CN111296985A - Shoe with optical fiber vamp and manufacturing method thereof - Google Patents

Abstract

The invention relates to the technical field of shoes, in particular to a shoe with an optical fiber vamp, which comprises a sole and the vamp, wherein the vamp is adhered to the sole, the sole is integrated with a control device, the control device comprises a microprocessor, a luminous body, a power supply and a control switch, the vamp comprises a plurality of vamp regions, each vamp region is woven with an optical fiber bundle, each optical fiber bundle comprises a plurality of optical fibers, the end parts of the corresponding optical fibers in each vamp region are respectively bundled into one end to form an optical fiber bundle end part, each optical fiber bundle end part is respectively connected with different luminous bodies, and the control device controls the optical fiber bundles in different regions of the vamp to synchronously or asynchronously emit light. The luminous toy is novel in structure, firm and stable, not easy to scatter, good in luminous effect, low in power consumption, capable of emitting light integrally and in different areas, strong in interestingness and high in identification degree.

Description

Shoe with optical fiber vamp and manufacturing method thereof

Technical Field

The invention relates to the technical field of shoes, in particular to a shoe with an optical fiber vamp and a manufacturing method thereof.

Background

In the prior art, in order to enhance the aesthetic feeling of shoes, a light-emitting device is arranged on the shoes, such shoes provided with the light-emitting device adopt light-emitting bodies such as light-emitting diodes or lamp beads and the like, the light-emitting bodies are fixed at soles or heels, and the light-emitting bodies directly irradiate the outside of the shoes. The shoes adopting the light-emitting device can not be fixed on the vamp because the light-emitting diodes or the lamp beads need to occupy certain space for fixation, and the range of the soles is limited, so that the light-emitting effect which can be achieved actually is not ideal. In addition, if the brightness is to be improved, the number of the light emitting elements must be increased or the light emitting elements with higher light emitting intensity must be used, which will increase the power consumption.

Some luminous shoes on market include the shoes body and the luminescent layer of outsourcing on shoes body surface, and the luminescent layer drops very easily, and the luminescent layer generally adopts luminous lamp strip or other illuminator to weave or arrange directly to form, because luminescent material itself texture is harder, leads to whole very loose, very easily scatters.

Also optical fiber shoes have appeared on the market for solve above-mentioned problem, chinese patent application No. 201710061086.2 discloses a luminous shoes, including the shoes body, shoes body surface is provided with a slice at least and shines to weave the layer, it is woven by weft and warp and forms to shine the layer, at least warp is the luminous optic fibre of side, the outside extension of the luminous optic fibre of side just gathers into the optical fiber bundle, the optical fiber bundle tip is provided with the light source that kicks into to interior optical fiber bundle, the luminous optic fibre of side includes the optical core and along the transparent sheath of optical core axial parcel optical core. The luminous shoe has the advantages of being capable of being arranged on the vamp and uniform in light emitting.

The common optical fiber shoe form and the knitting method lead the luminescence of the shoe body to be integrated, at most, the luminescence of the whole single color or the luminescence of the changed color can be realized, and the luminescence of the independent subareas can not be realized, thus lacking the interest and the identification degree. Moreover, the shoe can only emit light in a single and integral synchronous manner, and cannot be applied to the interactive use environment with the intelligent shoes.

Disclosure of Invention

The invention aims to overcome the defects and provide a shoe with an optical fiber vamp, which not only can emit light with single color or light with variable colors integrally, but also can emit light in different regions independently, thereby greatly increasing the interestingness and the identification degree.

In order to achieve the purpose, the technical solution of the invention is as follows: the utility model provides a shoes with optic fibre vamp, includes sole, vamp, the vamp is glued on the sole, the sole is integrated with controlling means, controlling means includes microprocessor, luminous body, power, control switch, the vamp includes that a plurality of vamp is regional, every optic fibre bundle has been woven in the vamp region, every optic fibre bundle includes a plurality of optic fibre, every the one end formation optic fibre bundle tip is restrainted respectively to the optic fibre tip that corresponds in the vamp region, every optic fibre bundle tip all connects different luminous body separately, controlling means controls the synchronous or asynchronous luminescence of optic fibre bundle in the different regions of vamp.

