CN211047260U - Soaking scald preventing graphite alkene piece that generates heat - Google Patents

Abstract

The utility model relates to a soaking scald preventing graphene heating sheet, which comprises an insulating carrier film, a conductive coating on the carrier film, a resistance heating coating on the carrier film and covering a positive electrode wire and a negative electrode wire, and an insulating coating film arranged on the carrier film. The positive electrode wire of the conductive coating is provided with a first end facing the unconnected bus bar and protruding out of the resistance heating coating, and the negative electrode wire is provided with a second end facing the unconnected bus bar and protruding out of the resistance heating coating so as to optically detect the coating position of the resistance heating coating. In one example, the end of the electrode wire forms a unit test point exposed to the resistive heating coating to realize the resistance detection of the individual heating module in the manufacturing process.

Description

Soaking scald preventing graphite alkene piece that generates heat

Technical Field

The utility model belongs to the technical field of the technique that graphite alkene generates heat and specifically relates to a soaking scald preventing graphite alkene piece that generates heat is related to.

Background

The thin film heating sheet which utilizes the graphene film layer to generate heat mechanically forms a heating bag which generates heat or/and chemically reacts with a warm bag, so that the thin film heating sheet is more suitable for human bodies and has the characteristic of environmental protection, the thin film heating sheet can be repeatedly used, the thin film heating sheet is easy to attach and use, the small film heating sheet can be conveniently carried or can be clamped in clothes. The quality problem that people are easily scalded in the use that can not uniformly generate heat generally exists in the existing heating sheet technology and products in the market. One of the main reasons for analyzing the uniformity and thickness consistency of the heating film is that a graphene film layer formed in advance is purchased from an external import and is attached to a PI substrate in a factory, which has the highest manufacturing cost and is not independently controllable at present, and the heating efficiency of the heating sheet is also affected by the installation error during attachment. However, when the heating film is directly printed on the PI substrate in a coating manner, the variation of the local resistance value due to the difference of the concentration uniformity and the thickness variation of the material printed on the substrate by the coating affects the abnormal variation of the local resistance value, resulting in the inconsistency of the resistance value, and when the resistance of a certain heating area is lower than that of the adjacent heating area, the local heating increase abnormality is caused, even the skin of the human body is scalded.

The technology that a graphene heating sheet is fixed by a graphene membrane assembly in a bonding mode is taught in Chinese patent publication No. CN110177402A, and discloses a graphene electric blanket, wherein the graphene electric blanket is characterized in that a bottom layer is an anti-slip layer, a surface layer is a decorative layer, the heating sheet is laid between the bottom layer and the surface layer, the heating sheet comprises an upper layer of insulating cloth and a lower layer of insulating cloth and a graphene heating sheet in a middle layer, the graphene heating sheets are distributed at intervals, copper leads are fixed on the left side and the right side of the graphene heating sheet, the graphene heating sheets are arranged at intervals, and the graphene heating sheets and the copper leads are bonded in the upper layer of insulating cloth and the lower layer of insulating cloth; the copper wire is used for connecting with a power line. The other traditional method is to coat graphene slurry on a soft base material and then add a copper electrifying conductive material to prepare the graphene-based conductive material.

Another teaching of an assembled graphene heater adopting a graphene membrane separation design is in chinese patent publication No. CN107396468A, which discloses a far infrared heating module, comprising: the graphene heating membrane comprises a first surface and a second surface; the front plate is arranged on the first surface and provided with a hollow part; the blank holder strip is arranged at the edge of the second surface; the graphene heating membrane is fixed by the front plate and the edge pressing strip; the graphene heating membrane comprises a single-layer or multi-layer graphene membrane and parallel strip-shaped electrodes arranged at two opposite edges of the graphene membrane, wherein the graphene membrane and the parallel strip-shaped electrodes are clamped between two insulating films.

Disclosure of Invention

The utility model aims at providing a soaking scald preventing graphite alkene piece that generates heat can get rid of the local that resistance heating coating position is inaccurate to cause in advance in the processing procedure and generate heat unusually to solve the human quality problem of scald, can realize carrying out resistance measurement to the district module that generates heat in the processing procedure even in the preferred example, can get rid of resistance heating coating thickness nonconformity in advance in the processing procedure, the local that the material composition distributes the inhomogeneous and cause generates heat unusually, evenly generate heat with the realization product, in order to solve the human quality problem of scald more comprehensively.

The utility model discloses a main objective second provides a preparation method of soaking scald preventing graphite alkene piece that generates heat for preparation can soak scald preventing graphite alkene piece that generates heat, can carry out resistance measurement to the district heating module even in the preferred example in the processing procedure.

The utility model discloses a main objective can be realized through following technical scheme:

the utility model provides a soaking scald preventing graphite alkene piece that generates heat includes:

an insulating carrier film;

the conductive coating is formed on the insulating carrier film and comprises a positive electrode pattern and a negative electrode pattern which are not directly electrically connected with each other, the positive electrode pattern is integrally formed with a plurality of positive electrode wires and a first bus bar connected with the positive electrode wires, the negative electrode pattern is integrally formed with a plurality of negative electrode wires and a second bus bar connected with the negative electrode wires, and the positive electrode wires and the negative electrode wires are arranged in an equidistant staggered mode to separate a plurality of heating modules;

a resistance heating coating formed on the insulating carrier film, the resistance heating coating being located between the first bus bar and the second bus bar and covering the positive electrode wire, the negative electrode wire and the thin film part between the positive electrode wire and the negative electrode wire, wherein the positive electrode wire has a first end facing the second bus bar and protruding from the resistance heating coating, the negative electrode wire has a second end facing the first bus bar and protruding from the resistance heating coating, and

and the insulating coating is arranged on the insulating carrier film.

