CN117889043B - Breeze generator with wind and heat combined utilization - Google Patents

Abstract

The invention discloses a breeze generator for compositely utilizing wind and heat, which relates to the technical field of wind power generation and comprises a turbine fan, an air duct and a base, wherein the turbine fan, the air duct and the base are sequentially communicated from top to bottom, a wind generating set is arranged between the turbine fan and the air duct, the base is used for being installed on a roof, an air inlet is arranged on the base and used for enabling indoor hot air to enter the air duct, one side of the air duct is provided with an air inlet, the air inlet is used for enabling outdoor wind to enter the air duct, the air inlet turns along with the direction of the outdoor wind, a wind-binding mechanism is arranged in the air duct, and the wind-binding mechanism is used for carrying out wind-binding acceleration on the indoor hot air and the outdoor wind and guiding the indoor hot air and the outdoor wind into the turbine fan, so that the rotation speed of the wind generating set is increased, and the power generation efficiency is improved. The invention can regularly guide and accelerate the indoor hot air and the outdoor natural wind of the building for wind power generation, and greatly improves the wind power generation efficiency while improving the indoor air environment.

Description

Breeze generator with wind and heat combined utilization

Technical Field

The invention relates to the technical field of wind power generation, in particular to a breeze generator with wind and heat combined utilization.

Background

Wind power generation is one of the main directions of development in the future as a mature green power, and particularly after the substitution rate of building energy becomes a mandatory index, the development direction of searching for renewable energy sources of the building becomes a forced demand.

The breeze generator is a generating set which is used for regularly restraining the air or the air flow in the natural world and has the characteristics of low noise and high generating efficiency. The existing industrial plants, flues, equipment exhaust and the like can generate organized airflow flow when hot gas or dirty gas is exhausted.

Therefore, how to provide a breeze generator, not only can realize rapid discharge of indoor gas and improve air environment, but also can be coupled with outdoor breeze power generation to generate green power is a problem to be solved urgently at present.

Disclosure of Invention

The invention aims to provide a breeze generator capable of utilizing wind and heat in a combined way, so that the problems in the prior art are solved, the breeze generator can be used for wind power generation after regular diversion and acceleration of indoor hot air and outdoor natural wind of a building, and the wind power generation efficiency is greatly improved while the indoor air environment is improved.

In order to achieve the above object, the present invention provides the following solutions: the invention provides a breeze generator capable of utilizing wind and heat in a combined mode, which comprises a turbine fan, an air duct and a base, wherein the turbine fan, the air duct and the base are sequentially communicated from top to bottom, a wind generating set is arranged between the turbine fan and the air duct, the base is used for being installed on a roof, an air inlet is formed in the base, indoor hot air enters the air duct, an air inlet is formed in one side of the air duct, the air inlet is used for enabling outdoor wind to enter the air duct, the air inlet turns along with the direction of the outdoor wind, a wind-binding mechanism is arranged in the air duct, and the wind-binding mechanism is used for carrying out wind-binding acceleration on the indoor hot air and the outdoor wind and guiding the indoor hot air and the outdoor wind into the turbine fan so that the wind generating set carries out wind power generation.

Preferably, the air duct is rotatably connected between the turbine fan and the base, one side of the air duct is a windward side, the other side of the air duct is a leeward side, the windward side is arranged on the windward side, and the arc length of the windward side is greater than that of the leeward side, so that the air duct can rotate along with the wind direction of outdoor wind, and the windward side faces the wind direction of the outdoor wind.

Preferably, the wind-guiding mechanism can separate the wind guiding barrel so as to form a first wind-guiding channel and a second wind-guiding channel in the wind guiding barrel, one end of the first wind-guiding channel is communicated with the windward opening, the other end of the first wind-guiding channel is communicated with the turbine fan, and the first wind-guiding channel is used for accelerating the outdoor wind in a wind-guiding way and guiding the outdoor wind into the turbine fan; one end of the second air-binding channel is communicated with the air inlet, the other end of the second air-binding channel is communicated with the turbine fan, and the second air-binding channel is used for carrying out air-binding acceleration on indoor hot air and guiding the indoor hot air into the turbine fan.

Preferably, the air-blowing mechanism comprises a first transverse air guide plate, a second transverse air guide plate and a vertical air guide plate, wherein the first transverse air guide plate and the second transverse air guide plate are obliquely arranged in the air guide cylinder, the first transverse air guide plate is used for separating the windward opening from the air inlet so as to enable the air guide cylinder to form the first air-blowing channel and the second air-blowing channel, the second transverse air guide plate is arranged above the first transverse air guide plate, and the second transverse air guide plate is used for transversely separating the first air-blowing channel; the vertical air deflector penetrates through the first transverse air deflector and the second transverse air deflector, and the vertical air deflector is used for vertically separating the first air-bundling channel from the second air-bundling channel.

