DE29903775U1 - Self-heating cooking vessel - Google Patents

Description

02.03.1999 06426-97 La/T/bs

SiCeram GmbH D-07751 Jena-Maua

Self-heating cooking vessel

The present invention relates to self-heating cooking vessels, in particular rice cookers, with a container for the food to be cooked and an electric heating device.

Self-heating cooking vessels include kettles, which can be used to heat water for tea. To heat the food being cooked, exposed heating coils can be used inside the container, but these are difficult to clean, especially because they are easily calcified, and are not suitable for heating and cooking solid foods. It is also known to arrange the heating device outside the container and to heat the food being cooked indirectly by heating the walls, especially the base, of the container. However, such cookers often have a relatively poor level of efficiency and long boiling times.

The invention is therefore based on the object of creating an improved cooking vessel of the type mentioned, which eliminates the known disadvantages of the prior art.

nic. In particular, a high level of efficiency and a short boiling time should be achieved.

According to the invention, this object is achieved in a cooking vessel of the type mentioned in that the heating device has a heating plate made of high-performance ceramic and a heating conductor in surface contact therewith.

Such high-performance ceramics are particularly suitable for use as hotplates due to their thermal conductivity, their permissible surface load and their specific electrical resistance. The thermal conductivity of such high-performance ceramics can be in the order of magnitude of about 5-40 W/mK. The resistance of such high-performance ceramics is sufficiently high that the electrical heating conductor can be attached directly to the hotplate and can be in the order of magnitude of 10 ¹³ Ohm/cm. By using the high-performance ceramic hotplate with the heating conductor in direct surface contact with it, the cooking vessel achieves a high level of efficiency and short boiling times. The heat generated in the heating conductor is transferred directly to the hotplate. The food can be heated and cooked with low energy consumption.

Although known electric cookers have long been considered unsatisfactory in terms of their efficiency and boiling times, the use of heating plates made of high-performance ceramics with heating conductors in surface contact with them in self-heating cooking vessels has so far been avoided. Such heating devices were considered unsuitable for these special applications. In contrast to conventional cookers with inductive heaters, the cooking vessel according to the invention does not cause strong magnetic fields. Electrosmog is avoided.

The heating plate can preferably be made of a high-performance ceramic based on silicon carbide or silicon nitride. This gives the heating plate very good mechanical, thermomechanical and chemical properties.

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The heating plate can also be made of a high-performance ceramic based on aluminum nitride. Such a heating plate is particularly advantageous if the cooking vessel is operated at lower temperatures in the range of around 250 ⁰ C.

The heating conductor can be designed in different ways. A preferred design consists in providing a metal foil as the heating conductor, which is pressed against the heating plate. The metal foil can be self-supporting, which simplifies handling during production.

According to another advantageous development of the invention, the heating conductor can consist of a metal layer applied to the heating plate. The metal layer can be printed or vapor-deposited. The metal layer can also advantageously be applied to the heating plate by sputtering.

In order to achieve a rapid transfer of heat to the food and its rapid heating, the heating plate is advantageously connected directly to the container; in particular, the heating plate can form the base of the cooking vessel. The container can be designed as a bowl, i.e. it does not have an additional base. The bowl is placed directly on the heating plate.

In a further development of the invention, the heating plate is soldered to the container, thereby achieving a durable and firm connection between the heating plate and the container. A soft solder that is temperature-resistant up to approximately 350 ⁰ C is expediently used for soldering. According to another embodiment of the invention, the heating plate can be glued to the container. This facilitates the manufacture of the cooking vessel.

The connection between the heating plate and the container can also be made in a form-fitting or force-fitting manner using a temperature-resistant seal, in particular a silicone sealant. Here too, the heating plate is preferably connected directly to the container.

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In a further development of the invention, the heating device is encapsulated against the environment. It is sealed against moisture and protected against mechanical influences. The heating device is preferably arranged in a housing on which the container can stand. The housing can expediently be designed as an annular sleeve with which the cooking vessel can be placed on a work surface.

