TH36629B - Method for the use of a gas storage with a low methane concentration for supplying fuel for turbines. - Google Patents

Abstract

DC60 The invention focuses on a method of supplying gas turbine fuel from natural gas reserves. with relatively low methane concentration. The invention allows the use of such reserves to be used per purchase. Fuel to Gas Turbine to Generate Electric Power Methods of fabrication include the provision of natural gas, comprising no more than approximately 40 percent of methane on a volumetric reference basis, and mixing of natural gas methane with hydrogen to provide a methane/hydrogen mixture. have higher hydrogen which contains enough hydrogen to provide flame stabilization during combustion. After that, if a higher hydrogen content methane/hydrogen mixture is required, water is dehydrated to separate the volume. Enough water to provide for the methane/hydrogen mixture was removed. Higher hydrogenated water kept the flame steady. A higher hydrogen natural gas mixture was used per fuel supply per gas turbine generator. to the method of supplying gas turbine fuel from natural gas reserves with relatively low methane concentration. The invention allows the use of such reserves to be used per purchase. Fuel to Gas Turbine to Generate Electric Power Methods of invention include the provision of natural gas, which comprises no more than approximately 40 percent of methane on a volumetric reference, and Mixing methane of natural gas with hydrogen gas to form a methane/hydrogen gas mixture have higher hydrogen which contains enough hydrogen to provide flame stabilization during combustion. After that, if a higher hydrogen content methane/hydrogen mixture is required, water is dehydrated to separate the volume. Enough water to provide the methane/hydrogen mixture is removed. Higher hydrogen water keeps the flame steady. A higher hydrogen natural gas mixture is used per fuel supply per gas-turbine generator.

Claims (6)

