Dynamics modelling and analysis of impact in multibody systems

Modarres Najafabadi, Seyed Ali.

January 2008

No description available.

On the NIP - mechanics of rolling processes.

Sinha, Shailendra K.

January 1972

No description available.

Cylinders

Rolling contact

Viscoelasticity

Contact dynamics for rigid bodies : modeling and experiments

Zhang, Yuning, 1979-

January 2007

No description available.

DETECTING SOCIAL CONTACT PATTERNS AND HEALTH STATUS OF THE ELDERLY WITH ILLNESS IN KANCHANABURI, THAILAND

Jaratsit, Suporn

17 June 2013

No description available.

Gerontology

SOCIAL CONTACT PATTERN

The Effect of Geometrical Contact Input to Wheel-Rail Contact Model

Martin, Michael

January 2018

Wheel-rail contact is an important aspect of railway, the forces transferred between the wheel and rail are the one that guide, brake, or accelerate the train, and that is why the understanding of the contact between wheel and rail is an interesting research topic. In this master thesis wheel-rail contact model named ANALYN is used to see the effect of the different geometrical input, like undeformed distance, relative longitudinal curvature, and relative lateral curvature calculation affect the contact patch estimation formed at the wheel-rail contact.  In the process, a geometrical contact search code is made to find the contact point between wheel and rail for certain lateral displacement, yaw angle, and roll angle of the wheelset. The codes used to calculate the three geometrical inputs are also prepared, with two methods are prepared for each input. The results that generated from combination of the geometrical contact search and geometrical input preparation are used as the input to ANALYN. The results showed that different geometrical input calculations do affect the shape of the contact patch, with the calculation of lateral curvature being the most important since it affects the shape of the contact patch greater than other geometrical inputs. It is also shown that taking yaw angle into account in the contact search will affect the shape of the contact patch.

Wheel-rail contact

geometrical contact input

contact point search

contact patch

rail vehicle.

Vehicle Engineering

Farkostteknik

Electrification and Wetting at Water–Hydrophobe Interfaces: Fundamentals and Applications

Nauruzbayeva, Jamilya

10 March 2022

Interfaces of water with water-repellent, or hydrophobic, materials are relevant in numerous natural and applied contexts. Examples include lotus leaves, membranes-assisted separation processes, and oil–water emulsions. Typically, water repellence is realized with the help of hydrocarbons and perfluorocarbons. Although these materials present low adhesion to water, their interfaces with water are known to be electrically charged. Origins of the electrification of water–hydrophobe interfaces is a century-old mystery that has been intensely debated on. A number of competing hypotheses have been proposed: specific interfacial adsorption of hydroxide ions, water dipole moment, partial interfacial charge transfer, specific interfacial adsorption of protons, cryptoelectrons, bicarbonate ions, and surfactant contamination. Given the significance of these interfaces, we investigated the origin of water–hydrophobe electrification. To disentangle the role of the various factors, we studied water’s interfaces with: solid hydrophobes, e.g., polypropylene; liquid hexadecane; and gas (air). Electrical charges incurred by water droplets formed using pipettes/tubes of hydrophobic (and hydrophilic) chemical make-up were quantified via electrometers and uniform electric fields. Specifically, we interrogated the contributions of water–hydrophobe surface area, surface chemistry, and water’s ionic strength, pH and dissolved CO2 content. We deduced that common solid hydrophobes have negatively charged surfaces even in air: when a hydrophobic pipette/tube is used to draw an aliquot of water from the bulk, hydrated cations form an electrical double layer at the liquid–solid interface. For the water–hexadecane interface, we tracked interfacial tensions over time. Our investigation revealed that trace amounts of impurities are present in the oil, despite purification, which interfere with purely interfacial effects. Lastly, we applied these fundamental insights to investigate slippery liquid-impregnated surfaces (SLIPS) realized using microtextured SiO2/Si wafers and sand dollar (Dendraster excentricus) templated PDMS surfaces. Recognizing the significant activity in triboelectric nanogenerators (TENGs), we conducted a parametric study of the device output and water–hydrophobe interfacial properties; and tested whether SLIPS could be incorporated in next-generation TENGs. The findings reported in this thesis address some long-standing questions on the spontaneous electrification of water–hydrophobe interfaces, and they should aid the rational development of practical applications such as SLIPS, TENGs, and beyond.

