Use this guide to check your height to find the perfect stick for you or your hockey mate! Remember this is a guide only. If you can get in-store to measure yourself up and find the perfect stick size for you!
Carbon fibre offers the advantage of being light with high stiffness [stiffness describes how much a material deflects (or bends) under force], and high tensile strength [tensile strength is the force required to bend the material until breakage]. When used correctly Carbon is an ideal component for hockey stick composition contributing to delivering high ball speed [power for hitting, slapping, pushing] whilst light [stiffness to weight ratio] so contributes to reducing overall weight to enhance players ability to move the stick quickly enabling “quick hands”.
Carbon fibre has the disadvantage of being brittle [being brittle describes that a material when subjected to stress breaks easily] in a hockey sense this mean that from impacts the carbon fibres are easily broken from stick to stick impacts and from repeated ball striking, and secondly carbon fibre has limited vibration dampening characteristics.
These key disadvantages are overcome by how the Carbon is used and the use of Kraibon, Fibreglass, Aramid and The Resin Matrix in the composite Lay-up.
Fibreglass is the most common fibre in the composite industry.
It is heavier and not as stiff than carbon fibre but is more impact resistant and has a greater elongation to break than carbon fibre.
Fibreglass is used to control the flex, for its easy formability characteristics and high mechanical strength. These specifications make Fibreglass a crucial material in protecting carbon fibre from impacts.
Aramid fibre provides an exceptional impact resistance and is very abrasion resistant.
Heavier than Carbon, Aramid fibre is key in vibration reduction and fatigue resistance which make it a great addition to Carbon and Fibreglass in the Lay-up.