RU2774553C1 - System for the production of environmentally friendly fuel at tpp with a steam boiler - Google Patents

Abstract

FIELD: thermal power engineering.

SUBSTANCE: invention relates to the field of thermal power engineering and can be used in thermal power plants (TPPs) with a steam boiler during their new construction or technical re-equipment with more energy efficient equipment. The system for the production of environmentally friendly fuel is connected to a TPP plant equipped with a steam boiler and using fuel gas coming from a gas distribution station as fuel. The system contains a liquefied natural gas production unit, a hydrogen production unit by electrolysis, one, but not limited to, a gas-oil heat exchanger, one, but not limited to, an expander with an electric generator and a water treatment unit for filtering and cleaning the condensate flow from the cooling tower water traps. The gas-oil heat exchanger and the expander are interconnected in series and connected to the fuel gas supply line. The electric generator of the expander is electrically connected to the liquefied natural gas production unit and to the hydrogen production unit, and the water treatment unit is connected to the outlet of the water traps of the cooling tower and is connected by pipelines for supplying and draining the condensate flow to the electrolyzer of the hydrogen production unit. The gas-oil heat exchanger is connected to the oil supply system of the heating steam turbine, as well as to the flue gas removal system of the boiler of the combined heat and power plant.

EFFECT: organizing the production of environmentally friendly fuel: liquefied natural gas and hydrogen during the operation of a TPP with a steam boiler, increasing energy efficiency and, in general, the efficiency of such a TPP.

1 cl, 1 dwg

Description

The invention relates to the field of thermal power engineering and can be used in combined heat and power plants (CHP) during their new construction or technical re-equipment with more energy efficient equipment.

CHP is a source of thermal energy in centralized heat supply systems: in the form of steam and hot water, including for providing hot water, heating residential and industrial facilities. Gaseous (natural gas), liquid and solid fuels are used as fossil fuels for CHPPs. CHP is also a source of electricity and, being a source of combined generation of electricity and heat, has a fairly high efficiency - up to 75%.

The operating principles of CHPs equipped with steam boilers are widely known (https://altenergiya.ru/poleznye-stati/princip-raboty-i-tipy-tec-ustrojstvo-tes.html#h2_3). Thermal power plants, like thermal power plants, convert the thermal energy of the burned fuel. But in addition to electricity, combined heat and power plants supply heat to consumers. CHP plants are especially relevant in cold climatic zones, where it is necessary to provide residential buildings and industrial buildings with heat. At the CHPP, part of the generated thermal energy is used to produce electricity, and the other part is used to heat the coolant, which is supplied to the consumer.

Mosenergo power plants are known, which generate electricity and heat for Moscow and the region (https://mosenergo.gazprom.ru/about/plantwork/). Mosenergo's CHPP uses the most environmentally friendly fuel, natural gas, as fuel. The gas enters the combustion chamber of the steam boiler through a gas pipeline and burns, heating the water. Also, air is supplied to the combustion chamber of the steam boiler, which serves as an oxidizer in the process of gas combustion. Flue gases formed during the combustion of fuel are discharged into the chimney and dispersed in the atmosphere. The hot gas passes through the flue and heats the water passing through the special tubes of the boiler. When heated, the water turns into superheated steam, which is fed into the cogeneration steam turbine, generating electrical energy for distribution to the consumer. The steam exhausted in the cogeneration steam turbine is sent to the condenser, where it turns into water and returns to the boiler. Cooling towers with water traps are used to cool water with atmospheric air at CHPPs.

However, the main disadvantage of known CHPPs is the lack of efficiency of their operation due to the lack of utilization of the heat of flue gases, the heat of oil from gas and steam turbines, in addition, during the operation of known CHPPs, conditions for generating additional electricity are not provided, and, moreover, it is not provided the possibility of expanding the scope of use of electricity generated at well-known thermal power plants.

Solving the problem of increasing the production of electricity generation at CHPPs, as well as expanding the area of use of such electricity, will improve the efficiency of the CHP as a whole.

As an option, it is expedient to direct the additionally generated electricity at the CHPP to the production of environmentally friendly fuel: to the systems for the production of liquefied natural gas (LNG) and to the hydrogen production systems installed on the territory of the CHP. LNG is recognized by the leading countries of the world as one of the most promising types of energy carriers for the foreseeable future, and hydrogen is the most energy-intensive and light substance of all fuels. At present, the prospect of switching to hydrogen energy has become a reality, since one of the main problems with its storage for further use as automotive fuel has been solved. According to experts, by 2050 the demand for hydrogen will increase tenfold and will take from 15 to 20% of the entire world energy market.

However, both the production of LNG and the production of hydrogen, for example, by electrolysis, require large energy consumption, therefore, the location of such production facilities is economically feasible near sources where there are constantly large surpluses of electricity, as an option, at CHPPs fueled by natural gas, pressure drops which can be used to generate additional electricity.

