JP7240284B2 - Connection structure of steel structure and precast concrete member, structural wall having the connection structure, and connection method of steel structure and precast concrete member - Google Patents

Description

The present invention provides a structural wall using a steel structure buried in the ground with a portion protruding above the ground (hereinafter referred to as "steel structure wall"), and precast concrete installed on the upper part of the steel structure wall. It relates to a connection structure with a member.

Steel sheet piles and steel pipe sheet piles are mainly used as steel structure walls buried in the ground. Regarding steel sheet piles in particular, hat-shaped steel sheet piles, which are superior to conventional U-shaped steel sheet piles in workability, structural reliability, and economic efficiency, have been developed and are now widely used. A type of steel structure wall using steel pipe sheet piles with excellent rigidity has also been developed. Such a steel structure wall is used not only by being buried in the ground, but also by being used with its upper part protruding above the ground as disclosed in Patent Document 1.

JP 2013-049981 A

However, since the structural wall disclosed in Patent Document 1 is made of steel, corrosion progresses over time, spoiling the landscape. In particular, when using the structural wall of Patent Document 1 in harbors, oceans, etc., it will be used in an environment where it is in contact with seawater, which is prone to corrosion. At the time of construction, anti-corrosion treatment to coat the surface of the steel material with resin etc. is required. Construction of the steel structure wall itself enables efficient work and is excellent in terms of construction period, but performing the anticorrosion treatment as described above is a disadvantage in terms of construction period.

Therefore, it is conceivable to build a structural wall using a hybrid structure in which a steel structure is installed in the underground part and precast concrete members that do not require anticorrosion treatment are installed on the steel structure in the aboveground part. When adopting such a structure, the method of connecting the underground steel structure and the above-ground precast concrete member is important. This poses a problem in terms of construction efficiency.

The present invention has been made in view of the above-mentioned circumstances, and provides a connection structure and its connection that are excellent in fixing property of precast concrete members installed on the underground steel structure and are excellent in construction efficiency. It is an object of the present invention to provide a method and a structural wall utilizing the connecting structure.

The present invention for solving the above problems is a connection structure in which a steel structure and a precast concrete member are connected, wherein the steel structure is buried in the ground with a part protruding above the ground, and the precast The concrete member has an opening downward, a steel frame member protruding from the precast concrete member is arranged in the opening, and a protruding portion, which is a portion of the steel structure protruding above the ground, extends from the precast concrete member. When the precast concrete member is installed so as to be inserted into the opening, the steel frame member and the protrusion are arranged to face each other, and the void in the opening of the precast concrete member is filled with mortar or concrete. It is characterized by being

In this connection structure, a fixing member may be attached to the lower end of the steel frame member to prevent the precast concrete member from slipping upward. Further, a restraining member may be provided in which a rod-shaped member is inserted so as to penetrate the precast concrete member and the steel structure, restrains the reinforcing bars inside the precast concrete member, and the rod-shaped member penetrates. In this case, the restraint member may have a flange portion, and the reinforcing bars inside the precast concrete member may pass through the flange portion.

Another aspect of the present invention is a structural wall, characterized in that these connection structures are arranged continuously.

In this structural wall, the steel structure may be composed of a plurality of steel sheet piles connected to each other via joints. Further, the steel structure may be composed of a plurality of steel pipe sheet piles connected to each other via joints. Further, the steel structure and the precast concrete member may be arranged so that the position of the width direction end surface of the precast concrete member and the position of the joint portion of the steel structure do not overlap.

According to still another aspect of the present invention, there is provided a connection method for connecting a steel structure and a precast concrete member, wherein the precast concrete member has an opening downward, and the opening protrudes from the precast concrete member. A protruding portion, which is a portion of the steel structure buried in the ground in which a steel frame member is arranged and protrudes above the ground, is inserted into the opening of the precast concrete member. a step of arranging the steel frame member and the protrusion so as to face each other when the precast concrete member is installed, and filling a gap in the opening of the precast concrete member with mortar or concrete. It is characterized by having a step of solidifying with.

ADVANTAGE OF THE INVENTION According to this invention, the steel structure of an underground part and the precast-concrete member of an above-ground part can be firmly connected with excellent work efficiency.

