Your search keyword '"Work output"' showing total 4 results

1. Analysis of an Air Powered Engine System Using a Multi-Stage Radial Turbine

Author

Xinjing Zhang, Chunqing Tan, Xiaohui Yan, Haisheng Chen, and Xuehui Zhang

Subjects

thermodynamic analysis, radial turbine, thermal efficiency, exergy efficiency, work output, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

The performance and design criteria of air powered multistage turbines are studied thermodynamically in this paper. In-house code is developed in the C++ environment and the characteristics of four-stage turbines with inter-heating are analyzed in terms of maximum thermal efficiency, maximum exergy efficiency and maximum work output over the inlet temperature range of 293 K–793 K with inlet pressure of 70 bar. It is found that the maximum thermal efficiency, maximum exergy efficiency and maximum work output are 62.6%, 91.9%, 763.2 kJ/s, respectively. However, the thermal efficiency, exergy efficiency and work output are not equivalent for the four-stage radial turbine. It is suggested that at low working temperatures both maximum exergy efficiency and maximum work output can be used as the design objective, however, only maximum work output can be used as the design objective for the four-stage radial turbine over the working temperature range in this work.

Published

2013

2. Analysis of an Air Powered Engine System Using a Multi-Stage Radial Turbine.

Author

Xuehui Zhang, Haisheng Chen, Xiaohui Yan, Xinjing Zhang, and Chunqing Tan

Subjects

*TURBINES, *C++, *AIR engines, *THERMAL efficiency, *ENERGY consumption, *TURBOMACHINES, *PERFORMANCE

Abstract

The performance and design criteria of air powered multistage turbines are studied thermodynamically in this paper. In-house code is developed in the C++ environment and the characteristics of four-stage turbines with inter-heating are analyzed in terms of maximum thermal efficiency, maximum exergy efficiency and maximum work output over the inlet temperature range of 293 K-793 K with inlet pressure of 70 bar. It is found that the maximum thermal efficiency, maximum exergy efficiency and maximum work output are 62.6%, 91.9%, 763.2 kJ/s, respectively. However, the thermal efficiency, exergy efficiency and work output are not equivalent for the four-stage radial turbine. It is suggested that at low working temperatures both maximum exergy efficiency and maximum work output can be used as the design objective, however, only maximum work output can be used as the design objective for the four-stage radial turbine over the working temperature range in this work. [ABSTRACT FROM AUTHOR]

Published

2013

3. Effects of Direct Fuel Injection Strategies on Cycle-by-Cycle Variability in a Gasoline Homogeneous Charge Compression Ignition Engine: Sample Entropy Analysis

Author

Lev Guzmán-Vargas, P.L. Curto-Risso, Alejandro Medina, Grzegorz Litak, and Jacek Hunicz

Subjects

Valve timing, cycle-by-cycle variability, Work output, Homogeneous charge compression ignition, General Physics and Astronomy, lcsh:Astrophysics, sample entropy, Combustion, Fuel injection, Automotive engineering, lcsh:QC1-999, Sample entropy, negative valve overlap, lcsh:QB460-466, Environmental science, direct injection, lcsh:Q, HCCI, Gasoline, lcsh:Science, Simulation, lcsh:Physics, Petrol engine

Abstract

In this study we summarize and analyze experimental observations of cyclic variability in homogeneous charge compression ignition (HCCI) combustion in a single-cylinder gasoline engine. The engine was configured with negative valve overlap (NVO) to trap residual gases from prior cycles and thus enable auto-ignition in successive cycles. Correlations were developed between different fuel injection strategies and cycle average combustion and work output profiles. Hypothesized physical mechanisms based on these correlations were then compared with trends in cycle-by-cycle predictability as revealed by sample entropy. The results of these comparisons help to clarify how fuel injection strategy can interact with prior cycle effects to affect combustion stability and so contribute to design control methods for HCCI engines.

Published

2015

4. Parametric Analysis of the Exergoeconomic Operation Costs, Environmental and Human Toxicity Indexes of the MF501F3 Gas Turbine

Author

Helen D. Lugo-Méndez, Martín Salazar-Pereyra, Raúl Lugo-Leyte, Edgar Vicente Torres-González, and Alejandro Torres-Aldaco

Subjects

gas turbine, Overall pressure ratio, Thermal efficiency, Work output, 020209 energy, Airflow, General Physics and Astronomy, lcsh:Astrophysics, 02 engineering and technology, environmental index, Turbine, Natural gas, exergetic cost, exergoeconomic, parametric analysis, lcsh:QB460-466, 0202 electrical engineering, electronic engineering, information engineering, lcsh:Science, Process engineering, business.industry, lcsh:QC1-999, Environmental science, lcsh:Q, Combustion chamber, business, Gas compressor, lcsh:Physics

Abstract

This work presents an energetic, exergoeconomic, environmental, and toxicity analysis of the simple gas turbine M501F3 based on a parametric analysis of energetic (thermal efficiency, fuel and air flow rates, and specific work output), exergoeconomic (exergetic efficiency and exergoeconomic operation costs), environmental (global warming, smog formation, acid rain indexes), and human toxicity indexes, by taking the compressor pressure ratio and the turbine inlet temperature as the operating parameters. The aim of this paper is to provide an integral, systematic, and powerful diagnostic tool to establish possible operation and maintenance actions to improve the gas turbine’s exergoeconomic, environmental, and human toxicity indexes. Despite the continuous changes in the price of natural gas, the compressor, combustion chamber, and turbine always contribute 18.96%, 53.02%, and 28%, respectively, to the gas turbine’s exergoeconomic operation costs. The application of this methodology can be extended to other simple gas turbines using the pressure drops and isentropic efficiencies, among others, as the degradation parameters, as well as to other energetic systems, without loss of generality.

Published

2016