KR101909136B1 - Method for constructing country house - Google Patents

Abstract

The present invention relates to a prefabricated power house, which uses a C-shaped steel and a pipe-like base material, minimizes the amount of concrete used to reduce the construction cost, shortens the construction period, .
A method of constructing a power house according to the present invention includes a first step of installing a plurality of files at a predetermined distance from each other according to the structure of a power house, A second step of fixing a column made of a pipe to the head of the pile installed in the first step and fixing the pillars to each other and installing a cross bar between the pillars to reinforce the pillars; A third step of constructing a slab in an inner space of the columns installed in the second step; A fourth step of constructing a wall at the periphery of the slabs and the pillars constructed in the third step; And a fifth step of constructing a roof after the fourth step. In the third step, a slab cross bar is installed in a lateral direction between neighboring columns, a lower heat insulator is installed on the upper side of the slab cross bar, A deck plate is installed on the upper part of the deck plate, an upper insulating material is installed on the deck plate, a hot water pipe is piped on the upper insulating material, and a floor material is installed. In the fourth step, The heat insulating material fastener of the C-shaped steel is installed in the lateral direction, the heat insulating material is fixed to the heat insulating material fastener, and the outer wall or the finishing material for the inner wall is installed on the heat insulating material.

Description

METHOD FOR CONSTRUCTING COUNTRY HOUSE <br> <br> <br> Patents - stay tuned to the technology METHOD FOR CONSTRUCTING COUNTRY HOUSE

The present invention relates to a power house, and more particularly, to a power house, and more particularly, to a power house that uses a C-shaped steel pipe and a flue gasket, and reduces the construction cost by minimizing the amount of concrete used, The present invention relates to a power house construction method and a prefabricated power house constructed by this method.

Typical houses are constructed using cement concrete, cement blocks, reinforcing bars, plastics, etc. for residing people. Mortars mixed with cement and sand at a certain ratio are used as the interior materials, or boards made of gypsum are used .

These houses made of cement are harmful to the health of the residents by releasing harmful gas to the human body due to the cement properties. In addition, the children in urban areas grown in the concrete houses are more immune than the ones growing in the rural areas. There is a problem that it is infected and goes to hospital often.

Therefore, it is hoped that the people living in the majority of apartments and private houses that have moved to the power house when the living conditions are important due to the importance of health for the modern people are to have the pots, air cleaner, charcoal, etc. in their homes to live in a more pleasant environment And is trying to practice it.

In addition, the houses in which most of the residents are living now are exposed to the atmosphere, and due to the exposure in the atmosphere, insulation must be made in the winter season. Therefore, a gypsum board, styrofoam, or the like is used for the insulation, or chemical insulation is used.

Such a heat insulating material is not only harmful to the human body but also can not be a nature-friendly house pursued by modern people. In addition, there is a problem that the heating cost is excessively consumed due to exposure in the air during the winter season, There is a problem of causing warming.

In recent years, the preference of powerhouses constructed with natural winds has been rapidly increasing recently due to the increase in the closure environment of the city centered with the pace of development of the industry. Typical construction methods include ocher houses or wooden houses, Housing.

Patent Document (Japanese Patent No. 10-1381408) discloses a roof member comprising: a roof member; The H beam is supported by a concrete column which forms a fixed bar and a vertical bar. A guide pin is formed on the H beam by forming a guide bar guided along the slot, and the adjustment position is fixed as a tightening nut in a vertical bar passing through the H beam And a lower end portion of the H beam forms a rim. Inside the H beam, a bottom insulating layer, a deck plate, and a heat insulating layer in which a pipe for a boiler is embedded are embedded and formed to form a floor; A first wall member having a window frame formed of a frame for a window frame and a window provided inside the frame, a second wall member having a door frame formed of a frame for the door frame, a door provided inside the frame, A wall member made of a third wall member forming a space capable of being filled and each having a coupling groove; And a connecting projection formed with a fastening hole are formed on at least one side of each of the pillars so that the floor member and the roof member are connected by a pillar member and a wall member is provided on both sides of the connecting pillar of the pillar member , And a roof member is provided on the upper part of the wall member, and is a prefabricated structure of a floor, a wall, and a roof.