Preferably, the optical fiber is a short-hand optical fiber, and is a fiber made of glass or plastic, which can be used as a light conducting tool, and the transmission principle is "total reflection of light", that is, when the angle of the incident light reaches or exceeds a certain angle, the refracted light disappears, and the incident light is totally reflected, which is the total reflection of light. Generally, a Light Emitting Diode (LED) or a laser beam is used as a transmitter at one end of the optical fiber to transmit an optical pulse to the optical fiber, and a photosensor is used as a receiver at the other end of the optical fiber to detect the pulse. The present invention uses a plastic optical fiber, that is, an optical fiber in which a core and a cladding are both made of plastic (polymer). Early products were used primarily for decorative and light-conducting lighting and optical communication for short-range optical links. The raw materials mainly comprise organic glass (PMMA), Polystyrene (PS) and Polycarbonate (PC). The loss is limited by the inherent C-H combination structure of the plastic, and generally can reach dozens of dB per km. The use of plastics of the fluorosoxhlet series is being developed in order to reduce the losses.

Preferably, the sole comprises an outsole and an insole arranged above the outsole, the upper surface of the outsole is concavely provided with a control device groove for placing a control device, and the side wall of the control device groove is provided with a guide groove for placing an optical fiber bundle in an extending manner. The control device groove is arranged at the arch of the sole.

Preferably, the upper surface of the outsole is provided with a plurality of pressure sensors, each pressure sensor corresponds to an upper area, and each pressure sensor is connected with the microprocessor through a lead.

Preferably, the upper surface of the insole is provided with a plurality of pressure sensors, each pressure sensor corresponds to an upper area, and each pressure sensor is connected with the microprocessor through a lead.

Preferably, a plurality of pressure sensors are arranged on the vamp, each pressure sensor corresponds to the vamp area, each pressure sensor is connected with the microprocessor through a lead, the pressure sensors are flexible pressure sensors, the best film pressure sensors are more attached to the vamp, and the induction range is larger.

Preferably, the end of the optical fiber bundle is provided with a heat-shrinkable sleeve, and the heat-shrinkable sleeve is sleeved with the luminous body. The heat-shrinkable sleeve is a special polyolefin heat-shrinkable sleeve, which can be called as an EVA (ethylene vinyl acetate copolymer) sleeve, the outer layer is made of a high-quality soft cross-linked polyolefin material and an inner layer of hot melt adhesive in a composite processing mode, the outer layer has the characteristics of insulation, corrosion resistance, wear resistance and the like, and the inner layer has the advantages of low melting point, water tightness, high adhesion and the like.

Preferably, the control switch is any one of a key switch, a voice control switch, a vibration switch and a pressure switch.

Preferably, the control device further comprises a wireless module, the wireless module is connected with the microprocessor, the microprocessor is wirelessly connected with the mobile terminal through the wireless module, and a user can control the light emitting body to emit light and extinguish through the mobile terminal, so that convenience is greatly improved.

Preferably, the microprocessor is a microprocessor chip with a model ADM691AARWZ, the power supply is a lithium battery module with a model FIT-BAT, the wireless module is a Bluetooth chip with a model Nordic52810, and the luminous body is an LED lamp.

The invention also provides a manufacturing method of the shoe with the optical fiber vamp, which comprises the following steps:

A. dividing the vamp into a plurality of vamp areas;

B. the optical fibers are woven into each vamp area in one mode of crossing the warps, the wefts and the warps and the wefts, the optical fibers are exposed and woven outside the vamp in the vamp area needing to emit light, and the other areas are hidden and woven in the vamp to form the optical fiber vamp;

C. bundling the optical fiber end parts corresponding to the vamp areas into one end respectively to form the end parts of the optical fiber bundles;

D. a control device groove and a guide groove are concavely arranged on the upper surface of the outsole, and the control device is arranged in the control device groove;

E. the end part of each optical fiber bundle passes through the guide groove to be connected with different illuminants;

F. the vamp is glued to the sole.

Preferably, the method for manufacturing the shoe with the optical fiber vamp comprises the following steps:

A. dividing the vamp into a plurality of vamp areas;

B. the optical fibers are woven into each vamp area in one mode of crossing the warps, the wefts and the warps and the wefts, the optical fibers are exposed and woven outside the vamp in the vamp area needing to emit light, and the other areas are hidden and woven in the vamp to form the optical fiber vamp;

