RU223859U1 - Device for direct conversion of thermal energy of exhaust gases into electrical energy of marine diesel engines - Google Patents

Abstract

The utility model relates to the electric power industry and can be used by diesel design organizations, river and sea transport vessels. The technical result is achieved by the fact that the device additionally contains an intermediary heat exchanger installed on the exhaust pipeline with the possibility of heat exchange of the coolant - thermal oil with exhaust gases, the output is connected to the evaporator of the organic Rankine cycle (ORC), where heat exchange occurs between the thermal oil and the low-boiling substance ORC and through the outlet it is connected to the ORC steam turbine, and then the low-boiling substance in the condenser turns into liquid. An intermediary heat exchanger is installed on the exhaust pipeline, the coolant of which is thermal oil. This is caused by the exhaust gas temperature reaching 500°C. Thermal oil is more resistant to high temperatures and allows heat to be transferred to a low-boiling substance (LV) no higher than a given temperature. Thermal oil serves as a transfer link, remaining a liquid at high temperatures, it transfers thermal energy well. The temperature of thermal oil at the outlet of the heat exchanger is in the range of 280-310°C. Thermal oil circulates in a closed circuit: in the heat exchanger, heat exchange occurs between the exhaust gases and thermal oil, then the heated oil enters the evaporator, where, as a result of heat exchange between the thermal oil and the low-boiling substance, the NV boils and its pressure and temperature increase, then the vapor enters the turbine with the generator, as a result of expansion, electrical energy is generated, and the waste thermal oil enters the heat exchanger, where, as a result of heat exchange, the sea water is heated. The heated sea water is used by the thermal energy consumer, then the heated waste water is discharged overboard. Thus, the proposed device for direct conversion of thermal energy of exhaust gases into electrical energy of marine diesel engines through the use of the organic Rankine cycle makes it possible to utilize the thermal energy of exhaust gases, while the resulting electrical energy can be used by ship consumers to increase the efficiency of the ship's power plant. 1 salary f-ly, 1 ill.

Description

The utility model relates to the electric power industry and can be used by diesel design organizations, river and sea transport vessels.

A significant part of the thermal energy of a ship's power plant (SPP) is used extremely inefficiently and is often simply dissipated in the environment.

Known patent No. 92247, H01L 35/28. Marine thermoelectric generator / V.N. Timofeev. Publ. 03/10/2010 in BI No. 7 [1]. A marine thermoelectric generator installed on the exhaust pipeline allows the thermal energy of exhaust gases to be utilized, resulting in a direct conversion of thermal energy into electrical energy. However, the thermoelectric generator utilizes insufficiently spent thermal energy from the exhaust gases of marine diesel plants, and the low efficiency of the thermoelectric generator.

Patent No. 217073, Russia, MPK V63 N 21/14 is also known. Device for converting thermal energy of the cooling system of the main marine diesel engine into electrical energy / Timofeev V.N., Salakhov I.R., Kutepova L.M., Kharisova N.R., Kayumova G., G., Grechko N.V., Yunusova A. R., Timerbulatova I. R., Sharafutdinov A. D. Publ. 03/16/2023. Bull. No. 8 [2]. Utility model No. 217073 relates to the diesel industry and can be used by diesel design organizations and river and sea transport vessels in operation.

A device for converting thermal energy of the cooling system of a marine internal combustion engine into electrical energy, contains the main marine diesel engine; a cooling system consisting of an internal circuit with an electric thermostat and automation elements; external contour; exhaust pipe; superheater; absorption refrigeration machine, organic Rankine cycle.

An organic Rankine cycle evaporator is connected to the internal circuit of the cooling system, and the cycle circuit is connected to a steam turbine, and an electric generator is located on the shaft.

In addition, the device contains an electric three-way valve that regulates the required temperature of the sea water by connecting it to the absorption refrigeration machine. The condenser maintains a temperature difference of 52°C between the heat source - exhaust steam and the heat sink - sea water.

