Utility model content
In order to overcome problem above, the utility model aims to provide a kind of battery thin film and its system, existing so as to improve
Battery thin film transparency and power storage amount.
In order to achieve the above object, the utility model provides a kind of battery thin film, has at least one battery unit, often
Individual battery unit includes:First transparent graphene layer, transparent graphene lower electrode layer, it is grown on transparent graphene lower electrode layer
Nano-wire array, the transparent graphene upper electrode layer at the top of nano-wire array, and positioned at transparent graphene Top electrode
The second transparent graphene layer on layer.
Preferably, the battery thin film layer includes the stacked structure of multiple battery units;Adjacent battery unit it
Between connect;Wherein, the battery unit of stacking is followed successively by the first battery unit to N battery units, adjacent K electricity from top to bottom
In pool unit and K+1 battery units, the transparent graphene Top electrode of K+1 battery units connects the transparent of K battery units
Graphene bottom electrode, the transparent graphene bottom electrode of K+1 battery units connect electricity in the transparent graphene of K+2 battery units
Pole;Wherein, to be positive integer and >=2, K=1 circulate to the integer between N-2, K N from 1 between N-2;Most pushed up positioned at stacked structure
The transparent graphene of the transparent graphene upper electrode layer of the battery unit in portion and the N battery units positioned at stacked structure bottommost
Lower electrode layer connects the both positive and negative polarity of external power source respectively.
Preferably, the battery thin film layer includes the battery unit of multiple stackings;Between adjacent battery unit simultaneously
Connection;Wherein, the battery unit of stacking is followed successively by the first battery unit to N battery units from top to bottom, the first battery unit
Transparent graphene Top electrode connects the both positive and negative polarity of external power source with transparent graphene bottom electrode;Adjacent K battery units and K
In+1 battery unit, electricity under the transparent graphene of the transparent graphene Top electrode connection K battery units of K+1 battery units
Pole, the transparent graphene Top electrode of the transparent graphene bottom electrode connection K battery units of K+1 battery units;Wherein, N is
Positive integer and >=2, K=1 are circulated from 1 between N-1 to the integer between N-1, K.
Preferably, between adjacent battery unit using transparent graphene band be used as connecting wire, transparent graphene band and
Adjacent battery unit is integrally formed;Transparent graphene between each battery unit and battery unit adjacent above it
Band, and each transparent graphene band between battery unit and battery unit adjacent below are located at the battery unit respectively
Not homonymy.
Preferably, a MOS is connected between the transparent graphene Top electrode of the first battery unit or bottom electrode and external power source
Pipe, the grid end of first metal-oxide-semiconductor connects voltage source, and the first battery unit and outer is controlled by controlling the voltage of grid end positive and negative
On or off between portion's power supply;
It is connected between adjacent two battery units up and down by a metal-oxide-semiconductor, adjacent Lian Ge electricity up and down is controlled by metal-oxide-semiconductor
On or off between pool unit;
When external power source transmits electric energy to the first battery unit, turn on, lead between external power source and the first battery unit
Crossing the 1st metal-oxide-semiconductor turns off the first battery unit and the second battery unit;
When the amount of storage of the first battery unit reaches preset value, turned off between the first battery unit and external power source;It is logical
Crossing the 1st metal-oxide-semiconductor makes the first battery unit be turned on the second battery unit, and the first battery unit charges to the second battery unit;
……;
When the electric amount of storage of J+1 battery units reaches preset value, by j-th metal-oxide-semiconductor make J+1 battery units with
Turned off between J battery units;J+1 battery units are made to be turned on J+2 battery units by the J+1 metal-oxide-semiconductor, J+1
Battery unit charges to J+2 battery units;At the same time, started with J+1 battery units, be spaced a battery unit upwards
Afterwards, charge, that is to say to corresponding battery unit, charged to the battery unit with J+2 battery units with identical odevity,
And it can be made by opening the metal-oxide-semiconductor between corresponding battery unit and battery unit or external power source adjacent above it
Adjacent battery unit or external power source charge to corresponding battery unit above corresponding battery unit;Wherein, N is positive integer
And >=2, J=1,2 ... ..., N-2.
Preferably, each battery unit is respectively provided with the positive and negative electrode outwardly to charge, when battery thin film outwardly discharges,
The positive and negative electrode that electric amount of storage is reached to the battery unit of preset value turns on extraneous, is outwardly charged to perform;It is more when occurring
When the electric amount of storage of individual battery unit all reaches preset value, the battery unit of preset value will be reached positioned at the electric amount of storage of bottom
Positive and negative electrode turned on extraneous, outwardly charged to perform.
Preferably, another layer of transparent graphene oxide layer is additionally provided with below the first transparent graphene oxide layer, and
Antenna film on another layer of transparent graphene oxide layer, for receiving and dispatching each frequency band signals.
Preferably, the antenna film is ultra micro antenna film, including a transparent dielectric layer, and transparent dielectric layer has at least
One groove, channel bottom set graphene antenna pattern, graphene antenna pattern, the first transparent oxygen are higher by the top of trenched side-wall
On graphite alkene layer is supported at the top of trenched side-wall.
Preferably, the material of transparent dielectric layer is organic transparent material.
