JP5164190B2 - Lightweight thermal insulation block for construction and its construction method - Google Patents

Description

  The present invention relates to a lightweight insulating block for construction and a construction method thereof, and more specifically, by providing a finishing material to a block main body made of a lightweight foamed synthetic resin and finishing the inner and outer walls of a building, thereby reducing the material cost. The present invention relates to a lightweight building heat insulation block that can simplify the block construction process as well as reduce the energy consumption and reduce the energy consumption by 80 to 90% from an existing house, and a construction method thereof.

  In general, blocks used for wall construction are mainly used for construction by blending sand, cement and additives in a certain ratio, then putting them in a certain mold and curing them. It is often used for simple construction such as partitioning. These blocks were piled up while adjoining adjacent blocks using mortar to construct a desired wall.

  In this connection, cement blocks and red bricks are known in Korea Public Utility Model No. 1992-15206 and Korean Registered Utility Model No. 346650, etc. When it is constructed by laminating on the body, a separate heat insulating material must be installed as a hollow wall on the external wall body, and it has the feature of performing the finishing process inside and outside.

  The conventional techniques as described above have a problem that workability is deteriorated, and internal partitioning work must be accompanied by a finishing process after lamination. In addition, since the entire block is made of cement mortar, not only the cost of manufacturing the block is high, but in the case of a multi-layer building, the problem of reducing the durability of the building due to the weight of the block during wall construction, In order to cope with this, there is a disadvantage that the structure of the frame must be reinforced.

Building lightweight insulating block of the present invention made to solve the above SL problems is the insulation block forming the internal and external wall by stacking a plurality in a direction perpendicular to the underlying bottom surface of the building, thermal insulation blocks Made of foamed synthetic resin, has a coupling protrusion on its upper surface and a coupling groove laminated by fitting the coupling protrusion on its lower surface so that no gap is generated during lamination, and a part of the lower part of one side of the heat insulation block Cut into an 'L' shape and connect one of the following auxiliary blocks or assembly blocks to the crossing block in which a circular fitting groove is formed in the upper part of the cut member. And
Here, the auxiliary block is formed by cutting a part of one side upper part of the heat insulating block into an 'L' shape and forming a circular fitting protrusion on the upper part of the cut member. A “U” -shaped cutting groove is formed at the center upper portion of the heat insulation block, and a circular fitting protrusion is formed at the upper portion of the cut member.

  The lightweight insulation block for buildings and the construction method thereof according to the present invention not only reduce the material cost by providing finishing materials on the block made of foamed synthetic resin and finishing the inner and outer walls of the building, but also the block construction process. It has the effect of simplifying and reducing energy consumption by 80 to 90% compared to existing houses, has excellent heat insulation, prevents condensation and increases air conditioning efficiency, and is light and does not reduce the durability of buildings due to load There is.

It is the perspective view which showed the lightweight insulation block for construction of 1st Embodiment by this invention. It is the perspective view which showed another example of the lightweight insulation block for buildings of 1st Embodiment by this invention. It is a right view of the lightweight insulation block for buildings by FIG. It is the perspective view which showed further another example of the lightweight insulation block for buildings of 1st Embodiment by this invention. It is the perspective view which showed further another example of the lightweight insulation block for buildings of 1st Embodiment by this invention. It is a left view of the lightweight insulation block for buildings by FIG. It is the front view, side view, and top view which showed the various examples of the lightweight insulation block for buildings by FIG. It is the perspective view which showed the lightweight heat insulation block for construction of 2nd Embodiment by this invention. It is sectional drawing of the AA line of FIG. It is the isolation | separation perspective view which showed the lightweight insulation block for construction of 2nd Embodiment by this invention. It is the use condition figure which showed the lightweight heat insulation block for construction of 2nd Embodiment by this invention. It is the perspective view which showed the lightweight heat insulation block for construction of 3rd Embodiment by this invention. It is the side view which showed the lightweight heat insulation block for construction of 3rd Embodiment by this invention. It is the isolation | separation perspective view which showed the lightweight insulation block for construction of 3rd Embodiment by this invention. It is the perspective view which showed the lightweight heat insulation block for construction of 4th Embodiment by this invention. It is sectional drawing of the BB line of FIG. It is the isolation | separation perspective view which showed the lightweight insulation block for construction of 4th Embodiment by this invention. It is the perspective view which showed the lightweight heat insulation block for construction of 5th Embodiment by this invention. It is the side view which showed the lightweight heat insulation block for construction of 5th Embodiment by this invention. It is the isolation | separation perspective view which showed the lightweight heat insulation block for construction of 5th Embodiment by this invention. It is drawing which shows the construction method of the lightweight insulation block for buildings by this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view showing a lightweight construction heat insulation block according to the first embodiment of the present invention, and FIG. 2 is a perspective view showing another example of the construction lightweight heat insulation block according to the first embodiment of the present invention. FIG. 3 is a right side view of the building lightweight heat insulation block according to FIG. 2, and FIG. 4 is a perspective view showing still another example of the building light insulation block according to the first embodiment of the present invention. FIG. 5 is a perspective view showing still another example of the building lightweight heat insulation block according to the first embodiment of the present invention, and FIG. 6 is a left side view of the building light insulation block according to FIG. FIG. 7 is a front view, a side view, and a plan view showing various examples of the lightweight insulation block for building according to FIG.

