JP3650761B2 - Metal vacuum double container and manufacturing method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a metal vacuum double container used as a heat insulating container such as a pot.
[0002]
[Prior art]
The metal vacuum double container includes an inner container and an outer container made of metal such as stainless steel (SUS), and a vacuum-insulated heat insulation space is formed between the inner container and the outer container. Thereby, the contents can be kept warm. However, the temperature of the contents decreases after a long time. Therefore, if the contents are to be heated, the contents cannot be heated directly from the outside because a heat insulating space is formed.
[0003]
Therefore, in JP-A-8-280554, an inner container made of a ferromagnetic metal material (magnetic shunt alloy) and an outer container made of a nonmagnetic metal material are provided, and the contents are heated by electromagnetic induction heating of the inner container. A metal vacuum double container that can be used is disclosed.
[0004]
[Problems to be solved by the invention]
However, the metal vacuum double container is distorted in the inner container due to the atmospheric pressure when evacuating in the manufacturing process. In this case, there is a problem that the distance between the inner container and the induction heating coil is not constant, and the efficiency of electromagnetic induction heating is poor.
[0005]
Then, this invention makes it a subject to provide the metal vacuum double container in which efficient electromagnetic induction heating is possible.
[0006]
[Means for Solving the Problems]
As a means for solving the above problems, the first invention provides:
A metal inner container having a bottomed shape;
A heat insulating space is formed between the inner container and a metal outer container having a bottomed shape,
A heating metal plate made of a magnetic shunt alloy having a Curie point arranged on the lower side of the inner container bottom plate;
A copper or aluminum foil layer provided between the inner container bottom plate and the heated metal plate;
A spacer provided between the heated metal plate and the outer container bottom plate;
A deformable portion that can be deformed in the vertical direction provided in the inner container or the outer container,
The inner container bottom plate and the heated metal plate provide a metal vacuum double container joined to each other via the copper or aluminum foil layer by evacuating the heat insulation space.
[0007]
In the above invention, when the heat insulation space formed between the inner container and the outer container is evacuated, the deforming portion provided in the inner container or the outer container is deformed in the vertical direction. At this time, the inner container bottom plate moves toward the outer container bottom plate while maintaining a flat shape, and the heat insulating space between the inner container bottom plate and the outer container bottom plate is compressed. As a result, the spacer uniformly presses the heated metal plate against the inner container bottom plate. At this time, the upper surface of the heated metal plate and the copper or aluminum foil layer are joined, and the copper or aluminum foil layer and the inner container bottom plate are joined. The heated metal plate is integrally joined to the inner container bottom plate via the copper or aluminum foil layer. Is done. When the heated metal plate is heated by electromagnetic induction, the applied heat is transferred to the inner container through the copper or aluminum foil layer, and the contents contained in the inner container can be heated.
[0008]
The outer container is preferably made entirely of a nonmagnetic metal. Thereby, the heated metal plate can be effectively heated by electromagnetic induction. Or you may comprise the said outer container baseplate from ceramics, such as an alumina, for example.
[0009]
Temperature detecting means for detecting the temperature of the heated metal plate, display means for displaying the current temperature of the heated metal plate based on an output signal from the temperature detecting means, and supplying power to the display means It is preferable to provide a power supply unit. At this time, the user can judge the temperature of the heated metal plate by viewing the temperature displayed on the display means, and can appropriately heat the contents in the inner container.
[0010]
Further, temperature detection means for detecting the temperature of the heating metal plate, data transmission means for transmitting current temperature data of the heating metal plate based on an output signal from the temperature detection means, and the data transmission means It is preferable to provide a power supply unit for supplying electric power. At this time, the heating device that electromagnetically heats the heated metal plate can receive the temperature data transmitted from the data transmission unit, and can control the electromagnetic induction heating based on the temperature data.
[0011]
The power supply unit is preferably a coil that generates electromotive force by electromagnetic induction. At this time, the power supply unit supplies the generated power to the display unit and / or the data transmission unit. Further, instead of providing a coil as a power supply unit, a primary or rechargeable secondary battery may be used.
[0012]
Moreover, it is preferable to provide a convex part or a recessed part inside the inner container bottom plate. Thereby, when the contents stored in the inner container boil, the metal vacuum double container vibrates. At this time, for example, by providing vibration detecting means for detecting the vibration in a heating device that electromagnetically superheats the heated metal plate, it is possible to detect the boiling of the contents such as the liquid.
