3D Printing Services

We offer a comprehensive 3D printing service for small to medium-sized batches of parts made from polymers and metals.

Based on your 3D CAD model, we print the product or a small series of products.
From a drawing, we create a 3D CAD model and print it.
If you bring us an existing product, we scan it using a 3D scanner, create a 3D CAD model, and print it. This process is called reverse engineering.

We provide advice on selecting the appropriate technology and materials.

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Fast production of complex shapes with excellent precision and productivity

Reduce production time and lower costs for small batch manufacturing. Depending on the selected printing technology, we can print your products in as little as one day. Our 3D printing services do not require expensive casting tools or time-consuming CNC machining, where most of the material is wasted as scrap.

We offer 3D printing of products using MBJ, BMD, SLS, DLP, and FDM technologies.

MBJ Technology (Metal Binder Jetting) for metal 3D printing is known for its high productivity and cost efficiency. Compared to DMLS, it is significantly faster and more affordable. MBJ-printed parts have mechanical properties comparable to those made by casting. We use this system to print 17-4PH stainless steel (1.4542).
BMD Technology (Bound Metal Deposition) is ideal for printing individual parts. It is user-friendly and supports a wide range of metal alloys, including 17-4PH, 316L, and 304L stainless steels, 4140 chromium-molybdenum steel, tool steels such as A2 (DIN 1.2363), D2 (DIN 1.2379), H13 (DIN 1.2344), IN625 and IN718 nickel alloys, Ti64 titanium alloy, and copper.
SLS Technology (Selective Laser Sintering) for polymer powder 3D printing is perfect for manufacturing final components, prototypes, tools, and small batch products where high mechanical properties, precision, and complexity are required.
DLP Technology (Digital Light Processing) for 3D printing with photopolymer resins is widely used in industries like dentistry, jewelry, design, and for producing functional models, prototypes, and small batch tools.
FDM Technology (Fused Deposition Modeling) offers flexible and cost-effective solutions across various industries. With a wide selection of materials, it supports rapid iteration, reduces development costs, and is ideal for small batch production of final products.

Printed parts can also undergo further mechanical processing, including grinding, milling, turning, drilling, reaming, and more.

Overview of Available Technologies

Metal Binder Jetting

Metal Binder Jetting (MBJ) is a 3D printing method based on sintering that enables the production of highly precise parts from powder materials.

The fine metal powder is evenly distributed across the build area, ensuring precise layer thickness. The inkjet printhead moves across the powder layer, selectively depositing a liquid binder, similar to glue, onto the powder, defining the cross-section of the desired part. This process is repeated until the part reaches its full height. The working frame, containing both bound and loose powder, is then removed, and the freshly printed parts are carefully extracted and prepared for sintering. The sintering process occurs in an industrial furnace, where the parts are exposed to temperatures close to the material's melting point, consolidating the structure to full density. Additional steps, such as machining or heat treatment, may be employed to achieve the desired properties.

We utilize the Desktop Metal Shop system, ideal for both single-piece and serial production. We print using stainless steel 17-4PH (1.4542), and the printed parts exhibit full density, comparable to those produced through traditional methods. These parts can be further refined with post-processing techniques such as milling, turning, grinding, and more.

Key Features: Exceptional surface finish and resolution, surpassing laser-based 3D printing systems. The result is isotropic, full-density metal parts free from internal stresses. This technology is a perfect solution for complex geometries that are either impossible or inefficient to produce with conventional methods.

Tehnologija je primerna za tiskanje malih ali srednje velikih serij izdelkov.

Printer Build Volume: 350 x 222 x 200 mm

Sintering Oven Capacity: 10 kg

Layer Thickness: 50, 75, or 100 μm

Bound Metal Deposition

Bound Metal Deposition (BMD) is a 3D printing method based on the thermo-extrusion of a special filament.

Similar to FDM technology, the polymer binder in the filament is melted here. The process begins with extruding the melted filament through a nozzle, which builds the part layer by layer based on the 3D model. After printing, the part undergoes a debinding process, where the polymer binder is removed. This is followed by sintering in a furnace, where the metal powder is melted at high temperatures close to the material's melting point, allowing the metal particles to fuse and solidify, resulting in the part achieving nearly full density.

For 3D printing of individual parts, we use the Desktop Metal Studio system, which allows for fast and easy material changes. We offer printing with alloys such as 17-4PH (1.4542), 316L, copper, and Inconel IN625.

