JP2000008613A - Concrete structure and manufacture thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a concrete structure, in which structure and manufacturing method are simplified while ensuring high strength, and a manufacturing method thereof. SOLUTION: An N-pole magnet 8 and an S-pole magnet 9 are installed at opposed places in the end plates 4 of forms 2, and the lines of magnetic force 10 are generated. Small pieces 13 for magnetic induction consisting of a magnetic substance are mounted into forms 2, and a concrete material 1 placed in forms 2 is composed of high superplasticized concrete filled with fibers 12 for reinforcement made up of the magnetic substance. Since the fibers 12 for reinforcement of the concrete material 1 are collected and oriented along the lines 10 of magnetic force magnetically induced by the small pieces 13, the concrete structure having high strength can be manufactured while controlling the places of the fibers 12 for reinforcement.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a concrete structure formed in a plate shape or an arc shape, such as a floor slab or a segment, and a method of manufacturing the same.

[0002]

2. Description of the Related Art In general, a concrete structure formed in a plate shape or an arc shape, such as a floor slab, a wall, or a segment, is made of a single material such as concrete or steel, or a formwork. There is a steel-concrete composite in which steel is reinforced concrete and then concrete is poured into the steel, or concrete is filled in a steel box-shaped frame.

[0003]

However, in recent years,
As a building in which the floor slabs and segments are used,
Large-scale structures have been constructed, and concrete structures formed by a simplified structure and method while ensuring sufficient strength have been demanded for the purpose of cost reduction and the like.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a concrete structure and a manufacturing method in which the structure and the manufacturing method are simplified while ensuring high strength.

[0005]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the present invention relates to a concrete structure formed in a plate shape, wherein a magnetic material oriented in the concrete along its longitudinal direction is provided. Characterized by being filled with a reinforcing fiber consisting of

According to the present invention, concrete is filled with reinforcing fibers made of a magnetic material, and the reinforcing fibers are oriented in the longitudinal direction. Strength against the generated tensile stress is enhanced.

In the concrete structure as described above, a concrete containing reinforcing fibers made of a magnetic material is poured into a plate-shaped form made of a non-magnetic material, and the longitudinal direction of the form is placed in the concrete. The method is realized by a method for manufacturing a concrete structure, wherein a reinforcing magnetic field in the concrete is oriented by applying a magnetic field along the direction, and the concrete is solidified in the oriented state.

A concrete containing a reinforcing fiber made of a magnetic material is poured into a plate-shaped mold made of a non-magnetic material,
Since the reinforcing fibers are oriented by the magnetic field applied along the longitudinal direction of the form, a concrete structure having high strength against tensile stress in the longitudinal direction can be easily manufactured.

[0009] The magnetic field can be generated by a pair of magnets arranged outside the end plate facing the mold so as to face each other along the longitudinal direction of the mold.

[0010] A pair of magnets are arranged outside the facing end plate of the form on which concrete filled with reinforcing fibers made of a magnetic material is poured so as to face each other along the longitudinal direction. A magnetic field is generated between the pair of magnets in the mold. For this reason, the reinforcing fibers filled in the concrete are accumulated and oriented along the magnetic field lines due to the magnetic field, so that it is possible to easily produce a high-strength concrete structure against tensile stress in the longitudinal direction, Since the process is simplified, a high-strength and low-cost concrete structure can be obtained.

The magnetic field is generated by winding a coil around the entire form along the longitudinal direction of the form from the vicinity of one end plate of the form to the vicinity of the other end plate, and causing a current to flow through the coil. It can also be generated.

[0012] A coil is wound around the mold along the longitudinal direction of the mold from the vicinity of one end plate of the mold to the vicinity of the other end plate, and a current flows through the coil to extend the length of the mold. To generate a magnetic field in the direction to orient the reinforcing fibers,
With a simple structure, a concrete structure having high strength against tensile stress in the longitudinal direction of the form can be manufactured.
Further, since the strength of the magnetic field can be easily changed depending on the magnitude of the current flowing through the coil, such as when the reinforcing fibers having weak magnetic properties are filled, even when the type of the reinforcing fibers to be filled is changed. It can be easily handled.

It is also possible to arrange a plurality of small pieces for magnetic induction made of a magnetic material inside the mold along the longitudinal direction of the mold. By arranging a plurality of small pieces made of a magnetic material along the longitudinal direction, the lines of magnetic force generated by the magnetic field are guided to the small pieces. for that reason,
The lines of magnetic force are concentrated, and the position of the reinforcing fibers that are accumulated and oriented along the lines of magnetic force can be reliably controlled, and the reinforcing fibers can be reliably arranged at desired positions inside the concrete structure. And a high-strength concrete structure can be obtained.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A concrete structure and a method for manufacturing the same according to one embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing one embodiment of a concrete structure and a method for manufacturing the same according to the present invention.

