JP2011220075A - Wall construction method, wall, and face block - Google Patents

Abstract

PROBLEM TO BE SOLVED: To raise the strength of a wall built by masoning blocks while increasing the flexibility in selecting blocks for masonry.SOLUTION: A construction method of a wall 10 constructed by masoning blocks 20 includes: masoning a plurality of blocks 20 on which through holes 26 and U grooves 22 are formed so that grid-like caves 30 are formed by penetration holes 26 and U grooves 22 in combination; and placing mortar that develops higher intensity than that of the blocks 20 after hardening in the grid-like caves 30. This forms a grid-like structure 40.

Description

  The present invention relates to a wall construction method in which blocks are stacked, a wall constructed by the construction method, and a decorative block.

  There is a known method of constructing a seismic wall by placing a grout material between an existing wall and a built-up concrete block and arranging the bars and integrating the existing wall and the concrete block ( For example, see Patent Documents 1 and 2). The concrete block used in this method is a structural material constituting a part of the RC wall.

JP 2004-197328 A JP 2003-49545 A

  By the way, in order to improve the designability of the existing frame such as an existing wall, there may be a case where the surface of the existing frame is finished using a decorative block such as a brick block or a porous block. In such a case, in the method described in the above-mentioned patent document, it is difficult to use a low-strength decorative block instead of the concrete block because the concrete block is a structural material and requires high yield strength.

  In view of the above circumstances, the present invention can expand the degree of freedom of selection of blocks to be stacked, and can also increase the strength of a wall formed by stacking blocks. Wall and decorative block.

  In order to solve the above problems, a wall construction method according to the present invention is a wall construction method in which blocks are stacked, and the plurality of blocks in which at least one of a through hole and a groove is formed, Stacking is performed so that a lattice-like cavity is formed by combining at least one of the through hole and the groove, and a grout material that exhibits higher strength than the block after curing is placed in the lattice-like cavity. To do.

  In the wall construction method, the wall may decorate and reinforce the existing housing. In the wall construction method, the existing housing may be an outer wall. In the wall construction method, at least one of the upper and lower ends and the left and right ends of the wall may be fixed to the existing housing.

  In the wall construction method, the blocks may be stacked so that the lattice-like cavities formed by intersecting cavities extending vertically and horizontally are formed. In the wall construction method, the blocks may be stacked so that the lattice-like cavities formed by intersecting cavities extending in an oblique direction are formed.

Moreover, in order to solve the said subject, the wall which concerns on this invention is a wall constructed | assembled by the said construction method of the wall.
Furthermore, in order to solve the above-described problem, a decorative block according to the present invention is a decorative block that is stacked to form a wall, and has at least one of a through-hole and a groove that are combined to form a lattice-shaped cavity. Is formed.

  According to the above-described wall construction method, the wall constructed by this method, and the decorative block, the blocks to be assembled can be freely selected, and the strength of the walls constructed by constructing the blocks can be increased.

It is the front view (A) and side sectional view (B) which show the wall constructed | assembled by the construction method of the wall which concerns on this embodiment. It is the front view (A) which shows a block, a side view (B), and a top view (C). It is an enlarged front view which shows a wall. It is an expanded front sectional view which shows the cross section which cut | disconnected the wall in the center part of the thickness direction. It is a sectional side view (5-5 sectional view of Drawing 3) showing a wall. FIG. 6 is a plan sectional view showing a wall (cross-sectional view taken along 6-6 in FIG. 3). It is a front view which shows the wall which concerns on other embodiment. It is a top view which shows the example which constructed | assembled the finishing wall of each plane of the existing polygonal outer wall. It is a top view which shows the example which constructed | assembled the partition wall fixed to the existing pillar.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1: is the front view (A) and side sectional view (B) which show the wall 10 constructed | assembled by the construction method of the wall which concerns on this embodiment. As shown in this figure, the wall 10 is a finishing wall that is externally attached to an existing outer wall 100 constructed of reinforced concrete (hereinafter referred to as RC) and decorates the outer wall 100, and includes a rectangular parallelepiped shaped block 20. Is built. A large number of blocks 20 constituting the wall 10 are stacked in a staggered manner in the height direction so that the horizontal positions of the walls 10 are aligned every other step.

  Here, the block 20 is a decorative block whose strength is lower than that of concrete such as a brick block or a porous block, and in this embodiment, a brick block is used. The porous block is a block in which continuous fine pores are formed, and is generally used for vegetation and heat insulation.

  RC beams 12 and 14 are arranged along the upper and lower ends of the wall 10 at both upper and lower ends of the wall 10. The RC beams 12 and 14 are joined to the outer wall 100, and the upper and lower ends of the wall 10 are fixed to the RC beams 12 and 14. Instead of providing the RC beams 12 and 14, at least a part of the upper, lower, left and right ends of the wall 10 may be fixed to the outer wall 100 with a flat bar, an angle, an anchor, or the like.

