Indiana Professional Engineers Professional Development Courses
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Indiana Professional Engineers Packages
30-Hour Online Renewal Package
WHY IT’S FOR YOU
- You are a licensed Professional Engineer in Indiana and need to renew your license.
- You prepare, sign, seal and submit engineering plans and drawings to a public authority for approval, or to seal engineering work for public and private clients.
- You prefer to take your continuing education via self-paced online due to your busy schedule and availability.
- This package contains 30 hours of online instruction which consists of 2 hours of mandatory topics and 28 elective hours.
WHAT’S INCLUDED
30-Hours of Online Indiana Professional Engineer Renewal Courses
Customer Phone and Email Support 7 Days a Week
Completion Certificates for Indiana included
COURSES INCLUDED
Critical Facilities and High Wind Safety (5 hrs)
Bridges: Upkeep and Repairs for Professional Engineers (4 hrs)
Concrete and Masonry Wall Buildings: Earthquake Repairs for Engineers (3 hrs)
Ethical Practice in Engineering and Land Surveying (mandatory topic) (3 hrs)
Constructable Highway Design (2 hrs)
Engineering and Surveying – An Uncommon Language (2 hrs)
Introduction to Wind Energy (2 hrs)
Observation of Rainfall Practices (2 hrs)
Indiana Statutes and Rules for Professional Engineers (mandatory topic) (1 hr)
30-Hour Correspondence Renewal Package
WHY IT’S FOR YOU
- You are a licensed Professional Engineer in Indiana and need to renew your license.
- You prepare, sign, seal and submit engineering plans and drawings to a public authority for approval, or to seal engineering work for public and private clients.
- You prefer to take your continuing education via correspondence due to your busy schedule and availability.
- This package contains 30 hours of online instruction which consists of 2 hours of mandatory topics and 28 elective hours.
WHAT’S INCLUDED
30-Hours of Correspondence Indiana Professional Engineer Renewal Courses
Customer Phone and Email Support 7 Days a Week
Completion Certificates for Indiana included
COURSES INCLUDED
OC: Critical Facilities and High Wind Safety (5 hrs)
OC: Bridges: Upkeep and Repairs for Professional Engineers (4 hrs)
OC: Concrete and Masonry Wall Buildings: Earthquake Repairs for Engineers (3 hrs)
OC: Ethical Practice in Engineering and Land Surveying (mandatory topic) (3 hrs)
OC: Constructable Highway Design (2 hrs)
OC: Engineering and Surveying – an Uncommon Language (2 hrs)
OC: Introduction to Wind Energy (2 hrs)
OC: Observation of Rainfall Practices (2 hrs)
OC: Indiana Statutes for Professional Engineers (mandatory topic) (1 hr)
Indiana Professional Engineers Courses
Ethical Practice in Engineering and Land Surveying
Ethical Practice in Engineering and Land Surveying
Indiana Statutes and Rules for Professional Engineers
Indiana Statutes and Rules for Professional Engineers
A Discussion of the Notre-Dame Cathedral
A Discussion of the Notre-Dame Cathedral
Becomeknowledgeable about the unusual construction features of the Notre-Dame in thepast and present.
ADA Standards for Accessible Design
ADA Standards for Accessible Design
Alternative Energy Sources
Alternative Energy Sources
Amusing Ourselves Safely
Amusing Ourselves Safely
COURSE HIGHLIGHTS:
- Look at essential design principles used to create the world’s greatest roller coasters using the ASTM Standard F2291 Standard Practices for Design of Amusement Rides and Devices
- Learn details of the revolutionary design of several classic toys
- Discuss how the ASTM Standard F1148 Standard Consumer Safety Performance Specifications for Home Playground Equipment applies to designing a safe platform for children’s equipment
- Explore ASTM F963 Standard Consumer Safety Specifications for Toy Safety to show how to design toys for stability
Basics of Drinking Water Well Construction
Basics of Drinking Water Well Construction
Basics of Fire Protection Systems
Basics of Fire Protection Systems
Bridge Inspections: An Overview for Professional Engineers
Bridge Inspections: An Overview for Professional Engineers
Bridges: Upkeep and Repairs for Professional Engineers
Bridges: Upkeep and Repairs for Professional Engineers
In this course, you will explore preventative maintenance and describe common maintenance tasks, common repairs, and understand the methods used to repair, strengthen, or replace members, especially timber members. Finally, you will identify repairs and upgrades relevant to concrete bridges.
