In the aerospace industry, industrial CT technology is employed to examine samples ranging in size from millimeters to meters. By utilizing in-situ loading devices, industrial CT can simulate various environmental conditions, including tension, compression, fatigue, and temperature, to monitor how the internal structure of samples changes over time. This approach assists in obtaining internal structural information that closely mirrors real-world working conditions.
Industrial CT scanning is a non-destructive imaging technique that harnesses the principles of X-ray transmission to achieve holographic scans of objects. It reconstructs data to provide clear, accurate, and intuitive representations of the internal structures and material defects of the inspected object in both three-dimensional and sliced formats. As a result, it is widely acclaimed as the leading technology for non-destructive testing in today's industry.
Industrial CT technology, with its outstanding density and spatial resolution, offers reliable inspection capabilities. It has become widely adopted in the additive manufacturing sector, encompassing areas such as quality control of additive powders, refinement of sample printing processes, and quality assurance for delivered components.
Industrial CT boasts a broad application scope in the automotive sector, encompassing the inspection of metal parts, non-metal components, and electronic components. Compared to traditional non-destructive testing, Industrial CT offers superior density and spatial resolution, presenting internal structures and defects in a clear 3D manner, thereby significantly enhancing the accuracy of inspection results. Notably, compared to traditional 2D X-ray inspection, Industrial CT eliminates the issue o
Industrial CT scanners enable non-destructive inspection of the internal structures of batteries, thereby identifying minute defects. These scanning techniques can detect issues resulting from substandard lithium battery production processes, such as misalignment of electrodes, electrode wrinkling, internal inclusion, and frequent battery accidents caused by electrode fractures due to charging and discharging. They cater to the inspection needs across all stages of battery production, from indiv
Industrial CT technology offers non-contact, non-destructive, and swift inspections with sub-micron accuracy and exceptional density resolution, becoming essential in contemporary engineering, materials science, and physics research.
X-ray equipment finds extensive applications not only in industrial research but has also given rise to a variety of detection systems in the field of public safety. These include X-ray security inspection systems, vehicle inspection systems, and backscatter inspection systems. These devices play a crucial role in safeguarding public safety by effectively detecting metal contraband, suspicious liquids, flammable and explosive solids and gases, as well as various military toxins and gases.
CT scanning of rock cores reveals variations in grayscale due to differences in atomic number/density among their internal components. This grayscale differentiation allows for a quantitative analysis of various components, enabling the extraction of data such as particle characteristics, porosity, including morphology, volume, surface area, and average particle size within the rock core.
Industrial CT technology has been extensively utilized in archaeological research, cultural heritage preservation, and digital museum displays. This technology presents the internal structure, composition, materials, and defects of inspected items in a clear, accurate, and intuitive manner using two-dimensional or three-dimensional digital images, all without causing any damage to the examined object.
The application of industrial CT technology in the field of flora and fauna is expanding. This includes areas such as plant growth analysis, pathological diagnosis, agricultural product quality inspection, paleobotanical research, genetic breeding, environmental adaptability evaluation, reproduction technique exploration, and analysis of animal skeletal and physiological structures.
