CN106847505A - The preparation method of apparatus for storing electrical energy - Google Patents

Abstract

The invention discloses the preparation method of apparatus for storing electrical energy, including：Generate the film of the first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, the second conductive paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer；Surface to the film of each layer is processed to set magnetic polarization direction；Each layer is laminated successively and is compacted form capacity plate antenna according to the structure of capacitor；Capacity plate antenna is cut, and electric installation is set, electric installation is welded on the position that the capacity plate antenna is cut；It is monomer electric capacity that capacity plate antenna is packaged, and monomer electric capacity is encapsulated as into apparatus for storing electrical energy according to default circuit.The beneficial effect of the invention is：The preparation method program is simple, saves cost of manufacture；Obtained apparatus for storing electrical energy capacity is big, and small volume is lightweight, and battery can be replaced to use.

Description

The preparation method of apparatus for storing electrical energy

Technical field

The present invention relates to electric energy storage technology field, more particularly to apparatus for storing electrical energy preparation method.

Background technology

The capacity of apparatus for storing electrical energy especially electric capacity, influences execution efficiency and the activity duration of electronics, especially The big electric capacity substitution battery of development power storage amount, there is the advantage such as lightweight, small volume, pollution-free, can improve people's now Life.

Giant magnetoresistance effect is a kind of quantum mechanics and condensed state physics phenomenon, and one kind of magnetoresistance can be in magnetic material Observed in material film layer (several nanometer thickness) structure alternate with nonmagnetic substance.The resistance value of this structural material with it is ferromagnetic The direction of magnetization of property material film layers is relevant, the resistance value under two-layer magnetic material direction of magnetization reverse situation, hence it is evident that more than magnetic Resistance value when change direction is identical, resistance amount of varying widely under very weak externally-applied magnetic field.

High efficiency insulation body is done using giant magnetoresistance effect, capacitor is made using magnetic capacitance, included in the structure of magnetic capacitance Magnetosphere there is south magnetic pole and magnetic north pole, magnetic field intensity is the result of magnetic domain concentrated expression in magnet, Fig. 1 is refer to, in Fig. 1 What is drawn is that reason causes the polarised direction of magnetic domain different because magnetisable material is uneven in magnetic capacitance etc., due to permanent magnet and magnetic Property material inside magnetic domain skewness, the magnetic domain direction of magnetization is inconsistent, is eventually exhibited as in the magnetic pole normal orientation magnetic line of force not Uniformly, this inhomogeneities general performance is the magnetic polarization direction of normal direction.Magnetic polarization direction is the knot of numerous magnetic domain concentrated expressions Really, it should be noted that magnet edges have the magnetic line of force, and this magnetic line of force is closed because of the distribution of magnet inside magnetic domain.

Because the type magnetic capacitor make use of giant magnetoresistance effect, and the pole plate particle characteristic and dielectric layer of electric capacity are thin Layer, therefore, the capacity of this electric capacity is big, and small volume is lightweight, and battery can be replaced to use in a way, there is actual demand.

The content of the invention

It is an object of the invention to provide the preparation method of apparatus for storing electrical energy.

The technical solution adopted for the present invention to solve the technical problems is：

On the one hand, there is provided a kind of preparation method of apparatus for storing electrical energy, including：

Generate the first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, the second conduction The film of paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer；

To first electroconductive magnetic layer, the second electroconductive magnetic layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer The surface of film is processed to set magnetic polarization direction；

According to the structure of capacitor successively to first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic Stratum granulosum, dielectric layer, the second conductive paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer are laminated and are compacted To form capacity plate antenna；

The capacity plate antenna is cut, and electric installation is set, the electric installation is welded on the flat board electricity Hold cut position；

It is monomer electric capacity that the capacity plate antenna is packaged, and the monomer electric capacity is encapsulated as into electricity according to default circuit Can storage device.

In preparation method of the present invention, the first electroconductive magnetic of generation layer, the second electroconductive magnetic layer, first are led The film of electric paramagnetic particle layer, dielectric layer, the second conductive paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer, Including：

First electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, second are led Electric paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer are disposed as thin layer；

The first electroconductive magnetic layer, the second electroconductive magnetic are generated by way of sputter or chemical precipitation or crystal growth Layer, the first conductive paramagnetic particle layer, dielectric layer, the second conductive paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic The film of layer.

It is described to first electroconductive magnetic layer, the second electroconductive magnetic layer, the 3rd in preparation method of the present invention The surface of the film of electroconductive magnetic layer and the 4th electroconductive magnetic layer is processed to set magnetic polarization direction, including：

The magnetic polarization direction of first electroconductive magnetic layer and the 4th electroconductive magnetic layer is set to first direction；

The magnetic polarization direction of second electroconductive magnetic layer and the 3rd electroconductive magnetic layer is set to second direction；Its In, the first direction is mutually perpendicular to the second direction.

In preparation method of the present invention, the first direction is horizontal direction, and the second direction is Vertical Square To.

It is described by first electroconductive magnetic layer and the 4th electroconductive magnetic layer in preparation method of the present invention Magnetic polarization direction be set in first direction, by first electroconductive magnetic layer magnetic polarization direction and the 4th conductive magnetism Property layer magnetic polarization direction be set to identical or rightabout.

The magnetic polarization direction by second electroconductive magnetic layer and the 3rd electroconductive magnetic layer is set to second party Xiang Zhong, phase is set to by the magnetic polarization direction in the magnetic polarization direction of second electroconductive magnetic layer and the 3rd electroconductive magnetic layer Same or rightabout.

In preparation method of the present invention, the structure according to capacitor is successively to first electroconductive magnetic Layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, the second conductive paramagnetic particle layer, the 3rd electroconductive magnetic layer And the 4th electroconductive magnetic layer be laminated and be compacted form capacity plate antenna, including：

Stack gradually first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, Second conductive paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer；

Insulating barrier is arranged at the upper surface of the first electroconductive magnetic layer；

It is compacted the insulating barrier, the first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric Layer, the second conductive paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer are forming capacity plate antenna.

