SU1617160A1 - Thermoelectric plant - Google Patents

Abstract

The invention improves maneuverability and efficiency. Steam from selections 3 of turbine 2 is supplied to mains heaters 6, where it heats the main and distribution heating networks 7 and 12. During the period of electrical load reduction, the network water is heated by electric boiler 10 and 13. The source water from line 32 is preheated in the beam 23 of the condenser 21 It passes through the wastewater treatment plant 35 and is fed to heat pumps 38 and 39, where it is heated and directed to hot water consumers 45 and 48. At the same time, cold water is obtained in heat pumps, which is supplied to consumers 47 and 49. 1 hp f-ly., 1 ill.

Description

The invention relates to energy and can be used in cogeneration plants that release heat for social and industrial needs.

The purpose of the invention is to increase maneuverability and efficiency.

The drawing shows a cogeneration plant.

The cogeneration plant contains a steam boiler 1.0, a turbine 2 connected to it with steam pipelines 3 and 4, connected respectively to a steam consumer 5 and to network heaters 6, which are located in the main heating network 7. In the latter there is also a peak boiler 8, a peak hot water heater a boiler 9, an electric boiler 10 and an intermediate heat exchanger 11, which is connected through a heated medium to a heat distribution network 12. The latter houses an electric boiler 13, a heat consumer 14 and a water-water heater 15 with an input of 16 n heated water and the outlet 17. Turbine 2 is connected to an electric generator 18 having a system 19 of transformation and transmission of electricity and a cooling system 20. The exhaust of the turbine 2 is connected to the condenser 21 with tube bundles 22 and 23, t inputs 24 and 25 and outputs 26 and 27, respectively.

The input 24 of the beam 22 is connected to the cooling tower 28 through chilled water, and the output 26 is connected to the cooling system 20, to the consumer 29 of hot process water and through the heater 30 and the chemical water treatment system 31 to the condenser 21 and the main heating network 12. The input 25 of the beam 23 is connected to the line 32 of the source water, which contains the filter 33 and is connected to the cooling tower by a pipe 34. The output 27 of the beam 23 is connected through the treatment plant 35 and the storage tank 36 to the consumer 37 of hot drinking water.

The cogeneration plant is also equipped with heat pumps 38 and 39 for technical and domestic heat supply, respectively, with pipes 40 and 41 for supplying and discharging cooled water and pipes 42 and 43 for supplying and discharging heated water, respectively. The nozzles 42 and 40 for supplying heated and cooled water of the heat pump 38 for technical heat supply are connected respectively to the storage tank 36 and to the outlet 26 of the tube bundle 22, and the nozzles 43 and 41 for the outlet of heated and cooled water of the heat pump 38 are connected respectively through the hot water accumulator 44 to the consumer 45 hot process water and, through an accumulator of 46 cold water, to a consumer 47 of cold process water. The nozzles 42 and 40 for supplying heated and cooled water of the heat pump 39 of the domestic heating supply are connected to the storage tank 36, and the nozzles 43 and 41 of the outlet for heated and cooled water of the heat pump 39 are connected respectively through the hot water accumulator 44 to the inlet 16 of the water-water heater 15, the output of which 17 connected to the consumer 48 hot domestic water and through the accumulator 46 cold water to the consumer 49 cold domestic water.

Electric boilers 10 and 13 and heat pumps 38 and 39 are connected by electrical power to the system 19 of transformation and transmission of electricity.

Cogeneration works as follows.

The steam generated in the boiler 1 is supplied to the turbine 2, which drives the electric generator 18. The steam from the turbine selection 4 is supplied to the consumer 5 steam and, if necessary, to the peak boiler 8.

Steam from pipelines of 3 turbine withdrawals is directed to the network heaters, in which the network water circulating in the main heating network 7 is heated. In partial modes, the network water is heated in the boiler 9 and in the peak boiler 8. During the failure of the electric load, the network water is heated in the electric boiler 10 . In the intermediate heat exchanger 11, the heating water is circulated in the distribution heat network 12. During the failure of the electrical load, the heating water is heated in the electric boiler 13. Heat from the heat supply 14 etsya heat consumer, for heating water in the water-water heat exchanger 15.

