KR20220062437A - Mu ltifunctional thermal stimulation transdermal patch and its manufacturing met hod - Google Patents

Abstract

The present invention relates to a multifunctional thermal stimulation transdermal patch using a planar heating element and a method for manufacturing the transdermal patch. The present invention is to form a patch body as a finished product by accommodating a heat-generating paper formed by laminating a scoria coating layer, a shungite coating layer, and a low-frequency stimulation unit in a molding structure to a surface-attached outer shell. The formed patch body is attached to a pain part of the user's body, and the material characteristics of the scoria coating layer and the shungite coating layer, thermal stimulation by the heating paper and vibration stimulation by the low-frequency stimulation unit provide the pain-relief effect to perform a human body treatment function. The present invention comprises: a patch body; a power supply pad; and a storage battery. In addition, the method for manufacturing the thermal stimulation transdermal patch comprises: a heating paper forming process, a scoria composition pretreatment process, a shungite composition pretreatment process; a health supplement material coating process, a patch body molding process, and a power pad assembly process.

Description

Multifunctional thermal stimulation transdermal patch and its manufacturing method using a planar heating element

The present invention relates to a thermal stimulation transdermal patch, and more particularly, to have a stable use relationship regardless of disconnection of a planar heating element or other damage, and in particular, a heating action by electric heating, and emission of far infrared rays and negative ions A multifunctional thermal stimulation transdermal patch using a cotton heating element, and its manufacturing method using a face heating element that can simultaneously provide health support such as sterilization, deodorization, deodorization, etc., and pain relief by thermal stimulation and low-frequency vibration stimulation. is about

Although the planar heating element, which generates heat by electrical resistance, has a low power consumption in the range of 20 to 40% compared to general heat transfer devices, the heating efficiency is relatively excellent, and furthermore, it is very excellent in terms of smoothness and durability. has well-known structural characteristics,

The planar heating element of such characteristics is, as well as residential heating devices such as bedding mats, cushions, home dry saunas, etc., as well as various industrial heating devices, for example, agricultural products drying systems, anti-icing devices for roads, anti-fog devices for automobile glass It is widely used in various fields.

On the other hand, if we briefly look at the material composition of the planar heating element used in various industries as described above, it can be seen that it is largely divided into a metal heating element, a non-metal heating element, and other heating elements.

Here, first, the metal heating element is a mainstream of the initial heating element and uses a material of a high melting point metal, such as platinum, molybdenum, tungsten, and the like, and the non-metal heating element uses a material such as silicon carbide, silicide, carbon, zirconia, etc., and other heating elements uses materials such as ceramics.

Alternatively, looking at the basic product configuration and principle of the conventional planar heating element formed according to the selection of materials listed above, it is built with an electrode and a heating wire (nichrome wire, etc.) inside a planar insulating film paper as a single wire connection structure, , by transferring the resistance heat of the built-in heating wire to the outside through the surface of the insulating material to perform a heating action.

However, the conventional planar heating element configured as described above has a characteristic in which energy for generating resistance heat, for example, electrical energy flows through a heating wire connected in a single wire structure, therefore, any one part of the heating wire In the event of a break, the flow of electricity is blocked at the source, making it impossible to generate heat at all, and in particular, when the heating wire is short-circuited, the electrical resistance of the short-circuited part is greatly reduced, resulting in abnormal heat generation at high temperatures. There is a significant structural problem inevitably inevitably exposed to the risk of fire because of the induced.

In addition, the conventional planar heating element as described above has a problem in that the temperature distribution over the entire surface of the planar heating element cannot be made uniformly as only the portion of the heating wire connected by the wire structure partially heats up.

On the other hand, in recent years, as a solution to the problems of the conventional planar heating element described above, "a method of manufacturing a carbon fabric planar heating element and a carbon fabric planar heating element manufactured by the method" registered as an earlier application at the Korean Intellectual Property Office (Registration Patent No. 1734378)" has been created

This prior application registration technology prevents the occurrence of a gap between the heating element and the electrode body, thereby preventing dangerous phenomena such as sparks that may be caused by the existing gap, and, at the same time, ensures smooth conductivity even when disconnection occurs in the electrode wire. The feature of the technology is the planar heating element with a functional structure that allows it to be exhibited.

