CN215804105U - Energy-saving emission-reducing aluminum alloy door and window - Google Patents

Abstract

The utility model discloses an energy-saving emission-reducing aluminum alloy door and window, which comprises a door frame and two door leaves which are connected in the door frame in a sliding manner, wherein the door frame comprises an upper rail, a lower rail and two side frames, and a first heat-insulating silica gel strip which is vertically arranged is fixedly arranged on the side of each side frame, which faces to the door leaf; the door leaf comprises a leaf frame and heat insulation glass arranged in the leaf frame; and a clamping groove in snap fit with the first heat insulation silica gel strip is arranged on the end face of the fan frame along the sliding direction. The door leaf is made of heat insulation glass, so that heat insulation between the indoor space and the outdoor space is facilitated, and energy conservation and emission reduction of indoor heating or air conditioning are facilitated; in addition, through set up first thermal-insulated silica gel strip between door frame and door leaf, reduce the gap between door frame and the door leaf, further improve thermal-insulated effect, and can not have the noise when making the door leaf close, also can not be blown in addition and produce wind and cry.

Description

Energy-saving emission-reducing aluminum alloy door and window

Technical Field

The utility model relates to the technical field of aluminum alloy doors and windows, in particular to an energy-saving and emission-reducing aluminum alloy door and window.

Background

The aluminum alloy door and window is a door and window with a frame and sash structure made of aluminum alloy building profiles and is widely applied to the field of building engineering; the patent with the publication number of CN209293632U discloses an aluminum alloy door and window, including door frame sliding connection at the inside door leaf of door frame, the door frame includes track and lower track, the equal fixedly connected with frame in orbital bottom both ends, the bottom of frame and orbital both ends fixed connection down, at least a T-shaped groove has been seted up to orbital upper surface down, the door leaf includes protecting frame and glass, glass fixed mounting is in the inside of protecting frame, the equal fixedly connected with L shape connecting block in the bottom both ends of protecting frame, L shape connecting block is located the inside in T-shaped groove, it is connected with first pivot to rotate on the L shape connecting block, the equal fixedly connected with first gyro wheel in both ends of first pivot, the one end fixedly connected with that protecting frame was kept away from to L shape connecting block pushes away the shovel, it is convex to push away the shovel. The dust and the garbage in the lower rail can be pushed into the collecting frame, so that the inside of the lower rail can be cleaned conveniently.

However, the existing aluminum alloy doors and windows have some disadvantages, such as a large gap between the door frame and the door leaf even after the door frame and the door leaf are closed, and a large gap is also formed between the two door leaves, so that the aluminum alloy doors and windows cannot have a good heat insulation effect, the indoor and outdoor heat transfer is fast, and the aluminum alloy doors and windows are not convenient for energy conservation. In addition, in windy weather, a gap between the door frame and the door leaf can generate wind sound noise to influence use; in addition, when the door is closed, the door collides with the door frame, thereby generating noise.

SUMMERY OF THE UTILITY MODEL

In view of the above, the utility model provides an energy-saving and emission-reducing aluminum alloy door and window, which can solve at least one of the above problems to a certain extent.

The technical scheme of the utility model is realized as follows:

an energy-saving emission-reducing aluminum alloy door and window comprises a door frame and two door leaves which are connected in the door frame in a sliding mode, wherein the door frame comprises an upper rail, a lower rail and two side frames, and a first heat-insulating silica gel strip which is vertically arranged is fixedly arranged on the side, facing the door leaves, of each side frame; the door leaf comprises a leaf frame and heat insulation glass arranged in the leaf frame; and a clamping groove in snap fit with the first heat insulation silica gel strip is arranged on the end face of the fan frame along the sliding direction.

As a further alternative of the energy-saving and emission-reducing aluminum alloy door and window, the side frame extends two L-shaped clamping plates towards the side face of the door leaf, the edges of the L-shaped clamping plates are bent to form clamping edge parts, and the clamping edge parts on the two L-shaped clamping plates are arranged oppositely; the first heat insulation silica gel strip comprises a base station and a clamping station part fixedly arranged on one end face of the base station; the clamping platform part is wider than the base platform; the base station is arranged between the two L-shaped clamping plates; two side surfaces of the base station are provided with grooves, and the clamping edge parts on the two L-shaped clamping plates are clamped into the two grooves respectively.

As a further alternative of the energy-saving emission-reducing aluminum alloy door and window, two wing plates which are arranged oppositely extend out of the end surface of the sash frame along the sliding direction, and the clamping groove is formed between the two wing plates; and clamping parts are arranged on the inner side surfaces of the two wing plates, and the clamping table part of the first heat insulation silica gel strip is in clamping fit with the clamping parts.

As a further alternative of the energy-saving and emission-reducing aluminum alloy door and window, the clamping table part is provided with a wedge surface on the end surface facing the groove.

