CN110329631B - Printing light-emitting packaging device based on magnetic resonance wireless power supply technology and design method - Google Patents

Abstract

The invention discloses a printing luminous packaging device based on a magnetic resonance wireless power supply technology and a design method thereof, wherein the device comprises a printing coil, a printing circuit, a printing capacitor and a printing luminous module which are arranged in a packaging box body; the printed coil, the printed capacitor and the printed light-emitting module are mutually connected through a printed circuit, the printed coil and the printed capacitor are mutually connected in parallel to form a receiving end of magnetic resonance wireless power supply, a transmitting end of the magnetic resonance wireless power supply is arranged outside the packaging box body, the receiving end transmits the electric energy to the printed light-emitting module by receiving the electric energy of the transmitting end, and the function of commodity packaging light-emitting display is realized through an electroluminescence principle; wherein: the printed coil, the printed circuit and the printed capacitor are printed on a piece of PET plastic film by conductive ink, and the PET plastic film is attached inside the packaging box body. The invention can realize the luminous display of the commodity package without influencing the volume and the weight of the commodity package.

Description

Printing light-emitting packaging device based on magnetic resonance wireless power supply technology and design method

Technical Field

The invention relates to the technical field of wireless power supply luminous display packaging, in particular to a printing luminous packaging device based on a magnetic resonance wireless power supply technology and a design method.

Background

Magnetic resonance wireless charging technology, consisting of an energy transmitting device and an energy receiving device, which can exchange energy with each other when both devices are tuned to the same frequency, or resonate at a specific frequency.

The carbon-based water-based conductive ink can conduct electricity through graphite particles in the ink, and the conductivity of the ink is close to that of copper, so that a flexible printed circuit can be realized.

The printing OLED technology can only realize partial printing of the display device, namely the printing of the OLED material, but does not form a breakthrough on the printing of the TFT backboard. Compared with the traditional evaporation process, the printing type has the advantages of simple process, low cost, high material utilization rate and more suitability for large-size panels, and once the bottleneck of mass production is crossed in OLED printing, great development opportunities are met.

However, if a conventional light-emitting circuit and a wireless charging circuit are adopted, or a battery is arranged in a package, the cost is increased, potential safety hazards are brought to transportation, and meanwhile, the on-off of the circuit is difficult to operate externally; the wires of the external power supply can bring inconvenience to carrying and transportation, and meanwhile, if the bulbs or the diodes are used, the overall shape of the packing box can be affected, and carrying and transportation can be hindered.

Disclosure of Invention

The invention aims to solve the technical problem of providing a printing luminous packaging device based on a magnetic resonance wireless power supply technology and a design method aiming at the defects in the prior art.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the invention provides a printing light-emitting packaging device based on a magnetic resonance wireless power supply technology, which comprises a printing coil, a printing circuit, a printing capacitor and a printing light-emitting module, wherein the printing coil, the printing circuit, the printing capacitor and the printing light-emitting module are arranged in a packaging box body; the printed coil, the printed capacitor and the printed light-emitting module are mutually connected through a printed circuit, the printed coil and the printed capacitor are mutually connected in parallel to form a receiving end of magnetic resonance wireless power supply, a transmitting end of the magnetic resonance wireless power supply is arranged outside the packaging box body, the receiving end transmits the electric energy to the printed light-emitting module by receiving the electric energy of the transmitting end, and the function of commodity packaging light-emitting display is realized through an electroluminescence principle; wherein: the printed coil, the printed circuit and the printed capacitor are printed on a piece of PET plastic film by conductive ink, and the PET plastic film is attached inside the packaging box body.

Furthermore, the printing light-emitting module comprises a three-layer structure, wherein a conductive ink cathode, an OLED light-emitting layer and an indium tin oxide anode are respectively arranged from the part close to the packaging box body to the part far away from the packaging box body, and are attached to the outer surface of the packaging box body through three times of printing.

Furthermore, the printed capacitor comprises a front electrode plate and a back electrode plate which are respectively arranged on two sides of the PET plastic film; a plurality of holes are formed in the PET plastic film; the printed coil, the front electrode plate of the printed capacitor and the printed light-emitting module are connected through a printed circuit and are all arranged on the same side of the PET plastic film; the back side polar plate of the printed capacitor is arranged on the other side of the PET plastic film, the front side polar plate and the back side polar plate are connected with each other through a printed circuit penetrating through the hole, and the hole is filled with conductive ink.

