RU2156373C1 - Off-line stirling-stirling power plant - Google Patents

Abstract

FIELD: thermal engineering; gas regenerating machines using forward and reverse Stirling cycles. SUBSTANCE: off-line heat-and-power generating plant is meant to supply stationary and mobile loads. Stirling engine 1 produces useful energy in the course of its running which is converted into electricity by means of electric generator 4. Cooling system 10 is provided to cool down engine 1. System 10 coolant gives off heat upon cooling down to ambient temperature in heat exchanger 11 which is used by Stirling heat pump 6 for heating condensate in line 18. Then coolant whose temperature is reduced below ambient is passed to cooler 3 of engine 1 through intermediate heat insulated cavity 12. Amount of air passed through feed line 14 is controlled by valve 16. Waste gases go first through discharge line 17 to steam generator and then to heat exchanger wherein they heat air before its admission to combustion chamber 2. Return condensate is preheated in heat exchanger of load 7 and effectively converted to high-pressure saturated steam in steam generator 5. EFFECT: improved efficiency and environmental friendliness of engine and plant. 1 dwg

Description

 The invention relates to the field of heat power and gas regenerative machines operating on the direct and reverse Stirling cycles, is intended as stand-alone power plants for stationary and mobile facilities while generating electricity and heat.

 Decentralized heat supply systems with heat pumps operating in the reverse Stirling cycle are known, which are characterized by the highest efficiency and environmental friendliness, since ozone-depleting substances such as helium, hydrogen, air, etc. are used as the working fluid of the heat pump. (Kirillov N.G., Sudar Yu.M. et al. Decentralized heat supply systems with heat pumps operating according to the reverse Stirling cycle. / Newsletter: "Thermal Power Technologies" /, N 1, S. -Pb., 1997, pp. .38-40) [1]. However, to reduce the supplied electric energy for driving the heat pump, it is desirable to use a working medium with the highest possible temperature as a source of low potential heat.

 A device is known that operates on the reverse Stirling cycle, containing compression and expansion cavities, a crankcase, a regenerator, a load heat exchanger, a refrigerator, a displacer, a working piston with a displacer rod seal, a drive (Russian patent N 2079069. Bull. N 13, 05/10/97. ) [2].

 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, S.-Pb., 1997, p. 140) [3].

 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: Mir, 1986, p. 55) [4]. However, to increase engine efficiency, it is necessary to minimize the lowest cycle temperature.

 A technical solution is known for a thermal power plant with an engine and a heat pump operating on the forward and reverse Stirling cycles, while the engine and the heat pump are connected through a shaft (US patent N 4458495. Review journal "Invention of the World", issue 8-97, N 3, 1985, p. 13) [5]. However, the Stirling engine and heat pump are made in the form of free-piston machines, which limits the installation's capabilities in terms of electric power and heat output.

 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 fluid through which the exhaust gases of the Stirling engine pass, while the heated fluid is transferred to external pipelines (application EPO N 0457399. The journal “The invention of the world ", issue B-65, N 5, 1993, p. 13) [6]. However, this installation has a low thermal energy productivity, and it does not use the heat of the engine coolant, which leads to the loss of useful low-potential energy.

 The technical result that can be obtained by carrying out the invention is to increase the efficiency of the engine and the installation as a whole, highly efficient production of saturated high-pressure steam, and also to reduce the negative environmental impact on the environment.

 To achieve this technical result, the self-contained power plant "Stirling-Stirling", which includes a Stirling engine with an electric generator on one shaft, fuel supply lines and a heat exchanger for heating the liquid of the external heat consumption system, through which the exhaust gases of the Stirling engine pass, the external heat supply system pipes, is equipped with a heat pump operating on the reverse Stirling cycle, the drive of which can be carried out from the shaft of the Stirling engine or from an external electric drive, and connected to the engine through the engine cooling system passing through the engine and heat pump refrigerators, including the engine coolant cooling heat exchanger located in front of the heat pump, an intermediate heat-insulated tank, and a circulation pump that allows coolant to move through the engine and heat pump refrigerators, as well as the air supply line to the combustion chamber of the engine with an air preheater and a control valve, passage through the cooling coil of the engine cooling system, and a line for discharging exhaust gases from the combustion chamber of the engine passing through the heat exchanger for heating the coolant of the external heat consumption system, made in the form of a steam generator, while the external heat consumption system contains a return condensate heating line with a circulation pump passing through the load heat exchanger heat pump to the steam generator, and a high-pressure saturated steam line connecting the steam generator to the consumer bodies.

 The introduction of the Stirling-Stirling autonomous power plant to the Stirling heat pump associated with the Stirling engine through the engine cooling system containing the cooling liquid cooling exchanger through which the air supply line passes, as well as the design of the heat carrier heat exchanger of the external heat consumption system in the form of a steam generator, allows get a new property, which consists in cooling the coolant of the engine cooling system to temperatures below the environment, which leads to an increase in engine efficiency and the use of residual heat from the engine cooling system to heat condensate in the heat pump load heat exchanger, as well as air heating due to heat exchange from the coolant of the engine cooling system and the residual heat of the exhaust gases, which together leads to an increase in the efficiency of the entire installation and highly efficient high-pressure saturated steam, with the use of a low-emission Stirling engine and a Stirli heat pump ha ozononerazrushayuschim working fluid reduces the level of environmental pollution.