In preparation method of the present invention, the capacity plate antenna is cut, and electric installation is set, will be described Electric installation is welded on the position that the capacity plate antenna is cut, including：

The capacity plate antenna is cut to make capacitance module；

Electric installation is set, and the electric installation is led including the first conductive layer, the second conductive layer, the 3rd conductive layer and the 4th Electric layer；

The electric installation is welded on the position that the capacity plate antenna is cut；Wherein, by first conductive layer and 3rd conductive layer is respectively arranged at the first electroconductive magnetic layer, the second electroconductive magnetic layer and the first conductive paramagnetic particle layer Both sides；Second conductive layer and the 4th conductive layer are respectively arranged at the described second conductive paramagnetic particle layer, the 3rd The both sides of electroconductive magnetic layer and the 4th electroconductive magnetic layer.

In preparation method of the present invention, described being packaged to the capacity plate antenna is monomer electric capacity, according to pre- If circuit the monomer electric capacity is encapsulated as apparatus for storing electrical energy, including：

The m monomer electric capacity is provided, m is the positive integer more than or equal to 2；

When m is equal to 2, the 3rd conductive layer of the 1st monomer electric capacity is connected with the first conductive layer of the 2nd monomer electric capacity, 4th conductive layer of the 1st monomer electric capacity is connected with the second conductive layer of the 2nd monomer electric capacity；

When m is more than 2, the 3rd conductive layer of the 1st monomer electric capacity is connected with the first conductive layer of the 2nd monomer electric capacity, 4th conductive layer of the 1st monomer electric capacity is connected with the second conductive layer of the 2nd monomer electric capacity；I-th the 3rd of monomer electric capacity the Conductive layer is connected with the first conductive layer of i+1 monomer electric capacity, and i-th the 4th conductive layer of monomer electric capacity is single with i+1 The second conductive layer connection of body capacitance, i-th first conductive layer and the i-th -1 the 3rd conductive layer of monomer electric capacity of monomer electric capacity Connection, i-th second conductive layer of monomer electric capacity is connected with the 4th conductive layer of the i-th -1 monomer electric capacity；M-th monomer electric capacity The first conductive layer be connected with the 3rd conductive layer of the m-1 monomer electric capacity, m-th second conductive layer and m- of monomer electric capacity 1 the 4th conductive layer connection of monomer electric capacity；Wherein, i is the positive integer more than 1 and less than m.

On the other hand, there is provided a kind of preparation method of apparatus for storing electrical energy, including：

Generate the first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, the second conduction The film of paramagnetic particle layer and the 3rd electroconductive magnetic layer；

At the surface of the film of first electroconductive magnetic layer, the second electroconductive magnetic layer and the 3rd electroconductive magnetic layer Manage to set magnetic polarization direction；

According to the structure of capacitor successively to first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic Stratum granulosum, dielectric layer, the second conductive paramagnetic particle layer and the 3rd electroconductive magnetic layer are laminated and are compacted form capacity plate antenna；

The capacity plate antenna is cut, and electric installation is set, the electric installation is welded on the flat board electricity Hold cut position；

It is monomer electric capacity that the capacity plate antenna is packaged, and the monomer electric capacity is encapsulated as into electricity according to default circuit Can storage device.

In preparation method of the present invention, described being packaged to the capacity plate antenna is monomer electric capacity, according to pre- If circuit the monomer electric capacity is encapsulated as monomer electric capacity, including：

The n monomer electric capacity and the 4th electroconductive magnetic layer be provided, the magnetic polarization direction of the 4th electroconductive magnetic layer with The magnetic polarization direction of the first electroconductive magnetic layer is parallel, and n is the positive integer more than or equal to 2；The electric installation includes the One conductive layer, the second conductive layer, the 3rd conductive layer and the 4th conductive layer；First conductive layer and the 3rd conductive layer are distinguished It is arranged at the both sides of the first electroconductive magnetic layer, the second electroconductive magnetic layer and the first conductive paramagnetic particle layer；Described second leads Electric layer and the 4th conductive layer are respectively arranged at the both sides of the described second conductive paramagnetic particle layer and the 3rd electroconductive magnetic layer；

When n is equal to 2, the 1st the second conductive layer of monomer electric capacity is connected with the first conductive layer of the 2nd monomer electric capacity, 4th conductive layer of the 1st monomer electric capacity is connected with the 3rd conductive layer of the 2nd monomer electric capacity, the 2nd the 3rd of monomer electric capacity the Electroconductive magnetic layer is connected with the 4th electroconductive magnetic layer；

When n is more than 2, the 1st the second conductive layer of monomer electric capacity is connected with the first conductive layer of the 2nd monomer electric capacity, 4th conductive layer of the 1st monomer electric capacity is connected with the 3rd conductive layer of the 2nd monomer electric capacity；J-th the second of monomer electric capacity Conductive layer is connected with first conductive layer of+1 monomer electric capacity of jth, j-th the 4th conductive layer of monomer electric capacity and+1 list of jth Second conductive layer of the 3rd conductive layer connection of body capacitance, j-th first conductive layer of monomer electric capacity and -1 monomer electric capacity of jth Connection, the 4th conductive layer of -1 monomer electric capacity of j-th the 3rd conductive layer of monomer electric capacity and jth is connected；N-th monomer electric capacity The first conductive layer be connected with the second conductive layer of (n-1)th monomer electric capacity, the 3rd conductive layer of n-th monomer electric capacity and n-th- 1 the 4th conductive layer connection of monomer electric capacity, n-th the 3rd electroconductive magnetic layer of monomer electric capacity and the 4th electroconductive magnetic layer Connection；Wherein, j is the positive integer more than 1 and less than n.

