CN214006910U

CN214006910U - Bridge-cut-off aluminum alloy door and window with inward opening door and window and outward opening screen window

Info

Publication number: CN214006910U
Application number: CN202022429250.0U
Authority: CN
Inventors: 朱学良; 朱学忠; 付浩
Original assignee: Henan Zhongsheng Intelligent Door & Window Co ltd
Current assignee: Henan Zhongsheng Intelligent Door & Window Co ltd
Priority date: 2020-10-27
Filing date: 2020-10-27
Publication date: 2021-08-20
Anticipated expiration: 2030-10-27

Abstract

The utility model relates to the field of doors and windows, in particular to a bridge cut-off aluminum alloy door and window with an inward opening door and window and an outward opening screen window; the window comprises a window frame, a screen window and an internally-opened window sash, wherein the internally-opened window sash is arranged at the position of the window frame close to the indoor direction and is hinged with one side of the window frame; the utility model discloses an aluminum alloy door and window adopts thermal-insulated bridge cut-off aluminium alloy and cavity glass to combine window frame, screen window and interior division of casement rationally to set up nylon heat insulating strip and cooperate foaming glue layer and heat preservation isotructure to make simultaneously the utility model discloses an aluminum alloy door and window has functions such as comparatively excellent thermal-insulated, energy-conservation, sealed.

Description

Bridge-cut-off aluminum alloy door and window with inward opening door and window and outward opening screen window

Technical Field

The utility model relates to a door and window field, concretely relates to bridge cut-off aluminum alloy door and window with interior door and window and external-open screen window.

Background

As a widely applied door and window structure, the heat insulation and sealing performance of the aluminum alloy door and window directly determine the quality of the aluminum alloy door and window. The plastic steel window has the advantages of good heat insulation, air tightness, water tightness, heat preservation and the like, and the related performance advantages of the aluminum alloy are not obvious, so that how to optimize the structure of the aluminum alloy so as to improve the related performance is very important.

Disclosure of Invention

For solving the problems of the prior art, the utility model provides a bridge cut-off aluminum alloy door and window with internal-open door and window and external-open screen window.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a bridge cut-off aluminum alloy door and window with an inward opening door and window and an outward opening screen window comprises a window frame, the screen window and an inward opening window sash, wherein the inward opening window sash is arranged at the position, close to the indoor direction, of the window frame, the inward opening window sash is hinged with one side of the window frame, the screen window is arranged at the position, close to the outdoor direction, of the window frame, and the screen window is hinged with the other side of the window frame;

the window frame comprises a first window frame section, a second window frame section, a nylon heat insulation strip and a foaming adhesive layer, wherein the first window frame section is close to the outdoor side, the second window frame section is close to the indoor side, the foaming adhesive layer is arranged between the upper parts of the first window frame section and the second window frame section, a gap is arranged between the first window frame section and the second window frame section, and the nylon heat insulation strip is fixedly arranged between the gaps;

the inner side of the window frame section bar is integrally and fixedly provided with a first hollow chamber, the cross section of the first hollow chamber is rectangular, the side wall of the first hollow chamber is provided with a first embedded groove, a second embedded groove, a third embedded groove and a fourth embedded groove, the first embedded groove, the second embedded groove, the third embedded groove and the fourth embedded groove are distributed from top to bottom, and the upper part of the first hollow chamber is provided with a foaming adhesive layer; the first embedded groove and the third embedded groove are both wedge-shaped structures, the second embedded groove is ︺ -shaped, and the fourth embedded groove is L-shaped;

a second hollow chamber is integrally and fixedly arranged on the inner side of the second window frame section, the section of the second hollow chamber is of a rectangular structure, the section area of the second hollow chamber is larger than that of the first hollow chamber, one side of the second hollow chamber is provided with a fifth embedded groove, a sixth embedded groove, a seventh embedded groove and an eighth embedded groove, the fifth embedded groove, the sixth embedded groove, the seventh embedded groove and the eighth embedded groove are distributed from top to bottom, and the upper part of the second hollow chamber is provided with a foaming layer;

