UA99328C2 - Combined system for separation of gas mixes and energy conversion - Google Patents

Abstract

The invention relates to separation of gases or mixtures of those by means of treatment with cold with use of cryogenic gas machines and energy conversion with heat pumps and engines that operate by Stirling cycle and can be used in different areas of industry. A combined system for separation of gas mixtures and energy conversion comprises cryogenic Stirling machine, rectification column, heat exchanger for moisture and carbon dioxide freezing, heat insulated vessel for liquid nitrogen, high pressure pump, pipelines for liquid and gaseous nitrogen and device for conversion of energy of gaseous nitrogen. It comprises Stirling heat pump and Stirling engine cooled with liquid nitrogen installed with cryogenic Stirling machine in one body, those have a common rod with a hydraulic cylinder and pneumatic cylinder, and additionally comprises at least one Stirling engine as a device for conversion of difference of energy of heat and liquid nitrogen. The invention provides increase of effectiveness of separation of gas mixtures with minimal power consumption.

Description

The invention belongs to the field of separation of gases or their mixtures by cold treatment using cryogenic gas machines and energy conversion by heat pumps and engines operating on the Stirling cycle, and can be used in various industries.

Currently, there are known installations and systems for the production of liquid nitrogen and oxygen, which contain a Stirling cryogenic machine, a rectification column, a heat exchanger for freezing moisture and carbon dioxide, heat-insulated tanks for liquid nitrogen and oxygen, and deep cooling applications./ Sat. articles under the editorship of M.P. Malkova - M.: Foreign. literature, 1961. - P. 44; patent

Russian Federation: Mo 2151976, IPC B25)) 1/00, publ. 06/27/2000; Mo 2151977, IPC P25)) 1/02, P259 3/00, publ. 06/27/2000; Mo 2166710, IPC P25u 3/04, G258 9/14, publ. 10.05.2001). These installations allow you to obtain liquid nitrogen and oxygen quite efficiently by extracting them from the air.

However, the air and industrial gases contain a sufficiently large amount of other gaseous impurities, the disposal of which is necessary to reduce harmful emissions into the atmosphere. These devices and systems do not allow separating such gas mixtures into components and disposing of them.

In addition, during the operation of such systems and installations, a huge amount of heat is released, which is released into the atmosphere, which is impractical from an economic and ecological point of view.

The closest to the claimed invention in terms of technical essence and achievable result is a combined system for the separation of gas mixtures and energy conversion, containing a cryogenic Stirling machine, a rectification column, a heat exchanger for freezing moisture and carbon dioxide, a heat-insulated capacity for liquid nitrogen, a high-pressure pump, pipelines of liquid and gaseous nitrogen and a device for converting the energy of gaseous nitrogen

Ipatent of the Russian Federation Mo 2162579, IPC R25u 1/02, G258 9/14, publ. 27.01.2001), selected as a prototype. In this system, it is possible to obtain not only liquid nitrogen, but also liquefied natural gas, and at the same time use the energy of gaseous nitrogen to perform useful work, using a turbine with an electric generator located on the same shaft as the turbine as a device for converting the energy of gaseous nitrogen.

The disadvantages of the known system are: impossibility of separating gas mixtures into components; high energy losses due to incomplete use of received cold and heat,

What stands out at the same time; low efficiency of gasification of liquefied gas, which leads to low efficiency of the entire system; high energy consumption of the system.

The claimed invention is aimed at solving the problem of expanding the possibility of separating different gas mixtures into components, making full use of the heat released during cooling, and cold during the gasification of liquefied components with obtaining a high degree of energy conversion at different temperatures, which will increase the efficiency of the separation of gas mixtures with minimal energy costs.

