Patent application number | Description | Published |
20100242429 | SPLIT FLOW REGENERATIVE POWER CYCLE - Split flow regenerative power cycle systems are provided. The systems can include a gas turbine configured to generate a split flow exhaust stream having a first exhaust stream and a second exhaust stream, a regenerator operatively coupled to the gas turbine and configured to receive the first exhaust stream, and a heat recovery steam generator operatively coupled to the gas turbine and configured to receive a second exhaust stream. The systems can include generating a gas turbine exhaust stream from a gas turbine, splitting the exhaust stream to a first exhaust stream and a second exhaust stream, directing the first exhaust stream from the gas turbine to a first regenerative power cycle and directing the second exhaust stream from the gas turbine to a second heat recovery power cycle. | 09-30-2010 |
20100281843 | MULTI-STAGE COMPRESSOR FAULT DETECTION AND PROTECTION - In certain embodiments, a system includes a controller configured to obtain an inter-stage pressure measurement between stages of a multi-stage compressor. The controller is also configured to identify actual damage in the multi-stage compressor based at least in part on the inter-stage pressure measurement. | 11-11-2010 |
20100281844 | STEAM TURBINE POWER SYSTEM AND METHOD OF ASSEMBLING THE SAME - A method of assembling a steam turbine power system with a coolant source is provided. The method includes providing a first steam turbine train including a first high pressure turbine assembly, a first low pressure turbine assembly coupled in flow communication with the first high pressure turbine assembly, and a first condenser coupled in flow communication with the first low pressure turbine assembly. The method also includes providing a second steam turbine train including a second high pressure turbine assembly, a second low pressure turbine assembly coupled in flow communication with the second high pressure turbine assembly, and a second condenser coupled in flow communication with the second low pressure turbine assembly. The method further includes coupling cooling tubes to the first condenser and the second condenser, the cooling tubes configured to deliver coolant from the coolant source through the first condenser, from the first condenser through the second condenser, and from the second condenser back to the coolant source. | 11-11-2010 |
20100287935 | BIASING WORKING FLUID FLOW - A system and methods are disclosed that assist in biasing of a working fluid. In one embodiment, the method includes providing a first portion of a working fluid to a first low pressure turbine and a second portion of the working fluid to a second low pressure turbine, the second portion being greater in quantity than the first portion; processing the first portion of the working fluid in the first low pressure turbine to create a first exhaust fluid and processing the second portion of the working fluid in the second low pressure turbine to create a second exhaust fluid; providing the first exhaust fluid to a first condenser; and providing the second exhaust fluid to a second condenser, wherein the second exhaust fluid is greater in quantity than the first exhaust fluid. | 11-18-2010 |
20110314819 | SYSTEM INCLUDING FEEDWATER HEATER FOR EXTRACTING HEAT FROM LOW PRESSURE STEAM TURBINE - A system is disclosed including a low pressure steam turbine; an air-cooled condenser (ACC) in fluid connection with the low pressure (LP) steam turbine, the ACC for receiving a portion of steam from an exhaust of the LP steam turbine; a feedwater heater in fluid connection with the low pressure steam turbine via a conduit, the feedwater heater for receiving a portion of supply steam from the LP steam turbine; and a condensate pump in fluid connection with the ACC and the feedwater heater, the condensate pump for receiving condensate fluid from the ACC and drain fluid from the feedwater heater. | 12-29-2011 |
20120204573 | SYSTEM AND METHOD FOR PRODUCING A HYDROGEN ENRICHED FUEL - A system for producing a hydrogen enriched fuel includes a gas turbine comprising a compressor, a combustor, and a turbine. A fuel reformer is connected between the compressor and the combustor. The fuel reformer comprises an inlet connected to the compressor and an outlet connected to the combustor, and the fuel reformer produces the hydrogen enriched fuel. A method for producing a hydrogen enriched fuel includes compressing a working fluid with a compressor to produce a compressed working fluid and diverting a first portion of the compressed working fluid to a fuel reformer. The method further includes mixing a fuel with the compressed working fluid in the fuel reformer to produce the hydrogen enriched fuel and an exhaust stream and flowing the exhaust stream to a combustor | 08-16-2012 |
20120240549 | Combined Cycle Power Plant - A combined cycle power plant in which a gas turbine engine generates power, a heat recovery steam generator (HRSG) produces steam from high energy fluids produced from the generation of power in the gas turbine engine and a steam turbine engine generates additional power from the steam produced in the HRSG. The combined cycle power plant includes a heating element fluidly interposed between the steam turbine engine and the HRSG to heat fluid output from the steam turbine engine, which is to be fed to the HRSG and a control system to control an amount the fluid output from the steam turbine engine is heated by the heating element based on differences between HRSG and ambient temperatures. | 09-27-2012 |
20140110092 | ATOMIZING AIR HEAT FOR ATTEMPERATION - An attemperation system and an atomizing air system are integrated for a combined cycle turbine including a gas turbine and a steam turbine. The atomizing air system receives compressor discharge air for fuel atomization. The atomizing air system includes an atomizing air cooler that serves to cool the compressor discharge air. A heat recovery steam generator receives exhaust from the gas turbine and generates steam for input to the steam turbine via an attemperation system. A feed water circuit draws feed water from the heat recovery steam generator and communicates in a heat exchange relationship with the atomizing air cooler to heat the feed water. The feed water circuit communicates the heated feed water to the attemperation system of the heat recovery steam generator. | 04-24-2014 |
20140126991 | SYSTEMS AND METHODS FOR ACTIVE COMPONENT LIFE MANAGEMENT FOR GAS TURBINE ENGINES - The present application thus provides an active cooling system for a compressor and a turbine of a gas turbine engine. The active cooling system may include an air extraction pipe extending from the compressor to the turbine, a heat exchanger positioned about the air extraction pipe, and an external air cooling system in communication with the air extraction pipe. | 05-08-2014 |
20140257526 | PLANT CONTROL SYSTEMS AND METHODS - Systems and methods provided herein. In one embodiment, a system includes an advisory system including a loss computation engine configured to derive a total system loss for an industrial plant based on a first sensor positioned in a first industrial plant component and on a first physical model of the first industrial plant component. The advisory system further includes a cost model configured to use a cost function to derive a cost based on the total system loss, and a control strategy system configured to derive an advisory report, a control correction factor, or a combination thereof, based on the cost, wherein a control system is configured to apply the control correction factor to control a process in the industrial plant. | 09-11-2014 |