CN205243305U - Aluminum alloy sliding door's thermal insulation construction - Google Patents

Abstract

The utility model relates to a heat insulation structure of an aluminum alloy sliding door and window, which comprises an upper guide rail outer frame and a lower guide rail outer frame which are set up and down oppositely, and side frames are vertically arranged on both sides of the upper guide rail outer frame and the lower guide rail outer frame , a slidable window sash is arranged between the outer frame of the upper guide rail and the outer frame of the lower guide rail, the first heat insulation strip corresponding to the center of the window sash is arranged on the outer frame of the upper guide rail, and the outer A second heat insulating strip corresponding to the center of the window sash is provided on the frame, and the number of the first heat insulating strip and the second heat insulating strip is at least two. The utility model effectively cuts off the energy conduction on the upper, lower, left, and right frames of the aluminum alloy sliding window caused by the indoor and outdoor temperature difference by arranging the heat insulation strip at the closing position of the corresponding window sash, reduces the indoor energy loss of the building, and improves the aluminum alloy sliding window. The energy-saving and thermal insulation performance of the alloy sliding window greatly increases the heat insulation effect of the aluminum alloy sliding window frame and solves the problem of thermal bridges.

Description

A kind of heat insulation structure of aluminum alloy sliding door and window

technical field

The utility model relates to the field of doors, windows and curtain walls, in particular to a heat insulation structure of aluminum alloy sliding doors and windows.

Background technique

As shown in Figure 1-3, the traditional aluminum alloy sliding doors and windows include outer frame profiles and window sashes 4 with insulating glass. The side frames 3 are arranged symmetrically, and the sash 4 slides and moves along the upper rail frame 1 and the lower rail frame 2. Bar 5 is heat-insulated, and it is divided into two parts, inside and outside. Since the inside and outside of the sash are staggered, there is a gap between the two sash. When the sash is closed, the outer frame profile in the outdoor part communicates with the outer frame profile in the room. Thermal bridges are formed, resulting in loss of energy in the interior of the building.

Utility model content

The purpose of the utility model is to provide a heat insulation structure of an aluminum alloy sliding door and window, which solves the problem of forming a thermal bridge when the window sash is closed, and has a good heat insulation effect.

The purpose of this utility model is to realize through the following technical solutions:

A heat insulation structure of an aluminum alloy sliding door and window, comprising an upper guide rail outer frame and a lower guide rail outer frame oppositely arranged up and down, both sides of the upper guide rail outer frame and the lower guide rail outer frame are vertically provided with side frames, the upper A slidable window sash is provided between the outer frame of the guide rail and the outer frame of the lower guide rail. The first heat insulation strip corresponding to the center of the window sash is provided on the outer frame of the upper guide rail. The number of the second heat insulation strip corresponding to the center of the window sash, the number of the first heat insulation strip and the second heat insulation strip are at least two.

Further, the number of the first heat insulation strips is 2, and the outer frame of the upper guide rail is divided into three parts: the first outer frame, the first inner frame and the first middle frame, and the first outer frame and the first middle frame The first inner frame is symmetrically arranged on both sides of the outer frame of the upper guide rail, and the inner side of the first outer frame and the first inner frame are provided with a first upper guide rail, and both sides of the first middle frame are provided with A second upper guide rail corresponding to the first upper guide rail.

Further, a third heat insulation strip is provided between the first upper guide rail and the second upper guide rail, which is used for heat insulation and also serves as a supporting function between the first upper guide rail and the second upper guide rail.

Further, a limiting block is provided on the inner side of the first middle frame.

Further, the number of the second heat insulation strip is 2, and the outer frame of the lower guide rail is divided into three parts: the second outer frame, the second inner frame and the second middle frame, and the second outer frame and the second middle frame The second inner frame is symmetrically arranged on both sides of the outer frame of the lower guide rail, the inner sides of the second outer frame and the second inner frame are provided with first lower guide rails, and both sides of the second middle frame are provided with A second lower guide rail corresponding to the first lower guide rail.

Further, a heat insulation base is provided between the first lower guide rail and the second lower guide rail, and an aluminum alloy guide rail profile is arranged on the heat insulation base, which is used to make the aluminum alloy guide rail profile and the outer surface of the lower guide rail The frames are separated to play a role of heat insulation, and also serve as a support between the first lower guide rail and the second lower guide rail.

