Hawaii Wind Load Requirements

Hawaii Building Code Overview

Hawaii has adopted the 2018 Hawaii Building Code, which is based on the 2018 International Building Code (IBC) with significant state amendments tailored to Hawaii's unique tropical island environment. The code became effective in April 2021 and incorporates ASCE 7-16 with the critical addition of Appendix W: Hawaii Wind Design Provisions.

Hawaii's island geography presents unique wind load challenges. The state's exposure to Pacific hurricanes, tropical storms, trade winds, and complex terrain-induced wind patterns necessitates specialized design provisions. Appendix W addresses these Hawaii-specific conditions by providing refined wind speed maps, topographic factors, and design criteria developed specifically for the Hawaiian Islands.

ASCE 7-16 with Appendix W: Hawaii Wind Design Provisions

The most significant feature of Hawaii's wind load requirements is the mandatory use of ASCE 7-16 Appendix W, which contains Hawaii-specific wind provisions developed through extensive research and hurricane modeling. Appendix W supersedes the standard ASCE 7-16 wind provisions for Hawaii projects.

Why Appendix W is Critical

Hawaii's wind environment differs from the mainland United States in several key ways:

• Pacific hurricanes: Different track patterns and intensities compared to Atlantic hurricanes
• Trade winds: Persistent northeast trade winds create unique exposure conditions
• Volcanic topography: Dramatic elevation changes and terrain features (Mauna Kea, Mauna Loa, Haleakala)
• Island channeling effects: Wind acceleration between islands and through valleys
• Coastal cliffs and ridges: Steep escarpments amplifying wind speeds

Appendix W provides Hawaii-specific provisions including:

• Refined wind speed maps: Island-by-island wind speed contours
• Topographic factors: Detailed Kzt calculations for Hawaii's complex terrain
• Exposure categories: Guidance for determining exposure in island environments
• Velocity pressure coefficients: Adjusted Kh and Kz values for Hawaii conditions

ASCE Wind Design Geodatabase

Hawaii building departments require the use of the ASCE Wind Design Geodatabase to determine basic wind speeds. This online tool provides site-specific wind speeds based on latitude/longitude or address, incorporating the refined Appendix W wind maps.

The geodatabase accounts for:

• Precise geographic location on each island
• Distance from coastline
• Elevation and surrounding terrain
• Local topographic amplification factors

Design Wind Speeds and Wind-Borne Debris Regions

Hawaii's design wind speeds vary considerably based on island, elevation, and exposure. Typical design wind speeds by island and location:

Oahu (Honolulu County)

• Honolulu (urban): 100-115 mph
• North Shore: 115-130 mph
• Windward coast: 110-125 mph
• Elevated areas (ridges): 125-140+ mph

Maui County (Maui, Molokai, Lanai)

• Coastal Maui: 110-130 mph
• Haleakala slopes: 130-150+ mph (elevation-dependent)
• Molokai: 110-130 mph
• Lanai: 110-125 mph

Hawaii County (Big Island)

• Kona coast: 100-120 mph
• Hilo area: 105-125 mph
• Mauna Kea/Mauna Loa slopes: 130-150+ mph (extreme elevation)
• South Point: 125-140 mph (exposed headland)

Kauai County (Kauai, Niihau)

• Coastal Kauai: 115-130 mph
• North Shore: 125-140 mph
• Waimea Canyon area: 125-145 mph (topographic amplification)

Wind-Borne Debris Regions

Areas with design wind speeds of 130+ mph are designated as wind-borne debris regions. In these areas, all glazed openings (windows, doors, skylights) must be protected with:

• Impact-resistant glazing (ASTM E1996)
• Impact-resistant window/door assemblies
• Approved hurricane shutters
• Engineered protection systems (PE-sealed)

Hawaii City Wind Load Guides

For detailed city-specific wind load requirements, building codes, and local enforcement information, explore our Hawaii city guides:

Professional Engineer (PE) Seal Requirements

Hawaii requires Professional Engineer (PE) seal for work performed by registered design professionals. A Hawaii-licensed PE must review and seal all structural drawings, calculations, and specifications to verify compliance with the Hawaii Building Code and ASCE 7-16 with Appendix W.

When PE Sealing is Required

• All commercial buildings: Non-residential structures regardless of size
• Multi-family structures: Apartments, condominiums, townhomes
• Residential structures requiring registered design professional: Custom homes, complex geometry, unusual loads
• High-wind areas: Structures in 130+ mph wind zones
• Essential facilities: Risk Category III and IV structures (hospitals, fire stations, shelters)
• Elevated structures: Buildings on piles or elevated foundations

PE-stamped plans provide assurance that wind load calculations incorporate Appendix W provisions, account for Hawaii-specific topographic effects, and comply with all applicable building code requirements.

Corrosion-Resistant Hardware Requirements

Hawaii's tropical marine environment is extremely corrosive to standard metal fasteners and connectors. Salt spray, high humidity, and warm temperatures accelerate corrosion, leading to rapid degradation of unprotected steel hardware. Hawaii's building code mandates corrosion-resistant hardware for all construction.

