CN202948674U - Anti-counterfeiting unit and device provided with the same - Google Patents

Abstract

The utility model discloses an anti-counterfeiting unit and a device provided with the anti-counterfeiting unit. The anti-counterfeiting unit and the device provided with the anti-counterfeiting unit are used for solving the problems that an anti-counterfeiting unit can not be folded or bent, and an application range is caused to be limited in the prior art. The anti-counterfeiting unit comprises a display screen displaying anti-counterfeiting marks, and a power module connected with the display screen, wherein the display screen is a flexible display screen, and the power module is a flexible power module. Both the display screen and the power module which are adopted for the anti-counterfeiting unit are flexible, and therefore the anti-counterfeiting unit can be folded or bent according to needs, and can be applied to devices in various shapes.

Description

False proof device and comprise the equipment of this false proof device

Technical field

The utility model relates to false proof demonstration field, particularly a kind of false proof device and comprise the equipment of this false proof device.

Background technology

At present, in order to differentiate the true and false of product, various false proof modes have appearred, for example, can show that the mode of anti-counterfeiting mark reaches false proof purpose by display screen, still, these display screen materials are harder, often not collapsible or crooked, can't design according to the actual requirements its form, cause its scope of application very limited.

The utility model content

The utility model provides a kind of false proof device and comprised the equipment of this false proof device, and is not collapsible or crooked in order to solve false proof device of the prior art, causes the limited problem of usable range.

The utility model provides a kind of false proof device, comprising: show the display screen of anti-counterfeiting mark, and the power module that is connected with described display screen, wherein, described display screen is flexible display screen, and described power module is the flexible electrical source module.

Alternatively, described display screen is the LCD screen, and perhaps, described display screen is electronic-paper display screen.

Alternatively, described display screen be shaped as a kind of in following shape: circle, rectangle, annular and rhombus, described power module be shaped as a kind of in following shape: circle, rectangle, annular and rhombus; And the shape of described display screen and the shape of described power module are identical or different.

Alternatively, described display screen contacts and is electrically connected to described power module, and perhaps, described display screen does not contact and is connected by wire with described power module.

Alternatively, described power module is the nano friction generator; Perhaps, described power module is slimline battery, and described slimline battery comprises: flexible package lithium cell, all solid-state thin-film lithium battery and paper battery.

Alternatively, when described power module was the nano friction generator, described nano friction generator comprised: the first high molecular polymer insulation course; The first electrode is positioned on the first side surface of described the first high molecular polymer insulation course; The second high molecular polymer insulation course; The second electrode is positioned on the first side surface of described the second high molecular polymer insulation course; Wherein, described the first electrode and the second electrode are the output electrodes of described nano friction generator; The second side surface of described the first high molecular polymer insulation course contacts with the second side surface of the second high molecular polymer insulation course, and the second side surface of the second side surface of described the first high molecular polymer insulation course and the second high molecular polymer insulation course is respectively arranged with the micro-nano concaveconvex structure.

Alternatively, when described power module was the nano friction generator, described nano friction generator comprised: the first electrode that is cascading, the first high molecular polymer insulation course, and friction electrode; Wherein, be provided with the micro-nano concaveconvex structure at least one face in the first high molecular polymer insulation course and two faces being oppositely arranged of friction electrode; Described the first electrode and friction electrode are the output electrode of nano friction generator.

Alternatively, described nano friction generator further comprises: the second high molecular polymer insulation course and the second electrode, wherein, and described the first electrode, the first high molecular polymer insulation course, the second high molecular polymer insulation course and the second electrode are cascading; Described friction electrode is arranged between described the first high molecular polymer insulation course and the second high molecular polymer insulation course; Be provided with the micro-nano concaveconvex structure at least one face in the first high molecular polymer insulation course and two opposite faces of friction electrode; Be provided with the micro-nano concaveconvex structure at least one face in the second high molecular polymer insulation course and two opposite faces of friction electrode; Described the first electrode and the series connection of the second electrode are an output electrode of nano friction generator; Another output electrode that described friction electrode is the nano friction generator.

Alternatively, described friction electrode comprises the third electrode layer that is cascading, third high Molecularly Imprinted Polymer layer and the 4th electrode layer; Be provided with the micro-nano concaveconvex structure at least one face in two opposite face of the first high molecular polymer insulation course and third electrode layer; Be provided with the micro-nano concaveconvex structure at least one face in the second high molecular polymer insulation course and two opposite faces of the 4th electrode layer; Described the first electrode and the series connection of the second electrode are an output electrode of nano friction generator; The third electrode layer of described friction electrode and the series connection of the 4th electrode layer are another output electrode of nano friction generator.

