CAD model of the robot inspecting a wire cable
The bearer cables and tethers of bridges,
elevators, and cable cars are exposed to high levels of stress. For this
reason, their functional reliability must be monitored on a regular basis. A
new robot recognizes fissures before they pose a danger
Slowly, very slowly, the robot climbs up the wire
cable. As it crawls upward with caterpillar-like movements, it scans the steel
surface and detects whether it has any defects. Researchers at the Fraunhofer
Institute for Nondestructive Testing IZFP have named the system FluxCrawler. It
is designed to monitor the quality of stay cables and wire ropes on a regular
basis. Such cables are common features of bridges, elevators, cranes, cable
cars, and ski lifts. And these checks are vital, as the tension-induced strain,
wear, and corrosion that affect these steel cables mean that they are under
enormous stress
By conducting a magnetic flux leakage test, the
robot not only identifies tiny fissures in the cable surface, it also
recognizes deeper cracks. This process exposes the cable to a magnetic field
that is disrupted in the event of a defect. A measurable leakage field is
created wherever defects are located.If such micro-fissures are not discovered
in time, the steel can break. This is why material checks are absolutely vital
to avoid deadly consequen- ces or even catastrophes, says Dr. Jochen Kurz, an
engineer and department head at IZFP in Saarbrücken
Test system is suitable for many cable sizes
While the testing of steel cables using magnetic
flux leakage is already a common approach, until now coils were used that had
to clasp the cable. But this posed a problem: since the diameter of steel
cables and their jackets vary considerably, the coilslimited diameter range
meant that they could only be used in a limited number of instances. Moreover,
they were unable to locate the exact angle of a defect. In contrast,
FluxCrawler can be applied regardless of a cables diameter. The robot, which is
about seventy centimeters long, scans cylinder-shaped surfaces by revolving
around the cable. As a result, there is no need to clasp the cable. A permanent
magnet prevents slipping and holds FluxCrawler to the cable. At the same time,
it generates the magnetization required to make measure- ments. Between the two
ends of the u-shaped magnet, a line of sensors equipped with several probes is
able to rapidly scan the surface. While FluxCrawler moves around the cable,
these sensors can identify the exact angle of the defect: they recognize whether
defects are on the left, on the right, on the bottom or on top of the cable.
The robot can carry out checks on cables with diameters ranging from four to 20
centimeters. The battery-operated platform is controlled with a computer via
Bluetooth. An image of the magnetic field on the cable entire surface appears
on the computer, and each conspicuous spot is illustrated in high resolution on
the computer screen
Cooperation with the French Carnot Institute
FluxCrawler is the result of FilameNDTproject (NDT
is short for nondestructive testing). Jochen Kurz and his team from IZFP are
cooperating with the French Carnot Institute VITRES-IFFSTAR to further develop
magnetic leakage testing as well as other non- destructive testing methods.
These include using Electromagnetic Acoustic Transducers (EMAT) and
micromagnetic testing methods, the latter being used for monitoring purposes. It
should be noted that FluxCrawler cannot be used in all situations. For
instance, the robot cannot recognize defects in covered areas, for instance in
the area where the cable is anchored. To detect defects in such cases, we apply
another non-destructive testing method, namely, EMAT, says Kurz. To do this,
the researchers create a guided ultrasound wave with a transducer that is
placed directly on the cable. The wave penetrates the material and is reflected
when it hits a flaw. The signals that are sent back to the computer are used to
reconstruct an image. The computer uses this image to analyze the physical
changes that the wave perceives in the material, and can thus determine the
situation in the materials interior. As a result, the seriousness of even the
smallest of flaws can be determined
A monitoring system is already being tested at a bridge in Mettlach,
Germany that is currently undergoing renovation. Kurz and his team are
confident that FluxCrawler will soon be used in everyday practice to diagnose
defects: the team has already received enquiries from industry. The robot is
now patented, and the researchers have already successfully tested cables in
the laboratory. In the next step, tests will be conducted at DMT GmbH, a cable
testing facility in Bochum that comprises a testing laboratory for
non-destructive and destructive testing.

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