KR100948255B1 - Constructure method of green house using expanded block, expanded block of green house and expanded roof block of green house - Google Patents

Abstract

PURPOSE: A construction method of a green house using foamed styrofoam blocks with high heat and sound insulation, an foamed styrofoam block, and a foamed styrofoam roof panel are provided to construct a building of high energy efficiency by preventing heat exchange between the interior and exterior of the building. CONSTITUTION: A construction method of a green house using foamed styrofoam blocks with high heat and sound insulation is as follows. A surface is arranged and compacted. A foamed styrofoam wall block(100) is installed on the top of the foundation. Concrete mortar is poured in a mortar inlet(130) of the wall block to form a wall of a building. A floor or ceiling is constructed.

Description

Construction method of green house using foam insulation styrofoam block with high insulation sound insulation, foamed styrofoam block with high insulation sound insulation and foamed styrofoam ceiling panel with high insulation sound insulation {constructure method of green house using expanded block, expanded block of green house and expanded roof block of green house}

The present invention is a green house construction method using a high-insulation soundproof foamed styrofoam block that minimizes waste of energy by using a foamed styrofoam block for wall construction, a foamed styrofoam block of high-insulation soundproof, and a foamed styrofoam ceiling panel of a high-insulation soundproof . In particular, the foamed foam foam forms an inner insulation portion and an outer insulation portion, and forms a wall surface by pouring concrete mortar into the space between the inner insulation portion and the outer insulation portion, and the ceiling is connected through a ceiling panel that can be connected through a joint structure. Green house construction method using high-insulation soundproof foam styrofoam block to form high energy efficient building by fundamentally blocking internal and external heat exchange of the building, foam insulation styrofoam block with high insulation sound insulation and foamed styrofoam ceiling with high insulation sound insulation It is a panel.

In general, a building is constructed as a block or concrete mortar, and the styrofoam is bonded to the outside of the outer wall to add insulation.

By the way, many problems have arisen in such a conventional building.

In other words, the conventional method of building a building was constructed by constructing a frame, which is the outer wall of the building, in the form of a guff house and placing concrete mortar between them. After the outer wall frame of the building is installed, the outer wall is glued to the outside of the styrofoam in the form of a panel, the outer panel is bonded to the outside of the construction is completed in the form of completing the outer wall of the building.

After all, even if the construction of the inner wall is folded, the construction of the outer wall is too complicated and expensive. In addition, the building constructed through this construction method has a weak function of insulation or sound absorption, causing another inconvenience to residents.

Nowadays, green house concept buildings need more effective heat insulation to minimize all heat sources and power used inside them. Furthermore, all heat sources used in buildings can be self-produced through infinite solar light. The time has come to emphasize the point. In other words, there was a need for a special method of thermal insulation to more completely block the heat exchange between outside and inside air.

Therefore, the conventional Patent No. 10-804087 "wall construction block" has been proposed.

That is, as shown in FIGS. 21 and 22, the inner heat insulating part 20 and the outer heat insulating part 10 arranged in parallel to each other and the inner heat insulating part 20 and the outer heat insulating part 10 are connected to each other. A plurality of connecting rods 30 forming a mortar input part 31 in a space between the outer insulation parts 20 and 10 and the upper and lower surfaces of the inner and outer insulation parts 20 and 10 correspond to each other. In the wall construction block formed with the coupling groove 40 and the coupling protrusion 50 to be engaged, the space portions 13 and 23 are formed inside the inner insulation portion 20 and the outer insulation portion 10. It is produced in the form. The conventional block is formed by dividing the inner insulation and the outer insulation in order to achieve a perfect insulation, and the construction of the building by pouring concrete mortar in the mortar input portion that is a space therebetween. Therefore, the building's robustness and the function of more perfect insulation were improved.

However, such a conventional wall construction block also has the following problems.

First, the block is produced through a mold, which must be produced in a significant volume, which results in the hardening of the mold by falling on the inner circumferential surface of the mold. As a result, such a problem is a decrease in production compared to the input cost.

Second, in order to construct a more efficient green house, a construction method using the styrofoam block like the present invention has to be invented, but there is no special construction method since it is a narrow field. It is difficult to significantly reduce the construction period because only the construction using the block as described above is applied by applying the construction method used in the prior art. In particular, although the construction of a single-story building using a conventional block can be built to some extent, there were many difficulties in the construction of a two-story or more building.

Third, the function of insulation is greatly improved, but the problem is that the function of sound absorption is weak. That is, as shown, the conventional block forms a separate space portion penetrating a certain depth from the bottom to the upper portion to block the transmission of sound through the space portion, but the spacing of the space portion is insignificant and there is no effect. .

Fourth, a special problem in the conventional block is that its workability is poor. First, after the wall surface is erected through the block, cement mortar must be poured on the outside of the outer heat insulating portion, and an exterior material such as an exterior tile or an exterior panel must be attached. However, in the case of the styrofoam, since the synthetic resin has soft physical properties, the cementum mortar does not adhere and falls. Therefore, in the related art, once pure cement has been mixed with water and applied to the surface of the outer heat insulating portion, the cement has been cured, and then sand cement mixed with sand is poured on the surface. Of course, even using this method, the firm adhesive strength is weak, there is a problem that the exterior panel falls after construction.

In order to solve this problem, the conventional block forms a plurality of uneven surfaces at predetermined intervals on the surfaces of the outer and inner insulation parts, but this is an unnecessary configuration having no effect at all.

The present invention relates to a building using a foamed foam foam block for constructing a wall, the foamed foam foam forms an inner insulation and an outer insulation and the wall surface in the manner of placing concrete mortar in the space between the inner insulation and the outer insulation portion. And the ceiling is constructed through the ceiling panel that can be connected through the joint structure, and the green house construction using the high-insulation soundproof foam styrofoam block to form a high-energy efficient building by fundamentally blocking heat exchange inside and outside the building. To provide a method, a high insulation sound insulation foam styrofoam block and a high insulation sound insulation foam styrofoam ceiling panel.

Green house construction method using a high-insulation sound-proof foamed foam foam block according to the present invention, the building construction method, the first step: the level of groundwork (1) to flatten the ground, the step of foundation work; The second step: stacking and arranging the wall block 100 of the foam insulation styrofoam of the high insulation sound insulation to the top of the foundation floor; The third step: building a concrete wall (5) of the building by pouring concrete mortar (2) on the mortar input portion 130 of the wall block (100); The fourth step: constructing the ceiling surface 501 using the ceiling panel 500 of the high-insulation foam styrofoam having a coupling structure or the bottom surface for forming the upper layer according to the building; It includes the construction of a building.

Further, according to the present invention, the green house construction method using the foam insulation styrofoam block of the high insulation sound insulation, the base construction to form the basement can be carried out in a later step to form a basement layer: Forming a foundation concrete layer (3) on which floor concrete is poured: The foundation works, the floor foundation concrete layer (3) is poured on the ground (1), and the wall block construction plate (80) on the foundation concrete layer (3) ) And is configured to insert the wall block 100 of the first stage into the wall block construction plate (80).

In addition, according to the green house construction method using the foam insulation styrofoam block of the high-insulation soundproofing of the present invention, the wall block construction plate 80 is a bottom plate 81 and the left and right side plates 82 in the shape of "c" shape. It is formed, the left and right side plates 82 to form a wedge-shaped pressure hook 83 to be protruded toward the inside at regular intervals, the bottom plate 81 is formed in a plurality at regular intervals through the vertical direction The ball 84 is configured to firmly fasten the side surface of the wall block 100 inserted into the space 85 between the left and right side plates 82 through the pressure hook 83 so that the wall of the building is secured. To be perfectly supported: The method of installing the wall block construction plate 80 on the foundation concrete layer 3, the level of placing the wall block construction plate 80 on top of the base concrete layer (3) (a), the wall blocks in the base concrete layer (3) The level (b) of filling the side plate 82 of the plate 80 so as to be partially locked, the side plate 82 of the wall block construction plate 80 is completely embedded in the foundation concrete layer (3) To be able to use a construction method selected from one of the levels (c): The wall block 100, the inner insulation 110 and the outer insulation portion 120 and spaced apart equilibrium, the inner A plurality of connecting rods 140 for forming a mortar input portion 130 in the space between the inner and outer insulation portions 110 and 120 while connecting the heat insulation portion 110 and the outer insulation portion 120, the inner and outer In the styrofoam block formed with coupling grooves 111 and coupling protrusions 112 engaged with the top and bottom surfaces of the heat insulating parts 110 and 120, the inner and outer insulation parts 110 and 120 are provided. A concave-convex suction groove 150 having a tapered surface 151 having a side tapered at regular intervals on a surface of the connecting table 140; A plurality of sound absorbing holes 160 formed at a predetermined interval so as not to penetrate from the lower end to the upper end of the outer heat insulating part 120; Is coupled to the concrete mortar or cement mortar (2) to the concave-convex suction groove 150 to easily finish the outer wall, and to expand the functionality of the production and sound absorption of the product through the suction groove 150 It is configured to include.

