CN220599611U - Waterproof sealing structure for doors and windows - Google Patents

Abstract

The utility model belongs to the technical field of door and window systems, and particularly relates to a waterproof sealing structure for doors and windows, which comprises a door and window sleeve and a door and window frame, wherein a first magnet is fixedly embedded in the door and window sleeve in an array mode, a dehumidifying structure for treating moisture in a sliding rail is arranged at one end of the bottom of the door and window frame, a dust removing structure for cleaning dust in the sliding rail is arranged at the other end of the bottom of the door and window frame, the dehumidifying structure comprises a first bottom cavity fixedly arranged at one end of the bottom of the door and window frame, a second bottom cavity fixedly arranged at the other end of the bottom of the door and window frame, inner piston bodies are respectively and slidably arranged in the first bottom cavity and the second bottom cavity, and a second magnet is fixedly arranged in the inner piston body. The utility model can effectively and automatically process the moisture and dust in the gaps of the door and window frames and the door and window sleeves, solves the problem of sanitation, optimizes the indoor environment, and is fully automatic in the whole process without being opened deliberately.

Description

Waterproof sealing structure for doors and windows

Technical Field

The utility model belongs to the technical field of door and window systems, and particularly relates to a waterproof sealing structure for doors and windows.

Background

The door and window is divided into enclosure components or separation components according to different positions of the door and window, different design requirements are provided with functions of heat preservation, heat insulation, sound insulation, water resistance, fire resistance and the like, new requirements are energy saving, heat lost by gaps of the door and window in cold areas accounts for about 25% of total heating heat consumption, the requirement of tightness of the door and window is an important content in energy saving design, and the door and the window are important components in a building enclosure structure system.

Problems of the prior art:

the existing sliding door and window has the following problems that although various waterproof sealing structures can effectively prevent moisture from entering a room and simultaneously play a role in heat insulation and sound insulation, moisture originally in a structural gap is not treated, so that the moisture in the gap is gathered for a long time and is unfavorable for volatilization, corrosion, biological colony growth and even peculiar smell can occur in the structural gap due to excessive moisture, and how to solve the problem is a sanitary problem which is difficult to treat at present; 2. dust remaining in structural gaps is also a relatively difficult hygiene problem.

Disclosure of Invention

The utility model aims to provide a waterproof sealing structure for doors and windows, which can effectively and automatically treat moisture and dust in gaps between a door and window frame and a door and window sleeve, solves the problem of sanitation, optimizes the indoor environment, and is fully automatic in the whole process without being opened deliberately.

The technical scheme adopted by the utility model is as follows:

the waterproof sealing structure for the door and window comprises a door and window sleeve and a door and window frame, wherein sliding rails are arranged at the upper end and the lower end of the inside of the door and window sleeve, the door and window frame is assembled in the door and window sleeve in a sliding manner through the sliding rails, a first magnet is fixedly embedded in the door and window sleeve in an array manner, a dehumidifying structure for treating moisture in the sliding rails is arranged at one end of the bottom of the door and window frame, and a dust removing structure for cleaning dust in the sliding rails is arranged at the other end of the bottom of the door and window frame;

the dehumidifying structure comprises a first bottom cavity fixedly arranged at one end of the bottom of the door and window frame, one end of the first bottom cavity is fixedly connected with a folding pipe, a filter element for absorbing water is arranged in the middle of the folding pipe in a filling mode, and one end, close to the first bottom cavity, of the folding pipe is connected with a branch pipe;

the dust removing structure comprises a second bottom cavity fixedly arranged at the other end of the bottom of the door and window frame, and one end of the second bottom cavity is fixedly connected with an end pipe extending to the outer wall of the door and window frame;

the inner piston bodies are slidably arranged in the first bottom cavity and the second bottom cavity, springs are connected to one end of the inner piston body and the inner walls of the first bottom cavity and the second bottom cavity, and a second magnet is fixedly arranged in the inner piston body.

The filter screen I is fixedly arranged in the tail ends of the folding pipes and the branch pipes, and unidirectional blocking flaps are arranged in the tail ends of the folding pipes and the branch pipes.