The task is solved by the fact that a combined system for the separation of gas mixtures and energy conversion, containing a cryogenic Stirling machine, a rectification column, a heat exchanger for freezing moisture and carbon dioxide, a heat-insulated capacity for liquid nitrogen, a high-pressure pump, pipelines for liquid and gaseous nitrogen, and an energy conversion device of gaseous nitrogen, according to the invention, contains a Stirling heat pump and an engine

Stirling, cooled by liquid nitrogen, installed with a cryogenic Stirling machine in one housing, having a common rod with a hydraulic cylinder and a pneumatic cylinder, and additionally containing as a device for converting the energy difference of heat and liquid nitrogen at least one engine

Stirling. At the same time, the cryogenic machine and the heat pump are connected by a recuperator, and the heat pump with the engine is connected by a recuperator with a heat accumulator.

The introduction into the combined system of the Stirling heat pump allows you to collect all the thermal energy released during the cooling of gas mixtures, and the Stirling engine, which uses this heat and is cooled by liquid nitrogen, produces energy for the operation of the entire system together with a hydraulic cylinder and a pneumatic cylinder, which uses the energy of gaseous nitrogen

An additional Stirling engine uses excess liquid nitrogen and energy from a thermal accumulator or an additional source of thermal energy to perform useful mechanical work.

The essence of the combined system for the separation of gas mixtures and energy conversion, which is claimed, is explained by the drawing.

The combined system includes a Stirling cryogenic machine 1, a Stirling heat pump 2 and a Stirling engine 3 installed in one housing (not shown in the drawing), which have a common rod 4 with a hydraulic cylinder 5 and a pneumatic cylinder 6, while the cryogenic machine 1 and the heat pump 2 are connected recuperator 7, and heat pump 2 is connected to the engine With recuperator 8, heat accumulator 9, rectification column 10, gas mixture supply pipeline 11, heat exchanger 12 for freezing moisture, heat exchanger 13 for freezing carbon dioxide, heat exchanger 14 for liquefaction of gases with a temperature range of -110 76 - -170 "С, pipeline 15 of cooled gas mixture with pump 16, pipeline 17 with heat-insulated capacity 18 of liquefied gas mixture, pipeline 19 of supply of liquefied gas mixture by pump 20 to the rectification column 10, pipeline 21 and heat-insulated capacity 22 for liquid oxygen, pipeline 23 and a high-pressure pump 24 for supplying liquid oxygen to the heat exchanger 14, pipe pipeline 25 for supplying gaseous oxygen to the consumer, pipelines 26 with heat-insulated capacities 27, 28 for liquid gas components with a temperature of -110 C - - 170 C, pipeline 29 with a heat-insulated capacity 30 for liquid gas components with a temperature of -185 C - -191 "C, pipeline 31 with a heat-insulated capacity 32 for liquid nitrogen, pipeline 33 with a pump 34 for supplying liquid nitrogen to the Stirling Z and 35 engines, pipeline 36 with a liquid metal coolant for supplying energy to a heat accumulator 9, a power take-off shaft 37 to an electric generator 38, a pipeline 39 for the removal of gaseous nitrogen to a device for converting the energy of gaseous nitrogen into a pneumatic cylinder b, pipeline 40 for the removal of gaseous nitrogen to the consumer, pipeline 41 for the removal of gaseous components - hydrogen, neon, helium.

The combined system for separation of gas mixtures and energy conversion works as follows.

From an external source (not shown on the figure), energy is supplied to the hydraulic cylinder 5, driving the rod 4. The cryogenic machine 1 pumps thermal energy into the recuperator 6 from the gas mixture coming through the pipeline 11. The liquefied gas mixture is poured through the pipeline 17 into a heat-insulated capacity 18. Heat pump 2 pumps heat energy with a temperature of -6О0 С - -100 С from recuperator 7 to recuperator 8 with heat accumulator 9, raising the temperature to 1550 "С - 4600 "С.