In order to achieve the above object, the utility model additionally provides a kind of battery system, and it includes:External power source, control
Device, precharge circuit selector part and battery thin film;Wherein,
Battery thin film has at least one battery unit, and each battery unit includes:First transparent graphene layer, transparent stone
Black alkene lower electrode layer, the nano-wire array being grown on transparent graphene lower electrode layer are transparent at the top of nano-wire array
Graphene upper electrode layer, and the second transparent graphene layer on transparent graphene upper electrode layer;
The battery thin film layer includes the battery unit of multiple stackings;It is in parallel between adjacent battery unit;Wherein,
The battery unit of stacking is followed successively by the first battery unit to N battery units, the transparent graphite of the first battery unit from top to bottom
Alkene Top electrode connects the both positive and negative polarity of external power source with transparent graphene bottom electrode;Adjacent K battery units and K+1 battery lists
In member, the transparent graphene bottom electrode of the transparent graphene Top electrode connection K battery units of K+1 battery units, K+1 electricity
The transparent graphene Top electrode of the transparent graphene bottom electrode connection K battery units of pool unit;Wherein, N be positive integer and >=
2, K=1 circulate from 1 between N-1 to the integer between N-1, K;
Connect a metal-oxide-semiconductor between the transparent graphene Top electrode or bottom electrode and external power source of first battery unit, first
A metal-oxide-semiconductor, the grid end of first metal-oxide-semiconductor are connected between the transparent graphene Top electrode or bottom electrode and external power source of battery unit
Voltage source is connect, by controlling the positive and negative on or off to control between the first battery unit and external power source of the voltage of grid end;
It is connected between adjacent two battery units up and down by a metal-oxide-semiconductor, adjacent Lian Ge electricity up and down is controlled by metal-oxide-semiconductor
On or off between pool unit;
When external power source transmits electric energy to the first battery unit, control device is controlled described using first metal-oxide-semiconductor
Turned between external power source and the first battery unit, and control the first battery unit and the second battery unit to turn off;
When the amount of storage of the first battery unit reaches preset value, control device control controls the using the 1st metal-oxide-semiconductor
Turned off between one battery unit and external power source, and controller by control the 2nd metal-oxide-semiconductor come control the first battery unit with
Second battery unit turns on, and the first battery unit charges to the second battery unit;
When the electric amount of storage of J+1 battery units reaches preset value, control device by control the J+1 metal-oxide-semiconductor come
Control and turned off between the J+1 battery units and J battery units, and by controlling the J+2 metal-oxide-semiconductor to control J+
1 battery unit turns on J+2 battery units, and J+1 battery units charge to J+2 battery units;At the same time, with J+
1 battery unit starts, upwards be spaced a battery unit after, to corresponding battery unit charge, that is to say, to J+2 electricity
The battery unit that pool unit has identical odevity charges, and can be adjacent with its top by opening corresponding battery unit
Battery unit or external power source between metal-oxide-semiconductor make battery unit or external power source adjacent above corresponding battery unit
Charged to corresponding battery unit;Wherein, N is positive integer and >=2, J=1,2 ... ..., N-2.
Preferably, each battery unit is respectively provided with the positive and negative electrode outwardly to charge;When battery thin film outwardly discharges,
The precharge circuit selector part selects electric amount of storage to reach the battery unit of preset value, and then, control device controls selected electricity
The positive and negative electrode that amount of storage reaches the battery unit of preset value turns on extraneous, is outwardly charged to perform;When the charging choosing
When selecting device and judging that the electric amount of storage of multiple battery units all reaches preset value, the charging selecting unit selection is positioned at most lower
The battery unit for reaching preset value of side, then the selected battery unit positioned at bottom of control device control is being just
Negative electrode turns on extraneous, is outwardly charged to perform.
Preferably, between adjacent battery unit using transparent graphene band be used as connecting wire, transparent graphene band and
Adjacent battery unit is integrally formed;Transparent graphene between each battery unit and battery unit adjacent above it
Band, and each transparent graphene band between battery unit and battery unit adjacent below are located at the battery unit respectively
Not homonymy.
In order to achieve the above object, the utility model additionally provides a kind of preparation method of above-mentioned battery thin film, described
Battery thin film layer includes the stacked structure of multiple battery units;It comprises the following steps:
Step 01:Battery thin film layer area is designed on a transparent graphene oxide layer;Wherein, in battery thin film layer area
Design multiple side by side in the battery cell region of a row, and be used between adjacent battery cell region by adjacent electricity
Transparent conductors region between the battery unit that pool unit is mutually electrically connected, the photoelectric conversion layer region is with the battery cell region same
One arranges and positioned at the either end of the row;
Step 02:Battery thin film layer is prepared on transparent graphene oxide layer in battery thin film layer area;
Step 03:Another transparent graphene oxide layer is covered in the whole substrate for completing step 02;
Step 04:Corresponding folding line is designed in transparent conductors region between battery unit, by battery thin film layer area
Adjacent battery cell region forms the battery thin film layer that the battery unit of stacking is formed along corresponding folding line doubling.