It is a front view showing a schematic structure of a structure wall concerning a 1st embodiment of the present invention. FIG. 2 is a cross-sectional view taken along line AA in FIG. 1; It is the figure which expanded the connection part of the steel structure and precast concrete member which concern on the 1st Embodiment of this invention. 3 is a cross-sectional view taken along line CC in FIG. 2; FIG. FIG. 5 is a front view showing a schematic configuration of a structural wall according to a second embodiment of the present invention; FIG. 6 is a cross-sectional view taken along the line AA in FIG. 5; It is the figure which expanded the connection part of the steel structure which concerns on the 2nd Embodiment of this invention, and a precast concrete member. FIG. 4 is a partial cross-sectional view of a structural wall according to a second embodiment of the present invention, and is a diagram for explaining through-holes in a steel structure and a precast concrete member; FIG. 7 is a cross-sectional view taken along the line BB in FIG. 6; 7 is a cross-sectional view taken along line CC in FIG. 6; FIG. It is the figure which expanded the connection part of the steel structure which concerns on the 3rd Embodiment of this invention, and a precast concrete member. FIG. 3 is a diagram showing a schematic configuration of a structural wall according to a third embodiment of the present invention, and is a diagram corresponding to the CC cross section in FIG. 2; It is the figure which expanded the connection part of the steel structure which concerns on the 4th Embodiment of this invention, and a precast concrete member. FIG. 4 is a diagram showing a schematic configuration of a structural wall according to a fourth embodiment of the present invention, and is a diagram corresponding to the CC cross section in FIG. 2; It is a front view which shows schematic structure of the structure wall which concerns on the 5th Embodiment of this invention. FIG. 10 is a view showing a schematic configuration of a structural wall according to a fifth embodiment of the present invention, and is a view corresponding to the CC cross section in FIG. 2; It is a figure which shows an example of the installation method of the precast concrete member which concerns on the 6th Embodiment of this invention. It is a figure which shows an example of the installation method of the precast concrete member which concerns on the 6th Embodiment of this invention. It is a figure which shows an example of the installation method of the precast concrete member which concerns on the 6th Embodiment of this invention. It is a figure which shows an example of the installation method of the precast concrete member which concerns on the 6th Embodiment of this invention. It is a figure which shows the example of a shape of a precast concrete member. FIG. 4 is an enlarged view of a connecting portion between a steel structure and a precast concrete member according to an embodiment of the present invention, omitting a rod-shaped member; FIG. 3 is a diagram showing a schematic configuration of a structural wall according to an embodiment of the present invention with rod-shaped members omitted, and is a diagram corresponding to the CC cross section in FIG. 2; FIG. 4 is an enlarged view of a connecting portion between a steel structure and a precast concrete member according to an embodiment of the present invention, omitting a rod-shaped member; FIG. 3 is a diagram showing a schematic configuration of a structural wall according to an embodiment of the present invention with rod-shaped members omitted, and is a diagram corresponding to the CC cross section in FIG. 2; It is a figure which shows the example of a shape of a steel-frame member. It is a figure which shows the example of a shape of a steel-frame member. It is a figure which shows the example of a shape of a steel-frame member.

The present invention is a connection structure and connection method between a steel structure installed underground as a foundation and a precast concrete member installed above ground. Also, the present invention is a structural wall comprising a steel structure and a precast concrete member having the connecting structure. Applications for this structural wall include, for example, earthworks, seawalls, breakwaters or piers.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the present specification and drawings, elements having substantially the same functional configuration are denoted by the same reference numerals, thereby omitting redundant description.

<First Embodiment>
In the first embodiment, a steel sheet pile is used as the steel structure forming the foundation of the structural wall. As shown in FIG. 1, the structural wall 1 includes a plurality of steel sheet piles 20 continuously installed in a row along the extension direction L (normal direction) of the structural wall 1, and It is composed of a plurality of precast concrete members 50 installed in succession. The precast concrete member 50 in this embodiment has a width of two steel sheet piles 20 . The width direction of the precast concrete member 50 and the steel sheet pile 20 is the same direction as the extension direction L of the structural wall 1 .

As shown in FIGS. 2 and 3, the steel sheet pile 20 is buried in the ground, but part of it protrudes above the ground. The lower end of the precast concrete member 50 is provided with an opening 51 capable of accommodating the portion of the steel sheet pile 20 that protrudes above the ground (hereinafter, “protrusion 21”). The opening 51 is formed so as to penetrate the precast concrete member 50 in the extension direction L (FIG. 1), and as shown in FIG. It has a shape divided into an end portion 52 and a second end portion 53 .

The precast concrete member 50 is placed on top of the steel sheet pile 20 with the protrusion 21 of the steel sheet pile 20 positioned between the first end 52 and the second end 53 . That is, in a side view of the structural wall 1, the projection 21 of the steel sheet pile 20 is inserted into the opening 51 of the precast concrete member 50, and the first end 52 of the precast concrete member 50 and the second The end portion 53 is installed so as to straddle the projecting portion 21 of the steel sheet pile 20 .

At the opening 51 of the precast concrete member 50 , a steel frame member 55 projecting downward from the inside of the precast concrete member 50 toward the opening 51 is arranged. In the illustrated embodiment, the steel frame member 55 is composed of two steel plates arranged parallel to each other with a predetermined interval. The upper half of the steel frame member 55 is embedded inside the precast concrete member 50 , and the lower half of the steel frame member 55 protrudes downward within the opening 51 . However, the lower end of the steel frame member 55 is set at a position that is the same as or slightly higher than the lower ends of the precast concrete member 50 (the lower ends of the first end portion 52 and the second end portion 53). Further, a fixing member 56 may be attached to the lower end of the steel frame member 55 composed of these two steel plates so as to connect the lower ends of the steel plates to each other. By installing the precast concrete member 50 so that the projecting portion 21 of the steel sheet pile 20 is inserted into the opening 51 of the precast concrete member 50, the steel frame member 55 and the projecting portion 21 are arranged to face each other. state.

