EP0123986A1 - Feed-water heater - Google Patents

Abstract

In the case of a feed water preheater of the horizontal type with an integrated desuperheater, the last deflection chamber of the desuperheater is provided with lateral steam outlet openings (13). As a result, the heated steam does not reach the free cross-section of the tube bundle in the condensation zone, as before, but in the free space around the condensation bundle (2), which it can then apply to the inside with a minimal flow rate.

Description

The present invention relates to a feed water preheater of the horizontal type according to the preamble of claim 1.

In thermal power plants, the feed water is gradually warmed up in preheaters before it enters the steam generator. These preheaters can be designed in a vertical or horizontal construction. If superheated steam is introduced into a feed water preheater, part of the superheating heat can be used thermodynamically in a desuperheater if the steam is sufficiently overheated. The steam is introduced into the desuperheater through a nozzle directed towards the tube bundle and is passed in countercurrent around the tube bundle and thereby heats the feed water flowing in the tubes, the heating taking place by convective means. With horizontal type desuperheaters, the bleed steam is used corresponding to the degree of superheating at high speed in the axial direction of the preheater through one or more chambers arranged in the desuperheater and then flows into the condensation zone of the preheater. The steam pressure in the condensation part of the preheater is significantly lower than at the inlet of the desuperheater due to the flow losses the steam suffers when it traverses until it leaves the desuperheater.

In the known designs of horizontal preheaters, the steam outlet openings are arranged on the end face of the desuperheater facing the condensation part or on the last desuperheater support plate. At this point, part of the preheater tubes is unsupported, and the steam flows through the outlet openings directly to and along the condensation tubes.

This creates a cross flow between the steam emerging from the desuperheater and the condensate falling from the condensation pipes, whereby the condensate is entrained by the steam and thrown against the condensation pipes, especially at high steam speeds. This can result in erosion / corrosion damage to the condensation pipes.

It is an object of the invention to provide a desuperheater design in which the risk of erosion / corrosion damage from a direct flow of steam to the condensation tubes is avoided.

According to the invention, the aforementioned object is achieved by the characterizing features of patent claim 1.

In the ^- drawing two embodiments of the invention are shown schematically.

• Fig. 1 Einen Längsschnitt durch einen Speisewasservorwärmer mit ungerader Kammerzahl im Enthitzer;
• Fig. la einen Querschnitt durch den Vorwärmer entlang der Schnittlinie A-A in Fig. 1;
• Fig. 2 einen Längsschnitt durch einen Speisewasservorwärmer mit gerader Kammerzahl im En'thitzer;
• Fig. 2a einen Querschnitt durch den Vorwärmer entlang der Schnittlinie B-B in Fig. 2.

It shows:

• 1 shows a longitudinal section through a feed water preheater with an odd number of chambers in the desuperheater.
• Figure la shows a cross section through the preheater along the section line AA in Fig. 1.
• 2 shows a longitudinal section through a feed water preheater with an even number of chambers in the de-heater;
• 2a shows a cross section through the preheater along the section line BB in Fig. 2nd

Elements not essential to the invention, such as the water chambers, support plates and the like, are not shown. The direction of flow of the heating steam is indicated by arrows.

Both embodiments show a horizontal preheater with built-in desuperheater at the feed water outlet and flooded condensate subcooler at the feed water inlet.

In the cross sections of FIGS. 1 a and 2 a, the desuperheating bundles are designated 1, the condensation bundles 2 and the supercooling bundles 3. A steam jacket 5, only partially shown, is placed over the tube bundle. The tubes 6 combined into the bundles mentioned are welded into the tube sheet 4.

The actual desuperheater is formed by a sheet metal jacket 12 which is closed on all sides and carries the steam inlet 7 on its upper side. The supercooling bundle 3 is enclosed on all sides by a supercooling jacket 8. This is by means of baffles 9 in individual chambers shares, the last of which carries the condensate outlet 10. The cooler is flooded, the condensate level is designated 11.

