JP2018532543A - Vacuum container for induction - Google Patents

Abstract

The present invention relates to an induction vacuum vessel that heats an object to be heated by induction heating. An inner container member that is formed from a material that can be heated by induction and that can be induction-heated by induction, and that is formed in a size larger than the inner container member, and that accommodates the inner container member and cannot be induction-heated by induction. An outer container member made of a material and a vacuum space to be evacuated between the inner container member and the outer container member. It can be used in a wide variety of inductions, and not only can the object to be heated be heated within a short time, but also it can be easily carried in a state in which the object to be heated is heated. [Selection] Figure 1

Description

  The present invention relates to an induction vacuum vessel that heats an object to be heated by induction heating.

  In general, when food is cooked, it is cooked by heating the food in a gas range placed in a container.

However, since the gas cooker cooks food by directly heating the container, there is a problem that when the food is heated for a long time, the food and the container burn and a fire occurs.
In order to solve this, conventionally, an induction capable of cooking food by an indirect heat source rather than direct heat has been proposed.

  This type of induction generates an induced current, and the container is formed from a material that is heated by the induced current and is configured to heat the food by induction heating, thereby preventing the occurrence of a fire associated with heating by the heat source I was able to.

  On the other hand, a container used in induction has been disclosed in the title of “Induction container and manufacturing method thereof” in Korean Patent Registration No. 10-126378 (registered on May 15, 2013).

  A conventional induction container includes an aluminum body having a container shape, an induction heating member installed on a bottom surface outside the aluminum body, and a ceramic coating layer that coats the outer surface and the inner surface of the aluminum body. It becomes.

  In the conventional induction container having such a configuration, food can be heated by the induction heating member that generates heat when the induction heating member receives the induction current of the induction.

  However, since the conventional induction container can only heat food at the part where the induction heating member is installed, the container is heated unevenly, and the coil that generates induction current in the induction corresponds to the induction heating member. There was a problem that it was not possible to use in the case of the induction installed in the place where it was not.

  In addition, since the heatability of the induction container is reduced due to heat exchange with the outside, not only the cooking time is prolonged, but there is a problem that it is difficult to carry food in a state where heat is transmitted to the outside and heated.

Korean Registered Patent Publication No. 10-126378

  The present invention has been devised in order to solve the above-described problems, and the problem to be solved by the present invention is that a variety of inductions can be used regardless of the position of the coil for induction heating in the induction. It is possible to provide an induction vacuum vessel that can be used not only in the process, but also can improve heat insulation, shorten cooking time, and facilitate carrying.

In order to achieve the above object, an induction vacuum container according to an embodiment of the present invention includes an inner container member made of a material that accommodates an object to be heated and can be induction-heated by induction, and is larger than the inner container member. An outer container member that is formed in a size and accommodates the inner container member and is formed of a material that cannot be induction-heated by the induction, and a vacuum space that is evacuated between the inner container member and the outer container member And comprising.
Preferably, the inner container member includes a coating layer that forms a layer on the inner surface of the inner container member and prevents an object to be heated from sticking to the object by heating.

  According to the present invention, the inner container member is formed from a material capable of induction heating and can be used in a wide variety of induction regardless of the portion where induction heating is performed in the induction. The time for heating the object to be heated can be shortened by providing a space, and the object to be heated can be easily carried even in a heated state.

The perspective view which shows the vacuum container for induction which concerns on embodiment of this invention Side sectional view showing a vacuum vessel for induction according to an embodiment of the present invention Plan sectional drawing which shows the vacuum container for induction which concerns on embodiment of this invention

Hereinafter, an induction vacuum container according to an embodiment of the present invention will be described with reference to the accompanying drawings.
As shown in FIGS. 1 to 3, the induction vacuum container 100 according to the embodiment of the present invention may include an inner container member 110.
The inner container member 110 may be formed in a container shape, for example, a shape into which an object to be heated such as a cup, a teacup, a frying pan, or a dish is placed.
Here, the object to be heated may be a fluid to be heated, a food to be cooked, or a chemical substance that requires heating, and the kind of the object to be heated is not limited.

  Further, the inner container member 110 may be formed of a material that can be induction-heated as a whole. Here, examples of materials that can be induction-heated include iron (Fe) -based materials, iron (Fe) -based alloys, magnetic materials, and conductive ceramics.

  Here, if the inner container member 110 is formed of a material capable of induction heating, the inner container member 110 can be heated regardless of the position of the coil that performs induction heating in the induction, and thus can be used in a wide variety of inductions. is there.

For example, an induction applied to an electric rice cooker must be heated within a short time, so a coil for induction heating is provided around the container, and a normal induction has a coil for induction heating on the bottom surface. It is preferable that the position of the coil is different for each type of induction installed.
The inner container member 110 may include a coating layer 140.
The coating layer 140 is disposed on the inner surface of the inner container member 110 and can prevent an object to be heated contained in the inner container member 110 from sticking due to heating.

Meanwhile, the coating layer 140 may be formed so as to form a layer on the inner surface of the inner container member 110 in which the object to be heated is accommodated, and the coating layer 140 may be made of, for example, ceramic, fluororesin, or other heated material. It may be formed from a non-adhesive material or the like, or two or more different materials may be stacked and overlapped.
As shown in FIGS. 1 to 3, the induction vacuum container 100 according to the embodiment of the present invention may include an outer container member 120.

