CN111846633A - Packing carton generates heat - Google Patents

Packing carton generates heat Download PDF

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Publication number
CN111846633A
CN111846633A CN202010697829.7A CN202010697829A CN111846633A CN 111846633 A CN111846633 A CN 111846633A CN 202010697829 A CN202010697829 A CN 202010697829A CN 111846633 A CN111846633 A CN 111846633A
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China
Prior art keywords
low
voltage
box
heating ink
ink
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Pending
Application number
CN202010697829.7A
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Chinese (zh)
Inventor
钱俊
叶双莉
廖宇
刘汉东
王鑫
谷思怡
黄月
张海斋
孙基素
马晓花
李庆芝
赵美君
宋蓉
程凯兴
魏旭冉
陈袁
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Wuhan Shidimu Cultural Media Co ltd
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Wuhan Shidimu Cultural Media Co ltd
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Priority to CN202010697829.7A priority Critical patent/CN111846633A/en
Publication of CN111846633A publication Critical patent/CN111846633A/en
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65DCONTAINERS FOR STORAGE OR TRANSPORT OF ARTICLES OR MATERIALS, e.g. BAGS, BARRELS, BOTTLES, BOXES, CANS, CARTONS, CRATES, DRUMS, JARS, TANKS, HOPPERS, FORWARDING CONTAINERS; ACCESSORIES, CLOSURES, OR FITTINGS THEREFOR; PACKAGING ELEMENTS; PACKAGES
    • B65D81/00Containers, packaging elements, or packages, for contents presenting particular transport or storage problems, or adapted to be used for non-packaging purposes after removal of contents
    • B65D81/34Containers, packaging elements, or packages, for contents presenting particular transport or storage problems, or adapted to be used for non-packaging purposes after removal of contents for packaging foodstuffs or other articles intended to be cooked or heated within the package
    • B65D81/3476Packages provided with an electrical circuit, e.g. resistances, for heating the contents

Abstract

The invention relates to the technical field of packaging boxes, in particular to a heating packaging box which at least comprises an outer box and an inner box, wherein a low-voltage heating ink layer is arranged on the outer side of the bottom of the inner box, and a power supply is arranged in the outer box; when the inner box is arranged inside the outer box, the low-voltage heating ink layer and the power supply form a loop. The bottom of box in the low voltage heating printing ink layer of this scheme is located, lightly just does not account for outer box and the interior space between the box, the capacity of box in the obvious increase.

Description

Packing carton generates heat
Technical Field
The invention relates to the technical field of packaging boxes, in particular to a heating packaging box.
Background
The current packing carton that generates heat is traditional quick lime class self-heating pot, and quick lime accounts for the storage space big and weight is heavy to inconvenient, the printing ink that generates heat lightly and do not account for the space, compare in other self-heating pots place quick lime between outer box and interior box and more can save space, the capacity of box in the increase.
Disclosure of Invention
In order to solve the problems, the invention provides the packaging box capable of utilizing the heating ink to generate heat, the bottom wall of the inner box is coated with the heating ink as a heating layer and is connected with a circuit, and when the packaging box is used, a user can connect the circuit through an external power supply such as a charger or a socket to enable the heating layer to generate heat, so that food is cooked in the inner box, and the packaging box is convenient to carry and use.
The technical scheme adopted by the invention is as follows: a heating packaging box at least comprises an outer box and an inner box, wherein a low-voltage heating ink layer is arranged on the outer side of the bottom of the inner box, and a power supply is arranged in the outer box; when the inner box is arranged inside the outer box, the low-voltage heating ink layer and the power supply form a loop.
The power supply is a USB interface or a switch and a battery which can be connected with electricity, the USB interface or the switch is positioned on the side wall of the outer box, and the low-voltage heating ink layer is connected with the power supply through conductive ink or conductive metal.
And a limit stop for limiting the position of the inner box is arranged in the outer box, and the conductive ink or the conductive metal is arranged on the limit stop.
The size of the low-voltage heating ink layer is 15cm multiplied by 15cm, and the power supply voltage is 36V.
The heating packaging box is also provided with a box cover.
The low-voltage heating ink layer comprises the following components in percentage by mass: 5-10% of water-based acrylic resin, 5-10% of rosin resin, 5-15% of graphite, 3-10% of carbon black, 0-50% of carbon nanotube dispersion liquid, 0.5-1.5% of pH regulator, 1-5% of dispersing agent, 0-1% of xanthan gum, 0.5-1% of defoaming agent and 10-50% of deionized water.