As a further alternative of the energy-saving and emission-reducing aluminum alloy door and window, vertically arranged second heat-insulating silica gel strips are arranged on the opposite side surfaces of the two sash frames; when two the fan frame respectively with two when the side frame buckle is connected, two the mutual butt of second heat-insulating silica gel strip.

As a further alternative of the energy-saving and emission-reducing aluminum alloy door and window, a T-shaped rib is fixedly arranged on the side surface of the sash frame provided with the second heat-insulating silica gel strip, and a T-shaped groove used for clamping the T-shaped rib is arranged on the second heat-insulating silica gel strip; the end face of one second heat insulation silica gel strip along the sliding direction is abutted with the end face of the other second heat insulation silica gel strip along the sliding direction.

As a further alternative of the energy-saving and emission-reducing aluminum alloy door and window, two convex edges are formed on the end surface of the second heat-insulating silica gel strip along the sliding direction, and the two convex edges are staggered with each other and abut against the end surface of the other second heat-insulating silica gel strip along the sliding direction.

The utility model has the following beneficial effects: the door leaf is made of heat insulation glass, so that heat insulation between the indoor space and the outdoor space is facilitated, and energy conservation and emission reduction of indoor heating or air conditioning are facilitated; in addition, through set up first thermal-insulated silica gel strip between door frame and door leaf, reduce the gap between door frame and the door leaf, further improve thermal-insulated effect, and can not have the noise when making the door leaf close, also can not be blown in addition and produce wind and cry.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an energy-saving emission-reducing aluminum alloy door and window of the utility model;

FIG. 2 is a cross-sectional view A-A of FIG. 1;

FIG. 3 is a cross-sectional view B-B of FIG. 1;

FIG. 4 is a schematic cross-sectional view of the first insulating silicone strip;

fig. 5 is a schematic cross-sectional view of the second insulating silicone strip.

In the figure: 1. a door frame; 11. an upper rail; 12. a lower rail; 13. a side frame; 131. an L-shaped clamping plate; 132. a rib portion; 2. a door leaf; 21. a fan frame; 211. a wing plate; 212. a clamping part; 213. t-shaped ribs; 22. heat insulating glass; 3. a first heat insulation silica gel strip; 31. a base station; 311. a groove; 32. a clamping table part; 321. a tapered wedge surface; 4. a second heat insulation silica gel strip; 41. a T-shaped slot; 42. and (7) a rib.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "vertical", "horizontal", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "above," and "over" a second feature may mean that the first feature is directly above or obliquely above the second feature, or that only the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

Referring to fig. 1, 2 and 4, an energy-saving and emission-reducing aluminum alloy door and window is shown, and comprises a door frame 1 and two door leaves 2 slidably connected in the door frame 1, wherein the door frame 1 comprises an upper rail 11, a lower rail 12 and two side frames 13, and a first heat-insulating silica gel strip 3 vertically arranged is fixedly arranged on the side, facing the door leaves 2, of each side frame 13; the door leaf 2 comprises a leaf frame 21 and heat insulation glass 22 arranged in the leaf frame 21; a clamping groove (not marked in the figure) in snap fit with the first heat insulation silica gel strip 3 is arranged on the end face of the fan frame 21 along the sliding direction.

Therefore, the door leaf 2 adopts the heat insulation glass 22, which is beneficial to heat insulation between the indoor and the outdoor and is convenient for energy conservation and emission reduction of indoor heating or air conditioning; in addition, through set up first thermal-insulated silica gel strip 3 between door frame 1 and door leaf 2, reduce the gap between door frame 1 and the door leaf 2, further improve thermal-insulated effect, and can make the door leaf 2 not have the noise when closing, also can not be blown in addition by wind and produce wind and cry. It should be noted that the fan frame 21 is used for abutting against one end face of the door frame 1 and is provided with the clamping groove, and when the clamping groove is matched with the first heat insulation silica gel strip 3 in a buckling mode, the aluminum alloy door window is changed into a closed state.

In the above embodiment, referring to fig. 2 and 4, the side frame 13 extends two L-shaped fastening boards 131 to the side surface of the door leaf 2, the edge of the L-shaped fastening board 131 is bent to form a rib part 132, and the rib parts 132 on the two L-shaped fastening boards 131 are arranged oppositely; the first heat insulation silica gel strip 3 comprises a base table 31 and a clamping table part 32 fixedly arranged on one end face of the base table 31; the table portion 32 is wider than the base 31; the base 31 is arranged between the two L-shaped clamping plates 131; two side surfaces of the base 31 are provided with grooves 311, and the rib parts 132 of the two L-shaped clamping plates 131 are respectively clamped in the two grooves 311. Two wing plates 211 which are arranged oppositely extend out of the end face of the fan frame along the sliding direction, and the clamping groove is formed between the two wing plates 211; the inner side surfaces of the two wing plates 211 are respectively provided with a clamping part 212, and the clamping table part 32 of the first heat insulation silica gel strip 3 is in clamping fit with the clamping part 212. Because the first heat-insulating silica gel strip 3 has elasticity, when a pulling force is applied to the fan frame 21, the clamping groove can be separated from the clamping table part 32, so that the door leaf 2 is opened; in addition, referring to fig. 4, in order to facilitate insertion of the card holder portion 32 into the card slot, an end surface of the card holder portion 32 facing the recess 311 is provided with a tapered wedge surface 321; thus, the card holder portion 32 is pointed at one side and is easily inserted into the card slot.

