A modular technical system for creating a patient-data-specifically individualized foot sole last (15) having a modular structure, characterized in that per zone (16; 24, 25, 26, 27) of the foot sole last (15) it comprises respectively one or more mutually exchangeable standard foot sole last modules (17) as standardized components whichafter selection of the suitable standard module (17) from orthopaedic aspects for the respective zone (16; 24, 25, 26, 27) of a patient's footcan be mounted consecutively along the longitudinal axis (22) of the foot sole last (15) in series zone-wise or at least partially adjacently to one another to form a patient-data-specifically individualized foot sole last (15) having a modular structure, wherein the upper sides of the standard modules (17) are configured depending on shoe size and depending on zone (16) as negative to the corresponding zones (16) of the foot of the patient and/or each have a shape which, specific to shoe size and specific to zone (16), corresponds from orthopaedic aspects to the most logical shape for correction or treatment of one specific or several of the statistically most commonly occurring deformities or diseases requiring treatment from orthopaedic aspects and wherein the transitions (23; 28, 29, 30) between two neighbouring standard modules (17; 24, 25, 26, 27)in the side vieware stepless and smooth andin the plan viewadjoin one another without gaps.

A method for manufacturing an insole for a shoe. The method includes providing instructions to a person to attain a first pose; capturing a first three-dimensional image of a first foot of the person in the first pose; providing instructions to the person to attain a second pose, wherein the second pose is different from the first pose; capturing a second three-dimensional image of a second foot of the person in the second pose; generating a first three-dimensional model of the first foot from the first three-dimensional image; generating a second three-dimensional model of the second foot from the second three-dimensional model; manufacturing a first insole for the first foot based on the first three-dimensional model of the first foot; and manufacturing a second insole for the second foot based on the second three-dimensional model of the second foot.

Various articles, such as footwear, apparel, athletic equipment, watchbands, and the like, and methods of forming those articles are presented. The articles are generally formed, in whole or in part, using rapid manufacturing techniques, such as laser sintering, stereolithography, solid deposition modeling, and the like. The use of rapid manufacturing allows for relatively economical and time efficient manufacture of customized articles. The articles may include one or more reinforcements configured to provide added durability to various regions of the articles. In addition, the articles may be formed from two or more materials in a single rapid manufacturing process. The rapid manufacturing additive fabrication technique may also include using of varying intensities of the laser to fuse material to form the articles.

A high heel shoe that contains a sole insert that includes a forward region supporting the forefoot and a reduced thickness or cut out area disposed beneath the first metatarsal head. The reduced thickness or cut out area provides less support to the first metatarsal head than is provided to other areas of the forward region that support the forefoot. The rear region supports the midfoot and the rearfoot including the heel, with the rear region extending from the forefoot to the back of the optional heel. An arch support may also be provided. Also disclosed are the sole insert itself, methods of making the sole insert and methods of making shoes that contain the sole insert.

A method of producing a customized shoe last for individual fitting and shaping of the inner surface of the shoe includes production of a shoe last based on a precise shape and size of the digital foot model. The actual physical shape of the foot is converted into a foot model using 3D scanning. The digital foot model is divided into parts required for insertion and functioning of a mechanism, and simulation of the bend in the metatarsophalangeal and ankle joints. The parts of the foot obtained by dividing the digital model are then manufactured. An extendable mechanism to move the parts of the shoe last against each other in three axes of coordinates is developed, based the produced parts, an individual shoe last is manufactured in the form of a physical foot model, configured for personal fitting and shaping of an inner surface of the shoe.

In some examples, a sole layer for a footwear includes a housing structure, a cell in the housing structure, a solid support inside the cell to maintain a shape of the cell, and an inlet to the cell to receive an injected material to dissolve the solid support.

A kiosk for providing footcare product recommendations comprises a base, a foot mat positioned in a recess in the base, a removable cover plate positioned over the recess for covering at least a portion of the foot mat, the cover plate comprising an opening leaving at least a portion of the foot mat uncovered, and one or more spacers located in the recess for positioning the foot mat in the recess.

The ability to capture an undistorted image of the foot or foot and ankle is essential to the production of effective custom orthotics and shoes. This patent solves the problem of providing an accurate three-dimensional measurement of an undistorted foot/ankle by using a system involving the automated and controlled orbit of a point cloud capture device around the foot/ankle with the foot/ankle in a non-weight bearing position so as to capture a three-dimensional image.

The present invention discloses a tilting controller that measures foot-related human biomechanical data. The tilting controller for measuring foot-related human biomechanical data includes a mechanism having a foot hold on which a rear foot portion is placed, and a control module that tilts the foot hold by controlling the mechanism portion.

Disclosed is a technique for use in generating and delivering 3-D printed wearables via the use of body image data where the body is in under multiple physical conditions. Some embodiments include further body part data including videos of sequences of motion, static images, both 2-D and 3-D modeling, and user preference. Users take videos and/or photos of parts of their body as input into a custom wearable generation application. The body photos are subjected to a precise computer vision (CV) process to determine specific measurements of the user's body and the stresses.