Preferably, the base comprises an annular seat, a fixed shaft and a yaw mechanism, wherein the air inlet is formed by the inner ring of the annular seat, and the fixed shaft is vertically fixed in the inner ring of the annular seat; the turbine fan comprises a central shaft, an upper rotating disc, a lower rotating disc and fan blades, wherein the central shaft is fixed at the top of the fixed shaft and is coaxially arranged with the fixed shaft, and the upper rotating disc and the lower rotating disc are sequentially connected onto the central shaft in a rotating manner from top to bottom; the fan blades are provided with a plurality of fan blades, all the fan blades are uniformly distributed between the upper rotating disk and the lower rotating disk in a lantern shape, and an airflow channel is reserved between the adjacent fan blades; the wind generating set is arranged on the central shaft; the air duct is sleeved on the fixed shaft, the top of the air duct is rotationally connected with the lower rotating disk, the bottom of the air duct is rotationally connected with the annular seat, and the air duct can rotate around the fixed shaft through the yaw mechanism.

Preferably, the yaw mechanism comprises a yaw planet wheel, a yaw rotating shaft, a connecting rod and a yaw planet wheel, wherein the yaw planet wheel and the fixing shaft are coaxially arranged in the annular seat, the yaw rotating shaft is vertically arranged, the top of the yaw rotating shaft is fixedly connected with the inner wall of the air duct through the connecting rod, and the bottom of the yaw rotating shaft is rotatably connected with the yaw planet wheel through the yaw planet wheel.

Preferably, a ball is arranged between the bottom of the air duct and the annular seat.

Preferably, the wind generating set comprises a generator main shaft, generator blades, a generator gear box, a speed increaser shaft and a wind driven generator, wherein the generator main shaft is rotationally sleeved on the central shaft, the generator blades are arranged at the bottom of the generator main shaft, and the generator main shaft is connected with the wind driven generator sequentially through the generator gear box and the speed increaser shaft.

Compared with the prior art, the invention has the following technical effects: the breeze generator capable of utilizing wind and heat comprises a turbine fan, an air duct and a base, wherein the turbine fan, the air duct and the base are sequentially communicated from top to bottom, a wind power generation unit is arranged between the turbine fan and the air duct, and a wind-binding mechanism is arranged in the air duct. The invention can regularly guide and accelerate the indoor hot air and the outdoor natural wind of the building for wind power generation, and greatly improves the wind power generation efficiency while improving the indoor air environment.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic diagram of a working state of a breeze generator utilizing wind and heat in a combined manner according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of a breeze generator with combined wind and heat utilization according to an embodiment of the present invention.

Fig. 3 is an exploded view of a breeze generator utilizing wind and heat in a combined manner according to an embodiment of the present invention.

Fig. 4 is a second angular schematic diagram of a breeze generator utilizing wind and heat in combination according to an embodiment of the present invention.

Fig. 5 is a schematic view of a breeze generator with combined wind and heat utilization according to a third embodiment of the present invention.

Fig. 6 is a fourth schematic angle diagram of a breeze generator utilizing wind and heat in a combined manner according to an embodiment of the present invention.

Fig. 7 is a plan view of a breeze generator for wind and heat combined utilization according to an embodiment of the present invention.

Fig. 8 is a bottom view of a breeze generator for wind and heat combined utilization according to an embodiment of the present invention.

Fig. 9 is a schematic diagram of an air duct according to an embodiment of the present invention.

Fig. 10 is an exploded view of an air duct according to an embodiment of the present invention.

Fig. 11 is a schematic view of a base provided in an embodiment of the present invention.

Fig. 12 is an exploded view of a base provided by an embodiment of the present invention.

Fig. 13 is a cross-sectional view of an air duct provided in an embodiment of the present invention at a position near a base.

Fig. 14 is a schematic view of a turbo fan according to an embodiment of the present invention.

Fig. 15 is an exploded view of a turbo blower according to an embodiment of the present invention.

Fig. 16 is a schematic view of a wind turbine generator system according to an embodiment of the present invention.

Fig. 17 is an exploded view of a wind turbine generator system according to an embodiment of the present invention.