[0013]
The second aspect of the present invention
One is provided with a metal outer container and an inner container having a deformable portion that can be deformed in the vertical direction,
Placing the inner container in the body of the outer container;
Joining the upper opening of the outer container and the inner container together,
Arrange a copper or aluminum foil layer below the inner container bottom plate,
A heating metal plate made of a magnetic shunt alloy having a Curie point on the lower side of the copper or aluminum foil layer,
A spacer is disposed under the heated metal plate;
By joining the outer container bottom plate to the outer container, a heat insulating space is formed between the inner container and the outer container,
A method of manufacturing a metal vacuum double container in which the inner container bottom plate and the heated metal plate are joined via the copper or aluminum foil layer by evacuating the heat insulating space is provided.
[0014]
In the above invention, when the heat insulation space formed between the inner container and the outer container is evacuated, the deforming portion provided in the inner container or the outer container is deformed in the vertical direction. At this time, the inner container bottom plate moves toward the outer container bottom plate while maintaining a flat shape, and the heat insulating space between the inner container bottom plate and the outer container bottom plate is compressed. As a result, the spacer uniformly presses the heated metal plate against the inner container bottom plate. At this time, the upper surface of the heated metal plate and the copper or aluminum foil layer are joined, and the copper or aluminum foil layer and the inner container bottom plate are joined. The heated metal plate is integrally joined to the inner container bottom plate via the copper or aluminum foil layer. Is done. When the heated metal plate is heated by electromagnetic induction, the applied heat is transferred to the inner container through the copper or aluminum foil layer, and the contents contained in the inner container can be heated.
[0015]
When the heat insulating space is evacuated, the inner container bottom plate and the heated metal plate can be reliably joined by electromagnetic induction heating of the heated metal plate.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
[0017]
FIG. 1A shows a metal vacuum double container 1 according to the present invention. The metal vacuum double container 1 includes an inner container 2 and an outer container 3 made of stainless steel (SUS304) having nonmagnetic properties. The inner container 2 and the outer container 3 have cylindrical main bodies 2a and 3a having upper and lower ends opened. The main body 2a of the inner container 2 and the main body 3a of the outer container 3 are joined at their upper ends by welding or the like. Moreover, as shown in FIG.1 (b), the bottom plates 2b and 3b are joined to the opening part of the bottom of the inner container 2 and the outer container 3 by welding etc., respectively. Thereby, a heat insulating space 12 is formed between the inner container 2 and the outer container 3. A bellows-like deformed portion 3 c is provided around the opening of the outer container 3. The deforming portion 3c is deformed in the vertical direction and contracted during evacuation to be described later. In the present embodiment, the entire outer container 3 is made of stainless steel, which is a nonmagnetic metal, but the bottom plate 3b of the outer container 3 may be made of a ceramic such as alumina.
[0018]
Further, a metal foil 4 made of copper, aluminum or the like for preventing thermal radiation is disposed between the main body 2a of the inner container 2 and the main body 3a of the outer container 3. A getter 5 for adsorbing gas generated in the heat insulating space 12 is disposed between the inner container 2 and the outer container 3.
[0019]
Further, as shown in FIG. 1B, between the inner container bottom plate 2b and the outer container bottom plate 3b, there are a heating metal plate 6, copper or aluminum foil 7 (copper or aluminum foil layer), a spacer 8 and a temperature sensor. 9 is disposed.
[0020]
The heating metal plate 6 has a circular plate shape, and is made of a magnetic shunt alloy (ferromagnetic material) having a Curie point at a relatively low temperature of 350 ° C., for example. The heating metal plate 6 is disposed below the inner container bottom plate 2b. The heated metal plate 6 is heated by electromagnetic induction by an eddy current generated when a high-frequency current is applied to an induction heating coil 21 of a heating device 20 described later. Moreover, the Curie point of the heating metal plate 6 should just be a value below 350 degreeC. This Curie point can be changed by changing the composition of the heated metal plate 6.
[0021]
The copper or aluminum foil 7 is provided between the inner container bottom plate 2b and the heating metal plate 6, and integrally joins the inner container bottom plate 2b and the heating metal plate 6. The spacer 8 is made of glass wool or ceramic wool, and is provided between the heating metal plate 6 and the outer container bottom plate 3b. The temperature sensor 9 is provided integrally with the lower surface of the heating metal plate 6 and detects the temperature of the heating metal plate 6. The temperature sensor 9 is connected to a temperature display unit 10 (display means) provided on the outer surface of the outer container 3 through a wiring with an insulating coating. The temperature display unit 10 displays the current temperature of the heated metal plate 6 based on a signal output from the temperature sensor 9, and in the present embodiment, displays the liquid crystal.