In the case of the cement concrete type, the power house according to the prior art has a disadvantage that the air is very long and not environmentally friendly, and when the eco-friendly material such as loess is used, there is a disadvantage such as heat insulation and strength.

Patent No. 10-1381408

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to reduce the construction cost by minimizing the amount of concrete used, by using the C-shaped steel and the pipes, and to shorten the construction period, The present invention provides a method of constructing a prefabricated power house having excellent earthquake resistance and a prefabricated power house constructed by the method.

A method of constructing a power house according to the present invention includes a first step of installing a plurality of files at a predetermined distance from each other according to the structure of a power house, A second step of fixing a column made of a pipe to the head of the pile installed in the first step and fixing the pillars to each other and installing a cross bar between the pillars to reinforce the pillars; A third step of constructing a slab in an inner space of the columns installed in the second step; A fourth step of constructing a wall at the periphery of the slabs and the pillars constructed in the third step; And a fifth step of constructing a roof after the fourth step. In the third step, a slab cross bar is installed in a lateral direction between neighboring columns, a lower heat insulator is installed on the upper side of the slab cross bar, A deck plate is installed on the upper part of the deck plate, an upper insulating material is installed on the deck plate, a hot water pipe is piped on the upper insulating material, and a floor material is installed. In the fourth step, The heat insulating material fastener of the C-shaped steel is installed in the lateral direction, the heat insulating material is fixed to the heat insulating material fastener, and the external wall or the finishing material for the inner wall is installed on the heat insulating material to construct the wall.

According to the method of constructing the prefabricated power house according to the present invention and the prefabricated prefabricated house constructed by this method, it is possible to construct the power house by assembling the prefabricated materials such as the C-shaped steel and the pipes through a simple assembly method, It is possible to expect the activation of the power house by the construction of the power house, and the construction period can be shortened by using a very small amount of concrete and the use of the material that is friendly to the environment is possible, thereby providing a healthy and comfortable living environment .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front view of a construction state of a file and a column applied to a method of constructing a power house according to the present invention; FIG.
2 is a perspective view of a column fastener applied to a method of constructing a power house according to the present invention;
FIG. 3 is a front view of a separated state showing a connection between a pillar and a pillar crossbar applied to a power house construction method according to the present invention; FIG.
4 is a front view of a construction state of a slab applied to a method of constructing a power house according to the present invention.
FIG. 5 is a front view of a construction state of a column and a wall applied to a method of constructing a power house according to the present invention. FIG.
6 is a front view of the construction of a window frame applied to a method of constructing a power house according to the present invention.
FIG. 7 is a plan view of a construction of a column and a wall applied to a method of constructing a power house according to the present invention; FIG.
8 is a front view of a construction state of a roof applied to a method of constructing a power house according to the present invention.
9 is a front view of a power house constructed by a method of constructing a power house according to the present invention.
10 is a front view showing a turning means of a two-story building by a method of constructing a power house according to the present invention.
11 is a plan view of a turning means applied to a method of constructing a power house according to the present invention.
12 is a bottom view showing a rail of a turning means applied to a method of constructing a power house according to the present invention.
13 and 14 are a front view and a side view of a sun roof applied to a method of constructing a power house according to the present invention, respectively.

A method of constructing a power house according to the present invention is as follows.

1. Planarization and selection.

Plane is removed while large rocks are removed from the road surface where the power house is to be constructed.

2. Install the files.

The file is a foundation structure for supporting columns and is installed in the ground.

As shown in Fig. 1, the file (1) is, for example, a screw file, which exhibits a large composite force with the ground due to its structural characteristics, so that the settlement caused by subsidence of the ground is small and the conduction due to the behavior of the ground is small.

In the case of the screw-type file (1), the file (1) is rotated and fixed to the ground to construct the file (1).

The file 1 is installed at a certain depth below the ground so that the file 1 and the pillar 10 are connected to each other so that the connection between the pile 1 and the pillar 10 is buried in the ground, 10).

