JPH1136231A - Composite column base structure and method of constructing the same - Google Patents

Abstract

(57) [Problem] To provide a composite column base structure which is excellent in the integrality of an outer shell portion made of a steel panel or the like, the strength and weather resistance of the column base structure as a whole, easy to construct, and economical. The construction method is provided. SOLUTION: Outer panels 2 provided with bolt-fitting flanges 11 on both side ends of an arc-shaped steel plate 10 are circumferentially connected to each other to assemble a unit cylindrical outer shell 1a. Unit cylindrical outer shell 1a is welded in the vertical direction to form a columnar cylindrical outer shell 1
Is formed, and concrete 3 is filled therein. By using the jack-up stand and jacking up, successively adding the unit cylindrical outer shell 1a from below to build the cylindrical outer shell 1, and without using a large crane, etc., on the ground The joining operation can be performed at a close, fixed position.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure of a column base structure used as a pier, a main tower, or a column in another structure of a bridge, and a method of constructing the same.

[0002]

2. Description of the Related Art Columnar bases having a relatively large scale include a columnar base having a reinforced concrete structure and a columnar base having a steel structure made of a steel pipe or the like.

[0003] Reinforced concrete structures are generally economical and are widely used structures. In particular, in the case of a large-scale structure, a movable form is sequentially moved upward by a sliding form method, a jumping form method, or the like. While arranging the reinforcement, concrete is laid and a column base structure is constructed.

In a steel structure, a column-base structure can be constructed in a short construction period by successively adding a steel pipe or the like having a predetermined length upward by welding or bolting, and has a uniform material. Therefore, there is an advantage that reliability is high also in terms of strength.

On the other hand, as an economical column base structure having excellent workability, there is a column base structure described in Japanese Patent Application Laid-Open No. 5-263404. In this structure, concrete is formed inside a columnar body formed by arranging grooved steel frames provided with a number of bolt fastening through holes in flanges formed on both sides in the width direction in a staggered manner and fastening with bolts. It is a filled composite column base structure. According to this structure, the mechanical strength is strong,
It is said that a column base having excellent weather resistance can be easily and inexpensively constructed.

[0006]

When a column base of a reinforced concrete structure is constructed by a sliding form method or a jumping form method, scaffolds, supports, and other temporary materials are required. It takes time and labor to assemble, jack up, disassemble, etc., and requires a lot of manpower and construction time.

Further, in the case of a column base having a steel structure using a steel pipe or the like, there are problems in that it is difficult to carry the column base to a large-sized structure, and a large crane is required for installation. In addition, the cost of materials is higher than reinforced concrete.

On the other hand, the column base structure described in Japanese Patent Application Laid-Open No. 5-263404 has a simple structure, a low workability, and can be constructed with a short work without requiring a skilled worker. However, it has the following problems.

When a moment acts on the column pedestal, a vertical tensile force acts on a part of the steel tubular body formed of the unit-shaped steel frame. Since the spaces are not connected, at the upper and lower unit steel frame connection positions, the effective cross-sectional area of the steel tubular body becomes smaller than other portions, and the tensile strength decreases. In addition, a gap may be formed between the opposed edges of the upper and lower unit-shaped steel frames, and concrete may leak or rainwater may enter when the concrete is poured.

In the case where the central steel pipe column is provided inside the cylindrical body, the central steel pipe column is first erected, and then the unit-shaped steel frame is assembled to construct the cylindrical body. Since the diameter of the column is smaller than the outer steel tubular body, if it is used alone, the moment resistance is small, and there is a risk of collapse due to wind or the like during construction. In particular, this point becomes a problem when the central steel pipe column is used as a guide mast.

[0011] The assembling and joining work of the steel tubular body and the central steel pipe column are advanced from the bottom to the top and the work place is changed, so that large-scale facilities such as a total scaffold and a moving platform are required. However, it is difficult to take sufficient safety measures at each location and prepare a working environment.

In the case of a pier supporting a girder of a bridge, in a single-column structure in which cross-sectional dimensions in a bridge axis direction and a direction perpendicular to the bridge axis are substantially equal,
It is difficult to secure strength and rigidity in the direction perpendicular to the bridge axis.

The present invention has been made to solve the above-mentioned problems in the prior art, and is excellent in the integrity of the outer shell portion made of a steel panel or the like, the strength and weather resistance of the column base structure as a whole, and It is an object of the present invention to provide a composite column base structure which is easy and economical and a method of constructing the same.

