This short course should be of interest to geotechnical engineers, structural engineers, and civil engineers who wish to have a better understanding of the current, state-of-the-art with respect to the analysis and design of pile foundations. All key concepts and terminology will be explained and emphasis will be placed on the practical application of the information provided.
This course is a comprehensive two days deep foundations course dealing with bored, driven, and helical screw piles foundations. Major emphasis will be on the analytical methods and the problem solving aspects of the design and construction of pile foundations. This course provides the participants with an opportunity to apply the design procedures to "real life" challenging foundation design projects.
The main objective of this course is to equip the participants with the needed tools to select the best pile foundation solution for each particular project. After completing the course, participants should be able to design deep foundations and supervise their construction. The course philosophy is to provide the participants with the information they need to design foundations at the state of the art.
Structural, civil, and geotechnical engineers, consulting engineers, technicians and technologists, public works and construction department employees of federal, provincial, and municipal governments and engineers responsible for large industrial, commercial, or institutional facilities who must deal with different types of foundations, and foundation construction contractors.
The two-day course consists of a series of lectures and workshops. Worked examples with numerical reference reinforce the lecture content. Case studies that illustrate the full range of problems are a feature of the course. In addition, a comprehensive pile design workshop will be conducted under the instructor guidance.
- Subsoil Exploration:
- Purpose of soil exploration
- Subsurface exploration program
- Geophysical exploration
- Interpretation of soil parameters for deep foundations design
- Analysis and Design of Pile Foundations for Vertical Loads:
- Types of deep foundations
- Bearing capacity of single piles in sand, bearing capacity of single piles in clay
- Empirical analysis (Correlation with standard field tests)
- Pullout capacity of piles, estimation of pile length, stresses on underlying strata
- Bearing capacity of pile groups
- Pile caps, pile driving formulas, negative skin friction
- Settlements of single piles and pile groups
- Analysis and Design of Pile Foundations for Lateral Loads:
- Lateral capacity of single piles in sand, lateral capacity of single piles in clay
- Lateral capacity of pile groups
- Lateral deflection of single piles and pile groups
- Bearing and Uplift Capacities of Helical Screw Piles:
- Bearing capacity of single-helix and multi-helix piles in sand
- Bearing capacity of single-helix and multi-helix piles in clay
- Uplift capacity of single-helix and multi-helix piles in sand
- Uplift capacity of single-helix and multi-helix piles in clay
- Capacity of pile groups
- Pile design workshop
- Questions, answers, and feedback to participants on achievement of learning outcomes
- Concluding remarks and final adjournment
- Judge when deep foundations should be considered.
- Recognize the failure modes of deep foundations.
- Determine the bearing capacity of deep foundations.
- Describe procedures for construction inspection and performance monitoring of deep foundations, and
- Achieve confidence in the design of pile foundations.
Associate Professor of Geotechnical Engineering, Dalhousie University
Hany has more than 20 years of experience in civil construction, geotechnical, and structural engineering and research in Canada and overseas. He has participated in several structural and geotechnical investigations, and is experienced in analysis and design of foundations and soil-structure interaction of buried infrastructure. Dr. El Naggar and his research team has investigated the soil-structure interaction (SSI) effects around buried infrastructure, explored innovative use of tire derived aggregate (TDA) as a buffer zone to create stress arching and reduce demand on rigid culverts, proposed an earth pressure reduction system using geogrid reinforced platform bridging system to reduce stresses on buried utilities, and developed innovative “cellular” precast concrete pipe system. He also has developed a simplified technique to account for the group effect in pile dynamics, and closed form solutions for the moments and thrusts in jointed and un-jointed composite lining systems, designed several foundation systems ranging from machine foundations subjected to dynamic loads to raft foundations for underground structure, as well as several tunnels and underground structures in the United States, Europe, and Canada.
The findings from Dr. El Naggar’s research have been reported in more than 65 technical publications covering both experimental and numerical work in the fields of soil-structure interaction, buried infrastructure and concrete pipes. He is the recipient of the 2005–2006 Outstanding Teaching Award from the Department of Civil and Environmental Engineering at Western. Prof. El Naggar won the 2006 L. G. Soderman Award, the 2005 R.M. Quigley Award, and the 2004 Milos Novak Memorial Award. Dr. El Naggar is the current chair of the Buried Structures Committee, CSCE; also, he is member of the technical committee on buried structures of the Canadian Highway Bridge Design Code (CHBDC). In addition, he is the current editor-in-chief of the International Journal of Civil Infrastructure.