 The drawing shows a self-contained power plant "Stirling-Stirling."

 The self-contained power plant "Stirling-Stirling" includes a Stirling engine 1 with a combustion chamber 2 and a refrigerator 3, an electric generator 4 located on the same shaft as engine 1, a heat exchanger for heating the coolant of an external heat consumption system made in the form of a steam generator 5, a Stirling heat pump 6 s load heat exchanger 7, refrigerator 8 and electric drive 9, cooling system 10 of engine 1 passing through refrigerators 3 and 8 and consisting of a cooling liquid cooling heat exchanger 11 located at d heat pump 6, an intermediate insulated tank 12 and pump 13, an air supply line 14 with an air heating heat exchanger 15 and a control valve 16 passing through a cooling heat exchanger 11 into a combustion chamber 2 of engine 1, an exhaust line 17 of engine 1 passing through a steam generator 5 and a heat exchanger 15, an external heat consumption system consisting of a return condensate heating line 18 with a circulation pump 19 passing through a heat exchanger of the load 7 of the heat pump 6, and a saturated high pressure steam 20, which connects the steam generator 5 with consumers. The engine 1 is equipped with a fuel supply line 21.

 Autonomous power plant "Stirling-Stirling" works as follows.

 During operation, engine 1 produces useful energy that is converted into electrical energy using an electric generator 4 located on the same shaft as engine 1. To cool the Stirling engine 1, a cooling system 10 is provided, by which, taking heat from the working fluid of engine 1 in the refrigerator 3, cooling the liquid enters the cooling heat exchanger 11, where its temperature drops to the ambient level due to heat exchange with air, and is supplied to the refrigerator 8 of the Stirling heat pump 6. By supplying an external energy source from the electric drive 9 (or from the motor drive 1), the heat of the coolant of the cooling system 10 is transferred to the return condensate of the external heat consumption system, flowing through the heat exchanger of the load 7 of the heat pump 6 through line 18 and entering the steam generator 5 using the pump 19. Having entered the load heat exchanger 7 with the ambient temperature and having given a significant part of its heat to the working body of the heat pump 6, the coolant is cooled to a temperature below the environment, and then it is fed into an intermediate heat-insulated container 12, from where it is again supplied to a refrigerator 3 by means of a pump 13 to cool engine 1. The air supplied through line 14 passes through a heat exchanger 11, where it is heated by the cooling liquid of the cooling system 10, and then enters the air heat exchanger 15 where it is heated by the residual heat of the exhaust gases of engine 1, and is supplied to the combustion chamber 2 of engine 1, while the amount of air supplied is regulated by valve 16. Fuel is also supplied to the combustion chamber through line 21, as a result The combustion of which produces high temperature exhaust gases. These gases are discharged through the discharge line 17 to the steam generator 5. Into the steam generator 5 through the condensate supply line 18, the return condensate is pre-heated to the boiling temperature in the load heat exchanger 7 by means of the pump 19. As a result of the heat exchange by the exhaust gases, the return condensate boils and passes saturated saturated superheated steam. After the steam generator, the exhaust gases enter the heat exchanger 15, where they give the residual heat to the air, before it enters the combustion chamber 2 of the engine 1. Then the exhaust gases are removed into the environment. Saturated steam from the steam generator 5 through line 20 is supplied to an external consumer.

Sources of information
1. Kirillov N.G., Sudar Yu.M. and others. Decentralized heat supply systems with heat pumps operating on the reverse Stirling cycle. / Newsletter: "Thermal Power Technologies". N 1, S.-Pb., 1997, pp. 38-40.

 2. Patent of Russia N 2079069. Bull. N 13 from 05/10/97.

 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, S.-Pb., 1997, p. 140.

 4. G. Reeder., C. Hooper. Stirling engines. M.: Mir, 1986, p. 55.

 5. US patent N 4458495. The abstract journal "Invention of the World", issue B-97, N 3, 1985, p. 13.

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

Claims (1)

 Autonomous power plant "Stirling-Stirling", which includes a Stirling engine with an electric generator on one shaft, fuel supply lines and a heat exchanger for heating the liquid of an external heat consumption system, through which the exhaust gases of the Stirling engine pass, external heat supply system pipes, characterized in that it is equipped with a heat a pump operating according to the reverse Stirling cycle, the drive of which can be carried out from the shaft of the Stirling engine or from an external electric drive, and connected to the engine through cuts the engine cooling system passing through the engine and heat pump refrigerators, including the engine cooling system cooling liquid heat exchanger located in front of the heat pump, an intermediate heat-insulated tank, and a circulation pump that provides cooling fluid movement through the engine and heat pump refrigerators, as well as a line air supply to the combustion chamber of the engine with an air preheater and a control valve passing through the heat exchangers to cooling the engine cooling system, and the exhaust gas discharge line from the engine combustion chamber passing through the heat exchanger of the heat transfer medium of the external heat consumption system, made in the form of a steam generator, while the external heat consumption system contains a return condensate heating line with a circulation pump passing through the heat pump load heat exchanger to the steam generator, and a high-pressure saturated steam line connecting the steam generator with consumers.