CN221856505U - Aluminum alloy door and window with buffer mechanism - Google Patents

Abstract

The utility model relates to the technical field of aluminum alloy doors and windows, and particularly discloses an aluminum alloy door and window with a buffer mechanism, which comprises two mounting frames, wherein two groups of sliding rails are mounted between the two mounting frames, two aluminum alloy door and window bodies are clamped in the two groups of sliding rails, the aluminum alloy door and window bodies located on the right side are mounted in a way of rotating one hundred eighty degrees relative to the aluminum alloy door and window bodies located on the left side, the buffer assembly is provided with two groups of buffer assemblies located on the right side and is mounted in a way of rotating one hundred eighty degrees relative to the left side, the buffer assembly is used for buffering the aluminum alloy door and window bodies in the closing process, the limiting assembly is provided with two groups of limiting assemblies located on the right side and is mounted in a way of rotating one hundred eighty degrees relative to the left limiting assembly, and the limiting assemblies are mounted on two sides of the two aluminum alloy door and window bodies and are used for limiting the positions of the aluminum alloy door and window bodies after being closed.

Description

Aluminum alloy door and window with buffer mechanism

Technical Field

The utility model relates to the technical field of aluminum alloy doors and windows, in particular to an aluminum alloy door and window with a buffer mechanism.

Background Art

Aluminum alloy doors and windows refer to doors and windows made of aluminum alloy extruded profiles as frames, stiles, and sashes. Aluminum alloy doors and windows include doors and windows with aluminum alloy as the base material of the load-bearing rods (rods that bear and transmit deadweight and loads) and doors and windows composited with wood and plastic, referred to as aluminum-wood composite doors and windows and aluminum-plastic composite doors and windows. With the continuous improvement of people's living standards, the types of doors and windows and their derivative products are increasing, and the grades are gradually rising, such as thermal insulation aluminum alloy doors and windows, wood-aluminum composite doors and windows, aluminum-wood composite doors and windows, solid wood doors and windows, solar energy houses, glass curtain walls, wooden curtain walls, etc.

At present, most aluminum alloy doors and windows on the market are opened or closed horizontally using a guide rail structure. Most aluminum alloy doors and windows are often not equipped with an effective buffer structure when opening or closing. At this time, when the doors and windows are opened and closed too quickly, the doors and windows may cause a heavy collision with the wall. If the collision is more serious, it may cause damage to the doors and windows.

For this reason, we propose an aluminum alloy door and window with a buffer mechanism.

Summary of the invention

The purpose of the utility model is to provide an aluminum alloy door and window with a buffer mechanism to solve the problems raised in the above background technology.

To achieve the above-mentioned purpose, the utility model provides the following technical solutions: an aluminum alloy door and window with a buffer mechanism, comprising a mounting frame, the mounting frame having two, two sets of slide rails are installed between the two mounting frames, two aluminum alloy door and window bodies are clamped inside the two sets of slide rails, the aluminum alloy door and window body located on the right side is installed by rotating 180 degrees with respect to the aluminum alloy door and window body located on the left side, a buffer assembly, the buffer assembly having two groups, the buffer assembly located on the right side is installed by rotating 180 degrees with respect to the buffer assembly located on the left side, the buffer assembly is used for buffering the aluminum alloy door and window body during closing, a limit assembly, the limit assembly having two groups, the limit assembly located on the right side is installed by rotating 180 degrees with respect to the limit assembly located on the left side, the limit assembly is installed on both sides of the two aluminum alloy door and window bodies, and the limit assembly is used for limiting the position of the aluminum alloy door and window body after closing.

Preferably, the buffer assembly located on the left side includes mounting grooves, which are respectively opened on the right side surfaces of the mounting frame, and two symmetrical moving blocks are placed inside the mounting grooves. A limiting groove is opened on the bottom surface of each moving block, and limiting rods are clamped inside the two limiting grooves, and the sides of the two limiting rods that are away from each other are respectively fixedly connected to the top wall and the bottom wall of the mounting groove; a trapezoidal block is fixedly connected to the left side surface of the aluminum alloy door and window body located on the left side, and the inclined surface of the trapezoidal block is in contact with the moving block.

Preferably, a blocking plate is fixedly connected between the mutually approaching sides of the two limit rods.

Preferably, the limiting groove is provided with a smooth inner wall, and the limiting rod is provided with a smooth outer wall.

