CN117122123A

CN117122123A - Intelligent shoe and manufacturing method thereof

Info

Publication number: CN117122123A
Application number: CN202210548073.9A
Authority: CN
Inventors: 汪伟; 何永刚; 张涛; 陈晓旭
Original assignee: Zhuhai Tianwei Additives Co ltd
Current assignee: Zhuhai Tianwei Additives Co ltd
Priority date: 2022-05-18
Filing date: 2022-05-18
Publication date: 2023-11-28

Abstract

The invention provides an intelligent shoe and a manufacturing method thereof, wherein the intelligent shoe comprises a shoe body, an insole and a monitoring device, the shoe body is provided with a sole and an vamp, the shoe body is provided with a shoe cavity, the insole is arranged in the shoe cavity, the sole and/or the insole is made of a first 3D printing forming material, the sole or the insole is provided with a functional area, the functional area comprises a toe area, a half sole area and a heel area, the functional area is made of a second 3D printing forming material, the second 3D printing forming material comprises a 4D material, the monitoring device is arranged in the sole and/or the insole, the monitoring device comprises a processor, a sensing module, a power management module and a wireless communication module, the sensing module is respectively and electrically connected with the processor, the sensing module sends detection data to the processor, and the processor controls the 4D material to deform according to the detection data. The manufacturing method is used for manufacturing the intelligent shoe, the intelligent shoe is low in customization cost, and can be suitable for various sports scenes and can be adjusted in self-adaptability according to different sports scenes.

Description

Intelligent shoe and manufacturing method thereof

Technical Field

The invention relates to the technical field of shoes, in particular to an intelligent shoe and a method for manufacturing the intelligent shoe.

Background

With the continuous development of science and technology and the continuous improvement of life quality requirements of people, the requirements of people on wearing articles are also higher and higher, and the functional requirements of the wearing articles are also more and more, especially for sports equipment. For example, the sports shoes are suitable for the sports shoes, not only have good wearing comfort, but also are beneficial to protecting feet, and in addition, the good sports shoes are beneficial to improving sports performance; the conventional sports shoes generally have a structure of adding an air cushion or an air bag and the like to the sole to assist in shock absorption so as to improve the shock absorption performance, but the sole structure is complicated, the weight is increased, the problem of inconvenient processing occurs, and the shoes cannot meet the requirement of light weight. At present, there is mill to print sole hollow out construction through 3D printing technique in order to satisfy the lightweight requirement, even to some more professional sports shoes, the mill can gather sports personnel's foot data and customize dedicated sports shoes according to the foot data who gathers, and this kind of mode can improve the travelling comfort of sports shoes and make the sports shoes satisfy sports personnel's functional requirement, but its shortcoming that has:

firstly, the customization cost is high, and the common user is difficult to consume;

secondly, the foot needs to be scanned by a special 3D laser scanner, although the customization accuracy is higher, the user is required to scan or self-purchase the 3D laser scanner on site, and the foot data of the user is easy to excessively collect and leak;

thirdly, the sports shoes do not have a motion detection function, and the sports shoes cannot carry out matching adjustment on the sports shoes under different sports conditions.

Disclosure of Invention

In order to solve the problems, the main purpose of the invention is to provide an intelligent shoe which has low customization cost, is applicable to various sports scenes and can adjust the self-adaptability according to different sports scenes.

Another object of the present invention is to provide a method for manufacturing the intelligent shoe.

In order to achieve the main object of the present invention, the present invention provides an intelligent shoe, comprising a shoe body and an insole, the shoe body having a sole and an upper, the sole being connected to the upper, the shoe body having a shoe cavity, the insole being disposed in the shoe cavity, wherein the sole and/or the insole is printed from a first 3D printing forming material, the sole or insole having a functional area, the functional area comprising a toe area, a half sole area and a heel area, the functional area being printed from a second 3D printing forming material, the second 3D printing forming material comprising a 4D material, the intelligent shoe further comprising a monitoring device, the monitoring device being disposed in the sole and/or insole, the monitoring device comprising a processor, a power management module and a wireless communication module, the processor being electrically connected to the sensing module, the power management module, the wireless communication module, respectively, the sensing module sending detection data to the processor, the processor controlling the 4D material to deform according to the detection data.

