CN217420914U - Aluminum alloy section containing double-heat-insulation bridge-cut-off structure - Google Patents

Abstract

The utility model relates to an aluminum alloy ex-trusions technical field specifically is an aluminum alloy ex-trusions that contains two thermal-insulated bridge cut-off structures, including first aluminum alloy ex-trusions, two first support columns of one side fixedly connected with of first aluminum alloy ex-trusions, two first support column is the symmetric distribution, two a first joint board of the equal fixedly connected with in one side of first support column. The utility model has the advantages that: the thermal-insulated structure of only one deck among the great majority bridge cut-off aluminum structure, the thermal-insulated structure of one deck can not be complete dispels the heat to aluminium alloy ex-trusions, long-time use just can make aluminium alloy ex-trusions warp, unable normal use, give first aluminium alloy ex-trusions and second aluminium alloy ex-trusions through first thermal-insulated subassembly in this neotype aluminium alloy ex-trusions that contain two thermal-insulated bridge cut-off structures and separate, because the metal has the heat conductivity, the second louvre in the rethread radiating block dispels the heat, the third louvre in the first thermal-insulated subassembly also can dispel the heat.

Description

Aluminum alloy section containing double-heat-insulation bridge-cut-off structure

Technical Field

The utility model relates to an aluminum alloy ex-trusions technical field, especially an aluminum alloy ex-trusions that contains two thermal-insulated bridge cut-off structures.

Background

The bridge-cut-off aluminum is called as heat-insulating bridge-cut-off aluminum profile, heat-insulating aluminum alloy profile, bridge-cut-off aluminum alloy, cold and hot bridge-cut-off profile and bridge-cut-off aluminum-plastic composite profile, which has more excellent performance than common aluminum alloy profile, and in the field of door and window manufacturing, the door and window made of various materials such as aluminum alloy, plastic or plastic steel are widely applied to fixed buildings, wherein the door and window frame supported by the aluminum alloy profile has the advantages of light weight and low cost due to the fact that the door and window frame has considerable strength and attractiveness, so that the application range is widest, and the aluminum alloy is an aluminum alloy material and has good heat-conducting performance.

Most bridge cut-off aluminium only has the thermal-insulated bridge cut-off structure of one deck, and the thermal-insulated bridge cut-off structure of one deck can not let the window effectually dispel the heat, will appear warping, reduces the whole life of window, in order to solve this problem, so the utility model provides an aluminum alloy ex-trusions that contains two thermal-insulated bridge cut-off structures.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art's shortcoming, provide an aluminum alloy ex-trusions who contains two thermal-insulated bridge cut-off structures.

The purpose of the utility model is realized through the following technical scheme: the utility model provides an aluminum alloy ex-trusions that contains two thermal-insulated bridge cut-off structures, includes first aluminum alloy ex-trusions, two first support columns of one side fixedly connected with of first aluminum alloy ex-trusions, two first support column is the symmetric distribution, two first joint board of the equal fixedly connected with in one side of first support column, a plurality of first louvres have been seted up to one side of first aluminum alloy ex-trusions, and is a plurality of first louvre is linear array and distributes, the first thermal-insulated subassembly of one side fixedly connected with of first aluminum alloy ex-trusions, one side fixedly connected with second aluminum alloy ex-trusions of first thermal-insulated subassembly, the first sealed glue of one side fixedly connected with of second aluminum alloy ex-trusions, the first sealed glue one side fixedly connected with second thermal-insulated subassembly of gluing.

Optionally, the first heat insulation assembly comprises a heat dissipation block, a plurality of second heat dissipation holes are formed in the middle of the heat dissipation block, the second heat dissipation holes are distributed in a linear array mode, a fixing plate is fixedly connected to two sides of the heat dissipation block, a plurality of third heat dissipation holes are formed in one side of the fixing plate, and the third heat dissipation holes are distributed in a linear array mode.

Optionally, the second aluminum alloy section bar includes the bottom plate, two second support columns of one side fixedly connected with of bottom plate, two the second support column is the symmetric distribution, two the equal fixedly connected with second joint board in one side of second support column, a plurality of fourth heat dissipation holes have been seted up to one side of bottom plate, and is a plurality of the fourth heat dissipation hole is linear evenly distributed.