However, most of the planar heating elements including the prior application registration technology have a very limited scope of use as their intended use is merely limited to articles or devices for heating or insulation, and, therefore, versatility and efficiency of use Of course, there is also the problem of significant economic degradation.

The present invention has been devised to solve the general problems of the general purpose and efficiency of use of the conventional planar heating element, and deterioration of economic feasibility;

An object of the present invention is to laminate a scoria coating layer and a schungit coating layer on the surface and back surface of a heating paper of a mesh structure woven with carbon fiber, and install a low-frequency stimulation unit on one surface where the scoria coating layer and the schungit coating layer are formed, and again, After forming the patch body as a finished article by sealingly accommodating the heating paper installed with the low-frequency stimulation unit in a surface-attached shell made of a silicone material with a molding structure, the patch body thus formed is applied to the user's body pain area, for example, bruises or arthritis, It attaches to body parts that require stability and treatment due to muscle pain or other fractures, and imparts sterilization, detoxification and deodorization functions by the material properties of the Scoria coating layer and the Schungit coating layer, such as far-infrared rays and anion emission functions, and , It is to provide a multifunctional thermal stimulation transdermal patch using a planar heating element and a method for manufacturing the same using a planar heating element that provides pain relief by thermal stimulation by a planar heating element and vibration stimulation by a low-frequency stimulation unit to perform a human body treatment function. .

In addition, an object of the present invention is to variably form the shape and shape of the patch body into a shape suitable for joint parts such as knees, elbows, shoulders, etc., for each body part characteristic, so that the patch body can be manufactured regardless of the characteristics of each body part. Multifunctional using a planar heating element that allows for attachment and use, and also prevents the attached patch body from being easily detached according to the variable formation structure suitable for the joint area, thereby greatly increasing the handling, portability and convenience of use. To provide a thermal stimulation transdermal patch and a method for manufacturing the same.

In addition, an object of the present invention is to selectively vary the shape, shape, and standard (size) of the patch body, as well as as a function of a simple transdermal patch used to attach to a body pain area, as well as control the temperature of food or beverages. Usability and versatility by allowing a wide range of uses such as a thermal cover to keep warm, a heating mat for leisure that can be used as a thermal insulation means for enjoying camping, mountain climbing, and fishing, a heating cushion for outdoor use, and other auxiliary heating sheets for automobiles And, it is to provide a multifunctional thermal stimulation transdermal patch using a planar heating element so as to greatly improve the functionality and a method for manufacturing the transdermal patch.

Therefore, as a specific means of a multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention for achieving the above object and a method for manufacturing the transdermal patch;

A heating paper having a mesh structure, a scoria coating layer and a Schungit coating layer are laminated on the surface and back of the heating paper, a low-frequency stimulation unit is laminated and installed on one surface of the heating paper on which the coating layer is formed, and a heating paper having a low-frequency stimulation unit installed on the surface A patch body sealed and accommodated in a molding structure in an attachment shell, and coated with a silicone adhesive layer on one side of the surface attachment shell;

a power supply pad that forms an electrical connection part and a storage battery connection hole and is coupled and connected to one side of the patch body;

A pair of power connection terminals symmetrical to one side protrude, and it is achieved by configuring a storage battery that is detachably attached and coupled to the storage battery connection hole in a rotation-locking connection structure.

In addition, as a series of methods for manufacturing the thermal stimulation transdermal patch, a heating paper molding process, a scoria composition pretreatment process, a shungit composition pretreatment process, a health supplement coating process, a patch body molding process, and a power pad assembly It is achieved by making the process happen.

