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The carbon fiber X-ray table is extremely stiff and does not block x-rays. As a result, this material ensures high-quality scanning and prevents excessive X-ray radiation exposure, both of which are crucial when considering the impact on patients’ and staff members’ health.
For various purposes, there are three types of X-ray charts available: high contrast and ultra-high resolution types, as well as standard type.
Carbon fiber X-ray table-reinforced composite materials are used to make parts for aircraft and spacecraft, racing cars, golf club shafts, bicycle frames, fishing rods, car springs, sailboat masts, and many other parts that need to be light and strong.
In the field of medical devices, the carbon fiber X-ray table has one distinct advantage over other materials: it is radiolucent, which means that it is virtually transparent to x-rays and appears black on x-ray images.
There are numerous benefits to carbon fibers: high stiffness, high tensile strength, high strength-to-weight ratio, high resistance to chemicals, tolerance for high temperatures, and low thermal expansion. When you make changes to your car, you can use a carbon fiber X-ray table to get a sleek, durable, and light-weight addition to your vehicle.
The Global Carbon fiber X-ray table market accounted for $XX Billion in 2023 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2024 to 2030.
The introduction of a composite system by JCE components that makes it possible to quickly fix and release a variety of attachments that are necessary for the operating table to function effectively is one of the most important things we were able to accomplish.
We were able to virtually eliminate all obstructions that limited visibility in comparison to conventional solutions, and the tabletop has a translucent side rail that provides much better visibility of the patient. The most challenging task was to design and construct a composite material with a variable Young’s modulus and distinct elastic properties across its various sections.
Additionally, the structure had to be resistant to sudden changes in load. It required extensive research, testing, and trial and error. The finished product was unquestionably much more challenging than we initially anticipated. However, we have successfully completed the project and produced a product that meets all of those requirements.
Additionally, we have made a potentially significant contribution to healthcare.
