CN205993708U - Luminous shoe - Google Patents

Abstract

The utility model discloses a kind of Luminous shoe, including sole and vamp, also includes：Triboelectricity module, rectification circuit module and display module；Wherein, triboelectricity module and rectification circuit module are located at sole site, and display module is located on sole and/or vamp；Triboelectricity module includes at least one friction generator, for converting mechanical energy into electric energy；Rectification circuit module includes at least one rectifier bridge, and which is connected with triboelectricity module, for carrying out rectification process to the electric energy that triboelectricity module is exported；Display module, its are connected with rectification circuit module, for receiving the electric energy of rectification circuit module output, so that display module carries out luminescence display.According to the Luminous shoe that the utility model is provided, can guarantee in the case of without battery shoe body luminous needed for electricity sustainable supply, green pollution-free, and structure and manufacture craft simple, with low cost.

Description

Luminous shoes

Technical Field

The utility model relates to an electronic circuit field especially relates to a luminous shoes.

Background

With the development of science and technology, luminous shoes have gradually come into people's lives as a highly interesting high-technology product. Especially, the emergence of many children's shoes that give out light, not only bring very strong interest to them, and the shoes that give out light can lead to the way for children at night, make children discover the change of the peripheral environment in time, thus take precautions against the dangerous situation voluntarily; meanwhile, in the dark, the luminous shoes can be found by the vehicle driver in time, so that traffic accidents are avoided.

Although the luminous shoes have many advantages, most of the existing luminous shoes are powered by batteries, and the batteries cannot continuously emit light after being used up, so that the luminous time of the luminous shoes is greatly limited. Moreover, the replacement of the battery brings trouble to the use, and also causes damage to the shoe body and influences the subsequent wearing.

In addition, in the process of walking at ordinary times, the sole generates pressure on the road surface through the shoes, thereby generating mechanical energy. The mechanical energy generated by an adult through shoes in the walking process is very considerable, but the mechanical energy is not utilized by the current luminous shoes, so that the mechanical energy is wasted.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the defect of prior art, provide a luminous shoes for solve among the prior art luminous shoes need battery powered, the extravagant energy, the polluted environment to and structure and preparation technology are complicated, problem with high costs.

According to an aspect of the utility model, a luminous shoes is provided, including sole and vamp, still include: the device comprises a friction power generation module, a rectifying circuit module and a display module; the friction power generation module and the rectifying circuit module are positioned at the sole part, and the display module is positioned on the sole and/or the vamp; the friction power generation module comprises at least one friction power generator and is used for converting mechanical energy into electric energy; the rectifying circuit module comprises at least one rectifying bridge, is connected with the friction power generation module and is used for rectifying the electric energy output by the friction power generation module; and the display module is connected with the rectifying circuit module and used for receiving the electric energy output by the rectifying circuit module so as to enable the display module to perform light-emitting display.

Optionally, the friction generator is a friction generator with a common electrode structure, and the display module is a single or multiple LED strips.

Optionally, the common electrode structure friction generator comprises m electrode layers and n high molecular polymer insulating layers, wherein m is greater than or equal to 3, n is greater than or equal to 2, and m-n is equal to 1; the electrode layers and the high molecular polymer insulating layers are sequentially and alternately stacked, the electrode layers and the high molecular polymer insulating layers rub against each other to form a friction interface, and two adjacent electrode layers form a group of output ends of the friction generator with a common electrode structure; or,

the common electrode structure friction generator comprises m electrode layers and n high polymer insulating layers, wherein m is greater than or equal to 3, n is greater than or equal to 4, and 2m-n is equal to 2; the electrode layers and the two high polymer insulating layers are sequentially and alternately stacked, the two high polymer insulating layers which are in contact mutually rub to form a friction interface, and the two adjacent electrode layers form a group of output ends of the friction generator with the common electrode structure.

Optionally, at least one of the two surfaces forming the friction interface is provided with a raised structure.

Optionally, multiple groups of output ends of the common electrode structure friction generator are respectively connected with the multiple rectifier bridges in a one-to-one correspondence manner.

Optionally, a plurality of groups of output ends of the common electrode structure friction generator are connected with a plurality of rectifier bridges, wherein the output ends of the common electrode structure friction generator connected with one rectifier bridge are connected in series and/or in parallel.

Optionally, a plurality of groups of output ends of the common electrode structure friction generator are connected with one rectifier bridge, wherein the output ends of the common electrode structure friction generator connected with one rectifier bridge are connected in series and/or in parallel.

Optionally, a single LED strip is connected to a plurality of rectifier bridges; or the LED lamp belts are respectively connected with the rectifier bridges in a one-to-one correspondence manner; or the plurality of LED lamp belts are connected with the plurality of rectifier bridges in a series and/or parallel mode.

Optionally, the single LED strip is connected to a rectifier bridge; or the LED lamp belts are connected with one rectifier bridge in a series and/or parallel mode.

Optionally, the sole further comprises a bottom surface and a side surface, the display module being disposed at the side surface of the sole.

Optionally, the upper includes a surface layer and an interior layer, the display module being disposed between the surface layer and the interior layer.

Optionally, the LED strip can be arranged in a preset shape; the preset shape includes: chinese character shape, phonetic shape, or luminous shoe mark shape.

Optionally, the luminescent shoe further comprises: an energy storage module; the energy storage module is connected with the rectifying circuit module and the display module.

