Silicon Carbide (SiC) is an exceptionally durable ceramic material, boasting superior thermal stability, electrical conductivity, chemical resistance, extreme hardness, low expansion rates and being ideal for space telescope mirrors.
Schunk Carbon Technology has developed an innovative process for 3D printing with silicon carbide that offers greater design freedom and increased reliability.
Binder jetting
Binder jetting is a 3D printing technique that employs liquid binder to fuse powder particles together, providing an economical yet eco-friendly 3D printing option for parts with complex geometries and difficult-to-reach surfaces. Binder jetting also produces parts much faster than traditional industrial 3D printing methods and requires fewer processing steps, saving both time and resources during production.
This process is also ideal for high-precision printing, providing objects with accuracy of 1 micron or better, which enables accurate component manufacturing without needing machining and polishing operations. Furthermore, its results produce strong and durable parts ideal for mechanical applications.
Producing large parts with this method is also possible, using a printer capable of producing up to one meter wide and tall pieces – perfect for producing machine parts with complicated shapes as well as printing with various materials such as silicon carbide.
Researchers utilized an amine-based printing binder and silica powder (b-SiC from Weifang Huamei New Mat Co. of China) for this experiment, in combination with polycarbosiloxance preceramic polymers as printing binder. Once their prints were complete, they underwent heat debinding and pyrolysis heat treatment in an oxygen-free kiln to extract carbon from their binder; this results in extremely hard surfaces resistant to blunt force or ballistic impacts.
This process is particularly suited for producing low-cost metal parts, full-color prototypes and large sand-casting cores and moulds – as well as mobile printing systems producing replacement parts for US Army soldiers.
Advantageous to other industrial 3D printing techniques is that this technique does not rely on support structures; unbound powder acts as its support structure instead and can accommodate multiple prints simultaneously. This enables rapid production of functional precision parts, such as End-of-Arm Tooling (EOAT), jigs and fixtures, dental aligner molds, orthotics/prosthetics devices, medical devices, automotive components, wire harnessing or fluid systems.
FDM
FDM 3D printing uses FDM filament that is heated and extruded layer by layer to produce objects. While not ideal for silicon carbide due to its extremely high melting point, FDM works great for a range of other materials like polyurethane and nylon and creates durable yet flexible parts with rubber-like qualities perfect for footwear or sports equipment applications.
additive manufacturing offers advantages over traditional manufacturing processes in terms of cost effectiveness, design flexibility, faster turnaround time and experimentation of new ideas. However, certain challenges must first be overcome before this technology can fully utilized; such as materials quality issues, post-processing issues and environmental considerations.
Silicon carbide not only stands up well under extreme temperatures, but its chemical stability and mechanical strength make it suitable for parts that must endure harsh chemical processing plant environments; additionally it makes an ideal material choice for pumps and bearings, providing superior wear resistance.
Silicon carbide’s key advantage lies in its versatility as an inkjet printer-printable material, enabling companies to easily create complex parts which would have otherwise been unattainable with traditional manufacturing techniques. This technology is especially advantageous to businesses looking to quickly and economically produce multiple prototypes quickly and easily.
Another key advantage of this technology is that it enables precise ceramic printing, eliminating tooling and machining costs, which saves considerable money. Ceramic material also boasts strong properties making it suitable for demanding applications in industries like aerospace and automotive.
3D printing uses a layer-by-layer approach, with the first layer serving as the base for further building of parts. As each layer is added on top of one another, its final shape becomes clear. Binders such as CONCR3DE’s particle-filled binder help increase density of finished parts while increasing mechanical properties and decreasing thermal mass and energy consumption for optimized fit in limited volume furnaces.
SLS
SLS 3D printing uses ceramic-based materials to produce intricate three-dimensional objects. The process starts with creating a digital design file containing geometry and dimensions of an object to be created, then using Sintering technology to convert that data into 3D models using ceramic powders.
Sintering occurs in a build chamber heated to the desired temperature for efficient sintering of powders. Powders are distributed across a build platform in layers from 50 microns up to 200 microns thick; then, lasers sinter their surfaces together into an object.
SLS printing has quickly become an indispensable component design and prototyping method in the automotive industry, providing lightweight parts that significantly decrease vehicle weight while improving fuel economy, and producing parts resistant to corrosion and wear. Additionally, SLS printers can print components with features designed for maximum resistance against wear.
SLS printers can use various materials, from ceramics and metals to silicon carbide (SiC). SiC is frequently utilized because it offers superior endurance, temperature resistance, hardness, and degree of hardness – qualities which make it suitable for aerospace and automotive manufacturing processes.
Aluminum is another potential material for SLS printing, commonly used in structural components and engine parts. AlSi10Mg is the go-to alloy when it comes to SLS printing of this type, as its composition features aluminum with silicon and magnesium and offers excellent corrosion resistance and thermal conductivity, making it suitable for high speed engines.
Other applications of SLS printers include medical and dental components. SLS printers can produce surgical guides and models from medical imaging data to help surgeons plan procedures more effectively and improve patient outcomes. Furthermore, SLS printers can create custom-fitted orthopedic implants tailored specifically for each patient’s anatomies.
SLS printing does have some drawbacks. Some manufacturers utilize toxic sulfates in their SLS powder; plant-based sulfates may come from palm oil production and lead to rainforest destruction and deforestation.
DMLS
DMLS (laser powder bed fusion or selective laser melting; SLM) is an additive manufacturing technology that employs high-powered laser beams to scan and fuse metal powder particles together, layer by layer. This creates strong and durable parts. DMLS is one of the most advanced additive manufacturing technologies available and can create complex geometrical components impossible to produce using other methods while at the same time reducing weight up to 80% without losing strength.
DMLS starts with creating a digital blueprint of the final component using CAD software, then cutting this blueprint into layers for use by the DMLS machine as guides in creating it layer by layer. This method ensures accurate parts with tight tolerances and fine features using various metals such as tool steels, stainless steels, aluminum alloys as well as nickel alloys and cobalt-chrome.
DMLS differs from SLM by using less energy to sinter metal particles into an aggregate form, resulting in superior detail resolution and lower production costs. DMLS machines also use smaller metal particles than SLS printers for thinner layers with better resolution.
DMLS provides an economical solution for industries requiring rapid prototyping. Due to its versatility and speed, it makes DMLS an attractive alternative to more costly fabrication techniques that take more time and resources to implement. Furthermore, using DMLS reduces mold costs as well as overall costs related to tooling requirements; further lowering overall costs during production.
DMLS is an ideal choice for the aerospace industry, as it can produce high-strength metal parts not possible to create through traditional means. DMLS technology has proven particularly valuable in automotive and medical industries where high precision components are essential. Furthermore, this technique can enhance existing metal parts’ strength and durability as well as consolidating multiple parts into one compact part to reduce costs and assembly time – it could even serve to create replacement components of old worn-out ones!