Development of an individual tree-based mechanical model to predict wind damage within forest stands

Models predicting forest stand wind-firmness are usually based on the calculation of a critical wind speed above which the mean tree of a stand is broken or uprooted. This approach is well adapted to regular stands, but in heterogeneous stands, not all the trees are necessarily damaged at the same t...

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Published inForest ecology and management Vol. 203; no. 1; pp. 101 - 121
Main Authors Ancelin, Philippe, Courbaud, Benoît, Fourcaud, Thierry
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 13.12.2004
Elsevier
Subjects
Animal and plant ecology
Animal, plant and microbial ecology
Biological and medical sciences
Critical wind-speed
Environmental Sciences
FOREOLE
Forest management. Stand types and stand dynamics. Silvicultural treatments. Tending of stands. Natural regeneration
Forestry
Fundamental and applied biological sciences. Psychology
Stand types and stand dynamics. Silvicultural treatments. Tending of stands. Natural regeneration
Synecology
Terrestrial ecosystems
Transfer matrix method
Tree biomechanics
Tree stability
Wind-firmness
Tree stability
TMM
VRS
Tree biomechanics
VSS
Wind-firmness
Transfer matrix method
FOREOLE
CWS
Critical wind-speed
Wind
Statistical analysis
Forest stand
Wood
Stress
Stem
Mechanical stress
Tree crown
Development
Damage
Adaptation
CAPSIS
Online AccessGet full text
ISSN0378-1127
1872-7042
DOI10.1016/j.foreco.2004.07.067

