KR102285693B1 - Insulating materials structure - Google Patents

Abstract

The present invention provides a composite structure of an insulated outer wall of a building. The composite structure of an insulated outer wall of a building comprises: an outer wall dividing an indoor space and an outdoor space; installation spaces formed in grid arrangement inside the outer wall; vacuum cubes inserted into and disposed in the installation spaces and having inner vacuum spaces; vacuum sensors measuring vacuum degrees of each vacuum cube; a vacuum provider providing vacuum to each vacuum cube; a first temperature sensor measuring first temperature of the indoor space; a second temperature sensor measuring second temperature of the outdoor space; and a controller using the vacuum provider to form a reference temperature difference where the measured first temperature and second temperature are set to variably control the vacuum degree measured by the vacuum sensors.

Description

Building insulation exterior wall composite structure {INSULATING MATERIALS STRUCTURE}

The present invention relates to a building insulation exterior wall composite structure, wherein lattice-shaped spaces are formed inside the wall of a building, vacuum cubes forming a vacuum inside each of the spaces on the lattice are arranged, and a cover is installed inside the wall Building insulation exterior wall composite that can achieve effective insulation by controlling the vacuum degree of vacuum cubes in real time to achieve a set temperature, maintaining the vacuum degree of the vacuum cubes constant in real time, and achieving a set temperature between the inside and outside of the wall It's about structures.

In general, a building refers to a building with a roof, columns, and walls among structures built on the ground. These buildings are constructed using various building materials, and as one of these building materials, recently, insulated walls that are convenient to install and inexpensive have been widely used.

The insulating wall as described above is assembled by placing an insulating material between two iron plates positioned to face each other.

In addition, the insulating wall can have different strength and flame retardancy depending on the material of the insulating material positioned between the two iron plates, and various types of insulating walls are manufactured and used according to the selection of the material of the insulating material.

Conventional insulated walls include an insulated wall that is configured such that the upper and lower plates are adhered to both sides of the heat insulator, as in Korean Patent Registration No. 10-1132153 (2012.03.26), and Republic of Korea Utility Publication No. 20-0475363 (2014.11.11). As in .20), when an insulated wall constructed in a building is exposed to fire, an insulated wall equipped with a fire extinguishing device that can easily extinguish a fire generated in the insulated wall has been proposed.

However, conventional insulated walls such as Korean Patent Publication No. 10-1132153 (2012.03.26) and Korean Utility Publication No. 20-0475363 (2014.11.20) are convenient to assemble and have the advantage of having flame retardancy, but , it was difficult to efficiently solve the inherent problem of insulated walls, which are vulnerable to fire, and when a fire occurs in a building constructed with insulated walls, it is difficult to prevent the spread of fire. There was a problem that was difficult to prevent.

In order to solve the above problems, the present invention forms lattice-shaped spaces inside the wall of a building, arranges vacuum cubes that create a vacuum inside each of the spaces on the lattice, and installs a cover from the inside of the wall A building insulation exterior wall composite structure that can maintain the vacuum degree of the vacuum cubes in real time, and control the vacuum degree of the vacuum cubes in real time to achieve a set temperature for the temperature difference between the inside and outside of the wall to achieve efficient insulation. intended to provide

In addition, the present invention provides a building insulation exterior wall composite structure capable of automatically controlling thermal insulation by arranging a heating coil or a cooling coil in an installation space in which each of the vacuum cubes is disposed to control the temperature of the installation space and the wall constituting the installation space. to do it for a different purpose.

In addition, the present invention detects the vacuum level of each of the vacuum cubes in real time, and when the control of the vacuum level is not performed normally, an alarm is generated to the outside so that the vacuum cube in which the abnormality has occurred can be replaced, and the corresponding cover It is another object to provide a composite structure of a building insulation exterior wall that can be opened.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention not mentioned may be understood by the following description, and will be more clearly understood by the examples of the present invention. Moreover, it will be readily apparent that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

In order to achieve the above object, the present invention provides a building insulation exterior wall composite structure.

The building insulation exterior wall composite structure includes an exterior wall partitioning indoors and outdoors, installation spaces formed in a grid arrangement inside the exterior wall, and vacuum cubes inserted and disposed in the installation spaces, in which a vacuum is formed and vacuum sensors for measuring the degree of vacuum of each of the vacuum cubes; a vacuum providing device for providing a vacuum to each of the vacuum cubes; a second temperature sensor for measuring a second temperature; and a controller for variably controlling the degree of vacuum measured from the vacuum sensors using the vacuum provider to achieve a difference between the measured first temperature and a reference temperature at which the second temperature is set.

