CN217813121U

CN217813121U - A built-in heat insulating strip that is used for Low-E three glasss two chamber glass door and window

Info

Publication number: CN217813121U
Application number: CN202221171602.XU
Authority: CN
Inventors: 宋伟男; 白一帆; 宋朋朋; 黄哲; 高健; 杨兵
Original assignee: Road and Bridge International Co Ltd; CCCC Ruitong Construction Engineering Co Ltd
Current assignee: Road and Bridge International Co Ltd; CCCC Ruitong Construction Engineering Co Ltd
Priority date: 2022-05-13
Filing date: 2022-05-13
Publication date: 2022-11-15
Anticipated expiration: 2032-05-13

Abstract

The utility model discloses a built-in heat insulating strip for Low-E three-glass two-chamber glass door and window relates to building materials technical field. The utility model comprises an inner sealing structure and a positioning structure, wherein the lower part of the inner sealing structure is fixedly connected with the positioning structure; the inner sealing structure comprises a peripheral coating sheet, a glass groove and an inner inserting plate, wherein the glass groove is arranged between the peripheral coating sheet and the inner inserting plate; the positioning structure comprises a main support plate and heat-insulating material filling grooves, and the two heat-insulating material filling grooves are formed in the main support plate. The utility model discloses an interior structure and location structure of sealing have solved built-in heat insulating strip leakproofness poor and have the problem that the heat scatters and disappears.

Description

A built-in heat insulating strip for Low-E three-glass two-chamber glass door and window

Technical Field

The utility model belongs to the technical field of building materials, especially, relate to a built-in heat insulating strip that is used for Low-E three-glass two-chamber glass door and window.

Background

Glass is an important building material, and with the increasing requirements on the decoration of buildings, the usage amount of glass in the building industry is also increasing. However, in addition to the aesthetic and appearance characteristics of the windows and doors, the windows and doors in the present day buildings pay more attention to the balance of heat control, refrigeration cost, and comfort of the internal sunlight projection. This makes the Low-E glass stand out. The Low-E glass is also called Low-radiation glass, and is a film system product formed by plating a plurality of layers of metal or other compounds on the surface of the glass, wherein a film plating layer has the characteristics of high visible light transmission and high mid-far infrared ray reflection, so that the Low-E glass has excellent heat insulation effect and good light transmission compared with common glass and traditional architectural coated glass, therefore, the Low-E three-glass two-cavity glass is widely applied to doors and windows, and in order to protect the sealing property and the heat insulation capability of the doors and windows, a heat insulation strip is required to be utilized when the Low-E three-glass two-cavity glass doors and windows are installed, but the heat insulation strip of the existing Low-E three-glass two-cavity glass doors and windows is generally positioned below the glass and is in an external state, the sealing property is poor, and certain heat loss can also exist.

Therefore, the existing Low-E triple-glass two-cavity glass door and window with built-in heat insulation strips cannot meet the requirements in practical use, so that an improved technology is urgently needed in the market to solve the problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a built-in heat insulating strip for three glasss two chamber glass doors and windows of Low-E through interior structure and location structure, has solved the poor problem that scatters and disappears with having the heat of current built-in heat insulating strip leakproofness.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme:

the utility model relates to a built-in heat insulation strip for a Low-E three-glass two-cavity glass door and window, which comprises an inner sealing structure and a positioning structure, wherein the lower part of the inner sealing structure is fixedly connected with the positioning structure;

the inner sealing structure comprises a peripheral coating sheet, a glass groove and an inner inserting plate, wherein the glass groove is arranged between the peripheral coating sheet and the inner inserting plate, and the peripheral coating sheet, the glass groove and the inner inserting plate are arranged to be used for comprehensively coating the end part of the Low-E three-glass two-cavity glass and enhancing the sealing property of the Low-E three-glass two-cavity glass;

the positioning structure comprises a main supporting plate and two heat-insulating material filling grooves, wherein the two heat-insulating material filling grooves are formed in the main supporting plate, and the main supporting plate is used for supporting and positioning glass and reinforcing the heat-insulating capacity of the heat-insulating strip through heat-insulating materials.

Furthermore, the inner sealing structure also comprises a molecular sieve groove and a support platform, and the lower ends of the peripheral cladding sheet and the inner inserting plate are fixedly connected with the support platform;

the inner part of the inner inserting plate is provided with molecular sieve grooves, glass grooves are also arranged between the inner inserting plates, the molecular sieve grooves are used for storing and fixing molecular sieves, and the supporting table is used for supporting and conducting the gravity of glass.