Optionally, the luminescent shoe further comprises: the control switch module of connection between energy storage module and display module, wherein, the control switch module is: a spring switch, a push button switch, a vibration switch or a voice operated switch.

Optionally, a plurality of friction generators are disposed in a stacked or tiled manner within the sole.

According to the utility model provides a luminous shoes, the external force that will act on the sole when walking through the friction electricity generation module turns into the electric energy, and rethread rectifier circuit module changes it for display module on the luminous shoes provides the electric energy, thereby makes display module luminous. According to the luminous shoes provided by the utility model, the mechanical energy of the human body when walking is reasonably utilized through the friction power generation module, and the use of the battery is omitted, so that the trouble that the luminous shoes cannot emit light and then the battery is replaced after the electric quantity of the battery is exhausted is avoided; the use of batteries is reduced, so that energy is saved and the environment is protected; and simultaneously, the utility model provides a luminous shoes structure and preparation simple process, low cost are fit for extensive industrial production.

Drawings

FIG. 1 is a schematic view of the overall structure of an embodiment of the light-emitting shoe provided by the present invention;

FIG. 2 is a schematic block diagram of an embodiment of the light-emitting shoe provided by the present invention;

FIGS. 3a-3k are schematic views of the connection structure of the modules in the embodiment of the light-emitting shoe provided by the present invention;

FIG. 4 is a schematic view of an embodiment of the light-emitting shoe provided by the present invention;

FIGS. 5a-5b are schematic structural views of a friction generator with a common electrode structure in a pair of luminous shoes according to the present invention;

FIG. 6 is a circuit diagram of another embodiment of a light-emitting shoe provided by the present invention;

fig. 7 is a circuit diagram of another embodiment of the light-emitting shoe provided by the present invention.

Detailed Description

The present invention will be described in detail with reference to the following embodiments in order to fully understand the objects, features and functions of the present invention, but the present invention is not limited thereto.

Fig. 1 is a schematic overall structural diagram of an embodiment of the light-emitting shoe provided by the present invention, as shown in fig. 1, in this embodiment, the light-emitting shoe includes: the sole 100 and the upper 200 further include a friction power generation module 300, a rectifier circuit module 400, and a display module 500 as shown in fig. 2. The friction power generation module 300 and the rectification circuit module 400 are positioned at the sole part, and the display module is positioned on the sole and/or the vamp; the friction power generation module 300 includes at least one friction power generator for converting mechanical energy into electrical energy, that is, the friction power generation module 300 senses external force acting on the sole when walking and converts mechanical energy generated by the sensed external force into electrical energy for output; the rectifier circuit module 400 includes at least one rectifier bridge, which is connected to the friction power generation module 300 and is used for rectifying the electric energy output by the friction power generation module 300; and the display module 500 is connected with the rectifier circuit module 400 and is configured to receive the electric energy output by the rectifier circuit module 400, so that the display module 500 performs light emitting display.

The friction power generation module 300 may include one friction power generator or a plurality of friction power generators, which may be selected by those skilled in the art according to the needs, and is not limited herein. If the friction generating module 300 includes a plurality of friction generators, the plurality of friction generators may be connected in series and/or parallel, and the plurality of friction generators connected in series and/or parallel may be disposed inside the sole in a stacked and/or tiled manner.

The friction generator in the friction generating module 300 may be a friction generator in the prior art, such as a friction generator with a common electrode structure, and those skilled in the art may select the friction generator according to the needs, which is not limited herein. Since the friction power generating module 300 is a core component in the light-emitting shoe, it will be separately described in detail later. The connection of the modules will be described first.

As to the specific connection manner of the friction power generation module 300, the rectifier circuit module 400 and the display module 500, reference may be made to fig. 3a to 3 k.

Example one

The triboelectric power generation module 300 may comprise at least one common electrode structure triboelectric generator, the rectifier circuit module 400 may comprise at least one rectifier bridge, and the display module may comprise a single LED strip. The multiple groups of output ends of the common electrode structure friction generator can be respectively connected with the multiple rectifier bridges in a one-to-one correspondence mode. A single LED strip may be connected to a plurality of rectifier bridges.

As shown in fig. 3a, the friction power generation module 300 includes 1 common electrode structure friction power generator, which is a common electrode structure friction power generator 1; the rectifier circuit module 400 comprises 5 rectifier bridges, namely a rectifier bridge 1, a rectifier bridge 2, a rectifier bridge 3, a rectifier bridge 4 and a rectifier bridge 5; the display module 500 includes 1 LED strip, which is the LED strip 1. Wherein, the common electrode structure friction generator 1 has 5 groups of output ends, namely an output end 1, an output end 2, an output end 3, an output end 4 and an output end 5, that is, the friction generating module 300 has 5 groups of output ends, the 5 groups of output ends are respectively and independently connected with 5 rectifier bridges in a one-to-one correspondence manner, that is, the output end 1 of the common electrode structure friction generator 1 is connected with the rectifier bridge 1, the output end 2 of the common electrode structure friction generator 1 is connected with the rectifier bridge 2, the output end 3 of the common electrode structure friction generator 1 is connected with the rectifier bridge 3, the output end 4 of the common electrode structure friction generator 1 is connected with the rectifier bridge 4, the output end 5 of the common electrode structure friction generator 1 is connected with the rectifier bridge 5, 5 groups of output ends of the friction generating modules 300 are connected with 5 rectifier bridges in a one-to-one correspondence manner, and electric energy is output to the rectifier bridges connected with the corresponding output ends. LED lamp area 1 is connected with 5 rectifier bridges simultaneously, and 5 rectifier bridges all provide LED lamp area 1 with the electric energy after the rectification, supply LED lamp area 1 luminous.