And a second filter screen is fixedly arranged in the tail end of the end pipe.

The balls are embedded in the inner array type rolling mode of the two side walls of the inner piston body.

The inside embedded fixed mounting of door and window frame has the door and window board.

The cross section shape and the area of the inner piston body are the same as those of the first bottom cavity, and the size and the structure of the first bottom cavity and the second bottom cavity are the same.

The utility model has the technical effects that:

when the door and window frame is pulled in one direction, the inner piston body and the first bottom cavity are moved relatively, so that suction force is generated in the first bottom cavity, air in the gap of the sliding rail is pumped in and dehumidified, the sucked air is reintroduced into the gap of the sliding rail after the iron suction Dan Er is separated from the iron suction stone to a certain distance, the moisture in the gap of the door and window frame and the door and window frame can be effectively treated through the process, the problem that the moisture in the gap is too heavy to be effectively dried is solved, the sanitation problem and the generation of peculiar smell gas can be effectively avoided, the indoor environment is optimized, the whole dehumidification process can be synchronously realized by utilizing the process of pulling the door and window frame, and the dehumidification operation is fully automatic and is not required to be started intentionally.

When the door and window frame is pulled in one direction, the inner piston body and the bottom cavity II relatively move, so that suction force is generated in the bottom cavity I and a certain amount of air is sucked, after the second magnet is separated from the first magnet to one end, the inner piston body can quickly push out the air in the bottom cavity II under the action of the spring in a pressed state, dust in a gap of a bottom guide rail of the door and window frame can be effectively blown out by means of the high-speed air flow, the problem that the dust gathers in the guide rail is solved, the sanitation problem that the dust in the guide rail is difficult to clean is solved, and the indoor sanitation condition is further optimized.

Drawings

Fig. 1 is a structural perspective view of a door and window body according to an embodiment of the present utility model;

fig. 2 is a partial cross-sectional view of a single window and door frame provided by an embodiment of the utility model;

FIG. 3 is a partially enlarged structural view at A in FIG. 2;

FIG. 4 is a partial enlarged block diagram at B in FIG. 2;

fig. 5 is a sectional structural view of an inner piston body provided in an embodiment of the present utility model.

In the drawings, the list of components represented by the various numbers is as follows:

1. a door and window cover; 2. door and window frames; 201. a first bottom cavity; 202. a bottom cavity II; 203. folding the pipe; 204. a filter element; 205. a branch pipe; 206. one-way baffle flaps; 207. a first filter screen; 208. an end pipe; 209. a second filter screen; 3. door and window panels; 4. a first magnet; 5. an inner piston body; 501. a second magnet; 502. a ball; 6. and (3) a spring.

Detailed Description

The present utility model will be specifically described with reference to examples below in order to make the objects and advantages of the present utility model more apparent. It should be understood that the following text is intended to describe only one or more specific embodiments of the utility model and does not limit the scope of the utility model strictly as claimed.

As shown in fig. 1-5, a waterproof sealing structure for doors and windows comprises a door and window sleeve 1 and a door and window frame 2, wherein sliding rails are arranged at the upper end and the lower end of the inside of the door and window sleeve 1, the door and window frame 2 is assembled in the inside of the door and window sleeve 1 in a sliding manner through the sliding rails, and a door and window plate 3 is fixedly arranged in the inside of the door and window frame 2 in an embedded manner.

Referring to fig. 1, a first magnet 4 is fixedly embedded in an inner array type of the door and window pocket 1.

Referring to fig. 2, one end of the bottom of the door and window frame 2 is provided with a dehumidifying structure for treating moisture in the sliding rail, and the other end of the bottom of the door and window frame 2 is provided with a dust removing structure for cleaning dust in the sliding rail; the dehumidification structure includes that the fixed end of seting up in the end of door and window frame 2 bottom chamber one 201, and dust removal structure is including the fixed end of seting up in the end of door and window frame 2 bottom chamber two 202, and interior piston body 5 is all installed to the inside of end chamber one 201 and end chamber two 202, and two interior piston body 5 one end all are connected with spring 6 with end chamber one 201 and end chamber two 202 one end inner wall, and interior piston body 5's inside fixed mounting has magnet two 501.