The preparation method of apparatus for storing electrical energy disclosed above has the advantages that：Filled by making electrical power storage Put, the dielectric constant of dielectric medium is increased after its magnetization, the capacitance of the type magnetic capacitance is significantly greatly increased；Apparatus for storing electrical energy capacity Greatly, small volume, it is lightweight, battery can be replaced to use；Not only program is simple for the preparation method, also saves cost of manufacture.

Brief description of the drawings

Fig. 1 is the pole orientation schematic diagram of permanent magnet and magnetisable material magnetic pole surfaces magnetic domain；

The flow chart of the preparation method of the apparatus for storing electrical energy that Fig. 2 is provided for first embodiment of the invention；

The section of structure of the monomer electric capacity that Fig. 3 is provided for first embodiment of the invention；

The section of structure of the apparatus for storing electrical energy that Fig. 4 is provided for first embodiment of the invention；

The section of structure of the monomer electric capacity that Fig. 5 is provided for second embodiment of the invention；

The section of structure of the apparatus for storing electrical energy that Fig. 6 is provided for second embodiment of the invention；

The section of structure of the apparatus for storing electrical energy that Fig. 7 is provided for third embodiment of the invention；

The electrical block diagram of the apparatus for storing electrical energy that Fig. 8 is provided for third embodiment of the invention.

Specific embodiment

In order to make the purpose , technical scheme and advantage of the present invention be clearer, it is right below in conjunction with drawings and Examples The present invention is further elaborated.It should be appreciated that specific embodiment described herein is only used to explain the present invention, not For limiting the present invention.

The invention provides the preparation method of electrical energy storage device 10, it is intended that by making electrical energy storage device 10, the dielectric constant of dielectric medium is increased after its magnetization, the capacitance of the type magnetic capacitance is significantly greatly increased；Apparatus for storing electrical energy capacity Greatly, small volume, it is lightweight, battery can be replaced to use；Not only program is simple for the preparation method, also saves cost of manufacture.

Referring to Fig. 2, the flow chart of the preparation method of the apparatus for storing electrical energy that Fig. 2 is provided for first embodiment of the invention, bag Include step S1-S5：

S1, generation the first electroconductive magnetic the 101, second electroconductive magnetic of layer the 102, first conductive paramagnetic particle layer 103, dielectric of layer The film of the 105, the 3rd electroconductive magnetic of the conductive paramagnetic particle layer layer 106 of layer 104, second and the 4th electroconductive magnetic layer 107；Step S1 Including sub-step S11-S12：

S11, by the conductive paramagnetic particle layer 103 of first electroconductive magnetic the 101, second electroconductive magnetic of layer layer 102, first, The 105, the 3rd electroconductive magnetic of the conductive paramagnetic particle layer layer 106 of dielectric layer 104, second and the 4th electroconductive magnetic layer 107 are disposed as Thin layer；

S12, generate by way of sputter or chemical precipitation or crystal growth the first electroconductive magnetic layer 101, second The conductive paramagnetic particle layer the 105, the 3rd of the conductive paramagnetic particle layer 103, dielectric layer 104, second of electroconductive magnetic layer 102, first is conductive The film of the electroconductive magnetic of magnetosphere 106 and the 4th layer 107.

Wherein, sputter is commonly referred to as magnetic control sputtering plating, belongs to high-speed low temperature sputtering method.The technological requirement vacuum 1 × 10^-3Torr or so, i.e., 1.3 × 10^-3The vacuum state of Pa is filled with inert gas argon gas (Ar), and in plastic rubber substrate (anode) and High voltage direct current is added between metal targets (negative electrode), because the electron excitation that glow discharge (glow discharge) is produced is lazy Property gas, produce plasma, the atom of metal targets driven out of, is deposited on plastic rubber substrate by plasma.

Chemical precipitation is generally and adds chemical agent, makes to need the dissolving material of removal to be converted into indissoluble material and separate out in water Method for treating water.

Crystal growth refer to material under the conditions of uniform temperature, pressure, concentration, medium, pH etc. by gas phase, liquid phase, solid phase Conversion, forms the process of specific dimension sized crystals.

S2, to first electroconductive magnetic layer the 101, second electroconductive magnetic layer the 102, the 3rd electroconductive magnetic layer 106 and the 4th The surface of the film of electroconductive magnetic layer 107 is processed to set magnetic polarization direction；The step S2 includes sub-step S21- S22：

S21, by first electroconductive magnetic layer 101 and the 4th electroconductive magnetic layer 107 magnetic polarization direction be set to First direction；By the magnetic polarization direction of first electroconductive magnetic layer 101 and the magnetic polarization side of the 4th electroconductive magnetic layer 107 To being set to identical or rightabout.

S22, by second electroconductive magnetic layer 102 and the 3rd electroconductive magnetic layer 106 magnetic polarization direction be set to Second direction；Wherein, the first direction is mutually perpendicular to the second direction.By the magnetic of second electroconductive magnetic layer 102 The magnetic polarization direction of polarised direction and the 3rd electroconductive magnetic layer 106 is set to identical or rightabout.

Preferably, the first direction is horizontal direction, and the second direction is vertical direction.

S3, the structure of foundation capacitor are successively to first electroconductive magnetic the 101, second electroconductive magnetic of layer layer 102, first Conductive paramagnetic particle layer 103, dielectric layer 104, second the 105, the 3rd electroconductive magnetic of conductive paramagnetic particle layer layer 106 and the 4th is conductive Magnetosphere 107 is laminated and is compacted form capacity plate antenna；Step S3 includes sub-step S31-S33：

S31, stack gradually first electroconductive magnetic the 101, second electroconductive magnetic of layer the 102, first conductive paramagnetic particle of layer Layer 103, dielectric layer 104, second the 105, the 3rd electroconductive magnetic of conductive paramagnetic particle layer layer 106 and the 4th electroconductive magnetic layer 107；

S32, the upper surface that insulating barrier is arranged at the first electroconductive magnetic layer 101；

S33, the compacting insulating barrier 112, the first electroconductive magnetic the 101, second electroconductive magnetic of layer layer 102, first are conductive suitable Magnetic stratum granulosum 103, dielectric layer 104, second the 105, the 3rd electroconductive magnetic of conductive paramagnetic particle layer layer 106 and the 4th electroconductive magnetic layer 107 forming capacity plate antenna.