From the above, through the design of the intelligent shoe, the adaptation scene of the intelligent shoe is wide, the intelligent shoe can adapt to different sports scenes, and adaptive changes can be made in the different sports scenes, so that the most comfortable experience is provided for a user, wherein the cooperation of the 4D material and the monitoring device can better detect and match different movements, and the wireless communication module can perform information interaction with the intelligent terminal (such as a mobile phone, an intelligent watch, a tablet computer and the like), so that the user can know the current state and related data of the intelligent shoe through the intelligent terminal, and meanwhile, the user can perform corresponding parameter setting, control and the like on the intelligent shoe through the intelligent terminal; in addition, the intelligent shoe can realize accurate customization, so that the intelligent shoe can be better attached to the foot of a user, and the use experience of the user is improved.

In a preferred embodiment, the sensing module includes a nine-axis sensor and a positioning monitor sensor, and the nine-axis sensor and the positioning monitor sensor are respectively electrically connected with the processor.

From the above, the design of the sensing module enables the monitoring device to accurately detect the movement gesture of the user so as to adjust the intelligent shoe, so that the intelligent shoe is adapted to the current movement state of the user.

Another preferred embodiment is that the 4D material comprises one or more materials that deform with at least one of motion strength, temperature, humidity, pressure, and match the motion scene in which the intelligent shoe is positioned.

From the above, the 4D material can be correspondingly deformed under the stress condition of the material, the external temperature, the external humidity and the like, so that the areas closely contacted with the feet, namely the toe area, the half sole area and the heel area, can be self-regulated in real time to adapt to the current motion state of a user, and the comfort of the intelligent shoe is improved.

Further, the 4D material includes a deformable material, and the monitoring device is configured to control the deformable material to deform according to a preset deformation mode.

From the above, the monitoring device can adjust the 4D material to deform according to the detected data, so that the areas of the toe area, the half sole area and the heel area, which are in close contact with the foot, can be better attached to the foot.

In another further scheme, the 4D material comprises a temperature change material, and the monitoring device can control the temperature change material to change the temperature according to a preset temperature change mode.

From the above, the monitoring device can adjust the temperature of the 4D material according to the detected data, so that the foot is more comfortable.

In yet a further aspect, the 4D material includes a humidity variable material, and the monitoring device is configured to control the humidity variable material to change humidity according to a predetermined humidity change pattern.

From the above, the monitoring device can adjust the humidity of the 4D material according to the detected data, so that the foot is more comfortable.

Still further, the vamp is made of a third 3D printing forming material, or the vamp is made of one or more of textile material, mesh cloth, leather, artificial leather, synthetic material, PVC, PU, nubuck, superfine fiber, natural leather, EVA, TPR, SBS.

From the above, the vamp can be manufactured by selecting corresponding materials according to the factors such as the use requirement, the comfort requirement, the appearance requirement and the like, so that the comfort of the vamp is ensured, and the vamp can be better attached to the foot of a user.

In another preferred form, the 4D material comprises a TPU material and one or more of dibutyltin dilaurate, nano zinc oxide, and diisopolyacrylate; or the 4D material comprises EVA material and one or more materials of dibutyl tin dilaurate, nano zinc oxide and diisopolyacrylate.

The power management module comprises a battery and a first control unit, and the first control unit is respectively and electrically connected with the battery and the processor; or the power management module comprises a friction power generation unit and a second control unit, and the second control unit is respectively and electrically connected with the friction power generation unit and the processor.

From the above, the power management module can be set into a storage battery form or a self-generating form, so that the power management module can provide enough power for the processor, the sensing module and the wireless communication module to ensure that the processor, the sensing module and the wireless communication module can work normally and stably.

