TW201946599A - Far-infrared magnetic energy patch structure and manufacturing method thereof characterized by containing the magnetic element and the mineral powders to generate the magnetic force and the effective vibration for treating user's body, and by having the printing pattern layer to increase the appearance diversity - Google Patents

Abstract

The present invention relates to a far-infrared magnetic energy patch structure and a manufacturing method thereof. The main structure includes a breathable patch. The breathable patch includes at least a first sheet body, at least one adhesive part, and a second sheet body. The first sheet body is provided with a printing pattern layer. The printing pattern layer includes a water-based glue, a plurality of mineral powders distributed in the water-based glue, and a magnetic element. The magnetic element is adhered to the first sheet body via the adhesive part. With the above structure, when user uses the patch, the user can detach the first sheet body from the second sheet body and adhere to the user's body with the adhesive part. The magnetic element and the mineral powders generate the magnetic force and the effective vibration to treat user's body. The first sheet body has dual effect. Because the printing pattern layer is manufactured by a printing manner, the printing pattern layer can be printed to have various patterns, thereby increasing the appearance diversity.

Description

   Far infrared magnetic energy patch structure and manufacturing method thereof   

The invention is to provide a far-infrared magnetic energy patch structure and a manufacturing method thereof, in particular to a far-infrared magnetic energy patch structure with dual effects and a more diverse appearance and a manufacturing method thereof.

Press, because most of the modern office workers will sit in front of the computer for a long time, so the problem of shoulder and neck pain has become a common problem of office workers. In addition, some people also have soreness in various parts of the body due to poor posture or sports injuries. situation. However, if such a sore condition occurs in modern people, most people will use a patch to relieve sore symptoms.

And most of the sore patches have only a single effect, some will use patches that emit far-infrared wave fluctuations, and some will use magnets to radiate magnetic force to produce various effects on the human body. But no matter what kind of patch, if you want to make multiple performances together at the same time, it is more troublesome, and the shape of most patches is more uniform, there are no special patterns or styles, so it will not increase consumers. The desire to buy and the variety of appearances are limited.

Therefore, how to solve the above-mentioned problems and shortcomings, that is, the direction in which the applicants of the new model and the relevant manufacturers engaged in this industry are eager to study and improve.

Therefore, the inventor of the present invention, in view of the above-mentioned shortcomings, collected relevant information, evaluated and considered from various parties, and based on years of experience accumulated in this industry, and continued to make trials and modifications, he began to design such utilization of ore powder and magnetic The component has dual effects, and can also change the appearance of the printed modeling layer, so that it has a variety of far-infrared magnetic energy patch structures and the inventor of its manufacturing method.

The main purpose of the present invention is to use the ore powder and magnetic components to make the first sheet have double performance, and the printing modeling layer with the ore powder can be printed into different shapes, and the printing method can have convenience and speed and appearance. Diversified effects.

To achieve the above object, the main structure of the present invention includes: a breathable patch, and the breathable patch includes at least a first sheet body, at least one adhesive portion defined on the first sheet body, and a first sheet body The second sheet body at one side of the body, a printing modeling layer, the printing modeling layer includes a water-based glue printed on the first sheet body, a plurality of ore powder mixed in the water-based glue, and a connection to the first through an adhesive portion. A magnetic element on a body.

With the above structure, the user needs to take the breathable patch, cut the breathable patch to a predetermined size, then mix the water-based glue with a plurality of ore powders, and then print the water-based glue mixed with the ore powder on the On the first sheet body, cut the breathable patch to the shipping size, and cut out the perforated part on the second sheet body, and then the magnetic element can be pasted on the adhesive part through the perforated part, thereby making the magnetic element Connected to the first sheet body.

When using, the user can tear off the first piece from the second piece, and then use the adhesive part to stick the first piece to the human body, and then use the wave emitted by the ore powder in the water-based glue ( (Such as far-infrared rays or negative ions), and the magnetism emitted by magnetic components, to have a positive impact or efficacy on the human body. In addition, the printing modeling layer can be printed into various patterns, so that it can quickly and conveniently have dual effects at the same time, and can make the appearance diverse.

With the above-mentioned technology, it is possible to break through the problem that conventional patches are troublesome to manufacture if they have dual functions, and cannot have various appearances, so as to achieve the practical advancement of the above advantages.

1‧‧‧ breathable patch

11, 11a‧‧‧ the first body

111a‧‧‧The first cutting department

12‧‧‧ Adhesive Department

13, 13a‧‧‧Second body

131‧‧‧Perforation

132a‧‧‧Second Cutting Section

133a‧‧‧Ministry of Graphic Arts

2‧‧‧printing modeling layer

21‧‧‧ Water-based glue

22‧‧‧ore powder

3‧‧‧ magnetic components

The first figure is a perspective view of a preferred embodiment of the present invention.

The second figure is an exploded view of a preferred embodiment of the present invention.