a foaming rubber chamber is formed between the upper parts of the first hollow chamber and the second hollow chamber and the upper part of the first nylon heat insulation strip, and a foaming rubber layer is filled in the foaming rubber chamber;

the second hollow chamber is fixedly connected with the galvanized square tube through screws, and the screws penetrate through a foaming adhesive layer in the foaming adhesive chamber and are fixedly connected with the galvanized square tube; both sides of the galvanized square pipe are provided with plastering layers; the upper part of the plastering layer is provided with a heat-insulating layer, one side of the heat-insulating layer is fixedly connected with the wall body, one end of a nylon expansion nail is fixedly connected with the galvanized square tube, and the other end of the nylon expansion nail penetrates through the heat-insulating layer and then is fixedly connected with the wall body;

the internally-opened window sash comprises a first window sash frame, a second window sash frame, sealing strips and hollow glass, the sealing strips are arranged between the upper parts of the first window sash frame and the second window sash frame, and the hollow glass is arranged between the lower parts of the first window sash frame and the second window sash frame;

the window frame is characterized in that a first window sash chamber is arranged on one side of the window sash frame, the cross section of the first window sash chamber is of a rectangular structure, a first window sash embedding groove, a second window sash embedding groove and a third window sash embedding groove are arranged on one side of the first window sash chamber, the first window sash embedding groove, the second window sash embedding groove and the third window sash embedding groove are distributed from top to bottom, the first window sash embedding groove and the third window sash embedding groove are both of wedge-shaped structures, and the cross section of the second window sash embedding groove is of an ︺ -shaped structure;

two one sides of window fan frame set up window fan room two, and casement room cross-section is rectangular column structure, and casement room one side sets up casement embedded groove four, casement embedded groove five and casement embedded groove six, and casement embedded groove four, casement embedded groove five and casement embedded groove six distribute from last to down, and casement embedded groove four, casement embedded groove six are the wedge structure, and casement embedded groove five is "︺" column structure.

Preferably, the sections of the fifth embedded groove and the seventh embedded groove are both wedge-shaped structures, the six sections of the embedded groove are ︺ -shaped structures, and the eight sections of the embedded groove are L-shaped structures.

Preferably, the first embedded groove is arranged corresponding to the fifth embedded groove, the second embedded groove is arranged corresponding to the sixth embedded groove, the third embedded groove is arranged corresponding to the seventh embedded groove, and the fourth embedded groove is arranged corresponding to the eighth embedded groove.

Preferably the nylon heat insulating strip includes nylon heat insulating strip one, nylon heat insulating strip two and nylon heat insulating strip three, sets up nylon heat insulating strip one between embedded groove one and the embedded groove five, and the matching of nylon heat insulating strip one end is embedded into embedded groove one, and the matching of a nylon heat insulating strip other end is embedded into embedded groove five.

Preferably set up nylon heat insulating strip two between embedded groove three and the embedded groove seven, two one ends of nylon heat insulating strip match and imbed to embedded groove three in, two other ends of nylon heat insulating strip match and imbed to embedded groove seven in.

A third nylon heat-insulating strip is preferably arranged between the fourth embedded groove and the eighth embedded groove, one end of the third nylon heat-insulating strip is embedded into the fourth embedded groove in a matching manner, and the other end of the third nylon heat-insulating strip is embedded into the eighth embedded groove in a matching manner; two sides of the upper portion of the nylon heat insulation strip are provided with a first groove and a second groove, the front end of the bottom of the embedded groove IV is embedded into the first groove, and the front end of the bottom of the embedded groove VIII is embedded into the second groove.

Preferably, the first window sash embedded groove is correspondingly matched with the fourth window sash embedded groove, the second window sash embedded groove is correspondingly matched with the fifth window sash embedded groove, and the third window sash embedded groove is correspondingly matched with the sixth window sash embedded groove.