S4, the capacity plate antenna is cut, and electric installation is set, the electric installation is welded on the flat board The position that electric capacity is cut；Step S4 includes sub-step S41-S43：

S41, the capacity plate antenna is cut to make capacitance module；

S42, setting electric installation, the electric installation include that the first conductive layer 108, the second conductive layer the 109, the 3rd are conductive The conductive layer 111 of layer 110 and the 4th；

S43, the electric installation is welded on the position that the capacity plate antenna is cut；Wherein, it is conductive by described first Layer 108 and the 3rd conductive layer 110 are respectively arranged at first electroconductive magnetic the 101, second electroconductive magnetic of layer layer 102 and the The both sides of one conductive paramagnetic particle layer 103；Second conductive layer 109 and the 4th conductive layer 111 are respectively arranged at institute State the both sides of the second the 105, the 3rd electroconductive magnetic of conductive paramagnetic particle layer layer 106 and the 4th electroconductive magnetic layer 107.

S5, the capacity plate antenna is packaged is monomer electric capacity 100, according to default circuit by the monomer electric capacity 100 are encapsulated as apparatus for storing electrical energy.The monomer electric capacity that the monomer electric capacity is provided referring to Fig. 3, Fig. 3 for first embodiment of the invention Section of structure, the monomer electric capacity 100 includes the first electroconductive magnetic the 101, second electroconductive magnetic of the layer layer 102, for stacking gradually One conductive paramagnetic particle layer 103, dielectric layer 104, second the 105, the 3rd electroconductive magnetic of conductive paramagnetic particle layer layer 106 and the 4th is led Electromagnetically layer 107.It is i.e. internal a total of 7 layers, and the magnetic polarization side of the first electroconductive magnetic layer 101 and the 4th electroconductive magnetic layer 107 To parallel, and the second electroconductive magnetic layer 102 is parallel with the magnetic polarization direction of the 3rd electroconductive magnetic layer 106, and with the first conductive magnetism Property the electroconductive magnetic layer 107 of layer 101 and the 4th magnetic polarization direction it is vertical, the first conductive paramagnetic particle layer 103 and second is conductive suitable Paramagnetic metal particle is used in magnetic stratum granulosum 105, beneficial to the surface area for improving magnetic capacitance, simultaneously as the second conductive magnetism Property the electroconductive magnetic layer 106 of layer 102 and the 3rd magnetic field to the conductive paramagnetic particle layer of the first conductive paramagnetic particle layer 103 and second 105 have magnetization, are contacted with the conductive paramagnetic particle layer 105 of the first conductive paramagnetic particle layer 103 and second in dielectric layer 104 Also can should mutually there be magnetization phenomenon on surface, increased the dielectric constant of dielectric layer 104, so as to increased the appearance of the magnetic capacitor Amount.

The first electroconductive magnetic layer 101 and the 4th electroconductive magnetic layer 107 are used to constrain electron escape；Described second Electroconductive magnetic layer 102 and the 3rd electroconductive magnetic layer 106 magnetic polarization direction perpendicular to first electroconductive magnetic layer 101 and The magnetic polarization direction of the 4th electroconductive magnetic layer 107, the second electroconductive magnetic layer 102 and the 3rd electroconductive magnetic layer 106 capacitances for being used to increase the monomer electric capacity 100；Described first conductive paramagnetic particle layer 103 and the second conductive paramagnetic Stratum granulosum 105 is used to increase polar plate area to increase the capacitance of the monomer electric capacity 100；The dielectric layer 104 is used to store electricity Energy；Wherein, the magnetic polarization direction of electroconductive magnetic layer adopts indicated by an arrow in figure, i.e. the first electroconductive magnetic layer 101 and the 4th is led Electromagnetically the magnetic field intensity of layer 107 is parallel, the second electroconductive magnetic layer 102 and the 3rd electroconductive magnetic layer 106 magnetic polarization direction perpendicular to 107 magnetic polarization direction of first electroconductive magnetic layer 101 and the 4th electroconductive magnetic layer, that is to say, that the first electroconductive magnetic layer 101 and the Four electroconductive magnetics layer, 107 magnetic polarization direction are parallel, parallel to dielectric layer 104.

The conductive paramagnetic particle layer 105 of first conductive paramagnetic particle layer 103 and second can be by the metal of multilayer paramagnetic material Particle packing is formed, and because particle is trickle, the surface area of this structure can be significantly greatly increased, thus increases the electric capacity of magnetic capacitance Amount.Because the first electroconductive magnetic layer 101 is parallel with 107 magnetic polarization direction of the 4th electroconductive magnetic layer, the second electroconductive magnetic 102 He of layer Hung down with the first electroconductive magnetic layer 101 and 107 magnetic polarization direction of the 4th electroconductive magnetic layer in 3rd electroconductive magnetic, 106 magnetic polarization direction of layer Directly, and the second electroconductive magnetic layer 102 and the 3rd electroconductive magnetic layer 106 are by respectively to the first conductive paramagnetic particle layer 103 and second Conductive paramagnetic particle layer 105 is magnetized, and keeps 106 magnetic polarization direction of the second electroconductive magnetic layer 102 and the 3rd electroconductive magnetic layer It is vertical with the first electroconductive magnetic layer 101 and 107 magnetic polarization direction of the 4th electroconductive magnetic layer, while keeping the first conductive paramagnetic particle The conductive paramagnetic particle layer 105 of layer 103 and second will not be by the first electroconductive magnetic layer 101 and the 4th electroconductive magnetic 107 strong magnetic of layer Change.