Preferably, in the step 04, first, wherein in a transparent graphene oxide layer surface, to adjacent cell
Unit area applies the charges of different polarity respectively;Then, by the transparent graphene oxide layer surface of the applied charges of different polarity along folding line
Doubling, there is a natural attraction between the sexes, the transparent graphene oxide surface for applying the charges of different polarity in adjacent cell region is mutually adsorbed;
Or
First, adjacent cell region one of battery cell region a transparent graphene oxide layer surface
Upper application electrostatic;Then, the transparent graphene oxide surface of applied electrostatic is made into phase along folding line doubling using Electrostatic Absorption
Mutually adsorb on the transparent graphene oxide surface for applying the charges of different polarity of adjacent battery cell region.
Preferably, the step 02 includes:
Step A:Layer of transparent graphene film is deposited on the transparent graphene oxide layer of step 01;
Step B:Nano-wire array is prepared on the transparent graphene film of battery thin film layer area;
Step C:Another layer of transparent graphene film is formed in the substrate for completing step B, also, patterns battery thin film
Another layer of transparent graphene film, nano-wire array and the layer of transparent graphene film in layer region, are formed side by side
In the nano-wire array pattern of multiple battery unit figures of a row, transparent graphene Top electrode, transparent graphene bottom electrode with
And the transparent graphene film band between adjacent battery unit;
It is in parallel between adjacent battery unit in the battery thin film formed after completing step 04;The battery list of stacking
Member is followed successively by the first battery unit to N battery units from top to bottom, the transparent graphene Top electrode of the first battery unit and thoroughly
The both positive and negative polarity of bright graphene bottom electrode connection external power source;In adjacent K battery units and K+1 battery units, K+1 electricity
Pool unit transparent graphene Top electrode connection K battery units transparent graphene bottom electrode, K+1 battery units it is transparent
Graphene bottom electrode connects the transparent graphene Top electrode of K battery units;Wherein, N be positive integer and >=2, K=1 to N-1 it
Between integer, K circulates from 1 between N-1.
Preferably, in the step 01, in addition to:One substrate is provided, applies electrostatic on the substrate, by a transparent oxygen
Graphite alkene layer adsorbs on the substrate.
Preferably, the step 02 includes:
Step A:Layer of transparent graphene film is deposited on the transparent graphene oxide layer of step 01;
Step B:Patterned transparent graphene film, the portion corresponding to battery unit is etched in transparent graphene film
Divide transparent graphene film bottom electrode and partially transparent graphene film Top electrode, and the transparent stone between adjacent cell
Black alkene band, and get rid of the transparent graphene film that need not be connected between adjacent cell;Wherein, transparent graphene band exists
It is arranged at intervals between adjacent battery unit;
Step C:Nano-wire array is prepared on the transparent graphene film of battery thin film layer area;
Step D:Nano-wire array is patterned, the nano-wire array pattern formed in battery unit;
Step E:Another layer of transparent graphene film is formed on nano-wire array pattern;
Step F:Another layer of transparent graphene film is patterned, battery list is etched in another layer of transparent graphene film
Partially transparent graphene film bottom electrode and partially transparent graphene film Top electrode corresponding to member, and adjacent cell
Between transparent graphene band, and get rid of the transparent graphene film that need not be connected between adjacent cell;Wherein, separately
Transparent graphene band in layer of transparent graphene film is arranged at intervals between adjacent battery unit, and with step B
The alternate setting of transparent graphene band;
After completing step 04, connected between adjacent battery unit;Wherein, the battery unit of stacking is from top to bottom successively
For the first battery unit to N battery units, in adjacent K battery units and K+1 battery units, K+1 battery units
Transparent graphene Top electrode connection K battery units transparent graphene bottom electrode, the transparent graphene of K+1 battery units
Bottom electrode connects the transparent graphene Top electrode of K+2 battery units;Wherein, N is positive integer and >=2, K=1 is between N-2
Integer, K circulate from 1 between N-2;Positioned at the battery unit of stacked structure top transparent graphene upper electrode layer and be located at
The transparent graphene lower electrode layer of the N battery units of stacked structure bottommost connects the both positive and negative polarity of external power source respectively.
Battery thin film of the present utility model and system, it is possible to increase the power storage amount of battery, charge-discharge velocity, and energy
Buffering and current stabilization effect are enough played, is advantageous to lighting, portability and the miniaturization of device.
Embodiment
To make content of the present utility model more clear understandable, below in conjunction with Figure of description, to of the present utility model interior
Appearance is described further.Certain the utility model is not limited to the specific embodiment, known to those skilled in the art
General replacement be also covered by the scope of protection of the utility model.
Battery thin film of the present utility model, has at least one battery unit, and each battery unit includes:First transparent stone
Black alkene layer, transparent graphene lower electrode layer, the nano-wire array being grown on transparent graphene lower electrode layer, positioned at nanometer linear array
Arrange the transparent graphene upper electrode layer at top, and the second transparent graphene layer on transparent graphene upper electrode layer.
The utility model is described in further detail below in conjunction with accompanying drawing 1~19 and specific embodiment.It should be noted that
Accompanying drawing using very simplified form, using non-accurately ratio, and only to it is convenient, clearly reach and aid in illustrating this reality
Apply the purpose of example.
