AP04_3web.vp


1 Introduction
During the 1980s a large number of works [1– 4] on UDF

(unducted fans) or propfans brought attention back to the use
of advanced propellers in transport aviation. All these works
pointed to the potential benefits in fuel efficiency and T/O
thrust of the new propellers. Despite the fact that attention on
propofans has decreased, there is still great interest in the use
of propellers in general aviation and commuter [2, 4, 8] air-
craft as well as in RPV and unmanned aircraft [5]. For these
classes of aeroplane the distance between the wing and the
propeller can be close enough to induce quite large effects on
the wing surfaces, especially when the propellers are operat-
ing at high thrust as in take-off and climb. At take-off the air-
craft speed is close to stall velocity and the whole process from
rotation to climb-out involves a large range of incidence with
the propeller operating all the time at maximum thrust.
Therefore, the effect of the propeller inflow on the wing in
this situation can be of considerable magnitude [6, 9]. Since
the 1930s a large number of investigations have been per-
formed on the effects of the slipstream on a wing and/or other
components of the aircraft, including tractor and pusher con-
figurations [13]. Almost a half of these works have been on
steady loads or steady state wing/propeller interaction. Optimi-
sation analyses performed by Kroo [10] and Miranda [11] have
demonstrated that propeller/wing interaction, for the case
of the tractor configuration, can result in significant wing
drag reduction. Recent work [5, 6] and also demonstrated that
laminar flow could be increased when pusher propellers are
installed in convenient positions behind a wing, resulting in
less friction drag. Concerning aircraft drag reduction we have
to take into account the effect of the propeller slipstream, (here
the propeller inflow is also considered as slipstream), on the
wing boundary layer characteristics. Tractor and pusher
propellers affect the boundary layer of a wing in completely
different way. The tractor propeller acts in a unsteady fashion,
due to the propeller wake and tip vortex crossing the wing

surfaces. Such an effect can promote transition [12] or induce
an alternation between laminar and turbulent states. On
the other hand, a pusher propeller only affects the flow angu-
larities on the wing surfaces, and for some positions it can
alleviate the adverse pressure gradient and so prevent separa-
tion or/and increase laminar flow. This paper describes two
experimental approaches to the analysis of the problem of
wing/propeller interference. The first set of experiments was
designed to analyse the effect of three different tractor pro-
pellers on the wing boundary layer. It was decided to use
propellers with two, three and four blades in order to investi-
gate the effect of the propeller wake and tip vortex frequency
crossing the wing The second method concentrated on test-
ing the effect of a high thrust pusher propeller driven by a
hydraulic motor on a two-dimensional wing at a wide range of
incidence and with the propeller also positioned at several
positions behind the wing. Measurements included pressure
distributions for the pusher case only, flow visualisation for
both cases and hot wire measurements for the tractor case.

2 Experimental set up

Pusher set up:
A Wortmann FX63-137 profile wing with a chord of

0.34 m was used for the tests. The wing carried 82 pressure
tappings around the centre line chord. A 0.52 m diameter
three blade propeller driven by a 20 hp hydraulic motor was
used. For the pressure measurements an 8 ft×4 ft open return
low speed wind tunnel was used with the wing positioned
vertically in the working section (Fig. 1). The propeller was
mounted on a separated pylon, which could be moved in
order to set the propeller/wing positions. The wing could be
moved vertically through the working section in order to
measure the spanwise effect of the propeller on the surface
pressure distribution.

