KR102508780B1 - Wood structure panelizing manufacturing method using vacuum insulation material as an ecological carbon-neutral energy agent - Google Patents

Abstract

The present invention relates to a wooden structure panelizing manufacturing method using an ecological carbon-neutral zero-energy vacuum heat insulating material realized to enable the manufacture of an eco-friendly, zero-energy wooden foldable architecture that is sustainable for 100 years. According to the present invention, the wooden structure panelizing manufacturing method using an ecological carbon-neutral zero-energy vacuum insulation comprises: a structure manufacturing step of manufacturing a structure that forms a frame of a panel with framing lumber according to the structure calculation; a heat insulating material filling step of filling a heat insulating material in a space between the framing lumber pieces; a lumber attachment step of covering the heat insulating material and attaching the framing lumber; a sheet installation step of installing a moisture-permeable waterproof sheet and an airtight sheet on the outer surface of the lumber; a panel connection step of connecting and installing each panel manufactured by the sheet installation step with each other using a connection hardware; and a piping installation step of installing the piping.

Description

Wood structure panelizing manufacturing method using vacuum insulation material as an ecological carbon-neutral energy agent}

The present invention relates to a method for manufacturing wood structure panelizing using vacuum insulation as an ecological carbon neutral energy zero, and more particularly, to an ecological carbon neutral energy zero vacuum insulation material realized to enable the manufacture of foldable wooden buildings as a sustainable eco-friendly energy zero for 100 years. It relates to a method for manufacturing wood structure panelizing using the present invention.

To create a virtuous cycle village for water, energy, and carbon cycles in residential space, a high-level technology industry focused on developing and commercializing future technologies is needed, and social demand for ecologically carbon-neutral zero-energy residential technology is increasing.

In accordance with the global trend of regulating carbon dioxide emissions to prevent environmental destruction due to accelerated global warming, carbon capture and storage technology (CCS) alone is reaching its limits. Carbon neutrality is realized by using wood, and a construction method using wood is being proposed as an alternative. In addition to this, a house is constructed using wood with excellent insulation performance, and an energy-free construction method with enhanced insulation is proposed as an alternative.

Therefore, the government and local governments are adopting carbon-neutral energy-free construction techniques as a new alternative, and the demand for the use of wood is explosively rising.

It is time for institutional improvement to sell carbon credits by issuing credits corresponding to the amount of reduction when carbon-neutral energy is reduced according to building technology.

Currently, concrete, steel frame, rebar, bricks, etc., which are common building materials, emit a lot of greenhouse gases during the raw material collection and manufacturing process, and are pointed out as the main culprit of global warming. Stability is questioned. Buildings consume enormous amounts of energy both in the construction phase and in use and disposal. However, wood plays an important role in absorbing carbon dioxide and preventing global warming during the process of growing for more than 20 years. )

Therefore, wood has many pores and contains a lot of air in its cells, so it acts as a very good natural insulation material. It has been proven to be an effective structure that increases energy efficiency by using excellent insulation materials such as wool.

As such, construction techniques using excellent natural materials are facing the needs of the times, and only the prefab foldable wooden house manufacturing technique, which can dramatically reduce the construction period in the construction process, will be the only alternative that meets the social needs of the times.

According to the special design, all products including the structure, interior materials, exterior materials, electrical facilities, air conditioning facilities, water supply and drainage facilities, bathroom facilities, and furniture products that make up the building are attached in the manufacturing process to complete the building. We have completed a system that can be delivered, and we plan to provide a system that can be quickly and simply unfolded at the building site to complete the building.

As a result, it is possible to build a building with a durability of more than 100 years, minimize construction waste generated in the disposal process and quantitatively reduce the environmental impact due to recycling, etc. Building manufacturing techniques can be presented as a new alternative.

On the other hand, the above-mentioned background art is technical information that the inventor possessed for derivation of the present invention or acquired in the process of derivation of the present invention, and cannot necessarily be said to be known art disclosed to the general public prior to filing the present invention. .

Korean Patent Registration No. 10-1402959 (2014.06.02. Notice)

One aspect of the present invention provides a method for manufacturing wooden structure panelizing using vacuum insulation as an ecological carbon neutral energy agent realized to enable the manufacture of foldable wooden buildings as a sustainable eco-friendly energy agent for 100 years.

