KR20130104984A - Wind generator with ventilation function - Google Patents

Abstract

The present invention relates to a wind power generation device, and more particularly, the indoor air is forced by installing a suction vane connected to a power generation turbine inside a fan duct installed on a roof of a building or a roof of a factory to ventilate indoor air. The present invention relates to a wind power generator having a ventilation function for generating electricity by driving a turbine for power generation through a ventilation action of suctioning and discharging.
According to the present invention, as the suction wing is connected to the power generation turbine is installed in the inside of the fan duct installed on the roof of the building or the roof of the factory to ventilate the indoor air through the process of forcibly suctioning and exhausting the indoor air The indoor air is forcedly ventilated while the electric turbine is driven to perform electric power generation.

Description

Wind generator with ventilation function {Wind generator with ventilation function}

The present invention relates to a wind power generation device, and more particularly, the indoor air is forced by installing a suction vane connected to a power generation turbine inside a fan duct installed on a roof of a building or a roof of a factory to ventilate indoor air. The present invention relates to a wind power generator having a ventilation function for generating electricity by driving a turbine for power generation through a ventilation action of suctioning and discharging.

In general, modern human civilization has developed variously on the basis of fossil fuels, but recently, the fossil fuel's power generation means that the atmospheric environment of the earth is seriously polluted by pollutants generated when the fossil fuel is burned. Air pollution actually causes serious environmental destruction such as global warming, and there is a limit to the reserves of fossil fuels. Recently, due to the depletion of fossil fuels, the development of energy production means to replace fossil fuels is needed. to be.

Such eco-friendly alternative energy production means include wind power generators using wind power, hydropower generators using downpours, tidal power generators using tidal tide, and solar power generators using solar light to produce alternative energy due to exhaustion of fossil fuels. It is a situation that has been developed and used in various forms for the purpose.

As such, in the case of the wind power generator among the alternative energy production means, a large wind turbine for power generation, a large blade for driving the turbine, and a post on which the blade and the turbine are mounted, the windy area such as high ground Installed in a number of ways to operate the power turbine using natural wind to produce electric energy is applied.

However, in the case of a conventional wind turbine, a large number of wind turbines must be installed in a region and a high land where a large amount of wind is combined to operate a turbine for power generation. At the same time, electrical productivity is low compared to the investment cost, and there is a problem that it is not easy to operate the wind power generator because there is not enough air volume to produce electrical energy to be installed in a general urban center.

The present invention is to solve the above problems, by installing a suction wing connected to the power generation turbine in the interior of the ventilation fan duct installed on the roof of the building or the roof of the factory to ventilate the indoor air, thereby through the indoor air It is an object of the present invention to provide a wind turbine generator having a ventilation function for forcibly ventilating indoor air while driving the turbine for power generation and performing electric power generation by forced suction and discharge.

In addition, the present invention is to install the auxiliary power generator for operating the power generation turbine by the wind blowing from the outside in the fan duct to perform electricity generation using a small amount of wind blowing from the outside with self-generation using indoor air. There is another purpose.

According to an aspect of the present invention, A ventilator duct in which a suction inlet and a discharge outlet are formed in the upper portion of the tubular shape having a “a” shape to discharge air, and a power generation turbine is fixedly coupled to the inside to generate electricity; A first suction wing coupled to the outlet for interconnection with the power generation turbine, the first suction wing generating electricity by operating the power generation turbine while inhaling indoor air into the vent duct when the in-situ rotation operation is performed by external wind; A second suction wing coupled to the suction port to be interconnected with the power generation turbine, and configured to generate electricity by operating the power generation turbine when the rotary operation is performed in situ by the indoor air sucked through the first suction wing; It provides a wind turbine having a ventilation function, characterized in that made.

According to the present invention, as the suction wing is connected to the power generation turbine is installed in the inside of the fan duct installed on the roof of the building or the roof of the factory to ventilate the indoor air through the process of forcibly suctioning and exhausting the indoor air The indoor air is forcedly ventilated while the electric turbine is driven to perform electric power generation.

In addition, the auxiliary power generator for operating the power generation turbine by the wind blowing from the outside is installed in the fan duct can be used to perform electricity generation using a small amount of wind from the outside as well as self-generation using the indoor air. It has a different effect.

1 is a perspective view of a wind turbine having a ventilation function according to the present invention.
Figure 2 is a side sectional view of a wind turbine having a ventilation function according to the present invention.
3 is an operational state diagram of a wind turbine having a ventilation function according to the present invention.
4 to 5 is a view showing a wind turbine having a ventilation function according to another embodiment.

With reference to the accompanying drawings, a wind turbine having a ventilation function according to the present invention will be understood by the embodiments described in detail below.

