Self-Repair & Interlayer Welding — Additives for 3D resins
Self-repair and interlayer-welding additives for 3D resins, developed to improve layer bonding, repairability and long-term toughness in advanced additive manufacturing workflows.
3Dresyns® additives in this collection are positioned for formulations where stronger interlayer cohesion, crack resistance and controlled repair concepts are part of the target material design.
Navigate by: interlayer welding, self-heal activation, repair assistance and release-assisted rework route.
This collection groups 3Dresyns® additives for self-repair, interlayer welding and repair-assisted photopolymer formulation strategies.
These materials are intended for projects where stronger bonding between printed layers, durability under repeated loading and repairable-part concepts are important development targets.
Key features & benefits
Choose your repairable additive route
Use the routes below to navigate the collection by repair logic, booster role and release-assisted rework concept.
- Interlayer welding and self-repair concepts for 3D-resin formulation development.
- Supports improved layer bonding, enhanced toughness and crack resistance depending on system.
- Useful for better durability under cyclic stress and long-life functional-part tuning.
- Suitable for advanced formulation R&D in engineering, molds & tooling and selected optics & photonics projects.
Typical applications
Typical use scenarios across the collection
This collection is relevant for projects where repairability and interlayer cohesion are part of the material-performance objective.
- Durable functional prototypes: parts designed for longer useful life under repeated use.
- Parts under repeated loading: components exposed to cyclic stress where damage tolerance matters.
- Interlayer strength improvement projects: formulations targeting better bonding between printed layers.
- Repairable part concepts: materials designed around rework or recovery logic.
- Advanced formulation R&D for toughness and longevity: development programmes seeking stronger, longer-lasting printed parts.
Why choose this collection
How to choose the right self-repair or welding additive
Select the most suitable route according to whether the project needs direct self-heal action, repair boosting, interlayer welding or release-assisted rework.
- Need a direct self-heal temperature-targeted route → choose 3D-ADD SH
- Need a photo/thermal assist repair booster → choose 3D-ADD SHB1 Self-Heal Booster
- Need stronger interlayer welding and rebonding → choose 3D-ADD ReBond Weld
- Need release-assisted rework or circular repair concepts → evaluate Circular RePrint DP80 or DP150
- Prioritise stronger interlayer cohesion → start with ReBond Weld
- Prioritise self-repair activation → start with SH or SHB1 depending on repair mechanism design
- Prioritise release-assisted rework logic → start with DP80 or DP150 depending on temperature window
Decision tree summary
Use this simplified engineering logic before detailed formulation validation.
- Need self-heal behavior → SH
- Need a repair booster → SHB1
- Need interlayer welding → ReBond Weld
- Need release-assisted rework → DP80 / DP150
Then validate the final route under the intended resin family, additive loading, exposure strategy, thermal conditions and repair protocol.
Products in this collection
Temperature-targeted self-heal additive
For formulations designed around direct self-repair logic activated through a temperature-targeted route.
Photo / thermal assist self-heal booster
For projects that require a booster-type additive supporting self-repair or assisted recovery concepts.
ReBond interlayer welding additive
For formulations focused on stronger bonding between printed layers and repairable rebonding behavior.
Warm-release and high-temperature release additive concepts
For projects where repair, release or rework concepts are linked to additive-assisted circular or detachable workflow logic.
Technical overview table
Workflow-dependent performance
Interlayer bonding, self-repair response, crack resistance and final durability depend on the interaction between the selected additive, the base resin, additive concentration, exposure strategy and any thermal-assist or repair protocol used.
Successful implementation therefore requires alignment between additive selection, target repair mechanism, formulation strategy and qualified processing workflow.
| Material | Primary role | Core concept | Main behavior | Typical positioning | Target workflow |
|---|---|---|---|---|---|
| 3D-ADD SH | Self-heal additive | Temperature-targeted repair | Direct self-repair concept for photopolymer formulations | Durable parts and repairable-part R&D | Advanced self-heal formulation development |
| 3D-ADD SHB1 | Repair booster | Photo/Thermal assist booster | Supportive repair-assist concept | Projects requiring enhanced self-heal activation logic | Repair-boosted formulation development |
| 3D-ADD ReBond Weld | Interlayer welding additive | Self-repair & rebonding | Improved layer bonding and rebonding concept | Interlayer strength improvement and long-life functional parts | Interlayer welding focused formulation R&D |
| DP80 | Warm-release additive | Release-assisted rework | Lower-temperature release concept | Repair/rework workflows using warm-release logic | Circular or detachable additive-assisted development |
| DP150 | High-T release additive | Release-assisted rework | Higher-temperature release concept | Repair/rework workflows using high-temperature release logic | Circular or detachable additive-assisted development |
Mobile: scroll horizontally to view all columns. The first column remains visible while scrolling.
Portfolio overview
A repair-mechanism platform rather than a single functional modifier
This collection is structured around multiple repair-related concepts, allowing users to approach durability from different formulation angles: direct self-heal, boosted repair, interlayer welding and release-assisted rework.
- SH covers the direct self-heal route.
- SHB1 covers the repair-booster route.
- ReBond Weld covers the interlayer-welding route.
- DP80 / DP150 extend the portfolio toward release-assisted rework concepts.
Workflow note
The right repair route depends on the target failure mode, not only on the additive name
These additives are most useful when the repair objective is defined first: stronger bonding between layers, direct self-heal response, assisted recovery or controlled rework via release logic.
In practice, the correct path is to define the intended repair mechanism first, then validate the additive under the intended resin chemistry, loading and process conditions.
Technical and commercial support
Documentation, technical selection help and project support
Use the resources below to move from additive preselection to technical discussion, formulation planning and advanced development support.
Final CTA
Select the right repair route and validate the full durability workflow
Use the route-based navigation above to identify the most relevant self-repair or interlayer-welding additive, compare candidates in the technical overview table, and move forward with formulation-specific validation for stronger and more repairable printed parts.
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From prototyping to industrial production, performance depends on materials, calibration and process control