In FIG. 1, a form 2 on which a concrete material 1 is cast is a rectangular plate having an open upper surface, and is made of a nonmagnetic material such as brass. The formwork 2 is composed of a pair of rectangular main girders 3, an end plate 4 connecting both ends of the main girders 3, and a bottom plate 5, and the internal space of the form 2 immediately matches the shape of the concrete structure to be manufactured. An opening 6 for casting the concrete material 1 is formed on the upper surface.

The concrete material 1 is a high-fluidity concrete filled with reinforcing fibers 12 for reinforcing a concrete structure to be manufactured, and is cast into a formwork 2. The reinforcing fibers 12 are made of magnetic fibers such as steel.

An N-pole magnet 8 and an S-pole magnet 9 having substantially the shape of the end plate 4 are provided on the outer surfaces of the two end plates 4 facing each other. The N-pole magnet 8 and the S-pole magnet 9 installed on the end plate 4 are provided inside the mold 2.
As a result, a magnetic field is generated in the longitudinal direction of the mold frame 2, and a magnetic field line 10 is generated from the N-pole magnet 8 to the S-pole magnet 9.

A plurality of small pieces 13 for magnetic induction made of a magnetic material such as an iron piece are arranged inside the formwork 2 along the longitudinal direction so as to be embedded in the concrete material 1. The small piece 13 is larger than the reinforcing fiber 12 and is supported by, for example, a support made of a non-magnetic material provided inside the formwork 2 or an auxiliary reinforcing bar. In addition, if necessary, reinforcing bars are provided along the longitudinal direction.

When a concrete structure is manufactured, the concrete material 1 is introduced through the opening 6 of the formwork 2. At this time, as shown in FIGS. 1 and 2, the reinforcing fibers 12 made of a magnetic material filled in the concrete material 1 are used.
Is the line of magnetic force 1 generated between the N-pole magnet 8 and the S-pole magnet 9.
0 and are oriented along the direction of the magnetic field lines 10.

In this case, as shown in FIG.
Is guided to a small piece 13 made of a magnetic material disposed inside the mold 2. That is, the portion of the small piece 13 facing the N pole magnet 9 is polarized to the S pole, and the portion facing the S pole magnet 9 is polarized to the N pole, and the density of the magnetic force lines 10 increases near the small piece 13. For this reason, the reinforcing fibers 12 are accumulated and oriented along the lines of magnetic force 10 where the density near the small pieces 13 is increased.

As described above, the N-pole magnet 8 and the S-pole magnet 9 are provided on the outside of the end plate 4 facing the form 2 so as to face each other. A magnetic field is generated between the magnetic field and the S-pole magnet 9, and a magnetic field line 10 is generated. Therefore, the reinforcing fibers 12 filled in the concrete material 1
Are integrated and oriented along the lines of magnetic force 10, so that a concrete structure having high strength against tensile stress in the direction along the orientation of the reinforcing fibers 12 can be easily manufactured, and the process is simplified. Therefore, a high-strength and low-cost concrete structure can be obtained.

Further, by disposing a plurality of small pieces 13 for magnetic induction made of a magnetic material inside the mold 2,
0 is guided to the small piece 13, the density of the magnetic force lines 10 near the small piece 13 increases, and the reinforcing fibers 12 are accumulated and oriented along the magnetic force lines 10. Therefore, the position of the reinforcing fibers 12 can be reliably controlled, and, for example, it is possible to accumulate the reinforcing fibers 12 in a portion where tensile stress tends to concentrate.

The desired effect can be obtained even if the mold is formed in an arc plate shape as shown in FIG. In this case, as shown in FIG. 4, it is possible to reliably arrange the reinforcing fibers in a portion where tensile stress tends to concentrate, such as an arc-shaped outer portion of the concrete structure, and to obtain a high-strength concrete structure. Can be.

Further, another manufacturing method as shown in FIG. 5 is also possible. In FIG. 5, a mold 42 formed of a nonmagnetic material such as brass is in the shape of a circular arc plate having an open upper surface, and connects a pair of circular arc-shaped main girders 43 to both ends of the main girders 43. The end plate 44 and the bottom plate 45 are assembled so that the internal space thereof is formed so as to conform to the shape of the concrete structure to be manufactured. An opening 46 is formed. This concrete material 41
It is made of high-fluidity concrete filled with reinforcing fibers made of a magnetic material. In the mold 42, a plurality of small pieces for magnetic induction made of a magnetic material are arranged.

The mold 42 has one end plate 44 of the mold 42.
A coil 50 is entirely wound along the longitudinal direction of the formwork 42 from the vicinity to the vicinity of the other end plate 44. A current is applied to the coil 50 from the symbol A to the symbol B in FIG. 5, and a magnetic field is generated in the mold 42 by the action of the current applied to the coil 50. As shown in the figure, the magnetic force lines 5 along the longitudinal direction of the
1 occurs. The lines of magnetic force 51 are magnetically induced by small pieces made of a magnetic material disposed on the mold 42,
The positions of the reinforcing fibers accumulated and oriented on the magnetic field lines 51 are controlled.