[0014]

According to a first aspect of the present invention, there is provided a composite column-base structure comprising a unit cylindrical outer shell having a closed cross section by connecting a plurality of outer panels arranged substantially vertically to each other in a horizontal direction. Is formed, and a plurality of unit cylindrical outer shells are welded and joined in the vertical direction to form a cylindrical outer shell, and concrete is filled inside the cylindrical outer shell.

The outer panel is joined in a horizontal direction and a vertical direction to form a cylindrical outer shell, and forms a composite structure together with the concrete filled inside. The outer panel has excellent strength and weather resistance, and has simple components. This is a form and is advantageous in terms of workability and economy.

In the cylindrical outer shell portion, since the vertical joint is joined by welding, the tensile strength at the joint is ensured, and concrete filled inside may leak or rainwater may enter. There is no.

According to a second aspect of the present invention, in the composite column base structure according to the first aspect, the outer panel is formed with flanges on both side ends of the steel plate, and the flanges of the adjacent outer panels are horizontally bolted to each other. This limits the case where the unit cylindrical outer shell is formed. In this case, joining the outer panels horizontally in the field is a very simple task.

On the other hand, a third aspect of the present invention is the composite column base structure according to the first aspect, wherein the outer panel is made of a steel plate having a reduced thickness at both side ends, and the side ends of the adjacent outer panels are welded to each other. By doing so, the case where the unit cylindrical outer shell is formed is limited.

When welding is used to connect adjacent outer panels in the horizontal direction, in order to prevent defects at the welded portion and to improve the strength against dynamic loads such as fatigue or impact force, it is necessary to use full-section penetration welding. It is desirable to do. In this case, if the thickness of the steel plate constituting the outer panel is large, the amount of welding increases, which impairs workability and economy. on the other hand,
The force acting on the cylindrical outer shell is dominant in the vertical direction, the acting force in the horizontal direction is relatively small, and it is not necessary to make a full-strength joint from a static strength.

Therefore, in the case of the invention according to the third aspect, the plate thickness at both end portions of the outer panel is reduced by cutting or the like, and sufficient dynamic and static strength is obtained by performing full-section penetration welding. , Welding defects are less likely to occur, the amount of welding is small, and an efficient joint can be obtained. In addition, as a welding method in that case, there is electrogas arc welding or the like.

According to a fourth aspect of the present invention, in the composite column base structure according to the first, second or third aspect, the outer panel is made of a steel plate, and protrudes toward the center on the inner surface side and is continuous in the column axis direction. A connecting material is fixed, and an inner panel formed by forming flanges at both ends of a steel plate is arranged and connected between the connecting materials of each outer panel to form a closed cross section inside the cylindrical outer shell. A cylindrical inner shell is formed, and concrete is filled between the cylindrical outer shell and the cylindrical inner shell.

The cylindrical outer shell and the cylindrical inner shell constitute a double cylindrical shell, and concrete is filled in the double cylindrical shell, so that the center of the column base can have a hollow structure. To that extent, the amount of concrete can be reduced without impairing the bending rigidity of the column base, and the economic efficiency is improved.

According to a fifth aspect of the present invention, a multi-column composite column base structure is obtained by arranging a plurality of the composite column base structures according to the first, second, third, and fourth aspects in parallel and connecting them by a connecting member. .

In the case of a pier supporting a girder of a bridge or the like, the use of a multi-column composite column base structure makes it easy to secure the strength and rigidity in the direction perpendicular to the bridge axis.

According to a sixth aspect of the present invention, there is provided a method of constructing a composite column-base structure according to the first, second, and third aspects, wherein a jack-up device using a jack such as a center hole jack at the column-base structure construction position. After fixing the jack-up gantry having, and installing the unit cylindrical outer shell located on the top of the column base structure in the jack-up gantry and jacking up the height of the substantially unit cylindrical outer shell, sequentially, A step of installing a unit cylindrical outer shell located on the lower side in the jack-up pedestal, and connecting the upper unit cylindrical outer shell already jacked up by welding, and a plurality of connected unit cylindrical outer shells; Is further repeated a required number of times, and then the unit cylindrical shell located at the bottom of the column base structure is welded to the upper unit cylindrical shell. Columnar cylindrical outer shell Formed, it is obtained so as to fill the concrete inside the tubular shell.

That is, while jacking up,
The unitary cylindrical shells are sequentially added from below to form a cylindrical shell, and the joining operation can be performed at a fixed position near the ground without using a large crane or the like.