In addition, according to the present invention the green house construction method using the foam insulation styrofoam block of the high-insulation soundproof, when constructing the corner of the wall surface (5) of the building, one side of the wall block 100 in the mortar input portion 130 separately Fastening the foam styrofoam blocking block 300, and fastening the auxiliary blocking block 400, including the connecting table 140 to the upper portion of the connecting table 140: pouring the concrete mortar of the third step Before, according to the number of floors of the building, the reinforcing bar (9) is arranged between the mortar input portion 130 of the wall block 100 to form a solid wall: to build the wall surface 5 of the building of the third step In the step, the wall block 100 is stacked in the multi-stage through the vertical adjustment means (60) is configured to include the concrete after being laminated in a precise vertical state with the ground.

In addition, according to the green house construction method using the foam foam styrofoam block of the high-insulation soundproof of the present invention, the vertical adjustment means 60, the cross section is made in the form of a rectangular shape so as to be interviewed in a multi-stacked wall block 100, A support 62 having a plurality of stopper balls 61 penetrated in the left and right direction at intervals; Adjusting bar (63) arranged horizontally at regular intervals with the support (62); A connecting bar 64 which combines the control bar 63 and the support 62 at regular intervals; A coupling stopper 65 inserted into the stopper hole 61 and screwed to the front surface of the wall block 100 through rotation; It is fastened to the lower end of the control bar 63 by adjusting the support angle of the wall block 100 of the support 62 by raising or lowering the control bar 63 to rotate to adjust the vertical state of the wall surface. Height adjusting unit 70; It is coupled to fasten in the shape of a ladder to the wall block 100 to the vertical control of the wall surface by adjusting the height adjustment unit 70: the height adjustment unit 70, the adjustment An upper screw 71 protruding from the lower end of the bar 63; A lower screw 73 fastened to protrude upward from the jig plate 72 formed in a plate shape so as to be in contact with the ground 1; The upper nut 74 and the lower nut 75 are fastened to the upper and lower portions so as to be fitted to both the upper screw 71 and the lower screw 73, and are elliptical integrally with the upper and lower nuts 74 and 75. Forming a rotating body 76, the rotation control unit 78 consisting of a support bar 77 vertically split the center of the rotating body 76; coupled, the upper screw 71 and the lower screw 73 ) Is inserted into the upper and lower nuts 74 and 75 corresponding to each other, and when the rotation control unit 78 is rotated to one side by forming screws in opposite directions, the control bar 63 is raised and rotated to the other side. When the upper and lower screws (71, 73) to narrow the gap down the adjustment bar (63): The height adjustment unit 70 of the other embodiment, the upper end is projected to the lower end of the adjustment bar (63) Screw 71; A lower screw 73 fastened to protrude upward from the jig plate 72 formed in a plate shape so as to be in contact with the ground 1; The upper nut screw 66 and the lower nut screw 67 are formed on the upper and lower inner circumferential surfaces of the upper screw 71 and the lower screw 73 so as to be fitted into both the upper screw 71 and the lower screw 73, and the rotation adjustment is performed at 90 ° through the outer peripheral surface of the central portion thereof. Cylindrical control tube 69 formed with a ball 68; is coupled, the upper screw 71 and the lower screw 73 is inserted into the upper, lower nut screws (66, 67) corresponding to each other in the opposite direction If the reinforcing bar (9) is inserted into the rotation control hole (68) of the control tube (69) and rotates to one side to raise the control bar (63), and to the other side to rotate the upper and lower screws (71). , 73) to narrow down the adjustment bar 63 is configured to include.

In addition, according to the present invention, the method of forming the bottom surface of the upper layer of the fourth step according to the green house construction method using the foam insulation styrofoam block of the high heat insulation, the inner insulation portion 110 of the wall block 100 which is the wall surface of the first floor. To cut, bundle a plurality of horizontal reinforcement (9) to the vertical reinforcement (9) vertically raised through the mortar input portion 130 with iron wires and arranged at regular intervals, by pouring concrete mortar (2) on the top Forming the bottom plate: The method of constructing the ceiling of the fourth step is to form a layer by seamlessly connecting the ceiling panel 500 on the slab roof or the bottom plate 590 of the bona triangular trans- sion roof, and then glue or cement on top. Mortar (2) is applied, and the adhesive or cementite mortar (2) is combined with a single or ceiling plate (591) to complete the ceiling: The ceiling panel 500 is a substantially integral panel, but four corners of each other Deviated at regular intervals Comprises a value overlaid off, each overlapping portion in the back and forth direction (531, 532, 533, 534) the top and bottom panels (510, 520) with the; The rear overlapping portion 532 of the upper panel 510 is formed at regular intervals with a rear insertion uneven protrusion 511 protruding around the outer portion; The front overlapping portion 531 of the lower panel 520 forms a front insertion concave-convex groove portion 521 at a predetermined interval corresponding to the corresponding rear insertion concave-convex portion 511 to be inserted therein; The insertion uneven groove 521 of the one ceiling panel 500 is configured to include connecting the insertion uneven protrusions 511 in the front and rear directions.

In addition, according to the green house construction method using the foam insulation styrofoam block of the high thermal insulation of the present invention, protruding end insertion concave-convex portion 513 is formed at the corners of the left side portions 533 and 532 of the upper panel 510. and; A concave end insertion recessed groove 523 is formed at the corners of the lower portions 534 and 531 which overlap the right side of the lower panel 520; One ceiling panel 500 end insertion recessed groove 523 of the other one of the ceiling panel 500, the end insertion recessed protrusion 513 is fitted to be connected to each other in the left, right direction overlapping configuration do.

According to the present invention, the high-insulation sound-proof foam styrofoam block, in the building styrofoam block, the inner heat insulating portion 110 and the outer heat insulating portion 120 are disposed equally spaced apart, the inner heat insulating portion 110 and the outside A plurality of connecting rods 140 for forming a mortar input portion 130 in the space between the inner and outer insulation portions 110 and 120 while connecting the heat insulation portion 120 and the inner and outer insulation portions 110 and 120. In the styrofoam block formed with a coupling groove 111 and a coupling protrusion 112 to be engaged with each other to the upper and lower surfaces of the inner surface, the side surface at regular intervals on the surface of the inner heat insulating portion 110 and the outer heat insulating portion 120 An uneven suction groove 150 having the tapered tapered surface 151 is formed; A plurality of sound absorbing holes 160 formed at a predetermined interval so as not to penetrate from the lower end to the upper end of the outer heat insulating part 120; It is coupled to the concrete mortar or cement mortar (2) to the concave-convex suction groove 150 to be able to easily finish the outer wall, and through the suction groove 150 to expand the production and sound absorption of the product: The outer heat insulating part 120 of the wall block 100 may have a thickness width of 1-4 times larger than the thickness width of the inner heat insulating part 110: the inner heat insulating part 110 and the outer heat insulating part. In the mortar input portion 130 between the portion 120, the coupling groove 111 and the coupling protrusion 112 formed on the upper and lower surfaces of the inner insulation portion 110 and the outer insulation portion 120 on the upper and lower surfaces. A series of panel coupling grooves 311 and panel coupling protrusions 312 are formed to correspond to each other; On the left and right sides, projections corresponding to the cross-section of the uneven suction groove 150 having a tapered surface 151 having side surfaces tapered at regular intervals on the surfaces of the inner insulation portion 110 and the outer insulation portion 120. It is configured to include a panel block blocking block 300 formed by forming the guider 320 is fastened and construct the building wall edge.

In addition, according to the present invention, the thermal insulation sound-proof foam foam foam block, connecting the connection between the inner heat insulating portion 110 and the outer heat insulating portion 120, 140, the inner heat insulating portion 110 and the outer heat insulating portion ( A series of block coupling grooves 411 is formed to correspond to the coupling groove 111 formed on the upper surface of the 120; On the left and right sides, protruding portions corresponding to the cross-section of the uneven suction groove 150 having a tapered surface 151 having side surfaces tapered at regular intervals on the surfaces of the inner insulation portion 110 and the outer insulation portion 120. Forming a block guider 420; The bottom surface is fitted with a block-shaped auxiliary blocking block 400 formed with a corresponding surface 430 of the upper and lower light corresponding to the sliding surface 148 having a cross section of the upper and lower light of the connecting table 140 to be fitted, and the edge of the building wall. It comprises the construction of a site.

In addition, the high-insulation soundproof foamed Styrofoam ceiling panel according to the present invention is a substantially integrated panel in a constructional Styrofoam ceiling panel, but the four corners of each other overlap each other at a predetermined distance from each other and overlap each other in the front, rear, left, and right directions. An upper and lower panel 510, 520 having portions 531, 532, 533, 534; The rear overlapping portion 532 of the upper panel 510 is formed at regular intervals with a rear insertion uneven protrusion 511 protruding around the outer portion; The front overlapping portion 531 of the lower panel 520 forms a front insertion concave-convex groove portion 521 at a predetermined interval corresponding to the corresponding rear insertion concave-convex portion 511 to be inserted therein; The insertion uneven groove 521 of the one ceiling panel 500 is configured to include connecting the insertion uneven protrusions 511 in the front and rear directions.

Also, according to the present invention, the foam insulation styrofoam ceiling panel of the present invention, at the corners of the left side of the upper plate and the overlapping portion (533, 532), protruding end insertion protrusions and protrusions (513) are formed; At the corners of the corresponding lower plate right side and the front overlapping portions 534 and 531, a concave end insertion recessed groove 523 is formed; It is configured to include the one end insertion recessed groove 523 of one ceiling panel 500, the other end panel insertion recessed protrusion 513 is fitted to be connected to each other in the left and right directions. .

According to the present invention, since the blocks can be sequentially stacked, concrete is poured, and the building can be completed by simply attaching exterior materials and interior materials, the construction period can be effectively shortened.

