RU2358192C1 - Heat exchanger - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention relates to the field of power engineering and is to find application in heat exchanger apparatus of low and high pressure feed heating systems of steam turbines, heat exchanger apparatus of heat supply systems designed to provide for water reheating due to steam condensation on the heat exchange surface tubes. Proposed is a heat exchanger composed of a housing with a nipple for steam inlet and steam condensate outlet, a tubular system, a water distribution chamber with an inlet, a turn and an outlet compartments with heated water inlet and outlet nipples. Before the nipple for heated water inlet into the heat exchanger a device is installed that reduces the flux passage and is connected to the water chamber turn compartment via a duct equipped with a control valve (valve gate).

EFFECT: improvement of the heat exchanger operational cost-efficiency due to provision for heated water recirculation and increase of the rate of its flow through the heat exchange surface tubes; the tube inside contamination intensity reduction and increase of heated water temperature at the heat exchanger inlet and outlet.

1 dwg

Description

The invention relates to the field of energy and can be used in heat exchangers of regenerative systems of low and high pressure steam turbines, in heat exchangers of heat supply systems designed to heat water by condensation of steam on the pipes of the heat exchange surface.

A well-known heater, comprising a housing with nozzles for steam inlet and outlet for its condensate, a pipe system, a water distribution chamber with nozzles for the inlet and outlet of heated water (PN-350-16-7-II. Industry catalog "Heat transfer equipment of steam turbine plants TSNIITEITAZHMASH, 1989, part I, p. 52).

A disadvantage of the known heater is the limitation of the possibility of increasing the consumption of heated water, and therefore its speed in the tubes of the heat exchange surface due to the inadmissibility of an increase in hydraulic resistance and the possibility of dangerous erosive destruction of the metal of the pipe of the heat exchange surface. These restrictions lead to the fact that the water velocity in the pipes is adopted from the conditions of the nominal mode and is below the permissible at maximum mode. With an increase in the flow rate of heated water, its initial temperature, as a rule, is maintained, which, if the value of the heat exchange surface and the pressure of the heating steam remains constant, leads to a decrease in the temperature of the heated water at the outlet of the heat exchanger.

Known heater, comprising a housing with steam inlet and outlet condensate nozzles, a pipe system, a water distribution chamber with heated water inlet and outlet nozzles and partitions, a rotary chamber with a dividing partition (PSV-200-7-15. Industry catalog. "Heat transfer equipment steam turbine plants ”TSNIITEITYAZHMASH, 1989, part II, p. 57).

By the totality of the features, this known heater is the closest to the claimed one and is taken as a prototype.

A disadvantage of the known heater adopted for the prototype is the fact that with increasing consumption of heated water due to changes in the number and location of partitions in the water chamber and maintaining the pressure of the heating steam and the initial temperature of the heated water, the final temperature decreases. To maintain the temperature at the outlet of the heater, it is necessary to increase the heating steam pressure, which is economically disadvantageous.

The claimed solution allows to increase the efficiency of the heat exchanger by recirculating the heated water and increasing its speed in the pipes of the heat exchange surface, reducing the intensity of contamination of the inner surface of the pipes and increasing the temperature of the heated water at the inlet and outlet of the heat exchanger.

A heat exchanger is proposed, including a housing with a steam inlet and condensate outlet pipe, a pipe system, a water distribution chamber with inlet, swivel and outlet sections with heated water inlet and outlet pipes, in which a narrowing passage section is installed in front of the heated water inlet pipe to the heat exchanger, connected to the rotary section of the water chamber by a pipeline with control valves installed on it (gate valve).

The invention is illustrated in the drawing, which shows a heat exchanger, a longitudinal section (General view).

The heat exchanger includes a housing 1 with a steam inlet pipe 2 and its condensate outlet pipe 3, a pipe system of the first-second stroke 4 and the third-fourth stroke 5 of heated water, input 6, rotary 7 and output 8 sections of the distribution water chamber with a heated water inlet pipe 9 and a pipe outlet of the heated water 10 from the heat exchanger. In front of the inlet of the heated water inlet to the heat exchanger 9, a device 11 (for example, a nozzle) is installed, which narrows the flow cross section for the heated water and increases the water velocity in it. By Bernoulli’s law, the water pressure in the device is less than before and after it. The device 11 is connected to the rotary section 7 of the water chamber by a pipe 12 with a valve 13 installed on it.

The heat exchanger operates as follows. The flow of heating steam enters the housing 1 through the pipe 2, where it condenses on the pipes of the heat exchange surface of the first or second stroke 4 and the third or fourth stroke 5, heating the water. The condensate of the heating steam accumulates in the lower part of the housing and through the pipe 3 is removed from the heat exchanger. The level of condensate in the housing is supported by a control valve installed on the pipeline connected to the pipe 3. The flow of heated water is supplied to the heat exchanger through the pipe and through the constriction device 11 and pipe 9 enters the inlet 6 of the water chamber. From where it is sent to the pipes of the first or second stroke 4, then through the rotary 7 section of the water chamber, water enters the pipes of the third or fourth stroke 5, after which the heated water enters the outlet 8 section of the water chamber and leaves the heat exchanger through the pipe 10. When the heated water moves through the constriction device 11, its pressure in it decreases, then in the pipe 9, where the water velocity decreases, its pressure is partially restored (increases, not reaching the value of the water pressure in front of the constriction device). Due to the hydraulic resistance of the pipes of the first or second stroke 4, the pressure in the rotary section 7 of the water chamber decreases compared to the pressure in the nozzle 9. The constriction device and the decrease in the pressure of the heated water in it are calculated so that the pressure in the device is less than the pressure in the rotary 7 section of the water chamber. Then, when the gate valve 13 is opened, part of the water heated in the pipes of the first or second stroke 4, through the pipe 12 will enter the narrowing device 11, increasing after mixing the temperature of the water entering the inlet section of the water chamber 6 and, ultimately, into the pipes of the first and second Stroke 4. At the same time, the temperature at the inlet to the pipes of the third or fourth strokes 5 will increase, which will lead to an increase in the temperature of the water at the outlet of the heat exchanger. In order to avoid a decrease in the consumption of heated water through the pipe 10 due to the recirculation of the heated water through the pipe 12, its consumption at the initial moment should be increased. The most economically considered heat exchanger will work when the consumption of heated water increases above the nominal. When the valve 13 is closed on the pipeline 12, an increase in the flow rate of water through the heater at a constant pressure of the heating steam will reduce the temperature of the outlet water. With a sufficient "margin" of water pressure in front of the constricting device 11, the opening of the valve 13 on the pipe 12, which can be connected to the rotary section 7 or to the outlet section 8 of the water chamber, the pollution of the inner surface of the pipes due to an increase in the speed of water can be reduced, and the temperature of the heated water at the outlet of the heat exchanger can be increased.

Claims (1)

A heat exchanger comprising a housing with a steam inlet and condensate outlet pipe, a pipe system, a water distribution chamber with inlet, swivel and outlet sections with heated water inlet and outlet pipes, characterized in that a narrowing passage section is installed in front of the heated water inlet to the heat exchanger connected to the rotary section of the water chamber by a pipeline with control valves installed on it (gate valve).