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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 48, 2016 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Eddy de Rademaeker, Peter Schmelzer
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-39-6; ISSN 2283-9216 

Analysis of the Resistance of Structural Components to 
Explosive Loading by Shock-Tube Tests and SDOF Models 

Alexander Stolz, Oliver Millon, Arno Klomfass 
Fraunhofer Institute for High-Speed Dynamics, Eckerstraße 4, 79104 Freiburg, Germany  
stolz@emi.fraunhofer.de 

The analysis of the resistance of structural components to explosive loading conditions is important for the 
design and assessment of buildings which are potentially exposed to explosions. Explosive loading conditions 
may arise from sabotage, terroristic attacks or accidental explosions and pose a significant hazard. The 
characteristics of explosive loading differ entirely from those of ordinary static or dynamic loading to which 
structures are regularly exposed. Reliable methods for the analysis of explosively loaded structures are thus 
required to design safe buildings and reliably assess existing buildings and thereby minimize the 
consequences of explosions. Experimental testing is a mandatory step towards a reliable analysis of 
explosively loaded structures and provides validation data for further simulation-based analysis. 
Shock-tube testing offers several advantages over range testing of explosively loaded structural components. 
This paper describes the shock-tube facility Blast-STAR of the Fraunhofer EMI, which is capable of replicating 
detonations of high explosives and gas explosions. Besides the presentation of the adjustable range of blast 
parameters and the installed diagnostic equipment, it is explained how shock-tube tests are used for the 
derivation of dynamic resistance parameters of building components. These resistance parameters are used 
in single-degree-of-freedom (SDOF) models, which permit an assessment of the structural response of 
components and entire buildings under various explosive loadings conditions. 

1. Introduction 

The knowledge of the behaviour of building structures exposed to explosive loading conditions is essential for 
the proper design of a new structure or the assessment of an existing structure which may be exposed to such 
loadings. Explosive loading is characterized by high overpressures, which act in a short duration. They can 
cause enormous damage, particularly to brittle materials like glass, masonry and concrete, which show a high 
sensitivity to such loading conditions. Depending on the degree of damage of a structural component and its 
function in the overall construction, a partial or complete failure of a building (progressive collapse) can occur 
as a result of a local damage. The correct prediction of the structural resistance and the appropriate design of 
components thus is the main purpose of the research in the field of protective structures. 
The most extreme loading conditions with respect to the exerted overpressure are typically caused by 
detonations of high explosives such as C4, TNT or other similar substances often used in sabotage or 
terroristic attacks.  Accidents with explosive substances used in the chemical industry can also cause 
significant blast loadings, particularly as often very large amounts of these substances are involved. In the 
public media large accidental explosions in industrial facilities are consistently reported as they often cause 
lots of victims and destructions not only on the site but also in surrounding areas. They can be regarded and 
must be treated as a significant hazard. Appropriate testing methods are thus not only needed for detonations 
of high explosives but also for gas or dust explosions and other explosion scenarios that might occur in 
industrial facilities. Blast waves caused by gas or dust explosions differ from those of TNT or other high 
explosives as they generate smaller overpressures and larger impulses in the near field. The experimental 
simulation of a large scale gas or dust explosions with high explosives would therefore require large amounts 
of explosives (often tons) and large distances (several hundred meters) to the structure under test. Such tests 
are in general prohibitive. An alternative approach for testing the blast resistance of structural components is 
the usage of a shock-tube, where the blast wave is generated by compressed gas. In a modern shock-tube 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1648026

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Stolz A., Millon O., Klomfass A., 2016, A large blast simulator for the experimental investigation  of explosively 
loaded building components, Chemical Engineering Transactions, 48, 151-156  DOI:10.3303/CET1648026  

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the blast wave parameters (peak overpressure and overpressure-impulse) can be adjusted in a certain range 
to simulate various explosive sources and distances. In this paper we give a brief introduction to the shock-
tube facility BLAST-STAR which was designed and is operated by Fraunhofer EMI. Furthermore we explain 
the process how shock-tube tests are used to develop resistance parameters for SDOF models. 

