WO2019171426A1 - Shoe spacer designing system - Google Patents

Abstract

The present invention addresses the problem that a shoe that is made to order to realize an ideal foot comfort not only requires a long time to make and is expensive, but also is often limited in design. This shoe spacer designing system (100) is provided with: a database (101) in which a plurality of pieces of model foot three-dimensional data (Dm) are stored; a selection unit (102) which, on the basis of a predetermined rule, overlays customer foot three-dimensional data (Dc) on each of the plurality of pieces of model foot three-dimensional data (Dm), and selects from among the plurality of pieces of model foot three-dimensional data (Dm) model foot three-dimensional data (Dm) from which the overlaid customer foot three-dimensional data (Dc) does not protrude; a determination unit (103) which, on the basis of a predetermined standard, determines one piece of model foot three-dimensional data (Dm) from among the selected model foot three-dimensional data (Dm); and a shoe spacer three-dimensional data generation unit (104) which, utilizing a difference between the customer foot three-dimensional data (Dc) and the one model foot three-dimensional data (Dm) that has been determined, generates shoe spacer three-dimensional data corresponding to the customer foot three-dimensional data (Dc).

Description

Shoe spacer design system

The present invention relates to a shoe spacer design system for designing a shoe spacer.

The shoes that originated from sandals worn by royals in ancient Egypt spread around the world as income increased.

Since the foot shape varies depending on the race, it is said that about 40 standard size models are prepared for one ready-made shoe, but it is difficult to absorb the individual variations of various sizes representing the foot shape. And quite a few people suffer from shoe rubs.

Therefore, a shoe manufacturing method that can easily change the foot circumference size of a shoe having one foot length and a foot width size is known (for example, see Patent Document 1).

JP 2002-101912 A

However, custom-made shoes for realizing ideal comfort not only require a long manufacturing time and are expensive, but also the design is often limited.

The present inventor is also paying attention to the reality that the transition from real store sales to online sales is delayed with regard to shoe sales with trial wear.

An object of the present invention is to provide a shoe spacer design system that can realize an ideal comfort at a low cost in consideration of the conventional problems described above.

A first aspect of the present invention is a database for storing a plurality of model foot three-dimensional data;
Based on a predetermined rule, customer foot 3D data is superimposed on each of the plurality of model foot 3D data, and the model foot 3D data that does not protrude from the superimposed customer foot 3D data A selection unit to select from among the model foot 3D data,
A determination unit that determines one model foot three-dimensional data from the selected model foot three-dimensional data based on a predetermined criterion;
Using the difference between the customer foot 3D data and the determined one model foot 3D data, a shoe spacer tertiary that generates shoe spacer 3D data corresponding to the customer foot 3D data An original data generation unit;
A shoe spacer design system comprising:

According to a second aspect of the present invention, in the predetermined rule, the customer foot three-dimensional data is set such that a matching starting point of the former part in the customer foot three-dimensional data matches a matching starting point of the former part in the model foot three-dimensional data. This is a shoe spacer design system according to the first aspect of the present invention, characterized in that the rule is superimposed on the model foot three-dimensional data.

A third aspect of the present invention is the shoe spacer design system according to the first or second aspect, wherein the predetermined criterion is a criterion for determining three-dimensional model foot data having a minimum foot length. .

According to a fourth aspect of the present invention, in the first or second aspect of the present invention, the predetermined criterion is a criterion for determining model foot three-dimensional data having a minimum difference from the customer foot three-dimensional data. Is a shoe spacer design system.

According to a fifth aspect of the present invention, the difference is a distance between the upper portion and the heel portion or a difference regarding a three-dimensional space between the upper portion and the heel portion. This is a shoe spacer design system.

According to the present invention, it is possible to provide a shoe spacer design system capable of realizing ideal comfort at low cost.

