The present invention relates to a connection structure of a column and beams and the like for connecting beams having different heights to a steel pipe column.
Conventionally, in a construction using a steel pipe column, there is a case in which a beam of H shaped steel is connected. To connect the column and the beam, a through-diaphragm corresponding to the height of a flange part of the beam is provided to transfer stress from the beam to the column efficiently at a connecting part thereof. The through-diaphragm is a plate-like member that is connected by welding and the like between a column and a column. Generally, the flange part of the beam is butted against the side surface of the through-diaphragm to be welded.
However, there are cases in which the sizes (heights) of the beams that are connected to the column are not equal in all directions. For example, there is a case in which a beam having a shorter height is connected in only one direction. In such cases, it is impossible to connect at least one of the upper and lower flanges of the beam to the through-diaphragm to which other beams are connected.
Therefore, to connect such beams having different heights, connecting an inner diaphragm inside the column or the like is necessary.
Also, as a connection structure of column-and-beam to connect beams having different heights, there is a connection structure of column-and-beam wherein, a flange part of a beam is connected to a diaphragm, a beam connection member is connected between the other flange part of the beam and the other diaphragm, and stress is transferred between the beam and the diaphragm via the beam connection member (See Patent Document 1).
However, the operation of providing an inner diaphragm in the column requires a large amount of welding and has a problem of poor workability. Also, in the structure described in Patent Document 1, it is impossible to connect the beam connection member if there is not enough space between the beam and the diaphragm.
The present invention was achieved in view of such problems. Its object is to provide a connection structure and the like of a column and beams, wherein the beams having different heights are connected to the column without connecting diaphragms and the like to the inside of the column, which is also applicable even if a gap between the beam and the diaphragm is small.
To achieve the above object, a first invention provides a connection structure of a column and beams comprising a column having an approximately rectangular cross-sectional outline, a pair of diaphragms formed on the column, a first beam of which flange parts are connected to the upper and the lower diaphragms respectively, a second beam that has a height different to the first beam and is connected to the column in a direction different to the first beam, and a reinforcing member connected to the outer surface of the column, wherein the reinforcing member has a first connecting part and a second connecting part that are formed perpendicular to each other to be approximately L-shaped, a first connecting part being connected to the surface of the column to which the second beam is connected and the second connecting part being connected to the surface which is perpendicular to the surface to which the second beam is connected, a first flange part of the second beam is connected to one of the diaphragms, a second flange part of the second beam is connected to the outer surface of the column, and a pair of the reinforcing member is connected to both sides of the column so as to interpose the second beam. It is preferable that the corner parts of the column are configured with curved surface parts and the inner surface side between the first connecting part and the second connecting part is a concave surface part.
The reinforcing member may have a convex part formed in the direction which is perpendicular to both the forming direction of the first connecting part and the forming direction of the second connecting part, the concave surface part which is continuously formed on the inner surface of the convex part, and at least one of the end part of the second beam in the width direction projecting out to the curved surface part of the column. The reinforcing member may be connected to the column and the second beam with the convex part being inserted into a gap between the curved surface part and the second flange part at the height of the second flange part of the second beam.
The width of the second beam is smaller than the width of the column, and the second beam may be eccentrically connected to the column in its width direction.
The radius of curvature of the concave surface part is preferably smaller than the radius of curvature of the curved surface part.
According to the first invention, the column can be reinforced efficiently against the stress and the like from the beams since the reinforcing member is connected to the column 5 in the vicinity of the connecting part of the beam. Also, since the reinforcing member is connected to the outer part of the column, the work can be done only outside the column. Therefore, the workability of connecting beams to a column is good. Also, the reinforcing member is easily applicable even if the distance between the flange part of the beam and the diaphragm is short since the reinforcing member is connected to both sides of the column to which the beam is connected.
