Hemp UV 3D — Sustainable Performance Resin

Hemp UV 3D Logo
Sustainable Performance Resin

Hemp UV 3D

High-performance, UV-curable composite resins engineered for SLA/DLP/LCD printing—built on hemp-derived reinforcements to push strength and sustainability together.

Because the future of 3D printing needs stronger, cleaner materials.

3D printing is scaling fast across prototyping and production—and materials are the unlock. Yet conventional photopolymer resins can be harsh on the environment and tricky to dispose of responsibly. Hemp UV 3D is our answer: a next-generation, hemp-reinforced UV resin platform targeting stronger-than-average mechanicals with improved sustainability from the ground up.

Built for growth: Additive manufacturing is expanding rapidly, and better materials win. Our goal is to meet pro-grade performance targets while reducing the environmental burden of resin printing.
Sustainability first: We’re exploring bio-based chemistries and hemp-derived reinforcements to cut petrochemical reliance, and designing SOPs that minimize waste and encourage responsible handling.
End goal: Deliver a sustainable performance resin family that prints cleanly, cures reliably, and achieves elevated strength, stiffness, and heat resistance—so parts last longer and the waste stream becomes more environmentally considerate.

If you believe the next wave of 3D printing should be both high-performance and planet-minded, scroll to see our science, formulations, SOPs, and roadmap.

View Investment Proposal See the Science Back Hemp UV 3D on Kickstarter
↓ Keep scrolling for the full breakdown ↓
385/405 nm SLA • DLP • LCD Lab-Pilot Ready Patent Pending © MythForge Studio 2025
3D printer close-up

Top-Line Highlights

70-110 MPa

Tensile strength target using methacrylated CNC, silanized micro-hemp, a stiff matrix, and robust UV + thermal post-cure.

3-6 GPa

Elastic modulus target via optimized filler content, cross-link density, and reactive diluent balance.

≥ 100 °C HDT

UDMA-rich matrices and dual post-cures to reach functional heat resistance for demanding end-use parts.

Hemp plant close-up

What We’re Building & Why It Matters

Our Product

Hemp UV 3D is a UV-curable composite resin line for SLA/DLP/LCD printers. Hemp-derived nanocellulose and bast micro-fibers improve stiffness-to-weight and sustainability without sacrificing printability.

  • Two formulation tracks: High-Performance & Bio-Heavier.
  • Reinforcement: methacrylated CNC/CNF (~0.5–3 wt%) + silanized micro-hemp (5–15 wt%).
  • Future: continuous aligned tow for directional strength.

Why Now

Recent literature supports high filler loadings with proper functionalization and cure strategies, while market pull for greener engineered materials is accelerating across tooling, fixtures, and short-run production.

  • Lower petrochemical dependency & improved LCA profiles.
  • Functional parts with an eco advantage.
  • Eligibility for grants, ESG programs, and industrial adoption.
Green beaker in laboratory

Backed by Research

Nanocellulose Loadings

UV-curable systems with high nanocellulose content are feasible (with solvent exchange and elevated PI levels), enabling substantial reinforcement—with color/Tg trade-offs to manage.

Fiber Preparation

Short bast hemp can yield CNC/CNF (≈5–12 nm diameter, 20–200 nm stacks, high crystallinity) after chemical + mechanical prep and surface functionalization.

Composite Benchmarks

Woven/aligned hemp in thermosets shows flexural strengths ~200 MPa and moduli ~7–8 GPa—guiding upper-bound performance goals.

Laboratory glassware

Formulation Candidates

Candidate A — High-Performance

UDMA/UA + Methacryl-CNC + Micro-Hemp

  • Matrix: UDMA + aliphatic UA; IBOA/HDDA tuning.
  • Reinforcement: CNC ~1.0–1.6 wt%; micro-hemp ~7–10 wt% (silanized).
  • Photopackage: TPO-L ~1.2 % + BAPO ~0.6 %.
  • Targets: 600–900 cP; Dp ~140–180 µm; Ec ~8–10 mJ/cm².
  • Post-cure: UV + 120 °C thermal ~45 min.
Candidate B — Bio-Heavier

AEHO/UA Hybrid + CNF + Micro-Hemp

  • Matrix: Acrylated epoxidized hemp oil + UA.
  • Reinforcement: CNF ~1.0 wt%; micro-hemp ~10 wt%.
  • Photopackage: BAPO ~1.0 % (tune for opacity).
  • Trade-off: Higher bio content & toughness; slightly less stiffness vs A.
Biotech lab bench

