EP0866641A2 - Electric cooking plate - Google Patents

Abstract

An electrical cooker plate has a plate body with a flat surface and heating layer below it. The heating layer is designed as a flat, especially sandwich-type, layer made of heat-resistant material with an electrical resistance element located inside, in contact with the underside of the part of the plate body to be heated. The heating layer is applied to the underside of the plate body and is maintained by a glue or filling material as a support element. The plate body is a glass ceramic plate, on whose underside a metal foil (3) is brought into direct contact, working as heating layer, and which is connected to an electric energy source.

Description

The invention relates to an electric hotplate with a hotplate body a flat surface and a heating arranged on its underside, according to the preamble of claim 1.

Conventional cooking systems are already known in practice, for which electrical separation of a heating conductor from a cooking zone underside an air gap of 8 mm must be observed. At this distance and at an operating temperature of less than 600 ° C, a dielectric strength of at least 3750 V reached. It does not matter what electrical resistance the Cooking zone cover assumes at higher operating temperatures. A disadvantage of In this conventional cooking system, the idle temperature required is over 500 ° C to achieve useful results in the cooking process. The efficiency cannot be increased significantly above 70% with this cooking system.

Instead of the glass ceramic plate used in the conventional cooking system it is already known from practice, a so-called plate made of high-performance ceramic, for example from silicon carbide or silicon nitride, which is manufactured in a highly insulating manner. This can eliminate an air gap because the high-performance ceramics conduct the heat so well that the operating temperature is already 250 ° C also sufficient for a cooking process and the ceramic in this temperature range does not conduct the electrical current. Due to the low operating temperature of 250 ° C, the cooking process can only be done with special pots that also have a ceramic floor, can be used optimally. Also own these high performance ceramics do not have directional heat conduction, i.e. the Longitudinal and transverse heat conduction is equally good. So the cooking zone can not be thermally delimited as with a glass ceramic plate.

DE 38 27 073 A1 discloses an electric hotplate of the generic type with a hotplate body and a heating arranged on its underside, which has an electrical heating resistor. This heating is as flat, paper-like or sandwich-like layer made of a heat-resistant material formed with an electrical resistance element arranged therein and is in contact with the underside of the part of the hotplate body to be heated. The hotplate body is alternatively made of gray cast iron, a shaped stainless steel or made from a sintered material. The heating is against the bottom of the hotplate body glued. Furthermore, the heating can thereby the bottom of the hotplate body are pressed into the lower cavity a filler with liquid-like properties is used, which by is closed at the bottom by an end cover.

Starting from the aforementioned prior art, it is the object of the invention to create an electric hot plate of the type mentioned, in which heat transfer between a heat source, for example a heat conductor, and a heat sink, for example a cooking vessel, with simple technical Medium and in compliance with the required dielectric strength is optimized.

According to the invention, this object is achieved by the features of patent claim 1 solved. Advantageous refinements and developments of the invention are shown in described the subclaims.

The main advantages of the solution according to the invention can be seen in the fact that the advantages of the different cooking systems described at the beginning connected to a system. You can use conventional glass ceramics conventional cooking vessels, but plan pot bases. Of the Efficiency increases to over 80% when the heat conductor foil is applied. Furthermore, it is essential and a main feature of the invention that the metal foil as a heating conductor surface contact on the glass ceramic underside with temperatures between 200 ° C to 400 ° C is used. At these low temperatures, the danger that a saucepan (bottom) warps and bends, relatively little, what turns out to be represents another advantage of the invention. There is also a cooking vessel / saucepan with a warp-free glass ceramic floor or a completely Glass-ceramic cooking vessel can be used with advantage.

With a smooth underside of the hotplate body formed from glass ceramic the metal foil is pressed over the entire surface. With a nubbed underside of the Glass ceramic existing hotplate body is between the metal foil and a very good temperature-conducting adhesive is used on the underside.

Another essential feature of the invention is seen in the fact that one of the electrical insulation dependent limit temperature is observed so that any thermally highly conductive material can be used as a cooking zone cover can by maintaining the maximum temperature at which an inserted Material just has its electrical insulation resistance properties owns. The temperature is increased automatically above the limit temperature, if bad parboiling values are achieved. Doing so simultaneously and automatically an increase in the air gap between the bottom of the Hotplate body and the metal foil introduced to even at higher temperatures to be electrically insulating.

