Jtam.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

50, 1, pp. 169-192, Warsaw 2012

50th anniversary of JTAM

VIBRO-ACOUSTIC DESIGN OF AN AIRCRAFT-TYPE

ACTIVE WINDOW. PART 1: DYNAMIC MODELLING AND

EXPERIMENTAL VALIDATION

Ignazio Dimino
CIRA, The Italian Aerospace Research Centre, Vibro-Acoustics and Smart Structures Laboratory,

Capua, Italy and PhD Student at Imperial College London, Department of Aeronautics, London,

Great Britain; e-mail: i.dimino@cira.it

Andrea Vigliotti
CIRA, The Italian Aerospace Research Centre, Vibro-Acoustics and Smart Structures Laboratory,

Capua, Italy; e-mail: a.vigliotti@cira.it

M.H. Ferri Aliabadi
Imperial College London, Department of Aeronautics, London, Great Britain;

e-mail: m.h.aliabadi@imperial.uk

Antonio Concilio
CIRA, The Italian Aerospace Research Centre, Vibro-Acoustics and Smart Structures Laboratory,

Capua, Italy; e-mail: a.concilio@cira.it

Recent investigations show that active noise control methods can improve no-
ise reduction capabilities of aircraft-type windows in the low-frequency region.
Being a privileged path for external noise transmission and one of the main
causes of high interior noise levels in a treated aircraft, a proper design of the
aircraft window can significantly contribute to the reduction of cabin noise le-
vels with aminimum impact on the aircraftmass and performances. This is the
first part of two companion papers. In this paper (Part 1), the vibro-acoustic
design of a triple-pane aircraft-type window prototype is presented. Numerical
andexperimental activities addressing the structuraldynamicsandtheactuation
performances are described in detail. The effectiveness of the piezo-stack actu-
ators in the excitation of the flexural bending modes of the structure by means
of adaptive in-plane and eccentric dynamic forces is experimentally investigated.
An experimentalmodal analysis is carried out to determine both single partition
and coupled fluid-structuremodal frequencies used to validate the finite element
model. For the purpose of estimating the sound radiation characteristics of the
window prototype, a numerical procedure coupling boundary and finite element
methods will be detailed in the second part of this paper (Part 2) to solve the
coupled acoustic-structure problem in the exterior acoustic domain.

Key words: structural acoustics, piezoelectric actuation, passenger comfort



170 I. Dimino et al.

1. Introduction

The importance of a quiet aircraft cabin is well documented in a number of
papers dealing with the passive and active control of the cabin environment.
Modern interior noise control technologies target weight-efficient solutions to
improve comfort of next-generation aircrafts minimizing the effect on perfor-
mances.

Although currently no certification requirement exists to regulate cabin
noise levels in aircraft, comfort is particularly appreciated by end-consumers
considering the effect of combined sound and vibration on comfort perception
as one of themost important aircraft quality indicators (Mellert et al., 2004).
The dynamics of fuselage structure and the properties of the interior acoustic
space are the main factors affecting the passenger’s psychoacoustic response.

The existing conflict between lightweight design on the one hand and pas-
sive safety and comfort requirements on the other hand can be solved thro-
ugh the use of active noise reduction concepts based on intelligent materials.
The integration of additional functionalities with respect to noise control can
be achieved by combining conventional structures with intelligent systems,
extending structural properties to sensing and actuating capabilities. A smart
structure incorporates sensors and actuators in such a way that enables the
structure to sense its environment and then respond adaptively.

Aircraft windows represent a significant path for structure-borne and air-
borne noise transmission in the aircraft. Turbulent Boundary Layer noise is
mainly transmitted into the cabin by airborne paths, but structure-borne no-
ise, associated with engine vibrations, and the interaction between aerodyna-
mic wakes and aircraft structure, makes a significant contribution to interior
noise levels, especially at certain discrete frequencies.

Theoretical studies (David andGuillaumie, 2000;Hayde et al., 1983;Röder
et al., 2006; Unruh and Till, 2002; Vaicaitis, 1983) indicate that the noise
transmitted through windows is a predominant cause of high interior noise
levels in a treated aircraft. Experiments (Guillaumie et al., 2000; Hald et al.,
2008; Morkholt et al., 2009) confirm that the airplane fuselage sidewalls in
general and the passenger windows in particular, are the dominant entry path
of external noise. Fuselage sidewalls radiate sound because of external forcing,
causing the surface to vibrate, and absorb energy from the incident noise field
because of the finite surface acoustic impedance. The distinction between the
incident and the radiated field is not obvious, even in the near field, and
recently novel beam-forming techniques have been proposed to enhance the
spatial resolution and separate different sound field components (Morkholt et
al., 2009).



