KR20180030351A - Prefabricated building, building construction method blocks, and on-demand building construction method using telecommunication lines - Google Patents

Abstract

An objective of the present invention is to provide a prefabricated building of a new concept which can be made or designed by any person in case of a low story small building even if the person is not a construction expert, a method of constructing the same, and a method of construction by receiving an order through a telecommunication line. The prefabricated building is made by comprising: a floor block (400); a wall (300) made by stacking one or more wall blocks; a roof block assembly (200); a coupling bar coupled between adjacent blocks; an internal and an external waterproof layer; and one or more inorganic adhesives selected from a group of inorganic adhesives including cement, sodium silicate, and ceramic. Reinforced cellulose is in a state where reinforced fiber is severed. The floor block (400), the wall blocks (310), a roof block (210), a roof finishing block and a cover block (450) are made of a vacuum extruded foam polystyrene insulation board (XPS).

Description

TECHNICAL FIELD [0001] The present invention relates to a building construction method using blocks, a method of constructing a building using blocks, and a method of constructing a building using a telecommunication line,

The present invention relates to a prefabricated building using a block, a building construction method using a block, and a method of constructing a building using an electric telecommunication line. More particularly, the present invention relates to a building construction method using a block, A method of constructing such a prefabricated house, and a method of constructing such a building by receiving a construction order using an electric telecommunication line.

Even if the size of a typical building is small or low, it is a reality that it is not easy to design and construct it without the design and construction of an architect. However, as the desire to directly design or produce the buildings that they want to build is increased, it is expected that many people will get the spotlight if they plan to meet these needs.

In order to realize this in reality, it is necessary to provide light and easy-to-handle materials, and to provide an easier construction method than usual methods.

In addition, it is anticipated that it will be possible to accommodate the demands of designing and building the building directly if the customer can construct the building easily in cyberspace and install it by the specialist construction worker.

However, there has not been proposed a realistic alternative, and the present invention has been devised to solve this problem.

Korean Utility Model Registration No. 20-0159817

It is an object of the present invention to provide a prefabricated building of a new concept and a method of constructing it so that anyone who is not a building expert may easily make or design a small building of a low level.

It is an object of the present invention to provide a method of constructing a foundation structure for a building in which a foundation is constructed on a single level and has a flat surface area corresponding to a floor area of a building to be constructed, A bottom block (400) having a bottom surface;

A wall block 400 is formed on the upper surface of the floor block 400 or on the upper surface of the floor block 400 and one or more wall blocks 322 are formed on the upper and lower surfaces, A wall 300 formed by stacking the wall 300;

The roof block 210 is formed by installing roof blocks 210 on the wall 300 and installing a roof finishing block on the top of the roof block 210. An engagement groove 215 is formed on the bottom surface of the roof block 210, Wherein the upper surface of the outer surface of the roof is connected to the flat surface, the flat surface is parallel to the bottom surface, the coupling groove (215) is formed on the flat surface, and the outer surface of the roof is assembled A roof block assembly 200 which is the surface forming the outer surface of the roof;

Is used for coupling between the respective blocks constituting the bottom block, the wall and the roof block assembly, and is formed to be longer than the coupling groove and has a horizontal section corresponding to the horizontal sectional shape of the space of the coupling groove A coupling rod inserted into the coupling groove to allow coupling between adjacent blocks;

Roofs and floors of the building formed by the floor block 400, the wall block 310 and the roof block 210 are covered with a reinforcing fiber fabric impregnated with an inorganic adhesive or an inorganic adhesive containing reinforcing fiber An inner waterproof layer formed by spraying;

The outer walls and roofs of the building formed by the floor block 400, the wall block 310 and the roof block 210 are covered with a reinforcing fiber fabric impregnated with an inorganic adhesive or sprayed with an inorganic adhesive containing reinforcing fibers An outer waterproof layer formed;

Wherein the inorganic adhesive is made of at least one inorganic adhesive selected from the group of inorganic adhesives including cement, sodium silicate, and ceramics,

The floor block 400, the wall block 310, the roof block 210, the roof finish block and the cover block 450 are assembled into a prefabricated building using a block made of a vacuum extruded polystyrene insulation board (XPS) .

