METHOD FOR PRODUCING INDIVIDUALIZED LAST FOR PERSONALIZED FITTING AND SHAPING OF THE INNER SURFACE OF A SHOE

Abstract

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.

Claims

1. A method of producing a shoe last for individual fitting and shaping of the inner surface of the shoe, comprising: production of an individual shoe last based on a precise shape and size of the digital foot model, wherein the actual physical shape of the foot is converted into a foot model using 3D scanning, the digital model is processed to obtain a personalized digital foot model, the digital foot model is divided into parts required for insertion and functioning of a mechanism, and bends in the metatarsophalangeal and ankle joints are simulated, the parts of the foot obtained by dividing the digital model are manufactured, a built-in mechanism to move the parts of the shoe last against each other in three axes of coordinates is developed, based on which and using 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 the form of a physical foot model for a particular foot.

2. The method of claim 1, wherein the process of producing a personalized digital foot model, depending on sensitivity or physiological features of a foot, or pathologies of a human body, the size of digital model can be increased or reduced in toe area, in the metatarsophalangeal articulation, in the bridge of the foot or in the heel.

3. The method of claim 1, wherein in the process of producing a personalized digital foot model, its surface can be smoothed to remove concavities.

4. The method of claim 3, wherein the digital foot model is divided by surfaces, constructed on dimensional points of the mechanism components, a row of surfaces and planes, necessary for functioning of the mechanism and surfaces of conjugation, imitating the joints of the foot.

5. The method of claim 4, wherein a built-in mechanism is individually designed for a specific digital foot model with a muscular mechanical, and/or pneumatic, and/or hydraulic, and/or electric, and/or electromagnetic drive that secures and moves parts of the foot model relative to each other.

6. The method of claim 5, wherein the parts obtained by separating the digital foot model by 3D printing and/or machine cutting, and/or plastic deformation, and/or deforming cutting and/or electrophysical machining, are then manufactured.

7. The method of claim 6, wherein the manufactured parts of the digital foot model and the built-in mechanism are assembled to move parts of the shoe last relative to each other in three axes of coordinates, while securing the parts of the model relative to each other by connecting to the mechanism to obtain an individual shoe last configured for personal fitting and shaping of the inner surface of the shoe.

Description

[0018] The method of producing an individual shoe last for fitting and shaping the inner surface of the shoe includes production of a shoe last that represents the precise shape and size of the foot. The actual physical shape of the foot is converted into a digital foot model using 3D scanning. The digital foot model is divided by surfaces, constructed on dimensional points of the mechanism components, a row of rotation surfaces, spherical surfaces and planes, necessary for functioning of the mechanism, and cylindrical surfaces, imitating the joints of the foot.

[0019] A built-in mechanism is individually designed for a specific digital foot model with a mechanical drive that secures and moves parts of the foot model relative to each other in three axes of coordinates.

[0020] The mechanism has a minimum position, wherein the size of the individual shoe last is reduced in circumference, length and width, which facilitates the insertion of the model in the shoe, and working position in which the individual shoe last is identical to the size of the digital foot model and which involves adjustment by increasing or decreasing the size of the individual block in circumference.

[0021] The parts of the digital foot model are manufactured by 3D printing and subsequent machining, surface grinding.

[0022] The parts are secured relative to each other by connecting to the mechanism to produce an individual shoe last configured for personal fitting and shaping of the inner surface of the shoe.

[0023] The method is implemented as follows.

[0024] 3D scanning results in a digital foot model, FIG. 1, which in this case corresponds to the digital foot model.

[0025] FIG. 2 shows the principle of division of the digital foot model. The model is cut into six parts (1-6) by vertical planes (FIG. 2). Parts 2, 3, 4, 5 and 6 have holes 7, 8, 9, 10, 11 for installation and operation of the mechanism. Holes 12 and 13 are used to secure the extendable mechanism. The gap 14 between parts 3, 4 and 5 is wedge-shaped to provide an imitation of the metatarsophalangeal articulation.

[0026] FIG. 3 shows the lateral-side view. 15 are holes to secure the extendable mechanism. 16 are cylindrical conjugation surfaces between parts 4, 5 and 3 and 6 parts of the foot model and imitate the metatarsophalangeal articulation (FIG. 2). The hole 17 (FIG. 3) is used to place the shafts, which are bent to simulate the metatarsophalangeal articulation, between the parts 5 and 6 of the digital foot model. (FIG. 2). In turn, the shafts installed in these holes are also parts of the extendable mechanism.

[0027] FIG. 4 shows the extendable mechanism. Vertical cylinders 18, 19, 20, 21 of the extendable mechanism are inserted in holes 2 and 13 (FIG. 2) of the foot model, respectively, and secured there with twelve horizontal cylinders 22, 23, 24, 25 (FIG. 4), with all vertical cylinders being composite and consisting of three parts. Horizontal cylinders are inserted in in cylindrical holes 15 (FIG. 3) and rigidly fastened to each of the three parts of the vertical cylinders using a threaded connection 26 (FIG. 4).

[0028] The vertical shaft 28 is connected to the vertical shafts 19 and 21 with four plates, providing horizontal movement of the shafts relative to each other. Similarly, the shaft 27 is connected to shafts 18 and 20. The connecting shaft 30 passes through the middle part of shafts 27 and 28 and perpendicularly to them, with half of the shaft having a right-handed thread, and the other half having the left-handed thread, so that when the shaft rotates, the vertically secured cylinders 27 and 28 either shift, reducing the gap between parts 3 and 4 (FIG. 2), or increase it. This movement allows reducing the volume of the model when inserting it in the shoe, or increasing it while stretching the shoe. Composite design of vertical cylinders allows them to rotate when moving cylinders 27 and 28 relative to shaft 30. A similar stretching mechanism is located at the forepart of the model. The principle of its work is similar to that described above. The only difference is that its height is reduced. Vertical cylinders only consist of one part. The horizontal shafts of both parts of the extendable mechanism are connected to each other by a flexible shaft, which allows the forepart of the model to move relative to the middle part in an angular direction.