENTION According to this invention, the roof frame structure which can join a brace without having a bad influence on appearance and a floor plan can be provided.

It is a perspective view of a building which has a frame structure concerning an embodiment of the present invention. It is a schematic perspective view of the frame structure concerning the embodiment of the present invention. It is a front view which shows the steel pipe pillar in FIG. 1, a ridge beam, and a brace. (A) And (b) is a figure which shows the structure of a column side joining piece periphery part. (A) And (b) is a figure which shows the structure of a brace | side bracing piece periphery part. It is a front view which expands and shows the junction part of FIG. It is the figure seen from the arrow X direction shown in FIG. It is a schematic diagram which shows the characteristic of various frame structures.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description, the same reference numerals are used for the same elements or elements having the same function, and redundant description is omitted.

  With reference to FIG.1 and FIG.2, the outline | summary of the frame structure concerning this embodiment is demonstrated. The frame structure 1 according to the present embodiment is, for example, a roof frame structure, and is a portion that is provided in a building such as a house and protrudes from the roof. The frame structure 1 is used particularly for a sloped ceiling (atrium), a shed storage, a loft, a penthouse, and the like. For example, as shown in FIG. 1, the frame structure 1 is used in a unit 6 provided on the roof of a two-story building body 2 and is supported by a lower structure 2 a such as a beam constituting the building body 2. The unit 6 includes a frame structure 1, a gradient roof surface 7 constituted by the frame structure 1, and a top light 8 attached to the gradient roof surface 7.

  As shown in FIG. 2, the frame structure 1 includes a pair of steel pipe columns 11 and 15 (steel columns), a master beam 17 (beam) installed on the steel pipe columns 11 and 15, and four frames installed on the master beam 17. And climbing beams 18-21. The steel pipe columns 11 and 15 extend in the vertical direction, for example. Lower ends 11b and 15b of the steel pipe columns 11 and 15 are respectively supported by the lower structure 2a. The steel pipe column 11 and the steel pipe column 15 are arranged in a straight line as a pair. On the steel pipe columns 11 and 15, a ridge beam 17 is bridged substantially horizontally between an upper end portion 11 a of the steel pipe column 11 and an upper end portion 15 a of the steel pipe column 15.

  The master beam 17 has one end portion 17 a supported by the upper end portion 11 a of the steel pipe column 11 and the other end portion 17 b supported by the upper end portion 15 a of the steel tube column 15. In the length direction of the master beam 17, climbing beams 18 to 21 are arranged at predetermined intervals.

  The climbing beam 18 is installed on the lower structure 2a and the end portion 17a of the ridge beam 17 so as to have an inclined shape having a climbing gradient from the base end portion 18b toward the distal end portion 18a. The tip 18 a of the climbing beam 18 is connected to the end 17 a of the ridge beam 17 and to the upper end 11 a of the steel pipe column 11. The base end portion 18b of the climbing beam 18 is connected to the lower structure 2a.

  The climbing beam 19 is installed on the lower structure 2a and the lengthwise middle portion 17c of the ridge beam 17 so as to have an inclined shape having a climbing gradient from the base end portion 19b toward the distal end portion 19a. The tip 19 a of the climbing beam 19 is connected to the midway portion 17 c in the length direction of the ridge beam 17. The base end portion 19b of the climbing beam 19 is connected to the lower structure 2a. In other words, the midway portion 17 c in the length direction of the ridge beam 17 is supported by the distal end portion 19 a of the climbing beam 19.

  The climbing beam 20 is installed on the lower structure 2a and the midway portion 17d in the length direction of the ridge beam 17 so as to have an inclined shape having an ascending gradient from the base end portion 20b toward the distal end portion 20a. The distal end portion 20 a of the climbing beam 20 is supported by a midway portion 17 d in the length direction of the ridge beam 17. The base end 20b of the climbing beam 20 is connected to the lower structure 2a. In other words, the midway portion 17 d in the length direction of the ridge beam 17 is supported by the distal end portion 20 a of the climbing beam 20.

