DE102006013864B3 - Power plant for condensation of water vapors, has condensing system and building structure has tunnel- like wind passage by which cooling air flows or sucked under heat exchanger elements - Google Patents

Abstract

A power plant (1) has a condensing system (2) and the building structure has tunnel-like wind passage (6) by which cooling air flows or is sucked under heat exchanger elements. A condensing element is attached on a supporting structure (8) and the wind passage is interspersed with a turbine house (3).

Description

The The invention relates to a power plant with a condensation plant according to the features in the preamble of claim 1.

condensation plants are used for cooling Turbine or process steaming used and are in the energy engineering field in very large dimensions in use for many years. The efficiency of a power plant does not hang irrelevant of the condensation capacity of the condensation plant depending on the local climatic conditions and the related wind speeds and wind directions have a significant impact on the condensation performance. Today's types of condensation plants therefore have windbreak walls, which the heat exchanger elements surrounded in their entirety to prevent recirculation of the heated cooling air.

Important is also that all fans of the condensation plant as possible be streamed evenly. higher Natural wind speeds can lead to a local pressure drop lead below the fans. The affected fans can not enough cooling air promote, through the condensation capacity drops and a connected to the steam cycle Turbine under circumstances reduced in their performance must become.

The Another extreme is that the condensation plant may be in the Slipstream of building structures, especially in the lee of the boiler house and the turbine house one Power plant is located. Usually If a condensation plant is as close as possible, i. in immediate Neighborhood to the turbine house built to short the conduction routes to hold and condense the water vapor as quickly as possible. Nevertheless an optimal flow to ensure, Condensation plants are already elevated relatively high, so a substantially unimpeded flow from all sides, i. independent of the wind direction possible is. In practice, however, it has been shown that in condensation plants, their intake space below the fans in the lee of Gebäudstrukturen is arranged, hot air recirculation occur there, where the oncoming Air through the remaining space between the building structure and the raised one Condensation plant due to the local cross-sectional constriction with relatively high speed down and under the heat exchanger elements flows. This may be the undesirable Effect come that despite installed windbreak walls warmed cooling air from the inflowing cooling air is entrained and under the heat exchanger elements promoted is, i. it comes to warm air recirculation. Due to the temperature increase of the cooling air decreases the condensation performance, which in turn disadvantageous affects the power plant efficiency.

In the DE 33 25 054 C2 has been proposed to prevent recirculation in unfavorable wind conditions, the heat exchanger elements aufzuständern in different heights, so that can be dispensed with consuming Windleitvorrichtungen or air directing devices. In particular, heat exchanger elements that are farther away from the turbine house should be raised higher and thereby divert crosswinds coming from the turbine house upwards.

Another proposal according to the DE 34 21 200 C2 provides a forced ventilation condensation system in which at least at the parallel to the turbine house extending edge of the condensation layer, a concentrated air jet is blown in the manner of an aerodynamic wall whose flow velocity is higher than the exit velocity of the cooling air from the center disposed in the heat exchanger elements. Also, this is intended to reduce the risk of recirculation with additional equipment expense.

Of these, Based on the object of the invention, a power plant with a condensation plant for the condensation of water vapor according to the features show in the preamble of claim 1, wherein the Warm air recirculation is reduced.

The solution is in a power plant with the features of claim 1 seen. Advantageous embodiments of the inventive concept are Subject of the dependent claims.

Extensive investigations have shown that the mentioned problem of hot air recirculation can be achieved particularly cost-effectively if building structures placed adjacent to the condensation plant have tunnel-like wind passages through which cooling air flows and / or is drawn under the heat exchanger elements. The wind passages are provided in particular in turbine houses and do not require separate structures to be built. It is important that the under certain circumstances already existing between boiler houses, undeveloped open spaces to the condensation system out so that inflowing air can flow near the ground between the boiler houses into the wind passages of the turbine house and thus not only the longer and recirculation prone over the roofs of the boiler - and turbine houses must take away, but un indirectly from below into the suction of the condensation plant passes. The interpretation, ie in particular the size of the wind passages is made according to requirements and taking into account the prevailing wind conditions, the climatic conditions and other factors, so that it can be ensured that the condensation plant operates without recirculation up to certain wind speeds, even if the condensation plant in the lee of Building structures of the power plant stands. With the solution according to the invention, it is possible to better meet warranty commitments, for example, if required by the operator of the power plant, that the condensation plant should work without recirculation at wind speeds above 3 m / s. The design of the condensation plant can not be done analytically due to the complex flow conditions, but only by numerical calculation methods. Using Computational Fluid Dynamics (CFD) methods, it is possible to compare different shapes and arrangements of building structures and thus analyze local flow phenomena that are difficult or impossible to measure with measurements. Due to the large number of parameters and the size of today's new power plant new buildings result in extremely complex calculation models, through which the well-known problem of hot air recirculation often can only be located.

Of course it is it always possible, very much high windbreak walls edge of the heat exchanger elements to arrange, so that the heated cooling air under any circumstances with the sucked cooling air is mixed. However, the investment costs in the construction modern power plants significantly, so after cost-effective Alternatives and supportive activities must be sought. By providing wind passages in previously closed building structures open Not only new streamlines for the supply of cooling air, but also effective Options, the influence of the wind on the power plant efficiency at the same time low investment.

