JPH0978731A - Construction method of wall body using construction block bodies - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wall body with large strength which can be arranged and layed easily without requiring reinforcing bars. SOLUTION: A construction block body H consists of two side plates 1 arranged opposite to each other and formed into substantially rectangular, and a connecting member 2 in which a pair of engaging members consisting of an engaging recessed tools 5 and connecting protrusion tools 6 which connect the side plates 1 to each other and mutually engage in the vertical and/or horizontal directions is fixedly arranged. Then the construction block bodies H are joined to each other through the engagement members in the vertical and horizontal directions. In addition, filling concrete is deposited between the side plates opposed to each other.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for constructing a wall such as a wall or a partition wall in a building, and more particularly, to a method for constructing a wall for such a wall, that is, a so-called construction block. The present invention relates to a method for constructing a wall body by joining the walls.

[0002]

2. Description of the Related Art A conventional concrete block for walls and walls has a hollow portion formed vertically through it. The concrete blocks are stacked and the reinforcing bars are inserted into the hollow portion to form a wall or wall. It was to reinforce the body.
However, according to this conventional concrete block wall construction method, it takes a high degree of skill and labor to arrange the reinforcing bars according to the design, and the construction cost increases due to the shortage of skilled workers. Moreover, since the surface of the concrete block is not coated, there is a problem in terms of appearance.

[0003]

DISCLOSURE OF THE INVENTION In view of the above circumstances, the present invention uses a building block which can be easily assembled and obtained a strong wall without requiring a reinforcing bar. An object (technical problem) is to provide a method of constructing a wall.

[0004]

Means for Solving the Problems In order to achieve the above object, a method for constructing a wall using a construction block according to the present invention employs the following constitution (technical means). That is, the first
The second aspect of the present invention is to provide two side plates 1 which are arranged to face each other and which are substantially rectangular and which are connected to each other and which are engaged with each other in the vertical and / or horizontal directions thereof. A building block H composed of a connecting member 2 in which a pair of engaging members composed of a tool 5 and an engaging projection 6 are fixedly attached, and the building block bodies H are joined vertically and laterally with the engaging members. It is made by pouring filling concrete between the side plates 1 facing each other. The second aspect of the present invention is one side plate 1 and the side plate 1.
A pair of engaging members that are engaged with each other and are engaged with each other in the vertical and / or lateral directions, and that are engaged with the side plate 1. The building blocks H, which are composed of a connecting member 2 having a reinforcing plate 7 fixed to the opposite side thereof, are joined to each other with the engaging members in the vertical and lateral directions to form the side plate 1 and the reinforcing plate 7. It is made by placing the filling concrete in between. The third aspect of the present invention is to engage one side plate 1 and a reinforcing plate 7 arranged to face the side plate 1 with engaging recesses 5 and engaging members which engage with each other in the vertical and / or lateral directions. A pair of engaging members composed of the compound protrusions 6 are fixedly provided, and the building block bodies H formed by connecting them with a connecting beam that can be attached to each other, the side plates 1 to each other, and the reinforcing plates 7 to each other. After joining with the engaging members, the connection beams are used to hold the gap, and the filling concrete is placed between the side plate 1 and the reinforcing plate 7. Furthermore, a fourth aspect of the present invention is, in a substantially rectangular side plate 1 having a predetermined thickness, one side plate 1 having an engaging recess for engaging one side of the side plate 1 vertically and / or laterally. The building block H, to which the engaging member composed of the tool 5 and the engaging projection 6 is fixed, is joined together in the vertical and lateral directions with the engaging member to form one mold wall, The other formwork wall is arranged so as to face one formwork wall with an appropriate interval, and the filling concrete is placed between them. (Operation) In the construction of the wall body using this block body, the block bodies are arranged in the vertical direction or the horizontal direction in the same phase state, and the engaging concave tool 5 and the engaging convex tool 6 are arranged. And can be fitted together. Thereafter, the block body is filled with concrete, and thereby the engaging projection is constrained.

[0005]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a method for constructing a wall using a construction block according to the present invention will be described with reference to the drawings. (First Embodiment) FIGS. 1 to 3 show an embodiment (first embodiment) of the present invention, showing a building block body mainly applied to a wall or a wall. That is, FIG. 1 shows the entire block body, and FIGS. 2 and 3 show members used in the block body. This block body H includes two side surface plates 1 arranged to face each other, and a connecting member 2 connecting the side surface plates 1.
And The detailed configuration of each member will be described below. The side plate 1 is made of an appropriate hard material such as concrete, tile, or synthetic resin, has a predetermined wall thickness, and has a rectangular shape. Reference numeral 10 is a surface of the side plate 1, and the surface 10 is subjected to a makeup process. 11 is the back surface. Side plate 1
Stepped portions 12 are formed on the upper and lower side surfaces of the base plate 1 and the side surface plates 1 are engaged with the other side surface plates 1 arranged in the vertical and horizontal directions. On the back surface of the side plate 1, a plurality of vertical grooves, that is, dovetail grooves 13, are vertically provided along the width direction at predetermined intervals. Connecting member 2
Is a flat plate-shaped abdominal plate 3, vertical members fixed to both sides of the abdominal plate 3, that is, dovetail members 4, engagement recesses 5 fixed to the upper part of the abdominal plate 3, and the abdominal plate 3. Engaging projection 6 fixed to the lower part of the
And consisting of More specifically, the abdominal plate 3 has a predetermined rigidity due to a predetermined thickness, and an opening 15 is formed in the center thereof. The width of the abdominal plate 3 determines the distance between the side plates 1. The dovetail member 4 is fitted into the dovetail groove 13 of the side plate 1.
16 is a shelf board. The engaging recess 5 has a base 5a and a crimping portion 5b.
Made of an elastic material. Base 5a
Is fixed to the abdominal plate 3 and the shelf 16 stretched from the abdominal plate 3. The engaging projection comprises a base portion 6a and a wedge portion 6b.
The base 6a is fixed to the abdominal plate 3 and has rigidity. Thus, the side plate 1 and the connecting member 2 are assembled as shown in FIG. That is, the dovetail member 4 of the connecting member 2 is fitted into the dovetail groove 13 of the side surface plate 1. Both are firmly fixed via an adhesive. The side plates 1 are connected to each other by two or more (two in this embodiment) connecting members 2, so that the side plates 1 become independent and maintain required rigidity. FIG. 4 shows a state in which the block bodies H are vertically stacked. That is, each block body H is placed in the same phase state in the vertical direction. When the upper block H is placed on the lower block H, the wedge portion 6b of the engaging projection 6 is The crimping portion 5b of the engaging recess 5 is pushed and expanded and fitted,
Thereafter, the crimping portion 5b of the engaging recess 5 presses against the engaging protrusion 6 by its elasticity. In this state, concrete is inserted into the hollow portion of the block body H (this is called filled concrete).
Is pressed, the crimping portion 5b of the engaging recess 5 is restrained by the filled concrete, thus preventing the engaging protrusion 6 from coming off.