In the figure: the wind turbine comprises a 1-turbine fan, a 101-central shaft, a 102-upper rotating disc, a 103-upper rotating flange, a 104-lower rotating disc, a 105-lower rotating disc supporting rod, 106-fan blades, a 2-wind guide barrel, a 201-wind guide barrel main body, a 202-upper connecting barrel, a 203-lower connecting disc, a 204-first transverse wind guide plate, a 205-second transverse wind guide plate, a 206-vertical wind guide plate, a 3-base, a 301-annular base, a 302-fixed shaft, a 303-fixed shaft supporting rod, a 304-yaw planet wheel, a 305-yaw rotating shaft, a 306-connecting rod, a 307-yaw planet wheel, a 4-wind generating set, a 401-generator main shaft, 402-generator blades, a 403-generator gearbox, a 404-speed increaser shaft and 405-wind generating set.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The invention aims to provide a breeze generator capable of utilizing wind and heat in a combined way, so that the problems in the prior art are solved, the breeze generator can be used for wind power generation after regular diversion and acceleration of indoor hot air and outdoor natural wind of a building, and the wind power generation efficiency is greatly improved while the indoor air environment is improved.

In order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to the appended drawings and appended detailed description.

As shown in fig. 1-8, the embodiment provides a breeze generator with combined utilization of wind and heat, which comprises a turbine fan 1, an air duct 2 and a base 3 which are sequentially communicated from top to bottom, wherein a wind generating set 4 is arranged between the turbine fan 1 and the air duct 2, the base 3 is arranged on a roof, an air inlet is arranged on the base 3 and is used for enabling indoor hot air to enter the air duct 2, one side of the air duct 2 is provided with an air inlet, the air inlet is used for enabling outdoor wind to enter the air duct 2, the air inlet turns along with the wind direction of the outdoor wind, a wind-binding mechanism is arranged in the air duct 2 and is used for carrying out wind-binding acceleration on indoor hot air and outdoor wind, and the indoor hot air and the outdoor wind are led into the turbine fan 1, so that the wind generating set 4 carries out wind power generation.

When the device is used, the device is installed on a roof through the base 3, indoor hot air such as flue gas and the like enters the air duct 2 through the air inlet on the base 3 to form bottom-up airflow, meanwhile, outdoor air enters the air duct 2 through the windward opening on the air duct 2 to form bottom-up airflow, the airflow is accelerated through the beam fan mechanism and guided into the turbine fan 1, and then the airflow is accelerated and discharged outdoors through the turbine fan 1 in a turbine rotating mode, so that the wind generating set 4 performs wind power generation, the rotation rate of the wind generating set 4 is increased, and the power generation efficiency is improved. The invention can regularly guide and accelerate the indoor hot air and the outdoor natural wind of the building for wind power generation, and greatly improves the wind power generation efficiency while improving the indoor air environment.

In this embodiment, as shown in fig. 9-10, the air duct 2 is rotatably connected between the turbine fan 1 and the base 3, one side of the air duct 2 is a windward side, the other side is a leeward side, the windward side is provided with the windward side, and the arc length of the windward side is greater than that of the leeward side, so that the air duct 2 can rotate along with the wind direction of the outdoor wind, and the windward side faces the wind direction of the outdoor wind; specifically, the air duct 2 in this embodiment includes an air duct main body 201, and the air duct main body 201 is rotationally connected with the turbo fan 1 through an upper connecting tube 202 and is rotationally connected with the base 3 through a lower connecting disc 203, and balls are provided between the bottom of the lower connecting disc 203 and the base 3, so that the air duct 2 is convenient to rotate relative to the base 3.

In this embodiment, the wind-binding mechanism can separate the wind guide barrel 2, so that a first wind-binding channel and a second wind-binding channel are formed in the wind guide barrel 2, one end of the first wind-binding channel is communicated with the windward port, the other end of the first wind-binding channel is communicated with the turbine fan 1, and the first wind-binding channel is used for carrying out wind-binding acceleration on outdoor wind and guiding the outdoor wind into the turbine fan 1; one end of the second air-binding channel is communicated with the air inlet, the other end of the second air-binding channel is communicated with the turbine fan 1, and the second air-binding channel is used for carrying out air-binding acceleration on indoor hot air and guiding the indoor hot air into the turbine fan 1.