The third figure is a schematic diagram of the manufacturing process of the preferred embodiment of the present invention.

The fourth figure is a schematic diagram (a) of the cutting of the preferred embodiment of the present invention.

The fifth figure is a printing schematic diagram of a preferred embodiment of the present invention.

The sixth figure is a schematic diagram of cutting (b) of the preferred embodiment of the present invention.

The seventh figure is a schematic diagram of the peeling of the preferred embodiment of the present invention.

The eighth figure is a schematic diagram of sticking according to a preferred embodiment of the present invention.

The ninth figure is a schematic diagram of a preferred embodiment of the present invention.

The tenth figure is an exploded view of still another preferred embodiment of the present invention.

The eleventh figure is a schematic diagram of a manufacturing process according to another preferred embodiment of the present invention.

The twelfth figure is a printing schematic diagram of still another preferred embodiment of the present invention.

The thirteenth figure is a schematic cutting diagram of still another preferred embodiment of the present invention.

The fourteenth figure is a schematic diagram of the use of another preferred embodiment of the present invention.

The fifteenth figure is a schematic diagram of tearing off according to another preferred embodiment of the present invention.

In order to achieve the above-mentioned object and effect, the technical means and structure adopted by the present invention are described in detail below with reference to the preferred embodiments of the present invention.

Please refer to the first to ninth figures, which are perspective views to schematic diagrams of the preferred embodiments of the present invention. It can be clearly seen from the figure that the present invention includes: a breathable patch 1, a plurality of first sheets 11 , A plurality of adhesive portions 12, a second sheet body 13, a plurality of perforated portions 131, a printing modeling layer 2, a water-based adhesive 21, a plurality of ore powder 22, a plurality of magnetic elements 3, wherein the breathable patch 1 includes a plurality of first pieces Body 11, and the adhesive part 12 is defined on the first sheet body 11, and the first sheet body 11 is adhered to the second sheet body 13 by the adhesive part 12, and the first sheet body 11 is a breathable tape, and the adhesive part 12 is passed through The adhesive is approved by medical glue, and the second sheet body 13 is a release paper. The perforated portion 131 is formed on the second sheet body 13. A printing modeling layer 2 is printed on the first sheet body 11. The printing modeling layer 2 includes a printing The water-based glue 21 on the first sheet body 11 and a plurality of ore powders 22 mixed in the water-based glue 21, and each magnetic element 3 penetrates through the perforated portion 131, and is connected to the first piece body 11 by the adhesive portion 12. .

Based on the above description, the structure of the technology can be understood, and according to the corresponding cooperation of this structure, the printed molding layer 2 and the magnetic element 3 can be used to make the first sheet body 11 have dual performance, and the printed molding layer 2 can Various patterns are printed to make the appearance diverse, and detailed explanation will be described below.

The manufacturing method of the present invention is: (a) take a breathable patch 1, and the breathable patch 1 includes at least a first sheet 11 and is adhered to a second sheet 13 by using at least an adhesive portion 12; b) Refer to the fourth figure, cut the breathable patch 1 to a predetermined size (about 29cm * 21cm); (c) Refer to the fifth figure, take a water-based glue 21 and multiple ore powder 22, and then The water-based glue 21 and the ore powder 22 are mixed with each other and printed on the breathable patch 1 to form a printed modeling layer 2; (d) Referring to the sixth figure, the first sheet 11 in the breathable patch 1 And the second sheet body 13 is cut to the shipping size (the second sheet body 13 is about 8cm * 6cm); (e) the perforated portion 131 can be cut out on the second sheet body 13 as shown in the seventh figure; (f ) As shown in FIG. 8, the magnetic element 3 is passed through the position of the perforated portion 131 and then connected to the first sheet body 11 according to the positive and negative electrodes.

Since the printed modeling layer 2 contains the water-based adhesive 21, it can be printed on the first sheet 11 in a printed manner. The user can tear the first sheet 11 away from the second sheet 13 during use, and then use the adhesive part. 12 Adhere the first sheet body 11 to the human body.

As shown in the ninth figure, the ore powder 22 in the printed modeling layer 2 is a ore powder 22 having a far-infrared function or a ore powder 22 having a negative ion function, but it is not limited, so that the ore powder layer 22 can be It emits waves that are beneficial to the human body. The magnetic element 3 is a magnet that can emit magnetism. It can cooperate with the ore powder layer 22 to create dual effects on the human body. Far-infrared rays can penetrate into the subcutaneous tissue of the human body to produce a resonance effect to expand blood vessels and promote blood circulation. Magnets can balance the positive and negative currents in the human body to promote blood circulation and eliminate fatigue.

In addition, the printing modeling layer 2 can be printed into various cute patterns, so that it has a variety of appearances, so as to increase consumers' purchase desire.

