KR101451673B1 - A composite panel - Google Patents

Abstract

The present invention relates to a lightweight stone composite panel structure, which has the disadvantage of being heavy in weight, which is a disadvantage of natural stone while maintaining the advantages of natural stone, and the problem of no heat insulating performance, It is an object of the present invention to provide a honeycomb heat insulator and an inorganic heat insulator so as to reduce the weight of the stone panel and to refine the standard of the stone panel, and to maximize the heat insulation performance and the sound insulation performance.
In addition, since the thickness of the stone is thin, it is possible to reduce the weight of the stone panel, protect the stone resources, reduce the cost of the stone panels, and form a nonflammable inorganic insulator. It does not need to cut off the toxic gas and separate sealant finishing work. It is possible to minimize the construction time and shorten the construction period and reduce the construction cost.
It is an object of the present invention to provide a method and apparatus for improving the quality of a stone panel while maintaining the advantages of a natural stone while reducing the cost of a stone panel, reducing the price of a stone panel, enhancing heat insulation performance and sound insulation performance, minimizing damage in case of fire and earthquake, It is a useful invention with effects such as reduction of construction cost.

Description

Lightweight stone composite panel structure {A composite panel}

The present invention relates to a lightweight stone composite panel structure and more particularly to a lightweight stone composite panel structure in which a honeycomb thermal insulating material is disposed on a back surface of a thin plate- The light weight stone composite panel structure is light in weight, so that the low-temperature construction becomes convenient, the frame is assembled precisely and convenient, and the air layer is constituted by the honeycomb heat insulating material, so that the weight of the panel and the sound insulating performance are improved In addition, since the panel wall fixing groove and the vertical transverse joint wing portion and the receiving groove are formed on one side of the frame, the airtightness is maintained as well as the convenience of the construction, so that no additional sealant operation is required, Lightweight stone composite panel structure provides efficient and economical effect One will.

It is widely used as natural granite and marble or artificial stone which is processed into flat plate type as the finishing material for exterior materials of buildings.

Generally, there are dry method and wet method as the construction methods of stone. Among them, dry method is to install many anchors at fixed intervals and to fix the stone at regular intervals from the wall.

Generally, the thickness of the exterior panel stone panel is mainly 20-30 mm. The construction method is wet and dry construction method, but dry panel construction method of stone panel of building exterior is general.

FIG. 1 is a cross-sectional view of a conventional dry stone installation structure. As shown in FIG. 1, in the dry stone installation method for a facade stone, a heat insulating material 15 is sealed in a building wall 5 to prevent heat insulation and condensation A plurality of anchor bolts 21 are fixed to the wall 5 to fix the stone panel 10 and are then joined to the fastener 22 and the stone panel 10 is fixed to the upper portion of the fastener 22 An adjusting plate 23 for adjusting the interval is disposed. After the interval between the stone panel 10 and the wall 5 is adjusted, the fastener 22 and the adjustment plate 23 are firmly assembled by a nut. The constructor should be formed with an insertion groove into which the fixing pin 24 can be inserted on the upper, lower, left, and right sides of the quadrangular stone panel 10, and the adjusting plate 23 And the fixing pin 24 is inserted into the upper surface of the stone panel.

At this time, one end of the anchor is fixed to the wall by the fixing member, and the upper and lower ends of the stone panel 10 are fixed by the fixing pin 24 by constituting the insertion groove on the upper and lower sides of the rectangular plate type stone.

However, since the exterior materials such as the stone panel are expensive, the construction cost is increased. In addition to the problem that the construction cost is heavy, it is difficult to transport because the weight is heavy. Therefore, Since the worker has to work on the upper and lower side insertion grooves of the stone panel 10, the field installer can easily mount the stone panel on the anchor adjusting plate without forming the troublesome insertion grooves, and the epoxy work as the stone adhesive It is not fixed firmly and it is a reality that there are many problems that are easily broken when an phenomenon such as an earthquake occurs.

