KR101480852B1 - Composite power generating device mounted on the building - Google Patents

Abstract

The present invention relates to a power generation apparatus mounted to a sidewall of a building that generates the electricity by using wind at the upper portion of the building and sunlight radiated on a wide area of the sidewall. The power generation apparatus includes a housing formed lengthwise in the vertical direction, with a front portion and upper and lower portions being opened; a plurality of guide blocks disposed in the housing at regular intervals, and guiding a direction of wind from a front space of the housing to a rear space; rotation blades disposed on the upper portion of the guide blocks and rotated by the wind guided to the space formed between the guide blocks; a generator connected to the rotating blades to generate the electricity; and a solar panel disposed on the top surfaces of the guide blocks.

Description

{Composite power generating device mounted on the building}

The present invention relates to a building-mounted wind power generator, and more particularly, to a building-mounted wind power generator having a structure attached to a side wall of a building to generate wind generated from the upper side of the building, Generating device.

Because wind power has the advantage of obtaining electricity at low cost, it is attracting attention as an alternative to pollution and environmental pollution problems that are facing the present fossil energy and as pollution-free alternative energy.

There are large wind power generation systems and small wind power generation systems for wind power generation, and large wind power generation systems using large blades have advantages of lower power generation cost compared to small wind power generation systems. However, the small wind power generation apparatus has an advantage that it can generate power at a relatively low wind speed as compared with a large wind power generation apparatus.

In the prior art, it is general to install a separate power tower on the roof of the building and to mount the blade on the power tower.

However, there is a limitation in that a sufficient number of wind power generators can not be installed on the roof of a limited building due to the restriction that a sufficient separation distance is required between the wind turbines using the blades, .

In addition, the wind turbine device using such a blade tends to be reluctant to install because it hurts the appearance of the building.

And, to increase the energy efficiency of the building, it is a common installation method to install a solar module on the roof of a building. However, in this case, the roof of the building is occupied by the solar power module, which is not desirable for space utilization of the building. In addition, in the case of a building, especially a high-rise building, since the area receiving the sunlight is large, there is a problem that a large amount of energy is consumed in the air conditioner in order to maintain the temperature.

Korean Patent Laid-Open No. 10-2012-0109889

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a building-mounted power generation device that generates electricity by using wind generated from the upper side of a building attached to a side wall of a building, .

To achieve the above object, according to the present invention, there is provided a mobile communication terminal comprising: a housing having a front and a top and a bottom; A plurality of guide blocks arranged at predetermined intervals in the housing to guide the wind direction of the front space of the housing to the rear space of the housing; A rotary blade disposed on the guide block and rotated by wind guided to a space formed between adjacent guide blocks; A generator connected to the rotary vane to generate electricity; And a solar panel disposed on an upper surface of the guide block.

The guide block is characterized in that the wind separation tip is formed so as to divide the wind at the lower end portion.

In addition, a rotary blade seat groove is recessed at an upper end of the guide block so as to have a space for rotating the rotary blade.

In addition, convex upper and lower concave portions are formed on the upper surface of the guide block, convex lower convex portions are formed on the lower surface of the guide block, convex upper convex portions are formed on the upper surface of the guide block, The lower surface concave portion and the upper surface concave portion are formed as a continuous curved surface, and the lower surface convex portion and the lower surface concave portion are formed as continuous curved surfaces.

In addition, a block waist is formed at a portion where the lower surface concave portion becomes the upper surface concave portion and the lower surface convex portion changes to the lower surface concave portion at a thickness smaller than the circumference.

Further, when two or more guide blocks are provided vertically adjacent to each other, the rotary vanes are located on the rear side of the upper lower surface convex portion.

Further, the guide block is characterized by being made of a transparent body or an opaque body.

Through the present invention, it is possible to minimize the influence on the overall appearance of the building while utilizing the side wall of the building as a place for producing electric energy. It is also possible to produce electricity continuously from the air movement existing in the outer wall of the building.