  As shown in FIGS. 1 to 7, the present invention relates to a heat insulating block that is constructed by being laminated on the inner and outer walls of a building, and the heat insulating block 1 is made of a foamed synthetic resin. In order to prevent moisture permeation, a coupling protrusion 11 is formed on the upper surface, a coupling groove 12 corresponding to the coupling protrusion 11 is formed on the lower surface, and a protrusion 13 and a concave groove 14 are formed on the front and back surfaces. Is to be formed.

Auxiliary block 6 is formed in the same shape as the insulation block 1, by cutting the part of the upper portion to the 'L' shaped form one side, on top of the cut member circular fitting projection 15 is formed, characterized the kite.
Assembling block, the insulation in the central upper part of the block 1 to form a cut groove 17 in the shape of 'U', and said the top of the cut member circular fitting projection 15 is formed .

Further, the auxiliary block 6 or the assembly block in which the fitting protrusion 15 is formed is formed with a coupling protrusion 11 which is bent at one end and extending on the upper surface, and a coupling groove 12 is formed on the lower surface thereof. and protrusions 13 and the concave groove portion 14 and a portion of one side bottom of the insulation block 1 formed by cutting the 'L' shaped form on the back, the upper portion of the cut member circular fitting groove 16 cross block 7 formed is characterized Rukoto coupled longitudinally or at right angles to each other.

  Further, the block is characterized in that a vertical coupling groove 18 is formed in a vertical direction on one lower side of the bottom surface, and the coupling projections 11 of the block are vertically sandwiched and coupled.

  In addition, the protrusions 13 formed on the front and back surfaces of the block are formed in a wedge shape so that the protrusions 13 become wider toward the outside and fill spaces are formed on both side surfaces thereof.

  Further, the protrusions 13 and the concave grooves 14 formed on the front surface and the back surface of the block are formed in a lattice shape.

  Further, the block is formed with a plurality of concave groove portions 14 that divide and divide the front surface or the rear surface thereof, and the finishing material is supported and fixed to the front surface or the rear surface while being filled in the concave groove portions. It is characterized by.

  In addition, an adhesive filling groove 111 is formed in the upper portion of the coupling protrusion 11 of the heat insulating block 1 in the longitudinal direction so as to be filled with an adhesive for a firm coupling.

  Further, a wire mesh (not shown) is formed by insertion molding in the heat insulating block 1 in order to increase the bonding force and to reinforce the masonry wall body in the vertical and horizontal directions.

  In addition, a filling groove 19 is formed in the lateral direction at the corners of the front plate and the back plate of the heat insulating block 1.

  A filling groove is formed in each corner of the heat insulation block 1 in the longitudinal direction, and the laminated heat insulation blocks are fixed to each other by filling the filling groove with a filler.

  The filler may be any one of an adhesive, cement, gypsum, iron, plastic, and wood fastener.

  Further, a fastening groove 112 is formed so as to be fastened by fastening metal fittings at both upper ends of the coupling protrusions 11 of the heat insulating blocks 1.

  Also, a finishing material can be formed on the front and back surfaces of the block, and the finishing material is any one of cement, plaster, iron panel, wallpaper, ocher, and cement mixed with stone powder. It is characterized in that various hues are added and used.