Here, on one side of the exterior wall body on the indoor side,

Doors for opening and closing the installation spaces are installed,

Each of the doors is connected to one side of the outer wall to be rotatably opened and closed through a hinge end,

The hinge end,

It is axially connected to the motor shaft of the motor,

Preferably, the controller rotates the motor shaft using the motor to rotate and open and close the doors.

And the inner surface portion of each of the doors is formed with a protrusion corresponding to the size of each of the installation spaces,

In the circumferential area of the installation spaces,

It is preferable that a sealing in close contact with the inner surface of each of the doors connected to the protrusion is installed.

Also, the controller is

When the measured vacuum degree is less than or equal to a preset reference vacuum degree, a vacuum cube having a measured vacuum degree that is less than or equal to the reference vacuum degree is selected as an ideal vacuum cube,

Opening and closing the door opening and closing the installation space where the ideal vacuum cube is installed using the rotary motor to open the installation space,

It is preferable to transmit the information of the abnormal vacuum cube to an external server and generate an alarm notifying the occurrence of an abnormality through an alarm generator.

In particular, the vacuum provider,

have vacuum lines,

Each of the vacuum lines,

It is connected to each of the installation spaces through the inside of the outer wall,

A connection end is formed at an end of each of the vacuum lines,

In each of the vacuum cubes,

A vacuum injection terminal is formed,

The connecting end is

It is slidably coupled to the vacuum injection terminal to be detachable.

In addition, in each of the installation spaces,

a heating coil and a cooling coil are disposed;

The heating coil is provided with a current through a first current provider to achieve a constant heating temperature,

The cooling coil receives a current through a second current provider to achieve a constant cooling temperature,

The controller is

Controls driving of the first current provider and the second current provider.

In addition, in the heating coil,

The heating fins are formed to protrude,

The heating fins are

Inserted and contacted with a first insertion groove having a predetermined length formed around the vacuum cube,

In the cooling coil,

Cooling fins are formed to protrude,

The cooling fins are

Doedoe inserted into and contacted with a second insertion groove having a predetermined length formed around the vacuum cube,

The heating fins and the cooling fins,

When the vacuum cube is moved to be inserted into the installation space, the vacuum cube is inserted into the first and second insertion grooves.

In addition, the outer wall body,

forming an interspace formed between the installation spaces,

In the area between the

A lattice-shaped insulating space is formed,

The insulated space is

It is connected to the inlet hole and the outlet hole formed in the outer wall,

The inlet hole is connected to the first tube,

The outlet hole is connected to the second tube,

The first and second tubes are connected to a heat insulating material supplier for supplying a gel-like heat insulating material,

The controller is

According to a set period, the driving of the insulating material supply is controlled so that the gel-like insulating material is replaced in the insulating space using the first and second tubes.

In addition, an auxiliary heat insulating layer is buried inside both sides of the installation space to prevent a hot bridge and a cold bridge.

On the other hand, a pair of cylinders are installed on both sides of the installation space according to the present invention. The pair of cylinders has a shaft projecting forward.

Rails are respectively installed on the shafts of the pair of cylinders.

Accordingly, a pair of rails are installed on both sides of the installation space.

The pair of rails are coupled to move the door.

The pair of rails is connected to the linear motor.

The linear motor raises and lowers the door along the pair of rails under the control of the controller.

The controller uses a pair of cylinders to project the shaft to project the pair of rails.

By the above solution means, the present invention forms lattice-shaped spaces inside the wall of a building, arranges vacuum cubes that create a vacuum inside each of the spaces on the lattice, and installs a cover from the inside of the wall, , there is an effect of maintaining the vacuum degree of the vacuum cubes constant in real time, and controlling the vacuum degree of the vacuum cubes in real time to achieve a set temperature for the temperature difference between the inside and the outside of the wall to efficiently achieve thermal insulation.

In addition, the present invention has an effect of automatically controlling the insulation by controlling the temperature of the installation space and the wall forming the installation space by placing a heating coil or a cooling coil in the installation space where each of the vacuum cubes are arranged.

