CN219795447U - Base station chimney type high-altitude wind power generation device - Google Patents

Abstract

The utility model provides a base station chimney type high-altitude wind power generation device, which comprises: the device comprises a chimney type steel pipe (3), a first storage battery bracket (4), a first storage battery (5), a first wind driven generator (8), a wind driven generator set (9), a second wind driven generator (11), a second storage battery (13), a second storage battery bracket (14), a chimney type steel pipe air inlet (15), blades (16), wherein the first storage battery bracket (4) and the second storage battery bracket (14) are respectively arranged on two sides of the chimney type steel pipe (3); the first storage battery (5) is arranged on a first storage battery bracket (4) of the bracket of the chimney type steel pipe (3); the second storage battery (13) is arranged on a second storage battery bracket (14) of the chimney type steel pipe (3); the power generation device can keep the stability of the wind driven generator through the base station on one hand, and can fully utilize the space of the base station on the other hand.

Description

Base station chimney type high-altitude wind power generation device

Technical Field

The utility model relates to a power generation device, in particular to a base station chimney type high-altitude wind power generation device.

Background

With the rapid development of the Internet in China, particularly the development of 5G, the demand of a signal transmitting base station for electric energy is higher and higher. Moreover, the territories in China are vast, and part of residents live in remote areas, so that the base station is specially built on a large scale for mobile phone signals. Therefore, the quantity of the base stations in recent years in China is greatly increased, and on one hand, the construction cost of the base stations is greatly increased; on the other hand, the base station has more and more electric energy requirements, and even a power grid needs to be specially built, and the power requirements of the base station are specially supplied, so that the cost is further increased. Wind power generation has the advantage of natural gas, and wind power resources in nature can be utilized to drive a generator to generate power. In addition, most of base stations are built on mountains, gao Shanfeng force is strong, and the base stations are very suitable for installation and power generation of wind driven generators.

Disclosure of Invention

In order to solve the problems in the prior art, the utility model provides a base station chimney type high-altitude wind power generation device which can be driven by air convection by utilizing high-altitude pressure difference.

The technical scheme of the utility model is to provide a base station chimney type high-altitude wind power generation device, which comprises: chimney type steel pipe, first battery support, first battery, first aerogenerator, wind generating set, second aerogenerator, second battery support, chimney type steel pipe air intake, blade, wherein:

the first storage battery bracket and the second storage battery bracket are respectively arranged at two sides of the chimney type steel pipe;

the first storage battery is arranged on a first storage battery bracket of the chimney type steel pipe bracket;

the second storage battery is arranged on a second storage battery bracket of the chimney type steel pipe;

the wind generating set comprises a first wind power generator and a second wind power generator;

the first wind driven generator and the second wind driven generator are arranged at the top end of a chimney type steel pipe, and a chimney type steel pipe air inlet is formed in the bottom end of the chimney type steel pipe;

the first wind driven generator and the second wind driven generator both comprise a plurality of blades.

Further, the first signal transmitter is arranged on a signal transmitter bracket of the chimney type steel pipe;

the second signal emitter is arranged on a signal emitter bracket of the chimney type steel pipe;

the first wind driven generator is connected with the first signal transmitter and supplies power;

the first wind driven generator is also connected with a first storage battery; the first storage battery can be used for electricity storage and discharging;

the second wind driven generator is connected with the second signal transmitter and supplies power;

the second wind driven generator is also connected with a second storage battery; the second battery can be used for storing and discharging electricity.

Further, the first storage battery is connected with the first signal transmitter and used for supplying power to the first signal transmitter;

the second storage battery is connected with the second signal transmitter and is used for supplying power to the second signal transmitter.

Further, the first storage battery and the second storage battery are respectively connected with the energy management controller through wires.

Further, the first signal transmitter and the second signal transmitter are respectively connected with the energy management controller through wires.

Further, a rainproof device is arranged vertically above the top of the chimney type steel pipe.

The beneficial effects of the utility model are as follows: according to the scheme, the wind driven generator is installed on the base station, so that the wind driven generator is installed inside the base station, on one hand, the stability of the wind driven generator can be kept through the base station, and on the other hand, the space of the base station can be fully utilized. Meanwhile, the wind driven generator can directly supply power to the signal transmitter, so that the dependence on an external power grid is reduced, a plurality of energy storage batteries are additionally arranged, even the self-sufficiency of the electricity consumption of the base station can be realized, and the electricity consumption cost of the base station can be greatly reduced.