Preferably, the limit assembly located on the left side includes a card slot, and there are two card slots, both of which are opened on the upper surface of the trapezoidal block, and the inside of the two card slots are clamped with card blocks, and second springs are fixedly connected between the two card blocks and the bottom walls of the card slots, and spherical blocks are fixedly connected to the front sides of the two card blocks, and the right arms of the two mounting frames are provided with spherical slots.

Preferably, the adjacent sides of the two mounting frames are fixedly connected with dust-proof plates, and the opening positions of the dust-proof plates are adapted to the size of the trapezoidal blocks.

Preferably, the interior of the slide rail is provided with a smooth inner wall.

Preferably, the two aluminum alloy door and window bodies are both double-layer structures.

The utility model has at least the following beneficial effects:

1. When the aluminum alloy door and window body needs to be closed, first pull the aluminum alloy door and window body on the left to move to the left. By setting the clamping connection between the slide rail and the aluminum alloy door and window body, the aluminum alloy door and window body can move stably to the left. When the aluminum alloy door and window body on the left moves too fast to the left, the inclined surface of the trapezoidal block will contact the outer surfaces of the two moving blocks. At this time, the two moving blocks are squeezed by the inclined surfaces of the trapezoidal blocks. At this time, the clamping cooperation of the set limit rod and the limit groove can make the two moving blocks move stably in the direction away from each other. At this time, the influence of the first spring force will provide a certain resistance to the movement of the moving blocks, thereby further achieving the effect of providing a buffer for the rapid closing of the aluminum alloy door and window body. When closing the aluminum alloy door and window body on the right, similarly, you only need to pull the aluminum alloy door and window body on the right to the right.

By setting up a buffer component, the problem that most aluminum alloy doors and windows on the market are often not equipped with an effective buffer structure when opening or closing is solved. At this time, when the doors and windows are opened and closed too quickly, the doors and windows may cause a heavy collision with the wall. When the collision is more serious, it may cause damage to the doors and windows.

2. When the aluminum alloy door and window body on the left is in the process of closing, the spherical block will first contact the right side of the mounting frame on the left. Because the spherical block is a spherical structure, the spherical block can enter the interior of the slot through the coordination of the spherical block, the card block and the card slot. When the aluminum alloy door and window body on the left is completely closed, the spherical block is affected by the elastic force of the second spring, which will cause the spherical block to be stuck in the spherical slot and will not be stuck. When the aluminum alloy door and window body on the left needs to be opened, just pull it to the right with a little force. The same applies to the opening or closing of the aluminum alloy door and window body on the right.

By setting the limit assembly, the closed position of the aluminum alloy door and window body can be limited, so that the aluminum alloy door and window body can be more stable when in the closed state.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a schematic diagram of the overall structure of the utility model;

Fig. 2 is a schematic diagram of the front cross-sectional structure of the utility model;

FIG3 is a schematic diagram of a side cross-sectional structure of the utility model;

FIG4 is an enlarged schematic diagram of the structure at A in FIG3 of the present utility model;

FIG5 is a schematic diagram of the cross-sectional structure of the utility model from top view.

In the figure: 1. Buffer assembly; 2. Limit assembly; 3. Mounting bracket; 4. Slide rail; 5. Aluminum alloy door and window body; 6. Mounting groove; 7. Moving block; 8. Limit rod; 9. First spring; 10. Trapezoidal block; 11. Slot; 12. Second spring; 13. Slot block; 14. Spherical block; 15. Spherical groove; 16. Dust shield; 17. Blocking plate; 18. Limit groove.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the utility model to clearly and completely describe the technical solutions in the embodiments of the utility model. Obviously, the described embodiments are only part of the embodiments of the utility model, not all of the embodiments. Based on the embodiments in the utility model, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the utility model.