Optionally, the second heat insulation assembly comprises a limiting plate, two supporting plates and two supporting plates are fixedly connected to one side of the limiting plate, the supporting plates are symmetrically distributed and two, a top plate is fixedly connected to one side of the supporting plates, a plurality of X-shaped supporting plates are fixedly connected to one side of the limiting plate, one side of the top plate is fixedly connected to one side of the X-shaped supporting plates, a second sealant is fixedly connected to one side of the top plate, and a third aluminum alloy section is fixedly connected to one side of the second sealant.

Optionally, the polystyrene foam board is filled inside each of the first aluminum alloy section, the second aluminum alloy section and the third aluminum alloy section.

Optionally, the first sealant and the second sealant are made of high-temperature-resistant resin.

Optionally, a plurality of the X-shaped supporting plates are uniformly and symmetrically distributed, and a plurality of the X-shaped supporting plates are distributed in a linear array.

The utility model has the advantages of it is following:

most of bridge-cut-off aluminum structures only have one layer of heat insulation structure, the one layer of heat insulation structure can not completely radiate the aluminum alloy section, the aluminum alloy section can be deformed after long-time use, and can not be normally used, the novel aluminum alloy section containing the double-heat-insulation bridge-cut-off structure separates the first aluminum alloy section from the second aluminum alloy section through the first heat insulation assembly, because metal has heat conductivity, and then radiates heat through the second heat radiation holes in the heat radiation block, the third heat radiation holes in the first heat insulation assembly can also radiate heat, so that the first heat insulation assembly is maximally utilized to radiate the first aluminum alloy section and the second aluminum alloy section, the second heat insulation assembly separates the second aluminum alloy section from the third aluminum alloy section, and the X-shaped support plate, the support plate and the top plate form a polystyrene foam plate in a cavity to isolate a large amount of heat, go out through the cavity heat dissipation, first thermal-insulated subassembly and second thermal-insulated subassembly pass through the cooperation and to the partition of aluminum alloy ex-trusions and let aluminum alloy ex-trusions's thermal-insulated and heat dissipation obtain very big promotion, have also prolonged aluminum alloy ex-trusions's life moreover.

Drawings

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

fig. 2 is a schematic diagram of the explosion structure of the present invention;

FIG. 3 is a schematic view of a first thermal insulation assembly according to the present invention;

fig. 4 is a schematic structural view of a second thermal insulation assembly according to the present invention.

In the figure: 1-first aluminum alloy profile, 101-first supporting column, 102-first clamping plate, 103-first heat dissipation hole, 2-first heat insulation component, 201-heat dissipation block, 202-second heat dissipation hole, 203-fixing plate, 204-third heat dissipation hole, 3-second aluminum alloy profile, 301-bottom plate, 302-second supporting column, 303-second clamping plate, 304-fourth heat dissipation hole, 4-first sealant, 5-second heat insulation component, 501-limiting plate, 502-supporting plate, 503-top plate, 504-X type supporting plate, 6-second sealant and 7-third aluminum alloy profile.

Detailed Description

The invention will be further described with reference to the accompanying drawings, but the scope of the invention is not limited to the following description.

As shown in FIGS. 1-4, an aluminum alloy section containing a double-heat-insulation bridge-cut-off structure comprises a first aluminum alloy section 1, wherein one side of the first aluminum alloy section 1 is fixedly connected with two first supporting pillars 101, the two first supporting pillars 101 are symmetrically distributed, one side of each of the two first supporting pillars 101 is fixedly connected with a first clamping plate 102, the first clamping plate 102 is fixedly connected with one side of a fixing plate 203 through a bolt clamp, one side of the first aluminum alloy section 1 is provided with a plurality of first heat dissipation holes 103, the first heat dissipation holes 103 and the second heat dissipation holes 202 are arranged on the same straight line, so that the first heat dissipation holes 103 and the second heat dissipation holes 202 are mutually matched for heat dissipation, the plurality of first heat dissipation holes 103 are distributed in a linear array, one side of the first aluminum alloy section 1 is fixedly connected with a first heat insulation component 2, one side of the first heat insulation component 2 is fixedly connected with a second aluminum alloy section 3, one side of the second aluminum alloy section bar 3 is fixedly connected with a first sealant 4, and one side of the first sealant 4 is fixedly connected with a second heat insulation assembly 5.

