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ISO 3898:1976

(Main)

Bases for design of structures — Notations — General symbols

Bases for design of structures — Notations — General symbols

Bases du calcul des constructions — Notations — Symboles généraux

General Information

Status
Withdrawn
Publication Date
31-Aug-1976
Withdrawal Date
31-Aug-1976
ICS
91.080.01 - Structures of buildings in general
Technical Committee
ISO/TC 98 - Bases for design of structures
Drafting Committee
ISO/TC 98 - Bases for design of structures
Current Stage
9599 - Withdrawal of International Standard
Completion Date
01-Dec-1987
Ref Project

Relations

Revised
ISO 3898:1987 - Bases for design of structures — Notations — General symbols
Effective Date
15-Apr-2008

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ISO 3898:1976 - Bases for design of structures -- Notations -- General symbolsISO 3898:1976 - Bases for design of structures -- Notations -- General symbols
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ISO 3898:1976 - Bases for design of structures -- Notations -- General symbols
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ISO 3898:1976 - Bases for design of structures — Notations — General symbols Released:9/1/1976ISO 3898:1976 - Bases for design of structures — Notations — General symbols Released:9/1/1976
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ISO 3898:1976 - Bases for design of structures — Notations — General symbols Released:9/1/1976
French language
4 pages
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,en!*,
INTERNATIONAL STANDARD @ ‘*E& 3898
INTERNATIONAL ORGANIZATION FOR STANDARDIZATION -MEiliLIYHAPOIIHAR OPrAHM3AUMR II0 CTAHLIAPTM3AUMM .ORGANISATION INTERNATIONALE DE NORMALISATION
*
Bases for design of structures - Notations - General symbols
Bases du calcul des constructions - Notations - Symboles généraux
First edition - 1976-09-30
I
w
-
UDC 624.04 : 003.62 Ref. No. IS0 3898-1976 (E)
Descriptors : buildings, construction, structural design, formulas (mathematics), symbols, definition.
w
Price based on 4 pages

---------------------- Page: 1 ----------------------
FOREWORD
IS0 (the International Organization for Standardization) is a worldwide federation
of national standards institutes (IS0 Member Bodies). The work of developing
International Standards is carried out through IS0 Technical Committees. Every
Member Body interested in a subject for which a Technical Committee has been set
up has the right to be represented on that Committee. International organizations,
governmental and non-governmental, in liaison with ISO, also take part in the work.
Draft lnternational Standards adopted by the Technical Committees are circulated
to the Member Bodies for approval before their acceptance as International
Standards by the IS0 Council.
International Standard IS0 3898 was drawn up by Technical Committee
ISO/TC98, Bases for design of structures, and was circulated to the Member
Bodies in June 1975.
It has been approved by the Member Bodies of the following countries :
Australia India South Africa, Rep. of
Belgium Israel Spain
Bulgaria New Zealand Sweden
Denmark Norway Turkey
France Poland United Kingdom
Portugal Yugoslavia
Germany
Romania
Hungary
The Member Bodies of the following countries expressed disapproval of the docu-
ment on technical grounds :
Czechoslovakia
Switzerland
O International Organization for Standardization, 1976
Printed in Switzerland

---------------------- Page: 2 ----------------------
INTERNATIONAL STANDARD IS0 3898-1976 (E)
Bases for design of structures - Notations - General symbols
1 SCOPE AND FIELD OF APPLICATION
2.2 Construction of symbols
The construction of a symbol to represent a given quantity
This International Standard defines standard notations for
or term shall be carried out as follows :
structural design.
1) The main letter of the symbol shall be selected
It covers only general terms which are necessary to this
from table 2, 3, 4 or 5, based on consideration of
field of application and excludes terms relevant to a par-
0
dimensions and usage, as given in table 1.
ticular material (for example steel, concrete, wood, etc.) or
to a special technical field (for example foundations, etc.),
2) An apostrophe ('1 can be used to represent com-
which will be defined separately.
pression (especially for geometrical or locational pur-
poses).
It indicates only the symbols to be used and does not preju-
3) Descriptive subscripts may be selected as desired.
dice the exact definition of each term, which will be within
6,
When subscripts other than those appearing in tables
the scope of other International Standards.
7 and 8 are used, a clear definition of their meaning
shall be given.
This International Standard has been established for use in
regulations, standards, technical literature and design. It
4) In the construction of symbols, the first subscripts
does not cover future developments in safety theories or
shall indicate the location, and the following subscripts
new techniques in computer design.
shall identify the cause (nature, location, etc.)' ).
However, for the time being, letter J (table 2) has been
5) When there is no likelihood of confusion, some or
reserved for line printers and telex.
all descriptive subscripts may be omitted.
6) Numerical figures may be used as subscripts.
7) The sign of a computed stress is given by positive
(+) for tension, and negative (-) for compression.
2 TYPES OF SYMBOL
e
Owing to the possibility of confusion, the following pre-
cautions must be taken :
2.1 Tables of letters and symbols
- Where there is a possibility of confusing 1 (numeral)
with I (letter) in some typewritten work, L shall be used
in place of I (letter) where ambiguity wcluld otherwise
2.1.1 Table 1 gives general indications about the usage of
arise.
different types of letter.
- Roman upper and lower case letter O shall not be
used as a leading letter owing to the possibility of con-
2.1.2 Tables 2, 3 and 4 give the meanings of letters when
fusion with zero. The lower case O may, however, be
used as a main symbol.
used as a subscript, with the same meaning as O (zero).
- Greek lower case letters iota (61, omicron (01 and
upsilon (U) shall not be used owing to the possibility of
2.1.3 Table 5 gives a list of special and mathematical
confusing them with various Roman letters. For the
symbols.
same reason, it is recommended that, as far as possible,
the use of kappa (K) and chi (x) be avoided. When Greek
lower case letters eta (77). omega (U) and mu (p) are
2.1.4 Tables 6, 7 and 8 give the meanings of letters or used, care must be taken in writing the letters to avoid
groups of letters when used as subscripts. confusion with Roman lower case letters n, w and U.
1) Where it is necessary to avoid confusion, it is recommended that a comma be used between the two categories of subscript.
1