In addition, in order to reinforce the connection between the pile 1 and the pillar 10, the space around the pile 1 of the pile 1 is tapped to secure a space, and after the pillar 10 is connected, It is also possible that the pile 1 and the column 10 are integrally formed through the sieve 2 and one or more auxiliary files 3 (C-shaped steel) are provided in the head reinforcement 2 .

On the other hand, the screw-type file 1 is formed with a flat joining plate 1a on its head. In the present invention, since the column 1 is connected to the pillar 1 via a bolt-type fastener, the pillar 1 is connected to the pillar 1, A bolt-type column fastener 20 is fixed to the base 1a.

As shown in FIG. 2, the bolt-type column fastener 20 has four bolts 21 for stable fixing. For example, two rods of the U-shape are combined in a cross shape, Four bolt portions 21 are formed. That is, the column fastener 20 can be manufactured by fixing two eutectoid bolts by welding.

In addition, a fixed band 22 is formed to maintain the spacing of the four bolts 21.

The fixed band 22 is fixed, for example, along four bolt portions 21 as rectangular bands, and functions to support the bolts 21 at the bottom as well as fixing the bolt portions 21. [

The fixed band 22 is not limited to a band, but may be a plate.

The column fastener 20 can be fixed to the pile 1 before the pillar 10 is connected after the pile 1 has been applied.

On the other hand, the files 1 are installed at regular intervals from each other and support the columns 10, and are not connected to each other. Of course, it is also possible that a plurality of files 1 are not combined with each other by connection, but a larger supporting force can be secured by integrating a plurality of files 1, so that it is also possible to constitute as follows.

After the ground is tapped to a certain depth so as to be connected to the file 1 between the files 1, the reinforcing bars are placed in the tearing space and the concrete is laid on the ground reinforcement member 4. Accordingly, the plurality of files 1 are synthesized through the reinforcing concrete composite ground reinforcement 4. Preferably, an auxiliary pile 5 (C-shaped steel) is provided in the ground reinforcement member 4.

3. Installing the column.

The column (10) is fixed to a column fastener (20) whose bottom is fixed to the head of the pile (1).

The column 10 is a tube, and a column fastener 20 and a file fixing plate 11 for fixing the column 10 are formed at the bottom.

The file fixing plate 11 is a rectangular plate having a larger area than the pillar 10, and bolt through holes are provided in the four corners thereof.

The column 10 is fixed by fixing the bolt 21 of the column fastener 20 to the bolt through hole while fixing the bottom of the file fixing plate 11 on the column fastener 20 .

In the meantime, it is difficult to fit one column 10 to the height of the power house. Therefore, two or more pipes can be connected and used. Each pipe is formed with a connecting plate at its longitudinal end, (Or welding), or a connection pipe inserted into two neighboring pipes in order to increase the connection strength of each pipe can be applied.

4. Install the pole posts.

A plurality of pillars 10 are installed through the entire process, and the pillars 10 are connected to each other to form a pillar cross bar 30 for the integral synthesis.

The pillar crossbar 30 is connected to the column 10 adjacent to both sides in the longitudinal direction as each pipe. 3, the column connecting plate 12 is formed on the side of the column 10, the column connecting plate 31 is formed on the longitudinal end of the column crossing 30, and the column connecting plate 12 and the column connecting The plate 31 is formed with bolt holes communicating with each other, and the bolt 32 is fastened to the bolt holes so that the post 30 is connected between the posts 10.

The pillar crossbar 30 is installed between the pillars 10 at a predetermined height mutually in accordance with the structure of the power house. In the figure, a pillar cross bar 30 is shown to be installed on the ground reinforcement 4.

The pillar crosspiece 30 is disposed higher than the ground, and a groove is formed between the pillar crossbars 30, and the pits 30 can contain air purifying and charcoal 6 for moisture removal. It is preferable that the charcoal 6 is contained in the net and stored in the groove. For example, the charcoal 6 is laid at a height of 30 cm to remove the energy barrier moisture of the sow, and to prevent the sickness.

5. Construction of one-story slab.

After completing the construction of the columns 10, the slab is constructed as follows.

First, the present invention forms an air pocket (A) between a one-story slab and a ground. The air pocket (A) is an air layer between the ground and one-layer slab, and this air layer functions as an insulation.