  The thicknesses of the lines and the sizes of the components illustrated in the drawings may be exaggerated for clarity of explanation and convenience. Moreover, the term mentioned later is a term defined in consideration of the function in this invention, and this may change with a user, an operator's intention, or a custom. Therefore, the definitions for these terms must be made based on the overall content of this specification.

  Also, the following embodiments are not intended to limit the scope of rights of the present invention, but are merely presented by way of example, and there may be various embodiments embodied through this technical idea.

  As shown in FIG. 1, the present invention is a heat insulating block that is constructed by being laminated on the inner and outer walls of a building, and the heat insulating block 1 is made of a foamed synthetic resin, so that a gap is not generated at the time of lamination. The coupling protrusion 11 is formed, the coupling groove 12 corresponding to the coupling protrusion 11 is formed on the lower surface thereof, and the protruding portion 13 and the concave groove portion 14 are formed on the front surface and the rear surface.

  At this time, it is shown that the coupling protrusion 11 of the heat insulation block 1 is formed in a single shape and is bonded and laminated by the coupling groove 12 corresponding to the coupling protrusion 11, but is not limited thereto. Instead, the coupling protrusion 11 and the coupling groove 12 can be formed in various shapes such as a triangle, a square, and a semicircle.

  The heat insulation block 1 has a coupling protrusion 11 formed on the upper surface thereof, and a coupling groove 12 corresponding to the coupling protrusion 11 is formed on the lower surface of the heat insulation block 1 to connect the heat insulation block 1 in the vertical direction.

  The heat insulating block 1 is made of a foamed synthetic resin, that is, foamed polystyrene, and can be recycled as well as reducing the material cost.

  As shown in FIG. 2, the auxiliary block 6 is made of a foamed synthetic resin like the heat insulating block 1 in FIG. 1, and a coupling protrusion 11 is formed on the upper surface thereof so as not to generate a gap during lamination. A coupling groove 12 corresponding to the coupling protrusion 11 is formed on the lower surface, and a protruding portion 13 and a concave groove portion 14 are formed on the front surface and the rear surface.

As shown in FIG. 5, the intersection block 7 has a coupling protrusion 11 formed on its upper surface so that one end thereof is vertically bent into an “L” shape, and a coupling groove 12 is formed on its lower surface. The protrusion 13 and the groove 14 are formed on the front and back surfaces.

Further, a part of the lower part is cut into an “L” shape, and a circular fitting groove 16 is formed on the upper part of the cut member.

Thus the auxiliary block 6 the cutting end of the 'L' shaped are formed as shown in FIG. 2, the assembly blocks cut grooves 17 of shape of the upper center 'co' is formed in FIG. 4 5 and 6 are combined with the intersecting block 7 formed with the fitting groove 16 to form a ' T' - shaped block combination or a 'ten'- shaped block combination. Can be combined into various shapes.

  Further, one side surface of the cross block 7 with the fitting groove 16 is rounded, and the fitting groove 16 is joined to the fitting protrusion 15 to be rotated and molded and manufactured so that the coupling angle can be adjusted. The heat insulation block 1 can also be connected and used.

  As shown in FIG. 7, the heat insulating block 1 is formed with a plurality of concave grooves 14 that divide and divide the front surface or the rear surface, and supports the front or back surface while filling the concave grooves 14 with the finishing material. Fix it. This is because the cement mortar flows from the front surface or the back surface of the heat insulation block 1 in the process of applying and curing cement mortar used as the finishing material (not shown), which will be described later, to the heat insulation block 1. The cement mortar is firmly fixed while supporting the applied cement mortar while being filled in the plurality of concave groove portions 14 while preventing the finishing material from being peeled off after curing.

  Then, a filling groove 19 is formed at each corner of the heat insulating block 1 in the longitudinal direction, and the filling groove 19 of the block is filled with a filler so that the laminated heat insulating blocks 1 are fixed to each other. By doing so, the stacked blocks are fixed to each other in the longitudinal direction as well as the upward and downward directions.

  On the other hand, the finishing material can be fixed to the front or back surface of the heat insulating block 1 using cement mortar as described above, and a cement panel formed by hardening the cement mortar is used. Various colors can be added to panels, wallpaper, ocher, cement mixed with stone powder, and the like, and fixed to the front or back of the heat insulation block 1.

  The finishing material is not limited to cement mixed with the above-mentioned cement mortar, plaster, iron panel, wallpaper, ocher, and stone powder, and is attached to the front or back surface of the heat insulating block 1 and the heat insulating block. Any one can be used as long as it can protect 1 and at the same time create aesthetics.

