EP0927503B1 - Radiant heating element with a metal foil heat conductor - Google Patents

Abstract

A radiant heating body for a cooking hob has a heating conductor comprising a metal foil and an insulating bottom (12). To make the heating conductor easy to fit and to provide advantageous heat radiation properties the flat geometrical heating conductor pattern is separated out of the metal foil. The pattern forms heating limbs (1) whose large surface is towards the cooking hob and which are held at least at an outer annular rim (13) of the insulating bottom (12).

Description

The invention relates to a radiant heater for a hob, in particular a glass ceramic hob with a metal foil heating conductor.

US-A-4,034,206 discloses a generic radiant heater for a glass ceramic cooktop with a heating conductor made of a metal foil and an insulating base underneath the heating conductor. The heating conductor runs between in a geometric pattern the hob and the insulating floor. The geometric pattern of the heating conductor is from the Separated metal foil and forms heating webs whose thickness is much smaller than theirs Width and the large surface of which faces upwards towards the glass ceramic cooktop. The Heating bars are held and lie on at least one outer ring edge of the insulating base with external current bridges free in recesses in the wall, so a certain To be able to record movement of the heating conductor.

From US-A-3,316,390 a radiant heater is known in which the The bottom of the heating webs facing the insulating floor is at least partially free at a distance runs over the insulating floor.

Further radiant heaters are described in DE 42 39 375 A1 and EP 0 585 831 A2. The heating conductor consists of a flexible flat strip that spirals on the insulating floor is laid that its large surface perpendicular to the insulating floor and stand by the hob. Only its narrow top edge faces the hob. By this arrangement mutually irradiates the large surfaces. To determine the Heizleiterbandes this on its lower edge retaining tabs, which in the insulating floor are plugged in themselves. The assembly of the heating conductor is complex because the ribbon must be laid in spiral turns, and because the retaining tabs in the insulating floor must be pushed in. At the high temperatures, greater than 600 ° C, the In radiation operation, corresponding strains occur on the heating conductor, which do not lead to this may that the heating conductor detaches from the insulating floor.

A heating conductor is described in EP 0 175 662 B1 whose flat geometric pattern is stamped out a foil laminate enclosing a metal foil is separated out. This radiator is only suitable for Temperatures below 200 ° C, max. 400 ° C, and is therefore as Radiant heaters cannot be used.

According to EP 0 175 662 B1, the film laminate two nested metal radiators punched out, which reduces the punching waste.

EP 0 229 928 A2 describes a heating element for Cooking places known that a Heizleiterbahn in Flat conductor technology, preferably thick-film paste technology, has on a dimensionally stable support element is applied. A radiant heater where it is on the glow of the heating conductor arrives is not there described.

U.S. Patent 3,567,906 describes a sinusoidal winding flat heating wire, in parallel strips is laid under the hob. The flat heating wire should not be visible through the hob. It is not a radiant heater, where it is important that the heating conductor for the User glows visibly.

DE 41 22 106 A1 is a radiant heater described, the heating coil by means of a molded part are held down on the insulating floor.

The object of the invention is a radiant heater to propose of the type mentioned at the outset Heating conductor can be easily installed above the insulating floor, whereby the thermal expansion of the heating conductor is safe caught and favorable radiation properties, before all with regard to the quickly visible glow and of efficiency, should be achieved.

According to the invention, the above task is for one Radiant heater of the type mentioned by Features of the characterizing part of claim 1 solved.

Since the heating conductor is separated from a metal foil, for example punched out, cut out or etched out is, it is in the plane of its flat geometric Patterns fairly stable, with this plane parallel between the level of the hob and the level of the Insulating floor. The geometric pattern is for example star-shaped, meandering or spiral. It can also take the form of a company logo, for example a character, a characteristic Sequence of letters, or of letters and / or numbers take in.

The heating conductor can be made in one piece from a metal foil cut out if a metal foil is available, the one corresponding to the diameter of the heating conductor Width. However, it can also be made up of several pieces put together, each part of the geometric Pattern. The heating conductor pieces are thereby preferably in such widened zones with each other connected in operation compared to the heating bars stay cold.

The prefabricated heating conductor can be easily over put the insulating floor, laying procedures such as for example, spiral winding is eliminated.

