Combined Cycle Performance Evaluation and Dynamic Response Simulation

<p class="1Body">Several modifications have been made to the simple gas turbine cycle in order to increase its thermal efficiency but within the thermal and mechanical stress constrain, the efficiency still ranges between 38 and 42%. The concept of using combined cycle power or CPP plant would be more attractive in hot countries than the combined heat and power or CHP plant. The current work deals with the performance of different configurations of the gas turbine engine operating as a part of the combined cycle power plant. The results showed that the maximum CPP cycle efficiency would be at a point for which the gas turbine cycle would have neither its maximum efficiency nor its maximum specific work output. It has been shown that supplementary heating or gas turbine reheating would decrease the CPP cycle efficiency; hence, it could only be justified at low gas turbine inlet temperatures. Also it has been shown that although gas turbine intercooling would enhance the performance of the gas turbine cycle, it would have only a slight effect on the CPP cycle performance.</p>

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99/01503 ASME PTC 47 — development of a new code for integrated gasification combined cycle performance testing

Fuel and Energy Abstracts ◽

10.1016/s0140-6701(99)96684-5 ◽

1999 ◽

Vol 40 (2) ◽

pp. 151

Keyword(s):

Performance Testing ◽

Combined Cycle ◽

Cycle Performance ◽

Integrated Gasification Combined Cycle ◽

Integrated Gasification

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A Case Study of Optimizing Combined Cycle Performance at Kalaeloa

ASME 2009 Power Conference ◽

10.1115/power2009-81108 ◽

2009 ◽

Author(s):

Helmer Andersen

Keyword(s):

Power Plants ◽

Performance Monitoring ◽

Combined Cycle ◽

Plant Performance ◽

Operational Performance ◽

Cycle Performance ◽

Monitoring Tools ◽

Online Performance Monitoring ◽

On Line

Fuel is by far the largest expenditure for energy production for most power plants. New tools for on-line performance monitoring have been developed for reducing fuel consumption while at the same time optimizing operational performance. This paper highlights a case study where an online performance-monitoring tool was employed to continually evaluate plant performance at the Kalaeloa Combined Cycle Power Plant. Justification for investment in performance monitoring tools is presented. Additionally the influence of various loss parameters on the cycle performance is analyzed with examples. Thus, demonstrating the potential savings achieved by identifying and correcting the losses typically occurring from deficiencies in high impact component performance.

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Thermodynamic analysis and simulation of a new combined power and refrigeration cycle using artificial neural network

Thermal Science ◽

10.2298/tsci101102009f ◽

2011 ◽

Vol 15 (1) ◽

pp. 29-41 ◽

Cited By ~ 3

Author(s):

Abdolreza Fazeli ◽

Hossein Rezvantalab ◽

Farshad Kowsary

Keyword(s):

Neural Network ◽

Artificial Neural Network ◽

Heat Source ◽

Exergy Efficiency ◽

Combined Cycle ◽

Cycle Performance ◽

Working Fluid ◽

Refrigeration Cycle ◽

Water Mixture ◽

Artificial Neural

In this study, a new combined power and refrigeration cycle is proposed, which combines the Rankine and absorption refrigeration cycles. Using a binary ammonia-water mixture as the working fluid, this combined cycle produces both power and refrigeration output simultaneously by employing only one external heat source. In order to achieve the highest possible exergy efficiency, a secondary turbine is inserted to expand the hot weak solution leaving the boiler. Moreover, an artificial neural network (ANN) is used to simulate the thermodynamic properties and the relationship between the input thermodynamic variables on the cycle performance. It is shown that turbine inlet pressure, as well as heat source and refrigeration temperatures have significant effects on the net power output, refrigeration output and exergy efficiency of the combined cycle. In addition, the results of ANN are in excellent agreement with the mathematical simulation and cover a wider range for evaluation of cycle performance.

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Pressure gain combustion advantage in land-based electric power generation

Journal of the Global Power and Propulsion Society ◽

10.22261/jgpps.k4md26 ◽

2017 ◽

Vol 1 ◽

pp. K4MD26 ◽

Cited By ~ 6

Author(s):

Seyfettin C. Gülen

Keyword(s):

Power Generation ◽

Power Plant ◽

Gas Turbines ◽

Combined Cycle ◽

Cycle Performance ◽

Heavy Duty ◽

Quantum Leap ◽

Pressure Gain Combustion ◽

Industrial Gas Turbines ◽

Plant Efficiency

AbstractThis article evaluates the improvement in gas turbine combined cycle power plant efficiency and output via pressure gain combustion (PGC). Ideal and real cycle calculations are provided for a rigorous assessment of PGC variants (e.g., detonation and deflagration) in a realistic power plant framework with advanced heavy-duty industrial gas turbines. It is shown that PGC is the single-most potent knob available to the designers for a quantum leap in combined cycle performance.