In order to achieve the best possible cooking results, a temperature control can be provided for the heating device, with which the heating of the food can be influenced. The temperature control has a temperature sensor assigned to the heating plate and/or the heating conductor in order to record their temperature. The temperature sensor is preferably arranged on the underside of the plate, i.e. the side of the heating conductor. The temperature control makes it possible to regulate the power required to maintain a specified temperature level. In rice cookers in particular, it is particularly advantageous if the required temperature of the food can be precisely controlled and the rice can simmer for the necessary time.

According to a particularly advantageous embodiment of the invention, a microprocessor is provided which enables the temperature and cooking or heating time to be specified. By using a microprocessor, a high degree of automation of the cooking process can be achieved.

In order to ensure sufficient safety for the self-heated cooking vessel, overload protection is appropriately provided.

An advantageous embodiment of the invention also consists in that thermal insulation is provided on the side of the heating device facing away from the container. This ensures that the cooking vessel does not reach high temperatures on its outside and can be touched without problems or placed on a non-heat-resistant surface. On the other hand, heat loss is reduced and the heating power is largely focused on heating

of the food being cooked. In conjunction with a metal foil as a heating conductor, the thermal insulation can be used to press the heating conductor against the heating plate. This means that no further components are required to press the metal foil on.

These and other features emerge not only from the claims but also from the further description and the associated drawing, with the aid of which a preferred embodiment of the invention is explained in more detail.

In the single drawing, a self-heating cooking vessel according to an embodiment of the invention is shown schematically in cross section.

The cooking vessel has a deep-drawn bowl with a circular cylindrical shape as container 1, the peripheral walls of which merge integrally into the base surface. An additional pot or container base is not provided. The bowl is preferably made of stainless steel.

A heating plate 2 of essentially flat and circular shape is provided directly on the bottom of the container 1. The heating plate 2 is placed directly on the bottom of the bowl 1. The bowl 1 and the heating plate 2 are soldered or glued together. The solder layer or glue layer is designated by the reference number 3.

The heating plate of the embodiment shown can be made of silicon carbide, silicon nitride or aluminum nitride.

The heating conductor 4 is arranged on the underside of the heating plate 2 and in the version shown is a metal foil that is pressed against the heating plate. The heating conductor 3 is preferably designed in a meandering shape.

For heat shielding, a thermal insulation 5 is provided on the underside of the heating plate 2 and the heating conductor 4, which is designed as a circular plate.

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The thermal insulation can be made of different materials and is thick enough to ensure adequate heat shielding.

The thickness of the insulation plate is preferably about 5-20mm, in particular about 10mm. The thickness of the heating plate 2 can be in the range of a few millimeters, in particular about 3mm. The heating device of the cooking vessel is built accordingly low.

The entire heating device is arranged inside a housing 6, which encapsulates the heating device from the outside. The housing 6 has an annular sleeve 7, on the lower end of which a base plate 8 is attached and fastened. On its upper end, the sleeve 7 has an inward-facing projection, on which the heating plate 2 sits. The heating plate can be soldered or glued to the projection, thereby closing off the interior of the housing. The seating surfaces of the sleeve projection and the heating plate 2 that sit on top of one another can be beveled in the manner of a bevel, as shown in the drawing. The projection acts as a stop or contact surface for the heating plate 2, which cannot be pushed out of the housing in this way. It can be inserted into the housing from the bottom side.

Unlike what is shown in the drawing, it is also possible for the bowl-shaped container 1 not to have its own base. This can be formed directly by the heating plate 3, with the container 1 being placed tightly on the upper edge of the housing 6.

As shown in the drawing, a plate 9 is also provided inside the housing 6, which is arranged under the thermal insulation 5. By means of the plate 9, the heating conductor 4 can be pressed against the underside of the heating plate 2 via the thermal insulation 5. For this purpose, pressure means pressing on the plate 9 can be provided, for example.