The aim of the invention is the production of environmentally friendly fuel: liquefied natural gas and hydrogen during the operation of thermal power plants equipped with steam boilers, increasing the energy efficiency of the thermal power plant, increasing the efficiency of the thermal power plant as a whole by ensuring the most complete utilization of heat from the oil of the heating steam turbine and the residual heat of the flue gases of the steam boiler , as well as condensate from the water traps of the cooling tower.

The technical result of the invention is the development of a system for the production of environmentally friendly fuel: liquefied natural gas and hydrogen during the operation of a thermal power plant equipped with a steam boiler, ensuring the generation of additional electricity, as well as increasing the efficiency of the thermal power plant by ensuring maximum utilization of heat from the oil of the heating steam turbine, the residual heat of flue gases steam boiler, condensate from water traps of the cooling tower.

The set goal and the required technical result are achieved due to the fact that the system for the production of environmentally friendly fuel is connected to a combined heat and power plant equipped with a steam boiler, a combined heat and power steam turbine and a cooling tower in the circulating water supply system, and using fuel gas coming from the gas distribution station as fuel. The system includes a liquefied natural gas production unit, a hydrogen production unit by electrolysis, one, but not limited to, a gas-oil heat exchanger, one, but not limited to, an expander with an electric generator and a water treatment unit for filtering and cleaning the condensate stream from the water traps of the cooling tower sent to the electrolyzer of the hydrogen production unit. The gas-oil heat exchanger and the expander are interconnected in series and connected to the fuel gas supply line. The inlet of the expander is connected to the outlet of the gas-oil heat exchanger, the inlet of which is supplied with fuel gas from the gas distribution station, and the outlet of the expander is connected by pipelines for supplying and removing fuel gas to the inlet of the combustion chamber of the steam boiler of the combined heat and power plant. The electric generator of the expander is electrically connected to the liquefied natural gas production unit and to the hydrogen production unit, and the water treatment unit is connected to the outlet of the water traps of the cooling tower and is connected by pipelines for supplying and draining the condensate flow to the electrolyzer of the hydrogen production unit. The gas-oil heat exchanger is connected to the oil supply system of the heating steam turbine, as well as to the flue gas exhaust system of the steam boiler. The flow of fuel gas coming from the gas distribution station, before entering the combustion chamber of the steam boiler, is supplied for heating to the inlet of the gas-oil heat exchanger and then sent to the expander, and the electric power generated by the electric generator of the expander is supplied to the inlet of the liquefied natural gas production unit and to the inlet of the production unit hydrogen. The condensate flow from the water traps of the cooling tower of the circulating water supply system after filtration and purification in the water treatment unit is sent to the electrolyzer of the hydrogen production system. As a heating medium for heating the fuel gas in the gas-oil heat exchanger, the heat of the oil of the cogeneration steam turbine and the residual heat of the flue gases of the steam boiler are used.

When implementing the invention, connecting and operating a system for the production of environmentally friendly fuel: liquefied natural gas and hydrogen on the territory of an existing CHPP equipped with a steam boiler allows, in addition to obtaining environmentally friendly fuel, to increase the energy efficiency of the CHP. In addition, the generation of additional electricity at the CHPP and the provision of the most complete utilization of heat from the oil of the cogeneration steam turbine, the residual heat of the flue gases of the steam boiler, and condensate from the water traps of the cooling tower contribute to an increase in the efficiency of the CHP as a whole.

The present invention and its advantages will be better understood by reference to the following description and the accompanying drawing. The drawing shows a structural diagram of a system for the production of environmentally friendly fuel at a CHP plant equipped with a steam boiler. Various required auxiliary systems such as valves, network heaters, control systems, sensors are excluded from the drawings for the sake of simplicity and clarity of presentation.

The system for the production of environmentally friendly fuel at a CHP with a steam boiler is installed and connected to a combined heat and power plant (CHP) equipped with a steam boiler 3, a heating steam turbine 6 and a cooling tower 11 in the circulating water supply system. The CHP plant uses fuel gas coming from the gas distribution station as fuel. The system includes a liquefied natural gas production unit 12, a hydrogen production unit 13 by electrolysis, one, but not limited to, a gas-oil heat exchanger 16, one, but not limited to, an expander 1 with an electric generator 2 and a water preparation unit 15 for filtering and purification of the condensate flow from the water traps of the cooling tower, directed to the electrolyzer of the hydrogen production unit 13.

In one particular embodiment, in accordance with the accompanying drawing, the system for the production of environmentally friendly fuel at a CHP with a steam boiler operates as follows.