---------------------- Page: 3 ----------------------
IS0 3898-1976 (E)
TABLE 1 - Letter guide for the construction of symbols
Usage
1 Action and action-effects
to a power other than 1,
2 Area, first and second moments of area
temperature
3 Elastic moduli (exception to the general rule)
4 Temperature
-
Roman lower case Length, quotient of length and 1 Actions and action-effects per unit of length or area
time to a power, force per unit
2 Linear dimensions (length, width, thickness, etc.)
length or area, mass, time
3 Strengths
4 Velocity, acceleration, frequency
5 Descriptive letters (subscripts)
6 Mass
7 Time
Reserved for mathematics
Greek upper case
1 Coefficients and dimensionless ratios
Greek lower case Dimensionless
2 Strains
3 Angles
4 Densities (mass density and weight density) (exception to the general rule)
5 Stresses (exception to the general rule)
NOTE - Concepts not included in the table above shall comply with the nearest appr
...

INTERNATIONAL ORGANIZATION FOR STANDARDIZATION .MEX,!lYHAPO,!lHAR OPrAHWJAUWff Il0 CTAH,!lAPTMJAUMW .ORGANISATION INTERNATIONALE DE NORMALISATION
@
Bases du calcul des constructions - Notations -
Symboles généraux
Bases for design of structures - Notations - General symbols
Premiere édition - 1976-09-30
O
- U.
Réf. no : IS0 3898-1976 (FI
CDU 624.04 : 003.62
fi
z
Descripteurs : bstiment, construction, projet de construction, formule, symbole, definition.
Co
i4
a
Prix base sur 4 pages

---------------------- Page: 1 ----------------------
AVANT-PROPOS
L'ISO (Organisation Internationale de Normalisation) est une fédération mondiale
d'organismes nationaux de normalisation (Comités Membres ISO). L'élaboration des
Normes Internationales est confiée aux Comités Techniques ISO. Chaque Comité
Membre intéressé par une étude a le droit de faire partie du Comité Technique
correspondant. Les organisations internationales, gouvernementales et non
gouvernementales, en liaison avec I'ISO, participent également aux travaux.
Les Projets de Normes Internationales adoptés par les Comités Techniques sont
soumis aux Comités Membres pour approbation, avant leur acceptation comme
Normes Internationales par le Conseil de 1'1S0.
La Norme Internationale IS03898 9 été établie par le Comité Technique
ISOfTC98, Bases du calcul des constructions, et a été soumise aux Comités
Membres en juin 1975.
Elle a été approuvée par les Comités Membres des pays suivants :
Afrique du Sud, Rép. à' France Portugal
Allemagne Hongrie Roumanie
Australie Inde Royaume-Uni
Belgique Israël Suède
Bulgarie Norvège Turquie
Danemark Nouvelle-Zélande Yougoslavie
Espagne Pologne
I
o
Les Comités Membres des pays suivants ont désapprouvé le document pour des
raisons techniques :
Suisse
Tchécoslovaquie
1
0 Organisation Internationale de Normalisation, 1976
Imprimé en Suisse