Referring to fig. 2 and 3, one end of the first bottom cavity 201 is fixedly connected with a folding pipe 203, a filter element 204 for absorbing moisture is filled in the middle of the folding pipe 203, one end of the folding pipe 203, which is close to the first bottom cavity 201, is connected with a branch pipe 205, the tail ends of the folding pipe 203 and the branch pipe 205 are internally and fixedly provided with a first filter screen 207, and the tail ends of the folding pipe 203 and the inside of the branch pipe 205 are respectively provided with a one-way baffle 206.

According to the above structure, when the door and window frame 2 is pulled in one direction, the inner piston body 5 at one end of the first bottom cavity 201 is attracted by the first magnet 4 and the second magnet 501, and moves relatively to the first bottom cavity 201, the inner piston body 5 at this time is continuously close to the other end of the first bottom cavity 201 and presses the spring 6, in this process, suction force is generated in the first bottom cavity 201, air in the sliding rail gap of the door and window frame 2 and the door and window sleeve 1 enters the first bottom cavity 201 through the folding pipe 203, moisture in the part of air can be absorbed by the first filter screen 207 to achieve the dehumidification effect, then the door and window frame 2 is continuously pulled, after the second magnet 501 and the first magnet 4 are separated to a distance, the suction force between the two is disappeared due to the overlarge distance, the inner piston body 5 at this moment can rapidly push out the air in the first bottom cavity 201 under the action of the spring 6, the pushed air can be reintroduced into the sliding rail gap through the branch pipe 205, the moisture in the door and window frame 2 can be effectively processed through the process, the problem of drying the door and window frame 1 can not be effectively solved, the problem of humidity in the whole door and window frame can not be automatically and synchronously realized, and the problem of humidity can not be effectively solved, and the problem of the indoor humidity and humidity can not be automatically and completely and synchronously solved.

Referring to fig. 2 and 4, an end pipe 208 extending to the outer wall of the door and window frame 2 is fixedly connected to one end of the second bottom chamber 202, and a second filter screen 209 is fixedly installed inside the end of the end pipe 208.

According to the above structure, when the door and window frame 2 is pulled in one direction, the inner piston body 5 at one end of the bottom cavity two 202 moves relatively to the bottom cavity two 202 due to the attraction between the first magnet 4 and the second magnet 501, the inner piston body 5 continuously approaches to the other end of the bottom cavity two 202 and presses the spring 6, in this process, external air slowly enters the bottom cavity two 202 through the end pipe 208, when the second magnet 501 is separated from the corresponding first magnet 4 to a distance of one end, the attraction between the two is lost due to the overlarge distance, the inner piston body 5 at this time can rapidly push out the air in the bottom cavity two 202 under the action of the spring 6 in a pressed state, and dust in a gap of a bottom guide rail of the door and window sleeve 1 can be effectively blown out by means of the high-speed airflow, so that the problem that dust gathers in the guide rail is solved, the problem that the dust in the guide rail is difficult to clean is solved, and the indoor sanitary condition is further optimized.

Referring to fig. 2 and 5, balls 502 are embedded in the inner array of the two side walls of the inner piston body 5, the cross-sectional shape and the area of the inner piston body 5 are the same as those of the first bottom cavity 201, and the size and the structure of the first bottom cavity 201 and the second bottom cavity 202 are the same.

According to the above structure, the balls 502 are provided to facilitate sliding of the inner piston body 5.

The working principle of the utility model is as follows: when the door and window frame 2 is pulled in one direction, the inner piston body 5 at one end of the first bottom cavity 201 moves relatively to the first bottom cavity 201 due to the attraction between the first magnet 4 and the second magnet 501, the inner piston body 5 at the moment is close to the other end of the first bottom cavity 201 and presses the spring 6, in the process, suction force is generated in the first bottom cavity 201, air in a sliding rail gap of the door and window frame 2 and the door and window frame sleeve 1 enters the first bottom cavity 201 through the folding pipe 203, moisture in the part of air is absorbed by the first filter screen 207 to achieve a dehumidification effect, the door and window frame 2 is pulled continuously, after the second magnet 501 and the first magnet 4 are separated to a distance of one end, the suction force between the second magnet 501 and the first magnet 4 disappears due to the fact that the distance is too large, the inner piston body 5 at the moment can push out the air in the first bottom cavity 201 rapidly under the action of the spring 6 in a pressed state, and the pushed air can be reintroduced into the sliding rail gap through the branch pipe 205;