Refer to Fig. 1 and Fig. 2, in the present embodiment, battery thin film includes:First transparent graphene oxide layer 01;Positioned at
Battery thin film layer on one transparent graphene oxide layer 01, for storing electric energy, and outwardly discharges electric energy;Positioned at battery thin film
The second transparent graphene oxide layer 03 on layer.Specifically, battery thin film layer has at least one battery using three-decker
Unit, each battery unit include:Transparent graphene lower electrode layer T1, the nanometer being grown on transparent graphene lower electrode layer T1
Linear array 02, and the transparent graphene upper electrode layer T2 positioned at the top of nano-wire array 02.
In the present embodiment, as shown in figure 1, battery thin film layer can include the above-mentioned battery unit of multiple stackings.In addition, phase
Serial or parallel connection mode can be used between adjacent battery unit.
Here illustrated by taking parallel way as an example, then parallel way can repeat no more here so that the rest may be inferred.It please join
Refering to Fig. 1 and 3, the battery unit of stacking is followed successively by the first battery unit to N battery units, the first battery unit from top to bottom
Transparent graphene Top electrode connect external power source with transparent graphene bottom electrode;Adjacent K battery units and K+1 batteries
In unit, the transparent graphene bottom electrode of the transparent graphene Top electrode connection K battery units of K+1 battery units, K+1
The transparent graphene Top electrode of the transparent graphene bottom electrode connection K battery units of battery unit;Wherein, N be positive integer and
>=2, K=1 are circulated from 1 between N-2 to the integer between N-2, K.By taking two adjacent battery units as an example, for example, please again
Secondary to refer to Fig. 3, the transparent graphene bottom electrode of the first battery unit is mutually electric with the transparent graphene Top electrode of the second battery unit
Even, the transparent graphene Top electrode of the first battery unit is mutually electrically connected with the transparent graphene bottom electrode of the second battery unit, and second
The transparent graphene Top electrode of the transparent graphene bottom electrode and the 3rd battery unit of battery unit is mutually electrically connected, the second battery unit
Transparent graphene Top electrode and the transparent graphene bottom electrode of the 3rd battery unit be mutually electrically connected, the transparent stone of the 3rd battery unit
The transparent graphene Top electrode of black alkene bottom electrode and the 4th battery unit is mutually electrically connected, electric in the transparent graphene of the 3rd battery unit
Pole and the transparent graphene bottom electrode of the 4th battery unit are mutually electrically connected ... ..., the like.
Here, as shown in figure 3, in adjacent K battery units and K+1 battery units, K+1 battery units it is transparent
(K+1) is used between graphene Top electrode and the transparent graphene bottom electrode of K battery units1Transparent graphene band is as company
Wire is connect, the transparent graphene bottom electrode of K+1 battery units and the transparent graphene Top electrode of K battery units use (K
+1)2Transparent graphene band is as connecting wire, also, (K+1)1Transparent graphene film band is saturating with K+1 battery units
Bright graphene Top electrode, the transparent graphene bottom electrode of K battery units are formed as one;And/or (K+1)2Transparent graphite
Alkene film band is integrated with the transparent graphene bottom electrode of K+1 battery units, the transparent graphene Top electrode of K battery units
Formed.For example, the transparent graphene Top electrode of the second battery unit and the transparent graphene bottom electrode of the first battery unit
Between use the 2nd2Transparent transparent graphene band is as connecting wire, the transparent graphene bottom electrode of the second battery unit and first
The transparent graphene Top electrode of battery unit uses the 2nd1Transparent transparent graphene band is as connecting wire;Moreover, the 3rd battery
The 3rd is used between the transparent graphene Top electrode of unit and the transparent graphene bottom electrode of the second battery unit2Transparent stone
Black alkene band is as connecting wire, on the transparent graphene bottom electrode of the 3rd battery unit and the transparent graphene of the second battery unit
Electrode uses the 3rd1Transparent transparent graphene band is as connecting wire;..., the rest may be inferred.On between adjacent cell
The connection of graphene ribbon, Fig. 5 can be referred to, by taking two neighboring battery unit as an example, connects the graphene of adjacent battery unit
The transparent graphene bottom electrode T1 of one end connection top battery unit with D1, the other end connect the transparent stone of underlying battery unit
The transparent graphene Top electrode T2 of black alkene bottom electrode T1', graphene ribbon D2 one end connection top battery unit, other end connection
The transparent graphene bottom electrode T2' of underlying battery unit.
In other embodiments of the present utility model, series system can be used between adjacent battery unit, it is adjacent
Connected between battery unit;Wherein, the battery unit of stacking is followed successively by the first battery unit to N battery units from top to bottom,
In adjacent K battery units and K+1 battery units, the transparent graphene Top electrode connection K batteries of K+1 battery units
The transparent graphene bottom electrode of unit, the transparent graphene bottom electrode of K+1 battery units connect the transparent of K+2 battery units
Graphene Top electrode;Wherein, to be positive integer and >=2, K=1 circulate to the integer between N-2, K N from 1 between N-2;Positioned at heap
The transparent graphene upper electrode layer of the battery unit of stack structure top and the N battery units positioned at stacked structure bottommost
Transparent graphene lower electrode layer connects the both positive and negative polarity of external power source respectively, as shown in figure 4, by taking three battery units as an example, connection
The transparent graphene bottom electrode T1 of the graphene ribbon D1 of adjacent battery unit one end connection top battery unit, the other end connect
Connect the transparent stone of transparent graphene the Top electrode T2', graphene ribbon D2 of underlying battery unit one end connection top battery unit
Black alkene bottom electrode T1', the other end connect the transparent graphene Top electrode T2' of underlying battery unit.