An example of a method of constructing a wall body using the block body H will be described below in accordance with a construction procedure. (1) The foundation concrete B is placed at the planned construction position of the wall body, and the connecting reinforcing bars 17 are embedded along the center line of the wall body so as to project onto the upper surface of the foundation concrete B. In this state, the lower end surface of the side plate 1 is made into a flat fence, and the block body H (which is referred to as a foundation block body) without the engaging projection 6 is constructed such that the connecting rebar 17 is held in the hollow portion of the foundation concrete B. Is placed on the upper surface of the block body, and a plurality of these block bodies H are arranged in the horizontal direction. At this time, since the side surfaces of the block bodies H are the step portions 12, they are fitted into each other and arranged closely. (2) Next, the second-stage block body H is placed on the basic block body H with the same phase. At this time, the positions of the engaging concave tool 5 and the engaging convex tool 6 in the upper and lower block bodies H are on the same vertical line, and therefore, as described above, the engaging convex tool 6 of the upper block body H is in the lower part. It fits in the engaging recess 5 of the block body H. The upper and lower block bodies H are also aligned by the step portion 12. (3) Then, the filling concrete 18 is filled between the block bodies H of the first stage and the second stage. The filling of the filling concrete 18 is performed up to the middle of the upper block body H. When the filling concrete 18 is filled, the crimping portion 5b of the engaging concave tool 5 strongly crimps the wedge portion 6b of the engaging convex tool 6 due to the filling pressure, so that the upper block body H does not fall over and is pulled out. Be blocked. The action is concrete 1
It is further increased with the consolidation of 8. (4) The blocks H are further stacked on the upper stage, and the filling concrete 18 is poured in the same manner as in (3) to construct the wall. In the above process, it is possible to prevent the blocks H from being piled up in the upward direction, to prevent them from collapsing, and to collectively pour the filled concrete 18 thereafter. The wall constructed in this way is filled with concrete 18
By solidifying, the wedge portion 6b of the engaging projection 6 is firmly restrained via the crimping portion 5b of the engaging recess 5 and exerts a great resistance force against falling. This restraint force is exerted not only on the individual block bodies H but also on the entire wall body. Therefore, in the construction of a wall body using this block body, the same strength as that of a conventional concrete block wall body with reinforcing reinforcing bars can be obtained without using reinforcing reinforcing bars, so that it is possible to eliminate the time required to purchase and purchase reinforcing reinforcing bars. It has an advantage that construction efficiency can be improved.

FIG. 5 shows another mode of the connecting member included in the first embodiment. In this connecting member 2A, the abdominal plate 3
The engaging concave tool 5A and the engaging convex tool 6A along the longitudinal direction of the abdominal plate 3 are attached to the upper and lower parts of the. This engaging recess 5A
The crimp portions 5b are provided so as to face each other, and the wedge portions 6b of the engaging projections 6 are elastically inserted between the facing crimp portions 5b. FIG. 6 shows still another mode of the connecting member. In this connecting member 2B, the abdominal plate 3A has flexibility, and flange plates 20 are fixed to both ends of the abdominal plate 3A instead of the dovetail members. More specifically, a flexible plate 21 having a curvature is interposed in the center of the abdominal plate 3A. At the lower end of the flange plate 20, an engagement protrusion 6 that fits into the engagement recess 5 is fixedly provided. This connecting member 2B is used by interposing it in the hollow portion K of a normal lightweight concrete block body J. The flange plate 20 of the connecting member 2B is pressed and fixed to the inner wall of the block body J, and after the block bodies J are assembled with each other, the filling concrete is poured to construct the wall body.

(Second Embodiment) FIGS. 7 and 8 show another embodiment of the construction block body of the present invention. In the drawing, the same reference numerals are given to the same members as those in the previous embodiment. In the block body H1 of this embodiment, the engaging concave tool 5C and the engaging convex tool 6C of the connecting member 2C are the block body H1.
It is characterized in that it is arranged toward the side of. That is, one coupling member 2C has one end of the flange plate 21 fixedly abutted against the abdominal plate 3 along the side plate 1, and the other end of the flange plate 21 has a base portion 5a and a crimp portion 5b. The engaging concave tool 5C consisting of is fixedly mounted via the base portion 5a. Further, a flange plate 22 similar to the engaging recess 5c is fixed to the abdominal plate 3 on the other connecting member 2C ', and the flange plate 22 has a crimping portion of the engaging recess 5C. An engaging protrusion 6C to be fitted into 5b is fixedly provided. The heights of the engaging concave tool 5C and the engaging convex tool 6C may be smaller than the height of the side plate 1, but are normally about 1/2 to 1/3, and at that time, they are arranged at the same position. Of course. Further, it is also possible to adopt a mode in which a plurality of elements are arranged in the vertical direction. Then, when these block bodies H1 are arranged in the lateral direction, the engaging concave tool 5C and the engaging convex tool 6C between the adjacent block bodies H1 are fitted to each other, and thereafter, they are driven into these hollow portions. The engaging portion is restrained by the filled concrete, and an integral wall body is formed. In addition, this aspect is effective for a block body in which the height of the block body H1 is large. FIG. 8 shows another block body H2 included in this embodiment. In this block body H2, a dovetail-shaped protrusion 13A is formed so as to protrude from the wall surface of the side plate 1, and the connecting member 2
A dovetail groove member 4A fitted to the protrusion 13A is fixed to both ends of the abdominal plate 3 at D, and the connecting member 2D is laterally integrated by the intermediate flange plate 23. Further, as shown by the broken line in FIG.
The engaging concave tool 5 and the engaging convex tool 6 may be attached to the upper and lower ends of the upper and lower ends of the block 3 to fix them to the upper and lower block bodies H2. Further, the engaging recess 5 for engaging the flange plates 21 and 22 in FIG.
The same applies to the attachment of the engaging projection 6. In the above embodiments, the engaging recesses 5, 5A, 5B, 5C do not have a restraining action by themselves, but the filling action, that is, the filling concrete, exerts a restraining action.