Mandatory Corrosion Protection

The following corrosion protection methods are required for Hawaii construction:

Stainless Steel Fasteners

• Type 304 stainless steel: Minimum standard for interior applications
• Type 316 stainless steel: Required for coastal exposure (within 3000 feet of high water line)
• Applications: Nails, screws, bolts, anchors, joist hangers, hurricane straps

Hot-Dip Galvanized Steel

• ASTM A153 galvanizing: Minimum for structural hardware
• Triple-coated galvanizing: Enhanced protection for high-exposure areas
• Applications: Structural connectors, metal framing, fasteners

Specialized Coatings

• Polymer coatings: Additional protection over galvanized hardware
• Ceramic coatings: High-performance applications
• Epoxy coatings: Anchors and embedded hardware

Cost Considerations

Corrosion-resistant hardware is significantly more expensive than standard galvanized or zinc-plated fasteners. Budget considerations:

• Type 316 stainless fasteners: 3-5x cost of standard fasteners
• Stainless hurricane straps: 2-3x cost of galvanized
• Long-term value: Prevents premature failure and costly repairs
• Insurance benefits: May reduce premiums for hurricane-prone properties

While the initial cost is higher, corrosion-resistant hardware is essential for long-term structural integrity in Hawaii's harsh coastal environment.

Design Considerations for Hawaii Structures

Successful wind load design in Hawaii requires attention to topographic effects, building envelope integrity, and material selection for the marine environment.

Topographic Wind Speed-Up Effects

Hawaii's volcanic terrain creates significant topographic amplification of wind speeds. ASCE 7-16 Appendix W provides detailed guidance for calculating the topographic factor (Kzt) for:

• Ridges and escarpments: Coastal pali (cliffs), crater rims, ridge lines
• Valleys and channels: Wind channeling between mountains
• Isolated hills: Volcanic cones and cinder cones
• Elevation changes: Structures on slopes with upwind terrain transitions

Buildings located on exposed ridges or near the tops of escarpments can experience wind speed increases of 30-60% compared to flat terrain at the same elevation. Proper Kzt calculation per Appendix W is essential for accurate wind load determination.

Continuous Load Path Design

A continuous load path transfers wind forces from the roof through the walls to the foundation using corrosion-resistant connectors:

• Roof-to-wall connections: Stainless steel hurricane straps or structural screws
• Wall-to-foundation connections: Stainless steel or epoxy-coated anchor bolts
• Sheathing attachment: Stainless steel nails/screws at specified spacing
• Structural sheathing: Plywood or OSB providing shear wall and diaphragm action

Roofing System Design

Hawaii roofing systems must withstand hurricane-force winds while resisting moisture intrusion from tropical rains:

• Enhanced shingle attachment: 6-nail pattern with stainless steel or hot-dip galvanized nails
• Self-sealing shingles: Factory adhesive strips for wind resistance
• Roof deck attachment: Stainless steel nails at 6" o.c. at panel edges (high-wind zones)
• Secondary water barrier: Self-adhering underlayment at eaves, rakes, and valleys
• Metal roofing: Standing seam systems with concealed stainless fasteners and high uplift ratings

Building Envelope Integrity

Maintaining envelope integrity prevents internal pressurization and moisture intrusion:

• Impact-resistant windows and doors in wind-borne debris regions (130+ mph)
• Wind-rated garage doors with stainless steel hardware
• Sealed roof and wall penetrations with marine-grade sealants
• Continuous flashing at all openings (stainless steel or coated aluminum)
• Soffit vents designed for positive and negative wind pressures

Unique Hawaii Considerations

Hawaii construction presents challenges beyond wind loads that must be integrated into structural design:

Termite Protection

Hawaii's tropical climate supports aggressive Formosan termite populations. Wind-resistant structural connectors must also accommodate termite protection systems:

• Stainless steel mesh termite shields
• Chemical treatments compatible with corrosion-resistant hardware
• Pressure-treated lumber or naturally termite-resistant species (redwood, cedar)

Tsunami and Flood Design Coordination

Coastal Hawaii structures may require both hurricane wind design and tsunami/flood resistance. Design coordination includes:

• Elevated structures: Open foundations (piles/columns) increase wind exposure
• Breakaway walls: Must fail under tsunami loads without compromising wind resistance of upper structure
• Flood vents: Must be designed to remain closed during wind events

Volcanic Ash and Vog (Volcanic Smog)

Active volcanic activity on the Big Island produces ash and vog that accelerate corrosion. Additional protection measures:

• Upgrade to Type 316 stainless even in non-coastal areas downwind of active vents
• Sealed roof penetrations to prevent ash infiltration
• Washable exterior surfaces for ash removal

Resources and Professional Assistance

For Hawaii projects, consulting with a Hawaii-licensed Professional Engineer experienced in Appendix W provisions is strongly recommended. A PE can provide:

• Accurate wind load calculations using ASCE 7-16 Appendix W
• Site-specific wind speeds from ASCE Wind Design Geodatabase
• Topographic factor (Kzt) calculations for complex Hawaiian terrain
• Corrosion-resistant hardware specifications
• Stamped plans meeting county building department requirements

Additional resources include:

• Hawaii Department of Accounting and General Services: State building code administration
• County Building Departments: Hawaii County, Honolulu, Maui County, Kauai County
• ASCE 7-16 with Appendix W: Available from the American Society of Civil Engineers
• ASCE Wind Design Geodatabase: Online tool for site-specific wind speeds
• Hawaii Board of Professional Engineers: PE licensing and requirements

Understanding and complying with Hawaii's unique wind load requirements is essential for safe, durable construction in one of the nation's most challenging coastal environments. By following the 2018 Hawaii Building Code, ASCE 7-16 with Appendix W, and using corrosion-resistant materials throughout, builders and designers can create structures that withstand Hawaii's tropical Pacific climate for generations.