It should be noted that for the ease of clearly expressing, the view in Fig. 4 and Fig. 5 for Fig. 1 C directions is only shown
Graphene ribbon D1 and D2 are gone out.
Here, transparent graphene band is used between adjacent battery unit as connecting wire, transparent graphene band and phase
Adjacent battery unit is integrally formed, that is to say all transparent graphene bands and all battery units can integrally into
Type, it is of course also possible to be adjacent two battery units and its between transparent graphene band can be integrally formed.So, by
Connecting wire and battery unit between battery unit are integrally formed, and can improve the charge-discharge velocity and electricity of battery unit
Energy amount of storage, avoids current loss caused by the boundary defect of each junction, further, since the stacking knot of above-mentioned battery unit
Structure designs, and realizes the massive store of slimline battery, also, in the present embodiment, when the first transparent graphene oxide layer, second
Transparent graphene oxide layer uses single-layer graphene oxide layer, transparent graphene Top electrode, the transparent graphene of battery unit
When bottom electrode uses monoatomic-layer graphene film, the thickness of the battery thin film formed is in 1~1000nm, contained electricity
Pool unit can be up to millions of layers to ten million layer, and therefore, the power storage amount that can be generated is significantly larger than traditional graphene
Lithium battery, it is advantageously implemented in the case of improving graphene battery energy storage capacity and charging and discharging capabilities so that battery surpasses
Thinning and portability, and the ultrathin of device and lighting.
It is transparent between each battery unit and battery unit adjacent above it referring to Fig. 3 in the present embodiment
Graphene ribbon, and each transparent graphene band between battery unit and battery unit adjacent below are located at the electricity respectively
The not homonymy of pool unit.Specifically, as shown in figure 3, connect the (K+ of adjacent K battery units and K+1 battery units
1)1Transparent graphene film band, with (K+1)2Transparent graphene film band is respectively positioned on adjacent K battery units and K+1 electricity
The phase homonymy of pool unit;The K that K battery units are connected1Transparent graphene film band and K2Transparent graphene film band position
In the phase homonymy of K battery units, moreover, (K+1)1Transparent graphene film band and (K+1)2Transparent graphene film band,
With K1Transparent graphene film band and K2Transparent graphene film band is located at the not homonymy of K battery units.Each battery list
The transparent graphene Top electrode of member connects the top adjacent cell of the battery unit with the side of transparent graphene bottom electrode
Respective electrode phase the same side, its opposite side connects the identical of the respective electrode of the lower section adjacent cell of the battery unit
Opposite side.
In the present embodiment, in order to realize battery thin film discharge and recharge simultaneously, also, in order to realize battery thin film discharge and recharge simultaneously
When each battery unit optimization collocation improve the efficiency of battery thin film, in the present embodiment, the first battery unit it is transparent
A metal-oxide-semiconductor is connected between graphene Top electrode or bottom electrode and external power source, the grid end of first metal-oxide-semiconductor connects voltage source, passed through
Control the positive and negative on or off to control between the first battery unit and external power source of voltage of grid end;Specifically, on adjacent
It is connected between lower two battery units by a metal-oxide-semiconductor, is controlled by metal-oxide-semiconductor and adjacent connect leading between battery unit up and down
Logical or shut-off.
First metal-oxide-semiconductor is connected between the transparent graphene Top electrode or bottom electrode and external power source of first battery unit,
The grid end of first metal-oxide-semiconductor connects voltage source, and the first battery unit and external power source are controlled by controlling the voltage of grid end positive and negative
Between on or off.For also using corresponding metal-oxide-semiconductor from the first battery unit to the break-make between N battery units,
Specifically include:The transparent graphene Top electrode of K+1 battery units connects the source or drain terminal, K batteries of the K+1 metal-oxide-semiconductor
The drain terminal or source of the K+1 metal-oxide-semiconductor are connected between the transparent graphene bottom electrode of unit;Or K+1 battery units
Transparent graphene bottom electrode connect the K+1 metal-oxide-semiconductor source or drain terminal, the transparent graphene Top electrode of K battery units
Connect the drain terminal or source of the K+1 metal-oxide-semiconductor;The grid end of the K+1 metal-oxide-semiconductor connects voltage source, by described in control
The positive and negative conducting to control between the K battery units and K+1 battery units of voltage of the grid end of K+1 metal-oxide-semiconductor
Or shut-off.