Preferably the sealing strip includes sealing strip one and sealing strip two, sets up sealing strip one between casement embedded groove one and the casement embedded groove four, and the sealing strip one end matches the embedding to the casement embedded groove in one, and the other end of sealing strip matches the embedding to the casement embedded groove in four, sets up sealing strip two between casement embedded groove three and the casement embedded groove six, and two one ends of sealing strip match the embedding to the casement embedded groove in three, and two other ends of sealing strip match the embedding to the casement embedded groove in six.

Preferably, one side of the bottom of the window sash chamber is fixedly connected with the upper end of the buckling strip, and the bottom end of the buckling strip is fixedly connected with one side of the upper part of the hollow glass through a first sealing adhesive layer.

Preferably, the bottom of the first window sash frame is fixedly connected with the other side of the upper part of the hollow glass through a second sealant layer.

Compared with the prior art, the beneficial effects of utility model are that: the utility model discloses an aluminum alloy door and window adopts thermal-insulated bridge cut-off aluminium alloy and cavity glass to combine window frame, screen window and interior division of casement rationally to set up nylon heat insulating strip and cooperate foaming glue layer and heat preservation isotructure to make simultaneously the utility model discloses an aluminum alloy door and window has functions such as comparatively excellent thermal-insulated, energy-conservation, sealed.

Drawings

Other features, objects and advantages of the invention will become more apparent from a reading of the following detailed description of non-limiting embodiments thereof, with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the middle window frame section of the present invention.

Fig. 3 is a schematic structural view of the middle window frame section of the present invention.

Fig. 4 is a schematic structural view of a middle sash frame according to the present invention.

Fig. 5 is a schematic structural view of the middle sash frame of the present invention.

Fig. 6 is a schematic diagram of three structures of the nylon heat insulation strip of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the following examples, which are provided only for illustrating the present invention and do not limit the scope of the present invention.

Please refer to fig. 1-6, which illustrate a bridge-cut-off al-alloy door/window with an inward-opening door/window and an outward-opening screen window, comprising a window frame 1, a screen window 2 and an inward-opening sash 3, wherein the inward-opening sash 3 is arranged at the indoor side of the window frame 1, the inward-opening sash 3 is hinged with one side of the window frame 1, the screen window 2 is arranged at the outdoor side of the window frame 1, and the screen window 2 is hinged with the other side of the window frame 1;

the window frame 1 comprises a first window frame section bar 11, a second window frame section bar 12, a nylon heat insulation strip 13 and a foaming adhesive layer 14, wherein the first window frame section bar 11 is close to the outdoor side, the second window frame section bar 12 is close to the indoor side, the foaming adhesive layer 14 is arranged between the upper parts of the first window frame section bar 11 and the second window frame section bar 12, a gap 121 is arranged between the first window frame section bar 11 and the second window frame section bar 12, and the nylon heat insulation strip 13 is fixedly arranged between the gaps 121; the nylon heat insulation strips 13 and the foam rubber layer 14 improve the heat insulation performance of the window frame 1, and further improve the heat insulation performance of the aluminum alloy door and window integrally.

Please refer to fig. 2, the inner side of the window frame section bar i 11 is integrally and fixedly provided with a first hollow chamber i 111, the cross section of the first hollow chamber i 111 is rectangular, one side wall of the first hollow chamber i 111 is provided with a first embedded groove 1111, a second embedded groove 1112, a third embedded groove 1113 and a fourth embedded groove 1114, the first embedded groove 1111, the second embedded groove 1112, the third embedded groove 1113 and the fourth embedded groove 1114 are distributed from top to bottom, and the upper part of the first hollow chamber i 111 is provided with a foam rubber layer 14; the foamed adhesive layer 14 is made of foamed polyurethane.