The typical explanatory view of the composition of the shoe spacer design system of an embodiment in the present invention. The typical perspective view of the shoe spacer of an embodiment in the present invention. Block diagram of a shoe spacer design system according to an embodiment of the present invention Explanatory drawing of customer foot three-dimensional data of embodiment in this invention Schematic explanatory diagram of model foot three-dimensional data according to an embodiment of the present invention (part 1) Schematic explanatory diagram of model foot three-dimensional data according to the embodiment of the present invention (part 2) Schematic explanatory diagram of model foot three-dimensional data according to the embodiment of the present invention (No. 3) Schematic explanatory diagram of model foot three-dimensional data according to the embodiment of the present invention (No. 4) Schematic perspective view of the marking according to the embodiment of the present invention (part 1) Typical perspective view of the marking of embodiment in this invention (the 2)

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

First, the configuration of the shoe spacer design system 100 of the present embodiment will be specifically described with reference mainly to FIGS.

FIG. 1 is a schematic explanatory view of the configuration of the shoe spacer design system 100 according to the embodiment of the present invention. FIG. 2 is a schematic perspective view of the shoe spacer 10 according to the embodiment of the present invention. FIG. 3 is a block diagram of the shoe spacer design system 100 according to the embodiment of the present invention.

The shoe spacer design system 100 includes a database 101, a selection unit 102, a determination unit 103, and a shoe spacer three-dimensional data generation unit 104.

The configurations of the database 101, the selection unit 102, the determination unit 103, the shoe spacer three-dimensional data generation unit 104, and the like are realized using a cloud server 22 such as a personal computer.

The customer images the customer's foot 11 as still image data or moving image data with the smartphone 21 or the like in which dedicated application software that can also be used for foot chart self-management is installed after the trial period. Then, the two-dimensional image data of the customer foot 11 is transmitted from the smartphone 21 to the cloud server 22 and converted into the customer foot three-dimensional data Dc by the cloud service software. The input unit 105 is a unit that inputs such two-dimensional image data from the smartphone 21 to the selection unit 102.

For example, a shoe manufacturer fills an unmatching gap between the customer foot 11 and the model foot based on the customer foot 3D data Dc and the corresponding shoe spacer 3D data, such as a silicone resin material similar to the inner sole. The three-dimensional shoe spacer 10 is molded on demand by a 3D (three-dimensional) printer 23. The output unit 106 is a unit that outputs such shoe spacer three-dimensional data from the shoe spacer three-dimensional data generation unit 104 to the 3D printer 23.

Therefore, the individual custom-made service of the shoe spacer 10 is realized at low cost by the IoT (Internet of Things) technology using the cloud 20, and one excellent business plan for providing low-priced so-called semi-custom-made shoes is completed. Is done.

Next, the configuration of the shoe spacer design system 100 of the present embodiment will be described more specifically with reference mainly to FIGS.

4 is an explanatory diagram of the customer foot three-dimensional data Dc according to the embodiment of the present invention. FIGS. 5 to 8 are schematic explanatory diagrams of the model foot three-dimensional data Dm according to the embodiment of the present invention (FIG. One to four).

5 to 8, the model foot three-dimensional data Dm is indicated by a solid line, and the customer foot three-dimensional data Dc for reference is indicated by a one-dot chain line.

In FIG. 5, the superimposed customer foot 3D data Dc does not protrude from the model foot 3D data Dm. In FIG. 6, the superimposed customer foot 3D data Dc protrudes from the model foot 3D data Dm.

In FIG. 7, the superimposed customer foot three-dimensional data Dc does not protrude from the model foot three-dimensional data Dm, and the distance δ and the three-dimensional space Σ are considerably small. In FIG. 8, the superimposed customer foot three-dimensional data Dc does not protrude from the model foot three-dimensional data Dm, but the distance δ and the three-dimensional space Σ are considerably large.

The database 101 is a database that stores a plurality of model foot three-dimensional data Dm.

