JPH0939407A - Manufacture of heat transfer sheet containing substance developing contact potential and method for sticking substance developing contact potential to cloth - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the method for sticking a substance developing contact potential to cloth, by which the substance developing contact potential such as germanium, silicon or the like is easily stuck to cloth. SOLUTION: Substance developing contact potential such as germanium, silicon or the like is pulverized into fine particles having the mesh, which is at least 100 mesh, so as to mix the resultant pulverized substance and a foaming agent with a non-electroconductive heat-transfer adhesive. The heat-transfer adhesive mixed with the substance developing contact potential such as germanium, silicon or the like is applied through silkscreen to releasing paper 1 so as to form a heat transfer adhesive layer 2. By heating from the top surface of the releasing paper 1 under the condition that the heat transfer adhesive layer 2 is applied against the cloth 3 on the side contacting with skin, the projecting substance developing contact potential such as germanium, silicon or the like is bonded to the cloth 3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for producing a thermal transfer sheet containing a substance that causes a contact potential difference and a method for adhering a substance that causes a contact potential difference to a cloth, and in particular, to a substance such as germanium or silicon that causes a contact potential difference easily. The present invention relates to a method for producing a thermal transfer sheet containing a substance that produces a contact potential difference that can be attached to a fabric, and a method for attaching a substance that produces a contact potential difference to the fabric.

[0002]

2. Description of the Related Art The fact that a solid piece made of germanium is brought into contact with the acupuncture points of the skin of the human body to have stiff shoulders and shoulder pain is described, for example, in Japanese Patent Publication No. 58-48186. , Is known.

The skin fastener disclosed in Japanese Patent Publication No. 58-48186 has a solid piece of germanium fixed to the acupuncture route of the skin of the human body with a bandage.

[0004]

However, in the one described in this publication, germanium is brought into contact with the skin by a plaster, so that some people have a rash on the skin, and the adhesive force is changed due to the change over time of the plaster. Because it decreases
There was a problem in that the bandages had to be replaced frequently, which was annoying.

In order to improve this problem, finely powdered germanium is mixed with an adhesive on a cloth such as clothes and directly printed (applied) through a silk screen to form an adhesive layer containing germanium, After that, it is conceivable that the adhesive layer containing germanium is heated to be bonded.

However, in the above method, if the sewn portion of the cloth such as clothes or the cloth itself has an uneven portion,
There is a problem in that a gap is formed between the silk screen and the fabric to be printed, which makes uniform printing difficult.

It is an object of the present invention to provide a method for producing a thermal transfer sheet containing a substance that causes a contact potential difference and a method for adhering a substance that causes a contact potential difference to a cloth so as to eliminate the above-mentioned conventional problems.

[0008]

In order to achieve the above object, the method for producing a thermal transfer sheet containing a substance that produces a contact potential difference according to the present invention is a method in which a substance such as germanium or silicon that produces a contact potential difference is finely powdered. The powdered substance is mixed with a thermal transfer adhesive to form a thermal transfer adhesive layer on release paper.

Further, the method of depositing a substance for producing a contact potential difference according to the present invention is a method of depositing germanium for producing a contact potential difference,
A substance such as silicon is finely powdered, the finely powdered substance is mixed with a thermal transfer adhesive to form a thermal transfer adhesive layer on release paper, and the thermal transfer adhesive layer is applied to a fabric, and the thermal transfer adhesive layer is applied from the upper surface of the release paper. A material such as germanium or silicon that is heated to cause the contact potential difference is adhered to the cloth.

Further, the method of depositing a substance for producing a contact potential difference according to the present invention includes a germanium which produces a contact potential difference,
The size of the mesh is at least 1 for materials such as silicon
Thermal transfer in which the fine powder is made larger than 00 mesh, and the finely powdered substance and the foaming agent are mixed with a non-conductive heat transfer adhesive to mix the contact potential difference, such as germanium and silicon, and the foaming agent. The adhesive is applied to release paper through a silk screen to form a heat transfer adhesive layer, and the heat transfer adhesive layer is applied to the fabric on the side that contacts the skin, and the heat is applied from the upper surface of the release paper to the fabric. A material such as germanium or silicon which causes the above-mentioned contact potential difference protruding is adhered.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a schematic cross-sectional view of an embodiment of a thermal transfer sheet S containing a substance that produces a contact potential difference. The thermal transfer sheet S containing a substance that produces a contact potential difference is a surface adhesive agent.
A thermal transfer adhesive layer 2 is formed on a release paper 1 coated with a release agent.

