For inspections of concrete on dam structures, accessibility can be a major challenge. Surface inspections have often required the used of extensive scaffolding and rope systems, exposing personnel to potentially hazardous working conditions.

There is little doubt that inspections could be carried out in a safer, more efficient manner with the use of robotic machines. Although existing machines on the market could be used for inspection purposes with some modifications, they may not be suitable for the large vertical surfaces found on dam structures.

As a result, EPRI put out a request for proposals for robotic technology that is: rugged enough for outdoor deployment; equipped with enough battery or independent power to operate for four days; flexible enough to carry a variety of inspection devices to detect different types of flaws; and able to traverse rough surfaces.

A range of ideas were submitted, and EPRI’s choice for further evaluation was a concrete crawler from International Climbing Machine, which was designed to negotiate concave, convex, or overhanging vertical structures while carrying over 40 pounds of equipment.

Held to the surface by vacuum force, the crawler has been deigned to adhere to essentially any hard surface. The patented, highly flexible seal ensures the machine is securely adhered as it moves the machine over surface obstacles such as bolt heads, plates, weld seams or virtually any surface irregularity. The vacuum chamber is surrounded by a rolling foam seal that guards against leakage and facilities propulsion.

The crawler, which was essentially a remote-controlled climbing vehicle, now acts as a platform for automated inspection and advanced nondestructive evaluation of major concrete structures at power plants. It applies onboard systems, including simultaneous localization and mapping (SLAM) technology and advanced NDE instrumentation developed for concrete applications, to conduct automated, high-precision inspections and to capture computer-encoded data and images for maintenance decision-making.
This data will support realtime condition assessment and long-term monitoring of degradation and aging processes to guide maintenance decision-making and risk-informed management for hydro assets.

Demonstration project
In July this year, EPRI, in collaboration with New York Power Authority (NYPA), American Electric Power, Exelon, the Southwest Research Institute, International Climbing Machines (ICM), the University of Texas at Austin and Rutgers University, put the concrete crawler to the test at NYPA’s Niagara power plant.

The robot was attached to the dam wall and was controlled using a commercially available controller. As part of the test, the team used an acoustic sensor to check for delamination, and used a mapping system for positioning.

"When you’re taking data on structures such as this, you want to know where you are on the structure, so you have to measure it with a tape measure," said Michael Blanton, Southwest Research Institute. "With a mapping system you alieviate that manual inspection process. Every little shift in the robot, every little turn, you’re able to pick that up and track it. We saw exactly what we needed to see."

Other technology demonstrated included Air coupled echo technology, and Infrared thermography.

"Infrared thermography is where we use a thermal camera to look at the heat that is being emitted from a structure, and that can tell us a lot about what’s there, whether its delamination, or if a repair is good or bad," commented Jeremy Renshaw of EPRI. "Essentially, we can do a rapid screening of the entire dam, and then go back with a more detailed, precise inspection, with something that could be installed on the crawler over a smaller area."

Future plans
The tests allowed the research team to identify potential developments to the system, such as a new control system. Maria Guimaraes, senior project manager at EPRI, said that the team will eventually be able to use an IPad to control the crawler. "We are currently developing the IPad communication system, so users will eventually be able to control all aspects of the crawler from a single interface."

Other improvements being planned include reducing the size of the sensor payload and equipping the crawler with a variety of interchangeable sensors. There is also the potential to use technologies which are not typically used in the assesment of structures, for example moisture measurement.

A fully functional first-generation prototype will be constructed and evaluated in diverse industry settings during 2014, with further refinements and field tests expected which will lead to the development of specifications for a commercial inspection robot. This robot is expected to help deliver unprecedented insights on concrete degradation and aging processes.

"We are in the initial phase of testing, but this device shows great potential for advancing the industry’s concrete inspection process," concluded Maria Guimaraes. "By the end of the year we’d like the data that can be collected by this robot to provide a real-time, accurate assessment of the conditions and integrity of concrete."

A call to action
Updates on the concrete crawler are provided on www.epri.com and through the advisory structures of the Technology Innovation Program and the Nuclear, Generation, and Environment & Renewable Energy sectors. EPRI seeks utilities and vendors to support development and field demonstration of autonomous, highfidelity inspection technology for cooling towers, hydro dams, and
reactor containment structures.