The selection unit 102 converts the customer foot 3D data Dc into the model foot 3D data so that the matching start point Pc of the back portion in the customer foot 3D data Dc matches the matching start point Pm of the back portion in the model foot 3D data Dm. Based on the rule for superimposing with Dm, the customer foot 3D data Dc is overlaid with each of the plurality of model foot 3D data Dm, and the overlaid customer foot 3D data Dc does not protrude. Is a unit that selects from among a plurality of model foot three-dimensional data Dm.

An example of the predetermined rule in the present invention is that the customer foot three-dimensional data Dc is set so that the matching starting point Pc of the upper part in the customer foot three-dimensional data Dc matches the matching starting point Pm of the upper part in the model foot three-dimensional data Dm. This is the rule of the present embodiment described above that is superimposed on the model foot three-dimensional data Dm.

The determination unit 103 is a unit that determines one model foot three-dimensional data Dm from among the selected model foot three-dimensional data Dm based on a criterion for determining the model foot three-dimensional data Dm having the minimum foot length λ. It is.

An example of the predetermined standard in the present invention is the above-described standard for determining the model foot three-dimensional data Dm having the minimum foot length λ.

In the embodiment of the modification, an example of the predetermined standard in the present invention is a customer regarding the distance δ between the upper part and the heel part or the three-dimensional space Σ between the upper part and the heel part. It may be a criterion for determining the model foot three-dimensional data Dm having the smallest difference from the foot three-dimensional data Dc.

The shoe spacer three-dimensional data generation unit 104 uses the difference between the customer foot three-dimensional data Dc and the determined one model foot three-dimensional data Dm, and the shoe foot corresponding to the customer foot three-dimensional data Dc. A unit that generates spacer three-dimensional data.

It is extremely effective to pay attention to the difference between the customer foot 3D data Dc and the determined one model foot 3D data Dm. That is, the present inventor has realized that the matching between the customer foot 11 and the model foot, rather than the matching between the customer foot 11 and the shoe, is quite important for the comfort. Therefore, by forming the shoe spacer 10 that fills the difference between the customer foot 3D data Dc of the customer foot 11 and the model foot 3D data Dm of the standard model foot assumed by the shoe manufacturer, It is possible to reproduce the ideal comfort that is assumed by shoe manufacturers.

Next, the operation of the shoe spacer design system 100 of the present embodiment will be specifically described with reference mainly to FIGS.

While explaining the operation of the shoe spacer design system 100 of the present embodiment, the shoe spacer design method of the invention related to the present invention will also be explained.

(Model foot 3D data storage step)
The database 101 stores a plurality of model foot three-dimensional data Dm.

For example, one ready-made shoe is provided with 40 model foot three-dimensional data Dm corresponding to about 40 standard size models.

(Model foot 3D data selection step)
The selection unit 102 converts the customer foot 3D data Dc into the model foot 3D data so that the matching start point Pc of the back portion in the customer foot 3D data Dc matches the matching start point Pm of the back portion in the model foot 3D data Dm. Based on the rule for superimposing with Dm, the customer foot 3D data Dc is overlaid with each of the plurality of model foot 3D data Dm, and the overlaid customer foot 3D data Dc does not protrude. Are selected from a plurality of model foot three-dimensional data Dm.

Typically, as described above, the two-dimensional image data of the customer foot 11 is transmitted from the smartphone 21 to the cloud server 22 and converted to the customer foot three-dimensional data Dc.

However, a 2D image data upload service may be provided in which a real store staff images the customer foot 11 with a dedicated imaging device or the like, and the 2D image data of the customer foot 11 is transmitted to the cloud server 22.

That is, the shoe spacer design system 100 is effective not only in the B2C (Business-to-Consumer) business but also in the B2B (Business-to-Business) business.

