An Assessment of the Brayton Cycle for High Performance Power Plants

As reported in the “Clean energy for all Europeans package” set by the EU, a sustainable transition from fossil fuels towards cleaner energy is necessary to improve the quality of life of citizens and the livability in cities. The exploitation of renewable sources, the improvement of energy performance in buildings and the need for cutting-edge national energy and climate plans represent important and urgent topics to be faced in order to implement the sustainability concept in urban areas. In addition, the spread of polygeneration microgrids and the recent development of energy communities enable a massive installation of renewable power plants, high-performance small-size cogeneration units, and electrical storage systems; moreover, properly designed local energy production systems make it possible to optimize the exploitation of green energy sources and reduce both energy supply costs and emissions. In the present paper, a set of key performance indicators is introduced in order to evaluate and compare different energy communities both from a technical and environmental point of view. The proposed methodology was used in order to assess and compare two sites characterized by the presence of sustainable energy infrastructures: the Savona Campus of the University of Genoa in Italy, where a polygeneration microgrid has been in operation since 2014 and new technologies will be installed in the near future, and the SPEED2030 District, an urban area near the Campus where renewable energy power plants (solar and wind), cogeneration units fed by hydrogen and storage systems are planned to be installed.

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A Small Scale Biomass Fueled Gas Turbine Engine

Volume 3: Coal, Biomass and Alternative Fuels; Combustion and Fuels; Oil and Gas Applications; Cycle Innovations ◽

10.1115/98-gt-315 ◽

1998 ◽

Author(s):

Joe D. Craig ◽

Carol R. Purvis

Keyword(s):

Gas Turbine ◽

Power Plants ◽

Small Scale ◽

Brayton Cycle ◽

Prime Mover ◽

Turbine Engine ◽

Rice Hulls ◽

Turbine Component ◽

The Cost ◽

New Generation

A new generation of small scale (less than 20 MWe) biomass fueled, power plants are being developed based on a gas turbine (Brayton cycle) prime mover. These power plants are expected to increase the efficiency and lower the cost of generating power from fuels such as wood. The new power plants are also expected to economically utilize annual plant growth materials (such as rice hulls, cotton gin trash, nut shells, and various straws, grasses, and animal manures) that are not normally considered as fuel for power plants. This paper summarizes the new power generation concept with emphasis on the engineering challenges presented by the gas turbine component.

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Utilization of Waste from Thermal Power Plants in High Performance Materials’ Production

Materials Science Forum ◽

10.4028/www.scientific.net/msf.1011.109 ◽

2020 ◽

Vol 1011 ◽

pp. 109-115

Author(s):

Inna Maltseva ◽

Svetlana Kurilova ◽

Alexey Naumov

Keyword(s):

Environmental Pollution ◽

Waste Disposal ◽

High Performance ◽

Power Plants ◽

Building Materials ◽

Thermal Power ◽

Environmental Problems ◽

Thermal Power Plants ◽

Operational Characteristics

One of the effective ways to solve the environmental problems of the region at present is the waste disposal from Novocherkasskaya TPP, one of the largest sources of environmental pollution. The solution to this problem is associated with the integrated use of ash and slag mixtures components in the effective building materials’ production. On the TPP waste basis, the authors obtained structural and heat-insulating concrete with enhanced physical, mechanical and operational characteristics.

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RESOLVING THE ENERGY–WATER NEXUS IN LARGE THERMOELECTRIC POWER PLANTS: A CASE FOR APPLICATION OF ENHANCED HEAT TRANSFER AND HIGH-PERFORMANCE THERMAL ENERGY STORAGE

Journal of Enhanced Heat Transfer ◽

10.1615/jenhheattransf.2017024681 ◽

2016 ◽

Vol 23 (4) ◽

pp. 263-282 ◽

Cited By ~ 3

Author(s):

Raj M. Manglik ◽

Milind A. Jog

Keyword(s):

Heat Transfer ◽

Energy Storage ◽

Thermoelectric Power ◽

Thermal Energy ◽

Thermal Energy Storage ◽

High Performance ◽

Power Plants ◽

Enhanced Heat Transfer ◽

Thermoelectric Power Plants

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Reheat and Regenerative Gas Turbines for Feed Water Repowering of Steam Power Plant

