SU1025960A1 - Vertical regenerative heater - Google Patents

Abstract

VERTICAL REGENERATIVE HEATER, comprising a housing, inside which a tube bundle and a condensate cooler are installed, in the casing of which horizontal guide walls, water supply and drainage chambers are placed, communicating respectively with the tube bundle inlet and outlet, the condensate branch fitting, and the branch unit. on the housing from the side of the water supply chamber, and the steam supply pipe to the steam volume, characterized in that, in order to increase reliability and efficiency, the cooler is installed above the water The water supply chamber placed in the lower part of the heater, the cooler housing covers part of the tube bundle, and the cooler communicates with the steam volume of the heater through an additional box installed on the housing that covers the whole tube bundle and has two vertical partitions located on the bottom side in the area of the condensate drain pipe on both sides of the casing with the formation of a water seal.

Description

The invention relates to heat exchangers installed, in particular, in low and high pressure regenerative schemes of power steam turbines and designed to preheat feed water due to the heat of steam taken from the intermediate stages of the turbine and due to the heat of steam taken from the turbine, and due to the heat generated by the supercooling of this vapor condensate.

A regenerative preheater is known, comprising a housing with steam supply and condensate drain pipes, a tube bundle installed inside the housing, and a condensate cooler installed outside the housing and connected through corresponding pipelines with fittings to the housing 1.

The disadvantage of this regenerative preheater is the low reliability of operation and the complexity of operation caused by the autonomous installation of condensate coolers.

A vertical regenerative preheater is also known, comprising a housing inside which a tube bundle and a condensate cooler (C) are installed in a housing - which has horizontal guide walls, water supply and drainage chambers communicated respectively with the tube bundle inlet and outlet, the condensate drain connection mounted on the housing from the side of the water supply chamber and the branch pipe under; water vapor in steam volume 2.

A disadvantage of the known regenerative preheater is the installation of a large number of baffles, which inevitably increases the hydraulic resistance OK on the condensate side. This resistance reduces the available pressure drop across the control valve (valve that dampens the level of condensate in the body), which necessitates an increase in the level of condensate in the body or the discharge of condensate in addition to OK. Both circumstances reduce the efficiency of the heater. In addition, through the hole in the shroud OK, intended to enter the condensate in the event of a sharp decrease in its normal level, the flow of heating steam can flow into the shroud.

If the level of condensate increases after the steam enters the OK casing, this steam will be in an isolated, confined space that is not associated with the vapor volume of the preheater.

In this case, the occurrence of water hammer hazardous for the entire design of the preheater is possible.

Water hammers in the OK can also occur if there are leaks (holes) in the casing located above the level of condensate. Through these holes thanks

the fact that the pressure in the OK is less than that in the steam volume of the preheater, OK enters the steam. Therefore, to heaters with built-in condensate coolers

There are increased requirements in the manufacture, which increases the cost of their production. The design of these heaters does not provide for the possibility of changing the size of the surface of the condensate cooler during its operation.

The purpose of the invention is to increase the reliability and efficiency of the heater.

This goal is achieved by the fact that in a vertical regenerative preheater,

5 comprising a housing inside which a tube bundle and condensate cooler are installed, 8 of which are placed horizontal guide walls, water under the water supply and drainage chambers, communicated respectively with the tube bundle inlet and outlet, a condensate drain fitting installed on the housing from the side the water supplying chamber, and the steam supply pipe to the steam volume; the cooler is installed above the water supply chamber located in the lower part of the preheater; the cooler case covers the entrance part of the tube bundle a, a cooler in communication with the steam heater by volume additionally mounted on the box casing, covering the whole

Q tube bundle and having from the bottom - in the area of the condensate drain pipe are two vertical partitions placed on both sides of the casing with the formation of a water seal.

FIG. 1 depicts a heater,

lengthwise cut; in fig. 2 is a section A-A in FIG. one; FIG. 3 is a section BB in FIG. one.

Vertical regenerative heater includes a housing 1 with a pipe 2 supplying steam to the steam volume 3 and a heater. branch pipe 4 condensate. A tube bundle 5 and a condensate cooler 6 are installed inside the housing 1, in the casing 7 of which horizontal guide walls 8 are placed.

At the bottom of the heater on it

 The housing 1 is installed with a water supply and drainage chambers 9 and 10, communicated respectively with the inlet 11 and the outlet 12 of the tube bundle 5.

0 The condenser condenser 6 is located in the lower part of the heater body 1 and communicates with the steam volume 3 of the heater by means of an additional box 13 installed on the casing 7, covering the whole tube bundle 5 and having

5 sides of the bottom in the area of the pipe 4 condensate drain two vertical partitions 14, placed on both sides of the casing 7 with the formation of a hydraulic seal.

The casing 7 of the cooler 6 covers the input part of the tube bundle 5.

Vertical regenerative heater works as follows.