alternatively, described electrode material therefor is indium tin oxide, Graphene, nano silver wire film, metal or alloy, and wherein metal is Au Ag Pt Pd, aluminium, nickel, copper, titanium, chromium, selenium, iron, manganese, molybdenum, tungsten or vanadium, alloy is aluminium alloy, titanium alloy, magnesium alloy, beryllium alloy, aldary, kirsite, manganese alloy, nickel alloy, lead alloy, ashbury metal, cadmium alloy, bismuth alloy, indium alloy, gallium alloy, tungalloy, molybdenum alloy, niobium alloy or tantalum alloy, described friction electrode material therefor is metal or alloy, and wherein metal is Au Ag Pt Pd, aluminium, nickel, copper, titanium, chromium, selenium, iron, manganese, molybdenum, tungsten or vanadium, alloy is aluminium alloy, titanium alloy, magnesium alloy, beryllium alloy, aldary, kirsite, manganese alloy, nickel alloy, lead alloy, ashbury metal, cadmium alloy, bismuth alloy, indium alloy, gallium alloy, tungalloy, molybdenum alloy, niobium alloy or tantalum alloy, described high molecular polymer insulation course material therefor is selected from Kapton, the aniline formaldehyde resin film, the polyoxymethylene film, ethyl cellulose film, polyamide film, the melamino-formaldehyde film, polyglycol succinate film, cellophane, cellulose acetate film, the polyethylene glycol adipate film, the polydiallyl phthalate film, regeneration sponge film, the elastic polyurethane body thin film, the styrene-acrylonitrile copolymer copolymer film, the styrene-butadiene-copolymer film, the regenerated fiber film, polymethyl methacrylate film, polyvinyl alcohol film, the polyisobutylene film, pet film, polyvinyl butyral film, formaldehyde phenol condensed polymer film, the neoprene film, the butadiene-propylene copolymer film, the natural rubber film, the polyacrylonitrile film, any one in vinyl cyanide vinyl chloride copolymer film.

The utility model also provides a kind of equipment, comprises above-mentioned false proof device.

Alternatively, described equipment comprises first component and second component, engagement connection or be threaded between described first component and second component.

Alternatively, the described display screen in described false proof device and described power module are arranged on described first component, and perhaps, described display screen and described power module in described false proof device are arranged on described second component.

Alternatively, the described display screen in described false proof device is arranged on described first component, and the described power module in described false proof device is arranged on described second component; Perhaps, the described display screen in described false proof device is arranged on described second component, and the described power module in described false proof device is arranged on described first component.

Alternatively, when described first component separated with described second component, the described display screen in described false proof device and the connection between described power module disconnected.

The display screen that false proof device in the utility model embodiment adopts and power module are flexible, and therefore, this false proof device can fold as required or be crooked, can be applicable to the equipment of various shapes.

Description of drawings

The structural representation of the false proof device that Fig. 1 provides for the utility model;

Fig. 2 a and Fig. 2 b show respectively that the display screen of the false proof device that provides when the utility model and power module are rectangle and structural representation and sectional view when being in contact with one another;

Fig. 3 a and Fig. 3 b show respectively that the display screen of the false proof device that provides when the utility model and power module are circle and structural representation and sectional view when being in contact with one another;

The display screen that the false proof device that provides when the utility model is provided Fig. 4 is not connected with power module and is contacted and the structural representation when connecting by wire 10;

The display screen that the false proof device that provides when the utility model is provided respectively for Fig. 5 a and Fig. 5 b is structural representation and the sectional view for around display screen 11 annular the time for circular, power module;

Fig. 6 shows the first structural representation of nano friction generator;

Fig. 7 shows the second structural representation of nano friction generator;

Fig. 8 shows the structural representation of another improvement implementation of the nano friction generator in Fig. 7;

Fig. 9 shows the structural representation of another improvement implementation of the nano friction generator in Fig. 8;

Figure 10 shows a kind of structural representation of the equipment that comprises this false proof device that the utility model provides;

Figure 11 shows the another kind of structural representation of the equipment that comprises this false proof device that the utility model provides;

Figure 12 a, Figure 12 b and Figure 12 c show another structural representation of the equipment that comprises this false proof device that the utility model provides;

Figure 13 shows another structural representation of the equipment that comprises this false proof device that the utility model provides.

Embodiment

For fully understanding purpose, feature and the effect of the utility model, by following concrete embodiment, the utility model is elaborated, but the utility model is not restricted to this.

The utility model provides a kind of false proof device and has comprised the equipment of this false proof device, can solve false proof device of the prior art not collapsible or crooked, causes the limited problem of usable range.

Fig. 1 shows the structural representation of the false proof device that the utility model provides.As shown in Figure 1, comprising: show the display screen 11 of anti-counterfeiting mark, and the power module 12 that is connected with display screen 11, wherein, described display screen 11 is flexible display screen, and described power module 12 is the flexible electrical source module.

Because the each several part of the false proof device in the present embodiment is all flexible, therefore, arbitrarily bending can adapt to the demand of the equipment of various shapes.In addition, the use of nano friction generator, itself just can play false proof effect, for example: still can't power when the nano friction generator generation deformation as the display screen in the false proof device of installing on fruit product, can determine that the false proof device of installing on this product palms off, therefore, this product is also imitation.

