KR101241302B1 - Construction method of ALC block build during winter - Google Patents

Abstract

The present invention allows the end of the computer bolt to be inserted into the hole formed in the concrete column or wall, while at least one row of the fixing rod located in the square groove formed in at least one row on one side of the upper and lower surfaces of the inner wall lightweight foam concrete block. The installation of zinc-plated computer bolts to be in contact with each other and the installation of thin wire mesh between lightweight foamed concrete blocks without the above-mentioned computer bolts provide a stable construction even in winter while supplying AC power to the computer bolts and thin wire meshes. In addition to the above, the heat insulation and strength of the double-walled wall having a space between the semi-circular bent portion and the zinc-plated computer bolt supporting the square groove and the thin wire mesh and the fasteners and the stable support on the column or the wall In the winter construction method of the wall using the lightweight foam concrete block which was reinforced One will.

The present invention described above,

In the narrow lightweight foam concrete block, the process of forming two rectangular grooves in the longitudinal direction on the upper or lower surface of the wide lightweight foamed concrete block while forming one square groove in the longitudinal direction on one surface of the upper surface or the lower surface,

Forming the upper and lower projections by bending the upper and lower portions on the other side of the fixing rod having at least one semicircular bent portion formed on one side in the square groove of the lightweight foam concrete block of the inner wall;

The lightweight foamed concrete block formed with the square grooves is formed by bundling into the inner wall and forming a space while masonrying the lightweight foamed concrete block without the square grooves into the outer wall;

Inner wall first row lightweight foam concrete block is a process of masonry to form a concave-convex coupling by the mortar of the floor while the square groove toward the bottom,

Inner wall second row light weight foam concrete block is a process to ensure stable construction in winter by the thin wire mesh and mortar between the first row light weight foam concrete block while the square groove is located on the upper surface,

The process of assemble the outer wall first row lightweight foam concrete block twice the height of the inner wall to be combined with the mortar of the floor,

The lower and upper projections on the other side of the fasteners in which the semi-circular bent portions are located in the square grooves of the second row of lightweight foamed concrete blocks on the inner wall are respectively the upper surface of the first row of lightweight foam concrete blocks and the lower side of the second row of lightweight foam concrete blocks. The process of strengthening the strength between the inner wall and the outer wall and the strength of the outer wall itself as well as ensuring stable construction in winter by the steel wire mesh and mortar interposed therebetween,

Zinc-plated computerized to pass through the semi-circular bent portion of the fastener located in the square groove of the second row of lightweight foamed concrete blocks while inserting the end of the zinc-plated computer bolt into the holes formed in both concrete columns or walls. Install bolts to fill the square grooves with mortar, and place the third row of lightweight foam concrete blocks on the inner wall where the next square grooves are not formed. Process,

The process of placing the square mesh of the inner wall of the fourth row of lightweight foamed concrete blocks on the flat top surface of the inner wall of the third row of lightweight foam concrete blocks so that the square grooves of the inner wall of the fourth row of lightweight foamed concrete blocks are positioned upwards to ensure stable construction in winter. and,

Applying mortar to the flat upper surface of the outer row first-rate light-weight foam concrete blocks and placing the thin wire mesh between them, the inner wall and outer wall are arranged side by side by repeating the process of stably installing the outer row second row light-weight foam concrete blocks in winter. It is characterized by the configuration to masonry.

Lightweight foam concrete block, inner wall, outer wall, square groove, clamp, bolt, wire mesh

Description

Winter construction method of wall using lightweight foam concrete block {Construction method of ALC block build during winter}

The present invention relates to a winter construction method of the wall using a lightweight foam concrete block, and in detail, one side of the upper and lower surfaces of the inner wall lightweight foam concrete block while inserting the end of the computer bolt into the hole formed in the concrete column or wall By installing a bolt plated with zinc to contact one semi-circular bent portion of the clamp located in the square groove formed in at least one row at the same time, a thin wire mesh is installed between the lightweight foam concrete blocks in which the bolt is not installed. While supplying AC power to the bolts and thin wire meshes, it is possible to ensure stable construction even in winter, as well as zinc plated bolts for supporting the semi-circular bent portions and square grooves and thin wire meshes and fasteners and columns or walls. Thermal insulation of double walls with space between them by stable support In winter the wall with a light weight cellular concrete block strength is such that the reinforcing relates to a construction method.