Further, a limiting block is provided on the inner side of the second middle frame.

Further, a fourth heat insulating strip is provided on the side frame corresponding to the closed position of the sash, and divides the side frame into two parts: a side outer frame and a side inner frame.

The beneficial effects of the utility model are as follows: the utility model effectively cuts off the energy conduction on the upper, lower, left, and right frames of the aluminum alloy sliding window caused by the temperature difference between indoor and outdoor by setting the heat insulation strip at the closing position of the corresponding window sash, and reduces the energy consumption of the building. The loss of indoor energy improves the energy-saving and thermal insulation performance of aluminum alloy sliding windows, greatly increases the heat insulation effect of aluminum alloy sliding window frames, and solves the problem of thermal bridges.

Description of drawings

Below according to accompanying drawing, the utility model is described in further detail.

Fig. 1 is the external structural diagram of traditional aluminum alloy sliding doors and windows described in the utility model;

Fig. 2 is an A-A sectional structural view of the aluminum alloy sliding doors and windows described in the background technology in Fig. 1;

Fig. 3 is a B-B sectional structural view of the aluminum alloy sliding door and window described in the background technology in Fig. 1

Fig. 4 is an A-A cross-sectional structure diagram of a heat insulation structure of an aluminum alloy sliding door and window described in the embodiment of the utility model in Fig. 1;

Fig. 5 is a B-B cross-sectional structure diagram of an aluminum alloy sliding door and window heat insulation structure according to the embodiment of the utility model in Fig. 1 .

In the picture:

1. Outer frame of upper guide rail; 2. Outer frame of lower guide rail; 3. Side frame; 4. Sash; 5. Heat insulation strip; 6. First outer frame; 7. First inner frame; 8. First middle frame; 9. The first upper guide rail; 10. The second upper guide rail; 11. The second outer frame; 12. The second inner frame; 13. The second middle frame; 14. The first lower guide rail; 15. The second lower guide rail; 16 , heat insulation base; 17, aluminum alloy guide rail profile; 18, limit block; 19, first heat insulation strip; 20, second heat insulation strip; 21, third heat insulation strip; 22, fourth heat insulation strip .

detailed description

As shown in Figures 1 and 4, the heat insulation structure of an aluminum alloy sliding door and window according to the embodiment of the present invention includes an upper guide rail outer frame 1 and a lower guide rail outer frame 2 arranged up and down oppositely, and an upper guide rail outer frame 1 and a lower guide rail outer frame Both sides of the outer frame 2 are vertically provided with side frames 3 , and a slidable window 4 is arranged between the upper guide rail outer frame 1 and the lower guide rail outer frame 2 .

The upper rail outer frame 1 is provided with two first heat insulating strips 19 corresponding to the center of the window sash 4, and the upper rail outer frame 1 is divided into a first outer frame 6, a first inner frame 7 and a first middle frame 8 Three parts, the first outer frame 6 and the first inner frame 7 are symmetrically arranged on both sides of the upper rail outer frame 1, and the inner sides of the first outer frame 6 and the first inner frame 7 are provided with a first upper guide rail 9, and the first upper rail 9 is arranged on the inner side of the first inner frame 7. Both sides of a middle frame 8 are provided with a second upper guide rail 10 corresponding to the first upper guide rail 9, and a third heat insulating strip 21 is arranged between the first upper guide rail 9 and the second upper guide rail 10. The inner side of the frame 8 is provided with a limit block 18, which is used to prevent the window sash 4 from derailing and falling. The number of the first middle frame 8 of the window sashes 4, the first heat insulation strip 19 is arranged between the two first middle frames 8, so that the number of the first heat insulation strip 19 is equal to the number of the window sashes 4.