First electroconductive magnetic layer 101, second electroconductive magnetic layer 102, the 3rd electroconductive magnetic layer 106 and institute State the 4th electroconductive magnetic layer 107 and be thin magnetic film (material such as iron-based, Ni-based or cobalt-base alloys, thickness is nanoscale).It is described First conductive paramagnetic particle layer 103 and the second conductive paramagnetic particle layer 105 are respectively provided with paramagnetic metal particle packing structure, i.e., The conductive paramagnetic particle layer 105 available (material such as iron-based, Ni-based or cobalt-base alloys) of first conductive paramagnetic particle layer 103 and second is received It is prepared by nanoscale powder；Dielectric layer 104 can be made up of relative dielectric constant big material such as barium titanate or titanyl compound.

The monomer electric capacity 100 also includes：First conductive layer 108, the second conductive layer 109, the 3rd conductive layer 110 and the 4th Conductive layer 111；First conductive layer 108 and the 3rd conductive layer 110 are respectively arranged at the first electroconductive magnetic layer 101st, the both sides of the conductive paramagnetic particle layer 103 of the second electroconductive magnetic layer 102 and first；Second conductive layer 109 and described Four conductive layers 111 are respectively arranged at the described second the 105, the 3rd electroconductive magnetic of conductive paramagnetic particle layer layer 106 and the 4th conductive magnetism Property layer 107 both sides.First conductive layer 108, second conductive layer 109, the 3rd conductive layer 110 and the described 4th Conductive layer 111 is thin layer, or first conductive layer 108, second conductive layer 109, the 3rd conductive layer 110 and 4th conductive layer 111 can be made up of silver or Copper thin film.

Preferably, the monomer electric capacity 100 also includes insulating barrier 112, and the insulating barrier 112 is arranged at first conductive magnetism Property layer 101 upper surface.The purpose of insulating barrier 112 is positive plate and negative plate when preventing monomer electric capacity 100 and system 10 to be superimposed Contact, is easy to circuit integrated.

Step S5 includes sub-step S51-S53：

S51, m monomer electric capacity of offer, m is the positive integer more than or equal to 2；Referring to Fig. 4, Fig. 4 is the present invention the The section of structure of the apparatus for storing electrical energy 10 that one embodiment is provided, the apparatus for storing electrical energy 10 is the monomer electricity of first embodiment Hold 100 corresponding products, the apparatus for storing electrical energy 10 includes m monomer electric capacity 100 as described above, and m is more than or equal to 2 Positive integer.

S52, when m is equal to 2, the of the 3rd conductive layer 110 of the 1st monomer electric capacity 100 and the 2nd monomer electric capacity 100 One conductive layer 108 is connected, the 1st the 4th conductive layer 111 and the 2nd the second conductive layer of monomer electric capacity 100 of monomer electric capacity 100 109 connections；

S53, when m is more than 2, the of the 3rd conductive layer 110 of the 1st monomer electric capacity 100 and the 2nd monomer electric capacity 100 One conductive layer 108 is connected, the 1st the 4th conductive layer 111 and the 2nd the second conductive layer of monomer electric capacity 100 of monomer electric capacity 100 109 connections；I-th the 3rd conductive layer 110 of monomer electric capacity 100 connects with the first conductive layer 108 of i+1 monomer electric capacity 100 Connect, i-th the 4th conductive layer 111 of monomer electric capacity 100 is connected with the second conductive layer 109 of i+1 monomer electric capacity 100, i-th First conductive layer 108 of individual monomer electric capacity 100 is connected with the 3rd conductive layer 110 of the i-th -1 monomer electric capacity 100, i-th monomer Second conductive layer 109 of electric capacity 100 is connected with the 4th conductive layer 111 of the i-th -1 monomer electric capacity 100；M-th monomer electric capacity 100 the first conductive layer 108 is connected with the 3rd conductive layer 110 of the m-1 monomer electric capacity 100, m-th monomer electric capacity 100 Second conductive layer 109 is connected with the 4th conductive layer 111 of the m-1 monomer electric capacity 100；Wherein, i be more than 1 and less than m just Integer.

The preparation method of the apparatus for storing electrical energy of second embodiment of the invention includes step S101-S105：

S101, the 102, first conductive paramagnetic particle layer 103 of generation the first electroconductive magnetic the 101, second electroconductive magnetic of layer layer, it is situated between The film of the conductive paramagnetic particle layer 105 of electric layer 104, second and the 3rd electroconductive magnetic layer 106；Step S101 is walked with first embodiment The sub-step of rapid S1 is identical.

S102, to first electroconductive magnetic layer the 101, second electroconductive magnetic layer 102 and the 3rd electroconductive magnetic layer 106 it is thin The surface of film is processed to set magnetic polarization direction；Step S102 is identical with the sub-step of first embodiment step S2.

S103, according to the structure of capacitor successively to first electroconductive magnetic the 101, second electroconductive magnetic of layer layer 102, the The one conductive conductive paramagnetic particle layer 105 of paramagnetic particle layer 103, dielectric layer 104, second and the 3rd electroconductive magnetic layer 106 carry out layer Fold and be compacted to form capacity plate antenna；Step S103 is identical with the sub-step of first embodiment step S3.

S104, the capacity plate antenna is cut, and electric installation is set, the electric installation is welded on described flat The position that plate electric capacity is cut；Step S104 is identical with the sub-step of first embodiment step S4.