Please refer to Figures 1 to 5. The utility model provides a technical solution:

Embodiment 1, an aluminum alloy door and window with a buffer mechanism, includes a mounting frame 3, wherein the mounting frames 3 are provided with two, two sets of slide rails 4 are installed between the two mounting frames 3, two aluminum alloy door and window bodies 5 are clamped inside the two sets of slide rails 4, and the two aluminum alloy door and window bodies 5 are both double-layer structures, which can make the sound insulation effect of the aluminum alloy door and window bodies 5 better. The interior of the slide rail 4 is provided with a smooth inner wall, which can make the aluminum alloy door and window body 5 smoother when moving left and right. The aluminum alloy door and window body 5 on the right is installed by rotating 180 degrees with respect to the aluminum alloy door and window body 5 on the left. The buffer component 1 has two groups. The buffer component 1 on the right is installed by rotating 180 degrees with respect to the buffer component 1 on the left. The buffer component 1 is used for buffering the aluminum alloy door and window body 5 during the closing process. The limit component 2 has two groups. The limit component 2 on the right is installed by rotating 180 degrees with respect to the limit component 2 on the left. The limit component 2 is installed on both sides of the two aluminum alloy door and window bodies 5. The limit component 2 is used to limit the position of the aluminum alloy door and window body 5 after closing.

The buffer assembly 1 located on the left side includes a mounting groove 6, which is respectively opened on the right side of the mounting frame 3. Two symmetrical moving blocks 7 are placed inside the mounting groove 6. A limiting groove 18 is opened on the bottom surface of each moving block 7. The two limiting grooves 18 are both clamped with limiting rods 8. The sides of the two limiting rods 8 that are away from each other are respectively fixedly connected to the top wall and the bottom wall of the mounting groove 6. A trapezoidal block 10 is fixedly connected to the left side of the aluminum alloy door and window body 5 on the left side, and the inclined surface of the trapezoidal block 10 is in contact with the moving block 7.

A blocking plate 17 is fixedly connected between the surfaces of the two limiting rods 8 that are close to each other, which can limit the position of the limiting groove 18 and prevent the moving block 7 from falling off the outer surface of the limiting rod 8.

The limiting groove 18 is provided with a smooth inner wall, and the limiting rod 8 is provided with a smooth outer wall, so that the moving block 7 can be smoother when moving up and down.

When the aluminum alloy door and window body 5 needs to be closed, first pull the aluminum alloy door and window body 5 on the left to move left. By setting the clamping connection between the slide rail 4 and the aluminum alloy door and window body 5, the aluminum alloy door and window body 5 can move stably to the left. When the aluminum alloy door and window body 5 on the left moves too fast to the left, the inclined surface of the trapezoidal block 10 will contact the outer surfaces of the two moving blocks 7. At this time, the two moving blocks 7 are squeezed by the inclined surfaces of the trapezoidal blocks 10. At this time, the clamping cooperation of the set limit rod 8 and the limit groove 18 will make the two moving blocks 7 move stably in the direction away from each other. At this time, the influence of the elastic force of the first spring 9 will provide a certain resistance to the movement of the moving block 7, further achieving the effect of providing a buffer for the rapid closing of the aluminum alloy door and window body 5. When closing the aluminum alloy door and window body 5 on the right, similarly, you only need to pull the aluminum alloy door and window body 5 on the right to the right.

By providing the buffer component 1, the problem that most aluminum alloy doors and windows on the market are often not provided with an effective buffer structure when opening or closing is solved. At this time, when the doors and windows are opened and closed too quickly, the doors and windows may cause a heavy collision with the wall. When the collision is more serious, it may cause damage to the doors and windows.

Embodiment 2, the limit assembly 2 located on the left side, includes a card slot 11, and there are two card slots 11. The two card slots 11 are both opened on the upper surface of the trapezoidal block 10, and the inside of the two card slots 11 is clamped with a card block 13, and a second spring 12 is fixedly connected between the two card blocks 13 and the bottom wall of the card slot 11, and the front of the two card blocks 13 is fixedly connected with a spherical block 14, and the right arms of the two mounting frames 3 are provided with a spherical slot 15.

The adjacent sides of the two mounting frames 3 are fixedly connected with dust-proof plates 16, and the opening positions of the dust-proof plates 16 are adapted to the size of the trapezoidal blocks 10. The dust-proof plates 16 can play a certain role in dust-proofing and can extend the service life of the entire device to a certain extent.

When the aluminum alloy door and window body 5 on the left is in the process of closing, the spherical block 14 will first contact the right side surface of the left mounting frame 3. Since the spherical block 14 is a spherical structure, the spherical block 14 can enter the interior of the slot 11 through the coordinated setting of the spherical block 14, the clamping block 13 and the slot 11. When the aluminum alloy door and window body 5 on the left is completely closed, the spherical block 14 is affected by the elastic force of the second spring 12, which will cause the spherical block 14 to be stuck in the interior of the spherical slot 15 and will not be stuck. When the aluminum alloy door and window body 5 on the left needs to be opened, it only needs to be pulled to the right with a little force. The same is true for opening or closing the aluminum alloy door and window body 5 on the right.