C. bundling the optical fiber end parts corresponding to the vamp areas into one end respectively to form the end parts of the optical fiber bundles;

D. a control device groove and a guide groove are concavely arranged on the upper surface of the outsole, and the control device is arranged in the control device groove;

E. a pressure sensor corresponding to the vamp area is arranged on the sole or the vamp, and the pressure sensor is connected with a control device through a lead;

F. the end part of each optical fiber bundle passes through the guide groove to be connected with different illuminants;

G. the vamp is glued to the sole.

By adopting the technical scheme, the invention has the beneficial effects that: the invention respectively manufactures a plurality of bundles of optical fibers and the vamp into a whole by electric embroidery or weaving, so that the vamp is divided into a plurality of different luminous areas, not only can the whole luminous with single color or the luminous with variable colors be realized, but also the independent luminous areas can be realized, the aesthetic property and the interest of the shoe are greatly increased, and the identification degree of the shoe is also improved. The invention also integrates a plurality of pressure sensors on the sole or the vamp, each pressure sensor respectively corresponds to the optical fiber of different vamp areas, the optical fibers of different vamp areas can emit light or extinguish in response to the sensing condition of the corresponding pressure sensor, the interest of the shoe is enhanced, and the shoe is suitable for being worn in various sports, entertainment and other scenes. The luminous toy is novel in structure, firm and stable, not easy to scatter, good in luminous effect, low in power consumption, capable of emitting light integrally and in different areas, strong in interestingness and high in identification degree.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an expanded view of the upper of the present invention;

FIG. 3 is an exploded view of the sole of the present invention;

FIG. 4 is a schematic structural view of example 2 of the present invention;

FIG. 5 is a schematic structural view of example 3 of the present invention;

FIG. 6 is a schematic structural view of example 4 of the present invention;

FIG. 7 is a schematic diagram showing the operation of embodiment 1 of the present invention;

fig. 8 is a working principle diagram of embodiments 2-4 of the present invention.

Description of the main reference numerals: (1, sole; 11, outsole; 12, insole; 13, control device slot; 14, guide slot; 2, vamp; 3, control device; 31, microprocessor; 32, light emitter; 33, power supply; 34, control switch; 35, pressure sensor; 36, wireless module; 4, vamp area; 41, area A; 42, area B; 43, area C; 5, fiber bundle; 51, fiber; 52, fiber bundle end; 53, heat shrink tube).

Detailed Description

The invention is further described below with reference to the figures and the specific embodiments.

The directional phrases used in this disclosure include, for example: upper, lower, inner, outer, etc., are referred to in the description only in the direction of fig. 1. Accordingly, the directional terminology used is intended to be illustrative only and is not intended to be limiting of the invention.

Example 1

As shown in fig. 1-2, a shoe with an optical fiber vamp comprises a sole 1 and a vamp 2, the vamp 2 is glued on the sole 1, the sole 1 is integrated with a control device 3, the control device 3 comprises a microprocessor 31, a light 32, a power supply 33 and a control switch 34, and the vamp 2 comprises 3 vamp areas 4, namely an area a 41, an area B42 and an area C43. The area a 41 is the vamp area 4 corresponding to the toe cap, that is, the routing range when part of the optical fiber 51 and the vamp 2 are integrated by embroidery or weaving is the toe cap area. The B area 42 is the upper area 4 corresponding to the arch, that is, the routing range of the optical fiber 51 and the upper 2 when they are embroidered or woven into a whole is the arch area. The C area 43 is the upper area 4 corresponding to the heel, that is, the routing range when part of the optical fiber 51 and the upper 2 are embroidered or woven into a whole is the heel area. Each vamp region 4 is woven with an optical fiber bundle 5, each optical fiber bundle 5 comprises a plurality of optical fibers 51, the corresponding optical fiber end portions in each vamp region 4 are respectively bundled into one end to form an optical fiber bundle end portion 52, each optical fiber bundle end portion 52 is respectively connected with different illuminants 32, and the control device 3 controls the optical fiber bundles 5 in different regions of the vamp to synchronously or asynchronously emit light.

As shown in fig. 3, the sole 1 comprises an outsole 11 and an insole 12 arranged above the outsole 11, wherein a control device groove 13 for placing the control device 3 is concavely arranged on the upper surface of the outsole 11, and a guide groove 14 for placing the optical fiber bundle 5 is extendedly arranged on the side wall of the control device groove 13. The control means slot 13 may be provided at the arch, heel or half sole of the outsole 11.