As shown in FIGS. 1 and 4, the one-story slab 40 includes a slab crossbar 41, a bottom insulator 42, a deck plate 43, an upper insulator 44, a hot water pipe 45, .

The slab crossbar 41 is fixed to the adjacent pillars 10 on both sides in the longitudinal direction while the slab crossbar 41 is arranged transversely between adjacent pillars 10 (fixed in the same manner as the pillar crossbar 30 described above) ]do.

On the other hand, when the slab cross bar 41 is provided only between the columns 10, a sag is generated at a position far from the column 10, so that a cross beam can be additionally provided between the slab cross bars 41. The cross beams are fixed to the slab crossbars 41 adjacent to each other in the longitudinal direction (same as the fixed structure of the slab crossbars 41 and the columns 10).

In addition, it is also possible to provide a plate for supporting the heat insulating material 42 or the like installed on the upper part of the upper side of the slab cross bar 41.

The lower heat insulating material 42 is installed on the slab cross bar 41 as a usual plate type heat insulating material and can be fixed to the deck plate 43 through fasteners (pieces or the like).

On the other hand, a reinforcing material 47 for reducing the upper load may be provided at the edge of the lower heat insulating material 41.

The reinforcing member 47 is fixed to the edge of the slab cross bar 41 as a pipe by welding or the like.

The deck plate 43 can be used as a prefabricated product widely used in the field of construction (a plate, a plurality of truss reinforcements provided on the plate, concrete to be laid back), and the deck plate 43 is placed on the heat insulating material 42, And is supported on the cross bar (41).

At the edge of the deck plate 43, a side panel 48 for supporting the deck plate 43 and preventing sagging is provided, together with a function of closing a concrete installation space. The side panels 48 may be provided to block between the columns 10.

The side panel 48 includes a lower horizontal portion, a vertical portion extending from an outer end of the lower horizontal portion, and an upper horizontal portion extending from the upper end of the vertical portion in a direction opposite to the lower horizontal portion. The lower horizontal part is interposed between the bottom part of the deck plate 43 and the slab cross bar 41 and welded to the slab cross bar 41. The vertical part is welded to the side face of the deck plate 43 And the upper vertical portion may be fixed to a material installed on the outside of the column 10. [

The upper insulation 44 is installed on the deck plate 43 with the same product as the lower insulation 42. [

The hot water pipe (45) is a boiler pipe which is normally used as a boiler pipe in the field of construction and is installed by a conventional method.

After the hot water pipe 45 is installed, the concrete can be installed in accordance with the height of the inside of the deck plate 43 and the hot water.

The floor material 46 is an indoor floor, and various products can be used.

6. Wall construction.

An outer wall heat insulating material (50) is provided on the outside of the columns (10).

The outer wall heat insulator 50 is used as it is as a conventional outer wall heat insulator. C-shaped steel is used as the heat insulator fixture 51.

The heat insulating fixture 51 is fixed to the column 10 by welding or the like while arranging the heat insulating fixture 51 in the lateral direction outside the column 10. [ Of course, the heat insulating fixture 51 may be installed at two or more stages having different heights in order to stably fix the outer wall heat insulating material 50.

The outer wall heat insulator 50 is fixed to the heat insulator fixture 51 through a fastener while standing up against the wall surface on the outside of the heat insulator fixture 51.

It is also possible to provide the inner wall heat insulator inside the column 10 through the same method. That is, as shown in FIG. 5, a heat insulating material fixture 61 of C-shaped steel is provided on the inside of the column 10 and the inner wall heat insulating material 60 is fixed to the heat insulating material fixing hole 61 by fastening means.

After the outer wall insulator 50 and the inner wall insulator 60 are installed, the outer wall and the inner wall are closed through the finishing material 80.

The finishing material can be various kinds of finishing materials such as a stone panel, wood, gypsum board, gypsum, and art wall.

