| Titre : |
Strength of materials |
| Type de document : |
texte imprimé |
| Auteurs : |
Hartog, Jacob Pieter den, Auteur |
| Editeur : |
New York : Dover publications |
| Année de publication : |
1949 |
| Importance : |
VIII, 352 p. |
| Présentation : |
ill. |
| Format : |
24 cm. |
| ISBN/ISSN/EAN : |
978-0-486-60755-9 |
| Note générale : |
Index [321,322] p. |
| Langues : |
Anglais (eng) |
| Mots-clés : |
Tension torsion Strenth of materials |
| Index. décimale : |
539.4 Résistance à la tension |
| Résumé : |
Strength of materials
by J. P. Den Hartog
Professor of Mechanical Engineering Massachusetts Institute of Technology
Among introductory texts on the strength of materials, this work is particularly distin-guished. It was originally developed by Professor Den Hartog to meet the needs of engi-neering students at M.I.T. for a sound yet lucid first course in strength of materials. As such it has also enjoyed wide popularity in engineering schools throughout the world.
But the book was remarkable in a number of other ways, so that it has become one of the favorite refresher and reference works for engineers as well as a popular self-study text. Perhaps the chief reason for this is that in addition to all the customary elementary ma-terial on the subject (i.e., clear introductions to the fundamentals of tension, torsion, bend-ing, compound stresses, deflection of beams, etc.) it also contains a considerable amount of more advanced material concerning methods of great practical value to working engi-neers which are not usually included in introductory texts. This material is presented in starred sections (which may be omitted on a first reading without interrupting the flow of the presentation) and includes a full treatment of the Mohr circle and its applications to the determination of moments of inertia and strains as well as stresses; a lucid elemen-tary presentation of the theory of the center of shear; and one of the few elementary discussions of the "Myosotis" method of calculating beam deflections, a method which often possesses considerable advantages over the more usual methods involving moment-area or the differential equation of bending.
Other material not usually found in elementary texts but which are frequently of great value to the practicing engineer are the discussions of the statically indeterminate truss, reinforced concrete, plastic deformations, thick-walled cylinders, thick curved bars, Max-well's Reciprocal Theorem, and photoelasticity.
In all sections, both general principles and concrete applications are given. Another feature which readers have found unusually helpful is the 85-page section of 350 problems which gives the student practice in techniques and further illustrates applications. All problems are complete with answers.
|
| Note de contenu : |
Summary:
1. Tension
2. Torsion
3. Bending
4.Compound stresses
5. Deflections of beams
6. Special beam problems
7. Cylinders and curved bars
8. The energy method
9. Buckling
10. Exprimental elasticity
|
Strength of materials [texte imprimé] / Hartog, Jacob Pieter den, Auteur . - New York : Dover publications, 1949 . - VIII, 352 p. : ill. ; 24 cm. ISBN : 978-0-486-60755-9 Index [321,322] p. Langues : Anglais ( eng)
| Mots-clés : |
Tension torsion Strenth of materials |
| Index. décimale : |
539.4 Résistance à la tension |
| Résumé : |
Strength of materials
by J. P. Den Hartog
Professor of Mechanical Engineering Massachusetts Institute of Technology
Among introductory texts on the strength of materials, this work is particularly distin-guished. It was originally developed by Professor Den Hartog to meet the needs of engi-neering students at M.I.T. for a sound yet lucid first course in strength of materials. As such it has also enjoyed wide popularity in engineering schools throughout the world.
But the book was remarkable in a number of other ways, so that it has become one of the favorite refresher and reference works for engineers as well as a popular self-study text. Perhaps the chief reason for this is that in addition to all the customary elementary ma-terial on the subject (i.e., clear introductions to the fundamentals of tension, torsion, bend-ing, compound stresses, deflection of beams, etc.) it also contains a considerable amount of more advanced material concerning methods of great practical value to working engi-neers which are not usually included in introductory texts. This material is presented in starred sections (which may be omitted on a first reading without interrupting the flow of the presentation) and includes a full treatment of the Mohr circle and its applications to the determination of moments of inertia and strains as well as stresses; a lucid elemen-tary presentation of the theory of the center of shear; and one of the few elementary discussions of the "Myosotis" method of calculating beam deflections, a method which often possesses considerable advantages over the more usual methods involving moment-area or the differential equation of bending.
Other material not usually found in elementary texts but which are frequently of great value to the practicing engineer are the discussions of the statically indeterminate truss, reinforced concrete, plastic deformations, thick-walled cylinders, thick curved bars, Max-well's Reciprocal Theorem, and photoelasticity.
In all sections, both general principles and concrete applications are given. Another feature which readers have found unusually helpful is the 85-page section of 350 problems which gives the student practice in techniques and further illustrates applications. All problems are complete with answers.
|
| Note de contenu : |
Summary:
1. Tension
2. Torsion
3. Bending
4.Compound stresses
5. Deflections of beams
6. Special beam problems
7. Cylinders and curved bars
8. The energy method
9. Buckling
10. Exprimental elasticity
|
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Strength of materials (1949)