Through adopting above-mentioned basic technical scheme a whole, utilize conductive coating with resistance heating coating forms in proper order on the insulating carrier film, and keep positive electrode line with negative electrode line respectively has outstanding in the first end and the second end of resistance heating coating to optical detection in the processing procedure in the soaking scald preventing graphite alkene heating plate resistance heating coating is right conductive coating's the coverage degree of accuracy is got rid of in advance resistance heating coating covers inaccurate heating plate.

The present invention may be further configured in a preferred embodiment as: the first end is provided with a first unit test point exposed out of the resistance heating coating, and the second end is provided with a second unit test point exposed out of the resistance heating coating.

By adopting the preferable technical scheme, the resistance of the individual heating module between the positive electrode wire and the negative electrode wire can be detected in the process by utilizing that the first unit test point and the second unit test point are not covered by the resistance heating coating, and the heating sheets with uneven covering thickness of the resistance heating coating or/and uneven distribution formed after printing of the resistance heating coating are eliminated in advance.

The present invention may be further configured in a preferred embodiment as: the length of the first end and the second end exceeding the resistance heating coating is 0.5-3 mm, preferably 1-2 mm.

By adopting the above preferred technical solution, the resistance of the individual heating module between the positive electrode wire and the negative electrode wire can be pinpointed by using the length range of the resistance heating coating beyond the first end and the second end without damaging the resistance heating coating, for example, a probe with a needle diameter of 0.5mm can be used for pinpointing.

The present invention may be further configured in a preferred embodiment as: the heating gap between the adjacent positive electrode wire and the negative electrode wire is 0.4-1.2 cm, preferably, a first gap is formed between the first end and the second bus bar, a second gap is formed between the second end and the first bus bar, third gaps are respectively formed between the resistance heating coating and the first bus bar and between the resistance heating coating and the second bus bar, preferably, the first gap and the second gap are 0.5-3.0 mm, and the third gap is 2.0-5.0 mm.

By adopting the above preferred technical scheme, because the resistance heating coating layer covers the thin film part between the positive electrode wire and the negative electrode wire and also covers the electrode wires, electrical contact for realizing resistance heating is formed, then a plurality of strip-shaped and adjacent heating modules are established by utilizing the heating gap range between the positive electrode wire and the negative electrode wire, preferably, the third gap is larger than the first gap and the second gap, so that the first gap between the first end of the positive electrode wire and the second bus bar and the second gap between the second end of the negative electrode wire and the first bus bar are ensured not to have the residue of the resistance heating coating layer, a resistance short path is not established between the bus bar and the electrode wires which are close to but not connected, and the first bus bar and the second bus bar can be arranged close to each other as much as possible, so as to achieve the effect of size densification.

The present invention may be further configured in a preferred embodiment as: the arrangement mode of the positive electrode wires and the negative electrode wires is linear staggered intervals or wavy staggered intervals.

By adopting the preferable technical scheme, the shape change of the heating modules is realized by utilizing the arrangement form of the positive electrode wires and the negative electrode wires, for example, a plurality of straight strip-shaped heating modules are provided at linear staggered intervals, and for example, a plurality of wavy heating modules are provided at wavy staggered intervals.

The present invention may be further configured in a preferred embodiment as: the resistance heating coating is in positive electrode line with seted up a plurality of holes of dodging between the negative electrode line, insulating carrier film has seted up a plurality of alignments and is in dodge downthehole bleeder vent, the bleeder vent has and is less than dodge the size in hole and run through to insulating tectorial membrane.

Through adopting above-mentioned preferred technical scheme, utilize dodge the hole the bleeder vent, both positions the form and the dimensional relation of running through of bleeder vent make soaking scald preventing graphite alkene generate heat the piece and have ventilation function, and the resistance heating coating is sealed completely, reaches water-proof effects.

The present invention may be further configured in a preferred embodiment as: the thickness of the polyester film of the insulating carrier film is 0.025-0.1 mm, more preferably 0.038-0.05 mm, the thickness of the polyester film of the insulating laminating film is smaller than that of the polyester film of the insulating carrier film, preferably 0.025-0.038 mm, the painting thickness of the conductive coating is 4-12 mu m, the total film thickness of the soaking anti-scald graphene heating sheet is 0.08-0.4 mm, preferably, the conductive coating comprises a silver paste coating, and the resistance heating coating comprises a graphene heating coating.

Through adopting above-mentioned preferred technical scheme, utilize specific polyester film thickness scope, conductive coating to brush on the thickness scope with the total membrane thickness scope of soaking scald preventing graphite alkene piece that generates heat, make soaking scald preventing graphite alkene piece that generates heat has enough thin structure, attaches human body or clothing surface more easily.

