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FDM (Fused Deposition Modeling)

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Additive manufacturing technologies are systems developed as alternatives to traditional manufacturing methods, producing objects in three dimensions from digital models. Among these technologies, FDM (Fused Deposition Modeling) is a widely used additive manufacturing technique that operates by melting and depositing material layer by layer. Due to features such as low cost, system simplicity, and a broad range of available materials, it is preferred across various industries.

FDM distinguishes itself from other additive manufacturing methods such as SLS, SLA, and DMLS primarily through its low investment cost and ease of use. FDM printers can be used in prototyping workshops, schools, and even homes. However, they have certain limitations in terms of surface quality and mechanical properties. Parts produced via FDM may exhibit lower mechanical strength compared to those produced by methods such as laser sintering. Nevertheless, the ease of process control and the continuous expansion of material options enhance the advantages of this method.

Definition and History of FDM Systems

FDM was first developed in 1988 by Scott Crump and later commercialized by Stratasys. According to ASTM standards, the FDM process is classified under the heading "Material Extrusion" and is based on the principle of melting thermoplastic materials and depositing them layer by layer through a nozzle. Although initially developed for prototyping, today FDM is also used for the production of end-use parts.

Working Principle of the FDM Method

An FDM system consists fundamentally of three main components: a filament feeding system, a heating unit (nozzle), and a build platform. The process begins when a polymer-based filament is fed by a motor into the heated zone. The material is melted and extruded as a fine filament, which is deposited onto the build platform according to the specified geometry. After each layer cools and solidifies, the next layer is added on top until the object is fully formed in three dimensions.

Materials Used in FDM Technology

The primary materials used in FDM production are thermoplastic polymers. These polymers are suitable for layer-by-layer manufacturing due to their low melting temperatures and viscosity characteristics. The most commonly used materials include polylactic acid (PLA), acrylonitrile butadiene styrene (ABS), polycarbonate (PC), polyethylene terephthalate glycol (PETG), and nylon.

PLA is particularly favored for prototyping and educational applications due to its biodegradable nature and ability to be processed at low temperatures. ABS, on the other hand, is used in functional prototypes and engineering applications because of its higher impact resistance and heat resistance.

In recent years, composite filaments and polymers with functional additives designed specifically for FDM processes have gained attention. For example, PLA and ABS filaments reinforced with carbon fiber, glass fiber, or graphene are used to enhance mechanical strength and thermal conductivity. Additionally, specialized filament types have been developed that contain conductive polymers, antimicrobial additives, and flame retardants.

The properties of materials used in FDM are not only influenced by printing parameters but also by physical characteristics such as crystallization behavior, cooling rate, and coefficient of thermal expansion. Controlling these parameters directly affects the quality of interlayer adhesion and, consequently, the mechanical properties of the part.

Meanwhile, research into the use of recycled polymers in FDM processes is increasing from the perspective of environmental sustainability. Studies on the processability and performance of recycled materials such as PET, HDPE, and PLA highlight their potential to reduce environmental impact.

Application Areas

FDM technology is widely used across various sectors including automotive, aerospace, medical, education, and consumer electronics. In the automotive industry, it is employed for prototyping and part validation; in the medical sector, it is used for producing customized implants, orthoses, and prostheses. Additionally, in educational institutions, it serves as a supportive tool for teaching engineering design processes. Thanks to advancing material technologies, it is now possible to produce parts with conductive, heat-resistant, or biodegradable properties using FDM.

Medical and Biomedical Applications

FDM technology offers a broad range of applications in the medical field. It is particularly utilized for customized implants, prostheses, and in the field of biological tissue engineering. FDM-produced biomimetic structures enable the development of organic tissue production and medical devices compatible with the human body. Moreover, personalization and manufacturing of medical devices such as dental prostheses have become more efficient thanks to this technology.

Prosthetic protector produced via additive manufacturing (AA)

Electronics and Sensor Technologies

FDM plays a significant role in the production of electronic devices and sensors. Integrated circuits and sensor elements can be manufactured using electrically conductive filaments and polymer-based sensor matrices, providing alternative solutions to conventional electronic manufacturing methods. Moreover, FDM enables the production of lighter and more flexible electronic devices. These characteristics are particularly important for wearable technology and medical device manufacturing.

Circuit boards produced via additive manufacturing (AA)

Automotive and Aerospace Industries

In the automotive and aerospace industries, FDM has a wide range of applications from prototyping to functional part production. Aircraft and automobile components are manufactured using high-temperature-resistant materials and composites. FDM-produced prototypes are used in design validation processes, enabling faster production cycles and reduced costs. Furthermore, this technology provides efficient solutions in industrial part manufacturing by considering critical factors such as lightweighting and durability.