(Third Embodiment) FIGS. 9 and 10 show still another embodiment of the construction block body of the present invention. The reference numerals in the figure correspond to those in the previous embodiment. This embodiment is mainly applied to retaining walls. FIG. 9 shows the connecting member. In the connecting member 2E, the abdominal plate 3 and the dovetail member 4 are the same as those in the first embodiment, but the engaging concave tool 5E and the engaging convex tool 6E.
The engaging member made of, especially the engaging recess 5E is characterized. In the connecting member 2E, the engaging recess 5E and the engaging protrusion 6E are connected by the flange plate 25. The flange plate 25 is interposed between the abdominal plate 3 and the dovetail member 4, and also functions as an interposing member that fixes both members. Engagement recess 5E
Has a substantially rectangular tubular shape that opens vertically, and the opening area is narrowed downward. That is, the engaging recess 5E is composed of a rear wall 26, a side wall 27, and a front wall 28. The rear wall 26 and the side wall 27 are formed thick, and the rear wall 26 also serves as the flange plate 25, and the side wall 27 is downward. The width gradually decreases to form a trapezoid. The front wall 28 is formed thin and inclines downward toward the rear wall 26. In the opening of the engaging concave tool 5E, its length a is larger than the width d of the engaging convex tool 6E, and the upper width b is sufficiently larger than the maximum thickness e of the engaging convex tool 6E. Has a width c slightly smaller than e. As a result, the front wall 28 has some elasticity. Then, when the engaging projection 6E is fitted into the engaging recess 5E, the engaging projection 6E is moved to the front wall 2 of the engaging recess 5E.
8 is pushed in to enter, and the pulling force resists the pulling force by engaging the uneven surface of the upper surface of the wedge portion 6E of the engaging projection 6E with the lower side of the front wall 28. As a result, the connecting member 2E has pull-out resistance by itself.
Furthermore, when the binding material 30 is filled in the engaging recesses 5E, the pullout resistance further increases (see FIG. 9B). FIG. 9 (c) shows another mode of the engaging recess 5E. The front wall 28 of the engaging recess 5E is not inclined and is thin so that it has flexibility, and when inserting the engaging protrusion 6E, the front wall 28 is expanded by its flexibility. Allows easy insertion. After the engaging projection 6E is inserted, the original state is restored, and the engaging projection 6
Resist the withdrawal of E.

FIG. 10 shows another embodiment of a block to which this connecting member 2E is applied. In FIG. 10 (a), this block H3 has one side plate 1 and a connecting member 2F in which the other side connected to the side plate 1 is a reinforcing plate 7 and a connecting beam 8 is used instead of the abdominal plate. And consists of. More specifically, on the side fitted to the side plate 1, the connecting member 2 </ b> F is composed of the dovetail member 4 and the engagement recesses 5 </ b> E and the engagement protrusions 6 </ b> E which are fixed above and below the dovetail member 4. Become. On the other hand, on the opposite side of the side plate 1, the reinforcing plate 7 includes a horizontal beam 32 and a vertical beam 33.
And a wire mesh (mesh) 35 is fixed between the horizontal beam 32 and the vertical beam 33. The engaging concave tool 5E and the engaging convex tool 6E are fixedly provided inside the reinforcing plate 7A. Connecting beam 8
Although the dovetail member 4 and the reinforcing plate 7 are fixedly connected as an integral member, a bending beam 8A can be used instead of this mode. In the bending type connecting beam 8A, a beam 37 extending from the dovetail member 4 and a beam 38 extending from the reinforcing plate 7 are pin-coupled 40 by an intermediate beam 39. Thus, the angle between the side plate 1 and the reinforcing plate 7 can be freely changed, and the side plate 1 and the reinforcing plate 7 can be handled independently. 10B and 10C show still another mode of the connecting beam. The connecting beam 8B includes a beam 37 extending from the dovetail member 4 and a beam 38 extending from the reinforcing plate 7.
Via the two intermediate beams 41, 42, those beams 37, 3
Pins 45 are provided in pin holes 43 that are provided in a large number in 8, 41, 42.
The length of the connecting beam 8B can be expanded and contracted by inserting. As a result, the distance between the side plate 1 and the flange plate 7A can be made variable, and the angle between them can be made variable, and the side plate 1 and the reinforcing plate 7A can be made variable.
And can be handled independently. In the block body H3 using the connecting beams 8A and 8B, the side plate 1 and the reinforcing plate 7 can be easily assembled on site by simply inserting and removing the pins 40 and 45 via the connecting beams 8A and 8B.

