RU2088864C1 - Power producing and cooling system - Google Patents

Abstract

FIELD: thermal engineering; power generating and cooling system for equipment not communicating with atmosphere during their functioning. SUBSTANCE: exhaust gases of diesel engine 6 enter in reaction with alkaline-earth metal and produce great amount of heat and synthesis gas used as diesel engine fuel. Synthesis gas possesses high thermodynamic potential and goes to heater 13 thereby ensuring thermodynamic cycle with useful refrigeration output obtained. Liquid oxygen taken from tank 21 functions at first as heat-accumulating substance and then, in gaseous state, it expands in expander 21 producing useful work and is used as oxidizer for diesel engine 6. EFFECT: enlarged functional capabilities. 1 dwg

Description

 The invention relates to the field of power engineering and can be used as an energy refrigerating system for objects operating without any connection with the atmosphere.

 The device of the Wulemier-Taconis machine is known, which is a mechanically closed system consisting of a refrigerating machine and an engine, the latter developing such power as is needed for the refrigerating machine. The cycle is carried out by supplying heat from an external source. As the working fluid, substances are used that do not destroy the ozone layer, for example, helium, air, etc. However, for the effective implementation of the working cycle of the machine, it is necessary that the heat supplied to the machine be of a sufficiently high thermodynamic potential (Arkharov A.M. Marfenina I.V. Mikulin E.I. Theory and calculation of cryogenic systems. M. Mechanical Engineering, 1978. p. 305).

A known method of producing an artificial gas mixture and increase the thermodynamic potential of the exhaust environments of a diesel power plant operating in a closed cycle for objects without communication with the atmosphere. The essence of this method is the oxidation of metal by oxygen from the composition of dioxide (CO ₂ ) at high temperature with the release of a significant amount of heat, which allows you to get additional useful work in another heat engine, for example, a gas turbine. The disadvantage of these power plants is that, in the absence of a connection with the atmosphere, oxygen pre-supply or oxygen recovery systems are required for their operation, which leads to a complication of the design and an increase in the volume of material media inside the object (Description of the invention by RF patent N 2013588).

Autonomous stationary energy-refrigerating systems for objects operating without any connection with the atmosphere are known, which are a structurally functional combination of a direct cycle converter (PPC) and a reverse cycle converter (POC) intended for the joint production of electric energy and cold due to the energy of a high-temperature heat source. Energy-refrigerating systems can be created on the basis of various types of converters, with PPC used to receive electrical energy, and POC to produce cold. For the normal functioning of the PPC and POC, it is necessary to remove heat from them (1 and 2 laws of thermodynamics), and due to the lack of communication with the atmosphere, this low-grade heat must be accumulated and stored inside the object. Therefore, the cooling of the transducers is carried out due to the heat-accumulating substance (TAB), which is water, at a temperature of about + 4 ^o C, which necessitates the creation of storages with large volumes for storing cold water and water that accumulated the heat of the transducers. The disadvantage is that although the structural and functional combination of PPC and POC can reduce the consumption of TAV by switching cold water supply circuits to the refrigerators of the converters, in this case, too, TAV reserves make up a significant percentage of the total volume of the facility, which leads to a large construction cost objects of this type (Grishutin M.M. Sevastyanov A.P. Theory and calculation methods of autonomous energy-refrigerating units. M. Izd. MPEI, 1992. 240 p.).

 The technical result that can be obtained by carrying out the invention is to reduce the volume of fuel storage tanks, fuel and oxidizer storage tanks for the PCP, significantly reducing capital costs for the construction of facilities that are not connected with the atmosphere, and obtaining additional electrical energy for the needs of the facility.

 To achieve this technical result, an energy-refrigerating system consisting of a direct cycle converter of a closed loop diesel power plant, a reverse cycle converter of a Wulemier-Takonis machine, is equipped with an open circuit with a cryoagent including a heat-insulated container with liquid oxygen, a pump designed to supply liquid oxygen, a heat exchanger for evaporation liquid oxygen and heat exchange with the cooled liquid supplied to the transducers, an expander connected to the pump by one shaft, and p The transmission of the high-temperature potential from the PPC exhaust gases to the POC working fluid occurs through the heater of the Wulemier-Taconis machine.

 The introduction of an open-loop system with a cryoagent into the energy refrigerating system allows one to obtain a new property consisting in the possibility of using liquid oxygen, first as a surfactant, and then as an oxidizing agent for PPC, due to its transition from a liquid to a gaseous state, with obtaining additional useful energy .

 The drawing shows a diagram of an autonomous energy refrigerating system with a cryogenic liquid.

 The energy-refrigerating system includes a closed-loop diesel power plant circuit 1, a Wulemieu-Taconis machine circuit 2, PPC and POC cooling system circuits 3 and 4, respectively, an open circuit with cryogenic agent 5.

