KR102322056B1 - Manufacturing method of seamless waterproof heating pad - Google Patents

Abstract

A seamless waterproof heating pad is disclosed. A seamless waterproof heating pad according to the present invention, a fabric for thermal diffusion; an insulating sheet for heat storage that is bonded and coupled to the back surface of the fabric for heat diffusion; and a thermal insulation sheet bonded to the back surface of the thermal insulation sheet for heat storage, wherein a heating wire is bonded and coupled between the fabric for thermal diffusion and the thermal insulation sheet for thermal storage. According to the present invention, the work of fixing the heating wire by sewing with a needle needle can be eliminated by placing the insulating coated heating wire between the fabric for thermal diffusion and the thermal insulation sheet for heat storage and then attaching and bonding in a laminating method, thus damaging the heating wire Since it can be fixed without being unwrapped, waterproofing can be achieved. Also, since the heating wire is made of stainless microfibers and the insulating coating material made of silicone is coated to have flexibility, it can be easily applied to clothing or other products worn on the human body. , especially like nichrome wire, there is no phenomenon that it is oxidized and disconnected due to frequent bending, etc., and can be used at high temperatures due to its excellent thermal stability. can provide

Description

Seamless waterproof heating pad manufacturing method {MANUFACTURING METHOD OF SEAMLESS WATERPROOF HEATING PAD}

The present invention relates to a method for manufacturing a seamless waterproof heating pad, and more particularly, by fixing the heating wire in a laminating method without needle needle bar work, it is possible to prevent the short circuit of the heating wire by the needle, and to provide a feeling of warmth to the human body. It relates to a method for manufacturing a seamless waterproof heating pad that can be maximized and waterproof.

One-sidedly, the heating pad is used for products such as electric mats, electric blankets, and electric blankets, and generates heat by using AC 110V or AC 220V power, which is a general household commercial power source.

These heating pads have one heating circuit in one heating pad, so one heating pad composed of a large heating area such as an electric blanket or an electric carpet generates a heating temperature that is enough to feel the body warm (about 50℃). In order to do this, the amount of power must be at least 300W and it has to be supplied at one time.

As a prior art of such a heating pad, Korean Patent Registration No. 10-0980108 (published on September 7, 2010) discloses a multi-purpose heating pad. The heating pad of this structure is one in which a neoprene sheet, a polyurethane sheet, an insulating sheet, etc. are laminated with a heating wire interposed therebetween, and a skin material is bonded to the outside by sewing.

However, the insulation pad according to the prior art having such a structure has a problem in that the heating wire is damaged by the needle during sewing, as the insulation sheet and the skin material are sewn and combined with the heating wire interposed therebetween, and resist heat in the damaged area. This caused a fire.

In particular, in the insulation pad applied to clothing intended to be worn on the human body, the heating wire may be damaged by the needle needle during the process of bonding to the clothing. There was a problem in that a short circuit occurred because the penetration was not made waterproof.

That is, as shown in FIG. 1, the heat insulation pad according to the prior art performs a sewing operation with a needle needle in order to fix the heating wire 2 (filament hot wire) to the fabric paper 1, and the heating wire 2 to the sewing thread 3 ) to the fabric paper (1), when the needle needle damages the heating wire (2) during sewing work, resistance heat is generated in the damaged area, resulting in a fire, disconnection, or damage part), which caused various problems due to infiltration of moisture.

. Republic of Korea Patent No. 10-0980108 (Announcement Date: 2010.09.07)

An object of the present invention is to provide a means by which the insulation-coated heating wire is fixed to the heat storage micro-bubble insulation material in a laminating method, which can be safely fixed without damaging the heating wire, as well as being waterproof.

Another object of the present invention is to provide a means capable of minimizing the heat loss of the heating wire.

In addition, the problem to be solved by the present invention is not limited to the technical problems mentioned above, and other technical problems not mentioned are clearly to those of ordinary skill in the art to which the present invention belongs from the description below. can be understood

The above object, according to the present invention, a fabric for thermal diffusion; an insulating sheet for heat storage that is bonded and coupled to the back surface of the fabric for heat diffusion; and a thermal insulation sheet bonded to the back surface of the thermal insulation sheet for heat storage, wherein a heating wire is adhered and coupled between the fabric for thermal diffusion and the thermal insulation sheet for thermal storage It is achieved by a seamless waterproof heating pad. .