1 to 2 are diagrams for explaining the wind turbine generator having a ventilation function according to the present invention.

According to the wind power generator 1 according to the present invention, the inlet 112 and the upper outlet 111 are formed in the lower portion of the tube shape having a shape of “a”, respectively, to discharge air, and to generate electricity inside. A fan duct 110 to which the power turbine 140 is fixedly coupled; The outlet 111 is coupled to the power turbine 140 to be connected to each other, and when the rotary operation in place by the external wind to operate the power turbine 140 while sucking the indoor air into the vent duct 110. A first suction wing 120 for producing electricity; It is coupled to the intake port 112 to be interconnected with the power generation turbine 140, when the in-place rotation operation by the indoor air sucked through the first suction wing 120 to operate the power generation turbine 140 It comprises a second suction wing 130 to produce electricity.

Hereinafter, the respective components will be described in detail.

First, the ventilation fan duct 110 is installed on the roof of a building or the roof of a factory and is provided to ventilate by discharging the indoor air to the outside. The ventilation duct 110 is an air of the room in the form of "a". It is manufactured in a tubular shape to be discharged, and the inlet 112 and the upper outlet 111 is formed in the lower portion respectively to ventilate the indoor air of the building by the action that the indoor air is sucked into the exhaust duct 110 and discharged. will be.

At this time, the power generation turbine 140 for producing electricity through the indoor air and the outside wind is fixedly coupled to the inside of the fan duct 110, the power generation turbine 140 is a power generator using a common wind power Since it is widely used to produce electricity by using the rotational force of the wind, a detailed description of the structure will be omitted.

In addition, the first suction vane 120 is provided to suck the indoor air of the building into the ventilator duct 110 as the in-situ rotation operation by using the wind blowing from the outside, the first suction vane 120 ) Is fixedly coupled to the inside of the ventilator duct 110 to rotate in place by coupling the power turbine 140 and the shaft to the outlet 111 side, the first suction blade 120 is the power turbine 140 And the first suction blade 120 is rotated in place by external wind to operate the power turbine 140 to produce electricity.

On the other hand, the first suction wing 120 is basically a coupling of one first suction wing 120 to the outside from the outlet 111 side as a single body, the outside and inside of the vent duct 110, if necessary The first suction wing 120 is made in a pair of forms to increase the electrical productivity of the power turbine 140 by increasing the rotational force of the first suction wing 120 in response to the wind blowing in a small amount will be.

The second suction wing 130 is connected to the power generation turbine 140 and rotates in place using indoor air sucked through the first suction wing 120, thereby generating the power generation turbine 140. It is provided to operate to produce electricity, the second suction wing 130 is fixed to the inside of the exhaust fan duct 110 by coupling with the power turbine 140 into the suction port 112 inside. The second suction wing 130 is connected to the power generation turbine 140 and rotates in place through indoor air to generate electricity by operating the power generation turbine 140.

On the other hand, the second suction wing 130 corresponds to the indoor air sucked in a small amount and the rotational force of the second suction wing 130 as the second suction wing 130 is coupled to the inside of the suction port 112 in a pair. To increase the electrical productivity of the power turbine 140 is to be increased.

In addition, a rotation means 150 is coupled to a lower circumference of the fan duct 110 to freely rotate the fan duct 110 up and down, and the rotation means 150 is generally manufactured in a circular rail. Alternatively, the fan duct 110 separated at the upper side is slid in a state in which the fan duct 110 is vertically separated by a bearing, and the fan duct 110 separated at the lower side is fixed to the roof of the building and the roof of the factory. The fan duct 110 may be freely rotated, and the rudder 113 for rotating the fan duct 110 through external wind is coupled to the center of the upper end of the fan duct 110 by rotating the fan. Through the means 150 and the rudder 113, the fan duct 110 is free to rotate.

On the other hand, Figure 3 is a view showing the operating state of the wind turbine having a ventilation function according to the present invention.

According to FIG. 3, the wind power generator 1 having the structure as described above rotates the first suction wing 120 through the outside wind of the building to force the suction and discharge the inside of the fan duct 110. It shows the state of producing electricity by operating the power turbine 140, when the first suction wing 120 of the wind turbine (1) is rotated in place through the outside wind the vent duct 110 is installed When the indoor air of the building is sucked into the ventilator duct 110 through the rotation of the first suction wing 120, if the indoor air is sucked into the ventilator duct 110 through the first suction wing (120). The second suction wing 130 is rotated in place by the indoor air sucked, the first suction wing 120 and the second suction wing 130 as described above through the rotation operation the turbine 140 for power generation To generate electricity.

