The History of Furniture Construction
Elasticity of Wood
As a natural raw material, wood is characterised as both anisotropic, as well as volatile in its properties in the function of space; therefore, it is referred to as a non-homogeneous material. Below are the physical theories of elasticity for an anisotropic body and understood as an equation binding the component of the stress tensor with the components of a strain tensor. The most general form of such equations in the linear theory of elasticity is the equation (Nowacki 1970): where
Oij stress tensor,
Aijkl tensor of elasticity and Eki strain tensor.
|
Botanical name |
Trade name |
Symptoms of illness |
Common use |
Inadvisable use |
|
Pericopsis elata v. Meeuwen |
Afrormosia, kokrodua, asamela |
Skin irritation |
To use inside and outside of buildings, furniture and veneers |
|
|
Afzelia africana Sm. |
Afzelia, doussi, lengue, ара |
Skin irritation, irritation of mucous membranes |
To use inside and outside of buildings |
Kitchens |
|
Gossweilerodendron balsamifentm Harms |
Agba, tola, tola branca |
Irritation of mucous membranes |
To use inside and outside of buildings, substitutes oak |
|
|
Antiaris africana Engl. |
Antiaris, bonkonko, oro, kirundu, andoum, upas |
Irritation of mucous membranes of the nose, throat and skin |
Furniture and veneers |
|
|
Turraeanthus africanus Pellegr. |
Avodire |
Irritation of mucous membranes, nosebleeds |
Luxurious finishing of building interiors, children’s furniture and veneers |
|
|
Distemonanthus benthamianus Baillon |
Ayan, movingui |
Mild allergies |
Doors, windows, office furniture |
Kitchens laundry rooms |
|
Castanospermum austraie A. Cunn. |
Black bean, moreton bay chestnut |
Contains isoflavones |
Finishing of building interiors, furniture and veneers |
|
|
Fagus sylvatica L. |
Beech |
Possibility of eczema caused by particulates and sawdust |
Furniture, food containers, tools, parts of musical instruments |
|
|
Betula papyracea Ait |
Birch |
Possibility of recurring skin irritation during sanding of wood |
Furniture and veneers |
|
|
Acacia melanoxylon R. Br. |
Blackwood |
Nosebleeds asthma, skin irritation |
High-quality furniture, finishing of building interiors, musical instruments |
|
|
Guibourtia tessmannii J. Leonard |
Bubinga, kevazingo |
Skin irritation |
High-quality furniture, finishing of building interiors, floors |
|
Table 4.2 Major species of wood showing toxic, irritant or sensitising properties (Hausen 1981) |
|
4.5 Materials Used in Furniture Design 205 |
|
Botanical name |
Trade name |
Symptoms of illness |
Common use |
Inadvisable use |
|
Machaerium scleroxylon Tul. |
Caviuna vermelha, pao ferro, moradillo, jacaranda pardo, santos palisander |
Possible cases of skin irritation |
High-quality furniture, finishing of building interiors |
|
|
Cedrelci odorata L. |
Cedar, cedro |
Skin irritation |
Executive furniture, interior design |
|
|
Castanea sativa Mill. |
Chestnut, Spanish chestnut |
Possible cases of skin irritation |
Furniture, kitchen furniture, veneers |
|
|
Brya ebenus DC. |
Cocus, Jamaican ebony. |
Skin irritation |
Furniture, veneers |
|
|
Cordia miUenii Baker |
Cordia, canalete, freijo |
Skin irritation |
Furniture, finishing of building interiors |
|
|
Hymenaea courbaril L. |
Courbaril, locust |
Skin irritation |
Furniture |
|
|
Pseudotsuga menziesii (Mirb.) Franco |
Douglas fir, Oregon pine, douglasie |
Skin irritation and dermatitis, eczema |
Furniture, veneers |
|
|
Entandrophmgma angolense DC. |
Gedu nohor, tiama, edinam, kalungi |
Skin irritation |
Furniture |
|
|
Guarea thompsonii Sprague & Hutch. |
Guarea, bosse, obobo. |
Irritation of mucous membranes of the nose, throat and skin |
Furniture, finishing of building interiors |
|
|
Liquidambar styraciflua F. |
Gum, American sweetgum, red gum, bilsted, amberbaum |
Skin irritation |
Furniture, interior design |
|
|
TenninaHa ivorensis A. Chev. |
Idigbo, framire, emeri, black afara |
Skin irritation |
Furniture, finishing of building interiors |
Kitchen furniture |
|
(continued) |
|
206 4 Introduction to Engineering Design of Furniture |
|
Botanical name |
Trade name |
Symptoms of illness |
Common use |
Inadvisable use |
|
Chlorophorci excelsa Bentham and Hooker |
Iroko, kambala, mwule, odum |
Skin irritation |
Substitutes teak |
|
|
Larix decidua Miller |
Larch |
Skin irritation |
Furniture |
|
|
Shorea |
Lauan, red |