According to a seventh aspect of the present invention, there is provided a method of constructing a composite column base structure having a hollow structure in which concrete is filled in a double cylindrical shell according to the fourth aspect. After fixing the jack-up gantry having the device, installing the unit cylindrical outer shell located at the top of the column base structure in the jack-up gantry and jacking up by the height of the substantially unit cylindrical outer shell, then sequentially Installing the lower unit cylindrical shell in the jack-up pedestal and connecting the upper unit cylindrical shell already jacked up by welding, and connecting the plurality of unit cylindrical outer shells. The step of jacking up the shell further by the height of the substantially unit cylindrical outer shell is repeated a required number of times, and then the unit cylindrical outer shell located at the bottom of the column base structure is connected to the upper unit cylindrical outer shell. Connected by welding to form a cylindrical outer shell At the same time, a cylindrical inner shell consisting of an inner panel is formed inside the cylindrical outer shell via a connecting material, and concrete is filled between the cylindrical outer shell and the cylindrical inner shell. is there.

As one method of forming the cylindrical inner shell, as one mode, an inner panel having flanges provided on both side ends of a steel plate is arranged between connecting members, and the connecting members are sandwiched between adjacent flanges by bolts. A unit cylindrical inner shell having a closed cross-section is formed by coupling, and a unit double cylindrical shell is formed together with the unit cylindrical outer shell. There is a method of constructing a double cylindrical shell composed of a shell and a cylindrical inner shell.

In addition, it is also possible to assemble the cylindrical outer shell constituting the double cylindrical shell while shifting the cylindrical inner shell. In this case, the outer panel constituting the unit cylindrical outer shell is provided. And the height of the inner panel forming the cylindrical inner shell may be different. Alternatively, the cylindrical inner shell may be assembled first, and the outer panel may be arranged outside the cylindrical inner shell to form a double cylindrical shell.

An eighth aspect of the present invention provides a method of constructing a multi-column composite column base structure (corresponding to a part of the multi-column composite column base structure according to the fifth embodiment). A plurality of outer panels arranged are connected in a horizontal direction to form a unit cylindrical outer shell having a closed cross section, and a plurality of unit cylindrical outer shells are arranged in parallel and connected by a connecting member to form a multi-column cylindrical unit. An outer shell is formed, a jack-up gantry having a jack-up device is fixed at a column base structure construction position, and a unit multi-column cylindrical outer shell located at the top of the column pier structure is installed in the jack-up frame. After jacking up approximately the height of the multi-column cylindrical outer shell, the lower unit multi-column cylindrical outer shell is sequentially placed in the jack-up rack, and the upper unit already jacked up A process of welding to the multi-column cylindrical outer shell by welding; Step of jacking up the plurality of unit multi-column cylindrical shells further by the height of the substantially unit multi-column cylindrical shell, the required number of times, and then the unit multi-column located at the bottom of the column base structure The cylindrical outer shell is connected to the upper unit multi-column cylindrical outer shell by welding to form a multi-column cylindrical outer shell, and the inside of the multi-column cylindrical outer shell is filled with concrete.

A ninth aspect of the present invention further provides a method of constructing a multi-column composite column base structure having a hollow section (corresponding to a part of the multi-column composite column base structure according to the fifth embodiment). According to the constitution of claim 8, the multi-column cylindrical outer shell is formed, and in the forming process, a plurality of inner panels are connected to the inside of each of the cylindrical outer shells constituting the multi-column cylindrical outer shell via a connecting member. A cylindrical inner shell is formed, and concrete is filled between each cylindrical outer shell and the cylindrical inner shell.

In the construction method according to the seventh to ninth aspects, similarly to the construction method according to the sixth aspect, the cylindrical outer shell or the cylindrical outer shell and the cylindrical outer shell are successively added from below while jacking up. The inner shell is constructed in a columnar shape, and the joining operation can be performed at a fixed position near the ground without using a large crane or the like.

[0033]

FIG. 1 shows an embodiment in which the composite column-base structure according to claims 1 and 2 of the present application is applied to a leg member for a bridge. FIG. 2 is a horizontal sectional view of the column base, and FIG. 2B is a perspective view of the entire column base.

In this example, as shown in FIG. 2, an outer panel 2 having an arc-shaped steel plate 10 provided with flanges 11 at both end portions.
Are connected to each other in the circumferential direction to form a unit cylindrical outer shell 1a.
The unit cylindrical outer shell 1a is welded and joined in the vertical direction to form a columnar cylindrical outer shell 1, and concrete 3 is filled therein to construct a composite column base.