The technical problem of the present invention is not limited to the technical problem mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

A method for manufacturing wood structure panelizing using vacuum insulation as an ecological carbon neutral energy agent according to an embodiment of the present invention includes a structure manufacturing step of manufacturing a structure for forming a skeleton of a panel with structural wood according to structure calculation; A heat insulating material filling step of filling a heat insulating material in the space between the structural timbers; A plywood attachment step of covering the heat insulating material and attaching a structural plywood; A sheet installation step of installing a moisture-permeable waterproof sheet and an airtight sheet on the outer surface of the plywood; A panel connection step of connecting and installing each panel manufactured by the sheet installation step with each other using a connection hardware; and a pipe installation step of installing the pipe.

" 형상으로 절곡 형성되어 서로 대향하면서 설치되는 두 구조목의 각 대향면에 설치되어 상기 제1 자바라식 브라켓, 상기 진공 단열재, 및 상기 제2 자바라식 브라켓에 의해 이루어지는 단열 구조물의 일측 및 타측 내측면을 체결하는 내측 브라켓; 및 "

" 형상으로 절곡 형성되어 서로 대향하면서 설치되는 두 구조목의 각 대향면에 설치되며, 상기 내측 브라켓에 의해 지지 중인 상기 단열 구조물의 일측 및 타측 외측면을 체결하는 외측 브라켓;을 포함할 수 있다.In one embodiment, the insulator is formed in the form of a corrugated bellows-type flat plate capable of extension or contraction in the left and right directions, and a first bellows type bracket installed covering the space between the structural necks; A vacuum insulator installed covering the front surface of the first bellows type bracket facing the outdoor or indoor environment; A second bellows type bracket formed in the form of a corrugated bellows flat plate capable of extension or contraction in the left and right directions and installed covering the front surface of the vacuum insulator facing the outside or inside the room; "

One side and the other inner side of the insulation structure formed by the first bellows type bracket, the vacuum insulator, and the second bellows type bracket installed on each opposing surface of two structural timbers bent in a shape and installed while facing each other. An inner bracket for fastening; and "

It is installed on each opposing surface of two structural timbers bent in a shape and installed while facing each other, and an outer bracket fastening one side and the other outer surface of the insulation structure supported by the inner bracket.

In one embodiment, the structural plywood may be made of structural OSB plywood.

" 형상으로 절곡 형성되며, 일측이 서로 인접하여 배치되는 제1 패널과 제2 패널 중 상기 제1 패널의 타측 상단 및 하단에 각각 연결 설치되고, 타측이 상기 제2 패널 일측 상단 및 하단에 각각 연결 설치되는 제1 절곡 프레임; 및 상기 제1 절곡 프레임와 대칭 구조인 "

" 형상으로 절곡 형성되며, 타측이 상기 제2패널의 일측 상단 및 하단에 각각 연결 설치되고, 일측이 상기 제1 패널의 타측 상단 및 하단에 각각 연결 설치되며, 중단 절곡 부위가 상기 제1 절곡 프레임의 중단 절곡 부위와 "X" 형상으로 접철 가능하도록 연결 설치되는 제2 절곡 프레임;을 포함할 수 있다.In one embodiment, the connection hardware, "

Of a first panel and a second panel that are bent into a " shape, one side of which is disposed adjacent to each other, the first panel is connected to the top and bottom of the other side of the first panel, and the other side is connected to the top and bottom of one side of the second panel, respectively. A first bending frame installed; And a structure symmetrical with the first bending frame "

It is formed bent in a " shape, the other side is connected to the upper and lower ends of one side of the second panel, and the one side is connected to the upper and lower ends of the other side of the first panel, respectively, and the middle bent portion is installed in the first bending frame. A second bending frame connected and installed to be foldable in an “X” shape with the middle bent portion of the; may include.

In one embodiment, the panel, a plurality of buffer units for buffering vibration or shock generated between other panels installed adjacent to one side are spaced apart in the vertical direction along one side where the other panel is closely disposed. It can be.