The space in the opening 51 of the precast concrete member 50 is filled with mortar or concrete a (hereinafter referred to as “mortar or the like a”). That is, in a state in which the precast concrete member 50 is installed so that the projecting portion 21 of the steel sheet pile 20 is inserted into the opening portion 51 of the precast concrete member 50, the steel plates in the steel frame member 55 composed of two steel plates are separated from each other. , the gap formed between the steel frame member 55 and the projecting portion 21, and the gap formed between the inner surface of the opening 51 and the steel frame member 55 and the projecting portion 21 are all filled with mortar or the like a. is in a state of

As shown in FIG. 4, the steel sheet piles 20 are connected to each other via joints 23. In the structural wall 1 of this embodiment, the position of the width direction end surface 50a of the precast concrete member 50 is the position of the steel sheet pile 20. A precast concrete member 50 is installed at a position different from the position of the joint portion 23 of . That is, the joint portion (width direction end face 50a) of the precast concrete members 50 adjacent in the extension direction L of the structural wall 1 and the joint portion (joint portion 23) of the steel sheet pile 20 adjacent to each other are at different positions. Wall 1 is built. Although it is not essential to arrange the precast concrete members 50 in this manner, by preventing the joints of the precast concrete members 50 and the joints of the steel sheet piles 20 from overlapping each other, the joints may be displaced in the event of an earthquake or the like. can be mutually suppressed by the steel sheet pile 20 and the precast concrete member 50 .

The structural wall 1 of the first embodiment is constructed as described above. Next, a method for connecting the steel sheet pile 20 and the precast concrete member 50 will be described.

(First step)
First, a plurality of steel sheet piles 20 are buried in the ground as the foundation of the structural wall 1. At this time, the steel sheet piles 20 are installed so that a part (protruding part 21) protrudes above the ground. Keep Then, a precast concrete member 50 manufactured in advance at a factory is installed on top of the steel sheet pile 20 . Here, the opening 51 formed at the lower end of the precast concrete member 50 is aligned with the projecting portion 21 of the steel sheet pile 20, and the precast concrete member 50 is covered with the projecting portion 21 of the steel sheet pile 20. The member 50 is suspended on the ground surface. Thereby, the precast concrete member 50 is installed in such a state that the protrusion 21 of the steel sheet pile 20 is inserted into the opening 51 of the precast concrete member 50 . Further, inside the opening 51 , the steel frame member 55 protruding from the precast concrete member 50 is placed facing the projecting portion 21 of the steel sheet pile 20 .

In this embodiment, the precast concrete members 50 are installed such that one precast concrete member 50 is placed on three steel sheet piles 20 . When the structural wall 1 is used as a seawall or a breakwater, when installing the precast concrete member 50 on the seabed, a temporary cofferdam is performed around the steel structure, and the work is performed after the completion of drainage.

(Second step)
Next, the voids in the openings 51 of the precast concrete member 50 are filled with mortar or the like a through a mortar injection hole (not shown) provided in the precast concrete member 50 . Then, the steel sheet pile 20 and the precast concrete member 50 are connected by solidifying the filled mortar or the like. At this time, in the present embodiment, the projecting portion 21 of the steel sheet pile 20 is positioned between the first end portion 52 and the second end portion 53 of the precast concrete member 50, and the steel sheet pile 20 and the precast concrete member 50 are in a state of being superimposed on each other, they are firmly connected. In particular, when the structural wall 1 is used near the coast such as a seawall, it receives a large rotational moment from the sea side toward the land side when a tsunami occurs. It is useful to overlap and connect

By connecting the steel sheet pile 20 and the precast concrete member 50 by the above method, the projecting portion 21 of the steel sheet pile 20 is covered with the precast concrete member 50 . Therefore, since the projecting portion 21 of the steel sheet pile 20 does not appear in the structural wall 1 having this connection structure, anti-corrosion treatment of the steel sheet pile 20 can be omitted during construction. This makes it possible to shorten the construction period.

Further, inside the opening 51, the steel frame member 55 and the projecting portion 21 are arranged facing each other in parallel. and the gap formed between the inner surface of the opening 51 and the steel frame member 55 and the projecting portion 21 are all filled with solidified mortar or the like a. Therefore, the rotational moment received by the precast concrete member 50 is effectively transmitted to the steel sheet pile 20, making it possible to strongly receive the external force acting on the precast concrete member 50 when a tsunami or the like occurs. Further, when a fixing member 56 is attached to the lower end of the steel frame member 55, the precast concrete member 50 is firmly fixed by the solidified mortar or the like a in the opening 51, and the precast concrete member 50 can be pulled out upward. prevented.

According to the connection structure of this embodiment, it is possible to increase the rigidity of the structural wall 1 . In addition, in the present embodiment, each precast concrete member 50 is arranged so that one precast concrete member 50 is connected to a plurality of steel sheet piles 20, so that the rigidity of the structural wall 1 can be further improved. .

Furthermore, in this embodiment, since the joints of the adjacent precast concrete members 50 and the joints of the adjacent steel sheet piles 20 are connected so as not to overlap each other, the joints of the steel sheet piles 20 when an earthquake occurs, etc. Displacement and dislocation of joints of the precast concrete member 50 can be suppressed.