  The climbing beam 21 is installed on the lower structure 2a and the end portion 17b of the ridge beam 17 so as to have an inclined shape having a climbing gradient from the base end portion 21b toward the distal end portion 21a. The tip 21 a of the climbing beam 21 is connected to the end 17 b of the ridge beam 17 and is connected to the upper end 15 a of the steel pipe column 15. The base end portion 21b of the climbing beam 21 is connected to the lower structure 2a.

  In the middle of the climbing beams 18-21, steady rests 40-45 are attached. The steady rests 40 to 45 are small beams that cross between the beams. The steady rests 40 and 43 connect the climbing beam 18 and the climbing beam 19. The steady rests 41 and 44 connect the climbing beam 19 and the climbing beam 20. The steady rests 42 and 45 connect the climbing beam 20 and the climbing beam 21.

  A plurality of roof surface areas are defined by the master beam 17, the climbing beams 18 to 21, and the steady rests 40 to 45. A slope roof surface 7 (see FIG. 1) of the unit 6 is configured by attaching roof panels or the like to a plurality of roof surface regions. A top light panel 47 is attached to a central region of the plurality of roof surface regions. The top light panel 47 is a skylight panel installed in the frame structure 1 for daylighting or ventilation, and the top light 8 of the unit 6 is attached to the panel. Moreover, the cross-shaped gradient surface braces 50-57 are each attached to the area | region where the top light panel 47 is not attached among the said roof surface area | regions.

  A brace-shaped brace 25 is installed between the steel pipe column 11 and the master beam 17. The brace 25 extends obliquely between the lower end portion 11 b of the steel pipe column 11 and the midway portion 17 c in the length direction of the ridge beam 17. The upper end portion 25 a of the brace 25 is supported by the lengthwise intermediate portion 17 c of the ridge beam 17, and the lower end portion 25 b of the brace 25 is supported by the lower end portion 11 b of the steel pipe column 11. The brace 25 is not limited to the space between the steel pipe column 11 and the building beam 17, but may be installed between the steel tube column 15 and the building beam 17 instead of between the steel tube column 11 and the building beam 17. In addition, the steel pipe column 15 and the master beam 17 may be installed between the master beam 17 and the master beam 17. For example, the brace 25 may be provided on both sides symmetrically between the two steel pipe columns 11 and 15 (see FIG. 8B) and intersect between the two steel pipe columns 11 and 15. It may be provided (refer to (c) of Drawing 8), and may be provided crossing between steel pipe pillar 16 and steel pipe pillar 11 arranged between two steel pipe pillars 11 and 15 (figure 8). 8 (d)). In this embodiment, the brace 25 is installed only at one place between the two steel pipe columns 11 and 15 (see FIG. 8A).

  Next, with reference to FIG. 3, the structure of the steel pipe pillar 11, the master beam 17, and the brace 25 is demonstrated in detail. FIG. 3 is a front view showing the steel pipe columns, the building beams, and the braces in FIG. 1.

  As shown in FIG. 3, the steel pipe column 11 includes a column main body 12, a column head 13 formed on the upper end 12 a of the column main body 12, and a column base formed on the lower end 12 b of the column main body 12. 14. The column main body 12 is formed of, for example, a square steel pipe, and its cross section is a closed cross section. The column head 13 is formed by connecting the upper flange 13a and the lower flange 13b with a cross-shaped web 13c, and the cross section is a cross-shaped open cross section. The lower flange 13 b of the column head 13 is fixed to the upper end portion 12 a of the column main body 12 by welding.

  The joining member 3 is attached to the web 13c of the column head 13 by welding or the like. The column head portion 13 is fixed to the end portion 17 a of the ridge beam 17 through the joining member 3. The master beam 17 is formed of H-shaped steel formed by connecting the center portions of the upper flange 17f and the lower flange 17g with a web 17e, and the cross section is an H-shaped open cross section. The joining member 3 is in surface contact with the web 17e of the ridge beam 17 at the end portion 17a of the ridge beam 17, and is fixed by a bolt or the like.