Also, it is possible to transfer the stress from the beam to the column with certainty by inserting the convex part of the reinforcing member into a gap between the side edge part of the flange part of the beam and the corner part (curved surface part) of the column. Such a structure is particularly effective when the beam is connected to the column eccentrically.
Also, no gap may be formed between the tip part of the convex part and the column by making the radius of curvature of the concave surface part of the inner surface of the convex part smaller than the radius of curvature of the curved surface part of the corner part of the column.
A second invention is a reinforcing member used in a connection structure of a column and beams, wherein a first connecting part connected to a first surface of the column and a second connecting part connected to a second surface that is perpendicular to the first surface are formed perpendicular to each other in an approximately L-shape and an inner surface side between the first connecting part and the second connecting part is a concave surface part.
A convex part may be formed in the direction which is perpendicular to both the forming direction of the first connecting part and the forming direction of the second connecting part, and the concave surface part may be continuously formed on the inner surface of the convex part.
The convex parts may be provided in the directions that are opposite to each other in relation to the second connecting part, respectively.
According to the second invention, the vicinity of the connecting part of the column and the beam can be effectively reinforced, and work can be done only outside the column. Therefore, the workability of connecting beams to a column is good.
Also, it is possible to transfer the stress from the beam to the column with certainty since the convex part of the reinforcing member can be inserted into a gap between the side edge part of the flange parts of the beam and the corner part (curved surface part) of the column. Also, by forming such convex parts on both sides, it can be used in either direction.
The present invention can provide a connection structure and the like of a column and beams, wherein the beams having different heights are connected to the column without connecting diaphragms and the like to the inside of the column, which is also applicable even if a gap between the beam and the diaphragm is small.
Hereinafter, a connection structure 1 of a column and beams according to an embodiment of the present invention will be described.
The column 5 is a hollow, square-shaped steel piped column of which the cross sectional outline is approximately rectangular. The beams 9a and 9b are H-shaped steel. The heights of the beams 9a and 9b are different. Although the example shown in
A pair of diaphragms 3a and 3b is connected to the column 5. The diaphragms 3a and 3b are through diaphragms protruding outwardly from the column 5. The diaphragms 3a and 3b are provided on the upper and lower parts of the column 5 with a predetermined interval.
The edge parts of the upper and lower flange parts of the beam 9a, which is a first beam, are connected to the diaphragm 3a and 3b by welding respectively. That is, the installation interval between the diaphragms 3a and 3b is equal to the flange interval of the beam 9a. Therefore, stress from the beam 9a can be transferred to the column with certainty.
The edge part of an upper flange part 11a of the beam 9b, which is a second beam, is connected to the upper diaphragm 3a by welding. Since the height of the beam 9b is shorter than the height of the beam 9a, a gap is generated between a lower flange part 11b of the beam 9b and the diaphragm 3b. Therefore, the flange part 11b is connected to the outer surface of the column 5.
A reinforcing member 13 is connected to the outer surfaces of the column 5 on both sides of the beam 9b where the reinforcing member 13 does not interfere with the flange part 11b of the beam 9b. For example, the reinforcing member 13 is connected to a position slightly above the flange part 11b of the beam 9b. The reinforcing member 13 is an approximately L-shaped member and connected to the outer surfaces of the column 5. That is, the reinforcing member 13 is connected to the column 5 straddling the surface to which the beam 9b is connected and the other surface which is perpendicular thereto.
The reinforcing member 13 is, for example, made of steel having excellent weldability. On the connecting parts 15a and 15b, groove parts 19 are formed on the parts corresponding to the welding parts of the column 5 (welding parts 21 in
The thickness of the reinforcing member 13 is approximately equal to the protrusion margin of the diaphragm 3b in relation to the column 5. Therefore, as shown in
Thus, providing the reinforcing member 13 on the vicinity of the connecting part of the flange part 11b of the beam 9b, which is an outer surface of the column 5, can reinforce the column 5 with certainty against forces given to the column 5, such as tension or compressive stress from the beam 9b and the moment originating from the connecting part with the diaphragm 3a. Also, the column 5 can be reinforced with certainty even if the distance between the beam 9b (the flange part 11b) and the diaphragm 3b is small.
