Journal of Facade Design and Engineering 3 (2015) 39–47
DOI 10.3233/FDE-150028
IOS Press

39

Full-scale performance testing and
evaluation of unitized curtain walls
E. Ilter, A. Tavil∗ and O.C. Celik
Department of Architecture, Istanbul Technical University, Istanbul, Turkey

Abstract. Unitized curtain wall systems have been widely seen on high-rise buildings’ facades by bringing benefits with
regard to ease of construction, lightness, etc. However, some design and application problems related to structural and
infiltration performance of a facade system might arise during its life cycle, which is difficult for the building to compensate.
This paper presents a comparative analysis of the structural and infiltration performance of the two identically detailed and
produced unitized curtain wall system mock-ups. In order to understand long-term environmental effects on the curtain
wall system, a fatigue process was applied on one system in addition to the standard test procedures, while the standard
test procedure was applied on the other reference specimen. The tests on the two identical specimens were conducted
in accordance with TS EN 13830 and AAMA 501.4 Standards. As a result of air infiltration and wind load resistance tests,
air infiltration and frontal deflection values on the facade surface were obtained. Hence, experimental performance of the
systems was compared and the effect of the fatigue procedure on the facade performance was evaluated.

Keywords: Unitized curtain wall, full-scale test, structural and infiltration performance

1. Introduction

Recent curtain wall applications in the building construction sector show that unitized curtain wall
system becomes more preferable by architects and system manufacturers especially for high-rise build-
ings, owing to the advantages with regard to the ease of construction, lightness, weather tightness,
quality detailing, thermal performance, etc. Unitized systems enable straightforward processing by
means of serial production and pre-assembly of the individual facade units. Most of the system com-
ponents are assembled in a plant under controlled working conditions, promoting quality assembly
and allowing for fabrication lead-time and rapid closure of the building without being affected by
weather conditions (Horowitz, 1991). Right along with the advantages of the unitized curtain walls,
some design and application problems related to the structural and infiltration performances might
arise during their life cycle. Repeated variable wind loads and climatic conditions are the most signif-
icant factors affecting the long-term structural and infiltration performances. Experiences verify that
the criteria such as structural integrity, provision for movement, and weather tightness are of great
importance during their design. Certainly, there are a number of other considerations, most of which
are of less critical importance and some of which vary in importance depending on the location and
type of building (Wong, 2007).

∗Corresponding author: Prof. Dr. Aslihan Tavil, Department of Architecture, Istanbul Technical University, Taskisla, Taksim,
34367 Istanbul, Turkey. Tel.: +90 2931300/Ext. 2356; Fax: +90 212 2514895; E-mail: tavil@itu.edu.tr.

ISSN 2214-302X/15/$35.00 © 2015 – IOS Press and the authors. All rights reserved
This article is published online with Open Access and distributed under the terms of the Creative Commons Attribution Non-Commercial License.

mailto:tavil@itu.edu.tr


40 E. Ilter et al. / Full-scale performance testing and evaluation

Curtain wall construction has stimulated the development of the most significant test programs.
Programmed testing has become a requirement on curtain wall mock-ups for air-leakage, water
leakage, structural strength, thermal performance and further testing for capabilities such as seismic,
acoustical, dust or snow performances. Full-scale preconstruction curtain wall mock-up testing is today
normally considered a standard practice for buildings where the curtain wall is a custom application
for high-rise buildings, and for buildings where a high confidence level is desired. Curtain wall mock-
up tests comprise a full size representative portion of the proposed exterior wall system along with
the simulated environmental conditions, such as wind, temperature extremes, and seismic exposure.
Standard test methods, however, may not be sufficient to specify all the requirements for a mock-up
test program with regard to some performance assessment. For example, there is no standard test
procedure to assess the long-term performance of curtain wall systems (Sakhnovsky, 1991; Kasket
et al., 1998). Mock-up tests provide an indication of the performance of the curtain wall only at
the time it is brand-new. Workmanship quality of the mock-up is usually very good because every
element is constructed under a thorough inspection that is not expected during construction of the
curtain wall on the building. Whether through aging or because of sealant related problems, most
curtain wall systems let some water enter, which causes decrease on the structural and infiltration
performance (Sakhnovsky, 1991).
This paper presents the test procedures for evaluating long-term structural and weather (air, water)