The flow of fuel gas with a pressure of 1.2 MPa is supplied to the CHPP from the gas distribution station. A gas-oil heat exchanger 16 and an expander 1 connected in series with an electric generator 2 are installed on the fuel gas flow supply line. The fuel gas is heated to a temperature of plus 60 ° C in the gas-oil heat exchanger 16 and is fed to expander 1 for expansion. ensures reliable and efficient operation of the expander 1, and also eliminates the possibility of supercooling of the fuel gas after the expander. The electric generator 2 of the expander 1 generates electricity, which is sent to the liquefied natural gas production system 12 installed at the CHPP and connected to the CHP equipment and to the hydrogen production system by electrolysis 13, for the production of environmentally friendly fuel.

The gas-oil heat exchanger 16 is connected to the oil supply system of the cogeneration steam turbine 6, as well as to the flue gas exhaust system of the steam boiler 3 of the CHPP, and the heat of the oil of the cogeneration steam turbine 6 and the residual heat of the flue gases of the steam boiler 3. If necessary, expanders with electric generators and gas-oil heat exchangers for heating fuel gas can be additionally connected to the system.

At the outlet of the expander 1, a fuel gas flow with a temperature of up to plus 40°C and a pressure of up to 0.9 MPa is fed into the combustion chamber 4 of the steam boiler 3, where air is supplied through the compressor 14. A heat exchanger (coil) 5 is installed in the steam boiler 3, in which water evaporates due to the heating of the combustion chamber 4 with the heat of the exhaust gases. 7 heating steam turbine 6 generates electricity for the needs of CHP. From the condenser 9, the condensate is pumped out by the condensate pump 8, passed through the heaters and the deaerator (not shown in the drawing). Here, the condensate is heated by steam to saturation temperature, while oxygen and carbon dioxide are released from it and removed into the atmosphere to prevent equipment corrosion. The deaerated water is pumped to the steam boiler 3. The pressure pump 10 circulates the circulating water in the circulating water supply system. Also, cooling tower 11 is used in the circulating water supply system. One of the key problems in the operation of cooling towers is drop entrainment. Since air flows and water jets move towards each other in the cooling tower, the air flows capture water droplets, creating the problem of water carryover from the cooling tower. To solve this problem, water traps are used (not shown in the drawing). A condensate stream is removed from the water traps of the cooling tower 11, filtered and cleaned in the water treatment unit 15, then sent to the electrolyzer (not shown in the drawing) of the hydrogen production system 13.

Such an arrangement of the system for the production of environmentally friendly fuel, its installation and connection to a thermal power plant equipped with a steam boiler, makes it possible to obtain environmentally friendly fuel: liquefied natural gas and hydrogen by electrolysis, allows you to organize the generation of additional electricity, thereby increasing the energy efficiency of the CHPP, allows you to significantly increase efficiency of the CHP as a whole by ensuring the most complete utilization of the heat received at the CHP during production processes, with the simultaneous direction of this heat for the operation of the system for the production of environmentally friendly fuel.

Claims (1)

An environmentally friendly fuel production system connected to a combined heat and power plant equipped with a steam boiler, a combined heat and power steam turbine and a cooling tower in the circulating water supply system and using fuel gas from the gas distribution station as fuel, which includes a liquefied natural gas production unit, a hydrogen production unit using the electrolysis, one, but not limited to, a gas-oil heat exchanger, one, but not limited to, an expander with an electric generator and a water treatment unit for filtering and cleaning the condensate stream from the water traps of the cooling tower, directed to the electrolyzer of the hydrogen production unit, while the gas-oil heat exchanger and the expander are connected are connected to each other in series and connected to the fuel gas supply line, in addition, the expander inlet is connected to the outlet of the gas-oil heat exchanger, the inlet of which is supplied with fuel gas from the gas distribution station, and the expander outlet is connected It is connected by pipelines for supplying and discharging fuel gas to the inlet of the combustion chamber of the steam boiler of the combined heat and power plant, in addition, the electric generator of the expander is electrically connected to the liquefied natural gas production unit and to the hydrogen production unit, and the water treatment unit is connected to the outlet of the water traps of the cooling tower and is connected by inlet and outlet pipelines condensate flow with the electrolyzer of the hydrogen production unit, while the gas-oil heat exchanger is connected to the oil supply system of the heating steam turbine, as well as to the flue gas exhaust system of the steam boiler, while the fuel gas flow coming from the gas distribution station, before entering the combustion chamber of the steam boiler, is supplied to heating to the inlet of the gas-oil heat exchanger and then sent to the expander, and the electricity generated by the electric generator of the expander is supplied to the inlet of the liquefied natural gas production unit and to the inlet of the hydrogen production unit, in addition, the condensate flow from the water traps of the cooling tower of the circulating water supply system, after filtration and purification in the water treatment unit, is sent to the electrolyser of the hydrogen production system, while the heat of the oil of the heating steam turbine and the residual heat of the flue gases of the steam boiler are used as a heating coolant for heating the fuel gas in the gas-oil heat exchanger.

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