The heating wire, a filament made of 200-400 stainless microfibers having a thickness of 4-30㎛; And it may be made of an insulating coating material made of a silicone material or a Teflon material so as to have flexibility to wrap and coat the filament.

The heating wire may have a thickness of 0.4 - 0.8 mm.

The fabric for thermal diffusion may be made of carbon fiber, the heat insulating sheet for heat storage may be made of polyethylene foam having microbubbles, and the insulating sheet may be made of wool wool.

The above object is a manufacturing method for manufacturing a seamless waterproof heating pad according to the present invention, after forming an adhesive layer between the fabric for thermal diffusion and the thermal insulation sheet for heat storage, wiring the heating wire, and supplying power to the heating wire In the state of applying heat to 60 - 80 ° C., by pressing the fabric for thermal diffusion and the insulation sheet for heat storage, the fabric for heat diffusion, the heating wire, and the insulation sheet for heat storage are integrated to manufacture the seamless waterproof heating pad. It is achieved by a manufacturing method of a seamless waterproof heating pad characterized in that.

The thermal insulation sheet may be bonded to the back surface of the thermal insulation sheet for heat storage.

The heating wire can be manufactured to a thickness of 0.4 - 0.8 mm by covering the outside of the filament made of 200-400 stainless microfibers having a thickness of 4-30 μm with an insulating coating material made of a silicone material or Teflon material to have flexibility. have.

According to the present invention, the work of fixing the heating wire by sewing with a needle needle can be eliminated by placing the insulating coated heating wire between the fabric for thermal diffusion and the thermal insulation sheet for heat storage and then attaching and bonding in a laminating method, thus damaging the heating wire Since it is possible to fix it without making it, it is possible to provide an effect that can be waterproofed.

In addition, since the heating wire is made of stainless microfibers and is coated with an insulating coating material made of silicone to have flexibility, it can be easily applied to clothing or other products worn on the human body. There is no disconnection phenomenon, and it can be used at high temperatures due to its excellent thermal stability, and because of its high heat density, it can provide the effect of rapidly heating up to a desired temperature when power is supplied.

In addition, since the heating wire is located between the fabric for heat diffusion and the insulation sheet for heat storage and is integrated with the fabric for heat diffusion and the insulation sheet for heat storage, heat loss can be minimized, and the carbon fiber fabric for heat diffusion is beneficial to the human body while spreading heat It becomes possible to provide the effect of emitting far-infrared rays.

1 is a schematic plan view showing a thermal insulation pad according to the prior art.
2 is a schematic perspective view showing a heat insulating pad according to the present invention.
FIG. 3 is a partially enlarged cross-sectional view illustrating the heat insulating pad shown in FIG. 2 .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted in order to clarify the gist of the present invention.

Of the accompanying drawings, FIG. 2 is a schematic perspective view showing a heat insulating pad according to the present invention, and FIG. 3 is a partially enlarged cross-sectional view showing the heat insulating pad shown in FIG. 2 .

As shown in FIGS. 2 and 3 , the seamless waterproof heating pad 10 according to the present invention is to be fixed by an adhesive method without fixing the heating wire 50 by a sewing method, and a fabric for thermal diffusion 20 And, a heat insulating sheet 30 for heat storage that is bonded and coupled to the back surface of the fabric 20 for heat storage, a heat insulating sheet 40 that is bonded and bonded to the back surface of the heat insulating sheet 30 for heat storage, and a fabric for heat diffusion 20 ) and a heating wire 50 that is wired between the heat-storage insulating sheet 30 is configured.

This will be described in more detail.