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Abstract Models predicting forest stand wind-firmness are usually based on the calculation of a critical wind speed above which the mean tree of a stand is broken or uprooted. This approach is well adapted to regular stands, but in heterogeneous stands, not all the trees are necessarily damaged at the same time. Models used to analyse the distribution of damage within a population of trees can be a good alternative. In this perspective we developed FOREOLE, an individual-based mechanical model of tree response to wind. FOREOLE is based on a numerical description of tree structure allowing both wind and self-weight loads to be calculated at every level of the stem, as well as the bending moment at the tree base and mechanical stresses along the stem. We use a static approach to model wind forces in which the turbulent aspect of wind is taken into account through a gust factor. Stem breakage or uprooting is then predicted from comparisons to failure criteria, i.e. critical bending moment and critical compressive stress, respectively. Implemented in the software called CAPSIS, FOREOLE is compatible with a model of coniferous forest stand dynamics and allows wind-firmness to be simulated both in measured and virtual populations of trees. On individual trees, FOREOLE provided predictions of critical wind speed comparable to the existing models known as GALES and HWIND, despite differences in the method used to describe tree shape and to solve mechanics. These predictions appeared particularly sensitive to the gust factor and the drag coefficient. We then analysed the influence of stand structure, wind speed and individual tree characteristics on the type and amount of damage. From simulations in stands representing three different structures (regular, intermediate and selection stands), we showed that irregular stands experience scattered damage for a relatively wide range of wind speeds, whereas regular stands tend to collapse as a whole above a critical wind speed. Irregularity also increased the ratio between loss in volume of wood and loss in number of trees. Regarding tree characteristics, the highest and the slenderest subjects were the most sensitive, both to stem breakage and to overturning. Sensitivity to breakage was also increased by shorter crowns. In addition, statistical analysis of the simulation results also showed that wind speed remained the most significant variable in explaining wind damage.
AbstractList The development of an individual tree-based mechanical model, FOREOLE, to predict wind damage within forest stands is detailed, and results are presented from a evaluation of FOREOLE with the models, HWIND and GALES, at the single tree scale. The developed model was then applied to three Norway spruce Picea abies populations to investigate the influence of wind speed and stand structure on damage. FOREOLE is composed of an individual tree-based mechanical model applied to every tree within the stand, and stand-level analysis tools. All governing numerical equations are provided. Results show that, while the average difference between GALES and HWIND in predicted wind speed for overturning was 11.6%, it was 5.1 and 12.8% between FOREOLE and GALES and between FOREOLE and HWIND, respectively. Analysis of sensitivity to internal model parameters showed that the drag coefficient and the gust factor were two key parameters of the model. Application of FOREOLE to three Norway spruce stands of different structures showed that irregular stands experienced scattered damage for a relatively wide range of wind speeds, while regular stands tended to collapse as a whole above a critical wind speed.
Models predicting forest stand wind-firmness are usually based on the calculation of a critical wind speed above which the mean tree of a stand is broken or uprooted. This approach is well adapted to regular stands, but in heterogeneous stands, not all the trees are necessarily damaged at the same time. Models used to analyse the distribution of damage within a population of trees can be a good alternative. In this perspective we developed FOREOLE, an individual-based mechanical model of tree response to wind. FOREOLE is based on a numerical description of tree structure allowing both wind and self-weight loads to be calculated at every level of the stem, as well as the bending moment at the tree base and mechanical stresses along the stem. We use a static approach to model wind forces in which the turbulent aspect of wind is taken into account through a gust factor. Stem breakage or uprooting is then predicted from comparisons to failure criteria, i.e. critical bending moment and critical compressive stress, respectively. Implemented in the software called CAPSIS, FOREOLE is compatible with a model of coniferous forest stand dynamics and allows wind-firmness to be simulated both in measured and virtual populations of trees.On individual trees, FOREOLE provided predictions of critical wind speed comparable to the existing models known as GALES and HWIND, despite differences in the method used to describe tree shape and to solve mechanics. These predictions appeared particularly sensitive to the gust factor and the drag coefficient. We then analysed the influence of stand structure, wind speed and individual tree characteristics on the type and amount of damage. From simulations in stands representing three different structures (regular, intermediate and selection stands), we showed that irregular stands experience scattered damage for a relatively wide range of wind speeds, whereas regular stands tend to collapse as a whole above a critical wind speed. Irregularity also increased the ratio between loss in volume of wood and loss in number of trees. Regarding tree characteristics, the highest and the slenderest subjects were the most sensitive, both to stem breakage and to overturning. Sensitivity to breakage was also increased by shorter crowns. In addition, statistical analysis of the simulation results also showed that wind speed remained the most significant variable in explaining wind damage.
Models predicting forest stand wind-firmness are usually based on the calculation of a critical wind speed above which the mean tree of a stand is broken or uprooted. This approach is well adapted to regular stands, but in heterogeneous stands, not all the trees are necessarily damaged at the same time. Models used to analyse the distribution of damage within a population of trees can be a good alternative. In this perspective we developed FOREOLE, an individual-based mechanical model of tree response to wind. FOREOLE is based on a numerical description of tree structure allowing both wind and self-weight loads to be calculated at every level of the stem, as well as the bending moment at the tree base and mechanical stresses along the stem. We use a static approach to model wind forces in which the turbulent aspect of wind is taken into account through a gust factor. Stem breakage or uprooting is then predicted from comparisons to failure criteria, i.e. critical bending moment and critical compressive stress, respectively. Implemented in the software called CAPSIS, FOREOLE is compatible with a model of coniferous forest stand dynamics and allows wind-firmness to be simulated both in measured and virtual populations of trees. On individual trees, FOREOLE provided predictions of critical wind speed comparable to the existing models known as GALES and HWIND, despite differences in the method used to describe tree shape and to solve mechanics. These predictions appeared particularly sensitive to the gust factor and the drag coefficient. We then analysed the influence of stand structure, wind speed and individual tree characteristics on the type and amount of damage. From simulations in stands representing three different structures (regular, intermediate and selection stands), we showed that irregular stands experience scattered damage for a relatively wide range of wind speeds, whereas regular stands tend to collapse as a whole above a critical wind speed. Irregularity also increased the ratio between loss in volume of wood and loss in number of trees. Regarding tree characteristics, the highest and the slenderest subjects were the most sensitive, both to stem breakage and to overturning. Sensitivity to breakage was also increased by shorter crowns. In addition, statistical analysis of the simulation results also showed that wind speed remained the most significant variable in explaining wind damage.
Author Ancelin, Philippe
Courbaud, Benoît
Fourcaud, Thierry
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  fullname: Courbaud, Benoît
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  surname: Fourcaud
  fullname: Fourcaud, Thierry
  organization: Programme Modélisation des Plantes, CIRAD-AMIS, Laboratoire de Rhéologie du Bois de Bordeaux, UMR 5103 CNRS/INRA/University Bordeaux I, Domaine de l’hermitage, 69 Route d’Arcachon, 33612 Cestas Gazinet, France
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Issue 1
Keywords Tree stability
TMM
VRS
Tree biomechanics
VSS
Wind-firmness
Transfer matrix method
FOREOLE
CWS
Critical wind-speed
Wind
Statistical analysis
Forest stand
Wood
Stress
Stem
Mechanical stress
Tree crown
Development
Damage
Adaptation
CAPSIS
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Snippet Models predicting forest stand wind-firmness are usually based on the calculation of a critical wind speed above which the mean tree of a stand is broken or...
The development of an individual tree-based mechanical model, FOREOLE, to predict wind damage within forest stands is detailed, and results are presented from...
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SubjectTerms Animal and plant ecology
Animal, plant and microbial ecology
Biological and medical sciences
Critical wind-speed
Environmental Sciences
FOREOLE
Forest management. Stand types and stand dynamics. Silvicultural treatments. Tending of stands. Natural regeneration
Forestry
Fundamental and applied biological sciences. Psychology
Stand types and stand dynamics. Silvicultural treatments. Tending of stands. Natural regeneration
Synecology
Terrestrial ecosystems
Transfer matrix method
Tree biomechanics
Tree stability
Wind-firmness
Title Development of an individual tree-based mechanical model to predict wind damage within forest stands
URI https://dx.doi.org/10.1016/j.foreco.2004.07.067
https://www.proquest.com/docview/14726876
https://www.proquest.com/docview/17788120
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