According to the present invention, as well as completely block the outside noise through the sound-absorbing hole formed in the block, when the sound-absorbing hole is formed for the production of the block through the pipe through which the refrigerant flows more effectively disassemble the block from the mold There is an advantage to this.

According to the present invention, a plurality of suction grooves formed in the block grab the cemental mortar to facilitate the casting of cemental mortar, which has the advantage of easy construction.

According to the present invention, there is an advantage that the construction method using the Schiropol block, which has not found a special construction method in the prior art, is perfectly created and improved.

The present invention relates to a building construction method.

Therefore, the configuration and operation of the present invention will be described in detail with reference to FIGS.

The present invention first step: the ground (1) evenly, and goes through the steps of foundation work to compact the floor. That is, the ground (1) of various shapes as in the conventional building method is to be compacted, and in a special case, a base construction is performed by shaving one side of the ground or forming an underground layer. This work is essential for the construction of all buildings. It is a basic construction that allows the building to be installed more upright, and the building must be constructed in such a vertical state to ensure more durable durability.

Next, the present invention undergoes a second step: stacking and arranging the wall blocks 100 of the foamed styrofoam of high insulation sound insulation to the upper part of the foundation floor. The present invention is a building method for forming the wall block 100 made by using a styrofoam as the outer wall of the building, it is very simply finished by laminating the wall block 100 in the position where the outer wall should be formed. Wall block 100 of the present invention is formed of a foamed foam, it is possible to create a higher effect of heat insulation by adding a graphite inside.

Next, the present invention is a third step: the concrete mortar (2) is poured into the mortar input portion 130 of the wall block 100 goes through the step of building the wall (5) of the building. That is, in the present invention, the foamed styrofoam wall block 100 is laminated, and concrete mortar 2 is poured into the mortar input part 130 formed on the wall block 100 to complete the outer wall surface. Since the wall block 100 is formed of styrofoam, the wall block 100 is also used as a high-efficiency heat insulator, but also serves as a girdle for pouring concrete mortar 2 at the same time. The conventional construction method has been a method of installing a girder house and placing concrete mortar between the girdle house, the construction is complicated and the cost is high. In addition, after the wall is completed, the trouble of having to re-insulate the insulation using a separate styrofoam also occurs.

However, the present invention eliminates all such operations and simply stacks the wall blocks 100 and complex concrete conventional construction methods only by placing the concrete mortars 2 on the mortar input part 130 formed on the wall blocks 100. Has replaced the majority.

Next, the present invention is a fourth step: according to the construction of the floor for forming the top layer or through the step of constructing the ceiling 501 using the high-insulation foam styrofoam ceiling panel 500 having a bonding structure Complete the building. Therefore, it is to construct a building that blocks the emission of energy.

That is, according to the construction method of the present invention, a single-story building or two or more floors can be constructed. Therefore, after the wall surface forming the first floor is completed, a separate two-layer wall construction may be followed to construct the second layer, and the same or similar to that of the wall block 100 so as to finish the first layer. The ceiling 501 is constructed by using the ceiling panel 500 made of a material. In the case of the ceiling panel 500, the ceiling panel that can be connected to each other through the coupling structure, without the need to adhere the tape between them in the state of laying a plate-shaped flat styrofoam as in the prior art It is possible to construct more effectively with 500.

Then look at the construction method of the present invention to be constructed in more detail. That is, look at the action of the parts and components necessary for the construction method of the present invention and look at a special construction method.

In the present invention, the foundation work for compacting the floor, the basement layer can be formed, and can be carried out in a later step. That is, in the construction of the building through the construction method of the present invention, the basement may be formed and the foundation may be performed, or the foundation may be formed and the basement may be formed. It is wiser to just construct the basement floor and carry out the work for the foundation work. The above-described construction method is a method already invented, but it is unique that the same can be performed through the wall block 100 of the present invention. In other words, while using a method of placing an outer wall surface completely different from the conventional one to allow the basement and foundation construction in the same manner as the conventional.

And looking at a more detailed method of the foundation work, a method of forming a foundation concrete layer 3 on which the floor concrete is poured on the ground (1) is used, which is to cast the ground foundation concrete layer (3) on the ground (1) The method may be used, and the wall concrete block plate 80 may be installed on the basic concrete layer 3, and the wall block 100 may be inserted into the wall block plate 80. have. That is, as shown in Figures 1 to 3, it is a method of constructing a base concrete layer for placing the floor concrete on the ground.

As shown in FIG. 1, a method of laying a foundation concrete parallel to the ground by laying the foundation and stacking the wall block 100 directly on top of the ground is also possible, and a separate wall block shown in FIG. 2 is possible. The method using the construction plate 80 can also be used.

The wall block construction plate 80 may be manufactured through a metal or a synthetic resin. The wall block construction plate 80 may be manufactured in a form capable of accommodating a part of the wall block 100 and planted in the foundation concrete layer 3. Looking at a more specific form of the wall block construction plate 80 through Figures 2 and 3, the cross section is formed of a bottom plate 81 and the left and right side plates 82 in the shape of "C", the left and right The wedge-shaped pressure hook 83 is formed to the inner side of the side plate 82 at regular intervals. In addition, the bottom plate 81 is configured to include a plurality of vertical through-holes 84 are formed at regular intervals, the wall block 100 is inserted into the space portion 85 between the left and right side plates 82. ) Side is firmly fastened through the pressure hook 83 so that the walls of the building can be perfectly supported.

Part of the wall block 100 is to be accommodated, the outer surface is formed in the wall block construction plate 80 so as to hold the side plate 82 of the wall block construction plate 80 tightly It is preferable to adjust the width of (85). In other words, the width of the wall block 100 is the same as or similar to the width of the outer circumferential surface of the wall block 100 so that the wall block 100 is not easily removed when the wall block 100 is inserted. As shown in FIG. 2, the wall block construction plate 80 is placed on top of the base concrete layer 3, and the wall block 100 is placed in the inner space 85 of the wall block construction plate 80. It will be inserted sequentially. At this time, both side surfaces of the wall block 100 are inserted while sliding between the side plate 82 of the wall block construction plate 80, the wedge-shaped pressure hook protruding at a predetermined interval from the side plate 82 ( Since the 83 is torn in an open form toward the ground 1, the wall block 100 is easily inserted when the wall block 100 is pushed from the top to the bottom. However, since the wedge-shaped pressure hook 83 formed on the side plate 82 of the wall block 100 protrudes downwardly and tapered to the space 85, the wall block 100 is inserted and inserted once. After the wall block 100 is securely fastened so as not to escape to the outside. That is, even when the wall block 100 is formed as a wall and receives a large wind, the wall block 100 serves to hold firmly so as not to fall or fall in the opposite direction of the wind. And the above-mentioned up-and-down through hole 84 maintains the state buried in the foundation concrete layer 3 to achieve a secure fastening with the foundation concrete layer (3).

The method of installing the wall block construction plate 80 on the foundation concrete layer 3 includes a level (a) of placing the wall block construction plate 80 on the top of the foundation concrete layer 3 and the foundation concrete. The level (b) of embedding the side plate 82 of the wall block construction plate 80 to be partially locked to the layer (3), the side of the wall block construction plate 80 to the base concrete layer (3) It is possible to use a construction method of one of the levels (c) to allow the plate 82 to be completely embedded.

That is, as shown in Figure 2, the wall block construction plate 80 of the present invention can be combined with the base concrete layer 3 in three ways. That is, the wall block construction plate 80 is simply installed on the upper portion of the base concrete layer (3) is a method of inserting the wall block 100 therein. As shown in the figure shown in the position designated a level is a construction method so that only the through-hole 84 is simply buried in the bottom plate can be buried. 2 b shows a construction method in which the wall block construction plate 80 is partially buried in the foundation concrete layer 3. The side plate 82 and the bottom plate 81 is partially buried in the base concrete layer 3, but the wedge-shaped pressure hook 83 formed in the side plate 82 is not buried. Of course, at this time, the concrete mortar (2) is not poured in the space portion 85 between the side plates (82). Only the through-holes 84 of the bottom plate 81 is buried in the base concrete layer 3 so that the wall block construction plate 80 can be buried in the base concrete layer 3.

As shown in FIG. 2, which is finally shown in FIG. 2, c is constructed with the wall block construction plate 80 of the present invention completely buried in the base concrete layer 3. That is, the left and right side plates 82 are completely buried in the foundation concrete layer 3, but be careful not to pour the concrete mortar 2 in the space portion 85 therein, and the gap of the wedge-shaped pressure hook 83 Be careful not to pinch the concrete mortar (2) in the gap. If the worker works in a way that scrapes off in a state in which water is missing from the concrete mortar (2), it can be buried in the foundation concrete (3) not so difficult.

Then it looks at the detailed configuration of the wall block 100 that is mainly used in the present invention.

