SU1645571A1 - Thermoelectric plant - Google Patents

Abstract

The invention relates to a power system, in particular, to power plant systems for combined power generation - to heat and power plants, and it allows to increase profitability by reducing costs in the operation of an additional heating circuit. The combined heat and power plant is equipped with a heat pump 7 7, an evaporator 13 and a condenser 14 of which are installed on lines 7 and 11 of the return network water of the main and additional heat consumers 8 and 9, respectively. The compressor 16 of the heat pump 12 is driven in the form of a turbine 19 connected at the inlet to the steam extraction line 5 of the cogeneration turbine (heat distribution complex) 2, to the output 5 to the extraction line 5 or condenser 3 of the turbine 2. Residual heat from the return network water 7 is transferred in the evaporator 13 to the working fluid and the coolant of the heat pump 12 when the return network water is cooled. The working fluid and the coolant are compressed in the compressor 16 and give off heat to the return network water line 11 in the condenser 14. The water is heated through line 10 to the additional heat consumer 9. Using the heat of the return network water in line 7 to ensure, using a heat pump 12, the optimum temperature of the network water in line 10 for the additional heat consumer 9 increases the efficiency of the heat and power plant. 1 hp f-ly, 2 ill. (L S o

Description

The invention relates to a power system, in particular to systems of power plants for the combined generation of electrical and thermal energy - thermal power plants (CHP).

The aim of the invention is to increase the profitability of CHP by reducing the cost of an additional heating circuit.

Figure 1 is a schematic diagram of a CHP plant; Fig. 2 is a schematic diagram of a heat and steam turbine installation.

The CHP contains a source of heat 1 (a boiler, a nuclear reactor, a steam generator, etc.) communicated in pairs with a cogeneration turbine (heating distribution complex) 2, the condenser 3 of which, via pump 4, communicates condensate with source 1 of heat and pipelines 5 of steam extraction connected to regenerative and network heaters (not shown). The network heaters are connected by lines b and 7 of the direct and reverse network water with the main consumer 8 of heat. The additional heat consumer 9 is connected to lines 10 and 11 of the direct and reverse network water.

The CHP is equipped with a heat pump 12, the evaporator 13 and the condenser 14 of which are installed on lines 7 and 11 of the reverse mains BOCS, respectively, and are interconnected by a pipe 15, and with a compressor 16 are pipes 17 and 18 respectively. The compressor 16 is driven in the form of a turbine 19, the inlet of which by pipe 20 is connected to the steam extraction line 5 of the cogeneration turbine 2, and the output by the pipe 21 to the steam extraction line 5 or to the condenser 3. The heat generation turbine 2 drives the electric generator 22.

In working condition, the steam from the heat source 1 enters the heat and power generation turbine (heat distribution complex) 2, the spent steam from which it buys into the condenser, where we condense. and further, in the form of condensate, enters the pump 4, by means of which n heat source 1 is supplied. The return network water via line 7 enters the network heaters or the heat distribution complex 2. where it is heated with steam from the respective extraction lines 5 to the required parameters. On line 6, the direct network question is fed to the main consumer of heat, where it gives off thermal energy and returns on line 7 of the return network water.

Before directing the return mains into the segmented heaters, the residual heat of the return mains is transmitted

through the evaporator 13 to the working fluid and heat carrier of the heat pump 12. This increases the efficiency of the thermodynamic cycle of the heating circuit with the main heat consumer 8 in connection with the after cooling of the return network water in the evaporator 13. The heat carrier and the working fluid of the heat pump 12 are removed from the residual heat from reverse water network in

line 7. enters the compressor 16, where it is compressed to a predetermined pressure, repeatedly increasing its heat content, and when the required thermodynamic parameters are reached, it is directed to the condenser 14, where the resulting heat is returned to the return network water (heat carrier) circulating in the heating circuit with an additional consumer 9 heat

The heat carrier in the line 11 of the return network water, having reached the required thermodynamic parameters in the condenser 14, goes through the line 10 to the additional network water to the additional consumer 9

heat, which gives thermal energy, and enters the line 11. To drive the turbine 19 of the heat pump 12 uses steam from the corresponding pipeline 5 of the extraction of the turbine 2, which is fed to

turbine inlet 19 through line 20, and then, after being triggered in turbine 19, through line 21 returns to steam extraction line 5 or condenser 3 of turbine 2.

The use of a heat pump as a transformer of thermal energy from the thermal potential of the return network water in line 7 to the required thermal potential of the direct network water in

line 10, provided that turbine 19 is used as a drive for compressor 16, will increase the efficiency of the thermodynamic cycle of the main heating circuit by reducing the thermal potential of the return supply water in line 7 and go through the evaporator 13. The efficiency and efficiency of the additional heating circuit is improved by using heat pump 12 with a pipe drive (turbine) 19 and the possibility of lowering the maximum temperature of the direct network water in line 10 depending on the meteorological conditions during the operation of the additional heating circuit according to the individual (not generalized with the main heating circuit) thermal schedule, as well as due to the possibility of providing a flexible (even within one day) heat schedule providing additional consumer 9 heat, which eliminates unproductive energy losses in the additional heating circuit when the ambient air temperature fluctuates.

Claims (2)

Claim 1. Thermal power plant, containing a heat source communicated in pairs with a heat-and-power turbine, the extraction lines of which qapa are connected to regenerative and networked preheaters, the latter of which are connected by direct and reverse mains water five heat consumer, and additional heat with direct and reverse network water, characterized in that, in order to increase efficiency, the heat and power plant is equipped with a heat pump, an evaporator and a condenser which is installed on the reverse network water lines of the main and additional heat consumers respectively. 2. Heat and power plant according to claim 1. characterized in that the drive of the heat pump compressor is made in the form of a turbine, the inlet of which is connected to the steam extraction line of the cogeneration turbine. + + Ґ