Although an example in which the height of the beam 9b is shorter than the height of the beam 9a is described in this embodiment, the present invention is applicable to a case in which the beam 9b is higher than the beam 9a. In this case, a predetermined range of the web of the beam 9b is cut and the reinforcing member 13 is connected to the column 5 and the lower surface part and the like of the diaphragm 3b.
Also, the beam 9b and the reinforcing member 13 may be connected in an upside down state of
Next, another variation of the reinforcing member 13 will be described. The same numerals from
The concave surface part 17, which is provided on the inner surface of the connecting parts 15a and 15b, is continuously formed on the inner surface of the convex parts 23. That is, the reinforcing member 13a has the concave surface part 17 extending upward and downward with a fixed curvature. Therefore, a concave surface edge part 25, which is a tip of a region of the concave surface part 17 protruding from the connecting parts 15a and 15b, has a cross sectional shape which is tapered toward the tip. The convex parts 23 are provided on the upper and lower surfaces of the connecting part 15b respectively in the directions that are opposite to each other and the concave surface edge part 25 is formed to face the side of the connecting part 15a.
In the connection structure 1a of a column and beams, the beam 9b is disposed eccentrically in the width direction of the column 5. That is, the beam 9b is disposed eccentrically to the column 5 so that one side of the column 5 (on the right in the diagram) coincides with one side (on the right in the diagram) of the beam 9b (flange part 11b).
The convex parts 23 formed on the reinforcing member 13a are disposed toward the longitudinal direction of the column 5. That is, the convex parts 23 are disposed along the corner part (the curved surface part 7) of the column 5.
At this time, since the radius of curvature of the concave surface part 17 is smaller than the radius of curvature of the curved surface part 7, there is no gap formed between the reinforcing member 13a and the column 5. The convex parts 23 are welded and connected with the column 5 and the flange part 11b in this state.
The height of the convex part 23 (the protruding margin from the connecting part 15b) is determined taking the distance from the position in which the connecting parts 15a and 15b are connected and the thickness of the flange part 11b into consideration. That is, the height of the convex part 23 is determined so that the convex part 23 can cover the whole thickness of the flange part 11b when the reinforcing member 13a is connected to the column 5.
According to the second embodiment, similar effects as the first embodiment can be obtained. Also, in the case in which the beam 9b is eccentrically connected, the gap 26 between the curved surface part 7 at the corner part of the column 5 and the flange part 11b is filled with the convex part 23 (the concave surface edge part 25) and hence it is possible to transfer the stress with certainty between the beam 9b and the column 5 at this part.
Although the convex parts 23 are provided on both sides of the reinforcing member 13a, one convex part 23 may be provided only on either side. However, by forming the convex parts 23 on both sides, the reinforcing member 13a can be used in reversed position so that the same component can be used independent of the eccentric direction of the beam 9b. Therefore, it is unnecessary to manufacture and manage two types of reinforcing members.
Although the embodiments of the present invention have been described referring to the attached drawings, the technical scope of the present invention is not limited to the embodiments described above. It is obvious that persons skilled in the art can think out various examples of changes or modifications within the scope of the technical idea disclosed in the claims, and it will be understood that they naturally belong to the technical scope of the present invention.
For example, although the curved surface part 7 is formed on the corner part of the column 5 and the concave surface part 17 is formed on the reinforcing member 13 or 13a in the examples shown in the above-mentioned embodiments, the present invention is not limited to these examples. Each of the plane surfaces of the connecting parts 15a and 15b may be formed to be orthogonal to each other and, in this case, the corner part of the column 5 may also have the plane surfaces that are orthogonal to each other without forming the curved surface part 7.
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