RU2053374C1 - Method of preheating of feed water - Google Patents

Abstract

FIELD: heat-power engineering. SUBSTANCE: provision is made in steam power-plant for reheat of water and regenerative heat of feed water in low- pressure heaters, deaerator 2 and high-pressure heaters 5,6 and 7; plant is also provided with remote gas cooler 15 of heating steam drains which are discharged from heaters 5 and 6 to deaerator 2 in separate flows if (i_b-i₁)/(i₁-i_d) ≥ 4,4, where i_b, i₁, i_d are enthalpies of steam fed respectively to turbine inlet, deaerator and heater 5. EFFECT: enhanced efficiency. 1 dwg

Description

 The invention relates to a power system and can be used in schemes for regenerative heating of feed water of steam turbines of thermal power plants.

A known method of heating feed water with steam from turbine offsets in regenerative heaters by sequentially supplying low pressure heaters (HDPE), deaerator and high pressure heaters (LDPE) and draining the heating steam drainage from the second LDPE feed water along the first one before the HDPE deaerator [1 ] A prototype of the present invention is a method for heating the feed water of a steam power plant with intermediate steam overheating by successively heating the feed water with heat exchange with steam from rubins in low-pressure heaters, deaerator and LDPE, parallel to the last part of the feed water in the remote desuperheater of the first LDPE in the water, supplying drainage of heating steam from the above heaters to the downstream and deaerator [2]
A disadvantage of the known technical solution is the low profitability of the thermal circuit implemented by this method.

 The purpose of the invention to increase efficiency.

This goal is achieved by the fact that in the method of heating the feed water of a steam-powered plant with intermediate steam overheating by successive heat exchange of feed water with steam of turbine withdrawals in low-pressure heaters, deaerator and high-pressure heaters, parallel to the last heat exchanges of part of the feed water in the external desuperheater of the first one along the way water heater high pressure, supplying drainage of heating steam from the upstream heaters in the downstream and in the deaerator, with (i _in i ₁ ) / (i ₁ i _d ) ≥ 4.4 drainage of heating steam from the first and second high pressure heaters along the feed water is supplied to the deaerator in separate flows, where i _in , i _d , i _{1 are the} enthalpies of steam supplied respectively to the turbine inlet, deaerator and the first him a high pressure heater.

 The invention is illustrated in the drawing, which shows a diagram of a turbine that implements the method.

 The steam turbine installation comprises a turbine 1, a deaerator 2, connected by a feed water pipe 3 through a feed pump 4 to the first LDPE 5 along the feed water, which is connected through the feed water with subsequent LDPE 6 and 7. The deaerator 2 and LDPE 5, 6 and 7 are connected to 8, 9, 10 and 11 turbines 1, respectively. The condensate of the heating steam from the LDPE 7, 6 and 5 is drained by pipelines 12, 13 and 14, respectively.

 The LDPE 5 is equipped with an external desuperheater (PO) 15. A part of the feed water after the LDPE 5 is diverted through the pipe 17 to the feedwater pipe 3 for the LDPE 7.

 PRI me R. The method of heating the feed water is as follows (for example, the turbine K-500-18,0).

 The feed water is heated in the deaerator 2 with steam from the selection 8 of the turbine 1 and the feed steam from the selection 8 of the turbine 1 and the feed pump 4 are pumped through the LDPE 5, 6 and 7, where it is heated with steam from the samples 9, 10 and 11, respectively.

 The condensate of the heating steam from the LDPE 7 is cascaded through the pipe 12 to the LDPE 6. Then the enthalpies of the steam supplied respectively to the turbine inlet 1, deaerator 2 and the first LDPE 5, which are equal to 804.4, 785.7, 753.6, respectively, are calculated. kcal / kg. The enthalpy difference ratio (804.4 783.7) / (785.7 753.6) 4.54 indicated by the formula is determined.

Since the obtained ratio is more than 4.4, the drainage of the heating steam from LDPE 6 and LDPE 5 is sent to the deaerator 2 in separate streams. To remove the overheating of the steam that comes from selection 8 on the LDPE 5, part of the feed water through the pipe 16 is brought to PO 15, in which it is heated and through the pipe 17 is sent to the feed water line 3. Drainage of drainage from LDPE 6 to deaerator 2 leads to an increase in steam consumption at LDPE 5 from 49.24k t / h to 55.91 t / h, which in this scheme increases the enthalpy of feed water in pipeline 17 by increasing the heat removal in PO 15 from 273.9 to 288.2 kcal / kg. Thus, by increasing the thermal load software 15 HP heater 5 provides a finite increase in feedwater temperature 250.3 ^{° C} to 251.1 ° ^C.

 The steam consumption from selection 8 to deaerator 2 is reduced from 82.74 to 76.82 t / h.

The specified increase in feed water temperature provides a decrease in the specific heat consumption for electricity generation from 1782.7 to 1781.9 kcal / kW ^. h

Claims (1)

METHOD FOR HEATING NUTRITION WATER of a steam-powered plant with intermediate steam overheating by successive heat exchange of feed water with steam from turbine take-offs in low-pressure heaters, deaerator, and high-pressure heaters, parallel to the last heat exchanges of part of the feed water in the remote desuperheater of the first high-pressure water heater drainage of heating steam from upstream heaters to downstream heaters and a deaerator, characterized in that, in order to increase onomichnosti at (i _in - i ₁₎ / (i ₁ - i _d) ≥ 4,4 heating steam drains of the first and second downstream high pressure feedwater heaters is fed into a deaerator separate streams, where _a i, _d i, i ₁ - enthalpies of steam supplied respectively to the turbine inlet, deaerator and the first high-pressure heater after it.