The heating bars of the heating conductor turn their large Surface to the hob. It is thus achieved that the heating conductor covers a large part of the area of the Occupies the hob, making it cheap Radiation properties are achieved. The distances between the narrow edges of the heating conductor only need be so large that the necessary electrical insulation between the heating bars is guaranteed. The for Available surface of the hob can be largely cover with heating conductors.

Comparative tests have shown that a The glow time is much shorter than in known radiant heaters. Because the radiating Surface is large in relation to the cross section given good heat dissipation that allows the Heating bars with a comparatively large current density strain. There will also be a short parboil with high Efficiency achieved.

Another advantage is that the overall height of the radiant heater can be made small, or at the same height, the thickness of the insulating floor and so that its thermal insulation effect can be increased.

The actual heating webs preferably float, especially when cold and preferably also when hot, free above the insulating floor. You can at the consequence the high radiation temperatures, which are above 600 ° C and can reach up to 1200 ° C, inevitably occurring Thermal expansion in the direction of the insulating floor sag without loosening the Heating conductor comes. The air space between the heating bars and the insulating floor has a heat-insulating effect. To do that To decrease sagging can reduce the rigidity of the flexible heating elements can be increased in that they are U-shaped or V-shaped in their cross-section. The profiling can extend over the entire length or extend part of the length.

The heating conductor is preferably fixed on its Geometric pattern designed holding tabs for example on a ring edge of the insulating base sit. This ring edge can be a separate part of the Insulated floor attached or in one piece on this be designed.

The outer ring edge is preferably one ring-shaped outer zone of the Isolierboden and a ring part placed on this made of thermally and electrically insulating material formed, the retaining tabs between the outer zone and grip the ring part. This allows the Simply attach the heating conductor to the ring-shaped one Put on the outer zone, keeping the desired distance from occupies the insulating floor. By putting on the ring part the heating conductor is fixed.

The frictional and / or positive fixation leaves using pull-throughs or claws on the retaining tabs improve, with the passages or claws through Press the ring part upwards into the ring part and / or down into the annular outer zone of the Penetrate the insulating floor.

In a similar way, the heating conductor can also be connected to a central inner point of the heating web fixed his.

In a preferred embodiment of the invention Holding tabs so wide than the heating bars that their Operating temperature remains below the annealing temperature. It is thus avoided that those sitting in the ring edge Retaining tabs on the insulating material unnecessarily heating temperature come. In addition, in such widened, especially comparatively cool zones also any necessary electrical connections be provided so that this the life of the Do not affect the heating element.

Figuren 1 bis 5 Aufsichten eines Heizleiters mit verschieden geometrischen Mustern und Haltelaschen im noch nicht in den Strahlungsheizkörper eingebauten Zustand,

Figuren 6,7,8,10 einen Strahlungsheizkörper schematisch im Querschnitt mit eingesetztem Heizleiter,

Figur 9 einen Querschnitt benachbarter profilierter Heizstege längs der Linie IX-IX nach Fig. 7,8 vergrößert,

Figur 11 eine Detailansicht zu Fig. 6,7,8,10 einer Befestigungsmöglichkeit des Heizleiters

Figuren 12 bis 14 eine Detailansicht weiterer Befestigungsmöglichkeiten,

Figur 15 eine Alternative zu den Fig. 6,7,8,10,

Figur 16 einen Heizleiter mit Wellung in Längsrichtung,

Figur 17 eine zweite Gestaltung der Wellung,

Figur 18 eine dritte Gestaltung der Wellung,

Figur 19 eine Aufsicht eines mäanderförmigen Folienteils, aus dem der Heizleiter zu biegenist,

Figur 20 einen in sein geometrisches Muster aus dem Folienteil nach Fig. 11 gebogenen Heizleiter,

Figuren 21 bis 27 Detailansichten weiterer Befestigungsmöglichkeiten der Haltelaschen.

