RU2132527C1 - Air-condensing plant - Google Patents

Abstract

FIELD: thermal engineering; steam- turbine units. SUBSTANCE: plant has steam supply line, heat- transfer surface, condensate discharge pipeline, hot well with deaerator and deaeration steam supply line, Condensate discharge pipeline incorporates water seal, and additional steam supply line is routed to bottom part of deaerator. EFFECT: improved economic efficiency of steam power cycle and facilitated condensate deaeration. 1 dwg

Description

 The invention relates to the field of power engineering and can be used in steam turbine plants.

 Known air-condensing installations, consisting of a heat exchange surface, a manifold for supplying steam and condensate drain (see the Handbook of heat exchangers, T-2, M., Energoatomizdat, 1987, p. 89, 91).

 The disadvantage of these installations is a significant hypothermia of the condensate and a high oxygen content in it.

 Condensation plants are known that contain a heat exchange surface, steam supply and condensate drain manifolds that enter the condensate collector with a deaeration device of an inkjet, film or bubble type built into it (see G.G. Shklover, O.O. Milman Studies and calculation of a condensation device steam turbines.- M .: Energoatomizdat, 1985, p. 198-199).

 The main disadvantage of this installation is the need for an additional flow of high pressure steam for deaeration, which reduces the overall efficiency of the steam turbine cycle.

 The purpose of the invention is to increase the efficiency of the steam-power cycle.

 The essence of the invention lies in the fact that an additional steam supply line is installed from the steam supply pipeline to the air-condensing unit to the condensate collector with an integrated jet or film type deaeration device that reduces the consumption of additional steam for deaeration.

 As a result of the presence of this essential feature, the air-condensing installation acquires the following new properties.

 1. Increases the overall efficiency of the steam-power cycle by reducing the consumption of high-pressure steam.

 2. Improves deaeration of the condensate in the jet or film deaeration device, which is in contact with practically pure steam containing a small amount of oxygen.

 The drawing shows an air condensing installation.

 It includes a steam supply pipe 1, a heat exchange surface 2, a condensate drain pipe 3, a condensate collector 4 with a deaeration device 5 and a high pressure steam supply line 8. A water trap 6 is installed on the condensate discharge pipe and an additional steam supply line 7 is laid in the lower part of the deaeration devices 5.

 Air-condensing installation operates as follows. The exhaust steam through the pipeline 1 enters the heat exchange surface 2, where it condenses, the condensate is collected in the pipeline 3 and is discharged through the water trap 6 to the upper part of the deaeration column. At the same time, from the bottom of the deaeration device, almost pure steam containing very small amounts of non-condensing gases flows from line 1 from line 1. Condensate flowing from above containing dissolved gases is heated in countercurrent with an upward steam flow to a saturation temperature and, according to Henry's law, dissolved gases are released into pure heating steam. Part of the steam condenses, heating the condensate, non-condensing steam in a mixture with gases released from the condensate is removed by an air removal device.

 A water trap 6 prevents the breakthrough of steam from the diaeration device into the condensate drain pipe.

 The amount of steam entering through the pipeline 7 is determined by not heating the condensate to the saturation temperature and the flow rate to the air exhaust device. The latter value is usually very small.

 By using the combination of the above design solutions, the supply of hot steam is reduced or eliminated, and the amount of deaeration is improved.

Claims (1)

 An air-condensing installation comprising a steam supply pipe, a heat exchange surface, a condensate drain pipe and a condensate collector with a deaeration device integrated therein and a high pressure steam supply line for deaeration, characterized in that a water seal is installed on the condensate discharge pipe, the drain from which is directed to the top part of the deaeration device, and a line from the steam supply pipeline to the air-condensation unit is connected to the lower part of this device.