A skate (e.g., an ice skate) for a user (e.g., a hockey player). The skate comprises a skate boot for receiving a foot of the user and a skating device (e.g., a blade and a blade holder) disposed beneath the skate boot to engage a skating surface. The skate boot may be constructed by molding (e.g., injection molding) so as to have useful performance and/or characteristics (e.g., reduced weight; enhanced fit, comfort and range of motion; enhanced appearance; etc.) while being cost-effectively manufactured.

A skate (e.g., an ice skate) for a user (e.g., a hockey player). The skate comprises a skate boot for receiving a foot of the user and a skating device (e.g., a blade and a blade holder) disposed beneath the skate boot to engage a skating surface. The skate boot may be constructed by molding (e.g., injection molding) so as to have useful performance and/or characteristics (e.g., reduced weight; enhanced fit, comfort and range of motion; enhanced appearance; etc.) while being cost-effectively manufactured.

A figure skating boot has a monocoque structure formed of monocoque material including a sole portion to receive the foot thereon, inner and outer side wall portions, a heel cup portion about the heel, two ankle portions extending over the ankles, and front and rear mounting surfaces below the sole portion for connection to front and rear ends of a mounting frame, for example the mounting frame of a skate blade. A heel member is formed separately from the boot and is supported by the monocoque material to extend downwardly from the heel end of the sole portion so that the rear mounting surface is at the bottom of the heel member. Each ankle portion is joined to the respective side wall portion by a relief junction enabling the ankle portions of the monocoque structure to be flexed relative to the side wall portions of the monocoque structure.

A figure skating boot has a monocoque structure formed of monocoque material including a sole portion to receive the foot thereon, inner and outer side wall portions, a heel cup portion about the heel, two ankle portions extending over the ankles, and front and rear mounting surfaces below the sole portion for connection to front and rear ends of a mounting frame, for example the mounting frame of a skate blade. A heel member is formed separately from the boot and is supported by the monocoque material to extend downwardly from the heel end of the sole portion so that the rear mounting surface is at the bottom of the heel member. Each ankle portion is joined to the respective side wall portion by a relief junction enabling the ankle portions of the monocoque structure to be flexed relative to the side wall portions of the monocoque structure.

A skate boot or other piece of footwear is provided with a flexible midfoot section that is not rigidly connected to either a sole and/or base of the boot, in order to adjustably tighten around the bottom, sides, and/or top of the wearer's midfoot to provide arch support and uniform snugness. The midfoot section is in a hammock type arrangement while the ball and heel portions of the wearer's foot rests on the footbed over the respective sole portions.

A hockey skate includes a fiber-reinforced, composite frame, or an injected plastic frame, including a boot form and integral pedestals that serve as a blade-holder. The pedestals are integral with the bottom of the boot sole and are optionally spaced relatively far apart to provide a long span between them. An optional bridge assembly may be used to connect the blade to the pedestals. The bridge assembly may provide increased stiffness and vibration damping, as well as customized fit options.

A hockey skate includes a fiber-reinforced, composite frame, or an injected plastic frame, including a boot form and integral pedestals that serve as a blade-holder. The pedestals are integral with the bottom of the boot sole and are optionally spaced relatively far apart to provide a long span between them. An optional bridge assembly may be used to connect the blade to the pedestals. The bridge assembly may provide increased stiffness and vibration damping, as well as customized fit options.

An example loosening-resistant blade mounting bracket for an ice skate includes a platform having one or more slot configured to receive a first fastener therethrough for attaching the platform to the bottom of a skate boot. One or more riser is provided substantially perpendicular on the platform. The riser has at least one opening configured to receive a second fastener therethrough for attaching the riser to a skate blade. A set screw may be provided on the at least one riser to tighten the riser against a mounting hump on the skate blade to reduce movement between the at least one riser and the mounting hump.

An example loosening-resistant blade mounting bracket for an ice skate includes a platform having one or more slot configured to receive a first fastener therethrough for attaching the platform to the bottom of a skate boot. One or more riser is provided substantially perpendicular on the platform. The riser has at least one opening configured to receive a second fastener therethrough for attaching the riser to a skate blade. A set screw may be provided on the at least one riser to tighten the riser against a mounting hump on the skate blade to reduce movement between the at least one riser and the mounting hump.

A hockey skate includes a fiber-reinforced, composite frame, or an injected plastic frame, including a boot form and integral pedestals that serve as a blade-holder. The pedestals are integral with the bottom of the boot sole and are optionally spaced relatively far apart to provide a long span between them. An optional bridge assembly may be used to connect the blade to the pedestals. The bridge assembly may provide increased stiffness and vibration damping, as well as customized fit options.