The conversion from the 2D image data to the customer's 3D data Dc is realized by a known 3D data shape restoration technique without a large-scale 3D measuring device. In order to improve the image recognition accuracy in such a three-dimensional data shape restoration technique, as shown in FIGS. 9 and 10, the customer wears a sock 12 on which a large number of markings M with patterns or colors are printed. In this state, the customer foot 11 may be imaged.

9 and 10 are schematic perspective views (No. 1 and No. 2) of the marking M according to the embodiment of the present invention.

The socks 12 described above may be prepared according to the size of the customer's feet 11 and delivered to the customer. The upper marking Mi indicating the upper portion corresponding to the matching starting point Pc of the upper portion, and the heel portion, which are used to determine one model foot three-dimensional data Dm from the selected model foot three-dimensional data Dm, It is desirable that the heel marking Mh shown is printed on the socks 12. And so as to obtain accurate imaging data corresponding to the front view, the rear view, the left side view, the right side view, the plan view, and the bottom view, a lattice pattern or the like that assists the imaging by the customer is printed on the socks 12. May be.

The customer foot three-dimensional data Dc may be stored as IoT personal information and sold to a shoe manufacturer developing a product.

(Model foot 3D data determination step)
The determination unit 103 determines one model foot three-dimensional data Dm from the selected model foot three-dimensional data Dm based on a criterion for determining the model foot three-dimensional data Dm having the minimum foot length λ.

In the embodiment of the modified example, the determination unit 103 determines the distance δ between the upper part and the heel part or the customer foot three-dimensional data Dc regarding the three-dimensional space Σ between the upper part and the heel part. One model foot three-dimensional data Dm may be determined from among the selected model foot three-dimensional data Dm based on a criterion for determining the model foot three-dimensional data Dm having the smallest difference from the above.

It is extremely effective to pay attention to the difference from the customer foot three-dimensional data Dc regarding the distance δ between the former part and the heel part or the three-dimensional space Σ between the former part and the heel part. That is, the present inventor has realized through matching with a customer questionnaire and the like that matching between the instep portion and the heel portion, which has hardly been omitted until now, is quite important for the comfort. Therefore, by forming the shoe spacer 10 that fills the difference between the upper part and the heel part, it is possible to reproduce the ideal comfort assumed by the shoe manufacturer.

As described above, the model foot three-dimensional data determination step may be executed after the model foot three-dimensional data selection step, but may be executed before the model foot three-dimensional data selection step. For example, a plurality of model foot three-dimensional data Dm are sequentially examined in the order of the length of the foot length λ until the model foot three-dimensional data Dm in which the superimposed customer foot three-dimensional data Dc does not protrude is found. Also good. In other words, it is important that one optimal model foot three-dimensional data Dm is finally determined based on the above-described criteria, in which the superimposed customer foot three-dimensional data Dc does not protrude.

(Shoe spacer three-dimensional data generation step)
The shoe spacer three-dimensional data generation unit 104 uses the difference between the customer foot three-dimensional data Dc and the determined one model foot three-dimensional data Dm, and the shoe foot corresponding to the customer foot three-dimensional data Dc. Generate 3D spacer data.

Typically, as described above, the shoe manufacturer forms the shoe spacer 10 on-demand by the 3D printer 23 based on the shoe spacer three-dimensional data corresponding to the customer foot three-dimensional data Dc.

However, with the spread of 3D printers, customers may be provided with a shoe spacer 3D data delivery service in which the shoe spacer 10 is molded at the nearest print shop.

In the formation of the shoe spacer 10, the comfort may be improved by using data obtained as a measurement result by a laser device that measures the three-dimensional space inside the shoe.

Of course, even if the shoe spacer 10 incorporates an intelligent small IoT sensor such as a wire type displacement sensor that measures body temperature, exercise amount, working time, calorie consumption, energy consumption, etc. according to customer requests. Good. Human motion data obtained as a result of sensor measurement is transmitted to an online storage such as the cloud server 22 in real time via a mobile terminal device such as the smartphone 21 and stored as IoT personal information. With the spread of AI (Artificial Intelligence), an IoT health management system that provides a health maintenance advice service that contributes to reducing insurance use by grasping the amount of exercise of the public by analyzing basic statistics of exercise statistics collected automatically is realized. Is done.