Since the sealant 31 is filled after the backup material 32 is inserted to maintain the airtightness of the gap between the stone panels 10, there is a problem of stone contamination caused by the sealant and the durability of the sealant is low, There were various problems that require maintenance.

In order to solve these problems, there is a composite panel of stone and insulation. However, since most of the heat insulation materials used are organic materials, that is, urethane and compressed styrofoam bonding methods, they can achieve the purpose of heat insulation performance and light weight of panel. In addition to the disadvantage that the thickness of the panel increases, toxic gas is generated when a fire occurs.

Therefore, it is urgently required to reduce the cost of construction by the convenience of construction while maintaining the merit of stone, reduce the cost of stone by using thin stone, and develop stone panel with heat insulation performance.

An object of the present invention is to solve the above-mentioned problems, and it is an object of the present invention to reduce the use of a stone by using a thin stone to protect the resources of a stone and realize a light weight of a stone panel, The present invention is to provide a lightweight stone composite panel structure which is capable of precisely constructing and simplifying the construction and shortening the construction period and reducing the construction cost.

Another object of the present invention is to add a honeycomb heat insulating material between a stone and an inorganic heat insulating material to maximize the light weight of the stone, the sound insulating performance and the heat insulating performance effect owing to the air layer, and to increase the strength of the durability and bending strength And to provide a lightweight stone composite panel structure having an effect.

It is a further object of the present invention to provide a lightweight stone composite panel structure which is composed of a nonflammable inorganic component as a main component of a heat insulating material and which is capable of preventing the generation of toxic gas when a fire occurs and reducing the thickness of the panel.

It is still another object of the present invention to provide a method of manufacturing a building, which is characterized in that a frame in which longitudinal wings and receiving grooves are formed is fixedly inserted into a fixing groove on the side of a stone to maintain airtightness as well as convenience of construction, So that it is possible to provide an economical effect.

In order to achieve the above-mentioned objects, the present invention is generally characterized in that the thickness of the exterior stone panel is 20-30 mm, but the stone thickness of the present invention is 10 mm or less.

A fixing groove is continuously formed so as to insert and fix the extruded aluminum frame on the side surface of the stone panel 4 processed to within 10 mm in the shape of a rectangular frame body and the depth of the fixing groove is machined to about 3 mm in the width of 10 mm.

In addition, apart from the formation of the fixing pin insertion groove, a vertical lateral joint wing portion and a wing portion receiving groove are formed to maintain airtightness.

The left and right side frames of the four aluminum frames, that is, the fourth frame frame and the outer side of the third frame have a "∃" character shape and a "ㅌ" character shape in order to enhance the effect of insulation performance, prevention of rainwater inflow and airtightness . The effect of this is that it does not require separate finishing work such as sealant and backing material as well as insulation effect and sound insulation performance effect and the gap between stone panel and panel.

”자 형상을 갖는 것을 특징으로 한다.In addition, in order to improve the bonding property between the incombustible inorganic insulating material and the frame on the inner surface of the side panel of the stone panel 4,

Quot; shape.

In addition, a honeycomb heat insulating material is provided between the stone panel and the incombustible inorganic heat insulating material in order to increase the heat insulating property, the car sound, and the weight of the panel. In addition to this, it has the effect of increasing the bending strength and durability of thin stone.

In addition, the aluminum frame of four sides is inserted and fixed on the side of the stone panel 4, and then the honeycomb heat insulating material is formed to constitute the air layer to maximize the effect of heat insulation, sound insulation and weight reduction of the panel, and the upper surface thereof is filled with incombustible inorganic heat insulating material And after molding, the effect of heat insulation is maximized.

The lightweight stone composite panel structure according to the present invention is a multifunctional stone composite panel that fully exploits the advantages of natural stone and compensates for its disadvantages by adopting a frame-type fitting method in the four side- There is an effect of preventing the detachment of the accessory material.

The lightweight stone composite panel structure according to the present invention has the effect of protecting the resources of the stone with a thin-walled stone structure and simplifying the construction due to the weight reduction of the stone panel, thereby reducing the cost of the stone panel, shortening the construction period and reducing the construction cost.

