SU378643A1 - B'chBLIOTHIA - Google Patents

Description

The invention relates to a power system, in particular to steam power plants of units with direct flow boilers.

Starting circuits of blocks with flow boilers are known, in which there are separators embedded in the steam line of the boiler with a drain formed in the steam separator to the boiler superheater, and water to the pilot expander. The evaporation from the pilot dilator is allocated either to the heating of the reheat system, or to the heating and deaeration of water in the unit deaerator, and the excess vapor is discharged to the turbine condenser. Water from the pilot expansion tank is discharged either to the sewage system, or to the industrial tank, or to the turbine condenser, depending on its quality.

Discharge of water to the deaerator is not acceptable, since the low quality of the waste water does not allow mixing it with feed water. The large starting water consumption in the supply boilers, at least 30% of the nominal, and the loss of heat from the water discharged from the pilot dilator, caused large starting costs and heat losses: the consumption of the discharged water during heating the boiler and turning the turbine to em is about 70-80% of the water flow in the boiler.

The heat carried by the water in the boiler to the integrated separator is in the order of 60%. It is useful to use only the heat from the steam of the pilot dilator for heating and de-aerating the feed water in the deaerator, and sometimes also partially for heating water in one of the low pressure heaters (HDPE). In order to obtain sufficient vapor flow from the expander, it is necessary to maintain a low vapor pressure in it and, therefore, to have a low pressure in the deaerator, which causes a low feed water temperature.

In connection with significant heating and

the flow rate of the boiler in the boiler to the built-in separator heat load of the boiler during the operation on the separator mode does not correspond to the steam consumption through the primary and secondary steam superheaters, therefore the temperature of fresh steam and steam reheat is much higher than the required one. When starting blocks, it is necessary to wash the surfaces of the vapor spaces of high pressure heaters (LDPE) and HDPE from iron oxides.

In order to efficiently clean up, a large amount of heating steam is required for heaters and therefore flushing is performed up to a load of 60-70% of nominal. This reduces the efficiency of the unit, since it does not use the heat discharged into the sewage system or into the condenser condenser of the heating pair of heaters. The purpose of the invention is to improve the efficiency of the start-up modes of operation by utilizing the heat of waste water to preheat the feed water and speed up the flushing of the steam rooms of the high-pressure polyethylene and the HDPE. This is achieved by the fact that the evaporation pipeline from the built-in separator is connected to the vapor space of the latter along the LDPE feedwater, and the drainage pipe from the pilot expander to the vapor space of the last but one preheater. The drawing shows the scheme of the proposed installation. To ensure block start-up on sliding parameters of steam at an intermediate point of the path of the supply boiler after the flue screens 1, an inbuilt valve 2 is installed with the medium removed in front of it through pipe 5 with throttle valve 4 into the built-in separator 5, steam from which through pipe 6 with throttle valve 7 is directed to the boiler superheater 5. Water from the built-in separator through line 9 with the throttle valve 10 enters the kindling pilot 11. Steam from the kindling heater through line 12 through regulating A valve 13 is supplied to a deaerator 14 to deaerate the feed water. The feed water from the deaerator is pumped by the feed pump 15 through the LDPE and fed through the feed valve 16 of the boiler to the boiler. Water from the igniter has been piped through conduit 17 with a regulating valve 18 to the vapor space of the last but one in the course of LDPE feedwater 19. Part of the steam from the built-in separator through regulating valve 20 through conduit 21 is fed to the last PFD feedwater flow 22. 23 with a control valve 24, the condensate of this vapor enters the LDPE 19, where it is mixed with water coming from the pilot reamer. Through pipelines 25 of cascade drainage of LDPE drains with control valves 26, water passes through LDPE 27, and then, along with pipeline 28 with control valve 29, water is passed to HDPE 30. Next, water passes through pipelines 31 of cascade drain of low-pressure heaters with control valves 32 through HDPE and from the second preheater 55 or the first preheater 34 along the main condensate. The HDPE can be discharged through pipeline 55 with a control valve 36 into the circulation channel or through pipeline 37 with a control valve. Ahn 55 to the condenser 39 of the turbine. Water can also be supplied by a drain pump 40 from the HDPE to the main condensate path 41, through which the condensate pump 42 from the condenser 39 deposits the condensate aerator 14. To protect the latter preheater 22 and the last but one preheater 19 along the PVD feedwater from increasing pressure of the heating medium in them equipped with safety valves 43. Pipelines 44 - l 45 s are also provided. control valves for discharging water and steam from the pilot lavatory 11 to the condenser 39 of the turbine, pipe 46 for supplying steam to the deaerator from an external source, and pipelines 47 with control valves and valves for discharging water from the pilot dilator 11, as well as from the first along feed water LDPE 27 down the drain. In addition, the following designations are adopted in the diagram: pipelines 48 for supplying steam from turbine outlets to regenerative heaters, turbine 49, generator 50, intermediate heater 51. When starting the boiler in the separator mode, part of the steam from the built-in separator 5 is removed through control valve 20 to conduit 21 for preheating the feed water entering the boiler in the latter along the feedwater of the LDPE 22. Condensate of this steam is discharged into the LDPE 19 through conduit 23 with a control valve 24. Water from the heating broker 11 p stepped into the vapor space of the LDPE 19 for heating feedwater. From LDPE 19, after giving up some of the heat, the water from the scavenger comes through the pipelines 25 of the cascade drainage of the LDPE drains through the vapor space of the LDPE 27, again partially gives off its heat and then through the pipeline 28 through the control valve 29, which regulates the discharge of water from the LDPE 19 and is directed to the vapor space of the FPD 30. Passage through the vapor spaces of the FPD 30, 33 (34), connected by drainage pipes 31, water heats the main condensate entering the deaerator 14. The deaerator of the feed water in the deaerator is produced by steam, fasting From line 10, piping through pipe 12, through valve 13. After passing through high and low pressure regenerative heaters and delivering its heat to feed water and condensate, the water from the heating pad, cooled to a temperature close to the temperature of the main condensate after condensate, may, depending on of its quality, either be discharged into the sewage system through pipeline 35 with valve 36, if the quality of the water does not allow mixing it with the main condensate, or is supplied to condenser 39 through pipeline 57 with valve 38, if the quality of the water after treatment in the block desalting plant is satisfactory, or supplied with a drain pump 40 to the main condensate path, if it does not require additional chemical treatment of that water. The regulation of the water pass through the HDPE is made by one of three