Furthermore, the printed coil is a planar rectangular coil wound with a plurality of turns, and two ends of the printed coil are respectively positioned at the outer side of the printed coil and the central position of the printed coil; the outer side end of the printed coil is connected with the positive electrode plate of the printed capacitor; the number of the holes is three, and the three holes comprise a first hole, a second hole and a third hole; the connecting line of the central end of the printed coil passes through the first hole, and one end of the printed circuit passes through the second hole, so that the central end of the printed coil and the printed circuit realize jumper connection on the surface of the reverse side polar plate; the second hole and the third hole are connected through a printed circuit, and the printed circuit penetrates through the third hole, so that the reverse side pole plate and the printed circuit are connected with each other; the parallel connection of the printed capacitor and the printed coil with two poles respectively arranged on the two surfaces is realized.

Further, the conductive ink of the present invention is a carbon-based aqueous conductive ink.

Further, the fixing arrangement mode of the PET plastic film in the packaging box body comprises the following steps: the packaging box body is arranged on one surface of the packaging box body or a plurality of surfaces of the packaging box body; if the packaging box is arranged on a plurality of surfaces of the packaging box body, the printed circuits on the PET plastic films at the folding positions of two adjacent surfaces are provided with ink layer thickening positions through thickening treatment.

Further, the printed coil, the printed capacitor and the printed circuit of the present invention are processed by one-time printing.

The invention provides a design method of a printing luminous packaging device based on a magnetic resonance wireless power supply technology, which comprises the following steps:

step 1, determining an inductance value L of a printed coil and a capacitance value C of a printed capacitor according to the working frequency of magnetic resonance wireless power supply;

step 2, determining the outer diameter of the printed coil according to the size of the packaging box body;

step 3, calculating the number of turns, the line width and the line spacing of the printed coil, and determining the shape and the size of the printed capacitor; the calculation formula is as follows:

inductance

Wherein a ═ a₀-N(g+ω)，b＝b₀-N(g+ω),

a₀The dimension of the outline of the long side of the rectangular printed coil is the dimension; b₀The outline size of the short side of the rectangular printed coil is obtained; a is the average length of the rectangular printed coil; b is the average width of the rectangular printed coil; omega is the width of the wire; g is the line spacing; t is the cross-sectional height; n is the number of turns of the coil; mu.s₀For vacuum permeability, values of 4 π 10^-10(ii) a The value of p depends on the actual coil processing technology and is between 1.75 and 1.85; the obtained inductance unit isHenry;

capacitance C ═ ε rS/4 π kd

Wherein, epsilonr is the dielectric constant of the plastic film, d is the thickness of the plastic film, S is the area of the printed capacitor, and k is the electrostatic force constant;

step 4, determining the shape and size of the printed circuit according to the size of the packaging box body;

and 5, drawing by using plane software according to the calculated parameters, making a plate, printing, laminating, and connecting and printing the light-emitting module.

The invention has the following beneficial effects: according to the printing luminous packaging device and the design method based on the magnetic resonance wireless power supply technology, the luminous display elements are added to the commodity package, so that the package is endowed with stronger attraction, and meanwhile, the potential safety hazard of a built-in battery and the inconvenience caused by external power supply wires and a bulb diode are avoided; compare coil and the circuit that the copper line is constituteed, electrically conductive ink printed circuit is almost totally flat, does not occupy any space inside the packing box, and weight is very light simultaneously, thereby can not increase too much weight for whole package because of wireless power supply module and hinder the transportation, in addition, electrically conductive ink printed circuit's cost is very cheap, can not let the packing increase too much cost when bringing the function for the packing. The printed light emitting module can display a very exquisite light emitting pattern with extremely low power consumption, and has a better visual effect than a single bulb or diode.

Drawings

The invention will be further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a schematic representation of the front side print of a printed plastic film of an embodiment of the present invention;

FIG. 2 is a schematic reverse side print of a printed plastic film according to an embodiment of the present invention;

FIG. 3 is a schematic view of the relative positions of a printed plastic film and a packaging box according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a printed light module according to an embodiment of the present invention;

FIG. 5 is a schematic structural view of a printing method according to an embodiment of the present invention;

FIG. 6 is a schematic circuit diagram of an embodiment of the present invention;

in the figure: 1-printing a coil, 2-printing a positive electrode plate, 3-printing a light-emitting module, 4-holes, 5-printing an ink layer thickening part, 6-printing a negative electrode plate, 7-packaging a box body and 8-printing a PET plastic film.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

As shown in fig. 1-3, the printed light-emitting packaging device based on the magnetic resonance wireless power supply technology of the embodiment of the invention comprises a printed coil 1, a printed circuit, a printed capacitor and a printed light-emitting module 3 which are arranged inside a packaging box 7; the printed coil 1, the printed capacitor and the printed light-emitting module 3 are mutually connected through a printed circuit, the printed coil 1 and the printed capacitor are mutually connected in parallel to jointly form a receiving end of magnetic resonance wireless power supply, a transmitting end of the magnetic resonance wireless power supply is arranged outside the packaging box body 7, the receiving end transmits the electric energy to the printed light-emitting module 3 by receiving the electric energy of the transmitting end, and the function of commodity packaging light-emitting display is realized through an electroluminescence principle; wherein: the printed coil 1, the printed circuit and the printed capacitor are all printed on a piece of PET plastic film 8 by conductive ink, and the PET plastic film 8 is attached inside the packaging box body 7.

