KR100451912B1 - Far infrared ray emission pocket and thereof method - Google Patents

Abstract

The present invention relates to a far-infrared radiator bag and a manufacturing method thereof, wherein a guide member having a plurality of cylindrical main walls is welded on a bottom member, and a granular far-infrared radiator is contained in a cylindrical main wall of the guide member, and the guide member and A mesh covering member is covered on a far infrared radiator to provide a far infrared ray radiator bag and a manufacturing method thereof, wherein the peripheral portions of the mesh covering member, the guide member, and the bottom member are integrally welded together. The present invention has the advantage that can easily produce a plurality of far-infrared radiator bag, the amount of far-infrared radiator grains is uniformly embedded in the far-infrared radiator bag, the quality of the product is kept uniform, the built-in far-infrared radiator grains are mesh Since it is exposed to the outside through the covering member there is an advantage that the effect of emitting far infrared rays is improved.

Description

Far infrared ray radiator bag and manufacturing method thereof {FAR INFRARED RAY EMISSION POCKET AND THEREOF METHOD}

The present invention relates to a far-infrared radiator bag and a method for manufacturing the same, and in particular, filling the far-infrared radiator grains into the main wall of the guide member welded to the bottom member, and forming the far-infrared radiator grains to be exposed to the outside through the mesh covering member. The present invention relates to a far-infrared radiator bag and a method of manufacturing the same, which simplify the operation and improve the far-infrared emission effect.

1 to 4, the conventional far-infrared radiator mat has a configuration in which a plurality of far-infrared radiator pockets 20 are vertically and horizontally disposed and bonded to the mat body 10, and the far-infrared radiator pocket ( 20 is a peripheral portion of the synthetic resin laminate covering member 22 on the synthetic resin laminate bottom member 21 is joined by high frequency heat welding, etc., the far infrared radiator 1 is inserted between the bottom member 21 and the covering member 22. It is made up of. For this far-infrared radiator 1, jade processed into a disc shape is used, for example.

In manufacturing such a conventional far-infrared radiator mat, after placing the far-infrared radiator 1 processed into a disc shape on the bottom member 21, the covering member 22 in which the receiving groove into which the far-infrared radiator 1 is inserted is formed in advance. ) Is placed on the far-infrared radiator 1, and the far-infrared radiator bag 20 is formed by a process of thermally welding and joining the peripheral portions of the bottom member 21 and the covering member 22.

In this way, in manufacturing the far-infrared radiator bag 20, a plurality of far-infrared radiators are typically formed by using the bottom member 21 and the covering member 22 having a size in which a plurality of far-infrared radiator pockets 20 can be formed. After (1) is welded at a time, it is manufactured by the process of being separated into pieces by cutting.

The far-infrared radiator pocket 20 as described above has the bottom member 21 and the covering member 22 completely sealed, so that the far-infrared radiator 1 is inserted into the sealed receiving space, thereby reducing the effect of emitting far infrared rays. have.

In addition, in the case of using a grain form for the far-infrared radiator 1, there is a problem in that it cannot be employed structurally.

That is, when a large amount of crystal grains are stacked on the bottom member 21, and the covering member 22 is welded, the crystal grains are not gathered in a certain form and are scattered downward, so that a certain amount of correction cannot be welded in a desired form. Therefore, the same form as the conventional far-infrared radiator bag 20 was not applicable to the granular far-infrared radiator 1.

The present invention has been made to solve the above-mentioned problems and defects as described above, welding a guide member having a cylindrical main wall to a synthetic resin laminate bottom member, and filling the granular far-infrared radiator inside the main wall portion of the guide member; The far-infrared radiator pocket and its far-infrared radiating effect which can be easily packaged with a predetermined amount of the granular far-infrared radiator by welding the cladding member on it, and the far-infrared radiator is exposed through the mesh-covering member. The purpose is to provide a manufacturing method.

1 is a perspective view of a conventional far-infrared radiator mat.

Figure 2 is a partially cutaway perspective view of a conventional far infrared emitter mat.

Figure 3 is a longitudinal cross-sectional view of a conventional far infrared radiator bag.