The low-voltage heating ink layer is formed by coating low-voltage heating ink on the outer side of the bottom of the inner box through a screen printing or coating method.
The pH regulator is one or more of formamide, ethanolamine or ammonia water which are mixed in any proportion.
The dispersant is one of Dispenser W-518 type aqueous wetting dispersant, Dispenser W-920 type aqueous wetting dispersant, NUOSPERSE FX 600 type aqueous wetting dispersant or NUOSPERSE FX 365 type aqueous wetting dispersant or a plurality of the dispersant mixed in any proportion.
The defoaming agent is one or a plurality of types of DefomW-0506 type waterborne defoaming agents, TEGO Foamex 805 type waterborne defoaming agents or SF-809B type standard American silicon fluorine defoaming agents which are mixed in any proportion.
The technical scheme of the invention has the beneficial effects that:
(1) the bottom of box in the low voltage heating printing ink layer is located, lightly just does not account for the space between outer box and the interior box, the capacity of box in the obvious increase.
(2) The power supply has two options, namely a USB interface capable of being connected with electricity, and a switch and a battery. When the power supply adopts the combination of the switch and the battery, the switch is closed to provide power for the heating packaging box; when the USB interface is adopted, the charging power supply or the mobile power supply can be directly connected with the USB interface arranged on the side wall of the outer box of the heating packaging box, so that the USB interface is convenient to use and is not limited by places.
(3) The low-voltage heating ink provided by the invention has the following advantages: 1. biomass materials such as xanthan gum and rosin resin are used as raw materials, so that the effects of energy conservation and environmental protection are achieved; 2. under the combined action of the xanthan gum and the rosin resin, the overall proportion of the acrylic resin in the ink is reduced, so that the proportion of conductive fillers such as carbon black, graphite and carbon nano tubes in a carbon film formed after the prepared low-voltage heating ink is dried is increased, and the conductivity is excellent; 3. the low-voltage heating ink has higher viscosity and better thixotropy, the viscosity of the ink is instantly reduced under the action of shearing force in the printing process to form a thicker carbon film, the viscosity is rapidly improved after the printing is finished, so that the ink is not diffused on a printing stock, the printing adaptability of the ink is improved, and the low-voltage heating ink is suitable for screen printing; 4. the low-voltage heating ink can obtain a better heating effect under a lower working voltage. High heating efficiency and high heating rate.
Drawings
FIG. 1 is a schematic structural view of a heat-generating package;
FIG. 2(a) is a graph showing the operation of 3cm by 3cm low voltage heating ink packs prepared in example 1 of the present invention at different voltages;
FIG. 2(b) is the operation of the low-voltage heating ink block in example 1 under the condition of continuously changing voltage;
FIG. 3 is a graph showing the temperature of the low-voltage heat-generating ink stick as a function of time in example 1;
FIG. 4 is a graph showing the heating temperature of the low-voltage heating ink block as a function of power density in this example 1;
FIG. 5 is a graph showing the volt-ampere relationship of the low voltage thermal ink stick of this example 1;
fig. 6 is a graph showing the relationship between the input voltage and the saturation temperature of the low-voltage heating ink block in this embodiment 1.
Description of reference numerals: 1. the USB interface comprises a box cover, 2, an inner box, 3, a low-voltage heating ink layer, 4, an outer box, 5 and a USB interface.
Detailed Description
The present invention/invention will be described in detail with reference to the accompanying drawings and examples, and the present invention/invention is not limited to the examples.
A heating packaging box comprises a box cover 1, an outer box 4 and an inner box 2, wherein a low-voltage heating ink layer 3 is arranged on the outer side of the bottom of the inner box, and a power supply is arranged in the outer box. When the inner box is arranged inside the outer box, the low-voltage heating ink layer and the power supply form a loop. The power supply can adopt a mode of a switch and a battery, the battery is a dry battery or a storage battery, and the switch is positioned on the side wall of the outer box and is convenient to use; the power supply can also be a USB interface 5 which can be connected with electricity and is positioned on the side wall of the outer box. The low-voltage heating ink layer is connected with the power supply through conductive ink or conductive metal, and the conductive ink can adopt the low-voltage heating ink provided by the scheme and can also be conductive ink of other types.