As shown in fig. 4, the light emitting module 3 is not on the plastic film, and this position is used to correspond to the outer surface of the package box, and the printed light emitting module 3 includes a three-layer structure, which is a conductive ink cathode, an OLED light emitting layer, and an indium tin oxide anode from the position close to the package box 7 to the position far from the package box 7, and is attached to the outer surface of the package box 7 by three times of printing.

The printed capacitor comprises a front electrode plate 2 and a back electrode plate 6 which are respectively arranged on two sides of a PET plastic film 8; a plurality of holes 4 are formed in the PET plastic film 8; the printed coil 1, the front electrode plate 2 of the printed capacitor and the printed light-emitting module 3 are connected through a printed circuit and are all arranged on the same side of the PET plastic film 8; the back plate 6 of the printed capacitor is arranged on the other side of the PET plastic film 8, the front plate 2 and the back plate 6 are connected with each other through a printed circuit penetrating through the hole 4, and the hole 4 is filled with conductive ink.

Because conventional electric capacity is too big, be not suitable for on the printed packaging, so need adopt printed capacitance, but the electric capacity of condenser needs the capacitance value big enough, needs great area, and designs on same side, and the area is big enough. Therefore, the invention adopts the mode of arranging the capacitors on the front and back surfaces, and can meet the requirement on the capacitance value on the premise of ensuring small volume.

The printed coil 1 is a planar rectangular coil wound with a plurality of circles, and two ends of the printed coil are respectively positioned at the outer side of the printed coil and the central position of the printed coil; the outer side end of the printed coil is connected with the front electrode plate 2 of the printed capacitor; the number of the holes 4 is three, and the holes comprise a first hole, a second hole and a third hole; the connecting line of the central end of the printed coil passes through the first hole, and one end of the printed circuit passes through the second hole, so that the central end of the printed coil and the printed circuit realize jumper connection on the surface of the reverse side polar plate 6; the second hole and the third hole are connected through a printed circuit, and the printed circuit penetrates through the third hole, so that the back side polar plate 6 and the printed circuit are connected with each other; the parallel connection of the printed capacitor and the printed coil 1 with two poles respectively arranged on two surfaces is realized.

The conductive ink is carbon-based water-based conductive ink.

The fixed mode of setting of PET plastic film 8 inside packing carton 7 includes: arranged on one face of the packing box body 7 or on a plurality of faces of the packing box body 7; when the printed circuit board is provided on a plurality of surfaces of the packaging box body 7, the printed circuit boards on the PET plastic films 8 at the folding positions of the two adjacent surfaces are provided with the ink layer thickened parts 5 through thickening treatment.

The printed coil 1, the printed capacitor, and the printed circuit are formed by one-time printing.

The design method of the printing luminous packaging device based on the magnetic resonance wireless power supply technology comprises the following steps:

step 1, determining an inductance value L of a printed coil and a capacitance value C of a printed capacitor according to the working frequency of magnetic resonance wireless power supply;

step 2, determining the outer diameter of the printed coil according to the size of the packaging box body;

step 3, calculating the number of turns, the line width and the line spacing of the printed coil, and determining the shape and the size of the printed capacitor; the calculation formula is as follows:

inductance

Wherein a ═ a₀-N(g+ω)，b＝b₀-N(g+ω),

a₀The dimension of the outline of the long side of the rectangular printed coil is the dimension; b₀The outline size of the short side of the rectangular printed coil is obtained; a is the average length of the rectangular printed coil; b is the average width of the rectangular printed coil; omega is the width of the wire; g is the line spacing; t is the cross-sectional height; n is the number of turns of the coil; mu.s₀For vacuum permeability, values of 4 π 10^-10(ii) a The value of p depends on the actual coil processing technology and is between 1.75 and 1.85; the inductance unit obtained is Henry;

capacitance C ═ ε rS/4 π kd

Wherein, epsilonr is the dielectric constant of the plastic film, d is the thickness of the plastic film, S is the area of the printed capacitor, and k is the electrostatic force constant;

step 4, determining the shape and size of the printed circuit according to the size of the packaging box body;

and 5, drawing by using plane software according to the calculated parameters, making a plate, printing, laminating, and connecting and printing the light-emitting module.

It will be understood that modifications and variations can be made by persons skilled in the art in light of the above teachings and all such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.