Figur 1

eine Elektrokochplatte in schematischer Darstellung im Schnitt,

Figur 2

die Elektrokochplatte gemäß Figur 1 mit anderem Trägerelement im Schnitt,

Figur 3

die Elektrokochplatte nach Figur 1 mit Klebeschicht,

Figur 4

eine Kochplatte mit wellenartig geformtem Heizleiter,

Figur 5

die Kochplatte nach Figur 4 in anderer Bauweise im Schnitt,

Figur 6

die Kochplatte nach Figur 4 in noch anderer Bauweise im Schnitt,

Figur 7

eine Kochplatte mit bewegbarem Heizleiter im Schnitt.

An example of the invention is shown in the drawing. In it show:

Figure 1

an electric hotplate in a schematic representation in section,

Figure 2

1 with another carrier element in section,

Figure 3

the electric hotplate according to Figure 1 with adhesive layer,

Figure 4

a hotplate with a wave-shaped heating conductor,

Figure 5

4 the hotplate according to FIG. 4 in a different construction,

Figure 6

the hotplate according to Figure 4 in yet another construction in section,

Figure 7

a hotplate with a movable heating conductor in the cut.

The electric hotplate 11 has a hotplate body 1 made of a glass ceramic (Ceran), which is formed with a flat surface 12 on which a cooking vessel 13 is set up with the food. Usually four hot plates of different sizes and with the expansion of a roasting pan by a hotplate body 1 completely covered. The underside 14 of the hotplate body 1 can be flat or be nubbed. In the example of Figure 1 is from a flat bottom 14 of the hotplate body 1. At the bottom 14 of the Hotplate body 1 is a heater in the form of a metal foil 3 in direct Contact. The metal foil 3 is applied flatly and is supported by an insulating body 4. The insulating body 4 is made of a heat insulating and electrically non-conductive material and is produced with suitable means pressed flat against the metal foil 3 from below. As a suitable means for holding the insulating body 4 as a support element for the metal foil 3 can according to Figures 2 and 4 serve a bowl 5 below. It is theoretical but also conceivable to attach other support elements and even screw connections.

Through the direct and planar contacting of the hotplate body achieved according to FIG 1 is an optimal efficiency of heat transfer from the Heating conductor 3 achieved on the food to be cooked in the cooking vessel 13. Are because of direct contacting only temperatures from 200 ° C to 400 ° C necessary Metal foil 3 (foil radiator, heating conductor) is by appropriate electrical Connection 15 with an energy source and a control and regulating device connected.

The insulating body 4 in FIG. 1 is made of a thermally and electrically insulating, rigid and essentially inelastic compact formed. Instead of one pressed insulating body 4 is also a filament mat or another insulating body can be used with spring properties, on the one hand for a full-surface Attachment to the metal foil are suitable and on the other hand at higher temperatures expand in addition.

In the example according to FIG. 2, the heating is in the form of a metal foil 3 (Foil heating element, heating conductor) in turn directly on the underside 14 of the hotplate body 1, which is also a glass ceramic plate (Ceran) in this example. In this case, the metal foil 3 is pressed against the underside 14 by a cushion 7 made of an elastic material which is filled with air in the inner cavity, Liquid, gel, granular spheres or the like mass is filled. The pillow 7 is carried by a holder drop 5 and in the pressing position under the Metal foil 3 held. The elastic cushion over its entire pressure surface is optimally suitable for pressing against the metal foil in a goose area Format.

In Figure 3, the metal foil 3 as heating with the interposition of an adhesive layer 2 placed on the underside 14 of the hotplate body 1. On the for Hotplate body 1 facing away from the metal foil 3 is in turn Insulator 4 or 7. For electrical insulation of the heating conductor 3 there is Hotplate body 1 (glass ceramic) made of a modified material in itself offers a high dielectric strength. Alternatively, its surface is additionally provided with an electrically insulating and good heat-conducting coating. These coatings can e.g. evaporated or produced by tempering Be metal oxides. Instead of such special materials for glass ceramics 3 with a higher electrical dielectric strength Adhesive or an adhesive layer 2 with high electrical insulation and thermal good conductivity can be used. The thermal resistance of this adhesive layer 2 is very small compared to the hotplate body 1, so that the adhesive layer 2 does not act as a thermal insulator.

