CN220601708U - Energy-saving building top ventilation structure - Google Patents

Abstract

The utility model discloses an energy-saving building top ventilation structure, which relates to the technical field of buildings and comprises a wall body and a cleaning component, wherein a baffle is arranged at the upper end of the wall body, the cleaning component for cleaning a filter screen is arranged at one side of the wall body, the cleaning component comprises a ventilation opening, a clamping groove, the filter screen, a bearing frame, a motor, a screw rod and a cleaning brush, the clamping groove is formed in the inner side of the ventilation opening close to the edge, the filter screen is arranged at the middle end of the inner side of the ventilation opening, the bearing frame is arranged at the right side of the ventilation opening, the motor is connected with the lower end of the bearing frame, and the screw rod is connected with the upper end of the motor. This energy-conserving building top ventilation structure through clean subassembly's setting, can be when energy-conserving building top ventilation structure uses, utilizes the clean subassembly of wall body one side to avoid equipment to install and cause filter piece difficult dismantlement abluent problem at the building top, utilizes vent internally mounted's filter screen to filter the inside dust of ventilation in-process air.

Description

Energy-saving building top ventilation structure

Technical Field

The utility model relates to the technical field of buildings, in particular to an energy-saving building top ventilation structure.

Background

In the building, a ventilation structure is usually arranged at the top of the building, so that ventilation can be conveniently carried out indoors and outdoors, the ventilation is realized by means of ventilation dilution or ventilation elimination and the like, the propagation and harm of air pollutants are controlled, the indoor and outdoor air environment quality assurance is realized, and in order to enable the building to better meet the use requirements of users, the ventilation structure is needed.

The utility model of the application number CN202020959872.1 discloses an energy-saving building top ventilation structure, which realizes the purposes of saving energy and improving the ventilation effect by matching the wall body, the buffer mechanism, the baffle plate, the solar cell panel, the connecting rod, the fixing frame, the placement frame, the servo motor, the connecting block, the rotating rod, the fan, the storage battery and the solar energy converter, improves the practicability and usability of the device, and enhances the use experience of a user, thereby better meeting the use requirement of the user, but being similar to the comparison document of the application, and when the ventilation structure is used, the device is integrally installed at the top of the building, so that the too high filter piece is not easy to detach and clean, and the use convenience of the energy-saving building top ventilation structure is reduced.

Accordingly, in view of the above, research and improvement have been made on the conventional structure and the conventional drawbacks, and an energy-saving roof ventilation structure for buildings has been proposed.

Disclosure of Invention

The present utility model is directed to providing an energy-saving building roof ventilation structure to solve the above-mentioned problems set forth in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an energy-conserving building top ventilation structure, includes wall body and clean subassembly, the wall body upper end is provided with the baffle for the filter screen is clear clean subassembly sets up in wall body one side, and clean subassembly includes vent, joint groove, filter screen, accepts frame, motor, lead screw and cleaning brush, the inboard joint groove of being close to the edge of vent has been seted up, and the inside middle-end of vent is provided with the filter screen to the frame is accepted in the vent right side is installed, accepts the frame lower extreme simultaneously and is connected with the motor, the motor upper end is connected with the lead screw, and installs cleaning brush in the lead screw outside, the baffle upper end is provided with the energy-conserving subassembly that is used for energy-conserving ventilation.

Further, the clamping groove is connected with the cleaning brush in an embedded mode, and the inner size of the clamping groove is matched with the outer size of the cleaning brush.

Furthermore, the cleaning brush is connected with the vent in an embedded mode, and the cleaning brush is connected with the vent in a sliding mode through the screw rod.

Further, the screw rod is connected with the bearing frame in an embedded mode, and the screw rod is connected with the bearing frame in a rotating mode through the motor.

Further, the energy-saving assembly comprises a photovoltaic panel, a solar energy converter and a storage battery, wherein the solar energy converter is arranged at the lower end of the photovoltaic panel, and the storage battery is arranged at the lower end of the solar energy converter.

Further, the energy-saving assembly further comprises a servo motor, a bevel gear set and a fan, wherein the servo motor is additionally arranged at the lower end of the storage battery, the bevel gear set is connected to the lower end of the servo motor, and the fan is arranged on the outer side of the bevel gear set.

Further, the photovoltaic plate and the baffle are distributed horizontally, and the photovoltaic plate is connected with the baffle through threads.

Further, the fan is connected with the ventilation opening in an embedded mode, and the fan is connected with the ventilation opening in a rotating mode through the servo motor.