The thermal transfer adhesive layer 2 is formed by finely pulverizing a substance such as germanium or silicon which produces a contact potential difference,
It is formed by mixing a substance such as germanium, silicon, or the like, which is pulverized into a contact potential difference, into a thermal transfer adhesive.

Substances such as germanium and silicon which generate a contact potential difference are made into fine powder, for example, 100 mesh to 350 mesh (the upper limit is 350 mesh, but the finer the powder size, the better the mesh size. It is fine if it is at least larger than 100 mesh.)

The finely divided substance prevents the finely divided substance from damaging the fibers of the silk screen when passing through the silk screen described later.

Further, as the substance which causes the contact potential difference,
In addition to germanium and silicon, alloys such as silicon carbide and germanium silicon, and iron, magnetite, brass, titanium, silver, and gold may be used alone or in combination so as to easily generate a contact potential difference.

The shape of fine powder of a substance such as germanium or silicon that causes a contact potential difference should be used in a crimped shiatsu state for the effect of improving stiff shoulders, muscle strength recovery, back pain, and other pain. Considering this, it is preferable that the tip has an acute angle rather than a spherical shape.

Considering that the thermal transfer adhesive is mixed with a substance such as germanium or silicon that produces a contact potential difference, a non-conductive thermal transfer adhesive such as an acrylic (more specifically, for example, acrylic ester Type) and epoxy type adhesives are preferable.

The mixing ratio of the substance causing the contact potential difference and the thermal transfer adhesive is 2 g to the substance producing the contact potential difference.
The heat transfer adhesive is 1 kg per 200 g, and more preferably, the substance which causes the contact potential difference is 5 kg to 100 g per 1 g of the heat transfer adhesive.

If the substance that causes the difference in contact potential is less than 5 g,
The effect of improving stiff shoulders, muscle recovery, low back pain, and other pain improving effects is weak, and conversely, there are 20 substances that cause a difference in contact potential.
If it exceeds 0 g, the fluidity of the mixture of the substance that causes the difference in contact potential and the thermal transfer adhesive is poor, and the mixture becomes difficult to pass through the silk screen described later, and the productivity is lowered.

Next, a method of adhering a substance causing a contact potential difference to a cloth by using the thermal transfer sheet S containing the substance causing a contact potential difference will be described.

A substance such as germanium or silicon that produces a contact potential difference is 100 mesh to 350 mesh (the upper limit is 350 mesh, but the finer the powder size, the better. The mesh size is at least 100 mesh. It is better if it is larger.)

Next, the finely powdered substance and the foaming agent are mixed into a non-conductive heat transfer adhesive, and the substance such as germanium and silicon which generate a contact potential difference, and the heat transfer adhesive containing the foaming agent are silk-screened. Is applied to the release paper 1 having the surface coated with a release agent and a release agent, and dried by keeping the ambient temperature at 50 to 100 degrees to form the thermal transfer adhesive layer 2 on the release paper 1 ( See FIG. 2).

Next, as shown in FIG. 3, the release paper 1 is cut into a desired shape, and the cut thermal transfer adhesive layer 2 is applied to the cloth 3 such as a T-shirt or a trainer on the side which comes into contact with the skin, and the release paper 1 is cut. 4 is heated from above by using an iron 5 or the like, as shown in FIG.
As shown in (b), the release paper 1 is peeled off and a substance such as germanium or silicon that causes a contact potential difference protruding to the fabric 3 is adhered (see FIG. 4C).

(Example 1) Micronized germanium 2
Stir well 00g, 40g of silicon and 1kg of thermal transfer adhesive (acrylic acid type copolymer) to uniformly disperse germanium and silicon.

Next, using a 90-mesh silk screen, germanium, silicon, and
A mixture of a thermal transfer adhesive (acrylic acid type copolymer) is extruded, printed and dried to form a thermal transfer sheet S containing a substance that causes a contact potential difference.