In the drawings, reference numeral 4 denotes a circumferential joint, and reference numeral 5 denotes a vertical joint. The lower part of the cylindrical outer shell 1 is fixed to a reinforced concrete foundation 6.

FIG. 3 (a) shows an example of the form of the outer panel 2. In this example, the outer panel 2 is formed into a steel plate 10 formed into an arc shape, and flanges provided on both side ends of the steel plate 10 are shown. 1
And a bolt hole 1 for bolt connection in the flange 11
2 is provided. By connecting the outer panels 2 with each other with bolts in the circumferential direction, a unit cylindrical outer shell 1a is formed, and the unit cylindrical outer shells 1a are vertically welded to each other to form a columnar steel cylindrical outer shell. 1 is formed.

FIGS. 3 (b) and 3 (c) show other examples of the form of the outer panel 2. In these examples, in addition to the flanges 11 on both side ends of the arc-shaped steel plate 10, a circle is shown. The outer panel 2 is provided with the circumferential ribs 13 or the vertical ribs 14.
To increase the rigidity.

FIG. 4 shows an example of a joint portion in the case where the adjacent outer panels 2 are joined in the circumferential direction (horizontal direction) by welding. That is, in this example,
An arc-shaped steel plate 16 having a reduced thickness at both ends is used as the outer panel 2, and the ends are joined by full-section penetration welding such as electrogas arc welding. In the drawing, reference numeral 17 indicates a penetration welding portion of the entire cross section.

FIGS. 5A and 5B show an embodiment of the construction method according to the sixth aspect of the present invention, which can be used for constructing the composite column base structure shown in FIG. Hereinafter, the construction procedure will be described with reference to the reference numerals in FIG.

First, the foundation 6 for supporting the column base is constructed.
Usually, the foundation 6 is a reinforced concrete structure. When constructing the foundation 6, an anchor bolt for fixing the cylindrical outer shell 1 formed into a cylindrical column shape and a jack-up base 51 described later is embedded.

Next, a jack-up base 51 made of steel is constructed on the foundation 6 and its lower end is fixed to an anchor bolt embedded in the foundation 6. After the outer panel 2 is manufactured at the factory and carried into the site, the outer panel 2 is circumferentially connected by bolts or welding to form a unit cylindrical outer shell 1a in an assembly yard adjacent to the jack-up gantry 51.

Next, the unit cylindrical outer shell 1a is drawn into the jack-up stand 51, and the upper part of the unit cylindrical outer shell 1a and the lower part of the unit cylindrical outer shell 1a at the lower end of the cylindrical outer shell 1 already lifted. The lower part is connected vertically by welding.

Next, the connected cylindrical outer shell 1 is lifted by a jack 52 attached to a jack-up gantry 51 substantially by the height of the unit cylindrical outer shell 1a. Meanwhile, in the assembly yard, the next unit cylindrical outer shell 1a is assembled, and after jacking up in the jack-up gantry 51, a new unit cylindrical outer shell 1a is drawn into the jack-up gantry 51 and lifted. Is welded to the lower portion of the cylindrical outer shell 1.

By repeating this procedure, the cylindrical outer shell 1 is assembled into a column shape.

After assembling the cylindrical outer shell 1 to a predetermined height,
The lower end of the cylindrical outer shell 1 is fixed with anchor bolts embedded in the foundation 6. Thereafter, the inside of the cylindrical outer shell 1 is filled with concrete 3 and the jack-up gantry 51 is removed to complete the composite column base. In the process of assembling the cylindrical outer shell 1,
If the head of the anchor bolt protruding on the foundation 6 is in the way, provide a suitable base on the foundation to raise the working position to prevent interference with the anchor bolt head. Can be.

By using high-fluidity concrete as the concrete 3 to be filled, compaction work becomes unnecessary, and the filling work can be performed easily.

FIG. 6 shows an embodiment in which the composite column base structure according to claim 4 of the present application is applied to a bridge leg member, and (a) shows a horizontal section of the column base portion. FIG. 1B is a perspective view of the entire column base. FIG. 7 shows details of a circumferential joint between the outer panel 2 and the inner panel 22.

In the above-mentioned column base structure shown in FIG.
Is filled with concrete 3 in a solid state.
However, since the central portion of the cross section cannot resist the acting moment, the concrete in this portion is wasted, and the weight increases the acting force at the time of the earthquake. Therefore, it may be economically advantageous to form a hollow section near the center.