Display screen in the present embodiment can adopt the display screen of LCD screen, electronic-paper display screen or other low-power consumption.The content that shows screen display can be the anti-counterfeiting mark (for example, false proof logo, security code, name of product or product related information etc.) that pre-sets, and shows this anti-counterfeiting mark as long as display screen is just fixed once energising.Wherein, the shape of display screen can be any one in following shape: circle, rectangle, annular and rhombus, the shape of power module also can be any one in following shape: circle, rectangle, annular and rhombus, wherein, the shape of the shape of display screen and power module both can be the same or different.And, can contact with each other and be electrically connected between display screen and power module, perhaps, yet can not contact and be connected by wire between display screen and power module.In a word, the shape of display screen and power module and position relationship can be adjusted according to the actual requirements neatly, are the demonstration that display screen powers to realize display screen as long as can satisfy power module.

For example, Fig. 2 a and Fig. 2 b show respectively structural representation and the sectional view when display screen and power module are rectangle and are in contact with one another.In Fig. 2 a and Fig. 2 b, display screen 11 and power module 12 are all rectangle, and together bonded to each other between display screen 11 and power module 12, and connect by wire 10.Fig. 3 a and Fig. 3 b show respectively structural representation and the sectional view when display screen and power module are circle and are in contact with one another.In Fig. 3 a and Fig. 3 b, display screen 11 and power module 12 are all circular, and together bonded to each other between display screen 11 and power module 12, and connect by wire 10.Fig. 4 shows to be connected with power module when display screen 11 and does not contact (namely divide and be arranged) and the structural representation when connecting by wire 10.Fig. 5 a and Fig. 5 b show respectively when display screen 11 for circular, power module 12 structural representation and the sectional view for around display screen 11 annular the time, wherein, in Fig. 5 a and Fig. 5 b, the position of display screen and power module and shape also can be exchanged, be that power module is circular, display screen is the annular around power module.

Power module in the present embodiment can adopt the nano friction generator to realize.The first structure of nano friction generator comprises as shown in Figure 6: the first electrode 61, the first high molecular polymer insulation course 60, the second high molecular polymer insulation course 62 and the second electrode 63.Particularly, the first electrode 61 is positioned on the first side surface 60a of the first high molecular polymer insulation course 60, and the second electrode 63 is positioned on the first side surface 62a of the second high molecular polymer insulation course 62.The first electrode 61 and the second electrode 63 can be the metallic film of conduction, and it can be plated on the surface of corresponding high molecular polymer insulation course by vacuum sputtering or vapour deposition method.Wherein, the second side surface 62b of the second high molecular polymer insulation course 62 contacts with the second side surface 60b of the first high molecular polymer insulation course 60, and on the second side surface 62b of the second high molecular polymer insulation course 62, and on the second side surface 60b of the first high molecular polymer insulation course 60, be respectively equipped with micro-nano concaveconvex structure 80.Therefore, form a frictional interface between the micro-nano concaveconvex structure 80 on the second side surface 60b of the micro-nano concaveconvex structure 80 on the second side surface 62b of the second high molecular polymer insulation course 62 and the first high molecular polymer insulation course 60.Particularly, the second high molecular polymer insulation course and the first high molecular polymer insulation course be over against applying, and at two short edges by common adhesive plaster sealing, guarantee the appropriateness contact of two polymer insulation layer.Certainly, also can be fixed in other way contact between the second high molecular polymer insulation course and the first high molecular polymer insulation course.Also show the schematic diagram of micro-nano concaveconvex structure 80 of the second side surface 60b of the second side surface 62b of the second high molecular polymer insulation course 62 and the first high molecular polymer insulation course 60 in Fig. 6, this micro-nano concaveconvex structure can increase frictional resistance, improves generating efficiency.Described micro-nano concaveconvex structure can directly form when film preparation, and method that also can enough polishings makes the surface of high molecular polymer film form irregular micro-nano concaveconvex structure.Particularly, Fig. 6 shows semicircular micro-nano concaveconvex structure, and in Fig. 6, the recess of the micro-nano concaveconvex structure of the second side surface 62b of the second high molecular polymer insulation course 62 is relative with the protuberance of the second side surface 60b of the first high molecular polymer insulation course 60, make the contact area between the micro-nano concaveconvex structure maximum, therefore, the micro-nano concaveconvex structure in Fig. 6 is preferred version, can improve generating efficiency.But, what those skilled in the art should understand that is, also can make the protuberance of micro-nano concaveconvex structure of the second side surface 62b of the second high molecular polymer insulation course 62 relative with the protuberance of the second side surface 60b of the first high molecular polymer insulation course 60, perhaps, adjust the position relationship between recess and protuberance, for example, it is not just relative making between recess and protuberance, but certain distance that staggers a little, to regulate generating efficiency.And the shape of micro-nano concaveconvex structure also is not limited to this, can also be made into other shape, for example can be striated, cubic type, rectangular pyramid or cylindrical etc.In addition, this micro-nano concaveconvex structure be generally regular nanoscale to micron-sized concaveconvex structure (because the micro-nano concaveconvex structure is very little, in Fig. 6 in order to make the micro-nano concaveconvex structure to see clearly, therefore, the micro-nano concaveconvex structure is amplified, and namely the micro-nano concaveconvex structure in Fig. 6 is that not to scale (NTS) is drawn.Those skilled in the art can be understood that, in actual conditions, the micro-nano concaveconvex structure on the high molecular polymer insulation course is that nanoscale is to micron-sized very little concaveconvex structure).