Recently, lightweight foam concrete blocks, which are installed on the outer and inner walls of various buildings, are about one quarter lighter in weight than concrete blocks of the same size, are excellent in light weight, excellent in fire resistance, siliceous raw materials, calcareous raw materials, It is manufactured by mixing and foaming foaming agents such as powder quicklime, gypsum and aluminum at an appropriate ratio, and there is no generation of harmful gases as minerals.The thermal conductivity is about one tenth of that of general concrete blocks. It is excellent in blocking external noise and is used in various construction fields.

However, while having the advantages as described above, the light weight is weak to the impact transmitted from the outside and vulnerable to rain, there was a problem that the compressive strength is significantly lower than the general concrete block.

In addition, since the weight is light, there is an advantage that does not generate a lot of load, on the other hand, the wall is easily broken by the impact transmitted from the outside, or in particular, the wall collapsed due to the draft has been used only in limited places.

As a conventional technique proposed to solve this problem, Patent Registration No. 10-0663923 (dry masonry method and masonry of the masonry block) has been proposed,

This is, "In masonry the masonry block including a vertically open hollow, forming at least one square groove in the longitudinal direction on top of the masonry block, masonry blocks of the same layer while stacking the masonry block formed with a rectangular groove Insert the reinforcing bars of a certain length into the square grooves of the field in order to extend more than one row, and the hook bolt is hooked on the straight bars located on the lower part of the masonry block while the masonry blocks are stacked so that the upper part protrudes to the top of the masonry block. The hook is then hooked on a straight reinforcing bar located in the upper part to pass through the hook bolt, and the masonry blocks are laminated by tightening the connector through a nut, and the plurality of hooks protrude upward on the top of the masonry block. The upper portion of the bolt is further provided with a plurality of ceiling reinforcing bar is fixed to the front through the nut is inserted into the ceiling wall Dry masonry method of masonry blocks. " Is done.

However, according to the above-described dry masonry method and masonry of the masonry block, while inserting the linear reinforcement while structuring the masonry block, each of the linear reinforcement through the hook bolt and nut and the connection port or the masonry block is constant When more than the pressure is applied, it can be easily broken. When pulling the hook bolts and nuts and the connecting port connected up and down with strong force, the masonry block was broken. After all, there was a problem that the work costs also increased.

In addition, patent registration No. 10-337435 (brick construction method and its brick) has been proposed,

This includes, "a step of having a prefabricated ocher brick made of rock bricks and sharp bricks;

Installing a support member through a bottom surface to support and reinforce the ocher brick during construction;

Assembling the ocher brick step by step through the support member;

Installing the rebar in the transverse direction at each step;

Installing an exterior plate material on a main portion of the vertical beam and the corner beam; And

It is proposed a method of constructing a brick comprising a; a finishing step of treating the assembled ocher wall by painting, wallpapering, painting, etc. on the surface.

However, according to the construction method of the conventional brick and the brick technology as described above, a method of constructing the retaining wall, ondol or indoor partition of the building using the ocher brick or manufacturing according to a predetermined compounding ratio, the manufacturing cost is high, and the weight of the brick Compared with the conventional concrete block, there is a problem that the overall load of the building is heavy because of the similar degree.

Therefore, the applicant has proposed a patent application No. 10-2007-0049422 dated May 21, 2007 (construction method using a lightweight foam concrete block with reinforcing bars),

It is configured by forming at least one or more square grooves in the longitudinal direction on the upper surface and the lower surface of the lightweight foam concrete block, respectively,

As a construction method for constructing a wall or the like using the lightweight foam concrete block, arranging reinforcing bars on the bottom surface and placing concrete so as to bury only half of the diameter of the reinforcing bars while placing concrete on the reinforcing bars;

Fixing one end of the reinforcing bar to the vertical frame;

Fitting a square groove formed on a lower surface of the lightweight foam concrete block to a half protruding upward among the reinforcing bars;

Inserting reinforcing bars into a square groove formed on an upper surface of the lightweight foam concrete block;

Fixing one end of the reinforcing bar to the vertical frame; The step of applying a binder to the upper surface of the lightweight foam concrete block ".

