DE102016208233A1 - Induction heater and induction hob with such induction heating - Google Patents

Abstract

An induction heater (11) for an induction hob (33) comprises a flat induction heating coil (12), an induction heating coil support (14) and a plurality of flat ferrites (20a, 20'a) disposed on a flat side of the induction heating coil. Further, spring means (29a) are provided on the induction heater (11) for spring-loaded pressing the induction heater on a cooktop panel (34) as a cover over it. The spring means (29a) are each mounted directly on a ferrite (20a), to which on the ferrite (20a) a recess (22a) is provided, in which the spring means (29a) are held.

Description

AREA OF APPLICATION AND PRIOR ART

The invention relates to an induction heating device, as it can be used in particular for an induction hob, and an induction hob provided with such induction heating.

Induction heaters, such as those used in an induction hob or generally for inductive heating, may include a flat induction heating coil. This is arranged close to a cover on which there is an object to be heated, for example a cooking vessel. In order to direct and concentrate the magnetic flux, in particular to keep the area below the induction heater free from magnetic fields, ferrites are typically placed under the induction heating coil. These can also be flat and flat and oblong or strip-like.

From the EP 14198247.0 With filing date of 16 December 2015, such an arrangement of an induction heating coil in an induction hob is known, wherein induction heating coil and ferrites are arranged on a support. Thus, the assembly of the induction hob can be improved. The carrier is then pressed against the underside of a hob plate as a cover.

TASK AND SOLUTION

The invention has for its object to provide an induction heating device mentioned above and an induction hob provided with it, with which problems of the prior art can be avoided and it is in particular possible, a mounting or attachment of the induction heater, preferably in an induction hob, simple and practicable at low cost.

This object is achieved by an induction heating device with the features of claim 1 and by an induction hob with the features of claim 17. Advantageous and preferred embodiments of the invention are the subject of further claims and are explained in more detail below. In this case, some of the features are described only for the induction heater or only for the induction hob. However, they should be able to apply independently for both the induction heater and the induction hob independently. The wording of the claims is incorporated herein by express reference.

The induction heater has an induction heating coil and a carrier for the induction heating coil. Furthermore, it has at least one ferrite, advantageously several ferrites such as 4 to 12 ferrites. The at least one ferrite is disposed on the carrier on one side of the induction heating coil. It is advantageously arranged on a flat side of the induction heating coil, particularly advantageous if it is flat. A distance of the ferrite to the induction heating coil can be a maximum of 10 mm, advantageously at most 6 mm. In this case, a thin region of the carrier between induction heating coil and ferrite may be provided for assembly reasons. Furthermore, the induction heater has a spring means for resiliently urging the induction heater to a cover disposed above it. This means that a permanent and safe plant is still guaranteed without direct permanent attachment of the induction heater to the cover or on a bottom of the cover. Furthermore, can be compensated by the resilient or spring-loaded pressing component and mounting tolerances.

According to the invention, the spring means are held or fastened directly to the ferrite or engage directly on the ferrite, for which purpose a recess and / or a projection are provided on the ferrite. This results in a positive retention of the spring means on the ferrite in at least one direction, advantageously transversely to the spring direction or transversely to a direction along the surface of the ferrite. Thus, the spring means can not move laterally in an undesirable manner on the ferrite, in particular not from a designated advantageous position out.

In the prior art, the spring means are arranged on the carrier itself or press against the carrier itself, for example, its material, which is advantageously plastic. For this purpose, however, usually a slightly larger area is required on the carrier in order to be able to attach spring means which are advantageously designed in coil spring form and therefore have a large diameter. Furthermore, a type of force introduction of this region of the carrier, which abut the spring means in the surrounding carrier is then required to achieve a uniform and stable spring-loaded pressing with a few, for example, four spring means per induction heating coil. The fact that the spring means abut the ferrite due to the rigid and stable design of such ferrites automatically automatically distributes the applied spring force over a larger area, namely that of the ferrite achieved. Since this should be stably stored in the carrier anyway, the spring forces acting on the ferrite can also be well coupled into the carrier. Furthermore, can By changing the ferrites as separate parts alone, the invention can be realized. The cost of changing an injection mold for the carrier can be saved, apart from the fact that under certain circumstances not enough space on the support is free for the placement and pressing of the spring means. Advantageously, the side of the ferrite, on which the spring means are supported, largely free.

A recess in the ferrite can be subsequently created, for example by drilling or advantageously milling or grinding. In principle, a projection on the ferrite can also be produced by material removal, in particular around the projection. Advantageously, a projection, as possibly also a recess, is produced during the production of the ferrite, since these are usually pressed before sintering. So it only needs the mold or a punch to be changed in a simple manner. Alternatively, a projection can also be glued to the ferrite, wherein the projection can either consist of the same material as the ferrite or advantageously of a plastic, possibly a ferrite-containing plastic.