It is another object of the present invention to provide a method of constructing a building,

Installing a floor block (400) for installing a floor block (400) on the foundation of the building;

Installing a cover block (450) for installing a cover block (450) on the bottom block (400);

A wall tilling step of stacking at least one wall block selected from the group of wall blocks over the cover block 450 to form a wall 300 of the building;

A roof forming step of stacking one or more roof blocks selected from the group of roof blocks on the wall block 310 and installing a roof finish block on the top to form a roof;

A step of forming a place where tap water and sewage to be connected to the outside are installed inside the space formed by the cover block 450, the wall block 310 and the roof block 210, Forming a piping seat by dissolving a part of at least one of the block 450 and the floor block 400 with heat;

A piping installation step of installing a water supply pipe and a sewage piping connecting the inside and the outside of the space through the piping site formed at the pipe formation step;

A step of forming wiring posts 60 connected to the outside from the inside of the space formed by the cover block 450, the wall block 310 and the roof block 210, 450) and the bottom block (400) to form a wiring site (60);

A wiring step of wiring the electric wires from an external power source through the wiring posts 60 formed in the step of forming the wiring posts 60;

The exterior of the building formed by the floor block 400, the wall block 310 and the roof block 210 is covered with a reinforcing fiber fabric impregnated with an inorganic adhesive agent or an inorganic adhesive mixed with reinforcing fiber is sprayed to form a waterproof layer Forming an outer waterproof layer; And

The inner wall of the space formed by the cover block 450, the wall block 310 and the roof block 210 is covered with a reinforcing fiber fabric impregnated with an inorganic adhesive agent or an inorganic adhesive agent mixed with reinforcing fibers is sprayed to form a waterproof layer And providing a building construction method using a block including an inner waterproof layer formation step.

It is also an object of the present invention to provide a method and a system for providing a user with a terminal selected from a group of blocks including a floor block, a cover block, a wall block, a roof block, a roof finish block, a window block, An on-screen material providing step of displaying a block of the moving picture on the screen of the consumer terminal;

A screen assembling step of assembling a building on a screen using blocks displayed on a screen;

An appearance information transmission step of transmitting information on the external shape of the building made by the customer in the assembling step on the screen to the constructor through the electric communication line;

A cost information providing step of calculating a required number of each block used in a building assembled on a screen by a customer, calculating a material cost according to the calculated cost, and displaying the calculated cost on a screen of the user terminal; And

And a direct construction step in which the constructor receives the necessary materials from the information including the required number of blocks,

In the direct construction step,

A basic construction stage to lay the foundations for the location where the building will be constructed;

Installing a floor block (400) for installing a floor block (400) on the foundation of the building;

Installing a cover block (450) for installing a cover block (450) on the bottom block (400);

A wall tilling step of stacking at least one wall block selected from the group of wall blocks over the cover block 450 to form a wall 300 of the building;

A roof forming step of stacking one or more roof blocks selected from the group of roof blocks on the wall block 310 and installing a roof finish block on the top to form a roof;

A step of forming a place where tap water and sewage to be connected to the outside are installed inside the space formed by the cover block 450, the wall block 310 and the roof block 210, Forming a piping seat by dissolving a part of at least one of the block 450 and the floor block 400 with heat;

A piping installation step of installing a water supply pipe and a sewage piping connecting the inside and the outside of the space through the piping site formed at the pipe formation step;

A step of forming wiring posts 60 connected to the outside from the inside of the space formed by the cover block 450, the wall block 310 and the roof block 210, 450) and the bottom block (400) to form a wiring site (60);

A wiring step of wiring the electric wires from an external power source through the wiring posts 60 formed in the step of forming the wiring posts 60;

The exterior of the building formed by the floor block 400, the wall block 310 and the roof block 210 is covered with a reinforcing fiber fabric impregnated with an inorganic adhesive agent or an inorganic adhesive mixed with reinforcing fiber is sprayed to form a waterproof layer Forming an outer waterproof layer; And

The inner wall of the space formed by the cover block 450, the wall block 310 and the roof block 210 is covered with a reinforcing fiber fabric impregnated with an inorganic adhesive agent or an inorganic adhesive agent mixed with reinforcing fibers is sprayed to form a waterproof layer And providing a building construction method using a block including an inner waterproof layer formation step.

