DE10224849A1 - Wind turbine system for generating electricity by using hot air rising from building, has set of tall vertical chimneys taking hot air from building with glass roof - Google Patents

Abstract

The system is especially useful in countries with hot climates where a glass roof (1) may trap much solar heat. Hot air moving towards the chimneys (2) may be further warmed by waste process heat. Each chimney contains a turbine (3) which extracts energy from the rising hot air. Cool air is drawn in at the sides of the building, providing ventilation.

Description

The invention relates to an updraft power plant in a manner known per se Structuring that is comparatively simple and inexpensive Structure distinguished; its application is - contrary to realized and planned pilot plants - advantageously possible in every hemisphere.

As is well known, wind power plants are special Solar power plants, namely those that take advantage of the chimney effect Air flow through a wind turbine to generate energy. Under a huge glass or translucent plastic roof, the so-called collector, the air is warmed by solar radiation and - by the shape which preferably supports glass roofs - a fireplace that is in the middle of the Collector stands, fed, in which it strives upwards. From the edges of the Glass roofs flow in the cooler ambient air, which then also flows heated. A turbine built into the chimney converts the generated one Using a generator to convert wind energy into electrical energy.

Wind power plants are therefore a special case of using solar heat One of their advantages compared to the concentrated systems is the Solar technology the possibility of using diffuse radiation and the Extend the useful life via heat storage, which is part of the daytime can release radiated energy at night as heat. For this is the Use dark, water-bearing pipes that cover the ground under the Cover the collector, provided.

The first considerations about solar thermal power plants date back to the 1930s; but it was not until mid- 1986 that a pilot plant designed by J. Schlaich, Germany, which ran with a peak output of 50 kW almost without interruption until 1989 , was put into operation. The collector of this system had a diameter of 240 m; that of the 195 m high chimney made of sheet metal, which was brought down by a hurricane in 1989, was 10 m.

As a result of the pilot operation, it was repeatedly stated that economically working systems would have to be significantly larger. The chimney of a (not realized) 100 MW plant in Gahna should have a height of 950 m with a diameter of 115 m; the collector would have taken up an area of several square kilometers (see www.energieinfo.de). A power plant to be built in Australia is said to have even larger dimensions (and therefore expenses). This project anticipates a 1000 m high and 130 m thick chimney and a glass surface of 10 km in diameter (see SPIEGELONLINE 2002 ).

It is obvious that for such dimensions of an updraft plant there is no space in Europe, so that only remote areas such as B. Deserts or desert edges. But also where space and Sunlight abound are the extraordinarily high Construction costs an almost insurmountable obstacle. Projects are therefore in particular Africa and Asia (including Gahna, Sudan; India) failed; also for Australia must consider the feasibility of such a gigantic project among the Aspects of infrastructure, duration and risks of the approval process and amount the necessary initial investment and the resulting profitability significant doubts should be addressed.

In addition, a number of proposals are known that apply to the application of the Principle of an updraft power plant in the densely populated and comparatively Target sun-poor Europe. In addition to numerous details (including DE 41 14 501) and imaginative control solutions, such as B. the Formation of an all-round duct for daytime air flow and one such a channel for air flow at night (DE 297 15 254), suggestions, which should compensate for the geographical disadvantages of the location, in Center of developments. DE 199 39 663 describes an alternative system for bivalent electricity generation from wind and combustion energy proposed; According to DE 298 24 124, an updraft plant is said to have several types of use industrial waste heat and finally, the solar energy is targeted heat-storing stone surfaces (DE 299 17 453) or other Heat storage elements (DE 100 23 424) to supply the efficiency of a Increase wind power plant. They want other developments Limitations on the height of thermosolar wind power plants pick up that they are not vertical but one along a hill use inclined chimney (DE 198 06 489, DE 195 43 514, based on a Collector to a mountain is also known from DE 198 06 144, which one relevant air duct arrangement from DE 198 44 659).

Furthermore, various efforts are known to reduce the high construction costs of Wind power plants, especially those for the construction of the fireplace minimize. For this purpose, the chimney is used as a chimney tower in DE 40 00 100, for example a funnel-shaped protruding foot. The foot has over its entire outer circumference distributes air inlet openings and has one at least twice the outer diameter of the chimney tower. This should technically make such a system for using solar energy be easier to set up and cheaper.

There are also suggestions for the chimney as a hose made of plastic train so. B. by means of tubular film, the ring-like by fixed or inflatable Chambers is stiffened into a so-called suction hose. According to DE 100 46 287 the chimney is supposed to be a flexible-walled gas-impermeable casing have, which in connection with at least one filled with lifting gas Hollow structure stands, which holds the chimney upright. Finally was suggested that a conical, diverging upward Chimney hose made of high-strength fabric material or high-strength plastic films forms the lift channel and that on the chimney hose at intervals Helium-filled balloon rings or hoses for carrying the chimney hose are arranged.