infiltration performances of unitized curtain wall systems. In order to reach this objective, full-scale
mock-up testing of two identical unitized curtain wall panels was carried out. During the testing pro-
cess, one specimen was subjected to fatigue process before conducting the standard test procedures
while only the standard test procedures were applied on the other identical specimen. Experimental
performances of the two specimens were compared.

2. Experimental process

As is customary, for approval of the facade for a specific project, a series of various performance
tests must be carried out before starting the production and the site erection. All these perfor-
mance tests, that can help to increase the probability of trouble-free performance of the wall on
the completed building, are conducted on a 1:1 scale model of the facade, having exactly the same
characteristics of the real final product (Galli, 2011). Performance testing of the specimen, both prior
to construction and during construction, is a well-established and respected element of quality assur-
ance. Testing representative segments of curtain wall, or windows, for example, comprises three basic
tests such as air infiltration, water penetration, and structural loading. When the systems succeed
the performance tests, the system can be accepted to fulfil the requirements of water penetration,
strength, air infiltration, seismic performance, etc. that ensure the quality.

2.1. Mock-up design

The experimental study was carried out on a large test rig located at the Facade Testing Institute,
Istanbul (Fig. 1a and b). The test specimens shown in Fig. 1, consist of two identically detailed unitized
curtain wall systems with 2,40m width, 4,45m height dimensions, and are comprised of aluminum
framing members and insulating glass units. 4mm clear float and 8mm tempered glass double-glazing
units with structural silicone spacer were used for the transparent parts. Total surface area of each



E. Ilter et al. / Full-scale performance testing and evaluation 41

a

c

b

Fig. 1. Mock-up Design (1:1 Scale). a: Panel mounted in test rig (interior face). b: Exterior face of the panel. c: Specimen
geometry, applied static pressures and measurement points (M1, M2, M3 and cross-sections A-B).



42 E. Ilter et al. / Full-scale performance testing and evaluation

specimen is 10,68 m2, see Fig. 1c. Specimen P is the reference specimen and Specimen FP is the one
that the fatigue procedure was applied on to investigate the long-term environmental effects (Ilter
et al., 2014). The main difference between the two specimens is that the water penetration under
dynamic pressure and fatigue procedure tests were additionally conducted on Specimen FP besides
the standard test procedure.

2.2. Performance tests

The commonly used performance tests, which are static air infiltration, water penetration under
static and dynamic pressures, wind resistance for design load and safety requirement, seismic resis-
tance and fatigue process are explained below with respect to the related norms. In addition to them,
acoustic performance, impact resistance of glass, thermal cycling tests are also conducted on curtain
wall systems in Turkey but these tests are out of the scope of this study.
Air infiltration test under static pressure: Using the chamber developed for the mock-up testing, the

rate of air leakage through the specimens is determined at the project specified pressure differential
induced across the assemblies. The air leakage rates determined are compared against the acceptable
rates identified for the project. Prior to testing, the specimens’ exterior faces are covered with
a watertight steel plate. Subsequently, the specimens are subjected to the positive and negative
pressure of 660Pa (more than 10% of normal pressure value) by holding for 3 seconds, and then
released. Air infiltration is tested up to a test pressure of 600Pa by increasing with steps of 50, 100,
150, 200, 250, 300, 450, 600Pa (TS EN 12153, 2004).
Water penetration test under static pressure: A pressure differential is applied across the curtain

