DE19806489A1 - Thermal air convection power station - Google Patents

Abstract

The power station for utilization of thermal convection of the air between the ground and a cover (4) by a turbine and an electric generator (22) has a hill (2) to generate the upwind. The turbine consists of a shaft-free turbine ring with concentrically arranged turbine blades (12). The electrical generator is designed from a rotor and stator in the form of a ring. An air eddy is generated around the vertical axis of the hill by deflecting walls (14). Rollers are used to support the turbine ring. The bedrock of the hill is coated with a light-absorbing material (5), as also the bedrock of the catchment area (1).

Description

The invention relates to a power plant for harnessing thermal Convection of the air between the floor and a cover by means of a turbine in an electric generator.

Worldwide, the energy supply is still largely dependent on energy sources, their Inventories are limited. They also harbor risks to the environment and the climate from the Greenhouse effect. Both atomic and hydroelectric plants are in practice limits their potentially harmful impact on the environment. The sun is one unique and pure heat donor. Solar energy can provide mechanical power Power generation without polluting the environment. A method of exploitation solar energy for electricity generation is based on causing an upward directed airflow in a vertical chimney. This method is e.g. B. in DE 41 04 770 A1 described. The upward airflow within the chimney leaves a turbine rotate to produce a torque capable of generating an electrical To drive the generator. The upward air flow is generated by the Solar radiation is a volume of air in an essentially closed system heats up. The heated air rises convectively compared to the colder ambient air The thermal winds or air currents are then generated by an air turbine exploited, which is connected to a generator.

The power that can be drawn from the upward air flow is from Velocity and mass of heated air per unit time through the turbine flows depending. In conventional solar energy systems, which caused thermal Taking advantage of updrafts, the achievable speed is essentially due to the height of the chimney and the temperature difference between the air in the chimney and outside fixed. The height of the chimney is structural and in the proposed systems limited for economic reasons. The higher the chimney is to be built, the more higher requirements arise with regard to stability, which affects the Economic impact of the system has an unfavorable effect.

This is where the invention comes in. In particular, the aim is to remove the restrictions regarding the Height of thermosolar upwind power plants to lift the flow rate the air without increasing the construction effort disproportionately  to let. A construction which is simpler than that of the prior art is to be specified to reduce the cost per unit of performance. It is said to be a thermosolar Wind power plant can be described, which is capable of solar radiation energy to use a very large reception area and therefore a large bandwidth electrical power requirements can be adjusted.

These objects of the invention are achieved by a thermosolar upwind power plant when a hill 2 is used to generate the height difference for the upwind. Further advantageous embodiments of the invention are set out in the subclaims. Thus, the hill 2 can be almost completely covered with a light-absorbing material 5 . This coating of light-absorbing material 5 can encompass the entire catchment area 1, including the plane. The active surface to be used is covered by an overlap 4 which prevents vertical convection. The air stream 30 is thereby directed towards the center of the hill 2 .

Advantages over the prior art result from the structurally significantly simplified construction, which is limited to the use of a natural hill 2 or the creation of an artificial hill 2 for generating the height difference. In particular, the invention does not require a fireplace. Geographical conditions such as mountains can be used directly. This means that the height of thermosolar upwind power plants can be increased if the base area is increased without at the same time causing the construction effort to increase disproportionately. On hill 2 , an additional customary upwind channel in the form of a chimney can be erected as a conceivable extension. The described invention can be used successfully in areas of high solar radiation 31 . The materials used are readily available everywhere.

Embodiments of the invention are detailed below with reference to drawings described. In detail show:

Fig. 1 is a side view of the thermoelectric solar wind power plant according to the invention,

Fig. 2 is a Aufrißzeichnung in side view,

Fig. 3 is a perspective view of the thermoelectric solar wind power plant,

Fig. 4 is a schematic top view of the baffles 14 and the turbine ring 8 with the turbine blades 12,

Fig. 5 section of the turbine ring 8 of the turbine with the turbine blade 12 and generator 22 (detailed view),

Fig. 6 shows a detail of the solar-active surface (interface)

Fig. 7 another variant of the device for the start and vortex of the air (side view).