<Second embodiment>
Also in the second embodiment, a steel sheet pile is used as a steel structure forming the foundation of the structural wall. In this second embodiment, an example in which the lower end portion (first end portion 52 and second end portion 53) of the precast concrete member 50 and the upper portion (protruding portion 21) of the steel sheet pile 20 are connected by the bar-shaped member 2 is described. showing.

Similar to the first embodiment, as shown in FIG. , a plurality of precast concrete members 50 continuously installed on top of the steel sheet piles 20. The width direction of the precast concrete member 50 and the steel sheet pile 20 is the same direction as the extension direction L of the structural wall 1 .

As shown in FIGS. 6 and 7, the steel sheet pile 20 is buried in the ground, but part of it protrudes above the ground. The lower end of the precast concrete member 50 is provided with an opening 51 capable of accommodating the portion of the steel sheet pile 20 that protrudes above the ground (hereinafter, “protrusion 21”). The opening 51 is formed so as to penetrate the precast concrete member 50 in the extension direction L (FIG. 5), and as shown in FIG. It has a shape divided into an end portion 52 and a second end portion 53 .

The precast concrete member 50 is placed on top of the steel sheet pile 20 with the protrusion 21 of the steel sheet pile 20 positioned between the first end 52 and the second end 53 . That is, in a side view of the structural wall 1, the projection 21 of the steel sheet pile 20 is inserted into the opening 51 of the precast concrete member 50, and the first end 52 of the precast concrete member 50 and the second The end portion 53 is installed so as to straddle the projecting portion 21 of the steel sheet pile 20 .

At the opening 51 of the precast concrete member 50 , a steel frame member 55 projecting downward from the inside of the precast concrete member 50 toward the opening 51 is arranged. The upper half of the steel frame member 55 is embedded inside the precast concrete member 50 , and the lower half of the steel frame member 55 protrudes downward within the opening 51 . However, the lower end of the steel frame member 55 is set at a position that is the same as or slightly higher than the lower ends of the precast concrete member 50 (the lower ends of the first end portion 52 and the second end portion 53). In addition, a fixing member 56 is attached to the lower end of the steel frame member 55 composed of these two steel plates so as to connect the lower ends of the steel plates to each other. By installing the precast concrete member 50 so that the projecting portion 21 of the steel sheet pile 20 is inserted into the opening 51 of the precast concrete member 50, the steel frame member 55 and the projecting portion 21 are arranged to face each other. state.

The space in the opening 51 of the precast concrete member 50 is filled with mortar or the like a. That is, in a state in which the precast concrete member 50 is installed so that the projecting portion 21 of the steel sheet pile 20 is inserted into the opening portion 51 of the precast concrete member 50, the steel plates in the steel frame member 55 composed of two steel plates are separated from each other. , the gap formed between the steel frame member 55 and the projecting portion 21, and the gap formed between the inner surface of the opening 51 and the steel frame member 55 and the projecting portion 21 are all filled with mortar or the like a. is in a state of

FIG. 8 is a partial cross-sectional view of the structural wall 1. At the lower end of the precast concrete member 50 (the lower end of the first end 52 and the second end 53), there is a hole extending through the structural wall 1 in the thickness direction t. A through hole 60 is formed. A plurality of through holes 60 are provided along the width direction of the precast concrete member 50 , and four through holes 60 are formed at different heights at the lower end of one precast concrete member 50 . A through hole 22 is also formed in the upper portion (protruding portion 21 ) of the steel sheet pile 20 so as to pass through the structural wall 1 in the thickness direction t. The positions of the through holes 60 formed in the lower end portion of the precast concrete member 50 and the positions of the through holes 22 formed in the upper portion of the steel sheet pile 20 are aligned with each other.

As shown in FIG. 7 , at the joint between the steel sheet pile 20 and the precast concrete member 50 , the rod-shaped member 2 is inserted through the through hole 22 of the steel sheet pile 20 and the through hole 60 of the precast concrete member 50 . The material of the rod-shaped member 2 is not particularly limited as long as it has a high strength, and may be resin or metal. etc. is preferably used.

In this embodiment, a steel bolt is used as the rod-shaped member 2, and the inserted steel bolt is tightened with a nut so that tension is applied to the rod-shaped member 2 in the longitudinal direction. It is possible to connect the steel sheet pile 20 and the precast concrete member 50 even if the rod-shaped member 2 is not tensioned. and the connection of the precast concrete member 50 can be made stronger.

Reinforcement reinforcing bars are embedded inside the precast concrete member 50. As an example, as shown in FIG. , main reinforcing bars 62 are arranged in the vertical direction. Note that other reinforcing bars embedded inside the precast concrete member 50 include, for example, distribution reinforcing bars (not shown). In addition, in the structural wall 1 of the present embodiment, the restraining members 3, which are belt-shaped members (for example, steel), are provided inside the first end portion 52 and the second end portion 53 of the precast concrete member 50, respectively. there is The restraining member 3 is provided outside the main reinforcing bars 62 inside the precast concrete member 50 . In other words, the main reinforcing bars 62 of the precast concrete member 50 are located between the restraining member 3 and the opening 51 . Further, a fixing plate 63 may be provided at the tip of the main reinforcing bar 62 to improve the adhesion between the concrete and the reinforcing bar as in the present embodiment. The fixing plate 63 may be another member such as a nut.