The utility model discloses a main objective can realize through following technical scheme secondly:

the preparation method of the soaking anti-scald graphene heating sheet comprises the following steps:

providing an insulating carrier film, wherein the insulating carrier film is provided with a printing surface;

printing a conductive coating on the printing surface of the insulating carrier film for the first time, wherein the conductive coating comprises a positive electrode pattern and a negative electrode pattern which are not directly electrically connected with each other, the positive electrode pattern is integrally formed with a plurality of positive electrode wires and a first bus bar connected with the positive electrode wires, the negative electrode pattern is integrally formed with a plurality of negative electrode wires and a second bus bar connected with the negative electrode wires, and the positive electrode wires and the negative electrode wires are arranged in an equidistant staggered mode to separate a plurality of heating modules;

printing for the second time on the printing surface of the insulating carrier film to form a resistance heating coating, wherein the resistance heating coating is positioned between the first bus bar and the second bus bar and covers the positive electrode wire, the negative electrode wire and the thin film part between the positive electrode wire and the negative electrode wire, the positive electrode wire is provided with a first end facing the second bus bar and protruding out of the resistance heating coating, the negative electrode wire is provided with a second end facing the first bus bar and protruding out of the resistance heating coating, and

and arranging an insulating film on the printing surface of the insulating film.

By adopting the whole of the second basic technical scheme, the preparation of the soaking anti-scald graphene heating sheet is realized, the covering accuracy of the resistance heating coating relative to the conductive coating can be optically detected in the manufacturing process or the finished product before the insulating coating is arranged, and the heating sheet with inaccurate coverage of the resistance heating coating is excluded in advance.

The present invention may be further configured in a preferred embodiment as: the manufacturing method comprises the steps that a first unit test point exposed out of the resistance heating coating is formed at the first end on the printing surface, a second unit test point exposed out of the resistance heating coating is formed at the second end on the printing surface, the first unit test point and the second unit test point are detected before the insulation coating is arranged to measure the resistance between the positive electrode wire and the adjacent negative electrode wire, and the length of the first end and the length of the second end exceeding the resistance heating coating are preferably 0.5-3 mm and are preferably 1-2 mm.

By adopting the above preferred technical scheme, the resistance of the individual heating module between the positive electrode wire and the negative electrode wire can be detected in the process by detecting the first unit test point and the second unit test point on the printing surface before the insulating coating is arranged, and the heating sheets with uneven covering thickness of the resistance heating coating or/and uneven distribution formed after printing of the resistance heating coating are eliminated in advance.

The present invention may be further configured in a preferred embodiment as: the thickness of the polyester film of the insulating carrier film is 0.025-0.1 mm, more preferably 0.038-0.05 mm, the thickness of the polyester film of the insulating laminating film is smaller than that of the polyester film of the insulating carrier film, preferably 0.025-0.038 mm, the painting thickness of the conductive coating is 4-12 mu m, the total film thickness of the soaking anti-scald graphene heating sheet is 0.08-0.4 mm, preferably, the conductive coating comprises a silver paste coating, and the resistance heating coating comprises a graphene heating coating.

To sum up, the utility model discloses a following at least one useful technological effect:

1. the provided soaking anti-scald graphene heating sheet can be particularly applied to wearable equipment or clothes, and unqualified products with poor resistance heating coating coverage or products which are easy to damage in early stage can be eliminated in the manufacturing process;

2. providing a uniform heating anti-scald graphene heating sheet, and achieving the purpose of eliminating unqualified products which are formed by uneven composition materials or/and poor thickness coverage or easily damaged at early stage in the resistance heating coating in the manufacturing process;

3. the soaking anti-scald graphene heating sheet can be prepared, and defective products or products which are easy to damage in the early stage and caused by factors of the resistance heating coating can be eliminated in the manufacturing process;

4. the bus bar is integrated in the heating sheet in the preparation process of the soaking anti-scald graphene heating sheet, and the resistance heating coating is completely sealed, so that the waterproof effect is achieved;

5. the quality problem that in the prior art, a resistance heating coating such as a graphene heating coating is directly formed on a graphene heating sheet on an insulating carrier film, when the graphene heating sheet is used, part of products can not uniformly heat, and the skin of a human body is scalded is solved.

Drawings

Fig. 1 is a schematic bottom view and a partial enlarged view of a portion of a soaking anti-scald graphene heating sheet according to a first preferred embodiment of the present invention, which is opposite to a printing surface;

fig. 2 is a schematic top view and a partial enlarged view of a part of the soaking anti-scald graphene heating sheet facing the printing surface according to the first preferred embodiment of the present invention;

fig. 3 is a schematic partial sectional view of a soaking anti-scald graphene heating sheet according to a first preferred embodiment of the present invention;

fig. 4 is a flowchart illustrating a process for manufacturing a soaking anti-scald graphene heating sheet according to a second preferred embodiment of the present invention;

fig. 5A to 5D are schematic cross-sectional views of partial components in each main step of a preparation process of a soaking anti-scald graphene heating sheet according to a second preferred embodiment of the present invention;

fig. 6 is a schematic top view of a part of the soaking anti-scald graphene heating sheet according to the first preferred embodiment of the present invention, which faces the printing surface when the test is good;

fig. 7 is a schematic top view of a portion of the soaking anti-scald graphene heating sheet according to the first preferred embodiment of the present invention, which faces the printing surface when the first test is abnormal;

fig. 8 is a schematic top view of a part of the soaking anti-scald graphene heating sheet according to the first preferred embodiment of the present invention, which faces the printing surface when the second test is abnormal;

fig. 9 is a schematic partial bottom view of another soaking anti-scald graphene heating sheet according to a third preferred embodiment of the present invention, viewed from the back of the printing surface;

fig. 10 is a schematic top view of a part of a soaking anti-scald graphene heating sheet facing a printing surface according to a third preferred embodiment of the present invention;

fig. 11 is a schematic partial sectional view of a soaking anti-scald graphene heating sheet according to a third preferred embodiment of the present invention;

fig. 12 is a schematic top view of another soaking anti-scald graphene heating sheet according to a fourth preferred embodiment of the present invention, which is facing the printing surface.