Here, the bottom block 400 may have a large flat surface area corresponding to the floor area of the building to be installed, and may have an engaging groove along the outer circumferential surface thereof.

Here, the bottom surface of the wall block 310 is formed with coupling grooves through which the coupling concavity and convexity can be inserted and fixed, and the coupling concavity and convexity can be formed on the top surface.

Here, the roof block 210 is formed with an engaging groove to which the concave and convex joints can be inserted and fixed. The upper surface of the roof block 210 is formed with a roof surface and a flat surface, and an upper end of the roof surface is connected to the flat surface , The flat surface may be parallel to the bottom surface, and the concavity and convexity may be formed on the flat surface.

Here, an engaging groove is formed on the upper surface and the lower surface of the wall block 310, and a connecting rod having a shape corresponding to the horizontal end surface of the engaging groove and having a longer length than the depth of the engaging groove is used Lt; RTI ID = 0.0 > wall blocks. ≪ / RTI >

The upper surface of the roof block 210 is connected to the flat surface, and the flat surface of the roof block 210 is parallel to the floor surface. And a coupling rod having a shape corresponding to a horizontal cross section of the coupling groove and having a length longer than the depth of the coupling groove is inserted between the coupling grooves and fixed to each other.

Here, the roof blocks 210,

Each of the roof blocks 210 is connected to an outer surface of the roof from two walls 300 that are stacked and spaced apart to face each other,

The joining groove of the outermost roof block 210 is joined by the joining rod to the joining groove located below the roof outer surface of the roof block 210 disposed thereon,

Wherein the engaging rod has a shape corresponding to a horizontal end surface of the engaging groove and is longer than a depth of the engaging groove,

The sidewalls of the roof blocks 210, which are located at the highest height at the center of the space between the two walls 300,

The roof finishing block may be used to connect the top roof blocks 210 to each other using the coupling grooves of the roof blocks 210 at the top.

Here, the bottom block 400, the wall block 310, the roof block 210, the roof finish block, and the cover block 450 may be made of an extruded polystyrene insulation board (XPS) have.

Here, the inorganic adhesive may include one or more inorganic adhesives selected from the group of inorganic adhesives including cement, sodium silicate, and ceramics.

The method may further include displaying a map on a screen of the customer terminal, selecting a construction site by the customer, and providing the construction site to the customer.

The prefabricated building using the block of the present invention can be manufactured by assembling the blocks easily by the protrusions and the coupling grooves, and each block is made of the light XPS material, so that the construction can be easily performed. Further, a waterproof layer using an inorganic adhesive is formed to solve the waterproofing problem, and at the same time, the environmental hormone problem when the organic adhesive is used can be avoided.

According to the present invention, a block can be freely assembled by a customer on a computer screen to freely assemble the building, and a construction expert can construct the building to assemble the building. In addition, by leaving the construction to the experts, the problem of shortening the life of the building when the waterproof layer is properly installed is not caused.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic illustration of an embodiment of a prefabricated building using blocks according to the present invention.
FIG. 2 is a schematic view showing the construction of a roof block assembly used in a prefabricated building using blocks according to the present invention; FIG.
3 is a perspective view showing an example of a roof block used in the present invention.
4 is a perspective view of an example of a floor block used in the present invention.
5 to 7 are perspective views showing an example of a wall block used in the present invention.
8 is a view showing the configuration of a connecting rod used when connecting the respective blocks used in the present invention.
FIG. 9 is a view showing a method of connecting wall blocks using the coupling rods of FIG. 8. FIG.
10 is a flowchart illustrating an example of each step of a building construction method using a block according to the present invention.
11 is a flowchart illustrating an example of each step of a building construction method using a block according to the present invention.

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

FIG. 1 is a side cross-sectional view schematically showing an embodiment of a prefabricated building using a block according to the present invention, and FIG. 2 is a view schematically showing the construction of a roof block assembly used in a prefabricated building using the block of the present invention FIG. 3 is a perspective view showing an example of a roof block used in the present invention, FIG. 4 is a perspective view of an example of a floor block used in the present invention, and FIGS. 5 to 7 8 is a perspective view showing an example of a wall block used in the present invention, and FIG. 8 is a view showing a configuration of a connecting rod used for connecting the respective blocks used in the present invention. ≪ RTI ID = 0.0 > a < / RTI > manner of connecting the wall blocks using a connecting rod.