Contact electrification

water

hydrophobicity

Junctional complexes and their role in contact inhibition: a review

De Groh, David L.

January 1973

This document only includes an excerpt of the corresponding thesis or dissertation. To request a digital scan of the full text, please contact the Ruth Lilly Medical Library's Interlibrary Loan Department (rlmlill@iu.edu).

Intercellular Junctions

Contact Inhibition

Hyaluronic Acid Based Therapeutic Bandage Contact Lenses For Corneal Wound Healing

Tian, Jennifer (Jing Yuan)

January 2021

The cornea is an avascular transparent tissue exposed to the environment and therefore highly susceptible to damage. With an increase in corneal refractive surgeries, corneal transplants, and corneal injuries, understanding and improving corneal healing mechanisms are extremely important. Impaired healing of corneal wounds can lead to decreased visual acuity and extreme pain. Serum eye drops, amniotic membranes, pharmaceutical agents, biopolymers, and cell transplants are just a few approaches that have been employed to improve wound healing. Bandage contact lenses (BCLs) have been proposed as a simple method to facilitate wound healing while reducing pain. The synthesis of a silicone hydrogel contact lens capable of surface binding hyaluronic acid (HA) for corneal wound healing was explored in the current work. HA was used as both a wetting agent and a therapeutic. The work presented describes the synthesis, characterization, and cell testing of the HA binding model silicone hydrogels, composed of the hydrophilic monomer, 2-hydroxyethyl methacrylate (HEMA) and a hydrophobic silicone monomer, methacryloxypropyltris (trimethylsiloxy) silane (TRIS). Three different methods were evaluated for increasing HA binding and improving surface wettability. “Caged lenses” utilized the same base polymer with the incorporation of methacrylated N-Hydroxysuccinimide (NHS). Hydrophilic polyethylene glycol (PEG) chains were then tethered from the NHS, forming a “cage” with the potential to physically entrap HA. Although surface wettability was improved, less HA was entrapped in the caged lenses compared to model silicone hydrogels, presumably due to the increased hinderance resulting from the PEG chains. “Tethered HA” lenses utilized PEG as a spacer to conjugate HA to the lens surface in order to improve surface hydrophilicity. Methacrylated HA conjugation resulted in a significant decrease in contact angle (p <0.01) compared to model pHEMA-co-TRIS whereas tethered thiolated HA did not lead to a significant decrease (p >0.05) in contact angle. It was clear that neither of these methods would lead to sufficient HA binding. Ionic interaction lenses utilize monomers and small molecules that contain a positive charge to bind to the negatively charged HA under physiological conditions. The monomer diethylaminoethyl methacrylate (DEAEM) was polymerized directly into the polymer backbone, but resulted in no significant decrease (p >0.05) in contact angle. In comparison, surface functionalization using thiolene “click” chemistry allowed conjugation of the small molecule, dimethylamino ethanethiol (DMAET) and diethylamino ethanethiol (DEAET). DMAET and DEAET modified lenses showed significantly higher (p <0.001) HA binding compared to model pHEMA-co-TRIS controls at all time points. The modified lenses improved release kinetics preventing an initial burst release and showed consistent release when unloaded and reloaded with HA. The contact angle was significantly decreased (p <0.05) for the modified lenses with HA without affecting the equilibrium water content. Optical transparency was reduced following lens modifications although the thickness of the disks prepared was higher than a typical contact lens. Finally, the modified lenses did not exhibit any cytotoxicity in vitro with human corneal epithelial cells (HCECs). The synthesis of silicone hydrogels capable of surface binding HA have potential to be used as a bandage contact lens while improving surface wettability and enhancing comfort. / Thesis / Master of Applied Science (MASc)

Therapeutic Bandage Contact Lenses

Contact Lens Discomfort, Vision Correction Preferences, and Accommodative Treatment in Presbyopic and Non-Presbyopic Contact Lens Wearers

Rueff, Erin M.

18 October 2018

No description available.

Optics

contact lens, discomfort

Quantifying the effects of contact lens prescription parameters on human corneal oxygen uptake /

Fink, Barbara A.

January 1987

No description available.

Biology

Contact lenses

Cornea