Building Safe Structures in Flood Zones
Building Safe Structures in Flood Zones
Calculations of Hydrologic Design Peak Flows
Calculations of Hydrologic Design Peak Flows
COURSE HIGHLIGHTS:
- Learn how to use the NSS program to estimate flood-frequency statistics (e.g., 5-year or 100-year flood) for hydrologic basins in all states
- Review different procedures for NSS setup, input preparation, and extracting results on flood peaks and other streamflow statistic
- Gain insights on the automated procedure for input preparation using Geographical Information System (GIS) web-based tools
Community Rating Systems: An Overview
Community Rating Systems: An Overview
Concrete Hydraulic Structures: Evaluations for Earthquake Scenarios
Concrete Hydraulic Structures: Evaluations for Earthquake Scenarios
Concrete and Masonry Wall Buildings: Earthquake Repairs for Engineers
Concrete and Masonry Wall Buildings: Earthquake Repairs for Engineers
The criteria and procedures are based on the evaluation of the anticipated seismic performance of a subject building at three different times:
a) in its condition immediately before the damaging earthquake (pre-event)
b) in its damaged condition
c) in its repaired or upgraded condition
Constructable Highway Design
Constructable Highway Design
Constructed Wetlands for Wastewater Treatment
Constructed Wetlands for Wastewater Treatment
Critical Facilities and High Wind Safety
Critical Facilities and High Wind Safety
This course is designed to fulfill continuing education credits in health, safety and welfare for professional architects. This course will cover identifying critical facilities and evaluating their risk for damage caused by high winds. It will then explore various methods of making critical facilities safe from damage caused by high winds. By completing this course, the learner will better understand strategies for mitigating and preventing wind damage to critical facilities.
Design Storms: An Overview
Design Storms: An Overview
Design and Maintenance of Gravel Roads
Design and Maintenance of Gravel Roads
EPA Safe Drinking Water Act & Water Treatment Processes
EPA Safe Drinking Water Act & Water Treatment Processes
Energy Codes and Standards for Professional Engineers
Energy Codes and Standards for Professional Engineers
Understanding the importance of energy code guidelines and standards allow for more sustainable and ultimately desirable construction. Compliance to energy code guidelines and standards can be achieved by following a three-step approach. In this course, you will learn which three steps allow to lay the foundation for compliant engineering design that avoid unnecessary change orders and save energy and client resources.
Energy: Its Effect on our World and Lives
Energy: Its Effect on our World and Lives
Engineering and Surveying – an Uncommon Language
Engineering and Surveying – an Uncommon Language
This course is intended to be of benefit to both surveyors and engineers by removing one of the most common roadblocks to effective collaboration, communication. The class will dissect a design project considering both engineer and surveyor perspectives and discuss specific issues that can (will) arise. Although this class examines a land development project the subject matter and lessons learned are applicable to any surveyor/engineer interactions.
The leaning objectives are threefold:
1) understand survey criteria – what is and is not included;
2) examine the needs of the engineer;
3) understand how to make the two compatible.
Fly Ash Concrete
Fly Ash Concrete
COURSE HIGHLIGHTS:
- Learn the make-up of fly ash concrete
- Discuss the pros and cons of its use.
Fundamentals of Power Distribution
Fundamentals of Power Distribution
This course is an introduction to the basic principles,major equipment, protection and control systems relating to high-voltage powerdistribution and transmission. In this course, you will learn the basics inconstructing and maintaining a power transmission and distribution system, aswell as various components of the system.