  The filler is cement mortar, adhesive, wood, synthetic resin material, iron or plastic fastener, plaster, etc., and can add aesthetics by adding designs and colors to the fillers listed above. desirable.

  Explaining the installation process of the lightweight heat insulating block for building according to the present invention, first, in order to finish the inner and outer wall surfaces of the building, the heat insulating block 1 was fixed to the paper surface so as to be in contact with the adjacent positions of the inner and outer wall surfaces and the wall surface. Thereafter, the coupling protrusions 11 provided on the upper surface of the heat insulation block 1 are fitted with the coupling grooves 12 provided on the lower surface of the other heat insulation block 1, and the heat insulation blocks 1 are sequentially laminated in the upward and longitudinal directions. By filling the filling groove 19 with a filler and fixing it with an adhesive, the laminated heat insulating blocks 1 are mutually fixed in the vertical direction and the longitudinal direction.

In addition, the block coupling portion may be coupled in various shapes such as an “ L” -shaped block coupling body, a “ T” -shaped block coupling body, or a “ten” -shaped block coupling body. When a coupling angle is required, one side surface with the fitting groove of the heat insulating block 1 is rounded, and the fitting angle between the fitting groove 16 and the fitting protrusion 15 is adjusted and stacked.

  FIG. 8 is a perspective view showing a lightweight construction heat insulation block according to a second embodiment of the present invention, FIG. 9 is a cross-sectional view taken along line AA of FIG. 8, and FIG. It is the isolation | separation perspective view which showed the lightweight heat insulation block for construction of 2 embodiment, and FIG. 11 is the use condition figure which showed the lightweight insulation block for construction of 2nd Embodiment by this invention.

  As shown in FIGS. 8 to 11, the lightweight insulation block for building according to the present invention is constructed by being laminated on the inner and outer walls of the building, and the gap is not generated at the time of plural lamination. In the heat insulating block 1 in which the coupling protrusion 11 is formed on the upper surface and the coupling groove 12 corresponding to the coupling protrusion 11 is formed on the lower surface of the heat insulating block 1, the terminal end of the housing part 2 of the heat insulating block 1 is provided on the front surface and the rear surface. The two-step groove portions 3 formed by being bent in two steps are respectively formed, and the inner groove portion 31 positioned in the inner direction of the two-step groove portion 3 includes one of gypsum board, rock wool, and glass cotton mat. The heat-resistant plate material 4 to be configured is inserted, and the outer groove portion 32, which is located in the outer direction of the two-step groove portion 3 and has a filling groove 321 formed on one side thereof, is made of stone, steel fiber reinforced concrete, dry bit, PVC Finishing sheet material 5 composed of one of a metal is inserted.

  The heat insulation block 1 according to the present invention is made of foamed polystyrene, which is a lightweight foamed synthetic resin, and finishes the inner and outer walls of the building, reduces the material cost, simplifies the work process, and shortens the construction time.

  In the two-step groove portion 3 formed in the heat insulating block 1, the inner groove portion 31 is preferably longer than the outer groove portion 32.

  The heat-resistant plate material 4 inserted into the inner groove portion 31 is a lightweight heat-resistant material, and is excellent in waterproofing, soundproofing, and heat retaining effects. On the other hand, the gypsum board, rock wool, glass cotton mat and the like are already well known, and in the present invention, description of specific characteristics thereof is omitted.

  On the other hand, the characteristics of PVC, the remaining stone excluding metal, steel fiber reinforced concrete, and dry bit, which are generally used in the types of finished plate materials, will be briefly described as follows.

  First of all, stone, which is known as a relatively high-grade material, is an expensive product, so it can be said that it is a somewhat burdensome material to use as an outer wall material, but it has a hard durability that the outer wall gives, and it is not processed Because of its irregular texture, it is often used as an artistic decoration element. Stone may be applied to the entire outer wall, but it can be partially mixed with other materials as an alternative for reducing the construction cost and producing individuality.

  And steel fiber reinforced concrete means that the durability of the steel fiber is improved by preventing the cracks from being distributed in the concrete by irregularly arranging single-phase steel fibers instead of the traditional form of reinforcing bars. . This panel has improved durability by mixing steel fibers, so it does not shrink and deform in rain, wind and heat, and has excellent proportional strength and compressive strength.