In the example shown in FIGS. 6 and 7, a connecting member 18 projecting in the center direction and continuing in the column axis direction is fixed inside the steel plate 10 constituting the outer panel 2 of the cylindrical outer shell 1, and the connecting member 18 is connected. By disposing the inner panel 22 having flanges 31 at both ends of the arc-shaped steel plate 30 between the members 18 and connecting the adjacent flanges 31 in the horizontal direction with the bolts 33 with the connecting member 18 interposed therebetween, A cylindrical columnar structure having a cylindrical inner shell 21 formed between the inner surface of the cylindrical outer shell 1 and the outer surface of the cylindrical inner shell 21 filled with concrete 3 and having a hollow portion at the center of the cross section And

FIG. 8 shows an example of the form of the outer panel 2 used in the examples of FIGS. In this example,
An arc-shaped steel plate 10, flanges 11 provided at both ends of the steel plate 10, and a connecting member 18 protruding toward the center and continuing in the column axis direction inside the arc-shaped steel plate 10, Are provided with bolt holes 12 for bolt connection. The outer panels 2 are connected to each other by bolts in the circumferential direction to form a unit cylindrical outer shell.

FIG. 9 shows an example of the form of the inner panel 22 used in the examples of FIGS. Inner panel 22
Because a compressive force is applied to concrete at the time of casting, it is necessary to have a structure that does not buckle in the circumferential direction. Therefore, in this example, a liner plate is used as the inner panel 22.

The liner plate comprises a steel plate 30a having a corrugated cross section and formed in an arc shape, and flanges 31 provided at both ends of the steel plate 30a. The flange 31 has bolt holes 32 for bolt connection. is there. Bolt holes 34 are also provided at the upper and lower ends of the corrugated steel plate 30a for vertically connecting the inner panels 22 to each other. In the liner plate, since the steel plate has a corrugated cross section and high rigidity,
It does not buckle even if a compressive force acts during concrete casting.

Next, an example of the method of constructing the composite column base structure shown in FIG. 6 (corresponding to claim 7) will be described with reference to the reference numerals in FIG. 5 (FIG. 5 itself corresponds to claim 6). explain.

First, in the assembly yard adjacent to the jack-up gantry 51, the outer panel 2 having the connecting member 18 is assembled to form the unit cylindrical outer shell 1a, and then the inner panel 22 is arranged between the connecting members 18. By connecting the adjacent flanges 31 with bolts 32 with the connecting member 18 interposed therebetween, the cylindrical inner shell 21 is formed to form a unit double cylindrical shell.

At this time, when the unit height of the inner panel 22 is smaller than the height of the unit cylindrical outer shell 1a, the plurality of inner panels 22 are connected in the vertical direction, and the upper and lower inner panels 22 are joined by bolts. To the required height.

Next, the unit double cylindrical shell is pulled into the inside of the jack-up gantry 51, and the upper part of the unit double cylindrical shell and the lower part of the unit cylindrical shell that has already been lifted are removed. The shells 1a are connected vertically by welding, and the cylindrical inner shell 21 is connected vertically by bolts.

Next, the connected double cylindrical shell is lifted by the height of the substantially unit double cylindrical shell by the jack 52 attached to the jack-up stand 51. During this time, in the assembly yard, the next unit double cylindrical shell is assembled, and after the jack-up in the gantry 51, a new unit double cylindrical shell is drawn into the jack-up gantry 51 and lifted. Connected to the lower part of the double cylindrical shell. By repeating this procedure, the double cylindrical shell is assembled into a column shape.

When welding the unit cylindrical outer shells 1a,
When the construction is performed from both inside and outside, for example, FIG.
As shown in (a) and (b), when assembling the unit double cylindrical shell, the inner panel 22a at the joint is removed and the outer panel 2a is removed.
A method in which the inner panels 22a are attached to each other and then the inner panels 22 are joined to each other can be used.

After assembling the double cylindrical shell to a predetermined height,
The lower end of the double cylindrical shell is fixed with anchor bolts embedded in the foundation 6. Thereafter, the jack-up gantry 51 is removed, and the inside of the double cylindrical shell is filled with concrete 3 to complete a composite column base having a hollow cross section. By using high-fluidity concrete as the concrete to be filled, compaction work becomes unnecessary, and the filling work can be easily performed.