Adopt nano friction generator shown in Figure 6, can produce voltage or electric current between the first electrode and the second electrode by the friction between the first high molecular polymer insulation course and the second high molecular polymer insulation course, thereby be the display screen power supply.In addition, can also increase a film between two parties between the first high molecular polymer insulation course of nano friction generator shown in Figure 6 and the second high molecular polymer insulation course.This between two parties film be also a high molecular polymer insulation course, it is between the first high molecular polymer insulation course and the second high molecular polymer insulation course.A side surface of film has the micro-nano concaveconvex structure of rectangular pyramid or other shapes between two parties.Wherein, a side that is not provided with the micro-nano concaveconvex structure of film is fixed on the second side surface of described the second high molecular polymer insulation course between two parties, fixing method can be to use the thin uncured high molecular polymer insulation course of one deck as tack coat, after overcuring, film will be fixed on the second high molecular polymer insulation course firmly between two parties.By the use of film between two parties, can further increase the generating efficiency of nano friction generator.

The second structure of nano friction generator comprises as shown in Figure 7: the first electrode 71, the first high molecular polymer insulation courses 72 that are cascading, and friction electrode 73; Be provided with micro-nano concaveconvex structure (Fig. 7 is not shown, can with reference to implementation corresponding to Fig. 6) at least one face in two faces that the first high molecular polymer insulation course 72 and friction electrode 73 are oppositely arranged; Described the first electrode 71 and friction electrode 73 are triboelectricity machine voltage and current output electrode.

Wherein, the nano friction generator can be nontransparent layer flexible slab construction, and crooked or distortion causes electrification by friction between high molecular polymer insulation course 72 and friction electrode 73 arbitrarily.The surface with micro-nano concaveconvex structure of high molecular polymer insulation course 72 stacks the formation duplexer with the relative contact of friction electrode 73, and interlayer is without any binding.The edge of this triboelectricity machine seals with common adhesive plaster, guarantees that polymer insulation layer contacts with the appropriateness of friction electrode.

In a specific embodiment of the present invention, on the surface of the relative friction electrode 73 of high molecular polymer insulation course 72, the micro-nano concaveconvex structure is not set, the surface of the electrode 73 that only rubs is provided with the micro-nano concaveconvex structure.

In another embodiment of the present invention, high molecular polymer insulation course 72 surface of friction electrode 73 relatively is provided with the micro-nano concaveconvex structure, and on the surface of friction electrode 73, the micro-nano concaveconvex structure is not set.

The key distinction of nano friction generator shown in Figure 7 and nano friction generator shown in Figure 6 is: nano friction generator shown in Figure 6 is to generate electricity by the friction between polymkeric substance and polymkeric substance, and nano friction generator shown in Figure 7 is to generate electricity by the friction between polymkeric substance and metal (being electrode), mainly utilized metal easily to lose the characteristic of electronics, make between friction electrode and the first high molecular polymer insulation course and form induction field, thereby produce voltage or electric current.

Fig. 8 shows another improvement implementation of the nano friction generator in Fig. 7, as shown in Figure 8, the nano friction generator comprises the first electrode 81, the first high molecular polymer insulation course 82, the second high molecular polymer insulation courses 83 and the second electrodes 84 that are cascading; Wherein, be provided with friction electrode 85 between the first high molecular polymer insulation course 82 and the second high molecular polymer insulation course 83; Be provided with micro-nano concaveconvex structure (not shown) at least one face in the face of the first relative friction electrode 85 of high molecular polymer insulation course 82 and the face of relative the first high molecular polymer insulation course 82 of friction electrode 85; Be provided with micro-nano concaveconvex structure (not shown) at least one face in the face of the second relative friction electrode 85 of high molecular polymer insulation course 83 and the face of relative the second high molecular polymer insulation course 83 of friction electrode 85; Described the first electrode 81 and the second electrode 84 series connection are an output electrode of triboelectricity machine voltage and current; Described friction electrode 85 is another output electrode of triboelectricity machine voltage and current.

In a specific embodiment of the present invention, the nano friction generator is nontransparent layer flexible slab construction, crooked or distortion causes between the first high molecular polymer insulation course 82 and friction electrode 85 arbitrarily, electrification by friction between friction electrode 85 and the second high molecular polymer insulation course 83.Preferably, as shown in Figure 9, the friction electrode 85 of the nano friction generator in Fig. 8 can further include the third electrode layer 851 that is cascading, third high Molecularly Imprinted Polymer layer 852 and the 4th electrode layer 853.Be provided with micro-nano concaveconvex structure (not shown) on the surface of third electrode layer 851 and the 4th electrode layer 853.This micro-nano concaveconvex structure is nanoscale to micron-sized concaveconvex structure, and preferred height of projection 300nm-1 μ m(is 350-500nm more preferably) concaveconvex structure.