In order to achieve another object of the present invention, the present invention provides a method for manufacturing an intelligent shoe, comprising taking photographs of feet at different angles, taking tread patterns of toes, forefeet and heels of the feet in a stationary state and a moving state, generating three-dimensional data of the feet by three-dimensional image composition software; manufacturing three-dimensional models of soles and insoles according to the three-dimensional data; the method comprises the steps of printing a first 3D printing forming material to form a sole and an insole, wherein the sole or the insole is provided with a functional area, the functional area comprises a toe area, a half sole area and a heel area, printing a second 3D printing forming material to form the functional area, implanting a monitoring device into the sole and/or the insole in the process of printing the sole and the insole, wherein the second 3D printing forming material comprises a 4D material, and the monitoring device can control the 4D material to deform; the vamp is made of a third 3D printing forming material or made of one or more of textile materials, mesh cloth, leather, artificial leather, synthetic materials, PVC, PU, oxhorn, superfine fibers, natural leather and EVA, TPR, SBS, and the vamp is connected with the sole.

From the above, the intelligent shoe manufactured by the manufacturing method is applicable to scene light, can adapt to various sports scenes, can adapt to the change of the adaptation of the position in different sports scenes, and provides the most comfortable experience for a user, wherein the 4D material and the monitoring device can be matched to better detect and match different sports; in addition, the intelligent shoe can realize accurate customization, so that the intelligent shoe can be better attached to the foot of a user, and the use experience of the user is improved; furthermore, compared with the traditional method of adopting a 3D laser scanner to collect the foot data of the user, the manufacturing method of the invention can avoid excessively collecting the foot data of the user and has a relatively better protection effect on the privacy of the user.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the intelligent shoe of the present invention.

FIG. 2 is a schematic illustration of the construction of an embodiment of the intelligent shoe of the present invention, with parts of the components omitted.

FIG. 3 is a system block diagram of a monitoring device of an embodiment of the intelligent shoe of the present invention.

The invention is further described below with reference to the drawings and examples.

Detailed Description

Intelligent shoe embodiment

Referring to fig. 1 and 2, the intelligent shoe 100 includes a shoe body 1, an insole 2, and a monitoring device 3. The shoe body 1 is provided with a sole 11 and an upper 12, the sole 11 is fixedly connected with the upper 12, so that the shoe body 1 is provided with a shoe cavity 10, and the insole 2 is arranged in the shoe cavity 10. Wherein the sole 11 and/or the insole 2 are each printed from a first 3D printing form material, preferably the sole 11 and the insole 2 are each printed from a first 3D printing form material. The first 3D printing forming material may be PLA (polylactic acid), TPU (thermoplastic polyurethane elastomer rubber) or TPE (thermoplastic elastomer), and of course, the first 3D printing forming material may also be made by mixing PLA (polylactic acid), TPU (thermoplastic polyurethane elastomer rubber) or TPE (thermoplastic elastomer) with other 3D printing forming materials.

In addition, the sole 11 or the footbed 2 has a functional area, as in the present embodiment, the sole 11 has a functional area. The functional area is an area where the intelligent shoe 100 makes close contact with the user's foot during exercise and walking. The functional area comprises a toe area, a half sole area and a heel area, and the toe area, the half sole area and the heel area are all made of the second 3D printing forming material through printing. Wherein the second 3D printing molding material comprises a 4D material or the second 3D printing molding material is a 4D material; preferably, the first 3D printing modeling material may also be identical to the second 3D printing modeling material.