Further, the beam fan mechanism comprises a first transverse air guide plate 204, a second transverse air guide plate 205 and a vertical air guide plate 206, wherein the first transverse air guide plate 204 and the second transverse air guide plate 205 are obliquely arranged in the air guide cylinder 2, the first transverse air guide plate 204 is used for separating an windward opening from an air inlet so as to enable a first beam air channel and a second beam air channel to be formed in the air guide cylinder 2, the second transverse air guide plate 205 is arranged above the first transverse air guide plate 204, and the second transverse air guide plate 205 is used for transversely separating the first beam air channel; the vertical air guide plate 206 penetrates through the first transverse air guide plate 204 and the second transverse air guide plate 205, and the vertical air guide plate 206 is used for vertically separating the first air beam passage and the second air beam passage; specifically, in this embodiment, the number of vertical air deflectors 206 is 2, the first wind channel is divided into 6 channels, outdoor wind in each direction is accelerated by the 6 channels, then forms directional wind from bottom to top, drives the turbine fan 1 to rotate, the number of vertical air deflectors 206 is divided into 3 channels, indoor hot air is accelerated by the 3 channels to drive the turbine fan 1 to rotate, wind power is accelerated by the form of wind channel and turbine rotation, and the functions of exhausting indoor hot air and wind power generation are realized.

In this embodiment, as shown in fig. 11 to 13, the base 3 includes an annular seat 301, a fixed shaft 302, a fixed shaft support rod 303, and a yaw mechanism, an air intake is formed in an inner ring of the annular seat 301, and the fixed shaft 302 is vertically fixed in the inner ring of the annular seat 301 by the fixed shaft support rod 303; as shown in fig. 14 to 15, the turbo fan 1 includes a central shaft 101, an upper rotating disc 102, an upper rotating flange 103, a lower rotating disc 104, a lower rotating disc support rod 105, and fan blades 106, the central shaft 101 is fixed on top of a fixed shaft 302 and coaxially arranged with the fixed shaft 302, the upper rotating disc 102 is rotatably connected to the top of the central shaft 101 through the upper rotating flange 103, and the lower rotating disc 104 is rotatably connected to the bottom of the central shaft 101 through the lower rotating disc support rod 105; the fan blades 106 are provided with a plurality of fan blades 106, all the fan blades 106 are uniformly distributed between the upper rotating disk 102 and the lower rotating disk 104 in a lantern shape, and airflow channels are reserved between the adjacent fan blades 106; the wind generating set 4 is arranged on the central shaft 101; the air duct 2 is sleeved on the fixed shaft 302, the top of the air duct 2 is rotationally connected with the lower rotary disk 104, the bottom of the air duct 2 is rotationally connected with the annular seat 301, and the air duct 2 can rotate around the fixed shaft 302 through the yaw mechanism.

Further, the yaw mechanism comprises a yaw planet wheel 304, a yaw rotating shaft 305, a connecting rod 306 and a yaw planet wheel 307, the yaw planet wheel 304 and the fixed shaft 302 are coaxially arranged in the annular seat 301, the yaw rotating shaft 305 is vertically arranged, the top of the yaw rotating shaft 305 is fixedly connected with the inner wall of the air duct 2 through the connecting rod 306, the bottom of the yaw rotating shaft 305 is rotationally connected with the yaw planet wheel 304 through the yaw planet wheel 307, and the air duct 2 can move along the yaw planet wheel 304 through the yaw planet wheel 307 to steer.

In this embodiment, as shown in fig. 16-17, the wind generating set 4 includes a generator main shaft 401, a generator blade 402, a generator gear box 403, a speed increaser shaft 404, and a wind driven generator 405, where the generator main shaft 401 is rotatably sleeved on the central shaft 101, the generator blade 402 is disposed at the bottom of the generator main shaft 401, and the generator main shaft 401 is connected with the wind driven generator 405 sequentially through the generator gear box 403 and the speed increaser shaft 404; through the coaxial setting of turbo fan 1 and generator blade 402, in turbo fan 1 the in-process of accelerating the air current of leading out in the air duct 2, the air current from bottom to top in the air duct 2 drives the rotation of generator blade 402, realizes wind power generation.

In conclusion, the breeze generator for the combined utilization of wind and heat realizes the comprehensive utilization of wind power and hot air, can be arranged at outdoor positions such as industrial factory building roofs, flues, equipment exhaust ports and the like, has the characteristics of convenience in installation, small occupied area, low noise, high ventilation efficiency, high power generation efficiency and the like, and is suitable for popularization and application.

The principles and embodiments of the present invention have been described in detail with reference to specific examples, which are provided to facilitate understanding of the method and core ideas of the present invention; also, it is within the scope of the present invention to be modified by those of ordinary skill in the art in light of the present teachings. In view of the foregoing, this description should not be construed as limiting the invention.