As shown in fig. 3b, the friction power generation module 300 includes 2 common electrode structure friction power generators, namely, a common electrode structure friction power generator 1 and a common electrode structure friction power generator 2; the rectifier circuit module 400 comprises 5 rectifier bridges, namely a rectifier bridge 1, a rectifier bridge 2, a rectifier bridge 3, a rectifier bridge 4 and a rectifier bridge 5; the display module 500 comprises a single LED strip, which is the LED strip 1. Wherein, the common electrode structure friction generator 1 has 2 groups of output ends, namely an output end 1 and an output end 2, the common electrode structure friction generator 2 has 3 groups of output ends, namely an output end 1, an output end 2 and an output end 3, namely, the friction power generation module 300 has 5 groups of output ends, the 5 groups of output ends are respectively and independently connected with 5 rectifier bridges in a one-to-one correspondence manner, namely, the output end 1 of the common electrode structure friction generator 1 is connected with the rectifier bridge 1, the output end 2 of the common electrode structure friction generator 1 is connected with the rectifier bridge 2, the output end 1 of the common electrode structure friction generator 2 is connected with the rectifier bridge 3, the output end 2 of the common electrode structure friction generator 2 is connected with the rectifier bridge 4, the output end 3 of the common electrode structure friction generator 2 is connected with the rectifier bridge 5, the 5 groups of output ends of the friction power generation module 300 are connected with, so as to output the electric energy to the rectifier bridge correspondingly connected with the rectifier bridge. LED lamp area 1 is connected with 5 rectifier bridges simultaneously, and 5 rectifier bridges all provide LED lamp area 1 with the electric energy after the rectification, supply LED lamp area 1 luminous.

Example two

The friction power generation module 300 may include at least one common electrode structure friction power generator, the rectifier circuit module 400 may include at least one rectifier bridge, and the display module may include a plurality of LED strips. The multiple groups of output ends of the common electrode structure friction generator can be respectively connected with the multiple rectifier bridges in a one-to-one correspondence mode. The LED lamp belts can be connected with the rectifier bridges in a one-to-one correspondence mode respectively.

As shown in fig. 3c, the friction generating module 300 includes 1 common electrode structure friction generator, which is a common electrode structure friction generator 1; the rectifier circuit module 400 includes 5 rectifier bridges, which are a rectifier bridge 1, a rectifier bridge 2, a rectifier bridge 3, a rectifier bridge 4, and a rectifier bridge 5. The connection method of the friction power generation module 300 and the rectifier circuit module 400 is the same as that of the friction power generation module and the rectifier circuit module shown in fig. 3a in the first embodiment, and is not described herein again. The difference lies in, display module 500 includes 5 LED lamp areas, be LED lamp area 1 respectively, LED lamp area 2, LED lamp area 3, LED lamp area 4 and LED lamp area 5, 5 LED lamp areas are connected with 5 rectifier bridge one-to-one, rectifier bridge 1 connects LED lamp area 1 promptly, rectifier bridge 2 connects LED lamp area 2, rectifier bridge 3 connects LED lamp area 3, rectifier bridge 4 connects LED lamp area 4, rectifier bridge 5 connects LED lamp area 5, 5 rectifier bridge provides the electric energy after the rectification respectively for rather than corresponding 5 LED lamp areas of being connected, supply 5 LED lamp areas luminous.

As shown in fig. 3d, the friction power generation module 300 includes 2 common electrode structure friction power generators, namely, a common electrode structure friction power generator 1 and a common electrode structure friction power generator 2; the rectifier circuit module 400 includes 5 rectifier bridges, which are a rectifier bridge 1, a rectifier bridge 2, a rectifier bridge 3, a rectifier bridge 4, and a rectifier bridge 5. The connection method of the friction power generation module 300 and the rectifier circuit module 400 is the same as that of the friction power generation module and the rectifier circuit module shown in fig. 3b in the first embodiment, and is not described herein again. The difference lies in, display module 500 includes 5 LED lamp areas, be LED lamp area 1 respectively, LED lamp area 2, LED lamp area 3, LED lamp area 4 and LED lamp area 5, 5 LED lamp areas are connected with 5 rectifier bridge one-to-one, rectifier bridge 1 connects LED lamp area 1 promptly, rectifier bridge 2 connects LED lamp area 2, rectifier bridge 3 connects LED lamp area 3, rectifier bridge 4 connects LED lamp area 4, rectifier bridge 5 connects LED lamp area 5, 5 rectifier bridge provides the electric energy after the rectification respectively for rather than corresponding 5 LED lamp areas of being connected, supply 5 LED lamp areas luminous.

EXAMPLE III

The friction power generation module 300 may include at least one common electrode structure friction power generator, the rectifier circuit module 400 may include at least one rectifier bridge, and the display module 500 may include a plurality of LED strips. Wherein, the multiunit output of sharing electrode structure friction generator can be connected with a plurality of rectifier bridge one-to-one respectively, can also be connected with a plurality of rectifier bridges through series connection and/or parallel connection mode between a plurality of LED lamp areas.

