203 research outputs found
Wavet, a Custom Device Able to Measure Viscoelastic Properties of Wood Under Water-Saturated Conditions Up to 140 deg C (WAVET : Environmental Vibration Analyser for Wood)
This work presents an innovative experimental device conceived to
characterize the time-dependent behavior of hygroscopic materials, as wood, at
controlled moisture content and temperature. This device, the WAVET, permits
the determination of the viscoelastic properties of samples, using harmonic
tests at frequencies varying from 5.10-3 Hz to 10 Hz. Conceived to work up to 5
bar, it allows tests in dry or water-saturated conditions to be performed over
the temperature range 0\degree C to 140\degree C. In spite of these severe
working conditions, the careful device design, together with a rigorous data
analysis, allows a rigorous determination of the storage and loss modulus and
the loss factor. The results collected for several species of wood emphasize
the ability of the WAVET to underline the influence of numerous parameters,
namely specie, material direction, anatomical and macromolecular structure, on
the rheological properties and notably on the softening temperature. The WAVET
also establishes a efficient tool to follow the modifications of the
constitutive amorphous polymers of materials submitted to hydrothermal
treatments, in relation to the evolution of their viscoelastic properties.Comment: 3
Viscoelastic properties of wood across the grain measured under water-saturated conditions up to 135\degree C: evidence of thermal degradation
In this paper, the viscoelastic properties of wood under water-saturated
conditions are investigated from 10\degree C to 135\degree C using the WAVET*
apparatus. Experiments were performed via harmonic tests at two frequencies
(0.1 Hz and 1 Hz) for several hours. Four species of wood were tested in the
radial and tangential material directions: oak (Quercus sessiliflora), beech
(Fagus sylvatica), spruce (Picea abies) and fir (Abies pectinata). When the
treatment is applied for several hours, a reduction of the wood rigidity is
significant from temperature values as low as 80-90\degree C, and increases
rapidly with the temperature level. The storage modulus of oak wood is divided
by a factor two after three hours of exposure at 135\degree C. This marked
reduction in rigidity is attributed to the hydrolysis of hemicelluloses. The
softening temperature of wood is also noticeably affected by hygrothermal
treatment. After three short successive treatments up to 135\degree C, the
softening temperature of oak shifted from 79\degree C to 103\degree C, at a
frequency of 1 Hz. This reduction in mobility of wood polymers is consistent
with the condensation of lignins observed by many authors at this temperature
level. In the same conditions, fir exhibited a softening temperature decreasing
of about 4\degree C. In any case, the internal friction clearly raises
Enumeration method and medium design for a mixed culture of saccharomyces cerevisiae and chlorella vulgaris
The scientific literature shows a rising interest in studies on symbiotic mixed cultures as an innovative bioprocess to increase biomass and lipid productivity. The main issue with mixed cultures appears to be the dominance of one organism over the other during cultivation. In the current work, a methodology is proposed to develop a co-dominant mixed culture of Saccharomyces cerevisiae GFP and Chlorella vulgaris, in which their growth would be based on mutual symbiosis through recycling O2 and CO2. The first challenge was to develop a rapid and accurate method to distinguish and enumerate each population.
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Shrinkage of cane (Arundo donax L.) II Effect of drying condition on the intensity of cell collapse
To improve the drying method in the manufacture of woodwind reeds, green
canes (Arundo donax L.) were dried under various humidity-temperature
conditions and the intensity of cell collapse was evaluated from the swelling
due to steaming involving the recovery of collapse. At 30 C, the intensity of
collapse was increased by slower drying. It was considered that: 1) slower
drying resulted in higher sample temperature in the early stage of drying to
increase the collapse; 2) rapid drying stiffened the surface of sample and such
"shell" prohibited the following collapse; 3) slower drying i.e. longer loading
of liquid tension caused more remarkable and/or frequent viscoelastic yields of
cells. Consequently the intensity of collapse increased when the cane was dried
from its waxy outer surface or in the presence of node: both of them retarded
the drying. On the other hand, higher drying temperature caused greater
intensity of collapse in spite of faster drying. It was suggested that the
thermal softening of cane cells leads to easier yield of the cell wall, at the
same time the rapid drying does not allow the recovery of collapse after the
disappearance of free water. These results indicated that faster drying at
lower temperature is preferable for drying cane with less collapse.Comment: Will be published in J. Wood Sci. (Japanese wood research society) -
follows part I: J. Wood Sci. 50 : 295-30
8th International IUFRO wood drying conference Brasov-Romania, August 24-29, 2003
The IUFRO 5.04.06 Wood Drying Conference was organised by the "Transilvania" University of Brasov - Faculty of Wood Industry and hosted by the Aro Palace Complex in Brasov (Romania). Over 100 scientists from 28 countries attended the meeting. Two Keynote Addresses: " The Role of Wood Anatomy in the Drying of Wood: "Great Oaks from Little Acorns Grow " by the Wood Drying Working Party Leader, Patrick PerrC (France) and " High-Frequency Heating Combined With Vacuum Drying Of Wood by Helmut Resch (Austria) was an excellent start of the technical program of over 80 oral presentations and 28 poster presentations. The topics of the 10 oral presentation sessions and the poster session covered modelling, stress and strain behaviour of wood, properties ofwood related to drying, fast drying procedures, applied drying, heat and mass transfer, kiln control, drying quality, colorations and general
