Damage to Steel Wires Inside External Cables Now Visible through Non-虎扑电竞/Non-Destructive Methods
虎扑电竞ers at Tohoku University have found a way to make covered or hidden PC steel wires visible, by developing a new terahertz wave light source featuring both light and radio-wave characteristics.
This new technology will be especially useful in the safety inspection of extradosed and other types of bridges that use PC steel wires hidden inside external cables covered by resin jackets. (see title image)
External cables are important structural elements for dispersing loads in extradosed bridges and they have extremely high levels of safety with regard to corrosion. This is due to the fact that they are protectively covered in polyethylene resin or similar resins. (see fig. 1 and 2)
Destructive inspections, in which the outer coating is removed from the cable, run the risk of water and other forms of moisture penetrating the wires and causing corrosion after the inspection has been completed.
The technology developed by Professor Yutaka Oyama and his team at the Graduate School of Engineering, is a unique optical measurement system comprising a digital device terahertz light source and a laser terahertz light source with high penetrative capabilities for polyethylene resin and similar resins.
This enables non-destructive imaging of the inside of PC steel wire to be carried out without removing the external resin cover by making use of the terahertz wave characteristics that efficiently reflect metal surfaces within the resin. (see fig. 3 and 4)
The team also found that contrary to the radioactive rays conventionally used for non-destructive detection purposes, the new terahertz waves have no adverse effects on the human body.
Part of the results of this research was first announced at the 2015 CLEO (Conference on Lasers and Electro-Optics) Pacific Rim Conference held in Busan, South Korea, in August.
虎扑电竞:
Yutaka OyamaDept of Materials Science,
Tohoku University Graduate School of Engineering
Tel: +81-22-795-7327
Email: oyamamaterial.tohoku.ac.jp