The first above-mentioned electrode and the second electrode pair material therefor do not have particular provisions, can form the material of conductive layer all within protection scope of the present invention, for example indium tin oxide, Graphene electrodes, nano silver wire film, and metal or alloy, wherein metal is Au Ag Pt Pd, aluminium, nickel, copper, titanium, chromium, selenium, iron, manganese, molybdenum, tungsten or vanadium; Alloy is aluminium alloy, titanium alloy, magnesium alloy, beryllium alloy, aldary, kirsite, manganese alloy, nickel alloy, lead alloy, ashbury metal, cadmium alloy, bismuth alloy, indium alloy, gallium alloy, tungalloy, molybdenum alloy, niobium alloy or tantalum alloy.

the first above-mentioned high molecular polymer insulation course and the material of the second high molecular polymer insulation course can be the same or different, independently be selected from Kapton, the aniline formaldehyde resin film, the polyoxymethylene film, ethyl cellulose film, polyamide film, the melamino-formaldehyde film, polyglycol succinate film, cellophane, cellulose acetate film, the polyethylene glycol adipate film, the polydiallyl phthalate film, fiber (regeneration) sponge film, the elastic polyurethane body thin film, the styrene-acrylonitrile copolymer copolymer film, the styrene-butadiene-copolymer film, the regenerated fiber film, the methacrylic acid ester film, polyvinyl alcohol film, the polyisobutylene film, polyurethane flexible sponge film, pet film, polyvinyl butyral film, formaldehyde phenol film, the neoprene film, the butadiene-propylene copolymer film, the natural rubber film, the polyacrylonitrile film, any one in the vinyl cyanide vinyl chloride film.Preferably, the thickness of the first high molecular polymer insulation course 22 and the second high molecular polymer insulation course 23 is 100 μ m-500 μ m.

The first high molecular polymer insulation course and the second high molecular polymer insulation course arrange the micro-nano concaveconvex structure respectively on their surface, then adopt the conventional methods such as radio frequency sputter, do not arrange at the first high molecular polymer insulation course and the second high molecular polymer insulation course on the face of micro-nano concaveconvex structure the first electrode and the second electrode are set.The micro-nano concaveconvex structure is extremely micron-sized concaveconvex structure of nanoscale, the concaveconvex structure of preferred height of projection 50-300nm.

above-mentioned third high Molecularly Imprinted Polymer layer material used is different with the second high polymer layer from the first high polymer layer, is selected from Kapton, the aniline formaldehyde resin film, the polyoxymethylene film, ethyl cellulose film, polyamide film, the melamino-formaldehyde film, polyglycol succinate film, cellophane, cellulose acetate film, the polyethylene glycol adipate film, the polydiallyl phthalate film, fiber (regeneration) sponge film, the elastic polyurethane body thin film, the styrene-acrylonitrile copolymer copolymer film, the styrene-butadiene-copolymer film, the regenerated fiber film, polymethyl methacrylate film, polyvinyl alcohol film, the polyisobutylene film, pet film, polyvinyl butyral film, formaldehyde phenol condensed polymer film, the neoprene film, the butadiene-propylene copolymer film, the natural rubber film, the polyacrylonitrile film, any one in vinyl cyanide vinyl chloride copolymer film, preferably its thickness is 100 μ m-500 μ m, more preferably 200 μ m.

above-mentioned third electrode layer and the 4th electrode layer do not have particular provisions to material therefor, can form the material of conductive layer all within protection scope of the present invention, for example can select conductive film, conducting polymer, metal material, metal material comprises simple metal and alloy, simple metal is selected from gold, silver, platinum, palladium, aluminium, nickel, copper, titanium, chromium, selenium, iron, manganese, molybdenum, tungsten, vanadium etc., alloy can be selected from light-alloy (aluminium alloy, titanium alloy, magnesium alloy, beryllium alloy etc.), heavy non-ferrous alloy (aldary, kirsite, manganese alloy, nickel alloy etc.), low-melting alloy (lead, tin, cadmium, bismuth, indium, gallium and alloy thereof), refractory alloy (tungalloy, molybdenum alloy, niobium alloy, tantalum alloy etc.).

The surface with micro-nano concaveconvex structure of the first high molecular polymer insulation course shown in Figure 9 stacks with the relative contact of third electrode layer of friction electrode, then the surface with micro-nano concaveconvex structure of the second high molecular polymer insulation course stack the friction electrode the 4th electrode layer on form duplexer, interlayer is without any binding.The edge of this triboelectricity machine seals with common adhesive plaster, guarantees that polymer insulation layer contacts with the appropriateness of friction electrode.The first electrode and the series connection of the second electrode are an output electrode of triboelectricity machine voltage and current; The third electrode layer of friction electrode and the series connection of the 4th electrode layer are another output electrode of triboelectricity machine voltage and current.

