JP2017157535A - Heat-exchange auxiliary material for ih - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problem that nonmetal containers of ceramics, glass, paper, etc. in addition to a metal having no magnetic property, such as copper or aluminum have not been able to be heated in heating foodstuffs and others according to a conventional electromagnetic induction method (IH).SOLUTION: A heat-exchange auxiliary material for IH is produced by processing a metal with a magnetic property, especially an iron-copper alloy including copper blended at 50-70% into a disc-like form of 150-200 mm in diameter and 20-50 μm in thickness. The heat-exchange auxiliary material for IH is interposed between an electromagnetic induction apparatus and a container or receptacle to heat, which enables safe and easy heating.SELECTED DRAWING: Figure 1

Description

  The present invention relates to heating by an electromagnetic induction method such as an IH cooker.

  In the preceding paragraph, electromagnetic waves are not excited using a base material having high thermal conductivity such as a thin plate, foil, or a powder coated with an alloy mainly composed of iron and copper (hereinafter referred to as iron-copper alloy). It also enables heating of equipment.

  Conventionally, the base material by the electromagnetic induction method used for heating foods, etc. has relied on iron materials with poor thermal conductivity, so it takes time to heat, such as metals such as copper and aluminum, ceramics, glass, paper, etc. It was not possible to heat equipment that did not excite electromagnetic induction.

Wikipedia; "Electromagnetic cooker"

  In the present invention, when heating foods or the like by electromagnetic induction method, energy saving is achieved by a material having a higher heating efficiency than conventional base materials, and in addition to metals such as copper and aluminum, ceramics, glass, There has been a demand for materials that can also heat non-metallic containers such as paper.

  The 1st aspect of this invention is a member which conveys heat to the apparatus which requires heating by interposing between the heating instrument by an electromagnetic wave induction system, and the apparatus which requires heating.

  The second aspect of the present invention is a member provided with a base material made of a metal having magnetism or an alloy thereof processed into a thin plate or foil because of the necessity of electromagnetic wave induction.

  The third aspect of the present invention is based on an iron-copper alloy containing copper in a ratio of 50% to 70% in iron in the second aspect because of the necessity of electromagnetic induction and high heat conduction. It is a member provided.

  According to the fourth aspect of the present invention, a member comprising, as a base material, a material obtained by processing the iron-copper alloy according to the third aspect into a powder, mixing it in a non-metallic material such as rubber or resin, and processing it into a thin plate shape. It is.

Furthermore, according to the 5th aspect of this invention, it is a member provided with what processed the thin plate or foil of the base material in the said 2nd, 3rd, 4th aspect into the disk shape.

  The member manufacturing method of the present invention is performed by preparing any one member of the above-described embodiments.

  By using the members in the second to fifth aspects according to the present invention, the heating effect can be enhanced compared to the conventional appliances and equipment using the electromagnetic wave induction method, shortening the heating time, reducing the cost, Energy saving effect can be demonstrated.

  If the members according to the third to fifth aspects of the present invention are used, it is possible to heat not only metals such as copper and aluminum but also containers of non-metallic materials such as ceramics, glass and paper.

  By using the member according to the fourth aspect of the present invention and including the base material in a non-combustible base material having flexibility such as rubber or resin, it is easy to handle and secure a safe base material. .

  By appropriately selecting the ratio of copper in the base material, it is possible to select equipment suitable for the heating device.

To. The example which used the heat conversion auxiliary material for IH of this invention for an IH cooker is shown.

  A thin sheet of an iron-copper alloy having a copper blending ratio of 60% is processed into a shape that is easy to handle as follows, but the present invention is not limited to this embodiment.

The heat conversion auxiliary material for IH is manufactured by the following steps.
1) An iron-copper alloy ingot having a copper blending ratio of 60% is processed into a plate having a thickness of about 0.03 mm through processes such as forging and rolling.
2) The plate shape is cut into a disk shape having a diameter of about 150 mm.
3) Put your favorite handle so that it is convenient to carry and store the disk.

  An embodiment of the heat conversion auxiliary material for IH according to the present invention will be described with reference to FIG. 1, but the following embodiment is merely an example and is not limited to this embodiment.

  A heat conversion auxiliary material for IH is placed on the center of the upper part of the IH cooker, a cooking utensil is placed on the IH cooker, cooking ingredients are added, the IH cooker is operated, and cooking is performed.

1. IH cooker 2. Commercial paper bowl (with cooking ingredients) Heat conversion auxiliary material for IH (put a paper bowl on top)

Claims (3)

A heat exchange auxiliary material for IH used by processing a metal having magnetism or an alloy thereof into a circular thin plate or foil and inserting it between a heat exchange device (hereinafter referred to as IH) by an electromagnetic induction method and a heating device. 2. The heat exchange auxiliary material for IH according to claim 1, wherein an alloy mainly composed of iron and copper has a copper content of 50 to 70%. 3. The heat exchange auxiliary material for IH according to claim 2, wherein an alloy mainly composed of iron and copper is processed into powder and mixed into a flexible base material such as rubber or resin.