The 4D material includes one or more materials (such as some existing stimulus-responsive polymers) that can deform with at least one of exercise intensity, temperature, humidity, and pressure, so that the 4D material can deform correspondingly with stress conditions of itself, external temperature, humidity, and the like, and the toe area, the ball area, and the heel area can self-adjust in real time to adapt to the current exercise state of the user, thereby improving the comfort of the intelligent shoe 100. For example, the 4D material may include at least one of a deformable material (e.g., a material that can change shape, change hardness, etc.), a temperature-variable material (e.g., a material that can change temperature), and a humidity-variable material (e.g., a material that can change humidity); the monitoring device 3 can control the deformable material to deform according to a preset deformation mode, so that the monitoring device 3 can adjust the 4D material to deform according to the detected data, and the areas, such as the toe area, the half sole area and the heel area, which are in close contact with the foot can be better attached to the foot; the monitoring device 3 can control the temperature change material to change the temperature according to a preset temperature change mode, so that the monitoring device 3 can adjust the temperature of the 4D material according to the detected data, and the feet are more comfortable; the monitoring device 3 can control the humidity variable material to change the humidity according to a preset humidity change mode, so that the monitoring device 3 can adjust the humidity of the 4D material according to the detected data, and the feet are more comfortable. As another example, the 4D material includes a TPU material and one or more of dibutyltin dilaurate, nano zinc oxide, and diisopolyacrylate; or the 4D material comprises EVA material and one or more materials of dibutyl tin dilaurate, nano zinc oxide and diisopolyacrylate; or the 4D material is prepared by mixing the existing high molecular material or polymer or other known materials with the same function and function with corresponding catalysts.

The upper 12 is preferably printed from a third 3D printed molding material, which may be identical to the first 3D printed molding material or the second 3D printed molding material, so that the upper 12 is elastic and breathable. Of course, upper 12 may also be formed from one or more of textile materials, mesh, leather, imitation leather, synthetic materials, PVC, PU, nubuck, microfiber, natural leather, EVA, TPR, SBS.

Referring to fig. 3, in the present embodiment, the monitoring device 3 is preferably disposed in the sole 11, and the monitoring device 3 includes a processor 31, a sensing module 32, a power management module, and a wireless communication module 34, where the processor 31 is electrically connected to the sensing module 32, the power management module, and the wireless communication module 34, respectively.

The sensing module 32 preferably includes a nine-axis sensor 321 and a positioning monitor sensor 322, the nine-axis sensor 321 and the positioning monitor sensor 322 being configured to be electrically coupled to the processor 31 using flexible circuitry. The sensing module 32 is configured to detect a motion gesture of a user, and send detection data to the processor 31, so that the user can adjust a motion plan, a motion gesture, etc. of the user through the motion data of the user, preferably, the setting of the sensing module 32 also enables the processor 31 to adjust the intelligent shoe 100 according to the motion gesture of the user, for example, adjust the state of the 4D material (such as temperature, humidity, etc. of the 4D material) to change the shape of the 4D material, so that the intelligent shoe 100 better adapts to the current motion state of the user.

The power management module is used for providing power for the processor 31, the sensing module 32 and the wireless communication module 34 so as to ensure the normal operation of the monitoring device 3. The battery management module comprises a battery and a first control unit, and the first control unit is respectively and electrically connected with the battery and the processor 31; or the battery management module includes a friction power generation unit and a second control unit electrically connected to the friction power generation unit and the processor 31, respectively. It can be seen that the power management module can be set to a storage battery form or a self-generating form, so that the power management module can provide enough power for the processor 31, the sensing module 32 and the wireless communication module to ensure that the processor 31, the sensing module 32 and the wireless communication module can work normally and stably.

The wireless communication module 34 is configured to interact with an intelligent terminal (such as a mobile phone, a smart watch, a tablet computer, etc.), so that the monitoring device 3 can send detected data to the intelligent terminal, so that a user can know the current state and related data of the intelligent shoe 100 through the intelligent terminal, and the user can set and control corresponding parameters of the intelligent shoe 100 through the intelligent terminal.

Preferably, the monitoring device 3 further comprises a timer 35, the timer 35 being electrically connected to the processor 31. It should be noted that, in other embodiments, the monitoring device 3 may also be disposed in the insole 2; or the monitoring device 3 is arranged in the sole 11 and the insole 2, i.e. the monitoring device 3 is embedded between the sole 11 and the insole 2.