Fig. 1 shows a thermoelectric solar Aufwindkraftwerk according to the present invention. The updraft plant comprises a large catchment area 1 with a hill 2 in the middle. The areas of the catchment area 1 and the hill 2 as well as the covering 4 are covered with light-absorbing material 5 . As a result, the ambient air and in particular the air under the cover 4 is heated by the solar radiation 31 . An air flow 30 is created , which is first directed horizontally, then obliquely upwards along the shape of the hill 2 towards the center of the hill 2 . In order to reach a higher column of heated air above the hill 2 , the generation of a helical air stream 30 is useful. For this purpose, a large number of guide walls 14 are built on the hill 2 on and under the covering 4 , which are in the vicinity of the center of the hill 2 and can be spirally oriented. When the air rises above hill 2 , the centrifugal forces drive the air away from the center. The air releases the heat into the environment in higher, cold layers of the atmosphere. As a result, it condenses and moves further away from the center according to the law of inertia. This creates a column of heated air and an artificial low pressure area above hill 2 . At the periphery of catchment area 1 and possibly far beyond, a column of colder air already exists and, as a result, a higher pressure on the ground. This causes an opposite movement of the air on the ground towards the center. The centripetal air flow 30 at the bottom absorbs the heat from the light-absorbing material 5 . This increases the temperature of the air the closer it comes to the center of hill 2 . A cycle of air is created that drives the updraft plant.

Fig. 2 shows an inventive thermoplastic solar wind power plant in cross-section. Hill 2 rises continuously towards the center. The turbine blades 12 and the generator 22 are arranged on the hill 2 . The hill 2 is covered with a covering 4 at a certain distance from its surface. The cover 4 is anchored in the lower part by supports 3 and in the upper part by guide walls 14 on the hill 2 . The outer surface of the cover 4 is light-absorbing. The entire background 25 is also covered with a light-absorbing material 5 . The speed of the air flow 30 is increased on the one hand by the known chimney effect when rising below the tapered cover 4 , on the other hand the air flowing into the opening 27 of the cover 4 also acts due to the dynamic pressure. For stable operation of the thermosolar upwind power plant and to improve the thermal effect of solar radiation 31 , it can be useful to apply a layer of heat-storing material 6 under the light-absorbing material 5 on the catchment area 1 and the hill 2 , which additionally consists of a layer heat-insulating material 7 should be insulated from the substrate 25 . The stored heat heats the air in periods of low sunlight activity during the day and also extends the operation of the thermosolar wind power plant after sunset. This combination of heat-storing material 6 and heat-insulating material 7 on the substrate 25 is particularly well visible in FIG. 6. The entire arrangement is shown spatially in FIG. 3. The arrangement of the supports 3 and guide walls 14 can be seen particularly well in this picture.

Fig. 4 shows a schematic view of the device according to the invention from above. A plurality of guide walls 14 are arranged radially to the turbine blades 12 , below and above the cover 4 . The guide walls 14 are arranged spirally in the drawing and direct the air onto the turbine blades 12 in such a way that an ideal air vortex is created. A centrifugal blower 18 , which is driven by a motor 26, can be provided on the top of the hill 2 for the start and for a reliable execution of the process. The centrifugal fan 18 has a plurality of radially extending fan blades 19 and is used for the additional vortex of the air.