2. Blast parameters and existing standards for blast testing 

A blast wave generated by an explosion takes on a spherical or hemispherical shape at some distance from 
the explosion source. The loading of an object by such a wave can be approximated reasonably well by the 
overpressure-time curve shown in figure 1, described by the Friedlander equation (1). The initial shock wave 
causes the peak overpressure pmax after which the overpressure smoothly decays. Subsequently a suction 
phase with negative overpressure is formed until the overpressure finally decays. Beside the peak 
overpressure this model blast wave is characterized by the positive overpressure impulse i+, which is the 
hatched area below the positive overpressure in figure 1. The duration of the positive phase is specified by the 
parameter t+. This simplified model is applicable to both detonations of high explosives and gas or dust 
explosions. The values of the aforementioned blast parameters depend on the energy of the explosion source 
and the distance to the loaded object. Gas or dust explosions may generate relatively low overpressures in the 
far field but can exhibit long positive (and negative) durations up to some seconds resulting in large 
overpressure impulses. Detonations of high explosives tend to generate higher peak pressures, particularly in 
the near field, but have shorter durations in the order of tens of milliseconds. These differences must be taken 
into account in the investigation of explosively loaded structures. Accepted standards for testing methods and 
resistance classifications are available for security glazing, windows and further components exposed to 
detonations of high explosives (ISO16934, EN13541 and EN13123-1). Standards for other explosive sources 
such as gas or dust explosions are presently not defined. Table 1 summarizes the blast parameters required 
for a certain classification of security windows.  

 

= ∙ 1 − + − ∙ +                      (1) 
Figure 1: Load-time function of a blast load according to (EN13123-1). 

Table 1: Classification of blast resistance of windows, doors, shutters and security glazing (EN13123-1). 

Blast load class Loading pressure [kPa] Pos. specific impulse [Pa s] Positive duration [ms] 
EPR1   50 – 100    370 – 900 > 20 
EPR2 100 – 150    900 – 1,500 > 20 
EPR3 150 – 200 1,500 – 2,200 > 20 
EPR4 200 – 250 2,200 – 3,200 > 20 

3. Shock-tube facility Blast-STAR 

Shock-tube facilities have been used to classify and scientifically investigate the response and the resistance 
of structural components against blast loading for many decades (Kranzer, 2009; Stolz, 2013). Shock-tubes 
offer several advantages in comparison to range tests: the handling of high explosives is avoided, testing can 
be performed under laboratory conditions, a high reproducibility of the generated blast waves is achieved and 
the generated blast waves are nearly perfectly planar in a well-designed shock tube. However, the size of the 
test object is limited by the cross section of the tube and the attainable blast parameters (mainly the positive 
durations) are typically within a small range, as they are coupled to the dimensions of the shock tube.  
The shock-tube Blast-STAR (figure 2) is a gas driven shock-tube with a two-chamber design, consisting of a 
high pressure filling chamber and a low pressure expansion chamber. Figure 3 illustrates the conceptual 
design in a longitudinal view. Further details are given by (Klomfass, 2012). 

152



 

Figure 2: View on expansion chamber of the Blast-STAR facility with the end-section wall (grey) for the 
integration of test samples. 

 

Figure 3: Schematic visualization of the longitudinal profile of the shock-tube Blast-STAR. 

The end-wall section of the expansion chamber has a quadratic cross-section with size 3 m x 3 m. Modular 
rigs permit the fixation of test objects of various sizes up to about the full cross section. The filling pressure 
and the volume of the high pressure chamber are the mechanically adjustable parameters of the shock-tube, 
which control the resulting blast parameters on the test sample fixed in the end-wall section. For the simulation 
of blast waves generated by gas or dust explosions a long high pressure filling chamber with variable length 
up to 22 m is attached to the shock tube. This filling chamber is operated with comparatively low pressures. A 
short high pressure filling chamber with a variable length of up to 2 m and high filling pressures is used to 
generate blast waves, which replicate the far field of high explosive detonations. Figure 4 summarizes the 
range of blast parameters which can be generated in the Blast-STAR in an overpressure-impulse diagram. 
The diagram roughly indicates the different loading conditions arising from gas or dust explosions and 
detonations of high explosives and the separation into far-field and near-field loading conditions. The 
standardized classification levels for security windows are marked with EPR1 to EPR4 for shock-tube tests 
and EXR1 to EXR5 for range tests.  
Figure 5 shows exemplary test data. On the left side a blast wave replicating a high explosive detonation is 
shown and on the right side a blast wave representing a gas or dust explosion. Each graph includes the time 
histories of overpressure and overpressure-impulse. The overpressures were recorded on a planar solid test 
object (the closed end-wall) by two independent pressure gauges mounted at different positions R1 and R2. 
The overpressure impulses are obtained by numerical integration of the recorded overpressure transients. The 
fact that both gauges nearly show identical curves indicates that the incident waves are practically planar and 
the loading is uniform. In both cases the loading replicates the typical blast wave profile, although the low-
pressure, long-duration case (left diagram) is marked by superposed low frequency oscillations. The temporal 
rise of the overpressure-impulse is however not significantly affected by these oscillations and takes on a 
rather smooth shape. 