when the door and window frame 2 is pulled in one direction, the inner piston body 5 at one end of the bottom cavity II 202 moves relatively to the bottom cavity II 202 due to the attraction between the first magnet 4 and the second magnet 501, the inner piston body 5 continuously approaches to the other end of the bottom cavity II 202 and presses the spring 6, in the process, external air slowly enters the bottom cavity II 202 through the end pipe 208, after the second magnet 501 is separated from the corresponding first magnet 4 to one end, the attraction between the second magnet 501 and the corresponding first magnet is eliminated due to the overlarge distance, and the inner piston body 5 at the moment can rapidly push out the air in the bottom cavity II 202 under the action of the spring 6 in a pressed state, so that dust in a guide rail gap at the bottom of the door and window frame 1 can be effectively blown out by means of the high-speed air flow.

The foregoing is merely a preferred embodiment of the present utility model and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present utility model, which are intended to be comprehended within the scope of the present utility model. Structures, devices and methods of operation not specifically described and illustrated herein, unless otherwise indicated and limited, are implemented according to conventional means in the art.

Claims (6)

1. The utility model provides a waterproof seal structure of door and window, includes door and window cover (1) and door and window frame (2), both ends all are provided with the slide rail about the inside of door and window cover (1), just door and window frame (2) are through the inside of slide rail slip equipment in door and window cover (1), its characterized in that: the door and window frame comprises a door and window frame body, wherein a first magnet (4) is fixedly embedded in the door and window frame body (1) in an array mode, a dehumidifying structure for treating moisture in a sliding rail is arranged at one end of the bottom of the door and window frame body (2), and a dust removing structure for cleaning dust in the sliding rail is arranged at the other end of the bottom of the door and window frame body (2);

the dehumidifying structure comprises a first bottom cavity (201) fixedly arranged at one end of the bottom of the door and window frame (2), one end of the first bottom cavity (201) is fixedly connected with a folding pipe (203), a filter element (204) for absorbing moisture is arranged in the middle of the folding pipe (203) in a filling mode, and one end, close to the first bottom cavity (201), of the folding pipe (203) is connected with a branch pipe (205);

the dust removing structure comprises a bottom cavity II (202) fixedly arranged at the other end of the bottom of the door and window frame (2), and one end of the bottom cavity II (202) is fixedly connected with an end pipe (208) extending to the outer wall of the door and window frame (2);

the inner piston bodies (5) are slidably arranged in the first bottom cavity (201) and the second bottom cavity (202), springs (6) are connected to one end of each inner piston body (5) and the inner walls of the first bottom cavity (201) and the second bottom cavity (202), and a second magnet (501) is fixedly arranged in each inner piston body (5).

2. The waterproof sealing structure for doors and windows according to claim 1, wherein: the filter screen I (207) is fixedly arranged in the tail ends of the folding pipe (203) and the branch pipe (205), and unidirectional blocking flaps (206) are arranged in the tail ends of the folding pipe (203) and the branch pipe (205).

3. The waterproof sealing structure for doors and windows according to claim 1, wherein: and a second filter screen (209) is fixedly arranged in the tail end of the end pipe (208).

4. The waterproof sealing structure for doors and windows according to claim 1, wherein: the balls (502) are embedded in the inner array type rolling mode of the two side walls of the inner piston body (5).

5. The waterproof sealing structure for doors and windows according to claim 1, wherein: the door and window frame (2) is internally embedded and fixedly provided with a door and window plate (3).

6. The waterproof sealing structure for doors and windows according to claim 1, wherein: the cross section shape and the area of the inner piston body (5) are the same as those of the first bottom cavity (201), and the size and the structure of the first bottom cavity (201) and the second bottom cavity (202) are the same.