  FIG. 2 is a front view (A), a side view (B), and a plan view (C) showing the block 20. As shown in this figure, the block 20 is a rectangular parallelepiped block having a width dimension larger than the height dimension and a thickness dimension smaller than the height dimension. A U-groove 22 extending from one end portion in the longitudinal direction to the other end portion is formed on the upper surface 20U and the lower surface 20L of the block 20. In addition, the shelf part 24 which is a plane is provided in the thickness direction both ends of the upper surface 20U and the lower surface 20L.

  The block 20 is formed with a plurality of (two in this embodiment) through-holes 26 penetrating the block 20 in the height direction, arranged side by side in the lateral width direction when viewed from the front. The through hole 26 is a round hole. In the present embodiment, the two through holes 26 are arranged symmetrically with respect to the center line in the horizontal width direction when viewed from the front.

  FIG. 3 is an enlarged front view showing the wall 10, and FIG. 4 is an enlarged front sectional view showing a cross section obtained by cutting the wall at a central portion in the thickness direction. 5 is a side cross-sectional view (cross-sectional view taken along line 5-5 in FIG. 3) showing the wall 10, and FIG. 6 is a plan cross-sectional view showing the wall 10 (cross-sectional view taken along line 6-6 in FIG. 3). As shown in these drawings, the blocks 20 are stacked at a narrow interval, and the joint material 28 is filled between the adjacent blocks 20, and the adjacent blocks 20 are joined by the joint material 28. ing. Here, the joint material 28 is filled between the side surface 20S of the block 20 facing left and right and the shelf 24 of the block 20 facing the top and bottom, and the side surface 20S facing left and right is joined by the joint material 28. The shelf parts 24 that are vertically opposed to each other are joined by joint material 28.

  The block 20 is assembled so that the through hole 26 of the upper block 20 and the through hole 26 of the lower block 20 are coaxial. As a result, a cavity 30H extending in the height direction is formed in the wall 10 by combining the through holes 26 extending in the height direction so as to be continuous in the height direction. Further, the blocks 20 are assembled so that the U groove 22 of the upper block 20 and the U groove 22 of the lower block 20 are vertically symmetrical. As a result, a cavity 30 </ b> W extending in the lateral width direction is formed in the wall 10.

  Here, the cavity 30H extending in the height direction intersects with the cavity 30W extending in the lateral width direction. As a result, a lattice-like cavity 30 including a cavity 30 </ b> H and a cavity 30 </ b> W is formed in the wall 10. The cavity 30 is filled with mortar as a grout material. Thus, a lattice-like structure 40 is formed in the wall 10 by intersecting the mortar column 40P having a circular cross section and the mortar beam 40B having a circular cross section.

  By the way, the block 20 is a brick and does not have a proof stress to function as a structural material. On the other hand, the structure 40 is formed of mortar having a compressive strength and tensile strength larger than those of bricks and having a yield strength that functions as a structural material.

  Column bars are arranged at the joint between the upper end portion of the column 40P and the RC beam 12, and the upper end portion of the column 40P is fixed to the RC beam 12. In addition, column bars are also arranged at the joint between the lower end portion of the column 40P and the RC beam 14, and the lower end portion of the column 40P is fixed to the RC beam 14.

  One end side of a plurality of anchors 102 is embedded in the outer wall 100, and the plurality of anchors 102 protrude from the outer wall 100 to the wall 10 side. Each anchor 102 is arranged corresponding to a portion of the structure 40 where the column 40P and the beam 40B intersect, and the other end side of each anchor 102 is embedded in the intersecting portion of the structure 40. Thereby, the wall 10 is fixed to the outer wall 100. In addition, the anchor 102 should just be provided in order to prevent the wall 10 from falling down, and providing a large number is not essential.

  Further, the wall 10 is constructed with a space between the wall 10 and the outer wall 100, and a grout material 104 is filled between the wall 10 and the outer wall 100. The grout material 104 is mortar or the like, but it is not necessary to use a material having the strength like the mortar used for forming the structure 40. In addition, you may provide the heat insulation effect by providing an air layer between the wall 10 and the outer wall 100, without filling grout material. Further, a heat insulating material may be sandwiched between the wall 10 and the outer wall 100.

Next, the construction method of the wall 10 will be described.
First, the step of assembling the blocks 20 to a predetermined height lower than the total height of the wall 10 is performed so that the lattice-like cavities 30 are formed. In this step, the stacking is performed with a space between the outer wall 100 and the outer wall 100. In addition, by joining joints 28 between the side surfaces 20S of the blocks 20 adjacent to the left and right and between the shelves 24 of the blocks 20 adjacent to the upper and lower sides, the stacked blocks 20 are joined. To do. Further, the other end side of the anchor 102 is set at the intersection of the cavity 30H and the cavity 30W in the cavity 30. Further, a column bar for fixing to the RC beam 14 is arranged at the lower end of the cavity 30H.

