ADM Aluminum Design Standards Expert
Use this skill when users ask questions about aluminum structural design, ADM 2020, alloy properties, temper designations, heat-affected zones (HAZ), buckling constants, or any aluminum construction related queries.
Trigger Keywords
English: ADM, aluminum design, aluminium, aluminum structures, alloy, 6061-T6, 6063-T5, 5xxx series, temper, T4, T5, T6, H112, heat-affected zone, HAZ, welding aluminum, buckling constants, allowable stress design, ASD, aluminum beam, aluminum column, aluminum connection, extrusion, aluminum alloy, Aluminum Association, Specification for Aluminum Structures
Korean: ADM, 알루미늄설계, 알루미늄구조, 알루미늄, 합금, 6061, 6063, 템퍼, 열영향부, HAZ, 용접, 좌굴상수, 허용응력설계, 압출재
Tools Required
- •Grep: Search for keywords in ADM documents
- •Read: Read specific chapters and reference files
- •Glob: Pattern matching to find files
- •Bash: Execute Python scripts for searches and calculations
- •Write: (Optional) Save calculation results or reports
Document Structure
This skill provides access to comprehensive aluminum design documentation:
1. ADM 2020 Specification (Part I - Design Requirements)
Location: data/specification/*.md (13 chapter files + appendices)
Purpose: What you must follow - formulas, requirements, limits, design criteria
Chapters:
- •A: General Provisions (scope, materials, alloys, tempers)
- •B: Design Requirements (loads, analysis, elements, buckling constants)
- •C: Stability (second-order analysis, P-delta effects)
- •D: Tension Members (tensile strength, net area)
- •E: Compression Members (flexural buckling, local buckling, alloy-dependent)
- •F: Flexural Members (yielding, lateral-torsional buckling, section classification)
- •G: Shear Members (shear strength, web design)
- •H: Combined Forces (interaction equations, torsion)
- •J: Connections (welds with HAZ, bolts, rivets, screws, bearing)
- •L: Serviceability (deflection limits - critical for aluminum's lower E)
- •M: Fabrication (fabrication and erection requirements)
- •N: Quality (QC/QA requirements)
- •Appendices 1-6: Testing, Fatigue, Structural Analysis, Evaluation, Bracing
2. Commentary (Part II - Background and Rationale)
Location: data/commentary/Part_II_Commentary.md (244 KB)
Purpose: Understand why - background, research basis, design considerations
Contents: Detailed commentary on each Specification chapter with:
- •Historical development
- •Research background
- •Design examples and comparisons
- •Limit state explanations
- •Special considerations for aluminum
3. Design Guide (Part III - Practical Guidance)
Location: data/design-guide/Part_III_Design_Guide.md (76 KB)
Purpose: How to apply - practical design workflow
Topics:
- •Introduction to aluminum design
- •Section Selection (considering aluminum's properties)
- •Bending Members (deflection often controls)
- •Compression Members (local buckling critical)
- •Combined Loading
- •Connections (HAZ effects crucial)
- •Serviceability (E = 10,100 ksi vs steel's 29,000 ksi)
- •Sustainability (recyclability, energy efficiency)
4. Illustrative Examples (Part VII - Step-by-Step Calculations)
Location: data/examples/Part_VII_Illustrative_Examples.md (153 KB)
Purpose: See worked examples with complete calculations
Examples (~25 examples covering):
- •Tension members (rods, bars with HAZ effects)
- •Flexural members (W-shapes, tubes, pipes, plates)
- •Connections (rivets, pins, welds with HAZ reduction)
- •Compression members (various sections, local buckling)
- •Combined loading scenarios
5. Reference Data (Parts IV, V, VIII)
Location: data/reference-data/
- •
Part IV - Material Properties (114 KB): Alloy-specific mechanical properties
- •Tables for 6061-T6, 6063-T5, 5xxx series, etc.
- •Unwelded vs welded (HAZ) strengths
- •Temperature-dependent properties
- •Buckling constants by alloy and temper
- •
Part V - Section Properties (360 KB): Geometric properties
- •I-beams, channels, angles, tubes (round and rectangular)
- •A, I, S, Z, r values
- •Standard aluminum sections
- •
Part VIII - Sheet Metal Guidelines (38 KB): Building construction
- •Flashing details
- •Installation requirements
- •Design considerations for sheet metal
Key Distinction:
- •Specification → "What formula should I use?" "What are the limits?"
- •Commentary → "Why is this requirement needed?" "What's the background?"