The glass wool 52 is inserted into the space between the outer wall heat insulating material 50 and the column 10 in order to further increase the heat insulating effect. The glass wool 52 has the characteristics of adiabatic and non-burnable, and the channel 53 (in the form of opening toward the upper part) is installed laterally in the space between the column 10 and the outer wall heat insulating material 50 in one or more stages [ (Fixed to the outer wall heat insulating material 50 through the fastening tool 54) to divide into a multi-stage space, and the glass wool 52 is inserted into the divided space. Of course, the inside of the glass wool 52 is not exposed toward the room through the inner wall heat insulator 60.

According to the present invention, a space is formed between the pillars 10, and as shown in FIGS. 6 and 7, the space is provided in the space between the electrical wiring line E and the upper drain pipe P for electric wiring and water / .

A door for entrance and exit and a window for mining should be installed at the time of constructing such a wall, and a door and a window are installed through the same method as shown in FIG. 6, and a window will be described as an example.

Window frame supports 70-1 and 70-2 for installing window frames W between the columns 10 are installed on the upper and lower sides.

The upper and lower window frame supports 70-1 and 70-2 are C-shaped steel and the opening portions are arranged opposite to each other, and both sides in the longitudinal direction are fixed to the adjacent columns 10. [

The upper and lower window frame supports 70-1 and 70-2 are respectively provided with fixing plates 71-1 and 71-2 at both ends in the longitudinal direction.

The upper and lower fixing plates 71-1 and 71-2 are preferably provided with four fixing holes. At least one of the upper and lower fixing plates 71-1 and 71-2 has a long hole for adjusting the position thereof. Lt; / RTI &gt;

That is, a window frame W is installed between the upper and lower window frame supports 70-1 and 70-2. In this process, the height of the upper window frame support 70-1 is adjusted so that the upper window frame support 70 -1) is firmly mounted on the upper portion of the window frame W and fixed to the column 10 to firmly install the window frame W. The bolts for fixing the upper and lower window frame supports 70-1 and 70-2 to the columns 10 are both vertically and horizontally fastened.

The column 10 may be vulnerable to thermal insulation and the foamed thermal insulation material 13 may be provided inside the column 10 so as to provide an excellent thermal insulation effect in the column 10. [ Is applied.

The column 10 is a space in which the inside is hermetically sealed with the outside, and the urethane foam agent is injected into the inside of the column 10 to make the foamed heat insulator 13. Of course, the foamed heat insulating material 13 may be manufactured at a factory when the column 10 is manufactured, or may be replaced with another heat insulating material having an equivalent function.

After the wall construction is completed, two or more slabs are constructed in the same manner as the one-story slab 40. [

The wall has an inner wall dividing the outer wall and the room into a bedroom, a toilet, a living room, a kitchen, etc. Both the outer wall and the inner wall are constructed by the above-described method, and of course, the inner material suitable for the outer wall and the inner wall is selected.

7. Roof construction.

It is also possible to finish the construction of the power house through the construction of the uppermost slab. However, it is also possible to construct a roof to enhance the design aesthetics of the power house.

8, in order to construct the roof 90 inclined downwardly to the edge, the height of the edge is lowered to the column 10, and a horizontal beam 14 is formed on each column 10 Install it. Since the beam 14 is provided on the column 10, it is also possible to provide the beam 14 with the same height and with the edge to the lower height.

An inclined support 15 is installed on the upper part of the beam 14 in accordance with the inclination of the roof 90.

The inclined support 15 includes a bottom portion 15a fixed to the upper surface of the beam 14 by being seated and welded, an inclined portion 15b inclinedly connected to the upper portion of the bottom portion 15a and supported by the roof 90, .

The bottom portion 15a and the inclined portion 15b are reinforced and connected through the vertical reinforcing portion 15c. That is, the inclined portion 15b can be reinforced and connected through the reinforcing portion 15c formed at the substantially central portion of the bottom portion 15a while extending at one side end of the bottom portion 15a at an angle, May be formed to be inclined from the upper end of the reinforcing portion 15c erected at the substantially central portion of the bottom portion 15a.

A roof 90 is installed on the top of the slope support 15.

The roof 90 includes a roof frame 91, an upper panel 92 and a lower panel 93 installed at the upper and lower portions of the roof frame 91 and the upper and lower panels 93 and 91, And a finishing material 94 (tile or the like).