Claims (4)

1. The breeze generator with the composite utilization of wind and heat is characterized in that: the wind power generation device comprises a turbine fan, a wind guide cylinder and a base which are sequentially communicated from top to bottom, wherein a wind generating set is arranged between the turbine fan and the wind guide cylinder, the base is used for being installed on a roof, an air inlet is formed in the base, indoor hot air enters the wind guide cylinder, one side of the wind guide cylinder is provided with a windward opening, the windward opening is used for enabling outdoor wind to enter the wind guide cylinder, the windward opening turns along with the wind direction of the outdoor wind, a wind-binding mechanism is arranged in the wind guide cylinder, and the wind-binding mechanism is used for carrying out wind-binding acceleration on the indoor hot air and the outdoor wind and guiding the indoor hot air into the turbine fan so as to enable the wind generating set to carry out wind power generation;

The air duct is rotationally connected between the turbine fan and the base, one side of the air duct is a windward side, the other side of the air duct is a leeward side, the windward side is arranged on the windward side, and the arc length of the windward side is longer than that of the leeward side, so that the air duct can rotate along with the wind direction of outdoor wind, and the windward side faces the wind direction of the outdoor wind; the base comprises an annular seat, a fixed shaft and a yaw mechanism, the inner ring of the annular seat forms the air inlet, the fixed shaft is vertically fixed in the inner ring of the annular seat, the bottom of the air duct is rotationally connected with the annular seat, and the air duct can rotate around the fixed shaft through the yaw mechanism; the yaw mechanism comprises a yaw planet wheel, a yaw rotating shaft, a connecting rod and a yaw planet wheel, wherein the yaw planet wheel and the fixed shaft are coaxially arranged in the annular seat, the yaw rotating shaft is vertically arranged, the top of the yaw rotating shaft is fixedly connected with the inner wall of the air duct through the connecting rod, and the bottom of the yaw rotating shaft is rotationally connected with the yaw planet wheel through the yaw planet wheel;

the air-blowing mechanism can separate the air duct so as to form a first air-blowing channel and a second air-blowing channel in the air duct, one end of the first air-blowing channel is communicated with the windward opening, the other end of the first air-blowing channel is communicated with the turbine fan, and the first air-blowing channel is used for blowing and accelerating the outdoor air and guiding the outdoor air into the turbine fan; one end of the second air-binding channel is communicated with the air inlet, the other end of the second air-binding channel is communicated with the turbine fan, and the second air-binding channel is used for carrying out air-binding acceleration on the indoor hot air and guiding the indoor hot air into the turbine fan; the beam fan mechanism comprises a first transverse air guide plate, a second transverse air guide plate and a vertical air guide plate, wherein the first transverse air guide plate and the second transverse air guide plate are obliquely arranged in the air guide cylinder, the first transverse air guide plate is used for separating the windward opening from the air inlet so that a first beam air channel and a second beam air channel are formed in the air guide cylinder, the second transverse air guide plate is arranged above the first transverse air guide plate, and the second transverse air guide plate is used for transversely separating the first beam air channel; the vertical air deflector penetrates through the first transverse air deflector and the second transverse air deflector, and the vertical air deflector is used for vertically separating the first air-bundling channel from the second air-bundling channel.

2. The breeze-driven generator utilizing wind and heat in combination according to claim 1, wherein: the turbine fan comprises a central shaft, an upper rotating disc, a lower rotating disc and fan blades, wherein the central shaft is fixed at the top of the fixed shaft and is coaxially arranged with the fixed shaft, and the upper rotating disc and the lower rotating disc are sequentially connected onto the central shaft in a rotating manner from top to bottom; the fan blades are provided with a plurality of fan blades, all the fan blades are uniformly distributed between the upper rotating disk and the lower rotating disk in a lantern shape, and an airflow channel is reserved between the adjacent fan blades; the wind generating set is arranged on the central shaft; the air duct is sleeved on the fixed shaft, and the top of the air duct is rotationally connected with the lower rotating disk.

3. The breeze-driven generator utilizing wind and heat in combination according to claim 1, wherein: and a ball is arranged between the bottom of the air duct and the annular seat.

4. The breeze-driven generator utilizing wind and heat in combination according to claim 2, wherein: the wind generating set comprises a generator main shaft, generator blades, a generator gear box, a speed increaser shaft and a wind driven generator, wherein the generator main shaft is rotationally sleeved on the central shaft, the generator blades are arranged at the bottom of the generator main shaft, and the generator main shaft is connected with the wind driven generator sequentially through the generator gear box and the speed increaser shaft.