The feedwater flow through the water supply chamber 9 enters the tube bundle 5, after passing which the feed water through the drainage chamber 10 is removed from the preheater. The heating steam flow through the steam supply pipe 2 enters the steam volume 3 of the preheater, where the heating steam condenses on the tube bundle 5. All condensation of heating steam from the pipe start 5, located above the box. 13 enters the duct 13. The condensate of heating steam from the duct 13 enters directly into the condensate cooler 6, where, due to the presence of horizontal guide baffles 8, it performs several strokes, and through the hydraulic lock formed by two vertical partitions 14 and the casing 7 freely flows to the level of condensate, located in the housing 1.

The movement of condensate in the cooler b occurs due to the condensate back-up accumulating in the duct 13, and the hydraulic trap is necessary to create a guaranteed size of the heating surface in

.cooler 6 condensate, participating in the work under any loads of heating, l. Further, this condensate of heating steam through the pipe 4 of the condensate drain, which is installed on the housing 1 and is not connected; directly connected to the condenser condenser 6, discharged from the preheater. Heating steam condensate, approximately from the total condensate consumption, from the surface of the tube bundle 5, located below the duct 13, flows freely to the level

the condensate in the housing 1, then, during its movement, passes through the tube bundle 5, located under the condenser condenser 6, is cooled and removed from the preheater through the nozzle 4.

Since the movement of condensate in the cooler 6 occurs only due to the pressure created by its column, which accumulates in the box 13, the hydraulic resistance OK on the side of the condensate does not reduce the pressure drop across the control valve (not shown).

Due to the free drain of the condensate of heating steam from the OK and from the rest of the surface of the tube bundle 5 to the level of condensate in the housing 1, the pressure with which it enters the condensate drain pipe 4 is almost equal to the pressure of the heating steam in the steam volume 3 of the preheater. Therefore, a control valve installed on the condensate drain pipe from the preheater behind the condensate drain pipe 4, operates at the highest possible pressure drop, which ensures a steady level maintenance within the specified limits. The condensate pressure in the condenser condenser 6 will always be lower than that of the steam volume 3 of the preheater. Therefore, this condenser condenser 6 will work reliably even if the connections are depressurized (the appearance of holes) in the casing 7.

Condensate will flow into these holes, and steam will not be able through them to enter cooler 6 and cause water hammer. During operation of the cooler, the possibility of the occurrence of water hammer is also excluded, since with any fluctuations in the level of condensate 5 in the duct 13 or in the cooler 6 of the condensate itself, the steam region, which is in the cooler 6, for example, in the case of a level drop, will always be connected to the steam volume of the heater .

0 Thus, in the proposed heater, the built-in condenser condenser 6 is installed at some distance from the water supply chamber 9, while the input part of the tube bundle 5 is used as the heating surface. Such arrangement of the condenser condenser 6 makes it possible to use the maximum temperature difference, which allows with all other conditions being equal, reduce the heating surface of the condenser cooler 6.

The movement of condensate in condensate cooler 6 is carried out only by the backwater created by the condensate column accumulating in the box 13, and therefore

5, the hydraulic resistance of the condensate cooler 6 does not reduce the pressure differential across the control valve. Due to the same condensate column, its pressure in the condenser condenser 6 is always greater than the vapor pressure in the housing .1. and therefore, steam supply to the casing 7 through leaks in the casing 7 is prevented and, therefore, causes are eliminated. for the occurrence of water hammer. Hydraulic shocks in the proposed design of condenser condenser 6 cannot arise due to steam penetration to the heating surface OK along the path of the condensate. The steam penetrated into the OK casing with a sharp drop in the level of condensate in the cooler cannot be in a closed volume, since it is permanently connected to the steam volume 3 of the preheater.

The condenser chiller 6, due to the installation of a water seal, will always have a certain amount of surface guaranteed by the height of this water seal.

 heating involved in the work.

The proposed design of the heater with built-in condenser condenser 6, which has a branch pipe 4 outlet

condensate is not connected tightly by condensate cooler, will allow to install the cooler in the apparatus in the presence of

minimum pressure drop across the control valve will increase the economics of the heater and its reliability.

Claims (1)

VERTICAL REGENERATIVE HEATER, containing a housing inside which a tube bundle and a condensate cooler are installed, in the casing of which there are horizontal guide walls, water supply and water drainage chambers, respectively connected to the pipe bundle inlet and outlet, a condensate discharge pipe mounted on the water supply chamber to the chamber , and a pipe for supplying steam to the steam volume, characterized in that, in order to increase reliability and economy, the cooler is installed above the water supply a chamber located in the lower part of the heater, the cooler casing covers part of the tube bundle, and the cooler is in communication with the steam volume of the heater by means of an additional box installed on the casing, covering the entire tube bundle and having two vertical partitions located on both sides of the bottom of the condensate drain pipe located on both sides side of the casing with the formation of a water seal. SI with Ci> 1025960.