In addition, the present invention detects the vacuum level of each of the vacuum cubes in real time, and when the control of the vacuum level is not performed normally, an alarm is generated to the outside so that the vacuum cube in which the abnormality has occurred can be replaced, and the corresponding cover It has the effect of opening the

In addition to the above-described effects, the specific effects of the present invention will be described together while describing specific details for carrying out the invention below.

1 is a view showing a building insulation exterior wall composite structure of the present invention.
2 is a view showing a configuration example of a door for opening and closing an installation space according to the present invention.
3 is a view showing a configuration for opening a door and generating an alarm when an abnormal vacuum cube is selected from among the vacuum cubes according to the present invention.
4 is a view showing a connection process of a vacuum cube and a vacuum line.
5 is a view showing an example in which heating and cooling coils are installed around the installation space.
6 is a view showing an example in which fins are formed in the heating coil and the cooling coil according to the present invention.
7 is a view showing an example in which an insulating space is formed in an outer wall.
8 is a view showing another example of a door according to the present invention.

Hereinafter, with reference to the drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them.

The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly explain the present invention, parts irrelevant to the description are omitted, and the same reference numerals are given to the same or similar elements throughout the specification.

In the following, the provision or arrangement of an arbitrary component on the “upper (or lower)” or “top (or below)” of the substrate means that any component is provided or disposed in contact with the upper surface (or lower surface) of the substrate. means that

Further, it is not limited to not include other components between the substrate and any components provided or disposed on (or under) the substrate.

1 is a view showing a building insulation exterior wall composite structure of the present invention.

Referring to FIG. 1 , the building insulation exterior wall composite structure includes an exterior wall 100 partitioning indoors and outdoors, and installation spaces 200 formed in a grid arrangement inside the exterior wall 100 , and the installation spaces The vacuum cubes 300 which are inserted and disposed in 200, the vacuum is formed therein, the vacuum sensors 400 for measuring the degree of vacuum of each of the vacuum cubes 300, and the vacuum cubes 300 a vacuum provider 500 for providing a vacuum to each, a first temperature sensor 601 for measuring a first temperature inside the room, and a second temperature sensor 602 for measuring a second temperature outside the room; A controller 700 that variably controls the degree of vacuum measured from the vacuum sensors 400 using the vacuum provider 500 to achieve a difference between the measured first temperature and the reference temperature at which the second temperature is set. includes

A heat insulation panel 101 is embedded in the outer wall 100 .

2 is a view showing a configuration example of a door for opening and closing an installation space according to the present invention.

Referring to FIG. 2 , doors 110 for opening and closing the installation spaces 200 are installed on one side of the exterior wall 100 on the indoor side.

Each of the doors 110 is rotatably connected to one side of the outer wall 100 through a hinge end 111 .

The hinge end 111 is axially connected to the motor shaft of the motor 120 .

The controller 700 rotates the doors 110 by rotating the motor shaft using the motor 120 .

In addition, protrusions 112 protruding to the inside of the installation spaces 200 are formed on the inner side of each of the doors 110 .

In the circumferential area of the installation spaces 200 , a sealing 113 in close contact with the inner surface of each of the doors 110 connected to the protrusion 112 is installed.

3 is a view showing a configuration for opening a door and generating an alarm when an abnormal vacuum cube is selected from among the vacuum cubes according to the present invention.

Referring to FIG. 3 , when the measured vacuum degree is less than or equal to a preset reference vacuum degree, the controller 700 selects a vacuum cube 300 having a measured vacuum degree that is less than or equal to the reference vacuum degree as an ideal vacuum cube. .

Then, the controller 700 opens the installation space 200 by using the rotary motor 120 to open the door 110 for opening and closing the installation space 200 in which the abnormal vacuum cube is installed.

The controller 700 may transmit the information of the abnormal vacuum cube to the external server 800 , and may generate an alarm notifying the occurrence of an abnormality through the alarm generator 810 .

4 is a view showing a connection process of a vacuum cube and a vacuum line.

Referring to FIG. 4 , the vacuum provider 500 has vacuum lines 510 .

Each of the vacuum lines 510 is connected to each of the installation spaces 200 through the inside of the outer wall 100 .

A connection end 512 is formed at an end of each of the vacuum lines 511 .

A vacuum injection terminal 310 is formed in each of the vacuum cubes 300 .

The connection end 512 is configured to be slidably coupled to the vacuum injection terminal 310 to be detachable.

5 is a view showing an example in which heating and cooling coils are installed around the installation space.