Further advantageous refinements of the invention result from the subclaims and the following description of exemplary embodiments. The drawing shows:

FIGS. 1 to 5 are top views of a heating conductor with different geometrical patterns and holding tabs in the state not yet installed in the radiant heater,

FIGS. 6, 7, 8, 10 schematically show a radiant heater in cross section with the heat conductor inserted,

9 shows a cross section of adjacent profiled heating webs along the line IX-IX according to FIG. 7.8 enlarged,

11 shows a detailed view of FIGS. 6, 7, 8, 10 of a possibility of fastening the heating conductor

FIGS. 12 to 14 show a detailed view of further fastening options,

15 shows an alternative to FIGS. 6, 7, 8, 10,

FIG. 16 shows a heating conductor with corrugation in the longitudinal direction,

FIG. 17 shows a second configuration of the corrugation,

FIG. 18 shows a third configuration of the corrugation,

FIG. 19 is a plan view of a meandering film part from which the heating conductor is to be bent,

FIG. 20 shows a heating conductor bent into its geometric pattern from the film part according to FIG. 11,

Figures 21 to 27 detailed views of other mounting options for the retaining tabs.

A heating conductor is in a desired geometric Pattern (see Fig. 1 to 5) from a thin, equally thick Metal foil with a suitable for a heating conductor specific electrical resistance, for example through a cutting process, punching process or etching process separated. The thickness of the metal foil is for example about 0.03 to 0.1 mm. Preferably, the Heating conductor in one piece, being below one circular hob of a glass ceramic plate lying entire flat geometric pattern separated out a correspondingly wide metal foil is. However, if only a less wide metal foil for Is available or can be edited, it is possible, the heating conductor from two or more pieces with each piece being part of the forms geometric pattern.

There are several heating bars (1) on the heating conductor, outer ones Holding tabs (2) and two power connections (3) formed. The heating webs (1) are so wide that they are in operation glow visibly. The retaining tabs (2) and the Power connections (3) are wider than the heating bars (1) designed so that they do not Annealing temperature come.

1, the heating webs run (1) in a right and left semicircle, respectively parallel. The outer retaining tabs (2) are on the Circumference, with two adjacent heating bars are connected externally by an outer retaining tab.

Two adjacent heating elements (1) are on the inside an inner retaining tab (8) connected, the Heating bars (1) between the power connections (3) electrically in line. However, a row / Parallel connection can be designed.

The inner retaining tabs (8) lie in two rows a diagonal zone of circular shape (see Fig. 1). To the outer or inner retaining tabs (2.8) can Heating conductor in the manner described in more detail below fix.

1 is an extensive one Allocation of the circular heating surface with heating conductors reached. This results in heat radiation high efficiency and a uniform glow pattern.

1 is also suitable for Manufactured from two symmetrical individual pieces. This can be electrical at a connection point (X) with each other, for example by welding, connect.

1 exist in the outer retaining tabs (2) and the inner retaining tabs (8) as well as between the power connections (3) Stabilizing bars (5). These serve to stiffen the flexible heating conductor during transport and assembly. The cross section of each stabilizing bar (5) is much smaller than that of a heating element (1). After Installation of the heating conductor in the radiant heater the stabilizing bars (5) removed because they are electrical Show short circuits. This can be done by creating a electrical voltage, for example to the Power connections (3) take place. The stabilizing bars (5) then blow away.

In the exemplary embodiment according to FIG. 2, the heating conductor is composed of six identical segments, which on the Connection points (X) are interconnected. In the heating bars (1) run parallel to each segment to each other. Here too exist with the outer Retaining tabs (2) stabilizing bars (5). The inner ones Retaining tabs (8) are only indicated schematically. This Semiconductor pattern brings good use of the Heating surface and provides a star-like glow pattern.

A star-shaped heating conductor pattern is shown in FIG. 3. A pair of parallel heating elements (1) form one Ray of the star pattern. All outer Retaining tabs (2), each connecting a pair of heating elements, lie on the circumference. The rays are radial alternately different lengths, the inner Retaining tabs (8), each connecting a pair of heating elements, lie on circles of different diameters. in the Operation results in a star-shaped glow pattern, whereby in Outside area compared to the embodiment according to FIG. 4 higher power density is achieved.

4 forms in each case parallel pair of heating bars (1) a beam of the star pattern. Are on the heating bars (1) lateral retaining tabs (4) provided perpendicular to Level of the pattern can be turned down and for guidance in recesses or grooves of the below described insulating floor serve. This side Retaining tabs (4) can, however, also be omitted.