In fact, the specific setting position of the conductive ink or the conductive metal is set correspondingly according to the size of the low-voltage heating ink layer, for example, the conductive ink or the conductive metal is set at two ends of the low-voltage heating ink layer, for example, a limit stop for limiting the position of the inner box is arranged in the outer box, and the conductive ink or the conductive metal is arranged on the limit stop and connected with two ends of the low-voltage heating ink layer. The circuit is simple and easy to realize, and the circuit is formed by connecting a switch, a battery, a lead and a low-voltage heating ink layer into a loop, or two poles of a USB interface are connected with the low-voltage heating ink layer through the lead.
The low-voltage heating ink layer is formed by coating low-voltage heating ink on the outer side of the bottom of the inner box through a screen printing or coating method.
The technical scheme of the invention has the beneficial effects that:
(1) the bottom of box in the low voltage heating printing ink layer is located, lightly just does not account for the space between outer box and the interior box, the capacity of box in the obvious increase.
(2) The power supply has two options, namely a USB interface capable of being connected with electricity, and a switch and a battery. When the power supply adopts the combination of the switch and the battery, the switch is closed to provide power for the heating packaging box; when the USB interface is adopted, the charging power supply or the mobile power supply can be directly connected with the USB interface arranged on the side wall of the outer box of the heating packaging box, so that the USB interface is convenient to use and is not limited by places.
The low-voltage heating ink in the heating packaging box comprises the following components in percentage by mass: 5-10% of water-based acrylic resin, 5-10% of rosin resin, 5-15% of graphite, 3-10% of carbon black, 0-50% of carbon nanotube dispersion liquid, 0.5-1.5% of pH regulator, 1-5% of dispersing agent, 0-1% of xanthan gum, 0.5-1% of defoaming agent and 10-50% of deionized water. The pH regulator is one or more of formamide, ethanolamine or ammonia water which are mixed in any proportion. The dispersant is one of Dispenser W-518 type aqueous wetting dispersant, Dispenser W-920 type aqueous wetting dispersant, NUOSPERSE FX 600 type aqueous wetting dispersant or NUOSPERSE FX 365 type aqueous wetting dispersant or a plurality of the dispersant mixed in any proportion. The defoaming agent is one or a plurality of types of DefomW-0506 type waterborne defoaming agents, TEGO Foamex 805 type waterborne defoaming agents or SF-809B type standard American silicon fluorine defoaming agents which are mixed in any proportion.
The preparation method of the low-voltage heating ink specifically comprises the following steps:
(1) weighing each component of the low-voltage heating ink according to the mass parts, placing the water-based acrylic resin, the rosin resin, the pH regulator and the deionized water in a stirring kettle, stirring for 5-10 min, after uniformly mixing, sequentially adding the carbon black, the graphite, the carbon nanotube dispersion liquid and the xanthan gum, uniformly stirring, finally adding the dispersing agent and the defoaming agent, and uniformly stirring to form the primary heating ink;
(2) Mixing the primary heating ink and the ball-milled beads according to the mass ratio of 3:1, placing the mixture in an electric stirrer, stirring the mixture for 1-3 hours, taking out the mixture, filtering the mixture, and finally placing the primary heating ink in a sand mill, and grinding the mixture until the particle size is below 5 microns to obtain the low-voltage heating ink.
In the preparation process of the low-voltage heating ink, xanthan gum, conductive fillers such as carbon black, graphite and carbon nano tubes and deionized water can form a stable three-dimensional network structure, so that graphene, carbon black and graphite generated in the mechanical grinding process have better dispersion stability; the xanthan gum serving as the biomass hydrogel can form a reversible hydrogel with solvents such as deionized water and the like, free water molecules in the ink are reduced, the viscosity of the ink is improved, the reversible hydrogel enables the viscosity of the prepared low-voltage heating ink to be larger than 10000mPa & s in a standing state, the viscosity of the low-voltage heating ink is reduced to 4000-5000 mPa & s under stirring at a rotating speed of 60r/min, and the viscosity of the low-voltage heating ink is recovered to be more than 10000mPa & s after stirring is stopped.
Example 1:
weighing 7% of water-based acrylic resin, 7% of rosin resin, 6% of graphite, 10% of carbon black, 35% of carbon nanotube dispersion liquid, 0.5% of formamide, 0.5% of ethanolamine, 5% of Disponer W-518 type water-based wetting dispersant, 0.3% of xanthan gum, 0.5% of TEGO Foamex 805 type water-based defoaming agent and 28.2% of deionized water according to parts by mass.