But these developments, like the aforementioned, have so far had none commercial use of the principle of an updraft power plant. To The high initial investments and consequently the Amount of interest, which is primarily the price of the generated with this technique Determine current, counter.

The object of the invention is to sustain the disadvantage of the prior art to minimize, so it is worth considering the promotion of renewable Energy to produce electricity with solar thermal power plants. In particular, it is said be given a solution that allows the effort for the Reduce fireplace dramatically.

This object is solved by the features of claim 1. Appropriate embodiments of the invention result from the features of Claims 2 to 8.

According to the invention, industrial chimneys are provided larger Use height as a chimney for solar thermal power plants. For this are both decommissioned as well as in-service chimneys provided. The power plant is structured in a generally known manner and consists of essentially from a collector, preferably a spaced from the ground Glass roof, and a chimney with at least one turbine, which from the Chimney under adiabatic expansion of rising air previously through the solar radiation has been heated, is driven. The essence of Invention also includes multiple chimneys that are spatially more appropriate Stand in relation to each other, each used by the collector are enclosed, or on which the collector or, if applicable, Collector segments are connected. They are preferably at least 250 m high Chimneys used.

In addition, it is advantageous to use the chimney next to the chimney the energy generated by the rising air heated by the collector will, the residual energy potential of industrial emissions to drive the To use wind turbine. Furthermore, it is proposed to produce the waste heat analogously Power plant processes and / or cooling towers to improve the overall balance of the power plant to supply the wind turbine, which also in a known manner be arranged several times in one or more levels in the chimney can.

Coupling the use of the upside potential of industrial emissions and / or otherwise no longer due to conventional power plant processes (as a result of the small temperature difference to the ambient temperature) technically Energy that can be used sensibly with a solar thermal power station opens up just this Possibility. The resulting contribution to resource and Environmental protection is obvious.

The proposal to shut down industrial chimneys as a fireplace Using the wind power plant saves the high costs, otherwise necessary demolition.

The expenses for the adjustment of the chimneys (regardless of whether decommissioned or in operation) to the specific design of one Completed wind power plants are self-evident to one comparable new construction of a fireplace practically negligible.

The invention will now be described with reference to two exemplary embodiments explained.

Fig. 1 shows schematically the use of decommissioned industrial chimneys as a chimney of an updraft power plant. The three (former power plant) chimneys 2 are each 300 m high and integrated in a collector, designed as a glass roof 1 spaced from the floor. A wind turbine 3 is installed in each chimney 2 in a generally known manner.

Fig. 2 illustrates the use of an industrial chimney stone including the use of waste heat in operation of a power plant process in the manner described above. The chimney 2 is shown , to which a tunnel or a tube is connected, in which or in which the wind turbine 3 and the heat exchanger 4 , which is connected to the power plant process by the line 5 , are located. The tunnel or tube carries the collector designed as a glass roof 1 .

Both design variants can have heat accumulators (not shown here ) under the respective glass roofs 1 .

Claims (8)

1. Upwind power plant for the generation of electrical energy from a warm air flow generated in particular by solar radiation, essentially consisting of a collector for generating the warm air and a chimney in which there is at least one turbine which is driven by the air rising in the chimney under adiabatic expansion , characterized in that it uses chimneys ( 2 ) as a chimney. 2. Wind power plant according to claim 1, characterized in that several industrial chimneys ( 2 ), which are spatially in a suitable manner to each other, are used, these being enclosed by a collector, preferably made of glass, or on which collector segments in the form of glass roofs ( 1 ) are connected. 3. Wind power plant according to claim 1 and 2, characterized in that the industrial chimneys ( 2 ) are at least 250 m high. 4. Aufwindkraftwerk according to claim 1 to 3, characterized in that disused industrial chimneys ( 2 ) are used as a chimney. 5. updraft power plant according to claim 1 to 3, characterized in that the chimney in operation chimneys ( 2 ) are used, so that in addition to the heated air heated by solar energy, the residual energy potential of industrial gases is used to drive the wind turbine ( 3 ). 6. Aufwindkraftwerk according to claim 1 to 5, characterized in that one or more industrial chimneys ( 2 ) waste heat from power plant processes, especially from cooling towers, is supplied. 7. Aufwindkraftwerk according to claim 1 to 6, characterized in that on the industrial chimneys ( 2 ) a horizontally executed tunnel or a horizontally arranged tube, in or in which heat exchangers ( 4 ) are located, wherein the tunnel or the tube wear the collector designed as a glass roof. 8. wind power plant according to claim 1 to 7, characterized in that the glass roofs ( 1 ) all serve as a chimney industrial chimneys ( 2 ) or to which are connected in segments.