2,599 research outputs found
Hygroscopic behaviour of paper and books
This study presents experimental analysis and numerical modeling of hygroscopic moisture buffering by paper and books. First, a literature review of moisture transport properties of paper is presented. Experimental work on two paper types includes SEM analysis of the paper structure, determination of sorption isotherms and water vapor permeability measurements. A hysteretic model for paper is presented, which is based on the measurement of the main adsorption and desorption curves. It is shown that the water vapor permeability in a hysteretic model is dependent on the moisture content and not on the relative humidity. Books consist of several paper sheets with air layers between the sheets. To take the air layers into account, a parallel transport model is proposed to determine the effective moisture transport properties of books taking into account the air layers. The dynamic hygroscopic behavior of small book samples was measured. It is shown that, although the water vapor permeability of different paper types can be quite different, the effusivity of a book highly depends on the presence of the air layers and can therefore remain comparable for different paper type
Experimental investigation of cavity flow under building integrated photovoltaic panels using thermography and particle image velocimetry
Paper presented to the 3rd Southern African Solar Energy Conference, South Africa, 11-13 May, 2015.An extensive experimental investigation demonstrates the
impact of cavity airflow underneath photovoltaic (PV) panels
integrated in the roof assemblies of buildings. The benefit of
underside ventilation is seen in terms of an increased efficiency
of photovoltaic panels due to lowering their operating
temperature, resulting in less turn-off times as well as an
improved hygrothermal and durability behavior of the panels.
We perform an extensive measurement campaign of the
surface temperature using infrared thermography and of the
airflow using particle image velocimetry. A novel setup was
developed consisting of a building model with a mock PV
panel and a solar simulator placed inside a large-scale
atmospheric wind tunnel. A solar simulator is positioned in the
tunnel to provide a range of various radiation intensities over
the panels and the approaching upstream wind is well
controlled in the wind tunnel. The top surface temperatures and
air speeds above and below the panel are monitored
simultaneously.
It is shown that, in general, the airflow within the cavity is
faster compared to the free upstream air velocity, resulting in an
increased heat exchange between the PV and the air cavity and
a reduction of the PV surface temperatures. A stepped open
arrangement of panels is shown to be more effective in
reducing the surface temperatures comparing to a flat
arrangement.
The results also show the presence of different interacting
flow phenomena: natural convection due to irradiation, forced
convection due to the upstream wind, cavity ventilation and
surface convection, as well as the presence of complex 3D
flows patterns (e.g. lateral eddies), which contribute to a highly
non-uniform surface temperature distribution over the PV
modules.dc201
VE-cadherin and claudin-5: it takes two to tango
Endothelial barrier function requires the adhesive activity of VE-cadherin
and claudin-5, which are key components of adherens and tight endothelial
junctions, respectively. Emerging evidence suggests that VE-cadherin controls
claudin-5 expression by preventing the nuclear accumulation of FoxO1 and
-catenin, which repress the claudin-5 promoter. This indicates that a crosstalk
mechanism operates between these junctional structures
Percolation, Morphogenesis, and Burgers Dynamics in Blood Vessels Formation
Experiments of in vitro formation of blood vessels show that cells randomly
spread on a gel matrix autonomously organize to form a connected vascular
network. We propose a simple model which reproduces many features of the
biological system. We show that both the model and the real system exhibit a
fractal behavior at small scales, due to the process of migration and dynamical
aggregation, followed at large scale by a random percolation behavior due to
the coalescence of aggregates. The results are in good agreement with the
analysis performed on the experimental data.Comment: 4 pages, 11 eps figure
MiRP1 forms IKr potassium channels with HERG and is associated with cardiac arrhythmia.
A novel potassium channel gene has been cloned, characterized, and associated with cardiac arrhythmia. The gene encodes MinK-related peptide 1 (MiRP1), a small integral membrane subunit that assembles with HERG, a pore-forming protein, to alter its function. Unlike channels formed only with HERG, mixed complexes resemble native cardiac IKr channels in their gating, unitary conductance, regulation by potassium, and distinctive biphasic inhibition by the class III antiarrhythmic E-4031. Three missense mutations associated with long QT syndrome and ventricular fibrillation are identified in the gene for MiRP1. Mutants form channels that open slowly and close rapidly, thereby diminishing potassium currents. One variant, associated with clarithromycin-induced arrhythmia, increases channel blockade by the antibiotic. A mechanism for acquired arrhythmia is revealed: genetically based reduction in potassium currents that remains clinically silent until combined with additional stressors
Deletion of Macrophage Vitamin D Receptor Promotes Insulin Resistance and Monocyte Cholesterol Transport to Accelerate Atherosclerosis in Mice
Intense effort has been devoted to understanding predisposition to chronic systemic inflammation because it contributes to cardiometabolic disease. We demonstrate that deletion of the macrophage vitamin D receptor (VDR) in mice (KODMAC) is sufficient to induce insulin resistance by promoting M2 macrophage accumulation in the liver as well as increasing cytokine secretion and hepatic glucose production. Moreover, VDR deletion increases atherosclerosis by enabling lipid-laden M2 monocytes to adhere, migrate, and carry cholesterol into the atherosclerotic plaque and by increasing macrophage cholesterol uptake and esterification. Increased foam cell formation results from lack of VDR-SERCA2b interaction, causing SERCA dysfunction, activation of ER stress-CaMKII-JNKp-PPARγ signaling, and induction of the scavenger receptors CD36 and SR-A1. Bone marrow transplant of VDR-expressing cells into KODMAC mice improved insulin sensitivity, suppressed atherosclerosis, and decreased foam cell formation. The immunomodulatory effects of vitamin D in macrophages are thus critical in diet-induced insulin resistance and atherosclerosis in mice
Tree effects on urban microclimate: diurnal, seasonal, and climatic temperature differences explained by separating radiation, evapotranspiration, and roughness effects
Increasing urban tree cover is an often proposed mitigation strategy against urban heat as trees are expected to cool cities through evapotranspiration and shade provision. However, trees also modify wind flow and urban aerodynamic roughness, which can potentially limit heat dissipation. Existing studies show a varying cooling potential of urban trees in different climates and times of the day. These differences are so far not systematically explained as partitioning the individual tree effects is challenging and impossible through observations alone. Here, we conduct numerical experiments removing and adding radiation, evapotranspiration, and aerodynamic roughness effects caused by urban trees using a mechanistic urban ecohydrological model. Simulations are presented for four cities in different climates (Phoenix, Singapore, Melbourne, Zurich) considering the seasonal and diurnal cycles of air and surface temperatures.
Results show that evapotranspiration of well-watered trees alone can decrease local 2 m air temperature at maximum by 3.1 – 5.8 °C in the four climates during summer. Further cooling is prevented by stomatal closure at peak temperatures as high vapour pressure deficits limit transpiration. While shading reduces surface temperatures, the interaction of a non-transpiring tree with radiation can increase 2 m air temperature by up to 1.6 – 2.1 °C in certain hours of the day at local scale, thus partially counteracting the evapotranspirative cooling effect. Furthermore, in the analysed scenarios, which do not account for tree wind blockage effects, trees lead to a decrease in urban roughness, which inhibits turbulent energy exchange and increases air temperature during daytime. At night, single tree effects are variable likely due to differences in atmospheric stability within the urban canyon. These results explain reported diurnal, seasonal and climatic differences in the cooling effects of urban trees, and can guide future field campaigns, planning strategies, and species selection aimed at improving local microclimate using urban greenery
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