In some embodiments, even when the existing al-alloy door/window is closed, there is a large gap between the two door leaves 2, and the gap is easily penetrated by wind, which results in an improvement in the heat exchange efficiency between the inside and the outside of the room; referring to fig. 3 and 5, vertically arranged second heat insulation silica gel strips 4 are arranged on the opposite side surfaces of the two fan frames 21; when two fan frame 21 respectively with two side frame 13 buckle is connected, two the mutual butt of second thermal-insulated silica gel strip 4. In other words, through two the mutual butt of second thermal-insulated silica gel strip 4 for the clearance between two fan frames 21 is effectively dwindled, avoids wind to pass, thereby indoor energy consumption became high time.

In the above embodiment, the side of the fan frame 21 where the second heat insulation silica gel strip 4 is disposed is fixedly provided with a T-shaped rib 213, and the second heat insulation silica gel strip 4 is provided with a T-shaped groove 41 for engaging with the T-shaped rib 213; the end surface of one second heat insulation silica gel strip 4 along the sliding direction is abutted with the end surface of the other second heat insulation silica gel strip 4 along the sliding direction. In addition, two on the terminal surface of second thermal-insulated silica gel strip 4 along the sliding direction all be formed with bead 42, two beads 42 stagger each other and butt on another second thermal-insulated silica gel strip 4 along the terminal surface of sliding direction. Thus, the second heat insulation silica gel strip 4 is fixed on the T-shaped rib 213 of the fan frame 21 through the T-shaped groove 41 thereon; in addition, the rib 42 can make the clearance length of side between two thermal-insulated silica gel strips 4 of second, and wind is more difficult to pass, effectively improves this aluminum alloy door and window's thermal-insulated effect.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (7)

1. An energy-saving emission-reducing aluminum alloy door and window comprises a door frame and two door leaves which are connected in the door frame in a sliding manner, wherein the door frame comprises an upper rail, a lower rail and two side frames; the door leaf comprises a leaf frame and heat insulation glass arranged in the leaf frame; and a clamping groove in snap fit with the first heat insulation silica gel strip is arranged on the end face of the fan frame along the sliding direction.

2. The energy-saving emission-reducing aluminum alloy door and window as claimed in claim 1, wherein the side frames extend towards the side faces of the door leaves to form two L-shaped clamping plates, the edges of the L-shaped clamping plates are bent to form clamping edge portions, and the clamping edge portions of the two L-shaped clamping plates are arranged oppositely; the first heat insulation silica gel strip comprises a base station and a clamping station part fixedly arranged on one end face of the base station; the clamping platform part is wider than the base platform; the base station is arranged between the two L-shaped clamping plates; two side surfaces of the base station are provided with grooves, and the clamping edge parts on the two L-shaped clamping plates are clamped into the two grooves respectively.

3. The energy-saving emission-reducing aluminum alloy door and window as claimed in claim 2, wherein two wing plates arranged oppositely extend from the end surface of the sash frame along the sliding direction, and the clamping groove is formed between the two wing plates; and clamping parts are arranged on the inner side surfaces of the two wing plates, and the clamping table part of the first heat insulation silica gel strip is in clamping fit with the clamping parts.

4. The energy-saving emission-reducing aluminum alloy door and window as claimed in claim 3, wherein the end surface of the clamping table portion facing the groove is provided with a wedge surface.

5. The energy-saving emission-reducing aluminum alloy door and window as claimed in claim 1, wherein vertically arranged second heat-insulating silica gel strips are arranged on the opposite side surfaces of the two sash frames; when two the fan frame respectively with two when the side frame buckle is connected, two the mutual butt of second heat-insulating silica gel strip.

6. The energy-saving emission-reducing aluminum alloy door and window as claimed in claim 5, wherein the side of the sash frame provided with the second heat-insulating silica gel strip is fixedly provided with a T-shaped rib, and the second heat-insulating silica gel strip is provided with a T-shaped groove for clamping the T-shaped rib; the end face of one second heat insulation silica gel strip along the sliding direction is abutted with the end face of the other second heat insulation silica gel strip along the sliding direction.

7. The energy-saving emission-reducing aluminum alloy door and window as claimed in claim 6, wherein two ribs are formed on the end surfaces of the two second heat-insulating silica gel strips along the sliding direction, and the two ribs are staggered with each other and abut against the end surface of the other second heat-insulating silica gel strip along the sliding direction.

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