The sections of the first embedded groove 1111 and the third embedded groove 1113 are both wedge-shaped structures, the nylon heat insulation strips 13 can be firmly installed due to the wedge-shaped structures, the section of the second embedded groove 1112 is in an ︺ -shaped structure, and the section of the fourth embedded groove 1114 is in an L-shaped structure;

please refer to fig. 3, a second hollow chamber 121 is fixedly arranged on the inner side of the second sash profile 12, the section of the second hollow chamber 121 is rectangular, the sectional area of the second hollow chamber 121 is larger than that of the first hollow chamber 111, one side of the second hollow chamber 121 is provided with a fifth embedded groove 1211, a sixth embedded groove 1212, a seventh embedded groove 1213 and an eighth embedded groove 1214, the fifth embedded groove 1211, the sixth embedded groove 1212, the seventh embedded groove 1213 and the eighth embedded groove 1214 are distributed from top to bottom, and the upper part of the second hollow chamber 121 is provided with a foaming layer 14;

the cross sections of the five embedded grooves 1211 and the seven embedded grooves 1213 are both wedge-shaped structures, the cross section of the six embedded grooves 1212 is an ︺ -shaped structure, and the cross section of the eight embedded grooves 1214 is an L-shaped structure.

The first embedded groove 1111 is arranged corresponding to the fifth embedded groove 1211, the second embedded groove 1112 is arranged corresponding to the sixth embedded groove 1212, the third embedded groove 1113 is arranged corresponding to the seventh embedded groove 1213, and the fourth embedded groove 1114 is arranged corresponding to the eighth embedded groove 1214.

The nylon heat-insulating strip 13 comprises a first nylon heat-insulating strip 131, a second nylon heat-insulating strip 132 and a third nylon heat-insulating strip 133, the first nylon heat-insulating strip 131 is arranged between the first embedded groove 1111 and the fifth embedded groove 1211, one end of the first nylon heat-insulating strip 131 is embedded into the first embedded groove 1111 in a matching mode, the other end of the first nylon heat-insulating strip 131 is embedded into the fifth embedded groove 1211 in a matching mode,

a second nylon heat-insulating strip 132 is arranged between the third embedded groove 1113 and the seventh embedded groove 1213, one end of the second nylon heat-insulating strip 132 is embedded into the third embedded groove 1113 in a matching manner, and the other end of the second nylon heat-insulating strip 132 is embedded into the seventh embedded groove 1213 in a matching manner;

please refer to fig. 6, a third nylon heat-insulating strip 133 is arranged between the fourth embedded groove 1114 and the eighth embedded groove 1214, one end of the third nylon heat-insulating strip 133 is embedded into the fourth embedded groove 1114 in a matching manner, and the other end of the third nylon heat-insulating strip 133 is embedded into the eighth embedded groove 1214 in a matching manner; two sides of the upper part of the third nylon heat insulation strip 133 are provided with a first groove 1331 and a second groove 1332, the front end of the bottom of the embedded groove four 1114 is embedded into the first groove 1331, and the front end of the bottom of the embedded groove eight 1214 is embedded into the second groove 1332. The better heat insulation of the window frame 1 is realized through the cooperative cooperation of the first nylon heat insulation strip 131, the second nylon heat insulation strip 132 and the third nylon heat insulation strip 133.

A foaming rubber chamber 141 is formed between the upper parts of the first hollow chamber 111 and the second hollow chamber 121 and the upper part of the first nylon heat insulation strip 131, and the foaming rubber layer 14 is filled in the foaming rubber chamber 141; preferably, a foaming chamber sealant 1411 is disposed between the two sides of the foaming chamber 141 and the plastering layer 4.

The hollow chamber II 121 is fixedly connected with the galvanized square pipe 5 through a screw 120, and the screw 120 penetrates through a foaming adhesive layer 14 in the foaming adhesive chamber 141 and then is fixedly connected with the galvanized square pipe 5; both sides of the galvanized square pipe 5 are provided with plastering layers 4; the heat preservation 6 is arranged on the upper portion of the plastering layer 4, one side of the heat preservation 6 is fixedly connected with the wall body 7, one end of the nylon expansion nail 8 is fixedly connected with the galvanized square pipe 5, and the other end of the nylon expansion nail 8 penetrates through the heat preservation 6 and then is fixedly connected with the wall body 7. The galvanized square pipe 5 is fixedly connected with the second hollow chamber 121 through a screw 120, and the galvanized square pipe 5 is fixedly connected with the wall 7 through a nylon expansion nail 8.