FIG. 11 shows an example of application of the block body H3 to a retaining wall. FIG. 11 (a) shows a retaining wall using a block body H3 having a fixed connection beam. In the figure, E is the ground, and the ground E is dug down to lay the foundation stone 50 and the concrete footing 51 is placed on it. After that, the block bodies H3 are sequentially stacked, and when the number of stages becomes appropriate, the filling concrete 52 is poured. Along with this, the back-filled slabs 53 are filled in the back surface of the retaining wall. Hereinafter, the block bodies H3 are sequentially stacked to construct a retaining wall. In the retaining wall of this aspect, the width W of each block H3 is constant, and the sectional change of the retaining wall is made by placing concrete 52 on the back surface of the reinforcing plate 7 or adjusting the length of the connecting beam 8. . FIG. 11 (b) shows a retaining wall using a block body H3 having a telescopic connecting beam 8B. Also in this retaining wall, the foundation stone 50 and the concrete footing 51 are placed on the ground E, and the block bodies H3 are sequentially stacked thereon. 55 is leveling concrete. In the block body H3 in the lowermost stage, the connecting beam 8B has the maximum length, and the reinforcing plate 7 is inclined so that the width thereof decreases as it goes upward. Next, the block body H3 of the second stage in which the length of the connecting beam 8B is reduced is placed on this, and the engaging concave tool and the convex tool are engaged with each other, and in this state, the filling concrete 52 is poured. It Further, in the block body H3 in the upper stage, the length of the connecting beam 8B is reduced, and similarly, a retaining wall is constructed. Using the block body H3 shown in FIG. 10, the following wall construction method is adopted. That is,
The side plate 1 from which the connecting beams 8A and 8B have been removed and the reinforcing plate 7 are independently assembled with their engaging concave parts 5E and engaging convex parts 6E. 8
A or 8B is assembled with pins 40 and 45, and the space between the side plate 1 and the reinforcing plate 7 is fixed. After that, the concrete is filled with concrete and the wall is constructed. Further, in the embodiment of FIG. 10, one side plate 1 and an engagement recess 5 </ b> E and an engagement protrusion 6 </ b> E fixed above and below the dovetail member 4 that engages with the dovetail groove 13 of the side plate 1. Block body (this is called a side plate block body).
The engagement recesses and the engagement protrusions are also arranged in the lateral direction as appropriate. The side plate blocks are mutually engaged in the vertical and horizontal directions to form a wall (for example, a formwork substitute wall). In this case, the outer surface of the side plate 1 has a decorative finish,
On the inner surface side where the engaging members are arranged, another form material is arranged with an appropriate interval, and the filling concrete is placed between them. 12 and 13 show another aspect included in this third embodiment. The engagement recess 5F shown in FIGS. 12 (a) and 12 (b) is formed by pin engagement. That is, the front wall portion 28A
Has a flange portion 60 along the side wall 27 at both ends thereof, and the side wall 27 and the flange portion 60 are pivotally attached by a pin 61, whereby the front wall portion 28A can rotate about the pin 61. Further, hinge springs 62 are attached to one of the pins 61 by abutting both ends thereof to the rear wall 26 and the front wall portion 28A, whereby the front wall portion 28A is set in a broken line state after the engagement protrusion is inserted. However, when it is inserted, it returns to the normal position. In the connecting member 2G shown in FIG. 13, the dovetail members 4 are fixed to each other via a box-shaped engaging concave tool 5G on the upper side and an engaging convex tool 6G on the lower side.

The present invention is not limited to the above embodiments, but various design changes can be made within the scope of the basic technical idea of the present invention. That is, the following aspects are included in the technical scope of the present invention. The engaging concave member and the engaging convex member may be attached opposite to each other. Instead of the dovetail groove, a T groove or an L groove may be used.

[0013]

According to the present invention, the adjacent block bodies in the vertical or horizontal direction are connected to each other by the engaging concave member and the engaging convex member, and, in combination with the filling concrete, form a strong bond, and the reinforcing bar is unnecessary. Walls can be built.
In other words, it is possible to eliminate the time required to acquire the reinforcing bars and improve the construction efficiency.

[Brief description of drawings]

1 (a) is a plan view of a block body of an embodiment (first embodiment) of a building block used in the present invention, FIG.
1B is a sectional view taken along line I-I of FIG. 1A, and FIG. 1C is a sectional view taken along line II-II of FIG.

FIG. 2 is a perspective view of a side plate used for this block body.

3 (a) is a perspective view of the connecting member plate, FIG. 3 (b) is a side view thereof, FIG. 3 (c) is a plan view thereof, and FIG.
III-III sectional view taken on the line.

FIG. 4 is a diagram showing a stacked state of this block.

FIG. 5 is another aspect view of the connecting member.

FIG. 6 (a) is a further embodiment view of the connecting member, and FIG. 6 (b) is an application example thereof.

FIG. 7 is a plan view of a block body according to another embodiment (second embodiment) of the present invention.

FIG. 8 is an embodiment view of still another block body of the present invention.

9 (a) is a perspective view of a connecting member of yet another embodiment (third embodiment) of the present invention, and FIG. 9 (b) is a detailed view thereof.

10A is a perspective view of a block body to which this connecting member is applied, and FIGS. 10B and 10C are a plan view and a side view showing another embodiment of the connecting beam.

11 (a) and (b) are construction sectional views of a retaining wall using this block.

FIG. 12 (a) is a plan view showing another mode of the engaging recess of the connecting member, and FIG. 12 (b) is a sectional view taken along the line IV-IV.

FIG. 13 (a) is a perspective view showing another embodiment of the connecting member, and FIG. 13 (b) is a sectional view taken along line VV of FIG.

[Explanation of symbols]

H, H1, H2, H3 ... Block body, 1 ... Side plate, 2,
2A, 2B, 2C, 2D, 2E, 2F, 2G ... Connecting member, 3 ... Abdominal plate, 4 ... Dove member, 5, 5A, 5B, 5C,
5D, 5E, 5F, 5G ... engaging recesses, 6, 6A, 6B,
6C, 6D, 6E, 6F, 6G ... Engaging projections, 7 ... Reinforcing plate, 8, 8A, 8B ... Connecting beam

[Procedure amendment]

[Submission date] December 28, 1995

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of Invention] Method of constructing wall using block for construction

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for constructing a wall such as a wall or a partition wall in a building, and more particularly, to a method for constructing a wall for such a wall, that is, a so-called construction block. The present invention relates to a method for constructing a wall body by joining the walls.

[0002]

2. Description of the Related Art A conventional concrete block for walls and walls has a hollow portion formed vertically through it. The concrete blocks are stacked and the reinforcing bars are inserted into the hollow portion to form a wall or wall. It was to reinforce the body.
However, according to this conventional concrete block wall construction method, it takes a high degree of skill and labor to arrange the reinforcing bars according to the design, and the construction cost increases due to the shortage of skilled workers. Moreover, since the surface of the concrete block is not coated, there is a problem in terms of appearance.