S105, the capacity plate antenna is packaged is monomer electric capacity 100, according to default circuit by the monomer electric capacity 100 are encapsulated as apparatus for storing electrical energy 10.Referring to Fig. 5, the structure of the monomer electric capacity 100 that Fig. 5 is provided for second embodiment of the invention Profile, it is have 6 layers inside the monomer electric capacity 100 that the monomer electric capacity 100 is different from first embodiment part, including successively The conductive paramagnetic particle layer 103, dielectric layer 104 of first electroconductive magnetic the 101, second electroconductive magnetic of layer layer 102, first of stacking, the Two conductive paramagnetic particle layers 105 and the 3rd electroconductive magnetic layer 106；

The first electroconductive magnetic layer 101 is used to constrain electron escape；The second electroconductive magnetic layer 102 and the described 3rd The magnetic polarization direction of electroconductive magnetic layer 106 is perpendicular to the magnetic polarization direction of first electroconductive magnetic layer 101, and described second is conductive Magnetosphere 102 and the 3rd electroconductive magnetic layer 106 are used to increase the capacitance of the monomer electric capacity 100；Described first is conductive suitable Magnetic stratum granulosum 103 and the second conductive paramagnetic particle layer 105 are used to increase polar plate area to increase the electricity of the monomer electric capacity 100 Capacity；The dielectric layer 104 is used to store electric energy；

The monomer electric capacity 100 also includes：First conductive layer 108, the second conductive layer 109, the 3rd conductive layer 110 and the 4th Conductive layer 111；

First conductive layer 108 and the 3rd conductive layer 110 be respectively arranged at first electroconductive magnetic layer 101, The both sides of the conductive paramagnetic particle layer 103 of the second electroconductive magnetic layer 102 and first；Second conductive layer 109 and the described 4th lead Electric layer 111 is respectively arranged at the both sides of the described second conductive paramagnetic particle layer 105 and the 3rd electroconductive magnetic layer 106.

Step S105 includes sub-step S1051-S1053：

S1051, the n electroconductive magnetic of the monomer electric capacity 100 and the 4th layer 107 of offer, the 4th electroconductive magnetic layer 107 Magnetic polarization direction and first electroconductive magnetic layer 101 magnetic polarization direction it is parallel, n is the positive integer more than or equal to 2；Institute Stating electric installation includes the first conductive layer 108, the second conductive layer 109, the 3rd conductive layer 110 and the 4th conductive layer 111；Described One conductive layer 108 and the 3rd conductive layer 110 are respectively arranged at the first electroconductive magnetic layer the 101, second electroconductive magnetic layer 102 and first conductive paramagnetic particle layer 103 both sides；Second conductive layer 109 and the 4th conductive layer 111 are respectively provided with In the described second conductive paramagnetic particle layer 105 and the both sides of the 3rd electroconductive magnetic layer 106；Referring to Fig. 6, Fig. 6 is the present invention second The section of structure of the apparatus for storing electrical energy 10 that embodiment is provided, the apparatus for storing electrical energy 10 is the monomer electric capacity of second embodiment 100 corresponding system products, it includes n monomer electric capacity 100 as described above and the 4th electroconductive magnetic layer 107, the described 4th The magnetic polarization direction of magnetic polarization direction and first electroconductive magnetic layer 101 of electroconductive magnetic layer 107 is parallel, n be more than or wait In 2 positive integer.

S1052, when n is equal to 2, the second conductive layer 109 of the 1st monomer electric capacity 100 and the 2nd monomer electric capacity 100 First conductive layer 108 is connected, the 4th conductive layer 111 of the 1st monomer electric capacity 100 and the 2nd it is the 3rd of monomer electric capacity 100 the conductive Layer 110 is connected, and the 3rd electroconductive magnetic layer 106 of the 2nd monomer electric capacity 100 is connected with the 4th electroconductive magnetic layer 107；

S1053, when n is more than 2, the second conductive layer 109 of the 1st monomer electric capacity 100 and the 2nd monomer electric capacity 100 First conductive layer 108 is connected, the 4th conductive layer 111 of the 1st monomer electric capacity 100 and the 2nd it is the 3rd of monomer electric capacity 100 the conductive Layer 110 is connected；Second conductive layer 109 of j-th monomer electric capacity 100 and first conductive layer 108 of+1 monomer electric capacity 100 of jth Connection, the 3rd conductive layer 110 of+1 monomer electric capacity 100 of j-th the 4th conductive layer 111 of monomer electric capacity 100 and jth is connected, Second conductive layer 109 of -1 monomer electric capacity 100 of j-th first conductive layer 108 of monomer electric capacity 100 and jth is connected, j-th 4th conductive layer 111 of -1 monomer electric capacity 100 of the 3rd conductive layer 110 and jth of monomer electric capacity 100 is connected；N-th monomer electricity The first conductive layer 108 for holding 100 is connected with the second conductive layer 109 of (n-1)th monomer electric capacity 100, n-th monomer electric capacity 100 The 3rd conductive layer 110 be connected with the 4th conductive layer 111 of (n-1)th monomer electric capacity 100, n-th the 3rd of monomer electric capacity 100 the Electroconductive magnetic layer 106 is connected with the 4th electroconductive magnetic layer 107；Wherein, j is the positive integer more than 1 and less than n.

Referring to Fig. 7, the section of structure of the apparatus for storing electrical energy 10 that Fig. 7 is provided for third embodiment of the invention, the implementation The combination and superposition of the apparatus for storing electrical energy 10 that example is provided for first embodiment and second embodiment.

Referring to Fig. 8, the structural representation of circuit 200 of the apparatus for storing electrical energy 10 that Fig. 8 is provided for third embodiment of the invention. Because each monomer electric capacity 100 is the type magnetic capacitance, n parallel branch, longitudinal m electricity are constituted in horizontal n electric capacity Hold and constitute m parallel branch, and be connected to positive electrode 201 and negative electrode 202.