A ferrite may be formed substantially flat with a maximum thickness of 10 mm, advantageously about 3 mm to 8 mm. It can particularly advantageously have an approximate geometric basic shape, such as an approximated triangle or an approximated quadrilateral, in particular a quadrangle as trapezoid or rectangle. It is also possible to provide at least two or three types of ferrites per induction heating coil, wherein it is not necessary for each spring to have a spring means.

In an embodiment of the invention, the recess and / or the projection for holding the spring means are provided on an underside of the ferrite, which points away from the induction heating coil. Thus, a spring-loaded pressing against the underside of the ferrite and thus against the underside of the carrier can be achieved, which in turn pushes the induction heating coil located on its top up to an underside of said cover.

In the event that a projection for supporting the spring means is provided, this projection may have a distance of at least 50% of the minimum width of the projection from an edge of the ferrite. This means that the projection should, if possible, not be arranged directly very close to an edge of the ferrite. Rather, a projection or a spring means should generally be arranged in a middle region or a center of gravity of the ferrite for a good initiation of the spring forces.

If a recess is provided for holding, advantageously only one recess and no projection, this recess may have a spacing of at least the minimum thickness of the ferrite from an outer edge of the ferrite. This essentially ensures that the stability of the ferrite and, above all, the edge area holding the spring means is sufficiently good. It should be avoided that a too thin edge region of the ferrite can break off to the recess during the production of the ferrite, during assembly or in use. Advantageously, this distance is at least twice the minimum thickness of the ferrite.

In an alternative embodiment of the invention, a recess may be provided in the ferrite for holding the spring means, which extends to an edge of the ferrite, so that the recess is open to this edge side of the ferrite. To the other edges out, to which the recess is then not open, the aforementioned distance condition may apply to just make the edge of the recess sufficiently stable. The advantage of a side-open recess for a spring means may be that then, as will be explained in more detail below, if necessary, an undercut may be provided in the recess, which is formed for example in the manner of a dovetail guide. A spring means can be inserted into the undercut from the edge. In the direction transverse to a bottom of the recess or transversely to the ferrite and away from this, the spring means is then secured by the undercut.

In a further embodiment of the invention, a recess bottom can extend parallel to the opposite flat side of a flat ferrite. Thus, a ferrite is easy to manufacture and also a spring means according to the invention can be easily and advantageously arranged therein. Advantageously, an entire ferrite for a spring means is plane-parallel and flat.

In an embodiment of the invention, a bore may be provided in the ferrite, which is advantageously a blind bore. Such a bore can be particularly advantageously provided in a recess in the ferrite for holding, but alternatively also on or adjacent to an aforementioned projection. This bore serves to retain a protruding portion of the spring means therein to secure the spring means against displacement, rotation or generally against removal by the spring means. Elaborate attachments such as gluing or the like so can be saved. Furthermore, such a bore can also be generated simultaneously during the production of the ferrite, in particular similar to a recess itself, for example, when pressing the ferrite from appropriate starting material.

An aforementioned bore can extend either substantially at right angles to the main extension into the ferrite, advantageously in an aforementioned recess bottom. Alternatively, it may also be provided in a recess edge, so that at this point the edge of a, for example, round recess has a small bulge of a few millimeters in length.

In an embodiment of the invention, the spring means may be formed as a wire spring. Here is a metal wire spring offers. Advantageously, it is designed as a helical spring and may have a diameter which is between 10% and 50% of the maximum extent of the ferrite. Such a coil spring may have a substantially round outer shape, and with a said diameter, it is ensured that a recess for receiving the coil spring has a sufficient distance from the edges or edge sides of the ferrite. Such coil springs made of metal wire have permanent spring properties with great spring force, in addition, they are very temperature resistant.

Particularly preferably, a coil spring can have a decreasing diameter, so that it also has a certain spiral shape in plan view. It can be provided that an end with the larger width or the larger diameter rests on the ferrite or by means of the recess and / or depression is supported thereon.

The advantage of this certain spiral spring shape is that the spring can be virtually completely compressed and then only has a height corresponding to the diameter of the wire. With imperceptibly reduced spring force so so a spring means can be created with less space.

In an alternative embodiment of the invention, the spring means may be formed as a leaf spring. You can have at least one kink or at least one bend, so either as a kind of U-spring with a small distance between the two legs in the compressed state, or as a so-called Z-spring. Such spring means can also have a relatively small space requirement or relatively low height compressed, but at the same time have a sufficient spring length to bridge larger distances or to act at longer distances resiliently. They are advantageously made of metal.

In yet another embodiment of the invention, it is also conceivable that the spring means are formed as a block-shaped spring body. For this purpose, they may preferably consist of a voluminous elastic plastic material, for example in foamed form. As a material, especially offers heat-resistant rubber or silicone rubber. A temperature resistance of the spring means should be at least 100 ° C, preferably at least 120 ° C due to the use in an induction heater or an induction hob and by the direct concern with the good heat conducting ferrites.