Placing 7% of water-based acrylic resin, 7% of rosin resin, 0.5% of formamide, 0.5% of ethanolamine and 28.2% of deionized water in a stirring kettle, stirring for 5-10 min, after uniformly mixing, sequentially adding 10% of carbon black, 6% of graphite, 35% of carbon nanotube dispersion liquid and 0.3% of xanthan gum, uniformly stirring, finally adding 5% of Disponer W-518 type water-based wetting dispersant and 0.5% of TEGO Foamex 805 type water-based defoaming agent, and uniformly stirring to form primary heating ink; mixing the primary heating ink and the ball-milled beads according to the mass ratio of 3:1, placing the mixture in an electric stirrer to be mixed and dispersed for 2 hours, taking out the mixture to be filtered, and finally placing the primary heating ink in a sand mill to be ground until the particle size is below 5 mu m to obtain the low-voltage heating ink.
The low-voltage heating ink obtained in the embodiment has the viscosity of 9000-11000 mPa & s under stirring at the rotating speed of 12r/min, the viscosity of 4000-5000 mPa & s under stirring at the rotating speed of 60r/min, the thickness of the dried ink layer is 15-18 mu m, the low-voltage heating ink can be used for screen printing of a 200-mesh silk screen printing plate once, and the sheet resistance value of the low-voltage heating ink is 9.6 omega/25 mu m. The saturation temperature of the low-voltage heating ink heating module with the size of 2cm multiplied by 2.5cm under the working voltage of 3V can reach 80 ℃.
The measurement conditions were as follows: 1. square resistance: measurement using a four-probe sheet resistance tester
2. Viscosity: measurement using a rotational viscometer
3. Saturation temperature: measured using an infrared camera.
FIG. 2(a) is a graph showing the operation of the 3cm by 3cm low voltage heating ink packs prepared in example 1 of the present invention at different voltages. And respectively switching on heating data of direct current voltages of 1.0v, 1.5v, 2.0v, 2.5v and 3.0v, and testing the temperature response rate of the low-voltage heating ink block and the saturation temperature of the low-voltage heating ink block at each working voltage. The temperature influence speed is fast, the saturation temperature can be reached by switching on the power supply for about 10s, the required voltage is extremely low, the heating efficiency is high, and the heating rate is fast. When 1.0v of voltage is applied to the low-voltage heating ink block, the passing working current is 0.28A, and the saturation temperature which can be reached is about 47 ℃; when 1.5v voltage is switched on, the passing working current is 0.428A, and the saturation temperature is 70 ℃; when 2.0v of voltage is applied, the working current is 0.583A, and the saturation temperature is 100 ℃; when 2.5v of voltage is applied, the working current is 0.749A, and the saturation temperature is 130 ℃; when 3.0v voltage was applied, the operating current was 0.915A, and the saturation temperature reached by the low voltage heat-generating ink block was about 175 ℃. The prepared low-voltage heating ink block has very high electrothermal radiation conversion efficiency, extremely low required working voltage and safer use of the low-voltage heating ink. Fig. 2(b) shows the operation of the low-voltage heating ink block under the condition of continuously changing voltage, the voltage applied to the low-voltage heating ink block is continuously increased from 1.0v to 3.0v at intervals of 0.5v, and it can be seen that the response rate and the heating stability are very stable, and the saturation temperature reached at the same voltage is consistent with that of the graph in fig. 2 (a). According to an electrothermal radiation conversion efficiency formula: β ═ S α (T) r 4-T0 4) P, where β is the electrothermal radiation conversion efficiency of the electrothermal film, S is the heating area of the electrothermal film, and α is the Spander-Boltzmann constant (5.67 × 10)-8In the unit of W/m2K4),TrIs the saturation temperature, T, at a certain operating voltage0P is the ambient temperature and electric power. According to the formula, the electrothermal radiation conversion efficiency beta of the low-voltage heating ink block under the working voltage of 3v is 74.75 percent, which is about 10 percent higher than that of the traditional electrothermal material.
