RU2162532C1 - Off-line stirling-engine heat-and-power cogeneration plant - Google Patents

Abstract

FIELD: thermal engineering; off-line cogeneration plants for feeding stationary and mobile loads. SUBSTANCE: in the course of running, Stirling engine 1 produces useful energy which is converted into electrical energy by means of electric generator 5 mounted on same shaft. Engine 1 is cooled by water supplied to cooler 3 from cooling system 9 communicating with external heat supply system 10 through heat exchanger 9 and with tap water line 14 through heat exchanger 16. Water supplied from water main 12 is partially passed to steam generator 6 through heat exchanger 16 and other portion of water is delivered to steam-water heating pump 7 through heat exchanger 8. High-pressure steam is conveyed from steam generator 6 over line 19 to steam-water heating pump 6 and mixed up with water coming from line 17 to produce high-temperature and high-pressure water. Hence, hot water is delivered under high pressure over line 20 of hot-water supply system. Exhaust-gas line 4 runs from combustion chamber through stream generator 6 and waste-heat exchanger 8. EFFECT: enhanced efficiency, reduced size and mass of power plant. 1 dwg

Description

 The invention relates to the field of heat power and Stirling engines, is intended as stand-alone power plants for stationary and mobile facilities while generating electricity and heat.

 A device is known for a power plant containing an internal combustion engine (ICE) with a power consumer shaft through a coupler and a steam turbine recycling plant with a working fluid circulation circuit including a steam turbine, condenser, feed pump, and a steam generator located in the ICE high-temperature exhaust gas exhaust pipeline (Copyright certificate N 1677360. Bulletin of inventions N 34 from 15.4.91, p. 141-142). However, this device is not designed to generate thermal energy for heat supply to external consumers and it uses a low-efficiency direct-cycle converter - ICE.

 A device for a steam-water pump-heater (PNP), designed for use in various industrial technologies using steam, combining the functions of a heater and a pump at the same time. The use of PPS allows you to significantly reduce energy consumption for your own needs and to reduce the weight and size characteristics of heat exchangers (Petersburg Power Engineering / newspaper /, N 5 (11), dated May 25, 1999). However, previously a steam-water heating pump was not used in cogeneration units.

 It is known that autonomous energy sources based on Stirling engines provide high efficiency and reduce the concentration of harmful emissions in exhaust gases (Kirillov N.G. Application of highly efficient and environmentally friendly Stirling machines in marine power engineering. / Proceedings of the 2nd international conference on marine intelligent technologies "Morintech-97" /, Volume N 5, St. Petersburg. 1997, p. 140). However, to increase the efficiency of the Stirling engine, it is necessary to use coolant with a minimum temperature.

 A device of the Stirling engine is known, including a combustion chamber, a heater, a regenerator, a refrigerator, a piston group and a drive (G. Reeder., C. Hooper. Stirling engines. M., Publishing House Mir, 1986, p. 55).

 Known is a combined installation based on a Stirling engine with an electric generator on one shaft, fuel supply lines and a heat exchanger for heating the liquid through which the exhaust gases of the Stirling engine pass, while the heated liquid is transferred to external pipelines (Application EPO N 0457399. Abstract magazine "Invention of the World ", issue B-65, N 5, 1993, p. 13). However, this installation has a complex system for co-cooling the engine and generator, and also, it is not designed to generate steam for use in external heat supply systems.

 A device is known for a cogeneration unit designed to simultaneously produce electricity and heat, including an internal combustion engine with an electric generator on one shaft, a fuel supply line, an engine cooling circuit, a heating circuit (heat supply system with heat consumers), a heat exchanger system that transfers heat to the cooling engine fluid and high-temperature exhaust gases to the heating circuit, and the control panel ("Construction Review" // Quality Journal //, St. Petersburg. N 5 (32), May-June 1999, p. 16-17). However, this device does not imply the production of steam and its use to reduce electric power consumption for own needs, and also, as a direct cycle converter, an internal combustion engine having a low efficiency and a high concentration of harmful substances in the exhaust gases is used.

 The technical result that can be obtained by carrying out the invention is to increase the efficiency of the installation, by reducing energy consumption for own needs and using a more highly efficient thermodynamic cycle of the direct cycle converter - the Stirling cycle, and reducing the overall dimensions of the autonomous installation.

 To achieve this technical result, an autonomous stirling unit for the simultaneous production of electricity and heat, including a direct-cycle converter (engine) with an electric generator on one shaft, fuel supply lines, a heat exchanger-heat utilizer of high-temperature exhaust gases of the engine through which the exhaust gas pipeline passes the engine, the engine cooling system, connected through a heat exchanger with an external heat supply system, is equipped as a direct converter cycle, by the Stirling engine, heat exchanger-utilizer of high-temperature exhaust gases of the Stirling engine, made in the form of a steam generator, steam-water pump-heater, heat exchanger-utilizer of low-temperature exhaust gases from the Stirling engine, heat exchanger-cooler, and also a water main with a control line to the control line, a valve passing through the heat exchanger-cooler to the steam generator, and a line with a control valve passing through the heat exchange an infrared utilizer of low-temperature exhaust gases from the Stirling engine to the steam-water pump-heater, a high-pressure steam line coming from the steam generator to the steam-water pump-heater, and a hot water supply line coming from the steam-water pump-heater, while the exhaust gas line of the Stirling engine is sequentially first passes through the steam generator, and then through the heat exchanger-utilizer of low-temperature exhaust gases.