[0022]
In order to manufacture the metal vacuum double container 1, the inner container bottom plate 2 b is welded and joined to the main body 2 a of the inner container 2, and then the inner container 2 is inserted into the main body 3 a of the outer container 3. The top opening of each is joined by welding or the like. Next, the copper or aluminum foil 7 and the heated metal plate 6 are sequentially arranged below the inner container bottom plate 2b. After the temperature sensor 9 is placed in contact with the lower surface of the heated metal plate 6, the spacer 8 is placed from below the heated metal plate 6. Then, the outer container bottom plate 3 b is welded and joined to the main body 3 a of the outer container 3. Thereafter, for example, the heat insulating space 12 is evacuated through the tip tube 11 provided in the lower portion of the side wall of the outer container 3.
[0023]
Since the deformed portion 3c of the outer container 3 contracts (deforms) in the vertical direction due to the pressure difference between the heat insulating space 12 decompressed by the vacuum exhaust and the atmospheric pressure, as shown by the arrow in FIG. 2, the inner container bottom plate 2b Moves toward the outer container bottom plate 3b. As a result, the heat insulation space 12 between the inner container bottom plate 2b and the outer container bottom plate 3b is compressed while maintaining the flat shape of the inner container bottom plate 2b and the outer container bottom plate 3b, and the state shown in FIG. 2 is obtained. At this time, the spacer 8 is compressed, and the heated metal plate 6 is pressurized against the inner container bottom plate 2b. As a result, the inner container bottom plate 2 b and the heated metal plate 6 are joined together with a flat shape maintained via the copper or aluminum foil 7. Specifically, the lower surface of the inner container bottom plate 2b and the upper surface of the copper or aluminum foil 7 are joined, and the lower surface of the copper or aluminum foil 7 and the upper surface of the heating metal plate 6 are joined. Further, since the spacer 8 is provided, the inner container bottom plate 2 b and the heated metal plate 6 do not contact the outer container 3. The lower surface of the heated metal plate 6 is pressed against the upper surface of the spacer 8 but is not joined.
[0024]
In this embodiment, the copper or aluminum foil 7 is provided between the inner container bottom plate 2b and the heating metal plate 6. However, instead of the copper or aluminum foil 7, copper or aluminum plating is used for the lower surface of the inner container bottom plate 2b. May be applied. At this time, as described above, when the heated metal plate 6 is pressed against the inner container bottom plate 2b, the inner container bottom plate 2b and the heated metal plate 6 are kept flat via copper or aluminum plating. Are joined together. Further, copper or aluminum plating may be applied to the upper surface of the heated metal plate 6.
[0025]
Further, instead of providing the bellows-like deformed portion 3 c around the opening of the outer container 3, the bellows-like deformed portion 2 c may be provided around the opening of the inner container 2. In this case, as described above, when the heat insulating space 12 is evacuated through the tip tube 11 provided in the lower portion of the side wall of the outer container 3, the deformed portion 2c of the inner container 2 extends in the vertical direction as shown in FIG. (Deform). As a result, the inner container bottom plate 2b moves toward the outer container bottom plate 3b as shown by the arrow in FIG. As a result, the heat insulating space 12 between the inner container bottom plate 2b and the outer container bottom plate 3b is compressed while the inner container bottom plate 2b and the outer container bottom plate 3b are kept flat. The inner container bottom plate 2b and the heated metal plate 6 are joined in a state of maintaining a flat shape.
[0026]
Moreover, when the heating metal plate 6 is pressurized with respect to the inner container bottom plate 2b and the inner container bottom plate 2b and the heating metal plate 6 are joined, you may make it carry out electromagnetic induction heating with the heating apparatus 20 mentioned later. Thereby, the inner container bottom plate 2b and the heating metal plate 6 can be more reliably joined.
[0027]
Since the inner container 2 and the outer container 3 are insulated by a vacuum heat insulating space 12, there is no heat dissipation or heat loss to the atmosphere side, and the contents such as the liquid contained in the metal vacuum double container 1 It is possible to keep things warm.
[0028]
Next, the case where the contents accommodated in the metal vacuum double container 1 are heated will be described.
[0029]
When heating the contents, a heating device 20 shown in FIG. 4A is used. This heating device 20 has an induction heating coil 21 disposed inside the main body. The induction heating coil 21 is provided at a position corresponding to the bottom of the metal vacuum double container 1 (outer container bottom plate 3b) when the metal vacuum double container 1 is set on the upper surface 20b.