In summary, the intelligent shoe provided by the invention has wide adaptation scene, can adapt to different sports scenes, can make adaptive changes in different sports scenes, and provides the most comfortable experience for a user, wherein the cooperation of the 4D material and the monitoring device can better detect and match different sports, and the wireless communication module can perform information interaction with the intelligent terminal, so that the user can know the current state and related data of the intelligent shoe through the intelligent terminal, and meanwhile, the user can perform corresponding parameter setting, control and the like on the intelligent shoe through the intelligent terminal; in addition, the intelligent shoe can realize accurate customization, so that the intelligent shoe can be better attached to the foot of a user, and the use experience of the user is improved.

Method embodiment of manufacturing Intelligent shoes

The manufacturing method provided by the invention is used for manufacturing the intelligent shoe 100 in the intelligent shoe embodiment, and the manufacturing method comprises the following steps:

and shooting photos of the foot at different angles, shooting stamping patterns of toes, forefeet and heels of the foot in a static state and a motion state, and generating three-dimensional data of the foot through three-dimensional image synthesis software. The shooting equipment of foot can adopt cell-phone or photographic equipment, and adopt the photo to acquire the data of foot to compare with current adoption 3D laser scanner and carry out data acquisition to the foot, it makes the data acquisition of foot simpler, convenient, can avoid causing excessive collection to user's foot data simultaneously, plays relatively better guard action to user's privacy. Of course, when the user does not have the three-dimensional image synthesizing software, the user can send the picture shot by the user to the manufacturer, so that the manufacturer can use the three-dimensional image synthesizing software to generate the three-dimensional data of the foot. This data collection enables users to customize on-line without requiring customers or manufacturers to go on-line and off-line, thereby making customization of the intelligent shoe 100 more convenient and time-saving.

After generating three-dimensional data of the foot, the manufacturer makes the sole 11 and the insole 2 according to the three-dimensional data by means of 3D printing. Specifically, the sole 11 and the insole 2 are printed using a first 3D printing molding material, wherein the sole 11 or the insole 2 has a functional area including a toe area, a half sole area, and a heel area, the functional area is printed using a second 3D printing molding material, and the monitoring device 3 is placed in the sole 11 and/or the insole 2 during the printing of the sole 11 and the insole 2.

Preferably, the first 3D printing forming material may be PLA (polylactic acid), TPU (thermoplastic polyurethane elastomer rubber) or TPE (thermoplastic elastomer), and of course, the first 3D printing forming material may also be made of PLA (polylactic acid), TPU (thermoplastic polyurethane elastomer rubber) or TPE (thermoplastic elastomer) mixed with other 3D printing forming materials. The second 3D printing molding material comprises a 4D material or the second 3D printing molding material is a 4D material; the first 3D printing molding material may be identical to the second 3D printing molding material.

Next, 3D printing techniques or conventional manufacturing methods process upper 12 and other portions. For example, the upper 12 is manufactured by printing with a third 3D printing forming material, or the upper 12 is manufactured by using one or more of textile material, mesh cloth, leather, artificial leather, synthetic material, PVC, PU, bus, ultra fine fiber, natural leather, EVA, TPR, SBS, and then the upper 12 is connected with the sole 11. The third 3D printing molding material may be identical to the first 3D printing molding material or identical to the second 3D printing molding material, so that the vamp 12 may have elasticity and ventilation.

After the above processing is completed, the data and 4D material of the intelligent shoe 100 are detected, and after the detection is completed, the intelligent shoe 100 is packaged for use.

In conclusion, the intelligent shoe manufactured by the manufacturing method is applicable to scene light, can adapt to various sports scenes, can adapt to the change of the adaptation of the parts in different sports scenes, and provides the most comfortable experience for a user, wherein the 4D material and the monitoring device can be matched to better detect and match different sports; in addition, the intelligent shoe can realize accurate customization, so that the intelligent shoe can be better attached to the foot of a user, and the use experience of the user is improved; furthermore, compared with the traditional method of adopting a 3D laser scanner to collect the foot data of the user, the manufacturing method of the invention can avoid excessively collecting the foot data of the user and has a relatively better protection effect on the privacy of the user.