Disclaimers (all) which will not appear on the advertisement page: 1. Methods for supplying methane turbines from natural gas reserves. Natural gas and hydrogen gas blending To provide a higher hydrogen-resistant gas mixture where hydrogen gas is comprised of at least 6% by volume of the gas mixture. Increased hydrogen-rich methane and increased hydrophobic gas turbine fuel supply. Which natural gas From natural gas reserves Which is not more than about 40 percent by volume of methane. 2. Method of claim 1, where natural gas is less than 35 percent by volume of methane. And methane mixture with higher hydrogen is from 6 to 10 percent by volume of hydrogen gas. 3. Method according to claim 2, where natural gas is 20 percent by volume of methane. And the methane mixture with higher hydrogen is from 6 to 10 percent by volume of hydrogen gas. 4. Method of claim No. 1, which will include the procedure of Removal of at least one acidic component from natural gas to provide a desulfurized natural gas. Natural gas and hydrogen blends include blends of fir removed natural gas and water. To provide sulfur-dehydrated natural gas, the catalytic conversion of one part of methane to hydrogen gas in natural gas. The sulfur that is hydrated to provide a higher hydrogen content of natural gas that is hydrated. Water removal to higher hydrogenated natural gas that is hydrated. To provide natural gas with Dehydrated higher hydrogen stabilizes the flame and provides fuel to turbine gas, including hydrogen-rich natural gas turbines. 5. Method according to claim No. 4, the procedure of removal of acidic components from Natural gas includes the removal of hydrogen sulfide from natural gas 6. Method of claim No. 5, where hydrogen sulfide is removed from natural gas as well. Physical solvent while reducing the emission of any inert gas. 7. Method according to claim 6, where physical solvent is selected from among which methanol is A mixture of dimethyl ether of polyethylene glycol Propylene carbonate N-Methyl-2-Pirolidone Mixture of oligo ethylene glycol methyl isopropyl ether Tri-n-Butyl Phosphonate Methyl Cyano-Acetate And their mixtures. 8. Method of claim No. 4 to item 7, any one Which natural gas with high hydrogen Water is dehydrated, including at least 6 percent by volume of hydrogen gas. 9. Method of Clause 4 to Item 7. Which methane in natural gas has been eliminated The hydrated sulfur was transformed by a catalyst using a promoted catalyst, selected from A group consisting of iron / chrome / copper Copper / Zinc / Aluminum And its mixtures 1 0. Methods of claim No. 4 to No. 9, any one Which natural gas does not have more than approximately 35 percent by volume of methane and higher hydrogen-rich natural gas is dehydrated. This includes from 6 to 10 percent by volume hydrogen gas 1 1. Method according to claim 10, where natural gas does not have more than approximately 20 percent by volume of methane and higher hydrogen-rich natural gas that is dehydrated. This includes from 6 to 10 percent by volume of hydrogen gas 1 2. Method for claim No. 1 and natural gas reserves which contain high sulfur gas. of The combination of high-sulfur natural gas and water to provide a highly-sulfur-hydrated natural gas and the process of Natural gas and hydrogen gas blending Which continues to include The catalytic conversion of one part of methane in the hydrated natural gas. To hydrogen gas to provide a natural gas with hydrated hydrogen. Water removal to higher hydrogenated natural gas that is hydrated to provide a more abundant natural gas. The higher hydrogen being dehydrated stabilizes the flame and where the fuel supply per gas turbine includes hydrogen-rich natural gas turbines. 1 3. Method for claim 12 in which the higher hydrogenated natural gas is hydrated includes At least 6% by volume of hydrogen gas 1 4. Method according to claim 12 or 13, which methane in high sulfur natural gas is The hydrate is replaced with a catalyst by means of chrom / molybdenum catalyst 1 5. Method according to claim 12, where natural gas does not exceed approximately 35% by volume of methane and natural gas. With higher hydrogen being dehydrated This includes from 6 to 10 percent by volume hydrogen gas 1 6. Method according to claim 15, in which natural gas does not have more than approximately 20 percent by volume of methane and higher hydrogen-rich natural gas is eliminated. water This includes from 6 to 10 percent by the amount of hydrogen gas 1. 7. Method of claim No. 4, which includes the process of inert gas injection into the turbines. Dehydrated higher hydrogen-rich natural gas 1 8. Method of claim 12, which includes the process of inert gas inert gas with There are natural gas with higher hydrogen that is dehydrated. 1 9. Methods for supplying methane turbines from natural gas reserves with high sulfur concentrations of natural gas. Relatively low in methane That method includes the steps of A mixture of high sulfur natural gas and water In order to provide a hydrated high-sulfur natural gas, water in the highly sulfur-hydrated natural gas is available in effective quantities for The catalytic conversion of one part of methane in high sulfur natural gas is allowed. To hydrogen gas. It is also effective for providing higher hydrogen-rich natural gas. Removes water, has a stable flame Natural gas with high sulfur Which is not more than about 40 percent by Methane volume The catalyst conversion of one part of methane in the natural gas has High sulfur that is hydrated to hydrogen To provide the highly hydrogenated natural gas that is hydrated Efficient catalytic conversion for the provision of highly hydrogenated natural gas. The more dehydrated, there is a stable flame. Water removal to higher hydrogenated natural gas that is hydrated to provide a more abundant natural gas. The higher the dehydrated hydrogen stabilizes the flame and the fuel supply to turbocharged with the dehydrated higher hydrogen gas 2 0. Method according to claim 19, in which natural gas is dehydrated. There is a higher hydrogen that is hydrated to be eliminated. Efficient amount of water for providing dehydrated increased hydrogenated natural gas. Out with at least 110 BTUs per standard cubic foot (298 kal / scm) of gas 2. 1. Methods of claim 19 in which the hydrogenated hydrogenated natural gas will include: At least 6 percent by volume of hydrogen gas 2 2. Method according to claim 19, the procedure of replacing part of methane with accelerator. Reaction in high sulfur natural gas that is hydrated to hydrogen To provide natural gas with Higher hydrogen being hydrated includes the use of a chrom / molybdenum 2 catalyst. 3. Method according to claim 19 or 20, in which natural gas containing high sulfur is not more than approximately 35 percent by volume of methane. And hydrogenated natural gas that is dehydrated This includes from 6 to 10 percent by the volume of hydrogen gas 2. 4. Method according to claim 23, in which natural gas containing high sulfur does not have more than approximately 20 percent by volume of methane. And the higher hydrogen-rich natural gas is dehydrated, it includes from 6 to 10 percent by the volume of hydrogen gas 2. 5. Method according to claim 19, the method also extends to the inert gas turbines containing the dehydrated higher hydrogen content 2. 6. Method according to claim 20, in which the method continues to include inert gas turbines with dehydrated higher hydrogen-rich natural gas.