  The column base portion 14 is formed by connecting the upper flange 14a and the lower flange 14b with a cross-shaped web 14c, and the cross section thereof is a cross-shaped open cross section. The upper flange 14 a of the column base portion 14 is fixed to the lower end portion 12 b of the column main body portion 12. The lower half (lower flange 14b side) of the column base 14 is buried in mortar or the like (not shown) and supported by a beam or the like of the lower structure 2a. In addition, the width | variety of the pillar main-body part 12, the pillar head part 13, and the pillar leg part 14 can be considered as each being substantially equal. That is, the width of the steel pipe column 11 is substantially constant. Moreover, the axial centers of the column main body 12, the column head 13, and the column base 14 all coincide.

  A column-side joining piece 31 protrudes from the side surface 11 c of the steel pipe column 11 so as to be located across the column main body 12 and the column base 14. The column-side joining piece 31 is fixed by welding to the side surface 12c of the column main body 12 and is fixed to the web 14c of the column base 14 by I-type butt welding. That is, the column-side joining piece 31 is provided and fixed by welding over the column main body 12 and the column base 14.

  The brace 25 has a brace body 26 and a beam joint 27 attached to the upper end 26 a of the brace body 26. The brace body 26 is formed of a steel pipe, and its cross section is a closed cross section. The beam joint portion 27 is formed by connecting the upper flange 27a and the lower flange 27b with a cross-shaped web 27c, and its cross section is a cross-shaped open cross section. The lower flange 27 b of the beam joint portion 27 is fixed to the upper end portion 26 a of the brace body portion 26. The upper flange 27a of the beam joint portion 27 is in surface contact with the lower flange 17g at the midway portion 17c in the longitudinal direction of the ridge beam 17, and is fixed by a bolt or the like. In addition, the width | variety of the brace main-body part 26 and the beam junction part 27 can each be considered as substantially equal. That is, the width of the brace 25 is substantially constant. Further, the axes of the brace body 26 and the beam joint 27 coincide with each other.

  A brace-side joining piece 35 is fixed by welding to a lower end portion 26b of the brace body 26 (steel pipe). The brace-side joining piece 35 is fixed to the column-side joining piece 31. Thereby, the brace 25 and the steel pipe column 11 are joined. That is, the joint portion 30 is formed across the side surface 11 c of the steel pipe column 11 and the lower end portion 25 b of the brace 25.

  Next, with reference to FIG.4 and FIG.5, the structure of the column side joining piece 31 and the brace side joining piece 35 is each demonstrated in detail. FIGS. 4A and 4B are diagrams showing the configuration of the periphery of the column-side joining piece. (A) and (b) of Drawing 5 is a figure showing composition of a brace side joined piece peripheral part.

  (A) of FIG. 4 is the figure which looked at the column side joining piece 31 periphery part from the surface side orthogonal to the side surface 12c of the column main-body part 12 of FIG. (B) of FIG. 4 is the figure which looked at the column side joining piece 31 periphery part from the side surface 12c side of the column main-body part 12 of FIG. As shown in FIGS. 4A and 4B, the column-side joining piece 31 includes a joining plate portion 32 and a reinforcing portion 33. The joining plate portion 32 is a plate-like member, and is erected at a position that is the center in the width direction of the side surface 11 c of the steel pipe column 11. That is, the joining plate portion 32 is erected at a position G that is the center in the width direction of the side surface 12 c of the column main body portion 12. The joining plate portion 32 extends at the position G along the axis P <b> 1 of the column main body portion 12. The joining plate part 32 is located over the column main body part 12 and the column base part 14. An upper end portion 32 e of the joining plate portion 32 is located on the column main body portion 12, and a lower end portion 32 f of the joining plate portion 32 is located on the column base portion 14. Bolt holes 32 h and 32 i that penetrate from the front surface 32 a to the back surface 32 b of the bonding plate portion 32 are formed in the bonding plate portion 32.