The overheated bleed steam is conducted in the desuperheater at a certain speed in countercurrent to the feed water and releases its superheat. The size of the desuperheater must be selected correctly so that the point at which the outer walls of the pipes reach the local saturation temperature and thus the condensation does not occur within the desuperheater. This means that, depending on the size of the desuperheater, the number of chambers required and thus the number of steam deflections is even or odd. This is crucial for the constructive design of the transition from the desuperheating zone to the condensation zone.

The solution according to the invention is shown in FIGS. I and la, as it presents itself in the case of an odd number of chambers. For the sake of simplicity, only one chamber is shown; it is understood, however, that even with three or five chambers, the same solution, which always affects only the last of the desuperheating chambers, is used.

The sheet metal jacket 12, which is closed on all sides and which surrounds the desuperheater, is provided in the last chamber with lateral steam outlet openings 13 which extend over the entire length of the chamber. These openings 13 are located below the desuperheating bundle 1, since when steam (7) enters at the top into the first chamber and if the number of chambers is odd, the last chamber is also flowed through from top to bottom. In order to prevent the steam escaping from the side from flowing against the steam jacket 5 on the one hand and whipping up the standing condensate (11) on the other hand, close to the outlet openings 13 Deflection plates 14. These baffles 14, which are supported in a suitable manner in the steam space, introduce the steam axially into the condensation zone. To this end, they can be dimensioned somewhat larger in their axial extent than the outlet openings 13, ie they can extend beyond the last deflection chamber into the condensation zone. In the end support plate 15 of the desuperheater, only a small amount of steam flows through the annular gaps between the tubes 6 and the plate holes and thus reaches the free cross section of the tube field in the longitudinal direction of the tube. The main part of the steam flows into the free space around the condensation bundle 2, which it can now flow through from outside to inside at a minimal speed. The baffle plates 14 are at a certain distance 17 from the steam jacket 5. As a result, part of the steam can flow around the deflection plate 14 and act on those parts of the condensation bundle 2 which are arranged directly below the bottom surface of the desuperheater shell 12.

FIGS. 2 and 2a show that solution which is used for an even number of deflection chambers. A desuperheater is shown, which is divided into two chambers by means of a baffle 18. When flowing into the first chamber from top to bottom resp. from the outside in, the desuperheater bundle 1 is in the last chamber from bottom to top resp. Flows through from inside to outside. Accordingly, any steam above the tube bundle 1 should be drawn off.

According to the invention, the sheet metal jacket 12, which is closed on all sides, is now provided in the rearmost chamber with lateral steam outlet openings 13, which in the example shown extend almost over the entire length of the chamber. In addition, there is the possibility of the end support plate 19 directly above the tube to interrupt the bundle. Together with the curved upper part of the sheet metal jacket 12, the support plate 19 thus forms a further outlet opening 20 for the heated steam. In order to avoid erosions of the steam jacket 5, the parts of the preheater jacket opposite the side openings 13 are covered with plated sheets 16.

Claims (4)

1. Feed water preheater of the horizontal type with built-in desuperheater, the sheet metal jacket (12) is divided by baffles (18) into deflection chambers, in which the steam to be desuperheated flows through the desuperheater bundle (1) before it is introduced into the condensation zone in the longitudinal direction of the pipe, thereby characterized in that in the last deflection chamber in the sheet metal jacket (12) steam outlet openings (13) are arranged laterally, which extend over the entire length of the chamber. 2. feed water preheater according to claim 1, characterized in that in the case of an odd number of chambers to the steam outlet openings (13) each has a baffle (14) which runs with a small lateral distance (17) to the steam jacket (5) and is at least the same length extends like the openings (13). 3. feed water preheater according to claim 1, characterized in that with an even number of chambers opposite the steam outlet openings (13) plated plates (16) are arranged made of erosion-resistant material. 4. feed water preheater according to claim 1, characterized in that with an even number of chambers, the end support plate (19) of the desuperheater above the desuperheater bundle (1) is interrupted and forms an outlet opening (20) for the desuperheated steam together with the upper part of the sheet metal jacket (12).

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