[0030]
The metal vacuum double container 1 is set at a predetermined position on the upper surface 20 b of the heating device 20. When energization of the induction heating coil 21 of the heating device 20 is started, the heated metal plate 6 of the metal vacuum double container 1 is heated by electromagnetic induction by generating an eddy current. At this time, since the distance between the heating metal plate 6 and the induction heating coil 21 of the heating device 20 is constant while maintaining a flat shape, the efficiency of electromagnetic induction heating is good. And when the heating metal plate 6 of the metal vacuum double container 1 reaches the Curie point, it is not heated by electromagnetic induction. Thereby, the heating metal plate 6 is not overheated. The heat applied to the heated metal plate 6 is transferred to the inner container 2 through the copper or aluminum foil 7, and the contents accommodated in the inner container 2 are heated.
[0031]
The temperature display unit 10 of the metal vacuum double container 1 displays the current temperature of the heated metal plate 6 on a liquid crystal display based on a signal output from the temperature sensor 9. Thus, the user can determine the current temperature of the heated metal plate 6. The electric power required by the temperature display unit 10 such as electric power for liquid crystal display is provided between the heated metal plate 6 and the spacer 8 of the metal vacuum double container 1 as shown in FIG. It is supplied from the IH coil 13 (power supply unit). This IH coil 13 supplies the induction power from the induction heating coil 21 of the heating device 20 to the temperature display unit 10 via a wire with insulation coating. Further, the electric power required by the temperature display unit 10 may be supplied from a battery 14 (secondary battery) built in the temperature display unit 10 (indicated by a one-dot chain line). At this time, it is preferable to charge the battery 14 with the induced power from the IH coil 13.
[0032]
As a modification of the embodiment, as shown in FIG. 5, a data transmission for transmitting the current temperature data of the heated metal plate 6 detected by the temperature sensor 9 to the temperature display unit 10 of the metal vacuum double container 1. A unit 22 a may be provided, and the heating device 20 may be provided with a data receiving unit 22 b that receives data transmitted from the data transmitting unit 22 a and a control unit 23 that controls the induction heating coil 21. At this time, when it is determined that the surface temperature of the heated metal plate 6 has reached a predetermined temperature based on the signal from the data receiving unit 22b, the control unit 23 stops energizing the induction heating coil 21. Thereby, the contents can be heated to a desired temperature.
[0033]
Further, as a modification of the embodiment, as shown in FIGS. 6A and 6B, a convex portion 24 is provided on the inner surface side of the inner container bottom plate 2 b of the metal vacuum double container 1, and the upper surface of the heating device 20. A vertical vibration detection sensor 26a that detects vertical vibration and a horizontal vibration detection sensor 26b that detects horizontal vibration may be provided in the vicinity of 20b. By providing the convex portion 24, the metal vacuum double container 1 is likely to vibrate when the contents accommodated in the inner container 2 boil. The control means 23 detects the vibration of the metal vacuum double container 1 when the contents in the inner container 2 boil based on signals from the longitudinal vibration detection sensor 26a and the lateral vibration detection sensor 26b, and is a liquid. When it is determined that the contents have boiled, the energization to the induction heating coil 21 is stopped. This prevents spillage or the like and improves safety. Moreover, as shown in FIG.6 (c), you may provide recessed part 24 'instead of providing the convex part 24 in the inner container bottom plate 2b inner surface side of the metal vacuum double container 1. As shown in FIG.
[0034]
As a modification of the embodiment, as shown in FIG. 7, the bottom surface of the metal vacuum double container 1 (the lower surface of the bottom plate 3 a of the outer container 3) is formed in a concave shape, and the upper surface 20 b of the heating device 20 is formed. It is good also as the convex shape corresponding to the said concave shape. Thereby, the metal vacuum double container 1 can be positioned at an appropriate position by fitting the bottom surface of the metal vacuum double container 1 to the convex portion of the upper surface 20 b of the heating device 20.
[0035]
As a modification of the embodiment, as shown in FIG. 8, a resin ring 25 colored in a pastel color or the like may be provided in the lower part of the metal vacuum double container 1. Thereby, it can prevent that a user sets fire to the metal vacuum double container 1 accidentally. Further, a sticker on which characters such as “no direct fire” are printed may be attached to the outer surface of the metal vacuum double container 1.
[0036]
Further, as a modification of the embodiment, a power measuring means (not shown) for measuring the electromotive force generated in the heated metal plate 6 is provided, and the electromotive force generated in the heated metal plate 6 during electromagnetic induction heating is a predetermined power value. It may be determined that the electromagnetic induction heating is completed when the temperature of the heated metal plate 6 becomes higher than the Curie point or when the electromagnetic induction is stopped. Thereby, the heating metal plate 6 is not overheated.