In one embodiment, the buffer unit is formed in the form of a hexahedral box in which the front end facing the other panel is formed open, and the installation case inserted into one side of the panel; a fixing bolt that passes through an inner surface of the installation case and is inserted to fix the installation case to one side of the panel; Close contact block installed in the installation case so that the front end is exposed from the installation case; A first block support that is installed on one side of the inner space of the installation case to support one side of the close contact block and at the same time buffer vibration or shock transmitted from the close contact block; A second block support that is installed on the other side of the inner space of the installation case while facing the first block support and supports the other side of the close contact block and at the same time buffers vibration or shock transmitted from the close contact block; and a contact plate formed along the front surface of the contact block so that the gear mount formed along the front face of the contact block can be seated while being engaged with, and installed on a side surface of the other panel while facing the contact block.

In one embodiment, the first block support portion, the installation block installed on one side of the inner space of the installation case; Vertical sliding grooves extending in vertical directions along the front end of the installation block; a vertical slider connected to and installed in the vertical sliding groove to enable sliding movement in vertical directions; first buffer springs installed on the upper and lower sides of the vertical sliding groove, respectively, to support the upper and lower sides of the vertical slider seated in the vertical sliding groove; a curved sliding groove extending along the front end of the vertical slider in a ")" shape with a middle end facing the other panel; A curved slider formed to be bent in a round shape corresponding to the curvature of the curved sliding groove, connected and installed to be slidably movable while drawing an arc in the curved sliding groove, and fastening and supporting one side of the contact block; and second buffer springs respectively installed on the upper and lower sides of the curved sliding groove to support the upper and lower sides of the curved slider seated in the curved sliding groove.

In one embodiment, the curved slider is formed to be bent in a round shape corresponding to the curvature of the curved sliding groove, upper and lower sides are supported by the second buffer spring, the curved frame seated in the curved sliding groove; and a plurality of frame support units spaced apart from each other at regular intervals along the inward and outward surfaces of the curved frame to support the curved frame in the curved sliding groove.

In one embodiment, the frame support portion, while forming an opening to the inward or outward surface of the curved frame, the slider seating groove formed in the curved frame; a support slider seated in the slider seating groove; a support sphere rotatably connected to the front end of the support slider exposed from the slider seating groove; a slider support spring installed inside the slider seating groove to support the inside of the support slider seated in the slider seating groove; and disposed along the inside of the slider support spring to support the inside of the support slider seated in the slider seating groove and installed inside the slider seating groove, as the support slider is inserted into the slider seating groove. A support cylinder that supplies the fluid contained in the inner space to another frame support that is not compressed, and expands as the fluid is supplied from the other frame support to expose the support slider from the slider seating groove. .

According to one aspect of the present invention described above, as a product that must be produced by selecting eco-friendly materials together with wood, it provides an ecological environment for living space to improve the quality of life, thereby completing the virtuous cycle of water / energy / carbon cycle. If this is achieved, it is expected that it will provide solutions to the immediate problems of the social ecological system.

Recently, the international community has paid attention to wood, which stores 250 kg of carbon per cubic meter through photosynthesis, as a way to solve the problem of climate change. Assuming that the average amount of wood used per wooden house is 36㎥, the amount of stored carbon reaches about 9 tons, and it contributes to the prevention of environmental pollution by reducing the generation of carbon dioxide in the processing process.

In addition, since it is possible to propose a plan to flexibly reorganize not only the local housing system, but also the housing system of the entire country macroscopically, a new concept of ecological construction plan through technology for commercialization of water/energy/carbon cycle and stabilization of quality of life. It is expected to contribute to the development of the local economy through sales increase.

Effects of the present invention are not limited to the effects mentioned above, and various effects may be included within a range apparent to those skilled in the art from the contents to be described below.

1 is a flowchart illustrating a method of manufacturing wood structure panelizing using a vacuum insulation material as an ecological carbon neutral energy agent according to an embodiment of the present invention.
2 is a view showing a heat insulating material according to the present invention.
6 is a view showing a panel manufactured according to the present invention.
7 is a view showing a connection relationship between panels manufactured according to the present invention.
8 is a view showing a buffer unit according to the present invention.
9 to 11 are views showing a buffer unit according to the present invention.
FIG. 12 is a view showing the first block support portion of FIG. 11 .
13 is a view showing the curved slider of FIG. 12;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The detailed description of the present invention which follows refers to the accompanying drawings which illustrate, by way of illustration, specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable one skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different from each other but are not necessarily mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in another embodiment without departing from the spirit and scope of the invention in connection with one embodiment. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description set forth below is not to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all equivalents as claimed by those claims. Like reference numbers in the drawings indicate the same or similar function throughout the various aspects.