 Introduction to the composition of an autonomous stirling installation for the simultaneous production of electricity and heat from the Stirling engine, as a direct-cycle converter, a heat exchanger-utilizer of high-temperature exhaust gases from the Stirling engine, made in the form of a steam generator, a steam-water heater pump, and a heat exchanger-utilizer from low-temperature exhaust gases from the Stirling engine, heat exchanger-cooler, as well as water supply lines passing, respectively, through the heat exchanger-cooler to steam the herator and through the heat exchanger-utilizer of low-temperature gases to the steam-water pump-heater, high-pressure steam lines, hot water supply lines, allows to obtain a new property, which consists in the possibility of using the heat of the Stirling engine cooling system to heat external heat consumers, and the residual heat of the engine exhaust gases Stirling for hot water supply, while high pressure steam is generated with a view to its further use as a replacement etevyh pumps and heat exchangers in a hot water system, and part of the water from the mains water pipeline is used to reduce the temperature of the coolant for the cooling of the Stirling engine.

 The drawing shows an autonomous stirling unit for the simultaneous production of electricity and heat.

 An autonomous stirling installation includes a Stirling engine 1 with a combustion chamber 2 and a refrigerator 3, an exhaust gas line 4, an electric generator 5 located on the same shaft as the engine 1, a heat exchanger-heat utilizer of high-temperature exhaust gases, made in the form of a steam generator 6, a steam-water pump -heater 7, heat exchanger-utilizer of low-temperature exhaust gases 8, cooling system 9 of engine 1, passing through the refrigerator 3 and connected through the heat exchanger 10 with an external heat supply system 11, a tap water line 12 with a control valve 13, which is divided into a line 14 with a control valve 15 and a heat exchanger-cooler 16, through which a cooling system 9 also passes through a steam generator 6, and a line 17 with a control valve 18 passing through a heat exchanger a low-temperature exhaust gas utilizer 8 to a steam-water pump-heater 7, a high-pressure steam line 19, going from the steam generator 6 to the steam-water pump-heater 7, and a main 20 of the hot water supply system. For the circulation of coolant in the cooling system 9 of the engine 1, a pump 21 is provided.

 Autonomous stirling installation for the simultaneous production of electricity and heat works as follows.

 During operation, engine 1 produces useful energy that is converted into electrical energy by means of an electric generator 5 located on the same shaft as engine 1. To cool engine 1, chilled water of cooling system 9 is supplied to refrigerator 3 using pump 21. To relieve heat load from engine 1 and achieve a minimum temperature of the coolant, the cooling system 9 is connected through a heat exchanger 10 to an external heat supply system 11 and through a heat exchanger 16 to a water line 14. Tap water, through a regulator the irrigation valve 13, through line 12 enters lines 14 and 17. Water through the water supply line 14 passes through a heat exchanger-cooler 16, where it cools the coolant of the cooling system 9 of engine 1 to a minimum temperature, while it itself is heated and enters the steam generator 6, where evaporates due to heat exchange with high-temperature exhaust gases coming from combustion chamber 2 through line 4. Water through line 17 passes through a heat exchanger-utilizer of low-temperature exhaust gases 8, where it is heated by low residual heat temperature exhaust gases coming from the steam generator 6, and enters the steam-water pump-heater 7, which simultaneously from the steam generator 6, through line 19, receives high pressure steam. In the steam-water pump-heater 7, due to the special design and the effect of mixing two-phase vapor-liquid media, an increase in pressure occurs, intensive mixing of steam and water, followed by hot water with a high temperature (up to 100 degrees Celsius) and pressure. Due to this pressure, hot water is supplied via line 20 to the hot water supply system. To regulate the flow of water, control valves 13, 15, 18 are provided.

Sources of information taken into account when preparing the application:
1. Copyright certificate. N 1677360. Bulletin of inventions N 34 from 15.4.91, p. 141-142.

 2. "Energy of St. Petersburg" // newspaper //, N 5 (11), from 05.25.99

 3. Kirillov N.G. The use of highly efficient and environmentally friendly Stirling machines in marine energy. / Proceedings of the 2nd Int. confer. on marine intellectual technologies "Morintech-97" /, Volume N 5, St. Petersburg., 1997, p. 140.

 4. G. Reader., C. Hooper. Stirling engines. M., ed. The World, 1986, p. 55.

 5. Application EPO N 0457399. The abstract journal "Invention of the World", issue B-65, N 5, 1993, p. 13.

 6. "Construction Review" // Journal of Quality //, St. Petersburg, N 5 (32), May-June 1999, pp. 16-17 - prototype.

Claims (1)

 Autonomous stirling unit for the simultaneous production of electricity and heat, including a direct-cycle converter (engine) with an electric generator on one shaft, fuel supply lines, a heat exchanger-heat utilizer of high-temperature engine exhaust gases, through which the exhaust gas line of the engine passes, and the engine cooling system connected through a heat exchanger to an external heat supply system, characterized in that it is equipped with a Stirlie engine as a direct cycle converter nga, a heat exchanger-utilizer of high-temperature exhaust gases of the Stirling engine, made in the form of a steam generator, a steam-water pump-heater, a heat exchanger-utilizer of low-temperature exhaust gases of the Stirling engine, a heat exchanger-cooler, and also a water main with a control valve that is divided into a line with a control valve that is divided into a line with a control valve through a heat exchanger-cooler to a steam generator, and a line with a control valve passing through a low-temperature heat exchanger-utilizer the Stirling engine’s exhaust gas to the steam-water heater pump, the high-pressure steam line coming from the steam generator to the steam-water heating pump, and the hot water supply line coming from the steam-water heating pump, while the exhaust gas line of the Stirling engine passes first through the steam generator and then through a heat exchanger-utilizer of low-temperature exhaust gases.