The utility model provides an energy-saving building top ventilation structure, which has the following beneficial effects:

1. according to the utility model, through the arrangement of the cleaning component, when the energy-saving building top ventilation structure is used, the problem that the filter piece is not easy to detach and clean due to the fact that the cleaning component on one side of the wall body is arranged on the top of the building is avoided, the dust in the air in the ventilation process is filtered by the filter screen arranged in the ventilation opening, the motor drives the screw rod in the bearing frame to rotate, the cleaning brush connected with the outer side of the screw rod slides up and down, so that dust attached to the inner side and the outer side of the filter screen is cleaned, the cleaning brush is stably moved by matching with the clamping groove formed in the ventilation opening, and the integral use efficiency of the equipment is improved.

2. According to the utility model, through the arrangement of the energy-saving assembly, when the ventilation structure at the top of the energy-saving building is used, the problem that the overall practicability is reduced due to poor ventilation effect in the use process of the existing ventilation structure is avoided through the energy-saving assembly at the upper end of the baffle plate, solar energy collected by the photovoltaic panel is converted into electric energy through the solar energy converter, the electric energy is stored by matching with the storage battery and is supplied to the servo motor, the servo motor is operated to drive the bevel gear set to rotate, so that the fan in the ventilation opening is operated, the air in the building is converted through the ventilation opening, and the ventilation effect is improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the roof ventilation structure of the energy-saving building of the present utility model;

FIG. 2 is an enlarged schematic view of the roof ventilation structure of the energy-saving building of the present utility model at A in FIG. 1;

fig. 3 is a schematic view of a ventilation opening three-dimensional structure of a ventilation structure at the top of the energy-saving building.

In the figure: 1. a wall body; 2. a baffle; 3. a cleaning assembly; 301. a vent; 302. a clamping groove; 303. a filter screen; 304. a receiving frame; 305. a motor; 306. a screw rod; 307. a cleaning brush; 4. an energy-saving assembly; 401. a photovoltaic panel; 402. a solar energy converter; 403. a storage battery; 404. a servo motor; 405. a bevel gear set; 406. a fan.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the utility model but are not intended to limit the scope of the utility model.

As shown in fig. 1 to 3, the ventilation structure at the top of the energy-saving building comprises a wall body 1 and a cleaning component 3, wherein a baffle plate 2 is arranged at the upper end of the wall body 1, the cleaning component 3 for cleaning a filter screen 303 is arranged at one side of the wall body 1, the cleaning component 3 comprises a ventilation opening 301, a clamping groove 302, a filter screen 303, a bearing frame 304, a motor 305, a screw rod 306 and a cleaning brush 307, the clamping groove 302 is formed in the inner side of the ventilation opening 301 near the edge, the filter screen 303 is arranged at the middle end inside the ventilation opening 301, the bearing frame 304 is arranged on the right side of the ventilation opening 301, meanwhile, a motor 305 is connected to the lower end of the bearing frame 304, a screw rod 306 is connected to the upper end of the motor 305, the cleaning brush 307 is arranged on the outer side of the screw rod 306, the clamping groove 302 is connected with the cleaning brush 307 in an embedded mode, the inner size of the clamping groove 302 is matched with the outer size of the cleaning brush 307, the cleaning brush 307 is connected with the ventilation opening 301 in an embedded mode, the cleaning brush 307 is connected with the ventilation opening 301 in a sliding mode through the screw rod 306, the screw rod 306 is connected with the bearing frame 304 in a rotating mode, the motor 306 drives the bearing frame 304 to rotate, the screw rod 306 in a rotating mode, the screw rod 306 in the rotating mode, the bearing frame 306 is connected with the bearing frame 306 in a rotating mode, the bearing frame 307 is connected with the bearing frame 307, the screw rod 307 in a rotating mode, the screw rod 307 is connected with the screw rod 307, the inside the filter brush 307 is connected with the filter brush and the inside and is further connected with the cleaning brush 307, and is matched with the inside, which is further, and the inside and is matched with the cleaning brush, and is further, and is matched with the inside and is matched with the cleaning device, and with the inside and has a cleaning device, and is further, and has a and is matched;

