Aztec

Replacement brake blocks for road brakes. Single hex bolt adjustment. Excellent value for money. Inmoulded road style fin.

Replacement brake blocks for road brakes. Also suitable for some types of U-type brakes. Excellent value for money. Supplied with nuts and dished washers for accurate alignment and toe-in.

Replacement Plus Race compound brake block system for road brakes. Anodised aluminium alloy pad shoe with built-in pivot system to save weight and make it easier to achieve perfect alignment.

Replacement Plus compound brake block system for road brakes. Anodised aluminium alloy pad shoe with built-in pivot system to save weight and make it easier to achieve perfect alignment. Brake pad inserts are held in securely with 2 mm Allen-head screws.

Replacement brake pads for Magura HS series hydraulic rim brakes fitted to e-bikes. Simple pull out and clip in replacement. Long life, high performance compound specifically designed for the rigours of E-bike useage.

Sintered metal compound replacement disc brake pads designed and developed for UK riding conditions. Sintered compounds have a higher thermal threshold, resulting in less brake fade under heavy braking.

Sintered metal compound replacement disc brake pads designed and developed for UK riding conditions. Sintered compounds have a higher thermal threshold, resulting in less brake fade under heavy braking.

Organic compound replacement disc brake pads designed and developed for UK riding conditions. Organic compounds are more forgiving on rotors with less brake squeal than sintered brake pads.

Organic compound replacement disc brake pads designed and developed for UK riding conditions. Organic compounds are more forgiving on rotors with less brake squeal than sintered brake pads.

Replacement disc brake pads optimised for use on e-bikes. Optimised for e-bike compound works well in all conditions, on or off road.

Replacement disc brake pads optimised for use on e-bikes. Optimised for e-bike compound works well in all conditions, on or off road.

Replacement disc brake pads optimised for use on e-bikes. Optimised for e-bike compound works well in all conditions, on or off road.

Replacement disc brake pads optimised for use on e-bikes. Optimised for e-bike compound works well in all conditions, on or off road.

Replacement disc brake pads optimised for use on e-bikes. Optimised for e-bike compound works well in all conditions, on or off road.

Replacement disc brake pads optimised for use on e-bikes. Optimised for e-bike compound works well in all conditions, on or off road.

Replacement disc brake pads optimised for use on e-bikes. Optimised for e-bike compound works well in all conditions, on or off road.

Replacement disc brake pads optimised for use on e-bikes. Optimised for e-bike compound works well in all conditions, on or off road.

Replacement disc brake pads optimised for use on e-bikes. Optimised for e-bike compound works well in all conditions, on or off road.

Replacement disc brake pads optimised for use on e-bikes. Optimised for e-bike compound works well in all conditions, on or off road.

Sintered metal compound replacement disc brake pads designed and developed for UK riding conditions. Sintered compounds have a higher thermal threshold, resulting in less brake fade under heavy braking.

Organic compound replacement disc brake pads designed and developed for UK riding conditions. Organic compounds are more forgiving on rotors with less brake squeal than sintered brake pads.

Organic compound replacement disc brake pads designed and developed for UK riding conditions. Organic compounds are more forgiving on rotors with less brake squeal than sintered brake pads.

Sintered metal compound replacement disc brake pads designed and developed for UK riding conditions. Sintered compounds have a higher thermal threshold, resulting in less brake fade under heavy braking.

Sintered metal compound replacement disc brake pads designed and developed for UK riding conditions. Sintered compounds have a higher thermal threshold, resulting in less brake fade under heavy braking.