The internally-opened window sash 3 comprises a first window sash frame 31, a second window sash frame 32, a sealing strip 33 and hollow glass 34, the sealing strip 33 is arranged between the upper parts of the first window sash frame 31 and the second window sash frame 32, and the hollow glass 34 is arranged between the lower parts of the first window sash frame 31 and the second window sash frame 32;

please refer to fig. 4, a first window sash chamber 311 is disposed on one side of the first window sash frame 31, the cross section of the first window sash chamber 311 is rectangular, a first window sash embedded groove 3111, a second window sash embedded groove 3112 and a third window sash embedded groove 3113 are disposed on one side of the first window sash chamber 311, the first window sash embedded groove 3111, the second window sash embedded groove 3112 and the third window sash embedded groove 3113 are distributed from top to bottom, the first window sash embedded groove 3111 and the third window sash embedded groove 3113 are wedge-shaped structures, and the cross section of the second window sash embedded groove 3112 is ︺ -shaped.

Please refer to fig. 5, a second sash chamber 321 is arranged on one side of the second sash frame 32, the section of the sash chamber 321 is rectangular, a fourth sash embedded groove 3211, a fifth sash embedded groove 3212 and a sixth sash embedded groove 3213 are arranged on one side of the sash chamber 321, the fourth sash embedded groove 3211, the fifth sash embedded groove 3212 and the sixth sash embedded groove 3213 are distributed from top to bottom, the fourth sash embedded groove 3211 and the sixth sash embedded groove 3213 are wedge-shaped structures, and the fifth sash embedded groove 3212 is in an ︺ -shaped structure.

Casement embedded groove one 3111 corresponds the setting with casement embedded groove four 3211 phase-match, and casement embedded groove two 3112 corresponds the setting with casement embedded groove five 3212 phase-match, and casement embedded groove three 3113 corresponds the setting with casement embedded groove six 3213 phase-match.

The sealing strip 33 comprises a first sealing strip 331 and a second sealing strip 332, the first sealing strip 331 is arranged between the first window sash embedding groove 3111 and the fourth window sash embedding groove 3211, one end of the first sealing strip 331 is embedded into the first window sash embedding groove 3111, the other end of the first sealing strip 331 is embedded into the fourth window sash embedding groove 3211, the second sealing strip 332 is arranged between the third window sash embedding groove 3113 and the sixth window sash embedding groove 3213, one end of the second sealing strip 332 is embedded into the third window sash embedding groove 3113, and the other end of the second sealing strip 332 is embedded into the sixth window sash embedding groove 3213. The sealing performance of the inward opening window sash 3 is improved by the matching of the first sealing strip 331, the first window sash embedding groove 3111 and the fourth window sash embedding groove 3211, and meanwhile, the sealing performance of the inward opening window sash 3 is further improved by the matching of the second sealing strip 332, the third window sash embedding groove 3113 and the sixth window sash embedding groove 3213.

One side of the bottom of the window sash chamber 321 is fixedly connected with the upper end of the buckle bar 3210, and the bottom end of the buckle bar 3210 is fixedly connected with one side of the upper part of the hollow glass 34 through a first sealing adhesive layer 32101. The first sealant layer 32101 is neutral silicone sealant; the window sash chamber 321 is fixedly connected with the hollow glass 34 in a sealing way by matching the buckle strip 3210 with the first sealant layer 32101.

The bottom of the first sash frame 31 is fixedly connected with the other side of the upper part of the hollow glass 34 through a second sealant layer 310. The second sealant layer 310 is neutral silicone sealant; the first sash frame 31 is fixedly and hermetically connected with the hollow glass 34 through the second sealant layer 310.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention. However, any simple modification, equivalent change and modification made to the above embodiments according to the technical substance of the present invention still belong to the protection scope of the technical solution of the present invention.