In a specific embodiment of the present invention, the first high molecular polymer insulation course rubs on the surface of electrode third electrode layer relatively, on the surface of electrode the 4th electrode layer that rubs relative to the second high molecular polymer insulation course, the micro-nano concaveconvex structure is not set all, only the surface of third electrode layer and the 4th electrode layer is provided with the micro-nano concaveconvex structure.

In another embodiment of the present invention, the first high molecular polymer insulation course rubs on the surface of electrode third electrode layer relatively, the surface that rub electrode four electrode layer relative to the second high molecular polymer insulation course is provided with the micro-nano concaveconvex structure, and on the surface of third electrode layer and the 4th electrode layer, the micro-nano concaveconvex structure is not set.

In a specific embodiment of the present invention, the nano friction generator is transparent layer flexible slab construction, crooked or distortion causes between the first high molecular polymer insulation course and friction electrode arbitrarily, electrification by friction between friction electrode and the second high molecular polymer insulation course.This triboelectricity machine comprises the first electrode that is cascading, the first high molecular polymer insulation course, friction electrode, the second high molecular polymer insulation course and the second electrode.The friction electrode comprises the third electrode layer that is cascading, third high Molecularly Imprinted Polymer layer and the 4th electrode layer.Be provided with micro-nano concaveconvex structure (not shown) at least one face in the face of the face of the first relative third electrode layer of high molecular polymer insulation course the first high molecular polymer insulation course relative to the third electrode layer; Be provided with the micro-nano concaveconvex structure at least one face in the face of the face of the second relative the 4th electrode layer of high molecular polymer insulation course the second high molecular polymer insulation course relative to the 4th electrode layer.Described the first electrode and the series connection of the second electrode are an output electrode of triboelectricity machine voltage and current; The third electrode layer of described friction electrode and the series connection of the 4th electrode layer are another output electrode of triboelectricity machine voltage and current.

The first electrode, the second electrode, third electrode layer and the 4th electrode layer independently are selected from respectively any one in indium tin oxide (ITO), Graphene electrodes and nano silver wire film.The first high molecular polymer insulation course, the second high molecular polymer insulation course, third high Molecularly Imprinted Polymer layer independently are selected from respectively any one in following transparent high polymer: polyethylene terephthalate (PET), dimethyl silicone polymer (PDMS), polystyrene (PS), polymethylmethacrylate (PMMA), polycarbonate (PC) and polymeric liquid crystal copolymer (LCP).After adopting above-mentioned preferred material, at this moment whole triboelectricity machine is a full transparent and soft device.

When power module adopts the nano friction generator of above-mentioned several forms to realize, this false proof device can be realized self-energizing, can produce electric energy as long as be subject to friction, can not occur that battery electric quantity exhausts and situation about can't use greatly facilitates user's use.Due to the characteristic of nano friction generator triboelectricity, this false proof device can not arrange power switch, when needing display screen to show, only needs to get final product by triboelectricity.Perhaps, also can utilize energy-storage travelling wave tube, for example storage capacitor stores the electric energy that the nano friction generator produces, and simultaneously, a power switch is set on false proof device, is used for controlling power module and when powers to display screen.

In addition, the power module in the present embodiment also can be slimline battery.Wherein, slimline battery comprises: flexible package lithium cell, all solid-state thin-film lithium battery and paper battery etc.Use slimline battery false proof device can be made to get small volume and less weight more.When adopting slimline battery to realize, also a power switch can be set on false proof device, be used for controlling power module and when power to display screen.

The embodiment of the present invention also provides a kind of equipment of using above-mentioned false proof device.This equipment comprises first component and second component, wherein, between first component and second component by engagement connection or be threaded.

Wherein, the described display screen in described false proof device and described power module are arranged on described first component, and perhaps, described display screen and described power module in described false proof device are arranged on described second component.

Perhaps, the described display screen in described false proof device is arranged on described first component, and the described power module in described false proof device is arranged on described second component; Perhaps, the described display screen in described false proof device is arranged on described second component, and the described power module in described false proof device is arranged on described first component.And when described first component separated with described second component, the described display screen in described false proof device and the connection between described power module disconnected.

The below describes the equipment of the above-mentioned false proof device of application provided by the invention with several object lessons.

Figure 10 shows a kind of structural representation of this equipment, and as shown in figure 10, this equipment comprises first component 111 and second component 112, and wherein, first component 111 can be for example bottle cap, and second component 112 can be for example body.Bottle cap is fixedly connected with body by engaging mode or screw thread rotation mode.Display screen 11 is arranged on the centre of bottle cap, and power module 12 is arranged on the side of bottle cap and body, and the first half of power module 12 is arranged on the bottle cap side, and the latter half of power module 12 is arranged on the body side.