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

1 is a flowchart illustrating a method of manufacturing wood structure panelizing using a vacuum insulation material as an ecological carbon neutral energy agent according to an embodiment of the present invention.

Referring to FIG. 1, in the method of manufacturing wood structure panelizing using vacuum insulation as an ecological carbon neutral energy agent according to an embodiment of the present invention, first, structural wood 11 (for example, 2X4, 2X6, 2X8, 2X10, etc.) to manufacture the structure 10 forming the skeleton 10 of the panel 50 (S110).

The space between the structural timbers 11 is filled with the heat insulating material 20 as described in FIG. 2 (S120).

Cover the insulator 20 and attach the structural plywood 30 (S130).

In one embodiment, the structural plywood 30 may be made of structural OSB plywood.

A moisture-permeable waterproof sheet and an airtight sheet are installed on the outer surface of the plywood (S140).

Using the connection hardware 40, each panel 50 manufactured by the sheet installation step is connected to each other and installed (S150).

As shown in FIG. 2, the panel 50 manufactured thereby is completed using a design for a foldable technique implemented so that each panel 50 can be folded and unfolded, so it is folded during movement or storage to reduce the overall volume , It can be unfolded during construction to easily realize the appearance of a complete house.

Piping (for example, various piping facilities and power piping, etc.) is installed (S160).

The method for manufacturing wood structure panelizing using vacuum insulation as an ecological carbon neutral energy agent according to an embodiment of the present invention having the configuration as described above is a product that needs to be produced by selecting and producing eco-friendly materials together with wood. When the virtuous cycle of water/energy/carbon cycle is completed by improving the quality of life by providing an ecological environment, it is expected that solutions to current problems of the social ecological system will be presented.

Recently, the international community has paid attention to wood, which stores 250 kg of carbon per cubic meter through photosynthesis, as a way to solve the problem of climate change. Assuming that the average amount of wood used per wooden house is 36㎥, the amount of stored carbon reaches about 9 tons, and it contributes to the prevention of environmental pollution by reducing the generation of carbon dioxide in the processing process.

In addition, since it is possible to propose a plan to flexibly reorganize not only the local housing system, but also the housing system of the entire country macroscopically, a new concept of ecological construction plan through technology for commercialization of water/energy/carbon cycle and stabilization of quality of life. It is expected to contribute to the development of the local economy through sales increase.

The wooden structure panelizing manufactured by the method of manufacturing wooden structure panelizing using vacuum insulation as an ecological carbon neutral energy agent according to an embodiment of the present invention having the configuration described above is all interior and exterior materials as shown in FIG. As a completed high-insulation wooden house, the construction period can be drastically shortened by folding the wall and roof structure, moving them to the construction site, and then unfolding them.

2 is a view showing a heat insulating material according to the present invention.

Referring to FIG. 2 , the insulator 20 includes a first bellows bracket 21, a vacuum insulator 22, a second bellows bracket 23, an inner bracket 24 and an outer bracket 25. .

The first bellows type bracket 21 is formed in the form of a corrugated bellows flat plate capable of extension or contraction in the left and right directions and is installed to cover the space between the structural necks 11.

The vacuum insulator 22 is installed to cover the front surface of the first bellows type bracket 21 facing the outdoors or indoors.

The second bellows-type bracket 23 is formed in the form of a corrugated bellows-type flat plate capable of extending or contracting in the left and right directions and is installed to cover the front surface of the vacuum insulator 22 facing the outdoors or indoors.

" 형상으로 절곡 형성되며, 도 3에 도시된 바와 같이 서로 대향하면서 설치되는 두 구조목(11)의 각 대향면에 설치되어 제1 자바라식 브라켓(21), 진공 단열재(22), 및 제2 자바라식 브라켓(23)에 의해 이루어지는 단열 구조물의 일측 및 타측 내측면을 체결한다.As shown in FIG. 4, the inner bracket 24 "

It is formed in a " shape and is installed on each opposing surface of the two structural timbers 11 installed while facing each other as shown in FIG. 3, the first bellows bracket 21, the vacuum insulator 22, One side and the other inner side of the heat insulation structure made by the bellows type bracket 23 are fastened.