- •Design Guide → "How do I start a design?" "What's the workflow?"
- •Examples → "Show me a complete calculation step-by-step"
- •Reference Data → "What are the properties of 6061-T6?" "What sections are available?"
Reference Files
This skill includes comprehensive reference materials:
- •
references/symbols.md: Complete symbols table (mathematical notation) - •
references/glossary.md: Technical terms and definitions - •
references/abbreviations.md: HAZ, ASD, ASTM, AWS, etc. - •
references/specification-structure.md: Chapter structure and section mapping - •
references/examples-index.md: Complete example index (~25 examples) - •
references/alloy-guide.md: Quick reference for common aluminum alloys - •
references/haz-factors.md: Welding strength reduction factors by alloy - •
references/buckling-constants-guide.md: Quick lookup for Tables B.4.1, B.4.2, B.5.1
Automation Scripts
Python scripts are available in scripts/ directory:
- •
smart_search.py: Category-aware keyword search - •
formula_finder.py: Extract formulas with context - •
example_matcher.py: Match user queries to appropriate examples - •
alloy_lookup.py: Material properties lookup by alloy/temper - •
haz_calculator.py: Calculate welded member strengths with HAZ - •
extract_references.py: Extract reference materials from documents
Workflow by Query Type
1. Formula Query (공식 질의)
User Intent: Find a specific formula or equation from ADM Specification.
Example Queries:
- •"What is the formula for flexural strength of aluminum beams?"
- •"Show me the compression buckling equation"
- •"알루미늄 보의 휨강도 공식을 알려줘"
Quick Process:
- •Identify topic (flexure → Chapter F, compression → Chapter E, etc.)
- •Grep relevant chapter file in
data/specification/ - •Extract formula with variable definitions from
references/symbols.md - •Note alloy dependency: Check if formula uses buckling constants from Table B.4.1/B.4.2
- •Present with ADM citation (e.g., "ADM 2020 Section F.2")
Keywords: formula, equation, 공식, 계산식
2. Design Example Query (예제 질의)
User Intent: See a step-by-step worked example of a design calculation.
Example Queries:
- •"Show me how to design an aluminum I-beam for flexure"
- •"I need an example of column design with aluminum"
- •"알루미늄 연결부 설계 예제를 보여줘"
Quick Process:
- •Check
references/examples-index.mdfor example number - •Identify appropriate example (e.g., Example 3: W-shape beam design)
- •Read from
data/examples/Part_VII_Illustrative_Examples.md - •Present step-by-step with complete calculations
- •Note any alloy-specific considerations (HAZ, temper, buckling constants)
Keywords: example, 예제, how to, step-by-step, 설계과정
3. Calculation Query (계산 질의)
User Intent: Perform structural calculations using ADM formulas with alloy-specific considerations.
Example Queries:
- •"Calculate flexural strength: I-beam 6061-T6, welded, Lb=10ft"
- •"Determine column capacity: Tube 6063-T5, unwelded, KL=8ft"
- •"용접된 6061-T6 보의 휨강도를 계산해줘"
Quick Process:
- •Identify alloy and temper - CRITICAL for aluminum
- •Check welded vs unwelded - HAZ reduces strength 20-60%
- •Find formula from Specification (use Formula Query workflow)
- •Look up material properties:
- •Option A: Use
alloy_lookup.pyscript - •Option B: Search
data/reference-data/Part_IV_Material_Properties.md
- •Option A: Use
- •Get buckling constants from Table B.4.1 or B.4.2 (alloy-dependent)
- •Find similar example from Part VII for methodology
- •Generate Python code following example structure
- •Execute and validate against ADM limits
Aluminum-Specific Checks:
- •✅ Alloy specified (6061-T6, 6063-T5, etc.)
- •✅ Temper verified (T4, T5, T6, H112, etc.)
- •✅ Welded status confirmed (affects strength significantly)
- •✅ Temperature exposure checked (T5/T6 degrade > 200°F)
- •✅ Buckling constants looked up (alloy-dependent)
- •✅ HAZ strength reduction applied if welded
Keywords: calculate, compute, determine, 계산, 산정, 구해줘
4. Terminology Query (용어 설명)
User Intent: Understand the meaning and context of aluminum design terminology.
Example Queries:
- •"What is a temper designation?"
- •"Explain heat-affected zone (HAZ)"
- •"허용응력설계법이 뭐야?"
