DE3315657A1 - Electric cooking appliance - Google Patents

Abstract

An electric cooking appliance with a glass ceramic plate (11) and at least one heating region has an opening (17) approximately in the middle of each heating region, in which opening a sleeve (20) is arranged such that it abuts in a liquid-tight manner against the edge of the opening (17). A temperature sensor (18), preferably one with a container (21) filled with an expansion liquid, is arranged within the sleeve (20). Several possible means of liquid-tight connection between the glass ceramic cooking plate (11) and the inserted sleeve (20) are proposed. <IMAGE>

Description

Electric cooker

The invention relates to an electric cooking appliance with a glass ceramic plate and at least one by an electrical one arranged below the hotplate Heating heatable heating area, in the approximate center of which a temperature sensor is arranged.

Such an electric cooking appliance is known (DE-OS 27 47 652). at this known electric cooking appliance is on the underside of the glass ceramic plate arranged spiral tubular heating element, which is connected to a thermal bridge to which the temperature sensor is attached. So with this arrangement a thermal coupling between part of the electrical heating and the Temperature sensor instead. A real detection of the temperature of the bottom of the saucepan however, it does not achieve this.

The invention is based on the object of an electric cooking appliance create, in which the temperature of the saucepan should be recorded as precisely as possible. To solve this problem, the invention provides that the glass ceramic hotplate has an opening with a sleeve inserted therein, in which the temperature sensor is arranged.

Such temperature sensor boxes are arranged in an opening known for a long time in the case of electric hotplates (e.g. DE-PS 24 22 687). With glass ceramic hotplates however, this possibility has not yet been considered.

In a further development, the invention proposes that the temperature sensor is slidably supported in the sleeve.

It can preferably be spring-loaded upwards against a stop be in such a way that it is slightly above the surface of the when it rests against the stop Glass ceramic hotplate protrudes. The measure of the supreme standing is chosen so that he certainly against a possibly slightly curved base of a saucepan is still under the action of a spring.

The invention proposes in a further embodiment that the temperature sensor laterally at least partially thermally insulated from the electrical heating is.

How strong the insulation is compared to the electrical heating, depends on the individual case and makes it possible to access the heating characteristics or the Response characteristics of the temperature sensor when heating up have a certain influence to be able to exercise. This is why it can make sense to use thermal insulation to train only weakly, while it is with other use cases it can be better to provide very good thermal insulation.

In a further development it is provided that the upper edge of the opening is a Has bevel. As the invention further suggests, the sleeve can have a Have a collar with which they are moisture-proof at the edge of the opening or at whose bevel is applied. This liquid-tight system is important for the invention, due to the ingress of moisture in the area of the electric heating must be prevented in any case. There are certain difficulties here because the Thermal expansion of the glass ceramic is much lower than that of metal which the sleeve is made. Therefore, the invention proposes a moisture-proof Training before that the sleeve is made of very thin material, so that they do not can exert very large forces on the glass ceramic. For example, under is very thin to understand a thickness of 0.2 - 0.3 mm.

Another possibility also proposed by the invention consists in that the sleeve is made of ceramic.

When the sleeve is formed from metal it can be provided that the sleeve is pressed against the bevel attached to the upper edge of the opening and is deformed from the bottom.

It can also be provided that the sleeve at least in the area its circumference resting against the edge of the opening is designed to be corrugated. This wavy Execution makes it possible that with thermal expansion of the sleeve this nevertheless no Exerts too great a force on the glass ceramic.

The underside of the collar is preferably smooth. So he lies at the bevel on the upper edge of the opening, while the thermal expansion added by the other measures, for example the corrugated training will.

In a further development it can be provided that with a radiant heater the insulating body holding the heating and / or the outer sheet metal plate the sleeve and the temperature sensor preferably surrounds cylindrically.

In this way, the thermal insulation can be effected, whereby through the thickness of the part surrounding the temperature sensor the degree of thermal insulation can be changed.

The temperature sensor can preferably be a hydraulic one Sensors act, although other sensors respond to temperature changes as well can be used.

It is particularly favorable if the temperature sensor is part of an automatic circuit is. For example, he can press two switches at different temperatures act, of which the first switch between 50% and 70% of the electrical Heating power and the second switch turns off the rest.

In a further development, the diameter of the temperature sensor can be approximately half be as large as the diameter of the sleeve.

