Press release of June 29, 2023
Using particle showers to scan the interior of structures
HZDR researchers seek to harness muon imaging for bridges, chemical parks, and Castor containers
Production plants like the ones at the Ludwigshafen Chemical Park are set to benefit in the future from non-destructive condition monitoring via particle showers from space. Picture: Fotolia (now: Adobe Stock) | eyetronic | Download
Earth is constantly being struck by cosmic particles. High-energy muons can easily penetrate several meters of steel or concrete. A team at the Helmholtz-Zentrum Dresden-Rossendorf (HZDR) seeks to harness the potential of this unavoidable background radiation to view the interior of industrial facilities or structures. The problem is that muon detectors used in high-energy physics at research centers such as CERN are highly sensitive and expensive. This is why tomography experts at the HZDR are now developing a demonstrator – a low-cost, large-scale, and high-resolution muon detector for non-destructive condition monitoring. The Helmholtz Association is providing €500,000 in funding for the project over a period of two years as part of its transfer campaign. The project is set to start on July 1, 2023.
According to the Federal Highway Research Institute, one in ten bridges in Germany is dilapidated. Corrosive attacks on concrete reinforcement have a major impact, which is why bridges are checked regularly. Continuous monitoring of production facilities is also essential in the basic materials industry, incurring enormous costs. Distillation columns up to 50 meters high, large steel casting plants, and rotary kilns for waste incineration must be brought to a standstill, because this is the only way to detect signs of wear. And what about the condition of the spent fuel elements currently kept in storage casks at Germany’s 17 interim storage facilities?
Left: Schematic of muon imaging on a CASTOR cask. The muon detectors are placed above and below. The material distribution of the cask causes slight deflections of the muon paths.
Right: Cross-sectional image of the material distribution in the cask reconstructed from simulated muon paths. The square basic shapes of the 19 fuel elements stand out yellowish in the image. | Source: HZDR | Download
“In theory, muon imaging is ideal for such applications,” emphasizes Professor Uwe Hampel, departmental head at the HZDR’s Institute of Fluid Dynamics. For example, it was in early March that the media again reported on a chamber discovered in 2017 in the 4,500-year-old Great Pyramid of Giza. What is a sensation for archaeologists owes much to muon imaging.
Muons are a component of cosmic rays. The charged particles are extremely energetic and penetrate deep into materials. This is why high-resolution detectors can be used to obtain three-dimensional images of the interior of large industrial facilities and structures.
“However, existing detector types are not sufficiently robust for monitoring, and are far too expensive,” explained the expert in imaging techniques in energy and process engineering. The cost drivers are complex manufacturing on the one hand, and the number of electronic channels required for high-resolution images on the other.
Clever adaptation to obtain inexpensive and robust detectors
It is hoped that new ideas will now help muon imaging achieve a breakthrough: One such idea is a detector concept with a special matrix structure for the electronics, which Hampel’s team originally designed for a patented wire-mesh sensor.
“Our structure is characterized by the ability to locate and transmit signals in the area with high efficiency, and then evaluate them using algorithms developed in-house. We have already managed to transfer this scheme to muon detectors,” Uwe Hampel reported.
In principle, the matrix structure is suitable not only for the wire electrodes of a gas ionization detector, but also for the optical fibers of a scintillation detector. Yet another advantage: Thanks to the sophisticated addressing scheme, both the number of electronics channels and the detector costs can be drastically reduced.
In the MYTOS project, which has received €500,000 in funding, experts at the HZDR are taking on the task of comparatively analyzing different detector principles. “We are particularly interested in whether the test detectors prove to be robust in an industrial environment, i.e. in the event of temperature fluctuations or vibrations,” Uwe Hampel explained.
Armed with the knowledge gained, he and his team of experienced measurement engineers and scientists plan to build a prototype and test it experimentally in collaboration with potential users. Also on board are BASF, EWN Entsorgungswerk für Nuklearanlagen [EWN Nuclear Waste Disposal Plant], and the Bundesanstalt für Materialforschung und -prüfung [Federal Institute for Materials Research and Testing, BAM].
As yet, the idea is limited to inspecting plants and structures using modular, mobile detectors at regular intervals. But Uwe Hampel is pursuing a clear vision: “In the long term, we want to reduce the cost of sensors and measurement technology to such an extent that stationary long-term monitoring becomes feasible.”
Further information:
Prof. Uwe Hampel
Institute of Fluid Dynamics at HZDR
Professorship for Imaging Techniques in Energy and Process Engineering at TU Dresden
Phone: +49 351 260 2772 | Email: u.hampel@hzdr.de
Media contact:
Simon Schmitt | Head
HZDR Communications and Media Relations Department
Phone: +49 351 260 3400 | Email: s.schmitt@hzdr.de