Figure 11 shows the another kind of structural representation of this equipment, and as shown in figure 11, this equipment comprises first component 111 and second component 112, and wherein, first component 111 can be for example bottle cap, and second component 112 can be for example body.Bottle cap is fixedly connected with body by engaging mode or screw thread rotation mode.Display screen 11 is arranged on the centre of bottle cap, and power module 12 is arranged on the body side.

Figure 12 a and Figure 12 b show another structural representation of this equipment.Figure 12 a shows the outside schematic diagram of this equipment, as shown in Figure 12 a, comprises first component 111 and second component 112, and wherein, first component 111 can be for example bottle cap, and second component 112 can be for example body.Bottle cap is fixedly connected with body by engaging mode or screw thread rotation mode.Display screen 11 is arranged on the centre of bottle cap, and power module 12 is arranged on the bottle cap side.Figure 12 b shows the schematic internal view of this equipment, and as shown in Figure 12 b, this device interior is provided with a raised structures 100, and when bottle cap rotates, this raised structures 100 will raise up and destroy display screen 11, as shown in Figure 12 c.Thus, after bottle cap was opened, display screen 11 was damaged, can't carry out false proof, thereby play once false proof effect.That is to say, when the bottle cap in this equipment was not yet opened, this false proof device can be normally false proof, and after the bottle cap in this equipment was opened, this false proof device was destroyed, thereby can't continue false proofly, avoided thus used equipment to pretend to be the situation of new equipment to occur.Wherein, Figure 12 a and Figure 12 b are only a kind of exemplary implementation, particularly, the equipment in Figure 10 and Figure 11 also can be realized equal purpose, for example, when the bottle cap in Figure 10 and Figure 11 is opened, because bottle cap separates with body, cause the distance between display screen and power module to increase, cause thus the wire fracture that connects between display screen and power module, thereby destroy the function of false proof device, avoid thus used equipment to pretend to be the situation of new equipment.

Figure 13 shows another structural representation of this equipment, and as shown in figure 13, this equipment comprises first component 111 and second component 112, and wherein, first component 111 can be for example bottle cap, and second component 112 can be for example body.Bottle cap is fixedly connected with body by engaging mode or screw thread rotation mode.Display screen 11 is arranged on the centre of bottle cap, and power module 12 is arranged on the bottle cap side.

Several implementations of above-described this equipment are only exemplary, and in fact, the equipment in the present invention can also adopt other structure to realize, as long as false proof device can be arranged on this equipment.In addition, the false proof device in the present invention can also be applied to other product, for example, and handbag, wine bottle cover and smart card etc.

Although it will be understood by those skilled in the art that in above-mentioned explanation, for ease of understanding, the step of method has been adopted the succession description, should be pointed out that for the order of above-mentioned steps and do not do strict restriction.

One of ordinary skill in the art will appreciate that all or part of step that realizes in above-described embodiment method is to come the relevant hardware of instruction to complete by program, this program can be stored in a computer read/write memory medium, as: ROM/RAM, magnetic disc, CD etc.

Will also be appreciated that the apparatus structure shown in accompanying drawing or embodiment is only schematically, the presentation logic structure.The module that wherein shows as separating component may or may not be physically to separate, and the parts that show as module may be or may not be physical modules.

Obviously, those skilled in the art can carry out various changes and modification and not break away from spirit and scope of the present utility model the utility model.Like this, if within of the present utility model these are revised and modification belongs to the scope of the utility model claim and equivalent technologies thereof, the utility model also is intended to comprise these changes and modification interior.

Claims (15)

1. a false proof device, is characterized in that, comprising: show the display screen of anti-counterfeiting mark, and the power module that is connected with described display screen, wherein, described display screen is flexible display screen, and described power module is the flexible electrical source module.

2. false proof device as claimed in claim 1, is characterized in that, described display screen is the LCD screen, and perhaps, described display screen is electronic-paper display screen.

3. false proof device as claimed in claim 1, it is characterized in that, described display screen be shaped as a kind of in following shape: circle, rectangle, annular and rhombus, described power module be shaped as a kind of in following shape: circle, rectangle, annular and rhombus; And the shape of described display screen and the shape of described power module are identical or different.

4. false proof device as claimed in claim 3, is characterized in that, described display screen contacts and is electrically connected to described power module, and perhaps, described display screen does not contact and is connected by wire with described power module.

5. false proof device as claimed in claim 1, is characterized in that, described power module is the nano friction generator; Perhaps, described power module is slimline battery, and described slimline battery comprises: flexible package lithium cell, all solid-state thin-film lithium battery and paper battery.

6. false proof device as claimed in claim 5, is characterized in that, when described power module was the nano friction generator, described nano friction generator comprised:

The first high molecular polymer insulation course;

The first electrode is positioned on the first side surface of described the first high molecular polymer insulation course;

The second high molecular polymer insulation course;

The second electrode is positioned on the first side surface of described the second high molecular polymer insulation course;

Wherein, described the first electrode and the second electrode are the output electrodes of described nano friction generator;

The second side surface of described the first high molecular polymer insulation course contacts with the second side surface of the second high molecular polymer insulation course, and the second side surface of the second side surface of described the first high molecular polymer insulation course and the second high molecular polymer insulation course is respectively arranged with the micro-nano concaveconvex structure.