As described above, the coil 50 is entirely wound around the mold 42 along the longitudinal direction, and a current flows through the coil 50 to generate the magnetic field lines 51 in the longitudinal direction of the mold 42. A high-strength concrete structure can be manufactured. Further, since the strength of the magnetic field can be easily changed depending on the magnitude of the current flowing through the coil 50,
It is possible to easily cope with a case where the type of the reinforcing fiber to be filled is changed, such as a case where the reinforcing fiber having a weak magnetic property is filled.

[0027]

The concrete structure and the method of manufacturing the same according to the present invention have the following effects. (1) Concrete is filled with a reinforcing fiber made of a magnetic material, and the concrete is filled in the longitudinal direction. By orienting the reinforcing fibers, the formed concrete structure has enhanced strength against tensile stress generated in the longitudinal direction. (2) A concrete containing a reinforcing fiber made of a magnetic material is poured into a plate-shaped mold made of a non-magnetic material, and the reinforcing fiber is caused to act along the longitudinal direction of the mold. Since it is oriented by the applied magnetic field, it is possible to easily manufacture a concrete structure having high strength against tensile stress for orientation. (3) Since a pair of magnets are arranged on the outside of the facing end plate of the form on which concrete filled with reinforcing fibers made of a magnetic material is poured so as to face each other along the longitudinal direction, A magnetic field is generated between the pair of magnets in the mold. For this reason, the reinforcing fibers filled in the concrete are accumulated and oriented along the magnetic field lines due to the magnetic field, so that it is possible to easily produce a high-strength concrete structure against tensile stress in the longitudinal direction, Since the process is simplified, a high-strength and low-cost concrete structure can be obtained. (4) A coil is wound around the mold along the longitudinal direction of the mold from the vicinity of one end plate of the mold to the vicinity of the other end plate, and a current is applied to the coil to extend the length of the mold. Since a magnetic field is generated in the direction to orient the reinforcing fibers, a concrete structure having a simple structure and high strength against tensile stress in the longitudinal direction of the formwork can be manufactured. Also,
Because the strength of the magnetic field can be easily changed depending on the magnitude of the current flowing through the coil, such as when the reinforcing fibers with weak magnetic properties are filled, even when the type of the reinforcing fibers to be filled is changed easily. Can respond. (5) It is also possible to arrange a plurality of small pieces for magnetic induction made of a magnetic material inside the mold along the longitudinal direction of the mold. By arranging a plurality of small pieces made of a magnetic material along the longitudinal direction, the lines of magnetic force generated by the magnetic field are guided to the small pieces. Therefore, the lines of magnetic force are concentrated, and the position of the reinforcing fibers that are accumulated and oriented along the lines of magnetic force can be reliably controlled, and the reinforcing fibers are reliably disposed at desired positions inside the concrete structure. And a high-strength concrete structure can be obtained.

[Brief description of the drawings]

FIG. 1 is a diagram showing an example of an embodiment of a concrete structure and a method for manufacturing the same according to the present invention.

FIG. 2 is a side view of FIG.

FIG. 3 is a diagram for explaining the function of magnetic induction of a magnetic piece.

FIG. 4 is a diagram illustrating a state in which reinforcing fibers are accumulated at desired positions by magnetic small pieces.

FIG. 5 is a view showing an example of another embodiment of the concrete structure and the method for manufacturing the same according to the present invention.

[Explanation of symbols]

 1, 41 Concrete material 2, 42 Formwork 3, 43 Main girder 4, 44 End plate 5, 45 Bottom plate 6, 46 Opening 8 N pole magnet 9 S pole magnet 10, 51 Line of magnetic force 12 Reinforcing fiber 13 Small piece 50 Coil

Claims (5)

[Claims] 1. A concrete structure formed in a plate shape, wherein concrete is filled with reinforcing fibers made of a magnetic material oriented along the longitudinal direction of the concrete. Structure. 2. A method for manufacturing a concrete structure formed in a plate shape, comprising: placing concrete containing reinforcing fibers made of a magnetic material into a plate-shaped formwork made of a non-magnetic material; Producing a concrete structure, wherein a reinforcing magnetic field in the concrete is oriented by applying a magnetic field along the longitudinal direction of the formwork to the concrete, and the concrete is solidified in the oriented state. Method. 3. The magnetic field is generated by a pair of magnets disposed outside a facing end plate of the mold so as to face each other along a longitudinal direction of the mold. 3. The method for producing a concrete structure according to item 1. 4. The magnetic field causes a coil to be wound around the entire form along a longitudinal direction of the form from near one end plate to near the other end plate of the form and current flows through the coil. The method for producing a concrete structure according to claim 2, wherein the concrete structure is generated. 5. The concrete according to claim 2, wherein a plurality of magnetic guiding pieces made of a magnetic material are arranged inside the form along an arc of the form. The method of manufacturing the structure.