Method and measuring device for examining the hydrogen permeability of a test object
Fusion technology / energy
Ref.-No.: 1801-5807-WT
Background
In some industries, ensuring the airtightness of systems is often crucial, particularly when dealing with flammable gases like hydrogen. To address this, methods have been developed to test the tightness of materials using gases such as hydrogen. Conventional techniques involve introducing hydrogen on one side of the material and measuring leakage on the other. These methods typically rely on vacuum systems and electrical sensors, which require complex and expensive setups. Additionally, they are limited to single, non-continuous tests and fail to provide detailed, location-specific information about leaks. There is a clear need for a simpler, more effective approach that allows for continuous monitoring and provides spatially resolved data to pinpoint leak locations in real-time, ensuring material integrity without the drawbacks of the existing methods.
Technology
This invention focuses on testing the tightness of materials using a hydrogen-containing gas and an advances sensor system. The sensor, placed on one side of the material, features a hydrogen sensitive layer, for instance made of Yttrium (Y). On the opposite side, the material is exposed to hydrogen, which permeates through potential weaknesses. The sensor reacts by undergoing a detectable physical change, such as a color shift from Y to YH2, indicating the presence of hydrogen. Using patterned tiny sensor elements, in the example discontinuous Y pixels, allows for spatially resolved detection of hydrogen permeation across the material. This setup enables real-time, continuous, and non-destructive monitoring if material tightness. Figure 1 shows an example of how the technology is applied. The system effectively identifies areas where hydrogen permeates, as the microscopic images of Y indicator layers deposited on tungsten show (Figure 2). The technology’s ability to localize leaks across the surface of material makes it more efficient and cost-effective than traditional methods.
Advantages
- Simple and Cost-effective: Simplified design reduces the need for expensive equipment, lowering operational costs.
- Continuous Measurement: Enables continuous, real-time monitoring of hydrogen permeability for long-term assessments.
- Non-destructive Testing: Suitable for long-term testing a wide range of materials and thicknesses without causing damage.
- High Spatial Resolution: Provides precise, localized detection of hydrogen leaks, improving accuracy in identifying potential issues.
Applications
- Non-destructive Monitoring of Gas Pipelines: Early detection of damage points in pipelines exposed to hydrogen.
- Leak Detection in Vacuum Systems: Ensures the airtightness of vacuum systems or other sealed environments by identifying hydrogen leaks.
- Materials Science Research: Supports research into the causes and effects of hydrogen embrittlement in various materials.
Patent Information
PCT application (WO2021/224124A1), regionalized and pending in EP and US.
Priority date: 04.05.2020 (DE102020111959A1).
Publication
[1] A. Manhard, et al., Nuc. Mar. Energy, 36 (2023), 101498, https://doi.org/10.1016/j.nme.2023.101498
PDF Download
- Ref.-No.: 1801-5807-WT (2.1 MiB)
Contact
PD Dr. Wolfgang Tröger
Physicist
Phone: +49 89 / 29 09 19-27
Email:
troeger@max-planck-innovation.de