DE102005024156B3 - Condensation assembly, for cooling turbines or process vapors, has heat exchangers in a roof-shape array on a support structure within an angled wind shrouding wall to prevent wind effects on the assembly - Google Patents

Abstract

The condensation assembly, for cooling turbines or process vapors, has a support structure (9) for heat exchangers (10) in a roof-shape array within a wind shrouding wall (13). Cooling air (K) is generated by fans (11). The lower edge (14) of the wall has a wider outer offset than the upper edge (15), giving the wall a pitch angle (NW) of 5-35[deg] against the vertical (V).

Description

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

condensation plants are used for cooling Turbines 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 from. The local climatic conditions and the related thereto Wind speeds and wind directions have a significant Influence on the condensation performance. Today's types of condensation plants have windbreak walls on which the heat exchanger elements surrounded in their entirety to immediate recirculation the heated one cooling air to prevent. The windbreak walls are usually inclined vertically or partially even obliquely outwards arranged as required by the building codes.

It it was found that laterally inflating winds, which under the Fans are pressed at higher Wind speeds to a local pressure drop below the Fans lead. Due to the negative pressure can the fans are not enough cooling air promote, whereby the condensation power decreases. As a result, accumulating Steam can not be condensed fast enough. This results, that a turbine connected to the steam cycle may in reduced their performance must become.

This has been known for a long time, for example, by that mounted in the suction space below the fans obstacles were, so-called wind crosses. Wind crosses divide the intake space below the fans into individual areas. This is too consider, that the fans are partially mounted at a height of up to 50 m are. The wind crosses are usually up to a height built of about 30% of this space, so that laterally oncoming wind can not flow unhindered under the fans, but deflected upwards at impact on the wind cross and the fans is forwarded.

The EP 1 496 326 A1 proposes, in this connection, movably mounted wind deflectors which allow automatic or manual adaptation to the particular wind situation. Although the wind crosses cause an improvement in the efficiency or a reduction in the pressure loss of the peripheral fans, the flow of the peripheral fans is often unsatisfactory.

In departure from the usual A-form or roof construction with oppressive arrangement is in the DE 103 23 791 A1 proposed a V-shaped arrangement of the cooling elements, wherein the cooling air is sucked through by at least two juxtaposed fans through the cooling elements. This allows a better flow with minimal deflection and reduced height. This can result in terms of energy balance advantages, since fewer deflections of the cooling air flow are required as in oppressive arrangement. Finally counts by the DE 19 62 061 an air-condensing system of the prior art, in which adjustable covers are arranged in the flow directions of the cooling air in the region in front of the upper, predominantly steam-flowed part of the cooling elements. This should make a dephlegmator operation of the condensation device unnecessary. However, the disadvantageous influences of laterally oncoming winds can not be remedied by the proposed adjustable covers.

Of the Invention is based on the object, the adverse effects laterally inflowing Winch on a on a support structure attached condensation plant to reduce.

These Task is with a condensation plant with the characteristics of Patent claim 1 solved.

advantageous Embodiments of the inventive concept are the subject of the dependent claims.

The Task is essentially solved by the windbreak is arranged inclined in the wind direction or that its lower edge on outward is issued as its top edge. Model calculations confirmed one Reduction of wind induced additional pressure losses on a scale independent of at least 10% of whether an additional Windkreuz is arranged below the fans. The benefits come in particular arranged at the edge of the condensation plant Fans to bear, whereby the pressure loss here by about 20% could be reduced.

The windbreak can be designed inclined overall or even in a portion of its height. An inclination angle of 5 ° to 35 °, ins particular from 15 ° to 30 °, compared to a vertical is considered appropriate. However, the angle of inclination must not be so great that there is a significant cross-sectional constriction, which hinders the unhindered upward flow of the heated cooling air, as this would have a negative impact on the efficiency. For example, a windbreak with a height of about 10 m could be displaced at its upper edge by 1 m to 3 m in the direction of the heat exchanger element. As a result, the cross section is reduced only to a small extent. If a suitable space is available, in principle, the lower edge of the windbreak can be shifted to the outside. As a result, the inclination can be increased without the outflow cross section being reduced. For example, with a windscreen about 10 m high, a maximum lateral offset of 3 m + 3 m = 6 m would be possible.

Additionally or Optionally, the windscreen can be concave towards the heat exchanger elements bent accomplished be. This also makes a larger share of the laterally flowing Wind deflected upward, causing the pressure drop below the edge fans is lower. Since the volume flow of upward deflected wind increases, becomes an additional barrier created from cold air, a warm air recirculation as well counteracts in an advantageous manner. Also on the leeward Side of the condensation plant has the slope of the windbreak benefits in terms of hot air circulation, since the hot air edge not vertical, but according to the slope of the windbreak wall flows further inside. This is the flow path the recirculating warm air longer.

In addition, can be provided that the windbreak at least in one of Lower edge of adjacent altitude range has a horizontally extending profiling. Usually become windbreak walls built of trapezoidal profiles, where the profiling in the vertical direction, this means from bottom to top. This orientation of the profiling indeed has a positive effect on the flow behavior from, in the form that the wind is derived down and up. However, just the derivative down is undesirable. Therefore, can at least the lower edge of the adjacent height range a horizontal have running profiling, which serves as a fluidic barrier. The upper altitude range the windbreak wall, on the other hand, can have a vertical profiling, to the outflow not to obstruct the wind upwards.