4 is a longitudinal cross-sectional view of a conventional far infrared radiator bag.

5 to 8 are views of the present invention,

5 is a partially cutaway perspective view of a far-infrared radiator mat to which the present invention is applied.

Figure 6 is a partially cutaway perspective view of the far infrared radiator bag according to the present invention.

Figure 7 is a longitudinal cross-sectional view of the far-infrared radiator bag according to the present invention.

8a to 8e is a manufacturing process explanatory diagram showing a step of manufacturing a far infrared ray radiator bag according to the present invention.

9 is a process chart showing a far-infrared radiator bag manufacturing process according to the present invention.

<Description of the symbols for the main parts of the drawings>

1: Far infrared emitter 100: Far infrared emitter bag

110: bottom member 120: guide member

121: cylindrical circumferential wall 130: covering member

In order to achieve the above object, the far-infrared radiator pocket according to the present invention is a guide member having a plurality of cylindrical main walls are welded on the bottom member, and the granular far-infrared radiator is contained in the cylindrical main wall of the guide member, the guide member And a mesh covering member on the far-infrared radiator, and the peripheral portions of the mesh covering member, the guide member and the bottom member are integrally welded together.

A mesh is used for the mesh covering member, or a synthetic resin thin film having a plurality of through holes is used.

In addition, the method of manufacturing a far-infrared radiator bag according to the present invention comprises the steps of forming a guide member having a plurality of cylindrical circumferential walls on a synthetic resin thin plate and having a predetermined width and length, and having a width and length equal to or greater than that of the guide member. Joining the member and the guide member, placing a granular far infrared radiator into the cylindrical circumferential wall of the guide member, and covering the guide member and the far infrared radiator with a mesh covering member to cover the mesh covering member, the guide member and the bottom member. And welding the circumference of the edge, and separating the welded circumference to separate the far-infrared radiator pocket.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail as follows.

Figure 5 shows a partially cutaway perspective view of the far-infrared radiator mat to which the present invention is applied, Figure 6 shows a partially cutaway perspective view of the far-infrared radiator bag according to the present invention, Figure 7 is a longitudinal cross-sectional view of the far-infrared radiator bag according to the present invention. As shown, the far-infrared radiator mat according to the present invention has a configuration in which a plurality of far-infrared radiator pockets 100 are vertically and horizontally disposed on the mat body 10 and welded, and the far-infrared radiator pocket ( 100 is a guide member 120 is welded on the bottom member 110, the granular far-infrared radiator 1 is contained in the cylindrical main wall 121 of the guide member 120, the mesh covering member 130 is The upper edge portion of the mesh covering member 130, the guide member 120 and the bottom member 110 is integrally welded on the cover.

8A to 8E are manufacturing process explanatory diagrams showing the manufacturing process of the far-infrared radiator bag according to the present invention step by step, and FIG. 9 is a process chart showing the manufacturing process of the far-infrared radiator bag according to the present invention. The far-infrared radiator bag manufacturing method according to the present invention comprises the steps of forming a guide member 120 having a plurality of cylindrical circumferential walls 121 and having a predetermined width and length on a synthetic resin sheet (S200) and the same as the guide member 120. Or bonding the bottom member 110 and the guide member 120 having a greater width or length (S210) and the granular far-infrared radiator 1 inside the cylindrical main wall 121 of the guide member 120. Step (S220) and the rim of the guide member 120 and the far-infrared radiator 1, the mesh covering member 130 over the mesh covering member 130, the guide member 120 and the bottom member 110 To call Weld step (S230), and cutting the welded peripheral portion is configured to include a step (S240) for separating the far-infrared radiator pocket (100).

In applying the present invention as described above, in manufacturing the far-infrared radiator bag 100, as shown in FIG. 8a, the synthetic resin thin plate is molded by a vacuum molding method, and then formed to have a plurality of cylindrical protrusions 122. Then, a press molding machine as shown in FIG. In the process of forming the opening 123 by cutting the upper surface of the cylindrical protrusion 122 using the blanking molding method, the guide member 120 having a predetermined width and length is formed to be provided with the plurality of cylindrical main walls 121 (S200). .

