RU145832U1 - HEAT ELECTRIC STATION - Google Patents

Abstract

1. Thermal power station, including a series-connected steam turbine, a steam turbine condenser and a condensate pump of a steam turbine condenser, as well as a main electric generator connected to a steam turbine, which is connected through a heating medium to the upper and lower network heaters, which are interconnected by a heated environment, characterized in that it introduced a heat engine with a closed circulation loop, operating on the organic Rankine cycle, while the closed loop heat circulation The fishing engine is made in the form of a circuit with a low-boiling working fluid containing a turboexpander with an electric generator, a water-cooled condenser and a condensate pump, the output of the condensate pump being connected via a heated medium to the input of the lower network heater, and the output of the upper network heater is connected through the heated medium to the input turboexpander, forming a closed cooling circuit. 2. The thermal power plant according to claim 1, characterized in that liquefied carbon dioxide CO is used as a low-boiling working fluid.

Description

The utility model relates to the field of energy and can be used at thermal power plants (TPPs) for the utilization of low-grade heat from steam from heating steam from a steam turbine for additional generation of electric energy.

The prototype is a thermal power plant containing a cogeneration turbine with heating steam extraction, supply and return pipelines of the heating network, network heaters connected via a heated medium between the supply and return pipelines of the heating network and connected via heating medium to the heating selection, heat pump installation with an evaporator included in the return the heating pipeline, and a condenser, while the condenser of the heat pump installation is included in the supply pipe of the heating network after heating ateliers (patent RU No. 2269014, IPC F01K 17/02, 01/27/2006).

The main disadvantage of the prototype is that the utilization of low-grade heat of the steam from the heating taps from the steam turbine is carried out in order to generate additional thermal energy, and not for additional generation of electric energy.

In addition, the disadvantage of the prototype is the relatively low efficiency of thermal power plants for the generation of electric energy, due to the cost of electric power to drive the heat pump installation.

The objective of the utility model is to increase the efficiency of TPPs by utilizing the low-grade heat of the steam from the heating taps from the steam turbine to generate additional electric energy.

The technical result is achieved by the fact that in a thermal power station comprising a series-connected steam turbine, a steam turbine condenser and a condensate pump of a steam turbine condenser, as well as a main electric generator connected to a steam turbine, which is connected via a heating medium to the upper and lower network heaters, which interconnected by a heated medium, according to this utility model, a closed-circuit heat engine has been introduced, operating on an organic qi in this case, the closed loop of the circulation of the heat engine is made in the form of a circuit with a low-boiling working fluid containing a turboexpander with an electric generator in series, a water-cooled condenser and a condensate pump, the output of the condensate pump being connected via a heated medium to the input of the lower network heater, and the output of the upper the network heater is connected via a heated medium to the inlet of the turboexpander, forming a closed cooling circuit.

As a low-boiling working fluid, liquefied carbon dioxide CO _{2 is used} .

Thus, the technical result is achieved by utilizing the low-grade heat of the steam from the heating taps from the steam turbine to additionally generate electric energy, which is carried out by heating in a network heater a low-boiling working fluid (liquefied carbon dioxide CO ₂ ) of a closed-loop heat engine operating on an organic Rankine cycle.

The essence of the utility model is illustrated by the drawing, which presents the proposed thermal power plant having a water-cooled heat engine and network heaters.

In the drawing, the numbers indicate:

1 - steam turbine,

2 - condenser of a steam turbine,

3 - condensate pump condenser of a steam turbine,

4 - the main generator

5 - heat engine with a closed circuit,

6 - turboexpander,

7 - electric generator,

8 - condenser water cooling

9 - condensate pump,

10 - upper network heater,

11 - lower network heater.

The thermal power plant includes a series-connected steam turbine 1, a steam turbine condenser 2 and a condenser pump 3 of the steam turbine condenser, as well as a main electric generator 4 connected to the steam turbine 1, which is connected via heating medium to the upper 10 and lower 11 network heaters, which are between connected by a heated medium.

The difference of the proposed thermal power plant is that it introduced a heat engine 5 with a closed loop, operating on the organic Rankine cycle.

