KR102094146B1 - Solar updraft powerplant having crane - Google Patents

Abstract

One embodiment of the present invention is installed on the ground, the roof spaced apart from the roof; A pedestal disposed in the center of the roof and communicating with a space between the roof and the ground, and a plurality of wind tunnels formed by extending from the intake; A pillar extending from the pedestal upward and forming an upper tunnel in communication with the wind tunnel; A protrusion projecting upward from an upper surface of the pedestal, surrounded by the pillar, and spaced apart from the pillar; A turbine installed in the wind tunnel; And includes a crane installed on the upper portion of the pedestal, the opening of the plurality of wind tunnels, has a shape surrounding the projection, the crane, the horizontal beam moving along the outer periphery of the projection; And it is possible to provide a solar heat rising airflow power plant having a hoist installed in the horizontal beam.

Description

SOLAR UPDRAFT POWERPLANT HAVING CRANE}

The present invention relates to a solar thermal power plant, and more particularly, to a solar thermal power plant with a crane.

A solar updraft tower is a facility for generating electric power from relatively low temperature solar heat. The solar upward airflow tower may be referred to as a “solar upward airflow power plant”. Sunlight heats air in collectors, such as very large greenhouses, and the heated air can form an upward stream in the chimney. This flow of air can drive wind turbines to generate power.

The solar rising airflow tower is a large-scale facility and may have difficulty in terms of maintenance. In particular, maintenance of a generator installed in a flow-path of air may be a problem. Therefore, there is a need for a solar rising air tower that is easy to maintain for a generator located in an air path that is difficult to access.

US 7956487 B2

The technical problem to be achieved by the present invention is to provide a solar thermal power plant with a crane.

Another technical problem of the present invention is to provide a solar thermal power plant with easy maintenance.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those skilled in the art from the following description. There will be.

According to an aspect of the present invention, the present invention is installed on the ground, the roof spaced apart from the roof; A pedestal disposed in the center of the roof and communicating with a space between the roof and the ground, and a plurality of wind tunnels formed by extending from the intake; A pillar extending from the pedestal upward and forming an upper tunnel in communication with the wind tunnel; A protrusion projecting upward from an upper surface of the pedestal, surrounded by the pillar, and spaced apart from the pillar; A turbine installed in the wind tunnel; And includes a crane installed on the upper portion of the pedestal, the opening of the plurality of wind tunnels, has a shape surrounding the projection, the crane, the horizontal beam moving along the outer periphery of the projection; And it is possible to provide a solar heat rising airflow power plant having a hoist installed in the horizontal beam.

The solar rising air flow power plant according to the embodiment of the present invention may include a crane.

The solar thermal power plant according to an embodiment of the present invention may be easy to maintain.

It should be understood that the effects of the present invention are not limited to the above-described effects, and include all effects that can be deduced from the configuration of the invention described in the detailed description or claims of the present invention.

1 and 2 is a view showing a solar thermal power plant according to an embodiment of the present invention.
3 to 5 are views showing various aspects of a crane according to an embodiment of the present invention.
6 to 8 are views showing an entrance and a hatch according to an embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings. However, the present invention may be implemented in various different forms, and thus is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and like reference numerals are assigned to similar parts throughout the specification.

Throughout the specification, when a part is "connected (connected, contacted, coupled)" to another part, this is not only when it is "directly connected", but also "indirectly" with another member in between. "It also includes the case where it is. Also, when a part is said to “include” a certain component, this means that other components may be further provided instead of excluding the other component unless otherwise stated.

The terms used in this specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this specification, terms such as “include” or “have” are intended to indicate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, and that one or more other features are present. It should be understood that the existence or addition possibilities of fields or numbers, steps, operations, components, parts or combinations thereof are not excluded in advance.

Referring to FIG. 1, a solar updraft power plant 100 according to an embodiment of the present invention may be installed on the ground 50. The solar rising airflow power plant 100 may be referred to as a “power plant”. The solar upward airflow power plant 100 may be referred to as a “solar upward airflow power plant with a crane”.

The solar rising airflow power plant 100 may include a chimney 200 and a roof 250. The place where the solar thermal airflow power plant 100 is installed may be an area where the annual precipitation is small and the amount of solar radiation is high due to drying.

The roof 250 may be installed on the ground 50. A portion of the roof 250 may communicate with the outside. For example, at least a portion of the outer circumference of the roof 250 may be spaced apart from the ground 50. The roof 250 may form an uphill slope in a direction from the outer periphery toward the center.