In addition, the module can be modularized to minimize the thickness protruding from the building exterior wall while covering the entire side wall of the building in order to improve the electric production capacity.

Particularly, it has an additional effect that it is possible to generate electricity by sunlight at the same time of power generation using wind power by burying the solar module on the surface, and to suppress temperature rise in the building due to absorption of sunlight.

1 is a perspective view of a building-mounted hybrid electric power generating apparatus according to an embodiment of the present invention
2 is a cross-sectional view of the building-mounted hybrid electric power generating apparatus of FIG.
Fig. 3 is a perspective view of the building-mounted combined-cycle power generating apparatus of Fig. 1 installed on an outer wall of a building.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components, and the same reference numerals will be used to designate the same or similar components. Detailed descriptions of known functions and configurations are omitted.

There is always a movement of air around the building, that is, the wind. In the present invention, the amount of wind power generation is increased by inducing the movement of the wind, and solar power generation is simultaneously performed by the solar panel. Therefore, the building-mounted combined cycle power generation system 100 according to the embodiment of the present invention is designed to be capable of both wind power generation and solar power generation.

The building-mounted combined cycle power generation apparatus 100 according to an embodiment of the present invention includes a housing 102 having a front portion and a top portion opened and a top portion and a long portion formed upward and downward, A rotating blades 106 disposed on the guide block 104 and rotated by the wind guided by the guide block 104 and connected to the rotating blades 106, (Not shown) for generating electricity, and a solar panel 108 disposed on the upper surface of the guide block 106.

The housing 102 has a substantially "C" shape and a rear surface is provided on the outer wall of the building 10. Alternatively, two plates may be provided on the outer wall of the building 10 in the longitudinal direction with an interval therebetween, and the outer wall of the building may be utilized as the bottom surface of the rear space 124. As shown in FIG. 3, the housing 102 may be disposed in contact with the width direction. The length of the housing 102 may be increased to increase the number of the guide block 104 and the rotary blades 106 in one housing 102. However, the housing 102 of the same size may be stacked in the longitudinal direction It is also possible to install it. In this case, the housing 102 should be aligned so that the wind can rise along the rear space 124 without being disturbed.

The guide block 104 can design a cross-sectional shape for guiding the wind, but basically, the guide block 104 has several characteristic components.

First, the guiding block 104 is formed with a wind separation tip 110 which is divided into upper and lower portions of the guide block 104 by dividing the wind at the lower end thereof. The direction of the wind separation tip 110 can be determined by a repeated experiment or an optimum design between the horizontal direction and the vertical direction.

The guide block (104) has an upper surface and a lower surface that are different from each other on the wind separation tip (110). That is, a concave upper surface lower concave portion 112 is formed on the upper surface of the guide block 104 and a convex lower surface convex portion 116 is formed on the lower surface of the guide block 104. In the upper portion of the guide block 104, The upper surface convex portion 114 is formed, and a concave lower surface concave portion 118 is formed on the lower surface. Accordingly, the guide block 104 has a unique curved surface as a whole, and the thickness thereof increases from the wind separation tip 110 toward the upper side.

At this time, the upper surface lower concave portion 112 and the upper surface upper concave portion 114 are formed into a continuous curved surface, and the lower surface convex portion 116 and the lower surface concave portion 118 are formed into a continuous curved surface Is formed.

However, in order to secure a space for the airflow that has passed through the rotary vanes 106 disposed above the guide block 104 on the lower side of the guide block 104 adjacent to the direction of wind, the upper surface concave portion A block waist 126 is formed at a portion where the upper lower concave portion 116 is in contact with the upper surface concave portion 118 and the lower lower convex portion 112 is changed into the lower surface concave portion 114 .

The guide block 104 is basically constructed as described above, and the fine profile can be determined by repeated experimentation or optimal design.