Fig. 5 shows the components of the solar air turbine according to the invention. The air turbine consists of a turbine ring 8 with an imaginary vertical axis of rotation in the center of the hill 2 , the turbine blades 12 and the adjustment devices 13 . The turbine ring 8 , which is located in the annular space 9 below the surface of the hill 2 , runs on rollers 10 . The turbine ring 8 can also be suspended on a magnetic cushion 11 . A plurality of turbine blades 12 , which are at an angle to the air flow 30, are attached in a circular manner to the turbine ring 8 . The turbine blades 12 can be brought into different inclinations to the air flow 30 30 depending on the power of the air stream. This is made possible by the adjustment devices 13 . As a result, the effect of the air turbine can be optimally adjusted for all flow speeds. The air turbine rotates, driven by the turbine blades 12 , about the imaginary axis. The rotor 15 of the generator 22 is connected to the turbine ring 8 . The stator 16 is fixed on the foundation 17 . In operation, the rotor 15 slides past the stator 16 , whereby energy is induced. The upper outward widening edge of the cover 4 deflects the external air flow 30 . Due to the interaction of the outer air flow 30 with the air vortex, an additional blocking pressure can be generated in the area after the air turbine, which accelerates the air flow 30 through the turbine. The air rising above the cover 4 can therefore also make a positive contribution to the overall balance.

FIG. 7 shows another variant of the device for reaching the swirled air flow 30 , consisting of a series of turbine engines 20 , which are radial to the center of the hill 2 with a certain angle of inclination to the horizontal. The turbine engines 20 can also serve as an additional device for starting the intended convection flow.

If the wind-up power plant falls below a certain height, the above-described circulation of air is not guaranteed, ie there is no need for the air flow 30 above the cover. For this reason, even in the event that an air stream 30 is not necessary, the cover 4 can be made transparent. As an extension of the covering 4 , a vertical chimney can be placed on the hill 2 .

Claims (14)

1. Power plant for harnessing thermal convection of the air between the floor and a cover ( 4 ) by means of a turbine in an electrical generator ( 22 ), characterized in that a hill ( 2 ) is used to generate the updraft. 2. Power plant for utilizing thermal convection of the air according to claim 1, characterized in that the turbine consists of a shaftless turbine ring ( 8 ) with concentrically arranged turbine blades ( 12 ). 3. Power plant for utilizing thermal convection of the air according to claim 2, characterized in that the electrical generator ( 22 ) from the rotor ( 15 ) and stator ( 16 ) is designed in the form of a ring. 4. Power plant for utilizing thermal convection of the air according to one of claims 1 to 3, characterized in that an air vortex about the vertical axis of the hill ( 2 ) is generated by guide walls ( 14 ). 5. Power plant for harnessing thermal convection of the air according to one of claims 1 to 4, characterized in that rollers ( 10 ) are used for mounting the turbine ring ( 8 ). 6. Power plant for utilizing thermal convection of the air according to one of claims 1 to 5, characterized in that the base ( 25 ) of the hill ( 2 ) is coated with a light-absorbing material ( 5 ). 7. Power plant for utilizing thermal convection of the air according to one of claims 1 to 6, characterized in that the substrate ( 25 ) of the catchment area ( 1 ) is coated with a light-absorbing material ( 5 ). 8. Power plant for utilizing thermal convection of the air according to one of claims 1 to 7, characterized in that the cover ( 4 ) is coated with a light-absorbing material ( 5 ). 9. Power plant for utilizing thermal convection of the air according to one of claims 1 to 8, characterized in that between the substrate ( 25 ) and the light-absorbing material ( 5 ), a heat-storing material ( 6 ) and a heat-insulating material ( 7 ) are attached . 10. Power plant for utilizing thermal convection of the air according to one of claims 1 to 9, characterized in that magnetic cushions ( 11 ) are used for mounting the turbine ring ( 8 ). 11. Power plant for utilizing thermal convection of the air according to one of claims 1 to 10, characterized in that the turbine and the generator ( 22 ) are built together on the hill ( 2 ). 12. Power plant for utilizing thermal convection of the air according to one of claims 1 to 11, characterized in that a centrifugal fan ( 18 ) provides an additional swirling of the air. 13. Power plant for utilizing thermal convection of the air according to one of claims 1 to 7 and 9 to 12, characterized in that the covering ( 4 ) is transparent. 14. Power plant for harnessing thermal convection of the air according to one of claims 1 to 13, characterized in that an additional updraft channel in the form of a chimney is built on the hill ( 2 ).