CFD Analysis of an Aircraft Turbofan Engine Combustion Process and the Effect on Turbine-Reference-Cited by-同舟云学术

CFD Analysis of an Aircraft Turbofan Engine Combustion Process and the Effect on Turbine

Published:2023-07-06 Issue:1 Volume:7 Page:135-139
ISSN:2587-1943
Container-title:International Journal of Innovative Engineering Applications
language:
Short-container-title:

Author:

CAN İbrahim¹^ORCID,ALNAK Dogan Engin¹^ORCID,SİPAHİ Muhammed²^ORCID

Affiliation:

1. SİVAS CUMHURİYET ÜNİVERSİTESİ

2. SIVAS CUMHURIYET UNIVERSITY

Abstract

In this paper, a two-dimensional computational fluid dynamics (CFD) study of Turbofan engine is presented using the ANSYS Fluent program, the navier–stokes equations is used for analysis, including a two-dimensional and symmetrical drawing of both the combustion chamber and in a 1.5 Stage Axial Flow Turbine. A GE-90 turbofan engine nacelle was used with Naca 63-412 type blades were used for the analysis of the flow on the turbine blades. Combustion chamber simulations were carried out using a previous study. The computational results were compared with other studies on the Exergetic analysis of a GE-21 turbojet engine. The GE-21 engine had a combustion chamber temperature of 2900 K, while the GE-90 engine had a temperature of around 2706 K. The previous study considered the velocity of fluid flow to be 200 m/s, whereas the velocity of flow in this study was 209 m/s as determined in the part of analysis and result.

Publisher

International Journal of Innovative Engineering Applications

Subject

Applied Mathematics,General Mathematics

Reference18 articles.

1. [1] Kerr, C., & Ivey, P. (2002). An overview of the measurement errors associated with gas turbine aeroengine pyrometer systems. Measurement science and technology, 13(6), 873.

2. [2] Willsch, M., Bosselmann, T., & Theune, N. M. (2004, October). New approaches for the monitoring of gas turbine blades and vanes. In Sensors, 2004 IEEE (pp. 20-23). IEEE.

3. [3] Horlock, J. H., & Torbidoni, L. (2006). Turbine blade cooling: the blade temperature distribution. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 220(4), 343-353.

4. [4] Gao, S., Wang, L., Feng, C., Xiao, Y., & Daniel, K. (2015). Monitoring temperature for gas turbine blade: correction of reflection model. Optical Engineering, 54(6), 065102-065102.

5. [5] Pullan G (2006). Secondary flows and loss caused by blade row interaction in a turbine stage. ASME Journal of Turbomachinery 128:484–491.