The test method comprises the following steps of reference numeral 10, an insulating carrier film, 11, a printing surface, 12, an air hole, 20, a conductive coating, 21, a positive electrode wire, 22, a negative electrode wire, 23, a first bus bar, 24, a second bus bar, 25, a first end 26, a second end, 27, a first unit test point, 28, a second unit test point, 29, a module test point, 30, a resistance heating coating, 31, an avoiding hole, 32, an abnormal area and 40, and insulating coating.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments for understanding the inventive concept of the present invention, and do not represent all the embodiments, nor do they explain the only embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art on the premise of understanding the inventive concept of the present invention belong to the protection scope of the present invention.

It should be noted that, if directional indications (such as upper, lower, left, right, front and rear … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are changed accordingly.

In order to understand the technical scheme of the utility model more conveniently, following will the utility model discloses a soaking scald preventing graphite alkene generates heat the piece and does further detailed description and explanation, nevertheless does not regard as the utility model discloses the protection scope who restricts.

Fig. 1 is a partial bottom view schematic diagram and a partial enlarged view of a back printing surface of a soaking anti-scald graphene heating sheet, and fig. 2 is a partial top view schematic diagram and a partial enlarged view of the soaking anti-scald graphene heating sheet facing the printing surface; fig. 3 is a schematic partial sectional view of the soaking anti-scald graphene heating sheet; referring to fig. 1, 2 and 3, a first embodiment of the present invention provides a soaking anti-scald graphene heating sheet, which comprises an insulating carrier film 10, a conductive coating 20, a resistance heating coating 30 and an insulating coating film 40, according to a forming sequence of a manufacturing process. A waterproof coating (not shown) may be selectively formed between the insulating coating film 40 and the resistance heating coating layer 30.

The insulating carrier film 10 is provided with a printing surface 11, the insulating carrier film 10 can be a PET polyester film, the color can be transparent, white or black, and the insulating carrier film is a transparent insulating carrier film and can be used for observing whether the position of the conductive coating 20 is printed well or not from the bottom surface.

The conductive coating 20 is printed on the printing surface 11 of the insulating carrier film 10, the conductive coating 20 includes a positive electrode pattern and a negative electrode pattern that are not directly electrically connected to each other, the positive electrode pattern integrally forms a plurality of positive electrode lines 21 and a first bus bar 23 connected to the positive electrode lines 21, the negative electrode pattern integrally forms a plurality of negative electrode lines 22 and a second bus bar 24 connected to the negative electrode lines 22, and the positive electrode lines 21 and the negative electrode lines 22 are arranged in an equidistant staggered manner to separate a plurality of heat generating modules. A heating module is located between one of the positive electrode lines 21 and the adjacent negative electrode line 22 and does not extend to the area of the first bus bar 23 and the second bus bar 24, and the conductive coating 20 is a conductive circuit formed by silver paste printing, is formed after printing and curing, and has excellent conductivity and flexibility and fracture resistance. But not limited thereto, the material of the conductive coating 20 may also include conductive carbon, copper, gold, iron, or any combination thereof.

The resistance heating coating 30 is printed on the printing surface 11 of the insulating carrier film 10, the resistance heating coating 30 is located between the first bus bar 23 and the second bus bar 24 and covers the positive electrode line 21, the negative electrode line 22 and the thin film part between the positive electrode line 21 and the negative electrode line 22, wherein the positive electrode line 21 has a first end 25 facing the second bus bar 24 and protruding out of the resistance heating coating 30, and the negative electrode line 22 has a second end 26 facing the first bus bar 23 and protruding out of the resistance heating coating 30. The resistance heating coating 30 is specifically a graphene heat-generating coating.

The insulating coating 40 is provided on the printing surface 11 of the insulating support film 10. One specific material of the insulating coating 40 may be PET polyester.

The implementation principle of the embodiment is as follows: the conductive coating 20 and the resistance heating coating 30 are sequentially printed on the printing surface 11 of the insulating carrier film 10, and the positive electrode wire 21 and the negative electrode wire 22 are respectively provided with a first end 25 and a second end 26 protruding out of the resistance heating coating 30, so that the covering accuracy of the resistance heating coating 30 on the conductive coating 20 in the soaking anti-scald graphene heating sheet is favorably detected optically in the manufacturing process, and the heating sheet with inaccurate coverage of the resistance heating coating 30 is eliminated in advance.

