Vasilică Ciocan scite author profile

At the end of 2019, a variation of a coronavirus, named SARS-CoV-2, has been identified as being responsible for a respiratory illness disease (COVID-19). Since ventilation is an important factor that influences airborne transmission, we proposed to study the impact of heating, ventilation and air-conditioning (HVAC) with a variable air volume (VAV) primary air system, on the dispersion of infectious aerosols, in a cardiac intensive care unit, using a transient simulation with computational fluid dynamics (CFD), based on the finite element method (FEM). We analyzed three scenarios that followed the dispersion of pathogen carrying expiratory droplets particles from coughing, from patients possibly infected with COVID-19, depending on the location of the patients in the intensive care unit. Our study provides the mechanism for spread of infectious aerosols, and possibly of COVID-19 infection, by air conditioning systems and also highlights important recommendations for disease control and optimization of ventilation in intensive care units, by increasing the use of outdoor air and the rate of air change, decreasing the recirculation of air and using high-efficiency particulate air (HEPA) filters. The CFD-FEM simulation approach that was applied in our study could also be extended to other targets, such as public transport, theaters, philharmonics and amphitheaters from educational units.

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Interactive computer simulations for standing waves

Radinschi

Fratiman

Ciocan

et al. 2017

Comp Applic In Engineering

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Interactive computer simulations and learning environments like virtual laboratories come out as an excellent alternative to conventional physics laboratories. Two of the physics laboratories from the second semester within the Faculty of Civil Engineering and Building Services of “Gheorghe Asachi” Technical University are focused on the study of standing waves. Standing waves are very important in the field of Civil Engineering because the structural integrity of buildings can be affected by standing waves and the mechanical resonance phenomenon. A good understanding of the properties of standing waves will make the properly constructed structures withstand various risk factors. Some improperly constructed structures could damage or breakdown even in the presence of vibrations or strong winds. This paper presents the computer simulations developed for the study of the standing waves on a vibrating string and the propagation of electromagnetic standing waves in a Lecher system. For both simulations, the canvas element, part of HTML5 standard, is used to draw the graphics animations. Also, many control components and some external JavaScript libraries are used to perform the virtual applications. Further, these computer simulations are posted on the virtual physics laboratory web‐site and thus, students are able to engage in more productive self or group activities. © 2017 Wiley Periodicals, Inc. Comput Appl Eng Educ 25:521–529, 2017; View this article online at http://www.wileyonlinelibrary.com/journal/cae; DOI

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Energy efficient heat pipe heat exchanger for waste heat recovery in buildings

Burlacu

Sosoi

Vizitiu

et al. 2018

Procedia Manufacturing

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Sustainable Development of Human Society in Terms of Natural Depleting Resources Preservation Using Natural Renewable Raw Materials in a Novel Ecological Material Production

et al. 2020

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In the last few years, the building industry experienced a significant development as a response to the demographic growth of human society and to the increasing demand for housing. Their construction involves the traditional use of concrete as a material that provides added strength to the finished building. This is manufactured respecting standard recipes depending on the way of its use. Anyway, all concrete recipes involve the use of mineral aggregates extracted from the riverbed, as is happening in Romania, or rock blocks crushing, as reported in other countries. Under these conditions, the rationalization of the use of natural mineral resources and the identification of new possibilities to reduce their consumption through their replacement with vegetal waste has become an important research issue. In this study, two types of vegetal waste—namely, shredded corn cobs and sunflower stalks—were used to manufacture novel ecological concretes. The vegetal wastes, both in untreated and treated forms (with 20% and 40% of sodium silicate solution), were used to replace 50% of the river (mineral) aggregate volume. The obtained concretes were tested, and the values of some important parameters in the concrete characterization (such as bulk density, water adsorption capacity, compressive strength and splitting tensile strength) were compared with the concrete contains cement CEM II/A-LL 42.5R. The obtained results show that these vegetal wastes have the potential to be used in the manufacturing of new ecological concrete. In addition, this alternative material meets the requirements for the sustainable and healthy development of the environment, offering low-polluting solutions in the context of an increasing demand for constructions.

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Evaluation of Different WRF Parametrizations over the Region of Iași with Remote Sensing Techniques

et al. 2019

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This article aims to present an evaluation of the Weather Research and Forecasting (WRF) model with multiple instruments when applied to a humid continental region, in this case, the region around the city of Iași, Romania. A series of output parameters are compared with observed data, obtained on-site, with a focus on the Planetary Boundary Layer Height (PBLH) and on PBLH-related parametrizations used by the WRF model. The impact of each different parametrization on physical quantities is highlighted during the two chosen measurement intervals, both of them in the warm season of 2016 and 2017, respectively. The instruments used to obtain real data to compare to the WRF simulations are: a lidar platform, a photometer, and ground-level (GL) meteorological instrumentation for the measurement of temperature, average wind speed, and pressure. Maps of PBLH and 2 m above ground-level (AGL) atmospheric temperature are also presented, compared to a topological and relief map of the inner nest of the WRF simulation. Finally, a comprehensive simulation performance evaluation of PBLH, temperature, wind speed, and pressure at the surface and total precipitable water vapor is performed.

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