RU2326246C1 - Ccpp plant for combined heat and power production - Google Patents

Abstract

FIELD: heat power industry.

SUBSTANCE: combined cycle power plant (CCPP) for combined heat and power production consists of gas turbine unit connected to heat recovery steam generator (HRSG), additional HRSG. Both generators are connected to steam extraction turbine. Turbine heat exchanger condenser and peaking water heater supplied with steam from HRSGs through pressure-reducing desuperheating station are included into heating line of delivery water supplied to consumers. Dry-air cooling tower with main-line recirculation pump are also a part of CCPP. Combined cycle power plant is provided with another gas turbine unit connected to additional HRSG and boiler. Besides, additional boiler is connected to extraction part of steam extraction turbine by steam while by water it is arranged between condenser heat exchanger and peaking water heater which outlet is connected to dry-air cooling tower with recirculation pump.

EFFECT: increase of heat and electric power under concurrent expansion of steam turbine plant capacity when electric and heat load is changed, independent heating of delivery water and minimisation of total plant area.

3 cl, 1 dwg

Description

The invention relates to a power system and can be used in power supply and heat supply systems of the adjacent energy district.

The impending energy crisis forces us to look for new non-traditional ways of providing consumers with heat and energy supply. One of such ways is the combination of combined cycle and steam plants.

Known combined-cycle plant (CCGT) for the combined production of thermal and electric energy according to patent US 5457951, containing a gas turbine installation (gas turbine), a waste heat boiler, from which steam enters a steam turbine that generates electrical energy, two parallel-connected condensers, one of which is connected to the cooling tower, and the second to the low-potential heat supply line to the consumer. In this installation, the heat of the exhaust gases is used to heat water and generate water vapor in a waste heat boiler, which allows to obtain additional electric power and thereby increase the efficiency of the entire combined CCGT unit.

A disadvantage of the known installation is the lack of heat output to an external consumer, which leads to the need for its production at the place of consumption.

The CCGT unit is known as a part of a combined cycle gas turbine power plant, in which a combined cycle of a gas turbine installation and a steam turbine installation is used, containing a steam turbine with two cogeneration regulated steam take-offs for heating the heating system network water in network heaters (D.P. Gokhshtein and others. “The problem of increasing efficiency of steam turbine power plants ”, ML, Gosenergoizdat, 1960, p. 174, fig. 9-28).

The known installation is characterized by insufficient heat load.

Of the known installations, the closest is the combined cycle gas and steam power plant, consisting of a gas turbine unit (GTU) connected to a steam recovery boiler and an additional steam recovery boiler connected to a steam heating turbine, the condenser heat exchanger of which and a peak boiler , the steam to which comes from waste heat boilers through a reduction and cooling unit is included in the heating line for the network water supplied to the consumer, and is dry Air cooling tower with recycling pump (patent GB 2152592, Figure 2).

According to the description of the operation of the known installation, during the season of intense heat consumption, the condenser is connected to the consumer, while the cooling tower can be completely or partially disconnected from the condenser, and, in addition, the water is heated in the boiler. The decrease in the degree of expansion in the turbine with intensive heat consumption is compensated by additional heat sources connected to the utilizers, and due to this, the generation of electric energy by the turbine is not reduced. It should be noted that in the known installation there are two sources of heat, one of which is a gas turbine unit connected to a steam recovery boiler, and the other source of heat is thermal waste or heat from an additional recovery boiler.

A disadvantage of the known installation is the insufficient power of the heat and electric load and the limited maneuverability of the CCGT unit when changing the electric and thermal load.

The technical result, the achievement of which the present invention is directed, is to increase the power of the heat and electric load while expanding the maneuverability of the CCGT unit when changing the electric and thermal load.

The technical result, the achievement of which the present invention is also directed, is to provide independent heating of the network water.

The technical result, to which the present invention is also directed, is to minimize the total installation area.

The specified technical result is achieved by the fact that a combined cycle heat and electric energy production unit consisting of a gas turbine unit (GTU) connected to a steam recovery boiler and an additional steam recovery boiler connected to a steam heating turbine, the condenser heat exchanger of which is peak a boiler, the steam to which comes from waste heat boilers through a reduction and cooling unit, is included in the heating line for the network water supplied to the consumer, and the dry-air cooling tower with a network recirculation pump is equipped with a second gas turbine connected to an additional steam recovery boiler and an additional boiler, with an additional boiler connected in pairs to a selection of a cogeneration turbine, and connected through water between the condenser heat exchanger and the peak boiler, to the outlet of which a dry-air boiler is connected cooling tower with recirculation pump.

The specified technical result is also achieved by the fact that the combined-cycle plant for the combined production of heat and electric energy is equipped with a heating boiler.

The indicated technical result is also achieved by the fact that the thermomechanical part of the combined-cycle plant for the production of heat and electric energy is located in the main building, on the roof of which there is a dry-air fan cooling tower, the heating boiler is made in the form of a tower-type boiler, and waste heat boilers are made in vertical design .

The drawing shows a schematic diagram of a combined cycle plant for the combined production of heat and electric energy.