As shown in FIG. 1, a prefabricated building using blocks according to the present invention includes a floor block 400, a wall 300, a roof block assembly 200, an interior waterproof layer, and an exterior waterproof layer.

The floor block 400 is installed at a level to perform a foundation work for laying the foundation of a building to be constructed. As shown in FIG. 4, the bottom block 400 has a large flat area corresponding to the floor area of the building to be constructed, in which an engaging groove 415 is formed along the periphery of the upper surface thereof, Are formed at regular intervals. In some cases, a cover block 450 is further constructed on the bottom block 400. A coupling groove 415 may be formed at a portion of the bottom block 400 facing the cover block 450 for coupling the cover block 450 and the bottom block 400. [

The wall 300 is formed by stacking at least two wall blocks 310 around the floor block 400 or the wall block 300 of the building around the cover block 450. As shown in the drawing, coupling grooves are formed on the upper and lower surfaces of the wall block 310.

The wall can be made by using one kind of wall block, but it is also possible to use wall blocks of various shapes in combination. For example, the wall block may have a lower height and a longer length as shown in FIG. 6 than that shown in FIG. 5, or a thinner wall as shown in FIG. 7. The joining rod may be made of a material that is co-molded with a block, or any other material that is flame retardant and has high strength.

The engaging grooves formed in the respective wall blocks are equal in size and spacing. Further, the coupling between the respective wall blocks or the coupling between the respective blocks can be achieved by inserting the coupling rod shown in FIG. 8 into the coupling grooves. The shape of the horizontal cross section of the joining rod is the same as the shape of the horizontal cross section of the joining groove and is longer than the depth of the joining groove. The maximum length of the joining rod corresponds to twice the depth of the joining groove. As shown in FIG. 9, the coupling rod is inserted into both sides of the coupling groove facing each other between the blocks to be connected, thereby making it possible to connect and fix the facing blocks.

As shown in FIG. 2, the roof block assembly 200 is constructed by stacking roof blocks 210 on the wall 300, and a roof finish block on the top. As shown in FIG. 3, the roof block 210 is also formed with a coupling groove, and coupling with other blocks is performed using a coupling rod. The roof block includes an upper roof outer surface, a flat surface, and a lower bottom surface, an upper end of the roof outer surface is connected to the flat surface, the flat surface is parallel to the floor surface, and a coupling groove is formed on the flat surface And a coupling groove is formed in the bottom surface.

The roof blocks 210 are connected to the coupling grooves located below the roof outer surface of the roof block 210 on which the coupling grooves of the roof block 210 located below are disposed. That is, when the roof blocks 210 are coupled to each other, the roof outer surfaces of consecutively connected roof blocks 210 may be coupled to one another. It may be a simple sloped surface as shown in the drawing of the outer surface of the roof, or a mixed shape of a curved surface or a curved surface and an inclined surface.

Roof finishing blocks are used at locations that form the highest point of the roof. The roof blocks 210 are connected to the roof walls 210 so as to extend from the roof walls 210 to two walls 300 spaced apart from each other by stacking the wall blocks 310, The side walls of the roof blocks 210, which are located at the highest level above the center of the roof blocks 210, abut against each other. At this time, the coupling grooves of the bottom surface of the roof finishing block and the coupling grooves of the roof blocks 210 at the top are connected to each other by using coupling grooves.

The bottom block 400, the wall block 310, the roof block 210, the roof finish block, and the cover block 450 may be made of vacuum extruded polystyrene insulation board (XPS).

The inner waterproof layer is formed by covering the inner wall, the roof and the bottom of the building formed by the floor block 400, the wall block 310 and the roof block 210 with a reinforcing fiber fabric impregnated with an inorganic adhesive to form a waterproof layer. The reinforcing fibers used herein include one selected from the group of reinforcing fibers including Aramid, Kevlar, Spectra, Dyneema, Polyurethane, Heracron, Or more.

The outer waterproof layer is formed by covering the outer wall and the roof of the building formed by the floor block 400, the wall block 310 and the roof block 210 with a reinforcing fiber fabric impregnated with an inorganic adhesive to form a waterproof layer.