  The joining plate portion 32 has a shape obtained by cutting off a part of a rectangular plate member obliquely, and has an inclined end surface 32c and a horizontal end surface 32d. The inclined end surface 32c is inclined with respect to the axis P1 of the steel pipe column 11 in a downward gradient from the upper end portion 32e of the joining plate portion 32 toward the lower end portion 32f. The horizontal end surface 32d is located substantially parallel to the axis P1 of the steel pipe column 11 from the column main body 12 to the column base 14. The horizontal end surface 32d is welded and fixed to the reinforcing portion 33 and the upper flange 14a of the column base portion 14.

  The reinforcing portion 33 is a rectangular plate member. The width W <b> 1 of the reinforcing portion 33 is smaller than the width W <b> 2 of the column main body portion 12, and the center position in the width direction coincides with the axis P <b> 1 of the column main body portion 12. That is, the reinforcing portion 33 is positioned so as to be within the width W2 of the column main body portion 12. The surface 33 a of the reinforcing portion 33 is fixed to the horizontal end surface 32 d of the joining plate portion 32 by welding. The back surface 33 b of the reinforcing portion 33 is fixed to the side surface 12 c of the column main body portion 12 by welding. The thickness of the column main body 12 is increased by the amount by which the reinforcing portion 33 is fixed to the column main body 12.

  (A) of FIG. 5 is the figure which looked at the brace side joining piece 35 peripheral part from the surface side orthogonal to the side surface 26c of the brace main-body part 26 of FIG. (B) of FIG. 5 is the figure which looked at the brace side joining piece 35 periphery part from the side surface 26c side of the brace main-body part 26 of FIG. As shown to (a) and (b) of FIG. 5, the brace main-body part 26 is a steel pipe pillar of the predetermined | prescribed width W3. This width W3 is smaller than the width W2 of the column main body 12. A pair of notches 26e and 26f are formed at the lower end portion 26b of the brace body 26 at positions that are line-symmetric with respect to the axis P2 of the brace body 26. A brace-side joining piece 35 is inserted into the pair of notches 26e and 26f.

  The brace-side joining piece 35 includes a first facing surface portion 36 and a second facing surface portion 37. The first facing surface portion 36 and the second facing surface portion 37 face each other substantially in parallel. The first facing surface portion 36 and the second facing surface portion 37 include penetration portions 36a and 37a and extending portions 36b and 37b, respectively. The penetration portions 36a and 37a are formed to have a predetermined weld length 35d, and are penetrated into the pair of notches 26e and 26f of the brace main body portion 26 and fixed by welding. The extending portions 36 b and 37 b extend from the lower end portion 26 b of the brace body 26 along the axis P <b> 2 of the brace body 26. The extending portions 36b and 37b are gradually reduced in width toward the tip portion, and the tip portion is rounded. Bolt holes 36h and 36i are formed in the extending portion 36b. The bolt holes 36h and 36i are arranged so as to coincide with the axis P2 of the brace body 26. Although not shown, two bolt holes corresponding to the bolt holes 36h and 36i are also formed in the extending portion 37b.

  Next, with reference to FIG.6 and FIG.7, the structure in the state where the column side joining piece 31 of FIG. 4 and the brace side joining piece 35 of FIG. FIG. 6 is a plan view for explaining the joint portion 30 of FIG. 3 in detail. FIG. 7 is a plan view seen from the direction of arrow X shown in FIG.

  As shown in FIG.6 and FIG.7, the joining plate part 32 of the column side joining piece 31 is protrudingly provided by the side surface 11c of the steel pipe pillar 11, and follows the axial center P1 of the steel pipe pillar 11 (namely, column main-body part 12). It extends up and down. The joining plate portion 32 receives the brace-side joining piece 35 at a position G that is the center in the width direction of the side surface 12c of the column main body portion 12 (a position that is the center in the width direction of the side surface 11c of the steel pipe column 11). The brace-side joining piece 35 receives the joining plate portion 32 so as to be sandwiched between the first facing surface portion 36 and the second facing surface portion 37.