4 there is on the heating conductor as a stabilizing web (5) an inner ring. This only serves to increase the stability of the heating element during transport and during Assembly. The inner ring (5) is because it has a forms an electrical short circuit before assembly, burned out, for example, over predetermined breaking points. in the In operation, the heating bars (1) are between the Power connections (3) electrically in series, being over the retaining tabs (2), which are on the branches of the geometric pattern are provided, and the outer Form connecting webs (6) and over inner Connecting webs (7), which are also inner retaining tabs (8) form, are electrically connected.

In Fig. 5 different courses of the heating webs (1) are Clarification of the possibilities shown. A part of Heating bars (1) run in pairs parallel to each other. Other heating webs (1 ') run approximately radially to Center point (M). For reasons of symmetry, in practice one or the other course for all heating webs (1,1 ') to get voted.

5, the outer retaining tabs (2) face each other the outer connecting webs (6) to the outside. The inner retaining tabs (8) are opposite the inner ones Connecting webs (7) inwards over. The widths of the inner connecting webs (7) and / or the outer Connecting webs (6) can do this depending on the requirement be designed so that they operate like the heating webs (1, 1 ') glow or not glow.

6,7,8,10,15 and 24 to 30 is one under one translucent glass ceramic plate (9) Radiant heater (10) shown schematically. In one Pot (11) made of sheet metal of the radiant heater (10) is a Insulating floor (12) from a radiator known, thermally and electrically insulating material arranged. There is an outer one on the insulating base (12) Ring edge (13) for mounting the outer retaining tabs (2). 6,7,8,10 and 24,27 the ring edge (13) of the insulating base (12) in Protruding in the direction of the glass ceramic plate (9) annular outer zone (14) and one on this attachable ring part (15) is formed. Between the annular outer zone (14) and the ring part (15) are the outer retaining tabs (2) frictionally or positively held. To improve the tight fit can the retaining tabs (2) described in more detail below Breakthroughs (21) or claws are provided, which after down into the outer zone (14) or up into the ring part (15) are depressed.

6 is for storage of the inner holding tabs (8) on the insulating base (12) a base (17) trained. This extends for one 1 in the diagonal zone on the the inner retaining tabs (8) are also located. The two parallel rows of the inner retaining tabs (8) (see Fig. 1) are by means of an inner holding part (19) by a straight retaining strip is formed on the base (17) fixed. The retaining strip consists of a ceramic Material that is more dimensionally stable than the material of the Insulated floor (12). The retaining bar is on the base (17) for example attached by gluing or staples or held by means of the ring part (15). Above the Retaining bar (19) extends parallel to the Radiant heaters known per se Expansion temperature sensor.

During operation, the temperatures exceed 600 ° C significant thermal expansion of the heating webs (1) in Longitudinal direction, which is particularly the case with non-profiled Heating bars (1) leads to considerable sag. Fig. 6 shows the sag (23) of the heating webs (1) in the hot Status. The arrangement is preferably chosen so that even when hot, the heating bars (1) the insulating floor (12) do not touch. In the cold state there is a correspondingly larger distance between the large lower Surface of the heating webs (1) and the insulating base (12).

Fig. 7 shows an alternative to Fig. 6. The heating webs are profiled here, as is shown in FIG. 9 is shown to the stability of the heating webs too increase and thus reduce the sag.

In Fig. 7, the inner retaining tabs (8) are like this bent down that they the heating webs (1) from Keep the insulating base (12) spaced apart. You are in one the insulating base (12) fastened holding part (19) electrically insulating material, for example ceramic or mikanite (resin-bonded mica), inserted. Corresponding insertion openings can be made on the holding part (19) be designed. The one occurring on the heating bars (1) Thermal expansion is due to the flexibility of the inner Holding tabs (8) caught. To accommodate the Thermal expansion can also be provided that the inner and / or outer holding tabs on their holding parts in are movable to a limited extent.

8, the heating webs (1) are only profiled over part of its length and in one Length range (L) not profiled. This length range (L) runs slightly angled and reduces thermal expansion the heating bars on. The profiled length ranges can lie completely or almost on the insulating floor (12).

9 shows a cross section of two neighboring ones profiled heating elements (1). This profile is through Press in the heating elements (1) before assembly in Radiant heater V or U-shaped. This Design has the advantage that the heating bars in Longitudinal direction become more stable and that neighboring, parallel heating elements (1) when the Heating conductor from the metal foil with a single Cut can be separated from each other without loss of material can and the necessary electrical insulation distance (c) then by pressing in the V-shaped profile arises. In addition, this shape has the advantage that the Radiation properties of each holding bridge (1) targeted be affected by either the concave surface or the convex surface of the glass ceramic plate (9) is facing.