The inorganic adhesive is made of at least one inorganic adhesive selected from the group of inorganic adhesives including cement, sodium silicate and ceramics.

A coating film may be further formed on the surface of the inner waterproof layer or the outer waterproof layer.

The coating layer on the inner waterproof layer and the outer waterproof layer is formed by spraying an inorganic adhesive mixed with reinforcing fibers on the outer waterproof layer. The reinforcing fiber has a short shape of the reinforcing fiber and has a physical shape different from that of the reinforcing fiber fabric. It is also possible to replace the inner waterproofing layer using the fabric or the outer waterproofing layer by spraying an inorganic adhesive using reinforcing fibers that do not use a fabric.

On the other hand, in order for the prefabricated building of the present invention to function as a building, wiring, waterworks, and sewage are required. For this purpose, the inner waterproof layer is formed in a state where the wiring block 60 for burying electric wires is formed in the wall block 310, the floor block 400, the cover block 450, and the roof block 210 . The interior waterproof layer or the external waterproof layer may be formed on the wall block 310, the cover block 450, and the floor block 400 in a state in which a water pipe or a sewer pipe is formed.

In the prefabricated building using the block of the present invention having the above-described structure, the blocks can be easily assembled by the projections and the coupling grooves, and each block is made of a light XPS material, so that the construction can be easily performed. Further, a waterproof layer using an inorganic adhesive is formed to solve the waterproofing problem, and at the same time, the environmental hormone problem when the organic adhesive is used can be avoided.

In addition to the above-described floor block, cover block, wall block, roof block, and roof finish block, a window block or door block may be further used. Window blocks or door blocks can be made of different materials from other blocks. For example, a transparent body such as a glass used for a general window or a door may be used, and a body other than a transparent body such as a glass may be a vacuum extruded expanded polystyrene insulation used as a material of the blocks, Material may also be used.

Hereinafter, a method of constructing a prefabricated building using blocks of the present invention will be described.

FIG. 10 is a flow chart illustrating steps of a building construction method using blocks according to the present invention.

10, the building construction method using the block according to the present invention includes a basic construction step, a floor block 400 installation step, a cover block 450 installation step, a wall body 300 red tide step, a roof formation step A piping site formation step, a piping installation step, a wiring site formation step 60, a wiring step, and a waterproof layer formation step.

The configuration of each block used in the present invention is substantially the same as the configuration of the blocks described above.

The foundation construction step is a step for finishing the foundation 500 where the building is to be installed. It is preferable to construct the concrete foundation, but it is sufficient for the construction of the rubble.

In the step of installing the floor block, the floor block 400 is installed on the foundation of the previously formed building. The bottom block 400 is formed with a coupling groove, and other blocks can be installed by the coupling rod.

The step of installing the cover block is a step of installing the cover block 450 on the bottom block 400.

The wall redepositing step is a step of building the wall 300 by stacking two or more layers of the wall blocks 310 forming the wall 300 of the building around the cover block 450.

The roof forming step is a step of stacking the roof blocks 210 on the wall 300 and forming a roof by installing a roof finishing block at the top.

The floor block 400, the wall block 310, the roof block 210, the roof finish block and the cover block 450 used in the previous steps are formed by vacuum extruded polystyrene insulation board (XPS) Is made.

In the pipe seat forming step, water and sewer pipes connected to the inside and the outside of the space formed by the cover block 450, the wall block 310 and the roof block 210 are formed. At this stage, a part of at least one of the wall block 310, the cover block 450, and the floor block 400 is melted with heat to form a water pipe seat. Vacuum compression foamed polystyrene basically has the property of melting in heat, so it can be melted as necessary by using gas torch, hot wire and the like.

In the piping installation step, a water supply pipe and a sewer pipe connecting the inside and the outside of the space are installed through a pipe seat formed in the piping seat forming step.

In the step of forming the wiring spots 60, the wiring spots 60 connected to the outside are formed from the space formed by the cover block 450, the wall blocks 310 and the roof block 210, A part of at least one of the wall block 310, the cover block 450, and the floor block 400 is melted to form a wiring seat 60.

In the wiring step, electric wires are connected from the external power source to the inside via the wiring site 60 formed in the wiring site 60 forming step.

