RU2444637C2 - Energy generation method - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: low pressure oxidiser is compressed with multi-stage compressor, and then it is supplied to high pressure combustion chamber to which some part of fuel and heated high pressure oxidiser flow is supplied as well. Combustion products are supplied from combustion chamber to gas turbine, and then to fuel element for electrochemical oxidation of the other fuel part. At least some part of low pressure oxidiser is supplied to fuel element input and the flow leaving the fuel element is burnt in low pressure combustion chamber. Low pressure oxidiser supplied to fuel element input is taken from lower stages of compressor.

EFFECT: reducing fuel flow, improving operating reliability of fuel element and decreasing the losses due to insufficient expansion of combustion products in the turbine.

9 cl, 1 dwg

Description

The invention relates to methods for converting the energy of gaseous fuels (natural or synthesis gas, hydrogen) into mechanical (electrical), mainly to transport power plants and energy supply systems based on them, and is intended for vehicles equipped with an electric or hybrid drive.

Known methods for converting the thermal energy of gaseous fuels (natural or synthesis gas, hydrogen) into mechanical (electrical), including in transport power plants that convert primary energy into electrical energy, which is stored in electric batteries and then, if necessary, serves as a vehicle propulsion drive. Hybrid energy sources have significant potential, which are advantageous to use under constant load, while the vehicle moves unevenly, which requires a change in power. Of the features of the work of transport energy-generating systems, the problem of increasing the efficiency of the energy source when working at variable power is known. Thus, the task arises of creating energy conversion methods, energy storage plants and systems capable of providing high energy generation efficiency in the uneven mode required by the consumption conditions, regardless of the schedule for primary energy generation.

In particular, a gas turbine electric power system is proposed, comprising a compressor for compressing the first medium and an electrochemical converter communicating with the compressor and adapted to receive the first and second medium. The converter is designed to carry out a chemical reaction between the first and second environments, generating electricity in accordance with this and producing an exhaust stream having a selected elevated temperature. The electric power system further comprises a turbine in communication with the electrochemical converter and adapted to receive the outlet of the converter so that the turbine converts this outlet into rotational energy and electric energy. The system may further comprise a steam generator and a steam turbine that generates electricity (RF application for invention No. 97104031, publication date 1999.04.10). The disadvantage of this method and device is the low temperature at the entrance to the turbine, which reduces the efficiency.

There is also known a method of producing electric energy from natural gas using a solid oxide fuel cell, comprising the stages of electrochemical oxidation of natural gas that has undergone preliminary expansion and heating the natural gas with a stream leaving the fuel cell (RF application for invention No.2000107827, publication date 2002.01.20 ) The disadvantage of this method and device is also the low temperature at the entrance to the turbine, which reduces the efficiency.

This drawback is partially overcome in a method and device for generating energy, in which, in order to increase efficiency, the oxidizing agent (air) is compressed by a compressor, heated, and then sent to a combustion chamber, into which a part of the fuel and an oxidizer stream heated regeneratively are also fed and from which the combustion products are directed to a gas turbine, it is cooled by an oxidizer inlet stream and sent to a fuel cell for electrochemical oxidation of another part of the fuel, the reaction products of which are cooled by an oxidizer stream, direct into the combustion chamber (US Application invention №2006 / 0105207, date of publication 2006.05.18). The disadvantage of this solution is the low reliability and efficiency of energy generation, which is associated with increased fuel costs, as well as the relatively low efficiency of gas turbine conversion in transient conditions associated with a low heating / cooling rate of the fuel cell limited by the thermal stability of ceramic electrodes.

The objective of the invention is to increase the dynamic and maneuverable capabilities of energy generation, reduce fuel consumption, reduce losses associated with insufficient expansion of the combustion products in the turbine, increase the reliability of the fuel cell due to additional options for regulating its temperature and power modes regardless of the gas turbine mode, improve economic indicators of power plants and energy supply systems and create conditions for effective improvement of the reliability of the energy source.

- The problem is solved by the fact that they apply the method of energy generation, in which the low-pressure oxidizer is compressed by a multistage compressor, and then sent to the high-pressure combustion chamber, which also supplies part of the fuel and the heated high-pressure oxidizer stream and from which the combustion products are sent to the gas a turbine, and then into the fuel cell for the electrochemical oxidation of another part of the fuel, while at least part of the low-pressure oxidizer is directed to the entrance to the fuel cell, and the output The flow from it is burned in a low pressure combustion chamber.

Besides:

- an oxidizer of low pressure supplied to the entrance to the fuel element is taken from the lower stages of the compressor;

- the fuel in front of the high-pressure combustion chamber is compressed, evaporated or reduced;

- at least a portion of the compressor stages are rotated using a gas turbine;

- after the low-pressure combustion chamber, the effluent from it is cooled by heating an oxidizing agent and / or fuel;

- combustion in the combustion chamber of low pressure is carried out on a catalyst selected on the basis of palladium, or rhenium, or platinum, or rhodium, or their compounds;

- regulate the supply of fuel and / or oxidizer to the fuel cell depending on the energy demand or the permissible heating rate of the fuel cell;

- the fuel is selected from the range containing hydrogen, natural gas, synthesis gas, hydrocarbons, methanol, ammonia, ethyl alcohol or mixtures thereof;

- oxygen or air is chosen as the oxidizing agent.