FIG. 11 shows an embodiment of the composite column base structure according to claim 5 of the present application. In this example,
Two composite column bases 40 are arranged in the direction perpendicular to the bridge axis, and the composite column bases 40 are connected by a connecting member 42 to form a multi-column composite column base structure.

With the multi-column structure, the required width in the direction perpendicular to the bridge axis determined by the width of the road is secured, and the rigidity and strength are increased.

As shown in FIG. 12, the multi-column composite column base is formed by connecting a unit multi-column cylindrical outer shell 41a formed by connecting a plurality of unit cylindrical outer shells 1a with a connecting member 42 to a jack-up method. To construct the multi-column cylindrical outer shell 41, and to fill the inside with concrete 3 to construct.

Also in this case, each of the composite column bases constituting the multi-column composite column base has a solid cross section composed of only a single cylindrical outer shell (corresponding to claim 8) and a double cylindrical steel base. There are both cases of a hollow section composed of a shell (corresponding to claim 9).

FIG. 13 shows an example of the shape of the cylindrical outer shell 1 other than the circular shape in the present invention.

The cross-sectional shape of the column base is basically circular. When the circular column is formed in a circular shape, the force generated by the internal pressure acting at the time of concrete casting causes the tensile force of the cylindrical outer shell 1 and the cylindrical inner shell to decrease. In some cases, only the compressive force of the cylindrical inner shell is generated and no moment is generated, so that the steel shell is hardly deformed.

When a cross section other than a circle such as a rectangle is used, it is necessary to weld a rib or the like to a steel shell to stiffen the steel shell so as not to be deformed even when a moment is applied at the time of placing concrete. .

Further, as shown in FIG. 13, by forming a cross section constituted by connecting a plurality of arcs smoothly, the direction of the bridge axis and the bridge axis can be changed according to the direction and magnitude of the force acting on the pier. The dimension ratio in the direction perpendicular to the axis can be freely set, and the moment generated at the time of placing concrete can be reduced.

[0068] In this example, as a substantially elliptical shape by combining a larger outer panel 2b of the small outer panel 2a curvature radius R ₁ of curvature radius R _2, also the outer panels 2a, 2b
By providing the flange 11 at the position where the curvature changes,
The curvature of the outer panels 2a and 2b alone becomes unitary, and bending of a steel plate by a roll bender or the like becomes easy.

[0069]

The composite column base structure of the present invention has a composite structure together with concrete filled inside by forming an outer panel formed by joining outer panels made of a steel plate or the like in the horizontal and vertical directions. In addition to being excellent in strength, the constituent members have a simple form, which is advantageous in terms of workability and economy.

In the cylindrical outer shell portion, since the vertical joint portion is joined by welding, the tensile strength at the joint portion is secured, and the concrete filled inside may leak or rainwater may enter. There is no.

In the composite column base structure according to the second aspect, the on-site joining of adjacent outer panels in the horizontal direction can be easily performed by bolts.

In the composite column base structure according to the third aspect, when the horizontal connection between adjacent outer panels is performed by full-section penetration welding, a small amount of welding is achieved while securing sufficient dynamic and static strength. By the amount, it is possible to obtain an efficient joint in which welding defects hardly occur.

In the composite column base structure according to the fourth aspect, the cylindrical outer shell and the cylindrical inner shell constitute a double cylindrical shell, and concrete is filled in the double cylindrical shell. The central portion can have a hollow structure, and accordingly, the amount of concrete can be reduced without impairing the bending rigidity as a column base, and the economic efficiency is improved.

In the multi-column composite column-base structure according to claim 5, when applied to a bridge pier or the like supporting a bridge girder,
It is easy to secure strength and rigidity in the direction perpendicular to the bridge axis.

In the method of constructing a composite column base structure according to the present invention, since a cylindrical outer shell is constructed by successively adding unit cylindrical outer shells from the bottom while jacking up, a large crane or the like is used. The joining work can be performed at a fixed position close to the ground without using, and the workability, safety and economy are improved. In addition, it is easy to prepare a work environment such as automation of welding work, curing against wind, etc., and safety equipment such as handrails.

In the construction method of the multi-column composite column base structure according to the eighth and ninth aspects, a plurality of cylindrical outer shells connected by the connecting members can be simultaneously constructed, and the construction period can be greatly reduced.

[Brief description of the drawings]

FIG. 1 shows an embodiment of a composite column base structure according to claims 1 and 2 of the present application, wherein (a) is a horizontal sectional view of the column base portion, and (b) is a perspective view of the entire column base portion. FIG.