There is provided herein the various operations of embodiment.In one embodiment, described one or operation may be constructed one The computer-readable instruction stored on individual or computer-readable medium, it will be so that computing device be held when being performed by electronic equipment The row operation.Describing the order of some or all of operations, to should not be construed as to imply that these operations necessarily order dependent 's.It will be appreciated by those skilled in the art that the alternative sequence of the benefit with this specification.Furthermore, it is to be understood that not being institute Having operation must exist in each embodiment provided in this article.

And, word " preferred " used herein means serving as example, example or illustration.Feng Wen is described as " preferably " any aspect or design be not necessarily to be construed as than other aspect or design it is more favourable.Conversely, the use purport of word " preferred " Concept is being proposed in a concrete fashion.Term "or" as used in this application is intended to mean the "or" for including and non-excluded "or".I.e., unless otherwise or clear from the context, " X uses A or B " means that nature includes any one of arrangement. That is, if X uses A；X uses B；Or X uses A and B both, then " X uses A or B " is met in foregoing any example.

And, although the disclosure, people in the art has shown and described relative to one or implementation Member will appreciate that equivalent variations and modification based on the reading and understanding to the specification and drawings.The disclosure includes all such Modification and modification, and be limited only by the scope of the following claims.Held particularly with by said modules (such as element etc.) Capable various functions, the term for describing such component be intended to correspond to the specified function of performing the component (for example its Functionally of equal value) random component (unless otherwise instructed), even if in structure with perform the disclosure shown in this article Exemplary implementations in function open structure it is not equivalent.Although additionally, the special characteristic of the disclosure relative to Only one in some implementations is disclosed, but this feature can with can be such as the phase for given or application-specific Hope one or other combinations of features with other favourable implementations.And, with regard to term " including ", " having ", " containing " or For its deformation is used in specific embodiment or claim, such term is intended to the side similar to term "comprising" Formula includes.

Each functional unit in the embodiment of the present invention can be integrated in a processing module, or unit list Solely it is physically present, it is also possible to which multiple or multiple above units are integrated in a module.Above-mentioned integrated module can both be used The form of hardware is realized, it would however also be possible to employ the form of software function module is realized.If the integrated module is with software function The form of module is realized and as independent production marketing or when using, it is also possible to which storage is situated between in an embodied on computer readable storage In matter.Storage medium mentioned above can be read-only storage, disk or CD etc..Above-mentioned each device or system, can be with Perform the storage method in correlation method embodiment.

In sum, although the present invention it is disclosed above with preferred embodiment, but above preferred embodiment and be not used to limit The system present invention, one of ordinary skill in the art without departing from the spirit and scope of the present invention, can make various changes and profit Adorn, therefore protection scope of the present invention is defined by the scope that claim is defined.

Claims (10)

1. a kind of preparation method of apparatus for storing electrical energy, it is characterised in that including：

Generate the first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, the second conductive paramagnetic The film of stratum granulosum, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer；

To the film of first electroconductive magnetic layer, the second electroconductive magnetic layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer Surface processed to set magnetic polarization direction；

According to the structure of capacitor successively to first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle Layer, dielectric layer, the second conductive paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer are laminated and are compacted with shape Into capacity plate antenna；

The capacity plate antenna is cut, and electric installation is set, the electric installation is welded on the capacity plate antenna institute The position of cutting；

It is monomer electric capacity that the capacity plate antenna is packaged, and the monomer electric capacity is encapsulated as into electric energy according to default circuit stores up Cryopreservation device.

2. preparation method according to claim 1, it is characterised in that the electroconductive magnetic of the generation first layer, second conductive Magnetosphere, the first conductive paramagnetic particle layer, dielectric layer, the second conductive paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th are conductive Magnetospheric film, including：

First electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, the second conduction is suitable Magnetic stratum granulosum, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer are disposed as thin layer；

Generated by way of sputter or chemical precipitation or crystal growth first electroconductive magnetic layer, the second electroconductive magnetic layer, First conductive paramagnetic particle layer, dielectric layer, the second conductive paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer Film.

3. preparation method according to claim 1, it is characterised in that described to be led to first electroconductive magnetic layer, second Electromagnetically the surface of the film of layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer is processed to set magnetic polarization direction, Including：

The magnetic polarization direction of first electroconductive magnetic layer and the 4th electroconductive magnetic layer is set to first direction；

The magnetic polarization direction of second electroconductive magnetic layer and the 3rd electroconductive magnetic layer is set to second direction；Wherein, The first direction is mutually perpendicular to the second direction.

4. preparation method according to claim 3, it is characterised in that the first direction is horizontal direction, described second Direction is vertical direction.

5. preparation method according to claim 3, it is characterised in that described by first electroconductive magnetic layer and described the The magnetic polarization direction of four electroconductive magnetics layer is set in first direction, by the magnetic polarization direction of first electroconductive magnetic layer and institute The magnetic polarization direction for stating the 4th electroconductive magnetic layer is set to identical or rightabout.

The magnetic polarization direction by second electroconductive magnetic layer and the 3rd electroconductive magnetic layer is set in second direction, By second electroconductive magnetic layer magnetic polarization direction and the 3rd electroconductive magnetic layer magnetic polarization direction be set to it is identical or Rightabout.

6. preparation method according to claim 1, it is characterised in that the structure according to capacitor is successively to described the One electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, the second conductive paramagnetic particle layer, the 3rd Electroconductive magnetic layer and the 4th electroconductive magnetic layer are laminated and are compacted form capacity plate antenna, including：

Stack gradually the first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, second Conductive paramagnetic particle layer, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer；

Insulating barrier is arranged at the upper surface of the first electroconductive magnetic layer；

It is compacted the insulating barrier, the first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, the Two conductive paramagnetic particles layers, the 3rd electroconductive magnetic layer and the 4th electroconductive magnetic layer are forming capacity plate antenna.

