KR101673916B1 - Power generation system using stack effect - Google Patents

Abstract

The present invention relates to a power generation system which does not need excavation of a deep road air passage and can perform stable power generation even though relatively less time and manpower and costs are required for construction thereof. The power generation system of the present invention includes: an air supply path formed vertically toward the underground on the ground; a connection path formed horizontally at a lower part of the air supply path; an air ventilation path formed vertically toward the ground at an end of the connection path at one side of the air ventilation path; a power generation part which is installed on an upper part of the air ventilation path, and has a wind power turbine generating power by air rising from the air ventilation path; a geothermal heat collection part which includes a borehole formed by being drilled underground to a lower part of the connection path, and a circulation pipe which is inserted into the borehole and accommodates water, and collects geothermal heat through the circulation pipe; and a heat exchange part which is installed between an upper part of the geothermal heat collection part and a lower part of the air ventilation path, and heats a lower part of the air ventilation path through the geothermal heat collected through the geothermal heat collection part.

Description

[0001] POWER GENERATION SYSTEM USING STACK EFFECT [0002]

The present invention relates to a power generation system using a stack effect, and more particularly, it relates to a power generation system using a stack effect that does not require excavation of an air passage with a high degree of accuracy, And a power generation system using the same.

Generally, the stack effect refers to a phenomenon called "chimney effect" in which the air in the vertical space is buoyant and moves to the upper side when the temperature in the vertical space is higher than the outside and the density (pressure) is lower. In this case, the direction in which the air moves in the vertical space differs depending on the temperature. When the internal temperature is higher than the external temperature, it flows from the lower side to the upper side.

2. Description of the Related Art Recently, various techniques for producing electricity by rotating a wind turbine with air flowing using the stacking effect have been developed. In particular, a variety of techniques have been proposed for heating the vertical space with geothermal heat to generate an air flow to generate a stack effect.

However, in order to generate a continuous stacking effect, a power generation system using a conventional geothermal heat generation system must excavate a vertical airway with a high degree of groundwater in the ground to form an air duct of a citron type, And it takes a lot of time, manpower and cost to construct.

Registered Patent No. 1221151 "Building Hybrid Ventilation and Power Generation System" (2013.01.04)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art,

SUMMARY OF THE INVENTION It is an object of the present invention to provide a power generation system using a stack effect, which requires no excavation of an airway path at a high level and thus ensures stable power generation despite a relatively short period of time and manpower and cost.

In order to achieve the above object, a "power generation system using a stack effect" according to the present invention comprises: an air supply passage vertically formed from a ground to a basement; A connection passage horizontally formed at a lower end of the air supply passage; An exhaust passage formed vertically from one end of the connection passage toward the ground to one side of the air supply passage; A power generator installed at an upper end of the exhaust passage and having a wind turbine to generate electricity by air raised in the exhaust passage; A geothermal heat collector for collecting geothermal heat through the circulation pipe, the geothermal heat collecting unit including a borehole formed in the lower part of the connection passage and a circulation pipe inserted into the borehole and receiving water therein; A heat exchanger installed between the upper part of the geothermal heat collecting part and the lower end of the exhaust passage and heating the lower end of the exhaust passage through the geothermal heat collected through the geothermal heat collecting part; .

Further, the power generation unit of the "power generation system using the stack effect" according to the present invention further comprises a vertical pipe vertically installed to communicate with the exhaust passage above the wind turbine.

Further, the circulation tube of the "power generation system using the stack effect" according to the present invention is characterized by being a tubular tube having a bottom end shape.

The heat exchanging unit of the "power generation system using the stack effect" according to the present invention includes a heat exchange tube wound around the lower end of the exhaust passage, and a heat exchange tube having an end portion of the heat exchange tube, A connection pipe connected between the end portions of the pipe, and a circulation pump installed on the pipe of the connection pipe and circulating the water.

Further, the heat exchanging unit of the " power generating system using the stack effect "according to the present invention is further characterized by a heat insulating member formed under the ground to surround the outer circumference of the heat exchanging tube and formed of a heat insulating material.

The present invention as described above has an effect that stable excavation of the air passage is not necessary due to a high degree of rigidity, so that stable power generation can be achieved despite the relatively short time, manpower and cost required for the construction.

1 is a schematic longitudinal section of a power generation system according to the present invention,
Figs. 2 to 4 are enlarged views of the essential parts of Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the invention can be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

1 to 4 are schematic views of a power generation system according to the present invention. As shown in the drawing, the power generation system using the stack effect according to the present invention includes an air supply passage 10 formed in the ground to the ground, a connection passage 20 formed at the lower end of the air supply passage 10, An exhaust passage 30 formed at the end of the passage 20 in the form of a ground, a power generating portion 40 installed at the upper end of the exhaust passage 30, And a heat exchanging unit 60 installed between the exhaust passage 30 and the geothermal heat collecting unit 50.

The air supply passage 10 is vertically formed from the ground toward the underground, and is formed toward the ground from the ground to a depth of several meters to several tens of meters, and serves to provide a passage through which the ground surface air flows toward the underground.

The connection passage 20 is horizontally formed at the lower end of the air supply passage 10 and is formed to have a length of several meters to connect the air supply passage 10 and the exhaust passage 30, (50) and the heat exchanging part (60).

The exhaust passage 30 is vertically formed at one side of the air supply passage 10 from the end of the connection passage 20 toward the ground to provide a passage through which air guided to the ground is raised.