8 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 44  No. 3/2004

On the Effects of an Installed Propeller
Slipstream on Wing Aerodynamic
Characteristics
F. M. Catalano

This work presents an experimental study of the effect of an installed propeller slipstream on a wing boundary layer. The main objective was
to analyse through wind tunnel experiments the effect of the propeller slipstream on the wing boundary layer characteristics such as: laminar
flow extension and transition, laminar separation bubbles and reattachment and turbulent separation. Two propeller/wing configurations
were studied: pusher and tractor. Experimental work was performed using two different models: a two-dimensional wing with a central
cylindrical nacelle for the tractor configuration, and a simple two-dimensional wing with a downstream propeller for the pusher tests. The
relative position between propeller and wing could be changed in the pusher model, and a total of 7 positions were analysed. For the tractor tests
the relative propeller/wing was fixed, but three different propellers: two, three and four bladed were tested. Measurements included pressure
distribution, hot wire anemometry and boundary layer characteristics by flow visualisation. The results showed that the pusher propeller inflow
affects the wing characteristics by changing the lift, drag, and also delays the boundary layer transition and separation. These effects are highly
dependent on the relative position of the wing/propeller. On the other hand, the tractor propeller slipstream induces transition and its effect is
dependent on the number of blades.

Keywords: Wing /propeller interference, propeller slipstream, boundary layer.



The force and moment measurements were made in an
8 ft×6 ft closed-circuit low speed wind tunnel using a similar
arrangement for the propeller to that described above. The
wing was attached vertically to a six-component balance and
spanned the tunnel except for a 3 mm gap at one end
so that force measurements could be made (Fig. 2). Flow visu-
alisation was carried out using both sublimation and oil

technique. The seven wing/propeller position (Table 1) was
tested through the incidence range of � 4 to �20 degrees
with and without a trip wire. Wing surface pressure distribu-
tion was measured at 10 spanwise positions. The Reynolds
number was set at 0.45 millions and the propeller was run
at a thrust coefficient of CT � 0.15 with an advance ratio of
J � 0.33. These propeller characteristics were chosen in order
to simulate a high power condition such as take-off and climb.

Tractor set-up:
The same Wortmann FX63-137 profile was used to con-

struct two wings with a chord of 0.28 m. These two wings were

attached to a nacelle of cylindrical shape, Fig. 3 and 4. Inside
the nacelle there was a shaft and two ball bearings, with the
propeller and pulley attached to each end. The propeller was
driven by a 5 Hp electric motor through a 1:2 pulley/belt sys-
tem. A frequency inverter controlled the Motor/Propeller
speed. The model span was 1m long and the nacelle diameter
0.9m. The wing tips were positioned close to the wind tunnel
wall in order to keep tip vortex at a minimum. Fig. 4 shows the

tractor propeller model mounted inside the wind tunnel
working section. The wind tunnel is of the open circuit type
with a 1 m×1 m working section. The three and four blade
propellers had the same diameter of 0.40 m and the two-
-blade propeller 0.36 m.

All experimental tests performed with the tractor model
were conducted at a Reynolds number of 350.000 with the
wing without any transition trip. The propeller speed was
7.000 rpm, resulting in an average advance ratio of J � 0.43
for the three and four bladed propellers, and J � 0.48 for the
two bladed propeller. The visualisation technique used for
transition localisation was by sublimation that consisted of
spraying naphthalene diluted in a volatile solvent on the wing
surfaces. Also oil flow visualisation was used for determining
the wing surface characteristics such as laminar bubble sepa-

©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/ 9

Acta Polytechnica Vol. 44  No. 3/2004

Fig. 1: Pressure measurements, pusher case

Fig. 2: Force and moment test set-up for the pusher case

Propeller position POS 01 POS 02 POS 03 POS 04 POS 05 POS 06 POS 07

Distance From TE 0.5 C 0.5 C 0.5 C 0.85 C 0.85 C 0.85 C 0.5 C

Above + below – chord 0.0 0.23 C 0.46 C 0.46 C 0.23 C 0.0 0.19 C (�)

Table 1 Propeller Positions for the pusher case

Fig. 3: Tractor propeller set-up

Fig. 4: Tractor propeller model



ration, turbulent separation, etc. Hot wire anomometry was
carried out at the 40 % chord position of the upper surface of
the wing in 30 spanwise positions. The hot wire was kept at
1 mm from the wing surface in order to ensure that the mea-
surements were taken inside the boundary layer for the whole
probe traverse. A constant temperature hot wire anemometer
with a traverse gear was used in the experiments.