7. false proof device as claimed in claim 5, is characterized in that, when described power module was the nano friction generator, described nano friction generator comprised: the first electrode that is cascading, the first high molecular polymer insulation course, and friction electrode; Wherein, be provided with the micro-nano concaveconvex structure at least one face in the first high molecular polymer insulation course and two faces being oppositely arranged of friction electrode; Described the first electrode and friction electrode are the output electrode of nano friction generator.

8. false proof device as claimed in claim 7, is characterized in that, described nano friction generator further comprises: the second high molecular polymer insulation course and the second electrode,

Wherein, described the first electrode, the first high molecular polymer insulation course, the second high molecular polymer insulation course and the second electrode are cascading; Described friction electrode is arranged between described the first high molecular polymer insulation course and the second high molecular polymer insulation course; Be provided with the micro-nano concaveconvex structure at least one face in the first high molecular polymer insulation course and two opposite faces of friction electrode; Be provided with the micro-nano concaveconvex structure at least one face in the second high molecular polymer insulation course and two opposite faces of friction electrode; Described the first electrode and the series connection of the second electrode are an output electrode of nano friction generator; Another output electrode that described friction electrode is the nano friction generator.

9. false proof device as claimed in claim 8, is characterized in that, described friction electrode comprises the third electrode layer that is cascading, third high Molecularly Imprinted Polymer layer and the 4th electrode layer;

Be provided with the micro-nano concaveconvex structure at least one face in two opposite face of the first high molecular polymer insulation course and third electrode layer;

Be provided with the micro-nano concaveconvex structure at least one face in the second high molecular polymer insulation course and two opposite faces of the 4th electrode layer;

Described the first electrode and the series connection of the second electrode are an output electrode of nano friction generator; The third electrode layer of described friction electrode and the series connection of the 4th electrode layer are another output electrode of nano friction generator.

10. described false proof device as arbitrary in claim 6-9, is characterized in that,

Described electrode material therefor is indium tin oxide, Graphene, nano silver wire film, metal or alloy, and wherein metal is Au Ag Pt Pd, aluminium, nickel, copper, titanium, chromium, selenium, iron, manganese, molybdenum, tungsten or vanadium; Alloy is aluminium alloy, titanium alloy, magnesium alloy, beryllium alloy, aldary, kirsite, manganese alloy, nickel alloy, lead alloy, ashbury metal, cadmium alloy, bismuth alloy, indium alloy, gallium alloy, tungalloy, molybdenum alloy, niobium alloy or tantalum alloy; Described friction electrode material therefor is metal or alloy, and wherein metal is Au Ag Pt Pd, aluminium, nickel, copper, titanium, chromium, selenium, iron, manganese, molybdenum, tungsten or vanadium; Alloy is aluminium alloy, titanium alloy, magnesium alloy, beryllium alloy, aldary, kirsite, manganese alloy, nickel alloy, lead alloy, ashbury metal, cadmium alloy, bismuth alloy, indium alloy, gallium alloy, tungalloy, molybdenum alloy, niobium alloy or tantalum alloy;

described high molecular polymer insulation course material therefor is selected from Kapton, the aniline formaldehyde resin film, the polyoxymethylene film, ethyl cellulose film, polyamide film, the melamino-formaldehyde film, polyglycol succinate film, cellophane, cellulose acetate film, the polyethylene glycol adipate film, the polydiallyl phthalate film, regeneration sponge film, the elastic polyurethane body thin film, the styrene-acrylonitrile copolymer copolymer film, the styrene-butadiene-copolymer film, the regenerated fiber film, polymethyl methacrylate film, polyvinyl alcohol film, the polyisobutylene film, pet film, polyvinyl butyral film, formaldehyde phenol condensed polymer film, the neoprene film, the butadiene-propylene copolymer film, the natural rubber film, the polyacrylonitrile film, any one in vinyl cyanide vinyl chloride copolymer film.

11. an equipment is characterized in that, comprises arbitrary described false proof device in the claims 1-10.

12. equipment as claimed in claim 11 is characterized in that, described equipment comprises first component and second component, engagement connection or be threaded between described first component and second component.

13. equipment as claimed in claim 12, it is characterized in that, described display screen in described false proof device and described power module are arranged on described first component, and perhaps, described display screen and described power module in described false proof device are arranged on described second component.

14. equipment as claimed in claim 12 is characterized in that, the described display screen in described false proof device is arranged on described first component, and the described power module in described false proof device is arranged on described second component; Perhaps, the described display screen in described false proof device is arranged on described second component, and the described power module in described false proof device is arranged on described first component.

15. equipment as claimed in claim 14 is characterized in that, when described first component separated with described second component, the described display screen in described false proof device and the connection between described power module disconnected.

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