Quick Process:
- •Check
references/glossary.mdfirst - •If not found, search "Glossary" sections in Specification or Commentary
- •Present definition with ADM citation
- •Provide usage examples from Specification chapters
- •For aluminum-specific terms: Explain material science background
Aluminum-Specific Terms:
- •Temper: Heat treatment condition (T4, T5, T6 for heat-treatable; H for strain-hardened)
- •HAZ: Heat-Affected Zone - area near welds with reduced strength
- •Alloy designation: 4-digit number (first digit = major alloying element)
- •Buckling constants: Bc, Dc, Cc - vary by alloy and temper
Keywords: what is, explain, definition, 뭐야, 설명, 의미
5. Symbol/Notation Query (기호 질의)
User Intent: Understand what a mathematical symbol represents.
Example Queries:
- •"What does Fty mean?"
- •"Define Cb lateral-torsional buckling factor"
- •"Bc 기호는 무엇을 의미하나요?"
Quick Process:
- •Check
references/symbols.md - •Return: Symbol | Definition | Units | Section Reference
- •Example: Fty = Tensile yield strength | ksi | Section A.4, Tables in Part IV
- •For buckling constants: Reference Tables B.4.1, B.4.2 by alloy
Common Aluminum Symbols:
- •Fty = Tensile yield strength (varies by alloy: 16-50 ksi)
- •Ftu = Tensile ultimate strength
- •Fcy = Compressive yield strength (often = Fty for aluminum)
- •E = Modulus of elasticity = 10,100 ksi (vs 29,000 for steel)
- •Bc, Dc, Cc = Buckling constants (alloy and temper dependent)
Keywords: symbol, notation, 기호, 표기
6. Alloy Lookup Query (합금 조회 - ALUMINUM-SPECIFIC)
User Intent: Find material properties for a specific aluminum alloy and temper.
Example Queries:
- •"What is the yield strength of 6061-T6?"
- •"Properties of 6063-T5 welded vs unwelded"
- •"6061-T6의 인장강도는 얼마야?"
Quick Process:
- •Identify alloy and temper from query
- •Check
references/alloy-guide.mdfor quick reference - •For detailed data, search
data/reference-data/Part_IV_Material_Properties.md - •Return properties:
- •Unwelded: Fty, Ftu, Fcy, Fsu, E
- •Welded (HAZ): Fty(HAZ), Ftu(HAZ), etc. (significantly reduced)
- •Temperature limits
- •Typical applications
- •Use
scripts/alloy_lookup.pyfor automated lookup
Common Alloys Quick Reference:
| Alloy | Temper | Fty (unwelded) | Fty (welded/HAZ) | Reduction | Applications |
|---|---|---|---|---|---|
| 6061 | T6 | 35 ksi | 19 ksi | 46% | General structural, most common |
| 6061 | T4 | 16 ksi | - | - | Lower strength, higher formability |
| 6063 | T6 | 25 ksi | 14 ksi | 44% | Architectural extrusions |
| 6063 | T5 | 16 ksi | 9 ksi | 44% | Lower strength architectural |
| 5xxx | H112 | 16-35 ksi | minimal | - | Marine, non-heat-treatable |
Keywords: alloy, properties, 6061, 6063, temper, strength, 합금, 물성
7. HAZ/Welding Query (열영향부 질의 - ALUMINUM-SPECIFIC)
User Intent: Understand or calculate effects of welding on aluminum strength.
Example Queries:
- •"How much does welding reduce 6061-T6 strength?"
- •"Calculate beam capacity for welded aluminum section"
- •"용접된 알루미늄의 강도 감소율은?"
Quick Process:
- •Identify alloy and temper
- •Check
references/haz-factors.mdfor reduction factors - •For design calculations:
- •Use welded (HAZ) properties from Part IV
- •Apply to relevant formulas
- •Note that HAZ width varies by welding process
- •Cross-reference with Chapter J (Connections) for weld design
- •Use
scripts/haz_calculator.pyfor automated calculations
HAZ Strength Reduction Factors:
| Alloy-Temper | Fty Reduction | Ftu Reduction | Notes |
|---|---|---|---|
| 6061-T6 | ~46% (0.54 factor) | ~37% (0.63 factor) | Most significant |
| 6061-T4 | minimal | minimal | Already in annealed state |
| 6063-T6 | ~44% (0.56 factor) | ~33% (0.67 factor) | Similar to 6061 |
| 6063-T5 | ~44% (0.56 factor) | ~44% (0.56 factor) | |
| 5xxx-H112 | minimal | minimal | Non-heat-treatable |
Critical Design Considerations:
- •Welding heat-treatable alloys (6xxx-T6/T5) → significant strength loss
- •Welding non-heat-treatable alloys (5xxx-H) → minimal loss
- •Post-weld heat treatment can restore strength (complex, often not practical)
- •HAZ zone width: typically 0.5-1.5 inches from weld centerline
Keywords: welding, HAZ, heat-affected zone, weld, strength reduction, 용접, 열영향부
8. Comparison Query (비교 질의)
User Intent: Compare aluminum design with steel, or compare different aluminum alloys.