A space may be formed between the roof 250 and the ground 50. Air may be located in a space between the roof 250 and the ground 50. The air located between the roof 250 and the ground 50 may be referred to as “internal air”. Air located outside the roof 250 may be referred to as “outside air”.

At least a portion of the sunlight incident on the roof 250 from the top of the roof 250 may provide thermal energy to the roof 250. Another portion of the sunlight incident on the roof 250 from the top of the roof 250 may pass through the roof 250. The sunlight transmitted through the roof 250 may provide thermal energy to the internal air.

The internal air may be supplied with heat energy by sunlight or heat energy from the roof 250. The temperature of the internal air can be increased by sunlight. When the temperature of the internal air rises, the density of the internal air may decrease. When the density of the internal air is lowered, the internal air may move toward the center of the roof 250 along the slope of the roof 250.

When the inside air moves toward the center of the roof 250, a difference in air pressure may occur between the inside and the outside of the roof 250. External air may be introduced between the roof 250 and the ground 50 by the air pressure difference. The internal air may be directed to the chimney 200 located at the center of the roof 250. In this sense, the roof 250 may be referred to as a “collector” or a “heat collector”.

The chimney 200 may include a pillar 210 and a pedestal 220. The pedestal 220 may be located between the ground 50 and the pillar 210. The pedestal 220 may support the pillar 210. The pedestal 220 may be installed on the ground 50.

The lower portion of the pedestal 220 may be referred to as a base 230. The base 230 may be installed on the ground 50. The upper portion of the pedestal 220 may be located above the base 230. The pedestal 220 coupled to the base 230 may mean a pedestal 220 in a narrow sense. The pedestal 220 in a narrow sense may mean the pedestal 220 located on the upper portion of the base 230. The pedestal 220 in a broad sense can be understood as a concept encompassing the pedestal 220 and the base 230 in a narrow sense.

The chimney 200 may include a pillar 210 and a pedestal 220 and a base 230. The base 230 may be installed on the ground 50. The pedestal 220 may be installed on the top of the base 230. The pillar 210 may be installed on the top of the pedestal 220.

The suction port 240 may be formed on the base 230. A plurality of suction ports 240 may be formed. Internal air may be introduced into the intake port 240. The inside air introduced into the intake 240 may be discharged to the outside through the pedestal 220 and the pillar 210. In the process in which the internal air moves from the intake 240 through the pedestal 220 toward the pillar 210, power generation using the flow of the internal air may be performed.

The base 230 may protrude with the suction port 240 interposed therebetween. The protruding shape of the base 230 may guide internal air to the intake port 240. That is, the protruding shape of the base 230 with the inlet 240 interposed therebetween can increase the pressure of the internal air flowing into the inlet 240. Therefore, the protruding shape of the base 230 can increase the efficiency of power generation using the flow of internal air.

2, a cross-sectional perspective view of the chimney 200 can be observed. The tunnel 300 may be formed in the chimney 200. The tunnel 300 may be in communication with the suction port 240.

The tunnel 300 may include a wind tunnel 310. The wind tunnel 310 may be formed to extend from the suction port 240. The wind tunnel 310 may include a horizontal portion 311, a bending portion 313, and a vertical portion 315. The internal air flowing into the intake port 240 may sequentially pass through the horizontal portion 311, the bending portion 313, and the vertical portion 315.

The horizontal portion 311 may be formed to extend from the suction port 240 toward the center of the base 230. The horizontal portion 311 may be formed on the base 230. The horizontal portion 311 may be substantially parallel to a horizontal plane.

The bending portion 313 may extend from the horizontal portion 311 but bend toward the upper portion. The bending portion 313 may communicate with the horizontal portion 311. The direction of movement of the internal air may be switched in the bending portion 313. That is, the internal air moving in the horizontal direction from the horizontal portion 311 may reach the bending portion 313 and move in the vertical direction.

The vertical portion 315 may extend from the bending portion 313 toward the top. The vertical portion 315 may communicate with the bending portion 313. The vertical portion 315 may communicate with the interior of the pillar 210.

The tunnel 300 may include an upper tunnel 340. The upper tunnel 340 may be formed on the pillar 210. The upper tunnel 340 may be understood as a hollow portion formed in the pillar 210. The upper tunnel 340 may communicate with the outside at an upper end of the pillar 210.

The tunnel 300 may include a jet tunnel 320 and a branching tunnel 330. The jet tunnel 320 may be formed at the center of the pedestal 220. The jet tunnel 320 may communicate with the upper tunnel 340. The jet tunnel 320 may communicate with the wind tunnel 310 through the branch tunnel 330. A portion of the internal air introduced into the branch tunnel 330 may pass through the branch tunnel 330 and enter the jet tunnel 320.