The optical fiber bundle end 52 is provided with a heat shrink tube 53, and the heat shrink tube 53 is sleeved with the light 32. The heat-shrinkable sleeve 53 is a special polyolefin heat-shrinkable sleeve, which can be called as an EVA (ethylene vinyl acetate copolymer) sleeve, the outer layer is made of a high-quality soft cross-linked polyolefin material and an inner layer of hot melt adhesive in a composite processing mode, the outer layer has the characteristics of insulation, corrosion resistance, wear resistance and the like, and the inner layer has the advantages of low melting point, water tightness, high adhesion and the like.

The control switch 34 is a voice-activated switch. The sound control switch is an energy-saving electronic switch which is internally provided with no contact point, adopts sound effect to stimulate a sound pick-up to carry out sound-electricity conversion under specific environment light rays to control the opening of an electric appliance and can automatically cut off a power supply after time delay.

The control device 3 further comprises a wireless module 36, the wireless module 36 is connected with the microprocessor 31, the microprocessor 31 is wirelessly connected with a mobile terminal through the wireless module 36, and a user can control the light emitting and extinguishing of the light emitting body 32 through the mobile terminal, so that convenience is greatly improved.

The microprocessor 31 is a microprocessor chip with a model number ADM691AARWZ, the power supply 33 is a lithium battery module with a model number FIT-BAT, the wireless module 36 is a Bluetooth chip with a model number Nordic52810, and the luminous body 32 is an LED lamp.

The embodiment provides a method for manufacturing a shoe with an optical fiber vamp, which comprises the following steps:

A. the vamp 2 is divided into 3 vamp areas 4 which are respectively an A area 41, a B area 42 and a C area 43;

B. the optical fibers 51 are woven into each vamp area 4 in a warp manner, the optical fibers 51 are exposed and woven outside the vamp 2 in the vamp areas 4 needing to emit light, and the other areas are hidden and woven in the vamp 2 to form the optical fiber vamp 2;

C. bundling the optical fiber ends corresponding to the vamp region 4 into one end to form each optical fiber bundle end 52;

D. a control device groove 13 and a guide groove 14 are concavely arranged on the upper surface of the outsole 11 of the sole 1, and the control device 3 is arranged in the control device groove 13;

E. connecting each fiber bundle end 52 to a different light 32 through the guide slot 14;

F. the upper 2 is glued to the sole 1.

The working principle of the embodiment is as follows: as shown in fig. 7, the user can control the light-emitting or extinguishing of each light-emitting body 32 through the mobile terminal or the voice-operated switch, and under the action of the optical fiber 51, each area on the shoe upper 2 can be synchronously or asynchronously illuminated or extinguished.

Example 2

As shown in fig. 1-2, a shoe with an optical fiber vamp comprises a sole 1 and a vamp 2, the vamp 2 is glued on the sole 1, the sole 1 is integrated with a control device 3, the control device 3 comprises a microprocessor 31, a light 32, a power supply 33 and a control switch 34, and the vamp 2 comprises 3 vamp areas 4, namely an area a 41, an area B42 and an area C43. The area a 41 is the vamp area 4 corresponding to the toe cap, that is, the routing range when part of the optical fiber 51 and the vamp 2 are integrated by embroidery or weaving is the toe cap area. The B area 42 is the upper area 4 corresponding to the arch, that is, the routing range of the optical fiber 51 and the upper is the arch area when they are embroidered or woven into a whole. The C area 43 is the upper area 4 corresponding to the heel, that is, the routing range when part of the optical fiber 51 and the upper 2 are embroidered or woven into a whole is the heel area. Each vamp region 4 is woven with an optical fiber bundle 5, each optical fiber bundle 5 comprises a plurality of optical fibers 51, the corresponding optical fiber end portions in each vamp region 4 are respectively bundled into one end to form an optical fiber bundle end portion 52, each optical fiber bundle end portion 52 is respectively connected with different illuminants 32, and the control device 3 controls the optical fiber bundles 5 in different regions of the vamp 2 to synchronously or asynchronously emit light.