Example Queries:
- •"Aluminum vs steel structural design differences"
- •"Compare 6061-T6 and 6063-T5"
- •"알루미늄과 철골 설계의 차이는?"
Quick Process:
- •Identify items to compare
- •For aluminum vs steel:
- •Material properties (E, density, strength)
- •Design philosophy (ASD only vs LRFD+ASD)
- •Welding effects (HAZ critical vs minimal)
- •Temperature sensitivity
- •For alloy comparison:
- •Use
references/alloy-guide.md - •Compare strength, weldability, applications
- •Use
- •Present in comparison table format
Aluminum vs Steel Quick Comparison:
| Property | Aluminum (typical 6061-T6) | Steel (A36) | Ratio |
|---|---|---|---|
| E (modulus) | 10,100 ksi | 29,000 ksi | 1:2.9 (stiffer) |
| Density | 0.098 lb/in³ | 0.284 lb/in³ | 1:2.9 (lighter) |
| Yield strength | 35 ksi (unwelded) | 36 ksi | similar |
| HAZ effect | -46% (welded) | minimal | critical difference |
| Thermal expansion | 13×10⁻⁶/°F | 6.5×10⁻⁶/°F | 2:1 (higher) |
| Design method | ASD only | LRFD + ASD | simpler |
Keywords: compare, difference, vs, 차이, 비교, aluminum vs steel
Quick Reference Tables
Document Categories
| Type | Location | Files | Purpose |
|---|---|---|---|
| Specification | data/specification/ | 13 + App | Formulas, limits, requirements |
| Commentary | data/commentary/ | 1 | Background, rationale, research |
| Design Guide | data/design-guide/ | 1 | Practical workflow guidance |
| Examples | data/examples/ | 1 (~25 ex) | Step-by-step calculations |
| Material Properties | data/reference-data/ | Part IV | Alloy properties, HAZ factors |
| Section Properties | data/reference-data/ | Part V | Geometric properties |
| Sheet Metal Guide | data/reference-data/ | Part VIII | Building applications |
| References | references/ | 8 | Symbols, glossary, alloy guide |
Common Search Patterns
| Topic | Keywords | Specification Chapter | Examples Location | Unique Considerations |
|---|---|---|---|---|
| Beam Design | flexure, bending, Cb, Lb, yielding | Chapter F | Part VII Ex 3-6 | Deflection often controls (low E) |
| Column Design | compression, buckling, KL/r, slenderness | Chapter E | Part VII Ex 9-14 | Local buckling critical, alloy-dependent |
| Tension Members | tension, net area, gross area, yielding | Chapter D | Part VII Ex 1-2 | HAZ if welded connections |
| Shear | shear strength, web | Chapter G | Part VII (various) | Similar to steel approach |
| Connections | bolts, welds, rivets, screws, bearing | Chapter J | Part VII Ex 7-8 | HAZ critical for welds |
| Material Lookup | alloy, 6061, 6063, properties | Part IV | - | Alloy and temper specific |
| Stability | second-order, P-delta | Chapter C, Appendix 4 | Part VII (some) | Similar to steel |
| Serviceability | deflection, vibration | Chapter L | Design Guide | Critical due to low E |
ADM Chapter-to-Example Mapping
| Spec Chapter | Topic | Part VII Examples | Key Considerations |
|---|---|---|---|
| A | General | - | Alloys, tempers, materials |
| B | Design Requirements | - | Buckling constants (alloy-dependent) |
| C | Stability | Various | Similar to steel approach |
| D | Tension | Example 1-2 | HAZ for welded |
| E | Compression | Example 9-14 | Local buckling, alloy-dependent |
| F | Flexure | Example 3-6 | Deflection often controls |
| G | Shear | Various | Similar to steel |
| H | Combined Forces | Various | Similar to steel |
| J | Connections | Example 7-8 | HAZ for welds critical |
| L | Serviceability | Design Guide Part 7 | E = 10,100 ksi (1/3 of steel) |
| M | Fabrication | - | Temperature limits for tempers |
| N | Quality | - | Similar to steel |
Units Convention
| Quantity | ADM Unit | Symbol | Notes |
|---|---|---|---|
| Force | kips | kip | 1 kip = 1000 lbs (same as AISC) |
| Moment | kip-in | kip-in | Typically inch-based |
| Stress | ksi | ksi | 1 ksi = 1 kip/in² |
| Length | inches | in | Metric also available |
| Area | square inches | in² | - |
| Modulus | ksi | ksi | E = 10,100 ksi for aluminum |
| Temperature | °F | °F | Critical for T5/T6 tempers |