In a preferred embodiment of the first end 25 and the second end 26, referring to fig. 6, the first end 25 is formed with a first unit test point 27 exposed to the resistance heating coating 30 on the printing surface 11, and the second end 26 is formed with a second unit test point 28 exposed to the resistance heating coating 30 on the printing surface 11. Before the insulating coating 40 is not provided in the manufacturing process, the first unit test point 27 and the second unit test point 28 are not covered by the resistance heating coating 30, so that the resistance of the individual heating module between the positive electrode wire 21 and the negative electrode wire 22 can be detected in the manufacturing process, and uneven coverage thickness of the resistance heating coating 30 or/and uneven composition distribution of the printed heating sheet of the resistance heating coating 30 are eliminated in advance. As shown in fig. 6, by detecting the first unit test point 27 and the second unit test point 28, when the measured resistances of the plurality of heat-generating modules are within an error range meeting the requirement, it indicates that the coverage thickness of the resistance heating coating 30 is uniform and the composition distribution of the resistance heating coating 30 after printing is uniform. As shown in fig. 7, when the resistance heating coating 30 has an abnormal region 32 with non-uniform coverage thickness and/or non-uniform composition distribution, by probing the first unit test point 27 and the second unit test point 28, the resistance value of the heat generating module covered by the abnormal region 32 is abnormally low or especially high, usually low, relative to other good heat generating modules, and can be found in advance in the manufacturing process. As shown in fig. 8, when the resistance heating coating 30 has an inaccurate covering position, it can be easily detected optically from the exposed lengths of the first end 25 and the second end 26 whether the resistance heating coating 30 is shifted. In addition, even if the surface of the first end 25 and the second end 26 is damaged by the needle test of the first unit test point 27 and the second unit test point 28, the resistance heating coating 30 is not damaged, and the resistance heating performance of the plurality of heat generating modules is not affected. In addition, in an embodiment, the first bus bar 23 and the second bus bar 24 are further provided with a module test point 29 for testing the resistance value of all the heat generating modules in the same area covered by the resistance heating coating 30 after being connected in parallel.

With respect to one possible range of protrusion lengths of the first end 25 and the second end 26, in a preferred example, the length of the first end 25 and the second end 26 beyond the resistive heating coating 30 is between 0.5mm and 3mm, preferably between 1 mm and 2mm, such that the first unit test point 27 and the second unit test point 28 have a sufficiently large area for pin testing. Therefore, by using the first end 25 and the second end 26 beyond the length of the resistance heating coating 30, the resistance of the individual heat generating modules between the positive electrode wire 21 and the negative electrode wire 22 can be measured by a needle without damaging the resistance heating coating 30, for example, a probe with a needle diameter of 0.5mm can be used for measuring by a needle.

Regarding the size range and the boundary gap relation of the plurality of heat generating modules in the bus bar direction, in a preferred example, the heat generating gap between the adjacent positive electrode line 21 and the negative electrode line 22 is 0.4-1.2 cm, preferably, the first end 25 forms a first gap with the second bus bar 24, the second end 26 forms a second gap with the first bus bar 23, and a third gap is formed between the resistance heating coating 30 and the first bus bar 23 and between the resistance heating coating and the second bus bar 24, preferably, the first gap and the second gap are 0.5-3.0 mm, and the third gap is 2.0-5.0 mm. Therefore, the resistance heating coating 30 covers the film part between the adjacent electrode wires and covers the positive electrode wire 21 and the negative electrode wire 22, so that electric contact for realizing resistance heating is formed, a plurality of strip-shaped heating modules which are adjacent to each other are established in the range of the heating gap between the positive electrode wire 21 and the negative electrode wire 22, and the heating of short-path resistance from the bus bar to the adjacent electrode can be avoided by utilizing the third gap between the resistance heating coating 30 and the bus bars on the two sides. Preferably, the third gap is larger than the first gap and larger than the second gap, so that the first gap between the first end 25 of the positive electrode wire 21 and the second bus bar 24 and the second gap between the second end 26 of the negative electrode wire 22 and the first bus bar 23 are ensured not to have the residue of the resistance heating coating 30, a resistance short path is not established between the bus bar and the electrode wire close to but not connected with the bus bar, and the first bus bar 23 and the second bus bar 24 can be arranged close to each other as much as possible, so as to achieve the effect of size densification.

Regarding various specific possible arrangement manners of the positive electrode lines 21 and the negative electrode lines 22, in the first embodiment, referring to fig. 2, the arrangement manners of the positive electrode lines 21 and the negative electrode lines 22 are linearly staggered and spaced. Alternatively, in the fourth embodiment, referring to fig. 12, the arrangement of the positive electrode lines 21 and the negative electrode lines 22 is in a wave-shaped staggered interval. Therefore, the shape of the heating module is changed by using the arrangement form of the positive electrode wire 21 and the negative electrode wire 22, for example, a plurality of straight strip-shaped heating modules are provided at linear staggered intervals, so that the actual area and the actual resistivity of the heating module can be more easily calculated and confirmed reversely, and a plurality of wavy heating modules are provided at wavy staggered intervals, preferably, as shown in fig. 12, the arrangement form of the positive electrode wire 21 and the negative electrode wire 22 is a wavy staggered interval, the positive electrode wire 21 and the negative electrode wire 22 have flexibility of bending resistance, and the breakage of the positive electrode wire 21 and the negative electrode wire 22 is not easily caused when the soaking anti-scald graphene heating sheet is bent. In addition, the leading-out of the positive electrode line 21 and the negative electrode line 22 is connected to an external electrode or a leading-out electrode on the side of the film through the first bus bar 23 and the second bus bar 24, and a leading-out structure in the prior art can be used, which is not described in detail herein.