" 형상으로 절곡 형성되며, 도 3에 도시된 바와 같이 서로 대향하면서 설치되는 두 구조목(11)의 각 대향면에 설치되며, 내측 브라켓(24)에 의해 지지 중인 단열 구조물의 일측 및 타측 외측면을 체결한다.As shown in FIG. 5, the outer bracket 25 "

One side and the other outer side of the heat insulation structure, which is formed in a " shape, is installed on each opposing surface of two structural timbers 11 installed while facing each other as shown in FIG. 3, and is supported by the inner bracket 24. to conclude

6 is a view showing a connection hardware according to the present invention.

Referring to FIG. 6 , the connecting hardware 40 includes a first bending frame 41 and a second bending frame 42 .

" 형상으로 절곡 형성되며, 일측이 서로 인접하여 배치되는 제1 패널(50)과 제2 패널(50) 중 제1 패널(50)의 타측 상단 및 하단에 각각 연결 설치되고, 타측이 제2 패널(50) 일측 상단 및 하단에 각각 연결 설치된다.The first bending frame 41 is "

Of the first panel 50 and the second panel 50 disposed adjacent to each other, one side is connected to the top and bottom of the other side of the first panel 50, and the other side is the second panel. (50) Connected and installed at the top and bottom of one side, respectively.

" 형상으로 절곡 형성되며, 타측이 제2패널(50)의 일측 상단 및 하단에 각각 연결 설치되고, 일측이 제1 패널(50)의 타측 상단 및 하단에 각각 연결 설치되며, 중단 절곡 부위가 제1 절곡 프레임(41)의 중단 절곡 부위와 "X" 형상으로 접철 가능하도록 연결 설치된다.The second bending frame 42 has a symmetrical structure with the first bending frame 41 "

It is formed bent in a " shape, the other side is connected to the top and bottom of one side of the second panel 50, and the one side is connected to the top and bottom of the other side of the first panel 50, respectively. 1 It is connected and installed so as to be foldable in an “X” shape with the middle bent portion of the bending frame 41.

In one embodiment, as shown in FIG. 8, the panel 50 is vibrated between panels 50-2 installed adjacently on one side (ie, between 50-1 and 50-2). Alternatively, a plurality of buffer units 100 for buffering shock may be spaced apart in the vertical direction along one side where the other panel 50-2 is closely disposed.

9 to 11 are views showing a buffer unit according to the present invention.

9 to 11, the buffer unit 100 includes an installation case 110, a fixing bolt 120, an adhesion block 130, a first block support unit 140, a second block support unit 150, and A contact plate 160 is included.

The installation case 110 is formed in the form of a hexahedral box in which the front end facing the other panel 50-2 is open and is inserted into one side of the panel 50.

The fixing bolt 120 penetrates the inner surface of the installation case 110 and is inserted to fix the installation case 110 to one side of the panel 50 .

The close contact block 130 is installed in the installation case 110 so that the front end is exposed from the installation case 110 .

The first block support 140 is installed on one side of the inner space of the installation case 110 to support one side of the close contact block 130 and at the same time absorb vibration or shock transmitted from the close contact block 130 .

The second block support part 150 is installed on the other side of the inner space of the installation case 110 while facing the first block support part 140 to support the other side of the close contact block 130 and at the same time from the close contact block 130. It dampens the transmitted vibration or shock.

The contact plate 160 forms a gear mountain 161 along the front surface so that the gear mountain 31 formed along the front surface of the contact block 130 can be engaged and seated, while facing the contact block 130 and other It is installed on the side of the panel 50-2.

A plurality of buffer units 100 having the configuration described above are installed along the contact surface between the panel 50-1 and the panel 50-2, which are disposed in close contact with each other, so that the panel 50-1 and the panel 50 -2) Reduction of noise that may occur in a building by making the fastening more firmly between the panels and effectively buffering the vibration or impact generated between the panels 50-1 and 50-2 And durability can be further improved.