In the present embodiment, metal-oxide-semiconductor can be that NMOS can also be PMOS, not be limited here.It the following specifically describes this reality
The matching relationship of each battery unit and metal-oxide-semiconductor during the fast charging and discharging of the battery thin film of example is applied, is specifically included:Work as outside
When power supply is to the first battery unit transmission electric energy, turns between external power source and the first battery unit, made by the 1st metal-oxide-semiconductor
First battery unit and the second battery unit turn off;
When the amount of storage of the first battery unit reaches preset value, turned off between the first battery unit and external power source;It is logical
Crossing the 1st metal-oxide-semiconductor makes the first battery unit be turned on the second battery unit, and the first battery unit charges to the second battery unit;
When the amount of storage of the second battery unit reaches preset value, the second battery unit and first are made by the 1st metal-oxide-semiconductor
Turned off between battery unit, then the second battery unit is turned on the 3rd battery unit by the 2nd metal-oxide-semiconductor, the second battery list
Member charges to the 3rd battery unit;At the same time, make to turn between external power source and the first battery unit by a metal-oxide-semiconductor, outside
Portion's power supply transmits electric energy to the first battery unit;
……;
When the electric amount of storage of J+1 battery units reaches preset value, by j-th metal-oxide-semiconductor make J+1 battery units with
Turned off between J battery units;J+1 battery units are made to be turned on J+2 battery units by the J+1 metal-oxide-semiconductor, J+1
Battery unit charges to J+2 battery units;At the same time, started with J+1 battery units, be spaced a battery unit upwards
Afterwards, charge, that is to say to corresponding battery unit, charged to the battery unit with J+2 battery units with identical odevity,
And it can be made by opening the metal-oxide-semiconductor between corresponding battery unit and battery unit or external power source adjacent above it
Adjacent battery unit or external power source charge to corresponding battery unit above corresponding battery unit;Wherein, J=1,
2 ... ..., N-2.
As procedure described above, any battery unit can be charged, and it is possible to be first filled with the battery of bottommost
Unit, then it is full of other battery units from the bottom up successively.So, the charging for battery unit realizes a continuous circulation
Process;Of course, it is also possible to carry out discharge process in charging process, put because discharge process can carry out selection to battery unit
Electricity, therefore, in discharge process it is also possible to charging process always be present, in order to avoid not rushed mutually between the battery unit of discharge and recharge
It is prominent, in the present embodiment, design each battery unit and be respectively provided with the positive and negative electrode outwardly to charge, when battery thin film outwardly discharges
When, the positive and negative electrode that electric amount of storage is reached to the battery unit of preset value turns on extraneous, is outwardly charged to perform;Work as appearance
When the electric amount of storage of multiple battery units all reaches preset value, by positioned at the positive and negative of the battery unit for reaching preset value of bottom
Electrode turns on extraneous, is outwardly charged to perform, while by controlling metal-oxide-semiconductor to control the battery unit adjacent with its top
Battery unit turns on, and when the battery unit outwards discharges, while the adjacent battery unit in top also enters to the battery unit
Row charging, the like, which battery unit no matter is selected, the adjacent battery unit in its top can all pass through corresponding metal-oxide-semiconductor
Turned on selected battery unit, it is thereby achieved that the circulation of the recharge-discharge in discharge process is continuous, avoid battery thin
Film can not meet the electrical energy demands of excess suddenly.Further, since the battery unit and composition multilayer circulation of selection bottom,
Similar spiral, can allow external power source to be less than discharge rate to the charge rate of the first battery, that is to say, obtain larger put
Electric speed, shorten the charging interval to the external world.Certainly, when charge rate is identical with discharge rate, and at least one battery list
When member stores electric energy and is not up to preset value, the stacked structure of the battery unit of the present embodiment so that electric current is from a battery list
Member moves to another battery unit, so as to play the buffering to electric current, current stabilization effect.In the present embodiment, figure is referred to
6, the battery system of the present embodiment, including:External power source, control device, the above-mentioned tool of precharge circuit selector part and the present embodiment
There is the battery thin film of the stacked structure of multiple battery units in parallel.
Specifically, external power source is used to provide electric energy to battery thin film layer.
Control device is used for the shut-off or conducting for controlling each metal-oxide-semiconductor (shown in Fig. 6 intermediate cam shapes);Specifically, incorporated by reference to
Fig. 6 and Fig. 3, the 1st metal-oxide-semiconductor of connection between the transparent graphene Top electrode or bottom electrode and external power source of the first battery unit
Source or drain terminal;The grid end of 1st metal-oxide-semiconductor connects voltage source, and control device is controlled described by controlling the voltage of grid end positive and negative
On or off between external power source and the first battery unit;
Incorporated by reference to Fig. 6 and Fig. 3, the transparent graphene Top electrode of K+1 battery units connects the source of the K+1 metal-oxide-semiconductor
Or the transparent graphene bottom electrode of drain terminal, K battery units connects the drain terminal or source of the K+1 metal-oxide-semiconductor;Or K
The transparent graphene bottom electrode of+1 battery unit connects the source or drain terminal, the transparent stone of K battery units of the K+1 metal-oxide-semiconductor
Black alkene Top electrode connects the drain terminal or source of the K+1 metal-oxide-semiconductor;The grid end of the K+1 metal-oxide-semiconductor connects voltage source, controller
Part controls the K battery units and K+1 battery units by controlling the voltage of the grid end of the K+1 metal-oxide-semiconductor positive and negative
Between on or off;
When external power source transmits electric energy to the first battery unit, control device is controlled described using first metal-oxide-semiconductor
Turned between external power source and the first battery unit, and control the first battery unit and the second battery unit to turn off;
When the amount of storage of the first battery unit reaches preset value, control device control controls the using the 1st metal-oxide-semiconductor
Turned off between one battery unit and external power source, and controller by control the 2nd metal-oxide-semiconductor come control the first battery unit with
Second battery unit turns on, and the first battery unit charges to the second battery unit;
When the electric amount of storage of J+1 battery units reaches preset value, control device by control the J+1 metal-oxide-semiconductor come
Control and turned off between the J+1 battery units and J battery units, and by controlling the J+2 metal-oxide-semiconductor to control J+
1 battery unit turns on J+2 battery units, and J+1 battery units charge to J+2 battery units;At the same time, with J+
1 battery unit starts, upwards be spaced a battery unit after, to corresponding battery unit charge, that is to say, to J+2 electricity
The battery unit that pool unit has identical odevity charges, and can be adjacent with its top by opening corresponding battery unit
Battery unit or external power source between metal-oxide-semiconductor make battery unit or external power source adjacent above corresponding battery unit
Charged to corresponding battery unit;Wherein, N is positive integer and >=2, J=1,2 ... ..., N-2.