However, by the construction method using the lightweight foam concrete block provided with the conventional reinforcing bar as described above, the combination of the lightweight foam concrete blocks connected to the left and right is stable, while in the state of being stacked in one layer, lightweight foam concrete Due to the limitation of the strength and thickness of the block, there is a drawback that it is reluctant to use it as a material for exterior walls in areas where there is a lot of rain and wind, as well as a lot of rain and wind depending on the region, and its strength is insignificant. When connected with concrete columns or reinforcing beams, there is a problem that can not have a strong bonding force and collapse or damage after construction.

Furthermore, in winter, when the temperature is low, there are cases where construction is required by using lightweight foam concrete blocks and stacking walls.In this case, even if the produced lightweight foam concrete blocks are used, the mortar for joining them is frozen and the curing is slow. Of course, there was a problem that the strength is lowered after hardening.

Thus, in order to prevent this, the mortar is rapidly cured by releasing heat with a hot air fan and raising the temperature of the room.

However, there is some effect of raising the indoor temperature by releasing heat to the hot air to harden the mortar, but due to the difference between the indoor temperature and the outdoor temperature caused by the hot air, the indoor and outdoor hardening conditions Due to the difference in the structural strength, such a problem occurs.

Accordingly, the present invention is to solve the conventional problems as described above, at least one line on one side of the upper and lower surfaces of the inner wall lightweight foam concrete block while the end of the computer bolt is inserted into the hole formed in the concrete column or wall. The square groove is formed by installing a thin plated computer bolt in contact with the semi-circular bent portion of the clamping plate located in the square groove formed above, and between the lightweight foam concrete blocks in which the bolt is not installed. Using lightweight foamed concrete blocks, which are fastened without freezing even in winter while supplying AC power to the thin wire mesh installed between the zinc-plated computer bolts installed between the formed lightweight foamed concrete blocks and the lightweight foamed concrete blocks. To provide a winter construction method of the wall The purpose.

In addition, the present invention is reinforced with thermal insulation and strength of the double wall having a space between the semi-circular bent portion and the zinc-plated computer bolt for supporting the square groove and the thin wire mesh and the fixed metal and the stable support on the column or wall For other purposes.

Winter construction method of the wall using the lightweight foam concrete block of the present invention for achieving the above object,

The narrow lightweight foamed concrete block of 75mm to 125mm has two rectangular grooves on the upper or lower surface of the wide lightweight foamed concrete block of 150mm to 250mm in width, while forming one square groove on one side of the upper or lower surface in the longitudinal direction. Forming in the longitudinal direction,

Forming the upper and lower projections by bending the upper and lower portions on the other side of the fixing rod having at least one semicircular bent portion formed on one side in the square groove of the lightweight foam concrete block of the inner wall;

The lightweight foamed concrete block formed with the rectangular grooves is formed by narrowing the narrow lightweight foamed concrete blocks without the rectangular grooves to the outer wall of the wall in a state in which a space of 20 to 70 mm is formed therebetween while being assembled to the inner wall of the wall. Process,

Inner wall first row lightweight foam concrete block is a process of forming a square groove toward the bottom so that the mortar of the bottom surface is introduced into the square groove to form a concave-convex coupling in the longitudinal direction,

Inner wall second row light weight foam concrete block is a process to ensure stable construction in winter by the thin wire mesh and mortar between the first row light weight foam concrete block while the square groove is located on the upper surface,

The process of assemble the outer wall first row lightweight foam concrete block twice the height of the inner wall to be combined with the mortar of the floor,

The lower and upper projections on the other side of the fasteners in which the semi-circular bent portions are located in the square grooves of the second row of lightweight foamed concrete blocks on the inner wall are respectively the upper surface of the first row of lightweight foam concrete blocks and the lower side of the second row of lightweight foam concrete blocks. The process of strengthening the strength between the inner wall and the outer wall and the strength of the outer wall itself as well as ensuring stable construction in winter by the steel wire mesh and mortar interposed therebetween,

Zinc-plated computerized to pass through the semi-circular bent portion of the fastener located in the square groove of the second row of lightweight foamed concrete blocks while inserting the end of the zinc-plated computer bolt into the holes formed in both concrete columns or walls. Install bolts to fill the square grooves with mortar, and place the third row of lightweight foam concrete blocks on the inner wall where the next square grooves are not formed. Process,

Process of stably installing the square groove of the fourth row of lightweight foam concrete blocks of the inner wall to be placed in the upper position while placing a thin wire mesh between mortars on the flat top surface of the third row of lightweight foam concrete blocks of the inner wall By repeating to configure the inner wall and the outer wall to be arranged side by side.

