Energy Transition and the Imperative of Industrial Inspection
Introduction: The Criticality of the Energy Transition
The energy transition is not merely a goal; it is an existential imperative for nations, regions, and corporations committed to achieving climate neutrality. For industries such as mobility and energy, the transition to net-zero carbon emissions is essential for sustainable futures.
Technological Challenges in Energy Transition
The development of technologies that support the energy transition faces numerous challenges, chief among them being the assurance of quality and safety throughout the product lifecycle. Industrial inspection and non-destructive testing (NDT) are vital in this context. Early-stage implementation of these inspections—particularly during the design phase—can fortify solutions, reduce time to market, and thereby accelerate climate neutrality efforts.
Evolving Inspection Needs in New Energy Technologies
As energy transition technologies evolve, so too do the demands for industrial inspection. Below are key examples that illustrate emerging challenges within the mobility and energy sectors.
Lithium-Ion Batteries: Inspection Imperatives
Lithium-ion batteries are central to the electrification of transportation. However, they carry significant risks, both financially and in terms of safety. Effective quality inspection during battery manufacturing is crucial in mitigating potential sources of failure.
One critical issue is the overhang after electrode stacking. Here, the precise distance and alignment between the anode and cathode must be validated. A minimal gap risks a thermal event, releasing energy explosively, while an excessive gap diminishes the battery's energy storage efficiency.
Contamination is another concern. Foreign materials, such as welding residue or excess anode or cathode material, can lead to electrical shorts, potentially causing battery failure or thermal runaway. Modern NDT applications are essential for ensuring that batteries are free from such contaminants.
Electrode cutting introduces yet another potential problem. The process, which involves the precise cutting of coated foils for individual battery cells, can result in sharp edges that may puncture the battery pouch, leading to electrolyte loss. Inaccurate cuts also exacerbate the risk of electrical shorts and overall battery failure. Robust industrial X-ray and Computed Tomography (CT) solutions are crucial in addressing these issues.
Wind and Solar Energy: Inspection in Renewable Energy
Renewable energy sources, particularly wind and solar, are foundational to the clean energy future.
In wind energy, inspection is critical in mitigating failures in wind turbine gearboxes, which are prone to defects such as corrosion and cracks. Industrial borescopes and ultrasound techniques are commonly employed to determine whether gearboxes require repair or can continue in operation.
Wind turbine blades, exposed to severe environmental forces, are another area of concern. Inspections are conducted visually, often using drones or telescopes, to assess external damage. For internal defects, especially in composite materials, ultrasound testing is employed.
In the solar industry, the increasing size and complexity of photovoltaic (PV) modules pose significant challenges in identifying manufacturing defects and field failures. CT imaging and 2D X-ray techniques are valuable in testing the electronics within solar panels. Visual inspections, often drone-assisted, are commonly used to maintain existing PV installations.
Hydrogen: Inspection in Emerging Energy Sources
Hydrogen is a promising partner to renewable energy sources, yet its relatively nascent industry is fraught with challenges. Industrial inspection solutions are essential in minimizing risks across hydrogen generation, transportation, and storage.
A particular concern is hydrogen’s embrittlement effect on steel, which necessitates more frequent inspections and shorter maintenance intervals in pipeline infrastructure. Other focal points include improving the quality, performance, and safety of fuel cells, electrolysers, storage tanks, and distribution systems. Scaling up these solutions to meet the global demand for hydrogen necessitates extensive inspection to manage quality and safety risks.
For example, CT imaging of fuel cells can detect issues such as stack misalignment, defective sealings, and other anomalies like cracks or porosity, which compromise efficiency and safety. In storage and distribution, corrosion within piping remains a significant concern, particularly when pipes are insulated, complicating detection. Standard practices involve ultrasound thickness measurements and radiographic imaging, though the costs of false detections are substantial, given the need to remove insulation.
Moreover, hydrogen storage tanks require periodic and likely intensive inspections, guided by risk-based schedules. Electromagnetic and ultrasonic methods, often enhanced by advanced robotics, are employed to enhance both speed and safety during these inspections.
Conclusion: The Role of Industrial Inspection in the Global Energy Transition
The global energy transition represents a profound challenge with far-reaching implications for humanity’s future. The industrial inspection sector, with its sophisticated NDT applications, plays a critical role in ensuring the safety, reliability, and efficiency of new technologies designed to decarbonize industries worldwide.