As described above, the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention and the method for manufacturing the transdermal patch are sterilized and detoxified by the material properties of the scoria coating layer and the schungit coating layer laminated with the heating paper, for example, a large amount of far infrared rays and anion emitting function. and a deodorizing function, and in particular, a pain relief action by thermal stimulation by a heating paper and vibration stimulation by a low-frequency stimulation unit to perform a human body treatment function, which provides hygiene and cleanliness as well as consumer use It provides the effect of improving satisfaction.

In addition, the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention and the method for manufacturing the same, the shape and shape of the patch body are variably formed into a shape suitable for body joint parts such as knees, elbows, shoulders, etc., and their body parts It enables the patch body to be easily attached and used without being limited by its specific characteristics, and also prevents the patch body attached to the body from being easily detached according to such a variable formation structure, which is characterized by handling and portability. And it provides the effect of increasing the convenience of use.

Alternatively, the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention and the method for manufacturing the transdermal patch selectively vary the shape, shape, and size (size) of the patch body, so as not only as a function of a simple transdermal patch , It can be widely used as a thermal cover that keeps food and beverages warm, a heating mat for leisure that can be used as a means of keeping warm for camping, mountain climbing, and fishing, an outdoor cushion, and an auxiliary heating seat for automobiles, etc. As such, it provides very useful expected effects, such as improving usability, versatility, and functionality.

1 is a perspective view of a multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention;
2 is a cross-sectional view of the combined state of the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention;
3 is a state diagram of a multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention;
4 is a perspective view of this embodiment of a multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention;
5 is a cross-sectional view of the combined state of this embodiment of the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention;
6 is a perspective view of a third embodiment of a multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention;
7 is a cross-sectional view of a three-embodiment combined state of the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention;
8 is a perspective view of a real embodiment of a multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention;
9 is a state diagram of the use of a multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention.
10 is a process flow chart of a multifunctional thermal stimulation transdermal patch manufacturing method using a planar heating element according to the present invention;

Hereinafter, the configuration of a preferred embodiment of the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention and a method for manufacturing the transdermal patch will be described in detail based on the accompanying drawings.

first. Looking at the schematic configuration of the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention with reference to the accompanying drawings, it is composed of a patch body (1), a power supply pad (2), and a storage battery (3) .

Here, the patch body 1 is selectively attached to and detached from the painful part of the user's body and is a core configuration of the present invention that provides thermal stimulation and low-frequency vibration stimulation. As such, the patch body 1 is, 1 or 2, based on the heating paper 11 having a mesh structure woven with carbon fiber yarns as a basis, the scoria coating layers 12 and 12' on the surface and the back surface of the heating paper 11. and Schungit coating layers 13 and 13' are formed in a symmetrical pair of sequential stacked structures as shown in a partially enlarged view of FIG. 2, and the Scoria coating layers 12 and 12' and the Schungit coating layer 13 ) (13') is formed by installing the low-frequency stimulation unit 14 on one surface of the heating paper 11 formed in a laminated structure, and again, the heating paper 11 in which the low-frequency stimulation unit 14 is installed is made of a soft synthetic resin material , It is preferable to seal and accommodate the surface-attached shell 15 made of a silicone material harmless to the towed body in a molding structure, and further coat the surface-attached shell 15 with a silicone adhesive layer 16 on one side of the entire surface. (Non-explained reference numeral 111 is an electrode)

At this time, in the patch body 1 described above, the scoria coating layers 23 and 23 ′ are health supplementary material layers provided to provide benefits to the human body. Scoria refers to clay calcined by high temperature heat due to volcanic activity, for example, a mineral raw material known as natural ceramic, which is porous with weak alkalinity and is divided into reddish brown and blackish brown. In particular, scoria is a natural state It has well-known material properties, exhibiting a far-infrared emissivity of 93%, antibacterial activity of 99.9%, and deodorization rate of 97%.

