CN219693506U - Novel green building ventilation structure - Google Patents

Abstract

The utility model provides a novel green building ventilation structure, which relates to the technical field of building ventilation and comprises the following components: the wall body, the top and the bottom position of wall body are equipped with first mounting hole and second mounting hole respectively, and first mounting hole is inside to be equipped with first connector, and second mounting hole is inside to be equipped with the second connector, and hot air subassembly, hot air subassembly locate the one end of first connector to and cold wind subassembly, and the one end of second connector is located to cold wind subassembly. The indoor temperature can not drop in the use of this kind of ventilation structure through hot-blast subassembly when ventilating in winter, avoids the lower time taking a breath of winter temperature with outside cold air pump to indoor, leads to indoor temperature to drop sharply, and secondly, can not rise in indoor temperature in the use of cold-blast subassembly when ventilating in summer, avoids when ventilating, pumps indoor with outdoor hot air, leads to indoor temperature to rise.

Description

Novel green building ventilation structure

Technical Field

The utility model relates to the technical field of building ventilation, in particular to a novel green building ventilation structure.

Background

In the building, ventilation structure can be offered at the top of building generally to can make things convenient for indoor and outdoor ventilation, but current ventilator can only realize gaseous circulation, but the heavy wind environment often accompanies the dust, does not possess dustproof performance, and when the wind speed is great faster, the wind that the ventilator brought is too urgent too fast, and smuggles the dust in secretly still can influence normal work and life.

With respect to a building ventilation structure, it is found through searching that, patent number CN211372682U discloses a building energy-saving ventilation structure, this kind of building ventilation structure is through setting up the air inlet dog, the air inlet dog cross-section shape sets up to right trapezoid, can make breeze after filtering through first filter, accelerate by a small margin, the cross-section shape of flow distribution plate sets up to trapezium, can make strong wind pass through the flow distribution plate and slow down the back, the bearing between blade and the dead lever, can reduce frictional resistance, the bearing between rotary drum and the dead lever, can reduce frictional resistance, the bearing between reduction drum and the dead lever can effectively reduce frictional resistance, the reduction drum rotates can effectively slow down the impulsive force of strong wind, this building energy-saving ventilation structure can make the wind velocity of flow alleviate, filter among them, however in actual use, considering weather's problem, ventilation can make outdoor cold air get into indoor in winter, can lead to indoor temperature decline, and indoor temperature is relatively low with outdoor temperature in summer, in ventilation.

Disclosure of Invention

The utility model aims to solve the defects in the background art, and provides a novel green building ventilation structure, which can realize ventilation and ventilation in winter through the use of a hot air component without lowering the indoor temperature, and avoid the phenomenon that the indoor temperature is suddenly lowered due to the fact that external cold air is pumped into the room when the air temperature is low in winter for ventilation.

In order to achieve the above object, the present utility model provides a novel green building ventilation structure, comprising: the wall body, the top of wall body and bottom position are equipped with first mounting hole and second mounting hole respectively, the inside first connector that is equipped with of first mounting hole, the inside second connector that is equipped with of second mounting hole, hot-blast subassembly is located the one end of first connector for ventilate when winter, and cold wind subassembly, cold wind subassembly is located the one end of second connector is used for ventilate when summer.

Further, the hot air assembly includes: the heating plate is characterized in that a tubular shell is arranged at one end of the first connector, a first ventilation pipe is connected to one end, far away from the first connector, of the tubular shell, a heating plate is arranged inside the tubular shell, and a plurality of heating wires are arranged between the inner walls of the heating plate.

Further, the cold air assembly includes: locate square shell of second connector one end, square shell is connected with the second ventilation pipe away from the one end of first connector, locates respectively square shell upper surface and lower surface's heating panel, two be connected with the copper pipe between the heating panel, the copper pipe is vertical runs through square shell and extends to inside, locates the outside a plurality of conducting strip of copper pipe, locates two respectively the outside radiator fan of heating panel.

Further, the bottom of the first ventilation pipe is connected with the output end of a T-shaped pipe, the output end of the bottom of the T-shaped pipe is connected with the second ventilation pipe, and the input end of one side of the T-shaped pipe is connected with a connecting pipe.

Further, the inside filter screen that is equipped with of connecting pipe, the shell body is connected to connecting pipe one end, the inside driving motor that is equipped with of shell body, the driving motor drive is connected with the flabellum.

Further, the air intake has been seted up to one side that the connecting pipe was kept away from to the shell body, air intake inner wall both sides are equipped with a plurality of installation pieces, and two are relative rotate between the installation piece and be connected with the rotary rod, the rotary rod bottom is equipped with the baffle.

