Add to ORKGThe Kalina cycle, which uses a varying composition ammonia-water mixture as the working fluid, is an efficient bottoming cycle for a gas turbine. This paper presents comparisons between Rankine and Kalina bottoming cycles under different gas turbine cycles. We present a new graphically based and interactive thermal cycle analysis program. We vary the ratio of bottoming cycle power to gas turbine power (the power fraction) and present First and Second law efficiency results. For the combined cycles we modeled, when the power fraction is between 0.25 and 0.5, the gas turbine- Kalina cycle is more efficient than the gas turbine-Rankine cycle. Below 0.25, they are nearly equal; above 0.5 the Rankine efficiency is higher. Up to a certain power f...
The paper presents a second-law and thermodynamic analysis of the Kalina cycle, aiming at discoverin...
This paper presents a parametric analysis of a combined power/cooling cycle, which combines the Rank...
Waste heat recovery systems can produce power from heat without using fuel or emitting CO2, therefor...
The Kalina cycle, which uses a varying composition ammonia-water mixture as the working fluid, is an...
A number of studies have shown that the Kalina cycle, using an ammonia-water mixture, can reach high...
ABSTRACT The Kalina Cycle utilizes a mixture of ammonia and water as the working fluid in a vapor po...
This master’s thesis analyses Kalina cycle, a power cycle where ammonia – water solution is used as ...
A multi-component (NB3/H2O) Kalina-type cycle that utilizes the exhaust from a gas turbine is invest...
In the present study, a new power and refrigeration cycle is investigated which is a combination of ...
Abstract–Energy-Utilization Diagrams is a graphic method to describe the exergy losses in industrial...
The Kalina split-cycle is a thermodynamic process for converting thermal energy into electrical powe...
This paper presents a comparative exergy analysis of ammonia-water Rankine cycles with and without r...
A thermodynamic modeling and optimization is carried out to compare the advantages and disadvantages...
This paper presents alternatives to Kalina cycles typically used in place of the organic Rankine cyc...
Improving the efficiency of thermodynamic cycles plays a fundamental role in reducing the cost of so...
The paper presents a second-law and thermodynamic analysis of the Kalina cycle, aiming at discoverin...
This paper presents a parametric analysis of a combined power/cooling cycle, which combines the Rank...
Waste heat recovery systems can produce power from heat without using fuel or emitting CO2, therefor...
The Kalina cycle, which uses a varying composition ammonia-water mixture as the working fluid, is an...
A number of studies have shown that the Kalina cycle, using an ammonia-water mixture, can reach high...
ABSTRACT The Kalina Cycle utilizes a mixture of ammonia and water as the working fluid in a vapor po...
This master’s thesis analyses Kalina cycle, a power cycle where ammonia – water solution is used as ...
A multi-component (NB3/H2O) Kalina-type cycle that utilizes the exhaust from a gas turbine is invest...
In the present study, a new power and refrigeration cycle is investigated which is a combination of ...
Abstract–Energy-Utilization Diagrams is a graphic method to describe the exergy losses in industrial...
The Kalina split-cycle is a thermodynamic process for converting thermal energy into electrical powe...
This paper presents a comparative exergy analysis of ammonia-water Rankine cycles with and without r...
A thermodynamic modeling and optimization is carried out to compare the advantages and disadvantages...
This paper presents alternatives to Kalina cycles typically used in place of the organic Rankine cyc...
Improving the efficiency of thermodynamic cycles plays a fundamental role in reducing the cost of so...
The paper presents a second-law and thermodynamic analysis of the Kalina cycle, aiming at discoverin...
This paper presents a parametric analysis of a combined power/cooling cycle, which combines the Rank...
Waste heat recovery systems can produce power from heat without using fuel or emitting CO2, therefor...