In addition, in the patch body 1 described above, the schungit coating layers 13 and 13' are also health supplementary material layers provided to provide benefits to the human body. Schungit refers to the only natural nanostructured composite mineral containing 30-40% carbon and 60-70% silicate. As a natural antioxidant, it has the function of increasing human immunity against diseases, and in addition to the adsorption function to purify water and air, the catalytic function to decompose adsorbed organic substances, absorption and shielding of harmful electromagnetic waves, and , has well-known material properties such as neutralization and absorption of radiation.

In addition, in the patch body 1 described above, the low-frequency stimulation unit 14 directly exercises muscles by weak electric (medium, low-frequency) stimulation transmitted to the human body to increase muscle mass and basal metabolic rate, The function to prevent obesity by directly stimulating fat cells, the function to increase the amount of energy consumed by increasing the body temperature by promoting blood circulation, and the function to make a resilient body by stimulating the skin As performing a well-known function of treating diseases such as, etc., in the present invention, a low-frequency stimulation pad having such a well-known functional configuration is applied and applied. to be omitted.

Alternatively, in the patch body 1 described above, the silicone adhesive layer 16 coated on one side of the front surface of the surface-attached shell 15 does not remain sticky and is contaminated with dust or foreign substances. A well-known adhesive whose adhesive strength is restored only by simple washing, for example, is formed by coating a silicone adhesive that is harmless to the human body. Also, the silicone adhesive layer 1 is a means for directly attaching the patch body 16 to the user's body skin, and in the present invention, the silicone adhesive layer 1 is replaced with a Velcro fastener layer (not shown). It may be formed and used by attaching the patch body 16 to the surface of the clothing worn by the user.

On the other hand, the power supply pad (2) is a kind of control means for controlling the operating relationship so that the aforementioned patch body (2) can smoothly perform the heating action and vibration action, such a power supply pad (2) 1 or 2, with a thin case configuration, for example, the thickness of the same standard as the patch body 2 described above, and the electrical connection part 21 on the inner surface as shown in a partially enlarged view of FIG. ), and as shown in FIG. 1 on the exposed outer side, a storage battery connection hole 22 taking the shape of a pair of symmetrical half-moon grooves is formed, and again, a position close to the storage battery connection hole 22 1, it is preferable to form the stimulation device manipulation unit 23. (reference numeral 231 denotes a stimulation operation on/off switch, reference numeral 232 denotes a stimulation intensity control switch, and 233 denotes a stimulation time setting switch)

Finally, the storage battery 3 is a means for stably supplying electrical energy required for the patch body 2 described above to generate heat and vibrate. As such, the storage battery 3 is shown in Fig. As shown in 1, in the power supply pad 2 described above on one side thereof, a means for detaching/attaching connection (coupling) with a rotation locking structure to the battery connection hole 22 taking the shape of a half-moon groove, for example, It is preferable to form a pair of symmetrical structures and to form the power connection terminals 31 vertically protruding by a predetermined length.

Therefore, looking at the mutual coupling relationship of the multifunctional thermal stimulation transdermal patch using the planar heating element according to the present invention composed of the above components;

This is the surface coated with the silicone adhesive layer 16 on the heating paper 11 on which the Scoria coating layers 12 and 12 ′, the Schungit coating layers 13 and 13 ′, and the low frequency stimulation unit 14 are stacked. Forming the patch body (1) by sealingly accommodated in a molding structure in the attachment shell (15);

As shown in the partial enlarged view of FIG. 2 on one side of the patch body 1, the power supply pad 2 is coupled in an electrical connection structure by the electrode 111 and the electrical connection part 21, and the combined power supply pad By coupling the storage battery 3 to the storage battery connection hole 22 of (2), a multifunctional thermal stimulation transdermal patch using the planar heating element according to the present invention is implemented.

At this time, in the thermal stimulation transdermal patch according to the present invention having the combination configuration as described above, the patch body 1 has a simple planar structure as well as various shapes and shapes according to user needs, for example, knees, elbows, and shoulders. It can also be formed into a bent three-dimensional shape that can correspond to body joint parts, such as the back.