Drawings

Fig. 1 is a schematic diagram of a base station chimney type high-altitude wind power generation device and a control method:

FIG. 2 is a schematic diagram of a wind turbine integration;

FIG. 3 is a schematic view of a vane pack;

the energy-saving type energy-saving device comprises a base station base, a 2-base mounting mechanism, a 3-chimney type steel pipe, a 4-first storage battery bracket, a 5-first storage battery, a 6-energy management controller, a 7-first signal transmitter, an 8-first wind driven generator, a 9-blade set, a 10-wind driven generator shaft, a 11-second wind driven generator, a 12-second signal transmitter, a 13-second storage battery, a 14-second storage battery bracket, a 15-chimney type steel pipe air inlet and 16-blades.

Detailed Description

The technical scheme of the utility model is further specifically described below with reference to fig. 1-3.

As shown in fig. 1, this embodiment provides a base station chimney type high-altitude wind power generation device, including: the system comprises a chimney type steel pipe 3, a first storage battery bracket 4, a first storage battery 5, a first wind driven generator 8, a wind driven generator set 9, a second wind driven generator 11, a second storage battery 13, a second storage battery bracket 14, a chimney type steel pipe air inlet 15 and blades 16.

The first storage battery bracket 4 and the second storage battery bracket 14 are respectively arranged on two sides of the chimney type steel pipe 3 through bolts and used for balancing the overturning moment of the base station base 1 and guaranteeing the stability of the base station base 1.

The first storage battery 5 is mounted on a first storage battery bracket 4 of the bracket of the chimney type steel pipe 3 through bolts;

the second storage battery 13 is mounted on a second storage battery bracket 14 of the chimney-type steel pipe 3 through bolts;

the first storage battery 5 and the second storage battery 13 are connected with the energy management controller 6 through wires, and the energy management controller 6 monitors the charge states of the first storage battery 5 and the second storage battery 13 in real time.

The first signal emitter 7 is mounted on the bracket of the chimney type steel pipe 3 through bolts;

the second signal emitter 12 is mounted on the support of the chimney type steel pipe 3 through bolts.

The first signal transmitter 7 and the second signal transmitter 12 are used for the base station to transmit wireless communication signals outwards;

the wind generating set 9 comprises a first wind generator 8 and a second wind generator 11;

the specific parameters of the first wind power generator 8 and the second wind power generator 11 are as follows:

rated power: 10kW

Rated rotational speed: 1500r/min, less than 110% of stable operation;

efficiency is that: about 68%

Insulation grade: F/H

Protection grade: IP54

The cooling mode is as follows: forced air cooling.

In other embodiments, the wind power generation set 9 may further include one wind power generator or more than three wind power generators.

The first wind driven generator 8 and the second wind driven generator 11 are arranged at the top end of the chimney type steel pipe 3, a chimney type steel pipe air inlet 15 is formed at the bottom end of the chimney type steel pipe 3, natural convection of air can be formed at the pressure difference of the two ends of the chimney type steel pipe 3, strong wind speed is formed through the top end of the chimney type steel pipe 3, and accordingly the blades 16 are blown to rotate, and the rotating blades 16 drive the wind driven generator shaft 10 to rotate, so that wind power generation is achieved.

The first wind power generator 8 and the second wind power generator 11 each include a plurality of blades 16.

The wind power generator generates electricity to supply power to the first signal emitter 7 and the second signal emitter 12 on one hand, and the first storage battery 5 and the second storage battery 13 can be charged by redundant electric quantity on the other hand.

The energy management controller 6 detects the states of charge of the first storage battery 5 and the second storage battery 13 in real time, detects the generated energy of the first wind driven generator 8 and the generated energy of the second wind driven generator 11 in real time, and detects the electricity consumption requirements of the first signal transmitter 7 and the second signal transmitter 12 in real time.

When the energy management controller 6 monitors that the generated energy of the first wind driven generator 8 and the generated energy of the second wind driven generator 11 are higher, the generated energy of the wind driven generator preferentially supplies power to the first signal emitter 7 and the second signal emitter 12, so that the signal quality of the first signal emitter 7 and the second signal emitter 12 is ensured; the surplus power generation amount is stored in the first battery 5 and the second battery 13.