Fundamentals of Solar Energy
Fundamentals of Solar Energy
In this course, we will give a general overview of the fundamentals of solar energy, including its definition, usage, types, and applications. We will further cover sources, location issues, and statistical data derived from a U.S. government database. There will also be an explicit description of the current applicability of solar energy across both industrial and residential sectors.
Course Learning Objectives
At the conclusion of this course, participants will be able to:
• Illustrate a detailed understanding of the solar energy concept, definition, and harvesting
• Explain the conversion of solar energy and the current consumption process
• Demonstrate comprehension of the concepts related to the technical phenomena as well as the working principles of the solar cell and solar energy, which are utilized to produce useful energy from the sun
• Explain the term solar radiation and how it is collected and converted into useful energy to support various entities like power industries and residential communities
• Summarize the PV system and its components and describe its use in converting solar light into electricity
• Differentiate the alternative methodologies that utilize solar power with a focus on how the conversion process is applied to support industrial and residential applications
• Illustrate a practical example of a solar collector layout and application
• Describe how to calculate certain
Heavy Loads: An Overview for Engineers
Heavy Loads: An Overview for Engineers
In this course, you will describe the criteria for the design of concrete floor slabs on grade in building for heavy loads and is applicable to all elements responsible for military construction. Heavy loads in buildings such as a warehouse include moving loads, stationary live loads, and wall loads.
Introduction to Earth Retention Structures
Introduction to Earth Retention Structures
COURSE HIGHLIGHTS:
- Review basic soil mechanics principles, along with common field and laboratory soil testing procedures
- Examine the methods used for calculating the factors of safety for sliding, overturning, bearing capacity, and shallow/deep shear failure modes
- Apply your knowledge through a case study of a wall failure situation which includes many of the common pitfalls of wall design
Introduction to Hydraulic Fracturing
Introduction to Hydraulic Fracturing
Introduction to Wastewater Treatment
Introduction to Wastewater Treatment
Introduction to Wind Energy
Introduction to Wind Energy
Making Critical Facilities Safe from Flooding
Making Critical Facilities Safe from Flooding
Mitigating Terrorist Attacks for Engineers and Building Designs
Mitigating Terrorist Attacks for Engineers and Building Designs
Municipal Wastewater Treatment Systems
Municipal Wastewater Treatment Systems
Observation of Rainfall Practices
Observation of Rainfall Practices
This course is designed to provide students with an overview of rainfall measurement and estimation from a hydrologic engineering perspective. The course will cover different methods for rainfall measurement, including the use of automated rainfall measurements, and their respective advantages/disadvantages. Coverage of different sources of rainfall data best suited for civil engineering applications is also provided.
Observations on the Performance of Critical Facilities
Observations on the Performance of Critical Facilities
Power Distribution Fundamentals
Power Distribution Fundamentals
Project Management for the Engineer
Project Management for the Engineer
Residential Storm Rooms
Residential Storm Rooms
Solar Thermal Energy: Concentrating the Sun
Solar Thermal Energy: Concentrating the Sun
COURSE HIGHLIGHTS:
- Discuss the basic components commonly found in the main types of CSP facilities: mirrors, receivers, and tracking systems, along with the ancillary components
- Review heat processes that can utilize the primary and secondary thermal output from CSP systems
Stabilizing Soils for Pavements
Stabilizing Soils for Pavements
Steel Moment Frame Construction Policy Guide
Steel Moment Frame Construction Policy Guide
The History and Future of Domes
The History and Future of Domes
COURSE HIGHLIGHTS:
- Examine the Romans’ Pantheon Dome to introduce the structural elements of domes: meridians, parallels and materials such as concrete
- Discover how modern domes are engineered and what loads must be considered in the design
- Explore the stories behind the building of Istanbul’s Hagia Sophia – a cathedral built 14 centuries ago that can still astonish a modern-day engineer – as well as one of the most revolutionary domes in the history of building: The Duomo (Dome) of the Basilica di Santa Maria del Fiore in Florence