Therefore, the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention uses the silicone adhesive layer 16 to apply the patch body 1 to the user's body pain area, such as bruises, arthritis, muscle pain, and other fractures. By attaching it to the body surface that requires stability and treatment as shown in FIG. 3 , it provides pain relief by thermal stimulation by the electrical resistance heat of the heating paper 11 and vibration stimulation by the low-frequency stimulation unit 14 . In addition, the material properties of the scoria coating layers 12 and 12 ′ and the schungit coating layers 13 and 13 ′, for example, provide sterilization, detoxification and deodorization functions by far-infrared rays and anion emitting functions.

On the other hand, FIG. 4 is a perspective view of this embodiment of the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention, and FIG. 5 is a cross-sectional view showing the combined state of this embodiment of the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention. (Hereinafter, in describing this embodiment of the present invention, the same name and the same reference numerals are used for the configuration having the same function as the one embodiment for convenience of description.)

In the present invention as this embodiment, in the above-described embodiment, the configuration of the patch body 1 is shown in FIG. 4 , the scoria coating layers 12 and 12 ′, and the schungit coating layers 13 and 13 ') and the low-frequency stimulation unit 14, the mesh structure of which the heating paper 11 is laminated is included in the surface-attached outer shell 15 in a molded structure;

As shown in FIGS. 4 and 5 in the central part of one side of the surface-attached shell 15 in which the heating paper 11 is accommodated, a plurality of regular and repeated through holes, for example, a vent hole P, are provided at a predetermined depth Further forming a sheet exchange groove 151 of;

coating and forming a silicone adhesive layer 16 on the inner surface of the sheet exchange groove 151 and one front surface of the surface-attached shell 15 on which the sheet exchange groove 151 is formed;

Again, it is preferable to form a sanitary sheet 17 installed in the sheet exchange groove 151 in a detachable and attachable exchange structure, for example, a kind of sanitary fabric excellent in breathability and sweat absorption.

At this time, the silicone adhesive layer 1 applied in this embodiment may be replaced with a Velcro fastener layer (not shown) as in one embodiment, and the patch body 1 may be attached to the surface of the clothing worn by the user. .

Therefore, as described above, the present invention as this embodiment replaces and installs the sanitary sheet 17 in the sheet exchange groove 151 in a detachable and attachable structure so that it always has a clean use relationship as it is used, and, in addition, the ventilation hole ( P) effectively dries body secretions, such as sweat, by smooth air circulation, and provides a pleasant use relationship.

Alternatively, FIG. 6 is a perspective view of three embodiments of the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention, and FIG. 7 is a cross-sectional view of three embodiments of the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention. (Hereinafter, in the description of the three embodiments of the present invention, the same names and the same reference numerals are used for components having the same functions as those of the one embodiment for convenience of description.)

The present invention as the above three embodiments, in the above-described embodiment, the configuration of the patch body 1 is composed of the scoria coating layers 12 and 12 ′, the Schungit coating layers 13 and 13 ′, and the low-frequency stimulation unit ( 14) excluded, for example, as shown in FIG. 7, the heating paper 11 of a mesh structure woven with carbon fiber yarn, and a surface-attached outer shell ( 15), a silicone adhesive layer 16 coated on one side of the surface-attached shell 15 in which the heating paper 11 is accommodated, and a heating paper 11 and an electrode structure on the outer surface of the surface-attached shell 15 connected to and formed with a power connector 18 exposed to the outside;

The configuration of the storage battery 3 is, as shown in Figs. 6 and 7, the power connector 18 of the patch body 1 and the power connection jack 33 connected in a detachable and attachable structure, and the storage battery 3 ) is preferably formed in a pad-type structure in which a power on/off switch 34 for intermittent power supply is provided.