The wall block 100 of the present invention, the inner heat insulating portion 110 and the outer heat insulating portion 120 and the inner heat insulating portion 110 and the outer heat insulating portion 120 are disposed to be equally spaced apart as shown in the figure While connecting the plurality of connecting rods 140 to form a mortar input portion 130 in the space between the inner, outer insulation (110, 120), and the upper and lower surfaces of the inner, outer insulation (110, 120) In the styrofoam block formed with the coupling groove 111 and the coupling protrusion 112 to be engaged to correspond to each other, the side surface at regular intervals on the surface of the inner heat insulating portion 110 and the outer heat insulating portion 120 and the connecting table 140 The uneven suction groove 150 having the tapered tapered surface 151 is formed, and a plurality of sound absorbing holes are formed at a predetermined interval so as not to penetrate from the lower end to the upper end of the outer heat insulating part 120 ( 160). Therefore, these are combined with the concrete mortar or cement mortar (2) to the concave-convex suction groove 150 to be able to easily close the outer wall, and through the suction groove 150 to expand the production and sound absorption of the product It is.

That is, the wall block 100 of the present invention has no significant change in shape compared to the wall block 100 described in the prior art. Only the conventional wall block 100 does not consider the construction method in the process of imitating the older wall block 100, because only the shape imitated a large technical effect was less. However, the wall block 100 of the present invention, when giving a shape to all the components, while maintaining the structural shape that brings the good effect of the prior art, but a slight shape deformation for the part that will bring an effect in the construction surface in particular Will achieve a great effect. Both the wall block 100 and the conventional wall block 100 of the present invention do not form a gulf in particular in forming a wall by using a foamed foam foam, and the wall block 100 itself may also serve as a guff. Mortar input portion 130 is formed in the inside so that. That is, by dividing into the inner heat insulating portion 110 and the outer heat insulating portion 120 to pursue a more sure effect of heat insulation, while forming a mortar input portion 130 in the space therebetween so as to perform the role of the giraffe. It is. In the present invention, the sound insulating hole 160 may be formed separately or separately in the outer heat insulating part 120 and the inner heat insulating part 110. In FIG. 17 and FIG. 18, the sound absorbing hole 160 is formed only in the outer heat insulating part 120, but the sound absorbing hole 160 may be formed in the inner heat insulating part 110, respectively. It is okay. Sound absorbing hole 160 of the present invention is to enhance the effect by forming a separate circular sound absorbing hole 160 in the inside while allowing the external noise to pass through the porous styrofoam to cancel. As sound waves pass through different areas of the medium, interference of sound is added to improve the effect of canceling the sound source.

By the way, the sound absorbing hole 160 of the present invention not only induces such effects but also more easily induces the manufacture of the wall block 100 of the present invention. That is, the wall block 100 of the present invention is wider and wider than the relatively general cement block. Therefore, it is accompanied by a process of dipping through a mold having a large shape, when taking the wall block 100 at a high temperature and high pressure and pulling the shaped wall block 100 to the outside of the mold, the temperature must be dropped and pulled out of the mold. Will fall off easily. The reason is that the block of the present invention forms the sound absorbing hole 160 in a circular shape, and forms a sound absorbing hole 160 having a relatively large diameter as compared to the conventional block. When the sound absorbing hole 160 is formed, a cylindrical rod is inserted to harden the wall block 100 by a process of flowing a coolant or a coolant into the rod. In addition, even in the process of removing the shaped wall block 100, the process of removing the wall block 100 inserted into the cylindrical rod is easier, and thus, a larger amount of production can be obtained than in the process of producing the conventional wall block 100. .

As a result, the sound absorbing hole 160 of the present invention can significantly increase the output of the wall block 100 itself while creating a remarkable effect compared to the effect of sound absorption generated in the conventional wall block space portion 13. It is an effective configuration.

And as shown in Figure 14, another effect of the wall block 100 of the present invention is that both the inner heat insulating portion 110 and the outer heat insulating portion 120 and the outer surface of the connecting table 140, the uneven suction groove 150 There is a big difference in forming. Conventionally, the outer uneven surfaces 12 and 22 of the concave-convex type are also formed on the outer surface of the wall block 100. The outer uneven surfaces 12 and 22 have the following problems. General cement mortar, that is, if you want to construct a plastering work using sand, it is not easily attached according to the quality difference between the cement and the wall block 100 of synthetic resin. When the cement mortar is applied to the outside of the wall block 100, the cement mortar flows as it is, so that the exterior panel S cannot be attached. In addition, in order to attach the tiles of the interior panel (P) in the interior, the cement mortar must be applied to the surface.

As a result, the conventional wall block 100 was able to accept only the working type of the coating method using an adhesive. However, in the case of the current building materials, it was concluded that marble exterior or tile interior and exterior materials that cannot be applied with adhesive cannot be built. Of course, the internal and exterior materials may be constructed by first diluting pure cement with water and then applying it to the surface of the wall block 100 first, and then applying sand sand after the cementite is cured. However, such work is an additional task for the worker, which is a serious problem that slows down construction.

Therefore, in the present invention, the suction groove 150 is formed on the surface of the inner heat insulating part 110 and the outer heat insulating part 120 at predetermined intervals, and the shape of the groove is manufactured in a tapered state. When the inner side is wider and the outer side becomes tapered, the gap becomes narrower, and when sand sand mortar (cement mortar) is applied, the tapered surface 151 grabs as if the cement mortar T is sucked. Grab it so that it can be applied firmly without falling even by the first application. Then, the exterior material is attached to the coated cement to form an exterior wall.

In addition, the wall block 100 of the present invention has the advantage that can facilitate the construction of the corner portion that has been a problem in the conventional block. That is, when constructing the corner portion of the wall surface 5 of the building, fastening a separate foamed styrofoam blocking block 300 to one side mortar input portion 130 of the wall block 100, the connection of the connecting table 140 The mortar is more easily cast by fastening the auxiliary blocking block 400 including the connecting unit 140 to the upper portion.

That is, the wall block 100 of the present invention has a great feature in the method of constructing the corners when stacking the wall block 100 and forming a living space as shown in FIGS. 4 and 5. The conventional wall block 100 has been performed in a manner of laminating and cutting through only one of the wall blocks 100, and thus has used a method of forming a separate girdle when constructing corners. That is, since the mortar input portion 130 of the wall block 100 bursts naturally at the site where the two walls meet and become corners, the concrete mortar that is poured into the space leaks out. Therefore, in the related art, in order to solve this problem, the wall block 100 forming the corner portion has a method of pouring concrete mortar by forming a separate guff house. However, in order to solve this problem, the wall block 100 according to the present invention has a separate blocking block 300 in the space between the inner heat insulating part 110 and the outer heat insulating part 120 forming the wall block 100. And the auxiliary blocking block 400 is put in place. In this way, the building of the present invention has a feature that the insulation of the corner area is perfect and robust to build the corner area.

In addition, in the present invention, as shown in Figure 3 (b), before the step of placing the concrete mortar of the third step, according to the number of floors of the building, between the reinforcing bars (9) between the mortar input portion 130 of the wall block 100 It is also possible to form a solid wall by arranging). That is, in the case of the conventional block, since no special construction method has been invented, the manufacture of a multi-story structure is being built through a great deal of trial and error. However, in the present invention, in order to provide such a construction method, before placing the mortar (2) on the mortar input portion 130, the reinforcing bar (9) is vertically woven to form a frame, and the concrete mortar (2) between the spaces therebetween. Is to build a perfect and solid structure. Detailed construction method will be described later.

In the present invention, in the step of building the wall surface 5 of the building of the third step, the concrete is laminated to the wall block 100 stacked in the multi-stage in the vertically accurate state with the ground through the vertical adjustment means (60) Follow pouring. For all buildings, it is important to build the wall correctly in the direction parallel to gravity. Therefore, all constructions have been proposed such a construction method to hold the vertical and horizontal. In the conventional method of stacking blocks made by cement mortar vertically to the ground, the blocks are stacked in such a way that the weights are lowered from the top and down on the threads as the layers are stacked one by one through the blocks, and the distance between the threads is accurately adjusted. It was. However, the wall block 100 of the present invention may have a problem that a considerable error occurs when the volume is considerable and one side is twisted. Therefore, the present invention proposes a special vertical adjustment means 60 that can completely control this problem.

10 to 13 show such a vertical adjustment means 60, two embodiments of which are proposed. First, as shown in Figure 10, the vertical adjustment means 60, the cross section is made in the form of a rectangular shape so as to be interviewed to the wall blocks 100 stacked in multiple stages, a plurality of stopper holes penetrated in the left and right direction at regular intervals There is a support (62) formed with a 61, there is a control bar (63) arranged horizontally at regular intervals with the support 62, the control bar (63) and the support (62) at regular intervals There is a connecting bar 64. In addition, there is a coupling stopper 65 is screwed to the front of the wall block 100 through the rotation is inserted into the stopper hole 61, the control bar 63 is fastened to the lower end of the adjustment bar ( There is a height adjusting unit 70 to adjust the vertical angle of the wall by adjusting the support angle of the wall block 100 of the support 62 by raising or lowering 63). Therefore, these are coupled to the wall block 100 is fastened in the shape of a ladder to control the vertical of the wall surface by adjusting the height adjustment unit 70.

That is, the vertical adjusting means used in the present invention sequentially stacks the wall blocks 100 and interviews the support 62 having a rectangular cross section inside or outside the wall blocks 100. The support 62 has a stopper hole 61 formed at regular intervals, and the stopper hole 61 is fitted with a coupling stopper 65 having a screw to rotate the inner insulation portion 110 of the wall block 100. ) Or to the external insulation 120 is firmly fastened. And the support 61 is formed with a connecting bar 64 is horizontally coupled to the support at regular intervals as shown, the end of the connecting bar 64 is a long cylindrical control bar 63 is fastened to have. Therefore, by adjusting the height adjusting unit 70 formed on the end of the control bar 63 to interview the ground, the vertical of the wall surface can be precisely aligned.