Furthermore, the positioning structure also comprises a positioning fan plate and an inserting plate, and the upper part of the main support plate is fixedly connected with the support platform;

two sides of the main support plate are fixedly connected with positioning fan plates, and the bottom of the main support plate is fixedly connected with two plug boards;

the two sides of the main support plate are fixedly connected with n positioning fan plates, n is larger than or equal to 2, the positioning fan plates are symmetrically distributed on the two sides of the main support plate, the positioning fan plates are used for connecting the heat insulation strips with the aluminum profile to support glass, and the insertion plate is used for connecting the heat insulation strips below.

The utility model discloses following beneficial effect has:

1. the utility model discloses a set up interior structure, solved the poor problem of current built-in heat insulating strip leakproofness, wherein be provided with peripheral cladding piece, glass groove and interior plugboard in the interior structure, through the setting of peripheral cladding piece, glass groove and interior plugboard for carry out comprehensive cladding to Low-E three-glass two-chamber glass tip, can strengthen the leakproofness to Low-E three-glass two-chamber glass, avoid inside heat preservation gaseous slowly scattering and disappearing.

2. The utility model discloses a structure in setting up, the problem that current built-in heat insulating strip exists the heat and scatters and disappears has been solved, wherein be provided with peripheral cladding piece in the structure including, glass groove and interior plugboard, through peripheral cladding piece, the setting of glass groove and interior plugboard, be used for carrying out comprehensive cladding to Low-E three-glass two-chamber glass tip, can promote thermal-insulated ability greatly, thermal storage capacity is improved, be provided with main extension board and insulation material filling tank in location structure, the main extension board is used for going on supporting and the location to glass, and pass through insulation material, strengthen the thermal-insulated heat preservation ability of heat insulating strip.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a bottom view of the present invention;

FIG. 3 is a cross-sectional view of the present invention;

fig. 4 is a front view of the present invention.

In the drawings, the reference numbers indicate the following list of parts:

1. an inner sealing structure; 101. a peripheral coating sheet; 102. a glass tank; 103. an interposer; 104. a molecular sieve tank; 105. supporting a platform; 2. a positioning structure; 201. a main support plate; 202. filling the groove with a heat insulation material; 203. positioning the fan plate; 204. a plugboard.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-4, the present invention relates to a built-in heat insulation strip for a Low-E three-glass two-chamber glass door and window, which comprises an inner sealing structure 1 and a positioning structure 2, wherein the lower part of the inner sealing structure 1 is fixedly connected with the positioning structure 2;

the inner sealing structure 1 comprises a peripheral cladding sheet 101, a glass groove 102 and an inner inserting plate 103, wherein the glass groove 102 is arranged between the peripheral cladding sheet 101 and the inner inserting plate 103;

the peripheral coating sheet 101 is a sealing coating strip on the outermost side, a glass groove 102 is formed between the peripheral coating sheet 101 and the inner inserting plate 103, the glass groove 102 is formed between the inner inserting plates 103, and three glass grooves 102 are formed in total, and the peripheral coating sheet 101, the glass groove 102 and the inner inserting plate 103 are arranged to be used for comprehensively coating the end part of Low-E three-glass two-cavity glass, so that the sealing performance of the Low-E three-glass two-cavity glass can be enhanced, the dissipation of internal gas is avoided, the heat insulation capacity can be greatly improved, and the heat preservation capacity is improved;

the positioning structure 2 comprises a main support plate 201 and two heat-insulating material filling grooves 202, wherein the two heat-insulating material filling grooves 202 are arranged in the main support plate 201;

the main support plate 201 is of a bottom supporting and positioning structure, two heat-insulating material filling grooves 202 are formed in the main support plate, heat-insulating glue can be filled in the heat-insulating material filling grooves 202 for heat insulation, the main support plate is used for supporting and positioning glass, and the heat-insulating capacity of the heat-insulating strips is enhanced through heat-insulating materials.