As shown in FIGS. 9 and 10 , the restraining member 3 is embedded inside the precast concrete member 50 with its longitudinal direction facing the width direction of the precast concrete member 50 . The restraining member 3 of the present embodiment has a length slightly shorter than the width of the precast concrete member 50, and a single restraining member 3 is long enough to cover the four through holes 60 in the width direction of the precast concrete member 50. It is A through-hole is formed in the restraining member 3 in the same manner as the through-hole 60 of the precast concrete member 50 , and the rod-like member 2 is inserted through the through-hole of the restraining member 3 as well. By providing the restraining member 3 as in the present embodiment, the plurality of bar members 2 are connected via the restraining member 3, thereby making the connection between the steel sheet pile 20 and the precast concrete member 50 stronger. be able to. In addition, since the restraint member 3 is provided outside the main reinforcing bars 62 of the precast concrete member 50, deformation of the main reinforcing bars 62 when a load is applied to the precast concrete member 50 can be suppressed. .

Further, as shown in FIG. 10, the steel sheet piles 20 are connected to each other through the joint portions 23, but the positions of the width direction end surfaces 50a of the precast concrete members 50 are different from the positions of the joint portions 23 of the steel sheet piles 20. The precast concrete member 50 is installed so that it becomes. That is, the joint portion (width direction end face 50a) of the precast concrete members 50 adjacent in the extension direction L of the structural wall 1 and the joint portion (joint portion 23) of the steel sheet pile 20 adjacent to each other are at different positions. Wall 1 is built. Although it is not essential to arrange the precast concrete members 50 in this manner, by preventing the joints of the precast concrete members 50 and the joints of the steel sheet piles 20 from overlapping each other, the joints may be displaced in the event of an earthquake or the like. can be mutually suppressed by the steel sheet pile 20 and the precast concrete member 50 .

As shown in FIG. 7, a concave portion 57 having a shape hollowed out from the outer surface of the precast concrete member 50 in the thickness direction t is provided at the position where the rod-shaped member 2 of the precast concrete member 50 is inserted. The recess 57 is pre-formed when the precast concrete member 50 is manufactured. The concave portion 57 is filled with mortar so that the inserted rod-shaped member 2 does not appear in the external appearance.

The structural wall 1 of the second embodiment is constructed as described above. Next, a method for connecting the steel sheet pile 20 and the precast concrete member 50 according to the second embodiment will be described.

(First step)
First, a plurality of steel sheet piles 20 are buried in the ground as the foundation of the structural wall 1. At this time, the steel sheet piles 20 are installed so that a part (protruding part 21) protrudes above the ground. Keep Then, a precast concrete member 50 manufactured in advance at a factory is installed on top of the steel sheet pile 20 . Here, the opening 51 formed at the lower end of the precast concrete member 50 is aligned with the projecting portion 21 of the steel sheet pile 20, and the precast concrete member 50 is covered with the projecting portion 21 of the steel sheet pile 20. The member 50 is suspended on the ground surface. Thereby, the precast concrete member 50 is installed in such a state that the protrusion 21 of the steel sheet pile 20 is inserted into the opening 51 of the precast concrete member 50 . Further, inside the opening 51 , the steel frame member 55 protruding from the precast concrete member 50 is placed facing the projecting portion 21 of the steel sheet pile 20 .

Also in this embodiment, the precast concrete members 50 are installed such that one precast concrete member 50 is placed on three steel sheet piles 20 . When the structural wall 1 is used as a seawall or a breakwater, when installing the precast concrete member 50 on the seabed, a temporary cofferdam is performed around the steel structure, and the work is performed after the completion of drainage.

(Second step)
Subsequently, the bar member 2 is inserted so as to pass through the through hole 60 (FIG. 8) of the precast concrete member 50 and the through hole 22 (FIG. 8) of the steel sheet pile 20, respectively. In this embodiment, a steel bolt is inserted as the rod-shaped member 2, and tension is applied to the rod-shaped member 2 in the longitudinal direction by tightening the nut. Thereby, the steel sheet pile 20 and the precast concrete member 50 can be connected more firmly. The through hole 60 of the precast concrete member 50 may be formed in advance when the precast concrete member 50 is manufactured, or may be formed by processing after the precast concrete member 50 is manufactured.

(Third step)
After that, mortar or the like a is filled into the opening 51 of the precast concrete member 50 through a mortar injection hole (not shown) provided in the precast concrete member 50 . Then, the steel sheet pile 20 and the precast concrete member 50 are connected by solidifying the filled mortar or the like. At this time, in the present embodiment, the projecting portion 21 of the steel sheet pile 20 is positioned between the first end portion 52 and the second end portion 53 of the precast concrete member 50, and the steel sheet pile 20 and the precast concrete member 50 are in a state of being superimposed on each other, they are firmly connected. In particular, when the structural wall 1 is used near the coast such as a seawall, it receives a large rotational moment from the sea side toward the land side when a tsunami occurs. It is useful to overlap and connect

By connecting the steel sheet pile 20 and the precast concrete member 50 by the above method, the projecting portion 21 of the steel sheet pile 20 is covered with the precast concrete member 50 . Therefore, since the projecting portion 21 of the steel sheet pile 20 does not appear in the structural wall 1 having this connection structure, anti-corrosion treatment of the steel sheet pile 20 can be omitted during construction. This makes it possible to shorten the construction period.

