Michigan Geotechnical and Ethics 30 PDH Discount Package 1

This online engineering PDH course presents the guidelines for calculation of the bearing capacity of soil under shallow and deep foundations supporting various types of structures such as buildings and houses, towers and storage tanks, fills, embankments and dams. These guidelines may be helpful in determining soils that will lead to bearing capacity failure or excessive settlements for given foundations and loads.

Bearing capacity is the ability of soil to safely carry the pressure placed on the soil from any engineered structure without undergoing a shear failure with accompanying large settlements. Applying a bearing pressure which is safe with respect to failure does not ensure that settlement of the foundation will be within acceptable limits. Therefore, settlement analysis should generally be performed since most structures are sensitive to excessive settlement.

This 10 PDH online course is applicable to civil, structural and geotechnical engineers, as well as design and construction personnel who are involved with foundation investigation and design.

This engineering online PDH covers the basic guidelines and principles of dam risk management.

Risk management is the overarching activity when risk is used to inform dam safety decision making and builds on risk analysis and risk assessment phases. It encompasses activities related to making risk-informed decisions, prioritizing evaluations of risk, prioritizing risk reduction activities, and making program decisions associated with managing a portfolio of facilities. Risk management includes evaluating the environmental, social, cultural, ethical, political, and legal considerations during all parts of the process.

This online engineering PDH course provides guidance for analyzing the static stability of slopes of earth and rock-fill dams, slopes of other types of embankments, excavated slopes, and natural slopes in soil and soft rock.

Slope stability criteria are presented for strength tests, analysis conditions, and factors of safety. The criteria are intended to be used with methods of stability analysis that satisfy all conditions of equilibrium. Methods that do not satisfy all conditions of equilibrium may involve significant inaccuracies and should be used only under the restricted conditions described herein.

This 4 PDH online course is applicable to geotechnical and structural engineers, as well as design and construction personnel working on projects involving slope stability analysis.

This online engineering PDH course presents essential roles and responsibilities of the tunnel staff, normal operating procedures, and emergency response guidelines for vehicle collisions, fires, explosions, floods and earthquakes.

Operating requirements vary among tunnel facilities because of the traffic level, the feasibility of alternative routes, accessibility to existing utilities, availability of emergency responders, and other conditions specific to each tunnel. Functional systems within the tunnel must be integrated with operational procedures to include the mechanical equipment, electrical components, lighting fixtures, fire and life safety systems, signs and security equipment installed within the tunnel.

This engineering online PDH course will provide an overview on the inspection of tunnel systems and the associated components.

This course focuses on developing safety inspections for highway tunnels. Some of the essential requirements of the NTIS are summarized to include the responsibilities of the tunnel inspection organization, qualifications of inspection personnel, inspection procedures and practices, and the different types of tunnel inspections. This course also explores health and safety issues for inspectors, inspection equipment, typical tunnel defects, owner defined elements, critical findings, and condition ratings. A glossary of selected terms and a list of references is also included at the end.

This engineering online PDH course will establish conditions under which, when an engineering failure has occurred, it can be attributed to negligence.    

Five causes of failure are proposed: negligence, rare failure mode, overlooked failure mode, new (previously unrecognized) failure mode, and incorrect assessment of a known risk. Negligence is the only cause that involves failing in an ethical duty.  These concepts are illustrated with five case studies of failures ranging from gross negligence to absolutely unforeseeable events: 1) the Great Boston Molasses Flood of 1919, for which a new possible cause was identified 95 years later (2014); 2) a building collapse in Bangladesh in which over 1,000 people died—one of the worst structural engineering disasters in history; 3) a meteorite strike of a private residence; 4) the crash of the British-French Concorde supersonic airliner, caused by an unlikely tire blow-out; and 5) radiation overdoses received by patients treated by the Thorac-25 medical linear accelerator, caused by errors in the software controlling the machine.