To explain in more detail, as shown in Figure 13, when the height adjusting unit 70 is raised, the adjusting bar 63 is raised, the rising of the adjusting bar 63 is connected to the connecting bar 63 integrally fastened By raising it, the support 62 of the other side is inclined to the left side based on the illustrated drawing. On the contrary, if the height adjustment unit 70 is lowered, the adjustment bar 63 is also lowered according to the action thereof, and the downward direction of the adjustment bar 63 describes the connection bar 64 integrally coupled with each other. The support 62 of the other side is operated to be inclined to the right side based on the illustrated drawing. Therefore, through this method of operation it is possible to complete the wall surface in a more precise vertical state before placing the concrete mortar (2) on the wall surface.

Furthermore, the height adjustment unit 70 used in the present invention can be produced in a wide variety of forms. This height adjustment unit 70 should be made of a very simple structure to be used in the construction site, and should have a solid durability as possible by simply adjusting the height. Therefore, discarding the complicated configuration, the height adjustment unit 70 of the present invention proposes a structure that can be used directly in the field.

First, such a height adjusting unit 70 is shown in FIG. 10 as the first embodiment, and shown in FIG. 11 and FIG. 12 as the second embodiment. Therefore, the height adjustment unit 70 of the present invention will be described based on this order.

First, the first embodiment, the height adjustment unit 70, the upper screw 71 is protruded to protrude to the lower end of the control bar 63, the plate-like so as to be in contact with the ground (1) There is a lower screw 73 is fastened to protrude to the upper portion of the jig plate 72 formed in the upper, upper and lower portions of the upper nut 74 and the lower nut so that it can be fitted to both the upper screw 71 and the lower screw 73 (75) is fastened, and the upper and lower nuts (74, 75) integrally formed with an elliptical rotating body (76), consisting of a support bar (77) vertically cutting the central portion of the rotating body (76). Rotation control unit 78 is formed. Therefore, these are combined, the upper screw 71 and the lower screw 73 is inserted into the upper, lower nuts (74, 75) corresponding to each other, forming a screw in the opposite direction to each other the rotation control unit 78 one side Rotating to raise the control bar 63, and when rotated to the other side to narrow the interval between the upper, lower screws (71, 73) is to lower the control bar (63).

That is, once the vertical adjustment means 60 of the ladder shape of the present invention screwed to the wall surface, and rotates the elliptical rotary body 78 of the height adjustment unit 70. In this case, the upper nut 74 and the lower nut 75 are firmly fastened to the center of the rotating body 78, and the upper nut 74 and the lower nut 75 are each of the adjustment bar 63. The upper screw 71 protruding from the end and the lower screw 73 protruding to the upper portion of the jig plate 72 standing on the ground is fitted. Accordingly, when the rotating body 78 is rotated, the rotating body 78 rotates the upper and lower nuts 75, and the upper nut 74 and the lower nut 75 are the upper screw 71 shown. ) And the lower screw 73, so that the upper screw 71 is moved on the upper nut 74. The important point is that the upper screw 71 and the lower screw 73 are formed with screw threads of the opposite direction. Therefore, the rotation of any one direction of the rotation control unit 78 is to move the control rod 73 in the vertical direction. If it rotates to the right side, the upper nut 74 performs the downward action on the upper screw 74, the lower screw 75 inserted into the lower nut 75 in the lower nut 75 Exit and move in a direction to form a wider gap between the upper screw 71 and the lower screw 73. Eventually, by vertically adjusting the angle of the support 62 connected integrally to act to lengthen the length of the control rod 63 as a whole it is possible to accurately adjust the vertical of the block. And by rotating the rotation control unit 78 in the reverse direction to move in the direction of narrowing the gap between the upper, lower screws (71, 73) will be able to adjust the angle of the support 62 in the reverse direction.

Of course, the upper screw 71 and the lower screw 73 of the present invention can be raised or lowered through the action of rotating in the left direction because it is formed to form the thread. That is, the method of forming the upper screw 71 and the lower screw 73 in the opposite direction is important, in particular, whether the left direction is rising or the right direction is different depending on the worker, so as to alternately form Can be used.

In addition, two support bars 62 for separating the upper nut 74 and the lower nut 75 forming the rotation control unit 78 are manufactured in an integrated state with the rotating body 76. The support bar 62 is provided for more robust durability of the rotating body (76). In addition, the inner space portion of the support bar 62 and the rotating body 76 is inserted into the reinforcing bar (9) or ash bar to consider the rotation of the rotating body 76 more effectively.

Next, the height adjusting unit which is the second embodiment of the present invention will be described in detail with reference to FIGS. 11 and 13. The height adjusting unit 70 of the second embodiment, the upper screw 71 is fastened to protrude to the lower end of the control bar 63, jig plate formed in a plate shape to be in contact with the ground (1) ( 72, there is a lower screw 73 is projected to protrude to the top, the upper nut screw 66 and the lower nut screw (67) on the upper and lower inner circumferential surface to be fitted to both the upper screw 71 and the lower screw (73) ) Is formed, and a cylindrical control tube 69 is formed with a rotation control hole 68 that penetrates the outer peripheral surface of the central portion at a 90 ° angle. Therefore, these are combined, the upper screw 71 and the lower screw 73 is inserted into the upper, lower nut screws (66, 67) corresponding to each other, to form a screw in the opposite direction to rotate the control tube 69 Insert the reinforcing bar (9) in the adjustment hole 68 and rotates to one side to raise the control bar (63), and to the other side to narrow the gap between the upper and lower screws (71, 73) control bar (63) It is downward.

This embodiment has a more robust and simpler structure than the first embodiment of FIG. 10 shown, the lower screw 73 and the lower end of the adjusting rod 63 protruding to the top of the jig plate 72 Forming the upper screw 71 protruding into the same as in the first embodiment described above. Only the configuration of the screw fastening to the upper, lower screws (71, 73) is also different from the point of screwing the control tube 69 is also formed in the opposite direction to the threaded. Of course, the control tube 69 is unique in that it maintains the shape of the general pipe, and in the upper and lower ends to form a screw in the opposite direction to each other, the rotation control hole 68 to be penetrated while maintaining a 180 ° angle to each other in the center There is a difference in how they are formed.

However, the height adjusting unit 70 of the second embodiment also maintains the same operation as the first embodiment described above. If the control tube 69 is rotated, the control tube 69 is screwed up and down both ends. The upper screw 71 and the lower screw 73 is moved. In more detail, when the control tube 69 is rotated to the right, the control tube 69 rides down the upper screw 71 and the lower screw 73 protrudes from the jig plate 72 which is interviewed with the ground. Since the screw is fastened state that the lower screw 73 of the jig plate 72 is also long out of its size.

As a result, the end gap between the upper screw 71 and the lower screw 73 sandwiched between the control tube 69 is widened to maintain the length of the control rod 63 as a whole. Accordingly, this operation can maintain the verticality of the wall block 100 by maintaining the operation of tilting the support 62 to the left side based on the illustrated figure as shown in FIG. 13.

In addition, the vertical adjustment means 60 according to the present invention may be firmly fastened to the wall, so that the operator can work on the top of the ladder-shaped vertical adjustment means 60. In addition, it is possible to use not only a means for adjusting the vertical, but also as a shelf to load the material because it can work on a variety of restraint on the vertical adjustment means (60).

Next, the present invention has already been described that may be applied to a multi-storey building. Therefore, the method of forming the bottom surface of the upper layer of the fourth step in the present invention will be described in detail. That is, for example, after completing the wall of one layer, in order to pour the wall of two layers, a bottom surface must be formed on the top of the first layer, and another two layers of wall surface must be formed on the top. In order to perform this operation, in the present invention, as illustrated in FIGS. 8 and 9, the inner insulation portion 110 of the wall block 100, which is the wall surface of the first floor, is cut and vertically raised through the mortar input portion 130. A plurality of horizontal reinforcing bars (9) to the reinforcing bars (9) are arranged at regular intervals by binding to the steel wire, and the concrete mortar (2) is poured on the top to form a bottom plate.

8 and 9 illustrate a view of forming a bottom surface of the multi-story building of the present invention. As shown in this figure, when the construction of the first floor or the upper floor is finished, the inner insulation 110 of the top wall block 100 is cut out to build the next floor. And the reinforcing bar (9) to be fitted into the wall block 100 to be horizontally aligned with the reinforcing bar (9) raised from the lower layer, the reinforcing bar (9) is arranged horizontally to the bottom surface and using concrete mortar (2) By pouring. Of course, before this operation, it is desirable to place the supporting girdle in the lower layer and to arrange the reinforcing bar on the upper part.

Next, the present invention, the method of constructing the ceiling of the fourth step, the ceiling panel 500 is formed seamlessly on the base plate 590 of the slab roof or the triangular transformer roof, the adhesive or cement mortar on the top (2) is applied, and it is preferable to complete the ceiling by bonding the single or the ceiling plate 591 to the adhesive or cementite mortar (2).

