CN220014249U - Green building modularization passive form ventilation assembly structure - Google Patents

Abstract

The utility model provides a green building modularized passive ventilation assembly structure, wherein an annular plate is arranged at the top end of a roof, a hood is arranged at the top end of the annular plate, a limit ring is fixedly connected to the top end of the roof, a plurality of side plates are fixedly connected to the side ends of the limit ring, a cavity is formed in each side plate, and a limit assembly is arranged in each cavity; according to the utility model, the slope-shaped rod is limited in the jack by the cooperation of the limiting component and the anti-slip ring, at the moment, the annular plate is assembled and fixed in the limiting ring, and the anti-slip resistance of the anti-slip ring to the side end of the annular plate can improve the fixing effect of the limiting ring, so that the passive ventilation unpowered hood is assembled, the installation efficiency of the hood is improved, and when the hood is disassembled, each pull plate is pulled outwards, so that after the inserted rod and the slope-shaped rod leave the jack, the annular plate can be taken out to disassemble and overhaul or replace the hood, and the disassembly efficiency of the hood is improved.

Description

Green building modularization passive form ventilation assembly structure

Technical Field

The utility model relates to the technical field of green buildings, in particular to a modularized passive ventilation assembly structure for a green building.

Background

The green building is a building capable of achieving the purposes of energy conservation and emission reduction, and the modularized building is provided with a passive ventilation structure on a roof for realizing green energy conservation and environmental protection, namely natural ventilation, namely a mode of utilizing natural energy or not relying on a traditional air conditioning equipment system and still maintaining a proper indoor environment. Natural ventilation most easily meets the requirements of building greening, does not generally use external non-renewable resources, and can often save a considerable amount of annual air conditioning load so as to achieve the purposes of energy conservation and greening.

The passive ventilating structure big ball for the modularized green building roof in the prior art, namely a unpowered hood, is also called a spherical ventilator, and the passive ventilating structure big ball for the modularized green building roof in the prior art utilizes natural wind to push a turbine of the ball to rotate and utilizes negative pressure formed by indoor and outdoor air temperature difference to push the ball to rotate, so that air flow in a parallel direction is accelerated to be converted into air flow vertical from top to bottom, thereby achieving the aim of indoor ventilation, and further enabling the modularized building to achieve green energy conservation and environmental protection; the unpowered hood is mainly formed by combining fan blades, a wind neck, an internal support and a bearing, wherein the arc-shaped fan blades are scientifically calculated, so that rainwater cannot invade in a working state, and the exhaust efficiency is high.

In the installation process of the traditional unpowered fan cap, four or more screws are required to be manually screwed on the installation base of the unpowered fan cap to be stably fixed on a roof, if the installation engineering quantity of the unpowered fan cap is large, the installation efficiency of the unpowered fan cap is not high enough through the screwing installation mode, and when the use time of the unpowered fan cap is too long, the fan cap is blocked when the fan cap rotates, the screws are required to be unscrewed one by one for overhauling or replacing, so that the disassembly efficiency of the unpowered fan cap is not high enough, and the problem is solved by the green building modularized passive ventilation assembly structure.

Disclosure of Invention

In order to solve the problems, the utility model provides a green building modularized passive ventilation assembly structure, which is used for more exactly solving the problems that in the installation process of the traditional unpowered wind cap, the installation base of the unpowered wind cap can be stably fixed on a roof by manually driving four or more screws, if the installation engineering quantity of the unpowered wind cap is large, the installation efficiency of the unpowered wind cap is not high enough by driving the screws, and when the service time of the unpowered wind cap is too long, the rotation of the wind cap is blocked, and the maintenance or replacement is required to be carried out, the screws are required to be unscrewed one by one, so that the disassembly efficiency of the unpowered wind cap is not high enough.

The utility model is realized by the following technical scheme:

the utility model provides a green building modularized passive ventilation assembly structure which comprises a roof, wherein an annular plate is arranged at the top end of the roof, a hood is arranged at the top end of the annular plate, a limit ring is fixedly connected to the top end of the roof, a plurality of sliding grooves are formed in the inner side end of the limit ring, a plurality of side plates are fixedly connected to the side end of the limit ring, a cavity is formed in each side plate, and a limit assembly is arranged in each cavity.

Further, the spacing subassembly includes the inserted bar, the inserted bar inserts from the outside side of curb plate and establishes to the cavity inside and extend to the inside side of spacing collar, is located the inside inserted bar outer end fixedly connected with limiting plate of cavity, be located the inside inserted bar outer pot head of cavity is equipped with the spring, is located the outside side of curb plate is fixed connection with the arm-tie.

Further, the side end of the inserted link extending to the side end inside the limit ring is fixedly connected with a slope-shaped rod.

Further, the inner side end of the limit ring is fixedly connected with an anti-slip ring.

Further, a plurality of jacks are formed in the side end of the annular plate, and a plurality of sliding blocks are fixedly connected to the side end of the annular plate.

Further, the sliding blocks arranged in the T-shaped mode are connected in the sliding grooves arranged in the T-shaped mode in a sliding mode.