Further, since above-mentioned each battery unit is respectively provided with the positive and negative electrode outwardly to charge;When battery thin film is outside
When boundary discharges, the precharge circuit selector part selects electric amount of storage to reach the battery unit of preset value, and then, control device controls institute
The positive and negative electrode that the electric amount of storage of selection reaches the battery unit of preset value turns on extraneous, is outwardly charged to perform;Work as institute
When stating precharge circuit selector part and judging that the electric amount of storage of multiple battery units all reaches preset value, the charging selecting unit selection
Positioned at the battery unit for reaching preset value of bottom, the then selected battery positioned at bottom of the control device control
The positive and negative electrode of unit turns on extraneous, is outwardly charged to perform.
As procedure described above, any battery unit can be charged, and it is possible to be first filled with the battery of bottommost
Unit, then it is full of other battery units from the bottom up successively.So, the charging for battery unit realizes a continuous circulation
Process;Of course, it is also possible to carry out discharge process in charging process, put because discharge process can carry out selection to battery unit
Electricity, therefore, in discharge process it is also possible to charging process always be present, detailed process may refer to foregoing description.
Referring to Fig. 7, the above-mentioned stacked structure with multiple battery units in parallel as shown in Figure 5 of the present embodiment
The preparation method of battery thin film, comprises the following steps:
Step 01:Referring to Fig. 8, providing a substrate 00, a transparent graphene oxide layer 01 is adsorbed in substrate;
Specifically, multiple pores penetrate substrate and connection vacuum plant, by being vacuumized to pore, substrate surface exposure
Pore adsorbs a transparent graphene oxide layer.It should be noted that absorption designated herein, can also include other absorption
Technology, for example, transparent graphene oxide layer uses mono-layer graphite oxide film, the theoretic throat of the single-layer graphene oxide film
For 0.34nm, now, one layer of electrostatic film is formed in substrate, adsorbed transparent graphene oxide layer in substrate using electrostatic film
On.
Then, referring to Fig. 9, designing battery thin film layer area on a transparent graphene oxide layer;Wherein, battery thin film
Designed in layer region multiple side by side in battery cell region U1~U8 of a row, and between adjacent battery cell region
For transparent conductors region C1~C8 between battery unit that adjacent battery unit is mutually electrically connected;
Step 02:Battery thin film layer is prepared on transparent graphene oxide layer in battery thin film layer area;
Specifically, because the above-mentioned battery thin film layer of the present embodiment is made up of the battery unit stacked;Each battery unit
Using three-decker, including:Transparent graphene lower electrode layer, the nano-wire array being grown on transparent graphene lower electrode layer,
And the transparent graphene lower electrode layer at the top of nano-wire array;Interlayer transparent Indium is used between adjacent battery unit
Graphene layer is isolated;
This step 02 can specifically include following steps:
Step A:Referring to Fig. 10, layer of transparent graphene film is deposited on the transparent graphene oxide layer 01 of step 01
T1';Here, the deposition on transparent graphene film T1' can be, but not limited to make using high temperature chemical vapor deposition technique
It is standby.Here, from the growing principle of graphene film, transparent graphene oxide layer T1' is also used as transparent graphene
Extension adsorption layer, the inculating crystal layer of the Seed Layer of film.
Step B:Figure 11 is referred to, nano-wire array is prepared on the transparent graphene film T1' of battery thin film layer area
02;Here, nano-wire array 02 can use transition group oxide material, for example, TiO2Material, ZnO material etc..Need to illustrate
, need to be in overlapping transparent graphene band if overlapping above and below the transparent graphene band between follow-up adjacent cell
Between isolated material is set, therefore, in other embodiments of the present utility model, in this step B, can also include:Patterning
Nano-wire array 02, the pattern of nanowires corresponding to battery unit is formed in nano-wire array 02;Then, in pattern of nanowires
Between transparent graphene film on form separation layer.
Step C:Figure 12 is referred to, another layer of transparent graphene film T2' is formed in the substrate 00 for completing step B, and
And another layer of transparent graphene film T2' of patterning, nano-wire array 02 and transparent graphene film T1', it is in one side by side to be formed
The patterns of nano-wire array 02 of multiple battery unit figures of row, transparent graphene Top electrode, transparent graphene bottom electrode and
Transparent graphene film band between adjacent battery unit.Here, transparent graphene film T2' is deposited on nano-wire array 02
On should not use epitaxial growth method, absorption method can be used, transparent graphene film T2' is prepared in other substrate, will be saturating
Bright graphene film T2' transparent stones formed with nano-wire array 02 on surface into step B using Electrostatic Absorption technique transfers
On black alkene film T1'.Specifically, the situation for forming separation layer in above-mentioned other embodiments, patterns battery in this step C
Pattern isolated layer can also be included during film layer region so that separation layer has identical pattern with transparent graphene band.