The cooling system contains an electric thermostat and automation elements. Under engine operating conditions, the cooling system maintains a cooling water temperature of 95-98°C at partial loads, and 85°C at nominal loads.

During engine operation, a stream of cooling water enters the evaporator of the organic Rankine cycle and, as a result of heat exchange between the cooling water and the low-boiling substance, it is converted into steam. Next, the steam passes through the superheater and enters the turbine, which rotates the electric generator and generates electrical energy. The exhaust steam enters the condenser, where it is cooled by sea water and turns into liquid, after which it is pumped back into the evaporator. The generated electricity is supplied to the consumer.

The main disadvantage of this patent is that in the ORC evaporator there is heat exchange between a coolant with a temperature of 98°C and a low-boiling substance with a temperature of less than 52°C, and in our application the temperature of the exhaust gas coolant ranges from 450°C and above, so heat exchange directly gases with a low-boiling substance is impossible due to high temperatures, since in this case the proposed design of the product can lead to a fire or an explosion is possible.

The claimed utility model solves the problem of recycling thermal energy from exhaust gases of marine diesel engines.

The technical result is the production of additional electrical energy as a result of the direct conversion of waste thermal energy of exhaust gases into electrical energy.

The technical result is achieved by the fact that a device for direct conversion of thermal energy of exhaust gases into electrical energy of marine diesel engines, containing the main marine diesel engine, exhaust pipeline, tachogenerator sensor, control controller; organic Rankine cycle (ORC), which includes an evaporator, a turbine with a generator, a condenser, a circulation pump, additionally contains an intermediary heat exchanger installed on the exhaust pipeline with the possibility of heat exchange of the coolant - thermal oil with exhaust gases, the output is connected to the evaporator, where ORC occurs heat exchange between thermal oil and low-boiling ORC substance and through the outlet is connected to the ORS steam turbine. In addition, the device for direct conversion of thermal energy of exhaust gases into electrical energy of marine diesel engines additionally contains a seawater heat exchanger, the input of which is connected to the coolant - thermal oil, the output through a thermal energy consumer is connected to the seawater channel.

In fig. 1 shows a schematic diagram of a device for recycling exhaust gases of the main marine diesel engine, which contains the main marine diesel engine 1; heat exchanger 2; evaporator 3, condenser 4, heat exchanger 5; turbine 6, generator 7; electric pumps 8, 9; control controller 10; electricity consumer 11; tachogenerator sensor 12; three-way valve 13; exhaust pipe 14; thermal energy consumer 34; thermal oil channels 15, 16, 17, 18; channels of low-boiling substance 19, 20, 21, 22; sea water channels 23, 24, 25, 26, 27, 28; electrical energy channels 29, 30, 31, 32; electrical signal channel 33.

Thermal oil circulates in a closed circuit and includes heat exchanger 2, channel 15, evaporator 3, channel 16, heat exchanger 5, channel 17, electric pump 9, channel 18.

The closed loop of the organic Rankine cycle (ORC) is charged with a low-boiling substance (LB). When choosing NVs, it is necessary to take into account a number of requirements for them: low cost; good thermophysical properties; non-toxic; lack of environmental impact on the environment (ozone layer, greenhouse effect); freezing at sufficiently low negative temperatures, which is important for the climatic conditions of the northern regions.

The organic Rankine cycle includes an evaporator 3, channel 20, a turbine 6 with a generator 7, channel 21, a condenser 4, channel 22, an electric pump 8, channel 19. The working fluid in ORC is a substance that has a temperature lower than that of water boiling. Due to this, the evaporation of the working fluid occurs at a relatively low temperature, which makes it possible to utilize low-potential energy.