Materials & Standard Operating Procedures

Bill of Materials (BOM)
  • Oligomers: UDMA, aliphatic UA, optional Bis-GMA.
  • Diluents: IBOA, HDDA, NPGDA.
  • Photoinitiators & Stabilizers: TPO-L, BAPO; MEHQ/BHT; UV stabilizers.
  • Reinforcements: Methacrylated CNC/CNF; silanized bast micro-hemp.
  • Bio route: AEHO (acrylated epoxidized hemp oil).
  • Additives: Fumed silica, defoamers, pigments.

SOP-01: Bast Fiber Cleanup & Silanization

  1. Alkaline wash (~3 % NaOH, ~70 °C, 60 min); rinse neutral.
  2. Peroxide bleach (1–3 % H₂O₂ + base, 50–60 °C, 30–60 min); rinse.
  3. Dry <0.1 % moisture; mill 50–200 µm; sieve.
  4. ~2–3 % MPS silane; cure ~110 °C for ~1 h; final dry.

SOP-02: CNC/CNF Methacrylation (GMA)

  1. Disperse CNC 5–10 wt% in water; cold sonication.
  2. pH 4.5–5.0; catalyst (p-TSA/DMAP).
  3. GMA 5–20 % on solids; 4–8 h at 50–60 °C (inert).
  4. Dialyze; optional solvent exchange; dry to paste/powder.

SOP-03: Compounding & Printing

  1. Matrix + diluents @ 40–50 °C; disperse CNC/CNF (high shear).
  2. Add micro-hemp; tune viscosity/thixotropy; add PI/inhibitors/defoamer; vacuum degas.
  3. Determine Ec/Dp; print (~50 µm start); UV post-cure both sides; thermal bake 100–120 °C for 30–90 min.
Blueprint and planning desk

Validation & Benchmarking

Experimental Plan

  • CNC/CNF: 0 / ~0.8 / ~1.6 wt%; Micro-hemp: 0 / ~7.5 / ~15 wt%.
  • IBOA: ~12 / ~20 / ~28 %; PI: ~0.8 / ~1.2 %; Post-cure: ~80 vs ~120 °C.
  • Metrics: tensile, flexural, impact, DMA (Tg/modulus), HDT, water uptake, Ec/Dp, viscosity.

Benchmarks

  • UV-curable matrix + high nanocellulose loading (cardanol systems reported).
  • Woven/aligned hemp composites: ~200 MPa flexural, ~7–8 GPa modulus.
  • PLA/hemp (~20 %) shows strong modulus uplift directionally.
Roadmap & Investment Proposal

Roadmap & Investment Proposal

12-Week Pilot

  • Materials + lab capability for CNC/CNF & micro-hemp.
  • ~10 trial formulations → top 2 with full mechanical/thermal data.
  • Printer compatibility & stability verification.

6-Month Scale-Up

  • 5–10 kg pilot batches; shelf-life & aging studies.
  • Beta partners; feedback loops; documentation & datasheets.
  • IP, regulatory, and supply-chain readiness.

Funding & Go-To-Market

  • Ask: USD 250,000 pre-seed.
  • Use: equipment, materials, personnel, QC, pilot reactor.
  • Milestones: prototypes; beta kits; data sheet; market trials.
  • Channels: Direct online + distributors; initial SKUs “Rigid-Pro”, “Bio-Hybrid”.
Shield concept for risk mitigation

Risks & Mitigations

UV Absorption & Cure Depth

Bleach/delignify; increase PI; use thinner layers; ensure spectral match to matrix/filler blend.

Viscosity & Sedimentation

Favor nano-scale fillers; thixotropy control; strong dispersion; consider mat impregnation for high loadings.

Toughness vs Stiffness

Tune reactive diluents; avoid over-crosslink; incorporate stress-relief post-cure schedules.

Hemp leaf macro

Key References

  1. 3D printing market growth projections; sustainability considerations in photopolymers.
  2. Bio-based UV resins and nanocellulose reinforcement pathways (literature survey).
  3. Benchmarking data for hemp-reinforced thermosets and PLA/hemp composites.
© MythForge Studio 2025 — Patent Pending
This document contains forward-looking statements; actual results may differ. All content & data are target values & estimates under R&D conditions.