Step 03:Figure 13 is referred to, another transparent graphene oxide layer is covered in the whole substrate for completing step 02;
Specifically, the covering of another transparent graphene oxide layer can use the means such as Electrostatic Absorption, in above-mentioned steps
Electrostatic Absorption means were had been described in, repeated no more here.
Step 04:Refer to Figure 14 and combine Fig. 1, transparent conductors region between battery cell region and battery unit in Figure 14
It is represented by dashed line;Corresponding folding line is designed in transparent conductors region between battery unit, will be adjacent in battery thin film layer area
Battery cell region along corresponding folding line doubling, form the battery thin film layer that the battery unit of stacking is formed.
Specifically, Figure 15 is referred to, first, wherein in a transparent graphene oxide layer surface, to adjacent cell list
First region applies the charges of different polarity respectively;Then, by the transparent graphene oxide layer surface of the applied charges of different polarity along folding line pair
Folding, as shown in figure 16, there is a natural attraction between the sexes, makes the transparent graphene oxide surface for applying the charges of different polarity in adjacent cell region
Mutually absorption.Certainly, Figure 17 is referred to, Electrostatic Absorption means can also be used, including:First, in adjacent cell region
One of battery cell region a transparent graphene oxide layer surface on apply electrostatic;Then, by applied electrostatic
Transparent graphene oxide surface applies the charges of different polarity along folding line doubling, using what Electrostatic Absorption made adjacent cell region
Transparent graphene oxide surface mutually adsorb.
The battery thin film connected between battery unit on Fig. 4 examples of above-mentioned other embodiments, incorporated by reference to Figure 18, this
In step 02 can include:
Step A:Layer of transparent graphene film T1' is deposited on the transparent graphene oxide layer 01 of step 01;
Step B:Patterned transparent graphene film T1', it is right that battery unit institute is etched in transparent graphene film T1'
The partially transparent graphene film bottom electrode answered and partially transparent graphene film Top electrode, and between adjacent cell
Transparent graphene band, and get rid of the transparent graphene film that need not be connected between adjacent cell;Wherein, transparent graphite
Alkene band is arranged at intervals between adjacent battery unit;
Step C:Nano-wire array 02 is prepared on the transparent graphene film T1' of battery thin film layer area;
Step D:Nano-wire array 02 is patterned, the pattern of the nano-wire array 02 formed in battery unit;
Step E:Another layer of transparent graphene film T2' is formed on the pattern of nano-wire array 02;
Step F:Another layer of transparent graphene film T2' is patterned, is etched in another layer of transparent graphene film T2'
Partially transparent graphene film bottom electrode and partially transparent graphene film Top electrode corresponding to battery unit, and adjacent electricity
Transparent graphene band between pool unit, and get rid of the transparent graphene film that need not be connected between adjacent cell;
Wherein, the transparent graphene band in another layer of transparent graphene film is arranged at intervals between adjacent battery unit, and with
Transparent graphene band in step B (is located at the transparent graphene film after the patterning in Figure 19 between adjacent cell
T1') alternate setting.Now, the battery thin film is not bent also, adjacent cell in the transparent graphene film T1' of bottom
Between the spaced setting of transparent graphene;In another layer of transparent graphene film T2' of top layer between adjacent cell
The setting alternate with the transparent graphene band of bottom of transparent graphene band.Explanation is needed exist for, Figure 15 is referred to, for every phase
Two adjacent battery units, apply transparent graphene oxide layer table of the charges of different polarity in the battery cell region of folding line both sides
Face, Figure 17 is referred to, apply transparent graphene oxide layer surface of the electrostatic in the battery cell region of folding line side, according to this
Set, that is to say that one battery unit in interval to apply the charges of different polarity in the transparent graphene oxide layer surface of battery cell region
Or electrostatic.
In addition, in other embodiments of the present utility model, Figure 19 is referred to, for the ease of expression, it is saturating to be not shown first
The battery thin film layer and the second transparent graphene oxide layer of the bright top of graphene oxide layer 01;In the first transparent graphene oxide layer
01 lower section is additionally provided with another layer of transparent graphene oxide layer 04, and on another layer of transparent graphene oxide layer 04
Antenna film, for receiving and dispatching each frequency band signals.Here antenna film can be ultra micro antenna film, including a transparent medium
Layer 05, transparent dielectric layer 05 have at least one groove, and channel bottom sets graphene antenna pattern G1, trenched side-wall top height
Go out graphene antenna pattern G1, the first transparent graphene oxide layer 01 is supported on trenched side-wall top.Transparent dielectric layer 05
Material be organic transparent material.Graphene antenna pattern G1 is prepared using monoatomic-layer graphene film, so as to realize antenna
The ultrathin of film.
Although the utility model is disclosed as above with preferred embodiment, the right embodiment is illustrated only for the purposes of explanation
, the utility model is not limited to, those skilled in the art is not before the spirit and scope of the utility model is departed from
Some change and retouching can be made by putting, and the protection domain that the utility model is advocated should be to be defined described in claims.