H9 ARRAY · NOW IN SERIAL PRODUCTION

Nine rotors.
One tower.
Rethinking wind.

WindHive's multi-rotor arrays capture the same wind with 30% less material, blades that travel on standard trucks, and swarm redundancy that keeps generating even during maintenance.

12.6 MWPer array
-22%LCOE vs single-rotor
99.2%Availability

H9 ARRAY · 9 × 1.4 MW · live output 11.8 MW

Why Multi-Rotor

Giant blades hit a wall.
Swarms scale.

Single-rotor turbines are reaching physical and logistical limits — blades longer than football fields that can't fit down a road. Multi-rotor arrays solve the problem with proven physics: many small rotors sweeping the same area as one giant, at a fraction of the cost and complexity.

[01]

30% less material

The square-cube law works in our favour: nine 19-meter blades weigh far less than three 80-meter ones sweeping the same area — cutting steel, carbon fiber and cost per megawatt.

[02]

Ships on standard trucks

No police escorts, no closed highways, no custom cranes. Every H9 component fits on a standard flatbed — opening thousands of sites big turbines can't reach.

[03]

Swarm redundancy

One rotor down for service? The other eight keep generating. Arrays maintain 99.2% availability versus total shutdowns on single-rotor machines.

[04]

Mass-produced parts

Identical rotors roll off one assembly line like car engines — driving costs down the manufacturing learning curve instead of one-off mega-engineering.

[05]

Faster wake recovery

Multi-rotor wakes mix and recover faster than single-rotor wakes, letting arrays stand closer together and produce more energy per square kilometer of wind farm.

[06]

Drop-in repowering

Replace aging turbines on existing pads and grid connections with 4x the capacity — permits, roads and substations already in place.

The Flagship

Meet the H9 Array

Nine 1.4 MW rotors on a single lattice tower deliver 12.6 MW — utility-scale power with components a regional crew can install and service without specialized vessels or cranes.

Independent pitch and yaw control on every rotor lets the array shed load in gusts, balance thrust across the frame, and keep producing in conditions that force single-rotor machines to shut down.

Get the Spec Sheet →
H9_ARRAY / TECHNICAL SPECIFICATIONS
Configuration9 rotors · 3×3 lattice
Rated capacity9 × 1.4 = 12.6 MW
Rotor diameter (each)38 m
Total swept area10,207 m²
Hub height (array center)150 m
Cut-in / rated / cut-out3.0 / 11.5 / 25 m/s
Capacity factor (site class II)up to 48%
Availability (swarm mode)99.2%
Blade transportstandard flatbed
Design life30 years
Deployments

Built for every wind frontier

⛰️

Onshore & Repowering

Reach ridge lines and constrained sites where mega-blades can't be delivered. Repower 1990s wind farms with 4x the output on existing infrastructure.

18 sites active
🌊

Offshore Fixed-Bottom

Smaller rotors mean lower tower-top mass and simpler jack-up vessel logistics — cutting offshore installation costs by up to 35%.

2 pilot parks
🛟

Floating Offshore

Distributed rotor mass lowers the center of gravity, shrinking the floating platform — the key cost driver in deep-water wind.

In certification
🏝️

Islands & Microgrids

A single H9 can power an island community, delivered by ferry and erected with local cranes. Pair with storage for 24/7 clean power.

4 communities
Impact To Date

Clean power, compounding

0 MWDeployed capacity
0kHomes powered
0Active sites
0%Recyclable by mass
Work With Us

Put a hive on your horizon

Developers, utilities and communities: request a free feasibility study and we'll model the H9's output, logistics and LCOE for your exact site.

  • Site wind-resource modelling within 2 weeks
  • Full logistics & permitting assessment
  • Bankable energy-yield report
⚡ Built by BudgetWeb