As an optimal technical solution of the utility model: the first heat insulation component 2 comprises a heat dissipation block 201, a plurality of second heat dissipation holes 202 are formed in the middle of the heat dissipation block 201, the plurality of second heat dissipation holes 202 are distributed in a linear array mode, two fixing plates 203 are fixedly connected to two sides of the heat dissipation block 201, a plurality of third heat dissipation holes 204 are formed in one sides of the two fixing plates 203, the plurality of third heat dissipation holes 204 are distributed in a linear array mode, most of broken bridge aluminum structures only have one layer of heat insulation structure, the heat insulation structure of one layer cannot completely dissipate heat of the aluminum alloy profile, the aluminum alloy profile can deform after being used for a long time, and cannot be normally used, the first aluminum alloy profile 1 and the second aluminum alloy profile 3 are separated through the first heat insulation component 2 in the novel aluminum alloy profile with the double heat insulation broken bridge structure, because metal has heat conductivity, heat dissipation is performed through the second heat dissipation holes 202 in the heat dissipation block 201, and the third heat dissipation holes 204 in the first heat insulation component 2 can also dissipate heat, this maximizes the use of the first insulating assembly 2 for heat dissipation of the first 1 and second 3 aluminium alloy profiles.

As an optimal technical solution of the utility model: second aluminum alloy ex-trusions 3 includes bottom plate 301, two second support columns 302 of one side fixedly connected with of bottom plate 301, two second support columns 302 are the symmetric distribution, second joint board 303 of the equal fixedly connected with in one side of two second support columns 302, second joint board 303 passes through the bolt fastening in one side of fixed plate 202, a plurality of fourth heat dissipation holes 304 have been seted up to one side of bottom plate 301, fourth heat dissipation hole 304 and third louvre 204 are a straight line, so fourth heat dissipation hole 304 and third louvre 204 can mutually support dispel the heat, two louvres just can the maximize dispel the heat like this, a plurality of fourth heat dissipation holes 304 are linear evenly distributed.

As an optimal technical solution of the utility model: the second heat insulation assembly 5 comprises a limit plate 501, one side of the limit plate 501 is fixedly connected with two support plates 502, the two support plates 502 are symmetrically distributed, one side of the two support plates 502 is fixedly connected with a top plate 503, one side of the limit plate 501 is fixedly connected with a plurality of X-shaped support plates 504, one side of the top plate 503 is fixedly connected with one side of the support plates 504, the second aluminum alloy profile and the third aluminum alloy profile 7 are separated through the second heat insulation assembly 5, the polystyrene foam plates in the cavity formed by the X-shaped support plates 504, the support plates 502 and the top plate 503 can isolate a large amount of heat, the heat is dissipated through the cavity, the heat insulation and the heat dissipation of the aluminum alloy profiles are greatly improved through the matching and the separation of the first heat insulation assembly 2 and the second heat insulation assembly 5 on the aluminum alloy profiles, the service life of the aluminum alloy profiles is prolonged, one side of the top plate 503 is fixedly connected with a second sealant 6, one side of the second sealant 6 is fixedly connected with a third aluminum alloy section 7.

As an optimal technical solution of the utility model: the polystyrene foam plates are filled in the first aluminum alloy section bar 1, the second aluminum alloy section bar 3 and the third aluminum alloy section bar 7, the polystyrene foam plates can prolong the service life of a building object, reduce the stress generated by structural deformation caused by temperature change, and reduce the corrosion of harmful substances and ultraviolet rays in the air to the structure.

As an optimal technical solution of the utility model: the first sealant 4 and the second sealant 6 are made of high-temperature resistant resin.

As an optimal technical solution of the utility model: the plurality of X-shaped support plates 504 are uniformly and symmetrically distributed, and the plurality of X-shaped support plates 504 are distributed in a linear array.