[0003]

DISCLOSURE OF THE INVENTION In view of the above circumstances, the present invention uses a building block which can be easily assembled and obtained a strong wall without requiring a reinforcing bar. An object (technical problem) is to provide a method of constructing a wall.

[0004]

Means for Solving the Problems In order to achieve the above object, a method for constructing a wall using a construction block according to the present invention employs the following constitution (technical means). That is, the first
According to a second aspect of the present invention, two side plates that are arranged to face each other and have a substantially rectangular shape, and an engagement recess that connects the side plates to each other and that engages with each other vertically and / or horizontally. A construction block body composed of a connecting member having a pair of engagement members made of engagement projections fixedly fixed thereto is joined with the engagement member, and filling concrete is poured between the side plates facing each other. It is made by setting. A second aspect of the present invention is a pair of engagements, each of which includes one side plate and an engagement recess and an engagement protrusion that engage with the side plate and engage with each other vertically and / or laterally. The construction block body, which comprises a connecting member having a member fixed thereto, and a reinforcing plate fixed to the side opposite to the side engaging with the side plate, is joined with the engaging member, It is made by placing filling concrete between the face plate and the reinforcing plate. A third aspect of the present invention is an engaging recess and an engaging device that engages one side plate and a side plate or a reinforcing plate arranged to face the side plate with each other vertically and / or laterally. A pair of engaging members composed of convex members are fixedly provided, and after connecting the building block bodies, which are connected to each other with connecting beams that can be attached, with the engaging members, the connecting beams are used to maintain a distance. It is made by pouring filling concrete between the side plates or between the side plates and the reinforcing plate. According to a fourth aspect of the present invention, one reinforcing plate and a reinforcing plate arranged to face the side plate are provided with engaging recesses and engaging protrusions that engage with each other vertically and / or laterally. A pair of engaging members are fixedly provided, and the building blocks, which are connected to each other with connecting beams that can be attached, are joined to each other with the engaging members, and then the connecting beams are used to maintain a space between them. It is made by placing filling concrete between the plates. Furthermore, a fifth aspect of the present invention is, in a substantially rectangular side plate having a predetermined thickness, an engaging concave member that engages with one surface of the side plate vertically and / or laterally. The building block bodies in which the engaging members made of the engaging projections are fixed are joined to each other with the engaging members to form one mold wall, and the one mold frame wall faces each other with an appropriate interval. The other formwork walls are placed while holding, and the filling concrete is placed between them. (Operation) In the construction of the wall body using this block body, the block bodies are arranged in the vertical direction or the horizontal direction in the same phase state, and the engaging concave tool and the engaging convex tool are provided. Mated. Thereafter, the block body is filled with concrete, and thereby the engaging projection is constrained.

[0005]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a method for constructing a wall using a construction block according to the present invention will be described with reference to the drawings. (First Embodiment) FIGS. 1 to 8 show one embodiment (first embodiment). First, FIGS. 1 to 3 show a construction block mainly applied to a wall or a wall. That is,
FIG. 1 shows the entire block body, and FIGS. 2 and 3 show members used in the block body. The block body H includes two side plates 1 arranged to face each other and a connecting member 2 connecting the side plates 1. The detailed configuration of each member will be described below. The side plate 1 is made of an appropriate hard material such as concrete, tile, or synthetic resin, has a predetermined wall thickness, and has a rectangular shape. Reference numeral 10 is a surface of the side plate 1, and the surface 10 is subjected to a makeup process. 11 is the back surface. The upper and lower sides of the side plate 1
Step portion 12 engaging with another side plate 1 arranged in the lateral direction
Is formed. On the back surface of the side plate 1, a plurality of vertical grooves, that is, dovetail grooves 13, are vertically provided along the width direction at predetermined intervals. The connecting member 2 includes a flat plate-shaped abdominal plate 3, vertical strip members fixed to both sides of the abdominal plate 3, that is, dovetail members 4, and abdominal plate 3.
The engaging concave tool 5 fixed to the upper part of the above, and the engaging convex tool 6 fixed to the lower part of the abdominal plate 3. More specifically, the abdominal plate 3 has a predetermined rigidity due to a predetermined thickness, and an opening 15 is formed in the center thereof. The width of the abdominal plate 3 determines the distance between the side plates 1. The dovetail member 4 is a dovetail groove 13 of the side plate 1.
Is fitted to. 16 is a shelf board. The engaging recess 5 is the base 5
It is composed of a and the crimping portion 5b, and is entirely made of an elastic material. The base portion 5a is fixed to the abdominal plate 3 and the shelf plate 16 stretched from the abdominal plate 3. The engaging projection comprises a base portion 6a and a wedge portion 6b. The base 6a is fixed to the abdominal plate 3 and has rigidity. Therefore, the side plate 1 and the connecting member 2 are not shown in FIG.
Are assembled as described above to form a unit block body H. That is, the dovetail member 4 of the connecting member 2 is fitted into the dovetail groove 13 of the side surface plate 1. Both are firmly fixed via an adhesive. Two or more side plates 1 (two in this embodiment)
Since they are connected by the connecting member 2 of No. 3, they are self-supporting and maintain a required rigidity. FIG. 4 shows a state in which the block bodies H are vertically stacked. That is, each block body H is placed in the same phase state in the vertical direction, and when the upper block H is placed with respect to the lower block H,
The wedge portion 6b of the engaging projection 6 is pushed into the crimp portion 5b of the engaging recess 5 to be fitted therein, and thereafter, the crimp portion 5b of the engaging recess 5 is crimped to the engaging projection 6 by its elasticity. . In this state, when concrete (this is referred to as filling concrete) is cast in the hollow portion of the block body H, the crimping portion 5b of the engaging recess 5 is restrained by the filling concrete, and therefore,
The engaging projection 6 is prevented from coming out.