Next, the material-containing thermal transfer sheet S which produces a contact potential difference is cut into a desired shape, and the cut thermal transfer adhesive layer 2 of the material-containing thermal transfer sheet S producing a contact potential difference is cut into a T-shirt cloth as shown in FIG. 3 (the fabric 3 may be, for example, natural fiber, chemical fiber, woven fabric, or nonwoven fabric), that is, the side of the T-shirt that comes into contact with the skin (for example, shoulders, flanks, abdomen, , Only one side is shown in the figure, but symmetrically both shoulders, both flanks,
The thermal transfer adhesive layer 2 is applied to the abdomen and back. ), A substance that causes a contact potential difference can be attached to the fabric 3 by heating for about 20 seconds with an iron press machine (not shown) at about 140 ° C. After the attachment, as shown in FIG. 6, the T-shirt cloth 3 is returned to the front side.

(Example 2) Germanium 25 pulverized into fine powder
g, 75 g of silicon, 1 Kg of thermal transfer adhesive (chromate, gutylcellosolg, adhesive having celloace as a main component, trade name TRANSFER INK manufactured by Yoshikawa Kako Co., Ltd.) are well stirred to uniformly disperse germanium and silicon.

Next, using a 90 mesh silk screen, germanium, silicon,
A mixture of a thermal transfer adhesive (acrylic acid type copolymer) is extruded, printed and dried to form a thermal transfer sheet S containing a substance that causes a contact potential difference.

Next, as in Example 1, the thermal transfer sheet S containing a substance that produces a contact potential difference is cut into a desired shape, and the cut thermal transfer adhesive layer 2 of the thermal transfer sheet S containing a substance that produces a contact potential difference is shown in FIG. As described above, applying the material that causes the contact potential difference to the cloth 3 by applying it to the side of the cloth 3 of the T-shirt that comes into contact with the skin, that is, the lining portion and heating it with an iron press machine (not shown) at about 120 ° C. for about 10 seconds. You can

Example 3 Germanium 50 pulverized
g, Silicon 200g, Thermal transfer adhesive (Matsui Dye & Chemical Co., Ltd. product name Forming Binder-ST
R) 500 g, foaming agent (manufactured by Matsui Pigment Chemicals Co., Ltd.
Product name Forming Binder-STR 728) 500
Stir g well to disperse germanium and silicon uniformly.

Next, using a 90-mesh silk screen, germanium, silicon, and
Printed by extruding a mixture of thermal transfer adhesive, 80 ℃
Then, the material is temporarily dried to form a thermal transfer sheet S containing a substance that produces a contact potential difference.

Next, as in the case of Example 1, the thermal transfer sheet S containing a substance that produces a contact potential difference is cut into a desired shape, and the cut thermal transfer adhesive layer 2 of the thermal transfer sheet S containing a substance that produces a contact potential difference is shown in FIG. As described above, applying the material that causes the contact potential difference to the cloth 3 by applying it to the side of the cloth 3 of the T-shirt that comes into contact with the skin, that is, the lining portion and heating it with an iron press machine (not shown) at about 120 ° C. for about 10 seconds. You can

In this embodiment, since the foaming agent is mixed in, the substance which causes the contact potential difference can be made more convex and can be attached to the fabric 3.

When the substance causing the contact potential difference is made more convex and is attached to the cloth 3, the substance causing the contact potential difference is more in contact with the body when the cloth 3 is worn, stiff shoulders, muscle recovery, Low back pain and other pain improving effects can be promoted.

In this embodiment, the T-shirt is used as the fabric 3, but the present invention is not limited to this. For example, as shown in FIG. 7 and FIG. 8 is a rubber portion, and H is a sewing portion in FIG. 8. Also, as shown in FIG. 9, socks, shirts (not shown), supporters (not shown), etc. can be similarly applied. Is.

[0037]

The method for producing a thermal transfer sheet containing a substance producing a contact potential difference according to the present invention comprises finely pulverizing a substance such as germanium or silicon producing a contact potential difference and mixing the finely pulverized substance with a thermal transfer adhesive. Since the thermal transfer adhesive layer is formed on the release paper, even if there is an uneven portion on the sewn portion of cloth such as clothing or the cloth itself, by applying the heat transfer adhesive layer to the portion and heating it It can be easily adhered to cloth such as clothes.

