ROLE OF MATERIAL COMPOSITION IN THE CONSTRUCTION OF VISCOELASTIC MASTER CURVES: SILICA-FILLER NETWORK EFFECTS

ABSTRACT One of the important aspects in the development of new tire compounds is the correlation between the dynamic mechanical properties of the rubber, measured on a laboratory scale, and the actual tire performance. The measuring protocol for dynamic mechanical properties with high precision and good correlation with tire properties is therefore of main concern. To predict wet traction, the viscoelastic behavior of the rubber materials at high frequencies (in the MHz range) need to be known. Viscoelastic master curves derived from time-temperature superposition can be used to describe the properties of the materials over a wide frequency range. The construction of master curves for tread compounds filled with different amounts of silica is discussed. From the vertical shifts as a function of temperature, activation energies are derived that apparently are in the linear response region by fulfilling the Kramers-Kronig relations, and their values correspond to physical phenomena as the underlying principle. Strain sweep viscoelastic measurements, per definition outside the linear region, lead to much higher activation energies. Because the deformation strains employed for these strain sweep measurements are more realistic for wet traction or skidding phenomena, it is concluded that the value of the above measurements in the linear region to predict traction is only limited or a first but still important indication.

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Temperature Dependent Dynamic Mechanical Properties of Hydrogenated Nitrile Butadiene Rubber and the Effect of Peroxide Cross-linkers

e-Polymers ◽

10.1515/epoly.2007.7.1.1536 ◽

2007 ◽

Vol 7 (1) ◽

Cited By ~ 1

Author(s):

Blaž Likozar ◽

Matjaž Krajnc

Keyword(s):

Mechanical Properties ◽

Cyano Group ◽

Viscoelastic Behavior ◽

Dynamic Mechanical Properties ◽

Cross Linking ◽

Butadiene Rubber ◽

Scanning Calorimetry ◽

Dynamic Mechanical ◽

Nitrile Butadiene Rubber ◽

The Cross

AbstractThe viscoelastic behavior of hydrogenated nitrile butadiene rubber (HNBR) was studied over a range of temperatures and shear frequencies. Dynamic mechanical properties were studied and modelled using the generalized Maxwell model and the Williams-Landel-Ferry equation. A fitting algorithm was developed to provide the best agreement between the experimental data and the model results. In addition to dynamic mechanical analysis (DMA), differential scanning calorimetry (DSC) was applied. The HNBR structure was characterized by X-ray diffraction (XRD). The developed model exhibited an excellent agreement with either isothermal or dynamic experiment data, yet only up to the rubbery plateau, after which a structure ordering occurred. This was explained by the cyano group secondary bonding and consequentially the cross-linking between HNBR chains. A molecular modeling simulation was made to confirm the cross-linking. The effect of peroxide cross-linking agents in a compound resembled the one usually observed in the filler formulated compounds.

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The Characteristics of Static and Dynamic Mechanical Properties of NEPE Propellant

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.684.111 ◽

2014 ◽

Vol 684 ◽

pp. 111-116

Author(s):

Yan Bin Gao ◽

Xiong Chen ◽

Jin Sheng Xu ◽

Shao Qing Hu

Keyword(s):

Mechanical Properties ◽

Loss Modulus ◽

Constant Strain Rate ◽

Viscoelastic Behavior ◽

Dynamic Mechanical Properties ◽

Mechanical Analysis ◽

Temperature Spectrum ◽

Dynamic Mechanical ◽

Nepe Propellant ◽

Static Conditions

In this paper, the static and dynamic mechanical viscoelastic behavior of NEPE propellant are studied. Under static conditions, five samples were subjected to constant-strain-rate monotonic loading with five different loading rates at room temperature. The dynamic mechanical analysis was employed for measurements of temperature and frequency dependence of the NEPE propellant by mean of BOSE-DMA-ELF3200 in frequency range from 1Hz to 16Hz. And get the dynamic mechanics temperature spectrum In the low temperature region, a single relaxation is observed in loss modulus-temperature Curves, which is glass transition relaxation. The results showed that NEPE propellant showed rate dependence and the same mechanical properties in the lower temperature and higher frequency.