The thermal diffusion fabric 20 is to diffuse the heat generated from the heating wire 50 and transfer it to the human body, and is made of carbon fiber. Far-infrared rays are emitted from these carbon fibers, and far-infrared rays emitted from carbon fibers can be beneficial to the human body. This thermal diffusion fabric 20 has better tensile strength and tensile elasticity than general fabrics, so that less fabric abrasion due to surface friction occurs according to the movement of the human body, and excellent electrical conductivity can block the emission of electromagnetic waves absorbed by the human body.

The heat insulating sheet 30 for heat storage is for accumulating heat generated from the heating wire 50 and preventing it from being taken away, and is made of polyethylene foam in which microbubbles 32 are formed. As shown in FIG. 3, the heat insulation sheet 30 for heat storage has a structure in which a plurality of microbubbles 52 are formed therein. 32) The internal air temperature is raised, and therefore, the heat generated from the heating wire 50 may be temporarily stored in each microbubbles 32 . As such, the heat generated from the heating wire 50 raises the air temperature in each microbubble 32, so that the heat generated from the heating wire 50 does not escape to the outside (in the opposite direction of the object to be kept warm), thereby keeping the object to be kept warm. In addition to maximizing the cooling efficiency, the inflow of cold air from the outside can be effectively blocked.

On the other hand, since the thermal insulation sheet 30 for heat storage is made of foam having microbubbles 32, it also serves to block the conduction of cold air from the outside to the body.

Insulating sheet 40, the heat generated from the heating wire 50 is conducted only toward the object to be kept warm, for example, the user's body, and to block cold air and keep the object to be kept warm so that cold air from the outside is not conducted toward the body For this purpose, it may be made of various fabric materials, but in this embodiment, it is made of wool wool having excellent thermal insulation properties.

The heating wire 50 is disposed between the thermal diffusion fabric 20 and the thermal insulation sheet 30 for heat storage, and as the thermal diffusion fabric 20 and the thermal insulation sheet 30 are adhered and combined, the thermal diffusion fabric 20 and the thermal storage for heat storage It is integrated between the insulating sheets 30, and is made by braiding 100-1,000 metal microfibers having a thickness of 4-30 μm to have ductility and a filament 52 to obtain a desired resistance value, and a silicone to have flexibility. It is made of an insulating coating material 54 which is made of a material or a Teflon material and wraps around the filament 52 .

A specific example of the aforementioned filament 52 will be described.

The filament 52 may be manufactured by processing a special alloy, and according to various embodiments of the present invention, nickel (Ni), chromium (Cr), molybdenum (Mo), copper (Cu), iron (Fe), It may include at least one of alumina (Al), manganese (Mn), silicon (Si), carbon (C), tungsten (W), and titanium (Ti). Preferably, based on iron (Fe), nickel (Ni) 12% to 15%, chromium (Cr) 16% to 18%, molybdenum (Mo) 2.0% to 3.0%, manganese (Mn) 2.0% or less , silicon (Si) 1.0% or less, and carbon (C) 0.03% or less. The composition of the filament 52 is a low-carbon alloy composition, and in particular, decarbonization occurs due to the reaction of carbon (C) and oxygen (O2) among the components of the steel material generated by high-temperature heat, resulting in the hardness and hardness of the surface. By weakening the corrosion resistance, it is possible to prevent the filament 52 from being vulnerable to a certain resistance value, refraction, and bending.

Filament yarns having a diameter of micron level can be extracted from the alloy of this composition through a cutting method, a drawing method, a melting method, or the like. Preferably, a drawing method can be used to extract filament yarns of uniform diameter. A more accurate resistance value can be obtained through the uniform diameter of the filament yarn, and a uniform temperature specification can be realized by reducing the temperature deviation. In addition, in the filament yarn extracted by the drawing method, a required resistance value can be obtained by plying bundles of usually 100 to 1,000 strands with each other. The filament 52 of the braided structure manufactured by this adjustment has higher ductility than a single wire nichrome wire, which is a general resistance wire, so that the wire break does not work well even with repeated refraction and bending, so a short circuit or wire breakage accident at the bending part does not occur easily.

The total thickness (thickness including the insulating coating material) of the heating wire 50 including the filament 52 is made of 0.4 - 0.8mm.