The glass ceramic surface is regularly smooth, while its underside 14 is usually napped. This knot on the underside 14 of the glass ceramic increases their mechanical stability under impact stress. It affects however disturbing in the intimate connection of the heating conductor 3 to the underside 14 the glass ceramic. For this reason too, it can be used for insulating glass-ceramic materials the hotplate body 1 may be necessary, an adhesive layer or an adhesive 2 to compensate for the knobs on the underside 14 of the hotplate body 1 to apply. This adhesive layer 2 then also acts as an intermediary with different expansion coefficients of the materials used for the hotplate body and the heating conductor.

In the aforementioned cases, the metal foil 3 in the adhesive layer or be introduced. The metal foil can also be used in a subsequent one second adhesive layer can be partially or completely embedded. This too second adhesive layer must then also be very good heat conductor. Dependent on the existing insulation can be the electrical insulation property of the second Adhesive layer will then be less.

In Figures 4, 5 and 6 are examples of an electric hot plate with wave-like shaped metal foil 16 used for heating. In the examples shown the top and the hotplate body 1 facing wave crests are each in an adhesive layer 2 is embedded, which is on the underside 14 of the hotplate body 1 is located. In the case of FIG. 6, there is 2 between the first adhesive layer and the underside 14 of the hotplate body 1, a further adhesive layer 17 inserted, among others also to compensate for unevenness on the underside, for example Pimples, serve. This second adhesive 17 has very good electrical properties insulating and heat-conducting properties. In Figure 4 are the lower troughs the wave-shaped metal foil 16 is molded into the insulating body 6. The The surface of the insulating body 6 is in each case on the undersides of the facing Metal foil 16 and partially on the adhesive layer 2. In contrast shows Figure 5 that the lower trough of the metal foil 16 on the in the holder drip 5 lie flat insulating body 18.

Sensors monitor when cooking or operating the electric hotplate the temperature of the hotplate body 1 and / or the temperature of the heating conductor 3, 16, if this is directly proportional to the glass ceramic temperature. If the Heating conductor 3, 16 abuts intimately on the underside of the hotplate body 1, a Limit temperature set at which the necessary electrical insulation properties can be guaranteed. This temperature represents the maximum limit temperature The control can now, depending on the preselection of the operator Increase energy accordingly until this limit temperature is reached.

According to Figure 7, another embodiment is shown, in which Specifying an air gap 9 between the bottom 14 of the hotplate body 1 and the heating conductor 3 can be inserted. This creates the opportunity even with usual high temperatures of up to 600 ° C without impairment due to insufficient electrical insulation of the hotplate body 1 to cook can. In this case, the heating conductor 3 is supplemented by a mechanism that is connected to a upstream control sets the limit temperature depending on its position. This regulation must now automatically the temperature changes per Monitor the unit of time and, in the event of rapid changes, information about the system change submit. Such data can be, for example: bad pot, bad container, good pot etc. The insulating effect of the air gap depends of the size of the gap 9. Depending on the required limit temperature, the Mechanics now dynamically change the air gap and a desired limit temperature to adjust. For this purpose, the insulating body 8 along the guide webs 9 regulated according to arrow 19 upwards or downwards. Thereby is the heating conductor 3 in one end position directly below the bottom of the Hotplate body 1, while it is optimal in the other end position Air gap 9 between its surface and the underside 14 of the hotplate body 1 takes. Such a mechanical method for temperature-dependent The heating conductor 3 can be lowered, for example, by means of levers, linkages, by motor, Springs can be carried out by memory metals or bimetals. The Carrying out the distance between the heating conductor 3 and the hotplate body 1 can be carried out manually with a position detector on the control. You can also automatically by the control itself based on the Evaluation of the heating curve is carried out using an actuator. With this mechanic it is possible that the electric hot plate automatically increases the temperature and with the Heating on air insulation distance goes when a bad pot or one bad cooking vessel 13 at a maximum temperature of 250 ° C none provides good parboiling results.

In the simplest case, the heating conductor 3 for the heating is made of an FeCrAl alloy educated. Theoretically, this heating conductor 3 can also consist of thick-film resistors consist of a screen printing process on the bottom 14 of the hob body are applied and then baked. On the place of the adhesive layers then occurs a glass layer and this is the Heating conductor 3 laid in thick film technology. To protect the heating conductor 3 against corrosion it is also covered with a layer of glass on the outside. The heating conductor structures can be applied by screen printing.