As shown in fig. 3e, the friction power generation module 300 includes 1 common electrode structure friction power generator, which is a common electrode structure friction power generator 1; the rectifier circuit module 400 includes 5 rectifier bridges, which are a rectifier bridge 1, a rectifier bridge 2, a rectifier bridge 3, a rectifier bridge 4, and a rectifier bridge 5. The connection method of the friction power generation module 300 and the rectifier circuit module 400 is the same as that of the friction power generation module and the rectifier circuit module shown in fig. 3a in the first embodiment, and is not described herein again. The difference lies in that display module 500 includes 7 LED lamp areas, be LED lamp area 1 respectively, LED lamp area 2, LED lamp area 3, LED lamp area 4, LED lamp area 5, LED lamp area 6 and LED lamp area 7, wherein, LED lamp area 1 is connected with rectifier bridge 1 one-to-one, LED lamp area 2, LED lamp area 3 and LED lamp area 4 are connected with rectifier bridge 2 through establishing ties or parallelly connected or establishing ties and the mode of parallelly connected (specifically establish ties and/or parallel connection mode is not shown in the figure), LED lamp area 5 is connected with rectifier bridge 3 and rectifier bridge 4 simultaneously, LED lamp area 6 and LED lamp area 7 are connected with rectifier bridge 5 through establishing ties or the mode of parallelly connected (specifically establish ties or parallel connection mode is not shown in the figure). The 5 rectifier bridges provide the rectified electric energy for the 7 LED lamp belts correspondingly connected with the rectifier bridges, and the 7 LED lamp belts are used for emitting light.

As shown in fig. 3f, the friction power generation module 300 includes 2 common electrode structure friction power generators, namely, a common electrode structure friction power generator 1 and a common electrode structure friction power generator 2; the rectifier circuit module 400 includes 5 rectifier bridges, which are a rectifier bridge 1, a rectifier bridge 2, a rectifier bridge 3, a rectifier bridge 4, and a rectifier bridge 5. The connection method of the friction power generation module 300 and the rectifier circuit module 400 is the same as that of the friction power generation module and the rectifier circuit module shown in fig. 3b in the first embodiment, and is not described herein again. The difference lies in that display module 500 includes 7 LED lamp areas, be LED lamp area 1 respectively, LED lamp area 2, LED lamp area 3, LED lamp area 4, LED lamp area 5, LED lamp area 6 and LED lamp area 7, wherein, LED lamp area 1 is connected with rectifier bridge 1 one-to-one, LED lamp area 2, LED lamp area 3 and LED lamp area 4 are connected with rectifier bridge 2 through establishing ties or parallelly connected or establishing ties and the mode of parallelly connected (specifically establish ties and/or parallel connection mode is not shown in the figure), LED lamp area 5 is connected with rectifier bridge 3 and rectifier bridge 4 simultaneously, LED lamp area 6 and LED lamp area 7 are connected with rectifier bridge 5 through establishing ties or the mode of parallelly connected (specifically establish ties or parallel connection mode is not shown in the figure). The 5 rectifier bridges provide the rectified electric energy for the 7 LED lamp belts correspondingly connected with the rectifier bridges, and the 7 LED lamp belts are used for emitting light.

Example four

The friction power generation module 300 may include at least one common electrode structure friction power generator, the rectifier circuit module 400 may include at least one rectifier bridge, and the display module 500 may include a single LED strip. The multiple groups of output ends of the common electrode structure friction generator can also be connected with a plurality of rectifier bridges, and the output ends of the common electrode structure friction generator connected with one rectifier bridge are connected in series and/or in parallel. The single LED lamp strip is connected with a plurality of rectifier bridges.

As shown in fig. 3g, the friction power generation module 300 includes 4 common electrode structure friction power generators, namely, a common electrode structure friction power generator 1, a common electrode structure friction power generator 2, a common electrode structure friction power generator 3 and a common electrode structure friction power generator 4; the rectifier circuit module 400 comprises 5 rectifier bridges, namely a rectifier bridge 1, a rectifier bridge 2, a rectifier bridge 3, a rectifier bridge 4 and a rectifier bridge 5; the display module 500 includes 1 LED strip. Wherein, shared electrode structure friction generator 1 has 2 groups of outputs, be output 1 and output 2 respectively, shared electrode structure friction generator 2 has 3 groups of outputs, be output 1 respectively, output 2 and output 3, shared electrode structure friction generator 3 has 2 groups of outputs, be output 1 respectively and output 2 respectively, shared electrode structure friction generator 4 has 2 groups of outputs, be output 1 respectively and output 2, that is to say, friction power generation module 300 has 7 groups of outputs in total. The 7 groups of output ends are connected with 5 rectifier bridges in series and/or parallel connection, the output end 1 and the output end 2 of the common electrode structure friction generator 1 are connected with the rectifier bridges 1 in series or parallel connection (the specific series or parallel connection is not shown in the figure), the output end 1, the output end 2 and the output end 3 of the common electrode structure friction generator 2 are connected with the rectifier bridges 2 in series or parallel connection or series and parallel connection (the specific series and/or parallel connection is not shown in the figure), the output end 1 of the common electrode structure friction generator 3 is connected with the rectifier bridges 3, the output end 2 of the common electrode structure friction generator 3 and the output end 1 of the common electrode structure friction generator 4 are connected with the rectifier bridges 4 in series or parallel connection (the specific series or parallel connection is not shown in the figure), the output end 2 of the common electrode structure friction generator 4 is connected with the rectifier bridges 5, and 7 groups of output ends are connected with the 5 rectifier bridges so as to output electric energy to the rectifier bridges correspondingly connected with the output ends. LED lamp area 1 is connected with 5 rectifier bridges simultaneously, and 5 rectifier bridges all provide the LED lamp area 1 rather than being connected with the electric energy after the rectification, supply LED lamp area 1 luminous.