The aforementioned heating wire 50 is formed in a structure in which a filament 52 made of metal microfibers including stainless steel is braided by an insulating coating material 54 made of silicon is wrapped and coated, and the total thickness is 0.4 - 0.8 mm. It has excellent flexibility that can be bent and unfolded freely.

As described above, since the heating wire 50 has flexibility, the operation of folding or unfolding the heating pad 10 according to the present invention can be smoothly performed, and even if the operations of folding, bending, and unfolding are repeated, disconnection does not occur. Therefore, it is possible to easily apply the heating pad 10 according to the present invention to a product applied to the body. In other words, it can be easily applied to various products such as foot warmers, cushions, gloves, blankets, vests, neck warmers, and clothing because it is free to bend and form patterns.

In addition, since the heating wire 50 is made of a filament 52 in which microfibers made of a metal alloy are braided, a phenomenon of being oxidized and disconnected like a single wire, that is, a single-wire nichrome wire, does not occur and has excellent bendability. It can be used for a long time because disconnection does not occur even after repeated bending and folding, and it is economical compared to nichrome wire due to low power consumption, and power equipment can be miniaturized.

As described above, the fabric 20 for thermal diffusion and the thermal insulation sheet 30 for heat storage are bonded to each other by the adhesive layer 70 with the heating wire 50 interposed therebetween. And on the back surface of the heat insulating sheet 30 for heat storage, the insulating sheet 40 is adhered by an adhesive.

In this way, in a state in which the flexible heating wire 50 is positioned between the fabric 20 for thermal diffusion and the thermal insulation sheet 30 for heat storage, the fabric 20 for thermal diffusion and the thermal insulation sheet 30 for thermal storage are attached to the adhesive layer 70. Since the insulating sheet 40 is adhered to the back surface of the thermal insulation sheet 30 for heat storage by an adhesive, the heating wire 50 is the fabric 20 for thermal diffusion and the thermal insulation sheet for heat storage without sewing work using a needle. It can be fixed between the 30, so that damage by the needle does not occur, as well as damage does not occur, so a waterproof effect can be obtained, and the operation of separately fixing the heating wire 50 can be deleted.

In addition, since the heating wire 50 has flexibility as described above, the heating pad 10 according to the present invention can be applied to various products that can be worn on the body.

In addition, in the heating pad 10 according to the present invention, with respect to the heating wire 50 , the fabric 20 for thermal diffusion is disposed in the direction toward the object of thermal insulation, and in the opposite direction, the thermal insulation sheet 30 for thermal storage and thermal insulation By disposing the sheet 40, the heat generated from the heating wire 50 can be transferred to the object of heat preservation without loss, so that the heat preservation efficiency can be improved, and in particular, the heat insulation sheet 40 and the heat insulation sheet 30 for heat storage The thermal insulation efficiency can be maximized by blocking the cold air transmitted from the opposite direction and forming a warm air layer by increasing the air temperature in the microbubbles 32 of the thermal insulation sheet 30 for heat storage.

A process for manufacturing the seamless waterproof heating pad 10 configured as described above will be described.

A manufacturing method for manufacturing the aforementioned seamless waterproof heating pad 10 is as follows.

a) step

An adhesive layer 70 is formed by providing an adhesive, an adhesive film, a coating layer, or the like between the fabric 20 for thermal diffusion and the heat insulating sheet 30 for heat storage.

b) step

When the adhesive layer 70 is formed between the fabric 20 for thermal diffusion and the heat insulating sheet 30 for heat storage, the heating wire 50 is wired between the fabric 20 for heat diffusion and the heat insulating sheet 30 for heat storage.

c) step

When the heating wire 50 is wired between the fabric 20 for thermal diffusion and the heat storage sheet 30, power is applied to the heating wire 50 to heat it at 60 - 80 ° C. By pressing the thermal insulation sheet 30 for thermal diffusion, the fabric 20 for thermal diffusion, the heating wire 50 and the thermal insulation sheet 30 for heat storage are integrated to manufacture a seamless waterproof heating pad 10 .

In this case, the thermal insulation sheet 40 may be simultaneously bonded and bonded to the back surface of the thermal insulation sheet 30 for heat storage, or may be bonded and bonded after the production of the heating pad 10 is completed.