3 Results
Pusher Propeller model:

The increase in suction on the upper surface of the wing
due to the propeller is clearly shown in the pressure distribu-
tions of Fig. 5, which resulted in a gain in CL as shown in the
CL– � curve of Fig. 6. The effect of the propeller is larger at
the working incidence angles (�4 to 6 degrees) for propeller
positions above the wing’s chord line and close to the trailing
edge due to the increase in effective incidence and camber in-

fluenced by the propeller inflow. A direct consequence of this
increase of suction on the upper surface of the wing is an
increase of pressure drag, as shown in the CL– CD curve of
Fig. 7. At high incidence angles part of this gain in CL is due to
a delay in turbulent separation, as demonstrated by the move-
ment downstream of the separation point S in the � � 12.5°
curve of Fig. 5. Flow visualisation using a smoke stream also
showed the effect of the propeller on separation and upwash
angle, as can be seen in Fig. 8. Because the boundary layer
transition, in this case, is free from any trip, and also due to
the low Reynolds number of the experiment, the effect of the
propeller on changing local flow incidence affects the transi-
tion front. This effect can be seen in Figs. 9 and 10 by the
movement of the transition front (determined by sublima-
tion). The maximum effect on the transition front occurs at
the centre of the wing and also acts on the laminar separation
bubble, as can be seen in Fig. 5 with a change in the position
of the point laminar separation (L’) and reattachment (R) This
effect decreases after incidence angles greater than 8 degrees
and may even promote transition, as the effect of the propel-
ler inflow at the leading edge is an increase of upwash. This

10 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 44  No. 3/2004

Pusher model, Alpha = 12.5
-4.5

-3.5

-2.5

-1.5

-0.5

0.5

0 0.2 0.4 0.6 0.8 1

X/C

C
p

Propoffs1

Poss1

Poss2

Poss3

T

T

S
S

Fig. 5: Pressure distribution at the centre line of the pusher model wing

Fig. 6: CL– � for the pusher model wing

Fig. 7: Drag polar for pusher model



effect for two incidence angles can be seen in Fig. 11, which
also shows that for high incidence angles, near the leading

edge, the flow incidence induced by the propeller can move
the transition front forward. This phenomenon is especially

©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/ 11

Acta Polytechnica Vol. 44  No. 3/2004

Fig. 8: Effect of the pusher propeller on separation, � � 14°

Fig. 9: Transition and separation points at centre line for pusher model at position 01

Fig. 10: Transition and separation points at the centre line for pusher model, position 03



intense for propeller positions above the chord line, but even
so it is much less intense than the backward movement of the
turbulent separation front due to the propeller inflow. There-
fore, the gain in friction drag due to the increase of laminar
flow found in low incidence angles is compensated by the
increase of pressure drag and, on the other hand, for high
incidence angles the decrease in pressure drag due to the
delay of turbulent separation is the main benefit. These
results can be seen in Fig. 12, which also shows that for pro-
peller position 03 there is a decrease in drag for the working
range of incidence angles. This happens not only due to the
extended laminar flow but mainly due to a shift forward of the
resultant force which will thus produce a small thrust force.

Tractor Propeller Model:
Due to working section restrictions, the range of incidence