Vibro-acoustic design of an aircraft-type active window... 171

For a prescribed noise source, active noise control methodologies are typi-
cally categorized dependingon theanti-noise strategies adopted for the interior
noise reduction: at the location of noise reception or at the origin of radiation.
The first approach is the loudspeaker-based active noise control (ANC), which
consists of anti-noise sources, radiating a secondary noise field, able tomitiga-
te passenger’s noise reception (Tiseo et al., 2007). Loudspeakers can be placed
either inside the receiving enclosure (room control) or inside the cavity be-
tween the layers of double-leaf or triple-leaf partitions (cavity control) (Jacob
andMoser, 2003a,b; Jacob et al., 2004). The errormicrophones are distributed
throughout the cabin space.

The other approach is the active structural acoustic control (ASAC). It
aims at controlling the structural vibrations themselves by using dynamic or
electric vibrationabsorbers (Misol andAlgermissen, 2009;Yu et al., 2007), pro-
perly or adaptively tuned to suppress the structure-bornenoise contribution to
the acoustic field. Vibration actuators and sensors, such as piezo patches, are
bonded or embedded into the structure to absorb andmodify vibrations, and
hence the way the structure radiates noise, through their electro-mechanical
coupling properties. Since each vibrationmode has different radiation efficien-
cyand somemodes canbebetter coupled to theacoustic field thanothers, only
few dominant radiating modes require to be controlled in amplitude. Other
ASAC approaches take advantage of the acoustic radiation capabilities of the
panels themselves in order to effectively control the direct sound radiation of
the panel speaker so that the interior acoustic pressure is minimized.

Many airplanes use triple-pane windows, having three panes separated by
air gaps, to break the vibration chain through the partitions and significantly
increase the sound transmission loss.Aircraftwindows canbe rectangularwith
rounded corners, circular, elliptical or oval in shape. They cannot be square
because this would cause high stress levels in the corners which can result in
cracks and structural failures.

In this paper, an application-oriented approach is used to design a smart
aircraft-type window prototype. The adaptive structure employs sensors, ac-
tuators and a controller to change beneficially the inherent structural charac-
teristics in the response to an external stimulation. A multilayered partition
design is used to increase the sound insulation properties.The change in densi-
ty of themedia travelling through the partition walls, separated by air spaces,
result in a greater transmission loss than would have been provided by do-
ubling themass or thickness of a single partition in the same amount of space.
For the purposes of this study, the window is modeled andmanufactured rec-
tangular and flat for ease of fabrication and testing. Although the obtained



172 I. Dimino et al.

results are approximately valid for a more realistic rectangular shape with
rounded corners, this assumption allows one to use some analytical solutions
in order to validate the numerical results. The effects of bending waves can
be accurately predicted as well as the motion and forces transmitted by the
control actuators. Moreover, the sound insulation properties of the triple-wall
window can be predicted by using analytical models of sound transmission
through finite aeroelastic multilayered partitions which assume that flat rec-
tangular panels are acoustically coupled and simply supported in an infinite
baffle.
The geometry and physical characteristics of the window prototype are

therefore intended to be representative of an actual aircraft window. Firstly,
the smart actuator configuration is evaluatedbycharacterizing its effectiveness
in exciting the structure at low-medium frequencies.The structural resonances
are computed for the single pane and the triple pane configuration, including
themodeling of the fluid between the two panes. A surface-based contact ap-
proach is used to couple the structure with the inner air. An experimental
modal analysis is carried out in order to validate FE predictions. The expe-
riments demonstrate that the elastomeric strips supporting the panes of the
prototype are closely approximated by simply supported conditions. In Part 2
of this paper, the validated modal model of the structure is employed to pro-
vide an accurate estimate of themodal acoustic power and radiation efficiency
for selected modes. Coincidence phenomena at which the speed of incident
acoustic waves matches that of the structural bending waves are addressed.
At this specific frequency and above, the acoustic waves are particularly effec-
tive in causing the structure to vibrate,making the vibrating structure a pure
sound radiator whose the overall radiation efficiency is dramatically increased.
However, the potential of using smart windows to control aircraft interior no-
ise control is investigated at low frequencies where the propagation velocity
of the bending wave of isotropic plates is much less of the sound speed in air.
At those frequencies, coupled structural-acoustical resonances together with
mass-air-mass phenomena result in a substantial decrease in the low-frequency
transmission losswhich can be compensatedbymeans of active structural aco-
ustic control.