FIG. 12 is a view showing the first block support portion of FIG. 11 .

Referring to FIG. 12, the first block support 140 includes an installation block 141, a vertical sliding groove 142, a vertical slider 143, a first buffer spring 144, a curved sliding groove 145, a curved A slider 146 and a second buffer spring 147 are included.

Here, the second block support portion 150 has the same configuration as the first block support portion 140 to be described later, and includes an installation block 141, a vertical sliding groove 142, and a vertical slider 143 of the first block support portion 140. ), the first buffer spring 144, the curved sliding groove 145, the curved slider 146 and the second buffer spring 147 can be equally applied, so the description is omitted to avoid duplication of description. to omit

The installation block 141 is installed on one side of the inner space of the installation case 110 .

The vertical sliding groove 142 extends vertically along the front end of the installation block 141 .

The vertical slider 143 is connected to and installed in the vertical sliding groove 142 to enable sliding movement in the vertical direction up and down.

The first buffer spring 144 is installed on the upper and lower sides of the vertical sliding groove 142, respectively, and supports the upper and lower sides of the vertical slider 143 seated in the vertical sliding groove 142.

The curved sliding groove 145 extends along the front end of the vertical slider 143 in a ")" shape so that the middle end faces the other panel 50-2.

The curved slider 146 is formed to be bent in a round shape corresponding to the curvature of the curved sliding groove 145, and is installed so as to be able to slide while drawing an arc in the curved sliding groove 145. Fastening one side of the close block 130 support

The second buffer spring 147 is installed on the upper and lower sides of the curved sliding groove 145, respectively, and supports the upper and lower sides of the curved slider 146 seated in the curved sliding groove 145.

The first block support 140 having the configuration described above effectively buffers vibrations or shocks that may occur in the vertical direction and the curved direction between the panels 50-1 and 50-2. As a result, it is possible to further improve durability and reduction of noise that may occur in a building.

13 is a view showing the curved slider of FIG. 12;

Referring to FIG. 13 , a curved slider 146 is a view showing a curved frame 200 and a plurality of frame supporters 300 .

The curved frame 200 is bent in a round shape corresponding to the curvature of the curved sliding groove 145, and the upper and lower sides are supported by the second buffer spring 147 and seated in the curved sliding groove 145.

The plurality of frame support parts 300 are spaced apart at regular intervals along the inward and outward surfaces of the curved frame 200 to support the curved frame 200 in the curved sliding groove 145 .

In one embodiment, the frame support 300 may include a slider seating groove 310, a support slider 320, a support sphere 330, a slider support spring 340, and a support cylinder 350.

The slider seating groove 310 is formed on the curved frame 200 while forming an opening on an inward or outward surface of the curved frame 200 .

The support slider 320 is seated in the slider seating groove 310 .

The support sphere 330 is rotatably connected to the front end of the support slider 320 exposed from the slider seating groove 310 .

The slider support spring 340 is installed inside the slider seating groove 310 to support the inside of the slider 320 seated in the slider seating groove 310 .

The support cylinder 350 is disposed along the inside of the slider support spring 340 and installed inside the slider seating groove 310 to support the inside of the support slider 320 seated in the slider seating groove 310, As the support slider 320 is inserted into the slider seating groove 310, the fluid contained in the inner space is supplied to the other uncompressed frame support 300, and the fluid is supplied from the other frame support 300. As it is extended, the support slider 320 is exposed from the slider seating groove 310.

The curved slider 146 having the configuration described above can transfer vibration or shock to the vertical slider 143 more stably as it moves along the curved sliding groove 145 more smoothly while drawing an arc.

The above-described embodiments are for illustrative purposes, and those skilled in the art to which the above-described embodiments belong can easily transform into other specific forms without changing the technical spirit or essential features of the above-described embodiments. You will understand. Therefore, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope to be protected through this specification is indicated by the following claims rather than the detailed description above, and should be construed to include all changes or modifications derived from the meaning and scope of the claims and equivalent concepts thereof. .