  The dry bit is manufactured by synthesizing 100% pure acrylic resin, chemicals and special cinnabar sand, and is a finishing material with various durability and good discoloration. If the outer wall is finished with a dry bit, there is no need for incidental heat insulation and waterproofing, and the structural cost is reduced by reducing the weight of the wall. In addition, the material has various textures and hues, has anti-condensation and normal temperature and humidity effects, and has the advantages of preventing cracks and maximizing waterproofness and durability.

  As the heat-resistant plate material and the finished plate material of the present invention, it is desirable to select a plate material having a performance corresponding to the structure and harmony of the building to be constructed.

  Hereinafter, the assembly process of the lightweight construction heat insulation block according to the second embodiment of the present invention will be described as follows.

  First, the heat-resistant plate material 4 is inserted into the inner groove portion 31 located inside the two-step groove portion 3 of the heat insulating block 1. After inserting the heat-resistant plate material 4, the finished plate material 5 is inserted into the outer groove portion 32.

  Then, the finishing plate material 5 is firmly fixed to the heat insulating block 1 by filling the filling groove 321 formed on one side of the finishing plate material 5 with an inorganic adhesive. As described above, if a plurality of heat insulation blocks 1 in which the heat resistant plate material 4 and the finish plate material 5 are sequentially fixed are provided on the front surface and the back surface of the heat insulation block 1, the coupling protrusion 11 of the basic heat insulation block 1 is connected to the other heat insulation block 1. A plurality of heat insulating blocks 1 are stacked with the coupling groove 12 positioned.

  On the other hand, before explaining the lightweight construction heat insulation block of the third to fifth embodiments according to the present invention, the construction lightweight insulation block of the third to fifth embodiments described later is characterized by the characteristics and blocks of the heat-resistant plate material and the finished plate material. The assembly process is the same as the lightweight construction heat insulation block of the second embodiment described above, and a detailed description thereof will be omitted.

  FIG. 12 is a perspective view showing a lightweight construction heat insulation block of a third embodiment according to the present invention, and FIG. 13 is a side view showing a lightweight construction heat insulation block of a third embodiment according to the present invention. FIG. 14 is an exploded perspective view showing a building lightweight heat insulation block according to a third embodiment of the present invention.

  As shown in FIGS. 12 to 14, the lightweight insulation block for building according to the present invention is a heat insulation block 1 which is constructed by being laminated on the inner and outer walls of a building, and the heat insulation block 1 is made of a foamed synthetic resin. A coupling protrusion 11 is formed on the upper surface thereof, and a coupling groove 12 corresponding to the coupling protrusion 11 is formed on the lower surface thereof so as not to generate a gap during lamination. A part of the upper portion of one side surface is cut into an L shape. A circular fitting protrusion 15 is formed on the upper part of the cut member; two steps formed by bending the front and back surfaces of the heat insulating block 1 in two steps at the end of the accommodating portion 2 of the heat insulating block 1; Each of the groove portions 3 is formed, and in the inner groove portion 31 positioned in the inner direction of the two-step groove portion 3, a heat-resistant plate material 4 composed of one of gypsum board, rock wool, and glass cotton mat is inserted, 2 step groove 3 A finish plate 5 made of one of stone, steel fiber reinforced concrete, dry bit, PVC, and metal is inserted into the outer groove 32 that is located in the outer direction and has a filling groove 321 formed on one side thereof. Is.

  In addition, a vertical coupling groove 18 is formed in the vertical direction on the lower side of the bottom surface of the heat insulating block 1, and the coupling protrusion 11 of the heat insulating block is sandwiched and coupled.

  FIG. 15 is a perspective view showing a lightweight construction heat insulation block according to a fourth embodiment of the present invention, FIG. 16 is a cross-sectional view taken along the line BB of FIG. 15, and FIG. It is the isolation | separation perspective view which showed the lightweight insulation block for construction of 4 embodiment.