10 there is between the Outer zone (14) and the ring part (15) a step (16) to the Insert the heat conductor without touching the pot (11) can. The heating conductor engages with its outer Retaining tabs (2) between the outer zone (14) and that Ring part (15), wherein the outer retaining tabs (2) are not made the plane of the geometric pattern are bent.

In the middle of the insulating floor (12) is like that Outer zone (14) in the direction of the glass ceramic plate (9) protruding base (17) formed, which like the Outer zone (14) has a step (18). On the base (17) a cap (19) can be put on as an inner holding part like the ring part (15) from an electrical and thermal insulating material.

On the outer retaining tabs (2) and / or the inner Retaining tabs (8) can be designed passages (21) (cf. Fig. 11). These passages (21) can be on the Simple metal foil in the area of the holding tabs (2.8) by hammering in a pointed tool, where metal foil tips arise. These take effect when Pressing on the ring part (15) (see Fig. 11) and / or the inner holding part (19) depending on the orientation in the Ring part (15) or the holding part (19) or in the outer zone (14) or the base (17). It can also be a combination of tabs and / or claws and / or passages be provided. Instead of the passages (21) could also claws bent at the ends of the retaining tabs (2,8) be provided. The passages or claws serve the radial securing of the heating conductor in the Radiant heater. Instead of the swivels or claws can also be a frictional clamping of the retaining tabs (2,8) through the ring part (15) and / or the holding part (19) be provided.

12 shows a further alternative for the definition the inner retaining tabs (8). On the insulating floor (12) as a base (17) attached a ceramic base part, the in the case of the heating conductor according to FIG. 1 via the diagonal Zone is elongated, in the case of the heat conductor Fig. 2 is star-like according to the segmentation and in the case of the heating conductor according to FIGS. 3 and 4 is circular. Over the upper edges (17 ', 17' ') of the Base part are the retaining tabs (8) in one Turning angle bent and using a U-shaped strip-like holding parts (19 ', 19' ') clamped. Thereby is a tight fit that prevents the retaining tabs (8) at the temperature-related Loosen stretch or shrink. This is because of it supports that the heating bars shrink to the Holding parts (19 ', 19' ') exert a tilting moment that the Clamp effect increased.

13 and 14 show further alternatives for the Fastening the retaining tabs. On the inner and / or outer retaining tabs (8,2) are indentations (8 ') trained (see Fig. 13), which a toothing (17 '' ') a ceramic, attached to the insulating base (12) Base part (17) is assigned. By inserting the Indentations (8 ') between the teeth (17' '') a positive fit of the retaining tabs is achieved. A similar form-fitting connection could also be carried out create a hole and pin pair.

The assembly is essentially as follows:

On the outer zone (14) and the base (17) Prefabricated heating conductors attached. The outer Retaining tabs (2) and the inner retaining tabs (8) are located then on, with those running between them Heating webs (1) preferably at a distance (a) from that Extend insulating floor (12). The bottom big ones Surfaces of the heating webs (1) are the insulating floor (12) facing. The upper large surfaces of the heating elements (1) are facing the level of the glass ceramic plate (9). Just the narrow edges of adjacent heating elements stand towards each other. Then, to fix the outer retaining tabs (2) and the inner retaining tabs (8) the ring part (15) and the inner holding part (19) placed. The retaining tabs (2.8) can therefore only be limited or stop moving, taking some agility in the radial direction on the outer zone (14) and / or on Base (17) can be approved. In any case, come loose the retaining tabs (2.8) for operational stretching and shrinkage from their attachment points. The upper large surface of the heating webs (1) is located thus at a distance (b) from the glass ceramic plate (9). Then, if necessary, the stabilizing bars (5) severed. In operation when the heating bars (1) at Temperatures above 600 ° C radiate visibly on them a considerable temperature expansion, so that it in sag the space (22) formed by the distance (a). This sag is 23 in FIGS. 6 and 10 designated. The distance (a) is designed so that the Heating bars (1) when sagging the insulating floor (12) preferably do not touch.

