KR20010045078A - Electromagnetic induction cooker - Google Patents

Abstract

PURPOSE: An electronic inducing cooking instrument is provided to prevent the all inducing heating unit from being peeled by partly peeling the inducing heating unit which must be peeled. CONSTITUTION: The electronic inducing cooking instrument(5) comprises a main body(7) having cooking space, a plurality of grooves(8) formed under the base of the cooking instrument, a plurality of inducing heating units. The grooves are formed with their own shapes and have their own independent regions. Each inducing heating unit is attached to the corresponding groove.

Description

Electromagnetic induction cooker

The present invention relates to an electromagnetic induction cooking container, and in particular, the induction heating member which generates heat by the electromagnetic induction apparatus is spray-bonded to be split on the bottom of the main body of the container, and thus the induction heating member is caused by various causes such as moisture invasion. When peeling, only the corresponding part is to be peeled off so as to prevent the entire induction heating member from being peeled off.

When a high frequency magnetic field is applied to a conductor, an eddy current loss occurs in the conductor, and heat is generated in the conductor.

Electromagnetic induction cooking container using this principle is attached to the induction heating member of a metal material having a conductor property on the bottom. Therefore, if the electromagnetic induction cooking vessel is placed on the electromagnetic induction device generating a high frequency magnetic field, an eddy current loss is generated between the high frequency generated in the electromagnetic induction device and the induction heating member having the properties of the conductor, and the induction heating member is the eddy current. As the internal particles collide with each other by the hand, heat is generated by itself, thereby supplying heat to the container body, thereby making it possible to boil and cook food stored in the container.

Fig. 1 shows a conventional electromagnetic induction cooking container 1, in which a plate-shaped metal induction heating member 4 is attached and fixed to the bottom concave portion 3 of the container body 2 containing food.

Here, since the induction heating member 4 is generally formed in a single thin plate shape having a thin thickness, the induction heating member 4 is forced by a temperature difference between the container body and the induction heating member 4 when it is attached and fixed to the recess 3. It is fixed by several methods such as crimping method, welding method using capsule and rivet method.

However, the electromagnetic induction cooking container 1 cooks the food stored in the main body 2 and is washed after cooking. The food water and washing water boiled during the cooking and washing process of the induction heating member 4 When invaded into the adhesion fixing part, oxidation occurs from this part and peeling occurs.

Therefore, since the induction heating member is composed of a single plate, the oxidation phenomenon is spread throughout the adhesion fixing part as the food continues to be cooked, so that the induction heating member 4 is peeled off from the main body and cannot be used.

Accordingly, the present invention is to solve the conventional problems as described above, the technical problem is that the induction heating member is separated from the bottom of the main body due to various reasons, such as moisture invasion by fixing the induction heating member to be divided into the bottom of the container The present invention provides an electromagnetic induction cooking container which prevents the entire induction heating member from being peeled off by only partially peeling the part to be peeled off.

The electromagnetic induction cooking container is characterized in that a plurality of receiving grooves are formed on the bottom of the container body, and an independent induction heating member is attached and fixed to correspond to the receiving grooves.

1 is a front cross-sectional view of a conventional electromagnetic induction cooking vessel,

2 is an enlarged view illustrating main parts of FIG. 1;

Figure 3 is a front sectional view of the electromagnetic induction cooking vessel according to the present invention,

Figure 4 is an enlarged view of the main portion of Figure 3, showing a fixed state of the induction heating member,

5 is a bottom view of the electromagnetic induction cooking vessel according to an embodiment of the present invention,

Figure 6 is a bottom view of the electromagnetic induction cooking container according to another embodiment of the present invention,

Figure 7 is a bottom view of the electromagnetic induction cooking container according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

5: cooking container 7: main body

8: receiving groove 9: metal

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings. 3 is a partial cross-sectional view of the electromagnetic induction cooking container according to the present invention, Figure 4 is an enlarged view of the main portion of Figure 3 is a view showing a fixed state of the induction heating member, Figures 5 to 7 each implementation of the present invention Bottom view of an electromagnetic induction cooking container according to an example.

The electromagnetic induction cooking container 5 includes a main body 7 having a space 6 for storing food therein, and a plurality of receiving grooves 8 recessed independently of the bottom of the main body 7. ) And a plurality of induction heating members 9 attached to and fixed to the respective receiving grooves 8.

Here, the receiving grooves (8) are divided into various shapes and are arranged adjacent to each other with an independent area on the bottom of the main body (7).

3 to 5 show the receiving groove 8 and the induction heating member 9 of one possible embodiment. As shown in this figure, each of the receiving grooves 8 is sequentially concave in a circular shape from the center to the center with the center of the bottom surface of the main body 7 as concentric. Each of the recessed grooves 8 concave in this way is concave in sequence with different diameters to have an independent area.

Each induction heating member 9 attached to the receiving grooves 8 is coated and fixed in a spray-coated form to correspond one-to-one with the receiving grooves 8.