In addition, in order to reinforce the problem of durability and hardness due to the thin stone composition, the lightweight stone composite panel structure according to the present invention is formed by forming a honeycomb heat insulating material between the stone panel and the inorganic heat insulating material to improve the hardness of the stone panel, It is possible to enhance the heat insulating performance by the heat insulating property, the sound insulating performance, and the light weight of the panel.

In addition, the lightweight stone composite panel structure according to the present invention not only improves the precision of the standard of the stone panel, but also has the effect of preventing panel breakage by constituting the extruded aluminum frame on the side of the stone panel 4.

In addition, a plurality of vertical line eye wings, horizontal joint wings and receiving grooves are formed on the outer surface of the frame to prevent penetration of rainwater, sound insulation effect, and heat insulation performance, It also has the effect of reducing damage caused by earthquakes.

In addition, the lightweight stone composite panel structure according to the present invention is characterized in that a frame is fixedly connected to a stone panel, a honeycomb thermal insulating material is formed inside the assembled frame, and then the incombustible inorganic thermal insulating material is filled and dried, thereby maximizing the heat insulating performance, It is possible to maximize the airtightness and the bonding force of the gas barrier and the stone composite panel structure.

1 is a cross-sectional view of a conventional stone panel dry construction structure
Fig. 2 is a perspective view of a stone panel in which frame fastening grooves are formed on four sides of the stone according to the first embodiment of the present invention. Fig.
3 is an exploded front view of a frame-integrated stone panel according to the first embodiment of the present invention
FIG. 4A is a cross-sectional view of a frame according to the first embodiment of the present invention,
Fig. 4B is a longitudinal sectional view of the frame according to the first embodiment of the present invention,
5 is an exploded perspective view of the composite stone panel constituting the honeycomb according to the first embodiment of the present invention.
FIG. 6 is a view showing a process of filling inorganic thermal insulating material inside a composite stone panel frame having a honeycomb according to the first embodiment of the present invention
Fig. 7 is a perspective view of a stone composite panel according to a first embodiment of the present invention.
8 is a cross-sectional view and a longitudinal sectional view of the stone composite panel according to the first embodiment of the present invention
9A and 9B are a cross-sectional view and a detailed view showing a state in which a stone composite panel according to a first embodiment of the present invention is cross-
10A and 10B are a cross-sectional view and a detailed view showing a state in which the stone composite panel according to the first embodiment of the present invention is installed in a longitudinal direction
11 is an enlarged perspective view of a substantial part of a stone composite panel according to the first embodiment of the present invention.

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

It should be noted that the present invention is not limited to the scope of the present invention but is only illustrative and can be modified within the scope of the present invention.

2 and 3 are views showing the stone panel 10 of the lightweight stone composite panel structure A according to the first embodiment of the present invention and examples of inserting and fixing the frame 20 into the stone panel 10 The thickness of the stone panel 10 is reduced to 10 mm or less so that the purpose of the present invention is to reduce the weight of the stone panel 10 and to protect the resources of the stone and reduce the cost.

Such a stone panel 10 is formed in a rectangular shape and a fixing groove 11aa is formed continuously in the longitudinal direction so that the frame 20 can be inserted and fixed to the four side portions 11 of the stone panel 10. The depth of the fixing groove 11a is 10 mm and the depth is 3 mm.

The frame 20 is preferably made of an extruded aluminum material and the frame 20 is inserted and fixed in the fixing groove 11aa of the stone panel 10 and the upper side portion 11a of the stone panel 10 The lower frame 20b is inserted and fixed to the lower side face portion 11b while the left side frame portion 20c is fixedly inserted into the left side face portion 11c. (20d) is inserted and fixed.

The frame 20 is attached to the side surface of the stone panel 10 and is used to fix the honeycomb thermal insulating material 30 and the inorganic thermal insulating material 40 to be described later and thus the honeycomb thermal insulating material 30 and the inorganic thermal insulating material 40 Since these portions are commonly constituted, these common portions are denoted by the same names and the same reference numerals.