  Next, a step of placing mortar in a lattice-like cavity 30 formed in the wall 10 is performed. In this step, mortar that exhibits high strength as described above after curing is poured into the cavity 30U from the through hole 26 on the upper surface 20U of the uppermost block 20, and from the lowermost through hole 26 to the uppermost through hole 26. Fill. Here, since the mortar at the time of construction has high fluidity, the mortar flows into the U-groove 24 when filled in the through-holes 26 of each stage. At this time, the mortar that has flowed into the U groove 24 is blocked by the joint material 28, thereby filling the cavities 30 </ b> W of each stage.

  Here, since the column bars for fixing with the RC beam 14 are arranged at the lower end portion of the cavity 30H, when the mortar filled in the cavity 30H is cured, the lower end portion of the beam 40P becomes the RC beam 14. To be established.

  Next, a step of filling the gap between the wall 10 and the outer wall 100 with a grout material is performed. In this step, a grout material having a low strength after curing as compared with the mortar filled in the cavity 30 is poured into the gap between the wall 10 and the outer wall 100 from above.

  The above steps are repeated for each predetermined height described above. Finally, a column for fixing with the RC beam 12 is arranged at the upper end of the cavity 30H, so that the upper end of the column 40P is attached to the RC beam 12. Let it settle. As described above, the wall 10 is constructed in which the upper and lower ends are fixed to the RC beams 12 and 14, and the lattice-shaped mortar structure 40 is stretched over the entire area.

  In the wall 10 constructed by such a method, the design of the outer wall 100 is improved by the new wall 10 constructed by stacking the blocks 20 that are brick blocks being the finishing wall of the existing outer wall 100. it can. Further, the lattice-shaped mortar structure 40 having both upper and lower ends fixed to the outer wall 100 is stretched over the entire area of the wall 10, whereby the compressive strength and tensile strength of the outer wall 100 can be reinforced, The seismic performance of the outer wall 100 can be improved.

  Here, since the lattice-like structure 40 is formed of a grout material having a strength higher than that of the block 20, it is possible to effectively improve the performance of the structure 40 as a structure material bearing a compressive load or a tensile load. Therefore, the proof stress required for the block 20 can be reduced. Accordingly, the degree of freedom in selecting the block 20 can be expanded, and the compressive strength and tensile strength of the wall 10 and the joint strength of the block 20 can be increased.

  In the present embodiment, since the lattice-like structure 40 is formed using a mortar having a strength higher than that of the block 20, in the wall 10, only the structure 40 is used as the structure material, and the block 20 is used as the structure material. It is possible to make a cosmetic block with low performance. Thereby, while making the block 20 into the porous block in which a brick or vegetation is possible, while improving the designability and heat insulation of the wall 10, the compressive strength of the wall 10, tensile strength, and the joint strength of the block 20 are securable. .

  In addition, since the porous block has high water absorption, when the block 20 is a porous block, the block 20 absorbs moisture of the grout material by performing water repellent treatment such as coating the block 20 with an epoxy resin. It is desirable to suppress this.

  Further, in the present embodiment, a lattice-like cavity 30 is stretched around the assembled block 20, and the lattice-like structure 40 can be formed by pouring mortar into the cavity 30. That is, since the mortar can be placed using the block 20 as a mold, a dedicated mold for placing the mortar can be dispensed with, and work man-hours and costs can be reduced.

  In the present embodiment, the bonding strength between the stacked blocks 20 is reinforced by the lattice-like structure 40 made of mortar. Therefore, peeling of the block 20 can be suppressed.

In addition, the structure 40 may be arranged if necessary for strength, and when a mortar having high strength (for example, compressive strength of 180 N / mm ² or more and tensile strength of 11.0 N / mm ² or more) is used. For example, when the proof strength required only by the strength of the grout material can be secured, the bar arrangement work may be omitted.

  FIG. 7 is a front view showing a wall 110 according to another embodiment. As shown in this figure, in the wall 110, the design features are added by the blocks 20 being stacked in a state where the blocks 20 are inclined by 45 ° with respect to the horizontal direction.

  Here, since the block 20 is inclined 45 ° with respect to the horizontal direction, the through hole 26 is inclined 45 ° with respect to the vertical direction, and the U-groove 22 is inclined 45 ° with respect to the horizontal direction. As a result, a cavity 130B extending in an oblique direction and a cavity 130B ′ extending in an oblique direction perpendicular to the cavity 130B are formed in the wall 10 by combining the through holes 26 so as to continue in the oblique direction. Has been. Accordingly, in the wall 110, a lattice-shaped cavity 130 composed of the cavity 130B and the cavity 130B ′ is formed.

