RU121300U1 - ENVIRONMENTALLY CLEAN ELECTRIC GENERATING DEVICE WITH HIGH-TEMPERATURE STEAM TURBINE AND AIR CONDENSER - Google Patents

Abstract

An environmentally friendly power generating device with a high-temperature steam turbine, containing a steam boiler, a high-temperature steam turbine with an electric generator and an air-cooled or water-cooled condenser, a high-temperature superheater, an installation for the production of oxygen and nitrogen by air separation, a suction ejector and a collection tank for non-condensable gases gas, pumps, characterized in that a high-temperature superheater is installed behind the steam boiler, in which a mixture of water vapor with carbon dioxide is superheated due to the combustion of natural gas with oxygen without an intermediate heat exchange surface, and the condenser outlet is connected by pipelines with an ejector and a tank for non-condensable gases, and the output of the latter is associated with the carbon dioxide utilization system.

Description

The device relates to the field of energy and can be used to produce electricity using combined fossil fuels.

A device is known (RU patent for utility model No. 54631 dated 06/08/05), containing a steam boiler, a plant for the production of hydrogen by conversion from natural gas, H ₂ / O ₂ - a steam generator (high temperature H ₂ / O ₂ - superheater), steam a turbine with an electric generator and a steam condenser, a heat recovery boiler.

Its disadvantages include the fact that the permissible amount of non-condensable gases in H ₂ and O ₂ entering the H ₂ / O ₂ steam generator is not indicated, the ratio of the costs of H ₂ and O ₂ . These indicators can affect the operation of the capacitor and reduce the energy efficiency of the installation as a whole. The sources and working media for oxygen production and cooling of the turbine flow section are not indicated.

The closest in technical essence is the device (RU patent for the invention No. 2335642 of 02.19.2007), containing a steam boiler, plants for producing hydrogen and oxygen, a high-temperature steam turbine and H ₂ / O ₂ - superheater, water vapor condenser.

Its disadvantages are the high cost of the installation for the production of hydrogen and the high explosiveness of hydrogen.

The purpose of the utility model is the creation of an electric generating complex for highly efficient continuous production of electricity using fossil fuels, as well as the utilization of carbon dioxide and the use of an air or water cooled condenser.

The essence of the utility model is that the device contains a steam boiler with coal (natural gas) as fuel, a high-temperature superheater, a high-temperature steam turbine with an electric generator and an air or water-cooled condenser, an apparatus for producing oxygen and nitrogen by air separation, an exhaust ejector and a non-condensable gas collection tank, a carbon dioxide recovery system, pumps, and the new one is that combustion is used to produce superheated water vapor native gas with oxygen in the water vapor medium after the boiler without an intermediate heat exchange surface, and the condenser outlet is connected by pipelines to an ejector and a tank for non-condensable gases, and the outlet of the latter is connected to a carbon dioxide recovery system.

It should be noted that the heating of water vapor in modern steam boilers above 900 K is virtually impossible due to burnout of pipes regardless of the type of fuel.

The device can also work without the use of a steam boiler, if not high-pressure steam is supplied to the high-temperature superheater, but feed water, which will turn into superheated steam.

The scheme of the proposed device is presented in figure 1.

The device comprises a steam boiler 1, an installation for the production of oxygen and nitrogen by air separation 2, a high-temperature superheater 3, a high-temperature steam turbine 4 with an electric generator and a condenser 5, a suction ejector 6 and a non-condensable gas collection tank 7, a carbon dioxide recovery system 8, pumps 9 and 10.

The device operates as follows.

From the steam boiler, 1 steam enters the high-temperature superheater 4. In the high-temperature superheater, the mixture of water vapor with carbon dioxide is overheated by burning natural gas with oxygen in it without an intermediate heat exchange surface. Next, a mixture of water vapor with carbon dioxide enters a high-temperature steam turbine 4 with an electric generator and a condenser 5. From a condenser 5, a mixture of carbon dioxide with impurities of water vapor and air enters the collection tank of non-condensable gases 7 using the suction ejector 6. Then it is sent to the recycling system carbon dioxide 8. Pumps 9 and 10 are used to pump condensate.

These features of the device will achieve the following results:

1. Generation of water vapor with a temperature of up to 1500 ° C without an intermediate heat exchange surface due to the combustion of natural gas and oxygen using a high-temperature superheater for operation of a high-temperature steam turbine.

2. Utilization of carbon dioxide at the outlet of the condenser of the steam turbine unit.

3. Elimination of technical water losses due to the use of environmentally friendly air condensers.

The advantage of this device is also that coal, fuel oil, alternative fuels and renewable energy sources can be used to generate steam and ensure its initial overheating in a steam boiler.

Claims (1)

An environmentally friendly power generating device with a high temperature steam turbine, comprising a steam boiler, a high temperature steam turbine with an electric generator and an air or water cooled condenser, a high temperature superheater, an oxygen and nitrogen production unit using air separation method, a suction ejector and a non-condensable gas recovery gas recovery tank, a system gas pumps, characterized in that a high temperature superheater is installed behind the steam boiler, in which The rum mixture of water vapor with carbon dioxide is overheated by burning natural gas with oxygen without an intermediate heat exchange surface, and the condenser outlet is connected by pipelines to an ejector and a tank for non-condensable gases, and the outlet of the latter is connected to the carbon dioxide recovery system.