Subsequently, the bottom member 110 prepared in advance to have the same width as the guide member 120 and several times longer as the guide member 120 is bonded to the guide member 120 (S210).

Here, the guide member 120 is cut and molded to a size such that a plurality of (3 to 10) far-infrared radiator pockets 100 are arranged in a row, and the bottom member 110 is a guide member 120 Cutting to have a length several times longer while having the same width and the like to thermally weld a plurality of guide members 120 one by one on the bottom member 110 in order to simplify the operation using a common high frequency heat welder. It is preferable to be able.

When the bottom member 110 and the guide member 120 are bonded as described above, a granular far-infrared radiator such as, for example, crystal grains or jade grains is formed inside the cylindrical main wall 121 of the guide member 120 as shown in FIG. 8D. 1) to the extent not to overflow the outer wall 121 (S220).

Subsequently, a mesh covering member 130 having a width and a length substantially equal to that of the guide member 120 is placed on the guide member 120 and the far-infrared radiator 1 as shown in FIG. 8E, and the mesh covering member as shown in FIG. 8F. 130, the peripheral portion of the guide member 120 and the bottom member 110 is welded using a common high frequency heat welder (S230).

Thereafter, the welded peripheral portions of the bottom member 110, the guide member 120, and the mesh covering member 130 are cut to separate the far-infrared radiator pocket 100 (S240).

Then, when a large amount of far-infrared radiator bag 100 is manufactured by the above-described process, the far-infrared radiator bag 100 is thermally welded on the mat body 10 so that the plurality of far-infrared radiator bag 100 is disposed longitudinally and horizontally. You get a radiator mat.

In implementing the present invention as described above, the width and length of the bottom member 110, the guide member 120 and the mesh covering member 130 can be selected as necessary, the main wall formed on the guide member 120 Although 121 is also described as a cylinder in the above contents, it may be molded into other shapes such as oval, rectangular, and the like.

As described above, the far-infrared radiator bag contains a granular far-infrared radiator such as a crystal grain or a jade grain in the cylindrical circumferential wall of the guide member deposited on the bottom member, and a mesh covering member is placed on the guide member and the far-infrared radiator. Since the periphery of the mesh covering member, the guide member and the bottom member is integrally welded, the granular far infrared radiator can be easily contained so as not to overflow to the inside of a predetermined frame, and can be uniformly contained as needed, and the mesh covering member Even when welding the periphery of the guide member and the bottom member, the granular far-infrared radiator is kept stable inside, so that the operation can be easily performed.

Therefore, the present invention has the advantage that it is easy to produce a plurality of far-infrared radiator bag, the amount of far-infrared radiator grains is uniformly embedded in the far-infrared radiator bag, the quality of the product is maintained uniformly, the built-in far-infrared radiator grains Since it is exposed to the outside through the mesh covering member there is an advantage that the effect of emitting far infrared rays is improved.

Claims (3)

Synthetic resin laminate bottom member (110); A synthetic resin thin plate guide member 120 having a cylindrical circumferential wall 121 in which the granular far-infrared radiator 1 is contained and welded on the bottom member 110; Far infrared ray radiator bag, characterized in that it comprises a mesh covering member 130 which is covered over the cylindrical peripheral wall 121 and the far-infrared radiator (1) of the guide member 120 is welded to the periphery of the guide member (120). The far-infrared radiator pocket according to claim 1, wherein the mesh covering member (130) is a mesh. Forming a plurality of cylindrical circumferential wall 121 on the synthetic resin sheet and forming a guide member 120 having a predetermined width and length (S200), and the bottom having a width and length the same as or greater than the guide member 120 Bonding the member 110 and the guide member 120 (S210), the step of containing a granular far-infrared radiator 1 in the cylindrical main wall 121 of the guide member 120 (S220), and A mesh covering member 130 is placed on the cylindrical circumferential wall 121 of the guide member 120 and the far-infrared radiator 1 to weld the periphery of the mesh covering member 130, the guide member 120, and the bottom member 110. And a step (S240) of separating the far-infrared radiator bag (100) by cutting the welded peripheral part (S230).