Jtam-A4.dvi


JOURNAL OF THEORETICAL SHORT RESEARCH COMMUNICATION

AND APPLIED MECHANICS

56, 4, pp. 1217-1221, Warsaw 2018
DOI: 10.15632/jtam-pl.56.4.1217

INFLUENCE OF PULSE SHAPER GEOMETRY ON WAVE PULSES

IN SHPB EXPERIMENTS

Robert Panowicz, Jacek Janiszewski, Krzysztof Kochanowski

Military University of Technology, Warsaw, Poland

e-mail: robert.panowicz@wat.edu.pl

Results of numerical analysis of the influence of pulse shaper geometry on wave signals in
the split Hopkinson pressure bar experiment are presented. Five pulse shapers, i.e. square,
ring, cross, star and disk ones have been analysed. It has been assumed that the disc pulse
shaper is the reference geometry to assess the remaining types of pulse shapers. The results
of numerical analyses have shown that pulse shapers with shapes different than disk are hi-
ghly capable ofminimizing high-frequencyPochhammer-Chreeoscillations and, thus, reduce
dispersion of waves propagating in the bar. The greatest damping ability has been observed
while using the ring pulse shaper at both low and high impact velocities of the striker.

Keywords: SHPB, pulse shaping technique, high-strain-rate testing, numerical analysis

1. Introduction

The Split Hopkinson PressureBar (SHPB) technique requires satisfying some fundamental con-
ditions, i.e., one-dimensional wave propagation in bars, no friction between the specimen and
the bars, negligibly low influence of inertia and nearly uniformly specimen deformation at a con-
stant strain rate under dynamically equilibrated stresses (Chen and Song, 2011). The condition
regarding the nearly uniformly specimen deformation under dynamically equilibrated stresses is
satisfied when stresses on external contact surfaces of the specimen are equal.

The waveform of the phenomenon results in the fact that at the initial moment of loading
the sample through the incident bar, the condition regarding the uniform deformation of the
specimen under dynamically equilibrated stresses cannot be satisfied. This condition is satisfied
after some time, depending on the shape of the incident pulse and on the pulse rising time as
well as geometrical parameters of the specimen and its properties (Frantz and Follansbee, 1984;
Follansbee, 1985; Gorham, 1991). Currently, the pulse shaper technique is widely used to shape
the incident pulse. The technique is based on placing a small coaxial disk (pulse shaper) between
the strike and the incident bar. This disk is made of a softmaterial compared to the striker and
bars material, and deforms plastically when the striker hits it.
Frantz and Follansbee (1984) and Follansbee (1985) showed that with an increase in the

shaper thickness, the pulse rise time increases and the amplitude of Pochhammer-Chree high-
-frequency oscillations (Pochhammer, 1876; Chree, 1886) decreases. As a result, the dispersion
is reduced and the dynamic equilibrium in the specimen is achieved much faster.

In most cases, during experimental tests, different thickness and diameter of shapers made
of copper were used to increase the rise time of the incident pulse to reduce dispersion as well
as to achieve the state of dynamic equilibrium faster, see e.g. (Chen et al., 2003; Naghdabadi et
al., 2012).
In SHPB, thin disks are used for wave shapers. This is due to, among others, the fact that

it is easy to produce themwith the use of machiningmethods or by punching them frommetal
sheets. For this reason, elements with more complex geometry, such as rings, crosses, stars, are



1218 R. Panowicz et al.

not used. Hence, the idea of examining the influence of various shapes of pulse shapers on wave
pulses registered in SHPB experiments.

The article presents results of numerical analyses for 5 types of geometry of the pulse shapers
presented in Fig. 1.

Fig. 1. Geometry of the analyzed pulse shapers

2. Numerical modelling

Themodel contains all main components of the arrangement: a pulse shaper, slide bearings and
a barrel. In simulation, dimensions of all elements of SHPB are the same as in the experiments
(Panowicz et al., 2017).
The Johnson-Cook constitutive model with the Gruneisen hydrodynamic equation of state

has been used to describe the behavior of the copper shaper and a titanium specimen (Hallquist,
2006).TheTi6Al4Vspecimen(3.7mmlength, 4mmdiameter) andcopperpulse shapermaterials
constants have been taken from literature (Grazka and Janiszewski, 2012; Ozel andSima, 2010).