While building a building using the wall block 100 of the present invention, there is a case in which the roof is raised on the uppermost floor. As in the related art, any method of raising the roof with a slab roof or a trance structure may be used. That is, the bottom plate 590 to be a ceiling plate is installed, the upper panel is to adhere the ceiling panel 500 formed of foamed foam used in the present invention. At this time, the ceiling panel 500 is not a method of adhesively bonding the ceiling panel and the ceiling panel with a tape as in the prior art, but because the state is firmly folded and bonded to each other through a joint structure, the wind does not leak, and the effect of heat insulation is increased. Can be. Of course, the ceiling using the ceiling panel 500 can be more firmly woven and its durability can be improved.

Then, the configuration and the operation of the ceiling panel 500 used in the present invention will be described in detail with reference to FIGS. 15, 16 and 20. Although the ceiling panel 500 of the present invention is a substantially unitary panel, the four edges of the present invention overlap each other at a predetermined distance from each other, and have overlapping portions 531, 532, 533, and 534, respectively. The upper and lower panels 510 and 520 are formed, and the rear overlapping portion 532 of the upper panel 510 is formed at regular intervals with a rear insertion uneven protrusion 511 protruding around the outer portion. The front overlapping portion 531 of the lower panel 520 is formed by forming a front insertion concave-convex groove portion 521 at a predetermined interval corresponding to the corresponding rear insertion concave-convex portion 511. Therefore, the insertion uneven protrusion 521 of the one ceiling panel 500 overlaps the insertion uneven protrusion 511 to be connected in the front-rear direction.

Ceiling panel 500 of the present invention having a shape through a single mold integrally as if the two panels are overlapped and fastened, the four corners are produced in the form of spaced apart at regular intervals. Therefore, the ceiling panel 500 is exposed four corners so that the other ceiling panel 500 can be superimposed on the portion having only half the thickness. Therefore, in the present invention, the overlapping sites are designated by designating the sites that can be overlapped with each other, and will be described with reference to FIGS. 15, 16 and 20.

First, the one ceiling panel 500 is bonded to the base plate 590 of the ceiling based on FIGS. 15 and 16. Then, the ceiling panel 500 is bonded to the bottom plate 590 while the two overlapping portions 531 and 532 face the sky while the other two overlapping portions face the ceiling panel 500. 15, other ceiling panels 500 are stacked and coupled to each other in the vertical direction, and overlapping portions 531 and 532 overlap each other to form a thickness of the integrated ceiling panel 500. The overlapping portions 531 and 532 overlap the overlapping portions 531 and 532 to form the same thickness as the overlapping portions 531 and 532, but are inserted into the uneven groove 521 formed in the overlapping recesses 521 and 532. ) Is pushed in the left and right directions so that the gap is not extended. The only problem that is heard in the vertical direction is that the overlapping portions 531 and 532 in the vertical direction are not easily heard in the vertical direction because they overlap each other in a state in which they are divided into upper and lower parts.

The present invention proposes a state in which the insertion recessed and projecting portion 511 and the insertion recessed and recessed groove portion 521 are formed to protrude in the overlapping portions, and have a structure corresponding to each other in a predetermined shape. However, the present invention is also possible to the fastening method using the insertion recessed and projecting portion 511 and the insertion recessed and projected groove portion 521 of the other forms shown. That is, the illustrated drawings are only one shape for realizing the present invention, but do not explain all of the present invention. Insertion and protrusion protrusion 511 and the insertion grooves and grooves 521 of the shape capable of realizing the technical idea of the present invention are formed in the overlapping portions (531, 532), all the panels that are connected to each other, connected and coupled to the present invention Included.

And in the present invention is shown as using the ceiling panel 500 attached only to the ceiling, it turns out that it may be used as an external insulation while building a general building.

In addition, in the present invention, only the above-described coupling embodiments in the up and down directions are described above, and the coupling in the left and right directions is unique, and secure coupling is realized. That is, protruding end insertion recessed and projecting portions 513 are formed at the corners of the left side portions 533 and 532 overlapping the left side of the upper panel 510, and the front portions overlapping the right side of the lower panel 520 at the front side 534. 531) At the corners, a concave end insertion recessed groove 523 is formed. Therefore, the other end of the one end panel insertion recessed groove 523 of the ceiling panel 500 is inserted into the other end of the ceiling panel 500 end recess 513 is to be connected to each other in the left, right direction.

As shown in FIG. 15, the ceiling panels 500 are bonded by connecting the ceiling panels 500 in the vertical direction to cover the roof and then connecting the ceiling panels 500 in the left and right directions. At this time, the method used is also formed in the corner portion of the overlapping portion 532, 533 of the rear and left side of the overlapping portion (531, 532, 533, 534) to form a protruding end insertion protrusions 513, Corresponding to the other side is to form the end insertion recessed grooves 523 overlapping each other. When one ceiling panel 500 is covered with a roof, the other ceiling panel 500 is overlapped and covered, and if there is an end insertion recessed part 513 at the corner visible from the already laid ceiling panel 500, the other ceiling panel 500 ) Inserts the end insertion recessed groove 523 into the end insertion recessed protrusion 513. This is because the overlapping state between the overlapping parts (533, 534) is combined, so that all four corners are overlapped to form the same thickness and are subsequently joined.

In the present invention, it is a construction method for constructing a building using various wall blocks 100 as described above. However, the present invention is not unique to this construction method. That is, the wall block 100 which realizes this construction method also has a feature. Therefore, look at the configuration of the wall block 100 used in the present invention and its operation.

The present invention, in the building styrofoam block, while connecting the inner and outer insulation portion 110 and the outer insulation portion 120 and the inner insulation portion 110 and the outer insulation portion 120 which are disposed equally spaced in the inner, outer A plurality of connecting rods 140 forming the mortar input portion 130 in the space between the heat insulating parts 110 and 120, and the upper and lower surfaces of the inner and outer heat insulating parts 110 and 120 are coupled to correspond to each other In the styrofoam block in which the groove 111 and the coupling protrusion 112 are formed, the concave-convex surface has a tapered surface 151 having a tapered side surface at regular intervals on the surfaces of the inner insulation portion 110 and the outer insulation portion 120. There are a plurality of sound absorbing holes 160 are formed at a predetermined interval to form a mold suction groove 150, so as not to penetrate from the lower end to the upper end of the outer insulation 120. Therefore, these are combined with the concrete mortar or cement mortar (2) to the concave-convex suction groove 150 to be able to easily close the outer wall, and through the suction groove 150 to expand the production and sound absorption of the product It is.

In addition, according to the present invention, the outer heat insulating portion 120 of the wall block 100, so as to have a thickness width of 1-4 times compared to the thickness width of the inner heat insulating portion (110).

That is, two types of wall blocks 100 are illustrated in FIGS. 1 and 17 to 19. Both are common to all the components, but the thickness of the external insulation 120 is different. That is, the thickness of one external insulation unit 120 is shown to be about twice as thick as the other. In the present invention, while manufacturing the wall block 100 having the outer heat insulating portion 120, the inner heat insulating portion 110 and the mortar input portion 130, the outer heat insulating portion 120 or the inner heat insulating portion 110 It is possible to build a variety of buildings by adjusting the thickness. By adjusting the thickness width, the blocks are produced with different thermal insulation properties, and they are applied to various environments as needed. The smaller width of the block can be used as the inner wall of the building, and can also be used as the outer wall of the small building.

And since the description of the basic wall block 100 of the present invention has already been described in the above-described construction method detailed description is avoided. When forming the corners of the building by only stacking the wall block 100, the blocking block 300 and the auxiliary blocking block 400 that can be used to fit the wall block 100 will be described.

In the present invention, the upper and lower surfaces of the inner insulation portion 110 and the outer insulation portion 120 on the upper surface and the lower surface of the mortar input portion 130 between the inner insulation portion 110 and the outer insulation portion 120. A series of panel coupling grooves 311 and panel coupling protrusions 312 are formed to correspond to the coupling grooves 111 and the coupling protrusions 112 formed on the left and right sides, and the inner insulation portion 110 and the outer insulation on left and right sides. Block blocking block 300 having a protruding guider 320 corresponding to a cross section of the uneven suction groove 150 having a tapered surface 151 having a tapered side at regular intervals on the surface of the part 120. ) And fasten the corners of the building wall.

That is, as shown in 4 and 5 in the drawing, when constructing the corner portion of the building using the wall block 100 of the present invention always at one end of the mortar input portion 130 is coupled to the open state Concrete mortar could not be placed on the wall block 100 in particular. Only install a separate giraffe surrounding the corner portion, and the concrete mortar was poured after preventing the concrete mortar from leaking to the outside. However, in the present invention, this problem is completely solved by a simple method of inserting the blocking block 300 and the auxiliary blocking block 400 into the wall block 100.

The blocking block 300 is inserted into the mortar input part 130 of the wall block 100 to be installed at the outermost corner portion as shown in FIG. 17. The blocking block 300 is inserted into the suction groove 150 formed on the surfaces of the inner heat insulating part 110 and the outer heat insulating part 120. Since the guider 320 having the same to similar cross-sectional shape corresponding to the suction groove 150 is formed on the side of the blocking block 100, the guide block 320 is fastened by sliding the guider 320. Then, the mortar input portion 130 of the outermost wall block 100 forming the corner portion of the building is easy to inject the concrete mortar (2) to maintain a closed state. In addition, the blocking block 300 may be coupled to each other, and the auxiliary blocking block 400 may be coupled to an upper portion of the connecting unit 140 of the mortar input unit 130.