EXAMPLE five

The friction power generation module may include at least one common electrode structure friction power generator, the rectifier circuit module may include at least one rectifier bridge, and the display module may include a plurality of LED strips. The multiple groups of output ends of the common electrode structure friction generator can also be connected with a plurality of rectifier bridges, and the output ends of the common electrode structure friction generator connected with one rectifier bridge are connected in series and/or in parallel. The LED lamp belts can be connected with the rectifier bridges in a one-to-one correspondence mode respectively. The connection mode of the friction power generation module and the rectifier circuit module is the same as that of the friction power generation module and the rectifier circuit module shown in fig. 3g in the fourth embodiment, and the connection mode of the plurality of LED strips and the rectifier circuit module is the same as that of the plurality of LED strips and the rectifier circuit module shown in fig. 3d in the second embodiment, which is not described herein again.

EXAMPLE six

The friction power generation module may comprise at least one common electrode structure friction power generator, the rectifier circuit module may comprise at least one rectifier bridge, and the display module may comprise a plurality of LED strips. The multiple groups of output ends of the common electrode structure friction generator can also be connected with a plurality of rectifier bridges, and the output ends of the common electrode structure friction generator connected with one rectifier bridge are connected in series and/or in parallel. The LED lamp belts can be connected with the rectifier bridges in series and/or parallel. The connection mode of the friction power generation module and the rectifier circuit module is the same as that of the friction power generation module and the rectifier circuit module shown in fig. 3g in the fourth embodiment, and the connection mode of the plurality of LED strips and the rectifier circuit module is the same as that of the plurality of LED strips and the rectifier circuit module shown in fig. 3f in the third embodiment, which is not described herein again.

EXAMPLE seven

The friction power generation module 300 may include at least one common electrode structure friction power generator, the rectifier circuit module 400 may include a rectifier bridge, and the display module 500 may include a single LED strip. The output ends of the common electrode structure friction generator are connected with a rectifier bridge, and the output ends of the common electrode structure friction generator connected with the rectifier bridge are connected in series and/or in parallel. The single LED lamp strip is connected with a rectifier bridge.

As shown in fig. 3h, the friction power generation module 300 includes 1 common electrode structure friction power generator, which is a common electrode structure friction power generator 1; the rectifier circuit module 400 includes 1 rectifier bridge, which is rectifier bridge 1; the display module 500 includes 1 LED strip, which is the LED strip 1. The common electrode structure friction generator 1 has 4 groups of output ends, namely an output end 1, an output end 2, an output end 3 and an output end 4, that is, the friction generating module 300 has 4 groups of output ends, and the 4 groups of output ends are connected in series and/or parallel and then connected with 1 rectifier bridge, that is, the output end 1, the output end 2, the output end 3 and the output end 4 of the common electrode structure friction generator 1 are connected with the rectifier bridge 1 in series or parallel or series and parallel (the specific series and/or parallel connection mode is not shown in the figure) and then output electric energy to the rectifier bridge 1 connected with the output end. The LED lamp strip 1 is connected with the rectifier bridge 1, and the rectifier bridge 1 supplies the rectified electric energy to the LED lamp strip 1 connected with the rectifier bridge 1 so that the LED lamp 1 can emit light.

As shown in fig. 3i, the friction power generation module 300 includes 2 common electrode structure friction power generators, namely a common electrode structure friction power generator 1 and a common electrode structure friction power generator 2; the rectifier circuit module 400 includes 1 rectifier bridge, which is rectifier bridge 1; the display module 500 includes 1 LED strip, which is the LED strip 1. The common electrode structure friction generator 1 has 2 sets of output ends, namely, the output end 1 and the output end 2, the common electrode structure friction generator 2 has 2 sets of output ends, namely, the output end 1 and the output end 2, namely, the friction power generation module 300 has 4 sets of output ends, the 4 sets of output ends are connected in series and/or parallel and then connected with 1 rectifier bridge, namely, the output end 1 and the output end 2 of the common electrode structure friction generator 1 are connected with the output end 1 and the output end 2 of the common electrode structure friction generator 2 in series or parallel or series and parallel (the specific series and/or parallel connection mode is not shown in the figure) and then connected with the rectifier bridge 1, so as to output electric energy to the rectifier bridge 1 connected with the common electrode structure friction generator. The LED lamp strip 1 is connected with the rectifier bridge 1, and the rectifier bridge 1 supplies the rectified electric energy to the LED lamp strip 1 connected with the rectifier bridge 1 so that the LED lamp 1 can emit light.

Example eight

The friction power generation module 300 may include at least one common electrode structure friction power generator, the rectifier circuit module 400 may include a rectifier bridge, and the display module 500 may include a plurality of LED strips. The output ends of the common electrode structure friction generator are connected with a rectifier bridge, and the output ends of the common electrode structure friction generator connected with the rectifier bridge are connected in series and/or in parallel. The LED lamp belts are connected with one rectifier bridge in a serial and/or parallel mode.