Further, the inside side fixedly connected with support frame of annular plate, the inside side fixedly connected with mount of hood.

Further, the fixing frame is rotatably arranged at the top end of the supporting frame through a bearing.

The utility model has the beneficial effects that:

according to the utility model, through the cooperation of the limiting component and the anti-slip ring, each sliding block at the side end of the annular plate is downwards pressed and slidingly connected in the sliding groove, when the annular plate contacts the slope-shaped rod, the slope-shaped rod and the inserting rod are propped against each other to move towards the cavity, when the inserting rod and the slope-shaped rod pass through the jack at the side end of the annular plate, the spring automatically props against the limiting plate to drive the inserting rod and the slope-shaped rod to rebound, at the moment, the slope-shaped rod is limited in the jack, at the moment, the annular plate is assembled and fixed in the limiting ring, the anti-slip resistance of the anti-slip ring to the side end of the annular plate can improve the fixing effect of the limiting ring, so that the passive ventilating unpowered hood is assembled, the installation efficiency of the hood is improved, and when the annular plate is taken out to detach, overhaul or replace the hood is carried out after the inserting rod and the slope-shaped rod leave the jack, and the hood is detached.

Drawings

FIG. 1 is an exploded perspective view of a green building modular passive ventilation assembly structure of the present utility model;

FIG. 2 is a top perspective view of a stop collar of the green building modular passive ventilation assembly structure of the present utility model;

FIG. 3 is a schematic view of the enlarged partial structure of FIG. 2A;

fig. 4 is a bottom perspective view of a hood for a green building modular passive ventilation assembly of the present utility model.

The reference numerals are as follows:

1. roof covering; 2. a limit ring; 201. a chute; 202. an anti-slip ring; 3. a side plate; 301. a cavity; 302. a rod; 303. a ramp shaped rod; 304. a limiting plate; 305. a spring; 306. pulling a plate; 4. an annular plate; 401. a jack; 402. a slide block; 403. a support frame; 5. a hood; 501. and a fixing frame.

Detailed Description

In order to more clearly and completely describe the technical scheme of the utility model, the utility model is further described below with reference to the accompanying drawings.

Referring to fig. 1-4, the utility model provides a passive ventilation assembly structure of a green building, which comprises a roof 1, wherein an annular plate 4 is arranged at the top end of the roof 1, a hood 5 is arranged at the top end of the annular plate 4, the hood 5 can be pushed by natural wind to rotate, the hood 5 is pushed to rotate by negative pressure formed by indoor and outdoor air temperature difference, air in parallel direction is accelerated to flow, the air in the parallel direction is accelerated to flow vertically from top to bottom, so that the purpose of indoor ventilation is achieved, the passive ventilation and environment-friendly effect is achieved, a limit ring 2 is fixedly connected to the top end of the roof 1, the limit ring 2 is used for limiting an annular plate 4, the installation of the hood 5 is completed, a plurality of sliding grooves 201 are formed at the inner side end of the limit ring 2, the sliding grooves 201 can facilitate the limit of the annular plate 4, the inner side end of the limit ring 2 is fixedly connected with an anti-slip ring 202, the resistance formed by the anti-slip ring 202 on the side end of the annular plate 4 can improve the fixing effect of the limit ring 2, the side end of the limit ring 2 is fixedly connected with a plurality of side plates 3, each hollow cavity 301 is formed by the inner side plate 301, and each hollow cavity 301 is fixedly provided with a plurality of passive ventilation assemblies, and each hollow cavity 301 is provided with no hollow cavities, and the passive ventilation assembly is assembled.

Referring to fig. 1, a plurality of insertion holes 401 are formed in the side end of the annular plate 4, the limiting assembly is convenient to limit by the insertion holes 401, a plurality of sliding blocks 402 are fixedly connected to the side end of the annular plate 4, the sliding blocks 402 arranged in a T-shaped mode are slidably connected in the sliding grooves 201 arranged in the T-shaped mode, the insertion holes 401 in the side end of the annular plate 4 can be conveniently aligned with the limiting assembly automatically, and therefore the limiting assembly is convenient to limit the annular plate 4.

Referring to fig. 4, the inner side end of the annular plate 4 is fixedly connected with a support frame 403, the inner side end of the hood 5 is fixedly connected with a fixing frame 501, the fixing frame 501 is rotatably arranged at the top end of the support frame 403 through a bearing, the hood 5 can be driven to rotate through natural wind, air flow is realized, the purpose of ventilation is achieved indoors, ventilation is not needed by means of a traditional air conditioner, and the effect of green energy conservation and environmental protection is realized for a building.