 The loop circuit of a closed loop diesel unit 1 consists of a diesel 6, a reactor 7, a hopper with alkaline earth metal 8, a solid reaction product accumulator 9, a separator 10, a cooler 11, a mixer 12. Circuit 1 is connected to the circuit of the Wuleme-Taconis 2 machine through a heater 13, which with a regenerator 14 and a refrigerator 15 comprise a block of heat exchangers of the engine line of the Wulemje-Takonis machine, and a refrigerator 16, a regenerator 17 and a cooler 18 make up the line of the Wulemje-Takonis refrigeration machine. The movement and distribution of the working fluid inside the machine is ensured by the reciprocating movement of the piston group 19. An electric motor 20 is provided for starting the machine, connected to the drive of the machine (not shown in the drawing).

 An open circuit with a cryoagent 5, including a thermally insulated container with liquid oxygen 21, a pump 22, a heat exchanger 23, an expander 24, is connected to the circuit 1 through a cooler 11. Gaseous oxygen, after expansion in the expander 24, enters the mixer 12 PPC as an oxidizing agent.

 The cooling circuit PPC 3 consists of a piping system 25 and a circulation pump 26, providing movement of the coolant from the diesel 6 to the heat exchanger 23.

 The cooling loop POC 4 is similar to circuit 3 for the purpose and principle of operation. It includes: a piping system 27, a circulation pump 28, which provides movement of the coolant (heat transfer) from the refrigerators of the Wulemier-Takonis 15, 16 machine to the heat exchanger 23.

The heat exchanger of the load 18 of the Wulemier-Taconis machine is connected through the pipelines 29 to a thermostatic system (ventilation and air conditioning
not shown in the drawing).

 Autonomous energy refrigeration system operates as follows.

 Previously, before the object starts operating in a mode without communication with the atmosphere, the necessary (calculated) amount of liquid oxygen is stored in it in the heat-insulating tank 21. Since the connection with the atmosphere has been limited, liquid oxygen is pumped from the tank 21 to the heat exchanger 23 by the pump 22, where it receives heat from liquids used to cool the cooling circuits 1 and 2 of the PPC and POC transducers, respectively, acting as a heat-accumulating substance. Due to the received heat, liquid oxygen heats up and evaporates and, entering the cooler 11, overheats, since the temperature potential of the synthesis gas in the diesel circuit 1 is much higher than the potential of gaseous oxygen, and the synthesis gas is cooled. Expanding in expander 24 to obtain useful work, oxygen enters the mixer 12 as an oxidizing agent. This circumstance eliminates the need for storage facilities for the collection of heated heat-accumulating substances.

The exhaust gases from the diesel 6 enter the reactor 7, where alkaline earth metal, for example magnesium, is simultaneously supplied from the hopper 8. In the reactor 7, the gas is processed by a reaction of the type:
2Mg + CO ₂ + H ₂ O _ → 2MgO + CO + H ₂ + Q,
with the release of heat, which is used to maintain a given temperature in the reaction zone (1000-1500 K) and increase the thermodynamic potential of the gas phase. Moreover, the mixture of carbon monoxide (CO) and hydrogen (H ₂ ) formed in the reaction is the so-called "synthesis gas", which can be used as fuel for internal combustion engines. The solid reaction products are collected in the accumulator 9, and the gaseous ones, through the separator 10, enter the heater of the Wulemier-Taconis machine 13, a part of the thermodynamic potential is triggered, and after the cooler 11 they enter the mixer 12, where gaseous oxygen is supplied from the open loop with cryoagent 5 to form an artificial gas mixture then entering the combustion chamber of the engine 6.

 High-potential heat transferred by the exhaust gases in the heater 14 to the working fluid of the Wulemier-Taconis machine, for starting which an electric motor 20 is used, which is switched off when the machine enters the operating mode, is converted into reciprocating movement of the piston group 19, ensuring the completion of a double thermodynamic cycle of the machine: cycle the refrigeration machine through heat exchangers 16, 17, 18 and the engine cycle through the heat exchangers 13, 14, 15, and the work of the latter is important for the implementation of the refrigeration chi class and obtain useful cooling capacity, removed in the heat exchanger load 18 coolant temperature control system, moving through pipelines 29.

 The cooling liquid from the cooling circuit of the PPC 3, through the piping system 25, using the pump 26, is supplied from the heat exchanger 23 to the diesel engine 6, cooling the diesel engine, by transferring heat to liquid oxygen in the heat exchanger 23.

 The cooling liquid from the cooling loop POC 4, through a system of pipelines 27, using a circulation pump 28, is supplied from the heat exchanger 23 to the refrigerators of the Wulemier-Takonis 15, 16 machine, cooling the machine by transferring heat to liquid oxygen in the heat exchanger 23.

 The heat exchanger of load 18 of the Wulemier-Taconis machine is connected via pipelines to a ventilation and air conditioning system (not shown in the drawing), which provides temperature control inside an object that operates without any connection to the atmosphere.

Claims (1)

 An energy-refrigerating system including a direct-cycle converter, characterized in that the system includes a cryo-agent circuit that is used as a heat-storage substance in the liquid state, and as an oxidizing agent for a direct-cycle converter in a gaseous state, and the inverse-cycle converter operates due to the heat of the exhaust gases direct cycle converter.