Further features, details and advantages of the invention result from the following description of preferred embodiments of the invention as well as based on the drawing. 1 shows a top view of a glass ceramic hob with four heating areas; FIG. 2 shows a section along line II-II in FIG. 1; FIG. Fig. 3 Sections through up to 10 differently designed inserts with temperature sensors; 11 shows a circuit diagram.

The glass ceramic hotplate shown in FIGS. 1 and 2 consists from a glass ceramic hob 11, which is held in a sheet metal tub 12, the with its edge 13 overlaps the upper edge of an opening in a wooden panel 14. Four radiant heating elements 15 are arranged below the glass ceramic field, which the approximately circular heating areas shown by the dashed circles in FIG. 1 16 form. In the middle of each heating area 16, the glass ceramic hob has a Opening 17, in which an insert sleeve is arranged, from its upper opening a temperature sensor 18 protrudes.

The temperature sensors 18 protrude about as far from the surface of the Glass ceramic hob 11 shows that it also has a curved base of a cooking vessel can still touch.

Fig. 3 now shows the section through the center of a heating area a first embodiment of an electric cooking appliance according to the invention. the Glass ceramic hotplate 11 has an opening 17, which is circular and whose The upper edge, as can be seen in particular from FIG. 4, has a bevel 19. In these Opening 17, a sleeve 20 is used, within which the actual temperature sensor 18 is supported. The temperature sensor 18 exists in the illustrated embodiments from a liquid-filled container 21, which is essentially flat-cylindrical is, however, has a step so that it has a larger one in its lower region Has diameter than in its upper region.

The lower step-shaped area 22 lies at the lower edge of the rim the opening of the insert sleeve 20. The insert sleeve 20 in the embodiment 3 and 5 to 9 has a circumferential collar 23 which is attached to the bevel 19 of the opening 17 rests smoothly. The top of the insert sleeve 20 does not protrude the top of the glass ceramic plate 11 in front.

The insert sleeve 20 has an opening 24 on its underside, in which a bracket 25 is used, which with the help of projections 26 on his The outside is supported in the insert sleeve 20. Between the container 21 and the top of the bracket 25 a helical spring, not shown in the drawings, is arranged, the temperature sensor 18 in the direction of the position shown in the figures applied. The temperature sensor slackens against the action of this spring Press it into the insert sleeve 20 at the bottom. The container 21 filled with liquid is via a capillary tube 27 with a known automatic gearshift tied together. When the liquid contained in the container 21 is heated, it expands and thus exerts a pressure on the automatic device, so that thereby a switch can be opened.

As can also be seen from FIG. 3, this is the radiant heating 28 holding insulating body 29 in the area of the insert sleeve 20 in the shape of a cylindrical ring guided upwards, the cylindrical ring-shaped part 30 providing thermal insulation of the temperature sensor 18 relative to the radiant heater 28 causes. The insulator 29 and the sheet metal plate 32 holding the insulating layer 31 underneath is in The area of the opening 17 in the glass ceramic hotplate 11 is also drawn upwards and surrounds the cylinder ring part 30 of the insulating body. By more or less strong ones Formation of the cylinder ring 30 and / or by more or less strong pulling up of the sheet metal plate 32 can be a certain thermal coupling between the temperature sensor 18 and the heater 28, which may be of interest for a switch-on phase can be.

In the embodiment shown in FIG. 3, the sleeve 20 is made of made of thin sheet metal, for example with a thickness of 0.2-0.3 mm, with it no excessive forces are exerted on the glass ceramic hotplate 11 when it is heated can be.

In the embodiment according to FIG. 4, the sleeve 33 is made of ceramic. In this case, a ring 34 is attached to the sheet metal plate 32, on which the Bracket 25 can be supported with its projections 26. The ceramic sleeve 33 owns the same thermal expansion coefficient as the glass ceramic plate 11, so that they do not have any forces on the glass ceramic hotplate even if they fit tightly 11 can exercise.

In the embodiment according to FIG. 5, the sleeve 20 lies with the underside its shoulder 23 tightly on the bevel 19 of the opening of the glass ceramic hotplate 11 on and is deformed from the underside by a bulge 35 to the outside, which also creates a liquid-tight connection between the glass ceramic hob 11 and the sleeve 20 is made.

In the embodiment of FIG. 6, the sleeve is also with the underside of their shoulder 23 smoothly at the chamfer 19 and is from the underside deformed by a bulge 35. In addition, however, the sleeve 20 in Area of their contact with the edge of the opening in the glass ceramic cooking surface 11 exhibits a waveform as shown in FIG. Fig. 7 shows a section approximately along line VII-VII in Fig. 6. This wave structure makes it possible that when heated, the material of the sleeve, which is made of metal, can expand, without too great forces occurring. At the same time, however, is due to the bulge 35 still achieved that the contact of the shoulder 23 on the chamfer 19 remains tight.

