Material Development (Custom Material Systems)

Custom material systems for additive manufacturing

Material Development may include:

• adjustment of mechanical, thermal, optical, electrical or chemical properties
• tuning of viscosity, reactivity, curing behaviour, jetting behaviour, powder interaction or binder performance
• optimization for specific printer architectures, wavelengths, light power, jetting heads, powder systems or thermal routes
• customization for post-processing, cleaning, curing, debinding, sintering or sterilization workflows
• adaptation to regulatory, safety, biocompatibility or industrial handling constraints
• versioning of material systems for defined implementation windows
• balancing process stability, printability, manufacturability and end-use performance

All customization work is performed within defined project scope and validated according to the intended material platform, technology route and application requirements.

Customizable material families

Material development can address multiple 3Dresyns® technology and material platforms, including:

• vat photopolymerization materials for SLA, DLP, LCD and MSLA systems
• inkjet and material jetting photopolymers
• Two-Photon Polymerization (2PP) materials for nano and microfabrication
• volumetric additive manufacturing materials
• NIL, UV / EB photoresists and advanced microfabrication systems
• Lithography-based Metal Manufacturing (LMM) binders
• direct print-to-sinter ceramic, metal and exotic loaded systems
• powder binders for SLS, cold metal fusion, cold ceramic fusion and related powder routes
• ceramic, metal, glass, polymer and exotic powder feedstock slurries for injection into printed molds
• sacrificial, soluble, castable and mold-making systems
• additives, auxiliaries, fine tuners, color systems and functional modifiers
• UV / visible-light curable adhesives, putties, gels, fillers and sealants

Performance and process tuning

Typical customization objectives include:

• improving printability on specific printers or manufacturing systems
• increasing resolution, precision or dimensional accuracy
• enhancing toughness, flexibility, rigidity, thermal resistance or impact behaviour
• reducing brittleness, warping, cracking, shrinkage or porosity
• optimizing transparency, refractive index, colour or surface finish
• adjusting reactivity for faster or slower processing
• improving jetting stability, droplet behaviour or viscosity-temperature response
• adapting binders for debinding, burnout, sintering or powder consolidation
• improving sacrificial removal, water solubility, solvent solubility or clean burnout
• developing application-specific handling, safety or documentation logic

Each project balances material performance, process stability and manufacturability.

Material development is not only formulation change

3Dresyns® integrates material design with the complete manufacturing workflow, including:

• printing parameters, exposure strategy, jetting strategy or powder-processing logic
• post-processing, curing, debinding or sintering workflows
• cleaning chemistry, washing protocols and handling constraints
• compatibility with additives, auxiliaries and fine-tuning systems
• alignment with printer architecture, recoating, peeling, optical power or thermal process windows
• dimensional control, shrinkage interpretation and repeatability

This ensures that customized material systems are designed for real implementation, not only for laboratory formulation performance.

Development route selection

Custom material development may support direct printing, indirect manufacturing or hybrid workflows depending on the final material objective.

• Direct AM: the material is printed as the final or near-final geometry.
• Indirect AM: the printed object is a mold, pattern, core, support, sacrificial structure or manufacturing intermediate.
• Print-to-sinter routes: the printed or shaped body is debound and thermally converted or sintered.
• Binder and powder routes: the material system supports powder consolidation, shaping or downstream densification.

The correct development route depends on final performance, density, purity, resolution, equipment, scale-up and manufacturing cost.

Application-dependent constraints

When required, material development projects may address:

• biocompatibility-oriented formulation and workflow constraints
• dental, medical, research or healthcare-related application requirements
• food-contact, low-odour, low-toxicity or handling constraints where applicable
• sterilization, cleaning, post-curing or residual species control
• documentation alignment with safety and regulatory frameworks

Final validation, qualification, certification and regulatory approval remain the responsibility of the legal manufacturer or end user.

Controlled development model

Material development projects are conducted under appropriate confidentiality and project-boundary conditions.

• confidentiality and non-disclosure frameworks where required
• clearly defined intellectual property boundaries
• controlled access to technical documentation
• defined scope for formulation, testing and supply

Customized material systems are developed as proprietary material platforms supplied by 3Dresyns® under controlled manufacturing conditions to support reproducibility and quality consistency.

Disclosure of full formulation architecture, detailed chemical composition or synthesis routes is not part of standard Material Development services. Material Development does not constitute formulation transfer unless a separate Technology Transfer framework has been explicitly agreed.

Typical customer profiles

Material Development programs are typically used by:

• industrial manufacturers
• medical and dental device developers
• research institutions and laboratories
• start-ups developing proprietary products
• service bureaus requiring differentiated materials
• technology developers working on new AM processes
• companies scaling from R&D to pilot or production workflows

Projects can range from targeted material adjustment to complete development of new additive manufacturing material systems.