The waterproof layer forming step may include an outer waterproof layer forming step and an inner waterproof layer forming step. The inner waterproof layer and the outer waterproof layer may be formed by covering the inner surface of the waterproof layer with a reinforcing fiber cloth impregnated with an inorganic adhesive or spraying an inorganic adhesive mixed with reinforcing fibers Or may be formed by covering a first layer with a reinforcing fiber fabric impregnated with an inorganic adhesive and spraying an inorganic adhesive mixed with reinforcing fiber onto the second layer.

The building construction method using the block of the present invention as described above can be applied as an order building construction method using an electric telecommunication line for building a building suited to a demand of a customer as follows.

In this specification, a 'terminal' is used as a name including any electronic device and a computing device capable of controlling the device through the wired / wireless telecommunication line, and performing the information processing and the like.

In this specification, 'telecommunication line' is used as a term including metaphorical wireless internet, and any other communication means.

FIG. 11 is a flowchart illustrating steps of a building construction method using a block according to an exemplary embodiment of the present invention.

As shown in FIG. 11, the method of constructing a building using an electric telecommunication line according to the present invention is basically a method in which a customer assembles a block on a terminal screen of his or her computer or a smart phone to determine the outline of the building, The method of constructing a building by performing a building construction method using a block is described.

More specifically, a building construction method using an order form block through an electric communication line of the present invention includes an on-screen material providing step, an on-screen assembling step, an appearance information transmitting step, a cost information providing step, and a direct construction step.

The step of providing the on-screen material may include providing a block of one director selected from the group of blocks including a floor block, a cover block, a wall block, a roof block, a roof finish block, a window block, On the screen of the consumer terminal. The material displayed on the screen can be moved along with the movement of the mouse when the user holds the mouse pointer with one click or click.

The assembling step on the screen is a step of assembling the building on the screen using the blocks displayed on the screen.

The step of transmitting the external appearance information is a step of transmitting the external information of the building made by the customer at the assembling step on the screen to the constructor through the electric communication line.

The cost information providing step is a step of calculating the required number of each block used in the building assembled on the screen by the customer, calculating the material cost according to the calculated cost, and displaying the cost on the screen of the user terminal. At this stage, it can be displayed together with the number of required materials. The previous appearance information transmission step and the present cost information providing step are not necessarily limited to each other, and the terminal for which calculation is performed may be a consumer's terminal, a contractor's terminal, or a separate designated server. However, in order to reduce the amount of information transferred and to provide immediate information, it is desirable that a terminal (computer, smart phone, or the like) displaying the external information of the building on the screen calculates the number of required materials and calculates a material cost estimate based on the calculation . That is, it has the advantage of informing the customer immediately of the demand of the material and the cost accordingly. Alternatively, it is possible to selectively or superimpose a method of automatically performing the calculation at the contractor's terminal or automatically reflecting the price of the material so as to inform the market price of the fluctuation of the market price of the material.

In the direct construction step, the builder receives the necessary materials from the information including the required number of blocks and places them at a place desired by the customer, and the building construction method using the blocks described above can be directly applied.

On the other hand, the construction site desired by the consumer can display a map on the screen of the consumer's terminal, and allow the consumer to select the construction location while viewing the map. This can be referred to as a construction site selection step.

In addition, a housing model assembled by a consumer in a block may have structural dynamical defects. Accordingly, the present invention may further include a step of confirming by the constructor before the construction of the customer's home model in the actual situation, and informing the customer of the part to be additionally installed or changed in design in actual construction. This step is not a one-sided notification but can be repeatedly carried out until a design satisfying the consumer is completed by exchanging opinions with the consumer. Whether or not there is a structural problem in this step may be performed by a structural inspection program designed in advance considering the bonding force between the material weight and the material and the distribution of the structural stress applied to the part.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings. It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the spirit of the invention.

In addition, the dimensions of each block shown in the drawings, the number and the size of the engaging irregularities are illustrative and are not limited to those shown in the drawings.