From the heat-insulated capacity 18, the liquefied gas mixture is fed through the pipeline 19 by the pump 20 into the rectification column 10. The separated liquid oxygen is fed through the pipeline 21

It is fed from heat-insulated capacity 22 and through pipeline 23 by pump 24 under high pressure to heat exchanger 14, in which the components of the gas mixture with a boiling temperature of -110 "C - - 170 "C are liquefied and collected through pipelines 26 in heat-insulated capacities 27 and 28. Through pipeline 25, gaseous oxygen with a temperature of -110C is sent to the heat exchanger 13 for freezing and collecting carbon dioxide from the gas mixture. Oxygen heated to -70 "C is sent to the heat exchanger 12 to remove moisture from the gas mixture entering the system. The gas mixture cooled to -170 "C is pumped by pump 16 through the pipeline | 5 is fed to the cryogenic machine 1, where the rest of the components are liquefied when cooled to -200 "C. Hydrogen, helium and neon, which are not liquefied, but cooled to a temperature of -200 "C, are sent through pipeline 41 for the further technological cycle. Separated components of the gas mixture with a boiling point of -185 "С - - 191 С are collected through pipeline 29 into a heat-insulated capacity 30 and sent to disposal. Liquid nitrogen is collected through pipeline 31 into a heat-insulated capacity 32 and fed into the cooling system of Stirling engines through pipeline 33 by pump 34 With and 35. At the temperature of the liquid metal heat carrier of the heat accumulator 9-600 C (873 K) and cooling with liquid nitrogen -196 "C (77 K), the thermal efficiency of the C engine with external heat supply and removal is equal to:

Efficiency same (Tnagr - Tohol)/I heat same (873-7 7)/873-0.91 -

This means that 91 95 of the thermal energy goes into mechanical energy, and only 995 of the supplied heat needs to be removed, and the remaining liquid nitrogen can be used in one or more additional engines 35, and the heat for heating with a liquid metal coolant is supplied through pipelines 36. If it is lacking in the thermal accumulator 9, then supply from any other source, for example, air in hot regions. At the same time, the obtained power and efficiency will be lower, but a large amount of water in the atmosphere is condensed on the air heat exchangers. When using solar and geothermal heat, the engines of the 35 combined system work without harmful emissions into the atmosphere and do not change the thermal balance of the Earth.

Gaseous nitrogen heated in the engines 3 and 35 is sent through the pipeline 39 to the pneumatic cylinder 6 of the two-stage expansion of nitrogen to use its energy together with the energy of the engine 3, providing for the operation of the combined system to reduce its consumption from the outside. Through pipeline 40, for the utilization of residual energy, gaseous nitrogen is sent to a turbine (not shown in the diagram) with an electric generator 38. Gaseous oxygen and nitrogen, heated to the required temperature and mixed in the proportion necessary for breathing, are sent to the premises of hospitals, enterprises and homes.

The presented diagram shows the general principles of operation of the nodes of the proposed combined system and can be redirected and supplemented to perform special tasks.

Thus, the proposed combined system for separating gas mixtures and energy conversion made it possible to expand the range of separation of various gas mixtures into components and provided an opportunity to dispose of harmful components, fully use the heat released during cooling and cold during gasification of liquefied components with an efficiency of 91 95 conversion of energy with different temperatures into mechanical energy, opening new prospects for external combustion engines, and significantly increase the efficiency of separation of gas mixtures, for example, removing carbon dioxide, carbon monoxide and methane in coal mines with minimal energy costs.

Claims (2)

FORMULA OF THE INVENTION 1. Combined system for separation of gas mixtures and energy conversion, containing a cryogenic Stirling machine, a rectification column, a heat exchanger for freezing moisture and carbon dioxide, a heat-insulated container for liquid nitrogen, a high-pressure pump, pipelines for liquid and gaseous nitrogen, and a device for converting energy from gaseous nitrogen, which characterized in that it contains a Stirling heat pump and a liquid nitrogen-cooled Stirling engine, installed with a Stirling cryogenic machine in the same housing, having a common rod with a hydraulic cylinder and a pneumatic cylinder, and additionally containing as a heat and liquid nitrogen difference conversion device at least one Stirling engine . 2. The system according to claim 1, which differs in that the cryogenic machine and the heat pump are connected by a recuperator. Q. The system according to claim 1, which differs in that the heat pump and the engine are connected by a recuperator with a heat accumulator.