2. The actively controlled aircraft-type window prototype

In general, airplane fuselage is composed of a structure of circular rings (fra-
mes) and longitudinal stringers on which an aluminium skin of thickness va-
rying between 1 and 1.5mm is wrapped. The fuselage interior is furnished by



Vibro-acoustic design of an aircraft-type active window... 173

trim panels fixed on the frames via rubber mounts. The space between the
fuselage skin and the trim panels is filled with blankets of insulatingmaterial.
The main purpose of this cavity treatment is thermal insulation; however,
acoustic absorption is also achieved at relatively high frequencies.

The growing attention of aircraft manufacturers towards passenger com-
fort has accentuated the demand of novel solutions able to improve interior
vibro-acoustic properties of aeronautical vehicles. Since visco-elastic damping
treatments, used to reduce noise radiation on floors, sidewalls and ceilings,
are not applicable for window surfaces, Fig.1, aircraft windows represent a
straightforward path by which the incoming sound energy enters the cabin.
This is confirmed by high variability of the sound pressure levels existing near
aircraft windows and usually being the highest at most frequencies.

Fig. 1. Cross section of the fuselage structure

The conventional approach for determining the sound transmission pro-
perties of flat or curved structures is to mount the test article between two
test chambers, typically a reverberant and an anechoic room constructed so
that the only significant sound path is through the specimen, introduce sound
in one of them and thenmeasure the loss in sound power due to transmission
through the specimen.

Transmission Loss tests on damped aircraft windows have demonstrated
that the total sound intensity is mainly radiated by the window area and
partially absorbed by the trim panel (Buehrle et al., 2002, 2003, 2004). Conse-
quently, heavy sidewall treatments, typically located behind the sidewall trim
panels to attenuate noise and vibration, do not ensure an effective solution for
cabin noise reduction if thewindows provide aweak link in noise transmission.

The introduction of active systems on window panels can lead to a signifi-
cant reduction in the transmitted noise, contributing to minimize SPL inside
the cabin without affecting structural design and weight. Active noise control



174 I. Dimino et al.

systems applied to conventional homogeneous windows have been proposed in
Bein et al. (2007), Bös et al. (2009), Grassi et al. (2007), 2003. The use of pie-
zoceramicmaterials to produce control forces and bending actuationmoments
or to add electromechanical damping has been extensively studied in Crawley
and Luis (1987), Hambric et al. (2006). Enabling the self-actuation and self-
sensing capabilities in a structure through piezoelectric actuators, labels the
structure as an adaptive structure since it is capable to control and adapt its
mechanical response.

While designing smart structures for noise and vibration control, the se-
lection of a suitable control concept is strictly related to the specific problem
to be addressed. Both active vibration and noise control (AVC/ANC) and ac-
tive structural acoustic control (ASAC) aim at controlling the vibro-acoustic
behavior of the structural components either by minimizing the total sound
power radiation or the vibrational energy using either activemounts or control
loudspeakers. In the attempt tominimize the acoustic radiation, a reduction in
the vibrational energy of the structure by cancelling the out-of-plane velocities
does not necessary guarantee a reduction in the total sound power radiated.
This is because the action of the control forces could, in principle, excite some
modes, previously unexcited, which could possibly bemore efficient radiators
of sound. The effect is that the total sound power output could be greater
than in the absence of control. Therefore, active noise control can target the
cancellation of acoustic pressure at fixed points only by using control loudspe-
akers emitting destructive sound waves or active mounts driven by acoustic
cost functions. A way to control actively noise in an enclosure consists in try-
ing tominimize thewhole acoustic potential energy (Nelson andElliot, 1992).
This potential is proportional to the volume integral of the sound pressure
mean square value. The sound pressure at low frequency can be represented
by a combination of a number of acoustic modes. A good estimate of the aco-
ustic potential energy in the enclosure could be the sum of the mean square
pressures measured at many different points in the room.

In this paper, a smart aircraft-type window prototype is presented. The
adaptive structural system is built from a conventional triple pane window
configuration, adding a number of piezoelectric stacks ensuring actuating and
sensing capabilities. An ASAC strategy is implemented in order to reduce
propeller-inducednoise ina turbopropaircraft cabin.Thestructural vibrations
are controlled so that the sound radiated to the environment is reduced. The
active mount, studied in this paper, is based on piezo actuators, distributed
along the window frame, in order to generate in-plane and eccentric forces
controlling the inner plexiglas window partition. They consist of a stack of



Vibro-acoustic design of an aircraft-type active window... 175

thin ceramic disks separated by electrodes. The electro-mechanical coupling
properties, describing the conversion of electric energy intomechanical energy
andviceversa, are such that thepiezoelectric constant d33 dominates theother
coefficients in the constitutive equations. Unlike the laminar design where the
useful direction of expansion is normal to that of the electric field, depending
on d31 and d32 coefficients, these actuators are characterized by the fact that
thepolarization axis and theapplied electric field coincidewith thedirection of
expansion of the piezoelectric stack (IEEE, 1978). Due tohigh strain constants
in the direction of the applied voltage, they are themost efficient piezoelectric
actuators to provide high normal forces suitable for active noise and control
systems.

