Abstract:
Dielectric elastomer actuators (DEAs) are widely used in soft robotics as they are flexible,
light weight, resembles natural muscle, induce large strain, have high energy density and
quick response time. The DEA is a capacitive structure consists of a pre-stretched elastomeric
film sandwiched between two compliant electrodes. On applying voltage, compressive
stresses are developed due to the charge accumulation at top and bottom electrode and induce
deformation in sandwiched elastomeric film. The deformation is converted into desired
actuation using varying actuator configurations such as beam bend, diaphragm, roll actuator,
bow-tie etc. Fundamentally, the actuation performance of DEA is governed by the induced
Maxwell stress (σ = 1/2 εoεEf
2) and stiffness of the elastomeric film. A stiffer material has
lower deformation at a given σ and thus adversely affects the actuation capacity of DEA.
Consequently, dielectric constant (ε) and elastic modulus (Y) are the two material parameters
which provide a handle to tailor the response of DEA under applied electric field Ef. The key
issues here are the low dielectric constant of existing soft elastomeric material, poor tearing
strength and resistance to crack propagation. Generating complex actuations with out of plane
deformation is also required for many engineering applications. This work explores the use of
nano- and continuous fiber reinforced polydimethylsiloxane (PDMS) composites as an
elastomeric layer in soft actuators using multitude of experimental and simulation tools. The
choice of these materials is motivated by one of the most amazing creation of nature, the
human skin. It has high tearing resistance and fracture toughness and can undergo large
deformation without snapping. These properties are primarily attribted to the composition of
skin where anisotropic fibers (collagen) are embedded in soft isotropic hyperelastic matrix
(elastin).
To achieve the objectives, experimental investigations are first carried out to quantify the
effect of carbon nanotubes (CNTs) addition on the actuation performance of PDMS based
soft dielectric elastomer actuator (DEA). Comparative analysis of experimental results shows
that incorporation of optimum CNT concentration (0.05 wt%) significantly enhances the tip
displacement (two times) and efficiency (three times) of pure PDMS based DEA. Increasing
the CNT concentration beyond optimum level degrades the tip displacement and efficiency of
bend actuator. It is shown that at optimum CNT concentration, the induced Maxwell stress
compensates for the increase in stiffness of DEA. Even though use of CNT reinforced PDMS augments the actuation performance, out of plane
deformation is not achieved in fabricated DEA. This is due to the isotropic nature of
CNT/PDMS composites caused by the random orientation of CNTs in PDMS matrix. To
exploit the coupling exists in fiber reinforced composites in DEA, PDMS matrix is infiltrated
by continuous glass fibers (GF). A detailed electromechanical analysis using FE simulations
is performed to optimize the fiber orientation and spacing for maximum out of plane
actuation. It is observed that 45 º fiber orientations provide maximum twist of 8º. After
optimizing the composition of DEA, finite element (FE) simulations are performed to
investigate the effect of fiber-induced anisotropy on the notch behavior in GF/PDMS
composites by modelling them as anisotropic hyperelastic skin type materials. The modified
anisotropic (MA) model is used to define the constitutive behavior in FE simulations through
Abaqus user defined material model UMAT. A parametric study is carried out to examine the
effect of fiber orientation, notch root radius and sample geometry on the stress field ahead of
the notch tip. It is shown that fibre orientation significantly influences the stress state and Jintegral
at the notch.It has been proposed that the response of soft tissues and skin type materials critically
depends on the orientation and re-orientation of reinforcing fiber. Here, we quantify the effect
of fiber orientation on the mechanical and fracture properties of anisotropic hyperelastic glass
fiber (GF)/polydimethylsiloxane (PDMS) composites through a unified experimental and
computational analysis. Experimental results show that the tensile strength and fracture
toughness of skin type materials depends on the initial orientation of fiber families and is
maximum for 0-90 fiber orientation. The re-orientation of fibers under tensile loading is
experimentally demonstrated. The experimental findings are well complimented by the finite
element (FE) simulations performed using bilinear strain stiffening fiber and matrix (BLFM)
material model for soft tissues. The material model parameters are obtained by fitting the
experimental data for a meaningful comparison. It is observed that fiber rotation along the
loading direction indeed enhances the resistance to crack growth in skin type materials. The
size of process zone (RC) ahead of the crack tip and relative contribution of anisotropic
energy is characterized using J integral and average strain energy density (ASED) criteria.
The RC and anisotropic energy contribution (ϕaniso-avg/ ϕavg) depends on the fiber orientation
with higher values for 0-90 fiber orientation. The larger process zone enhances the fracture
toughness for 0-90 orientation in comparison to other orientations. Moreover, RC and ϕanisoavg/
ϕavg are found to be independent of initial crack length and therefore, they can be
considered as material parameters for a given fiber orientation. It is envisaged that the findings of the present investigation will be a significant step in designing artificial skin type
materials for soft actuator, gripper and bio-medical applications with enhanced toughness and
tearing strength.