Performance Optimization
Search Strategy Priority
- •
Alloy-specific queries first: Always identify alloy/temper before proceeding
- •Quick check:
references/alloy-guide.md - •Detailed:
data/reference-data/Part_IV_Material_Properties.md - •Script:
scripts/alloy_lookup.py
- •Quick check:
- •
Reference files before full search:
- •Symbols →
references/symbols.md - •Terms →
references/glossary.md - •Examples →
references/examples-index.md - •Alloys →
references/alloy-guide.md - •HAZ →
references/haz-factors.md - •Buckling →
references/buckling-constants-guide.md
- •Symbols →
- •
Efficient chapter targeting:
- •Use topic keywords to identify specific chapter
- •Don't search all files - target 1-2 relevant chapters
- •Example: "aluminum beam design" → Only search Chapter_F + Part VII examples
- •
Smart document reading:
- •Read only relevant sections
- •Use offset and limit parameters for large files
- •Cross-reference between Specification, Commentary, and Examples when needed
Python Script Usage
Execute automation scripts when appropriate:
# Material properties lookup python3 scripts/alloy_lookup.py "6061-T6" --welded # HAZ strength calculation python3 scripts/haz_calculator.py --alloy "6061-T6" --member-type "beam" # Category-aware search python3 scripts/smart_search.py "lateral-torsional buckling" # Extract formula with context python3 scripts/formula_finder.py "Mn =" "Chapter_F" # Find matching example python3 scripts/example_matcher.py "aluminum beam" "flexure"
Response Quality Checklist
Every response should include:
- •✅ Accurate ADM citation (ADM 2020 Section X.Y or Example Z)
- •✅ Alloy and temper specified (6061-T6, 6063-T5, etc.)
- •✅ Welded vs unwelded clarified (HAZ effects noted)
- •✅ Temperature limits checked if applicable (T5/T6 > 200°F)
- •✅ Units specified (ksi, in, kip, °F)
- •✅ Variable definitions from symbols.md
- •✅ Buckling constants verified (alloy-dependent Tables B.4.1, B.4.2)
- •✅ Working Python code for calculations (tested and validated)
- •✅ Cross-references to examples when explaining formulas
- •✅ Limit states noted (yielding, buckling, rupture, etc.)
Special Features: Aluminum-Specific Considerations
Critical Differences from Steel Design
1. Material Property Variations
Steel: Relatively uniform (Fy = 36, 50, or 65 ksi) Aluminum: Highly variable by alloy/temper (Fty = 5-50 ksi)
→ Always verify alloy and temper before any calculation
2. Welding Effects (HAZ)
Steel: Minimal strength reduction from welding Aluminum: 20-60% strength reduction in heat-affected zone
→ Check welded vs unwelded for all welded members
3. Modulus of Elasticity
Steel: E = 29,000 ksi Aluminum: E = 10,100 ksi (35% of steel)
→ Deflection often controls aluminum design (not strength)
4. Temperature Sensitivity
Steel: Strength stable up to ~400°F Aluminum: T5/T6 tempers lose strength above 200°F
→ Check temperature exposure for heat-treated alloys
5. Buckling Constants
Steel: Standard formulas (uniform) Aluminum: Alloy-dependent tables (Bc, Dc, Cc vary)
→ Look up buckling constants by alloy from Tables B.4.1, B.4.2
6. Design Method
Steel AISC: LRFD + ASD (dual methods) Aluminum ADM: ASD only (single method)
→ Simpler design approach (no LRFD resistance factors)
Alloy Selection Guide
For General Structural Use:
- •6061-T6: Most common, good strength (Fty=35 ksi), weldable (with HAZ consideration)
- •6061-T4: Lower strength (Fty=16 ksi), better formability, less HAZ effect
For Architectural/Extrusions:
- •6063-T6: Moderate strength (Fty=25 ksi), excellent extrudability
- •6063-T5: Lower strength (Fty=16 ksi), good surface finish
For Marine/Corrosive Environments:
- •5xxx-H112: Non-heat-treatable, excellent corrosion resistance, minimal HAZ
For High Strength:
- •7xxx series: Highest strength (not extensively covered in ADM 2020)
When to Use Specification vs Commentary vs Design Guide vs Examples
Use Specification when:
- •User asks "what is the formula?"