2.1. Structural-acoustic modelling

Figure 2 shows a schematic description of the triple-glazed window. The
distance between the panes are d1 and d2, respectively. The velocity distribu-
tions on thepanes are denotedwith v1(x,y), v2(x,y) and v3(x,y), respectively
fromthe side of sound incidence to the side of sound radiation.The soundfield
between pane 1 and 2 is given by p12(x,y) and, the sound field between pane
2 and 3 is given by p23(x,y).

Fig. 2. Schematic of the model of the actively controlled triple-pane window

Fivedifferential equations canbestateddescribing thevibrational behavior
of the triple-glazed window (Jacob et al., 2004)

∆∆v1(x,y)−k
4
B1v1(x,y)=

jk4B1
m′′1ω
(p1(x,y,z=0)−p12(x,y))

∆p12(x,y)+k
2
0p12(x,y)=

jωρ

d1
(v2(x,y)−v1(x,y))



176 I. Dimino et al.

∆∆v2(x,y)−k
4
B2v2(x,y)=

jk4B2
m′′2ω
(p12(x,y)−p23(x,y)) (2.1)

∆p23(x,y)+k
2
0p23(x,y)=

jωρ

d2
(v3(x,y)−v2(x,y))

∆∆v3(x,y)−k
4
B3v3(x,y)=

jk4B3
m′′3ω
(p23(x,y)−p3(x,y,z= d1+d2))

Equations (2.1)1,3,5 are bendingwave differential equations describing the ve-
locity distributions of the panes. Equations (2.1)2,4 are differential equations
for sound in the air describing the cavity sound field distributions between
the three panes. Each cavity sound field is excited by the vibration of its two
adjacent panes, i.e. the cavity between pane 1 and 2 (Eq. (2.1)2) is excited by
the velocity distributions v1(x,y) and v2(x,y).
In Eq. (2.1)1, p1(x,y,z = 0) is the sound field distribution on incident

pane 1 due to the incoming wave. In Eq. (2.1)5, p3(x,y,z = d1 + d2) is the
external sound pressure reacting on the radiating pane due to the radiating
wave, i.e. the fluid loading. The fluid loading has a negligible effect and can
be omitted. ∆ is the Laplace operator ∆=∇∇, k0 is the free wave number
in the air. The bending wave numbers of the panes are defined by

k4Bu =
m′′u
B′u
ω2 (2.2)

with

B′u =
Eu

1−ν2
h3u
12

Eu =E0u(1+ jηu) (2.3)

where u=1,2,3 and m′′u = ρuhu are themasses per unit area of the panes of
densities ρu and thicknesses hu, respectively. B

′

u are the bending stiffnesses
with Poisson’s ratio ν and complexYoung’smoduli Eu taking the dissipation
of the panes into account via the loss factors ηu.
By assuming the panes to be simply supported at the boundaries, the

velocities can be written in the form

vu(x,y)=
∞
∑

n=1

∞
∑

m=1

Vunm sin
nπx

a
sin
mπy

b
(2.4)

with modal amplitudes Vunm where u=1,2,3.
For the cavity soundfields, themodal functions can bewritten in the form

pw(x,y)=
∞
∑

p=0

∞
∑

q=0

Awpq cos
pπx

a
cos
qπy

b
(2.5)

with modal amplitudes Awpq where w=12,23.



Vibro-acoustic design of an aircraft-type active window... 177

Compared to single panels, infinite multi-pane panels generally yield a
higher transmission loss, except around the low-frequencymass-air-mass reso-
nance where the two adjacent glass plates oscillate in anti-phase against the
stiffness of the compressible acoustic medium in the cavity. For a double-wall
partition, the mass-air-mass resonance is defined as

ω0 =

√

ρ0c
2
0

Lzc

(mp1+mp2
mp1mp2

)

(2.6)

where Lzc is the distance between two panes, ρ0 the density of the acoustic
medium in the cavity (1.225kg/m3), c0 the sound speed in that medium
(340m/s), and mp1 and mp2 represent the mass per unit area of both plates.