According to the winter construction method of the wall using the lightweight foam concrete block of the present invention as described above by forming a space of 20 ~ 70mm between the inner wall and the outer wall to separate the outer wall and the inner wall due to the air layer of the space inflow of rain water To improve the insulation effect

Forming a square groove on one side of the lightweight foam concrete block in the longitudinal direction so that the first row of lightweight foam concrete blocks in the inner wall face the square groove toward the bottom so that the mortar of the bottom surface flows in such a manner that the unevenness is combined in the longitudinal direction. and,

Place the semi-circular bent portion of the fastener in the square groove of the inner wall second row lightweight foam concrete blocks, and install it at regular intervals so that the upper and lower projections formed on the other side of the clamp are forced into the upper and lower parts of the outer wall lightweight foam concrete block, respectively. In addition, it is possible to stably install even in winter by the thin wire mesh and mortar between the inner and outer walls.

Zinc plated to pass through the semi-circular bent portion of the clamp located in the square groove of the second row of lightweight foamed concrete blocks while inserting both ends of the zinc-plated threaded rod into the holes formed in both concrete columns or walls. The computer bolt is installed to fill the square groove sufficiently while applying mortar, and the third row lightweight foam concrete block of the inner wall where the next square groove is not formed is positioned so that the zinc-plated computer bolt is located at the bottom. By the alternating current supplied by zinc-plated computer bolts, stable construction is possible even in winter, and the strength is further improved.

When the alternating current is supplied in parallel to the thin wire mesh installed at each position of the computer bolt and the mortar installed during the construction, there is an effect that stable construction is possible while preventing freezing even in winter.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view illustrating a construction process of a lightweight foam concrete block according to an embodiment of the present invention,

As shown in FIG. 2, the narrow lightweight foamed concrete block 10 having a width of 75 mm to 125 mm has a rectangular groove 11 formed on one side of an upper surface or a lower surface thereof in the longitudinal direction. Similarly, the process 101 of forming two rectangular grooves 46 and 47 in the longitudinal direction on the upper surface or the lower surface of the wide lightweight foamed concrete block 45 of 150 mm to 250 mm,

As shown in Fig. 4, the upper projections are bent upward and downward, respectively, on the other side of the clamping member 1 formed with at least one semicircular bent portion 2 located in the square groove of the lightweight foam concrete block on the inner wall. (3) and the process (102) of forming the lower projection (4),

The light-weight foamed concrete block 10 having the square grooves 11 formed therein is a narrow, lightweight foam that does not form a square groove in a state in which a space 25 of 20 to 70 mm is formed therebetween, while being assembled to the inner wall of the wall. Separating the concrete block 30 to be masonry to the outer wall of the wall 103;

The inner wall of the first row of lightweight foam concrete block 10 has a square groove 11 facing the lower end so that the mortar 12 of the bottom surface is introduced into the square groove so that the concavity and convexity are combined in the longitudinal direction, respectively. A process 104 of aligning the wire mesh to the mortar between the sides of the aerated concrete block 10, and

Gojeong (105) to enable fast and stable curing while supplying an alternating current to the thin wire mesh installed between the side of the inner wall first row of light-weight foamed concrete blocks 10,

As shown in FIG. 5, the inner wall second row lightweight foamed concrete blocks 15 are disposed between the side walls and between the side walls of the inner row first row lightweight foamed concrete blocks while the square grooves 16 are positioned on the upper surface thereof. Positioning 106 the wire mesh 14 to be bonded by the mortar 13, and

As shown in FIG. 6, the outer wall first-row lightweight foam concrete blocks 30 having a height twice as large as that of the inner wall may be coupled to the mortar 31 on the bottom surface of each of the lightweight foam concrete blocks 30. The process of forming a wire mesh to the mortar between the sides (107),

As shown in FIG. 7, the lower projection 4 on the other side of the clamping rod 1 on which one semicircular bent portion 2 is located in the square groove 16 of the inner wall second row light-weight foam concrete block 15. And the upper projections 3 are respectively inserted into the upper surface of the outer wall first row of lightweight foam concrete blocks 30 and the outer wall of the second row of lightweight foam concrete blocks 34 so as to be forcibly inserted to position the wire mesh 33 therebetween. While the process is to be bonded by the mortar (32) while the space 25 of the 20 to 70mm between the inner wall and the outer wall is kept constant so that not only the strength between the inner wall and the outer wall but also the strength of only the outer wall (108) (109) )and,

