Showing total 3 results

1. Development and validation of a 3D printed antiviral ventilator filter - a comparative study

Author

Mathew Francis, Barak Cohen, Esther Shaylor, Ruth Shaylor, and Solomon Dadia

Subjects

Paper, Surgical Sponges, Ventilator circuit, 3d printed, Coronavirus disease 2019 (COVID-19), Supply chain, Polyurethanes, Ultrafiltration, Peak Expiratory Flow Rate, Global Health, Automotive engineering, 03 medical and health sciences, Cartridge, 0302 clinical medicine, Anesthesiology, Humans, Medicine, RD78.3-87.3, Anesthesia, 030212 general & internal medicine, Coloring Agents, 030223 otorhinolaryngology, Pandemics, Ventilator, Ventilators, Mechanical, Filter paper, business.industry, COVID-19, Reproducibility of Results, Equipment Design, 3D printing, Anesthesiology and Pain Medicine, Filter (video), Printing, Three-Dimensional, Viruses, Feasibility Studies, business, Casing, Research Article

Abstract

Background The current coronavirus infectious disease 2019 (COVID-19) pandemic has caused unexpected pressure on medical supplies, interrupting supply chains and increasing prices. The supply of antiviral filters which form an essential part of the ventilator circuit have been affected by these issues. Three-dimensional (3D) printing may provide a solution to some of these issues. Methods We designed and tested 3D printed heat and moisture exchange (HME) and antiviral casing. For each casing we tested two different filter materials derived from a sediment water filter cartridge or 1.5-μm glass fiber filter paper. A polyurethane sponge was used for the HME. Each design was tested for circuit leak, circuit compliance, peak inspiratory pressure and casing integrity using methylene blue dye. Results We designed, produced, and tested two different types of antiviral filters with six different internal configurations. Overall, we tested 10 modified filter designs and compared them with the original commercial filter. Except for the combination of 1.5-μm filter paper and 5 mm sponge peak inspiratory pressure and circuit compliance of the filters produced were within the operating limits of the ventilator. All In addition, all filters passed the dye test. Conclusions Our filter may be of particular importance to those working in low middle-income countries unable to compete with stronger economies. Our design relies on products available outside the healthcare supply chain, much of which can be purchased in grocery stores, hardware stores, or industrial and academic institutions. We hope that these HMEs and viral filters may be beneficial to clinicians who face critical supply chain issues during the COVID-19 pandemic.

Published

2021

2. Does the use of load-reducing IPC on a wake-steering turbine affect wake behavior?

Author

Carlo L. Bottasso, Chengyu Wang, and Filippo Campagnolo

Subjects

Paper, History, Environmental science, Wake, Affect (psychology), Turbine, Automotive engineering, ddc, Computer Science Applications, Education

Abstract

This paper aims at quantifying and explaining the effects of Individual Pitch Control (IPC) on the wake of a wake-steering wind turbine. As the machine is intentionally misaligned with respect to the wind, IPC can be used to mitigate the resulting extra loading. However, while IPC reduces loads, it also affects the wake, which influences the power of downstream turbines. The question is therefore whether the IPC activity has any other appreciable effect at the wind farm level, in addition to its original turbine-level load reduction goal. In this work, experiments and CFD simulations of scaled wind turbines in a boundary layer wind tunnel are considered. The CFD model is first validated with measurements, and then used to show subtle changes in the wake, power and loads caused by IPC. It is observed that IPC does indeed have some non-negligible effects, and that these effects differ for positive and negative yawing.

Published

2020

3. Wake steering strategies for combined power increase and fatigue damage mitigation: an LES study

Author

Bruno Lopez, Andrés Guggeri, Martín Draper, and Filippo Campagnolo

Subjects

Paper, History, Environmental science, Fatigue damage, Wake, Automotive engineering, ddc, Computer Science Applications, Education, Power (physics)

Abstract

The impact of wake steering control strategy on power production and loads for a cluster of two wind turbines is analysed in this work. The power and loads data base are generated by means of high resolution simulations using an ALM-LES model along with an aeroelastic code for multibody analysis, while the optimal yaw misalignment values are obtained, for different wind directions and performance requirements, using a weighted cost function that accounts for both power production and fatigue damage on main wind turbine components. The sensitivity of the results regarding the inflow conditions, in terms of turbulence intensity, is also analysed. The overall results show that when accounting for both power production and fatigue damage, greater values of optimal yaw misalignment are obtained. This indicates that standard yaw misalignment strategies that accounts only for power production reduce at the same time the loading damage on the wind turbine, compared to greedy configuration.

Published

2020