That is, as shown in FIGS. 4 and 17 to 19, the auxiliary blocking block 400, which is another block that can be overlapped and covered on the upper and lower portions of the connecting table 140 forming the mortar input 130 of the wall block 100, is illustrated. ) To insert and combine. This auxiliary blocking block 400 is also shown, as the block guider 420 is formed on the side is inserted into the suction groove 150 is formed in the connecting portion 140, the upper coupling. The auxiliary blocking block 400 may be inserted into and coupled to the upper and lower portions of the wall block 100, respectively.

Then, the configuration of the auxiliary blocking block 400 of the present invention will be described.

In the present invention, the connecting groove 140 connecting the inner insulation portion 110 and the outer insulation portion 120, the coupling groove formed on the upper surface of the inner insulation portion 110 and the outer insulation portion 120 on the upper surface ( A series of block coupling grooves 411 are formed to correspond to 111, and on the left and right sides, tapered surfaces 151 having side surfaces tapered at regular intervals on the surfaces of the inner insulation portion 110 and the outer insulation portion 120. And a protruding block guider 420 corresponding to the end face of the uneven suction groove 150 having the end face corresponding to the sliding face 148 having the cross section of the upper and lower beams of the connecting table 140 to be fitted. A block-shaped auxiliary blocking block 400 having a corresponding surface 430 of the upper and lower beams is fitted and fastened, and the edge of the building wall is constructed.

Finally, the configuration of the above-described ceiling panel is described in the present invention. That is, in the architectural styrofoam ceiling panel 500, although the panel is a substantially unitary, the four edges overlap each other in a position apart from each other at regular intervals, and overlap each other in the front, rear, left, and right directions (531, 532, 533, 534). The upper panel and the lower panel 510 and 520 are formed, and the rear overlapping part 532 of the upper panel 510 is formed at regular intervals with a rear insertion uneven protrusion 511 protruding around the outer part. The front overlapping portion 531 of the lower panel 520 corresponds to the corresponding rear insertion recessed protrusion 511 to form a front insertion recessed groove 521 to which the protrusion may be inserted at a predetermined interval. Therefore, the insertion uneven protrusion 521 of the one ceiling panel 500 overlaps the insertion uneven protrusion 511 to be connected in the front-rear direction.

A protruding end insertion concave-convex portion 513 is formed at the corner of the left side of the upper plate and the overlapping portions 533 and 532, and concave end insertion concave is formed at the corner of the corresponding lower plate right side and the front of the concave portion 534, 531. Forming a groove portion 523; One end insertion recessed groove 523 of one ceiling panel 500 is inserted into the other end end recessed protrusion 513 of the other ceiling panel 500 to be connected to each other in the left and right directions.

The ceiling panel 500 of the present invention has been described in detail in the above-described construction method. Therefore, detailed explanation is avoided here.

1 is a view showing the basic construction for constructing a wall block according to the present invention,

2 is a view showing another embodiment of the foundation concrete construction according to the present invention,

3 is a view showing a cross-sectional view of the foundation concrete, according to the present invention,

4 is a view showing a method for constructing a corner of a building according to the present invention;

5 is a view showing a main part according to the present invention,

6 is a view showing the wall surface of the building constructed in accordance with the present invention,

7 is a cross-sectional view showing a wall section of the building according to the present invention;

8 is a view showing a method used when constructing a multi-storey building according to the present invention;

Figure 9 is a side view showing a multi-layer structure installation state according to the present invention,

10 is a view showing a vertical adjustment means according to the present invention,

11 is a view showing another embodiment of the vertical adjustment means according to the present invention,

12 is a view showing a cross section of the vertical adjustment means of FIG. 11 according to the present invention;

13 is a view showing an adjustment form of the vertical adjustment means according to the present invention,

14 is a view showing a state in which the concrete mortar is applied to the suction groove of the wall block according to the present invention,

15 is a view showing a state in which the ceiling panel is constructed, according to the present invention;

16 is a main view showing the construction of the ceiling panel according to the present invention,

17 is a view showing the appearance of a wall block, a blocking block and an auxiliary blocking block according to the present invention;

18 is a sectional view and a hexahed view of a wall block according to the present invention;

19 is a view showing another embodiment of the wall block and a sectional view of the wall block according to the present invention;

20 is a sectional view and a six-dimensional view of the ceiling block,

21 is a perspective view of a conventional block,

22 is a bottom view of a conventional block.

<Brief description of the major symbols in the drawing shown>

One; Floor 2; Concrete mortar

3; Foundation concrete layer 5; Wall panel

60; Vertical adjustment means 61; Stopper Ball

62; Support 63; Control bar

64; Connecting bar 65; Combined stopper

66; Upper nut screw 67; Lower Nut Screw

68; Adjuster 69; Regulator

70; Height adjusting unit 71; Upper screw

72; Jig plate 73; Lower screw

74; Upper nut 75; Lower nut

76; Rotating body 77; Support bar

78; Rotation control unit 100; Wall block

110; Internal insulation 111; Combined groove

112; Coupling protrusion 120; External insulation

130; Mortar input 140; Connecting rod

150; Suction groove 151; Tapered face

160; Sound-absorbing hole 300; Blocking Block

311; Panel coupling groove 312; Panel Joining Projection

320; Guider 400; Assistance Block

500; Ceiling panels

Claims (23)

