An apparatus for adjusting a shoe and methods for making and using the same. A relative movement can be generated between a platform and a model foot wearing the shoe such that the platform contacts the shoe and the model foot adjusts the shoe via the relative movement. Advantageously, the model foot can be a surrogate to a human foot in adjusting the shape of the shoe. The model foot can stretch the shoe in the same manner as human walk. A person can experience great comfort when wearing the stretched shoe. The model foot can simulate the mechanical characteristics of the natural foot. The model foot can simulate gait of a natural foot and the stretching of the shoe can be further customized.

A shoe tree having a body with an exterior surface for contacting an interior surface defining a shoe interior cavity during storage. An adjustment member removably engages with a mount on a rear wall of the body of the shoe tree and is engaged to a heel member. The heel member, when rotated on the adjustment member, will increase or decrease the overall length of the shoe tree. The body portion may include an insert which has indicia thereon concerning one or both of a location of purchase or the owner of the shoe tree.

A method of customizing a boot, for example a skate boot, includes generating a tridimensional digital representation of a wearer's foot using numerical data obtained by scanning the wearer's foot. A boot with a foot size corresponding generally to a foot length of the wearer's foot is selected. A core is also selected. The core, a medial side insert and a lateral side insert are inserted into an internal space of the boot such that the medial side insert and the lateral side insert straddle the core. The medial side insert and the lateral side insert are manufactured based on the tridimensional shape of the foot. At least a portion of the boot is then heated such that the boot is thermoformed to follow surfaces of the medial and lateral side inserts. The core, the medial side insert and the lateral side insert are then removed from the boot.

The present disclosure relates to a device for retaining the shape of a shoe. The shoe insert provided herein for retaining the shape of a shoe includes a toe fabric bag and a vamp fabric bag. Each fabric bag may be made of a malleable form-fitting fabric. Each fabric bag may be of different sizes and shapes to fit shoes of different sizes and shapes. Also disclosed are methods of manufacturing a shoe insert and methods of using a device for retaining the shape of a shoe.

A boot tree holder has a leg portion. The leg portion is configured to be inserted into an ankle part of a boot. A swivel component is coupled to the leg portion. A toe portion is coupled to the swivel component. The toe portion is to be inserted into a foot part of the boot. The swivel component is configured to provide an angle between the toe portion and the leg portion that is adjustable.

An apparatus for effecting the positioning of cleats on shoes includes a baseplate to apply the arch of the foot, a gauge provided with a stop that can slide freely on the baseplate to be in contact with the calcaneum of the foot, and a wall for wedging the front part of the foot at the metatarsophalangeal joint of the big toe. The stop is fixed on a plate that slides parallel to the baseplate and a support for a shoe corresponding to the foot is fixed to the sliding plate. The support includes a stop to be placed in contact with the shoe counter. A marker is secured to the apparatus base and designed to indicate, on the shoe sole, the location for placing the cleat. The apparatus enables the distance recorded between the metatarsophalangeal joint of the big toe and calcaneum to be transferred onto the shoe.

A method of method of manufacturing customized inserts for a boot, such as a skate boot, that is at least partially thermoformable includes receiving numerical data corresponding to a tridimensional shape of a wearer’s foot, and manufacturing a medial side insert and a lateral side insert based on the tridimensional shape of the wearer’s foot. The medial side insert and the lateral side insert are shaped to be insertable into the boot with a core that is dimensioned to generally correspond to a foot size of the boot, with a medial internal surface of the medial side insert and a lateral internal surface of the lateral side insert abutting respective outer surfaces of the core.

A computer system generates information describing authenticity and a grade of a collectible scanned by a scanning device. A feature vector is extracted from the information. The feature vector includes a first set of features and a second set of features. The first set of features is matched to authenticity profiles of collectible items. Each authenticity profile characterizes at least one collectible item across multiple features. A confidence score is generated with respect to the authenticity of the collectible based on the authenticity profiles. The second set of features is matched to grade profiles of the collectible items. A grade score describing the grade of the collectible is generated based on the grade profiles. The grade of the collectible is determined based on the grade score. A graphical representation of the grade and the confidence score is transmitted to a display device.

A shoetree includes a tubular element adapted to be inserted in a shoe and to bear at one end a portion that substantially reproduces the shape of the toe of a shoe. The opposite end includes with a shoehorn-shaped portion, which is pivoted to the tubular element, in order to pass from a condition for use as a shoetree to a condition for use as a shoehorn.

Disclosed is a method for manufacturing a device for adapting a footwear to the specific deformations of the foot of a user, including creating 3D scans of the foot in weight bearing and non-weight bearing positions, as well as of the footwear; determining rubbing areas between the foot and the footwear by means of superimposing the scanned 3D image of the footwear and the scanned 3D images of the weight bearing and the non-weight bearing foot; obtaining a final out-of-phase 3D image of the non-weight bearing foot, wherein the rubbing areas in this image are moved out of phase until they reach an intermediate position selected between a minimum and a maximum limit; printing the part of the heel and the part of the forefoot from the final out-of-phase 3D image. Finally, fitting a flexible element for joining together the part of the heel and the part of the forefoot.