Further, a valve seat is arranged at the joint of the T-shaped pipe, a valve core is arranged in the valve seat, and one side of the valve core is connected with a rotating handle.

The utility model provides a novel green building ventilation structure, which has the following beneficial effects:

the utility model has the advantages that the indoor temperature can not be reduced during ventilation in winter by using the hot air component, the phenomenon that the indoor temperature is rapidly reduced due to the fact that external cold air is pumped into the room during low ventilation in winter is avoided, and the indoor temperature can not be increased during ventilation in summer by using the cold air component, and the phenomenon that the outdoor hot air is pumped into the room during ventilation is avoided, so that the indoor temperature is increased.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is a cross-sectional view of the overall structure of the present utility model.

Fig. 3 is an enlarged view of fig. 2 a in accordance with the present utility model.

Fig. 4 is an enlarged view of fig. 2B in accordance with the present utility model.

In fig. 1-4: 1. a wall body; 11. a first mounting hole; 12. a first connector; 13. a second mounting hole; 14. a second connector; 2. a tubular shell; 21. a first ventilation pipe; 22. a heating plate; 23. heating wires; 3. a square shell; 31. a second ventilation pipe; 32. a heat dissipation plate; 33. copper pipe; 34. a heat conductive sheet; 35. a heat radiation fan; 4. a T-shaped pipe; 41. a connecting pipe; 42. an outer housing; 43. a driving motor; 44. a fan blade; 45. a mounting block; 46. a rotating rod; 47. a baffle; 5. a valve seat; 51. a valve core; 52. the handle is turned.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. It will be apparent that the described embodiments are only some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to fall within the scope of the utility model.

The embodiment of the utility model provides a novel green building ventilation structure, which can realize ventilation and ventilation in winter through the use of a hot air component, and meanwhile, the indoor temperature does not drop, so that the phenomenon that the indoor temperature drops sharply due to the fact that outside cold air is pumped indoors when the air temperature is low in winter is avoided.

The novel green building ventilation structure is described in detail below. The following description of the embodiments is not intended to limit the preferred embodiments.

The utility model is described in detail below with reference to the drawings and the detailed description. Referring to fig. 1-4, a novel green building ventilation structure provided in this embodiment includes: the wall body 1, the top and the bottom position of wall body 1 are respectively equipped with first mounting hole 11 and second mounting hole 13, and first mounting hole 11 inside is equipped with first connector 12, and second mounting hole 13 inside is equipped with second connector 14, and hot air subassembly, hot air subassembly locate the one end of first connector 12 for ventilate when winter, and cold wind subassembly, cold wind subassembly locate the one end of second connector 14 for ventilate when summer.

In some embodiments, the bottom of the first ventilation tube 21 is connected with the output end of the T-shaped tube 4, the output end of the bottom of the T-shaped tube 4 is connected with the second ventilation tube 31, the input end of one side of the T-shaped tube 4 is connected with the connecting tube 41, the filter screen is arranged inside the connecting tube 41, one end of the connecting tube 41 is connected with the outer shell 42, the driving motor 43 is arranged inside the outer shell 42, the fan blades 44 are connected in a driving manner, an air inlet is formed in one side of the outer shell 42 far away from the connecting tube 41, a plurality of mounting blocks 45 are arranged on two sides of the inner wall of the air inlet, a rotating rod 46 is rotatably connected between two opposite mounting blocks 45, a baffle 47 is arranged at the bottom of the rotating rod 46, the driving motor 43 is a forward and reverse motor capable of forward and reverse rotation, when the driving motor 43 forward rotates, the fan blades 44 rotate to generate suction force to enable the baffle 47 to open and close to one side of the forward and reverse motor under the influence of the suction force, external air enters the connecting tube 41 through the suction force generated by the fan blades 44, and the suction force generated by the fan blades 44 enters the connecting tube 41, and the clean air filtered through the filter screen inside the connecting tube 41.

In some embodiments, the hot air assembly comprises: the tubular shell 2 is arranged at one end of the first connecting head 12, one end, far away from the first connecting head 12, of the tubular shell 2 is connected with the first ventilation pipe 21, the heating plate 22 is arranged inside the tubular shell 2, a plurality of heating wires 23 are arranged between the inner walls of the heating plate 22, the joint of the T-shaped pipes 4 is provided with the valve seat 5, the valve seat 5 is internally provided with the valve core 51, and one side of the valve core 51 is connected with the rotating handle 52.

