Study of the Failure Mechanism of a High-Density Polyethylene Liner in a Type IV High-Pressure Storage Tank.

The use of Type IV cylinders for gas storage is becoming more widespread in various sectors, especially in transportation, owing to the lightweight nature of this type of cylinder, which is composed of a polymeric liner that exerts a barrier effect and an outer composite material shell that primarily imparts mechanical strength. In this work, the failure analysis of an HDPE liner in a Type IV cylinder for high-pressure storage was carried out. The breakdown occurred during a cyclic pressure test at room temperature and manifested in the hemispherical head area, as cracks perpendicular to the liner pinch-off line. The failed sample was thoroughly investigated and its characteristics were compared with those of other liners at different stages of production of a Type IV cylinder (blow molding, curing of the composite material). An examination of the liner showed that no significant chemical and morphological changes occurred during the production cycle of a Type IV cylinder that could justify the liner rupture, and that the most likely cause of failure was a design-related fatigue phenomenon.

Effect of moderate hydrostatic pressure on crystallization of palm kernel stearin-sunflower oil model systems.

Lipid crystallization under moderate hydrostatic pressure treatments (200 MPa, 20 °C, 1-24 h) was studied in palm kernel stearin (PS 100%) and its blends with sunflower oil (PS 80, 90 % w/w). Hyperbarically-crystallized samples exhibited significantly higher firmness, elastic modulus and critical stress values as compared to those of the samples crystallized at atmospheric pressure. These data indicate that moderate hydrostatic pressure favored the formation of a higher amount of small palm kernel stearin crystals as compared to those formed at atmospheric pressure. Pressurization did not affect fat polymorphism, but was able to enhance nucleation instead of crystal growth. This work clearly demonstrated the efficacy of moderate hydrostatic pressure in steering lipid crystallization, opening interesting possible applications of high-pressure processing technology in the fat manufacturing sector.

Raw milk preservation by hyperbaric storage: Effect on microbial counts, protein structure and technological functionality.

The possibility to apply hyperbaric storage (HS) at room temperature (20 °C) as a sustainable approach for preservation of raw skim milk was studied. Samples were stored at 200 and 150 MPa for up to 6 days. Optimal pressure for milk HS was found to be 150 MPa, since no clotting was detected for up to 6 days. 150 MPa-HS caused the irreversible inactivation of inoculated Escherichia coli (5.13 ± 0.33 logCFU mL-1) and Staphylococcus aureus (5.66 ± 0.93 logCFU mL-1) within 2 and 6 days, respectively. Inactivation of total and faecal coliforms (3.0 log reductions) below the detection limit was achieved after just 2 days, whereas lactic acid bacteria and coagulase-positive Staphylococci were inactivated after 6 days. Pressurized storage also caused an increase in proteose peptones and the release of submicelles from casein micelles. Micelles progressively aggregated with pressure-unfolded ß-Lactoglobulin. These phenomena led to milk presenting up to 4-fold better foaming capacity, probably due to ß-Lactoglobulin unfolding or higher proteose peptones content. This work demonstrated the capability of HS to guarantee milk preservation during storage, and brought attention on the opportunity to consider the technology for milk pasteurization and functionality improvement.

Study on the possibility of developing food-grade hydrophobic bio-aerogels by using an oleogel template approach.

The feasibility of producing food-grade hydrophobic bio-aerogels by supercritical-carbon dioxide (SC-CO2) extraction of oil from oleogels was investigated for the first time. Medium chain triglycerides (MCT) oil was gelled using ethylcellulose (EC) at increasing concentration (10, 15, 20% w/w) and grade (EC20, 45, 100), eventually in combination with fillers. Different SC-CO2 oil extraction procedures were tested. The acquired results show that both oleogel formulation and extraction conditions can steer the EC scaffold structure. The increase in EC concentration and grade resulted in oleogels more structurally stable to SC-CO2 extraction. The application of a pulsed extraction procedure allowed obtaining a low-density (0.39 â€‹g/cm3) EC scaffold presenting 60% oil. Addition of freeze dried lettuce powder improved macrostructure homogeneity. The obtained results lay the foundations for developing food-grade hydrophobic bio-aerogels, which are expected to present unique oil absorption and bioactive delivery features.