Further, inside the opening 51, the steel frame member 55 and the projecting portion 21 are arranged facing each other in parallel. and the gap formed between the inner surface of the opening 51 and the steel frame member 55 and the projecting portion 21 are all filled with solidified mortar or the like a. Therefore, the rotational moment received by the precast concrete member 50 is effectively transmitted to the steel sheet pile 20, making it possible to strongly receive the external force acting on the precast concrete member 50 when a tsunami or the like occurs. In addition, since the fixing member 56 is attached to the lower end of the steel frame member 55, the precast concrete member 50 is firmly fixed by the solidified mortar or the like a in the opening 51, and the precast concrete member 50 is prevented from slipping upward. be done.

In addition, in the connection structure of this embodiment, since the rod-shaped member 2 is inserted between the steel sheet pile 20 and the precast concrete member 50, the pull-out resistance or Pushing resistance can be generated. That is, according to the connection structure of this embodiment, it is possible to increase the rigidity of the structural wall 1 . Also in this embodiment, each precast concrete member 50 is arranged so that one precast concrete member 50 is connected to a plurality of steel sheet piles 20, so the rigidity of the structural wall 1 can be further improved. .

In addition, since the restraining member 3 through which the plurality of rod-shaped members 2 pass is provided outside the main reinforcing bar 62 of the precast concrete member 50, deformation of the main reinforcing bar 62 when a load is applied to the precast concrete member 50 is prevented. can also be suppressed.

Furthermore, in the present embodiment as well, since the joints of the adjacent precast concrete members 50 and the joints of the adjacent steel sheet piles 20 are connected so as not to overlap each other, the joints of the steel sheet piles 20 may be damaged when an earthquake or the like occurs. Displacement and dislocation of joints of the precast concrete member 50 can be suppressed.

<Third Embodiment>
In the third embodiment, the shape of the restraining member 3 is different from that in the first embodiment. As shown in FIG. 11, flange portions 3a projecting inward of the precast concrete member 50, that is, toward the opening portion 51, are formed at the upper end portion and the lower end portion of the restraining member 3 of the third embodiment. As shown in FIG. 12 , through holes 3 b are formed in the flange portion 3 a of the restraining member 3 at intervals along the longitudinal direction of the restraining member 3 . A main reinforcing bar 62 of the precast concrete member 50 passes through each through hole 3b.

Although the restraining member 3 and the main reinforcing bars 62 are not essential in the present invention, in the structural wall 1 of the third embodiment, the main reinforcing bars 62 pass through the flange portion 3a of the restraining member 3, thereby providing a restraining force. Adhesion between concrete and reinforcing bars can be enhanced through the member 3 . In addition, the binding force of the plurality of main reinforcing bars 62 can be increased, and the effect of suppressing deformation of the main reinforcing bars 62 when a load is applied to the precast concrete member 50 can be enhanced. That is, in the structural wall 1 of the third embodiment, the bar member 2, the restraining member 3, and the main reinforcing bar 62 are connected to each other, and the synergistic effect of the combination of the three produces the strength of the steel structure and the precast concrete member. The connection can be made even stronger. The number and positions of the flange portions 3a provided on the restraining member 3 are not particularly limited. For example, the flange portion 3a may be provided at either one of the upper end portion or the lower end portion of the restraining member 3, or the flange portion 3a may be provided at the center portion of the restraining member 3 as long as it does not interfere with the rod-shaped member 2. can be

<Fourth Embodiment>
As shown in FIG. 13, the upper end and the lower end of the restraining member 3 of the fourth embodiment are formed with flange portions 3a protruding outward from the precast concrete member 50, i.e., on the side opposite to the opening 51. there is As shown in FIG. 14 , through holes 3 b are formed in the flange portion 3 a of the restraining member 3 at intervals along the longitudinal direction of the restraining member 3 . A main reinforcing bar 62 of the precast concrete member 50 passes through each through hole 3b. As shown in the fourth embodiment, by passing the main reinforcing bars 62 through the flange portion 3a projecting outward from the restraining member 3, the position of the restraining member can be further adjusted as compared with the second and third embodiments. It can be set inside, that is, at a position close to the opening 51, and the thickness of the first end and the second end can be reduced. As a result, the thickness of the entire precast concrete member 50 can also be reduced, so that it is possible to expect advantages in terms of economy and construction due to weight reduction. The binding force of the main reinforcing bars 62 is also not greatly reduced compared to the second and third embodiments by passing the main reinforcing bars 62 through the through holes 3b of the flange portion 3a.

<Fifth Embodiment>
A steel pipe sheet pile 30 is used as a steel structure in the fifth embodiment. As shown in FIGS. 15 and 16, a plurality of steel pipe sheet piles 30 are arranged along the extension direction L of the structural wall 1, and each steel pipe sheet pile 30 is connected via joints 31 as shown in FIG. . In the fifth embodiment, three steel pipe sheet piles 30 are connected to one precast concrete member 50 . Further, the precast concrete members 50 are arranged so that the width direction end surfaces 50 a do not overlap the positions of the joint portions 31 of the steel pipe sheet piles 30 . This makes it possible to suppress the occurrence of displacement of the joints of the adjacent precast concrete members 50 .