2.2. The window design

Despite the acoustic transmission characteristics of aircraft-type windows
have been extensively studied for single and double pane configurations (Hills
et al., 2006; Navaneethan et al., 1980; Rassaian et al., 2008), only few papers
providenumerical andexperimentaldata for triplepanewindows.Multi-glazed
windowsprovidegood sound insulationonly at relatively high frequencies.Due
to the mass-air-mass resonance, their acoustic performance rapidly deteriora-
tes at low frequencies, where the sound transmission loss can even become
worse than that of a single partition. The design of the active aircraft-type
window is here reported. The dynamic behavior of the triple wall system is
analyzed. The low-frequency sound insulation characteristics and the sound
transmission loss will be addressed in Part 2, where the benefits achieved by
coupling a three-layer configuration with an adaptive control system will be
also experimentally investigated.

The prototype consists of an aluminium frame, measuring 22.2cm ×
×34.2cm×8.72cm, containing threewindowpaneswith a transparent area of
32cm×20cm. Two of the three panes aremade of 0.94cm thick glass and are
separated by an airspace of 1.66cm. The third pane, which is made of acry-
lic, is 0.64cm thick and is separated from one of the glass pane by a 3.62cm
airspace. When the window is installed, the acrylic pane faces the inside of
the fuselage cabin. The panes are supported by strips of elastomer. A silicon
rubber is used to secure the windows in the aluminium frame. A sketch of the
window frame and layers is shown in Fig.3a. Figure 3b shows a section of the
assembled prototype, including the layers and the strips of elastomer.

Concerning the actuation, no. 10 piezoelectric stack actuators aremounted
on the sides of the window. A planar actuation system is constrained to the



178 I. Dimino et al.

Fig. 3. (a)Window sketch. (b) Assembled prototype

Fig. 4. Sketch of the single actuationmechanism

window frame bymeans of a dedicated system of clamping. Each stack is pre-
stressed by the action of a screw compressing the actuator to the acrylic pane
though a metal rod. A sketch of the actuator mechanism is shown in Fig.4.
In this configuration, the actuator generates an off-midplane actuation force
on the active pane inducing local bending moments capable of exciting and
hence controlling the transverse modes.

Themanufacturing of the prototype required themachining of light-weight
clamping systems constraining the piezo actuators. A sketch of the distributed
piezo stacks and their clamping systems is reported inFig.5a. Apicture of the
assembled window prototype is depicted in Fig.5b. Figure 5c shows the clam-
ping system. The prototype has beenmanufactured and preliminary tested in
laboratory.

2.3. Numerical modelling

AFEmodel of the structure has been developed to evaluate the structural
dynamics. The two glass and acrylic panes, the elastomer and the aluminium
framehavebeen individuallymodeledwith constantmaterial properties.They
are listed in Table 1.

Two-dimensional shell elements have been used, Fig.6. The model of the
aluminium frame, the glass and plexiglas partitions and the elastomer gasket
totally consist of 3344 linear quadrilateral elements of 4-node general-purpose
S4 shells. The assembled FE model of the prototype is shown in Fig.7.



Vibro-acoustic design of an aircraft-type active window... 179

Fig. 5. (a) Sketch of the actuation grid. (b) Active window prototype. (c) Clamping
system of the piezo actuators

Table 1.Material properties of the window

Material
Young’s modulus Poisson’s ratio Density
[N/m2] [–] [kg/m3]

Plexiglas 0.31E+10 0.40 1190

Glass 6.20E+10 0.24 2480

Elastomer 2.50E+7 0.49 1300

Aluminium 7.24E+10 0.33 2780

Fig. 6. Aluminium box, the plexiglas layer and the two glass layers



180 I. Dimino et al.

Fig. 7. FE model of the prototype

Before analyzing the whole system, the modal characteristics of each ele-
ment of the window have been individually studied. The natural frequencies
of the three layers of the window have been analytically calculated in simply
supported boundary conditions, with

fl,n =
π

2

√

Et2

12(1−ν2)ρ

[( l

a

)2

+
(n

b

)2]

(2.7)

where t is thickness, ρ is the surface density, and a and b are the width and
the length of the window panes. Such frequencies are tabulated in Table 2
and compared to the numerical resonances computed for each single-pane. A
modal analysis of the assembled model has been carried out in ABAQUS.
Natural frequencies and mode shapes have been computed in the frequency
range up to 1KHz. The clamped boundary conditions have been prescribed
at the outer surface nodes, as described Fig.7 (right). As shown in Table 2,
a reasonable agreement between mode (1,1) and mode (1,2) of the simply-
supported acrylic pane and the respective modes of the outer plexiglas layer
of thewindowprototype, has been observed. This confirms that the boundary
conditions with the panes supported by the elastomer, as described in Fig.3b,
are approximated closely by simply supported conditions. Such an assumption
is also confirmedby the results reported inGrosveld (1988) for a similar triple-
pane window architecture.