As shown in fig. 3, the sole 1 comprises an outsole 11 and an insole 12 arranged above the outsole 11, wherein a control device groove 13 for placing the control device 3 is concavely arranged on the upper surface of the outsole 11, and a guide groove 14 for placing the optical fiber bundle 5 is extendedly arranged on the side wall of the control device groove 13. The control means slot 13 may be provided at the arch, heel or half sole of the outsole 11.

As shown in fig. 4, 3 pressure sensors 35 are disposed on the upper surface of the outsole 11, the 3 pressure sensors 35 are respectively disposed on the arch, the heel and the half sole of the upper surface of the outsole 11, and each of the pressure sensors 35 is connected to the microprocessor 31 through a wire.

The optical fiber bundle end 52 is provided with a heat shrink tube 53, and the heat shrink tube 53 is sleeved with the light 32. The heat-shrinkable sleeve 53 is a special polyolefin heat-shrinkable sleeve, which can be called as an EVA (ethylene vinyl acetate copolymer) sleeve, the outer layer is made of a high-quality soft cross-linked polyolefin material and an inner layer of hot melt adhesive in a composite processing mode, the outer layer has the characteristics of insulation, corrosion resistance, wear resistance and the like, and the inner layer has the advantages of low melting point, water tightness, high adhesion and the like.

The microprocessor 31 is a microprocessor chip of type ADM691AARWZ, the power supply 33 is a lithium battery module of type FIT-BAT, and the illuminant 32 is an LED lamp.

The manufacturing method of the embodiment comprises the following steps:

A. the vamp 2 is divided into 3 vamp areas 4 which are respectively an A area 41, a B area 42 and a C area 43;

B. the optical fibers 51 are woven into each vamp area 4 in a weft mode, the optical fibers 51 are exposed and woven outside the vamp 2 in the vamp areas 4 needing to emit light, and the other areas are hidden and woven in the vamp 2 to form the optical fiber vamp 2;

C. bundling the optical fiber ends corresponding to the vamp region 4 into one end to form each optical fiber bundle end 52;

D. a control device groove 13 and a guide groove 14 are concavely arranged on the upper surface of the outsole 11 of the sole 1, and the control device 3 is arranged in the control device groove 13;

E. pressure sensors 35 are arranged at the arch, heel and half sole of the upper surface of the outsole 11, and the pressure sensors 35 are connected with the control device 3 through leads;

F. connecting each fiber bundle end 52 to a different light 32 through the guide slot 14;

G. the upper 2 is glued to the sole 1.

The working principle of the embodiment is as follows: as shown in fig. 8, when the user wears the shoes and the foot-stepping part is the half sole, the pressure sensor 35 at the half sole senses and transmits a sensing signal to the microprocessor 31, the microprocessor 31 controls the light emitter 32 connected with the optical fiber 51 of the vamp 2 of the area a 41 to emit light, and after the light emitter 32 emits light, the corresponding vamp 2 of the area a 41 emits light under the action of the optical fiber 51. If the pressure sensors 35 in different areas sense simultaneously, if the half sole and the arch, the arch and the heel, and 3 areas sense simultaneously, the sensing signal is transmitted to the microprocessor 31, the microprocessor 31 controls the light emitter 32 corresponding to the optical fiber 51 in the sensing area to emit light at the same time, and after the light emitter 32 emits light, the shoe upper 2 in the corresponding area emits light at the same time under the action of the optical fiber 51. If any pressure sensor 35 does not sense pressure, the microprocessor 31 controls the light emitter 32 corresponding to the sensing area optical fiber 51 to be turned off, that is, the shoe upper 2 does not emit light.

Example 3

As shown in fig. 1-2, a shoe with an optical fiber vamp comprises a sole 1 and a vamp 2, the vamp 2 is glued on the sole 1, the sole 1 is integrated with a control device 3, the control device 3 comprises a microprocessor 31, a light 32, a power supply 33 and a control switch 34, and the vamp 2 comprises 3 vamp areas 4, namely an area a 41, an area B42 and an area C43. The area a 41 is the vamp area 4 corresponding to the toe cap, that is, the routing range when part of the optical fiber 51 and the vamp 2 are integrated by embroidery or weaving is the toe cap area. The B area 42 is the upper area 4 corresponding to the arch, that is, the routing range of the optical fiber 51 and the upper 2 when they are embroidered or woven into a whole is the arch area. The C area 43 is the upper area 4 corresponding to the heel, that is, the routing range when part of the optical fiber 51 and the upper 2 are embroidered or woven into a whole is the heel area. Each vamp region 4 is woven with an optical fiber bundle 5, each optical fiber bundle 5 comprises a plurality of optical fibers 51, the corresponding optical fiber end portions in each vamp region 4 are respectively bundled into one end to form an optical fiber bundle end portion 52, each optical fiber bundle end portion 52 is respectively connected with different illuminants 32, and the control device 3 controls the optical fiber bundles 5 in different regions of the vamp 2 to synchronously or asynchronously emit light.