In addition, in the fifth embodiment, by inserting the steel frame member 55 protruding downward toward the opening 51 from the inside of the precast concrete member 50 into the steel pipe sheet pile 30, the upper portion of the steel pipe sheet pile 30 (protrusion (corresponding to the part) and the steel frame members 55 are arranged to face each other.

Even when the steel pipe sheet pile 30 is used as the steel structure as in the fifth embodiment, the precast concrete member 50 is installed so as to straddle the portion of the steel pipe sheet pile 30 that protrudes above the ground. The steel structure (steel pipe sheet pile 30) and the precast concrete member 50 can be firmly connected when constructing the structural wall 1 in the same manner as in the embodiment. In addition, inside the opening 51, the steel frame member 55 and the upper part of the steel pipe sheet pile 30 are arranged facing each other in parallel. The gap formed between the upper part of the sheet pile 30 and the gap formed between the inner surface of the opening 51 and the steel frame member 55 and the upper part of the steel pipe sheet pile 30 are all filled with solidified mortar or the like a. It has become. Therefore, the rotational moment received by the precast concrete member 50 is effectively transmitted to the steel pipe sheet pile 30, making it possible to strongly receive the external force acting on the precast concrete member 50 when a tsunami or the like occurs.

<Sixth Embodiment>
In the above-described first to fifth embodiments, the method for connecting the steel structure and the precast concrete member 50 was described on the premise that the precast concrete member 50 was lowered to the ground surface, but in the sixth embodiment, the precast concrete An example of lowering the precast concrete member 50 onto a receiving surface provided on a steel structure when installing the member 50 will be described.

For example, as shown in FIG. 17, a flat base concrete member 5 may be provided in the vicinity of the ground surface of a steel pipe sheet pile 30 as a steel structure, and a precast concrete member 50 may be lowered onto this base concrete member 5. At this time, it is preferable to provide a spacer 6 having a predetermined height on the upper surface of the foundation concrete member 5 . When installing steel structures, the installation heights of adjacent steel structures may differ, but by appropriately providing spacers 6 with different heights, the installation heights of the precast concrete members 50 can be made uniform. can be done. Thereby, the scenery as the structural wall 1 can be improved. A packing 7 is provided between the basic concrete member 5 and the precast concrete member 50 to prevent leakage of the mortar or the like to be filled in the opening 51 later.

In the example shown in FIG. 17 above, the gap adjusting mechanism provided between the precast concrete member 50 and the receiving surface of the steel structure in contact with the bottom surface of the precast concrete member 50 includes a plurality of spacers 6 having different heights. is used, the gap adjusting mechanism is not limited to using the spacer 6 . For example, as shown in FIG. 18, a height adjusting bolt 8 may be provided at the lower end of the precast concrete member 50. As shown in FIG. In the example shown in FIG. 18 , the installation height of the precast concrete member 50 can be adjusted by adjusting the height of the bolt 8 projecting from the lower end surface of the precast concrete member 50 .

Also, when installing the precast concrete member 50 at a position away from the ground surface, a bracket 9 may be attached to the steel structure as shown in FIG. In the example shown in FIG. 19, the bottom formwork 10 extending in the width direction of the precast concrete member 50 is installed on the upper surface of the bracket 9, and the installation height of the precast concrete member 50 is adjusted by the spacer 6 as in the example shown in FIG. do. Regarding the bracket 9 after the precast concrete member 50 is installed, the ground surface of the installation location of the structural wall 1 may be buried with soil so that it is level with the surrounding ground surface, or it may be removed by gas cutting. can be Also, as shown in FIG. 20, a height adjusting bolt 8 may be provided as the gap adjusting mechanism in the same manner as in the example shown in FIG.

17 to 20 show an example of using the steel pipe sheet pile 30 as the steel structure, the same form can be adopted in the case of using the steel sheet pile 20 as the steel structure.

Although the embodiments of the present invention have been described above, the present invention is not limited to such examples. It is obvious that a person skilled in the art can conceive various modifications or modifications within the scope of the technical idea described in the claims, and these are also within the technical scope of the present invention. be understood to belong to

For example, the shape and installation position of the steel structure are not limited to those described in the above embodiments. Similarly, the shape of the precast concrete member 50 is not limited to those described in the previous embodiments. For example, as shown in FIG. 21, a shape having a low height may be used. In other words, the shape of the precast concrete member 50 is appropriately changed according to the use of the structural wall 1 . Further, the shape of the opening 51 of the precast concrete member 50 is appropriately changed depending on the shape of the steel structure to be used, the installation position, and the like.