Being a triple-leaf partition, particular attention has been paid to the si-
mulation of the air gap between the plexiglas and the upper glass layer and
that between the upper and lower glass layers. The air between the plexiglas
and the glass layer has beenmodeled with 2560 linear hexahedral elements of
typeAC3D8, while 1280 AC3D8 elements have been used to fill in the volume
of the interior air between the two glass layers, Fig.8. To simplify the pro-
blem, the effect of interacting air at the outside of the window box has been



Vibro-acoustic design of an aircraft-type active window... 181

Table 2.Calculated andmeasured window resonance frequencies

Reso- Thick- Calc. suply FE FEmodel Experim. analysis
nance Material ness Mode supported model Air gap no comp. 1Nm2Nm
system [cm] [Hz] [Hz] model. [Hz] [Hz] [Hz] [Hz]

Single Acrylic 0.64 1.1 177.58 175.77
layer 1.2 327.23 324.65

2.1 560.69 555.15
1.3 576.65 570.75

Glass 0.94 1.1
1.2 1405.7 1389.3

Window 1.1 170.48 194.17 197 193 192
prototype 1.2 304.76 297.52 264 255 251

2.1 475.37 470.36 455 447 450
Cavity

538.06 536 538 541
resonance

neglected. The air has been modeled with density of 1.225kg/m3 and bulk
modulus of 0.142MPa. The surface-based contact approach has been used to
couple the structural and acoustic meshes. Surfaces have been defined for the
frame, the two opposite layers and the free surface of the air. TheTIE option
has been used to couple the structure with the inside air. As a result, the
numerical model could simulate the acoustic coupling effects considering the
acoustic medium tied to the structure. The natural frequencies computed for
theuncoupledand coupled systemare given inTable 2.Theuncouplednatural
frequencies are also given in order to showhow the structure-acoustic coupling
affects the characteristics of the system.

Fig. 8. Air gapmodelling

Due to the coupling effects, the eigenfrequencies shifted mode by mode.
The first natural frequency of the coupled system has been observed higher



182 I. Dimino et al.

than the first natural frequency of the structural model. This is because the
acoustic chamber, represented by the fluid between the panes, “spring-loads”
the two plates. Each mode shape exhibited also more complex behavior with
respect to the structural modes, so that each mode had nonzero components
on both the structural and acoustic part.

Somemode shapes computed for the uncoupled case are reported inFig.9.

Fig. 9. Modes of the structure

The coupled structural-acoustic analysis resulted in an equal distribution
of the normal velocity for both the structural and the acoustic meshes. The
soundpressuredistribution of the acousticmedium,due to the coupledmodes,
has been calculated for the interior domain.As shown inFig.10a, the pressure
distribution in the air gap between the plexiglas and the upper glass layer (left
side of the picture)matches the first bendingmode (1,1) of the plexiglas plate
(right side of the picture). The same behavior has been observed also for the



Vibro-acoustic design of an aircraft-type active window... 183

second bendingmode (1,2), as shown in Fig.10b. The firstmode shape of the
system scaled to the aluminium frame is shown in Fig.11a. Finally, the cavity
resonance occurring in the air volume comprised between the plexiglas and
the upper glass layer is shown in Fig.11b.

Fig. 10. Section of the pressure distribution in the air gap between the plexiglas and
glass layer – 1st mode (a), 2ndmode (b)

Fig. 11. (a) Frame components of the 1st mode shape. (b) Cavity resonance in the
air gap between the plexiglas and glass layer

2.4. Experimental activities

An experimental modal analysis has been carried out in order to vali-
date the FE model of the structure. The experimental set-up consisted of
an instrumented hammer, used to excite the structure, and 18 accelerome-
ters distributed on a regular mesh. Data acquisition was done with the LMS
SCADAS data acquisition system. The transducers have been installed so as
to minimize the effects of mass-loading due to the sensors. The structure has



184 I. Dimino et al.

been tested clamped on the reference panel resting on a block of foam rubber
to simulate the free-free boundary conditions.

Fig. 12. Experimental modal tests on the window prototype

The mesh grid has been drawn on the plexiglas. The acquisition system
recorded simultaneously both the force impulse generated by the hammer and
the vibrations measured by the accelerometers. From the measured data, the
Frequency Response Functions have been computed by using a curve fitting
method in order to extract the structural modes. Themodal parameters have
been calculated by the LMS Polymax method. Figure 13 shows two expe-
rimental FRFs measured on point no. 5 and point no. 8 respectively, both
located nearby the centre of the plexiglas plate, Fig.16. No pre-stress through
the screws has been imposed, as numerically simulated in the FEmodel. The
first two experimental mode shapes measured on the structure are shown in
Fig.14.