Volume 4: Heat Transfer; Electric Power; Industrial and Cogeneration ◽

10.1115/95-gt-058 ◽

1995 ◽

Cited By ~ 2

Author(s):

G. Negri di Montenegro ◽

M. Gambini ◽

A. Peretto

Keyword(s):

Steam Turbine ◽

Gas Turbine ◽

Flow Rate ◽

Gas Turbines ◽

Power Plants ◽

Feed Water ◽

Brayton Cycle ◽

Energy Integration ◽

Steam Power ◽

Steam Power Plants

This study is concerned with the repowering of existing steam power plants (SPP) by gas turbine (GT) units. The energy integration between SPP and GT is analyzed taking into particular account the employment of simple and complex cycle gas turbines. With regard to this, three different gas turbine has been considered: simple Brayton cycle, regenerative cycle and reheat cycle. Each of these cycles has been considered for feed water repowering of three different existing steam power plants. Moreover, the energy integration between the above plants has been analyzed taking into account three different assumptions for the SPP off-design conditions. In particular it has been established to keep the nominal value for steam turbine power output or for steam flow-rate at the steam turbine inlet or, finally, for steam flow-rate in the condenser. The numerical analysis has been carried out by the employment of numerical models regarding SPP and GT, developed by the authors. These models have been here properly connected to evaluate the performance of the repowered plants. The results of the investigation have revealed the interest of considering the use of complex cycle gas turbines, especially reheat cycles, for the feed water repowering of steam power plants. It should be taken into account that these energy advantages are determined by a repowering solution, i.e. feed water repowering which, although it is attractive for its simplicity, do not generally allows, with Brayton cycle, a better exploitation of the energy system integration in comparison with other repowering solutions. Besides these energy considerations, an analysis on the effects induced by repowering in the working parameters of existing components is also explained.

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Dual Brayton Cycle Gas Turbine Pressurized Fluidized Bed Combustion Power Plant Concept

Volume 2: Coal, Biomass and Alternative Fuels; Combustion and Fuels; Oil and Gas Applications; Cycle Innovations ◽

10.1115/97-gt-123 ◽

1997 ◽

Author(s):

Xing L. Yan ◽

Lawrence M. Lidsky

Keyword(s):

Power Plant ◽

Gas Turbine ◽

Power Plants ◽

Environmental Benefits ◽

Brayton Cycle ◽

Plant Design ◽

Fluidized Bed Combustion ◽

Electric Power Plants ◽

Wide Range ◽

Pressurized Fluidized Bed Combustion

High generating efficiency has compelling economic and environmental benefits for electric power plants. There are particular incentives to develop more efficient and cleaner coal-fired power plants, to permit use of the world’s most abundant and secure energy source. This paper presents a newly-conceived power plant design, the Dual Brayton Cycle Gas Turbine PFBC, that yields 45% net generating efficiency and fires on a wide range of fuels with minimum pollution, of which coal is a particularly intriguing target for its first application. The DBC-GT design allows power plants based on the state-of-the-art PFBC technology to achieve substantially higher generating efficiencies while simultaneously providing modern gas turbine and related heat exchanger technologies access to the large coal power generation market.

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Part Load Conditions of Complex Cycle Power Plants With Intercooled Gas Turbine

ASME 1996 Turbo Asia Conference ◽

10.1115/96-ta-035 ◽

1996 ◽

Author(s):

A. Peretto

Keyword(s):

High Pressure ◽

Gas Turbine ◽

Working Conditions ◽

Power Plants ◽

Pressure Level ◽

Combined Cycle ◽

Brayton Cycle ◽

Part Load ◽

High Pressure Compressor ◽

Pressure Compressor

The present paper evaluates the behavior, in design and part load working conditions, of a complex gas turbine cycle with multiple intercooled compression, and the optional preheating of the air at the high pressure compressor outlet by means of the gas turbine outlet hot gas. The results are then compared with those obtained by a Brayton cycle gas turbine, with or without preheating of the air at the high pressure compressor outlet. Subsequently, the performance of complex combined cycles, with intercooled gas turbine as topper and one, two or three pressure level steam cycle as bottomer, in design and part load working conditions is also evaluated. The performance of these complex combined plants is then compared with that obtained by a Brayton cycle gas turbine as topper and one, two or three pressure level steam cycle as bottomer. Part load working conditions are realized by varying either the inlet guide vane angle of the first compressor nozzles or the maximum temperature at the combustor outlet. The study shows that in part load working conditions obtained by varying IGV, the complex cycles, in the examined gas turbine or in the combined cycle power plants, give conversion efficiencies decidedly greater than those obtainable by varying combustor exit temperature. Furthermore it is found that these complex power plant efficiencies, in part load working conditions, are far greater than those obtained by the Brayton cycle gas turbine, or by combined cycle with Brayton cycle gas turbine as topper, if IGV adjustment is adopted. If power variation is obtained with combustor outlet temperature adjustment, the efficiencies of the combined power plants with complex or Brayton cycle gas turbines, are substantially the same, for the same relative power variation.