The authors used the Finite Element Method with a central difference time integration
scheme implemented in explicit LS-Dyna to carry out numerical simulations (Hallquist, 2006).
In order to assess the correctness of the numerical model, validation with experimental

tests for two striker impact velocities (V =15.3m/s and 11.8m/s) and two shaper thicknesses
(d=0.101 and 0.201mm) has been carried out to obtain high compliance.

Fig. 2. Comparison of incident wave profiles obtained from numerical (FEM) and experimental (Exp.)
analyses, in which shapers with different thicknesses dwere used; the striker hits the bar with velocity V

3. Results and discussion

Numerical analysis of the geometry influence of the pulse shaper with thickness of 0.1mm has
been carried out for frequently used striker impact velocities, i.e. 10 and 15m/s. The results are
presented in the form of incident and reflect waves pulses shown in Figs. 3 and 4, respectively.

Based on the obtained results, the influence of the pulse shapers geometry on waves pulses
profiles has been confirmed, however, it is little, especially in the test with velocity of 10m/s
(Figs. 3a,b and 4a,b). This effect is also manifested in the course of both the rising and falling
time of wave profiles. In relation to the standard geometry of the pulse shaper – the disk
(geometry A, Fig. 1), the profiles of the rising and falling time of the incident wave, for the
remaining types of pulse shapers, have a characteristic inflection occurring at about 2/3 of the
wave amplitude. The rise time of the wave profile to the point of inflection is shorter in relation



Short Research Communication – Influence of pulse shaper geometry... 1219

Fig. 3. Incident pulses for different striker velocity: (a), (b) V =10m/s, (c), (d) V =15m/s,
(a) and (c) all signals, (b) and (d) zoom

Fig. 4. Reflected pulses for different striker velocity: (a), (b) V =10m/s, (c), (d) V =15m/s,
(a) and (c) all signals, (b) and (d) zoom

to the rise time when the classical shaper is used (geometry A, Fig. 1). This is due to a faster
process of deformation and work hardening of the pulse shapers.

Small differences can also be observed in the area of the occurrence of Pochhammer-Chree
high-frequency oscillations. The highest oscillation amplitude for the striker velocity of 10m/s



1220 R. Panowicz et al.

was found for the square geometry, and the smallest for the ring geometry. In turn, for the striker
impact velocity equal to 15m/s, the largest oscillation amplitude occurs in the case when the
pulse shaper of the disk type is used, and the smallest for the ring type. Therefore, it can be
concluded that the pulse shaper with ring (Fig. 1c) geometry has the highest ability to suppress
high-frequency components of the pulses and, thus, tominimize dispersion of waves propagating
in the SHPB bar.

It should be noted that the effect of the pulse shaper geometry is revealed with an increase
of the striker impact velocity. At the striker velocity equal to 15m/s, the high damping ability is
demonstrated by pulse shapers with geometry different than the disk (Fig. 1a). It follows that,
especially for high striker velocities, the use of a classical pulse shaper with disk geometry is
not appropriate. It is also observed in the reflected wave profile (Fig. 4c,d) on which the largest
oscillations amplitudes are found for the disk pulse shaper (geometry A). Too large oscillation
amplitudes visible on the wave profile delay the attainment of the specimen dynamic stress
equilibrium state and, thus, make it impossible to meet the basic methodological requirement
of the SHPB technique.

4. Conclusion

A method frequently used in the SHPB technique for forming an incident wave propagating in
the inputbar is theuse of apulse shaperwithdisk geometry.Thenumerical analysis presented in
thearticle shows, however, that it is advantageous tousepulse shaperswith shapesdifferent than
disks. It has been found that they have a high ability tominimize high-frequency Pochhammer-
-Chree oscillations and, thus, reduce dispersion of waves propagating in the bar. For example, a
ring pulse shaper has a greater ability to suppress oscillations than a disk pulse shaper at both
low andhigh striker impact velocities. The ringpulse shaper also allows reaching the equilibrium
stress state in the test specimen faster. This feature is really desirable, especially while testing
high-strength materials with low plastic properties.

Acknowledgements

The support of Military University of Technology grants PBS 23-937 and 23-941 is gratefully ack-

nowledged.

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Manuscript received March 22, 2018; accepted for print May 9, 2018