The sole measurement mat may be incorporated in the shoe spacer 10, and visualization of the sole may be realized using data obtained as a result of the sole measurement. If the arch arch is formed by the use of a suitable shoe spacer 10, the weight associated with the flat foot is greatly improved since the weight is applied straight to the sole.

Odor measuring device and deodorant material are incorporated in the shoe spacer 10, and the reduction of malodor may be realized by using data obtained as a result of odor measurement.

The program of the invention related to the present invention causes a computer to execute the operations of all or part of the steps (or processes, operations and actions) of the shoe spacer design method of the present invention related to the present invention described above. Which is a program that operates in cooperation with a computer.

The recording medium of the invention related to the present invention is the operation of all or a part of all or a part of steps (or processes, operations and actions) of the shoe spacer design method of the invention related to the present invention described above. Is a computer-readable recording medium on which a program for causing a computer to execute is recorded, and the read program is used in cooperation with a computer.

It should be noted that the “partial steps (or processes, operations, actions, etc.)” described above means one or some of the plurality of steps.

Also, the above-mentioned “operation of a step (or process, operation, action, etc.)” means an operation of all or a part of the above-described step.

Also, one use form of the program of the invention related to the present invention is a form in which the program is transmitted through a transmission medium such as the Internet, light, radio wave or sound wave, read by a computer, and operates in cooperation with the computer. It may be.

The recording medium includes ROM (Read Only Memory) and the like.

The computer is not limited to pure hardware such as a CPU (Central Processing Unit), but may include firmware, an OS (Operating System), and further peripheral devices.

Note that, as described above, the configuration of the present invention may be realized by software or hardware.

The shoe spacer design system according to the present invention can achieve ideal comfort at a low cost, and is useful for the purpose of being used in a shoe spacer design system for designing a shoe spacer, for example.

10 shoe spacer 11 customer foot 12 socks 20 cloud 21 smartphone 22 cloud server 23 3D printer 100 shoe spacer design system 101 database 102 selection unit 103 decision unit 104 shoe spacer 3D data generation unit 105 input unit 106 output unit Dc customer foot 3D Data Dm Model foot 3D data Pc, Pm Matching origin λ Foot length δ Distance Σ 3D space M Marking Mi Instep marking Mh 踵 Marking

Claims (5)

1. A database for storing a plurality of model 3D data,
   Based on a predetermined rule, customer foot 3D data is superimposed on each of the plurality of model foot 3D data, and the model foot 3D data that does not protrude from the superimposed customer foot 3D data A selection unit to select from among the model foot 3D data,
   A determination unit that determines one model foot three-dimensional data from the selected model foot three-dimensional data based on a predetermined criterion;
   Using the difference between the customer foot 3D data and the determined one model foot 3D data, a shoe spacer tertiary that generates shoe spacer 3D data corresponding to the customer foot 3D data An original data generation unit;
   A shoe spacer design system comprising:
2. The predetermined rule is that the customer foot 3D data is converted into the model foot 3D data so that the matching start point of the back portion in the customer foot 3D data matches the matching start point of the shell portion in the model foot 3D data. The shoe spacer design system according to claim 1, wherein the rule is a superposition rule.
3. The shoe spacer design system according to claim 1 or 2, wherein the predetermined standard is a standard for determining three-dimensional model foot data having a minimum foot length.
4. 3. The shoe spacer design system according to claim 1, wherein the predetermined standard is a standard for determining model foot three-dimensional data having a minimum difference from the customer foot three-dimensional data.
5. The shoe spacer design system according to claim 4, wherein the difference is a distance between the upper part and the heel part, or a difference regarding a three-dimensional space between the upper part and the heel part.

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