Also, as in the embodiment shown in FIGS. 22 and 23, the rod-shaped member 2 may be omitted. 22 and 23, the steel frame member 55 and the projecting portion 21, which is the upper portion of the steel sheet pile 20, are arranged parallel to each other inside the opening 51 even without the rod-shaped member 2. As a result, the rotational moment received by the precast concrete member 50 is effectively transmitted to the steel sheet pile 20, making it possible to firmly receive the external force acting on the precast concrete member 50 when a tsunami or the like occurs. As shown in FIGS. 22 and 23, even if there is no bar-shaped member 2, main reinforcing bars 62 are arranged vertically inside the precast concrete member 50 as reinforcing reinforcing bars. preferable.

Similarly, when the steel pipe sheet pile 30 is used as the steel structure as in the embodiment shown in FIGS. 24 and 25, the bar member 2 may be omitted. 24 and 25, the steel frame member 55 and the upper portion (corresponding to the projecting portion) of the steel pipe sheet pile 30 are arranged parallel to each other inside the opening 51 so as to form a precast concrete member. The rotational moment received by 50 is effectively transmitted to steel pipe sheet pile 30, making it possible to firmly receive the external force acting on precast concrete member 50 when a tsunami or the like occurs. When the rod-shaped member 2 is omitted as in the first embodiment and the embodiments shown in FIGS. The step of connecting (the second step described in relation to the second embodiment) can be omitted, improving work efficiency.

Further, in the above-described embodiment, as shown in FIG. 26, an example was shown in which the steel frame member 55 was composed of two steel plates, but as shown in FIG. can be According to the steel frame member 55 with the rib 70 shown in FIG. 27, the precast concrete member 50 is firmly fixed by the solidified mortar or the like a in the opening 51, and the precast concrete member 50 can be pulled out upward more reliably. can be prevented.

Alternatively, as shown in FIG. 28 , two steel plates may be welded and fixed with a U-shaped reinforcing bar 71 as the steel frame member 55 . According to the steel frame member 55 shown in FIG. 28, the distance between the two steel plates can be reliably kept constant, and deformation of the steel frame member 55 can be prevented.

INDUSTRIAL APPLICABILITY The present invention can be used, for example, for earth walls, seawalls, breakwaters or piers.

a Mortar, etc. 1 Structural wall 2 Rod-shaped member 3 Restraint member 3a Flange portion 3b of restraint member Through hole 4 Splicing plate 5 Foundation concrete member 6 Spacer 7 Packing 8 Height adjustment bolt 9 Bracket 10 Bottom formwork 20 Steel Sheet pile 21 Steel structure projecting portion 22 Steel sheet pile through hole 23 Steel sheet pile joint portion 30 Steel pipe sheet pile 31 Steel pipe sheet pile joint portion 50 Precast concrete member 50a Width direction end surface 51 of precast concrete member Opening 52 of precast concrete member Precast First end 53 of concrete member Second end 55 of precast concrete member Steel member 56 Anchoring member 57 Recess 60 of precast concrete member Through hole 62 of precast concrete member Main reinforcing bar 53 Anchoring plate L Structural wall extension direction t Structural wall thickness direction

Claims (9)

A connected structure in which a steel structure and a precast concrete member are connected,
The steel structure is buried in the ground with a part protruding above the ground,
The precast concrete member has an opening downward, and a steel frame member protruding from the precast concrete member is arranged in the opening,
When the precast concrete member is installed, the steel frame member and the protrusion face each other such that the protrusion, which is the portion of the steel structure that protrudes above the ground, is inserted into the opening of the precast concrete member. placed as
A connection structure between a steel structure and a precast concrete member, characterized in that the voids in the opening of the precast concrete member are filled with mortar or concrete. 2. The structure for connecting a steel structure and a precast concrete member according to claim 1, wherein a fixing member is attached to the lower end of the steel frame member to prevent the precast concrete member from slipping upward. . A rod-shaped member is inserted so as to penetrate the precast concrete member and the steel structure,
3. A connection structure between a steel structure and a precast concrete member according to claim 1 or 2, further comprising a restraining member that restrains the reinforcing bars inside the precast concrete member and through which the rod-like member penetrates. The restraining member has a flange,
4. The connection structure between the steel structure and the precast concrete member according to claim 3, wherein the reinforcing bars inside the precast concrete member penetrate the flange portion. Structural wall, characterized in that the connection structure according to any one of claims 1 to 4 is arranged in succession. 6. The structural wall according to claim 5, wherein said steel structure is composed of a plurality of steel sheet piles connected to each other via joints. The structural wall according to claim 5, wherein the steel structure is composed of a plurality of steel pipe sheet piles connected to each other via joints. 7. The steel structure and the precast concrete member are arranged so that the position of the width direction end face of the precast concrete member and the position of the joint portion of the steel structure do not overlap. 8. A structural wall according to any one of clauses 7 to 8. A connection method for connecting a steel structure and a precast concrete member, comprising:
The precast concrete member has an opening downward, and a steel frame member protruding from the precast concrete member is arranged in the opening,
The precast concrete is inserted into the opening of the precast concrete member so that a protruding portion, which is a portion of the steel structure buried in the ground with a portion protruding above the ground, is inserted into the opening of the precast concrete member. a step of arranging the steel frame member and the projecting portion to face each other when the member is installed;
and a step of filling voids in the opening of the precast concrete member with mortar or concrete to solidify the steel structure and the precast concrete member.

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