Automotive components produced via additive manufacturing (AA)

Educational and Research Fields

In educational institutions and research laboratories, FDM technology provides students and researchers with the ability to rapidly produce prototypes and conduct design tests. FDM printers enable the simple and low-cost production of complex geometries. Moreover, in academic research and experimental studies, models produced via FDM facilitate the visualization and testing of concepts.

FDM printers used in Deneyap workshops established for students (AA)

Art, Fashion, and Jewelry Design

FDM is transforming the fashion industry. Customized jewelry, accessories, and garments can be rapidly and cost-effectively produced using FDM printers. Complex geometries and personalized designs are made possible through this technology. By supporting more sustainable production processes, FDM enables the creation of individualized fashion designs.

Jewelry produced via additive manufacturing (AA)

Food Production

In food production, food inkjet printing has been developed to optimize nutritional content on an individual basis. This technology enables the production of food products tailored to individual dietary needs, offering personalized nutrition solutions in the food industry.

Food production via additive manufacturing (AA)

Construction Industry

In the construction industry, structures are built using concrete and cement-based materials. Additive manufacturing of buildings using FDM provides environmentally friendly and low-cost solutions. Additionally, due to the layer-by-layer production method, structural elements can be manufactured more quickly and with less labor.

Structure constructed via additive manufacturing (AA)

Bibliographies

Aisyah, S. N., & Widodo, A. (2021). Optimization of 3D printing process parameters on the FDM method using the Taguchi method. *ASSET: Journal of Technology and Vocational Education*, *1*(2), 99–106. https://journal2.upgris.ac.id/index.php/asset/article/view/1215/655

Aksöz, E. Ö., & Kıvak, T. (2023). Investigation of the mechanical and tribological properties of PLA/wood filament printed by fused deposition modeling (FDM) method. *Lubricants*, *13*(3), 98. https://www.mdpi.com/2075-4442/13/3/98

Arslan, E. (2021). Investigation of the effects of different nozzle diameters and print speeds on polymer parts produced by the FDM method. *Journal of Innovative Science and Engineering Technologies*, *4*(2), 49–56. https://dergipark.org.tr/tr/pub/jist/issue/61423/772977

Asiltürk, I., & Aslan, R. (2021). FDM tipi 3D yazıcılarla üretilen parçalarda farklı baskı parametrelerinin mekanik özelliklere etkilerinin incelenmesi. *Engineering Sciences (GMB Dergisi)*, *16*(1), 60–70. https://dergipark.org.tr/en/pub/gmbd/issue/81757/1392697

Gok, A., & Uzun, H. (2023). Dimensional accuracy improvement in fused deposition modeling (FDM) using statistical modeling and optimization. *The International Journal of Advanced Manufacturing Technology*, *125*, 3899–3918. https://link.springer.com/article/10.1007/s12008-023-01354-0

Mahapatra, S. S., & Sood, A. K. (2024). Mechanical characterization and dimensional precision in FDM printed parts. In A. K. Sood & S. S. Mahapatra (Eds.), *Additive Manufacturing Technologies From 3D Printing to Industry 4.0* (pp. 91–110). Springer. https://link.springer.com/chapter/10.1007/978-981-96-1274-1_5

Molla, M. K., & Mollick, M. M. R. (2023). Comprehensive review on advanced fused deposition modeling (FDM) printing process: Challenges and future directions. *Additive Manufacturing Letters*, *5*, 100228. https://www.sciencedirect.com/science/article/pii/S2590123025010175

Petry, L. A., Oliveira, M. M., Azambuja, D. S., and Amico, S. C. (2023). Effect of printing parameters on FDM 3D printed polylactic acid reinforced with graphene nanoplatelets. *Polymers*, *17*(2), 191. https://www.mdpi.com/2073-4360/17/2/191

Yücel, A., & Temiz, Ş. (2020). FDM ile üretilen kompozit yapıların mekanik özelliklerinin karşılaştırılması. *International Journal of 3D Printing Technologies and Digital Industry*, *4*(2), 99–110. https://dergipark.org.tr/tr/pub/ij3dptdi/issue/63100/838281

Çevik, S., & Tunçay, R. (2021). 3D baskı teknolojisiyle gıda üretimi ve uygulama alanları. *Eurasian Journal of Food Science and Technology*, *1*(2), 44–51. https://dergipark.org.tr/tr/pub/etoxec/issue/72705/1166445

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AuthorMustafa Enes BuldukDecember 8, 2025 at 1:23 PM

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Contents

  • Definition and History of FDM Systems

  • Working Principle of the FDM Method

  • Materials Used in FDM Technology

  • Application Areas

    • Medical and Biomedical Applications

    • Electronics and Sensor Technologies

    • Automotive and Aerospace Industries

      • Educational and Research Fields

      • Art, Fashion, and Jewelry Design

      • Food Production

      • Construction Industry

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