Please also refer to the tenth to fifteenth figures together, which are exploded views to tear off schematic diagrams of yet another preferred embodiment of the present invention. It can be clearly seen from the figure that this embodiment and the above embodiment are It is similar, the first sheet body 11a also has a plurality of first cutting parts 111a, and the second sheet body 13a has a plurality of second cutting parts 132a and at least one graphic part 133a. The process steps are as follows: In the above steps ( c) A step (c1) is added afterwards as shown in the twelfth figure, a plurality of graphic sections 133a are printed on the second sheet body 13a; a step (e1) is added after the above step (e) as the tenth step As shown in the three figures, a plurality of first cutting parts 111a are cut on the first sheet body 11a; after the above step (e1), a step (e2) is added as shown in the thirteenth figure on the second sheet body A plurality of second cutting sections 132a are added to 13a; in this way, the graphic section 133a can print the required text according to the needs of the user to increase its functionality. When the user attaches the first piece 11a to the joint, he can refer to the fourteenth figure. Since the first piece 11a can be separated by the first cutting portion 111a, the corner can be separated according to the joint surface. Fitting at different angles separately, so it can fit more closely to the joints of the user. When the user tears off the first sheet 11a, as shown in the fifteenth figure, the second sheet 13a can be torn apart through the second cutting portion 132a, so that the first sheet 11a can be easily separated from the second sheet.体 13a.

However, the above description is only the preferred embodiment of the present invention, and it does not limit the patent scope of the present invention. Therefore, all simple modifications and equivalent structural changes made by using the description and drawings of the present invention should be the same. It is included in the patent scope of the present invention and is incorporated by Chen Ming.

Therefore, the far-infrared magnetic energy patch structure of the present invention and the manufacturing method thereof can improve the conventional technology. The key lies in: using a printing method to quickly print the printing modeling layer 2 on the first sheet body 11 so as to cooperate with the magnetic element 3 to achieve Dual effect, and the printed shape layer 2 can have different shapes to increase the diversity of the appearance of the breathable patch 1.

In summary, the far-infrared magnetic energy patch structure of the present invention and the manufacturing method of the present invention are sure to achieve its efficacy and purpose when in use. Therefore, the present invention is an invention with excellent practicability and is in accordance with the application requirements of the invention patent He submitted an application in accordance with the law, and hopes that the review committee will grant the invention as soon as possible to protect the applicant's hard work. If there is any suspicion by the review committee of the Bureau, please follow the instructions of the letter, and the applicant will cooperate with all efforts and be honest.

Claims (10)

    A far-infrared magnetic energy patch structure mainly includes: a breathable patch, the breathable patch includes at least a first sheet body, at least an adhesive part, and a second sheet body, the adhesive part is defined in the first The first sheet body is affixed to the second sheet body with the adhesive part; a printing modeling layer is provided on the first sheet body, and the printing modeling layer uses a water Formed by mixing a plurality of ore powders and printing on the first sheet body; a perforated portion formed on the second sheet body; and at least one magnetic element connected to the magnetic element via the adhesive portion The first sheet body is located in the perforated portion.         The far-infrared magnetic energy patch structure according to item 1 of the scope of patent application, wherein the first sheet body has at least one first cutting portion.         The far-infrared magnetic energy patch structure according to item 1 of the patent application scope, wherein the second sheet body has at least one graphic portion.         The far-infrared magnetic energy patch structure according to item 1 of the patent application scope, wherein the second sheet body has at least one second cutting portion.         The far-infrared magnetic energy patch structure according to item 1 of the scope of the patent application, wherein the ore powder is one of a far-infrared ore powder or an anion ore powder.         A method for manufacturing a far-infrared magnetic energy patch structure, the steps are as follows: (a) taking a breathable patch, the breathable patch includes at least a first sheet body, at least one adhesive part defined on the first sheet body, And a second piece for adhering the first piece; (b) cutting the breathable patch to a predetermined size; (c) taking a water-based glue and a plurality of ore powders and mixing them with each other, and then mixing the The water-based glue of a plurality of ore powders is printed on the first sheet to form a printed modeling layer; (d) the breathable patch with the printed modeling layer is cut to the shipping size; (e) the second sheet is cut out At least one perforated part; (f) pasting at least one magnetic element on the adhesive part through the perforated part, so as to be connected to the first sheet body.         The manufacturing method of the far-infrared magnetic energy patch structure described in item 6 of the patent application scope, further comprising step (c1) at least one graphic portion is printed on the second sheet body.         According to the manufacturing method of the far-infrared magnetic energy patch structure described in item 6 of the patent application scope, the method further includes step (e1) cutting out at least one first cutting portion on the first sheet body.         According to the manufacturing method of the far-infrared magnetic energy patch structure described in item 6 of the patent application scope, the method further includes step (e1) cutting out at least one second cutting portion on the second sheet body.         The manufacturing method of the far-infrared magnetic energy patch structure described in item 8 of the scope of the patent application, further comprising step (e2) cutting out at least one second cutting portion on the second sheet body.