In the building construction method, First step: leveling the ground (1) evenly, the step of foundation work to compact the floor; The second step: stacking and arranging the wall block 100 of the foam insulation styrofoam of the high insulation sound insulation to the top of the foundation floor; The third step: building a concrete wall (5) of the building by pouring concrete mortar (2) on the mortar input portion 130 of the wall block (100); The fourth step: constructing the ceiling 501 using the ceiling panel 500 of the high-insulation foam styrofoam having a coupling structure or the bottom surface for forming the upper layer according to the building; Green house construction method using a high-insulation soundproof foam styrofoam block, characterized in that the construction to block the emission. The method according to claim 1, The foundation work to chop the floor, Green house construction method using a high-insulation soundproof foamed foam foam block, characterized in that the basement layer is formed, and can be carried out in a post-process. The method according to claim 1, The foundation work, Green house construction method using a foam insulation styrofoam block of high insulation sound insulation, characterized in that the ground concrete (1) to form a foundation concrete layer on the floor concrete. The method according to claim 1, The foundation work, A ground foundation concrete layer (3) is placed on the ground (1), and a wall block construction plate (80) is installed on the foundation concrete layer (3), and the wall block construction board (80) has one wall block ( Green house construction method using a high-insulation soundproof foam styrofoam block, characterized in that the construction to insert 100). The method according to claim 4, The wall block construction plate 80, The cross section is formed of a bottom plate 81 and the left and right side plates 82 in a "c" shape, The left and right side plates 82 form a wedge-shaped press hook 83 that is torn inwardly at regular intervals, The bottom plate 81 is configured to include a plurality of vertical through-holes 84 are formed at regular intervals, the wall block 100 is inserted into the space portion 85 of the left and right side plates 82. The green house construction method using a foam insulation styrofoam block of high insulation soundproof, characterized in that the fastening of the side through the pressure hook (83) to ensure that the walls of the building perfectly supported. The method according to claim 5, The method of installing the wall block construction plate 80 on the basic concrete layer 3, The level (a) of placing the wall block construction plate 80 on the top of the foundation concrete layer 3, the side plate 82 of the wall block construction plate 80 on the foundation concrete layer 3 Construction method selected from the level (b) of being buried so as to be locked, the level (c) so that the side plate 82 of the wall block construction plate 80 is completely embedded in the base concrete layer (3) Green house construction method using a high-insulation soundproof foam styrofoam block characterized in that it can be used. The method according to claim 1, The wall block 100, Between the inner and outer insulation portions 110 and 120 while connecting the inner insulation portion 110 and the outer insulation portion 120 and the inner insulation portion 110 and the outer insulation portion 120 are equilibrated and spaced apart. A plurality of connecting rods 140 forming a mortar input portion 130 in the space, and coupling grooves 111 and coupling protrusions 112 to be engaged with each other on the upper and lower surfaces of the inner and outer insulation parts 110 and 120. In the styrofoam block formed with Forming a concave-convex suction groove 150 having a tapered surface 151 having a side tapered at regular intervals on the surfaces of the inner heat insulating part 110, the outer heat insulating part 120, and the connecting table 140; A plurality of sound absorbing holes 160 formed at a predetermined interval so as not to penetrate from the lower end to the upper end of the outer heat insulating part 120; Is coupled to the concrete mortar or cement mortar (2) to the concave-convex suction groove 150 to easily finish the outer wall, and to expand the functionality of the production and sound absorption of the product through the suction groove 150 Green house construction method using foam insulation styrofoam block of high insulation sound insulation. The method according to claim 7, When constructing the corners of the wall surface 5 of the building, the foam foam block block 300 is fastened to the mortar input portion 130 at one end of the wall block 100, and then to the upper portion of the connecting table 140. Green house construction method using the foam insulation styrofoam block of the high insulation sound insulation, characterized in that for fastening the auxiliary blocking block 400 including the connecting table (140). The method according to claim 1, Before the step of pouring the concrete mortar of the third step, According to the number of floors of the building, the green house construction using a high-insulation soundproof foam styrofoam block, characterized in that to form a rigid wall between the reinforcing bars (9) between the mortar input portion 130 of the wall block (100). Way. The method according to claim 1, In the stage of building the wall surface 5 of the building of the third stage, Green house construction method using a high-insulation soundproof foam styrofoam block, characterized in that the concrete is poured after laminating in the vertically perpendicular state to the ground through the vertical adjustment means 60 to the multi-layered wall block 100 . The method according to claim 10, The vertical adjustment means 60, A support 62 made of a rectangular shape so as to be interviewed by the wall blocks 100 stacked in multiple stages, and having a plurality of stopper holes 61 penetrated in a left and right direction at regular intervals; Adjusting bar (63) arranged horizontally at regular intervals with the support (62); A connecting bar 64 which combines the control bar 63 and the support 62 at regular intervals; A coupling stopper 65 inserted into the stopper hole 61 and screwed to the front surface of the wall block 100 through rotation; It is fastened to the lower end of the control bar 63 by adjusting the support angle of the wall block 100 of the support 62 by raising or lowering the control bar 63 to rotate to adjust the vertical state of the wall surface. Height adjusting unit 70; It is coupled to the wall block 100 is fastened in the shape of a ladder to the high-insulation soundproof foam foam foam characterized in that the vertical control of the wall through the adjustment of the height adjustment unit 70 to accurately control Green house construction method using. The method according to claim 11, The height adjustment unit 70, An upper screw 71 protruding from the lower end of the control bar 63; A lower screw 73 fastened to protrude upward from the jig plate 72 formed in a plate shape so as to be in contact with the ground 1; The upper nut 74 and the lower nut 75 are fastened to the upper and lower portions so that the upper screw 71 and the lower screw 73 can be fitted to the upper screw 71 and the lower screw 73. Forming a rotating body 76, the rotation control portion 78 consisting of a support bar 77 vertically split the center of the rotating body 76; coupled, the upper screw 71 and the lower screw ( 73 is inserted into the upper and lower nuts 74 and 75 corresponding to each other, and when the rotation control unit 78 is rotated to one side by forming screws in opposite directions, the control bar 63 is raised to the other side. The green house construction method using the foam foam styrofoam block of the high insulation soundproof, characterized in that by lowering the gap between the upper and lower screws (71, 73) to lower the adjustment bar (63). The method according to claim 11, The height adjustment unit 70, An upper screw 71 protruding from the lower end of the control bar 63; A lower screw 73 fastened to protrude upward from the jig plate 72 formed in a plate shape so as to be in contact with the ground 1; The upper nut screw 66 and the lower nut screw 67 are formed on the upper and lower inner circumferential surfaces of the upper screw 71 and the lower screw 73 so as to be fitted into both the upper screw 71 and the lower screw 73, and the rotation adjustment is performed at 90 ° through the outer peripheral surface of the central portion thereof. Cylindrical control tube 69 formed with a ball 68; is coupled, the upper screw 71 and the lower screw 73 is inserted into the upper, lower nut screws (66, 67) corresponding to each other in the opposite direction If the reinforcing bar (9) is inserted into the rotation control hole (68) of the control tube (69) and rotates to one side to raise the control bar (63), and to the other side to rotate the upper and lower screws (71). , 73) green house construction method using a foam insulation styrofoam block of high insulation soundproof, characterized in that to lower the adjustment bar (63). The method according to claim 1, The method of forming the bottom surface of the upper layer of the fourth step, The internal insulation 110 of the wall block 100, which is the wall surface of the first floor, is cut, and a plurality of horizontal rebars 9 are tied to the vertical reinforcing bars 9 vertically raised through the mortar input unit 130, and tied with iron wires. Arranged at intervals, the green house construction method using a high-insulation soundproof foam styrofoam block characterized in that the bottom plate is formed by pouring concrete mortar (2) on the top. The method according to claim 1, The method of constructing the ceiling of the fourth stage, A ceiling panel 500 is formed on the slab roof or the base plate 590 of the bona triangular roof without any gaps, and an adhesive or cemental mortar (2) is applied to the upper part of the slab roof or the bona triangular roof. Green house construction method using a high-insulation soundproof foam styrofoam block characterized in that the ceiling is completed by combining a single or ceiling plate (591). The method according to claim 15, The ceiling panel 500, It is a substantially unitary panel, but the four edges of each other overlap each other in a spaced apart position, with the upper and lower panels 510, 520 having portions 531, 532, 533, 534 overlapping in the front, rear, left, and right directions, respectively. Done; The rear overlapping portion 532 of the upper panel 510 is formed at regular intervals with a rear insertion uneven protrusion 511 protruding around the outer portion; The front overlapping portion 531 of the lower panel 520 forms a front insertion concave-convex groove portion 521 at a predetermined interval corresponding to the corresponding rear insertion concave-convex portion 511 to be inserted therein; Green house construction method using a high-insulation soundproof foam styrofoam block, characterized in that the insertion uneven groove portion 521 of the one ceiling panel 500 overlaps the insertion uneven protrusion 511 in the front and rear directions. The method according to claim 16, A protruding end inserting convex-convex portion 513 is formed at a corner of the portion 533 and 532 which overlaps with the left side of the upper panel 510; A concave end insertion recessed groove 523 is formed at the corners of the lower portions 534 and 531 which overlap the right side of the lower panel 520; One end insertion recessed groove 523 of one ceiling panel 500 is inserted into the other end of the ceiling panel 500, the recessed projection 513 is characterized in that it can be connected to each other in the left, right direction overlapping Green House construction method using foamed Styrofoam block with insulation sound insulation. In construction styrofoam block, Between the inner and outer insulation portions 110 and 120 while connecting the inner insulation portion 110 and the outer insulation portion 120 and the inner insulation portion 110 and the outer insulation portion 120 are equilibrated and spaced apart. A plurality of connecting rods 140 forming a mortar input portion 130 in the space, and coupling grooves 111 and coupling protrusions 112 to be engaged with each other on the upper and lower surfaces of the inner and outer insulation parts 110 and 120. In the styrofoam block formed with A concave-convex suction groove 150 having a tapered surface 151 having a side tapered at regular intervals on the surfaces of the inner heat insulating part 110 and the outer heat insulating part 120; A plurality of sound absorbing holes 160 formed at a predetermined interval so as not to penetrate from the lower end to the upper end of the outer heat insulating part 120; Is coupled to the concrete mortar or cement mortar (2) to the concave-convex suction groove 150 to easily finish the outer wall, and to expand the functionality of the production and sound absorption of the product through the suction groove 150 The high insulation soundproof foam styrofoam block characterized by the above-mentioned. The method according to claim 18, The outer insulation unit 120 of the wall block 100, High-insulation soundproof foam foam foam characterized in that it has a thickness width of 1-4 times compared to the thickness width of the inner insulation (110). The method according to claim 19, Mortar input portion 130 between the inner insulation portion 110 and the outer insulation portion 120, A series of panel coupling grooves 311 and panel coupling corresponding to the coupling grooves 111 and the coupling protrusions 112 formed on the upper and lower surfaces of the inner and outer insulation parts 110 and 120 on the upper and lower surfaces. Forming a projection 312; On the left and right sides, protruding portions corresponding to the cross-section of the uneven suction groove 150 having a tapered surface 151 having side surfaces tapered at regular intervals on the surfaces of the inner insulation portion 110 and the outer insulation portion 120. High-insulation soundproof foamed foam foam block, characterized in that by inserting the panel block blocking block 300 formed with the guider 320 and the construction of the building wall edge. The method of claim 19, In the connection table 140 connecting the inner insulation 110 and the outer insulation 120, A series of block coupling grooves 411 are formed on an upper surface of the inner insulation part 110 and a coupling groove 111 formed on the upper surface of the outer insulation part 120; On the left and right sides, protruding portions corresponding to the cross-section of the uneven suction groove 150 having a tapered surface 151 having side surfaces tapered at regular intervals on the surfaces of the inner insulation portion 110 and the outer insulation portion 120. Forming a block guider 420; The bottom surface is fitted with a block-shaped auxiliary blocking block 400 formed with a corresponding surface 430 of the upper and lower light corresponding to the sliding surface 148 having a cross section of the upper and lower light of the connecting table 140 to be fitted, and the edge of the building wall. High-insulation soundproof foamed styrofoam block, characterized in that the construction of the site. In construction styrofoam ceiling panel, It is a substantially unitary panel, but the four edges of each other overlap each other in a spaced apart position, with upper and lower panels 510, 520 having portions 531, 532, 533, 534 overlapping in the front, rear, left, and right directions, respectively. Done; The rear overlapping portion 532 of the upper panel 510 is formed at regular intervals with a rear insertion uneven protrusion 511 protruding around the outer portion; The front overlapping portion 531 of the lower panel 520 forms a front insertion recessed groove 521 at a predetermined interval corresponding to the corresponding rear insertion recessed protrusion 511 to be inserted therein; High insulation insulation foam styrofoam ceiling panel, characterized in that the insertion uneven groove portion 521 of the one ceiling panel 500 overlaps the insertion uneven protrusion 511 in the front and rear directions. The method according to claim 22, A protruding end inserting convex-convex portion 513 is formed at a corner of a portion 533 and 532 which overlaps with the left side of the upper plate in the rear; At the corners of the corresponding lower plate right side and the front overlapping portions 534 and 531, a concave end insertion recessed groove 523 is formed; One end insertion recessed groove 523 of one ceiling panel 500 is inserted into the other end of the ceiling panel 500, the recessed projection 513 is characterized in that it can be connected to each other in the left, right direction overlapping Insulated, foamed Styrofoam ceiling panels.

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