An intermediary heat exchanger 2 is installed on the exhaust pipeline 14, the coolant of which is thermal oil. This is caused by the exhaust gas temperature reaching 500°C. Thermal oil is more resistant to high temperatures and allows heat to be transferred to a low-boiling substance no higher than a given temperature. Thermal oil serves as a transfer link, remaining a liquid at high temperatures, it transfers thermal energy well. The temperature of thermal oil at the outlet of the heat exchanger is in the range of 280-310°C. Thermal oil circulates in a closed circuit: in heat exchanger 2, heat exchange occurs between the exhaust gases and thermal oil, then the heated oil through channel 15 enters the evaporator 3, where, as a result of heat exchange between the thermal oil and a low-boiling substance, the NV boils and its pressure and temperature increase, then through the channel 20 enters turbine 6, and the waste thermal oil through channel 16 enters heat exchanger 5, where, as a result of heat exchange, it heats the sea water. Next, through channel 17 through the electric pump 9 and channel 18 it returns to heat exchanger 2 and the cycle repeats.

Sea water (pump not shown) enters through channel 23 into three-way valve 13, which directs part of the water flow through channel 26 into heat exchanger 5, and the other part through channel 24 into condenser 4. After heat exchange in condenser 4 between sea water and NV, sea water through channels 25, 28 it drains overboard, and the NV turns into liquid and through channel 28, pump 8 continues its closed operating cycle.

In heat exchanger 5, heat exchange occurs between sea water and thermal oil entering through channel 16. Heated water from heat exchanger 5 through channel 27 enters the thermal energy consumer 34, then waste water from the thermal energy consumer 34 through channel 28 is discharged overboard.

A device for directly converting thermal energy of exhaust gases into electrical energy of marine diesel engines operates as follows.

After starting the diesel engine 1, the proposed device begins to work, while the tachogenerator sensor 12 sends a signal via channel 33 to the control controller 10, where electricity is supplied from the consumer 11 via channel 30 and the electric pumps 8, 9 are started. The exhaust gases of the diesel engine 1 pass through the exhaust pipeline 14 and heat exchange occurs between the exhaust gases and thermal oil in heat exchanger 3. The heated oil is supplied through channel 15 to the evaporator 3, where heat exchange occurs between the thermal oil and the low-boiling substance, resulting in vaporization and an increase in the pressure and temperature of the HB.

The resulting steam from evaporator 3 through channel 20 enters turbine 6, which begins to operate, including generator 7, and electrical energy is generated. The received electricity is supplied through channel 29 to the electricity consumer 11.

Thus, a device for directly converting the thermal energy of exhaust gases into electrical energy of marine diesel engines by using the organic Rankine cycle makes it possible to utilize exhaust gases, while the resulting electrical energy can be used by ship consumers to increase the efficiency of the ship's power plant.

A source of information

1. Patent No. 92247, H01L 35/28. Marine thermoelectric generator / V.N. Timofeev. Publ. 03/10/2010 in BI No. 7.

2. Patent No. 217073 Russia, IPC V63 N 21/14. Device for converting thermal energy of the cooling system of the main marine diesel engine into electrical energy / Timofeev V.N., Salakhov I.R., Kutepova L.M., Kharisova N.R., Kayumova G., G., Grechko N.V., Yunusova A. R., Timerbulatova I. R., Sharafutdinov A. D. Publ. 16032.2023. Bull. No. 8.

Claims (2)

1. A device for direct conversion of thermal energy of exhaust gases into electrical energy of marine diesel engines, containing a main marine diesel engine, an exhaust pipeline, a tachogenerator sensor, and a control controller; organic Rankine cycle (ORC), which includes an evaporator, a turbine with a generator, a condenser, a circulation pump, characterized in that it additionally contains an intermediary heat exchanger installed on the exhaust pipeline with the possibility of heat exchange of the coolant - thermal oil with exhaust gases, the heat exchanger output - The thermal oil intermediary is connected to the ORC evaporator, where heat exchange occurs between the thermal oil and the low-boiling ORS substance; the ORS evaporator output for the ORS low-boiling substance is connected to the ORS steam turbine. 2. A device for direct conversion of thermal energy of exhaust gases into electrical energy of marine diesel engines according to claim 1, characterized in that it additionally contains a heat exchanger in which heat exchange occurs between sea water and thermal oil, the input of which is connected to the ORC evaporator via a coolant - thermal oil, the outlet through the thermal energy consumer is connected to the sea water channel.