The roof frame 91 is mounted on the upper part of the inclined portion 15b of the inclined support 15 as a C-shaped steel and fixed through a fastening hole. A plurality of the roof frames 91 are installed at regular intervals from each other, .

The upper and lower panels 92 and 93 are made of a material that can be used as a roof material, and are fixed to the roof frame 91 through fasteners.

The decorative finish 94 is installed on the top (outer surface) of the top panel 92 to provide a variety of roofs 90.

On the other hand, a ceiling panel 95 is provided on the inside (lower side) of the roof 90 for the purpose of insulation.

The ceiling panel 95 is preferably a heat-insulating product and can be suspended from the lower panel 93 through the hanger bar 96.

Since the ceiling panel 95 has the roof 90 and the air layer, the insulation effect is doubled.

A bracket for supporting the ceiling panel 95 at the bottom can be applied to the peripheral surface of the column 10.

In this way, a power house as shown in FIG. 9 is constructed. The material used in the present invention has excellent strength characteristics and the bonding strength of each material is very high, so that even if earthquake such as an earthquake occurs, the collapse risk is very low through the bearing force.

On the other hand, the present invention can be constructed as houses with two or more floors, and the two-story building can be rotated in such two or more floors.

As shown in FIG. 10, a two-story building 2F is installed on the one-story building 1F through the turning means 100 so that the two-story building 2F is turned.

10 to 12, the turning means 100 includes at least one turning motor 110 and two turning rollers 111 (shown as two in the drawing) installed on the roof bottom surface of the one story building 1F, A guide roller 112 formed on the bottom of the two-story building 2F and seated on a turning roller 111 and a guide roller 112 and provided with a turning roller 111 And a circular rail 113 which rotates in place and turns the two-story building 2F.

Two turning rollers 111 and two guide rollers 112 are alternately arranged along the circumferential direction along the rails 113 to induce stable turning of the two-story building 2F.

For example, a bolt rod 114 is formed at the bottom of the two-story building 2F, and the bolt rod 114 is formed at the bottom of the two-story building 2F. And is fixed by a nut 115 through a ceiling portion of the first story building 1F and a washer 116 therebetween.

The slip ring 116 is used as a method of supplying electricity to the two-story building 2F in the first story building 1F. The slip ring 116 is known as a material for supplying electric power to the rotating body and is coupled to the bolt rod 114 or the like. Therefore, electricity is supplied from the interior of the first story building (1F) to the outside of the second story building (2F) without separately performing the electric wiring, thereby relieving the discomfort caused by the electric wiring.

It is preferable that the ceiling portion of the first story building 1F is closed with a box so that the bolt rod 114 and the like can not be seen from the room.

In addition, a sunroof can be applied to the uppermost building so that the outdoor can be seen from the inside of the building.

As shown in FIG. 13, the sunroof 200 includes a transparent window 210 installed in an open portion formed in a ceiling portion of an uppermost layer such as a two-story building 2F, a transparent window 210 at the bottom of the transparent window 210, A door 220 installed to open and close, and an opening / closing means 230 of the door 220.

The transparent window 210 is made of transparent acrylic or the like so that it can be seen from outside the room. An open part is formed on the ceiling part of the two-story building 2F, and the transparent window 210 is installed in the open part.

The door 220 is slidably connected to a rail 221 installed on a ceiling portion of a two-story building 2F as a slide door so that both sides thereof are slidably connected. For example, a roller 222 is formed on both left and right sides, .

As shown in FIG. 14, the rail 221 has a blocking jaw 223 to prevent outside air and water from penetrating into the room.

