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3D PRINTING services

#SLS Selective Laser Sintering

is a 3D printing technology that uses a high-powered laser to selectively fuse powdered materials, typically polymers, layer by layer. The process starts with a bed of powdered material, and the laser precisely sinters the powder particles together based on a digital model, creating a solid object. This versatile and effective method enables the production of high-quality parts with precise dimensional accuracy, intricate details, and strong mechanical properties.

#MJF Multi Jet Fusion

is a 3D printing technology that uses a combination of inkjet printing and thermal fusing to create functional parts. It works by selectively applying a fusing agent to a layer of powdered material, followed by the application of an energy source to induce fusing. This process is repeated layer by layer, resulting in high-resolution, strong, and precise parts with excellent surface finish.

#SLA of different resins

is an additive manufacturing technology that uses a laser to solidify liquid photopolymer resin layer by layer, creating intricate and highly detailed 3D models. The process begins with a liquid resin bath, and as the laser selectively cures the resin, it solidifies and forms the desired object.

#DMLS Direct Metal Laser Sintering

is an advanced 3D printing technology that uses a high-powered laser to fuse metal powder particles together, layer by layer, to create complex metal parts. It offers high precision and allows for producing intricate designs with excellent mechanical properties, which may not be achievable through traditional manufacturing processes.

#LCM Lithography-based Ceramic Manufacturing

Is an advanced additive manufacturing technique that utilizes liquid photopolymerizable resins solidified through the use of ultraviolet, visible, or infrared light in a layered production process. To achieve specific shapes, photopolymers are selectively exposed using a system based on digital mirror devices. By incorporating a rotating building platform, this system can handle highly viscous resins and process solutions containing ceramic powders with high solid loading.

#FDM Fused Deposition Modeling

is a widely used 3D printing technology that works by melting and extruding thermoplastic filament through a heated nozzle. The printer moves the nozzle in a controlled manner, depositing the molten material layer by layer to build the desired object. FDM is known for its affordability, ease of use, and versatility, making it suitable for a wide range of applications.

#SLS Selective Laser Sintering

One of the key advantages of SLS is its ability to create objects without the need for support structures. The surrounding powder acts as a self-supporting material during the printing process, eliminating the need for additional support structures typically required in other 3D printing technologies. This makes SLS ideal for producing intricate and complex geometries that would be difficult or impossible to create using traditional manufacturing methods.

After the printing process is complete, the object is typically removed from the powder bed and undergoes post-processing. Excess powder is removed, and the object may undergo additional treatments such as polishing, sanding, or heat treatment to enhance its surface finish and mechanical properties.

Overall, SLS 3D printing offers a powerful additive manufacturing solution capable of producing complex, functional, and durable parts using a variety of materials. Its ability to create intricate geometries without the need for support structures makes it a valuable technology in various industries, driving innovation and expanding the possibilities of manufacturing.



One of the key advantages of DMLS is its ability to produce complex geometries and intricate internal structures that would be difficult or impossible to achieve with traditional manufacturing methods. The layer-by-layer approach allows for the creation of intricate shapes, internal channels, and lattice structures, which can enhance the strength-to-weight ratio of the final part.

During the printing process, support structures may be necessary to prevent sagging or distortion of overhanging features. These supports are typically made from the same metal powder and are removed after printing through various post-processing techniques.

Once the printing is complete, the object is typically subjected to post-processing steps to achieve the desired properties and finish. This can include removing supports, heat treatment to enhance mechanical properties, CNC machining for precise dimensions, and surface treatments like polishing or coating.

In summary, DMLS is a 3D printing technology that utilizes a laser to selectively melt and fuse metal powder layers, resulting in the creation of complex and high-quality metal parts. It offers versatility in material selection, enables intricate designs, and provides a cost-effective and efficient solution for producing metal components with excellent strength and precision.



SLA technology offers several advantages. It can produce highly detailed and intricate parts with smooth surface finishes, making it suitable for applications that require fine details and high resolution. The ability to create complex geometries, including thin walls and intricate internal features, sets SLA apart from other 3D printing technologies. SLA is often used for prototyping, product development, and creating master patterns for mold-making in industries such as automotive, aerospace, jewelry, and medical.

One consideration with SLA is the choice of materials. SLA resins are available in a wide range of formulations, including transparent, rigid, flexible, and even engineering-grade materials. However, the material choices for SLA may be more limited compared to other 3D printing technologies like FDM or SLS.

In summary, SLA is a 3D printing technology that uses a liquid photopolymer resin and a UV laser to selectively solidify and build up layers of an object. It offers high-resolution prints with excellent surface finish and is widely used for prototyping and creating detailed models across various industries.



MJF technology offers several advantages, including high productivity and fast printing speeds. It allows for the simultaneous printing of multiple parts within the same build volume, reducing production time and costs. Additionally, MJF is capable of producing functional parts with isotropic mechanical properties, meaning the strength and characteristics of the printed part are consistent in all directions.

MJF has found applications in various industries, including automotive, aerospace, consumer goods, and healthcare. It enables the production of end-use parts, prototypes, and customized components with complex geometries and high precision.

In summary, MJF is a 3D printing technology that utilizes inkjet printing and thermal energy to create functional and detailed parts. It offers fast printing speeds, an excellent surface finish, and the ability to produce complex geometries, making it a valuable tool for manufacturing diverse, high-quality objects.



LCM is a relatively new technology, but it has already been used to create a wide range of ceramic objects, including medical implants, dental restorations, and jewelry. It offers a number of advantages over traditional ceramic manufacturing methods, including:

    • High precision: LCM can be used to create objects with very high precision, down to the micrometer level. This is important for applications such as medical implants, where the fit and finish of the object are critical.
    • Complex geometries: LCM can be used to create objects with complex geometries that would be difficult or impossible to create using traditional methods. This makes it a good choice for applications such as aerospace and automotive engineering, where complex designs are often required.
    • High strength: Ceramic objects created using LCM are typically very strong and durable. This is because the laser curing process results in a very dense and uniform microstructure.

It is a promising technology that has the potential to revolutionize the way ceramic objects are made. It offers a number of advantages over traditional manufacturing methods, making it a good choice for a wide range of applications. As the technology continues to develop, it is likely to become even more widely used in a variety of industries.



FDM technology is known for its accessibility, ease of use, and versatility in material options. It supports a wide range of thermoplastics, allowing for the selection of materials with different mechanical properties, colors, and even specialty materials like conductive filaments or composite materials.

FDM is widely used for prototyping, rapid manufacturing, and producing functional parts across various industries, including automotive, aerospace, consumer goods, and education.

In summary, FDM is a 3D printing technology that utilizes a heated extruder to deposit and build objects layer by layer using melted thermoplastic filament. It offers a balance between affordability, ease of use, and material versatility, making it a popular choice for both professionals and hobbyists in the additive manufacturing field.