Regarding one possible range of the film thickness of each layer, in a preferred example, the thickness of the polyester film of the insulating carrier film 10 is 0.025-0.1 mm, and more preferably 0.038-0.05 mm, the thickness of the polyester film of the insulating cover film 40 is smaller than the thickness of the polyester film of the insulating carrier film 10, preferably 0.025-0.038 mm, the painting thickness of the conductive coating 20 is 4-12 μm, the total film thickness of the soaking and scald preventing graphene heating sheet is 0.08-0.4 mm, and preferably, the conductive coating 20 comprises a silver paste coating, and the resistive heating coating 30 comprises a graphene heating coating. Therefore, the thickness range of the specific polyester film, the coating thickness range of the conductive coating and the total film thickness range of the soaking anti-scald graphene heating sheet are utilized, so that the soaking anti-scald graphene heating sheet has a sufficiently thin structure and is more easily attached to the surface of a human body or clothes, and the thickness range of the conductive coating 20 can enable the circuit to be resistant to bending and prevent breakage. And thinner insulating tectorial membrane 40 is in order to balance the thermal expansion coefficient difference of each rete in the soaking scald preventing graphite alkene heating plate, generally the thermal expansion coefficient of conductive coating 20 is great and is pressed close to insulating year membrane 10, the attenuate insulating tectorial membrane 40 can alleviate soaking scald preventing graphite alkene heating plate is at the warping degree under no external force.

Regarding one specific implementation of the impedance value of the finished product, in a preferred example, the impedance value of the positive electrode line 21 and the impedance value of the adjacent negative electrode line 22 are between 10 Ω and 100 Ω, and may be 50 ± 5 Ω.

With respect to one practical material of the conductive coating 20, in a preferred example, the composition of the silver paste material used in the conductive coating 20 includes, by weight: 8-20% of spherical silver powder, and the particle size of the spherical silver powder is 2.5-6 microns; 40-60% of flake silver powder, wherein the particle size is 3-6 microns; 5-12% of nano silver powder, and the particle size of the nano silver powder is 18-60 nm; the organic carrier adopts 15-25% of vinyl resin, and the particle size of the vinyl resin is 0.9-1.5 microns; 5-15% of a DBE solvent; 0.1 to 1% of an oxide additive, and an average particle diameter of 0.4 to 1.0 μm. Therefore, with the specific composition of the silver paste material used for the conductive coating 20, the positive electrode wire 21 and the negative electrode wire 22 formed by the conductive coating 20 have the characteristics of bending resistance and fracture resistance.

In addition, the second embodiment of the present invention provides a method for manufacturing a soaking anti-scald graphene heating sheet, which is used to manufacture the soaking anti-scald graphene heating sheet of the first embodiment or a soaking anti-scald graphene heating sheet with similar functions, and fig. 4 shows a flowchart of the manufacturing process; fig. 5A to 5D are schematic cross-sectional views of a part of the device in the main steps of the manufacturing process, which is transverse to the extending direction of the positive and negative electrode lines 22; the preparation method includes the following main steps S1 to S4.

Referring to fig. 5A, the insulating carrier film 10 has a printing surface 11, the printing surface 11 of the insulating carrier film 10 can be divided into a heating area, a bus bar area and a peripheral area, the heating area is located between the bus bar areas, and the peripheral area is located at the periphery of the bus bar area;

step S2 is about the first printing on the insulating carrier film to form the conductive coating; with reference to figure 5B of the drawings, a first printing of a conductive coating 20 on the printing side 11 of the insulating carrier film 10 is carried out, the conductive coating 20 includes a positive electrode pattern and a negative electrode pattern that are not directly electrically connected to each other, the positive electrode pattern is integrally formed with a plurality of positive electrode lines 21 and first bus bars 23 connecting the positive electrode lines 21, the negative electrode pattern is integrally formed with a plurality of negative electrode lines 22 and a second bus bar 24 connecting the negative electrode lines 22, the positive electrode lines 21 and the negative electrode lines 22 are arranged in an equidistant and staggered manner, to separate a plurality of heating modules; the patterns of the positive electrode wires 21 and the negative electrode wires 22 of the conductive coating 20 are specifically located in the heat-generating area of the insulating carrier film 10; the first bus bar 23 and the second bus bar 24 of the electrically conductive coating 20 are in particular located in a bus region of the insulating support film 10;

step S3 is about forming a resistance heating coating by second printing on the insulating carrier film, referring to FIG. 5C, forming a resistance heating coating 30 by second printing on the printing surface 11 of the insulating carrier film 10, wherein the resistance heating coating 30 is positioned between the first bus bar 23 and the second bus bar 24 and covers the thin film part between the positive electrode line 21, the negative electrode line 22, the positive electrode line 21 and the negative electrode line 22, wherein the positive electrode line 21 has a first end 25 facing the second bus bar 24 and protruding out of the resistance heating coating 30, the negative electrode line 22 has a second end 26 facing the first bus bar 23 and protruding out of the resistance heating coating 30, and the pattern of the resistance heating coating 30 is specifically positioned in the heating area of the insulating carrier film 10;

step S4 is to form an insulating coating on the insulating support film, and referring to fig. 5D, an insulating coating 40 is formed on the printing surface 11 of the insulating support film 10 in a pressing manner, wherein the insulating coating 40 specifically covers the exposed portions of the resistance heating coating 30 and the conductive coating 20, such as the first bus bar 23 and the second bus bar 24. The size of the insulating coating film 40 is substantially equivalent to that of the insulating carrier film 10, but the thickness can be slightly smaller than that of the insulating carrier film 10;

specifically, the above main steps S1 to S4 are performed on a film mother sheet, a plurality of unit regions corresponding to the shape of the product film are integrated together, and the desired individual shape is cut after the printing and bonding processes are completed.

