| Week |
Theory |
Practical |
| Lecture Day |
Topic(including assignment/ test) |
Practical Day |
Topic |
| 1 |
1 |
INTRODUCTION (syllabus + codes) |
*** |
*** |
| 2 |
Introduction to the construction material, physical requirement of material. |
*** |
*** |
| 3 |
cement, aggregate and reinforcement. |
*** |
*** |
| 4 |
properties of material. Strength durability |
| 2 |
5 |
shrinkage and creep |
*** |
*** |
| 6 |
design of concrete mixes |
*** |
*** |
| 7 |
acceptability criteria and specification of material. |
*** |
*** |
| 8 |
Assignment + class test |
*** |
*** |
| 3 |
9 |
Design philosophies. WSM & LSM |
*** |
*** |
| 10 |
Brief introduction about WSM & LSM |
*** |
*** |
| 11 |
Technical terms used in method of design |
*** |
*** |
| 12 |
Stress-strain relationship for concrete and steel. |
| 4 |
13 |
Permissible stress in concrete and steel. |
*** |
*** |
| 14 |
Introduction and design steps of singly reinforced beam |
*** |
*** |
| 15 |
Design example |
*** |
*** |
| 16 |
Design of boubly reinforced baem |
*** |
*** |
| 5 |
17 |
Design example |
*** |
*** |
| 18 |
Design example (assignment) |
*** |
*** |
| 19 |
design of singly reinforced beanm by limit state method |
*** |
*** |
| 20 |
design example |
| 6 |
21 |
doobly reinforcement beam with minimum and maximum reinforcement. |
*** |
*** |
| 22 |
design example |
| 23 |
design example (assignment) |
*** |
*** |
| 24 |
Analysis and design of section in shear |
*** |
*** |
| 7 |
25 |
Technical terms used in method of design |
| 26 |
design steps |
*** |
*** |
| 27 |
design example |
*** |
*** |
| 28 |
design example |
| 8 |
29 |
design example |
*** |
*** |
| 30 |
Class test |
*** |
*** |
| 31 |
Concrete reinforcement and detailing, requirement of good detailing |
*** |
*** |
| 32 |
cover, spacing and reinforcement splicing |
| 9 |
33 |
Anchoring reinforcing in flexural and shear, curtailment of reinforcement. |
*** |
*** |
| 34 |
introduction to serviceability limit state, control of deflection,cracking. |
| 35 |
slenderness and vibrations, deflection and moment relationship. |
*** |
*** |
| 36 |
limit state of crack width. Design example |
| 10 |
37 |
design example |
*** |
*** |
| 38 |
Class test |
*** |
*** |
| 39 |
Introduction to the slab and general consideration, |
*** |
*** |
| 40 |
design steps of one way slab. |
| 11 |
41 |
design example |
*** |
*** |
| 42 |
design steps of two ways slab for distributed and concentrated load |
*** |
*** |
| 43 |
design example |
*** |
*** |
| 44 |
design example, |
| 12 |
45 |
design of non-rectangular slab, opening in slab |
*** |
*** |
| 46 |
design example |
| 47 |
Class test |
*** |
*** |
| 48 |
Introduction to column, types and assumptions. |
*** |
*** |
| 13 |
49 |
design steps of short column undr axial compression |
*** |
*** |
| 50 |
design example |
*** |
*** |
| 51 |
unaxial and biaxial bending in short column. |
*** |
*** |
| 52 |
design example |
*** |
*** |
| 14 |
53 |
introduction to footing, tyoes and permissible stresse in footing. |
*** |
*** |
| 54 |
design steps of isolated footing |
*** |
*** |
| 55 |
design example |
*** |
*** |
| 56 |
design steps of wall footing |
*** |
*** |
| 15 |
57 |
design example |
*** |
*** |
| 58 |
Introduction to retaining wall, forces and design criteria, stability requirement. |
*** |
*** |
| 59 |
cantilever and counterfort retaining wall |
*** |
*** |
| 60 |
design example |
*** |
*** |
