This paper discusses the impact of the external store on the aerodynamic performance of the light aircraft model in the subsonic region. Light aircrafts are commonly used for pilots training, survey, leisure and transportation. To date, there have been a lot of small aircrafts used for strategic purposes where an external store, either external fuel storage or armament, has been installed on its wing. Examples of such aircraft are KAI-KA1, A29 Super Tucano, and Beechcraft AT-6. Therefore, it is important to study the effect of this external store installation on the aerodynamic characteristics of a small aircraft. An available light aircraft model of UTM Low speed wind tunnel (UTM-LST) has been modified so that a generic external store can be mounted on the lower surface of the wing. Two set of experiments were carried out on the model which were; experimental with an external store followed by experimental without external store as a benchmark of tested configuration. The experiments were conducted at two different speeds of 26 and 39 m / s that correspond to Reynolds numbers 0.4 × 106 and 0.6 × 106respectively. Three measurement techniques were employed on each configuration.  The first measurement was the 6 component forces and moments measurement technique. The second technique was the pressure measurement on the wing, and the final test was the tufts flow visualization. The result of steady balance indicated that the external store has no effect on the coefficient of lift at low attack angle. However, it showed that there was a reduction of lift coefficient by 2% at higher angle of attack. The data showed that the coefficient of drag increases by 4% when the external is installed. Surprisingly, the installation of the store has insignificant effects on the pitching moment coefficient. An interesting feature observed from surface pressure studies where, the results showed that the pressure coefficient increased when the external is mounted on the wing at a low angle of attack. Such changes, however, do not occur at high angle of attack.
Copyright © 2018 Praise Worthy Prize - All rights reserved.

A. I. Kostic, Z. A. Stefanovic, & O. P. Kostic, (2014). Aerodynamic Analysis of a Light Aircraft at Different Design Stages. 94-105.
http://dx.doi.org/10.5937/fmet1402094k

G. Ocokoljic, B. Rasuo & M. Kozic (2017).Supporting system interference on aerodynamic characteristics of an aircraft model in a low-speed wind tunnel. Aerospace Science and Technology 64 (2017) 133–146
http://dx.doi.org/10.1016/j.ast.2017.01.021

S. Ristic, A. Viti´c, Z. Anastasijevi´c, Ð. Vukovi´c, Investigation of model support in-fluence upon aerodynamic characteristics of a torpedo model in the T-38 wind tunnel, Sci. Tech. Rev. LIV(1) (2011) 50–56.

I. S. Ishak, S. Mat, T. Mat Lazim, M. K. Muhammad, S. Mansor & M. Z. Awang (2006). Estimation of Aerodynamic Characteristics of A Light Aircraft. Jurnal Mekanikal, 66-74.

S. Mansor. (2008). Low Speed Wind Tunnel Universiti Teknologi Malayasia.

I. Bundu, S. Mat and I. S. Ishak, (2015). Effect of Control Surface and Reynolds number on flow separation of Generic Light Aircraft. Proceeding of Ocean, Mechanical and Aerospace -Science and Engineering.(1-6).

S. Mat, A. I. Bundu, N. I. Zulkefli, and I. S. Ishak, (2016).Wind Tunnel Testing For Light Aircraft Model. Aeronautical Engineering Research at UTM. Penerbit UTM Press.

I. Bundu, (2017). Experimental Investigation on A Generic Light Aircraft With Rotating Propeller at Low Reynolds number, Master thesis, Faculty of Mechanical Engineering, Universiti Teknologi Malaysia.

T. Mat Lazim, S. Mat, & H. Y. Saint. (2003). Computational Fluid Dynamic Simulation (CFD) and Experimental Study on Wing-external Store Aerodynamic Interence of a Subsonic Fighter Aircraft. Acta Polytechnica Vol. 43 No. 5, 60-65.

S. Mouton, E. Rantet, G. Gouverneur, & C. Verbeke, (2012), Combined Wind Tunnel Test and Flow Simulations fot Light Aircraft Performance Prediction. International Symposium of Applied Aerodynamics

S. Y.Yang, T. L. Wei & H.C. Qing (2014), Turbulent Study of Roll Pitch Yaw Phenomena for a Finned Store Release from a Wing Regarding Different Values of angle of Attack. Procedia Engineering 79 (2014) 86-93
http://dx.doi.org/10.1016/j.proeng.2014.06.314

L. Yang, Y. Y. Zheng & J. Wu (2016), The influence of the elastic vibrationof the carrier to the aerodynamics of the external Store on Air-Launch-to-Orbit Process, Acta Astronautika, 128, (2016) 440-454
http://dx.doi.org/10.1016/j.actaastro.2016.07.029

Aziz, M., Elsayed, A., CFD Investigations for UAV and MAV Low Speed Airfoils Characteristics, (2015) International Review of Aerospace Engineering (IREASE), 8 (3), pp. 95-100.
http://dx.doi.org/10.15866/irease.v8i3.6212

Mehta, R., Aerodynamic Design of Payload Fairing of Satellite Launch Vehicle, (2015) International Review of Aerospace Engineering (IREASE), 8 (5), pp. 167-173.
http://dx.doi.org/10.15866/irease.v8i5.8000

Ahmed, N., Forward Facing Flap for Delta Wing Performance Improvement, (2017) International Review of Aerospace Engineering (IREASE), 10 (2), pp. 90-95.
http://dx.doi.org/10.15866/irease.v10i2.11512

Razaami, A., Zorkipli, M., Lai, H., Abdullah, M., Razak, N., Unsteady Pressure Distribution of a Flapping Wing Undergoing Root Flapping Motion with Elbow Joint at Different Reduced Frequencies, (2017) International Review of Aerospace Engineering (IREASE), 10 (3), pp. 105-113.
http://dx.doi.org/10.15866/irease.v10i3.11530

Khurana, S., Suzuki, K., Rathakrishnan, E., Visualization of Vortex at Aero-Spike Root Using Hydraulic Analogy, (2017) International Review of Aerospace Engineering (IREASE), 10 (4), pp. 189-195.
http://dx.doi.org/10.15866/irease.v10i4.12816

Pope, Wind Tunnel Testing, Experimental Aerodynamics Division, Sandia Corporation, JohnWiley and Sons, Inc., London, 1947.

AIAA Recommended Practice for Wind Tunnel Testing-Part 1(2), R-092-1(2)-2003e, AIAA Standards, 2003.