  A joining plate portion 32 is inserted between the first facing surface portion 36 and the second facing surface portion 37. The first facing surface portion 36 faces the surface 32 a of the bonding plate portion 32. The second facing surface portion 37 faces the back surface 32 b of the bonding plate portion 32. In this state, the joining plate portion 32 and the brace-side joining piece 35 are fixed by the bolt 4 and the bolt 5. The bolt 4 is inserted into the bolt hole 32 h of the joining plate portion 32 and the bolt hole 36 h of the first facing surface portion 36 (and the corresponding bolt hole of the second facing surface portion 37). The bolt 5 is inserted into the bolt hole 32 i of the joining plate portion 32 and the bolt hole 36 i of the first opposing surface portion 36 (and the corresponding bolt hole of the second opposing surface portion 37). In this way, the joint portion 30 including the column side joining piece 31 and the brace side joining piece 35 is formed across the side surface 11 c of the steel pipe column 11 and the lower end portion 26 b of the brace main body portion 26.

  Since the lower half of the column base part 14 is filled with mortar or the like, the column side joining piece 31 and the brace side joining piece 35 are located above the part of the column base part 14 filled with mortar or the like. That is, the joint 30 is located above the intersection of the axis P1 of the column body 12 and the axis (not shown) of the beam (lower structure) joined to the column base 14. Nevertheless, the axis P2 of the brace body 26 passes through the intersection of the axis P1 of the column body 12 and the axis (not shown) of the beam (lower structure) joined to the column base 14. doing.

  As shown in FIG. 7, when viewed from the side surface 12 c of the column main body 12, the axis P <b> 1 of the column main body 12 and the axis P <b> 2 of the brace main body 26 coincide. Comparing the width (length in the direction orthogonal to the axes P1 and P2) viewed from the side surface 12c side of the column main body 12, the width of the column-side joining piece 31 (that is, the width W1 of the reinforcing portion 33) is It is smaller than the width W2 of the main body 12. The width W4 of the brace-side joining piece 35 is smaller than the width W2 of the column main body 12. That is, the width of the joint portion 30 (the column side joint piece 31 and the brace side joint piece 35) is smaller than the width W2 of the column main body portion 12. Accordingly, the joint portion 30 is within the range of the width W2 of the column main body portion 12, and does not have a larger structure than the column main body portion 12 when viewed from the side surface 12c side of the column main body portion 12.

  Next, with reference to FIG. 8, the effect by installing only one brace 25 of the frame structure 1 according to the present embodiment will be described. FIG. 8 is a schematic diagram showing characteristics of various frame structures. FIG. 8A shows the frame structure 1 according to the embodiment of the present invention. FIGS. 8B to 8D show a frame structure according to a modification of the present invention.

  In the frame structure 61 according to the modification shown in FIG. 8B, the braces 25 are provided symmetrically between the two steel pipe columns 11 and 15 on both sides. In the frame structure 62 according to the modification shown in FIG. 8C, the brace 25 is provided so as to intersect between the two steel pipe columns 11 and 15. In the frame structure 63 according to the modification shown in FIG. 8D, the brace 25 is provided so as to intersect between the steel pipe column 16 and the steel pipe column 11 disposed between the two steel pipe columns 11 and 15. It has been. The frame structure 100 shown in FIG. 8E is a so-called ramen frame structure, and the brace 25 is not provided.

  As shown in FIG. 8, according to the frame structures 61, 62, and 63 according to the modified example of the present invention, the cross sections of the steel pipe columns 11, 15, 16 and the building beam 17 are designed to be smaller than those of the conventional frame structure 100. can do. On the other hand, according to the frame structure 1 according to the above-described embodiment of the present invention, the cross section of the steel pipe columns 11 and 15 can be designed smaller than the conventional frame structure 100, and the frame structure according to the present embodiment. Reference numeral 1 denotes the roof frame structure on the top floor of the building, and since the burden load is not large, the cross section of the building beam 17 can be designed to be smaller than that of the conventional frame structure 100. Furthermore, according to the frame structure 1 according to the present embodiment, since the brace 25 is provided only in one place, the degree of freedom of opening between the steel pipe columns 11 and 15 can be increased, and the lower structure The influence on 2a can also be suppressed.

