FDM (Fused Deposition Modeling) is a method of 3D printing that involves extruding small beads of thermoplastic material, which are then layered to build the final product. It is commonly used in the production of orthotics and prosthetics because it is relatively low-cost, easy to use and has a wide range of materials available.
The process of FDM 3D printing in the production of orthotics and prosthetics typically involves the following steps:
- Patient assessment and measurement:
The first step is to assess the patient’s condition and take measurements to determine the specific needs of the orthotic or prosthetic device. This may include taking casts or scans of the affected limb or joint, as well as measuring range of motion and functional capabilities. - Computer-aided design (CAD):
Using the information gathered during the patient assessment, a 3D model of the orthotic or prosthetic device is created using CAD software. The design takes into account the patient’s specific needs, as well as any functional requirements and aesthetic considerations. - Slicing the model:
After the design is complete, the 3D model is “sliced” into thin cross-sectional layers, typically around 0.1-0.3mm thick. These slices are then used to control the 3D printer during the printing process. - 3D printing:
The sliced 3D model is sent to the 3D printer, which melts a thermoplastic material (such as ABS or PLA) and extrudes it through a small nozzle. The printer builds the device layer by layer, according to the instructions from the sliced model. The device is built on a build plate, on top of a support structure that is removed after the build. - Post-processing:
After the device is printed, it may require additional post-processing, such as sanding or polishing, to smooth out any rough edges or improve its surface finish. - Finishing and fitting:
The device is finished with painting, or any other surface treatment, then it’s fitted to the patient and adjusted as needed to ensure a proper fit and optimal function.
FDM 3D printing allows for the efficient and cost-effective production of customized orthotics and prosthetics, and also enables the creation of unique and complex geometries that would be difficult to produce using traditional manufacturing methods. The process also allows for a fast turnaround time, which can be beneficial for patients who require a device quickly.
Reliability
Fused Deposition Modeling (FDM) is a widely used and reliable method of 3D printing, and it can produce high-quality orthotics and prosthetics. The FDM process is known for its accuracy and repeatability, and it can produce parts with good mechanical properties and surface finish. The technology is widely adopted in the industry, and many manufacturers have developed their own FDM printers, materials and software, which has increased the reliability of the technology.
However, like any technology, there are certain limitations to FDM 3D printing. The resolution of the printed parts is limited by the size of the extruder nozzle and the layer thickness, which can affect the surface finish and the accuracy of the printed parts. Also, the mechanical properties of the printed parts are dependent on the type and quality of the thermoplastic material used, which can be affected by different factors such as temperature, humidity, and the print conditions.
In general, FDM 3D printing is considered a reliable technology for the production of orthotics and prosthetics, but it is important to ensure that the printer, materials, and software are properly calibrated and that the printed parts are post-processed and inspected to ensure that they meet the required quality standards.
FDM 3D PRINTERS
There are a variety of FDM 3D printers available on the market, ranging from entry-level to professional-grade machines. Some of the most popular and easily available FDM 3D printers include:
- Prusa i3:
The Prusa i3 is a popular and reliable entry-level 3D printer that is known for its ease of use and affordable price. It is widely used in education, hobbyist and small scale production. - Ultimaker:
Ultimaker is a popular brand of FDM 3D printers that offers a range of machines, from entry-level to professional-grade models. They are known for their high-precision printing and reliable performance. - MakerBot Replicator:
The MakerBot Replicator is another popular FDM 3D printer that is known for its ease of use and high-quality prints. MakerBot is a well-established brand and offers various models, including the Replicator Mini+ which is a compact and easy to use machine. - FlashForge Finder: The FlashForge Finder is a budget-friendly, easy to use and compact 3D printer that is known for its reliability and high-quality prints. It is a great option for home or small office use.
These are just a few examples, and there are many other brands and models of FDM 3D printers available on the market, each with their own unique features and capabilities. It’s important to consider your specific needs and budget when choosing a 3D printer, and to research and compare different models before making a purchase.
WHY FDM 3D PRINTING
FDM (Fused Deposition Modeling) 3D printing is considered a better option than other 3D printing technologies in some cases because of the following reasons:
- Cost-effective:
FDM 3D printers are relatively low-cost compared to other technologies, making them accessible to a wider range of users, including hobbyists, educators, and small businesses. The materials used in FDM printing are also relatively inexpensive, which can help to keep the overall cost of production low. - Wide range of materials:
FDM 3D printing can use a variety of thermoplastic materials, such as ABS, PLA, TPU, and Nylon, which allows for a wide range of properties, such as flexibility, strength, and heat resistance. - High reliability and repeatability:
FDM 3D printers are known for their reliability and repeatability, which makes them suitable for producing multiple parts or for production runs. - Easy to use:
FDM 3D printers are relatively easy to use, with most machines having a user-friendly interface, which can help to reduce the learning curve for new users. - Customization:
FDM 3D printing allows for the creation of customized parts and devices, which can be tailored to the specific needs of each patient. This is particularly useful in the field of orthotics and prosthetics, where a high level of customization is often required. - High-resolution:
FDM 3D printing has a high resolution, which allows it to produce detailed and precise parts. - Widely adopted:
FDM 3D printing is widely adopted in the industry and in the field of orthotics and prosthetics, and many manufacturers have developed their own FDM printers, materials and software, which has increased the reliability of the technology.
It’s important to note that FDM 3D printing may not be the best option for every application, as it may have some limitations, such as limited resolution and mechanical properties of the printed parts are dependent on the type and quality of the thermoplastic material used.