The supply passage 10, the connection passage 20, and the exhaust passage 30 are schematically shown in the drawing, but it is preferable that the air intake passage 10, the exhaust passage 30 and the exhaust passage 30 are formed as a concrete structure after securing a space recessed from the ground through a tapper. The geothermal heat collecting unit 50 is installed immediately after securing a space recessed on the ground by the terahertz and then the air supply passage 10 and the connecting passage 20 are installed together with the installation of the heat exchanging unit 60, And the exhaust passage (30).

The power generating unit 40 includes a wind turbine 41 installed at an upper end of the exhaust passage 30 and configured to generate electricity by air raised in the exhaust passage 30, The wind turbine 41 is rotated to generate electricity.

The power generation unit 40 further includes a vertical pipe 42 vertically installed to communicate with the exhaust passage 30 at an upper portion of the wind turbine 41. The vertical pipe 42 maximizes the temperature difference between the exhaust passage 30 and the outside air to maximize the stacking effect.

The geothermal heat collecting unit 50 includes a borehole 51 drilled in the lower part of the connection passage 20 and a circulation pipe 52 inserted into the borehole 51 and receiving water therein, . The geothermal heat collecting unit 50 collects geothermal heat by exchanging heat between the underground heat and the water through the circulation pipe 52.

The borehole 51 is a vertical hole formed by drilling a few kilometers to several tens of kilometers underground by a drilling equipment. After the drilling is completed, the circulation pipe 52 is inserted, The heat transfer medium may be accommodated in the heat exchanger 51. Although the boreholes 51 are shown as one in the drawing, they may be provided as many as necessary.

The circulation pipe (52) receives water therein and transfers the heat generated by the geothermal heat to the heat exchange unit (60) while the water is circulated by the heat exchange unit (60). It is preferable that the circulation pipe 52 having such a function is provided as a tubular pipe having a lower end shape so as to facilitate the circulation of water.

The heat exchanging unit 60 is installed between the upper part of the geothermal heat collecting unit 50 and the lower end of the exhaust passage 30 and is connected to the exhaust passage 30 through the geothermal heat collected through the geothermal heat collecting unit 50. [ To provide an exhaust driving force for generating a stacking effect.

The heat exchange unit 60 includes a heat exchange tube 61 wound around the lower end of the exhaust passage 30 and an end portion of the heat exchange tube 61 so that the heat exchange tube 61 forms a closed circuit. A connection pipe 62 connected between the ends of the circulation pipe 52 and a circulation pump 63 installed on the pipe of the connection pipe 62 and circulating the water.

The heat exchange unit 60 is connected to the heat exchange pipe 61 from the connection pipe 62 to the connection pipe 62 from the circulation pipe 52 by the operation of the circulation pump 64, Water circulated through the connecting pipe 62 to the circulating pipe 52 through the connecting pipe 62 and the hot water heated by the geothermal heat received in the circulating pipe 52 is supplied to the connecting pipe 62, And circulates the heat to the heat exchange pipe (61) to heat the lower end of the exhaust passage (30) while releasing heat from the heat exchange pipe (61).

The heat exchanging unit 60 further includes a heat insulating member 64 installed in the bottom of the heat exchanging tube 61 so as to surround the outer circumference of the heat exchanging tube 61 and formed of a heat insulating material. The heat insulating member 64 serves to prevent heat from being radiated to the outside of the heat exchange pipe 61.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is clear that the present invention can be suitably modified and applied in the same manner. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

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 scope of the present invention.

10: Supply passage
20: connection passage
30: Outlet passage
40:
41: Wind turbine 42: Vertical tube
50: Geothermal heat collector
51: Borehole 52: Circulation tube
60: Heat exchanger
61: heat exchanger tube 62: connecting tube
63: circulation pump 64:

Claims (5)

An air supply passage (10) formed vertically from the ground to the underground;
A connection passage 20 horizontally formed at a lower end of the air supply passage 10;
An exhaust passage 30 vertically formed at one side of the air supply passage 10 from an end of the connection passage 20 toward the ground;
A power generator 40 installed at an upper end of the exhaust passage 30 and having a wind turbine 41 for generating electricity by air raised in the exhaust passage 30;
A borehole 51 drilled in the lower part of the connection passage 20 and a circulation pipe 52 inserted into the borehole 51 and receiving water therein, A geothermal heat collecting unit 50 for collecting geothermal heat by exchanging heat between the underground heat and water through the heat exchanger 52;
The geothermal heat collecting unit 50 is installed between the upper part of the geothermal heat collecting unit 50 and the lower end of the exhaust passage 30 and heats the lower end of the exhaust passage 30 through the geothermal heat collected through the geothermal heat collecting unit 50, A heat exchanging part (60) for providing an exhaust driving force for generating an exhaust gas; Including,
The heat exchanging part (60)
A heat exchange tube 61 wound around the lower end of the exhaust passage 30,
A connection pipe (62) connected between an end of the heat exchange pipe (61) and an end of the circulation pipe so that the heat exchange pipe (61) forms a closed circuit,
A circulation pump 63 installed on the pipe of the connection pipe 62 for circulating water,
And a heat insulating member (64) installed in the ground to surround the outer circumference of the heat exchange pipe (61) and formed of a heat insulating material.
The method according to claim 1,
The power generation unit (40)
A vertical tube 42 vertically installed in the upper portion of the wind turbine 41 so as to communicate with the exhaust passage 30,
Wherein the power generation system further comprises a stack effect.
The method according to claim 1,
The circulation pipe (52)
And the lower end is a curved pipe having a curved shape.
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