  As mentioned above, according to the frame structure 1 which concerns on this embodiment, since the width | variety of the junction part 30 is smaller than the width W2 of the column main-body part 12 of the steel pipe column 11, the structure around the steel pipe column 11 is the said junction part 30. It can be avoided that the width is larger than the width W2 of the steel pipe column 11 due to the presence of. As a result, the brace 25 can be joined without adversely affecting the appearance and the floor plan due to the presence of the joint portion 30.

  Further, the joint portion 30 includes a column side joint piece 31 protruding from the side surface 11 c of the steel pipe column 11 and a brace side joint piece 35 attached to the lower end portion 25 b of the brace 25, and the column side joint piece 31. And the brace-side joining piece 35 is formed in a plate shape, and the brace-side joining piece 35 includes a first facing surface portion 36 facing the surface 32a of the column-side joining piece 31, and a column-side joining piece. And a second facing surface portion 37 that faces the back surface 32b of 31. For this reason, since the plate-like column-side joining piece 31 faces the first opposing surface portion 36 and the second opposing surface portion 37 of the brace-side joining piece 35, the column-side joining piece 31 is perpendicular to the surface. It is equally constrained from both sides for deformation in direction. Therefore, it becomes possible to sufficiently resist an out-of-plane force (a force penetrating perpendicularly to the surface) from any direction on the front surface 31a side and the back surface 32b side.

  Moreover, one joining piece is the column side joining piece 31, the other joining piece is the brace side joining piece 35, and the column side joining piece 31 is a steel pipe at a position that is the center in the width direction of the side surface 11c of the steel pipe column 11. A joining plate portion 32 extending vertically is included along the axis P1 of the column 11 (column body 12). For this reason, since the brace-side joining piece 35 can be received at the position in the center in the width direction of the side surface 11 c of the steel pipe column 11, there is no eccentricity in load transmission between the steel pipe column 11 and the brace 25.

  The steel pipe column 11 includes a column main body portion 12 formed of a steel pipe having a closed cross section, and a column base portion 14 having an open cross section formed at the lower end portion 12b of the column main body portion 12, and a column side joining piece. 31 is provided over the column main body 12 and the column base 14 and is fixed by welding. For this reason, the column-side joining piece 31 is welded and fixed to both the column main body portion 12 and the column base portion 14, so that the column-side joining piece 31 has a lower end from the upper end portion (the upper end portion 32 e of the joining plate portion 32). The load can be transmitted to the steel pipe column 11 over the portion (the lower end portion 32f of the joining plate portion 32). In particular, since the column-side joining piece 31 is also welded and fixed to the column base 14 having an open cross section, the load transmission to the column base 14 can be ensured.

  The column-side joining piece 31 includes a plate-like reinforcing portion 33 that is welded and fixed to the side surface 12 c of the column main body portion 12, and the joining plate portion 32 is fixed to the reinforcing portion 33. Therefore, since the thickness of the load transmission part in the steel pipe column 11 increases by the reinforcement part 33, it becomes possible to suppress the stagnation of the steel pipe column 11.

  The brace 25 includes a brace body 26 and a beam joint 27 attached to the upper end 26a of the brace body 26, and the brace body 26 is formed of a steel pipe. The brace-side joining piece 35 is fixed by welding to the lower end portion 26b of (26). Therefore, since the brace body 26 is formed of a steel pipe, it can resist not only tension but also compression. As a result, it becomes difficult to buckle as a whole, and the performance as a brace is improved.

  The lower end portion 26b of the brace body 26 is formed with a pair of notches 26e and 26f at positions that are line-symmetric with respect to the axis of the brace body, and the braces are formed on the pair of notches 26e and 26f. The side joining piece 35 is welded and fixed in a state where it penetrates. For this reason, the weld length 35d of the brace-side joining piece 35 can be ensured. As a result, the joining strength between the brace body 26 and the brace-side joining piece 35 can be ensured, and the load transmission between the brace body 26 and the brace-side joining piece 35 can be made smooth.

  Moreover, since the brace is installed only in one place between the two steel pipe columns 11 and 15, it is possible to design the cross sections of the steel pipe columns 11 and 15 and the ridge beam 17 to be small, and the steel pipe columns. The degree of freedom of opening between 11 and 15 can be increased, and the influence on the lower structure 2a can also be suppressed.