as shown in fig. 1, the upper end of the baffle 2 is provided with an energy-saving assembly 4 for energy-saving ventilation, the energy-saving assembly 4 comprises a photovoltaic panel 401, a solar energy converter 402 and a storage battery 403, the lower end of the photovoltaic panel 401 is provided with the solar energy converter 402, the storage battery 403 is installed at the lower end of the solar energy converter 402, the energy-saving assembly 4 further comprises a servo motor 404, a bevel gear set 405 and a fan 406, the servo motor 404 is additionally arranged at the lower end of the storage battery 403, the lower end of the servo motor 404 is connected with the bevel gear set 405, a fan 406 is installed at the outer side of the bevel gear set 405, the photovoltaic panel 401 and the baffle 2 are distributed horizontally, the photovoltaic panel 401 is in threaded connection with the baffle 2, the fan 406 is connected with the ventilation opening 301 in an embedded mode, the fan 406 is connected with the ventilation opening 301 in a rotating mode through the servo motor 404, solar energy collected by the photovoltaic panel 401 is converted into electric energy, the storage battery 403 is matched with the servo motor 404 to provide electric power, and the servo motor 404 operates to drive the bevel gear set 405 to rotate, so that the fan 406 inside the ventilation opening 301 operates, and thus the ventilation effect inside the building is improved.

In summary, this energy-conserving building top ventilation structure, when in use, firstly, solar energy that Fang Guangfu board 401 was collected on baffle 2 is converted into the electric energy through solar energy converter 402, cooperation battery 403 is with electric energy storage and provide electric power for servo motor 404, thereby improve clean energy availability factor, servo motor 404 operation drives bevel gear group 405 and rotates, make the inside fan 406 operation of vent 301, improve building top ventilation effect through vent 301 cooperation fan 406, then, utilize vent 301 internally mounted's filter screen 303 to filter the inside dust of ventilation in-process air, motor 305 drives and accept the inside lead screw 306 rotation of frame 304, make the cleaning brush 307 that the lead screw 306 outside is connected reciprocate, thereby clean the inside and outside attached dust of filter screen 303, and then avoid the dust to pile up and cause ventilation effect to descend, joint groove 302 that the inside of vent 301 seted up is spacing with cleaning brush 307, further increase practical performance when improving equipment availability factor.

The embodiments of the utility model have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the utility model in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, and to enable others of ordinary skill in the art to understand the utility model for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (8)

1. Energy-conserving building top ventilation structure, including wall body (1) and clean subassembly (3), a serial communication port, wall body (1) upper end is provided with baffle (2), is used for filter screen (303) clear clean subassembly (3) set up in wall body (1) one side, and clean subassembly (3) include vent (301), joint groove (302), filter screen (303), accept frame (304), motor (305), lead screw (306) and cleaning brush (307), the inboard joint groove (302) of being close to the edge of vent (301) has been seted up, and vent (301) inside middle-end is provided with filter screen (303) to accept frame (304) are installed on vent (301) right side, accept frame (304) lower extreme simultaneously and are connected with motor (305), motor (305) upper end is connected with lead screw (306), and the cleaning brush (307) are installed in the lead screw (306) outside, baffle (2) upper end is provided with energy-conserving subassembly (4) that are used for energy-conserving ventilation.

2. The energy saving building roof ventilation structure of claim 1, wherein the clamping groove (302) is connected with the cleaning brush (307) in an embedded manner, and the inner dimension of the clamping groove (302) is matched with the outer dimension of the cleaning brush (307).

3. The energy saving building roof ventilation structure according to claim 1, wherein the cleaning brush (307) is connected with the ventilation opening (301) in an embedded manner, and the cleaning brush (307) is connected with the ventilation opening (301) in a sliding manner through a screw (306).

4. The energy-saving building roof ventilation structure according to claim 1, wherein the screw (306) is connected with the receiving frame (304) in an embedded manner, and the screw (306) is connected with the receiving frame (304) in a rotating manner through the motor (305).

5. The energy-saving building roof ventilation structure according to claim 1, wherein the energy-saving assembly (4) comprises a photovoltaic panel (401), a solar energy converter (402) and a storage battery (403), the solar energy converter (402) is provided at the lower end of the photovoltaic panel (401), and the storage battery (403) is mounted at the lower end of the solar energy converter (402).

6. The energy-saving building roof ventilation structure according to claim 5, wherein the energy-saving assembly (4) further comprises a servo motor (404), a bevel gear set (405) and a fan (406), the servo motor (404) is additionally arranged at the lower end of the storage battery (403), the bevel gear set (405) is connected to the lower end of the servo motor (404), and the fan (406) is arranged at the outer side of the bevel gear set (405).

7. The energy-saving building roof ventilation structure according to claim 6, wherein the photovoltaic panels (401) are horizontally distributed with the baffle (2), and the photovoltaic panels (401) are screwed with the baffle (2).

8. The energy saving building roof ventilation structure according to claim 6, wherein the fan (406) is connected with the ventilation opening (301) in an embedded manner, and the fan (406) is connected with the ventilation opening (301) in a rotating manner through the servo motor (404).