In summary, the following steps: most of bridge-cut-off aluminum structures only have one layer of heat insulation structure, the one layer of heat insulation structure can not completely radiate the aluminum alloy section, the aluminum alloy section can be deformed after long-time use, and can not be normally used, the novel aluminum alloy section containing the double-heat-insulation bridge-cut-off structure separates the first aluminum alloy section 1 and the second aluminum alloy section 3 through the first heat insulation assembly 2, because metal has heat conductivity, the heat is radiated through the second heat radiation hole 202 in the heat radiation block 201, the heat can be radiated through the third heat radiation hole 204 in the first heat insulation assembly 2, so that the first heat insulation assembly 2 is maximally utilized to radiate the first aluminum alloy section 1 and the second aluminum alloy section 3, the second heat insulation assembly 5 separates the second aluminum alloy section and the third aluminum alloy section 7, and the second heat insulation assembly 5 separates the second aluminum alloy section and the third aluminum alloy section 7, the polystyrene foam board in the cavity formed by the X-shaped supporting plate 504, the supporting plate 502 and the top plate 503 can isolate a large amount of heat, the heat is dissipated out through the cavity, the heat insulation and dissipation of the aluminum alloy profile are greatly improved by the first heat insulation assembly 2 and the second heat insulation assembly 5 through matching and separation of the aluminum alloy profile, and the service life of the aluminum alloy profile is prolonged.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an aluminum alloy ex-trusions that contains two thermal-insulated bridge cut-off structures which characterized in that: comprises a first aluminum alloy section bar (1), wherein one side of the first aluminum alloy section bar (1) is fixedly connected with two first supporting columns (101), the two first supporting columns (101) are symmetrically distributed, one side of each of the two first supporting columns (101) is fixedly connected with a first clamping plate (102), one side of the first aluminum alloy section bar (1) is provided with a plurality of first heat dissipation holes (103), the first heat dissipation holes (103) are distributed in a linear array, one side of the first aluminum alloy section bar (1) is fixedly connected with a first heat insulation component (2), one side of the first heat insulation component (2) is fixedly connected with a second aluminum alloy section bar (3), one side of the second aluminum alloy section bar (3) is fixedly connected with a first sealant (4), one side of the first sealant (4) is fixedly connected with a second heat insulation assembly (5).

2. The aluminum alloy profile containing the double-heat-insulation bridge cut-off structure as recited in claim 1, wherein: first thermal-insulated subassembly (2) is including radiating block (201), a plurality of second louvres (202) have been seted up at the middle part of radiating block (201), and is a plurality of second louvre (202) are linear array and distribute, fixed plate (203) of the equal fixedly connected with in both sides of radiating block (201), two a plurality of third louvre (204) have all been seted up to one side of fixed plate (203), and are a plurality of third louvre (204) are linear array and distribute.

3. The aluminum alloy profile containing the double-heat-insulation bridge cut-off structure as recited in claim 1, wherein: second aluminum alloy ex-trusions (3) are including bottom plate (301), two second support columns (302) of one side fixedly connected with of bottom plate (301), two second support column (302) are the symmetric distribution, two second joint board (303) of the equal fixedly connected with in one side of second support column (302), a plurality of fourth heat dissipation holes (304) have been seted up to one side of bottom plate (301), and are a plurality of fourth heat dissipation holes (304) are linear evenly distributed.

4. The aluminum alloy profile containing the double-heat-insulation bridge cut-off structure as recited in claim 1, wherein: the second heat insulation assembly (5) comprises a limiting plate (501), two supporting plates (502) and two supporting plates (502) are fixedly connected to one side of the limiting plate (501), the two supporting plates (502) are symmetrically distributed and two, one side of each supporting plate (502) is fixedly connected with a top plate (503), a plurality of X-shaped supporting plates (504) are fixedly connected to one side of the limiting plate (501), and one side of each top plate (503) is fixedly connected with a limiting plate (501)X Shaped support plate(504) The sealing structure is characterized in that one side of the top plate (503) is fixedly connected with a second sealing glue (6), and one side of the second sealing glue (6) is fixedly connected with a third aluminum alloy section bar (7).

5. The aluminum alloy profile containing the double-heat-insulation bridge cut-off structure as recited in claim 1, wherein: the polystyrene foam plates are filled in the first aluminum alloy section (1), the second aluminum alloy section (3) and the third aluminum alloy section (7).

6. The aluminum alloy profile containing the double-heat-insulation bridge-cut-off structure as recited in claim 1, wherein: the first sealant (4) and the second sealant (6) are made of high-temperature-resistant resin.

7. The aluminum alloy profile containing the double-heat-insulation bridge cut-off structure as recited in claim 4, wherein: the X-shaped supporting plates (504) are uniformly and symmetrically distributed, and the X-shaped supporting plates (504) are distributed in a linear array.

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