To supply power, the heating conductor 4 has an electrical connection 10, which is arranged on the outside of the casing surface of the housing 6 and can be connected to a power cable. The cable ends of the heating conductor 4 are led through the thermal insulation 5 and the plate 9 at the edge. The electrical connection 10 itself is led through the sleeve 7. Appropriate through-holes are provided in the thermal insulation 5, the plate 9 and the sleeve 7 to lead through the supply cables or the connecting pieces.

Not shown in the drawing is a temperature sensor for measuring the temperature on the underside of the plate. The sensor is arranged on the same side of the heating plate 2 as the heating conductor 4. The temperature sensor is preferably integrated into the heating conductor 4.

The cooker shown can preferably be operated with a mains voltage of 230V. According to another embodiment, the cooking vessel can be operated with a low voltage of 12V - 60V at a current of 80A. In this low-voltage embodiment, it is advantageous to interpose a line element between the heating conductor and the electrical supply lines, which has a resistance value that lies between the resistance values of the heating conductor and the respective electrical supply line. This prevents the supply lines from overheating. In particular, without this being shown in more detail, a copper block can be provided at the free end of the power supply, which creates a transition connection between the respective supply and the electrical supply lines. In addition, for low-voltage operation, the power supply lines between the electrical connection 10 and the heating conductor 4 are designed with a cross-section approximately four times that of the actual heating conductor track, so that, based on the same cable length, only Vi of the power is converted in the supply lines compared to a heating conductor section of the same length. This ensures that the supply lines between the electrical connection and the actual heating conductor do not heat up undesirably.

To illustrate the structure of the heating device, the drawing shows the heating plate 2, the heating conductor 4, the thermal insulation 5 and the plate 9 spaced apart from one another. It is understood, however, that the components mentioned are in surface contact with one another. However, this is not necessarily the case if the heating conductor 4 is applied in the form of a metal layer on the underside of the heating plate 2.

Claims (12)

02.03.1999 06426-97 La/T/bs SiCeram GmbH D-07751 Jena-Maua Self-heating cooking vessel Protection claims 1. Self-heating cooking vessel, in particular a rice cooker, with a container for the food to be cooked and an electric heating device, characterized in that the heating device has a heating plate (2) made of high-performance ceramic and a heating conductor (4) in surface contact therewith. 2. Cooking vessel according to the preceding claim, wherein the heating plate (2) consists of silicon carbide or silicon nitride. 3. Cooking vessel according to claim 1, wherein the heating plate (2) consists of aluminum nitride. 4. Cooking vessel according to one of the preceding claims, wherein the heating conductor (4) is designed as a metal foil which is pressed against the heating plate (2). · -2- 5. Cooking vessel according to one of claims 1-3, wherein the heating conductor (4) consists of a metal layer applied to the heating plate (2). 6. Cooking vessel according to one of the preceding claims, wherein the heating plate (2) is directly connected to the container (1), in particular forms the bottom thereof. 7. Cooking vessel according to one of the preceding claims, wherein the heating plate (2) is soldered to the container (1). 8. Cooking vessel according to one of the preceding claims, wherein the heating plate (2) is glued to the container (1). 9. Cooking vessel according to one of the preceding claims, wherein a temperature control is provided for the heating device (2, 4), which has a temperature sensor associated with the heating plate (2) and/or the heating conductor (4). 10. Cooking vessel according to one of the preceding claims, wherein a thermal insulation (5) is provided on the side of the heating device (2, 4) facing away from the container (1). 11. Cooking vessel according to one of the preceding claims, wherein the heating device (2, 4) is encapsulated against the environment. 12. Cooking vessel according to one of the preceding claims, wherein the heating device (2, 4) is arranged in a housing (6), in particular an annular sleeve, on which the container (1) stands.