As shown in fig. 3, the sole 1 comprises an outsole 11 and an insole 12 arranged above the outsole 11, wherein a control device groove 13 for placing the control device 3 is concavely arranged on the upper surface of the outsole 11, and a guide groove 14 for placing the optical fiber bundle 5 is extendedly arranged on the side wall of the control device groove 13. The control means slot 13 may be provided at the arch, heel or half sole of the outsole 11.

As shown in fig. 6, 3 pressure sensors 35 are disposed on the upper 2, the 3 pressure sensors 35 are disposed at the toe cap, the arch and the heel of the upper 2, each pressure sensor 35 is connected to the microprocessor 31 through a wire, the pressure sensors 35 are flexible pressure sensors, preferably thin film pressure sensors, and are more attached to the upper, so that the sensing range is wider.

The optical fiber bundle end 52 is provided with a heat shrink tube 53, and the heat shrink tube 53 is sleeved with the light 32. The heat-shrinkable sleeve 53 is a special polyolefin heat-shrinkable sleeve, which can be called as an EVA (ethylene vinyl acetate copolymer) sleeve, the outer layer is made of a high-quality soft cross-linked polyolefin material and an inner layer of hot melt adhesive in a composite processing mode, the outer layer has the characteristics of insulation, corrosion resistance, wear resistance and the like, and the inner layer has the advantages of low melting point, water tightness, high adhesion and the like.

The microprocessor 31 is a microprocessor chip of type ADM691AARWZ, the power supply 33 is a lithium battery module of type FIT-BAT, and the illuminant 32 is an LED lamp.

The manufacturing method of the embodiment comprises the following steps:

A. the vamp 2 is divided into 3 vamp areas 4 which are respectively an A area 41, a B area 42 and a C area 43;

B. the optical fibers 51 are woven into each vamp area 4 in a warp and weft crossing mode, the optical fibers 51 are exposed and woven outside the vamp 2 in the vamp areas 4 needing to emit light, and the other areas are hidden and woven in the vamp 2 to form the optical fiber vamp 2;

C. bundling the optical fiber ends corresponding to the vamp region 4 into one end to form each optical fiber bundle end 52;

D. a control device groove 13 and a guide groove 14 are concavely arranged on the upper surface of the outsole 11 of the sole 1, and the control device 3 is arranged in the control device groove 13;

E. pressure sensors 5 are arranged at the toe cap, the arch and the heel of the vamp 4, and the pressure sensors 35 are connected with the control device 2 through leads;

F. connecting each fiber bundle end 52 to a different light 32 through the guide slot 13;

G. the upper 2 is glued to the sole 1.

The working principle of the embodiment is as follows: as shown in fig. 8, when the pressure sensor 35 is integrated on the outer surface of the shoe upper 2 or inside the interlayer of the shoe upper 2, the pressure sensor 35 touches the pressure sensor 35 during kicking or bumping, the pressure sensor 35 senses and transmits a sensing signal to the microprocessor 31, the microprocessor 31 controls the light emitter 32 connected to the optical fiber 51 of the corresponding area to emit light, and the corresponding shoe upper area 4 emits light after the light emitter 32 emits light. When the pressure sensor 35 is integrated on the inner surface of the shoe upper 2 or inside the interlayer of the shoe upper 2, the pressure sensor 35 is touched in situations such as wearing shoes or dancing, the pressure sensor 35 senses and transmits a sensing signal to the microprocessor 31, the microprocessor 31 controls the light emitter 32 connected with the optical fiber 51 of the corresponding area to emit light, and the corresponding shoe upper area 4 emits light after the light emitter 32 emits light. If the pressure sensors 35 in different vamp regions 4 sense simultaneously, for example, the toe cap and the arch, the arch being in the heel or 3 vamp regions sense simultaneously, the sensing signal is transmitted to the microprocessor 31, the microprocessor 31 controls the light emitter 32 corresponding to the optical fiber 51 in the vamp region 4 to emit light at the same time, and the vamp 2 emits light after the light emitter 32 emits light. If any pressure sensor 35 does not sense pressure, the microprocessor 31 controls the light emitter 32 corresponding to the sensing area optical fiber 51 to be turned off, and the shoe upper 2 does not emit light.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the scope of the present invention, and all equivalent variations and modifications made in the claims of the present invention should be included in the scope of the present invention.