Referring to FIG. 5 , a heating coil 210 and a cooling coil 220 are disposed in a peripheral area of each of the installation spaces 200 .

The heating coil 210 receives current through the first current provider 211 to achieve a constant heating temperature, and the cooling coil 220 receives current through the second current provider 221 . A constant cooling temperature is achieved.

The controller 700 controls driving of the first current provider 211 and the second current provider 221 .

6 is a view showing an example in which fins are formed in the heating coil and the cooling coil according to the present invention.

Referring to FIG. 6 , heating fins 210a are formed to protrude from the heating coil 210 .

The heating pins 210 are inserted into and contacted with the first insertion groove 321 having a predetermined length formed around the vacuum cube 300 .

Cooling fins 221 are formed to protrude from the cooling coil 220 .

The cooling fins 220 are inserted into and contacted with the second insertion groove 322 having a predetermined length formed around the vacuum cube 300 .

The heating fins 210 and the cooling fins 220 are inserted into the first and second insertion grooves 321 and 322 when the vacuum cube 300 is moved to be inserted into the installation space 200. accomplish

7 is a view showing an example in which an insulating space is formed in an outer wall.

Referring to FIG. 7 , the outer wall 100 forms an interspace formed between the installation spaces 200 .

A lattice-shaped insulating space 102 is formed in the in-between region,

The heat insulating space 102 is connected to the inlet hole 100a and the outlet hole 100b formed in the outer wall body 100 .

The inlet hole 100a is connected to the first tube 103 , and the outlet hole 100b is connected to the second tube 104 .

The first and second tubes 103 and 104 are connected to a heat insulating material supplier 105 for supplying a gel-like heat insulating material.

The controller 700 controls the driving of the insulating material supplier 105 so that the gel-like insulating material is replaced in the insulating space 102 using the first and second tubes 103 and 104 according to a set cycle. do.

In addition, the auxiliary thermal insulation layer 1000 is embedded in both sides of the installation space 200 to prevent a hot bridge and a cold bridge.

8 is a view showing another example of a door according to the present invention.

Referring to FIG. 8 , a pair of cylinders 1200 are installed on both sides of the installation space 200 according to the present invention. The pair of cylinders 1200 has a shaft 1210 protruding forward.

Rails 1211 are installed on shafts 1210 of the pair of cylinders 1200 , respectively.

Accordingly, a pair of rails 1211 are installed on both sides of the installation space 200 .

A door 110' is coupled to the pair of rails 1211 to move.

The pair of rails 1211 is connected to the linear motor 1300 .

The linear motor 1300 elevates the door 110 ′ along the pair of rails 1211 under the control of the controller 700 .

The controller 700 protrudes the shaft 1210 using a pair of cylinders 1200 to project the pair of rails 1211 .

According to its configuration, when the shaft 1210 protrudes, the rails 1211 protrude, and the door 110 ′ moves downward, the installation space 200 is opened, and the door 110 ′ rises conversely. When the shaft 1210 is inserted and the door 110 ′ is retracted, the installation space 200 may be sealed.

In addition, through the controller 700 according to the present invention, the driving source of the electronic device is supplied through solar energy collection or geothermal storage, and there is an advantage in using natural energy.

In addition, thermal bridge portions are formed between the installation spaces 200 according to the present invention. A space in which a separate gel-type insulating material 1400 is accommodated may be further formed in the thermal bridge parts.

Accordingly, since the insulating material 1400 in the form of a gel is accommodated between the installation spaces 200 , the problem of thermal bridges occurring in the portion can be solved, and thus the thermal insulation performance can be prevented from being deteriorated.

The present invention forms lattice-shaped spaces inside the wall of a building, arranges vacuum cubes that create a vacuum inside each of the spaces on the lattice, and installs a cover from the inside of the wall, There is an effect of maintaining a constant degree of vacuum, and controlling the degree of vacuum of the vacuum cubes in real time to achieve a temperature difference between the inside and outside of the wall to achieve a set temperature so as to efficiently achieve thermal insulation.

In addition, the present invention has an effect of automatically controlling the insulation by controlling the temperature of the installation space and the wall forming the installation space by placing a heating coil or a cooling coil in the installation space where each of the vacuum cubes are arranged.

In addition, the present invention detects the vacuum level of each of the vacuum cubes in real time, and when the control of the vacuum level is not performed normally, an alarm is generated to the outside so that the vacuum cube in which the abnormality has occurred can be replaced, and the corresponding cover It has the effect of opening the

As mentioned above, although specific embodiments related to the present invention have been described, it is apparent that various implementation modifications are possible within the limits that do not depart from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiments, and should be defined by the following claims as well as the claims and equivalents.

