TY - JOUR
T1 - On-design operation and performance characteristic of custom engine
AU - Mohamed Altarazi, Yazan Sofyan
AU - Abu Talib, Abd Rahim
AU - Saadon, Syamimi
AU - Yu, Jianglong
AU - Gires, Ezanee
AU - Abdul Ghafir, Mohd Fahmi
AU - Lucas, John
N1 - Funding Information:
The authors' thanks the Ministry of Education Malaysia for the financial support under the Fundamental Research Grant no. (FRGS No. TK07/UPM/02/2 No.5540072).
Publisher Copyright:
© 2020 PENERBIT AKADEMIA BARU.
Copyright:
Copyright 2020 Elsevier B.V., All rights reserved.
PY - 2020
Y1 - 2020
N2 - The purpose of this study is to investigate the design point performance of a custom engine via GasTurb software. In this study, a turbojet engine model is simulated without afterburners and limited to design point (DP) simulation at a speed of 15,000 rpm. The input parameters such as pressure ratio (PR) for the main components, the mechanical and burner efficiency, and isotropic PR for compressor and turbine have been identified for a custom engine as a design point. The results compared at different levels of the condition using GasTurb-13 and GSP-11 software. It was found that each software was able to provide similar results at various conditions tested. There are small differences in the values for the fuel flow and specific fuel consumption. Also, the same results were obtained at the baseline point. Furthermore, the heating value has a primary effect on specific fuel consumption. It was also found that the optimal thrust value was at 34.2 kN, and the best value for optimal specific fuel consumption was 20.9 g/kN.s. The main factors affecting biofuel properties are calorific value and viscosity. When the calorific value of the fuel is reduced, the thrust FN and specific fuel consumption increase. For example, Methanol and Ethanol recorded the highest amount of fuel consumption, which is 54.72 g/KN. s and 47.56 g/(KN. s), respectively. This is because they have the highest mass fuel flow (1.79 kg/s for Methanol, and 1.54 kg/s for Ethanol) than other types of fuel, while the mass fuel flow for green diesel (0.78 kg/s) was lower than other fuels, so its specific fuel consumption (22.11 g/(KN. s) was lesser than other fuels.
AB - The purpose of this study is to investigate the design point performance of a custom engine via GasTurb software. In this study, a turbojet engine model is simulated without afterburners and limited to design point (DP) simulation at a speed of 15,000 rpm. The input parameters such as pressure ratio (PR) for the main components, the mechanical and burner efficiency, and isotropic PR for compressor and turbine have been identified for a custom engine as a design point. The results compared at different levels of the condition using GasTurb-13 and GSP-11 software. It was found that each software was able to provide similar results at various conditions tested. There are small differences in the values for the fuel flow and specific fuel consumption. Also, the same results were obtained at the baseline point. Furthermore, the heating value has a primary effect on specific fuel consumption. It was also found that the optimal thrust value was at 34.2 kN, and the best value for optimal specific fuel consumption was 20.9 g/kN.s. The main factors affecting biofuel properties are calorific value and viscosity. When the calorific value of the fuel is reduced, the thrust FN and specific fuel consumption increase. For example, Methanol and Ethanol recorded the highest amount of fuel consumption, which is 54.72 g/KN. s and 47.56 g/(KN. s), respectively. This is because they have the highest mass fuel flow (1.79 kg/s for Methanol, and 1.54 kg/s for Ethanol) than other types of fuel, while the mass fuel flow for green diesel (0.78 kg/s) was lower than other fuels, so its specific fuel consumption (22.11 g/(KN. s) was lesser than other fuels.
KW - Aero-engine
KW - Alternative fuel
KW - GasTurb
KW - GSP
KW - On-design
KW - Optimization
UR - http://www.scopus.com/inward/record.url?scp=85086877609&partnerID=8YFLogxK
U2 - 10.37934/ARFMTS.70.1.144154
DO - 10.37934/ARFMTS.70.1.144154
M3 - Article
AN - SCOPUS:85086877609
SN - 2289-7879
VL - 70
SP - 144
EP - 154
JO - Journal of Advanced Research in Fluid Mechanics and Thermal Sciences
JF - Journal of Advanced Research in Fluid Mechanics and Thermal Sciences
IS - 1
ER -