Therefore, the indoor air is forcibly sucked and discharged using the first suction wing 120 and the second suction wing 130 to drive the power turbine 140 to perform electric power generation to force indoor air. There is a characteristic advantage that can be ventilated.

4 to 5 are views illustrating a wind power generator having a ventilation function according to another exemplary embodiment.

First, FIG. 4 is provided with a first auxiliary power generator 200 in a rearward direction of the fan duct 110 of the wind power generator 1, together with the first suction blade 120 and the second suction blade 130. As an exemplary embodiment for increasing the power generation efficiency by operating the power turbine 140, the first auxiliary power generator 200 and the ventilation fan duct 110 in the rearward direction of the first suction wing (120). An extension duct 210 extending integrally is formed, and the power generation turbine 140 is fixed to the extension duct 210 by the shaft coupling with the power generation turbine 140 inside the extension duct 210. When the external suction blade 220 is connected to each other and is rotated in place through the wind blowing from the outside when the external suction blade 220 is coupled to the power generation turbine 140 interconnected with the external suction blade 220 To generate electricity.

In addition, FIG. 5 is provided with a second auxiliary power generator 400 interconnected with the power generation turbine 140 at an upper portion of the fan duct 110 to provide the first suction wing 120 and the second suction wing ( In addition to 130 to illustrate another embodiment for increasing the power generation efficiency by operating the power turbine 140, the second auxiliary power generator 400 is projected on the top of the fan duct 110 to generate the power The horizontal rotary blade 410 is fixedly coupled to each other by the turbine turbine 140 and the shaft to be connected to the power turbine 140, and rotates in place through external wind, and is perpendicular to the outside of the fan duct 110. A plurality of external rotary blades 420 are installed by the support 421 is installed as, the external rotary blades 420 through the horizontal rotary blade 410 and the bevel gear 411 by the rotary shaft 422. The external rotary wing 420 when the wind blows from the outside is interconnected And the horizontal rotor blade 410 rotates in place to produce electricity as the power turbine 140 operates.

Therefore, the first auxiliary power generator 200 and the second auxiliary power generator 400 as described above can perform electric power generation by using a small amount of wind blowing from the outside as well as self-generation using indoor air. There will be advantages.

As described above. While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It will be understood by those skilled in the art that various changes, modifications, and alterations can be made by those skilled in the art.

1. Wind power generator 110. Ventilator duct
111.Outlet 112.Inlet
113. Rudder 120. First suction wing
130. 2nd suction wing 140. Turbine for power generation
150. Rotating means 200. First auxiliary generator
210. Extension duct 220. External suction wing
400. Second Auxiliary Generator 410. Horizontal Rotary Wing
411.Bevel Gear 420.External Rotating Blade
421. Holding 422. Rotating shaft

Claims (4)

Ventilator duct is fixed to the power inlet turbine 140 for producing electricity in the lower inlet 112 and the upper outlet 111 is formed in the lower portion of the "a" shape of the tubular shape ( 110);
The outlet 111 is coupled to the power turbine 140 to be connected to each other, and when the rotary operation in place by the external wind to operate the power turbine 140 while sucking the indoor air into the vent duct 110. A first suction wing 120 for producing electricity;
It is coupled to the intake port 112 to be interconnected with the power generation turbine 140, when the in-place rotation operation by the indoor air sucked through the first suction wing 120 to operate the power generation turbine 140 Wind turbines having a ventilation function, characterized in that it comprises a second suction wing 130 to produce electricity. The method of claim 1,
The lower periphery of the ventilator duct 110 is coupled to the rotating means 150 for freely rotating the ventilator duct 110 up and down, the ventilator duct 110 through the outside air in the upper center of the ventilator Wind turbine generator having a ventilation function, characterized in that the rudder 113 for rotating the duct 110 is further provided. The method of claim 1,
An extension duct 210 formed integrally with the ventilator duct 110 in a rearward direction of the first suction wing 120;
The outer duct 210 is made of an external suction blade 220 which is interconnected with the power generation turbine 140 to operate the power generation turbine 140 through the wind blowing from the outside to produce electricity. 1 Auxiliary generator 200 is a wind turbine having a ventilation function, characterized in that further provided. The method of claim 1,
A horizontal rotary blade 410 connected to the power turbine 140 at an upper portion of the fan duct 110 to operate the power turbine 140 in place by external wind;
It is coupled by the support 421 is installed vertically from the outside of the fan duct 110, the horizontal rotary blades 410 and the bevel gear 411 are interconnected through the in-situ rotation by the outside wind the power generation turbine Wind turbines having a ventilation function, characterized in that the second auxiliary power generator 400 made of an external rotary wing 420 to operate (140) is further provided.

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