At this time, the silicone adhesive layer 1 applied in this embodiment is replaced with a Velcro fastener layer (not shown) as in this embodiment and this embodiment, and the patch body 1 is attached to the surface of the clothing worn by the user. can be used by

Therefore, as described above, the present invention as a three-embodiment reduces the failure rate and increases economic efficiency according to a simplified structure in which only a thermal stimulation function is performed by the electrical resistance heat of the heating paper 11 .

In particular, the present invention as a third embodiment is not only for the use of a transdermal patch that relieves body pain due to the simple structural characteristics of performing only a thermal stimulation function, but also the shape, shape and size of the patch body 1 according to user needs. By processing and cutting in a variable configuration, it has functional characteristics that can be widely used for purposes such as leisure heating mats, outdoor heating cushions, food insulation covers, automobile heating seats, and the like.

8 is a perspective view of a real example of the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention, and FIG. (Hereinafter, in describing the actual embodiment of the present invention, the same name and the same reference numerals are used for the configuration having the same function as the one embodiment and the third embodiment for convenience of description.)

The present invention as an actual embodiment is shown in Fig. 8 on one side of the patch body 1 and the other side of the patch body 1 to which the storage battery 3 is coupled by the power connector 18 in the three embodiments described above. As shown in Fig. 9, a pair of auxiliary wearing holes 19 are vertically penetrating in a long hole structure and opposed to each other, and the pair of auxiliary wearing holes 19 and 19' are attached to the belt as shown in Fig. 9 ( By connecting B), it is preferable to form the patch body 1 so that it can be worn on the user's body pain area by the connected belt (B).

Therefore, as described above, the present invention as a third embodiment provides a method for fixing the patch body 1 to the user's body more firmly and stably in addition to the attachment function by the silicone adhesive layer 1 or the Velcro fastener layer (not shown). provide auxiliary functions.

On the other hand, the multifunctional thermal stimulation transdermal patch using a planar heating element according to the present invention is another differentiated method to form the transdermal patch, for example, by implementing a multifunctional thermal stimulation transdermal patch manufacturing method using a planar heating element, As shown in FIG. 10, the present invention as a method feature as described above is, as shown in FIG. This is achieved by performing the step (S4), the patch body molding step (S5), and the power pad assembly step (S6).

Here, in the flame retardant forming process (S1), the carbon fiber yarn is knitted by a weaving device to form a heating paper 11 having a network structure, and the formed heating paper 11 is attached to the body surface. It is preferable to cut it to a possible shape and size, and to make the process of forming the electrode 111 on one side of the cut heating paper 11 again.

In addition, in the scoria composition pretreatment process (S2), the scoria powder pulverized to a powder particle size in the range of 5 μm to 10 μm is 60 to 65 with a liquid inorganic binder in a weight ratio of 25 to 30%. %, and silver nano powder pulverized to a powder particle size in the range of 5 μm to 10 μm is added in a weight ratio of 5 to 10%, and the additive materials, for example, inorganic binder, scoria powder, and silver nano It is preferable to put the powder into an industrial mixing mixer and make it a process of mixing processing in the range of 100 to 120 minutes.

At this time, the inorganic binder added in the Scoria composition pretreatment process (S2) means a normal liquid adhesive material that does not contain heavy metals or other toxic substances and is harmless to the human body. A conventional weapon binder widely used in the field is selectively applied.

In addition, in the pretreatment step (S3) of the schungit composition, the liquid inorganic binder is used in a weight ratio of 25 to 30%, and the processed schungit powder to a powder particle size in the range of 5 μm to 10 μm is mixed with 60 to 65% by weight, and silver nano powder pulverized to a powder particle size in the range of 5 μm to 10 μm is added in a weight ratio of 5 to 10%, and the additive is added to an industrial mixing mixer for 100 to 120 minutes It is preferable to make it a process of mixing processing in the range.

At this time, the inorganic binder added in the scoria composition pretreatment process (S2) is the same as the inorganic binder used in the aforementioned scoria composition pretreatment process (S2), and a detailed description thereof will be omitted.