When the energy management controller 6 monitors that the generated energy of the first wind driven generator 8 and the generated energy of the second wind driven generator 11 can only meet the power consumption requirement of the signal transmitters, the generated energy of the wind driven generator is fully supplied to the power consumption requirement of the first signal transmitter 7 and the second signal transmitter 12, and the signal quality of the first signal transmitter 7 and the second signal transmitter 12 is guaranteed.

When the energy management controller 6 monitors that the generated energy of the first wind driven generator 8 and the generated energy of the second wind driven generator 11 cannot meet the power consumption requirement of the signal transmitters, the generated energy of the wind driven generator is fully supplied to the power consumption requirement of the first signal transmitter 7 and the second signal transmitter 12, and meanwhile, the first storage battery 5 and the second storage battery 13 supply power to the first signal transmitter 7 and the second signal transmitter 12 at the same time, so that the signal quality of the first signal transmitter 7 and the second signal transmitter 12 is guaranteed.

The power generation device comprises a base station base 1 and a base mounting machine 2, wherein a chimney type steel pipe 3 is mounted on a base mounting mechanism 2 of the base station base 1, the chimney type steel pipe 3 can be fixed by the base mounting mechanism 2, and the base mounting mechanism 2 of the base station base 1 can be fully utilized for damping.

In other embodiments, more signal transmitters may be provided to satisfy the role of the base station to transmit multiple wireless signals.

In other embodiments, the base station chimney type high-altitude wind power generation device can be provided with only a single wind power generator.

In other embodiments, a rain-proof device (not shown in the figure) is also installed vertically above the top of the chimney-type steel pipe 3.

In other embodiments, a speed increaser may be disposed on the rotating shaft of the generator, so as to improve the efficiency of power generation. The type of the speed increaser can be a vertical planetary type speed increaser with horizontal output.

While the utility model has been disclosed in terms of preferred embodiments, the embodiments are not intended to limit the utility model. Any equivalent changes or modifications can be made without departing from the spirit and scope of the present utility model, and are intended to be within the scope of the present utility model. The scope of the utility model should therefore be determined by the following claims.

Claims (4)

1. A base station chimney type high altitude wind power generation device, comprising: chimney type steel pipe (3), first battery support (4), first battery (5), first aerogenerator (8), wind generating set (9), second aerogenerator (11), second battery (13), second battery support (14), chimney type steel pipe air intake (15), blade (16), its characterized in that:

the first storage battery bracket (4) and the second storage battery bracket (14) are respectively arranged at two sides of the chimney type steel pipe (3);

the first storage battery (5) is arranged on a first storage battery bracket (4) of the bracket of the chimney type steel pipe (3);

the second storage battery (13) is arranged on a second storage battery bracket (14) of the chimney type steel pipe (3);

the wind generating set (9) comprises a first wind power generator (8) and a second wind power generator (11);

the first wind power generator (8) and the second wind power generator (11) are arranged at the top end of the chimney type steel pipe (3), and a chimney type steel pipe air inlet (15) is formed in the bottom end of the chimney type steel pipe (3);

the first wind power generator (8) and the second wind power generator (11) each comprise a plurality of blades (16).

2. The base station chimney type high-altitude wind power generation device according to claim 1, wherein:

the first signal emitter (7) is arranged on a signal emitter bracket of the chimney type steel pipe (3);

the second signal emitter (12) is arranged on a signal emitter bracket of the chimney type steel pipe (3);

the first wind driven generator (8) is connected with the first signal transmitter (7) and supplies power;

the first wind driven generator (8) is also connected with a first storage battery (5); the first accumulator (5) can be used for storing and discharging electricity;

the second wind driven generator (11) is connected with the second signal transmitter (12) and supplies power;

the second wind driven generator (11) is also connected with a second storage battery (13); the second accumulator (13) can be used for storing and discharging electricity.

3. The base station chimney type high-altitude wind power generation device according to claim 2, wherein: the first storage battery (5) is connected with the first signal transmitter (7) and is used for supplying power to the first signal transmitter (7);

the second storage battery (13) is connected with the second signal emitter (12) and is used for supplying power to the second signal emitter (12).

4. The base station chimney type high-altitude wind power generation device according to claim 2, wherein: a rainproof device is arranged vertically above the top of the chimney type steel pipe (3).