The carbon material is stable in chemical property, can stably exist in the air, is not suitable for reacting with oxygen, the aqueous acrylic resin used by the low-voltage heating ink block is stable and does not decompose in the air below 250 ℃, and the conductive carbon particles are stable and does not decompose in the air below 400 ℃, so that the prepared low-voltage heating ink block can continuously and stably work at the running temperature below 200 ℃. To further verify that the low voltage heat-generating ink block can continuously and stably operate at high temperature (175 ℃), the low voltage heat-generating ink block is modulated to have higher working voltage (3.0v) and is kept for more than 4h in the operation state at 175 ℃. As shown in fig. 3, the temperature and time variation relationship shows that the saturation temperature remains unchanged in the high temperature state, which indicates that the electrothermal infrared radiation efficiency of the low voltage heat-generating ink block and the composition and performance of the ink are not changed, which is enough to prove that the stability of the low voltage heat-generating ink in the air and in the high temperature state is very outstanding.
Fig. 4 shows a functional relationship between the heating temperature and the power density of the low-voltage heating ink block prepared in this embodiment, and a fitted curve of the temperature and the power density is approximately linear (T ═ 249 × P +37, T is the temperature, and P is the energy density), and as can be seen from the graph, the slope is steep (about 249.53 ℃ c, cm2W-1), which indicates that the saturation temperature that can be reached per unit area under the same power density condition is higher, i.e., the electrothermal infrared radiation efficiency is higher, which indicates that the electrothermal infrared radiation efficiency of the low-voltage heating ink block prepared based on this embodiment is higher, and the energy consumption is lower.
Fig. 5 is a graph of the volt-ampere (V-a) relationship of the low voltage heat-generating ink stick prepared in this example, and it can be seen from the fitted curve that the voltage V applied to the low voltage heat-generating ink stick is almost proportional to the passing current a, which shows that the resistance of the low voltage heat-generating ink stick does not change with the increase of temperature (the saturation temperature is 47 ℃ at 1.0V to 175 ℃ at 3.0V), i.e., the resistance does not change with the change of temperature.
Fig. 6 is a graph of the relationship between the input voltage and the saturation temperature of the low-voltage heat-generating ink block prepared in this example, and it can be seen from the fitted curve in the graph that the saturation temperature reached when the low-voltage heat-generating ink block is powered on is exponential to the voltage applied at both ends: t ═ A 1exp(-V/t1)-y0Where T is the saturation temperature of the electrothermal film, V is the voltage at which it is switched on, A1=39.98±13.40,t1=-1.91±0.31,y0-14.84 ± 16.71. The exponential relationship between temperature and voltage shows that the conversion efficiency of the low-voltage heat-generating ink block prepared in the embodiment through infrared heat radiation is high.
The low-voltage heating ink block is placed in a room-temperature air environment, the same voltage of 3.0v is applied to the same low-voltage heating ink block for ten consecutive days, the temperature response rate and the maximum saturation temperature of the low-voltage heating ink block are almost unchanged, the stable operation in the air is shown, and the advantage of the low-voltage heating ink block is obvious compared with some metal electrothermal materials (such as silver electrothermal materials) which are easy to oxidize in the air. In addition, in order to verify that the folding resistance test of the flexible electric heating material is carried out for 2500 folds continuously, the resistance of the low-voltage heating ink block is not changed obviously, and the resistance is regular along with the change of the bending angle, which shows that after 2500 folds, the ink on the flexible electric heating film is connected perfectly and is not broken. The pressure resistance of the material is extremely outstanding and is 1x10 when the material is subjected to pressure test by a tablet press5The structure is not destroyed under a pressure below kpa.
Example 2:
weighing 7% of water-based acrylic resin, 7% of rosin resin, 5% of graphite, 10% of carbon black, 35% of carbon nanotube dispersion liquid, 1% of ethanolamine, 5% of Disponer W-920 type water-based wetting dispersant, 0.3% of xanthan gum, 0.5% of DefomW-0506 type water-based defoaming agent and 29.2% of deionized water according to parts by mass.
Placing 7% of water-based acrylic resin, 7% of rosin resin, 1% of ethanolamine and 29.2% of deionized water in a stirring kettle, stirring for 5-10 min, after uniformly mixing, sequentially adding 10% of carbon black, 5% of graphite, 35% of carbon nanotube dispersion liquid and 0.3% of xanthan gum, uniformly stirring, finally adding 5% of Disponer W-920 type water-based wetting dispersant and 0.5% of DefomW-0506 type water-based defoaming agent, and uniformly stirring to form primary heating ink; mixing the primary heating ink and the ball-milled beads according to the mass ratio of 3:1, placing the mixture in an electric stirrer to be mixed and dispersed for 2.5h, taking out and filtering the mixture, and finally placing the primary heating ink in a sand mill to be ground until the particle size is below 5 mu m to obtain the low-voltage heating ink.