  As shown in FIGS. 15 to 17, the lightweight insulation block for building according to the present invention is a heat insulation block 1 that is constructed by being laminated on the inner and outer walls of a building, and the heat insulation block 1 is made of a synthetic foam resin. A coupling protrusion 11 is formed on the upper surface thereof, and a coupling groove 12 corresponding to the coupling protrusion 11 is formed on the lower surface thereof so that a gap is not generated during lamination; a cutting groove portion 17 is formed in the center upper portion of the heat insulating block 1. A circular fitting protrusion 2 is formed on the cut member; two steps formed on the front and back surfaces of the heat insulating block 1 by being bent in two steps at the end of the accommodating portion 2 of the heat insulating block 1; Each of the groove portions 3 is formed, and the heat-resistant plate material 4 composed of one of gypsum board, rock wool, and glass cotton mat is inserted into the inner groove portion 31 positioned in the inner direction in the two-step groove portion 3, The outer groove portion 32, which is located on the outer side of the step groove portion 3 and has a filling groove 321 formed on one side thereof, has a finished plate material made of one of stone, steel fiber reinforced concrete, dry bit, PVC, and metal. 5 is inserted.

  In addition, a vertical coupling groove 18 is formed in the vertical direction on the lower side of the bottom surface of the heat insulation block 1, and the coupling protrusion 11 of the heat insulation block is fitted and coupled.

  FIG. 18 is a perspective view showing a lightweight construction heat insulation block of a fifth embodiment according to the present invention, and FIG. 19 is a side view showing a lightweight construction heat insulation block of a fifth embodiment according to the present invention. FIG. 20 is an exploded perspective view showing a building lightweight heat insulation block according to a fifth embodiment of the present invention.

As shown in FIG. 18 to FIG. 20, the lightweight insulation block for building according to the present invention is a heat insulation block 1 that is laminated and constructed on the inner and outer walls of a building, and the heat insulation block 1 is made of a foamed synthetic resin. coupling protrusion 11 on its upper surface so that a gap does not occur is formed during lamination, the said on the lower surface coupling protrusion 11 and the corresponding coupling groove 12 is formed; the one side portion of the lower portion of the insulation block 1 'L' cut into shaped form, and the the upper portion of the cut member circular fitting groove 16 is formed; the front and back of the insulation block 1, bent in two stages at the end of the housing portion 2 of the insulating block 1 The two-stage groove portions 3 formed in the above-described manner are formed, and the heat-resistant plate material 4 made of one of gypsum board, rock wool, and glass cotton mat is formed in the inner groove portion 31 positioned in the inner direction of the two-step groove portion 3. Inserted The outer groove 32 is formed of one of stone, steel fiber reinforced concrete, dry bit, PVC, and metal. The finished plate material 5 is inserted.

  On the other hand, FIG. 21 is drawing which shows the construction method of the lightweight insulation block for buildings by this invention.

  As shown in FIG. 21, the construction method of the lightweight heat insulating block for building is based on a foundation construction step in which a plurality of shape steels 9 are provided in the vertical direction on the foundation bottom surface 8 of the building, and a foamed polystyrene material between the shape steels 9. A step of laminating a plurality of heat insulating blocks 1, a step of applying a finishing material on the inner and outer surfaces of the laminated heat insulating block 1, and a desired hue on the surface of the finishing material applied on the outer surface of the heat insulating block 1 Applying a paint.

  First, in the foundation construction step, a plurality of structural steels 9 are provided in the vertical direction on the foundation bottom surface 8 of the building. The foundation bottom surface 8 is generally constructed using concrete, and is constructed so that the heat insulation block 1 can be laminated in a balanced manner.

  The shape steel 9 is a rod-shaped rolled material having various cross-sectional shapes, and among the various types of shape steel 9, it is desirable to use H-shape steel mainly used as a structure of a building.

  In addition, the step of laminating the heat insulating blocks 1 further includes a step of applying an adhesive to the upper surface of the heat insulating block 1 located in the lower part in order to reinforce the coupling of the heat insulating blocks 1. Therefore, by performing the above-mentioned steps, there is an effect of increasing the binding force as well as preventing the flow of the heat insulating blocks 1 stacked in a plurality.

  In addition, in the step of constructing the finishing material on the inner and outer surfaces of the laminated heat insulation blocks 1, if the lamination of the plurality of heat insulation blocks 1 is completed, the building is protected from various external influences and the appearance of the building is improved. A finishing material is applied to the inner and outer surfaces of the heat insulating block 1 to be beautiful.

  As the finishing material, one of cement, gypsum, wallpaper, ocher, and cement mixed with stone powder is used.

  Finally, in the step of painting the desired hue on the surface of the finishing material applied to the outer surface of the heat insulation block 1, the work of drawing a partial paint or painting so that people can feel aesthetics from the outside. I do.