The jet tunnel 320 may be narrowed toward the upper portion. For example, the upper opening of the jet tunnel 320 may be smaller than the upper opening of the wind tunnel 310. The velocity of internal air passing through the jet tunnel 320 and toward the upper tunnel 340 may be greater than the velocity of internal air passing through the vertical portion 315 of the wind tunnel 310 and toward the upper tunnel 340. . The internal air passing through the jet tunnel 320 may increase the speed of the internal air in the upper tunnel 340 as a whole. Therefore, by the jet tunnel 320, the pressure inside the upper tunnel 340 may be relatively low. When the pressure inside the upper tunnel 340 is lowered, the speed of the internal air passing through the wind tunnel 340 may be increased.

The turbine 500 (see FIG. 5) may be installed in the vertical portion 315 of the wind tunnel 310. The turbine 500 (see FIG. 5) may include a generator, and the higher the speed of air passing through the turbine 500 (see FIG. 5), the higher the power output. By the jet tunnel 320, the turbine 500 (see FIG. 5) can produce relatively high power output.

Referring to FIG. 3, the protrusion 225 may be formed to protrude upward from the pedestal 220. The side surface of the protrusion 225 may be surrounded by a pillar 210. The protrusion 225 may be spaced apart from the pillar 210. The openings of the plurality of wind tunnels 310 may be located between the protrusions 225 and the pillars 210.

The boundary between the inner circumferential surface of the pillar 210 and the pedestal 220 may be referred to as a “first boundary”. The opening of the wind tunnel 310 may be located inside the first boundary. The boundary between the protrusion 225 and the pedestal 225 may be referred to as a “second boundary”. The opening of the wind tunnel 310 may be located between the first boundary and the second boundary. The crane 700 may be disposed between the first boundary and the second boundary.

The crane 700 may be installed inside the pillar 210. The crane 700 may be used to maintain parts and the like located inside the power plant 100. For example, the crane 700 may be used to maintain the turbine 500 (see FIG. 5) installed inside the wind tunnel 310.

The crane 700 may include an inner rail (711). The inner rail 711 may be installed on the outer peripheral surface of the protrusion 225. The inner rail 711 may have a shape of a ring. The protrusion 225 may have a shape inserted into the inner rail 711. The inner rail 711 may be spaced upward from the pedestal 220.

The crane 700 may include an outer rail 713. The outer rail 713 may be installed on the inner circumferential surface of the pillar 210. The outer rail 713 may be spaced upward from the pedestal 220. The outer rail 713 may be spaced apart from the pedestal 220 at the same level as the inner rail 711. For example, the height of the outer rail 713 from the pedestal 220 may be the same as the height of the inner rail 711 from the pedestal 220. The outer rail 713 may form a plane. The plane formed by the outer rail 713 may be the same as the plane formed by the inner rail 711. The plane formed by the outer rail 713 may be parallel to a horizontal plane. The rail 710 may be understood as a concept including the outer rail 713 and the inner rail 711.

The crane 700 may include a horizontal beam 720. The horizontal beam 720 may connect the inner rail 711 and the outer rail 713. The horizontal beam 720 can rotate from the center of the protrusion 225. The horizontal beam 720 may have a shape extending from a center of the protrusion 225 in a radial direction. The horizontal beam 720 may rotate around the protrusion 225 while maintaining the shape extending in the radial direction.

An end of the horizontal beam 720 is connected to the inner rail 711 and can move along the inner rail 711. One end of the horizontal beam 720 may be referred to as a “first end”. Alternatively, one end of the horizontal beam 720 may be referred to as an “inner end”. The other end of the horizontal beam 720 is connected to the outer rail 713 and can move along the outer rail 713. The other end of the horizontal beam 720 may be referred to as a “second end”. Alternatively, the other end of the horizontal beam 720 may be referred to as an “outer end”.

The ratio of the distance the inner end of the horizontal beam 720 moves and the distance the outer end moves is the ratio of the diameter of the inner rail 711 to the diameter of the outer rail 713. It can be the same.

The crane 700 may include a hoist 730. The hoist 730 may be installed in the horizontal beam 720. The hoist 730 may move along the length direction of the horizontal beam 720. The hoist 730 may move up and down. For example, the hoist 730 may descend from the horizontal beam 720 into the wind tunnel 310. For example, the hoist 730 may rise from the inside of the wind tunnel 310 to the horizontal beam 720.