Fig. 13. Experimental FRFmeasured by two sensors



Vibro-acoustic design of an aircraft-type active window... 185

Fig. 14. Experimental mode shapes: left (1,1), right (1,2)

The experimentalmodal frequencies are tabulated inTable 2.Agood agre-
ement between the experimental and numerical resonances has been observed,
especially for those resulting from the acoustic-structural coupled analysis.

The influence of themechanical pre-stress onto the structure has been also
examined. To this aim, a uniform torque has been applied to the screws con-
straining the piezo actuators through the borders. This static load determined
a slight reduction in the resonance frequencies of the structure depending on
the amplitude of the mechanical compressive axial force, as shown in Fig.15.
The resonance frequencies decreased with the increasing compression preload.
This has been demonstrated for two different levels of torque (1Nm, 2Nm)
tightening the screws.

Fig. 15. Influence of the compressive preload on the structural response

Afurther validation of the dynamicbehavior of the prototype has been carried
out in operative conditions. The window has been installed on the side of a
plumb steel box (2 tons of weight), used as the reference facility for the active
noise control experiments described in Dimino et al. (2010a-c), Fig.16. Unli-
ke the previous experiments, the structure has been directly excited by the



186 I. Dimino et al.

piezoelectric stack actuators. The experimental set-up consisted of 12 accele-
rometers, a signal generator and 10 amplifiers needed to drive the piezoelectric
actuators. The transfer functions of the acrylic pane have been measured by
imposing a broadband sweep excitation.

Fig. 16. Active windowmounted on the acoustic facility

Different levels of excitations driving the piezo actuators have been impo-
sed in order to capture potential non-linearities in the actuation chain in the
frequency range 100-1000Hz. The voltage has been set in the range of 100 to
400V. In the latter configuration, a non-linear response of the actuator has
been observed due to the power saturation limit. Figure 17 shows the FRFs
measured by two different points for each level of excitation.

Fig. 17. FRFs measured on point 8 (left) and point 5 (right). Four input levels
(1 – 100V, 2 – 200V, 3 – 300V, 4 – 400V

Since the choice of the actuator positions represents a crucial issue in the
design of smart structures, the influence of the actuation points has been in-
vestigated. In principle, the piezoelectric actuators must be placed in regions
of high average strain and away from areas of zero strain (Crawley and Luis,
1987). The position of these “strain nodes” is determined by twice differentia-



Vibro-acoustic design of an aircraft-type active window... 187

ting the analytic expressions for the platemodes and finding the zero-crossing
points of the resulting functions. For the second mode (1,2) of a simply sup-
portedplate, for instance, the actuators located behind such strain nodesmust
be driven 180deg out of phase with respect to the piezo located ahead. This
means that it is necessary to control individually the driving voltage applied
to each actuator in order to control each flexuralmode effectively. This cannot
be done if the actuators are continuous over the length of the structure. For
these reasons, segmented actuators are normally preferred in the control of
flexible structures.

Figures 18 and 19 describe the experimental FRFs obtained by exciting
the structure by single or grouped piezo stacks. Each color identifies both the
piezo actuator and the respective FRF.As expected, the simultaneous control
of eight piezo stacks (8 input channels) determined a good excitation of all
the structural modes included in the frequency range of interest, (b curve),
with particular reference to the symmetricmodes.Obviously, such a condition
cannot be considered as an optimal configuration since it has been obtained by
equally controlling each actuator. For this reason, further improvements can
be achieved by optimizing amplitude and phase signals driving each actuator.

Fig. 18. Influence of the actuation point on the experimental FRFs

Fig. 19. Influence of the actuation point on the experimental FRFs



188 I. Dimino et al.

Finally, the acoustic radiation properties of the window have been investi-
gated in anechoic conditions, Fig.20. A microphone has been installed inside
an anechoic chamber at a distance of 1m fromthewindowprototype.Thepie-
zoelectric actuators have been excited in the frequency range of 200-2000Hz.
A voltage transformer allowed achieving the high voltage required to drive the
actuators. The output of the pressure transducer has been sampled and pro-
cessedwith a spectrumanalyzer. Figure 21 shows the experimental Frequency
ResponseFunction of the acoustic pressuremeasuredby themicrophone. Such
a curve, generally flat for a commercial loudspeaker, provides a basic under-
standing of the acoustic radiation of a flexible structure. From this preliminary
analysis, it can be noted that the acoustic radiation of the structure exhibited
antiresonances in the regions between 700-1000Hz and 1800-2000Hz. Amore
detailed analysis of the structural radiation efficiency in the low-medium fre-
quency range will be addressed in Part 2 of this paper. Such a study impacts
also the design of an active noise control system suitable for the interior noise
control of a turbo-prop aircraft (Dimino et al., 2010c).

