RU2197433C1 - Vacuum-type deaeration unit - Google Patents

Abstract

FIELD: heat engineering. SUBSTANCE: vacuum-type deaeration unit has vacuum deaerator, basic water pipeline and vapors pipeline, which are connected to vacuum deaerator, surface- type vapors cooler connected through vapors pipeline to vacuum deaerator and through coolant pipe to basic water pipeline. Vapors cooler is connected through vapors condensate discharge pipe to upper part of vacuum deaerator by means of hydraulic gate of 8-10 m height. Deaeration unit may be used in boiler rooms and heat electric generating stations. EFFECT: enhanced reliability in operation and reduced cost of thermal water deaeration process. 1 dwg

Description

 The invention relates to the field of power engineering and can be used in boiler rooms and thermal power plants.

 A known analogue is a vacuum deaeration unit containing a vacuum deaerator with feed water and vapor pipes connected to it, a surface-type vapor cooler connected by a vapor pipe with a vacuum deaerator and connected through a cooling medium to the source water pipe (see V.I. Sharapov, Preparation of make-up water heat supply systems using vacuum deaerators. - M .: Energoatomizdat, 1996, Fig. 1.9 on p. 35). This analogue is adopted as a prototype.

 The reasons that impede the achievement of the technical result indicated below when using the known installation adopted as a prototype include reduced reliability and efficiency of vacuum deaeration of water due to inefficient removal and disposal of deaerator vapor.

 The technical result achieved by the claimed invention is to increase the reliability and efficiency of vacuum deaeration of water.

 To achieve this result, a vacuum deaeration unit is proposed, comprising a vacuum deaerator with feed water and vapor pipelines connected to it, a surface-type vapor cooler connected by a vapor pipe to a vacuum deaerator and connected to the source water pipeline through a cooling medium.

 The peculiarity lies in the fact that the vapor cooler is connected by a water trap with a height of 8-10 meters to drain the condensate of the vapor to the upper part of the vacuum deaerator. The new interconnection of elements allows to increase the reliability and efficiency of the process of removal and disposal of a vapor of vacuum deaerators.

 The drawing shows a schematic diagram of a deaeration plant.

 The installation comprises a vacuum deaerator 1 with feed water pipes 2 and evaporator 3 connected to it, a surface-type evaporator cooler 4 connected via a cooling medium to the feed water pipeline. The vapor cooler is connected by a water trap 5 with a height of 8-10 meters to drain the condensate of the vapor to the upper part of the vacuum deaerator.

 Installation works as follows.

 The source water is supplied to the vacuum deaerator 1 via pipe 2, deaerated water is discharged from the deaerator. The vapor formed during deaeration is removed from the deaerator through the vaporization pipe 3 and is cooled in a surface-type vaporizer cooler 4 with the feed water supplied to the deaerator. The condensate vapor from the cooler is sent to the upper part of the vacuum deaerator through the condensate line 5 with a height of 8-10 meters. The supply of condensate vapor to the upper part of the vacuum deaerator through a water trap 8-10 meters high allows you to completely utilize the heat and mass of the vapor and prevent possible suction of air into the deaerator from the vapor cooler.

Claims (1)

 A vacuum deaeration unit comprising a vacuum deaerator with feed water and vapor pipes connected to it, a surface-type vapor cooler connected by a vapor pipe to a vacuum deaerator and connected via a cooling medium to the source water pipe, characterized in that the vapor cooler is connected to the vapor condensate drain condensate conduit to the upper part of the vacuum deaerator through a water trap 8-10 m high.