As shown in fig. 3j, the friction power generation module 300 includes 1 common electrode structure friction power generator, which is a common electrode structure friction power generator 1; the rectifier circuit module 400 includes 1 rectifier bridge, which is rectifier bridge 1. The connection mode of the friction power generation module 300 and the rectifier circuit module 400 is the same as that of the friction power generation module and the rectifier circuit module shown in fig. 3h in the seventh embodiment, and the description thereof is omitted. The difference lies in that display module 500 includes 4 LED lamp areas, is LED lamp area 1, LED lamp area 2, LED lamp area 3 and LED lamp area 4 respectively. The LED lamp strips 1, 2, 3 and 4 are connected in series or in parallel or in series and parallel (the specific series and/or parallel connection mode is not shown in the figure), and then are connected with the rectifier bridge 1, and the rectifier bridge 1 supplies rectified electric energy to the 4 LED lamp strips connected with the rectifier bridge for the 4 LED lamp strips to emit light.

As shown in fig. 3k, the friction power generation module 300 includes 2 common electrode structure friction power generators, namely, a common electrode structure friction power generator 1 and a common electrode structure friction power generator 2; the rectifier circuit module 400 includes 1 rectifier bridge, which is rectifier bridge 1. The connection manner of the friction power generation module 300 and the rectifier circuit module 400 is the same as that of the friction power generation module and the rectifier circuit module shown in fig. 3i in the seventh embodiment, and the description thereof is omitted. The difference lies in that display module 500 includes 4 LED lamp areas, is LED lamp area 1, LED lamp area 2, LED lamp area 3 and LED lamp area 4 respectively. The LED lamp strips 1, 2, 3 and 4 are connected in series or in parallel or in series and parallel (the specific series and/or parallel connection mode is not shown in the figure), and then are connected with the rectifier bridge 1, and the rectifier bridge 1 supplies rectified electric energy to the 4 LED lamp strips connected with the rectifier bridge for the 4 LED lamp strips to emit light.

The above are all illustrations, and the connection mode in implementation can be set according to actual situations, and is not specifically limited herein.

The friction power generation module, the rectifying circuit module and the display module are connected with each other in different connection modes according to different set distances. When the distance is longer, the connection can be carried out by adopting a lead, and when the distance is shorter, the connection can be carried out by directly adopting a terminal.

The position of each module can be flexibly designed according to needs, such as: as shown in fig. 4, the friction power generation module 300 and the rectifier circuit module 400 are disposed at the sole, for example, the friction power generation module 300 and the rectifier circuit module 400 may be disposed inside the sole and the front sole and/or the arch and/or the heel contact portion; the display module 500 may also be disposed at a sole, wherein the sole includes a bottom surface and a side surface of the sole, and the display module 500 is disposed at the side surface of the sole so as not to affect the light emitting effect thereof. In addition, the display module 500 may also be disposed at the upper side and/or the front end and/or the rear end of the light-emitting shoe, etc.; the display module 500 may also be disposed on the upper. In order to set up the convenience, can be with the vamp preparation for double-deck vamp, including transparent top layer and nexine, display module 500 sets up between transparent top layer and nexine, neither can influence the comfort level of the shoes body itself like this, also can not influence the pleasing to the eye degree of the shoes body, has still prevented display module 500 effectively and has taken place by the phenomenon of wearing and tearing. Of course, the display module 500 may be directly attached to the outer surface of the light-emitting shoe.

The display module adopts the LED lamp area, and wherein, the LED lamp area can arrange into various shapes of predetermineeing, for example, can arrange into all kinds of shapes such as chinese character shape, pinyin shape, animal and plant pattern shape to satisfy people's aesthetic requirement and interesting demand. In addition, a plurality of LED lamp belts can be arranged into the shape of the logo of the luminous shoe (such as a logo of a product), so that the logo can be highlighted in the dark, and brand awareness can be improved. The LED lamp belts can be connected in series or in parallel, the series connection circuit is simple, and the constancy of the current passing through the LEDs can be guaranteed, so that the brightness of the LEDs is uniform; the parallel connection circuit has high reliability, and a proper connection mode can be selected according to requirements during specific design. Generally can be when the shoes of giving out light provide bigger luminance in needs, can set up many LED lamp areas into series connection, because the characteristic that series circuit partial pressure was not shunted for the electric current that flows through many LED lamp areas is bigger, thereby makes it provide bigger luminance. In addition, in order to enable the shape formed by the LED lamp strip to be more vivid, a light-transmitting cover covering the outside of the LED lamp strip can be further arranged on the light-emitting shoes, and the light shape is changed through the light-transmitting cover. For example, a light-transmitting part capable of transmitting light can be further arranged on the light-transmitting cover, and the light-transmitting part can be realized by a hollow hole or a light-transmitting material. The shape of the light-transmitting part can be not only a Chinese character shape, a pinyin shape or a product identification shape of the luminous shoe, but also other more precise shapes, such as the shapes of flowers, birds, fishes and insects, and the like, so that the emitted light can be consistent with the shape of the light-transmitting part, and the visual effect of the luminous shoe can be further improved. The shape of the light emitted by the LED lamp strip can be optimized to various fine shapes which are difficult to realize only through the arrangement mode of the LED lamp strip through the light-transmitting cover.