wall assembly, while simultaneously applying water spray onto the exterior surfaces. The testing
is performed to show the water penetration resistance of the curtain wall systems and transitions
between the system components. Static water penetration tests are conducted at a flow rate of 3.4
lt/(m²·min) at up to a test pressure of 600Pa according to TS EN 12155 standard. Specimens are
subjected to 660Pa positive pressures and held for 3 seconds, then released. Afterwards, considered
pressures of 50, 100, 150, 200, 250, 300, 450, 600Pa are applied to the specimens and held for
300 seconds per each pressure step (AAMA 501.1, 2005). Negative and positive wind pressures are
applied on the exterior face of the panel during the testing.
Water penetration test under dynamic pressure: Water penetration testing consists of utilizing a

portable wind generator and installing a spray rack system at the exterior of the specimen. A ROTAX
Airplane engine equipped with 1850mm diameter propeller producing 1350Pa (165km/h) wind veloc-
ity was used. The engine and prop assembly are mounted into a steel frame that incorporates a sheet
metal shroud and lifting fixture. Dynamic wind stream has been generated along with the water spray
perpendicular to the outdoor face of the specimen for a period of fifteen minutes, right along with
the water applied at the rate of 3.4 lt/(m²·min) on the face completely and continuously, see Fig. 2
(TS EN 12179, 2000).
Wind resistance test based on design load and safety requirements: The test is conducted through

Turkish Standards; TS EN 13116 describes performance requirements due to design load while TS EN
12179 specifies the method to determine the performance of curtain wall components under positive
and negative static air pressure regarding the safety issues. Positive test pressure is conducted before
the negative test pressure. Prior to testing, three measurement points were determined. M1 and M3
were at the level of structural supports on the middle axis while M2 was in the middle of M1 and



E. Ilter et al. / Full-scale performance testing and evaluation 43

Fig. 2. Dynamic water penetration test for the fatigue process.

M3 (Fig. 1c). The specimens are subjected to 1200Pa (50% of the design load) positive and negative
pressures, held for three seconds, and then released. Afterwards, pressures with increasing steps of
0, 600, 1200, 1800, 2400Pa are applied to the specimens and held for 10 seconds for each pressure
step. Lateral deflections were measured at positive and negative wind pressures up to ± 2400Pa.
Frontal deflections of the specimens were determined according to TS EN 13116. At the beginning
of the test three pulses of air pressure (50% of design wind load or 500Pa whichever is greater) is
applied. Then, the sample is subjected to 25%, 50%, 75%, and 100% of design wind load. The test
specimens are exposed to positive and negative wind loads by applying 150% of the design load
(PE= ± 3600 Pa) (AAMA, 2009, TS EN 12155, 2005).
Seismic resistance test: This test provides performance evaluation of curtain wall systems when

subjected to the specified horizontal displacements representing an earthquake. Furthermore, it is
intended to analyze the seismic safety of architectural glass components within a curtain wall. The
static test method is conducted through AAMA 501.4, which is applied on the same test chamber with
air infiltration, water-tightness, and wind resistance. Testing is done by means of a bottom structural
support unit for producing horizontal movements and completed at three full cycles where a cycle is
defined as a full displacement in one direction, back to the originating point, full displacement in the
opposite direction and back to the originating point. Each cycle is completed in almost 2 minutes.
The design displacement is taken as 34mm (0.010 × the greater of the adjacent story height), and
measured at the movable structural support unit. After the tests, all areas were inspected in detail,



44 E. Ilter et al. / Full-scale performance testing and evaluation

and no disengagement, metal distortion, sealant or glazing failures were observed (TS EN 12155,
2005).
Fatigue procedure: Uniformly distributed suction loads were applied on the outer surface of the

specimen. ETAG 17 comprises a static wind suction test, which is applied to specimens for the fatigue
procedure. The test was performed in successive steps of 500Pa to 3500Pa (lower than the extreme
load pressure: 3600Pa) with a return to zero at each level, and loads were held for 10 seconds per
each pressure step. The results of the fatigue test are given in Fig. 3.

Fig. 3. Fatigue procedure applied on the Specimen FP (ETAG 17).