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Development of a Novel Combined Absorption Cycle for Power Generation and Refrigeration

Journal of Energy Resources Technology ◽

10.1115/1.2751506 ◽

2006 ◽

Vol 129 (3) ◽

pp. 254-265 ◽

Cited By ~ 62

Author(s):

Na Zhang ◽

Noam Lior

Keyword(s):

Water System ◽

Rankine Cycle ◽

Combined Cycle ◽

Energy Utilization ◽

Utilization Efficiency ◽

Cycle Performance ◽

Base Case ◽

Ammonia Water ◽

Energy And Exergy ◽

The Impact

Cogeneration can improve energy utilization efficiency significantly. In this paper, a new ammonia-water system is proposed for the cogeneration of refrigeration and power. The plant operates in a parallel combined cycle mode with an ammonia-water Rankine cycle and an ammonia refrigeration cycle, interconnected by absorption, separation, and heat transfer processes. The performance was evaluated by both energy and exergy efficiencies, with the latter providing good guidance for system improvement. The influences of the key parameters, which include the basic working solution concentration, the cooling water temperature, and the Rankine cycle turbine inlet parameters on the cycle performance, have been investigated. It is found that the cycle has a good thermal performance, with energy and exergy efficiencies of 27.7% and 55.7%, respectively, for the base-case studied (having a maximum cycle temperature of 450°C). Comparison with the conventional separate generation of power and refrigeration having the same outputs shows that the energy consumption of the cogeneration cycle is markedly lower. A brief review of desirable properties of fluid pairs for such cogeneration cycles was made, and detailed studies for finding new fluid pairs and the impact of their properties on cogeneration system performance are absent and are very recommended.

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Seismic Performance Evaluation for Steel-Frame-Structure Considering Member Fracture

Volume 8: Seismic Engineering ◽

10.1115/pvp2017-65673 ◽

2017 ◽

Author(s):

Kensuke Shiomi

Keyword(s):

Performance Evaluation ◽

Dynamic Response ◽

Dynamic Analysis ◽

Seismic Performance ◽

Ground Motions ◽

Steel Frame ◽

Frame Structures ◽

Seismic Performance Evaluation ◽

Steel Frame Structures

Through the 2011 Tohoku Earthquake or the 2016 Kumamoto Earthquake, much larger earthquakes are considered recently in the seismic designs of large steel-frame structures. When structures are exposed by these severe ground motions, partial destructions in the structures, such as damage or fracture of members could happen. Especially, the low cycle fatigue of steel structures because of the repeated load from these long-term ground motions is a serious problem. However, current seismic performance evaluation method based on nonlinear dynamic analysis considers only elastic and plastic deformation of each member, excluding the fracture of members. If this member fracture happens during earthquakes, there is considered to be many effects on the seismic performance, like the changes of the vibration property, the dynamic response and the energy absorbance capacity of structures. Therefore, the fracture of members is preferably taken into account in the seismic performance evaluation for these large earthquakes. This paper proposes the dynamic analysis method for steel-frame structures which can express the member fracture. Dynamic analyses considering and not considering member fracture under the repeated loads supposing the long-term earthquake are conducted to the FEM model of full-scale structure. By comparing each result, the effects of considering member fracture to the seismic performance such as the dynamic response and the energy absorbance capacity are discussed.

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DEVELOPMENT AND ANALYSIS OF AN INTEGRATED MILD/PARTIAL GASIFICATION COMBINED (IMPGC) CYCLE

Journal of Energy Resources Technology ◽

10.1115/1.4052997 ◽

2021 ◽

pp. 1-34

Author(s):

Ting Wang ◽

Henry Long

Keyword(s):

Power Plants ◽

Energy Content ◽

Energy Resource ◽

Rankine Cycle ◽

High Energy ◽

Combined Cycle ◽

Cycle Performance ◽

Efficient Manner ◽

Volumetric Heating ◽

Partial Gasification

Abstract Around 50% of the world's electrical power supply comes from the Rankine cycle, and the majority of existing Rankine cycle plants are driven by coal. Given how unattractive coal is as an energy resource in spite of its high energy content, it becomes necessary to find a way to utilize coal in a cleaner and more efficient manner. Designed as a potential retrofit option for existing Rankine cycle plants, the Integrated Mild/Partial Gasification Combined (IMPGC) Cycle is an attractive concept in cycle design that can greatly increase the efficiency of coal-based power plants, particularly for retrofitting an old Rankine cycle plant. Compared to the Integrated Gasification Combined Cycle (IGCC), IMPGC uses mild gasification to purposefully leave most of the volatile matters within the feedstock intact (hence, yielding more chemical energy) compared to full gasification and uses partial gasification to leave some of the remaining char un-gasified compared to complete gasification. The larger hydrocarbons left over from the mild gasification process grant the resulting syngas a higher volumetric heating value, leading to a more efficient overall cycle performance. This is made possible due to the invention of a warm gas cleanup process invented by Research Triangle Institute (RTI), called the High Temperature Desulfurization Process (HTDP), which was recently commercialized. The leftover char can then be burned in a conventional boiler to boost the steam output of the bottom cycle, further increasing the efficiency of the plant, capable of achieving a thermal efficiency of 47.9% (LHV). This paper will first analyze the individual concepts used to create the baseline IMPGC model, including the mild and partial gasification processes themselves, the warm gas cleanup system, and the integration of the boiler with the heat recovery steam generator (HRSG). This baseline will then be compared with four other common types of power plants, including subcritical and ultra-supercritical (USC) Rankine cycles, IGCC, and natural gas. The results show that IMPGC consistently outperforms all other forms of coal-based power. IMPGC is more efficient than the standard subcritical Rankine cycle by nine percentage points, more than a USC Rankine cycle by nearly four points, and more than IGCC by seven points.

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