In addition, the health supplement coating process (S4), on the surface and back of the heating paper 11 formed through the above-mentioned heating paper forming process (S2), mixed through the above-mentioned Scoria composition pretreatment process (S3) The scoria composition is first applied by spraying to form the scoria coating layers 12 and 12', and again, the scoria coating layers 12 and 12' are subjected to the aforementioned Schungit composition pretreatment process (S3). It is preferable to perform secondary coating treatment of the chungit composition mixed through the spray method to form the schungit coating layers 13 and 13'.

In addition, the patch body molding process (S5) is a heating paper ( 11), the low-frequency stimulation unit 14 is laminated and bonded to one surface, and the entire configuration of the heating paper 11 to which the low-frequency stimulation unit 14 is laminated is molded into the surface-attached shell 15 made of silicone resin. It is preferable to seal and accommodate the heating paper 11 in a process of forming the patch body 1 by coating the silicone adhesive layer 16 on one side of the front surface of the surface-attached shell 15 accommodating the heating paper 11 . .

Finally, in the power pad assembly process (S6), the power supply pad (2) is fixedly coupled to one side of the patch body (1) formed through the above-described patch body molding process (S5) in a press engagement structure to supply power It is preferable to connect the electrical connection part 21 formed of the pad 2 and the electrode 111 formed of the heating paper 11 in an energized structure. A multifunctional thermal stimulation transdermal patch manufacturing method using a planar heating element according to the present invention is implemented.

1: patch body 2: power supply pad
3: storage battery 11: heating paper
12,12': Scoria coating layer 13,13': Schungit coating layer
14: low-frequency stimulation unit 15: surface-attached shell
16: silicone adhesive layer 17: sanitary sheet
18: power connector 19,19': auxiliary wear hole
21: electrical connection 22: storage battery connection hole
23: stimulation device control unit 31: power connection terminal

Claims (7)