On the insulating floor (12), below one or more the heating webs (1), a further metal foil part (20) be arranged as a temperature sensor (see Fig. 10). This has a temperature dependent electrical Resistance on which is a measure of the temperature of it irradiating heating webs (1). The temperature sensor (20) can with a usual with radiant heaters Temperature controller can be connected.

15 shows a further exemplary embodiment. There if the insulating base (12) does not face the glass ceramic plate (9) raised outer zone (14). On its outer Ring edge (13) recesses (24) are provided, in which the in this version angled downwards Engage the retaining tabs (2.8). A corresponding Design with recesses (25) is the inner Retaining tabs (8) provided. For further stabilization engage bent side retaining tabs (4) in the Insulated floor (12). Thermal expansion becomes a game here the retaining tabs caught in the recesses.

16 are the outer ones Holding tabs (2) are bent downwards and grip Play in a recess (24) in the outer zone (14). Similar grab the inner retaining tabs that are bent downwards (8) in a recess (25) of the base (17). The The heating conductor is thereby secured radially and its Thermal expansion is absorbed.

16, 17 and 18 are in the embodiment the heating webs (1) in the longitudinal direction, perpendicular to Insulated floor (12) corrugated. Between the wave valleys there is the distance (a) to the insulating floor (12). Between There is a distance (b) to the wave ceramic peaks (9). 16, the waves are uniform. According to Fig. 17 the wave crests or wave valleys are different high or low. This is in zone (A) with the higher waves have a higher radiation density than in zone (B) with the flatter waves. According to Fig. 18 the wavelengths are different. This will in the zone (A) with the shorter wavelengths a larger one Radiation density reached than in zone (B) with the longer wavelengths. This makes it a targeted one Influencing the radiation density in the inner and outer Areas of the radiant heater possible.

Another embodiment is shown in FIGS. 19 and 20 shown. A straight meandering pattern (cf. Fig. 19) is separated from a metal foil strip, the has the width (C). The cuts at which the Connect adjacent identical patterns are with the Power connections (3).

This pattern is shown in that in FIG Heating conductor shape bent. For this, the inner Connecting webs (7) can be shortened. this happens in that the connecting webs (7) are corrugated (cf. Fig. 20). In this form, the heating conductor is on the Insulated floor (12) placed on and fixed to this. This Execution has the advantage that less when disconnected Metal foil waste arises as if that Metal foil tape would have the width (D) (see Fig. 20).

21 to 24 show various others Possibilities for defining the outer retaining tabs (2) between the outer zone (14) and the ring part (15). By these designs is achieved that the Retaining tabs (2) by positive locking and if necessary supported by friction not under the ring part (15) pull out.

In the embodiment according to FIG. 21, the outer zone (14) has a slope (34) sloping outwards towards the pot (11) on. A corresponding slope (35) is on the Ring part (15) formed, the retaining tabs (2) engage a bend (36) between the bevels (34, 35). there can the bends (36) on the retaining tabs (2) be prefabricated. However, you can also do so arise that the holding part (15), mounted under the Glass ceramic plate (9), presses on the retaining tabs (2). By the from the ring part (15) on the bends (36) exerted pressure arises at the bends (36) Force component that tries to pull this outwards so that the heating webs (1) are stretched radially.

22 is on the retaining tabs (2) an upward bend (37) is provided, which engages in a recess (38) of the ring part (15). At 22 is the bend (37) around less than 90 ° from the plane of the geometric Pattern of the heating conductor bent. When executing 26 is the bend (39) of the retaining tab (2) more than 90 ° upwards from the plane mentioned bent over so that a fairly stable hook arises. This is one formed by the ring part (15) Stop (40) assigned to the bend (39) and thus the retaining tab (2) is not between the outer zone (14) and the ring part (15) can slide out.

24 is on the outer Retaining tab (2) a downward bend (41) intended. This is similar to that for the heating element above (1) described in their cross-section U- or V-shaped profiled. It is so stiff that it is direct can be pressed into the material of the insulating base (12). This material is usually softer than the material from which the ring part (15) consists. 21 and 22 the passages (21) described above are also shown, into the outer zone (14) of the insulating base (12) are indented. These passages (21) can also in the Embodiments of FIGS. 26 and 27 are provided his.