The low-voltage heating ink obtained in the embodiment has the viscosity of 9000-11000 mPa & s under stirring at the rotating speed of 12r/min, the viscosity of 4000-5000 mPa & s under stirring at the rotating speed of 60r/min, the thickness of the dried ink layer is 15-18 mu m, the low-voltage heating ink can be used for screen printing of a 200-mesh silk screen printing plate once, and the sheet resistance value of the low-voltage heating ink is 10.6 omega/25 mu m. The saturation temperature of the low-voltage heating ink heating module with the size of 2cm multiplied by 2.5cm under the working voltage of 5V can reach 72 ℃.
Example 3:
respectively weighing 10% of waterborne acrylic resin, 5% of rosin resin, 12% of graphite, 6% of carbon black, 40% of carbon nanotube dispersion liquid, 1.5% of ammonia water, 5% of NUOSPERSE FX 365 type waterborne wetting dispersant, 0.4% of xanthan gum, 1% of SF-809B type standard American silicon fluorine defoaming agent and 19.1% of deionized water according to the mass parts.
Placing 10% of water-based acrylic resin, 5% of rosin resin, 1.5% of ethanolamine and 19.1% of deionized water in a stirring kettle, stirring for 5-10 min, after uniformly mixing, sequentially adding 6% of carbon black, 12% of graphite, 40% of carbon nanotube dispersion and 0.4% of xanthan gum, uniformly stirring, finally adding 5% of NUEROSPSE FX 365 type water-based wetting dispersant and 1% of SF-809B type standard silicon fluorine defoaming agent, and uniformly stirring to form primary heating ink; mixing the primary heating ink and the ball-milled beads according to the mass ratio of 3:1, placing the mixture in an electric stirrer to be mixed and dispersed for 2.5h, taking out and filtering the mixture, and finally placing the primary heating ink in a sand mill to be ground until the particle size is below 5 mu m to obtain the low-voltage heating ink.
The low-voltage heating ink obtained in the embodiment has the viscosity of 15000-20000 mPa & s under stirring at the rotating speed of 12r/min, the thickness of the dried ink layer is 20-22 mu m, the low-voltage heating ink can be used for screen printing of a 200-mesh silk screen plate once, and the sheet resistance value of the low-voltage heating ink is 8.9 omega/25 mu m. The saturation temperature of the low-voltage heating ink heating module with the size of 2cm multiplied by 2.5cm under the working voltage of 5V can reach 76 ℃.
Example 4:
weighing 5% of water-based acrylic resin, 10% of rosin resin, 9% of graphite, 6% of carbon black, 30% of carbon nanotube dispersion liquid, 0.5% of ethanolamine, 4% of a mixture of Disponer W-920 type water-based wetting dispersant and NUOSPERSE FX 600 type water-based wetting dispersant, 0.5% of xanthan gum, 0.5% of TEGO Foamex 805 type water-based defoaming agent and 34.5% of deionized water according to parts by mass.
Placing 5% of water-based acrylic resin, 10% of rosin resin, 0.5% of ethanolamine and 34.5% of deionized water in a stirring kettle, stirring for 5-10 min, after uniformly mixing, sequentially adding 6% of carbon black, 9% of graphite, 30% of carbon nanotube dispersion and 0.5% of xanthan gum, uniformly stirring, finally adding a mixed solution of 4% of Disponer W-920 type water-based wetting dispersant and NUOSPERSE FX 600 type water-based wetting dispersant and 0.5% of TEGO Foamex 805 type water-based defoaming agent, and uniformly stirring to form primary heating ink; mixing the primary heating ink and the ball-milled beads according to the mass ratio of 3:1, placing the mixture in an electric stirrer to be mixed and dispersed for 3 hours, taking out the mixture to be filtered, and finally placing the primary heating ink in a sand mill to be ground until the particle size is below 5 mu m to obtain the low-voltage heating ink.
The low-voltage heating ink obtained in the example has viscosity of 12000mPa & s under stirring at a rotating speed of 12r/min, the thickness of the dried ink layer is 19 μm, the low-voltage heating ink can be used for screen printing of a 200-mesh screen printing plate once, and the sheet resistance value of the low-voltage heating ink is 9.6 omega/25 μm. The saturation temperature of the low-voltage heating ink heating module with the size of 2cm multiplied by 2.5cm under the working voltage of 5V can reach 70 ℃.