It includes a heating paper 11 having a mesh structure woven with thin fiber yarn, and a scoria coating layer 12 (12 ') and a schungit coating layer (13) (13 ') on the surface and the back surface of the heating paper 11. It is formed in a symmetrical pair of sequential stacking structures, and the low-frequency stimulation unit 14 is laminated and installed on one surface of the heating paper 11 on which the scoria coating layers 12 and 12 ' and the schungit coating layers 13 and 13' are formed. , The heating paper 11 with the low-frequency stimulation unit 14 installed is sealed and accommodated in a molding structure by a soft surface-attached outer shell 15, and a silicone adhesive layer 16 is further coated on one side of the surface-attached outer shell. patch body (1);
The electrical connection part 21 is built-in on one inner side, and a pair of half-moon groove-shaped storage battery connection hole 22 tube stimulation control unit 23 is formed on the outer surface, and the patch body 1 is coupled to one side. Power supply pad to be connected (2);
A pair of power connection terminals 31 symmetrical to one side are formed to protrude, and a pair of power connection terminals 31 are attached to and detached from the half-moon shaped storage battery connection hole 22 in a rotation hooking connection structure. A multifunctional thermal stimulation transdermal patch using a planar heating element, characterized in that it comprises a storage battery (3).
The method of claim 1 ;
The patch body (1) is a multifunctional thermal stimulation transdermal patch using a planar heating element, characterized in that it is formed in a bent three-dimensional shape corresponding to any one of the body joints of the knee, elbow, and shoulder.
The method of claim 1 ;
The patch body 1 has a mesh structure in which the scoria coating layers 12 and 12 ′, the schungit coating layers 13 and 13 ′, and the low frequency stimulation unit 14 are laminated on the surface of the heating paper 11 . It includes sealing and accommodating the attachment shell 15 in a molding structure;
forming a sheet exchange groove 151 in which a plurality of vent holes (P) are through-arranged in the central portion of one side of the surface-attached shell 15 in which the heating paper 11 is accommodated;
coating the sheet exchange groove 151 and the surface-attached outer shell 15 in which the sheet exchange groove 151 is formed with a silicone adhesive layer 16 on the entire surface;
A multifunctional thermal stimulation transdermal patch using a planar heating element, characterized in that it is formed of a sanitary sheet (17) installed in the sheet exchange groove (151) in a detachable and attachable exchange structure.
The method of claim 1 ;
The patch body (1) has a mesh structure woven from carbon fiber yarns (11), a surface-attached shell (15) for sealingly accommodating the heating paper (11) in a molding structure, and the heating paper (11). A silicon adhesive layer 16 coated on one side of the surface-attached shell 15 accommodated therein, and a heating paper 11 and an electrode structure on the outer surface of the surface-attached shell 15, and a power connector exposed to the outside (18);
The storage battery 3 is formed in a pad-type structure provided with a power connection jack 32 connected to the power connector 18 of the patch body 1 in a detachable and attachable structure, and a power on/off switch. Multifunctional thermal stimulation transdermal patch using a planar heating element.
5. The method of claim 4;
The patch body 1 forms a pair of auxiliary wearing holes 19 and 19' facing one side and the other side, and a belt (B) is formed in the pair of auxiliary wearing holes 19 and 19'. A multifunctional thermal stimulation transdermal patch using a planar heating element, characterized in that it is connected and the patch body (1) is worn on the painful part of the human body.
5. The method of claim 4;
The patch body (1) is processed and cut in a variable configuration in shape, shape, and size, and is variably formed into any one of a heating mat for leisure, a heating cushion for outdoor use, a cover for keeping food, and a heating seat for automobiles. Multifunctional thermal stimulation transdermal patch using a planar heating element.
The carbon fiber yarn is knitted by a weaving device to form a mesh-structured heating paper 11, and the formed heating paper 11 is cut to a shape and size that can be attached to the body surface, and the cut heating paper 11 ) forming an electrode 111 on one side of the heating paper forming process (S1);
With a liquid inorganic binder in a weight ratio of 25 to 30%, here, a scoria powder pulverized to a powder particle size in the range of 5 μm to 10 μm, in a weight ratio of 60 to 65%, and 5 μm to 10 μm Scoria composition pretreatment process (S2) in which silver nano powder pulverized to a powder particle size in the range is added in a weight ratio of 5 to 10%, and the additive material is put into an industrial mixing mixer and mixed and processed in a range of 100 to 120 minutes (S2) ;
With the liquid inorganic binder in a weight ratio of 25 to 30%, here, the Schungit powder processed to a powder particle size in the range of 5 μm to 10 μm, in a weight ratio of 60 to 65%, and 5 μm to 10 μm The pre-treatment process of the schungit composition in which silver nano powder pulverized to a powder particle size in the range of 5 to 10% by weight is added, and the additive material is put into an industrial mixing mixer and mixed and processed in the range of 100 to 120 minutes (S3) );
A scoria coating layer ( 12) (12') is formed, and the schungit composition mixed through the pre-treatment process (S3) of the schungit composition is applied to the formed scoria coating layers (12, 12') by a secondary coating process by spraying. A health supplement coating process (S4) to form the schungit coating layer (13) (13');
Through the health supplement coating process (S4), the low-frequency stimulation unit 14 is laminated and combined on one side of the heating paper 11 on which the scoria coating layers 12 and 12 ′ and the schungit coating layers 13 and 13 ′ are formed. The entire configuration of the heating paper to which the low-frequency stimulation unit 14 is laminated is sealed and accommodated in the surface-attached shell 15 made of silicone resin in a molding method, and a silicone adhesive layer ( 16) by coating the patch body to form the patch body 1 (S5);
The power supply pad 2 is fixedly coupled to one side of the patch body 1 formed through the patch body molding process (S5) in a press fit structure, and the electrical connection part 21 formed of the power supply pad 2 and the heating paper A multifunctional thermal stimulation transdermal patch manufacturing method using a planar heating element, characterized in that it is made through a power pad assembly process (S6) that connects the electrodes 111 formed of (11) in an energized structure.

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