In addition, as shown in Figures 7 and 8, the inner wall second row and light weight while the end of the zinc-plated threaded bolt 26 is inserted into the holes 51 formed in both concrete pillars or walls 50 After installing the zinc-plated computer bolts 26 to pass through the semi-circular bent portion 2 of the clamping element 1 located in the square groove 16 of the foam concrete block 15, while applying the mortar (17) Filled in the square groove 16 of the (110), the inner wall of the third row lightweight foam concrete block 18 is not formed by the square groove is assembled to place a bolt bolted zinc plated in the square groove (16) ( The process of masonry 26 to locate;

As shown in FIG. 8, the inner wall fourth row of lightweight foam concrete blocks 21 is placed while the wire mesh 20 is placed on the flat upper surface of the inner wall third row of lightweight foam concrete blocks 18 and the mortar 19 is applied. The process of assemble so that the square groove 22 of the upper portion 112,

The alternating current is supplied in parallel to the thin wire meshes installed on the side surfaces of each of the lightweight foam concrete blocks including the computer bolt 26 and the outer wall first thin wire mesh 33 so that the mortar does not freeze in the winter. By repeating the process (113) to assemble as possible to configure the inner wall and the outer wall side by side.

9 shows a state of supplying power according to the present invention,

In the earth leakage breaker (60) receiving AC power from the outside to automatically cut off the power according to whether or not

In the power transformer 61 receives the AC power through the earth leakage breaker 60 to adjust the magnitude of the voltage and current,

An AC power supply via the power transformer 61 is connected to one side of the inner wall first row wire mesh 14 via the first contact 62 and to one side of the computerized wire mesh 26 via the second contact 63. and,

The inner wall third row thin wire mesh 20 via the fourth contact 65 while connecting to one side of the outer wall first row thin wire mesh 33 via the third contact 64 from the AC power supply via the power transformer 61. On one side of the

The first wall wire mesh 14 of the inner wall 14, the threaded bolt 26 of the inner wall, the first row wire mesh 33 of the inner wall and the third row thin wire mesh 20 of the inner wall are connected to the common contact 66 on the other side. The parallel connection state is maintained in the state which connected the contact 62 thru | or the 4th contact 65, respectively,

The common contact 66 recognizes the AC power currently supplied through the ammeter 67 and the voltmeter 68 by returning the power transformer 61 through the ammeter 67 and the voltmeter 68. The intensity of the power supplied from the power transformer 61 is arbitrarily adjusted to enable normal heat generation by appropriate AC power.

The fastener of the lightweight foamed concrete block of the present invention configured as described above and the winter construction method of the wall using the same,

In the narrow lightweight foamed concrete block 10 having a width of 75 mm to 125 mm, one rectangular groove 11 is formed in the longitudinal direction on one surface of the upper and lower surfaces. Then, two rectangular grooves 46 and 47 are formed in the longitudinal direction on the upper surface or the lower surface of the wide lightweight foamed concrete block 45 of 150 mm to 250 mm.

The upper protrusion (3) is bent upwardly and downwardly on the other side of the clamping member (1) having at least one semicircular bent portion (2) formed in the square groove (11) of the lightweight foamed concrete block (10) of the inner wall, respectively. ) And the lower protrusion 4.

The lightweight foamed concrete block 10 having the square grooves 11 formed therein has a width of 20 to 70 mm between the walls of the wall and is not formed with the square grooves while forming a space 25 therebetween. The narrow lightweight foam concrete block 30 is bonded to the outer wall of the wall.

After applying mortar 12 to the bottom surface, the lightweight foam concrete block 10, which is assembled in the first row of the inner wall, is attached so that the square groove 11 faces the bottom so that the mortar 12 of the bottom surface flows into the square groove. Concavities and convexity of the concave-convex method is made at the same time as the wire mesh to the mortar between the side of each of the lightweight foam concrete block 10 is assembled.

A fast and stable hardening is possible while supplying an alternating current to the thin wire mesh installed between the side surfaces of the inner wall first row of light-weight foamed concrete blocks 10.

