High Temperature Resin Parameter
High temperature resin can withstand temperatures up to 130℃, which can simulate the thermal performance of engineering plastics. It is heat-resistant and moisture-resistant and has high humidity. It can be used in scenes with high-temperature resistance requirements such as vacuum plating, water plating, baking paint, and rapid molds
| Technology | SLA |
| Material | High-Temperature Resin |
| Original Color | Translucent Red |
| Thermal Deformation | 110-130°C |
| Hardness | 83D (ASTM D2240) |
| Surface Situation | Slight layer lines and scratches |
| Printing Platform Size | 600*600*400mm |
| Flexural modulus | 3165 Mpa (ASTM D790) |
| Flexural strength | 96.9 Mpa (ASTM D790) |
| Tensile modulus | 3235 MPa (ASTM D638) |
| Tensile strength | 47.2 MPa (ASTM D638) |
| Elongation at break | 1.5% (ASTM D638) |
| Impact strength notched Izod | 34.4 j/m (ASTM D256) |
| Tolerance | The local accuracy of the product is between 0.2-0.3mm~3.5 ‰, while overall accuracy is hard to control |
| Post Process | Assembly,Inset copper nuts, Physical polishing,Painting, Electroplating, Silkscreen, Water transfer printing, Coating |
| Wall thickness required | 0.8mm above, big parts according to 3D drawings |
The advantages of SLA heat-resistant resin are:
1.High Heat Tolerance: Heat-resistant resin can withstand elevated temperatures without deforming, making it suitable for applications in high-temperature environments.
2.Functional Prototyping: Ideal for creating functional prototypes of parts that will be exposed to heat or require good thermal stability.
3.Diverse Applications: Widely used in industries such as automotive, aerospace, and engineering where components may encounter high-temperature conditions during operation.
4.Mechanical Integrity: Retains its structural and mechanical properties even under prolonged exposure to heat, ensuring durability and performance in demanding conditions.
5.Versatility: Provides the versatility of SLA technology while addressing the need for heat resistance, allowing for complex, heat-resistant designs and components to be 3D printed.
The disadvantages of SLA heat-resistant resin are:
1.Limited Heat Threshold: Despite being heat-resistant, the resin may have a maximum temperature threshold beyond which it may start to lose its heat-resistant properties or deform.
2.Potentially Brittle: Heat-resistant resins may lean towards being more brittle compared to standard resins, impacting their ability to absorb mechanical stress or impact at high temperatures.
3.Post-Curing Required: Achieving optimal heat resistance often necessitates post-curing steps, adding to the overall production time and complexity.
4.Cost: Heat-resistant resins are typically more expensive compared to standard resins, affecting the overall cost of 3D printing heat-resistant components.