select-print-material

pjt222

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Diese Claude Skill unterstützt Entwickler bei der Auswahl geeigneter 3D-Druckmaterialien, indem sie Eigenschaften wie Festigkeit, Temperaturbeständigkeit und chemische Kompatibilität gängiger Filamente und Harze vergleicht. Sie leitet die Materialwahl für spezifische Anforderungen wie Außeneinsatz, Lebensmitteltauglichkeit oder die Balance zwischen Druckbarkeit und Leistung. Nutzen Sie sie zur Fehlerbehebung bei materialbedingten Druckproblemen und für fundierte Auswahlentscheidungen bei funktionalen Bauteilen.

Schnellinstallation

Claude Code

Dokumentation

Select Print Material

Choose 3D print material → match props to functional reqs. Covers FDM filaments (PLA, PETG, ABS, ASA, TPU, Nylon) + SLA resins (standard, tough, flexible, castable) w/ detailed property compare for strength, temp, chemical, flex, post-process.

Use When

Specific mechanical reqs (tensile, impact, flex)
Temp-sensitive (hot|cold)
Chemical|UV|outdoor exposure
Food-safe|biocompat
Balance printability vs perf for proto vs prod
Troubleshoot material-related fails
Optimize cost vs props for prod runs

In

functional_requirements: Load type (tensile|compress|bend|torsion), magnitude, duty cycle
environmental_conditions: Temp range, UV, chemical, moisture
mechanical_properties_needed: Strength, flex, impact, fatigue
surface_finish: Appearance, post-process
printability_constraints: Printer caps (heated bed, enclosure), user level
special_requirements: Food safe, biocompat, electrical, transparency

Do

1. ID Primary Req Category

Dominant req drives selection:

Mechanical Perf:

High strength under load
Impact|shock absorption
Flex|elastic behavior
Fatigue resistance (repeated load)

Env Durability:

High|low temp
UV|outdoor weathering
Chemical (solvents, oils, acids)
Moisture|water

Special Apps:

Food contact safety
Biocompat (medical)
Electrical (insulation, conductivity)
Optical (transparency, color)

Printability/Cost:

Easy print for protos
Min warp|support
Low cost for large parts
Wide availability

→ Primary req ID'd ("outdoor UV" or "high impact").

If err: multi reqs equally critical → decision matrix scoring (Step 6).

2. Material Filters

Filter 1: Process

FDM: All thermoplastics
SLA: All resins
Printer constraints: Heated bed (60-110°C) for ABS|ASA|Nylon; enclosure for ABS|ASA

Filter 2: Temp Range

Operating Temperature → Minimum Material Glass Transition (Tg):

< 45°C:  PLA, PLA+, Standard Resin, Tough Resin
< 60°C:  PETG, Flexible Resin
< 80°C:  ABS, ASA, CPE
< 100°C: Nylon, Polycarbonate, High-Temp Resin
> 100°C: PEEK, PEI (Ultem) - specialty printers only

Filter 3: Mechanical

High tensile strength:     Nylon > ABS/ASA > PETG > PLA > TPU
High impact resistance:    Nylon > PETG > ABS > ASA > PLA
Flexibility:              TPU > Flexible Resin > PLA (brittle)
Fatigue resistance:       Nylon > PETG > ABS > PLA

Filter 4: Env

UV resistance:            ASA > PETG > ABS > PLA (poor)
Chemical resistance:      Nylon > PETG > ABS/ASA > PLA
Outdoor durability:       ASA > Nylon > PETG > PLA (degrades)
Moisture resistance:      ABS/ASA > PETG > PLA > Nylon (hygroscopic)

→ 2-5 candidates remain.

If err: no material passes → relax least-critical req or post-process (UV coat for PLA).

3. Compare Properties

FDM Filament Properties

Material	Print Temp	Bed Temp	Tensile Strength	Elongation	Tg/HDT	UV Resist	Ease	Hygroscopic
PLA	190-220°C	50-60°C	50-70 MPa	5-7%	55-60°C	Poor	Easy	Low
PLA+	200-230°C	50-60°C	60-75 MPa	10-15%	60-65°C	Poor	Easy	Low
PETG	220-250°C	70-85°C	50-60 MPa	15-20%	75-80°C	Good	Medium	Medium
ABS	230-260°C	95-110°C	40-50 MPa	20-40%	95-105°C	Fair	Hard	Low
ASA	240-260°C	95-110°C	45-55 MPa	15-30%	95-105°C	Excellent	Hard	Low
TPU	210-230°C	40-60°C	30-50 MPa	400-600%	60-80°C	Good	Medium	Low
Nylon	240-270°C	70-90°C	70-80 MPa	50-150%	75-90°C	Excellent	Hard	Very High

Notes:

Tensile: Higher = stronger pull
Elongation: Higher = more flex before break
Tg/HDT: Glass transition|heat deflection temp (max op)
Ease: Print difficulty (warp, adhesion, stringing, supports)
Hygroscopic: Water absorb (needs dry box)

SLA Resin Properties

Resin Type	Cure Time	Tensile Strength	Elongation	HDT	Hardness	Best For
Standard	2-4s	45-55 MPa	6-8%	60-70°C	82-85 Shore D	Miniatures, prototypes
Tough	4-6s	55-65 MPa	15-25%	70-80°C	80-85 Shore D	Functional parts, snaps
Flexible	6-8s	5-10 MPa	80-120%	50-60°C	60-70 Shore A	Gaskets, grips
High-Temp	8-12s	60-70 MPa	6-10%	120-150°C	85-88 Shore D	Heat-resistant parts
Castable	3-5s	35-45 MPa	8-12%	60°C	80 Shore D	Jewelry (lost-wax)

→ Props compared, 1-3 top candidates ID'd.