The hoist 730 can be combined with an object. The hoist 730 can move like a combined object. For example, the hoist 730 may be coupled to a turbine 500 installed in the wind tunnel 310 (refer to FIG. 5) to move upwards of the wind tunnel 310. The hoist 730 can be separated from the combined object. For example, the hoist 730 can be separated from the combined turbine 500 (see FIG. 5).

A plurality of horizontal beams 720 may be provided. For example, the horizontal beam 720 may include a first horizontal beam 721 and a second horizontal beam 723. A plurality of hoists 730 may be provided. For example, the hoist 730 may include a first hoist 731 and a second hoist 733. The first hoist 731 may be installed on the first horizontal beam 721. The second hoist 733 may be installed on the second horizontal beam 723. Although not shown in the figure, the horizontal beam 720 may be provided in more than two. For example, the horizontal beam 720 may be provided corresponding to the number of wind tunnels 310. The hoist 730 may be provided corresponding to the number of horizontal beams 720.

Referring to Figure 4, the operation mode of the crane 700 can be observed. The operation mode of the crane 700 may correspond to the operation mode of the power plant 100 (see FIG. 3). The operating mode of the power plant 100 (see FIG. 3) may include a first operating mode in which the power plant 100 (see FIG. 3) produces power. The operation mode of the crane 700 may include a first operation mode in which the horizontal beam 720 does not overlap the wind tunnel 310 in the first operation mode of the power plant 100 (see FIG. 3). The operating mode of the power plant 100 (see FIG. 3) may include a second operating mode in which maintenance is applied to the power plant 100 (see FIG. 3). The operation mode of the crane 700 may include a second operation mode in which the horizontal beam 720 overlaps the wind tunnel 310 in the second operation mode of the power plant 100 (see FIG. 3). The second operation mode may be referred to as a “maintenance mode”.

Referring to (a) of FIG. 4, the horizontal beam 720 may not overlap with the wind tunnel 310. For example, the first horizontal beam 721 may be positioned between the first wind tunnel 310a and the third wind tunnel 310c. For example, the second horizontal beam 723 may be positioned between the second wind tunnel 310b and the fourth wind tunnel 310d. If the horizontal beam 720 does not overlap the wind tunnel 310, the crane 700 may not interfere with the flow of air flowing in the wind tunnel 310.

Referring to FIG. 4B, the horizontal beam 720 may overlap the wind tunnel 310. For example, the first horizontal beam 721 may overlap the first wind tunnel 310a. For example, the second horizontal beam 723 may overlap the second wind tunnel 310b. Although not illustrated in the drawing, the first horizontal beam 721 and the second horizontal beam 723 may overlap the same wind tunnel 310. For example, the first horizontal beam 721 and the second horizontal beam 723 may be arranged to overlap the first wind tunnel 310a. In this case, the first horizontal beam 721 and the second horizontal beam 723 may perform operations on the same object (for example, a turbine).

Referring to FIG. 5, the turbine 500 may be installed in the wind tunnel 310. The turbine 500 installed in the wind tunnel 310 may be referred to as a first state turbine 500a. The first state turbine 500a may be operated by air flowing in the wind tunnel 310 to generate electric power.

The first state turbine 500a may be separated from the wind tunnel 310 for breakdown or regular maintenance reasons. The hoist 730 may descend from the horizontal beam 720 and be coupled to the first state turbine 500a. The hoist 730 may separate the first state turbine 500a from the wind tunnel 310. The turbine 500 separated from the wind tunnel 310 may be referred to as a second state turbine 500b. The second state turbine 500b may access the horizontal beam 720 by the hoist 730. The second state turbine 500b approaching the horizontal beam 720 may move along the longitudinal direction of the horizontal beam 720. The moved second state turbine 500b may be checked and repaired.

The repaired second state turbine 500b may move along the length direction of the horizontal beam 720. The second state turbine 500b may be lowered by the hoist 730. The second state turbine 500b may be coupled to the wind tunnel 310 to become the first state turbine 500a.

Referring to FIG. 6, an entrance 215 may be formed in the pillar 210. The entrance 215 may be located on the upper surface of the pedestal 220. The doorway 215 may be a passage through which objects enter and exit. For example, an operator may enter and exit the interior of the pillar 210 through the entrance 215. For example, the turbine 500 (see FIG. 5) may enter and exit the pillar 210 through the entrance 215.

A hatch 800 may be installed at the doorway 215. The hatch 800 may open and close the doorway 215. The operation of hatch 800 can be strictly controlled, depending on the need for security. For example, hatch 800 may be operated by an authorized administrator. For example, the operation of the hatch 800 may further require an approval process performed remotely from the outside.