• Die Unterseite 14 des Kochplattenkörpers 1 (Glaskeramik) ist glatt, wenn der Heizleiter als Metallfolie vollflächig angepreßt wird. Die Unterseite 14 darf aber genoppt sein, wenn ein gut temperaturleitender Kleber 2 eingesetzt wird.
• Eine von der elektrischen Isolation abhängige Grenztemperatur ist einstellbar, so daß jedes thermisch gut leitende Material als Kochstellenkörper Verwendung finden kann, indem die Regelung jene maximale Temperatur einhält, bei der der eingesetzte Werkstoff gerade noch seine elektrische Isolationsfestigkeit besitzt.
• Es erfolgt eine automatische Erhöhung der Temperatur über die Grenztemperatur des Heizleiters 3, wenn schlechte Ankochwerte erzielt werden, wobei gleichzeitig eine automatische Erhöhung eines Luftspaltes zwischen dem Kochplattenkörper und dem Heizleiter eintritt, um auch bei höheren Temperaturen eine elektrische Isolierung zu gewährleisten.
• Es wird eine Glaskeramik für den Kochstellenkörper mit einer elektrischen Isolation gewählt, die entweder in Form höherer spezifischer Isolation oder durch eine zusätzliche Beschichtung mit einer elektrisch isolierenden, aber thermisch gut leitenden Schicht (Metalloxyde) erreichbar ist.

Overall, the essential features of the electric hotplate 11 are:

• The underside 14 of the hotplate body 1 (glass ceramic) is smooth if the heating conductor is pressed over the entire surface as a metal foil. The underside 14 may, however, be nubbed if a good temperature-conducting adhesive 2 is used.
• A limit temperature dependent on the electrical insulation can be set, so that any thermally highly conductive material can be used as a stove body by the regulation maintaining the maximum temperature at which the material used still has its electrical insulation strength.
• There is an automatic increase in the temperature above the limit temperature of the heating conductor 3 when poor parboiling values are achieved, and at the same time an automatic increase in an air gap between the hotplate body and the heating conductor occurs in order to ensure electrical insulation even at higher temperatures.
• A glass ceramic for the hob body with electrical insulation is selected, which can be achieved either in the form of higher specific insulation or by an additional coating with an electrically insulating but thermally highly conductive layer (metal oxides).

Claims (10)

Electric hotplate with a hotplate body with a flat surface and a heating arranged on its underside, which is designed as a flat, in particular sandwich-like layer of heat-resistant material with an electrical resistance element arranged therein and is arranged in contact with the underside of the part of the hotplate body to be heated, the Heating is pressed against the underside of the hotplate body and held by an adhesive and / or a filler as a carrier element,
characterized,
that the hotplate body (1) is a glass ceramic plate, on the underside (14) of which a metal foil (3, 16) acting as heating is brought into direct contact, which is connected to an electrical energy source. Electric hotplate according to claim 1,
characterized,
that between the metal foil (3,16) and the underside (14) of the hotplate body (1) an adhesive layer (2,17) is inserted, which consists of a highly heat-conducting, electrically insulating material. Electric hotplate according to claim 1 or 2,
characterized,
that the metal foil (3, 16) is pressed against the underside (14) of the hotplate body (1) by a carrier element made of an elastically deformable material. Electric hotplate according to claim 1 or 3,
characterized,
that the carrier element is a cushion (7) filled with an elastically deformable material. Electric hotplate according to claim 4,
characterized,
that the cushion (7) is filled with air, liquid, gel, granular spheres or the like. Electric hotplate according to one of the preceding claims,
characterized,
that the carrier element is a fiber mat with spring properties. Electric hotplate according to one of the preceding claims,
characterized,
that the metal foil (16) is wave-shaped, the upper waves directed towards the underside of the plate (14) being inserted in an adhesive layer (2), while the opposite lower waves are standing on or in an insulating body (6, 18). Electric hotplate according to one of the preceding claims,
characterized,
that a limit temperature is set up depending on the electrical insulation of the hotplate body (1), at which the material used has its required electrical insulation strength. Electric hotplate according to one of the preceding claims,
characterized,
that an automatic increase in temperature above the limit temperature can be regulated, in which an air gap (9) is automatically set up between the underside (14) of the hotplate body (1) and the heating conductor (3). Electric hotplate according to claim 9,
characterized,
that the heating conductor (3), together with the insulating body (8) arranged underneath, can be moved mechanically between an upper and a lower limit value in accordance with the temperature control.

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