6 shows, in another embodiment, that each of the receiving grooves 8 has a predetermined width but is arranged parallel to each other in the adjacent receiving grooves 8. Each of the induction heating members 9 sprayed onto the receiving grooves 8 is coated and coated in a one-to-one correspondence with the parallel receiving grooves 8.

The receiving grooves 8 may be recessed in parallel with each other in a straight form as shown in the drawing, but may be recessed in parallel with each other with a curved line or any other shape. Also in the above embodiment, each of the recessed grooves 8 concaved has an independent area and is attached with an induction heating member 9 configured to correspond to the inside thereof.

7 is a further embodiment of the present invention the receiving grooves 8 are sequentially deployed in a circular shape from the center to the outer side with respect to the bottom of the main body 7 and arranged radially centered around the concentric Each has its own realm. Each of the induction heating members 9 attached to and fixed to the receiving grooves 8 is spray-coated to the receiving grooves 8 one-to-one as in the embodiments.

As described above, the receiving grooves 8 to be recessed separately are the number of cases, and thus, the induction heating member 9 may be attached by being recessed into various shapes.

That is, the receiving grooves 8 may be recessed entirely on the bottom of the main body in the shape of a polygonal shape of triangle or more or unit puzzles of a fitted puzzle.

In addition, the surface of each of the receiving grooves 8 is recessed in a V shape to widen the contact area when the induction heating member 9 is attached with the adhesive 10, and the roughened surface may be roughened. The rough machining has a variety of processing methods, but will be able to be simplified by a sandblasting process.

The induction heating member 9 attached to the surface of the receiving groove 8 is composed of a powdered metal material 11 having a magnetic body and a powdered aluminum material 12 sprayed onto the outside of the metal material 11. It is spray-coated in an arc discharge type in the receiving groove 8 and coated sequentially. Here, the metal material 11 is composed of a mixed component of powdered nickel 95% and aluminum 5%.

When the induction heating member 9 is applied to the receiving groove 8 described with reference to Figure 4 as follows. The adhesive 10 is evenly sprayed on the surface of each of the receiving grooves 8 subjected to the rough processing by arc discharge method, and then the powder of the metal material 11 mixed with 95% nickel and 5% aluminum is mixed with the adhesive 10. In the arc discharge method by spraying to a thickness of approximately 80μ (micron), and then coated, and then to the surface of the coated metal material 11 is sprayed and dried to a thickness of 50μ to finish the aluminum material 12 of the powder state.

Here, the metal material 11 is recessed in the receiving groove 8 recessed in the V shape in consideration of the strength of the magnetic force and the shape of the receiving groove until the outer surface becomes a planar state, the aluminum material applied to the outer surface (12) It is preferable that the surface is coincident with the end of the receiving groove (8). Therefore, the metal material 11 is recessed in the receiving groove 8 and the maximum thickness of the recessed material is 80 mu.

Water and washing water of the food in the process of cooking and washing the food using the electromagnetic induction cooking container 5 of the present invention coated and bonded so as to partition the induction heating member (9) as described above Even if the induction heating member 9 applied to the accommodating groove 8 is peeled off due to invasion to the inside or other various causes, only the peeled induction heating member is peeled off from the main body 7. The phenomenon that the whole member 9 peels can be prevented.

Therefore, since the induction heating member is partially peeled off, the food can be cooked by applying heat to the container body with the induction heating members that are not peeled off, and thus the life of the electromagnetic induction cooking container can be further extended.

In addition, since the induction heating member is coated on the surface of the receiving groove in order to have a high airtightness has a further advantage that can significantly reduce the peeling phenomenon of the induction heating member due to moisture invasion.

Claims (7)

A main body having a space for accommodating food therein; A plurality of receiving grooves recessed in the bottom of the main body; Electromagnetic induction cooking vessel characterized in that it comprises a plurality of induction heating member that is accommodated and fixed to correspond to each receiving groove. According to claim 1, wherein each of the receiving grooves are sequentially deployed in a circular shape from the center to the center with the center of the bottom surface of the main body, each of the induction heating member is applied to correspond to the respective circular receiving grooves Electromagnetic induction cooking vessel, characterized in that attached. The method of claim 1, wherein each of the receiving grooves are recessed with a predetermined width but parallel to each other adjacent receiving grooves, each of the induction heating member is applied to be applied to correspond to the respective parallel receiving grooves Electromagnetic induction cooking vessel characterized in that. According to claim 1, wherein the receiving grooves are sequentially deployed in a circular shape from the center to the center outward from the center with the center of the bottom surface of the main body is radially divided around the concentric, each of the induction heating member is Electromagnetic induction cooking vessel characterized in that the coating is attached to correspond to the receiving grooves. The cooking container of claim 1, wherein a surface of each of the receiving grooves is roughened. The induction cooking container according to claim 1, wherein each of the receiving grooves is recessed in a V shape. The method of claim 1, wherein the unit induction heating member and the magnetic material of the magnetic material is sprayed to a predetermined thickness on the adhesive applied to the receiving groove; Induction heating member assembly apparatus for an electromagnetic induction cooking container comprising an aluminum material spray coating a predetermined thickness on the applied metal material.