EP1886084A1

EP1886084A1 - Condensing system

Info

Publication number: EP1886084A1
Application number: EP06753194A
Authority: EP
Inventors: Heinrich Schulze
Original assignee: GEA Energietchnik GmbH
Current assignee: GEA Energietchnik GmbH
Priority date: 2005-05-23
Filing date: 2006-05-22
Publication date: 2008-02-13
Anticipated expiration: 2026-05-22
Also published as: MA29230B1; US20080196435A1; DE502006001347D1; DE102005024155A1; AP2007004006A0; AU2006251721A1; TNSN07344A1; CN101091098A; CN100580361C; ES2309965T3; RU2347995C1; EP1886084B1; ATE404837T1; WO2006125420A1; MX2007005843A; AU2006251721B2; ZA200710041B; DE102005024155B4

Abstract

Disclosed is a condensing system comprising a plurality of heat exchanger elements (2) which are disposed especially in a roof-shaped manner and to which cooling air (K) is fed via fans (3). An aerodynamic wall (7) is embodied on an edge (5) of the condensing system (1) while a wind shielding wall (6) that is composed of plate elements (10) is arranged on said edge (5). The plate elements (10) are provided with a plurality of hollow chambers (9) which extend in the vertical direction. An air flow (L) can be introduced into at least some areas of the wind shielding wall (6) in order to configure an aerodynamic wall (7) above the wind shielding wall (6).

Description

condensation plant

The invention relates to a condensation plant having the features in the preamble of patent claim 1.

Especially with larger power plant units and buildings in the immediate vicinity of air-cooled condensation systems must be expected in unfavorable wind conditions partly with significant warm air recirculation. The warm air recirculation takes place in limited areas, especially in the corner areas of a condensation plant. The most obvious solution would be to increase the height of the windbreak walls surrounding the heat exchanger elements. Basically, this would only be necessary in the critical areas. Cost reasons, the statics of the condensation plant and environmental requirements and changing intensities of warm air recirculation speak against this approach and call for a more cost-effective and effective measure to temporarily, that is to reduce only in the concrete existence of the actual problem, the warm air recirculation. In DE 34 21 200 A1, a forced-ventilation condensation system with an aerodynamic wall is proposed to reduce the warm air recirculation. The flow velocity of the aerodynamic wall should be higher than the exit velocity of the cooling air from the heat exchanger elements. Here is dispensed with the easy-to-build wind walls and instead proposed a relatively large-volume nozzle assembly, the nozzles can be arranged above or to the side of the heat exchanger elements. There are also particularly designed slot nozzles conceivable, which are arranged at the edge of the condensation plant and which can be charged with cold or hot air.

Since the problem of warm air recirculation is highly dependent on the prevailing wind direction and the local wind speeds, a barrier formed exclusively as an aerodynamic wall represents a high outlay on equipment which is by no means compulsorily required on all marginal areas of a condensation plant. Although it is basically possible to provide a part of the edge region of the condensation plant with an aerodynamic wall, it is difficult to predict due to the change in wind conditions, if not temporarily other sections of the edge area are affected by increased warm air recirculation. Fast conversion is not possible in such a case. As a precaution, you would have to equip the entire edge area with an aerodynamic wall, which, however, does not make sense for cost reasons.

Proceeding from this, the present invention seeks to provide a condensation plant with an aerodynamic wall, which is at least partially switchable without major structural changes in case of need.

This object is achieved in a condensation plant with the features of claim 1.

Advantageous developments of the inventive concept are the subject of the dependent claims. The condensation plant according to the invention has at its edge a windbreak wall constructed from plate elements, wherein the plate elements have a multiplicity of hollow chambers extending in the vertical direction. The hollow chambers of this windbreak wall are used to form an air flow to create an aerodynamic wall above the windbreak wall. The essential advantage of the condensation plant according to the invention is that no additional slot nozzles or complex nozzle shafts must be installed, since the already existing windbreak wall is used to form an aerodynamic wall.

The introduced air flow is in particular a cold air flow, which mixes with the heated cooling air and alone due to the mixing reduces the negative effects of the remaining warm air circulation. Numerical checks showed a significant reduction of the local warm air recirculation rate by a few percentage points at suitable air flow rates. This leads to an improvement in the condensation performance and thus to an increase in power plant efficiency. The promotion of the accelerated air flow can be accomplished with a separate, e.g. take place with a mobile fan or by branching a partial flow of the cooling air conveying fans, which are associated with the peripheral heat exchanger elements. Although due to the relatively small cross section of the hollow chambers, a pressure loss would occur, however, the delivery rate of the fans is very high, so that the volume flow in the aerodynamic wind wall is relatively high and compensates the pressure losses. By using the existing wind walls can be temporarily and permanently a flexible and effective solution to reduce warm air recirculation with relatively little technical effort and also achieve low costs.