The lower guide rail outer frame 2 is provided with two second heat insulating strips 20 corresponding to the center of the window sash 4, and the lower guide rail outer frame 2 is divided into a second outer frame 11, a second inner frame 12 and a second middle frame 13 Three parts, the second outer frame 11 and the second inner frame 12 are symmetrically arranged on both sides of the lower rail outer frame 2, and the second middle frame 13 is arranged in the middle, and the inner sides of the second outer frame 11 and the second inner frame 12 are both A first lower guide rail 14 is provided, and second lower guide rails 15 corresponding to the first lower guide rail 14 are provided on both sides of the second middle frame 13, and a partition is provided between the first lower guide rail 14 and the second lower guide rail 15. The heat base 16 and the heat insulation base 16 are provided with an aluminum alloy guide rail profile 17, and the inner side of the second middle frame 13 is provided with a limit block 18, which is used to prevent the sash 4 from derailing and falling. When there are 3 or more layers of window sashes 4 between the outer frames 2, then add the second middle frame 13 of the excess number of window sashes 4, and a second heat insulation strip 20 is arranged between the two second middle frames 13 , so that the number of second heat insulation strips 20 is equal to the number of window sashes 4 .

As shown in Figure 5, a fourth heat insulation strip 22 is provided on the side frame 3 corresponding to the closed position of the sash 4, and the side frame 3 is divided into two parts: the side outer frame and the side inner frame. The traditional heat insulation strip 5 is set at the center of the side frame 3, but the sash 4 is set on both sides of the inside and outside of the side frame 3, so the inside and outside of the closure of the sash 4 and the side frame 3 are integrated aluminum alloy profiles, which increase heat conduction and cause heat loss , the utility model realizes that the inside and outside of the closed part of the window sash 4 and the side frame 3 are separated by the fourth heat insulation strip 22, which increases the heat insulation effect.

The utility model is not limited to the above-mentioned best implementation mode, anyone can draw other various forms of products under the enlightenment of the utility model, but no matter make any changes in its shape or structure, all have the same features as the application Or similar technical schemes all fall within the protection scope of the present utility model.

Claims (8)

1. A heat insulation structure of an aluminum alloy sliding door and window, comprising an upper guide rail outer frame and a lower guide rail outer frame oppositely arranged up and down, both sides of the upper guide rail outer frame and the lower guide rail outer frame are vertically provided with side frames, so A slidable window sash is provided between the outer frame of the upper guide rail and the outer frame of the lower guide rail. A second heat insulating strip corresponding to the center of the window sash is provided on the outer frame of the guide rail, and the number of the first heat insulating strip and the second heat insulating strip is at least two. 2. The heat insulation structure of aluminum alloy sliding doors and windows according to claim 1, characterized in that: the number of the first heat insulation strips is two, and the outer frame of the upper guide rail is divided into a first outer frame, a second outer frame, and a second outer frame. An inner frame and a first middle frame, the first outer frame and the first inner frame are symmetrically arranged on both sides of the upper rail outer frame, and the inner sides of the first outer frame and the first inner frame are both A first upper guide rail is provided, and second upper guide rails corresponding to the first upper guide rails are provided on both sides of the first middle frame. 3. The heat insulation structure of aluminum alloy sliding doors and windows according to claim 2, characterized in that: a third heat insulation strip is provided between the first upper guide rail and the second upper guide rail. 4. The heat insulation structure of aluminum alloy sliding doors and windows according to claim 2, characterized in that: a limiting block is provided on the inner side of the first middle frame. 5. The heat insulation structure of aluminum alloy sliding doors and windows according to claim 1, characterized in that: the number of the second heat insulation strips is two, and the outer frame of the lower guide rail is divided into a second outer frame, a second outer frame, and a second outer frame. The second inner frame and the second middle frame are three parts, the second outer frame and the second inner frame are symmetrically arranged on both sides of the lower guide rail outer frame, and the inner sides of the second outer frame and the second inner frame are both A first lower guide rail is provided, and second lower guide rails corresponding to the first lower guide rails are provided on both sides of the second middle frame. 6. The heat insulation structure of aluminum alloy sliding doors and windows according to claim 5, characterized in that: a heat insulation base is provided between the first lower guide rail and the second lower guide rail, and a heat insulation base is provided on the heat insulation base. There are aluminum alloy rail profiles. 7 . The heat insulation structure of aluminum alloy sliding doors and windows according to claim 5 , wherein a limiting block is provided on the inner side of the second middle frame. 7 . 8. The heat insulation structure of aluminum alloy sliding doors and windows according to claim 1, characterized in that: a fourth heat insulation strip is provided on the side frame corresponding to the closed position of the sash, and the side frame is divided into There are two parts, the side outer frame and the side inner frame.