Combined-cycle plant for the production of heat and electric energy consists of a gas turbine unit (GTU) 1 connected to a steam recovery boiler 2 and an additional steam recovery boiler 3 connected to a steam heating turbine 4 with a condenser heat exchanger 5. The combined cycle gas turbine installation contains a peak boiler 6, the steam to which comes from waste heat boilers 2 and 3 through the corresponding reduction and cooling plants 7. A heat exchanger is included in the heating water supply line 8 (return line) a condenser 5, an additional boiler 9 and a peak boiler 6 connected to a mains pump 10, creating a disposable pressure of the water entering the consumer. A dry-air cooling tower 11 is connected to the output of the peak boiler 11 with a network recirculation pump 12 connected to the water inlet to the heat exchanger of the condenser 5. The combined cycle plant contains a second gas turbine 13 connected to an additional steam recovery boiler 3. Additional boiler 9 is connected in pairs to a selection of a heating turbine 4 and condensate - with a condenser 5. Peak boiler 6 and condenser 5 are condensed through pumps through pumps connected to a deaerator 14 connected to waste heat boilers 2 and 3. Additional boiler 9 for heated water connected between condenser 5 and peak boiler 6.

A combined cycle plant may include a heating water heating boiler (TCE) 15 with a TCE 16 recirculation pump, a transient and peak network pump 17, and shut-off and control equipment with which it can be connected to the return line.

The thermomechanical part of the combined cycle plant can be located in the main building, on the roof of which there is a dry-air fan cooling tower, the heating boiler can be made in the form of a tower boiler, and waste heat boilers can be made in vertical design.

The operation of a combined cycle plant for the combined production of heat and electric energy is as follows.

Two similar gas turbine units 1 and 13 provide increased electrical power to the unit. The exhaust gases of gas turbine units 1 and 13 provide steam generation in waste heat boilers 2 and 3, the steam from which is supplied to a cogeneration steam turbine 4 with adjustable selection. The exhaust steam behind the turbine with a pressure of 0.08 MPa enters the heat exchanger of the condenser 5. The steam from the waste heat boilers 2 and 3 enters through the peak reduction and cooling units 7 to the peak boiler 6. The steam from the selection of the steam turbine 4 with a pressure of 0.25 MPa enters to the additional boiler 9. Condensate from the additional boiler through the condenser, as well as condensate from the peak boiler, is pumped to the deaerator 14. The feed water from the deaerator is fed to the steam boilers by means of low and high pressure feed pumps - tilizatory. Mains water from the return line with the help of a network pump of the 1st stage, selected on the basis of calculating the resistance of a group of heaters (5, 9 and 6) and an in-plant network, enters the network pump, which creates a disposable pressure at the outlet of the installation. Heated water sequentially in the heat exchanger of the condenser 5, the additional boiler 9 and the peak boiler 6 can significantly increase the thermal power of the installation.

In the case of excess heat obtained during the production of electric energy, part of the network water is pumped by the network recirculation pump 12 through a dry-air cooling tower 11 to the return line in front of the condenser.

If necessary, reheating (in case of insufficient heat), part of the network water passes through a heating boiler 15 (TCE). There are options for working TCEs, bypassing heaters. In this case, part of the water is supplied to the TCEs from the return line using transient and peak mode pumps 17, and after it the flows are combined by the network pump 10.

Thus, it is possible to reduce electric power without compromising heat supply to values in the range of 50-100%, taking into account own needs:

- gas turbines from 100 to 50%, which is due solely to environmental requirements;

- steam turbine to the state of maintaining synchronization (load 0.5-1.0 MW).

To ensure the ratio of electric and heat consumption, the heating boiler is selected from the calculation of the heat capacity exceeding the heat output of the steam turbine by approximately 2 (two) times. In this case, the heat load can be regulated in the range from 20 to 100%, which ensures hot water supply to the city, own needs of a combined cycle plant for the combined production of heat and electric energy and losses in networks in the summer. From the same condition, the total electrical power of the installation is determined by the selection of heating boilers.

In order to minimize the area occupied by the installation, one tower-type TCE is installed and waste-heat boilers in vertical design are used.

To reduce the cooling time of the network water (unproductive use of spent steam) when turning on / off the TCEs in operation, starting from 25-30% of the load, if there are free areas, it is desirable to install 2 TCEs in parallel, which will make it possible to halve this period.

To reduce the overall noise background, the thermomechanical part of the installation is located in the main building, on the roof of which, in order to minimize the total area occupied by the station, there is a dry-air fan cooling tower.

Claims (3)

1. Combined-cycle plant for the production of heat and electric energy, consisting of a gas turbine unit (GTU) connected to a steam recovery boiler and an additional steam recovery boiler connected to a steam heating turbine, the condenser heat exchanger of which and a peak boiler, steam for which comes from waste heat boilers through a reduction and cooling unit, included in the line for heating the network water supplied to the consumer, and the dry-air cooling tower with a recirculating mains pump II, characterized in that it is equipped with a second gas turbine connected to an additional steam recovery boiler and an additional boiler, the additional boiler being connected in pairs to a selection of a cogeneration turbine, and water is connected between the condenser heat exchanger and the peak boiler, to the outlet of which a dry-air boiler is connected cooling tower with recirculation pump. 2. Combined-cycle plant according to claim 1, characterized in that it is equipped with a heating cogeneration boiler. 3. Combined-cycle plant according to claim 1, characterized in that the thermomechanical part of the installation is located in the main building, on the roof of which there is a dry-air fan cooling tower, the heating boiler is made in the form of a boiler of a tower type, and waste heat boilers are made in vertical design.