Onshore Containerised AWES-100

Kitepower Falcon

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Rated power

100

kW

Yearly power output

250

MWh

Operational height

70

-

400

m

Battery

336-422

kWh

Market Entry

Coming
soon

Households supplied

150


Rounded estimate for The Netherlands assuming a 50% capacity factor and a household consumption of 3000 kWh/year. Actual values vary depending on locations. Value refers to the amount of households powered with one system.

Reshaping wind energy solutions for remote applications worldwide

Distributed generation for microgrids, particularly on islands, heavily relies on diesel for energy production. This not only incurs high costs and environmental pollution but also faces challenges in supply. Recognizing these drawbacks, there is a growing inclination towards hybridising with renewables. Kitepower systems, distinguished by their minimal material usage, offer heightened mobility and resilience compared to other renewables. The Kitepower Falcon, with its exceptional all-day energy production efficiency, stands out in its category.

Kitepower provides a mobile wind energy solution that is not only easy to transport and install but also occupies minimal ground space (m2). The versatile Kitepower Falcon finds applications in microgrids, humanitarian projects, and other remote areas. With this innovative system, wind energy is redefined through a local, renewable approach, promising to revolutionise microgrids worldwide.

The System Components

What does a Kitepower system consist of?
system_components_graphic

1. Ground Station (GS)

Converts the mechanical energy of the kite into electrical power and reels the kite in by using the generator as a motor.

  • 2.44 m x 2.60 m x 6.06 m
  • 9.6 t
  • IP64
  • 25 years
  • 400 V AC 3 phase
  • 550-700 V

2. Tether

A Dyneema® line is used for a lightweight and strong connection between the kite and the GS.

  • UHMWPE Dyneema®
  • 450 m

3. Kite Control Unit (KCU)

Controls the roll, pitch, and yaw of the kite and takes care of the communications between the sensor unit placed on the kite and the GS.

  • t
  • 2 km
  • IP65

4. Kite

Consists of a hybrid between an inflatable and a fixed fibre-glass skeleton, forming the best combination for a strong and lightweight wing.

  • 60-80 m²
  • 47 m²
  • 2,5 t
  • 110 km/h

It all fits in a 20ft. ISO container!

Operational Areas

Understanding the Falcon's space requirements
Zone Dimensions Dual Land-use*
Restricted Zone 30 m (r)
Flight Zone 350 m (r)
Potential Flight Zone* 350 m (r)
Safety Buffer* 425 m (r)
Landing Zone 100 m (r)
Launching Corridor 280x1 m
Launch Pad 20x20 m
(r) = Radius
Obstacles’ height within operational envelope:

1m allowance every 10m of distance from the GS.

*Land can be used for alternative activities while Kitepower is deployed. During operation untrained people are not allowed in the flight zone.

Obstacles’ height within operational envelope:

1m allowance every 10m of distance from the GS *Land can be used for alternative activities while Kitepower is deployed. During operation untrained people are not allowed in the flight zone.

System Configuration

Learn more about the Falcon's multiple applications

Kitepower’s Falcon system can be applied in a variety of circumstances. The system can be implemented into the grid and power (remote) communities like islands.

Next to that, the Falcon can be a full, permanent replacement of alternative fuel generators at construction sites or in the field of agriculture.

The Power Output

Understanding the Falcon's power cycle
Generation phases vs power output

The electricity generation works in two phases, which repeated in continuous cycles result in positive net energy output. The energy generated by the system while reeling out is greater than the energy consumed to reel the kite back in.

Generation phases vs power output

The electricity generation works in two phases, 1) reel-out and 2) reel-in, which repeated in continuous cycles result in positive net energy output. The energy generated by the system while reeling out is greater than the energy consumed to reel the kite back in.

The Kitepower Falcon:

  • Has a single cycle duration of 100 seconds
  • Produces 130 kW 80% of the cycle’s time when in reel-out
  • Consumes 20 kW 20% of the cycle’s time when in reel-in
Start generating electricity at lower wind speeds

Kitepower represents an innovative and cost-effective alternative to existing wind turbines. Kitepower systems start producing energy with lower wind speeds than the ones required by conventional wind turbines, moreover, Kitepower is capable to harness stronger and more persistent winds at higher altitudes.