The opening and closing means 230 includes a motor 231 for generating bi-directional rotational force, a driving drum 232 for receiving rotation of the motor 231 and a driving drum 232 for rotating the door 231. The opening and closing means 230 wind the door 233 on the opposite side to the driving drum 232, And a wire 234 which is fixed to the window 220 and slides in both directions by the rotational force of the driving drum 232 to open or close the transparent window 210. [

1: file, 2: head reinforcement element
3,5: auxiliary file, 4: ground reinforcement element
10: column, 11: file fixing plate
12: crossbar connecting plate, 13: foaming insulation
14: beam 20: column fastener
30: column post, 40: slab
41: slab crossbar, 42: bottom insulation
43: deck plate, 44: upper insulation
45: Hot water pipe, 46: Flooring
47: stiffener, 48: side panel
50: external heat insulator, 51: heat insulating fixture
60: Inner insulation, 70-1, 70-2: Upper and lower window frame supports
80: Finishing material, 90: Roof,
100: turning means, 110: turning motor
111: turning roller, 112: idler roller
113: rail, 114: bolt
115: nut, 116: slip ring
200: sunroof, 210: transparent window
220: door, 230: opening / closing means

Claims (13)

A first step of installing a plurality of files 1 in the ground at a certain distance from each other according to the structure of the power house;
A second step of fixing a column 10 made of a pipe to the head of the pile installed in the first step and fixing the pillars 10 to each other and providing a pillar crossbar 30 between the pillar to reinforce the pillars;
A third step of installing a slab (40) in an inner space of the columns installed in the second step;
A fourth step of constructing a wall at the periphery of the slabs and the pillars constructed in the third step;
And a fifth step of constructing the roof 90 after the fourth step,
The first step is to integrate the neighboring files by erecting the ground between the files, installing reinforcing bars and concrete in the terra cotta space to construct the ground reinforcement,
In the third step, a slab crossbar 41 of each pipe is installed in a lateral direction between neighboring columns, a stiffener of each pipe is installed at the edge of the slab crossbar, and a lower thermal insulator 42 is installed inside the reinforcing material A deck plate 43 is installed on the upper part of the lower heat insulating material and a side panel 48 for supporting the deck plate to prevent sagging is provided as well as a function of closing a concrete installation space at the edge of the deck plate The upper dehumidifier 44 is installed on the deck plate, the hot water pipe 45 is installed on the upper dehumidifier, the floor material 46 is installed,
In the fourth step, the heat insulating material fixture 51 of the C-shaped steel is installed laterally on the outside of the column, the outer wall heat insulating material 50 is fixed to the heat insulating material fastener 51, and the heat insulating material 50 of the C- The inner wall heat insulating material 60 is fixed after the fixture 61 is installed and glass wool is inserted into the space between the outer wall thermal insulating material and the column in a multistage manner in the space between the outer wall thermal insulating material and the column, And a door frame and a window frame are installed between the upper and lower support frames. At least one of the upper and lower support frames has a slot And the height of the power house is adjusted through the height adjustment. delete delete delete The method of claim 1, wherein the first step comprises fixing a column fastener having a plurality of bolt portions facing upward on a head portion of the pile, and the second step comprises assembling the bottom of the pillar to match the bolt portion of the column fastener And the column is installed through fastening of the rear nut.
The method of claim 1, wherein the second step is to apply a thermal insulator to the inside of the column. [5] The method of claim 1, wherein the step 5) comprises the steps of installing a horizontal beam on the upper part of the columns, providing an inclined support on the beam, and installing a plurality of roof frames on the upper part of the inclined support, And roofs are installed by installing upper and lower panels on upper and lower portions of the roof frame, respectively. [7] The method of claim 7, wherein the fifth step comprises installing a ceiling panel with an air layer at a lower portion of the roof. [2] The method of claim 1, wherein the prefabricated power house construction method comprises constructing a one-story building and a two-story building, wherein the two-story building is rotated to be rotated through a turning means. [12] The turning device according to claim 9, wherein the turning means comprises at least one turning motor installed on the roof bottom of the one-story building, a turning roller rotated by the turning motor, one or more guides A roller formed on the bottom of the two-story building and mounted on the turning roller and the guide roller and rotated in place by rotation of the turning roller to turn the two-story building; And a bolt rod (114) fastened to the one-story building through a ceiling of the one-story building and rotated by a nut to be rotated. [6] The method of claim 1, wherein the fifth step comprises constructing an openable and closable sunroof capable of seeing the outside from inside the roof. The method as claimed in claim 1, wherein the second step is to store charcoal in a predetermined thickness inside the cross bar. Wherein the housing is constructed by a method of constructing a power house according to claim 1.

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