Claims

1. The utility model provides a bridge cut-off aluminum alloy door and window with interior door and window and external-open screen window which characterized in that: the window comprises a window frame, a screen window and an internally-opened window sash, wherein the internally-opened window sash is arranged at the position of the window frame close to the indoor direction and is hinged with one side of the window frame;

2. The bridge-cut aluminum alloy door and window with the inward-opening door and window and the outward-opening screen window as claimed in claim 1, wherein the sections of the five embedded grooves and the seven embedded grooves are both wedge-shaped structures, the six embedded grooves are ︺ -shaped structures, and the eight embedded grooves are L-shaped structures.

3. The bridge-cut aluminum alloy door and window with the inward-opening door and window and the outward-opening screen window as claimed in claim 2, wherein the first embedded groove is correspondingly arranged with the fifth embedded groove, the second embedded groove is correspondingly arranged with the sixth embedded groove, the third embedded groove is correspondingly arranged with the seventh embedded groove, and the fourth embedded groove is correspondingly arranged with the eighth embedded groove.

4. The bridge-cut aluminum alloy door and window with the inward-opening door and window and the outward-opening screen window as claimed in claim 3, wherein the nylon heat insulation strips comprise a first nylon heat insulation strip, a second nylon heat insulation strip and a third nylon heat insulation strip, a first nylon heat insulation strip is arranged between the first embedded groove and the fifth embedded groove, one end of the first nylon heat insulation strip is embedded into the first embedded groove in a matching mode, and the other end of the first nylon heat insulation strip is embedded into the fifth embedded groove in a matching mode.

5. The bridge-cut-off aluminum alloy door and window with the inward-opening door and window and the outward-opening screen window as claimed in claim 4, wherein a second nylon heat-insulating strip is arranged between the third embedded groove and the seventh embedded groove, one end of the second nylon heat-insulating strip is embedded into the third embedded groove in a matching manner, and the other end of the second nylon heat-insulating strip is embedded into the seventh embedded groove in a matching manner.

6. The bridge-cut-off aluminum alloy door/window with the inward-opening door/window and the outward-opening screen window as claimed in claim 5, wherein a third nylon heat-insulating strip is arranged between the fourth embedded groove and the eighth embedded groove, one end of the third nylon heat-insulating strip is embedded into the fourth embedded groove in a matching manner, and the other end of the third nylon heat-insulating strip is embedded into the eighth embedded groove in a matching manner; two sides of the upper portion of the nylon heat insulation strip are provided with a first groove and a second groove, the front end of the bottom of the embedded groove IV is embedded into the first groove, and the front end of the bottom of the embedded groove VIII is embedded into the second groove.

7. The bridge-cut-off aluminum alloy door and window with the inward-opening door and window and the outward-opening screen window as claimed in claim 2, wherein the first sash embedded groove is correspondingly matched with the fourth sash embedded groove, the second sash embedded groove is correspondingly matched with the fifth sash embedded groove, and the third sash embedded groove is correspondingly matched with the sixth sash embedded groove.

8. The bridge-cut-off al-alloy door & window with inward-opening door & window and outward-opening screen window of claim 7, characterized in that, the sealing strip includes sealing strip one and sealing strip two, sets up sealing strip one between casement embedded groove one and casement embedded groove four, sealing strip one end matches and imbeds to in the casement embedded groove one, sealing strip one other end matches and imbeds to in the casement embedded groove four, sets up sealing strip two between casement embedded groove three and casement embedded groove six, two one ends of sealing strip match and imbeds to in casement embedded groove three, two other ends of sealing strip match and imbeds to in casement embedded groove six.

9. The aluminum alloy bridge-cut-off door/window with the inward-opening door/window and the outward-opening screen window as claimed in claim 8, wherein one side of the bottom of the window sash chamber is fixedly connected with the upper end of the fastening strip, and the bottom end of the fastening strip is fixedly connected with one side of the upper part of the hollow glass through a first sealing adhesive layer.

10. The bridge-cut aluminum alloy door/window with the inward-opening door/window and the outward-opening screen window as claimed in claim 9, wherein the bottom of the sash frame is fixedly connected with the other side of the upper part of the hollow glass through a second sealant layer.