Printer build volume: 300 x 200 x 200 mm

Printing capacity: 6,5 kg

Layer Thickness: 50 - 150 μm (high-resolution printhead) ali 150 - 300 μm (standard resolution printhead)

Selective Laser Sintering

Selective Laser Sintering (SLS) is a 3D printing technology in which a laser beam selectively fuses polymer powder particles into three-dimensional objects.

The process occurs in a closed chamber where powder (most commonly nylon) is applied in thin layers. The laser heats and sinters specific areas according to the CAD model. After each layer, the powder bed is raised, and the process repeats until the product is complete. After printing, the unused powder supports the object, enabling the creation of complex shapes without support structures. SLS is used to produce mechanically durable prototypes and functional end products.

We use the 3D Systems SLS300 system, which offers high precision, complex shapes, and functional properties, making this technology popular in industrial engineering. Selective laser sintering is used in numerous applications, from functional prototypes to final products, due to its ability to produce durable and complex parts.

The most commonly used materials are PA 12 (Polyamide 12), reinforced polyamides (PA12 GF, PA12 CF), and TPU (Thermoplastic Polyurethane).

It is ideal for producing final components, prototypes, tools, and small series of products where excellent mechanical properties, precision, and complexity are required. It is often used in industrial engineering production, automotive, aerospace, and biotechnology, where optimizing properties and complex geometries is crucial.

Printer working space: 300 x 300 x 300 mm

Precision: 0.1 mm

Printing speed: 12 mm/h

Digital Light Processing

Digital Light Processing (DLP) technology for 3D printing leverages a digital projector to project an image of each layer onto a liquid resin surface.

The process employs a digital projector, which uses a digital micromirror device (DMD) to project the entire layer of the model onto the resin's surface. Here, UV or visible light selectively cures the exposed parts. As the platform moves upward to create a new layer, the process repeats until the model is complete. The synchronized curing of entire layers makes DLP technology faster than SLA (Stereolithography) and ensures exceptionally high accuracy and fine detail resolution.

The ETEC D4K DLP 3D printer, known for its precision and speed, is widely used in industries requiring small, detailed parts and smooth surfaces. Its applications span dentistry, jewelry making, the design industry, and the production of functional models, prototypes, and tools in small batches.

It supports various photopolymer resins that cure upon light exposure, including standard resins, engineering resins, biocompatible resins, and castable resins.

Due to its accuracy and the ability to create complex shapes without the need for supports, DLP technology is ideal for applications where fine details and smooth surfaces are paramount.

Print area: 143 x 83 x 110 mm

Layer height: 25 - 150 μm

Printing speed: 45 mm/h

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Fused Deposition Modeling

Fused Deposition Modeling (FDM) is a 3D printing technology where molten thermoplastic filament is deposited layer by layer through a heated nozzle.

Moving along the X, Y, and Z coordinates, the heated nozzle deposits material layer by layer until the model is fully formed. The most commonly used materials are PLA, ABS, and PETG. The advantages of FDM technology include low cost, ease of use, and a wide range of materials. Disadvantages are lower precision compared to some other more complex technologies and visible layer lines on the model's surface.

For printing with FDM technology, we use Bambu Lab X1 E, X1 Carbon Combo, P1S Combo, and A1 Mini Combo printers, which are known for their user-friendliness and affordability, making this technology suitable for both home and industrial use. FDM, also referred to as FFF (Fused Filament Fabrication), extrudes thermoplastic material in precise layers, enabling the creation of geometrically complex models without the need for expensive tools or molds.

FDM printers support a wide range of materials, such as PLA, ABS, PETG, TPU, nylon, and various reinforced materials (glass and carbon fibers).

Thanks to the diverse selection of materials and printing flexibility, FDM provides customized solutions for nearly every industry. It allows for rapid iteration, reduces development costs, and is ideal for producing small series of finished products.

Print area: 256 x 256 x 256 mm

Layer height: 0.1 mm

Print head speed: 500 mm/s

Product Examples

Chess figurine

A chess figurine printed with Metal Binder Jetting.

Rings for Casting

A tree with rings, designed for casting multiple rings at once.

Bike Seat Prototype

A prototype for a bike seat, with PAHT and TPU 95A HF filaments used.

Mechanism Part

Part of a mechanism for a packaging machine in the food industry.