SU730987A1 - Water-supplying plant for power unit - Google Patents

Description

one

The invention relates to the field of power engineering and can be used in power unit and industrial boiler house schemes.

A known water installation is the installation of a power unit containing a deaerator, the feed tank of which is connected to the suction inlet of the booster pump by the pipeline on which the surface water-body heat exchanger 1 is installed.

The disadvantages of such an installation are the presence of a large-sized heat exchanger, which complicates the layout of the power unit, and a decrease in efficiency due to the constant cooling of the condensate in front of the booster pump.

Also known is the water supply installation of a power unit containing a regenerative heating system with heaters and a deaerator, the drain pipe of the feed tank of which is in communication with the suction pipe of the booster pump connected on the pressure side to the feed pump 2.

The disadvantage of such an installation is that the displacement of feed water and condensate occurs in the pipeline without a spinal device, and this does not contribute to a stable overcooling of water in front of the pump. In addition, non-deaerated condensate is unsuitable for blending with feed water.

The purpose of the present invention is to improve feedwater quality and reliability.

This is achieved by the fact that the drain pipe of the pilot tank is equipped with a displacing heat exchanger, and an extraneous source of deaerated water is connected to the last pipeline with a regulating valve.

The drawing shows a schematic diagram of the water supply installation.

A water pump contains a booster pump 1 connected on the pressure side with a suction pipe and a pilot pump 2, and on the suction side with a filament pipe 3, which is connected to an offset heat exchanger 4 embedded in the drain pipe 5 of the feed tank 6 of the deaerator 7. The biasing heat exchanger 4 is connected successively through line 8 with a regulating valve 9, a pump 10 and with an external source 11 of deaerated water, with an atmospheric deaerator. The control valve 9 is connected to the regulator 12 through line 13 through the actuator. The regulator 12, in turn, is connected via pulses 14 and 15 to

temperature sensors 16 and pressure 17, respectively. The feed pump 2 is connected by line 18 to a high pressure soil regenerative heater 19.

The deaerator 7 by the steam duct 20 is connected to a steam turbine 21 withdrawal. and line 22 of heated condensate from low pressure regenerative preheaters 23.

The operation of the water plant is carried out as follows.

The booster pump 1 and the feed pump 2 are put into operation, the water to which they feed through pipeline 3. At the same time, the deaerated feed water containing vapor bubbles enters the mixing heat exchanger 4 through the drain pipe 5 from the feed tank 6 of the deaerator 7. At the same time, the cooling deaerated water from an external source 11 is fed through the valve 9 through the valve 9 to the mixing heat exchanger 4 for condensing steam bubbles and supercooling the feed water.

Before entering the mixing heat exchanger 4, streams having different speeds and temperatures are mixed, vapor bubbles in the supercooled stream are condensed, the temperature and speed of the mixture of feed water with cooling water are stabilized, and a continuously cooled water is supplied to the feed line 3 at the suction booster pump 1.

A wide range of supercooling water control and its connection with steam parameters in deaerator 7 is provided by a controller 12 through line 13 and a control valve 9 that regulates the flow of cooling water to the condenser.

Regulator 12 receives pulses along lines 14 and 15 from sensors of temperature 16 and pressure 17, respectively, and using valve 9, regulates the flow of cooling water and the supercooling temperature of the feed water by the difference of temperature pulses in front of the booster pump 1 and pressure in the steam space of the feed tank 6 of the deaerator 7

From feed pump 2, feed water through line 18 enters a group of high pressure regenerative heaters 19. Heating steam enters deaerator 7 via steam line 20 from steam turbine selection 21. Heated condensate flow through line 22 enters deaerator 7 from a group of low-pressure regenerative preheaters 23.

Thus, the inclusion of the mixing heat exchanger in the drain on-tube of the deaerator feed tank significantly increases the reliability of the deaerator-booster pump-feed pump assembly, i.e. it stabilizes the process of supercooling the feed water in the zone of its exit from the deaerator. The stabilization of the flow, i.e., equalization of its speed and temperature in the area from the deaerator to the booster pump, has been achieved, which ensures that the booster pump and the feeder pump can work without any help and prolong the service life of their flow parts.

Connecting the mixing heat exchanger to an external source of deaerated water improves the quality of supercooled feed water, regardless of the proportion of cooling water added, thereby maintaining the cleanliness of the steam duct and expanding the range of application of the installation, especially on most power units equipped with low surface type preheaters.

Claims (2)

1. USSR author's certificate No. 317811, cl. F 01 / 13/00, 1970. 2. USSR author's certificate number 524009, cl. F 04 D 9/00, 1974. -/five