Further, the method of depositing a substance producing a contact potential difference on a cloth according to the present invention is a germanium which produces a contact potential difference,
A substance such as silicon is finely powdered, and the finely powdered substance is mixed with a thermal transfer adhesive to form a thermal transfer adhesive layer on release paper.Therefore, there are irregularities on the sewn portion of cloth such as clothing and the cloth itself. However, it is possible to apply a thermal transfer adhesive layer to the portion and heat the upper surface of the release paper to easily adhere a substance such as germanium or silicon that causes the contact potential difference to the cloth.

Further, the method for depositing a substance producing a contact potential difference on a cloth according to the present invention is a germanium which produces a contact potential difference,
The size of the mesh is at least 1 for materials such as silicon
Thermal transfer in which the fine powder is made larger than 00 mesh, and the finely powdered substance and the foaming agent are mixed into a non-conductive thermal transfer adhesive to mix the contact potential difference substance such as germanium and silicon, and the foaming agent. Apply adhesive to release paper through silk screen to form thermal transfer adhesive layer, and even if there is uneven part on the sewn part of cloth such as clothing, or the cloth itself, on the side that touches the skin A thermal transfer adhesive layer is applied, and a material such as germanium or silicon that causes the contact potential difference on the cloth by heating from the upper surface of the release paper can be easily adhered, and germanium,
Since substances such as silicon have a mesh size of at least 100 mesh and become fine powder and small,
When passing through a silk screen, it prevents damage to the silk screen, and by adding a foaming agent, the substance that causes a contact potential difference can be made more convex so that it can be attached to the fabric, resulting in a contact potential difference substance. There is more contact with the body to promote stiff shoulders, muscle recovery, low back pain and other pain improving effects.

[Brief description of drawings]

FIG. 1 is a schematic cross-sectional view of a thermal transfer sheet containing a substance that produces a contact potential difference according to an embodiment of the present invention.

FIG. 2 is a schematic perspective view of a thermal transfer sheet containing a substance that causes a contact potential difference of FIG.

FIG. 3 is a schematic perspective view of a state in which the thermal transfer sheet containing the substance causing the contact potential difference of FIG. 2 is cut.

FIG. 4 is a stepwise view showing a state in which a substance that causes a contact potential difference is adhered to a cloth. (C) shows a state in which the release paper is peeled off.

FIG. 5 shows a method of depositing a substance that causes a contact potential difference on a cloth according to an embodiment of the present invention, and is an explanatory view illustrating a state in which a substance that causes a contact potential difference is attached to a fabric by turning over a T-shirt. Is.

FIG. 6 is an explanatory diagram illustrating a state in which the T-shirt of FIG. 5 is turned upside down.

FIG. 7 is an explanatory diagram illustrating a state in which a substance that causes a contact potential difference is attached to the trunks.

FIG. 8 is an explanatory diagram illustrating a state in which a substance that causes a contact potential difference is attached to another trunk different from that in FIG.

FIG. 9 is an explanatory diagram illustrating a state in which a substance that causes a contact potential difference is attached to socks.

[Explanation of symbols]

 1 Release Paper 2 Thermal Transfer Adhesive Layer 3 Fabric

Claims (3)

[Claims] 1. A contact characterized in that a substance such as germanium or silicon which produces a contact potential difference is pulverized and the pulverized substance is mixed with a thermal transfer adhesive to form a thermal transfer adhesive layer on a release paper. A method for producing a thermal transfer sheet containing a substance that produces a potential difference. 2. A substance such as germanium or silicon which produces a contact potential difference is finely pulverized and the finely pulverized substance is mixed with a thermal transfer adhesive to form a thermal transfer adhesive layer on a release paper. Is applied to a cloth, and a substance such as germanium or silicon that causes the contact potential difference is adhered to the cloth by heating from the upper surface of the release paper. 3. The mesh size of a substance such as germanium or silicon which causes a contact potential difference is at least 100.
A thermal transfer adhesive containing a substance such as germanium or silicon that causes the contact potential difference, and the foaming agent mixed by mixing the finely pulverized material and the foaming agent into a non-conductive thermal transfer adhesive that is larger than the mesh The agent is applied to release paper through a silk screen to form a thermal transfer adhesive layer, and this thermal transfer adhesive layer is applied to the fabric that is in contact with the skin,
A method of adhering a material for producing a contact potential difference, which is characterized in that a substance such as germanium, silicon or the like, which is heated from the upper surface of the release paper and protrudes into the fabric, which causes the contact potential difference, is adhered.