The invention will be explained in more detail with reference to the embodiments illustrated in the drawings. Show it: Figure 1 is a side view of a condensation plant with a plurality of roof-shaped heat exchanger elements arranged in series, which are positioned between edge windshields;

Figure 2 is a condensation plant in plan view;

FIG. 3 a side-side heat exchanger element adjacent to a windbreak wall;

Figure 4 shows a further embodiment according to the representation of Figure 3 and

Figure 5 shows a cross section through a windbreak wall, as used in Figures 3 and 4 are used.

Figures 1 and 2 show a condensation plant 1 with a plurality of heat exchanger elements 2 arranged in series, which is supplied via fans 3 cooling air K. As a result, the water vapor supplied via a steam distribution line 4 condenses within the heat exchanger elements 2. The heat exchanger elements 2 are surrounded overall by a windbreak wall 6 arranged on the edge 5 of the condensation plant 1, which prevents immediate and unhindered recirculation of hot air. The degree of warm air recirculation is highly dependent on the locally prevailing wind direction. In particular, in the corner region of a condensation plant, there may be strong warm air recirculation, which negatively affects the condensation performance and thus the power plant efficiency. In the context of the invention, it is provided that an aerodynamic wall 7 is formed above the windbreak wall 6, which constitutes an additional barrier between the hot air W flowing out of the heat exchanger elements 2 and the cooling air K drawn in from below. FIG. 1 shows by way of example that such an aerodynamic wall 7 is formed only in the area of the windscreen wall 6 left in the image plane. Corresponding edge portions 8 of an aerodynamic wall 7 are likewise shown by way of example in the plan view of FIG. Such an aerodynamic wall is usually only local necessary, especially if very specific wind conditions prevail. It is crucial that the aerodynamic wall 7 can be formed at any desired edge portion 8, without significant structural changes to the condensation plant are required.

The air flow L required for forming an aerodynamic wall 7 is guided through hollow chambers 9 of the windbreak wall 6. In this embodiment, the hollow chambers 9 are trapezoidal configured (Figure 5). Windbreak walls 6 may in particular be constructed of self-supporting plate elements, e.g. have a trapezoid or waveform. FIG. 5 shows an example in which a central plate element 10 with trapezoidal hollow chambers 9 is closed on both sides by planar plate elements 11, 12, so that the required hollow chambers 9 are formed.

Figures 3 and 4 show how the air flow L is introduced into the hollow chambers 9. Figure 3 shows that in the lower edge region of the windbreak wall 6, a valve 13 is arranged, which branches off a partial air flow L1 of the cooling air flow K. The butterfly valves 13 can be opened and closed as needed. In addition to the butterfly valves 13 or optionally, the air flow L can be generated at least proportionally by additional fans 14. The embodiment of Figure 4 shows that the air flow L from the partial flows L1 and L2 composed, which are applied by the additional fan 14 and the fan 3.

Reference numerals:

1 - Condenser

2 - heat exchanger element

3 - Fan

4 - Steam distribution line

5 - edge v. 1

6 - windbreak wall

7 - aerodynamic wall

8 - edge section v. 5

9 - hollow chamber

10 - middle plate element

11 - cover plate

12 - cover plate

13 - Butterfly valve 14 - Additional fan

K - Cooling air L - Air flow L1 - Partial flow L2 - Partial flow W - Warm air

Claims

claims

1. condensation plant with a plurality of particular roof-shaped heat exchanger elements (2), which is supplied via fans (3) cooling air (K), wherein at one edge (5) of the condensation plant (1) an aerodynamic wall (7) is formed, characterized in that a wind protection wall (6) constructed from plate elements (10) is arranged on the edge (5), the plate elements (10) having a multiplicity of hollow chambers (9) extending in the vertical direction, the wind protection wall (6) thus formed ) at least partially an air stream (L) for forming an aerodynamic wall (7) above the windbreak wall (6) can be introduced.

2. Condensation system according to claim 1, characterized in that the plate elements (10) are trapezoidal or wave-shaped and are closed on one side or both sides to form hollow chambers (9) with cover plates (11, 12).

3. condensation plant according to claim 1 or 2, characterized in that the air flow (L) for the aerodynamic wall (7) at least partially a partial air flow (L1) of the peripheral fans (3).

4. condensation plant according to claim 3, characterized in that the air flow (L) is a partial air flow (L1) of the not yet heated cooling air (K).

5. Condensation system according to claim 3 or 4, characterized in that the partial air flow (L1) in the cooling air flow (K) arranged adjusting flaps (13) is adjustable.

6. Condensing installation according to one of claims 1 to 5, characterized in that the air flow (L) is at least partially generated by additional fans (14).