10: structure
20: insulation
30: plywood
40: connection hardware
50: panel

Claims (5)

A structure manufacturing step of manufacturing a structure that forms a frame of the panel with structural wood according to the structure calculation;
A heat insulating material filling step of filling a heat insulating material in the space between the structural timbers;
A plywood attachment step of covering the heat insulating material and attaching a structural plywood;
A sheet installation step of installing a moisture-permeable waterproof sheet and an airtight sheet on the outer surface of the plywood;
A panel connection step of connecting and installing each panel manufactured by the sheet installation step with each other using a connection hardware; and
Including; piping installation step of installing piping,
The insulation material is
A first bellows-type bracket formed in the form of a corrugated bellows-type flat plate capable of extension or contraction in the left and right directions and covering the space between the structural necks and installed;
A vacuum insulator installed covering the front surface of the first bellows type bracket facing the outdoor or indoor environment;
A second bellows type bracket formed in the form of a corrugated bellows flat plate capable of extension or contraction in the left and right directions and installed covering the front surface of the vacuum insulator facing the outside or inside the room;
"

One side and the other inner side of the insulation structure formed by the first bellows type bracket, the vacuum insulator, and the second bellows type bracket installed on each opposing surface of two structural timbers bent in a shape and installed while facing each other. an inner bracket for fastening; and
"

An outer bracket installed on each opposing surface of two structural timbers bent in a shape and installed while facing each other and fastening one side and the other outer side of the insulation structure being supported by the inner bracket; including, including Method for manufacturing wood structure panelizing using vacuum insulation as an ecological carbon neutral energy agent.
delete According to claim 1,
The structural plywood,
A method for manufacturing wood structure panelizing using vacuum insulation as an ecological carbon neutral energy agent made of structural OSB plywood.
According to claim 1,
The connecting hardware,
"

Of a first panel and a second panel that are bent into a " shape, one side of which is disposed adjacent to each other, the first panel is connected to the top and bottom of the other side of the first panel, and the other side is connected to the top and bottom of one side of the second panel, respectively. A first bending frame to be installed; And
A structure symmetrical with the first bending frame "

It is formed bent in a " shape, the other side is connected to the upper and lower ends of one side of the second panel, and the one side is connected to the upper and lower ends of the other side of the first panel, respectively, and the middle bent portion is installed in the first bending frame. A wooden structure panelizing manufacturing method using a vacuum insulation material as an ecological carbon-neutral energy agent, including;
According to claim 1,
the panel,
A plurality of buffer units for buffering vibration or shock generated between other panels installed adjacent to one side are spaced apart in the vertical direction along one side where the other panels are closely disposed,
The buffer unit,
an installation case formed in the form of a hexahedron box in which the front end facing the other panel is open and inserted into one side of the panel;
a fixing bolt that passes through an inner surface of the installation case and is inserted to fix the installation case to one side of the panel;
Close contact block installed in the installation case so that the front end is exposed from the installation case;
A first block support that is installed on one side of the inner space of the installation case to support one side of the close contact block and at the same time buffer vibration or shock transmitted from the close contact block;
A second block support that is installed on the other side of the inner space of the installation case while facing the first block support and supports the other side of the close contact block and at the same time buffers vibration or shock transmitted from the close contact block; and
A gear mountain formed along the front surface of the contact block forms a gear mountain along the front surface so that the gear mountain can be engaged and seated, and a contact plate installed on the side of the other panel while facing the contact block; includes,
The first block support,
An installation block installed on one side of the inner space of the installation case;
Vertical sliding grooves extending in vertical directions along the front end of the installation block;
a vertical slider connected to and installed in the vertical sliding groove to enable sliding movement in vertical directions;
first buffer springs installed on the upper and lower sides of the vertical sliding groove, respectively, to support the upper and lower sides of the vertical slider seated in the vertical sliding groove;
a curved sliding groove extending along the front end of the vertical slider in a ")" shape with a middle end facing the other panel;
A curved slider formed to be bent in a round shape corresponding to the curvature of the curved sliding groove, connected and installed to be slidably movable while drawing an arc in the curved sliding groove, and fastening and supporting one side of the contact block; and
Second buffer springs installed on the upper and lower sides of the curved sliding groove, respectively, to support the upper and lower sides of the curved slider seated in the curved sliding groove; wood structure panel using vacuum insulation as an ecological carbon neutral energy zero, including Rising manufacturing method.

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