angles was limited from 0° to 8°. In this phase of the tests, only
flow visualisation and hot wire measurements were carried
out. The first series of tests were to analyse the transition front
using the sublimation technique. Naphthalene was sprayed
only on the upper surface. The results are plotted in Fig. 13
for the three propellers and the measurement was taken in
a spanwise station correspondent to 75 % of the propeller
radius. The results showed that inside the slipstream the tran-
sition front was brought close to the leading edge. It was
found that there is no measurable difference between the
effects of the three propellers, at least with the sublimation
technique. Also it was not possible to observe if there was any
difference between the left and right wing flow due to the pro-
peller wake swirl. Fig. 14 shows a sketch of the transition front
on the upper surface wing. Flow visualisation using the oil
flow technique was more elucidating because it showed better
the flow pattern of the wing. Fig. 14 shows the whole left wing
at 4° with the different oil flow patterns. It can be seen that the
laminar separation bubble was washed out inside the slip-
stream and that the effect of the slipstream extends further
than the propeller radius due to the viscous mixing between
slipstream and external flow. Hot wire measurements were
effective in order to find the effect of the blade wake crossing
frequency. Fig. 15 shows the time history of the velocity inside
the boundary layer for the two-bladed propeller. The periodic
effect of the blade wake crossing the boundary layer can be
seen. Figs. 16 and 17 show the time history of velocity for the

12 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 44  No. 3/2004

EFFECT ON TRANSITION, SMOOTH WING, position 03

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1

-2 -1.5 -1 -0.5 0 0.5 1 1.5 2

SPANWISE STATION Y/C

X
/C

L'

L'

R

R

a=4

a=12

R = reattachment

L'= laminar separation

EFFECT ON TRANSITION, SMOOTH WING, position 03

0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1

- 2 - 1.5 - 1 - 0.5 0 0.5 1 1.5 2

SPANWISE STATION Y/C

X
/C

L'

L'

R

R

a=4

a=12

R = reattachment

L'= laminar separation

Fig. 11: Effect on spanwise transition due to the pusher propeller
at position 03

0

0 10 20 30

Incidence angle

C
D

o
n

-
C

D
o

ff

Pos 01

Pos 02

Pos 03

Pos 07

- 0.14

- 0.12

- 0.10

- 0.08

- 0.06

- 0.04

- 0.02

0

0.02

0.04

- 10 0 10 20 30

Incidence angle

C
D

o
n

-
C

D
o

ff

Pos 01

Pos 02

Pos 03

Pos 07

Fig. 12: Variation of CD for the pusher propeller on, compared
with the propeller off case

Transition front at 75% propeller radio

0

0.2

0.4

0.6

0.8

0 5 10 15 20

Incidence angle

X
/C

propoff

tractor

Fig. 13: Transition front for the tractor model, from flow
visualisation

Fig. 14: Location of the transition front determined by flow visualization



three and four bladed propellers. It can be observed from
these figures that when increasing the frequency in the wake
that is passing over the wing the injection of turbulence to the
boundary layer from the blade wakes is much more intense.
The turbulence intensity for the three propellers is plotted in
Fig. 18.

4 Conclusions
The effect of a pusher and a tractor propeller on the flow

over a straight wing was investigated by wind tunnel tests. A
total of 7 different configurations of the pusher model were
investigated and three different propellers were used for
the tractor model. The propeller induced flow over the wing
surfaces, thus increasing lift, pressure drag, and delaying tur-
bulent separation. For the pusher propeller the effect was
more intense on the rear of the wing but can also extend to
the front by changing the upwash angle. The propeller effects
are very dependent on the relative propeller/wing position.
Over the working range of incidence angles, pusher propeller
positions above the wing gave the best results. The propeller
inflow can also delay transition by preserving laminar flow on
a smooth wing at low Reynolds number due to the alleviation
of the adverse pressure gradient at the rear of the wing. For
the tractor propeller it was found that the slipstream passing
over the wing promotes transition, changing its position to
near the leading edge. If a laminar flow wing or a low
Reynolds profile is used inside the slipstream, laminar flow
can decrease 80 % of that for a clear wing with no propeller
flow. Also if a multi-blade propeller is in use it can destroy
the intermittent shift of laminar to turbulent flow encoun-
tered when a two-blade propeller wake passes over a laminar
wing as pointed out by Howard et al [12]. Pusher propeller
wing-body configurations are still attractive when compared
with the tractor configuration, particularly concerning wing
flow and cabin noise.