[0037]
【The invention's effect】
As is clear from the above description, according to the present invention, a metal inner container having a bottomed shape, an outer container, a heated metal plate disposed below the inner container bottom plate, a copper or aluminum foil layer, And a heat insulating space formed between the inner container and the outer container, comprising a spacer provided between the heating metal plate and the outer container bottom plate, and a deformable portion provided in the outer container and deformable in the vertical direction. Is evacuated, the inner container bottom plate moves toward the outer container bottom plate while maintaining a flat shape, and the spacer uniformly presses the heated metal plate against the inner container bottom plate. At this time, since the heating metal plate is integrally joined to the inner container bottom plate while maintaining a flat shape, when the heating metal plate is electromagnetically heated, the distance from the induction heating coil of the heating device is There is an effect that it is constant and the efficiency of electromagnetic induction heating is good.
[Brief description of the drawings]
FIG. 1 (a) is a cross-sectional view of a metal vacuum double container of the present invention. (B) is a partially enlarged view of (a).
FIG. 2 is a cross-sectional view showing a state in which the metal vacuum double container of FIG. 1 is evacuated.
3 is a cross-sectional view showing a modification of the metal vacuum double container of FIG. 1. FIG.
4A is a cross-sectional view showing a state in which the metal vacuum double container of FIG. 1 is placed on a heating device. FIG. (B) is a partially enlarged view of (a).
FIG. 5 is a cross-sectional view showing a modification of the metal vacuum double container and the heating device of FIG. 4;
6 (a) is a cross-sectional view showing a modification of the metal vacuum double container and the heating device of FIG. (B) is a partially enlarged view of (a). (C) is the partially expanded sectional view which showed the modification of the metal vacuum double container of (b).
7 is a cross-sectional view showing a modification of the metal vacuum double container and the heating device of FIG.
FIG. 8 is a cross-sectional view showing a modification of the metal vacuum double container of FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Metal vacuum double container, 2 ... Inner container, 2b ... Inner container bottom plate,
3 ... Outer container, 3b ... Outer container bottom plate, 3c ... Deformation part,
6 ... Heated metal plate, 7 ... Copper or aluminum foil, 8 ... Spacer,
12 ... Insulated space.

Claims (8)

A metal inner container having a bottomed shape;
A heat insulating space is formed between the inner container and a metal outer container having a bottomed shape,
A heating metal plate made of a magnetic shunt alloy having a Curie point arranged on the lower side of the inner container bottom plate;
A copper or aluminum foil layer provided between the inner container bottom plate and the heated metal plate;
A spacer provided between the heated metal plate and the outer container bottom plate;
A deformable portion that can be deformed in the vertical direction provided in the inner container or the outer container,
The metal vacuum double container, wherein the inner container bottom plate and the heated metal plate are joined to each other through the copper or aluminum foil layer by evacuating the heat insulation space. 2. The metal vacuum double container according to claim 1, wherein the outer container is made of a nonmagnetic metal. Temperature detecting means for detecting the temperature of the heated metal plate, display means for displaying the current temperature of the heated metal plate based on an output signal from the temperature detecting means, and supplying power to the display means A metal vacuum double container according to claim 1 or 2, further comprising a power supply unit for the purpose. Temperature detection means for detecting the temperature of the heating metal plate, data transmission means for transmitting current temperature data of the heating metal plate based on an output signal from the temperature detection means, and power to the data transmission means The metal vacuum double container according to claim 1, further comprising a power supply unit for supplying the gas. 5. The metal vacuum double container according to claim 3, wherein the power supply unit is a coil that generates an electromotive force by electromagnetic induction. The metal vacuum double container according to claim 1, wherein a convex portion or a concave portion is provided inside the inner container bottom plate. One is provided with a metal outer container and an inner container having a deformable portion that can be deformed in the vertical direction,
Placing the inner container in the body of the outer container;
Joining the upper opening of the outer container and the inner container together,
Arrange a copper or aluminum foil layer below the inner container bottom plate,
A heating metal plate made of a magnetic shunt alloy having a Curie point on the lower side of the copper or aluminum foil layer,
A spacer is disposed under the heated metal plate;
By joining the outer container bottom plate to the outer container, a heat insulating space is formed between the inner container and the outer container,
A method for producing a metal vacuum double container, wherein the heat insulation space is evacuated to join the inner container bottom plate and the heated metal plate via the copper or aluminum foil layer.   The method for manufacturing a metal vacuum double container according to claim 7, wherein when the heat insulation space is evacuated, the heated metal plate is heated by electromagnetic induction.

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