Skin irritation |
Furniture, interior design |
|
|
Terminalia superba Engler and Diels |
Limba, afara, korina |
Skin irritation, nosebleeds |
Chairs, interior design |
|
|
Diospyros celebica Bakh. |
Makassar Ebony, Coromandel |
Skin irritation and dermatitis, eczema |
Luxurious furniture, elements of musical instruments |
|
|
Khaya grandifoliola DC. |
African mahogany khaya, krala |
Skin irritation |
Furniture, executive offices, surfaces of worktops of office furniture |
|
|
Swietenia macrophyllci King |
American mahogany, tabasco, caoba |
Skin irritation |
Furniture, executive offices, interior design |
|
|
Tieghemella heckelii Pierre ex Chev. |
Makore, baku |
Irritation of mucous membranes of the nose and upper respiratory tract |
Furniture, veneers, high-quality interior design, doors |
|
|
Man son ia altissima A. Chev. |
Mansonia, bete |
Skin irritation, cough, nosebleeds, headaches |
Telecommunications engineering, furnishings of building interiors |
|
|
Prosopis juliflora DC. |
Mesquite |
Skin irritation |
To use inside and outside of buildings, furniture and interior design |
|
|
Pterocarpus angolensis DC. |
Muninga, kejaat |
May cause allergies |
Furniture, veneers, high-quality interior design |
|
|
Triplochiton scleroxylon K. Schum. |
Obeche, samba, wawa, abachi |
Asthma, skin irritation and rash |
Veneers, interior design |
|
4.5 Materials Used in Furniture Design 207 |
|
Botanical name |
Trade name |
Symptoms of illness |
Common use |
Inadvisable use |
|
Nerium oleander L. |
Oleander, laurier rose |
Poisonings have toxic properties |
Haberdashery |
Kitchen, contact with food |
|
Olea europaea L. |
Olive wood |
Severe skin irritation and paralysis |
Interior design, jewelery, for turning |
Direct contact with body |
|
Aspidospenna peroba Fr. All |
Peroba rosa |
Skin irritation. Particulates and sawdust cause irritation of mucous membranes of the nose, irritation of larynx and eyes, weakness, drowsiness, sweating, fainting |
Outdoor furniture, hand tools |
|
|
Pinus radiata D. Don |
Radiata pine, Monterey pine |
Skin irritation caused by the presence of resin and turpentine |
Furniture |
|
|
Pinus silvestris F. |
Pine |
Skin irritation |
Furniture, stairs and many more |
|
|
Gonystylus ban can us Baillon |
Ramin, malawis |
Skin irritation |
Furniture and interior design |
|
|
Dalbergia nigra All |
Brazilian rosewood, Jacaranda, Rio palisandre |
Eczema of hands and face, skin irritation |
Furniture, interior design, veneers, musical instruments |
|
|
Dalbergia latifolia Roxb. |
East Indian rosewood, Indian palisandre |
Eczema, skin irritation |
High-quality furniture, interior design, elements of musical instruments |
|
|
Entandrophragma cylindricum Sprague |
Sapelli, sapele, sapeli |
Skin irritation |
Furniture, interior design, veneers |
|
(continued) |
|
208 4 Introduction to Engineering Design of Furniture |
By entering the engineering markings of components of the stress and strain
tensor - @11 @x, @22 @y, @33 @z, T12 Txy, T23 Tyz, T31 Tzx, £11 £x, £22 £y,
£33 = «z, Y12 = Yxy, Y23 = Yyz and 731 = Yzx, and entering the markings: An = Ann, ..., A16 = A1131, ..., A21 = A2211, ..., A26 = A2231, ..., we obtain the following form of generalised Hooke’s law (Litewka 1997):
|
@x |
'A11 |
A12 |
A13 |
A14 |
A15 |
A16 |
_£x |
||
|
ry |
A21 |
A22 |
A23 |
A24 |
A25 |
A26 |
ey |
||
|
@z |
A31 |
A32 |
A33 |
A34 |
A35 |
A36 |
ez |
||
|
sxy |
A41 |
A42 |
A43 |
A44 |
A45 |
A46 |
Txy |
||
|
syz |
A51 |
A52 |
A53 |
A54 |
A55 |
A56 |
cyz |
||
|
szx _ |
_A61 |
A62 |
A63 |
A64 |
A65 |
A66_ |
Jzx_ |
If the symmetry of stress and strain tensors is considered, the number of components is 36. But when we take into account the differentiating alternation of free energy function in relation to the tensor’s components:
dstjdski dSkidstj ’
where
V elastic energy,
then the number of the tensor A components will decrease to 21. In specific anisotropic cases, like for example an orthotropic body, tensor A has 9 components, and for a transversally isotropic body—5 components. By expressing the strains of an anisotropic body in the general form, the following equation can be written as follows:
eij aijkl ‘ rkl;
where
a compliance tensor and
aijki components of the compliance tensor determined by the measurement of the strains of planes of a three dimensional body, taking into account normal and shear strains (Fig. 4.9).