In addition, the rotary blind spot groove 120 may be formed concavely at an upper end of the guide block 104 so as to have a space for rotating the rotary blades 106. As a result, the interval between the adjacent guide blocks 104 can be prevented from becoming unnecessarily large due to the rotary vane 106, and the speed of the wind can be further increased by narrowing the interval.

The rotary vane 106 is rotatably fixed to the guide block 104. When the rotary vane 106 is rotated by the wind, the rotary vane 106 is rotated to generate electric power. Particularly, when two or more guide blocks are provided adjacent to each other, the rotary vane 106 is positioned on the rear side of the lower surface lower convex portion 116 and is directed toward the rear space 124, The wind will be blown.

With this configuration, the wind in the front space 122 is moved to the rear space 124 by the guide block 104, and the air gathered in the rear space 124 is moved upward. Therefore, the rotary vane 106 is supplied to the rear space 124 from the front space 122, and the air is supplied to the rear space 124 through the lower guide block 104, As shown in Fig.

A solar panel 108 is attached to the upper surface of the guide block 104. The solar panel 108 is preferably embedded so as not to interfere with wind movement. The solar panel 108 uses a known technology, and a detailed description thereof will be omitted. Therefore, since the area where the solar panel 108 is mounted absorbs sunlight or reflects sunlight, the incident amount of sunlight can be reduced in a building, thereby suppressing an increase in temperature in the building.

Particularly, when the housing 102 is the outer wall of the building 10, when the outer wall of the building is made of glass and the sunlight is incident on the wall, the solar panel 108 reduces the incidence of sunlight, There is a fear of darkening me. Therefore, the guide block 104 is made of a transparent body or a translucent body, and sunlight is received through an area not covered by the solar panel 108, so that the illumination in the building can be made smooth and comfortable without glare. That is, the guide block 104 can serve as a light diffuser of sunlight.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the appended claims. It can be understood that

10: Building 100: Build-in wind power generator
102: housing 104: guide block
106: Rotating blade 108: Solar panel
110: wind separation front end 112: upper surface lower concave portion
114: Lower surface convex portion 116: Upper surface convex portion
118: Lower surface concave portion 120: Rotating blade seat groove
122: front space 124: rear space
126: Block waist

Claims (7)

A housing having a front side and an upper side and an upper side opened and formed to be vertically long;
A plurality of guide blocks arranged at predetermined intervals in the housing to guide the wind direction of the front space of the housing to the rear space of the housing;
A rotary blade disposed on the guide block and rotated by wind guided to a space formed between adjacent guide blocks;
A generator connected to the rotary vane to generate electricity; And
And a solar panel disposed on an upper surface of the guide block,
A convex lower surface convex portion is formed on a lower surface of the guide block, a convex upper surface convex portion is formed on an upper surface of the guide block, and a concave lower surface concave portion is formed on a lower surface of the guide block, Wherein the upper surface concave portion and the upper surface upper convex portion are formed in a continuous curved surface, and the lower surface convex portion and the lower surface concave portion are formed in a continuous curved surface.
[2] The building-mounted combined cycle power generation system of claim 1, wherein the guide block is formed with a sharp wind separation front end so as to divide the wind at the lower end thereof.
The building-mounted combined cycle power generation system according to claim 1, wherein a rotary blade seat groove is recessed at an upper end of the guide block so as to have a space for rotating the rotary blade.
delete 2. The building-mounted structure according to claim 1, characterized in that a block waist is formed in a section where the lower surface concave portion is formed into the upper surface convex portion and the lower surface convex portion is changed into the upper surface concave portion, Combined power generation equipment.
The building-mounted combined cycle power generation system according to claim 1, wherein, when two or more guide blocks are installed vertically adjacent to each other, the rotary blades are located on the rear side of the lower side lower convexity.
The building-mounted combined cycle power generation system according to claim 1, wherein the guide block is made of a transparent body or an opaque body.

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