The doorway 215 may have a corridor shape. The entrance 215 may provide a work space where an operator can repair the turbine 500 (see FIG. 5). An external door may be installed at the doorway 215. The external door may be located opposite the hatch 800.

Referring to FIG. 7, the hatch 800 may include a door 810 and a guide pole 820. The guide pole 820 may include a first guide pole 821 and a second guide pole 823. The first guide pole 821 may be parallel to the second guide pole 823. The guide pole 820 may guide the movement of the door 810.

The door 810 may be disposed between the first guide pole 821 and the second guide pole 823. The door 810 can move between the first guide pole 821 and the second guide pole 823. For example, the door 810 may move along the length direction of the guide pole 821. The longitudinal direction of the guide pole 820 may be the longitudinal direction of the first guide pole 821 or / and the longitudinal direction of the second guide pole 823.

Referring to (a) of FIG. 7, the door 810 may be located above the guide pole 820. When the door 810 is positioned on the upper portion of the guide pole 820, the hatch 800 may be opened. When the hatch 800 is opened, the doorway 215 (see FIG. 6) may be opened.

Referring to (b) of FIG. 7, the door 810 may be located under the guide pole 820. When the door 810 is located under the guide pole 820, the hatch 800 may be closed. When the hatch 800 is closed, the doorway 215 (see FIG. 6) may be closed.

8 can be described together with FIG. 7. 8 (a), the hatch 800 may be in an open state. 8 (a) may correspond to FIG. 7 (a). When the door 810 is inserted into the interior of the pillar 210, the hatch 800 can be opened. Although not shown in the drawing, a driving unit for driving the door 810 may be installed on the pillar 210.

Referring to (b) of FIG. 8, the hatch 800 may be closed. 8 (b) may correspond to FIG. 7 (b). When the door 810 is pulled out from the inside of the pillar 210, the door 810 may descend along the guide pole 820 (see FIG. 7). When the door 810 descends along the guide pole 820 (see FIG. 7), the hatch 800 may be closed.

The above description of the present invention is for illustration only, and those of ordinary skill in the art to which the present invention pertains can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is indicated by the following claims, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts should be interpreted to be included in the scope of the present invention.

100: solar thermal power plant 200: chimney
300: tunnel 500: turbine
700: crane 800: hatch

Claims (10)

A roof installed on the ground but separated from the ground;
A pedestal disposed in the center of the roof and communicating with a space between the roof and the ground, and a plurality of wind tunnels formed by extending from the intake;
A pillar extending from the pedestal upward and forming an upper tunnel in communication with the wind tunnel;
A protrusion projecting upward from an upper surface of the pedestal, surrounded by the pillar, and spaced apart from the pillar;
A turbine installed in the wind tunnel; And
It includes a crane installed on the upper portion of the pedestal,
The opening of the plurality of wind tunnels has a shape surrounding the protrusion,
The crane includes: a horizontal beam moving along the outer circumference of the protrusion; And having a hoist installed in the horizontal beam,
The crane includes an inner rail installed along the outer circumference of the protrusion; And includes an outer rail (outer rail) installed along the inner periphery of the pillar,
One end of the horizontal beam is coupled to the inner rail, and the other end of the horizontal beam is coupled to the outer rail,
Solar thermal power plant. delete According to claim 1,
The horizontal beam,
It rotates along the outer periphery of the protrusion,
One end of the horizontal beam,
It is movable along the inner rail,
The other end of the horizontal beam,
Movable along the outer rail,
Solar thermal power plant. According to claim 3,
The horizontal beam,
Maintaining the shape extending in the radial direction from the center of the protrusion,
Solar thermal power plant. According to claim 4,
The hoist,
It is possible to descend and rise in the horizontal beam,
Combinable and detachable with the turbine,
Solar thermal power plant. According to claim 4,
The inner rail and the outer rail,
Is installed spaced upward from the upper surface of the pedestal,
Solar thermal power plant. The method of claim 6,
The plane formed by the inner rail,
The same as the plane formed by the outer rail,
Solar thermal power plant. According to claim 1,
Located on the upper surface of the pedestal, formed on the pillar, the upper tunnel and an entrance communicating with the outside is formed on the pillar,
Solar thermal power plant. The method of claim 8,
It is installed on the pillar, further comprising a hatch to open and close the door (구),
Solar thermal power plant. The method of claim 9,
The hatch is
A door that enters and exits the column and opens and closes the doorway; And
A guide pole coupled to the door and guiding the movement of the door,
Solar thermal power plant.

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