At the same time, the following dependencies apply: for the direction of X-axis
_ ey ez ex ex
mxy — — ; V* — — ; Pzr. z — “ ; fizy, x — “ ;
ex ex czx Izy
|
for the direction of Y-axis
|
Thus, it is easy to write, e. g. an equation of normal strains in the direction of the X-axis:
ex — E vyx£y vzxez + ^zyyX ■ czy ” 1ZX, X ■ yzx ” MryjX ■ Уху-
By substituting the now well-known dependencies e = a/E and у = т/G, we obtain, respectively:
e =-X - v^- v ^ + и ^ + и —+ и - Xh С42П
ex E vyx E vzx E Hzy, x G ' игх, х g г их^,х g ’ ( )
Ex Ey Ez Gyz Gxz Gxy
or
ex E (rx vxyry vxzrz Г 1x, yzsyz Г 1x, xzsxz Г Ax^xy) -
Ex
For shear strains, e. g. ^ the equation of the sum of partial strains will have the form:
xy
yxy G ' 1y? x^ ■ ey ' Mx, xy ■ ex “г ■ ez "T” 1^,xy ■ yxz ""I” 1zy, xy ■ Tyz’
Gxy
hence finally
yxy — G i1xy, xrx + Mxyjry г Mxy^z г Mxyz^xz г 1xy, zyTyz г Txy) .
Gx
In the above equations, Ex, Ey and Ez are the linear elasticity modules at stretching, Gxy, Gxz and Gyz are shear elasticity modules in planes that are parallel to the lines of direction coordinates x, y, z, vxy, vyx, and vzx, vxz, vyz, vzy are Poisson’s
ratios characterising elongation in the direction of the first axis and shortening in the direction of the second axis of the plane. Coefficients, Mxzyz... ,Mxz>xy, called Chentsov coefficients (Ashkenazi 1958; Lekhnickij 1977), characterise shear strains in planes that are parallel to the coordinate system, caused by tangential stresses acting in the second planes parallel to the coordinate system. Coefficients, wyz>x... ,Mxy>z, according to Rabinowicz (1946) called the coefficients of mutual impact of first degree, they express elongation in the direction of the axis of the coordinate system, caused by tangential stresses acting in planes parallel to the coordinate system. Coefficients, Mxyz... ,Mz>xy, express shear strains in planes parallel to the global coordinate system, caused by normal stresses acting in the direction of the axis of the system. They can be called coefficients of mutual impact of the second degree (Ashkenazi 1958).
The equations above correspond only to the given Cartesian system of coordinates. Changing this system will automatically change the values of the coefficients,
although their number remains constant. However, if at any point of the anisotropic elastic body, three mutually perpendicular planes of its internal structure can be led, such material can be called orthotropic. Wood, as an orthotropic body, in a spatial state of stresses is subject to normal strains (Fig. 4.10) and changes in shape (Fig. 4.11).
By summing up the value of partial strains in particular anatomical directions, we obtain expressions for total strains in the form:
where
aL, aR, aT vector of normal stresses, respectively, in the direction:
longitudinal, radial and tangential;
El, Er, Et linear elasticity modules of wood, respectively, in the
direction: longitudinal, radial and tangential; and vLR, vLT, vRT, vTR, Poisson’s ratios, respectively, in anatomical directions: longi - vRL, vTL tudinal-radial, longitudinal-tangential, radial-tangential, tan
gential-radial, radial-longitudinal and tangential-longitudinal.
And expressions for shear strains are given as follows:
The generalised Hooke’s law in matrix convention has the form:
ri — Aijej; (4-34)
while for the discussed case, we will obtain:
|
_ |
ClEl |
CtlEl |
CrE,. |
0 |
0 |
0 |
|
|
ffL |
Ct (vrt+v, t vrl) |
Ct (vrt+vltvrl) |
Ct |
||||
|
Г7 |
vlt (1—vlrvrl )Et Ct |
(1—vlrvrl )Et Ct |
(vrt+v, t vrl)Et Ct |
0 |
0 |
0 |
|
|
ffR |
CrlEr |
(1—vlrvrl)(1—vlt vtl)Er |
(1—vlt vtl)Er |
0 |
0 |
0 |
|
|
SLT |
— |
Ct (vrt+vlt vrl) |
Ct (vrt+vltvrl) |
Ct |
|||
|
0 |
0 |
0 |
glt |
0 |
0 |
||
|
SLR |
0 |
0 |
0 |
0 |
Glr |
0 |
|
|
STR J |
0 |
0 |
0 |
0 |
0 |
G7R |
|
e, eT |
X £R ;
Jlt
Ilk
Ttr
(4.35)
where:
Ct (1 - vLTvTL)(1 - VlrVrl) - (vTR + VlrVlt)(Vrt + TltTrlX
CL CT(vRT + vLTvRL) + vLTvTL(1 - vLTRvRL)(vRT + vLTvRL) + vRL(vL7(1 - vLTvRL)
(1 - vLTvTL) - ^LT^Th CR vTL(vRT + vltVrL) + vRL(1 - vLTvTLX
CTL vTL(1 - vlrVrl)(Vrt + VltVrL) + vRL((1 - vLRvRL)(1 - vLTvTL) - CtX
CRL FltC1 - vLTvRL)(1 - vLTvTL) - vLTCT
Table 4.3 shows a list of elastic properties of selected wood species, commonly used in the furniture industry.