Each of the frames 20 is formed with an insertion protrusion 21 so as to be bent inwardly to be inserted into the fixing groove 11aa and an extension 22 extending rearward from the insertion protrusion 21 is formed, The honeycomb insulator 30 is formed with an inorganic guard 23 bent inward at the end of the honeycomb fired body 22 and the honeycomb insulator 30 is bent at a predetermined distance from the insertion protrusion 21, And an inorganic fixing part 25 bent backward is commonly formed at an end of the honeycomb fixing part 24, and a description of overlapping parts is omitted.

'한 단면형상으로 형성되어 있다.The upper frame 20a is formed with an upright projecting portion 26 erected upwardly outward adjacent to the insertion projecting portion 21 and extending rearward of the honeycomb fixing portion 24 of the extending portion 22 A pin fixing groove 27 into which the lower end of the fixing pin P is inserted is formed adjacent thereto,

Sectional shape.

'한 단면형상으로 형성되어 있다.The lower frame 20b is symmetrical with the upper frame 20a and cooperates with an upper frame 20a disposed adjacent to the lower frame 20b to fix the upper end of the fixing pin P. [ The lower frame 20b includes a first receiving groove 26 'extending downwardly for receiving the upright projecting portion 26 which is formed adjacent to the insertion projecting portion 21 and is uprightly formed above the adjacent upper frame 20a. And a pin fixing groove 27 'formed at a portion of the extending portion 22 adjacent to the first receiving groove 26' and into which the upper end of the fixing pin P is inserted,

Sectional shape.

'한 단면형상으로 형성되어 있다.The left frame 20c includes a second receiving groove 28 protruding in the left (outward) direction on the extension 22 adjacent to the insertion receiving portion 21, A wing portion 29 protruding leftward at a predetermined interval is formed,

Sectional shape.

'한 단면형상으로 형성되어 있다.The right frame 20d protrudes in the right (outward) direction on the extension 22 adjacent to the insertion protrusion 21 and is inserted and fixed at an intersection with the second receiving recess 28 of the left frame 20c An inorganic guard 23 formed in the third receiving groove 28 'and extending rearward adjacent to the third receiving groove 28' and bent inward at an end thereof; A honeycomb fixing part 24 extending at a predetermined distance from the back surface of the stone panel 10 and an inorganic fixing part 25 bent backward from an end of the honeycomb fixing part 24,

Sectional shape.

The insertion of the stone panel 10, the honeycomb heat insulating material 30 and the inorganic heat insulating material 40 into the fixing grooves 11aa of the side panel 11 of the stone panel 10, To prevent departure of the battery.

4A and 4B are longitudinal and transverse sectional views after inserting and fixing the four-sided frame 20 to the stone panel 10, and the frame is preferably made of an aluminum material extruded.

An upper pin fixing groove 27 is formed for inserting the fixing pin P into the outer surface of the upper frame 20a of the frame 20 of the present invention and the upright projecting portion 26 is formed separately, Is inserted into the first receiving groove 26 'of the arranged lower frame 20b so as to enhance the effect of fixing the stone panel 10 to the wall 5 and to improve the effect of the heat insulating performance, the sound insulating performance, It is to raise.

In addition, the upright projecting portion 26 maintains the airtightness between the adjacent stone panels 10, so that it is not necessary to perform a separate sealant operation, thereby reducing the construction period and the unit cost.

The third receiving groove 28 'is formed on the outer surface of the right frame 20d to increase the effect of insulation performance and sound insulation performance as well as to enhance airtightness such as prevention of inflow of rainwater. In addition, there is an advantage that a sealant operation is not required and construction is convenient.

The pin fixing grooves 27 'are formed in the lower frame 20b and are firmly fixed to the wall by using the fixing pins P, thereby reducing the damage of the earthquake. In addition, the upright projecting portion 26 and the first receiving groove 26 'are formed to enhance the effect of heat insulation performance and sound insulation performance, as well as enhance the airtightness, thereby enhancing the ease of construction.