An example of a method of constructing a wall body using the block body H will be described below in accordance with a construction procedure. (1) The basic concrete B is placed at the planned construction position of the wall body, and the connecting reinforcing bars 17 are embedded along the center line of the wall body so as to project onto the upper surface of the basic concrete B.
In this state, the lower end surface of the side surface plate 1 is made into a flat fence and the block body H (which is referred to as a basic block body) having no engaging projection 6 is held in the hollow portion so as to hold the connecting rebar 17.
It is placed on the upper surface of the basic concrete B, and a plurality of these block bodies H are arranged side by side in the lateral direction. At this time, since the side surfaces of the block bodies H are the step portions 12, they are fitted into each other and arranged closely. (2) Next, the block body H of the second stage is placed on the basic block body H with the same phase. At this time, the positions of the engaging concave tool 5 and the engaging convex tool 6 in the upper and lower block bodies H are on the same vertical line, and therefore, as described above, the engaging convex tool 6 of the upper block body H is in the lower part. It fits in the engaging recess 5 of the block body H. The upper and lower block bodies H are also aligned by the step portion 12. (3) Then, the block bodies H of the first and second stages
Filled with filling concrete 18 between them. The filling of the filling concrete 18 is performed up to the middle of the upper block body H. When the filling concrete 18 is filled, the crimping portion 5b of the engaging concave tool 5 strongly crimps the wedge portion 6b of the engaging convex tool 6 by the filling pressure, and the upper block body H is formed.
Falling out and withdrawal are prevented. The action is further increased with the solidification of the concrete 18. (4) Further, the block bodies H are stacked on the upper stage, and the filled concrete 18 is poured in the same manner as in (3) to construct the wall body. In the above process, it is possible to prevent the blocks H from being piled up in the upward direction, to prevent them from collapsing, and to collectively pour the filled concrete 18 thereafter. The wall constructed in this way is filled with concrete 1
When 8 is solidified, the wedge portion 6b of the engaging projection 6 is firmly restrained via the crimping portion 5b of the engaging recess 5 and exerts a great resistance against falling. This restraint force is exerted not only on the individual block bodies H but also on the entire wall body. Therefore, in the construction of a wall body using this block body, the same strength as that of a conventional concrete block wall body with reinforcing reinforcing bars can be obtained without using reinforcing reinforcing bars, so that it is possible to eliminate the time required to purchase and purchase reinforcing reinforcing bars. It is possible,
It has the advantage of improving the construction efficiency.

FIG. 5 shows another embodiment of the connecting member included in the block body applied to the first embodiment. In this connecting member 2A, an engaging concave tool 5A and an engaging convex tool 6A along the longitudinal direction of the abdominal plate 3 are attached to the upper and lower parts of the abdominal plate 3. The engagement recesses 5A are provided with the crimp portions 5b facing each other, and the wedge portions 6b of the engagement projections 6 are elastically inserted between the opposing crimp portions 5b. FIG. 6 shows still another mode of the connecting member. In this connecting member 2B, the abdominal plate 3
A has flexibility, and flange plates 20 are fixedly provided at both ends of the abdominal plate 3A instead of dovetail members. More specifically, a flexible plate 21 having a curvature is interposed in the center of the abdominal plate 3A. At the lower end of the flange plate 20, an engagement protrusion 6 that fits into the engagement recess 5 is fixedly provided. This connecting member 2B is used by interposing it in the hollow portion K of a normal lightweight concrete block body J. The flange plate 20 of the connecting member 2B is pressed and fixed to the inner wall of the block body J, and after the block bodies J are assembled with each other, the filling concrete is poured to construct the wall body.

FIGS. 7 and 8 show another embodiment of the building block used in the present invention. In the figure, the same reference numerals are given to members equivalent to those in the previous embodiment. The block body H1 of this embodiment is characterized in that the engaging recess 5C and the engaging convex 6C of the connecting member 2C are arranged toward the side of the block H1. In other words, one end of the flange plate 21 is fixed to one connecting member 2C so as to abut the side plate 1 along the side plate 1, and
At the other end of the flange plate 21, an engagement recess 5C composed of a base 5a and a crimping portion 5b is fixed via the base 5a.
Further, a flange plate 22 similar to the engaging recess 5c is fixed to the abdominal plate 3 on the other connecting member 2C ', and the flange plate 22 has a crimping portion of the engaging recess 5C. An engaging protrusion 6C to be fitted into 5b is fixedly provided. The height of the engagement recesses 5C and the engagement protrusions 6C may be smaller than the height of the side plate 1, but is usually about 1/2 to 1/3.
In that case, it goes without saying that they are arranged at the same position. Also,
It is also possible to adopt a mode of disposing a plurality of pieces in the vertical direction. Thus, when these block bodies H1 are arranged in the horizontal direction, the engaging recess 5C and the engaging convex 6 between the adjacent block bodies H1 are arranged.
C is fitted, and after that, the engaging portion is restrained by the filling concrete poured into these hollow portions, thereby forming an integral wall. In addition, this aspect is effective for a block body in which the height of the block body H1 is large. FIG. 8 shows another block body H2 included in this embodiment. In the block body H2, a dovetail-shaped ridge 13A is formed to protrude from the wall surface of the side plate 1, and a dovetail groove member 4A fitted to the ridge 13A is provided at both ends of the abdominal plate 3 in the connecting member 2D. The connection member 2D is fixed and the intermediate flange plate 23
Are integrated in the horizontal direction. Further, as shown by a broken line in FIG. 8, the engaging recesses 5 and the engaging protrusions 6 can be attached to the upper and lower ends of the flange plate 23 to fix the upper and lower block bodies H2. The same applies to the attachment of the engagement recess 5 and the engagement protrusion 6 to the flange plates 21 and 22 in FIG. 7. In the above embodiment, the engaging recesses 5, 5A, 5B, 5C have no restraining action by themselves, but the filling action, that is, the filling concrete, exerts the restraining action.