When in winter, the valve core 51 rotates in the valve seat 5 by rotating the rotating handle 52 anticlockwise, the valve core 51 rotates anticlockwise so that the connecting pipe 41 is communicated with the first ventilation pipe 21, clean air enters the tubular shell 2 along the first ventilation pipe 21, electric energy is converted into heat energy after the heating plate 22 is electrified, the heat energy is transferred to the heating wires 23, the clean air passes through the heating wires 23 and is heated, cold air is converted into hot air, and the hot air enters the room through the first connecting head 12, so that the indoor temperature can not be reduced when ventilation is performed in winter.

In some embodiments, the cool air assembly includes: the square shell 3 of locating second connector 14 one end, square shell 3 is kept away from the one end of first connector 12 and is connected with second ventilation pipe 31, locate square shell 3 upper surface and lower surface's heating panel 32 respectively, be connected with copper pipe 33 between two heating panels 32, copper pipe 33 vertically runs through square shell 3 and extends to inside, locate the outside a plurality of heat-conducting strip 34 of copper pipe 33, locate the outside radiator fan 35 of two heating panels 32 respectively, when in summer, will rotate handle 52 and change initial position, connecting pipe 41 and second ventilation pipe 31 are switched on this moment, the hot air after being filtered gets into square shell 3 inside along second ventilation pipe 31, the heat-conducting strip 34 can absorb the heat in the air when passing square shell 3 inside, the heat of absorption passes through copper pipe 33 and transmits to heating panel 32, heating panel 32 gives off heat to the air directly, radiator fan 35 can take away this part of hot air, the hot air temperature that the heat absorbed reduces, get into indoor through second connector 14, so that ventilation heat transfer is carried out in summer.

In the foregoing embodiments, the descriptions of the embodiments are emphasized, and for parts of one embodiment that are not described in detail, reference may be made to related descriptions of other embodiments.

The novel green building ventilation structure provided by the embodiment of the utility model is described in detail, and specific examples are applied to explain the principle and the implementation mode of the utility model, and the description of the above examples is only used for helping to understand the technical scheme and the core idea of the utility model; those of ordinary skill in the art will appreciate that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the utility model.

Claims (7)

1. Novel green building ventilation structure, its characterized in that includes:

the wall body (1), the top and bottom positions of the wall body (1) are respectively provided with a first mounting hole (11) and a second mounting hole (13), a first connector (12) is arranged in the first mounting hole (11), and a second connector (14) is arranged in the second mounting hole (13);

the hot air assembly is arranged at one end of the first connector (12) and is used for ventilation in winter; a kind of electronic device with high-pressure air-conditioning system

And the cold air assembly is arranged at one end of the second connector (14) and is used for ventilation in summer.

2. The novel green building ventilation structure of claim 1, wherein the hot air assembly comprises:

a tubular shell (2) is arranged at one end of the first connector (12), and a first ventilation pipe (21) is connected to one end of the tubular shell (2) far away from the first connector (12);

and a heating plate (22) arranged inside the tubular shell (2), wherein a plurality of heating wires (23) are arranged between the inner walls of the heating plate (22).

3. The novel green building ventilation structure of claim 1, wherein the cool air assembly comprises:

the square shell (3) is arranged at one end of the second connector (14), and one end, far away from the first connector (12), of the square shell (3) is connected with a second ventilation pipe (31);

the copper pipes (33) vertically penetrate through the square shell (3) and extend into the square shell;

a plurality of heat conducting fins (34) arranged outside the copper pipe (33);

and cooling fans (35) respectively arranged outside the two cooling plates (32).

4. The novel green building ventilation structure according to claim 2, wherein the bottom of the first ventilation pipe (21) is connected with a T-shaped pipe (4), the output end of the bottom of the T-shaped pipe (4) is connected with a second ventilation pipe (31), and the input end of one side of the T-shaped pipe (4) is connected with a connecting pipe (41).

5. The novel green building ventilation structure according to claim 4, wherein a filter screen is arranged inside the connecting pipe (41), one end of the connecting pipe (41) is connected with the outer shell (42), a driving motor (43) is arranged inside the outer shell (42), and fan blades (44) are connected with the driving motor (43) in a driving mode.

6. The novel green building ventilation structure according to claim 5, wherein an air inlet is formed in one side, far away from the connecting pipe (41), of the outer shell (42), a plurality of mounting blocks (45) are arranged on two sides of the inner wall of the air inlet, a rotating rod (46) is connected between two opposite mounting blocks (45) in a rotating mode, and a baffle (47) is arranged at the bottom of the rotating rod (46).

7. The novel green building ventilation structure according to claim 4, wherein a valve seat (5) is arranged at the joint of the T-shaped pipe (4), a valve core (51) is arranged inside the valve seat (5), and a rotary handle (52) is connected to one side of the valve core (51).