Look Keo Blade Carbon Ti Pedals

Look Keo Blade Carbon Ti Pedals

249.99

The Blade Carbon is the product of lengthy research by LOOK engineers to optimize all the innovative concepts developed within the family of blade pedals. The result is a pedal that is even more secure, stable, light and powerful.

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The Blade Carbon is the product of lengthy research by LOOK engineers to optimize all the innovative concepts developed within the family of blade pedals. The result is a pedal that is even more secure, stable, light and powerful.
 
Its design fully integrates the blade for unsurpassed aerodynamics. Fitted with a carbon body and blade, the Blade Carbon is available in version Ti (titanium axle) weighing only 90g per pedal, or version Cr (Chromoly+ axle) that weighs 110g per pedal. It is available in three release tensions: 12, 16 and 20.


BLADE TECHNOLOGY

Blade technology uses a blade instead of a conventional metal spring, which has many advantages for the user: 

  • Safe cleat entry/ release: the blade flexes, providing a firm hold once clipped-in, and when clipping-out, releases the foot faster at the end of the process in a quick and secure movement.
  • An aerodynamic shape: thanks to the integration of the blade inside the body, pedals equipped with BLADE technology have the best aerodynamic shape ever created.
  • Low weight: the design of the pedal around a blade system allows a significant reduction in weight and better load distribution.

CONTACT SURFACE AREA : MAXIMUM POWER TRANSFER

To answer the desires of some of the most demanding cyclists, notably competitors, the pedal and cleat system must allow efficient power transfer through a broad and rigid contact surface.
 
Because of this, the Blade Carbon platform surface is covered with a 68mm wide, stainless steel plate that has been molded into the body and optimizes, regardless of pedaling style, the over 700 mm² cleat/pedal contact area.


CARBON TECHNOLOGY

Using a carbon body can lighten the pedal weight and provide an additional gain in stiffness for better power transfer.