The inner wall second row lightweight foamed concrete blocks 15 are arranged so that the square grooves 16 are located on the upper surface, and the thin wire mesh 14 between the inner wall first row of lightweight foamed concrete blocks 10 and between the sides and the mortar is positioned. As shown in FIG. 5, it adhere | attaches so that it may adhere | attach by (13).

And the outer wall first row lightweight foam concrete block 30, which is twice the height of the inner wall is to be combined with the mortar 31 of the bottom surface and at the same time wire mesh going to the mortar between the sides of each lightweight foam concrete block 30 Masonry to be located.

The lower projection 4 and the upper projection 3 on the other side of the clamp 1 on which one semicircular bent portion 2 is located in the square groove 16 of the second row of lightweight foamed concrete blocks 15 of the inner wall. Are respectively inserted into the upper surface of the outer wall first row of lightweight foam concrete blocks 30 and the outer wall of the second row of lightweight foam concrete blocks 34 by mortar 32 while positioning the wire mesh 33 between them. By adhering, the space 25 between the inner wall and the outer wall is kept constant between the inner wall and the outer wall so as to strengthen the strength between the inner wall and the outer wall as well as the outer wall only.

Square groove 16 of the inner wall second row lightweight foamed concrete block 15 while allowing the end of the zinc-plated computer bolt 26 to be inserted into the holes 51 formed in both concrete columns or the wall 50. Install a zinc-plated threaded bolt 26 so as to pass through the semi-circular bent portion 2 of the clamping plate 1 located in the mortar 17 to sufficiently fill the square groove 16 while applying the mortar 17 (110). 7 is arranged so that the third row of lightweight foamed concrete blocks 18 of the inner wall where the next square groove is not formed is positioned so that the zinc-plated computer bolt 26 is located in the square groove 16 as shown in FIG. 7. Masonry

Placing the wire mesh 20 on the flat upper surface of the inner wall third row lightweight foam concrete block 18 and applying the mortar 19, the square groove 22 of the inner wall fourth row lightweight foam concrete block 21 is upward To be located as shown in FIG. 8.

The alternating current is supplied in parallel to the thin wire meshes installed on the side surfaces of each of the lightweight foam concrete blocks including the computer bolt 26 and the outer wall first thin wire mesh 33 so that the mortar does not freeze in the winter. Repeat the building process as much as possible to make the inner and outer walls side by side.

In case of construction in winter, by connecting the electric power to the computer bolts 26 and the thin wire meshes 14, 20, 33 in parallel while the lightweight foamed concrete blocks are assembled by wires, Low temperature heat is generated in the computerized bolt 26 and the thin wire mesh 14, 20, 33 that prevents the flow of resistance and current, and prevents freezing in cold weather and allows the drying to occur quickly. Even stable construction is possible.

That is, as the construction proceeds, one side of the inner wall of the first row wire mesh 14 and the second contact through the first contact 62 to the power transformer 61 that receives AC power through the earth leakage breaker 60 from the outside ( 63 of the inner wall of the third row wire mesh 20 via one of the threaded bolts 26 of the inner wall through the fourth contact 64 and one of the outer row of the first row wire mesh 33 via the fourth contact 65 via the fourth contact 65. After connecting one side of each, the common contact point of these inner wall 1st row thin wire mesh 14, the inner wall 3rd row thin wire mesh 20, the computer bolt 26 of an inner wall, and the outer wall 1st row thin wire mesh 33 In connection with the reference numeral 66, the AC power supplied from the power transformer 61 is regulated while the AC power currently supplied through the ammeter 67 and the voltmeter 68 is recognized.

FIG. 10 illustrates a state in which wire bolts are coupled to an H beam according to another embodiment of the present invention.

A process of stacking the lightweight foam concrete block 72 between the two H beams 70 and 71;

Drilling a coupling hole in the H beams 70 and 71;

Bonding the both ends of the zinc-plated computer bolts 73 and 74 to be inserted into the holes;

The H beams are connected by fastening nuts 75, 76, 77, 78 at both ends of the zinc plated threaded bolts 73, 74 that pass through the coupling holes to the H beams 70, 71. Heat is generated while AC power supplied through the bolts 73 and 74 flows, allowing normal masonry work without freezing even in winter, as well as zinc plated bolts 73 and 74 with H beams. To support it stably.

1 is a schematic diagram showing a construction process according to an embodiment of the present invention.

Figure 2 is a perspective view showing the configuration of a lightweight foam concrete block according to an embodiment of the present invention.