Finally, the specific structure of the friction generator with the electrode structure shared by the core components in the luminescent shoes provided by the embodiment of the invention is described in detail. The following will describe possible configurations of the common electrode configuration triboelectric generator by two examples. The common electrode structure friction generator is provided with a convex structure on at least one surface of two surfaces forming a friction interface. The convex structures are preferably micron-sized and/or nano-sized convex structures, and can be arranged in a rhombic arrangement mode. The protruding structure can effectively increase the friction contact area, increase the friction resistance and improve the output efficiency of the pressure electric signal.

Example 1

The common electrode structure friction generator comprises m electrode layers and n high polymer insulating layers, wherein m is greater than or equal to 3, n is greater than or equal to 2, and m-n is equal to 1. The electrode layers and the high polymer insulating layers are sequentially and alternately stacked, the electrode layers and the high polymer insulating layers rub against each other to form a friction interface, and two adjacent electrode layers form a group of output ends of the friction generator with the common electrode structure.

The common electrode structure triboelectric generator shown in fig. 5a is a 5-layer structure, comprising 3 electrode layers: first electrode layer 311, second electrode layer 313, and third electrode layer 315, and 2 high molecular polymer insulating layers: a first polymer insulating layer 312 and a second polymer insulating layer 314. The electrode layers and the polymer insulating layers are sequentially and alternately stacked, that is, the first electrode layer 311, the first polymer insulating layer 312, the second electrode layer 313, the second polymer insulating layer 314, and the third electrode layer 315 are sequentially stacked. The electrode layers and the polymer insulating layers rub against each other to form a friction interface, and specifically, the first electrode layer 311 and the first polymer insulating layer 312 and/or the first polymer insulating layer 312 and the second electrode layer 313 and/or the second electrode layer 313 and the second polymer insulating layer 314 and/or the second polymer insulating layer 314 and the third electrode layer 315 rub against each other to form a friction interface. Two adjacent electrode layers form one group of output ends of the common electrode structure friction generator, namely the first electrode layer 311 and the second electrode layer 313, and the second electrode layer 313 and the third electrode layer 315 form two groups of output ends. Optionally, at least one of two surfaces constituting the friction interface is provided with a protruding structure, that is, at least one of two surfaces where the first electrode layer 311 and the first high molecular polymer insulating layer 312 and/or the first high molecular polymer insulating layer 312 and the second electrode layer 313 and/or the second electrode layer 313 and the second high molecular polymer insulating layer 314 and/or the second high molecular polymer insulating layer 314 and the third electrode layer 315 are in contact friction with each other is provided with a protruding structure.

Example two

The common electrode structure friction generator comprises m electrode layers and n high polymer insulating layers, wherein m is greater than or equal to 3, n is greater than or equal to 4, and 2m-n is equal to 2; the electrode layers and the two high polymer insulating layers are sequentially and alternately stacked, the two high polymer insulating layers which are in contact mutually rub to form a friction interface, and the two adjacent electrode layers form a group of output ends of the friction generator with the common electrode structure.

The common electrode structure triboelectric generator shown in fig. 5b is a 7-layer structure comprising 3 electrode layers: first electrode layer 321, second electrode layer 324, and third electrode layer 327, 4 polymer insulating layers: a first high molecular polymer insulating layer 322, a second high molecular polymer insulating layer 323, a third high molecular polymer insulating layer 325, and a fourth high molecular polymer insulating layer 326. The electrode layer and the two polymer insulating layers are sequentially and alternately stacked, that is, the first electrode layer 321, the first polymer insulating layer 322, the second polymer insulating layer 323, the second electrode layer 324, the third polymer insulating layer 325, the fourth polymer insulating layer 326 and the third electrode layer 327 are sequentially stacked. The two polymer insulating layers in contact rub against each other to form a friction interface, specifically, the first polymer insulating layer 322 and the second polymer insulating layer 323 and the third polymer insulating layer 325 and the fourth polymer insulating layer 326 form a friction interface. Two adjacent electrode layers form one group of output ends of the common electrode structure friction generator, namely, the first electrode layer 321, the second electrode layer 324 and the third electrode layer 327 form two groups of output ends. Alternatively, at least one of two surfaces constituting the friction interface is provided with a protruding structure, that is, at least one of two surfaces where the first high polymer insulating layer 322 and the second high polymer insulating layer 323, and the third high polymer insulating layer 325 and the fourth high polymer insulating layer 326 contact and rub against each other is provided with a protruding structure.

According to the utility model provides a luminous shoes, the external force that will act on the sole when walking through the friction electricity generation module turns into the electric energy, and rethread rectifier circuit module changes it for display module on the luminous shoes provides the electric energy, thereby makes display module luminous. According to the luminous shoes provided by the utility model, the mechanical energy of the human body when walking is reasonably utilized through the friction power generation module, and the use of the battery is omitted, so that the trouble that the luminous shoes cannot emit light and then the battery is replaced after the electric quantity of the battery is exhausted is avoided; the use of batteries is reduced, so that energy is saved and the environment is protected; and simultaneously, the utility model provides a luminous shoes structure and preparation simple process, low cost are fit for extensive industrial production.