In the embodiment according to FIG. 8, a second sleeve is used 36, which has resilient lugs 37 on its inside, the sleeve 38, within which the temperature sensor 18 is arranged, pulled down, so that also a tight fit of the shoulder 23 on the bevel 19 of the glass ceramic cooking surface 11 given is.

In the two embodiments shown in FIGS. 9 and 10, a smaller temperature sensor 18 compared to the diameter of the sleeve is used.

In the embodiment according to FIG. 10, the opening 17 is in the glass ceramic cooking surface 11 initially provided with a metallic edge 39 on which the sleeve 20 then rests.

Fig. 11 shows a circuit diagram as used by the invention will. Each heating area 16 has two electrical resistance heaters 40, 41 that can be connected in parallel. Approximately in the middle of each heating area 16 the temperature sensor 18, which is shown schematically in FIG. 11, is arranged and which acts on the two switches 42, 43. When a first temperature is reached the switch 42, which switches off the heating 40, is first opened. Upon reaching A second, somewhat higher temperature is activated by opening the switch 43 41 switched off. In addition, there is an overheating protection switch for safety purposes 44 provided.

In all embodiments of the invention it is ensured that the Connection between the sleeve 20 or 33, within which the temperature sensor 18 is arranged, and the edge of the opening in the glass ceramic hotplate 11 always is liquid-tight, so that no liquid in the area of the electrical Can get heating.

Claims (16)

Claims electric cooker Electric cooker with a glass ceramic plate (11) and at least one through one arranged below the glass ceramic plate (11) electrical heating (28) heatable heating area (16) in its approximate center a temperature sensor (18) is arranged, characterized in that the glass ceramic plate (11) has an opening (17) with a sleeve (20, 33) inserted therein, in which the temperature sensor (18) is arranged. 2. Cooking device according to claim 1, characterized in that the temperature sensor (18) is held displaceably in the sleeve (20, 33). 3. Cooking device according to claim 1 or 2, characterized gekennzeicnnet that the The temperature sensor (18) is spring-loaded upwards against a stop in such a way that that when it is in contact with the stop it is slightly above the surface of the glass ceramic plate (11) survives. 4. Cooking device according to one of the preceding claims, characterized in that that the temperature sensor (18) laterally opposite the electrical heater (28) is at least partially thermally insulated. 5. Cooking device according to one of the preceding claims, characterized in that that the upper edge of the opening (17) has a bevel (19). 6. Cooking device according to one of the preceding claims, characterized in that that the sleeve (20) has a shoulder (23) or a collar with which or the it rests moisture-tight on the edge of the opening (17) or on the bevel (19). 7. Cooking device according to one of the preceding claims, characterized in that that the sleeve (20) consists of a very thin material. 8. Cooking device according to one of the preceding claims, characterized in that that the sleeve (33) consists of ceramic. 9. Cooking device according to one of claims 1 to 7, characterized in that that the sleeve (20) against the bevel attached to the upper edge of the opening (17) (19) is pressed and deformed from the underside. 10. Cooking device according to one of the preceding claims, characterized in that that the sleeve (20) at least in the area of its circumference resting on the edge of the opening is formed corrugated (Fig. 7). 11. Cooking device according to one of claims 6 to 10, characterized in that that the underside of the shoulder (23) or the collar is smooth. 12. Cooking device according to one of the preceding claims, characterized in that that in the case of a radiant heater, the insulating body (29) holding the heating (28) and / or the outer sheet metal plate (32), the sleeve (20, 33) and the temperature sensor (18) surrounds approximately cylindrical. 13. Cooking device according to one of the preceding claims, characterized in that that the temperature sensor (18) is a hydraulic sensor. 14. Cooking device according to one of the preceding claims, characterized in that that the temperature sensor (18) is part of an automatic circuit. 15. Cooking device according to one of the preceding claims, characterized in that that the temperature sensor (18) on two switches (42, 43) at different temperatures acts, of which the first switch (42) between 50% and 70 % of the electrical heating power and the second switch (43) the rest of the power turns off. 16. Cooking device according to one of the preceding claims, characterized in that that the diameter of the temperature sensor (18) is about half as large as the diameter the sleeve (20, 33).