7. preparation method according to claim 1, it is characterised in that cut to the capacity plate antenna, and setting leads Electric installation, the position that the capacity plate antenna is cut is welded on by the electric installation, including：

The capacity plate antenna is cut to make capacitance module；

Electric installation is set, and the electric installation includes that the first conductive layer, the second conductive layer, the 3rd conductive layer and the 4th are conductive Layer；

The electric installation is welded on the position that the capacity plate antenna is cut；Wherein, by first conductive layer and described 3rd conductive layer is respectively arranged at the two of the first electroconductive magnetic layer, the second electroconductive magnetic layer and the first conductive paramagnetic particle layer Side；Second conductive layer and the 4th conductive layer are respectively arranged at the described second conductive paramagnetic particle layer, the 3rd conduction The both sides of magnetosphere and the 4th electroconductive magnetic layer.

8. preparation method according to claim 7, it is characterised in that described being packaged to the capacity plate antenna is monomer Electric capacity, apparatus for storing electrical energy is encapsulated as according to default circuit by the monomer electric capacity, including：

The m monomer electric capacity is provided, m is the positive integer more than or equal to 2；

When m is equal to 2, the 3rd conductive layer of the 1st monomer electric capacity is connected with the first conductive layer of the 2nd monomer electric capacity, the 1st 4th conductive layer of monomer electric capacity is connected with the second conductive layer of the 2nd monomer electric capacity；

When m is more than 2, the 3rd conductive layer of the 1st monomer electric capacity is connected with the first conductive layer of the 2nd monomer electric capacity, the 1st 4th conductive layer of monomer electric capacity is connected with the second conductive layer of the 2nd monomer electric capacity；I-th the 3rd conductive layer of monomer electric capacity The first conductive layer with i+1 monomer electric capacity is connected, i-th the 4th conductive layer of monomer electric capacity and i+1 monomer electric capacity The connection of the second conductive layer, i-th first conductive layer of monomer electric capacity be connected with the 3rd conductive layer of the i-th -1 monomer electric capacity, I-th second conductive layer of monomer electric capacity is connected with the 4th conductive layer of the i-th -1 monomer electric capacity；M-th the of monomer electric capacity One conductive layer is connected with the 3rd conductive layer of the m-1 monomer electric capacity, m-th second conductive layer and m-1 of monomer electric capacity The 4th conductive layer connection of monomer electric capacity；Wherein, i is the positive integer more than 1 and less than m.

9. a kind of preparation method of apparatus for storing electrical energy, it is characterised in that including：

Generate the first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle layer, dielectric layer, the second conductive paramagnetic The film of stratum granulosum and the 3rd electroconductive magnetic layer；

To first electroconductive magnetic layer, the second electroconductive magnetic layer and the 3rd electroconductive magnetic layer film surface processed with Magnetic polarization direction is set；

According to the structure of capacitor successively to first electroconductive magnetic layer, the second electroconductive magnetic layer, the first conductive paramagnetic particle Layer, dielectric layer, the second conductive paramagnetic particle layer and the 3rd electroconductive magnetic layer are laminated and are compacted form capacity plate antenna；

The capacity plate antenna is cut, and electric installation is set, the electric installation is welded on the capacity plate antenna institute The position of cutting；

It is monomer electric capacity that the capacity plate antenna is packaged, and the monomer electric capacity is encapsulated as into electric energy according to default circuit stores up Cryopreservation device.

10. preparation method according to claim 9, it is characterised in that described being packaged to the capacity plate antenna is list Body capacitance, monomer electric capacity is encapsulated as according to default circuit by the monomer electric capacity, including：

The n monomer electric capacity and the 4th electroconductive magnetic layer be provided, the magnetic polarization direction of the 4th electroconductive magnetic layer with it is described The magnetic polarization direction of the first electroconductive magnetic layer is parallel, and n is the positive integer more than or equal to 2；The electric installation is led including first Electric layer, the second conductive layer, the 3rd conductive layer and the 4th conductive layer；First conductive layer and the 3rd conductive layer are respectively provided with In the both sides of first electroconductive magnetic layer, the second electroconductive magnetic layer and the first conductive paramagnetic particle layer；Second conductive layer And the 4th conductive layer is respectively arranged at the both sides of the described second conductive paramagnetic particle layer and the 3rd electroconductive magnetic layer；

When n is equal to 2, the 1st the second conductive layer of monomer electric capacity is connected with the first conductive layer of the 2nd monomer electric capacity, the 1st 4th conductive layer of monomer electric capacity is connected with the 3rd conductive layer of the 2nd monomer electric capacity, the 2nd the 3rd conductive magnetism of monomer electric capacity Property layer with the 4th electroconductive magnetic layer be connected；

When n is more than 2, the 1st the second conductive layer of monomer electric capacity is connected with the first conductive layer of the 2nd monomer electric capacity, the 1st 4th conductive layer of monomer electric capacity is connected with the 3rd conductive layer of the 2nd monomer electric capacity；J-th second conductive layer of monomer electric capacity The first conductive layer with+1 monomer electric capacity of jth is connected, j-th the 4th conductive layer of monomer electric capacity and+1 monomer electric capacity of jth The connection of the 3rd conductive layer, second conductive layer of -1 monomer electric capacity of j-th first conductive layer of monomer electric capacity and jth is connected, 4th conductive layer of -1 monomer electric capacity of j-th the 3rd conductive layer of monomer electric capacity and jth is connected；N-th the of monomer electric capacity One conductive layer is connected with the second conductive layer of (n-1)th monomer electric capacity, the 3rd conductive layer of n-th monomer electric capacity and (n-1)th The 4th conductive layer connection of monomer electric capacity, n-th the 3rd electroconductive magnetic layer of monomer electric capacity is with the 4th electroconductive magnetic layer even Connect；Wherein, j is the positive integer more than 1 and less than n.