In addition to the modules in the above embodiments, the light-emitting shoe may further include: an energy storage module. Fig. 6 is the circuit structure diagram of the embodiment module of luminous shoes, energy storage module 600 is connected with rectifier circuit module 400 and display module 500, and rectifier circuit module 400 can turn into the direct current with the alternating current that friction power generation module 300 produced to store through energy storage module 600, thereby make the electric energy that friction power generation module 300 produced obtain more efficient utilization. The energy storage module 600 may be an energy storage element, and may be a lithium battery, a nickel-metal hydride battery, a super capacitor, or other various energy storage elements.

Although the circuit structure shown in fig. 6 can achieve the effect of continuous illumination of the display module for a period of time, and avoid the flicker phenomenon. However, in the circuit configuration shown in fig. 6, light emission cannot be controlled, for example: if the user does not want the light-emitting shoes to emit light in some formal occasions in the daytime, the display module cannot be actively turned off, and the user can emit light as soon as walking, so that inconvenience is brought to the user. In order to solve the above problems, the luminous shoe further comprises: the control switch module, as shown in fig. 7, is connected between the energy storage module 600 and the display module 500 for controlling the supply of electric energy. Wherein, the control switch module can be: spring switch, button switch, vibration switch or sound control switch.

The utility model provides a luminous shoes through setting up energy storage module and control switch module, stores the electric energy that the friction electricity generation module produced, makes the user also can realize the luminous shoes of luminous shoes through the electric energy of storage in the energy storage module when not walking about, has satisfied the illumination needs of user under the static condition (if can observe the road conditions). Meanwhile, the control switch module can control the on and off of the luminescence of the shoe body, so that a user can turn off the shoe body under the condition that the user does not want the luminescence of the shoe body. Thereby fully meeting various requirements of users and providing great convenience for the users.

The utility model discloses in various modules, circuit mentioned are the circuit by the hardware realization, though wherein some module, circuit have integrateed the software, nevertheless the utility model discloses what protect is the hardware circuit of the function that integrated software corresponds, and not only software itself.

It will be appreciated by those skilled in the art that the arrangement of devices shown in the figures or embodiments is merely schematic and representative of a logical arrangement. Where modules shown as separate components may or may not be physically separate, components shown as modules may or may not be physical modules.

Finally, it is noted that: the above list is only the concrete implementation example of the present invention, and of course those skilled in the art can make modifications and variations to the present invention, and if these modifications and variations fall within the scope of the claims of the present invention and their equivalent technology, they should be considered as the protection scope of the present invention.

Claims (8)

1. A luminous shoes, includes sole and vamp, its characterized in that still includes: the device comprises a friction power generation module, a rectifying circuit module and a display module; the friction power generation module and the rectification circuit module are positioned at the sole part, and the display module is positioned on the sole and/or the vamp;

the friction power generation module comprises at least one friction power generator for converting mechanical energy into electric energy; the friction generator is a common electrode structure friction generator; the common electrode structure friction generator comprises m electrode layers and n high polymer insulating layers, wherein m is greater than or equal to 3, n is greater than or equal to 4, and 2m-n is equal to 2; the electrode layers and the two high polymer insulating layers are sequentially and alternately stacked, the two high polymer insulating layers which are contacted mutually rub to form a friction interface, and the two adjacent electrode layers form a group of output ends of the friction generator with the common electrode structure;

the rectifying circuit module comprises a plurality of rectifying bridges, is connected with the friction power generation module and is used for rectifying the electric energy output by the friction power generation module;

the display module is connected with the rectifying circuit module and used for receiving the electric energy output by the rectifying circuit module so as to enable the display module to perform light-emitting display; the display module is a single or a plurality of LED lamp belts;

the common electrode structure friction generator is connected with the rectifier bridges, wherein multiple groups of output ends of the common electrode structure friction generator are respectively connected with the plurality of rectifier bridges in a one-to-one correspondence manner; or a plurality of groups of output ends of the common electrode structure friction generator are connected with a plurality of rectifier bridges, and the output ends of the common electrode structure friction generator connected with one rectifier bridge are connected in series and/or in parallel;

the rectifier bridge is connected with the LED lamp strip, wherein a single LED lamp strip is connected with a plurality of rectifier bridges; or the LED lamp belts are respectively connected with the rectifier bridges in a one-to-one correspondence manner; or the LED lamp belts are connected with the rectifier bridges in series and/or parallel.

2. The illuminated shoe according to claim 1, characterized in that at least one of the two surfaces constituting the friction interface is provided with a raised structure.

3. The lighted shoe of claim 1, wherein the sole further comprises a bottom surface and a side surface, the display module being disposed on the side surface of the sole.

4. The lighted shoe of claim 1, wherein the upper includes a top layer and a bottom layer, the display module being disposed between the top layer and the bottom layer.

5. The lighted shoe of claim 1, wherein the LED strip is capable of being arranged in a predetermined shape; the preset shape includes: a Chinese character shape, a pinyin shape, or an identification shape of the light-emitting shoe.

6. The lighted shoe of claim 1, further comprising: an energy storage module; the energy storage module is connected with the rectifying circuit module and the display module.

7. The lighted shoe of claim 6, further comprising: the control switch module is connected between the energy storage module and the display module, wherein the control switch module is a spring switch, a button switch, a vibration switch or a sound control switch.

8. The lighted shoe of claim 1, wherein a plurality of the friction generators are disposed in a stacked or tiled arrangement inside the sole.