Claims (6)

1. A printing luminous packaging device based on a magnetic resonance wireless power supply technology is characterized by comprising a printing coil (1), a printing circuit, a printing capacitor and a printing luminous module (3) which are arranged in a packaging box body (7); the printed coil (1), the printed capacitor and the printed light-emitting module (3) are mutually connected through a printed circuit, the printed coil (1) and the printed capacitor are mutually connected in parallel to jointly form a receiving end of magnetic resonance wireless power supply, a transmitting end of magnetic resonance wireless power supply is arranged outside the packaging box body (7), the receiving end receives electric energy of the transmitting end and transmits the electric energy to the printed light-emitting module (3), and the function of commodity packaging light-emitting display is realized through an electroluminescence principle; wherein: the printed coil (1), the printed circuit and the printed capacitor are printed on a PET plastic film (8) by conductive ink, and the PET plastic film (8) is attached inside the packaging box body (7);

the printed capacitor comprises a front electrode plate (2) and a back electrode plate (6) which are respectively arranged on two sides of a PET plastic film (8); a plurality of holes (4) are formed in the PET plastic film (8); the printed coil (1), the front electrode plate (2) of the printed capacitor and the printed light-emitting module (3) are connected through a printed circuit and are arranged on the same side of the PET plastic film (8); a back side polar plate (6) of the printed capacitor is arranged on the other side of the PET plastic film (8), the front side polar plate (2) and the back side polar plate (6) are connected with each other through a printed circuit penetrating through the hole (4), and the hole (4) is filled with conductive ink;

the printing coil (1) is a plane rectangular coil wound with a plurality of circles, and two ends of the printing coil are respectively positioned at the outer side of the printing coil and the central position of the printing coil; the outer side end of the printed coil is connected with a front electrode plate (2) of the printed capacitor; three holes (4) are arranged, and comprise a first hole, a second hole and a third hole; the connecting line of the central end of the printed coil passes through the first hole, and one end of the printed circuit passes through the second hole, so that the central end of the printed coil and the printed circuit realize jumper connection on the surface of the reverse side polar plate (6); the second hole and the third hole are connected through a printed circuit, and the printed circuit penetrates through the third hole, so that the back side polar plate (6) is connected with the printed circuit; the parallel connection of the printed capacitor and the printed coil (1) with two poles respectively arranged on the two surfaces is realized.

2. The packaging device of claim 1, wherein the printed light emitting module (3) comprises a three-layer structure, from the part near the packaging box (7) to the part far from the packaging box (7), a conductive ink cathode, an OLED light emitting layer, and an indium tin oxide anode, which are attached to the outer surface of the packaging box (7) by three times of printing.

3. The printed light-emitting packaging device based on magnetic resonance wireless power supply technology as claimed in claim 1, wherein the conductive ink is carbon-based aqueous conductive ink.

4. The printed light-emitting packaging device based on the magnetic resonance wireless power supply technology is characterized in that the fixed arrangement mode of the PET plastic film (8) inside the packaging box body (7) comprises the following steps: is arranged on one surface of the packing box body (7) or on a plurality of surfaces of the packing box body (7); when the printed circuit board is arranged on a plurality of surfaces of the packaging box body (7), the printed circuit on the PET plastic film (8) at the folding positions of two adjacent surfaces is provided with an ink layer thickening part (5) through thickening treatment.

5. The printed light-emitting packaging device based on the magnetic resonance wireless power supply technology is characterized in that the printed coil (1), the printed capacitor and the printed circuit are processed by one-time printing.

6. A design method of a printed light-emitting packaging device based on magnetic resonance wireless power supply technology according to claim 1, characterized in that the method comprises the following steps:

step 1, determining an inductance value L of a printed coil and a capacitance value C of a printed capacitor according to the working frequency of magnetic resonance wireless power supply;

step 2, determining the outer diameter of the printed coil according to the size of the packaging box body;

step 3, calculating the number of turns, the line width and the line spacing of the printed coil, and determining the shape and the size of the printed capacitor; the calculation formula is as follows:

inductance

Wherein a ═ a₀-N(g+ω)，b＝b₀-N(g+ω),

a₀The dimension of the outline of the long side of the rectangular printed coil is the dimension; b₀The outline size of the short side of the rectangular printed coil is obtained; a is the average length of the rectangular printed coil; b is the average width of the rectangular printed coil; omega is the width of the wire; g is the line spacing; t is the cross-sectional height; n is the number of turns of the coil; mu.s₀For vacuum permeability, values of 4 π 10^-10(ii) a The value of p depends on the actual coil processing technology and is between 1.75 and 1.85; the inductance unit obtained is Henry;

capacitance C ═ ε rS/4 π kd

Wherein, epsilonr is the dielectric constant of the plastic film, d is the thickness of the plastic film, S is the area of the printed capacitor, and k is the electrostatic force constant;

step 4, determining the shape and size of the printed circuit according to the size of the packaging box body;

and 5, drawing by using plane software according to the calculated parameters, making a plate, printing, laminating, and connecting and printing the light-emitting module.

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