Finally, it should be emphasized that the foregoing description is merely illustrative of the preferred embodiments of the invention, and that various changes and modifications can be made by those skilled in the art without departing from the spirit and principles of the invention, and any such modifications, equivalents, improvements, etc. are intended to be included within the scope of the invention.

Claims

1. Intelligent shoe comprising

The shoe body is provided with a sole and an vamp, the sole is connected with the vamp, and the shoe body is provided with a shoe cavity;

the insole is arranged in the shoe cavity;

the method is characterized in that:

the sole and/or the insole are/is printed from a first 3D printing forming material, the sole or the insole has a functional area comprising a toe area, a half sole area and a heel area, the functional area is printed from a second 3D printing forming material, the second 3D printing forming material comprises a 4D material or the second 3D printing forming material is a 4D material;

the intelligent shoe further comprises a monitoring device, the monitoring device is arranged in the sole and/or the insole, the monitoring device comprises a processor, a sensing module, a power management module and a wireless communication module, the processor is respectively and electrically connected with the sensing module, the power management module and the wireless communication module, the sensing module sends detection data to the processor, and the processor controls the 4D material to deform according to the detection data.

2. The intelligent shoe of claim 1, wherein:

the sensing module comprises a nine-axis sensor and a positioning monitoring sensor, and the nine-axis sensor and the positioning monitoring sensor are respectively and electrically connected with the processor.

3. The intelligent shoe of claim 1, wherein:

the 4D material comprises one or more materials capable of deforming along with at least one of exercise intensity, temperature, humidity and pressure, and is matched with an exercise scene in which the intelligent shoe is located.

4. A smart shoe according to claim 3, wherein:

the 4D material comprises a deformable material, and the monitoring device can control the deformable material to deform according to a preset deformation mode.

5. A smart shoe according to claim 3, wherein:

the 4D material comprises a temperature change material, and the monitoring device can control the temperature change material to change in temperature according to a preset temperature change mode.

6. A smart shoe according to claim 3, wherein:

the 4D material comprises a humidity variable material, and the monitoring device can control the humidity variable material to change humidity according to a preset humidity change mode.

7. A smart shoe according to claim 3, wherein:

the vamp is made of a third 3D printing forming material or made of one or more of textile materials, mesh cloth, leather, artificial leather, synthetic materials, PVC, PU, bus, superfine fibers, natural leather and EVA, TPR, SBS.

8. The intelligent shoe of claim 1, wherein:

the 4D material comprises TPU material and one or more materials of dibutyl tin dilaurate, nano zinc oxide and diisopolyacrylate; or (b)

The 4D material comprises EVA material and one or more materials selected from dibutyl tin dilaurate, nano zinc oxide and diisopolyacrylate.

9. The intelligent shoe according to any one of claims 1 to 8, wherein:

the power management module comprises a battery and a first control unit, and the first control unit is respectively and electrically connected with the battery and the processor; or (b)

The power management module comprises a friction power generation unit and a second control unit, and the second control unit is respectively and electrically connected with the friction power generation unit and the processor.

10. The manufacturing method of the intelligent shoe is characterized by comprising the following steps:

shooting photos of feet under different angles, shooting stamping patterns of toes, forefeet and heels of the feet in a static state and a motion state, and generating three-dimensional data of the feet through three-dimensional image synthesis software;

manufacturing three-dimensional models of soles and insoles according to the three-dimensional data;

the method comprises the steps that a first 3D printing forming material is adopted to print and manufacture soles and insoles, the soles or the insoles are provided with functional areas, the functional areas comprise toe areas, half sole areas and heel areas, a second 3D printing forming material is adopted to print and manufacture the functional areas, monitoring devices are implanted into the soles and/or the insoles in the process of printing the soles and the insoles, the second 3D printing forming material comprises 4D materials, and the monitoring devices can control the 4D materials to deform;

and printing a third 3D printing forming material to form a vamp, or forming the vamp by one or more of textile materials, mesh cloth, leather, artificial leather, synthetic materials, PVC, PU, oxhorn, superfine fibers, natural leather and EVA, TPR, SBS, and connecting the vamp with the sole.