© Fraunhofer EMI 

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The standard diagnostic instrumentation of the shock tube facility includes high-speed video and laser-optical 
deflection measurements. High-speed video recordings provide the essential information about the global 
motion and possibly the failure development. Laser-optical measurements are applied to determine local 
deflections on points of interest. Especially these measurements are important for the determination of 
dynamic resistance parameters. 
 

 

 

Figure 4: Performance of the shock-tube facility “BLAST-STAR” with respect to loading scenarios defined by 
pressure and impulse. 

  

Figure 5: Example of overpressure-time histories generated in the shock tube; left: example of a blast wave 
representing a gas or dust explosion, right: example of a blast wave from a high explosive detonation. 

4. Development of resistance functions for structural components 

The analysis of building safety against explosive loading conditions typically requires the evaluation of a broad 
range of loading conditions (different explosive energies and distances). Such an analysis requires a reliable 
and efficient computational model, which predicts the structural damage of a component for the considered 

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range of loading conditions. A single degree of freedom model (SDOF) gives a simplified but useful 
description of the dynamic behaviour of a considered structure. It considers the transient deflection of a single 
characteristic point of the structure under the effects of the external loading, the effective structural mass, the 
elastic-plastic properties and the failure limits of the structure. Equation (2) gives the general equation of a 
SDOF model according to the illustration in figure 6. The time dependent deflection, the velocity and the 
acceleration of the reference point are expressed by x and its first and second derivatives, respectively. The 
external force is considered as the product of the loaded surface A of the structural component and the 
overpressure-time history p(t) of the blast wave. The elastic plastic properties and the failure limits are 
expressed by the resistance function R(x) which relates force to deflection. It depends on the design of the 
component, its size and material properties. A critical review of SDOF models showed, that the accuracy of 
SDOF models strongly depends on the chosen resistance function. Equation (3) gives a resistance function 
suggested by Stolz (Stolz, 2013). In this definition the area specific stiffness c0 of the component and the 
reference loading pressure pref are the free parameters of the function. The viscous damping term D is 
typically neglected for explosive loading conditions, as the maximum deflection (and thus the damage) occurs 
in the early stage of the response (Biggs, 1964). 
 

 

Figure 6: Definitions of the single degree of freedom (SDOF) model with regard to equation (2). 

∙ + + = ∙  (2) 
 

( ) 









⋅
⋅⋅

⋅
⋅

⋅=
refp

xcp
AxR

2
arctan

2 00 π
π

 (3) 