An example implementation of the invention is the method of generating energy, described below.

In the described embodiment of the invention, natural gas is used as fuel, air is used as an oxidizing agent, which allows us to characterize the features of the invention as applied to the processes of electrochemical oxidation of products of incomplete combustion of natural gas after the use of expansion machines, in particular, in transport or stationary power plants.

The figure shows a schematic solution of the proposed method for generating energy.

The method is as follows.

The natural gas combustion products are expanded in a gas turbine 1, into which the combustion products generated from low pressure air compressed in the compressor 2 and the fuel supplied from the natural gas tank 3 are supplied from the high pressure combustion chamber 4, and then sent to a fuel cell 6, into which another part of the natural gas can also be supplied by means of a supercharger 5 at a pressure mainly above atmospheric. Depending on the operating mode, air is also supplied to the fuel element 6, which can be taken from the lower stages of the compressor 2. The stream generated by electrochemical oxidation of the components entering the fuel element 6 is directed to a low-pressure combustion chamber 7, after which the stream exiting from it cooled by heating the oxidizing agent and / or fuel 10 in the heat exchanger 9. Burning in the low pressure combustion chamber is carried out on a catalyst 8 selected on the basis of palladium, rhenium, platinum, rhodium or their compounds, which allows provide flameless operation at different temperatures.

Fuel (in the described example, natural gas) is compressed, vaporized or reduced in front of the high-pressure combustion chamber, depending on the pressure and the state of aggregation of the fuel supplied from the natural gas tank 3. At least part of the compressor stages 2 are rotated using a gas turbine 1, which allows to reduce the size of the compressor 2 due to the high speed.

The supply of fuel and / or oxidizer to the fuel cell 6 is regulated by control valves 11-13 depending on the energy requirement or the permissible heating rate of the fuel cell 6, which, in turn, is limited mainly by the heat resistance of the ceramic components of the fuel cell 6.

Hydrogen, natural gas, synthesis gas, hydrocarbons, methanol, ammonia, ethyl alcohol or mixtures thereof can also be used as fuel.

As the oxidizing agent, both oxygen and air or mixtures thereof can be selected.

In the process of implementing the described method of energy generation, the possibilities of heating the fuel element 6 using an external heat supply can be used. It is also possible inside the fuel cell 6 to apply the preliminary conversion of the fuel by partially oxidizing it with an oxidizing agent or supplied steam, including as part of the fuel combustion products. The increase in energy generation while increasing the mechanical load on the gas turbine 1 is carried out both by changing the fuel supply by means of control valves 11-13, which can be used as a poppet valve, or a stem valve, or any other device that affects the hydraulic resistance to passage fuel or products of its combustion, as well as by changing the supply of the oxidizing agent from the compressor 2 through the control valve 12, which allows to increase the selection of the oxidizing agent from the compressor 2 bypassing the combustion chamber high pressure in order to increase the power of the fuel cell 6.

Thus, this method will increase the dynamic and maneuverability of energy generation, reduce fuel consumption, reduce losses associated with insufficient expansion of the combustion products in the turbine, increase the reliability of the fuel cell due to additional possibilities of regulating its temperature and power modes regardless of the gas mode turbines, improve the economic performance of power plants and energy supply systems.

Claims (9)

1. A method of generating energy, in which the low-pressure oxidizer is compressed by a multistage compressor, and then sent to a high-pressure combustion chamber, to which a part of the fuel and a heated stream of high-pressure oxidizer are also fed, and from which the combustion products are sent to a gas turbine, and then to the fuel an element for electrochemical oxidation of another part of the fuel, characterized in that at least part of the low-pressure oxidizer is directed to the entrance to the fuel element, and the stream leaving it is burned in the chamber low pressure combustion. 2. The method according to claim 1, characterized in that the low-pressure oxidizer supplied to the inlet of the fuel element is selected from the lower stages of the compressor. 3. The method according to claim 1 or 2, characterized in that the fuel in front of the high-pressure combustion chamber is compressed, evaporated or reduced. 4. The method according to p, 1 or 2, characterized in that at least part of the stages of the compressor is rotated using a gas turbine. 5. The method according to claim 1 or 2, characterized in that after the low-pressure combustion chamber, the effluent from it is cooled by heating an oxidizing agent and / or fuel. 6. The method according to claim 1 or 2, characterized in that the combustion in the combustion chamber of low pressure is carried out on a catalyst selected on the basis of palladium, rhenium, platinum, rhodium or their compounds. 7. The method according to claim 1 or 2, characterized in that they regulate the supply of fuel and / or oxidizer to the fuel cell depending on the energy requirement or the permissible heating rate of the fuel cell. 8. The method according to claim 1 or 2, characterized in that the fuel is selected from the range containing hydrogen, natural gas, synthesis gas, hydrocarbons, methanol, ammonia, ethyl alcohol or mixtures thereof. 9. The method according to claim 1 or 2, characterized in that oxygen or air is selected as the oxidizing agent.