(Second Embodiment) FIGS. 9 and 10 show another embodiment (second embodiment) of the present invention. The reference numerals in the figure correspond to those in the previous embodiment. FIG. 9 shows the connecting member. This connecting member 2E is similar to the first embodiment in that the abdominal plate 3 and the dovetail member 4 are the same as those in the first embodiment, but is characterized by an engaging member composed of an engaging concave tool 5E and an engaging convex tool 6E, particularly the engaging concave tool 5E. Have. In this connecting member 2E, the engaging concave tool 5E and the engaging convex tool 6E.
And are connected by a flange plate 25. Flange plate 2
5 is interposed between the abdominal plate 3 and the dovetail member 4, and also functions as an interposing material for fixing both. The engagement recess 5E is substantially a rectangular body that opens vertically, and the opening area is narrowed downward. That is, the engaging recess 5E is composed of a rear wall 26, a side wall 27, and a front wall 28. The rear wall 26 and the side wall 27 are formed thick, and the rear wall 26 also serves as the flange plate 25, and the side wall 27 is downward. The width gradually decreases to form a trapezoid. The front wall 28 is formed thin and inclines downward toward the rear wall 26. At the opening of the engaging concave tool 5E, the length a is larger than the width d of the engaging convex tool 6E, and the upper width b is the maximum thickness e of the engaging convex tool 6E.
The width c of the lower part is made slightly smaller than e. As a result, the front wall 28 has some elasticity. Then, when the engaging projection 6E is fitted into the engaging recess 5E, the engaging projection 6E pushes the front wall 28 of the engaging recess 5E to enter and engages the engaging projection 6E against the pulling force. The concave-convex surface on the upper surface of the wedge portion 6E of the tool 6E and the lower side of the front wall 28 are engaged with each other to resist the pulling force. As a result, the connecting member 2E has pull-out resistance by itself. Furthermore, when the binding material 30 is filled in the engagement recesses 5E, the pullout resistance further increases (see FIG. 9B). FIG. 9C shows another mode of the engaging recess 5E. The front wall 28 of the engaging recess 5E is not inclined and is thin so that it has flexibility, and when inserting the engaging protrusion 6E, the front wall 28 is expanded by its flexibility. Allows easy insertion. After the engagement projection 6E is inserted, the original state is restored and the pull-out of the engagement projection 6E is resisted.

FIG. 10 shows another embodiment of a block to which the connecting member 2E is applied. In FIG. 10 (a), this block body H3 is composed of one side plate 1 and a reinforcing plate 7 on the other side connected to the side plate 1, and a connecting member 2F having a connecting beam 8 in place of the abdominal plate. And consisting of More specifically, on the side fitted to the side plate 1, the connecting member 2 </ b> F is composed of the dovetail member 4 and the engagement recesses 5 </ b> E and the engagement protrusions 6 </ b> E which are fixed above and below the dovetail member 4. Become. On the other hand, on the opposite side of the side plate 1, the reinforcing plate 7 includes a horizontal beam 32 and a vertical beam 33.
And a wire mesh (mesh) 35 is fixed between the horizontal beam 32 and the vertical beam 33. The engaging concave tool 5E and the engaging convex tool 6E are fixedly provided inside the reinforcing plate 7A. Connecting beam 8
Although the dovetail member 4 and the reinforcing plate 7 are fixedly connected as an integral member, a bending beam 8A can be used instead of this mode. In the bending type connecting beam 8A, a beam 37 extending from the dovetail member 4 and a beam 38 extending from the reinforcing plate 7 are pin-coupled 40 by an intermediate beam 39. Thus, the angle between the side plate 1 and the reinforcing plate 7 can be freely changed, and the side plate 1 and the reinforcing plate 7 can be handled independently. 10B and 10C show another mode of the connecting beam. The connecting beam 8B is connected to the dovetail member 4
37 extending from the beam and beam 38 extending from the reinforcing plate 7
And 2 through two intermediate beams 41, 42
The length of the connecting beam 8B can be extended and contracted by inserting a pin 45 into a plurality of pin holes 43 formed in 7, 38, 41 and 42. Thus, the distance between the side plate 1 and the flange plate 7A can be made variable, the angle between them can be made variable, and the side plate 1 and the reinforcing plate 7 can be handled independently. In the block body H3 using the connecting beams 8A and 8B, the side plate 1 and the reinforcing plate 7 can be easily assembled on site by simply inserting and removing the pins 40 and 45 via the connecting beams 8A and 8B.

FIG. 11 shows an example of application of the block body H3 to a retaining wall. FIG. 11A shows a retaining wall using a block body H3 having a fixed connection beam. In the figure, E is the ground, and the ground E is dug down to lay the foundation stone 50 and the concrete footing 51 is placed on it. After that, the block bodies H3 are sequentially stacked, and when the number of stages becomes appropriate, the filling concrete 52 is poured. Along with this, the back-filled slabs 53 are filled in the back surface of the retaining wall. Hereinafter, the block bodies H3 are sequentially stacked to construct a retaining wall. In the retaining wall of this aspect, the width W of each block H3 is constant, and the sectional change of the retaining wall is made by placing concrete 52 on the back surface of the reinforcing plate 7 or adjusting the length of the connecting beam 8. . FIG. 11B shows a retaining wall using a block body H3 having a telescopic connecting beam 8B. Also in this retaining wall, the foundation stone 50 and the concrete footing 51 are placed on the ground E, and the block bodies H3 are sequentially stacked thereon. 55 is leveling concrete. In the block body H3 in the lowermost stage, the connecting beam 8B has the maximum length, and the reinforcing plate 7 is inclined so that the width thereof decreases as it goes upward. Next, the block body H3 of the second stage in which the length of the connecting beam 8B is reduced is placed on this, and the engaging concave tool and the convex tool are engaged with each other, and in this state, the filling concrete 52 is poured. It Further, in the block body H3 in the upper stage, the length of the connecting beam 8B is reduced, and similarly, a retaining wall is constructed. Using the block body H3 shown in FIG. 10, the following wall construction method is adopted. That is,
The side plate 1 from which the connecting beams 8A and 8B have been removed and the reinforcing plate 7 are independently assembled with their engaging concave parts 5E and engaging convex parts 6E. 8
A or 8B is assembled with pins 40 and 45, and the space between the side plate 1 and the reinforcing plate 7 is fixed. After that, the concrete is filled with concrete and the wall is constructed. Further, in this aspect, it is possible to adopt a mode in which the distance between the side plates 1 or the reinforcing plates 7 is variable. Further, in the embodiment of FIG. 10, one side plate 1 and an engagement recess 5 </ b> E and an engagement protrusion 6 </ b> E fixed above and below the dovetail member 4 that engages with the dovetail groove 13 of the side plate 1. Block body (this is called a side plate block body). The engagement recesses and the engagement protrusions are also arranged in the lateral direction as appropriate. The side plate blocks are mutually engaged in the vertical and horizontal directions to form a wall (for example, a formwork substitute wall). In this case, the outer surface of the side surface plate 1 is finished with makeup, the inner surface side where the engaging members are arranged is provided with another form material at an appropriate interval, and the filling concrete is placed between them. It is something. 12 and 13 show another embodiment. FIG.
The engagement recess 5F shown in (a) and (b) is a pin engagement.
That is, the front wall portion 28A has a flange portion 60 along the side wall 27 at both ends thereof, and the side wall 27 and the flange portion 60 are pivotally attached by a pin 61, whereby the front wall portion 28A rotates about the pin 61. It will be possible. Further, a hinge spring 62 is provided on one of the pins 61 at both ends thereof to form the rear wall 26 and the front wall portion 28.
A is attached so as to abut the front wall portion 28.
A is in the state of a broken line after the engagement projection is inserted, but it returns to the normal position at the time of insertion. In the connecting member 2G shown in FIG. 13, the dovetail members 4 are fixed to each other via a box-shaped engaging concave tool 5G on the upper side and an engaging convex tool 6G on the lower side.