60: Wiring seat 100: Prefabricated building
200: roof block assembly 210: roof block
215, 315, 415: coupling groove 300: wall
310, 311, 312: a wall block 350: a sewer pipe
355: faucet 400: floor block
450: cover block 460: base
500: coupling rod

Claims (10)

A floor block (400) installed on one foundation for laying the foundation of the location where the building is to be installed, and having a coupling groove (415) formed on the surface thereof corresponding to the floor area of the building to be installed or having a larger plane area;
A wall block 400 is formed on the upper surface of the floor block 400 or on the upper surface of the floor block 400 and one or more wall blocks 322 are formed on the upper and lower surfaces, A wall 300 formed by stacking the wall 300;
The roof block 210 is formed by installing roof blocks 210 on the wall 300 and installing a roof finishing block on the top of the roof block 210. An engagement groove 215 is formed on the bottom surface of the roof block 210, Wherein the upper surface of the roof outer surface is connected to the flat surface, the flat surface is parallel to the floor surface, the coupling groove (215) is formed on the flat surface, and the roof outer surface A roof block assembly 200 which is the surface forming the outer surface of the roof;
Is used for coupling between the respective blocks constituting the bottom block, the wall and the roof block assembly, and is formed to be longer than the coupling groove and has a horizontal section corresponding to the horizontal sectional shape of the space of the coupling groove A coupling rod inserted into the coupling groove to allow coupling between adjacent blocks;
Roofs and floors of the building formed by the floor block 400, the wall block 310 and the roof block 210 are covered with a reinforcing fiber fabric impregnated with an inorganic adhesive or an inorganic adhesive containing reinforcing fiber An inner waterproof layer formed by spraying;
The outer walls and roofs of the building formed by the floor block 400, the wall block 310 and the roof block 210 are covered with a reinforcing fiber fabric impregnated with an inorganic adhesive or sprayed with an inorganic adhesive containing reinforcing fibers An outer waterproof layer formed;
Wherein the inorganic adhesive is made of at least one inorganic adhesive selected from the group of inorganic adhesives including cement, sodium silicate, and ceramics,
The reinforcing fiber is a mixture of reinforcing fibers cut into an inorganic adhesive,
The floor block 400, the wall block 310, the roof block 210, the roof finish block and the cover block 450 are assembled buildings using a block made of a vacuum extruded polystyrene insulation board (XPS). A basic construction stage to lay the foundations for the location where the building will be constructed;
Installing a floor block (400) for installing a floor block (400) on the foundation of the building;
Installing a cover block (450) for installing a cover block (450) on the bottom block (400);
A wall tilling step of stacking at least one wall block selected from the group of wall blocks over the cover block 450 to form a wall 300 of the building;
A roof forming step of stacking one or more roof blocks selected from the group of roof blocks on the wall block 310 and installing a roof finish block on the top to form a roof;
A step of forming a place where tap water and sewage to be connected to the outside are installed inside the space formed by the cover block 450, the wall block 310 and the roof block 210, Forming a piping seat by dissolving a part of at least one of the block 450 and the floor block 400 with heat;
A piping installation step of installing a water supply pipe and a sewage piping connecting the inside and the outside of the space through the piping site formed at the pipe formation step;
A step of forming wiring posts 60 connected to the outside from the inside of the space formed by the cover block 450, the wall block 310 and the roof block 210, 450) and the bottom block (400) to form a wiring site (60);
A wiring step of wiring the electric wires from an external power source through the wiring posts 60 formed in the step of forming the wiring posts 60;
The exterior of the building formed by the floor block 400, the wall block 310 and the roof block 210 is covered with a reinforcing fiber fabric impregnated with an inorganic adhesive agent or an inorganic adhesive mixed with reinforcing fiber is sprayed to form a waterproof layer Forming an outer waterproof layer; And
The inner wall of the space formed by the cover block 450, the wall block 310 and the roof block 210 is covered with a reinforcing fiber fabric impregnated with an inorganic adhesive agent or an inorganic adhesive agent mixed with reinforcing fibers is sprayed to form a waterproof layer A building construction method using a block including an inner waterproof layer forming step. A block of one director selected from the group of blocks including a floor block, a cover block, a wall block, a roof block, a roof finishing block, a window block and a door block on the screen of the terminal connected to the consumer is displayed on the screen of the consumer terminal On-screen material providing step;
A screen assembling step of assembling a building on a screen using blocks displayed on a screen;