As shown in fig. 1-4, the inner sealing structure 1 further includes a molecular sieve tank 104 and a support 105, and the lower ends of the peripheral cladding sheet 101 and the inner insert plate 103 are fixedly connected to the support 105;

molecular sieve grooves 104 are arranged inside the inner inserting plates 103, and glass grooves 102 are also arranged between the inner inserting plates 103;

the molecular sieve groove 104 is a preset groove for positioning the molecular sieve, is arranged inside the inner insertion plate 103 and is used for storing and fixing the molecular sieve, and the support platform 105 is a structure with a peripheral coating sheet 101 and the inner insertion plate 103 fixed, and the bottom of the support platform is fixed with the main support plate 201 and is used for supporting and conducting the gravity of the glass.

As shown in fig. 1-4, the positioning structure 2 further includes a positioning fan plate 203 and an inserting plate 204, and the upper side of the main supporting plate 201 is fixedly connected with the supporting platform 105;

two sides of the main support plate 201 are fixedly connected with positioning fan plates 203, and the bottom of the main support plate 201 is fixedly connected with two plug plates 204;

the two sides of the main support plate 201 are fixedly connected with n positioning fan plates 203, n is more than or equal to 2, and the positioning fan plates 203 are symmetrically distributed on the two sides of the main support plate 201;

the positioning fan plate 203 is a positioning arm on two sides of the main support plate 201 and is used for connecting the heat insulation strips with the aluminum profile to support the glass, and the inserting plate 204 is two inserting positioning rods at the bottom of the main support plate 201 and can be inserted into the inner inserting plate 103 and be connected with the heat insulation strips below.

One specific application of this embodiment is: when the heat insulation strip is used, firstly, a molecular sieve is inserted into the molecular sieve groove 104, heat insulation glue is filled into the heat insulation material filling groove 202, then the built-in heat insulation strip is pushed up at the bottom of Low-E three-glass two-cavity glass, when the heat insulation strip is pushed up, the three pieces of glass are correspondingly inserted into the glass groove 102 one by one, then the heat insulation strip is connected with the plurality of heat insulation strips through the plug board 204, and then the heat insulation strip is connected with the door and window aluminum profile through the positioning fan board 203 and clamped.

The above is only the preferred embodiment of the present invention, and the present invention is not limited thereto, any technical solutions recorded in the foregoing embodiments are modified, and some technical features thereof are replaced with equivalent ones, and any modification, equivalent replacement, and improvement made thereby all belong to the protection scope of the present invention.

Claims

1. The utility model provides a built-in heat insulating strip for two chamber glass door and window of Low-E three-glass, includes interior structure (1) and location structure (2), its characterized in that: the lower part of the inner sealing structure (1) is fixedly connected with the positioning structure (2);

the inner sealing structure (1) comprises a peripheral cladding sheet (101), a glass groove (102) and an inner inserting plate (103), wherein the glass groove (102) is arranged between the peripheral cladding sheet (101) and the inner inserting plate (103);

the positioning structure (2) comprises a main support plate (201) and insulation material filling grooves (202), wherein the two insulation material filling grooves (202) are formed in the main support plate (201).

2. The built-in heat insulating strip for Low-E three-glass two-cavity glass doors and windows according to claim 1, characterized in that: the inner sealing structure (1) further comprises a molecular sieve groove (104) and a supporting platform (105), and the lower ends of the peripheral cladding sheet (101) and the inner inserting plate (103) are fixedly connected with the supporting platform (105).

3. The built-in heat insulating strip for Low-E three-glass two-cavity glass doors and windows according to claim 2, characterized in that: molecular sieve grooves (104) are arranged inside the inner insertion plates (103), and glass grooves (102) are also arranged between the inner insertion plates (103).

4. The built-in heat insulating strip for Low-E three-glass two-cavity glass doors and windows according to claim 2, characterized in that: the positioning structure (2) further comprises a positioning fan plate (203) and a plug board (204), and the upper portion of the main support plate (201) is fixedly connected with the supporting platform (105).

5. The built-in heat insulating strip for Low-E three-glass two-cavity glass doors and windows according to claim 1, characterized in that: two sides of the main support plate (201) are fixedly connected with positioning fan plates (203), and the bottom of the main support plate (201) is fixedly connected with two plug-in boards (204).

6. The built-in heat insulating strip for Low-E three-glass two-cavity glass doors and windows according to claim 1, characterized in that: the two sides of the main support plate (201) are fixedly connected with n positioning fan plates (203), n is larger than or equal to 2, and the positioning fan plates (203) are symmetrically distributed on the two sides of the main support plate (201).