References
[1] Henne P. A., Dahlin J. A., Peavey C. C., Gerren D. S.:

“Configuration design Studies and Wind Tunnel Tests
of an Energy Efficient Transport with a High Aspect Ra-
tio Supercritical Wing”. NASA CR-3224, May, 1982.

©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/ 13

Acta Polytechnica Vol. 44  No. 3/2004

Fig. 16: Time history of the velocity fluctuations inside the tractor
model boundary layer for the three-bladed propeller

Fig. 15: Time history of the velocity fluctuations inside the tractor
model boundary layer for the two-bladed propeller

Fig. 17: Time history of velocity fluctuations for the four-bladed
propeller

Local Turbulence Intensity

Tractor Propeller

0

0.5

1

1.5

2

2.5

3

3.5

4

0 100 200 300

Spanwise section

R
M

S
/U

% two bladed

four bladed

three bladed

Fig. 18: Spanwise turbulence intensity



[2] Goldsmith I. M.: “A Study to Define the research and
Technology Requirements for Advanced Turbo/Propfan
Transport Aircraft”. NASA CR-166138, 1981.

[3] Dunham D. M., Gentry G. L. Jr., Gregory M. S., Ap-
plin Z. T., Quinto P. F.: “Low Speed Aerodynamic Char-
acteristics of an Twin-Engine General Aviation
Configuration with Aft-Fuselage-Mounted Pusher Pro-
pellers”. NASA TP-2763, 1987.

[4] Coe P. L. Jr., Turner S. G., Owens D. B.: “Low Speed
Wind Tunnel Investigation of the Flight Dynamics Char-
acteristics of an Advanced Turboprop Business/Commu-
ter Aircraft Configuration”. NASA TP-2982, 1990.

[5] Catalano, F. M., Stollery J. L.: “The Effect of a High
Thrust Pusher Propeller on the Aerodynamic Character-
istics of a Wing at Low Reynolds”. ICAS - 94-6.1.3, Ana-
heim (California, USA) September 1994.

[6] Catalano F. M., Maunsell M. G.: “Experimental and Nu-
merical Analysis of the effect of a pusher propeller on a
wing and Body”. 35th AIAA Aerospace Sciences Meeting
and Exhibit, Reno (NV, USA), January 6–10, 1997.

[7] Maunsell, M. G.: “A Study of Propeller/wing /body Inter-
ference for a Low Speed Twin-Engined Pusher Configu-
ration”. ICAS-90-5.4.3, 1990.

[8] Johnson J. L., White E. R.: “Exploratory Low Speed
Wind Tunnel Investigation of an Advanced Commuter

Configuration Including an over-the-wing Propeller
Design”. AIAA-83-2531, 1983.

[9] Witkowski D. P., Johnston R. T., Sullivan J. P.: “Propel-
ler/Wing Interaction”. 27th Aerospace Science Meeting
Reno (NV, USA), January 9–12, 1989.

[10] Kroo I.: “Propeller-Wing Interaction for Minimum In-
duced Loss”. AIAA 84-2470, 1984.

[11] Miranda L. R., Brennan J. E.: “Aerodynamics Effects of
Wing Tip Mounted Propellers and Turbines”. AIAA
86-1802, 1986.

[12] Howard R. M., Milley S. J., Holmes B. J.: “An Investiga-
tion of the Propeller Slipstream on a laminar Wing
Boundary Layer”. SAE Paper No. 850859, 1985.

[13] Thompson J. S., Smelt R., Davison B., Smith F.: “Com-
parison of Pusher and Tractor Propeller Mounted on a
Wing”. Reports and Memoranda R&M, No. 2516 June
1940.

Fernando M. Catalano M.Sc Ph.D, MRAeS

Aircraft Laboratory
University of Sao Paulo – Brazil
Ave do Trabalhador SaoCarlense 400
Cep 13566-590 Sao Carlos SP

14 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 44  No. 3/2004


	8
	9
	10
	11
	12
	13
	14