Referring to fig. 3, the limiting assembly comprises a plug rod 302, the plug rod 302 is inserted from the outer side end of the side plate 3 to the inside of the cavity 301 and extends to the inner side end of the limiting ring 2, the side end of the plug rod 302 extending to the inner side end of the limiting ring 2 is fixedly connected with a slope rod 303, the outer end of the plug rod 302 located in the cavity 301 is fixedly connected with a limiting plate 304, the outer end of the plug rod 302 located in the cavity 301 is sleeved with a spring 305, the side end of the plug rod 302 located at the outer side end of the side plate 3 is fixedly connected with a pull plate 306, in the implementation, after each slide block 402 at the side end of the annular plate 4 is aligned with a sliding groove 201, the slide blocks 402 are connected in the sliding groove 201 in a sliding manner by pressing downwards, when the annular plate 4 contacts the slope rod 303, the slope rod 303 and the plug rod 302 move towards the inside of the cavity 301, at this moment, the limiting plate 304 is pressed against the spring 305, and when the annular plate 4 continues to press downwards, the plug rod 302 and the slope rod 303 pass through a jack 401 at the side end of the annular plate 4, the spring 305 automatically pushes the limiting plate 304 to drive the slope rod 302 and the slope rod 302, and the annular plate 303 is pushed downwards, and the annular plate 2 is pushed by the jack 401, and the annular plate 2 is pushed by the jack cap 2, and the annular plate 2, and the efficiency is detached from the jack cap 2.

Working principle: according to the green building modularized passive ventilation assembly structure, when the green building modularized passive ventilation assembly structure is used, after each sliding block 402 at the side end of the annular plate 4 is aligned to the sliding groove 201, the sliding blocks 402 are connected in the sliding groove 201 in a sliding manner by pressing downwards, the annular plate 4 passes through the anti-slip ring 202 in the pressing process, the anti-slip ring 202 can generate certain resistance to the annular plate 4 during installation, when the annular plate 4 contacts the slope rod 303, the top end of the slope rod 303 is in slope arrangement, the annular plate 4 can move towards the cavity 301 against the slope rod 303 and the inserting rod 302 in the pressing process, at the moment, the limiting plate 304 is pressed against the spring 305 to shrink, when the annular plate 4 continues to press downwards, the spring 305 automatically pushes the inserting rod 302 and the slope rod 303 to rebound through the insertion hole 401, at the moment, the annular plate 4 is assembled and fixed in the limit ring 2, the resistance of the annular plate 202 to the side end of the annular plate 2 can be improved, and thus the air cap 5 is driven by the air cap 5, the negative pressure is converted into a negative pressure effect of the ventilation cap 5, the ventilation cap 5 is realized, the ventilation cap 5 is rotated in a rotating direction, and the ventilation cap 5 is rotated in a vertical direction, and the ventilation effect is realized;

when the hood 5 is disassembled, each pull plate 306 is pulled outwards, so that after the inserted rod 302 and the slope-shaped rod 303 leave the jack 401, the hood 5 can be disassembled, overhauled or replaced by taking out the annular plate 4, and the disassembly efficiency of the hood 5 is improved.

Of course, the present utility model can be implemented in various other embodiments, and based on this embodiment, those skilled in the art can obtain other embodiments without any inventive effort, which fall within the scope of the present utility model.

Claims (7)

1. The utility model provides a green building modularization passive form ventilation assembly structure, includes roofing (1), the top of roofing (1) is equipped with annular plate (4), the top of annular plate (4) is equipped with hood (5), a serial communication port, the top fixedly connected with spacing collar (2) of roofing (1), a plurality of spout (201) have been seted up to the inside side of spacing collar (2), the side fixedly connected with of spacing collar (2) a plurality of curb plate (3), every cavity (301) have all been seted up to the inside of curb plate (3), every the inside of cavity (301) all is equipped with spacing subassembly;

the limiting assembly comprises a plug rod (302), the plug rod (302) is inserted into the cavity (301) from the outer side end of the side plate (3) and extends to the inner side end of the limiting ring (2), the outer end of the plug rod (302) positioned in the cavity (301) is fixedly connected with a limiting plate (304), the outer end of the plug rod (302) positioned in the cavity (301) is sleeved with a spring (305), and the side end of the plug rod (302) positioned at the outer side end of the side plate (3) is fixedly connected with a pulling plate (306).

2. The green building modular passive ventilation assembly structure according to claim 1, wherein a sloping rod (303) is fixedly connected to the side end of the inserted rod (302) extending to the inner side end of the limit ring (2).

3. The green building modular passive ventilation assembly structure according to claim 1, wherein the inner side end of the limit ring (2) is fixedly connected with an anti-slip ring (202).

4. The passive ventilation assembly structure of green building modularization according to claim 1 is characterized in that a plurality of jacks (401) are formed at the side end of the annular plate (4), and a plurality of sliding blocks (402) are fixedly connected to the side end of the annular plate (4).

5. A green building modular passive ventilation assembly structure according to claim 4, characterized in that the slide blocks (402) of the T-shaped arrangement are slidingly connected in the slide grooves (201) of the T-shaped arrangement.

6. The passive ventilation assembly structure of green building modularization according to claim 1 is characterized in that the inner side end of the annular plate (4) is fixedly connected with a supporting frame (403), and the inner side end of the hood (5) is fixedly connected with a fixing frame (501).

7. The passive ventilation assembly structure of green building modules according to claim 6, wherein the fixing frame (501) is rotatably arranged at the top end of the supporting frame (403) through a bearing.