The outer container member 120 may have a size larger than the inner container member 110 so as to accommodate the inner container member 110 and may be formed in a shape corresponding to the inner container member 110.
Further, the inner container member 110 housed in the outer container member 120 may be housed away from the outer container member 120.

Further, unlike the inner container member 110, the outer container member 120 may be formed of a material that cannot be induction-heated, for example, a metal that does not belong to iron (Fe), a synthetic resin, or a ceramic.
As shown in FIGS. 1 to 3, the induction vacuum container 100 according to the embodiment of the present invention may include a vacuum space 140.
The vacuum space 140 is preferably insulated by vacuum.

On the other hand, the vacuum space 140 may be a space between the inner container member 110 and the outer container member 120. The vacuum space 140 is evacuated by a method of sealing in a state where the air inside is extracted to the outside. The vacuum space 140 may be provided with a getter material (not shown) that sorbs the remaining gas to form a high vacuum.
At this time, the vacuum space 140 preferably has a pressure of approximately 10 ⁻³ to 10 ⁻⁶ mmHg.
Here, the vacuum space 140 can insulate between the inner container member 110 and the outer container member 120 by blocking heat and radiation heat by blocking convection.

Further, in order to block radiant heat on one of the surfaces of the inner container member 110 and the outer container member 120 forming the vacuum space 140, both surfaces, or the entire surface forming the vacuum space 140. It is plated with copper or silver foil is attached.
The induction vacuum vessel 100 according to the embodiment of the present invention may include a bridge portion (not shown).

  The bridge portion preferably connects the outer container member 120 and the inner container member 110 to guide induction heating of the induction contacted with the outer container member to the inner container member 110.

  Here, since the vacuum space 140 is formed between the outer container member 120 and the inner container member 110, there is a possibility that the induction heating to the inner container member 110 may be insufficient. It is preferable to introduce induction heating to the container member 110.

  On the other hand, the bridge portion is also made of an iron (Fe) -based material, an iron (Fe) -based alloy, a magnetic material, or a conductive material that is the same material as the inner container member 110 or a different material from the inner container member 110 so that induction heating is possible. Preferably, a plurality of ceramics may be arranged in a portion corresponding to a portion where a magnetic field is generated in the induction, and a plurality of portions may be uniformly distributed between the inner container member 110 and the outer container member 120 as a whole. It may be arranged.

  In the induction vacuum container 100 according to the above-described embodiment of the present invention, the inner container member 110 in which an object to be heated is accommodated is disposed inside the outer container member 120, and the outer container member 120 and the inner container member 110 are arranged. A vacuum space 140 that is evacuated is formed therebetween.

On the other hand, the inner container member 110 is formed of a material capable of induction heating, and a getter material may be inserted into the vacuum space 140 to increase the degree of vacuum. A coating layer 140 is formed on the inner surface of the inner container member 110. It is formed.
Further, unlike the inner container member 110, the outer container member 120 is formed of a material that cannot be induction-heated.

  The induction vacuum container 100 according to the embodiment of the present invention having such a configuration is generated from an induction coil if the induction container is placed on the induction while the object to be heated is accommodated in the inner container member 110 and the induction is operated. The inner container member 110 is induction-heated by the induced current, whereby the object to be heated accommodated in the inner container member 110 is heated.

  At this time, when the inner container member 110 is directly heated by induction induction heating and a bridge portion is provided, an induction current is transmitted through the bridge portion close to the induction coil, and the inner container member 110 is heated. May be.

  In addition, since a vacuum space 140 is formed between the inner container member 110 and the outer container member 120 and is insulated by the vacuum formed in the vacuum space 140, the heated object of the inner container member 110 is heated. However, not only can the induction vacuum vessel 100 be carried easily without worrying about burns, but also the object to be heated can be heated within a short time while minimizing heat loss.

  Therefore, the induction vacuum container 100 according to the embodiment of the present invention can be used not only for the inner container member 110 formed of a material that can be induction-heated and used in various inductions, but also for heat insulation by the vacuum space 140. Thus, the heating time of the object to be heated can be shortened, and the induction vacuum container 100 can be easily carried even when the object to be heated is heated.

  The embodiment of the present invention has been described above. However, the scope of the right of the present invention is not limited to this, and the embodiment of the present invention can be easily used by those having ordinary knowledge in the technical field to which the present invention belongs. Includes all changes and modifications to the extent that they are changed and found to be equivalent.

  The present invention has applicability to various industrial fields using induction such as chemical test containers and cooking containers.

DESCRIPTION OF SYMBOLS 100 Vacuum container for induction 110 Inner container member 120 Outer container member 130 Vacuum space 140 Coating layer

Claims (2)

An inner container member containing an object to be heated and formed from a material capable of induction heating by induction;
An outer container member formed from a material that is formed in a size larger than the inner container member, accommodates the inner container member, and cannot be induction-heated by the induction;
An induction vacuum container comprising: a vacuum space that is evacuated between the inner container member and the outer container member. The inner container member is
The induction vacuum container according to claim 1, further comprising a coating layer that forms a layer on the inner surface of the inner container member and prevents an object to be heated from sticking by heating.

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