Hydrogels are commonly
used materials in tissue engineering
and
organ-on-chip devices. This study investigated the nanomechanical
properties of monolithic and multilayered poly(ethylene glycol) diacrylate
(PEGDA) hydrogels manufactured using bulk polymerization and layer-by-layer
projection lithography processes, respectively. An increase in the
number of layers (or reduction in layer thickness) from 1 to 8 and
further to 60 results in a reduction in the elastic modulus from 5.53
to 1.69 and further to 0.67 MPa, respectively. It was found that a
decrease in the number of layers induces a lower creep index (CIT) in three-dimensional (3D) printed PEGDA hydrogels. This
reduction is attributed to mesoscale imperfections that appear as
pockets of voids at the interfaces of the multilayered hydrogels attributed
to localized regions of unreacted prepolymers, resulting in variations
in defect density in the samples examined. An increase in the degree
of cross-linking introduced by a higher dosage of ultraviolet (UV)
exposure leads to a higher elastic modulus. This implies that the
elastic modulus and creep behavior of hydrogels are governed and influenced
by the degree of cross-linking and defect density of the layers and
interfaces. These findings can guide an optimal manufacturing pathway
to obtain the desirable nanomechanical properties in 3D printed PEGDA
hydrogels, critical for the performance of living cells and tissues,
which can be engineered through control of the fabrication parameters.
Owing to their high hardness, fracture toughness and oxidation resistance, tungsten carbide (WC) coatings are extensively deposited on parts that operate in demanding applications, necessitating wear, erosion, and corrosion resistance. The application of thick and hard WC coatings has an inevitable effect on the original dimensions of the parts, affecting the geometrical tolerances and surface roughness. The capability of achieving a sub-micron surface finish and adhere to tight geometrical tolerances accurately and repeatably is an important requirement, particularly with components that operate in high-precision sliding motion. Meeting such requirements through conventional surface finishing methods, however, can be challenging due to the superior mechanical and tribological properties of WC coatings. A brief review into the synthesis techniques of cemented and binderless WC coatings is presented together with a comprehensive review into the available techniques which are used to surface finish WC-based coatings with reference to their fundamental mechanisms and capabilities to process parts with intricate and internal features. The binderless WC/W coating considered in this work is deposited through chemical vapour deposition (CVD) and unlike traditional cemented carbide coatings, it has a homogenous coating structure. This distinctive characteristic has the potential of eliminating key issues commonly encountered with machining and finishing of WC-based coatings. Here, six contact and non-contact surface finishing techniques, include diamond turning, precision grinding, superfinishing, vibratory polishing, electrical discharge machining, and electropolishing are discussed along with their current use in industry and limitations. Key challenges in the field are highlighted and potential directions for future investigation, particularly on binderless WC coatings, are proposed herein.
Nanostructured tungsten/tungsten carbide (W/WC) coatings produced by chemical vapour deposition are promising WC based coatings for applications where galling wear is prevalent due to the high hardness, toughness and stacking fault energy which the coatings possess despite low hardness to elastic modulus ratio (H/E). In this work the galling resistance of W/WC coatings has been studied through tibometer tests using sliding speeds of 0.014 m s −1 and contact pressures of up to 810 MPa. The study investigates the effects of surface finish and the use of similar and dissimilar material combinations on galling wear. Results show that self-mated stainless steel AISI 316 behave poorly under dry sliding wear conditions whilst uncoated stainless steel tested versus W/WC coating combinations are affected by galling due to material transfer forming a stainless steel on stainless steel tribosystem. The best performance was recorded for self-mated W/WC which did not develop any signs of galling even at the highest contact pressures (810 MPa) contradicting the common practice that the use of dissimilar materials can help prevent galling.
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