Claims (10)

1. The utility model provides a shoes with optic fibre vamp, includes sole, vamp, the vamp is glued on the sole, the sole is integrated with controlling means, controlling means includes microprocessor, luminous body, power, control switch, its characterized in that: the vamp comprises a plurality of vamp areas, each vamp area is woven with an optical fiber bundle, each optical fiber bundle comprises a plurality of optical fibers, the end parts of the corresponding optical fibers in each vamp area are respectively bundled into one end to form an optical fiber bundle end part, each optical fiber bundle end part is respectively connected with different illuminants, and the control device controls the optical fiber bundles in different vamp areas to synchronously or asynchronously emit light.

2. A shoe having a fiber optic upper as claimed in claim 1, wherein: the sole comprises an outsole and an insole arranged above the outsole, wherein a control device groove for placing a control device is concavely arranged on the upper surface of the outsole, and a guide groove for placing an optical fiber bundle is arranged on the side wall of the control device groove in an extending manner.

3. A shoe having a fiber optic upper as claimed in claim 2, wherein: the upper surface of the outsole is provided with a plurality of pressure sensors, each pressure sensor corresponds to the vamp area, and each pressure sensor is connected with the microprocessor through a lead.

4. A shoe having a fiber optic upper as claimed in claim 2, wherein: the upper surface of the insole is provided with a plurality of pressure sensors, each pressure sensor corresponds to the vamp area, and each pressure sensor is connected with the microprocessor through a lead.

5. A shoe having a fiber optic upper as claimed in claim 1, wherein: the vamp is provided with a plurality of pressure sensors, each pressure sensor corresponds to the vamp area, and each pressure sensor is connected with the microprocessor through a lead.

6. A shoe having a fiber optic upper as claimed in claim 1, wherein: the optical fiber bundle end is provided with a heat-shrinkable sleeve, and the heat-shrinkable sleeve is sleeved with the luminous body.

7. A shoe having a fiber optic upper as claimed in claim 1, wherein: the control switch is any one of a key switch, a voice control switch, a vibration switch and a pressure switch.

8. A shoe having a fiber optic upper as claimed in claim 1, wherein: the control device further comprises a wireless module, the wireless module is connected with the microprocessor, and the microprocessor is connected with the mobile terminal in a wireless mode through the wireless module.

9. A method of manufacturing a shoe upper with a fibre-optic upper according to any one of claims 1 to 8, characterized in that: the method comprises the following steps:

A. dividing the vamp into a plurality of vamp areas;

B. weaving optical fibers into each vamp area in one of a warp, a weft and a warp and weft crossing manner to form an optical fiber vamp;

C. bundling the optical fiber end parts corresponding to the vamp areas into one end respectively to form the end parts of the optical fiber bundles;

D. a control device groove and a guide groove are concavely arranged on the upper surface of the outsole, and the control device is arranged in the control device groove;

E. the end part of each optical fiber bundle passes through the guide groove to be connected with different illuminants;

F. the vamp is glued to the sole.

10. A method of manufacturing a shoe upper with a fiber optic upper as in claim 9, wherein: the method comprises the following steps:

A. dividing the vamp into a plurality of vamp areas;

B. weaving optical fibers into each vamp area in one of a warp, a weft and a warp and weft crossing manner to form an optical fiber vamp;

C. bundling the optical fiber end parts corresponding to the vamp areas into one end respectively to form the end parts of the optical fiber bundles;

D. a control device groove and a guide groove are concavely arranged on the upper surface of the outsole, and the control device is arranged in the control device groove;

E. a pressure sensor corresponding to the vamp area is arranged on the sole or the vamp, and the pressure sensor is connected with a control device through a lead;

F. the end part of each optical fiber bundle passes through the guide groove to be connected with different illuminants;

G. the vamp is glued to the sole.

Images