- •User needs official requirements or limits
- •User wants to understand code provisions
- •User asks about limit states or design criteria
Use Commentary when:
- •User asks "why is this required?"
- •User needs background or research basis
- •User wants to understand design philosophy
- •User asks "what's the history of this provision?"
Use Design Guide when:
- •User asks "how do I start a design?"
- •User needs overall workflow guidance
- •User wants practical tips and recommendations
- •User asks "what should I consider?"
Use Examples when:
- •User asks "how do I calculate this?"
- •User needs step-by-step procedure
- •User wants to see complete worked solution
- •User asks "show me a calculation"
Use Material Properties (Part IV) when:
- •User asks about alloy properties
- •User needs HAZ factors
- •User wants to compare alloys
- •User needs buckling constants
Use All Together when:
- •Comprehensive design questions
- •Teaching/learning scenarios
- •Formula explanation with practical context
- •Validation of calculations
Error Handling
Common Scenarios
- •
Alloy not specified:
- •Ask user: "Which aluminum alloy? (e.g., 6061-T6, 6063-T5)"
- •Offer common options: 6061-T6 (most common), 6063-T5 (architectural)
- •
Welded status unclear:
- •Ask user: "Is this member welded? (HAZ reduces strength 20-60%)"
- •Explain HAZ implications
- •
No results found:
- •Suggest alternative keywords
- •Check all document types (Spec, Commentary, Guide, Examples)
- •Recommend broader search terms
- •
Ambiguous query:
- •Clarify with multiple interpretations
- •Ask user: "Did you mean [option A] or [option B]?"
- •
Missing parameters:
- •List required values for calculation
- •Offer typical default values from examples
- •
Out of scope:
- •Clearly state limitations (no FEM, no legal advice)
- •Suggest consulting structural engineer for complex cases
Validation Checks
For all calculations:
- •✅ Verify alloy and temper specified
- •✅ Check welded vs unwelded status
- •✅ Verify units consistency (ksi, in, kip)
- •✅ Check against ADM limits (Fty ranges, buckling constants)
- •✅ Verify temperature exposure (< 200°F for T5/T6)
- •✅ Warn if parameters outside typical ranges
- •✅ Note all assumptions (bracing, load cases, HAZ extent)
- •✅ Cross-check with example from Part VII when possible
Special Notes
ASD (Allowable Strength Design) - Only Method
Unlike AISC steel design which offers both LRFD and ASD, ADM 2020 uses ASD only:
ASD Method:
- •Allowable strength = Nominal strength / Ω (safety factor)
- •Load combinations from ASCE/SEI 7 (D + L, D + L + W, etc.)
- •Safety factors (Ω) vary by limit state:
- •Ω = 1.65 for flexure
- •Ω = 1.95 for compression
- •Ω = 1.95 for tension
- •Ω = 1.60 for shear
- •(See each chapter for specific values)
No LRFD: ADM does not provide LRFD resistance factors (φ). If user asks about LRFD, explain that aluminum design uses ASD only.
Design Examples Format
- •Examples show complete step-by-step calculations
- •Example numbering: Number or Number-Letter (e.g., Example 3, Example 14A)
- •All examples cite specific Specification sections
- •Results presented to appropriate significant figures
- •HAZ effects shown when welded members are designed
Version Tracking
- •Specification: ADM 2020 (January 2020 edition)
- •Published by: The Aluminum Association
- •Always cite version in responses
Material Defaults (if not specified by user)
Unless specified otherwise, assume:
- •Alloy: 6061-T6 (most common structural aluminum)
- •Condition: Unwelded (unless connection design implies welding)
- •Temperature: Room temperature (< 200°F)
- •E = 10,100 ksi (modulus of elasticity for aluminum)
Always ask user to confirm if critical to calculation.
For comprehensive aluminum structural design work, this skill integrates:
- •Code requirements from ADM 2020 Specification
- •Background understanding from Commentary
- •Practical workflow from Design Guide
- •Worked applications from Illustrative Examples
- •Material data from Properties tables
- •Section properties from geometric tables
- •Alloy-specific tools (HAZ calculator, property lookup)
Always prioritize accuracy, cite sources, validate alloy/temper, check HAZ effects, and follow ASD methodology.