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Property Evolution and Reliability of Underfills Under Sustained High Temperature Storage

10.1115/ipack2021-74061 ◽

2021 ◽

Author(s):

Pradeep Lall ◽

Madhu Kasturi ◽

Haotian Wu ◽

Jeff Suhling ◽

Edward Davis

Keyword(s):

High Temperature ◽

Loss Modulus ◽

Viscoelastic Behavior ◽

Relaxation Modulus ◽

Dynamic Mechanical Properties ◽

Master Curves ◽

Dynamic Mechanical ◽

Point Bend ◽

Tan Δ ◽

Impact Reliability

Abstract Automotive underhood electronics may be exposed to high temperature in the neighborhood of 100°C–200°C. Property evolution may impact reliability and accuracy of predictive models to assure desired use life. In this paper, evolution of properties of two underfill material properties are studied using DMA (Dynamic Mechanical Analyzer). The underfills are exposed to three different operational temperatures in the range of 100°C to 140°C for the measurements. The dynamic mechanical properties such as storage modulus (E′), loss modulus (E″), tangent delta (tan δ), and respective glass transition temperatures (Tg) are studied using DMA. Study of viscoelastic behavior of underfills is achieved by performing TTS (time-temperature superposition) experiments at 7 discrete frequencies 0.1, 0.21, 0.46, 1, 2.15, 4.64, and 10 Hz using DMA in three-point bend mode. From the selected reference temperatures, the master curves were constructed for storage moduli, loss moduli and tan delta as a function of frequency using TTS results. Using the WLF (Williams-Landel-Ferry) equation, the shift factors as a function of temperature were determined along the frequency axis. The relaxation modulus as a function of temperature and time can be obtained using the master curves of storage and loss moduli. A simple and detailed procedure has been established to find the Prony series constants.

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DYNAMIC MECHANICAL PROPERTIES OF PASSIVE SINGLE CARDIAC FIBERS FROM THE CRAB CANCER MAGISTER

Journal of Experimental Biology ◽

10.1242/jeb.185.1.207 ◽

1993 ◽

Vol 185 (1) ◽

pp. 207-249 ◽

Cited By ~ 1

Author(s):

E. Meyhofer

Keyword(s):

Mechanical Properties ◽

Extracellular Matrix ◽

Energy Dissipation ◽

Strain Rate ◽

Sarcomere Length ◽

Viscoelastic Behavior ◽

Dynamic Mechanical Properties ◽

Cancer Magister ◽

Dynamic Mechanical ◽

Cardiac Fibers

I determined the dynamic mechanical properties of single relaxed cardiac fibers from the Dungeness crab Cancer magister. Single fibers were mechanically isolated, chemically skinned and subjected to small-amplitude sinusoidal length perturbations over a wide range of strain rates and sarcomere lengths to characterize their viscoelastic behavior. The observed mechanical properties, together with transcardiac pressure recordings and ultrastructural measurements, were related to the overall function of the heart. Single fibers, often longer than 1 mm, could be mechanically dissected from the heart of Cancer magister. They typically ranged from 20 to 100 micrometre in diameter and were surrounded by a 100- 400 nm thick extracellular matrix. In situ, under normal physiological loads, the heart of Cancer magister generated transcardiac pressures of about 1000 Pa and beat at 1 Hz, while the sarcomere lengths of fibers changed by 10 % from about 4.0 to 4.4 micrometre during contractions. The total stiffness of all fibers increased from approximately 0.01 MPa to 1 MPa in the sarcomere length range from 3.8 to 6.0 micrometre and increased two- to threefold with a rise in strain rate from 0.01 to 5 rad s-1. In the physiological range of sarcomere length (4.0-4.4 micrometre) and strain rate (0.5-1.2 rad s- 1), single cardiac fibers behaved viscoelastically, with average values for the relative energy dissipation ranging from 0.5 to 0.7. The volume fraction of the extracellular matrix correlated positively with the stiffness of single cardiac fibers. On the basis of these results, I propose a dual role for the viscoelastic behavior of Cancer magister cardiac fibers: (1) the viscous energy dissipation confers dynamic mechanical stability at the level of the single fiber, and (2) the storage and return of elastic strain energy saves energy at the level of the whole heart.

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