Example 5:
respectively weighing 10% of water-based acrylic resin, 10% of rosin resin, 15% of graphite, 10% of carbon black, 1.5% of ethanolamine, 5% of NUOSPERSE FX 365 type water-based wetting dispersant, 1% of DefomW-0506 type water-based defoaming agent and 47.5% of deionized water according to parts by weight.
Placing 10% of water-based acrylic resin, 10% of rosin resin, 1.5% of ethanolamine and 47.5% of deionized water in a stirring kettle, stirring for 5-10 min, after uniformly mixing, sequentially adding 10% of carbon black and 15% of graphite, uniformly stirring, finally adding 5% of NUOSPERSE FX 365 type water-based wetting dispersant and 1% of DefomW-0506 type water-based defoaming agent, and uniformly stirring to form primary heating ink; mixing the primary heating ink and the ball-milled beads according to the mass ratio of 3:1, placing the mixture in an electric stirrer to be mixed and dispersed for 3 hours, taking out the mixture to be filtered, and finally placing the primary heating ink in a sand mill to be ground until the particle size is below 5 mu m to obtain the low-voltage heating ink.
The low-voltage heating ink obtained in the example has a viscosity of 18000mPa · s under stirring at a rotation speed of 12r/min, has a thickness of 23 μm after drying, can be used for screen printing of a 200-mesh screen printing plate once, and has a sheet resistance value of 12.8 Ω/25 μm. The saturation temperature of the low-voltage heating ink heating module with the size of 2cm multiplied by 2.5cm under the working voltage of 5V can reach 68 ℃.
Example 6:
weighing 7.5% of water-based acrylic resin, 7.5% of rosin resin, 5% of graphite, 8% of carbon black, 50% of carbon nanotube dispersion liquid, 0.8% of ammonia water, 1% of Disponer W-920 type water-based wetting dispersant, 1% of xanthan gum, 0.3% of mixed liquid of TEGO Foamex 805 type water-based defoamer and SF-809B type standard silicon fluorine defoamer and 18.9% of deionized water according to parts by weight.
Placing 7.5% of water-based acrylic resin, 7.5% of rosin resin, 0.8% of ammonia water and 18.9% of deionized water in a stirring kettle, stirring for 5-10 min, after uniformly mixing, sequentially adding 8% of carbon black and 5% of graphite, uniformly stirring, finally adding a mixed solution of 1% of Disponer W-920 type water-based wetting dispersant, 0.3% of TEGO Foamex 805 type water-based defoaming agent and SF-809B type standard silicon fluorine defoaming agent, and uniformly stirring to form primary heating ink; mixing the primary heating ink and the ball-milled beads according to the mass ratio of 3:1, placing the mixture in an electric stirrer to be mixed and dispersed for 1h, taking out the mixture to be filtered, and finally placing the primary heating ink in a sand mill to be ground until the particle size is below 5 mu m to obtain the low-voltage heating ink.
The low-voltage heating ink obtained in the embodiment has the viscosity of 11000mPa & s under the stirring at the rotating speed of 12r/min, the thickness of the dried ink layer is 18 mu m, the low-voltage heating ink can be used for screen printing of a 200-mesh screen printing plate once, and the sheet resistance value of the low-voltage heating ink is 9.0 omega/25 mu m. The saturation temperature of the low-voltage heating ink heating module with the size of 2cm multiplied by 2.5cm under the working voltage of 5V can reach 76 ℃.
Example 7:
weighing 8% of water-based acrylic resin, 5% of rosin resin, 12% of graphite, 3% of carbon black, 40% of carbon nanotube dispersion liquid, 0.5% of formamide, 0.5% of ethanolamine, 3% of NUOSPERSE FX 365 type water-based wetting dispersant, 0.3% of xanthan gum, 0.6% of DefomW-0506 type water-based defoaming agent and 27.1% of deionized water according to parts by mass.
Placing 8% of water-based acrylic resin, 5% of rosin resin, 0.5% of formamide, 0.5% of ethanolamine and 27.1% of deionized water in a stirring kettle, stirring for 5-10 min, after uniformly mixing, sequentially adding 3% of carbon black and 12% of graphite, uniformly stirring, finally adding 3% of NUOSPERSE FX 365 type water-based wetting dispersant and 0.6% of DefomoW-0506 type water-based defoaming agent, and uniformly stirring to form primary heating ink; mixing the primary heating ink and the ball-milled beads according to the mass ratio of 3:1, placing the mixture in an electric stirrer to be mixed and dispersed for 2.5h, taking out and filtering the mixture, and finally placing the primary heating ink in a sand mill to be ground until the particle size is below 5 mu m to obtain the low-voltage heating ink.