 
In shock-tube experiments the transient loading and the transient deflection of the structural component are 
recorded. The reference point used for the definition of the deflection is usually located in the centre of the 
element (point of expected maximal deflection) on its outer surface (opposite to the loaded surface). The 
modelled deflection as solution of equation (3) is compared with the measured deflection of the shock-tube 
experiment and an optimization procedure is applied to calibrate the free parameters of the resistance function 
(Fischer, 2009). For a reliable identification of the resistance function and the failure limits a certain number of 
experiments have to be carried out with different loading conditions. The number of experiments is related to 
the number of free parameters in the resistance function. The free parameters typically represent the stiffness, 
the elastic limit, the maximum response pressure and the critical deflection where the structure fails. Shock-
tube tests can provide the majority of the data required for the derivation of an SDOF model. Additional data 
can be gained from range tests if possible and necessary or from high-fidelity computational finite-element 
models, which in turn can be validated by the shock tube data.  
For a simplistic waveform as the one in figure 1 it is sufficient to characterize a loading condition in terms of 
the peak overpressure and the overpressure-impulse. For such cases the calibrated SDOF model can be 
used to derive iso-damage curves in p-i diagrams (figure 7). Iso-damage curves are obtained as the set of all 
possible combinations of peak overpressure and overpressure impulse which lead to the same deflection 
amplitude i.e. to the same degree of damage. The iso-damage curve permits a simple and direct assessment 
of the damage in terms of the peak overpressure and the overpressure impulse. Complex waveforms can 
occur when the loaded object is not in direct line of sight to the explosions centre and the blast wave interacts 
with other objects on its propagation path. In such cases the SDOF model must be solved by numerical 
integration using the actual overpressure transient independently for each loading condition. SDOF models 
and iso-damage curves are common practice for the prediction of structural response due to blast loading, 
(Morison, 2006). Until today, wide applications can be found for the prediction of the structural resistance of 

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different materials and structural members, like masonry walls (Mayrhofer, 2002), reinforced concrete columns 
(Shi, 2008) or glazing facades (Smith, 2001). Thus, all structural components of a building for all essential 
construction materials can be analysed with the described method for a prognosis of the resistance of 
complete building structures. 
 

 

Figure 7: Effects of different blast loading intensities in a SDOF model (left) and an example of a pressure 
impulse diagram with an integrated iso-damage curve for a specific structural component (right). 

5. Conclusions 

A modern shock-tube facility can generate a wide range of relevant blast loading conditions. It can be used for 
testing and certification of components in accordance with existing norms and also for engineering 
investigations into new concepts of protection and retro-fitting measures.  Shock-tube data can be used to 
calibrate SDOF models, which permit an assessment of the structural safety under a broad range of possible 
loading conditions. This holds for explosive loading from the detonation of high explosives and also for 
loadings from other explosive sources like gas or dust explosions. 

Reference 

Biggs J., 1964, Introduction to Structural Dynamics, McGraw-Hill Book Company, New York, USA. 
European Committee for Standardization, 2012, EN 13541: Glass in building – Security glazing – Testing and 

classification of resistance against explosion pressure. 
European Committee for Standardization, 2001, EN 13124-1: Windows, doors and shutters – Explosion 

resistance – test method – Part 1: Shock tube. 
European Committee for Standardization, 2001, EN 13123-1: Windows, doors and shutters – Explosion 

resistance – Requirements and classification – Part 1: Shock tube. 
Fischer K., Häring I., 2009, SDOF response model parameters from dynamic blast loading experiments. 

Engineering Structures, 31 (8), 1677-1686. 
International Organization for Standardization, 2008, ISO 16934: Glass in building – Explosion-resistant 

security glazing – Test and classification by shock-tube loading. 
Kranzer C., 2009, Test methods for blast loads and classification of explosion-resistant structural elements 

according to DIN EN ISO standards, 13th International Symposium on the Interaction of the Effects of 
Munitions with Structures (ISIEMS), Brühl, Germany. 

Klomfass A., Kranzer, C., Mayrhofer C., Stolz A., 2012, A new large shock tube with square test section for 
the simulation of blast, 22nd Int. Symposium of Military Aspects of Blast and Shock, Bourges, France 

Morison C., 2006, Dynamic response of walls and slabs by single-degree-of-freedom analysis - a critical 
review and revision, International Journal of Impact Engineering, 32 (8), 1214-1247. 

Mayrhofer C., 2002, Reinforced masonry walls under blast loading, International Journal of Mechanical 
Sciences, 44 (6), 1068-1080. 

Shi Y., Hao H., Li Z.-X., 2008, Numerical derivation of pressure-impulse diagrams for prediction of RC column 
damage to blast loads, International Journal of Impact Engineering 35 (11), 1213-1227. 

Smith P., Rose T., Krahe S., 2001, An assessment of blast impulse reduction in city streets with non-structural 
building facades, 10th International Symposium on the Interaction of the Effects of Munitions with 
Structures (ISIEMS), San Diego, USA. 

Stolz A., et al., 2013, Resistance of structures to explosion effects: Review report of testing methods, 
European Commission Joint Research Centre, Ispra, Italy. 

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