The exhaust steam of the turbine 2 is condensed in the condenser 21 by transferring heat to the tube bundles 22 and 23. The water cooled in the cooling tower 28 is supplied to the inlet 24, heated in it and sent through the outlet 26 to the cooling system 20, and then through the heater 30 and the chemical water treatment system 31 in the condenser 21 and the heating network 7 as make-up water. Partially heated water from the beam 22 is supplied to the consumer 29 hot technical water. Part of the source water from the line 32 through the filter 33 enters through the pipe 34 B 'to the cooling tower 28 as cooling water, and part of it enters the inlet 25 of the beam 23, where it is heated and sent through the outlet 27 to the treatment plant 35, pre-mixed directly with cold water from line 32 to provide the required temperature.

From the treatment facilities 35, water is supplied to the storage tank 36, where a stock of purified water is created. From the tank 36, water is supplied to the heat pumps 38 and 39 of the technical and domestic heat supply, which are included in the work during a period of reduced electrical load. And in the heat. howling pump 38 water from the tank 36 is fed into the pipe 42 for supplying heated water. At the same time, water from the tube bundle 22 is supplied to the heat pump 38 through the pipe 40 for supplying cooled water. In the heat pump 38, heat is transferred from the cooled to the heated water.

Unheated water through the pipe 43 is supplied to the battery 44, and chilled water through the pipe 41 is discharged to the battery 46. From the batteries 44 and 46, water is supplied to consumers 45 and 47 of hot technical and cold technical water, respectively. In the heat pump 39, water from the tank 36 is supplied simultaneously to the nozzles 42 and 40 for supplying heated and cooled water. Hot and cold water is discharged respectively through nozzles 43 and 41 into accumulators 44 and 46. From the latter, cold water is supplied * to consumer 49 of cold domestic water. From the battery 44, hot water is supplied to the consumer 48 of domestic hot water through a water-water heat exchanger 15, where it is additionally heated. Electric boilers 10 and 13 and heat pumps 38 and 39 receive electric power from the electric power transformation and transmission system 19.

The invention improves maneuverability and efficiency by using electric boilers and heat pumps during the failure of the electrical load schedule and supplying consumers with water of various temperature levels.

Claims (2)

Claim 1. A heat and power plant, comprising a steam boiler, a turbine connected to it with steam extraction pipelines connected to network heaters, which are located in the main heating network, a water heater located in the last water heater with a heated water inlet and an outlet connected to a hot domestic water consumer, connected to a turbine is an electric generator with a system for transforming and transmitting electricity, a capacitor connected to the turbine output with a first tube bundle with an input and output connected to a dirne, and with a second tube bundle connected by the entrance to the source water line, and the outlet through the treatment plant to the storage tank, and consumers of hot and cold process water and cold household water, characterized in that, in order to increase maneuverability and efficiency It is equipped with heat pumps for technical and domestic heat supply with nozzles for supplying and discharging heated and cooled water, hot and cold water accumulators, and an electric boiler placed along the heated medium in the main heating system and connected by power supply to the system of transformation and transmission of electricity, while the nozzles for supplying heated and cooled water of the heat pump for technical heat supply are connected respectively to the storage tank and to the output of the first tube bundle, and its nozzles for removing the heated and cooled water are connected respectively through hot water accumulators to the consumer of hot process water and through the cold water accumulator to the consumer of cold process water, and the heating inlet pipes straight and chilled water heat pump is connected to the domestic heat accumulating tank and its discharge pipes being heated and chilled water are connected respectively through a hot water accumulator to the inlet water-water heater and the cold water through the battery - to the consumer household cold water. 2. The cogeneration plant according to claim 1, characterized in that it is equipped with a distribution heating network, and in the latter there is an electric boiler.