The implementation principle of the embodiment is as follows: the conductive coating 20 and the resistance heating coating 30 are respectively formed by single-sided multiple printing, and the insulating coating 40 is arranged, so that the preparation of the soaking anti-scald graphene heating sheet is realized, the covering accuracy of the resistance heating coating 30 relative to the conductive coating 20 can be optically detected in a manufacturing process or a finished product before the insulating coating 40 is arranged, and the heating sheet with inaccurate covering of the resistance heating coating is excluded in advance.

Regarding a practicable method for forming the patterned conductive coating 20 in step S2, in a preferred example, the pattern can be formed by using a polyester net pulled at an angle of 22.5 degrees by a 300-mesh cable, the thickness of the coating photoresist is 85 μm, and a special polyester coated screen plate is prepared by a special equipment mist spraying automatic developing machine; the conductive coating 20 with washing resistance, kneading resistance and high ductility is prepared by printing silver paste according to the screen pattern of the technical requirement by the printing technology of a full-automatic coil printing machine with a non-rising table top, and then, double-acting curing and aging are carried out by novel tunnel type short wave radiation and hot air circulation.

Regarding the printing form of the resistance heating coating 30 in step S3, the resistance heating coating 30 covers the thin film portion of the insulating carrier film 10 located in the predetermined heat generating region, and also covers the positive electrode line 21 and the negative electrode line 22, and as viewed from a cross section, the resistance heating coating 30 covers the side surfaces and the top surfaces of the positive electrode line 21 and the negative electrode line 22 except the bottom surface, so as to establish a non-planar and stable electrical contact relationship, and the risk of breaking the electrical contact interface between the resistance heating coating 30 and the positive electrode line 21/the negative electrode line 22 due to the thermal deformation stress is greatly reduced.

As a preferred example, the first end 25 is formed with a first unit test point 27 exposed to the resistance heating coating 30 on the printing surface 11, the second end 26 is formed with a second unit test point 28 exposed to the resistance heating coating 30 on the printing surface 11, and after step S3 and before step S4, the method may further include detecting the first unit test point 27 and the second unit test point 28 to measure the resistance between the positive electrode line 21 and the adjacent negative electrode line 22 before the insulating coating 40 is disposed, and the length of the first end 25 and the second end 26 beyond the resistance heating coating 30 is preferably 0.5 to 3mm, and preferably 1 to 2 mm. Therefore, by detecting the first unit test point 27 and the second unit test point 28 on the printing surface 11 before the insulating coating 40 is provided, the resistance of the individual heat generating module between the positive electrode line 21 and the negative electrode line 22 can be detected in the manufacturing process, and the uneven coverage thickness of the resistance heating coating 30 or/and the uneven composition distribution of the heat generating sheet after the printing of the resistance heating coating 30 can be eliminated in advance.

Regarding the range of possible thickness dimensions of the main member, in a preferred example, the thickness of the polyester film of the insulating carrier film 10 is 0.025-0.1 mm, more preferably 0.038-0.05 mm, the thickness of the polyester film of the insulating cover film 40 is less than the thickness of the polyester film of the insulating carrier film 10, preferably 0.025-0.038 mm, the painting thickness of the conductive coating 20 is 4-12 μm, the total film thickness of the soaking and scald preventing graphene heating sheet is 0.08-0.4 mm, preferably, the conductive coating comprises a silver paste coating, and the resistance heating coating comprises a graphene heating coating.

The third embodiment of the present invention further provides a soaking anti-scald graphene heating sheet, and fig. 9 is a schematic view of a local bottom view of the soaking anti-scald graphene heating sheet facing away from the printing surface; fig. 10 is a schematic top view of a part of the soaking anti-scald graphene heating sheet facing the printing surface; fig. 11 is a partial sectional view of the soaking anti-scald graphene heating sheet. Referring to fig. 9, 10 and 11, the soaking anti-scald graphene heating sheet comprises an insulating carrier film 10, a conductive coating 20, a resistance heating coating 30 and an insulating coating film 40.

The insulating carrier film 10 has a printed surface 11. The conductive coating 20 is printed on the printing surface 11 of the insulating carrier film 10, the conductive coating 20 includes a positive electrode pattern and a negative electrode pattern that are not directly electrically connected to each other, the positive electrode pattern integrally forms a plurality of positive electrode lines 21 and a first bus bar 23 connected to the positive electrode lines 21, the negative electrode pattern integrally forms a plurality of negative electrode lines 22 and a second bus bar 24 connected to the negative electrode lines 22, and the positive electrode lines 21 and the negative electrode lines 22 are arranged in an equidistant staggered manner to separate a plurality of heat generating modules. The conductive coating 20 is specifically a conductive circuit formed by silver paste printing, and is formed after printing and curing, so that the conductive coating has excellent conductivity and soft fracture-resistant toughness.