If err: props unclear → manufacturer datasheets via WebFetch.

4. Eval Printability Tradeoffs

Easy (PLA, PLA+):

Min warp, good bed adhesion
Wide temp tolerance
Low stringing, easy supports
Beginner|proto ideal
Tradeoff: Lower temp resist, UV degrade, brittle

Medium (PETG, TPU):

Mod warp (PETG needs 70°C+ bed)
Some stringing (tune retraction)
TPU needs direct drive + slow speed
Good strength-ease ratio
Tradeoff: PETG strings, TPU hard overhangs

Hard (ABS, ASA, Nylon):

Severe warp w/o enclosure
Strong fumes (ABS|ASA need ventilation)
Nylon extremely hygroscopic (dry box req)
High bed temps (95-110°C) + chamber heat
Tradeoff: Excellent mechanical+env

Cost:

Material cost per kg (typical):
PLA:    $15-25
PETG:   $20-30
ABS:    $18-28
ASA:    $25-35
TPU:    $30-45
Nylon:  $35-55
Standard Resin: $30-50/L
Specialty Resin: $60-150/L

→ Printability vs printer caps + user. Decision balances perf vs constraints.

If err: material too hard for setup → easier alt + design changes (thicker walls, fillets).

5. Special Reqs

Food Safety:

Safe printed correctly: PLA, PETG (w/ food-safe additives)
Never safe: ABS, ASA (toxic additives), Nylon (porous)
Reqs: Food-safe nozzles (stainless not brass), seal w/ food-safe epoxy
Note: FDM layers trap bacteria — SLA smooth resin better

Biocompat (medical|dental):

FDM: Nylon (some grades), PLA (limited)
SLA: Medical-grade certified resins
Warning: Home 3D not sterile; consult regs for medical

Electrical:

Insulation: PLA, PETG, ABS, ASA all good (>10^14 Ω·m)
Conductivity: Conductive filaments (carbon black, metal-fill)
Notes: Moisture (Nylon) ↓insulation

Transparency:

FDM: Nearly impossible (layer scatter); thin walls + extensive polish
SLA: Clear resins → transparency w/ post-process (sand|polish|coat)

UV Resist:

Excellent: ASA, Nylon
Good: PETG, TPU
Poor: PLA, ABS

→ Special reqs verified vs caps.

If err: doesn't meet → post-process (UV-resist coat on PLA) or diff material.

6. Final Selection Decision Matrix

Score candidates across weighted criteria:

Outdoor functional part example:

Criterion	Weight	PLA	PETG	ABS	ASA	Nylon
UV Resistance	30%	1	6	5	10	9
Strength	25%	6	7	6	7	9
Printability	20%	10	7	4	3	3
Temperature	15%	2	6	8	8	9
Cost	10%	10	8	8	6	4
Weighted Total		5.35	6.80	5.90	7.25	7.45

Score: 1 (poor) → 10 (excellent)

Decision: Nylon highest (7.45) but ASA (7.25) close + better printability. Select ASA if enclosure, else PETG (6.80).

→ Final selected w/ documented rationale.

If err: unclear → default PETG (FDM) or Tough Resin (SLA) — best all-around.

7. Document Settings

FDM template:

material: PETG
brand: "PolyMaker PolyLite"
color: "Blue"
nozzle_temp: 245°C
bed_temp: 80°C
chamber_temp: ambient
print_speed: 50mm/s
retraction_distance: 4.5mm
retraction_speed: 40mm/s
cooling: 50% (after layer 3)
notes: "Strings moderately, Z-hop helps. Dried 6h at 65°C."

SLA template:

resin: "Anycubic Tough Resin"
color: "Clear"
layer_height: 0.05mm
exposure_time: 6s
bottom_exposure: 40s
lift_distance: 6mm
lift_speed: 65mm/min
notes: "Post-cure 15min at 60°C for full strength. Brittle without cure."

→ Settings documented in project notes|slicer profile.

If err: start manufacturer recommended → iterate + document.

Check

Primary req ID'd (mech|env|special)
Candidates filtered by process, temp, reqs
Props compared via table|datasheet
Printability vs printer caps
Special reqs checked
Final via decision matrix w/ weighted priorities
Settings documented for reproducibility
Cost + availability verified for quantity

Traps

PLA for everything: Easy but unsuitable >50°C, outdoor, long-term durability
Ignore hygroscopy: Nylon+TPU absorb moisture → bubbling, poor adhesion, brittle. Dry box.
ABS w/o enclosure: Severe warp w/o heated chamber; ASA slightly better but still needs
Assume food safety: FDM porous traps bacteria; true safety needs sealing|SLA smooth
Over-design strength: Expensive Nylon when PETG enough; overkill wastes $ + adds difficulty
Underestimate temp: Parts near motors, heated beds, cars reach 60°C+ → PLA softens
UV neglect: PLA+ABS yellow+degrade in sun within months; use ASA or coat
Wet filament: Moisture → steam bubbles in extruder, weak adhesion, stringing — always dry hygroscopic
Ignore fumes: ABS+ASA emit styrene; needs active ventilation
Resin handling: Uncured = skin sensitizer + toxic; always gloves + ventilated

→

prepare-print-model: Slicer settings for material
troubleshoot-print-issues: Fix material fails
Dry Filament (future): Drying for hygroscopic
Post-Process 3D Prints (future): Sand, vapor smooth, paint, anneal

GitHub Repository

pjt222/agent-almanac

Pfad: i18n/caveman-ultra/skills/select-print-material

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