FIG. 2 is a perspective view showing an example of a unit cylindrical outer shell used for the column base of FIG. 1;

FIGS. 3A to 3C are perspective views each showing an example of an outer panel used in the present invention.

FIG. 4 is a horizontal cross-sectional view showing a circumferential joint between outer panels according to claim 3 of the present application.

5 (a) and 5 (b) are front views showing a construction procedure in an embodiment of a method of constructing a composite column base structure according to claim 6 of the present application.

FIG. 6 shows an embodiment of a composite column base structure according to claim 4 of the present application, wherein (a) is a horizontal sectional view of a column base portion,
(b) is a perspective view of the entire column base.

FIG. 7 is a horizontal sectional view showing an example of a circumferentially joined portion between an outer panel and an inner panel in the composite column base structure according to claim 4.

FIG. 8 is a perspective view showing an example of a form of an outer panel used in the composite column base structure according to claim 4.

FIG. 9 shows an example of the form of the inner panel used in the composite column base structure according to claim 4, wherein (a) is a front view, (b) is an AA cross-sectional view, and (c) is a view. It is a top view.

10 (a) and 10 (b) are vertical sectional views showing an example of an assembling procedure of a vertical joint between an outer panel and an inner panel in the composite column base structure according to claim 4.

FIG. 11 is a perspective view showing one embodiment of a composite column base structure according to claim 5 of the present application.

12 is a perspective view showing an example of a unit multi-column cylindrical outer shell used for the column base structure of FIG. 11;

FIG. 13 is a plan view showing an example of the shape of a cylindrical outer shell other than a circle according to the present invention.

[Description of Signs] 1 ... cylindrical outer shell, 1a ... unit cylindrical outer shell, 2 ... outer panel, 3
... concrete, 4 ... circumferential joint, 5 ... vertical joint, 6 ... foundation, 10 ... arc-shaped steel plate, 11 ... flange,
12: Bolt hole, 13: Circumferential rib, 14: Vertical rib, 16: Arc-shaped steel plate, 17: Penetration welded part of all cross section, 18: Connecting material, 19: Bolt hole, 21: Cylindrical inner shell, 22 ... Inner panel, 30 ... Corrugated steel plate, 31 ... Flange steel plate, 32 ... Bolt hole, 33 ... Bolt, 34 ... Bolt hole, 40 ... Composite column base, 41 ... Multi-column cylindrical outer shell, 41a ... Unit multi-column cylindrical shape Outer shell, 42: connecting member, 51: jack-up stand, 52: jack, 53: truck

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Yukio Abe 4-5-33 Kitahama, Chuo-ku, Osaka City Within Sumitomo Metal Industries Co., Ltd. Inside the Technical Research Institute (72) Inventor Eiji Omori 2-1, Tsukudo-cho, Shinjuku-ku, Tokyo Kumagaya Gumi Tokyo head office

Claims (9)

