On-demand Webinar

View Important Policies and System Requirements for this course.

This webinar was co-sponsored by ASCE's Transportation and Development Institute (T&DI) and ASCE Continuing Education

Instructor:  David K. Hein, P.Eng.

Course Length: 1 Hour

Purpose and Background

Roller compacted concrete is a modified blend of concrete materials such as fly ash, Portland cement, water, sand, aggregates and additives that contains much less water than conventional Portland cement concrete. It has been in use for more than 50 years around the world and was initially used for dam construction as it was able to be placed quickly, had similar desirable properties to concrete and did not generate a high heat during hydration which can be a problem when placing mass concrete such as for dams. It began to be used in pavements, initially as a base or subbase but has been gaining more popularity in its use as a pavement surface. The RCC material is typically delivered by dump trucks and spread by specially modified asphalt concrete spreading equipment. RCC mixtures are compacted with the use of vibratory, tamper bar screeds, and typically but not always with static rollers to achieve a target density. RCC mixtures are relatively dry and depend on the stiffness as supplied to the job site to support the paver screed and rollers during placement and compaction operations. It does not require reinforcing or joint steel and is placed without forms.

This webinar outlines the basics of the RCC pavement and mix design, construction placement and finishing best practices and key features for the long-term sustainable performance of RCC pavements.

Primary Discussion Topics

  • Basics of RCC pavement thickness design
  • Subgrade preparation and materials for bases/subbases
  • RCC Materials and mix design
  • Construction
  • RCC detailing and transition treatments
  • Quality assurance/control
  • Key features to ensure pavement longevity

Learning Outcomes

Upon completion of this course, you will be able to:

  • Determine the key factors to determine the use of RCC for pavements
  • Appreciate the importance of key design features
  • Recognize important pavement material requirements
  • Identify construction requirements to ensure success
  • Identity the factors that may impact the performance of RCC pavements

Webinar Benefits

  • Describe what to look for during construction to ensure high quality
  • Learn about RCC use and pavement design, materials selection and construction
  • Understand locations where RCC can be a cost effective pavement alternative
  • Recognize key RCC pavement design inputs and their impact on performance
  • Discuss the importance of pavement layer materials/properties
  • Understand the elements that may impact the long-term performance

Assessment of Learning Outcomes

Students' achievement of the learning outcomes will be assessed via a short post-assessment (true-false, multiple choice and fill in the blank questions).

Intended Audience

  • Civil engineers responsible for the design, construction, maintenance and rehabilitation of pavements
  • Agencies and other owners of highway, municipal and private sector pavement infrastructure
  • Pavement material suppliers and contractors
  • Operations personnel responsible for the maintenance and rehabilitation of pavements

Webinar Outline

  • Overview of RCC pavements and their differences from conventional pavements
  • Key consideration in the selection of RCC for a project
  • Overview of the key inputs of common RCC pavement design procedures
  • Materials selection and RCC mix design
  • Basics for construction to ensure performance
  • Target quality control/assurance processes for success
  • Recognize key design and construction features that impact performance

How to Earn your CEUs/PDHs and Receive Your Certificate of Completion

To receive your certificate of completion, you will need to complete a short on-line post-test and receive a passing score of 70% or higher within 1 year of purchasing the course.

How do I convert CEUs to PDHs?

1.0 CEU = 10 PDHs [Example: 0.1 CEU = 1 PDH]