By setting the limiting component 2, the closed position of the aluminum alloy door and window body 5 can be limited, so that the aluminum alloy door and window body 5 can be more stable when in the closed state.

It should be noted that, in this article, relational terms such as first and second, etc. are only used to distinguish one entity or operation from another entity or operation, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Moreover, the terms "include", "comprise" or any other variants thereof are intended to cover non-exclusive inclusion, so that a process, method, article or device including a series of elements includes not only those elements, but also other elements not explicitly listed, or also includes elements inherent to such process, method, article or device.

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

Claims (8)

1. The utility model provides an aluminum alloy door and window with buffer gear, includes mounting bracket (3), mounting bracket (3) have two, two install two sets of slide rail (4) between mounting bracket (3), the inside joint of two sets of slide rail (4) has two aluminum alloy door and window bodies (5), is located the right side aluminum alloy door and window body (5) are about being located rotatory one hundred eighty degrees installations of left side aluminum alloy door and window body (5), its characterized in that:

The buffer assemblies (1), wherein the buffer assemblies (1) are provided with two groups, the buffer assemblies (1) positioned on the right side are installed in a way of rotating one hundred eighty degrees relative to the buffer assemblies (1) positioned on the left side, and the buffer assemblies (1) are used for buffering the aluminum alloy door and window body (5) in the closing process;

Spacing subassembly (2), spacing subassembly (2) have two sets of, are located the right side spacing subassembly (2) are rotatory one hundred eighty degrees installations about being located left side spacing subassembly (2), spacing subassembly (2) are installed in the both sides of two aluminum alloy door and window bodies (5), spacing subassembly (2) are used for carrying out spacing use to the position behind aluminum alloy door and window body (5) closing.

2. An aluminum alloy door and window with a buffer mechanism according to claim 1, wherein: the buffer assembly (1) located on the left side comprises a mounting groove (6), the right side face at mounting bracket (3) is offered respectively to mounting groove (6), two symmetrical movable blocks (7) have all been placed to the inside of mounting groove (6), every spacing groove (18) have all been offered to the bottom surface of movable block (7), two the inside of spacing groove (18) has gag lever post (8), two the one side that gag lever post (8) kept away from each other is respectively with roof and diapire fixed connection of mounting groove (6), is located the left side fixedly connected with trapezoidal piece (10) of aluminum alloy door and window body (5), the inclined plane and the movable block (7) of trapezoidal piece (10) contact.

3. An aluminum alloy door and window with a buffer mechanism according to claim 2, wherein: a blocking plate (17) is fixedly connected between the two sides of the limiting rods (8) which are close to each other.

4. An aluminum alloy door and window with a buffer mechanism according to claim 2, wherein: the limiting groove (18) is provided with a smooth inner wall, and the limiting rod (8) is provided with a smooth outer wall.

5. An aluminum alloy door and window with a buffer mechanism according to claim 2, wherein: the left side limiting component (2) is located, the limiting component comprises clamping grooves (11), the clamping grooves (11) are two, the upper surfaces of the trapezoid blocks (10) are all arranged on the clamping grooves (11), clamping blocks (13) are all clamped in the clamping grooves (11), second springs (12) are fixedly connected between the clamping blocks (13) and the bottom wall of the clamping grooves (11), spherical blocks (14) are fixedly connected to the front surfaces of the clamping blocks (13), and spherical grooves (15) are formed in the right arms of the mounting frame (3).

6. An aluminum alloy door and window with a buffer mechanism according to claim 2, wherein: two the mounting bracket (3) are all fixedly connected with dust separation board (16) in the one side that is close to, the trompil position of dust separation board (16) and the big or small looks adaptation of trapezoidal piece (10).

7. An aluminum alloy door and window with a buffer mechanism according to claim 1, wherein: the sliding rail (4) is internally provided with a smooth inner wall.

8. An aluminum alloy door and window with a buffer mechanism according to claim 1, wherein: the two aluminum alloy door and window bodies (5) are of double-layer structures.