The resistance heating coating 30 is printed on the printing surface 11 of the insulating carrier film 10, the resistance heating coating 30 is located between the first bus bar 23 and the second bus bar 24 and covers the positive electrode line 21, the negative electrode line 22 and the thin film part between the positive electrode line 21 and the negative electrode line 22, wherein the positive electrode line 21 has a first end 25 facing the second bus bar 24 and protruding out of the resistance heating coating 30, and the negative electrode line 22 has a second end 26 facing the first bus bar 23 and protruding out of the resistance heating coating 30. The insulating coating 40 is provided on the printing surface 11 of the insulating support film 10.

In order to increase the gas permeability of product, resistance heating coating 30 is in positive electrode line 21 with a plurality of dodge holes 31 can be opened preferably between the negative electrode line 22, insulating carrier film 10 has seted up a plurality of alignments dodge hole 12 of hole 31, bleeder hole 12 has and is less than dodge the size of hole 31 and run through to insulating tectorial membrane 40. Therefore, the soaking anti-scald graphene heating sheet has a ventilation function by utilizing the avoiding hole 31, the air holes 12, the positions of the air holes 12 and the penetrating form and the size relation of the air holes 12, and the resistance heating coating 30 is completely sealed, so that a waterproof effect is achieved.

The embodiment of this detailed implementation mode is all regarded as convenient understanding or implementation the utility model discloses technical scheme's preferred embodiment, not restrict according to this the utility model discloses a protection scope, all according to the equivalent change that structure, shape, principle were done, all should be covered in the utility model discloses an ask the protection within range.

Claims (10)

1. The utility model provides a soaking scald preventing graphite alkene piece that generates heat which characterized in that includes:

an insulating carrier film (10);

the conductive coating (20) is formed on the insulating carrier film (10), the conductive coating (20) comprises a positive electrode pattern and a negative electrode pattern which are not directly electrically connected with each other, the positive electrode pattern is formed with a plurality of positive electrode wires (21) and first bus bars (23) connected with the positive electrode wires (21), the negative electrode pattern is formed with a plurality of negative electrode wires (22) and second bus bars (24) connected with the negative electrode wires (22), and the positive electrode wires (21) and the negative electrode wires (22) are arranged in an equidistant and staggered mode;

a resistance heating coating (30) formed on the insulating carrier film (10), the resistance heating coating (30) being located between the first bus bar (23) and the second bus bar (24) and covering the positive electrode wire (21), the negative electrode wire (22) and the thin film part between the positive electrode wire (21) and the negative electrode wire (22), wherein the positive electrode wire (21) has a first end (25) facing the second bus bar (24) and protruding from the resistance heating coating (30), the negative electrode wire (22) has a second end (26) facing the first bus bar (23) and protruding from the resistance heating coating (30), and

and the insulating coating (40) is arranged on the insulating carrier film (10).

2. The soaking anti-scald graphene heating sheet as claimed in claim 1, wherein a first unit test point (27) exposed out of the resistance heating coating (30) is formed at the first end (25), and a second unit test point (28) exposed out of the resistance heating coating (30) is formed at the second end (26).

3. The soaking anti-scald graphene heating sheet according to claim 2, wherein the length of the first end (25) and the second end (26) beyond the resistance heating coating (30) is 0.5-3 mm.

4. The soaking anti-scald graphene heating sheet as claimed in claim 1, wherein a heating gap between the adjacent positive electrode wire (21) and the adjacent negative electrode wire (22) is 0.4-1.2 cm.

5. The soaking anti-scald graphene heating sheet according to claim 1, wherein the first end (25) forms a first gap with the second bus bar (24), the second end (26) forms a second gap with the first bus bar (23), and third gaps are respectively formed between the resistance heating coating (30) and the first bus bar (23) and between the resistance heating coating and the second bus bar (24).

6. The soaking anti-scald graphene heating sheet according to claim 5, wherein the first gap and the second gap are 0.5-3.0 mm, and the third gap is 2.0-5.0 mm.

7. The soaking anti-scald graphene heating sheet as claimed in claim 1, wherein the positive electrode wires (21) and the negative electrode wires (22) are arranged in a linear staggered interval.

8. The soaking anti-scald graphene heating sheet as claimed in claim 1, wherein the arrangement mode of the positive electrode wires (21) and the negative electrode wires (22) is wave-shaped staggered intervals.

9. The soaking anti-scald graphene heating sheet according to claim 1, wherein a plurality of avoiding holes (31) are formed between the positive electrode wire (21) and the negative electrode wire (22) through the resistance heating coating (30), a plurality of air holes (12) aligned in the avoiding holes (31) are formed in the insulating carrier film (10), and the air holes (12) have a size smaller than that of the avoiding holes (31) and penetrate through the insulating coating film (40).

10. The soaking anti-scald graphene heating sheet according to any one of claims 1 to 9, wherein the thickness of the polyester film of the insulating carrier film (10) is 0.025-0.1 mm, the thickness of the polyester film of the insulating coating film (40) is smaller than the thickness of the polyester film of the insulating carrier film (10) and is 0.025-0.038 mm, the painting thickness of the conductive coating (20) is 4-12 μm, the total film thickness of the soaking anti-scald graphene heating sheet is 0.08-0.4 mm, the conductive coating (20) comprises a silver paste coating, and the resistance heating coating (30) comprises a graphene heating coating.

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