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A Comparison Study for Off-Design Performance Prediction of a Supercritical CO2 Compressor With Similitude Analysis

Volume 3A: Fluid Applications and Systems ◽

10.1115/ajkfluids2019-5017 ◽

2019 ◽

Cited By ~ 1

Author(s):

Yongju Jeong ◽

Seongmin Son ◽

Seong kuk Cho ◽

Seungjoon Baik ◽

Jeong Ik Lee

Keyword(s):

Critical Point ◽

Supercritical Co2 ◽

Power Plants ◽

Cycle Performance ◽

Working Fluid ◽

Brayton Cycle ◽

Power Cycle ◽

Design Performance ◽

Wide Range ◽

Phase Fluid

Abstract Most of the power plants operating nowadays mainly have adopted a steam Rankine cycle or a gas Brayton cycle. To devise a better power conversion cycle, various approaches were taken by researchers and one of the examples is an S-CO2 (supercritical CO2) power cycle. Over the past decades, the S-CO2 power cycle was invented and studied. Eventually the cycle was successful for attracting attentions from a wide range of applications. Basically, an S-CO2 power cycle is a variation of a gas Brayton cycle. In contrast to the fact that an ordinary Brayton cycle operates with a gas phase fluid, the S-CO2 power cycle operates with a supercritical phase fluid, where temperatures and pressures of working fluid are above the critical point. Many advantages of S-CO2 power cycle are rooted from its novel characteristics. Particularly, a compressor in an S-CO2 power cycle operates near the critical point, where the compressibility is greatly reduced. Since the S-CO2 power cycle greatly benefits from the reduced compression work, an S-CO2 compressor prediction under off-design condition has a huge impact on overall cycle performance. When off-design operations of a power cycle are considered, the compressor performance needs to be specified. One of the approaches for a compressor off-design performance evaluation is to use the correction methods based on similitude analysis. However, there are several approaches for deriving the equivalent conditions but none of the approaches has been thoroughly examined for S-CO2 conditions based on data. The purpose of this paper is comparing these correction models to identify the best fitted approach, in order to predict a compressor off-design operation performance more accurately from limited amount of information. Each correction method was applied to two sets of data, SCEIL experiment data and 1D turbomachinery code off-design prediction code generated data, and evaluated in this paper.

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New Free-Piston Topping Cycle for Gas-Turbine Power Plants

Volume 3: Turbo Expo 2003 ◽

10.1115/gt2003-38015 ◽

2003 ◽

Author(s):

William L. Kopko ◽

John S. Hoffman

Keyword(s):

High Performance ◽

Power Plants ◽

Waste Heat ◽

Combustion Engine ◽

Complete Recovery ◽

Combined Cycle ◽

Piston Engine ◽

Free Piston ◽

Free Piston Engine ◽

Topping Cycle

A proposed topping cycle inserts a free-piston internal-combustion engine between the compressor and the combustor of a combustion turbine. The topping cycle diverts air from the compressor to supercharge the free-piston engine. Because the free-piston engine uses gas bearings to support the piston and is built of high-temperature materials, the engine can increase the pressure and temperature of the gas, exhausting it to a small expander that produces power. The exhaust from the topping-cycle expander is at a pressure that can be re-introduced to the main turbine, allowing almost complete recovery of waste heat. A capacity increase exceeding 35% is possible, and overall cycle efficiency can approach 70% when incorporated into a state-of-the-art combined-cycle plant. The cost of per incremental kW of the topping cycle can be dramatically lower than that of the base turbine because of the high power density and simplicity of the engine. Building on decades of progress in combustion turbines systems, the new cycle promises high performance without the engineering risks of manufacturing a completely new cycle.

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