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

1 to the prior art, a calculation model for a laterally flowed condensation plant with vertically extending windbreak wall;

2 a first embodiment of a condensation plant with inclined windshield and

3 a further embodiment of a condensation plant with a concave windshield.

1 shows the model calculation of a condensation plant 1 as it belongs to the state of the art. The condensation plant is flowed laterally through the wind W in the model calculation. The heat exchanger elements are not shown in detail. Only the steam distribution lines associated with the heat exchanger elements 2 are recognizable in cross section. Below the steam distribution lines 2 the heat exchanger elements are arranged roof-shaped. Only schematically indicated fans 3 suck cooling air from below, with the heated cooling air at the steam distribution lines 2 flows over upwards. It can be clearly seen that not all fans 3 be streamed evenly. In particular, the peripheral fan promotes 4 recognizable less air than, for example, the mid-range fans 3 , This is due to the fact that the sideward-flowing wind W on a straight windbreak wall 5 meets and partly upwards, that is over the condensation plant 1 , but sometimes also in the suction space below the fans 3 . 4 is diverted. Through a flow obstacle 6 as well as a wind cross 7 the flow direction of the wind W can be at least partially changed, so that the wind the fans 3 is supplied. However, this only applies to a limited extent to the peripheral fans 4 to. Below the fan 4 There is less pressure in an area marked ΔP than below the other fans 3 , That is, the peripheral fan 4 can promote less cooling air, reducing the efficiency of the condensation plant 1 is reduced.

To solve this problem, it is proposed that the windbreak walls are arranged inclined, as exemplified in the 2 and 3 is shown. 2 shows in a very simplified representation of the edge region of a condensation plant 8th in which on a support structure 9 a plurality of rows of roof-shaped arranged heat exchanger elements are arranged, of which for the sake of simplicity, only edge-side heat exchangers ELEMENTS 10 the outer row are shown. Below the heat exchanger elements 10 there is a fan 11 sucking cooling air K from below and corresponding to the arrows on the heat exchanger elements 10 feeds, where the cooling air K heats up and flows in the direction of the arrow WL upwards. At the same time is from the ridge area of the heat exchanger elements 10 arranged steam distribution line 12 Steam in the direction of arrows D in the heat exchanger elements 10 initiated where the steam condenses.

Essential in this embodiment of a condensation plant is the design of the windbreak wall 13 , which in the embodiment of the 2 is arranged inclined relative to the vertical V. The windbreak wall 13 extends in height approximately to the upper edge of the steam distribution line 12 , The lower edge 14 the windbreak wall 13 is further exposed to the outside than the top edge 15 the windbreak wall 13 , In this embodiment, the inclination angle NW is about 5 °. Due to the set inclination of the windbreak wall 13 transverse wind W is diverted upwards to a greater extent than would be the case with a vertically oriented windbreak wall. As a result, the pressure difference ΔPL is that between the inlet side 16 and the outlet side 17 of the fan 11 measured, less than with vertically oriented windbreak walls.

The same effect is obtained even if the windbreak is not straight, but according to the embodiment of 3 is concavely curved. The windbreak wall 18 of the 3 is according to the 2 configured so that its bottom edge 19 further exposed to the outside than its top edge 20 , only with the difference that the windbreak wall 18 from the bottom edge 19 to the top edge 20 not straight but curved.

1

Kondesationsanlage

2

steam manifold

3

fan

4

fan

5

Windbreak wall

6

flow obstruction

7

cross wind

8th

condensation plant

9

support structure

10

Wärmetauscherelemen

11

fan

12

steam manifold

13

Windbreak wall

14

Lower edge v. 13

15

Top edge v. 13

16

Inlet side v. 11

17

Outlet side v. 11

18

Windbreak wall

19

Lower edge v. 18

20

Top edge v. 18

D

steam

.DELTA.P

pressure difference

ΔPL

pressure difference

K

cooling air

northwest

tilt angle

V

vertical

W

wind

WL

hot air

Claims (4)

Condensation plant with on a support structure ( 9 ), in particular roof-shaped heat exchanger elements ( 10 ) over fans ( 11 ) Cooling air (K) is supplied, wherein the heat exchanger elements ( 10 ) of a windbreak wall ( 13 . 18 Are surrounded), as characterized by, that the lower edge ( 14 . 19 ) of the windbreak wall ( 13 . 18 ) is exposed further to the outside than the top edge ( 15 . 20 ) of the windbreak wall ( 13 . 18 ). Condensing plant according to claim 1, characterized in that the windbreak wall ( 13 . 18 ) has at least over a portion of its height an inclination angle (NW) of 5 ° to 35 °, in particular from 15 ° to 30 °, with respect to a vertical (V). Condensation plant according to claim 1 or 2, characterized in that the windbreak wall ( 18 ) concave towards the heat exchanger elements ( 10 ) is curved. Condensation plant according to one of claims 1 to 3, characterized in that the windbreak at least in one of the lower edge adjacent height range a horizontal having running profiling.