[Claims] A plurality of outer panels arranged in a substantially vertical direction are connected to each other in a horizontal direction to form a unit cylindrical outer shell having a closed cross section, and a plurality of the unit cylindrical outer shells are welded and joined in a vertical direction. A composite column base structure characterized by forming a cylindrical shell by filling concrete inside the cylindrical shell. 2. The outer panel has a flange formed on both side ends of a steel plate, and a unit cylindrical outer shell is formed by horizontally connecting flanges of adjacent outer panels by bolts. Item 2. The composite column base structure according to Item 1. 3. The outer panel is formed of a steel plate having a reduced thickness at both side ends, and a unit cylindrical outer shell is formed by welding and joining side ends of adjacent outer panels. A composite column base structure as described. 4. A connecting member protruding in the center direction and continuing in the column axis direction is fixed to an inner surface side of the steel plate constituting the outer panel, and a connecting member of each outer panel is provided between both ends of the steel plate. By arranging and connecting the inner panel formed with a flange, a cylindrical inner shell having a closed cross section is formed inside the cylindrical outer shell, and between the cylindrical outer shell and the cylindrical inner shell. 4. The composite column base structure according to claim 1, wherein the composite column base structure is filled with concrete. 5. A multi-column composite column comprising a plurality of column composite structures according to claim 1, 2, 3 or 4, which are arranged in parallel, and the composite column structure is connected by a connecting member. Leg structure. 6. A method of constructing a composite column base structure according to claim 1, wherein a jack-up base having a jack-up device is fixed at a position where the column base structure is constructed. After the unit cylindrical outer shell located at the top is installed in the jack-up gantry and jack-up substantially by the height of the unit cylindrical outer shell, the unit cylindrical outer shell located at the lower side is sequentially jacked. A process of welding the upper unit cylindrical shell that has already been jacked up to the upper unit cylindrical shell, and connecting the connected unit cylindrical shells to the unit cylindrical shell by the height of the unit cylindrical shell. The step of raising and lowering is repeated the required number of times, and then the unit cylindrical outer shell located at the bottom of the column base structure is connected to the upper unit cylindrical outer shell by welding to form a columnar cylindrical outer shell. Filling the inside of the cylindrical outer shell with concrete. A method of constructing a composite column base structure. 7. The method for constructing a composite column base structure according to claim 4, wherein a jack-up base having a jack-up device is fixed at the column base structure construction position, and the jack-up base is located at the top of the column base structure. After the unit cylindrical outer shell to be installed in the jack-up rack and jack-up by the height of the substantially unit cylindrical outer shell, sequentially, the unit cylindrical outer shell located on the lower side is placed in the jack-up rack. A step of welding and connecting with the upper unit cylindrical shell that has already been jacked up, and a step of further jacking up the plurality of connected unit cylindrical shells by a height substantially equal to the unit cylindrical shell. Is repeated as many times as necessary,
Subsequently, the unit cylindrical outer shell located at the bottom of the column base structure is connected to the upper unit cylindrical outer shell by welding to form a columnar cylindrical outer shell, and inside the cylindrical outer shell. A method of constructing a composite column base structure, comprising: forming a cylindrical inner shell made of the inner panel via the connecting material; and filling concrete between the cylindrical outer shell and the cylindrical inner shell. 8. A plurality of outer panels arranged in a substantially vertical direction are connected to each other in a horizontal direction to form a unit cylindrical outer shell having a closed cross section, and a plurality of said unit cylindrical outer shells are arranged side by side by a connecting member. By forming a unit multi-column cylindrical outer shell by connecting, a jack-up gantry having a jack-up device is fixed at the column-base structure construction position, and a unit multi-column cylindrical outer shell positioned at the top of the column-base structure is formed. After the shell is set in the jack-up frame and jack-up is performed by the height of the substantially unit multi-column cylindrical outer shell, the unit multi-column cylindrical outer shell positioned sequentially below is set in the jack-up frame. Then, the step of welding and connecting the upper unit multi-column cylindrical outer shell that has already been jacked up, and further connecting the connected unit multi-column cylindrical outer shells to the height of the substantially unit multi-column cylindrical outer shell. The process of jacking up is repeated the required number of times, The unit multi-column cylindrical outer shell located at the lowermost part of the structure is connected to the upper unit multi-column cylindrical outer shell by welding to form a multi-column cylindrical outer shell, and the inside of the multi-column cylindrical outer shell is formed. A method of constructing a multi-column composite column base structure, characterized by filling concrete into concrete. 9. A plurality of outer panels arranged in a substantially vertical direction are connected in a horizontal direction to form a unit cylindrical outer shell having a closed cross section, and a plurality of said unit cylindrical outer shells are arranged side by side by a connecting member. By forming a unit multi-column cylindrical outer shell by connecting, a jack-up gantry having a jack-up device is fixed at the column-base structure construction position, and a unit multi-column cylindrical outer shell positioned at the top of the column-base structure is formed. After the shell is installed in the jack-up frame and jack-up is performed by the height of the substantially unit multi-column cylindrical outer shell, the unit multi-column cylindrical outer shell positioned sequentially below is installed in the jack-up frame. Then, the step of welding and connecting the upper unit multi-column cylindrical outer shell that has already been jacked up, and further connecting the connected unit multi-column cylindrical outer shells to the height of the substantially unit multi-column cylindrical outer shell. The process of jacking up is repeated the required number of times, The unit multi-column cylindrical outer shell located at the bottom of the structure is connected to the upper unit multi-column cylindrical outer shell by welding to form a multi-column cylindrical outer shell, and the multi-column cylindrical outer shell is formed. In the forming process, a cylindrical inner shell composed of a plurality of inner panels is formed through a connecting material inside each cylindrical outer shell constituting the multi-column cylindrical outer shell, and each cylindrical outer shell and the cylindrical inner shell are formed. A method for constructing a multi-column composite column base structure, characterized by filling concrete between the columns.