DESCRIPTION OF SYMBOLS 1 Heat insulation block 6 Auxiliary block 7 Cross block 11 Coupling protrusion 12 Coupling groove 13 Protrusion part 14 Concave groove part 15 Fitting protrusion 16 Fitting groove 17 Cutting groove part 18 Vertical coupling groove 112 Fastening groove

Claims (8)

In the heat insulation block which forms the inner and outer wall bodies by laminating a plurality in the direction perpendicular to the foundation bottom surface (8)
The heat insulation block is made of foamed synthetic resin, and a coupling groove (12) is formed by fitting the coupling protrusion (11) on the upper surface and laminating the coupling protrusion (11) on the lower surface so that no gap is generated during lamination. Have
A part of a lower part of one side of the heat insulation block (1) is cut into an 'L' shape, and a cross fitting block (7) in which a circular fitting groove (16) is formed in the upper part of the cut member. ,
One of the following auxiliary blocks or assembly blocks is connected to each other, and a lightweight insulating heat insulation block for construction.
Here, the auxiliary block (6) is formed by cutting a part of an upper part of one side of the heat insulating block (1) into an 'L' shape, and forming a circular fitting protrusion (15) on the upper part of the cut member. Is formed,
The assembly block has a U-shaped cutting groove (17) formed at the center upper portion of the heat insulating block (1), and a circular fitting protrusion (15) formed at the upper portion of the cut member. It is formed. Wherein the upper surface of the cross-block (7) is building lightweight insulating block according to claim 1, wherein the kite is coupled protrusion extending by bending one end (11) is formed. Wherein the auxiliary block (6) or the assembly block is the bottom surface from the vertical direction vertical coupling grooves (18) is further formed of that, and wherein the coupling protrusion (11) that is coupled sandwiched The lightweight insulation block for buildings of Claim 1 or 2 . It said auxiliary block (6) is housed portion (2) is formed on each of the vertical edges of the front and back, by bending the end of its two-stage groove having a recess of a two-stage (3) are respectively formed The heat-resistant plate material (4) made of one of gypsum board, rock wool, and glass cotton mat is inserted into the inner groove portion (31) located in the inner direction of the two-step groove portion (3), and 2 The outer groove portion (32) located on the outer side of the step groove portion (3) and having a filling groove (321) formed on one side thereof is one of stone, steel fiber reinforced concrete, dry bit, PVC, and metal. building lightweight insulating block according to claim 1 or 3, characterized in that the finishing sheet (5) is inserted formed in. The assembly block is housed part to the vertical edges of the front and rear (2) is formed, by bending the end of its two-stage groove having a recess of a two-stage (3) are respectively formed, wherein A heat-resistant plate material (4) made of one of gypsum board, rock wool, and glass cotton mat is inserted into the inner groove portion (31) located in the inner direction of the two-step groove portion (3), and the two-step groove portion The outer groove portion (32) located on the outer side of (3) and formed with a filling groove (321) on one side is composed of one of stone, steel fiber reinforced concrete, dry bit, PVC, and metal. building lightweight insulating block according to claim 1 or 3 finishing plate (5) is characterized in that it is inserted to be. It said cross blocks (7) is housed portion (2) is formed on each of the vertical edges of the front and back, by bending the end of its two-stage groove having a recess of a two-stage (3) are respectively formed The heat-resistant plate material (4) made of one of gypsum board, rock wool, and glass cotton mat is inserted into the inner groove portion (31) located in the inner direction of the two-step groove portion (3), and 2 The outer groove portion (32) located on the outer side of the step groove portion (3) and having a filling groove (321) formed on one side thereof is one of stone, steel fiber reinforced concrete, dry bit, PVC, and metal. building lightweight insulating block according to claim 1 or 2, characterized in that the finishing sheet (5) is inserted formed in. The lightweight heat insulating block for building according to any one of claims 4 to 6 , wherein the filling groove (321) is filled with an inorganic adhesive. A foundation construction step in which a plurality of sections are provided in the vertical direction on the bottom surface of the building;
Laminating a plurality of heat insulating blocks made of a polystyrene foam material between the shaped steels;
Applying a finishing material to the inner and outer surfaces of the laminated heat insulation blocks;
Applying a paint having a desired hue to the surface of the finishing material applied to the outer surface of the heat insulating block.

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