  Moreover, the brace 25 is constructed between the steel pipe columns 11 and 15 and the ridge beam 17, and the frame structure 1 can be used as a roof frame structure.

  As mentioned above, although preferred embodiment of this invention was described, this invention is not limited to the said embodiment, It changed within the range which does not change the summary described in each claim, or applied to the other thing It may be a thing.

  For example, in the said embodiment, when the column side joining piece is formed in plate shape among the column side joining piece and the brace side joining piece, and the brace side joining piece contains the 1st opposing surface part and the 2nd opposing surface part. However, it is not limited to this. For example, the column side joining piece may include a first facing surface portion and a second facing surface portion, and the brace side joining piece may be formed in a plate shape.

  In the said embodiment, although the cross-sectional shape of the steel pipe pillar 11 was made into the closed cross section, it is not restricted to this, An open cross section may be sufficient. From the viewpoint of cross-sectional performance, a closed cross-section is preferable. Also, the cross-sectional shape of the steel pipe column 15 may be either a closed cross section or an open cross section, similar to the steel pipe column 11.

  In the above embodiment, the frame structure 1 is, for example, a roof frame structure used for a unit provided on the roof. However, the frame structure 1 is not limited to this, and the frame structure 1 may be used, for example, on an intermediate floor that is not the roof. Further, in the case where the roof frame structure is not employed, the master beam 17 may be a simple beam instead of the master beam.

  DESCRIPTION OF SYMBOLS 1,61,62,63 ... Frame structure, 11, 15, 16 ... Steel pipe column (steel column), 11c ... Side surface, 12 ... Column main-body part, 14 ... Column base part, 17 ... Master beam (beam), 25 ... Brace 25b ... lower end, 26 ... brace body, 26b ... lower end, 26e, 26f ... notch, 27 ... beam joint, 30 ... joint, 31 ... column side joint, 32 ... joint plate part, 33 ... Reinforcement part, 35 ... Brace side joining piece, 36 ... 1st opposing surface part, 37 ... 2nd opposing surface part, P1, P2 ... Axis center.

Claims (9)

Steel pillars,
A beam joined to the steel column;
A brace constructed between the steel column and the beam;
With
A joint is formed across the side surface of the steel column and the lower end of the brace,
The width of the joint is smaller than the width of the steel column.
Frame structure. The joint has a column-side joining piece protruding from the side surface of the steel column, and a brace-side joining piece attached to the lower end of the brace,
Of the column-side joining piece and the brace-side joining piece, one joining piece is formed in a plate shape, and the other joining piece includes a first facing surface portion facing one surface of the one joining piece, A second facing surface portion facing the other surface of the one joining piece,
The frame structure according to claim 1. The one joining piece is the column side joining piece, and the other joining piece is the brace side joining piece,
The column-side joining piece includes a joining plate portion that extends vertically along the axis of the steel column at a position that is the center in the width direction of the side surface of the steel column.
The frame structure according to claim 2. The steel column has a column main body portion formed by a steel pipe having a closed cross section, and a column base portion having an open cross section formed at a lower end portion of the column main body portion,
The frame structure according to claim 3, wherein the column side joining piece is provided and fixed by welding over the column main body portion and the column base portion. The column-side joining piece includes a plate-like reinforcing portion that is welded and fixed to a side surface of the column main body portion.
The joining plate part is fixed to the reinforcing part,
The frame structure according to claim 4. The brace has a brace body and a beam joint attached to the upper end of the brace body.
The brace body is formed of a steel pipe, and the brace-side joining piece is welded and fixed to the lower end of the steel pipe.
The frame structure according to any one of claims 3 to 5. At the lower end of the brace body, a pair of notches are formed at positions that are line-symmetric with respect to the axis of the brace body,
The brace-side joining piece is welded and fixed to the pair of notches,
The frame structure according to claim 6. The brace is installed only in one place between the two steel columns,
The frame structure according to any one of claims 1 to 7. The brace is erected between the steel column and the master beam,
The frame structure according to any one of claims 1 to 8.

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