For the two specimens, test sequence was determined according to TS EN 13830 and AAMA
501.4. The tests were conducted at three phases during nine months with 90 days intervals between
each testing sequence. In total, six test sequences were conducted on the reference Specimen P
and fatigued Specimen FP. The categories of the tests for P are air infiltration, water penetration
under static pressure, wind resistance, seismic resistance as the standard tests. Water penetration
under dynamic pressure tests and fatigue procedure were the additional tests for FP along with the
standard tests. Although the design load value (PD, ±2400 Pa) was defined by the manufacturer,
normal pressure value (PN; %25 of PD, ±600 Pa) and extreme wind (safety) load (PE; %150 of PD,
±3600 Pa) were calculated according to TS EN 12154 and TS EN 12179. The applied test sequence in
order is given in Table 2.

3. Test results and performance evaluation

This experimental work revealed that the measured maximum air infiltration values were within the
acceptable limits (i.e. 1.50 m³/m²·h) for the reference Specimen P on which the fatigue process was
not applied during all three testing phases. However, the air infiltration values highly increased and
reached 2.31 m³/m²·h for positive pressure and 2.04 m³/m²·h for negative pressure after the fatigue
process was conducted in FP. The fatigue process was applied till the last testing phase. Water leakage
was not observed in P at the end of the three testing phases, while water leakage was observed in FP
after the second and third testing phases showing that the fatigue process caused loss of performance
on the curtain wall system as expected, see Table 1. The water was observed at the intersection of
the four panel pieces (A and C) on the vertical axis of the curtain wall panel, indicated as W1 (Fig. 1c).



E. Ilter et al. / Full-scale performance testing and evaluation 45

Table 1
Infiltration and structural test results

Specimen Time Load Air Air Water Frontal deflection Frontal deflection
label (days) type infiltration infiltration leakage value at 2400Pa (mm) limit value (mm)

value at 600Pa limit value
(m³/m²·h) (m³/m²·h)

P1 0 positive 0.63 1.50 No leakage 10.34 15.00
negative 0.52 1.50 No leakage 11.27 15.00

P2 90 positive 0.73 1.50 No leakage 10.97 15.00
negative 0.53 1.50 No leakage 12.00 15.00

P3 180 positive 1.07 1.50 No leakage 10.09 15.00
negative 0.80 1.50 No leakage 16.60 15.00

FP1 0 positive 0.89 1.50 No leakage 10.84 15.00
negative 1.20 1.50 No leakage 8.77 15.00

FP2 90 positive 0.92 1.50 at W1∗ 12.06 15.00
negative 1.24 1.50 at W1∗ 12.62 15.00

FP3 180 positive 2.31 1.50 at W1∗ 13.47 15.00
negative 2.04 1.50 at W1∗ 17.78 15.00

∗W1 is the intersection point of A and C units on vertical middle axis of the panel (Fig. 1c).
Note: Highlighted cells show the results that exceeded the limits.

Table 2
Results and performance classification according to the test categories and sequence

Test Test name Test standard Peak test Result Performance classification
Number pressure (Pa)

P1 P2 P3 FP1 FP2 FP3
1 1Air infiltration TS EN 12153 600 Pass A4 A4 A4 A4 A4 A2
2 2Water penetration (static) TS EN 12155 600 Pass R7 R7 R7 R7 R5 R5
3 3Water penetration (dynamic) AAMA 501.1 600 See note4 No water penetration at W1∗