An appearance information transmission step of transmitting information on the external shape of the building made by the customer in the assembling step on the screen to the constructor through the electric communication line;
A cost information providing step of calculating a required number of each block used in a building assembled on a screen by a customer, calculating a material cost according to the calculated cost, and displaying the calculated cost on a screen of the user terminal; And
And a direct construction step in which the constructor receives the necessary materials from the information including the required number of blocks,
In the direct construction step,
A basic construction stage to lay the foundations for the location where the building will be constructed;
Installing a floor block (400) for installing a floor block (400) on the foundation of the building;
Installing a cover block (450) for installing a cover block (450) on the bottom block (400);
A wall tilling step of stacking at least one wall block selected from the group of wall blocks over the cover block 450 to form a wall 300 of the building;
A roof forming step of stacking one or more roof blocks selected from the group of roof blocks on the wall block 310 and installing a roof finish block on the top to form a roof;
A step of forming a place where tap water and sewage to be connected to the outside are installed inside the space formed by the cover block 450, the wall block 310 and the roof block 210, Forming a piping seat by dissolving a part of at least one of the block 450 and the floor block 400 with heat;
A piping installation step of installing a water supply pipe and a sewage piping connecting the inside and the outside of the space through the piping site formed at the pipe formation step;
A step of forming wiring posts 60 connected to the outside from the inside of the space formed by the cover block 450, the wall block 310 and the roof block 210, 450) and the bottom block (400) to form a wiring site (60);
A wiring step of wiring the electric wires from an external power source through the wiring posts 60 formed in the step of forming the wiring posts 60;
The exterior of the building formed by the floor block 400, the wall block 310 and the roof block 210 is covered with a reinforcing fiber fabric impregnated with an inorganic adhesive agent or an inorganic adhesive mixed with reinforcing fiber is sprayed to form a waterproof layer Forming an outer waterproof layer; And
The inner wall of the space formed by the cover block 450, the wall block 310 and the roof block 210 is covered with a reinforcing fiber fabric impregnated with an inorganic adhesive agent or an inorganic adhesive agent mixed with reinforcing fibers is sprayed to form a waterproof layer A building construction method using a block including an inner waterproof layer forming step. The method according to claim 2 or 3,
Wherein the floor block (400) has a large flat surface area corresponding to a floor area of a building to be installed, and has an engaging groove formed along an outer circumferential surface thereof. The method according to claim 2 or 3,
The wall block 310 may have an engaging groove formed on an upper surface and a lower surface of the wall block 310. The engaging groove may have a shape corresponding to a horizontal cross section of the engaging groove and may have a longer length than the depth of the engaging groove, Wherein a connection between the building blocks is made. The method according to claim 2 or 3,
The upper surface of the roof block 210 is connected to the flat surface, the flat surface is parallel to the floor surface, and the lower surface of the roof block 210 is formed with an engaging groove. Wherein a coupling groove is formed on the flat surface and a coupling bar having a shape corresponding to a horizontal cross section of the coupling groove and longer than a depth of the coupling groove is inserted and fixed between the coupling grooves. Construction method of used building. The method according to claim 2 or 3,
The roof blocks 210,
Each of the roof blocks 210 is connected to an outer surface of the roof from two walls 300 that are stacked and spaced apart to face each other,
The joining groove of the outermost roof block 210 is joined by the joining rod to the joining groove located below the roof outer surface of the roof block 210 disposed thereon,
Wherein the engaging rod has a shape corresponding to a horizontal end surface of the engaging groove and is longer than a depth of the engaging groove,
The sidewalls of the roof blocks 210, which are located at the highest height at the center of the space between the two walls 300,
Wherein the roof finishing block connects uppermost roof blocks (210) to each other by using coupling grooves of uppermost roof blocks (210). The method according to claim 2 or 3,
The floor block 400, the wall block 310, the roof block 210, the roof finish block, and the cover block 450 are made of a vacuum extruded polystyrene insulation board (XPS). Building Construction Method Using Blocks. The method according to claim 2 or 3,
Wherein the inorganic adhesive includes one or more inorganic adhesives selected from the group of inorganic adhesives including cement, sodium silicate, and ceramics. The method of claim 3,
Further comprising a step of displaying a map on the screen of the customer's terminal, selecting a construction location by the customer, and providing the selected location information to the constructor.

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