Drying strategies capable of reducing the stress level of a stack of boards as defined by a comprehensive dual scale model
During drying, stresses and deformations develop in a wood board due to shrinkage fields which result from moisture content and temperature field variations. In spite of numerous works done in wood drying modelling in the last decades, wood drying optimisation based on modelling and simulation remains far from initial expectations. Two main reasons can explain this assessment: the huge variability of wood and the variations in drying conditions throughout the board stack in a dryer.To address these two key problems, we used a dual scale numerical tool able to compute simultaneously the stress and deformation of hundreds of boards in the stack during drying. A rigorous one-dimensional mechanical formulation, based on previous works, has been used for calculating stress and deformation during drying. The mechanical model is fitted into a module and then added to a dual scale (boardstack) model. This numerical tool has been used to improve the drying schedules recommended by the Technical Centre for Wood and Furniture in France (CTBA) for spruce. The proposed drying schedules allow the board quality to be improved. Note that the optimisation was limited to medium temperature values, so that the proposed schedule can be applied to conventional kilns
8th International IUFRO wood drying conference Brasov-Romania, August 24-29, 2003
The IUFRO 5.04.06 Wood Drying Conference was organised by the "Transilvania" University of Brasov - Faculty of Wood Industry and hosted by the Aro Palace Complex in Brasov (Romania). Over 100 scientists from 28 countries attended the meeting. Two Keynote Addresses: " The Role of Wood Anatomy in the Drying of Wood: "Great Oaks from Little Acorns Grow " by the Wood Drying Working Party Leader, Patrick PerrC (France) and " High-Frequency Heating Combined With Vacuum Drying Of Wood by Helmut Resch (Austria) was an excellent start of the technical program of over 80 oral presentations and 28 poster presentations. The topics of the 10 oral presentation sessions and the poster session covered modelling, stress and strain behaviour of wood, properties ofwood related to drying, fast drying procedures, applied drying, heat and mass transfer, kiln control, drying quality, colorations and general
Use of Heating Configuration to Control Marangoni Circulation during Droplet Evaporation
The present work presents a numerical study of the evaporation of a sessile liquid droplet deposited on a substrate and subjected to different heating configurations. The physical formulation accounts for evaporation, the Marangoni effect, conductive transfer in the support, radiative heating, and diffusion-convection in the droplet itself. The moving interface is solved using the Arbitrary Lagrangian-Eulerian (ALE) method. Simulations were performed using COMSOL Multiphysics. Different configurations were performed to investigate the effect of the heating conditions on the shape and intensity of the Marangoni circulations. A droplet can be heated by the substrate (different natures and thicknesses were tested) and/or by a heat flux supplied at the top of the droplet. The results show that the Marangoni flow can be controlled by the heating configuration. An upward Marangoni flow was obtained for a heated substrate and a downward Marangoni flow for a flux imposed at the top of the droplet. Using both heat sources generated two vortices with an upward flow from the bottom and a downward flow from the top. The position of the stagnation zone depended on the respective intensities of the heating fluxes. Controlling the circulation in the droplet might have interesting applications, such as the control of the deposition of microparticles in suspension in the liquid, the deposition of the solved constituent, and the enhancement of the evaporation rate
A mesoscopic drying model applied to the growth rings of softwood: Mesh generation and simulation results
A mesoscopic drying model that enables the drying simulation of quartersawn and flatsawn wood sections consisting of several growth rings is presented. The procedure to generate the virtual board description directly from real sample images is also described. This virtual structure accommodates the prominent sample features, including its geometrical and physical properties, together with the density and structural variation across the growth rings. We give a synopsis of the sophisticated techniques developed specifically to generate this virtual description and exhibit the final computational meshes produced by the software for quartersawn and flatsawn sections. Low temperature drying simulations are then performed for both heterogenous and homogeneous model variants using these virtual descriptions and comparisons are made of the resulting MC field evolution. A highlight of these comparisons is that the heterogeneous model captures realistic drying effects, including the fast drying of earlywood and the late removal of liquid water in latewood. In comparing the drying of quartersawn and flatsawn boards we conclude that the effect of the heterogeneous nature of the MC fields is diminished somewhat when considering the flatsawn section over the quartersawn section
Technical Note: Equilibrium Moisture Content of Norway Spruce at Low Pressure
The EMC of Norway spruce (Picea abies) was determined at various levels of temperature and RH under low pressures. EMC corresponded to temperature and RH and was strongly related to vapor pressure inside the chamber. The amount of air present in the vacuum chamber did not significantly affect the EMC. The Hailwood-Horrobin model can be used to estimate the EMC of wood under vacuum, although it is about 2-3% MC less than the actual EMC of wood during initial desorption
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