SU827815A1 - Steam power plant - Google Patents

Description

the hot steam (through the working steam line) and the steam extraction line 18 from the base turbine 2,

In the case of a peak turbine 11 in the form of several cylinders of different pressure (Fig. 2), part of the stages, for example steps 6 and 7, is connected through the ejector 12 and the superheater 15 to the corresponding cylinder of the peak turbine. In each stage of the expander, several ejectors 12 can be connected in parallel with the possibility of adjusting the number of working stages of the expander, depending on the nature of the loading of the peak turbine.

When performing a peak turbine 11 with the development of: the regeneration system, including, for example, heat exchangers 19, 20 and 21, the condensate line 22 can be connected to one of the stages of the expander (for example, to stage 7 or 9).

In line 4 for supplying heat to battery 5, a mixing heat exchanger 23 is connected, connected by line 24 for supplying cold water through pump 25 to collection tank 26. To pipe 1 is connected to steam generator 1 with cold water. The superheater 15 by line 28 of the condensate drain communicates with the heat accumulator. The peak turbine 11 is equipped with a condenser 29. The last stage 9 of the expander pipe 30 communicates with regenerative heat exchangers (not shown in the figures), the base turbine 2.

Steam installation works as follows.

The steam from the steam generator 1 is supplied to the base turbine 2 via the hot steam pipe 3 and via the power supply line 4 to the battery 5. The steam for charging the battery can flow from the hot steam pipe to the ejector 17, in which the hot steam ejects steam from the selection steam pipe 18 the steam of the base turbine, and then through the exhaust pipe 16 enters the bias heat exchanger 23, where simultaneously cold water from the collection tank 26 is supplied by pump 25. Cold water in an amount equal to the amount of heating steam is supplied to the mixing heat exchanger, h Res base turbine regeneration system with feed water is directed through line 27 to the steam generator 1.

When the steam accumulator 5 is discharged from heat, water flows successively in steps 6, 7, 8 and 9 of the expander. The steam from the extender stages is directed through the ejectors 12 through the exhaust pipes 13 to the ejector 14, from where steam superheater 15 flows through the steam supply route 10 to the peak turbine 11. Hot steam is used in the superheater as the heating medium, and condensate is discharged through line 28 to accumulator torus 5

heat From the condenser 29 of the peak turbine, water flows through the mixing regenerative heat exchangers 19, 20, 21 into the stage 9 of the expander, the pressure of which is lower than the pressure corresponding to the temperature of water heating in the system of regeneration of the peak turbine. Water from the last stage of the expander is directed through conduit 30 to the regenerative heat exchangers of the base turbine 2. Using the heat of water from the last stage of the expander reduces the recovery of steam for regeneration in the basic turbine and, thus, increases its capacity.

In the case of the use of surface-type regenerative heat exchangers 19, 20, 21, the condensate of heating steam is displaced with the condensate of the peak turbine 11 and directed to the stage 9 of the expander. If the peak turbine has several cylinders of different pressures, then the condensate from the condenser 29 of the peak turbine, passing successively through regenerative heat exchangers, is sent to stage 7 of the expander. In the general case, the condensate heated in the regenerative heat exchangers enters the expander, the trap of which is fed through the ejector 12 connected through the superheater 15 to the steam supply path 10 to the disk turbine. In this case, the saturation pressure corresponding to the condensate temperature at the outlet of the last regenerative preheater

21, must be higher than the pressure in the appropriate expander stage.

The use of a steam power plant allows to reduce the volume of the battery, while simultaneously increasing the efficiency of production

peak electricity due to partial recovery of the loss of efficiency of the working fluid. In addition, there is no need to develop and produce special peak turbines with different costs in the cylinders, which increase as the vapor pressure decreases (which is directly opposite to the conditions that are in real turbine designs). As peak turbines can

Separate cylinders of serial condensation turbines should be used, in particular a low pressure cylinder (LPD) designed for increased steam consumption, or an additional LPD for the base turbine (in the latter two cases, the need for a special peak turbine abolishes).

Thus, this steam-powered unit allows, as compared to the existing ones, to reduce the cost of ng: the construction of a steam-storage battery and a peak turbine, which leads to a decrease in the unit cost of additional peak power and cost of peak electricity.

Claims (3)

1. A steam-powered unit containing a base turbine equipped with steam extraction lines and a steam superheater, a steam generator connected to the turbine with a steam-generating steam line and connected to the last power line heat accumulator connected via a multi-stage expander to the steam supply line to the cylinders of the peak turbine, characterized by that, in order to improve efficiency, it is equipped with ejectors, connecting two adjacent stages of the expander in pairs and connected exhaust pipes through the superheaters to peak turbine cylinders. 2. The installation of claim 1, is excellent. so that the exhaust pipes of the ejectors of two adjacent pairs of stages of the expander are connected through an ejector additionally installed in the steam supply path to the peak turbine. 3. Installation on PP. 1 and 2, characterized in that an ejector is connected to the battery supply line, which is connected to the steam extraction line of the base turbine. Sources of information taken into account in the examination 1. Jifi Valasek, Manovrierfahigkeit von Fernwarmesystemen aus tschechoslowakischen Sicht, Energietechnik, 1978, no. 6, p. 221-225. thirty Ixf --f 27 2t thirty FIG. g