Not only the second receiving groove 28 is formed on the outer surface of the left frame 20c but also the wing portion 29 is formed to enhance the effect of the heat insulating performance and the sound insulating performance and to enhance the airtightness, .

A honeycomb thermal insulating material 30 having a standard shape such as the stone panel 10 is placed on the back surface of the stone panel 10 and the honeycomb thermal insulating material 30 is placed in the fixing grooves 11aa formed in succession to the four side portions 11 of the stone panel 10 The insertion protruding portion 21 of the frame 20 is inserted and fixed by the honeycomb fixing portion 24.

Here, the honeycomb thermal insulating material 30 has a honeycomb shape, and its material is preferably a honeycomb formed of an aluminum material. The honeycomb thermal insulating material 30 preferably has a thickness of 10 mm or less and may also be formed of gypsum. Such a honeycomb thermal insulating material 30 may be an unburned or late burned material, for example, a fireproof synthetic resin material.

This is because the honeycomb heat insulating material 30 is formed to form an air layer, which is an object of the heat insulating performance, the sound insulating performance and the lightening effect of the panel, and also has the disadvantage of applying the thick stone panel 10 within 10 mm, 10) in order to reinforce the durability and the lowering of the bending strength.

5 and 6 are exploded perspective views of the stone panel 10, the frame 20 and the honeycomb thermal insulating material 30 and the assembled stone panel 10 and the frame 20 and the honeycomb thermal insulating material 30 and the frame 20, And an inorganic heat insulating material 40 that has been agitated therein.

The inorganic insulator 30 applied to the present invention is composed of 10-30% by weight of olivine, 10-20% by weight of dolomite, 5-10% by weight of Bauxite, 10-30% by weight of Pelite 10 to 15 weight% of fumed silica, 15 to 30 weight% of an airgel are mixed to form an inorganic mixture , It is preferable that cement or gypsum is mixed in an amount of 70 to 130 parts by weight per 100 parts by weight of the mixed inorganic mixture.

In this embodiment, the inorganic insulator 30 is composed of 20% by weight of kaolin, 15% by weight of dolomite, 7% by weight of borgite, 12% by weight of perlite, 7% by weight of diatomaceous earth, 12% by weight of fly ash, 12% by weight of fumed silica, And the inorganic mixture is mixed, and 100 parts by weight of cement is mixed per 100 parts by weight of the inorganic mixture to produce an inorganic insulator.

This is advantageous in that it is not only a heat insulating performance as a nonflammable inorganic insulator but also a toxic gas is prevented from being generated when a fire, which is a disadvantage of an insulating material such as an organic compressed styrofoam, is cut down and the thickness of a lightweight stone composite panel structure is reduced.

In addition, the inorganic insulator 40 of the present invention fills and dries the inside of a frame 30 having a rectangular frame shape assembled with the stone panel 10. Its thickness shall be 10mm. The inorganic insulator (40) has a function of strengthening its binding force by the inorganic fixture (25).

7 and 8 are a perspective view and a cross-sectional view and a longitudinal sectional view taken along the line I-I and II-II of the lightweight stone composite panel structure according to the first embodiment of the present invention.

9 is a cross-sectional view showing the lightweight stone composite panel structure of the present invention in a transversely installed state. As shown in the figure, the lightweight stone composite panel structure A of the present invention is divided into the lightweight stone composite panel structures A adjacent to each other by the wings 29, 1 air layer (a1) and second air layer (a2) are formed to maximize the effect of heat insulation performance and sound insulation performance and to maintain the airtightness so as to prevent inflow of external rainwater. It is not necessary that the construction period is shortened and the construction cost is effective.

10 is a cross-sectional view illustrating the construction of the lightweight stone composite panel structure according to the present invention. The upper frame 20a and the lower frame 20b can be fixed to the upper and lower portions of the stone panel 10 by inserting and fixing the fixing pins P in the longitudinally coupled state of the stone panel 10 of the present invention, So that the construction worker does not need to work to receive the fixing pin P on the side of the separate stone so that the convenience of the construction can be provided and also the upper side The upright protruding portion 26 of the frame 20a and the first receiving groove 26 'of the adjacent lower frame 20b are formed to engage with each other to enhance the adiabatic performance and sound insulation performance as well as the function of preventing external rainwater inflow.