---------------------- Page: 2 ----------------------
NORME INTERNATIONALE
IS0 3898-1976 (F)
Bases du calcul des constructions - Notations -
Symboles généraux
1 OBJET ET DOMAINE D’APPLICATION
1) La lettre principale du symbole est choisie dans les
tableaux 2, 3, 4 ou 5, en se basant sur ses dimensions et
La présente Norme Internationale définit des notations
sur son usage, suivant les indications du tableau 1.
normalisées dans le domaine du calcul des constructions.
2) Une apostrophe (’1 peut être utilisée pour représen-
Elle concerne uniquement les termes généraux nécessaires
ter la compression (spécialement pour les usages géomé-
dans ce domaine, à l’exclusion des termes particuliers à un
triques ou topologiques).
0
matériau (acier, béton, bois, etc.) ou à une branche spéciale
de la technique (fondations, etc.), qui seront définis sépa- 3) Des indices descriptifs peuvent être choisis à volonté.
rément. Lorsque des indices autres que ceux qui figurent dans les
tableaux 6, 7 et 8 sont utilisés, on doit donner une défi-
La présente Norme Internationale indique les symboles à
nition claire de leur signification.
utiliser, mais ne préjuge pas des définitions exactes de
chaque terme, qui feront l‘objet d‘une autre Norme Inter-
4) Pour la construction des symboles, les premiers in-
nationale.
dices doivent indiquer l’emplacement et les suivants la
cause (nature, emplacement, etc.)’)
La présente Norme Internationale a été établie pour les
besoins de la réglementation, de la normalisation, de la
5) Quand il n’y a pas de risque de confusion, on peut
littérature technique et du calcul. Elle ne résout pas les
omettre les indices descriptifs, ou seulement quelques-
problèmes posés par les développements des théories de la
uns d’entre eux.
sécurité, ni par les nouvelles techniques de calcul auto-
6) Des chiffres peuvent être utilisés comme indices.
matique.
Toutefois, pour les besoins des imprimantes et du télex, il 7) Le signe d‘une contrainte calculée est positif (+I
a été prévu de réserver la lettre J (voir tableau 2). pour une traction et négatif (-1 pour une compression.
Pour éviter les confusions, les précautions suivantes doivent
être prises :
2 TYPES DE SYMBOLES
- On a reconnu la possibilité de confondre 1 (chiffre)
a
2.1 Tableaux des lettres et symboles
avec I (lettre) dans certains documents dactylographiés.
Un L (majuscule) sera donc utilisé à la place de I (lettre
2.1.1 Le tableau 1 donne des indications générales sur
minuscule), dans le cas où il y aurait risque d’ambiguïté
l‘emploi des différents types de lettres.
dans les documents dactylographiés.
2.1.2 Les tableaux 2, 3 et 4 donnent les significations des
- La lettre romaine O, majuscule et minuscule, ne doit
lettrxs utilisées comme symbole principal.
pas être utilisée comme lettre principale à cause de la
possibilité de confusion avec zéro. La minuscule O peut
2.1.3 Le tableau 5 donne une liste de symboles mathéma- cependant être utilisée en indice avec la même signifi-
tiques et spéciaux. cation que O (zéro).
- Les lettres minuscules grecques iota (11, omicron (O)
2.1.4 Les tableaux 6, 7 et 8 donnent les significations des
et upsilon (U) ne doivent pas être utilisées à cause de la
lettres ou groupes de lettres utilisés en indice.
possibilité de confusion avec diverses lettres romaines.
Pour la même raison, il est recommandé d’éviter autant
2.2 Construction des symboles
que possible kappa (K) et khi (x). Enfin, si les minuscules
grecques êta (7). oméga (a) et mu (p) sont employées,
La construction d‘un symbole, pour représenter une quantité
il faut prendre soin, en écrivant ces lettres, d’éviter la
ou un terme donné, se fait comme suit :
confusion avec les minuscules romaines n, wet U.
1) Quand cela est nécessaire, afin d’éviter des confusions, il est recommandé d’employer une virgule entre les deux catégories d’indice.
1

---------------------- Page: 3 ----------------------
IS0 3898-1976 (FI
TABLEAU 1 - Guide pour la construction des symboles
i
Type de lettre Dimensions Usage
I
Majuscule romaine Force, produit d'une force par 1 Actions et sollicitations
une longueur. longueur élevée à
2 Aire, moment statique et moment quadratique d'une aire
une puissance autre que 1,
3 Modules d'élasticité (par exception à la règle générale)
température
4 Température
Minuscule romaine Longueur, rapport longueur/ 1 Actions et sollicitations, par unité de longueur ou d'aire
I
I tmpS élevés à une PuisSance, I 7 Dimensions linéaires (lonaueur. iaraeur. éoaisseur. etc.)
-
force par unité de longueur ou
d'aire, masse, temps
4 Vitesse, accélération, fréquence
I
5 Lettres descriptives (en indice)
6 Masse
7 Temps
Réservé aux mathématiques
Majuscule grecque
Sans dimensions 1 Coefficients et rapports sans dimensions
Minuscule grecque
TABLEAU 2 - Majuscules romaines
Signification
Lettre
~~
Aire
A
B (Vide)
C (Vide)
D Rigidité de flexion des plaques et des coques
E Module d'élasticité longitudinale
E Action due
...

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