4 Wind resistance (design load) TS EN 12179 2400 See note5 ∗∗ ∗∗ ∗∗∗ ∗∗ ∗∗ ∗∗∗

5 1Air infiltration TS EN 12153 600 Pass A4 A4 A4 A4 A3 A1
6 2Water penetration (static) TS EN 12155 600 Pass R7 R7 R7 R7 R5 R5
7 Seismic resistance AAMA 501.4 – Pass No deformation
8 1Air infiltration TS EN 12153 600 Pass A4 A4 A4 A4 A3 A1
9 2Water penetration (static) TS EN 12155 600 Pass R7 R7 R7 R7 R5 R5
10 Wind resistance (extreme load) TS EN 12179 3600 Pass No deformation
11 Seismic resistance (static) AAMA 501.4 – Pass No deformation
12 3Fatigue procedure ETAG 17 3500 Pass – – – No deformation
1Classification was performed to TS EN 12152 and CWCT.
2Classification was performed to TS EN 12154 and CWCT.
3Applied only on FP1, FP2, and FP3.
4There is no classification or performance requirement for water penetration (dynamic) testing in AAMA standard.
5P1, P2, FP1, and FP2 successfully passed the wind resistance (design load) test requirements in the classification standard
of wind resistance testing (TS EN 13166). But specimen P3 and FP3 exceeded the limit value (15mm) at the peak pressure.

∗W1 is the intersection point of A and C units on vertical middle axis of the panel (see Fig. 1c).
∗∗Frontal deflection value <15mm.
∗∗∗Frontal deflection value ≥15mm. For air infiltration test, if exceeded the limit value: 1.5 m3/m2 h at 150Pa ⇒ class: A1;

at 300Pa ⇒ A2; at 450Pa ⇒ A3; at 600 Pa ⇒ A4 (TS EN 12152). For water penetration test (static), if exceeded the limit
value: 15mm at 150Pa ⇒ class: R4; at 300Pa ⇒ R5; at 450Pa ⇒ R6; at 600 Pa ⇒ R7 (TS EN 12154).



46 E. Ilter et al. / Full-scale performance testing and evaluation

Frontal lateral deflection values from wind loading increased at each testing phase, however some
values slightly exceeded the limit of 15mm at high negative pressure values while the positive deflec-
tions were within the acceptable limits. Results show that, as expected, the overall stiffness of the
tested panel is higher for positive pressures than negative pressures (Table 1). Test sequence and
infiltration and structural tests results were grouped with regard to the available standards for perfor-
mance classification (Table 2). The experimental results attained are demonstrated by the infiltration
and structural performance criteria, which were numerically obtained with the tests for performance
evaluation.
It is a crucial issue for the facade manufacturer, owner or contractor, and designer to evaluate the

long-term performance of a facade system. Tables 1 and 2, and Fig. 4 show that, at the maximum wind
pressure of 2400Pa, frontal deflections are exceeded by 6.67% and 18.53% for P and FP, respectively.
Air infiltration values for FP are measured as 2.31 m³/m²·h and 2.04 m³/m²·h at the third testing phase.
These values exceeded the acceptable limits by 54% and 36% in positive and negative loading type
respectively while the air infiltration values of P are within the acceptable limits at all testing phases.

Fig. 4. Frontal deflections under wind pressure (2400Pa) and air infiltration values of P and FP.

4. Conclusions

The following results can be drawn from this full-scale experimental work:

• Although the majority of today’s unitized curtain wall systems is technologically improved and per-
forms higher requirements, the test results indicate that the continuous impact of environmental
conditions cause a significant loss in performance (up to 54% due to air infiltration, 18.53% due
to wind pressure) during the curtain wall system’s life time.



E. Ilter et al. / Full-scale performance testing and evaluation 47

• The most critical criterion seemed to be the frontal deflections in P while water leakage limit was
exceeded first in FP in addition to exceedance limits of air infiltration and frontal deflections.

• Considering that the recent test procedures provide an indication of the curtain wall only at the
time when it is brand-new, test procedures which evaluate real life performance of the curtain
wall systems should be developed for more realistic evaluations.

• The process of mock-up testing plays an important role towards understanding the performance of
the curtain wall system regarding the critical issues. However, whole experiment process requires
experience, time, high efforts and cost issues.

Acknowledgments

This experimental research was fully supported by Façade Testing Institute (FTI) and Metal Yapı
A.Ş., Istanbul. This support is gratefully appreciated. However, any opinions, findings, conclusions,
and recommendations presented in this paper are those of the authors and do not necessarily reflect
the views of the sponsors.

References

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ETAG 17 (2006). Standard for Systemized Building Envelopes. Centre for Window and Cladding Technology - CWCT, UK.
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