The lightweight stone composite panel structure according to the present invention will be said to be industrially applicable because it will be possible to repeatedly manufacture the same product in the general stone panel manufacturing industry.

10. Stone panel 20. Frame 30. Insulation
40. Mineral insulation

Claims (6)

In the lightweight stone composite panel structure (A)
The lightweight composite composite panel structure A comprises a stone panel 10 having a fixing groove 11aa formed in a longitudinal direction so as to insert and fix the frame 20 on the side surface portion 11 thereof,
An insertion protrusion 21 is formed to be bent inwardly to be inserted into the fixing groove 11aa of the stone panel 10 and an extension 22 extending rearward from the insertion protrusion 21 is formed, The honeycomb insulator 30 is formed with an inorganic guard 23 bent inward at the end of the honeycomb fired body 22 and the honeycomb insulator 30 is bent at a predetermined distance from the insertion protrusion 21, And an inorganic fixing portion 25 bent backward is formed at the end of the honeycomb fixing portion 24 so that the honeycomb insulating member 30 disposed on the back surface of the stone panel 10, A frame 20 for fixing the frame 40,
A honeycomb thermal insulating material 30 which is tightly fixed to the back surface of the stone panel 10 by the honeycomb fixing portion 24 of the frame 20,
And an inorganic heat insulating material (40) filled on the back surface of the honeycomb heat insulating material (30) and cured,
The frame 20 is formed of extruded aluminum and the frame 20 is fixedly inserted into the fixing groove 11aa of the stone panel 10 and the upper side portion 11a of the stone panel 10 is fixed to the upper side The frame 20a is inserted and fixed and the lower frame 20b is fixedly inserted into the lower side face portion 11b. The left side frame portion 20c is fixedly inserted into the left side face portion 11c. 20d are inserted and fixed,
The upper frame 20a is formed with an upright protruding portion 26 erected upwardly outwardly adjacent to the insertion protruding portion 21 and a rear protruding portion 26 formed on the rear portion of the honeycomb fixing portion 24 of the extending portion 22 A pin fixing groove 27 into which the lower end of the fixing pin P is inserted is formed adjacent to the fixing pin 27,
The lower frame 20b includes a first receiving groove 26 'extending downwardly for receiving the upright projecting portion 26 which is formed adjacent to the insertion projecting portion 21 and is uprightly formed above the adjacent upper frame 20a. , And a pin fixing groove (27 ') formed in a portion of the extending portion (22) adjacent to the first receiving groove (26') for inserting an upper end of the fixing pin (P) Composite panel structure.
delete The method according to claim 1,
Characterized in that the honeycomb thermal insulating material (30) has a honeycomb structure and is formed of an aluminum material, a gypsum, or a non-burned or late burned synthetic resin material.
The method according to claim 1,
The inorganic heat insulating material 40 may include 10-30% by weight of olivine, 10-20% by weight of dolomite, 5-10% by weight of Bauxite, 10-30% by weight of Pelite, The inorganic mixture is formed by mixing 5-10 wt% of diatomaceous earth, 10-20 wt% of fly ash, 10-15 wt% of fumed silica and 15-30 wt% of airgel, Wherein the cement or gypsum is mixed with 70-130 parts by weight per 100 parts by weight of the inorganic composite mixture.
delete The method according to claim 1,
The adjacent upper and lower frames 20a and 20b are formed such that the upright projecting portion 26 of the upper frame 20a and the first receiving groove 26 'of the lower frame 20b adjacent to each other are engaged with each other,
The adjacent left and right frames 20c and 20d are assembled to be engaged with each other in the second receiving groove 28 and the third receiving groove 28 ' a1) and a second air layer (a2) are formed.

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