25, 26 and 27 show alternatives for the Fastening the inner retaining tabs (8). 25 and 26 is an inner holding part, a holding bar (19) intended. This has for the inner retaining tabs (8) of the heating conductor (see Fig. 1) two rows of slots (42), with each holding tab (8) having its own Slot is provided. The retaining bar (19) is there for example made of resin-bound mica flakes (Micanite). Through the slots (42) are the ends of the Retaining tabs (8) inserted and at the top and bottom of the Retaining strip (19) bent about 90 °, so that it in the Firmly lock the slots (42) (see Fig. 25). It is thus a fixation of the retaining tabs (8) in Longitudinal direction (R) of the heating webs (1) and transverse direction (Q) reached. By fixing in the longitudinal direction (R) ensures that the heating webs (1) within the Ring part (15) have the necessary tension. Through the Fixation in the transverse direction (Q) ensures that the Retaining tabs (8) can not slip so that Touch adjacent heating elements (1).

The retaining strip (19) according to FIGS. 25 and 26 can be on a base (17) of the insulating base (12) described above sit on and / or be attached to it. The Retaining strip (19) can, however, also over the insulating floor (12) float freely. The retaining tabs (8) are on the Retaining strip (19) attached before the heat conductor in the Pot (11) is used.

Fig. 27 shows a configuration similar to Figs. 10 and 12 of the inner holding part (19). Get in here Base (17), which is fixed to the insulating base (12), Bends (44) of the retaining tabs (8). By one in the Base (17) pressed-in holding part (19) made of ceramic Material are the bends (44) in the base (17) clamped. 1 are the Base (17) and the holding part (19) strip-shaped. For Heating conductor, in which the inner retaining tabs (8) on lie in a circle are the base (17) and that Holding part (19) correspondingly circular.

Instead of that described with reference to FIGS. 25 and 26 Fastening the retaining tabs (8) to the retaining strip (19) by bending over, it is also possible to hold the retaining tabs (8) to sew on the retaining bar (19). For this, a commercially available heat-resistant thread or thread, in particular made of ceramic fiber material. When sewing on, the retaining tabs (8) and Pierced retaining strip (19). The bottom line is too by attaching a fixation of the retaining tabs (8) the retaining strip (19) in the longitudinal direction (R) and in Transverse direction (Q) reached. If necessary, the Retaining tabs (8) also with two superimposed ones Retaining strips (19) are sewn, the retaining tabs (8) then lie between the two retaining strips (19). The Sewing with an annular carrier can also be done with the outer retaining tabs (2). This ring-shaped Carrier and the holding bar (19) can be a form one-piece molding. The sewing takes place before the insertion of the heating conductor in the pot (11) or the insulating floor (12). The sewn on the molding The heating conductor is then used as a prefabricated assembly in the Pot (11) or placed on the insulating base (12), wherein all retaining straps are fixed in their desired position. Then the ring part (15) can be put on.

Numerous others are within the scope of the invention Embodiments. For example, it is possible To combine partial features of the designs.

Claims (22)

1. Radiant heating element for a cooking zone, in particular a glass ceramic cooking zone, with a heat conductor and with an insulating base (12) disposed undemeath the heat conductor, in which the heat conductor is separated out in a geometric pattern from a metal foil and extends between the cooking zone and the insulating base (12) and forms heating members (1) of a thickness which is substantially smaller than their width, their large surface being directed upwards, and in which the heating members (1) are supported at least at an outer annular edge (13) of the insulating base (12),
   characterized in that

   the underside of the heating members (1), which faces the insulating base (12), extends freely at least in part at a distance above the insulating base (12),

   in that holding tabs (2, 4, 8) are shaped in the metal foil on the plane of the geometric pattern,

   in that the holding tabs (2), shaped at outer points of the geometric pattern, are fixed to the insulating base (12) by means of a holding component (15) at the outer annular edge (13) of said insulating base (12),

   in that the inner holding tabs (8) are formed at inner points of the geometric pattern of the heat conductor and are fixed to a member-supporting portion (17) of the insulating base (12) by means of a holding component (19), which is held on the supporting portion (17), and