Figure 3 is a perspective view showing the configuration of a lightweight foam concrete block according to another embodiment of the present invention.

Figure 4 is a perspective view showing the configuration of a clamp according to an embodiment of the present invention.

5 and 6 are schematic views showing a state in which a thin wire mesh is installed according to an embodiment of the present invention.

Figure 7 is a schematic diagram showing a state in which a zinc-plated computer bolt is installed according to an embodiment of the present invention.

8 is a schematic view showing a construction state according to an embodiment of the present invention.

9 is a block diagram illustrating a state in which AC power is supplied to computer bolts and thin wire meshes according to an exemplary embodiment of the present invention.

10 is a schematic diagram illustrating a state in which wire bolts are coupled to an H beam according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1: Fixture 11, 16, 22: Square groove

10, 15, 18, 21, 30, 34: Lightweight aerated concrete block

12, 13, 17, 19, 31, 328: mortar

14, 20, 33: fine wire mesh 25: space

50: concrete column or wall 51: hole

Claims (4)

It is configured to allow winter construction by supplying AC power in parallel to the upper and lower surfaces between the computer bolts installed between the lightweight foam concrete blocks and the lightweight foam concrete blocks, as well as to the parts bonded by the mortar on the side surfaces. On one side of the computerized bolt 26 and the thin wire mesh 14, 20, 33, the second contact 63, the first contact 62, the third contact 64, and the fourth contact the power transformer 61. Connect the contact 65, The other side of the threaded bolt 26 and the thin wire mesh 14, 20, 33 are connected in parallel to the power transformer 61 via an ammeter 67 and a voltmeter 68 while connecting to a common contact 66. A winter construction method of a wall using a lightweight foam concrete block, characterized in that the AC power supply is connected in parallel by connecting. The method according to claim 1, The inner wall first row lightweight foam concrete block 10 has a mortar between the sides of each lightweight foam concrete block 10 while allowing the mortar 12 of the bottom surface to flow into the square groove with the square groove 11 facing the bottom. The process of laying the wire mesh to A lump that allows fast and stable hardening while supplying an alternating current to the thin wire mesh installed between the side surfaces of the inner wall first row of light-weight foamed concrete blocks 10; The inner wall second row lightweight foamed concrete blocks 15 have a mortar while positioning the wire mesh 14 between the inner wall first row of lightweight foamed concrete blocks 10 and between the side surfaces while the square grooves 16 are positioned on the upper surface. Bonding process with (13), The outer wall first row of lightweight foam concrete blocks 30 are bonded to the mortar 31 on the bottom surface, and at the same time the process of assemble the wire mesh to the mortar between the sides of each lightweight foam concrete block 30 is positioned, The lower projection 4 and the upper projection 3 on the other side of the clamp 1 on which one semicircular bent portion 2 is located in the square groove 16 of the second row of lightweight foamed concrete blocks 15 of the inner wall. Are respectively inserted into the upper surface of the outer wall first row of lightweight foam concrete blocks 30 and the outer wall of the second row of lightweight foam concrete blocks 34 by mortar 32 while positioning the wire mesh 33 between them. Bonding the inner wall and the outer wall to keep the space 25 between 20 and 70 mm constant; Square groove 16 of the inner wall second row lightweight foamed concrete block 15 while allowing the end of the zinc-plated computer bolt 26 to be inserted into the holes 51 formed in both concrete columns or the wall 50. Install a zinc-plated threaded bolt 26 so as to pass through the semi-circular bent portion 2 of the clamping plate 1 located in the mortar 17 to sufficiently fill the square groove 16 while applying the mortar 17 (110). ) Assemble so that the third row lightweight foamed concrete blocks 18 of the inner wall where the next square groove is not formed are positioned so that the zinc-plated computer bolts 26 are located in the square groove 16; Placing the wire mesh 20 on the flat upper surface of the inner wall third row lightweight foam concrete block 18 and applying the mortar 19, the square groove 22 of the inner wall fourth row lightweight foam concrete block 21 is upward The process of masonry, The inner wall and the outer wall are side by side by repeating the alternating current to be supplied in parallel to the thin wire meshes installed on the side of each of the lightweight foam concrete blocks including the computer bolt 26 and the outer wall first thin wire mesh 33. Winter construction method of the wall using the lightweight foam concrete block, characterized in that configured to masonry. delete delete

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