3D printing is a modern technology that involves converting digital designs into physical objects by adding layers of pre-existing materials. In the industrial field, this technology is considered revolutionary, offering users numerous benefits in intelligent design and diagnosis, including customization.
How to 3D Print Prosthetics:
1. Digital Design:
Prosthetic limb design begins with a specialized program such as CAD (Computer-Aided Design), where specialists customize the prosthetic according to the patient's condition and needs. These can include classic limb designs such as the foot or hand, as well as additional features such as movable joints.
2. Using 3D Scanning:
In some cases, the body is scanned using a 3D scanner to accurately document the shape and measurements of the amputated parts. This data is used to create a digital model that matches the person's body.
3. Layer Printing:
After legal translation, the files are sent to a 3D printer. This printer attempts to produce products such as plastic, fiberglass, or metal to produce another product, as the new industry is built better. 4. Testing and Customization:
After the prosthesis is printed, it is tested to ensure quality and proper fit. The design can be easily modified as needed, allowing for complete customization.
Benefits of 3D Printing in Prosthetics:
1. Personalization:
One of the biggest benefits of 3D printing is the ability to customize the prosthetic to each patient's specific needs. It can be designed to fit the exact shape and function of the body, making it more suitable for larger and better-performing patients.
2. Low Cost:
Conventional prosthetics, which can be reliable, can be made independently using more expensive 3D printing technology, especially in developing countries. This technology helps reduce costs and improve the choice of prosthetics.
3. Speed ​​and Efficiency:
Prosthetics can be designed and manufactured much more quickly using 3D printing compared to traditional methods that require manual processing. A commercial drug has been produced in just a few days.
4. Design Difference:
3D printing has made significant progress in prosthetic research design. Teamwork, such as a partially integrated tiger or an internal snowflake, can be incorporated, providing tremendous strength and better support. They can also be classified according to a specific nuclear node, such as running or various sports.
5. Ability to print using products:
A variety of materials can be used in 3D printing, including flexible materials that can mimic natural movement, as well as rigid materials that provide durability and strength. These include plastics, fibers, and structural materials.
6. Recyclability:
Recycled materials can be used in 3D printing, helping to reduce waste as well as negative impact.
Disadvantages and Challenges:
1. Material Limitations:
Although 3D printing requires a comprehensive range of materials, some materials may not be able to meet the specific strength and durability requirements of some patients. Some components, including the flat head, may not be sufficient for new limb prostheses.
2. Technology is Still New:
Although 3D printing is still in development, its uses in industrial manufacturing are still in their infancy. This technology may need to be customized to further improve performance.
3. Challenges:
Instructions and designers may face challenges when using this technology, especially when it comes to producing prosthetic parts or requiring precise fitting. These challenges may include unique production.
4. Long-Term Sustainability:
While the 3D printing industry provides solutions, some researchers may need to replace or maintain their materials, especially if they contain product parts that could deteriorate or deteriorate over time.
The Future of 3D Printing in Industrial Research:
1. Smart Eradication:
As technology advances, it has become a leader in industrial printing, enabling more "smart" 3D electronic devices with advanced built-in sensors, such as pressure or positioning, to perform.