That is, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description, and the meaning and scope of the claims and their equivalents All changes or modifications derived from the concept should be construed as being included in the scope of the present invention.

100: outer wall
200: installation space
300: vacuum cube
400: vacuum sensor
500: vacuum provider
601: first temperature sensor
602: second temperature sensor
700: controller

Claims (4)

an exterior wall partitioning the interior and exterior;
installation spaces formed in a grid arrangement inside the outer wall;
vacuum cubes inserted into the installation spaces and having a vacuum formed therein;
vacuum sensors for measuring the degree of vacuum of each of the vacuum cubes;
a vacuum provider providing a vacuum to each of the vacuum cubes;
a first temperature sensor for measuring a first temperature of the room;
a second temperature sensor for measuring a second temperature of the outdoor; and,
a controller for variably controlling the degree of vacuum measured from the vacuum sensors by using the vacuum provider to achieve a difference between the measured first temperature and a reference temperature at which the second temperature is set,
On one side of the exterior wall body on the indoor side,
Doors for opening and closing the installation spaces are installed,
Each of the doors is connected to one side of the outer wall to be rotatably opened and closed through a hinge end,
The hinge end,
It is axially connected to the motor shaft of the motor,
The controller rotates and opens and closes the doors by rotating the motor shaft using the motor,
A protrusion corresponding to the size of each of the installation spaces is formed on the inner surface of each of the doors,
In the circumferential area of the installation spaces,
A sealing in close contact with the inner surface of each of the doors connected to the protrusion is installed,
The controller is
When the measured vacuum degree is less than or equal to a preset reference vacuum degree, a vacuum cube having a measured vacuum degree that is less than or equal to the reference vacuum degree is selected as an ideal vacuum cube,
Opening and closing the door opening and closing the installation space where the ideal vacuum cube is installed using the rotary motor to open the installation space,
Delivers the information of the abnormal vacuum cube to an external server, and generates an alarm notifying the occurrence of an abnormality through an alarm generator,
The vacuum provider has vacuum lines,
Each of the vacuum lines is connected to each of the installation spaces through the inside of the outer wall,
A connection end is formed at an end of each of the vacuum lines,
A vacuum injection terminal is formed in each of the vacuum cubes,
The connection end is slidably coupled to the vacuum injection terminal so as to be detachable,
A heating coil and a cooling coil are disposed in each of the installation spaces,
The heating coil is provided with a current through a first current provider to achieve a constant heating temperature,
The cooling coil receives a current through a second current provider to achieve a constant cooling temperature,
The controller controls driving of the first current provider and the second current provider,
In the heating coil, heating fins are formed to protrude,
The heating pins are inserted into and contacted with a first insertion groove having a predetermined length formed around the vacuum cube,
Cooling fins are formed protruding from the cooling coil,
The cooling fins are inserted into and contacted with a second insertion groove having a predetermined length formed around the vacuum cube,
The heating fins and the cooling fins form a state inserted into the first and second insertion grooves when the vacuum cube is moved to be inserted into the installation space,
The outer wall forms an interspace formed between the installation spaces,
A lattice-shaped insulating space is formed in the region between the two,
The heat insulation space is connected to the inlet hole and the outlet hole formed in the outer wall,
The inlet hole is connected to the first tube,
The outlet hole is connected to the second tube,
The first and second tubes are connected to a heat insulating material supplier for supplying a gel-like heat insulating material,
The controller controls the driving of the heat insulating material supplier so that the gel-like heat insulating material is replaced in the heat insulating space using the first and second tubes according to a set cycle,
A building insulation exterior wall composite structure, characterized in that an auxiliary heat insulation layer is buried inside both sides of the installation space to prevent a thermal bridge and a cold bridge.
The method of claim 1,
A pair of cylinders are installed on both sides of the installation space,
The pair of cylinders has a shaft projecting forward,
Rails are respectively installed on the shafts of the pair of cylinders,
The respective rails are installed on both sides of the installation space,
Each of the rails is coupled to move the door,
Each of the rails is connected to a linear motor,
The linear motor raises and lowers the door along the respective rails under the control of the controller,
The controller protrudes the shaft using the respective cylinders to project the respective rails. delete delete

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