A shoe sizing assembly for measuring and constructing custom shoe sizes includes a panel that is positionable on a support surface for having a person's foot placed thereon. A scanner is coupled to the panel and the scanner emits a measuring signal upwardly from the panel thereby facilitating the scanner to detect the sole of person's foot. In this way the scanner measures the size of the person's foot. A heating element is coupled to the panel and the heating element heats the panel when the heating element is turned. Thus, the heating element melts an adhesive between the shoe sole and the shoe upper for bonding the shoe sole to the shoe upper.

The present invention relates to an apparatus comprising: a seat for a patient; a support platform for the feet of the patient, positioned anteriorly to the seat; an alignment system allowing a patient's leg and its corresponding foot to be aligned in the three space planes in order to determine the tibia correct verticality; a system for properly positioning the foot on the platform including at least turrets able to allow pads to be applied in contact with the talus and/or scaphoid inside the foot and in contact with the calcaneus and/or cuboid outside the foot; a foot measurement system in a neutral position; an automatic real time driving system for properly positioning the leg and foot with numerical indication and direction of the movements to be carried out; a central unit capable for receiving and processing the data detected by the measurement system for footprint digitalization.

This disclosure relates to a computer-implemented system and related methods for the design, evaluation, and/or manufacture of protective patient footwear, such as shoes, braces, boots, casts, corrective footwear, and orthoses. The system includes suitable hardware, software, and related peripherals, which function to acquire data related to the patient's particular footwear needs, such as by image capture, including three-dimensional scanning. The system may also acquire data through other sources of input, such as through one or more sensors for detecting various physiologic parameters associated with the lower extremity, or through input of medical conditions, prior indicators, exam, analysis, lab results, or the like, such as through medical practitioner input or other input protocols. The various inputs may be suitably processed to generate output in the form of a design accommodation to design or modify the protective patient footwear, or in the form of one or more medical evaluations or recommendations.

Methods and apparatuses for designing custom footwear are disclosed. An apparatus for designing custom footwear may include a data collection system, a data processing system, and a manufacturing system, where the manufacturing system includes an additive manufacturing device. A method for designing custom footwear may comprise receiving user-specific data, generating a user model, identifying issues in the user model, determining corrective features, generating a custom footwear model, and manufacturing the custom footwear.

Disclosed is a platform for generating and delivering 3-D printed wearables. The platform includes scanning, image processing, machine learning, computer vision, and user input to generate a printed wearable. Scanning occurs in a number of ways across a number of devices. The variability of scanning generates a number of scanning output types. Outputs from the scanning process are normalized into a single type during image processing. The computer vision and machine learning portions of the platform use the normalized body scan to develop models that may be used by a 3D printer to generate a wearable customized to the user. The platform further provides opportunities for the user to check the work of the scanning, image processing, computer vision, and machine learning. The user input enables the platform to improve and inform the machine learning aspects.

The present disclosure relates to a shoemaking system, including a processing unit, a first conveying device, a first pickup device, a scanning device, a first coating device and a first applying device. The first conveying device comprises at least one support; the first pickup device picks up an upper and the upper is disposed on the first support of the first conveying device. The scanning device is connected to the processing unit and can scan a scanning area; the first conveying device moves the upper on the first support to the scanning area. The scanning device scans the upper in the scanning area and outputs three-dimensional structure data; the processing unit obtains the three-dimensional structure data from the scanning device and decides a first coating path and a first applying path. The first coating device is configured to spray a first treating agent to the upper according to the first coating path; the first applying device is configured to apply a first adhesive to the upper according to the first applying path.

A method and apparatus is provided for measuring human feet shape. Method and apparatus are designed to be effective for large scale measurement of feet, for example in shoe stores. Measurement is very fast, reliable, accurate, convenient for end consumer and easy to use either in self-service or by a trained operator. Apparatus involves usage of either one or multiple depth sensors, which capture part of the foot shape or whole foot surface, depending on the setup. Depth sensors are capable of capturing an image with depth information, which results in a three-dimensional point cloud from each sensor. Apparatus may be combined with a pressure plate, which provides complementary information on end-consumers feet and the gait behavior. The innovation provides a solution for many commercial/noncommercial applications, such as shoe retail business (matching the foot to particular footwear), biometrical research (examining the distribution of feet properties within particular population), clinical examination, etc.

An article of footwear includes an upper and a sole structure with a sole member. The sole member can be manufactured using a customized cushioning sole system. A user's foot morphology and/or preferences may be used to design the sole member. The sole member can include a column of apertures that are formed along the outer surface of the sole member.

One aspect of this disclosure is a method comprising: receiving, from a camera, a video feed depicting a pair of feet and a scaling object; capturing, with the camera, images of the feet and the scaling object based on the video feed; identifying foot features in each captured image; determining camera positions for each captured image by triangulating the foot features; generating a point cloud in a three-dimensional space by positioning each foot feature in the three-dimensional space based on the camera positions; scaling the point cloud based on the scaling object; segmenting the point cloud into at least a right-foot cluster and a left-foot cluster; fitting a first three-dimensional morphable model to the right-foot cluster according to first foot parameters; and fitting a second three-dimensional morphable model to the left-foot cluster according to second foot parameters. Related systems, apparatus, and methods also are described.

The present invention relates to a method of preparing insoles and to a system for preparing insoles. The invention uses a machine for imaging the foot inserted in the footwear, designs an insole and produces the insole for instance with a three dimensional printer.