Fig. 20. Acoustic measurements in the anechoic chamber

Fig. 21. Acoustic FRF of the widow prototype



Vibro-acoustic design of an aircraft-type active window... 189

3. Conclusions

Next generation aircraft will have larger windows and composite fuselages.
For this reason, the window design must be optimized to provide maximum
passenger external visibility whileminimizing acoustic noise transmitted thro-
ugh the windows. This paper is the first part of two companion papers. In
this part, the design of a smart aircraft-type window prototype is presented.
Such an adaptive structure is built from a passive, conventional, triple pane
window adding a number of piezo stacks controlling the structural panes. The
main benefits are related to the coupling between the enhanced sound trans-
mission loss due to themulti-partition design, and the active control aptitudes
provided by the piezo actuators.

The actuation mechanism, based on piezo-induced vibrations exciting the
structural flexural modes, has been experimentally validated. For a proper
installation of the actuators, a mechanical preload has been required to com-
pensate the small extensional strength of the stacks so that the piezo-induced
strains resulted smaller than themechanical strains imposed through the com-
pressive preloads. The vibro-acoustic properties of the window prototype ha-
ve been numerically and experimentally investigated. The structural frequ-
encies of resonance have been computed for the single pane individually as
well as for the whole system, including the modeling of the fluid between
the panes. An experimental modal analysis has been carried out to validate
the FE model. Experiments have demonstrated that the elastomeric strips
supporting the panes of the prototype can be well approximated by simply
supported conditions. Due to the fluid-structure coupling effect, the eigenfre-
quencies shifted mode by mode. The first natural frequency of the coupled
system resulted larger than the first natural frequency of the structure due
to the interaction between the fluid and the flexible structure. The sound
pressure distribution has been calculated in the interior domain. The link
between the kinetic energy of the vibrating structure and the acoustic emis-
sion properties of the structural modes will be discussed in Part 2 of this
paper.

Acknowledgments

The content of this paper is part of a research project funded by CIRA (The

Italian Aerospace Research Centre) and the Campania Region, Italy. The authors

would like to acknowledge the experimental support of the Centre for Acoustics and

Vibration (CAV) of Penn State University, Pennsylvania, USA.



190 I. Dimino et al.

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Projekt profilu wibroakustycznego aktywnego okna lotniczego.

Część 1: modelowanie dynamiczne i weryfikacja doświadczalna

Streszczenie

Ostatnio przeprowadzone badania pokazały, że skuteczność aktywnychmetod re-
dukcji hałasu stosowanych w oknach montowanych w samolotach można podnieść
w zakresie niskich częstości.Wobec szczególnie korzystnych warunków transmisji ze-
wnętrznego hałasu w samolocie i jego wysokiego poziomu, odpowiedni projekt okna
lotniczegomoże znacząco przyczynić się do ograniczenia hałasuw kabinie, przymini-
malnej ingerencji w masę i osiągi samolotu. Prezentowany artykuł stanowi pierwszą
część podwójnej publikacji na omawiany temat. W tej części opisano projekt profi-
lu wibroakustycznego prototypu trójszybowego okna lotniczego. Bardzo szczegółowo
przedstawiono numeryczne i doświadczalne aspekty badańmających na celu określe-
nie dynamiki układu oraz wydolności aktywnego sterowania. Stosując adaptacyjny,
płaski imimośrodowyukładprzykładanychsił, przeprowadzonobadania eksperymen-
talne nad skutecznością piezoelektrycznych elementów wykonawczych w tłumieniu
giętychpostaci drgań okna.Dlaweryfikacjimodelu elementów skończonychdokonano
także doświadczalnej analizy modalnej, co pozwoliło na wyznaczenie częstości wła-
snychpojedynczej strukturyorazukładuze sprzężeniempoprzez oddziaływanie z pły-
nem.Wczęścidrugiej oszacowanezostanącharakterystykiradiacji dźwiękuwprototy-
pie okna.W tym celu użyta będzie procedura łączącametodę elementów brzegowych
i skończonych, która umożliwi rozwiązanie sprzężonego, akustyczno-strukturalnego
problemu emisji hałasu w zewnętrznym obszarze akustycznym.

Manuscript received November 19, 2010; accepted for print May 13, 2011