The low-voltage heat-generating ink obtained in the example has a viscosity of 13000mPa · s under stirring at a rotation speed of 12r/min, has a thickness of 21 μm after drying, can be used for screen printing of a 200-mesh screen printing plate once, and has a sheet resistance value of 10.9 Ω/25 μm. The saturation temperature of the low-voltage heating ink heating module with the size of 2cm multiplied by 2.5cm under the working voltage of 5V can reach 71 ℃.
The low-voltage heating ink provided by the invention can obtain a better heating effect under a lower working voltage; the low-voltage heating ink has high viscosity and high thixotropy, the viscosity of the ink is instantly reduced under the action of shearing force in the printing process to form a thick carbon film, the viscosity is rapidly improved after the printing is finished, the ink is prevented from diffusing on a printing stock, the printing adaptability of the ink is improved, and the low-voltage heating ink is suitable for screen printing. The xanthan gum in the components can play a role in dispersing graphene, carbon black and graphite, can replace part of acrylic resin, and the addition of a small amount of rosin resin can make up the poor adhesive force and mechanical property of the xanthan gum; under the combined action of the xanthan gum and the rosin resin, the overall proportion of acrylic resin in the ink is reduced, the xanthan gum and the rosin resin are both biomass materials, the energy-saving and environment-friendly effects can be achieved, and in addition, the addition of the xanthan gum and the rosin resin enables the proportion of conductive fillers such as carbon black, graphite and carbon nano tubes in a carbon film formed after the prepared low-voltage heating ink is dried to be increased, and the conductivity is excellent.

Claims (10)

1. The utility model provides a packing carton generates heat, includes outer box and interior box at least, its characterized in that: a low-voltage heating ink layer is arranged on the outer side of the bottom of the inner box, and a power supply is arranged in the outer box; when the inner box is arranged inside the outer box, the low-voltage heating ink layer and the power supply form a loop.
2. A heat generation packing box according to claim 1, wherein: the power supply is a USB interface or a switch and a battery which can be connected with electricity, the USB interface or the switch is positioned on the side wall of the outer box, and the low-voltage heating ink layer is connected with the power supply through conductive ink or conductive metal.
3. A heat generation packing box according to claim 2, wherein: and a limit stop for limiting the position of the inner box is arranged in the outer box, and the conductive ink or the conductive metal is arranged on the limit stop.
4. A heat generation packing box according to claim 1, wherein: the size of the low-voltage heating ink layer is 15cm multiplied by 15cm, and the power supply voltage is 36V.
5. A heat generation packing box according to claim 1, wherein: the heating packaging box is also provided with a box cover.
6. A heat generation packing box according to claim 1, wherein: the low-voltage heating ink layer comprises the following components in percentage by mass: 5-10% of water-based acrylic resin, 5-10% of rosin resin, 5-15% of graphite, 3-10% of carbon black, 0-50% of carbon nanotube dispersion liquid, 0.5-1.5% of pH regulator, 1-5% of dispersing agent, 0-1% of xanthan gum, 0.5-1% of defoaming agent and 10-50% of deionized water.
7. A heat generation pack according to claim 6, wherein: the low-voltage heating ink layer is formed by coating low-voltage heating ink on the outer side of the bottom of the inner box through a screen printing or coating method.
8. A heat generation pack according to claim 6, wherein: the pH regulator is one or more of formamide, ethanolamine or ammonia water mixed in any proportion.
9. A heat generation pack according to claim 6, wherein: the dispersant is one of Dispenser W-518 type aqueous wetting dispersant, Dispenser W-920 type aqueous wetting dispersant, NUOSPERSE FX 600 type aqueous wetting dispersant or NUOSPERSE FX 365 type aqueous wetting dispersant or a mixture of the two in any proportion.
10. A heat generation pack according to claim 6, wherein: the defoaming agent is one or more of a DefomW-0506 type waterborne defoaming agent, a TEGO Foamex 805 type waterborne defoaming agent or a SF-809B type standard silicon fluoride defoaming agent which is mixed in any proportion.
CN202010697829.7A 2020-07-17 2020-07-17 Packing carton generates heat Pending CN111846633A (en)

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