The National Disaster Recovery Framework: An Overview
The National Disaster Recovery Framework: An Overview
Uses of Geotextiles in Engineering
Uses of Geotextiles in Engineering
OC: Ethical Practice in Engineering and Land Surveying
OC: Ethical Practice in Engineering and Land Surveying
OC: Indiana Statutes and Rules for Professional Engineers
OC: Indiana Statutes and Rules for Professional Engineers
OC: A Discussion of the Notre-Dame Cathedral
OC: A Discussion of the Notre-Dame Cathedral
OC: ADA Standards for Accessible Design
OC: ADA Standards for Accessible Design
OC: Alternative Energy Sources
OC: Alternative Energy Sources
OC: Basics of Drinking Water Well Construction
OC: Basics of Drinking Water Well Construction
OC: Bridge Inspections: An Overview for Professional Engineers
OC: Bridge Inspections: An Overview for Professional Engineers
OC: Bridges: Upkeep and Repairs for Professional Engineers
OC: Bridges: Upkeep and Repairs for Professional Engineers
OC: Community Rating Systems: An Overview
OC: Community Rating Systems: An Overview
OC: Concrete Hydraulic Structures: Evaluations for Earthquake Scenarios
OC: Concrete Hydraulic Structures: Evaluations for Earthquake Scenarios
OC: Concrete and Masonry Wall Buildings: Earthquake Repairs for Engineers
OC: Concrete and Masonry Wall Buildings: Earthquake Repairs for Engineers
The criteria and procedures are based on the evaluation of the anticipated seismic performance of a subject building at three different times:
a) in its condition immediately before the damaging earthquake (pre-event)
b) in its damaged condition
c) in its repaired or upgraded condition
OC: Constructable Highway Design
OC: Constructable Highway Design
OC: Constructed Wetlands for Wastewater Treatment
OC: Constructed Wetlands for Wastewater Treatment
OC: Critical Facilities and High Wind Safety
OC: Critical Facilities and High Wind Safety
OC: Design Storms: An Overview
OC: Design Storms: An Overview
OC: Design and Maintenance of Gravel Roads
OC: Design and Maintenance of Gravel Roads
OC: EPA Safe Drinking Water Act and Water Treatment Processes
OC: EPA Safe Drinking Water Act and Water Treatment Processes
OC: Energy Codes and Standards for Professional Engineers
OC: Energy Codes and Standards for Professional Engineers
OC: Engineering and Surveying – an Uncommon Language
OC: Engineering and Surveying – an Uncommon Language
This course is intended to be of benefit to both surveyors and engineers by removing one of the most common roadblocks to effective collaboration, communication. The class will dissect a design project considering both engineer and surveyor perspectives and discuss specific issues that can (will) arise. Although this class examines a land development project the subject matter and lessons learned are applicable to any surveyor/engineer interactions.
The leaning objectives are threefold:
1) understand survey criteria – what is and is not included;
2) examine the needs of the engineer;
3) understand how to make the two compatible.
OC: Fundamentals of Power Distribution
OC: Fundamentals of Power Distribution
This course is an introduction to the basic principles,major equipment, protection and control systems relating to high-voltage powerdistribution and transmission. In this course, you will learn the basics inconstructing and maintaining a power transmission and distribution system, aswell as various components of the system.
OC: Fundamentals of Solar Energy
OC: Fundamentals of Solar Energy
Course Learning Objectives
At the conclusion of this course, participants will be able to:
• Illustrate a detailed understanding of the solar energy concept, definition, and harvesting
• Explain the conversion of solar energy and the current consumption process
• Demonstrate comprehension of the concepts related to the technical phenomena as well as the working principles of the solar cell and solar energy, which are utilized to produce useful energy from the sun
• Explain the term solar radiation and how it is collected and converted into useful energy to support various entities like power industries and residential communities
• Summarize the PV system and its components and describe its use in converting solar light into electricity
• Differentiate the alternative methodologies that utilize solar power with a focus on how the conversion process is applied to support industrial and residential applications
• Illustrate a practical example of a solar collector layout and application
• Describe how to calculate certain performance and design parameters such as surface temperature, heat transfer rates, and energy consumption