   in that the inner and/or outer holding tabs (2, 8) are held by the holding components (15, 19) with frictional and/or positive fit.
2. Radiant heating element according to Claim 1,
   characterized in that
   the inner holding tabs (8) are inserted through slots (42) in the holding component (19) and bent towards its wide sides.
3. Radiant heating element according to Claim 1,
   characterized in that
   projections (21) and/or claws, formed on the holding tabs (2, 4, 8), engage in the material of the insulating base (12) and/or the annular component (15) and/or the holding component (19).
4. Radiant heating element according to Claim 1,
   characterized in that
   the holding tabs (2, 4, 8) are bent in relation to the plane of the geometric pattern and engage in recesses (24, 25) in the insulating base (12) with sufficient play or flexibility to accommodate the thermal expansion of the heating members (1).
5. Radiant heating element according to one of Claims 1 to 4,
   characterized in that
   the holding tabs (2, 4, 8) are wider than the heating members (1), so that during operation their temperature remains below the incandescent temperature.
6. Radiant heating element according to Claim 1,
   characterized in that
   the outer annular edge (13) comprises an annular, raised outer zone (14) of the insulating base (12) and an annular component (15) which is mounted on said outer zone and is made of thermally and electrically insulating material, the outer holding tabs (2) being held between the outer zone (14) and the annular component (15).
7. Radiant heating element according to Claim 1,
   characterized in that
   the supporting portion (17) comprises a component fixed to the insulating base (12), around at least one edge (17', 17") of which the inner holding tabs (8) are bent and clamped by means of at least one holding component (19, 19', 19").
8. Radiant heating element according to one of the preceding claims,
   characterized in that
   the outer holding tabs (2) lie on a circumferential circle of the heat conductor and the inner holding tabs (8) lie on a diagonal zone of the heat conductor and the heating members (1) run parallel to one another.
9. Radiant heating element according to one of the preceding Claims 1 to 8,
   characterized in that
   the outer holding tabs (2) lie on a circumferential circle of the heat conductor and the inner holding tabs (8) lie on at least one concentric circle, the heating members (1) extending parallel in pairs.
10. Radiant heating element according to one of the preceding claims,
    characterized in that
    in each case an outer holding tab (2) and an inner holding tab (8) join together heating members (1), said heating members (1) running in pairs parallel to one another.
11. Radiant heating element according to one of the preceding claims,
    characterized in that
    the bent-over portions (41) of the holding tabs (2, 8) are profiled in cross-section and are pressed into the material of the insulating base (12).
12. Radiant heating element according to one of the preceding claims,
    characterized in that
    the bent-over portions (36) of the outer holding tabs (2) are clamped between a portion (34), sloping outwardly downwards, of the insulating base (12) and a corresponding sloping portion (35) of the annular component (15).
13. Radiant heating element according to one of the preceding claims,
    characterized in that
    the bent-over portions (37) of the outer holding tabs (2) engage in a recess (38) disposed in the annular component (15).
14. Radiant heating element according to one of the preceding claims,
    characterized in that
    a shoulder (40) of the annular component (15) is associated with hook-like bent-over portions (39) of the outer holding tabs (2).
15. Radiant heating element according to Claim 1,
    characterized in that
    the holding component (19) lies on a supporting portion (17) of the insulating base (12) or is supported so as to hang free above the insulating base (12).
16. Radiant heating element according to one of the preceding claims,
    characterized in that
    the holding tabs (2, 8) are sewn on to a holding component.
17. Radiant heating element according to one of the preceding claims,
    characterized in that
    a profile is embossed into the heating members (1), said profile being V- or U-shaped in cross-section.
18. Radiant heating element according to one of the preceding claims,
    characterized in that
    the heating members (1) are at least partly corrugated in longitudinal direction, perpendicular to the insulating base (12).
19. Radiant heating element according to Claim 18,
    characterized in that
    the heights of the peaks of the corrugations and/or of the valleys thereof and/or the lengths of the corrugations differ so as to produce a varying radiation density.
20. Radiant heating element according to one of the preceding claims,
    characterized in that
    current connections (3) are formed with the geometric pattern of the heat conductor, said current connections (3) being wider than the heating members (1), so that during operation their temperature remains below the incandescent temperature.
21. Radiant heating element according to one of the preceding claims,
    characterized in that,
    the geometric pattern of the heat conductor is made up of several pieces which are separated out from a flat metal foil.
22. Radiant heating element according to one of the preceding claims,
    characterized in that
    the geometric pattern of the heat conductor is formed by bending a straight meander shape which is separated out from a flat metal foil.

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