It is considered advantageous when wind gates for changing the Flow area of the wind passages are provided. The width of the wind passages is often through structural requirements given. These distances are often barely change to let. However, it can be controlled relatively accurately by wind gates. what amount of air should be passed through the wind passages. The wind gates are usually complete open, to allow an unimpeded passage of the incoming air. Conversely, it is also possible at least partially close the wind gates when the wind speed is too high or if the wind direction has changed. In particular, the Windtore be coupled with means via which the flow area in response to the wind direction is controllable. For example, it might be a disadvantage if not the condensation plant, but the boiler and turbine houses in the lee stand. In this case it is more convenient to close the wind gates to keep so that below the heat exchanger elements a certain Dynamic pressure forms, which are increased by closing the wind gates can. Ultimately, it is crucial that the condensation plant can "breathe", that is you are independent from the wind direction cooling air flows in a way, which prevents warm air recirculation.

The Invention is described below with reference to an illustrated in the drawings embodiment explained in more detail. It demonstrate:

1 and 2 two perspective views of a power plant model according to the prior art;

3 and 4 two perspective views of a power plant model according to the solution according to the invention;

5 a model showing the flow conditions in a power plant according to the prior art and

6 a model that shows the flow conditions in a power plant according to the invention.

1 shows a calculation model of a power plant 1 with a condensation plant 2 for the condensation of water vapor, which condensation of the plant 2 from a turbine house 3 is supplied. The turbine house 3 is a boiler house 4 upstream. The turbine house 3 and the boiler house 4 are referred to in their entirety as building structures of the power plant. The wind direction W is symbolized by the arrow. The wind speed is for example 7 m / s. Based on the different shades of gray, the temperature profile of the heat exchanger elements 5 emerging, heated cooling air to recognize, in particular, the circled area is of interest. There it can be seen that obviously in the area of the turbine house 3 and the boiler house 4 Be adjacent longitudinal side of the condensation plant 2 a portion of the heated cooling air back into the heat exchanger elements from below 5 entry. This can be recognized by the illustrated temperature gradient of the cooling air. Despite existing windbreak walls, warm air recirculation occurs here.

Out 2 is indicated by the Flow lines clearly that warm air recirculation occurs not only in the circled corner of the illustrated condensation plant, but also in the area of the wind shadow behind the boiler and turbine houses 3 . 4 , The reason for this is in 5 to recognize. The drawn arrows in 5 illustrate the local wind direction. The length of the arrows is a measure of the local wind speed. The power station in the picture plane from the right 1 has a condensation plant 2 in the slipstream of the building structure of a power plant, ie the boiler house 4 and in particular of the turbine house 3 lies. Although the condensation plant 2 high up, the spatial proximity leads to the turbine house 3 in that the wind flowing in from the right in the image plane passes through a relatively narrow area under the heat exchanger elements 5 the condensation plant 2 must be sucked. The high number and density of the individual arrows in this area makes it clear that relatively high wind speeds prevail there. These high wind speeds, in turn, cause the condensation plant to be at the edge as well 2 in the circled area of the heat exchanger elements 5 escaping hot air is entrained and back under the condensation plant 2 flows.

In the context of the invention, it is now provided that the windshield-generating building structure, that is, in this case, the turbine house 3 , tunnel-like wind passages 6 comprising, by which cooling air under the heat exchanger elements 5 flows and / or is sucked. 3 shows that the turbine house no longer has a barrier for between the boiler houses 4 passing through cooling air, but rather a wind passage 6 limited, the only hinted wind gate 7 with the suction space below the condensation plant 2 fluidically connected. The wind passage 6 becomes a kind of tunnel through the turbine house 3 guided.

Theoretically would it be conceivable to subdivide the turbine house into individual sections, so that individually adjoining buildings result. However will the shared infrastructure is also interrupted. In particular with regard to the use of an overhead crane, the Tunneling is an economically viable solution.

The presentation of the 4 shows that the wind passages 6 below on a support structure 8th arranged heat exchanger elements 5 the condensation plant 2 flow out, leaving the wind passages 6 escaping air not completely over the roofs of the turbine houses 3 and boiler houses 4 must be sucked, but also directly over the wind passages 6 the condensation plant 2 can be supplied.

Based on 6 it can be seen that in a sectional plane through the wind passage 6 a significant proportion of the sucked or inflowing cooling air of the condensation plant 2 through the wind passage 6 is supplied. The proportion is at least so great that it is in the in 5 area shown to no hot air recirculation more comes and thus no impairment of the power plant efficiency.

1

power plant

2

condensation plant

3

Turbinenhaus

4

boiler house

5

Heat exchanger element

6

wind passage

7

Windtor

8th

support structure

W

wind direction

Claims (4)

Power plant with a condensation plant for the condensation of water vapor, wherein the condensation plant ( 2 ) on a support structure ( 8th ) mounted and by cooling air from below flowed heat exchanger elements ( 5 ), wherein the condensation plant ( 2 ) with its one longitudinal side in the immediate vicinity of a building structure of the power plant ( 1 ), characterized in that the building structure ( 3 ) at least one tunnel-like wind passage ( 6 ), through which cooling air under the heat exchanger elements ( 5 ) flows and / or is sucked. Power plant according to claim 1, characterized in that the wind passage ( 6 ) a turbine house ( 3 ) interspersed. Power plant according to claim 1, characterized in that wind doors ( 7 ) for changing the flow area of the wind passages ( 6 ) are provided. Power plant according to claim 3, characterized in that the wind doors ( 7 ) are coupled with means via which the flow area in dependence on the wind direction (W) is controllable.