The present invention is not limited to the above embodiments, but various design changes can be made within the scope of the basic technical idea of the present invention. That is, the following aspects are included in the technical scope of the present invention. The engaging concave member and the engaging convex member may be attached opposite to each other. Instead of the dovetail groove, a T groove or an L groove may be used.

[0013]

According to the present invention, the adjacent block bodies in the vertical or horizontal direction are connected to each other by the engaging concave member and the engaging convex member, and, in combination with the filling concrete, form a strong bond, and the reinforcing bar is unnecessary. Walls can be built.
In other words, it is possible to eliminate the time required to acquire the reinforcing bars and improve the construction efficiency.

[Brief description of drawings]

FIG. 1 (a) is a plan view of a block body according to an embodiment of a building block body used in the present invention, FIG. 1 (b) is a cross-sectional view taken along line II of FIG. 1 (a), FIG. 1C is a sectional view taken along line II-II of FIG.

FIG. 2 is a perspective view of a side plate used for this block body.

FIG. 3 (a) is a perspective view of a connecting member plate,
(B) figure is the side view, (c) figure is the top view, (d)
The figure is the III-III sectional view taken on the line of (b) figure.

FIG. 4 is a diagram showing a stacked state of this block.

FIG. 5 is another aspect view of the connecting member.

FIG. 6 (a) is a view showing still another embodiment of the connecting member,
The figure (b) is the application example figure.

FIG. 7 is a plan view of another embodiment of the block body.

FIG. 8 is a diagram showing another embodiment of the block body.

FIG . 9 (a) is a perspective view of a connecting member of the present invention,
Figures (b) and (c) are detailed views.

10A is a perspective view of a block body to which this connecting member is applied, and FIGS. 10B and 10C are a plan view and a side view showing another embodiment of the connecting beam.

11 (a) and 11 (b) are construction sectional views of a retaining wall using this block.

FIG. 12 (a) is a plan view showing another mode of the engaging recess of the connecting member, and FIG. 12 (b) is its IV-IV.
FIG.

13 (a) is a perspective view showing another embodiment of the connecting member, and FIG. 13 (b) is a sectional view taken along line VV of FIG.

[Explanation of reference numerals] H, H1, H2, H3 ... Block body, 1 ... Side plate, 2,
2A, 2B, 2C, 2D, 2E, 2F, 2G ... Connecting member, 3 ... Abdominal plate, 4 ... Dove member, 5, 5A, 5B, 5C,
5D, 5E, 5F, 5G ... engaging recesses, 6, 6A, 6B,
6C, 6D, 6E, 6F, 6G ... Engaging projections, 7 ... Reinforcing plate, 8, 8A, 8B ... Connecting beam

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI technical display area E04C 1/14 E

Claims (4)

[Claims] 1. A pair of substantially rectangular plates arranged facing each other.
A connection in which one side plate and a pair of engagement members, which connect the side plates to each other, and which vertically and / or laterally engage with each other, are formed by engaging recesses and engaging protrusions that engage with each other. A method of constructing a wall body, which comprises joining building blocks composed of members together in the vertical and lateral directions with the engaging members, and placing a filling concrete between the side plates facing each other. 2. A pair of engaging members comprising one side plate and an engaging concave member and an engaging convex member which are engaged with the side plate and are vertically and / or laterally engaged with each other. And a building block body comprising a connecting member in which a reinforcing plate is fixedly provided on the side opposite to the side engaging with the side plate, is joined vertically and laterally with the engaging member. , A method of constructing a wall body by placing filled concrete between the side plate and the reinforcing plate. 3. A side plate and a reinforcing plate arranged to face the side plate, each of which comprises an engaging concave member and an engaging convex member that engage with each other vertically and / or laterally. After a pair of engaging members are fixedly attached, and the building block bodies that connect them with a connecting beam that can be attached are joined together, the side plates and the reinforcing plates are joined by the engaging members,
A method for constructing a wall body, in which a space is held by the connecting beam, and a filling concrete is placed between the side plate and the reinforcing plate. 4. A substantially rectangular shape 1 having a predetermined thickness.
In a side plate of a sheet, a construction block body in which an engaging member composed of an engaging concave member and an engaging convex member engaging with each other vertically and / or laterally is fixedly provided on one surface of the side plate. , The upper and lower sides and the lateral direction are joined by the engaging member to form one formwork wall, and the other formwork wall is arranged so as to face the one formwork wall and maintain an appropriate interval, and between them. A method of constructing a wall body by placing filled concrete inside.