In this way, in order to couple the thermal insulation sheet 40 to the back surface of the thermal insulation sheet 30 for heat storage, an adhesive, a film, or a coating layer such as the above-described adhesive layer 70 is applied to the back surface of the thermal insulation sheet 30 or the thermal insulation sheet 40 ) formed on the surface of the heat storage sheet 30 and the thermal insulation sheet 40 by pressing and bonding.

On the other hand, in a state in which power is applied to the heating wire 50 wired between the fabric 20 for thermal diffusion and the thermal insulation sheet 30 for heat storage and heat is generated at 60 - 80 ° C. When 30) is pressed, the adhesive layer 70 adheres the fabric 20 for thermal diffusion and the thermal insulation sheet 30 for heat storage, and the adhesive layer 70 around the heating wire 50 is rusted by the heat of the heating wire 50. While the heating wire 50 is fixed between the fabric 20 for thermal diffusion and the thermal insulation sheet 30 for heat storage. That is, a part of the adhesive layer 70 and the heat-storage insulating sheet 30 melted by heat is firmly adhered to the outside of the insulating coating material 54 made of silicone material, so that the heating wire 50 is firmly attached to the thermal diffusion fabric 20. It may be fixed between the thermal insulation sheet 30 and the heat storage. In particular, since the heating wire 50 melts a portion of the heat-storage insulating sheet 30 , the heating wire 50 and the heat-storage heat-insulating sheet 30 can be more firmly integrated.

In addition, the process of adhering the fabric 20 for heat diffusion, the heat insulating sheet 30 and the heat insulating sheet 40 for heat storage may be performed by a generally applied laminating method.

The manufacturing of the seamless waterproof heating pad 10 is completed by integrating the fabric 20 for thermal diffusion, the heating wire 50 and the thermal insulation sheet 30 for heat storage by the above-described process.

As described above, the heating wire 50 is positioned between the fabric 20 for thermal diffusion and the heat insulation sheet 30 for heat storage, and then attached and combined in a laminating method, sewing with a needle needle to fix the heating wire 50 . This can be eliminated and thus the heating wire 50 can be fixed without damaging it, so that waterproofing can be achieved.

In the foregoing, specific embodiments of the present invention have been described and illustrated, but it is common knowledge in the art that the present invention is not limited to the described embodiments, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have Accordingly, such modifications or variations should not be individually understood from the technical spirit or point of view of the present invention, and modified embodiments should be considered to belong to the claims of the present invention.

10: heating pad 20: fabric for thermal diffusion
30: heat insulating sheet for heat storage 32: micropores
40: thermal insulation sheet 50: heating wire
52: filament 54: insulation coating material
70: adhesive layer

Claims (8)

delete delete delete delete delete As a manufacturing method for manufacturing a seamless waterproof heating pad,
A heating wire manufacturing step of manufacturing a heating wire having a thickness of 0.4 - 0.8 mm by coating a filament made of stainless microfibers with an insulating coating material made of a silicone material to have flexibility;
An adhesive layer forming step of forming an adhesive layer melted by heat of 60 - 80°C between a heat-diffusion fabric made of carbon fiber and a heat storage insulating sheet made of polyethylene foam having microbubbles, and forming an adhesive layer with an adhesive or film;
a heating wire wiring step of wiring the heating wire manufactured in the heating wire manufacturing step between the fabric for thermal diffusion on which the adhesive layer is formed and the thermal insulation sheet for heat storage;
When the heating wire is wired, the fabric for thermal diffusion, the heating wire, and the heat storage insulation sheet are integrated by pressing the heat diffusion fabric and the heat storage insulation sheet in a state where power is applied to the heating wire and heat is generated at 60 - 80 ° C. a bonding step; and
It characterized in that it comprises a completion step of manufacturing the seamless waterproof heating pad by adhering a thermal insulation sheet made of a textile material or wool wool to the back surface of the thermal insulation sheet for heat storage,
A method of manufacturing a seamless waterproof heating pad.





delete delete

Images