  The cavity 130 is filled with mortar as a grout material. Accordingly, a lattice-like structure 140 is formed in the wall 110 by intersecting the mortar brace 140B having a circular cross section and the mortar brace 140B ′ having a circular cross section.

  Here, since the X-shaped structure 140 is formed in the wall portion 110, the same effect as that of the above embodiment can be obtained, and the structure 140 functions as a brace. The compressive strength of 110 can be further increased. Therefore, the seismic performance of the outer wall 100 can be further improved.

  In this embodiment, in order to maximize the compressive strength of the structure 140, the blocks 20 are assembled while being inclined by 45 ° with respect to the horizontal direction. However, an inclination angle of 45 ° is not essential.

  FIG. 8 is a plan view showing an example in which the wall 10 is constructed as a finishing wall of each plane 101A of the existing polygonal outer wall 101. FIG. As shown in this figure, a corner 101C of a polygonal (for example, rectangular as shown) outer wall 101 is bent along the corner 101C (for example, bent into an L shape as shown), A support member 212 such as RC is installed. The upper and lower end portions of the support member 212 are fixed to the corner portion 101C.

  Here, the wall 10 is constructed between the adjacent support members 212, and both left and right ends thereof are fixed to the support member 212. As a result, a plurality of walls 10 constructed to face each plane 101 </ b> A of the polygonal outer wall 101 are supported by the outer wall 101.

  In addition, when constructing the wall 10 as a finished wall of a circular and endless outer wall, the walls 10 are formed by arranging the blocks 10 in an endless cylindrical shape by arranging the blocks 20 while tilting each one slightly. It can be supported by the wall 10 itself. This eliminates the need for fixing columns and beams.

  FIG. 9 is a plan view showing an example in which the wall 10 is constructed as a partition wall fixed to an existing column 310. As shown in this figure, the wall 10 is constructed along a plurality of existing pillars 310 arranged in a line.

  L-shaped support members 312 are fixed to the pillars 310 at both ends, and the wall 10 is fixed to the pillars 310 by the anchors 102, and the left and right ends are fixed to the left and right support members 312. Thereby, the wall 10 constructed along the plurality of pillars 310 arranged in a line is supported by the pillars 310 on both the left and right sides.

  In the above embodiment, the U groove 22 and the through hole 26 are formed in the block 20. However, only one of the U groove 22 and the through hole 26 may be formed in the block 20. Moreover, in the said embodiment, although the groove | channel was formed in the U-shape and the through-hole was formed circularly, the shape of a groove | channel and a through-hole is not restricted to these. Moreover, in the said embodiment, although the two through-holes 26 were formed in the block 20, the number of the through-holes 26 may be one or three, and should just set it suitably. Furthermore, in the above-described embodiment, no reinforcing bar is provided in the groove 22 and the through hole 26, but the wall 10 may be reinforced by arranging a reinforcing bar in the groove 22 and the through hole 26.

10 walls, 12, 14 RC beams, 20 blocks, 20U upper surface, 20L lower surface, 20S side surface, 22 U groove (groove), 24 shelves, 26 through-hole, 28 joint material, 30, 30H, 30W cavity, 40 structure , 40P pillar, 40B beam, 100, 101 outer wall, 101A plane, 101C corner, 102 anchor, 104 anchor, 110 wall, 130, 130B, 130B ′ cavity, 140 structure, 140B, 140B ′ bracing, 212, 312 Support member, 310 pillar

Claims (8)

A method of building a wall made up of blocks,
A plurality of the blocks in which at least one of a through hole and a groove is formed are stacked so that a lattice-like cavity is formed by combining at least one of the through hole and the groove, and is higher than the block. A wall construction method in which a grout material that develops strength after hardening is placed in the lattice-like cavity.   The wall construction method according to claim 1, wherein the wall decorates and reinforces an existing casing.   The wall construction method according to claim 2, wherein the existing frame is an outer wall.   The wall construction method according to claim 2 or 3, wherein at least one of the upper and lower ends and the left and right ends of the wall is fixed to the existing casing.   The method for constructing a wall according to any one of claims 1 to 4, wherein the blocks are stacked so that the lattice-like cavities formed by intersecting cavities extending vertically and horizontally are formed.   The wall construction method according to any one of claims 1 to 4, wherein the blocks are stacked so that the lattice-like cavities formed by intersecting cavities extending in an oblique direction are formed.   A wall constructed by the method according to any one of claims 1 to 6. A makeup block that is built up to form a wall,
A decorative block in which at least one of a through hole and a groove which are combined to form a lattice-like cavity is formed.

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