The closed circulation circuit of the heat engine 5 is made in the form of a circuit with a low-boiling working fluid containing a turboexpander 6 connected in series with an electric generator 7, a water cooling condenser 8 and a condensate pump 9, the output of the condensate pump 9 being connected via a heated medium to the input of the lower network heater 11, and the output of the upper network heater 10 is connected via a heated medium to the input of the turbo expander 6, forming a closed cooling circuit.

As a low-boiling working fluid, liquefied carbon dioxide CO _{2 is used} .

The proposed thermal power plant operates as follows.

The exhaust steam coming from the steam turbine 1 into the steam space of the condenser 2 is condensed on the surface of the condenser tubes. In this case, the condensate formed is sent via a condensate pump 3 of the steam turbine condenser to the regeneration system. The power of the steam turbine 1 is transmitted to the main generator 4 connected to one shaft.

The conversion of low-grade thermal energy from the steam from the steam turbine 1 to the mechanical and, further, to the electric one takes place in a closed loop of the heat engine 5 operating on the organic Rankine cycle.

The whole process begins with the compression in the condensate pump 9 of liquefied carbon dioxide CO ₂ , which is sent for heating and evaporation to the lower network heater 11, where heating steam is taken from the steam turbine 1 at a temperature of about 365 K.

The steam coming from the heating selection of the steam turbine 1 into the steam space of the lower network heater 11 condenses on the surface of the heated tubes, inside which the liquefied carbon dioxide CO ₂ flows.

In the process of condensation of heating steam in the lower network heater 11 of the steam turbine 1, the liquefied carbon dioxide CO ₂ is heated to a critical temperature of 304.13 K, followed by its evaporation at a supercritical pressure of 7.4 MPa to 25 MPa. After the lower network heater 11, gaseous carbon dioxide CO _{2 is} sent for overheating to the upper network heater 10, where the heating steam from the steam turbine 1 enters at a temperature of about 400 K.

The steam coming from the heating selection of the steam turbine 1 into the steam space of the upper network heater 10 condenses on the surface of the heated tubes, inside which gaseous carbon dioxide CO ₂ flows.

In the process of condensation of the heating selection steam in the upper network heater 10 of the steam turbine 1, the gaseous carbon dioxide CO ₂ overheats to a supercritical temperature of 304.13 K to 390 K at a supercritical pressure of 7.4 MPa to 25 MPa, which is sent to a turbine expander 6 .

The process is configured in such a way that carbon dioxide CO ₂ does not condense in the turboexpander 6 during the operation of the heat transfer. The power of the turboexpander 6 is transferred to an electric generator 7 connected to one shaft. At the outlet of the turboexpander 6, carbon dioxide CO ₂ has a temperature of about 288 K with a humidity not exceeding 12%.

Further, with a decrease in the temperature of carbon dioxide CO ₂ , it is liquefied in a condenser 8 of water cooling, cooled by industrial ambient water in the temperature range from 278.15 K to 283.15 K.

After the condenser 8 of water cooling in a liquefied state, carbon dioxide CO _{2 is} sent for compression to the condensate pump 9 of the heat engine 5.

Further, the organic Rankine cycle based on a low-boiling working fluid is repeated.

The condenser 8 water cooling has a higher heat transfer efficiency compared to air cooling and does not require large areas of the heat exchange surface. In this case, the power consumption for the drive of the circulation pumps of the water-cooled condenser 8 is less than for the drive of the fans of the air-cooled condenser.

Claims (2)

1. Thermal power station, including a series-connected steam turbine, a steam turbine condenser and a condensate pump of a steam turbine condenser, as well as a main electric generator connected to a steam turbine, which is connected through a heating medium to the upper and lower network heaters, which are interconnected by a heated environment, characterized in that it introduced a heat engine with a closed circulation loop, operating on the organic Rankine cycle, while the closed loop heat circulation The fishing engine is made in the form of a circuit with a low-boiling working fluid containing a turboexpander with an electric generator, a water-cooled condenser and a condensate pump, the output of the condensate pump being connected via a heated medium to the input of the lower network heater, and the output of the top network heater is connected through the heated medium to the input turboexpander, forming a closed cooling circuit. 2. Thermal power station under item 1, characterized in that as a low-boiling working fluid using liquefied carbon dioxide CO ₂ .