An aforementioned undercut configuration on a projection according to the invention and / or on a recess can be engaged behind by a section of the spring means so as to fasten the spring means in a form-fitting manner to the ferrite. Thus, a captive attachment of the spring means to the ferrite can be provided which secures, at least during assembly of the induction heater, the spring means on the ferrite against movement perpendicularly away from the surface of the ferrite. In principle, in the insertion direction or along the undercut recess, the spring means can still be moved. By a corresponding clamping or the like., For example, if the diameter of a lowermost turn of a coil spring as spring means is slightly larger than the width of the recess above the recess bottom, a moving out of the spring means can be prevented.

An undercut recess is advantageously opened up to a side edge or outer edge of the ferrite and also has the undercut over its entire length. In order to prevent an aforementioned automatic and undesired moving out or falling out of the spring means from the undercut recess may be provided to arrange a projection on the recess bottom and / or on a recess wall. This protrusion can be flattened or chamfered against a direction of insertion, so that the spring means, as it were, slide over it as it slides into the recess. On the other side or against a push-out direction, the projection may be formed approximately at right angles, so that an automatic moving over the projection is avoided.

An undercut projection as a support for the spring means may be formed in principle similar to a mushroom and have a diameter which lies above the diameter of a lowermost turn of a coil spring as a spring means. Thus, such a coil spring can be attached to the undercut projection, so to speak, or latched as an abutment.

While especially in an embodiment of the spring means as a helical spring with a slight spiral portion, the height of the compressed spring means may be about the diameter of a turn of the coil spring, a height of the unloaded spring means may generally be twice to twenty times greater than the maximum thickness of the ferrite. So just a greater distance of the spring means between abutment and ferrite can be bridged.

An induction hob according to the invention may have a housing for accommodating at least one, preferably a plurality, of the aforementioned induction heating device. This housing is arranged under a cooktop plate as the aforementioned cover, in particular attached thereto. For example, a housing can be fastened or screwed or hung on rails as a flat housing shell with a housing bottom on rails, which are glued to the underside of a hob plate. The induction heater is pressed from below against the hob plate, serve the spring means which are supported against the housing bottom as an abutment.

An induction heating coil can be pressed either directly or advantageously by means of an applied thermal barrier coating on the underside of the hob plate. This heat-insulating layer serves to achieve a certain degree of thermal insulation compared to a hot cooktop plate, which is heated by a heated pot placed above it.

The spring means in turn should advantageously not rest directly against the housing bottom or rest, but may indirectly press against the housing bottom. Intermediate units of the induction hob can be provided, for example a flat plate or a flat component carrier. On this further functional units of the induction cooktop can be arranged, in particular a control for the induction heating coil. Further, an electrical connector may be provided to a connector attached to the carrier for the induction heating coil. This is known from the aforementioned EP 14198247.0 with filing date of 16 December 2015, to which express reference is made.

These and other features will become apparent from the claims and from the description and drawings, wherein the individual features in each case alone or more in the form of sub-combinations in an embodiment of the invention and in other fields be realized and advantageous and protectable Represent embodiments for which protection is claimed here. The subdivision of the application into individual sections and intermediate headings does not limit the statements made thereunder in their generality.

BRIEF DESCRIPTION OF THE DRAWINGS

Further advantages and aspects of the invention will become apparent from the claims and from the following description of preferred embodiments of the invention, which are explained below with reference to the figures. Showing:

1 3 is an oblique view from below of an induction heating device according to the invention with two induction heating coils on a support on which flat ferrites are arranged, some of which have recesses for springs,

2 an enlarged plan view of a portion of the carrier accordingly 1 without induction heating coil with springs in the recesses in the ferrites,

3 an oblique view of an enlarged ferrite from below in a circular sector shape with a circular recess,

4 the ferrite out 3 with inserted into the recess coil spring,

5 similar to a modification of a ferrite 3 with an elongated undercut slot as a recess,

6 the ferrite out 5 with inserted into the undercut slot coil spring,

7 a view from behind on the ferrite 6 with a view along the undercut recess and

8th a schematic section through an inventive induction hob with an induction heater according 1 ,

DETAILED DESCRIPTION OF THE EMBODIMENTS

In the 1 is an oblique view of an induction heater according to the invention 11 shown. This has an induction coil 12a and an induction coil 12b on, which have approximately approximately rectangular shape, as essentially from the aforementioned EP 14198247.0 evident. The induction coils 12 but could also have natural circular and other forms. The induction heater 11 has a carrier 14 Made of plastic, which is in the 2 can be seen in the plan view and a lattice with a Variety of individual fields and laminar openings through which the induction heating coils 12a and 12b can be seen has. Above all, the wearer points 14 also bags 15 as such fields, in which then, as will be explained in more detail below, ferrites 20a and 20b such as 20a ' and 20b ' can be introduced. On the edge of the pockets 15 can hold noses 16 be molded into the pockets 15 intervention. On the bottom, namely induction heating coils 12a and 12b Covering is a flat cover 17 intended. This should have electrical insulation properties and thermal insulation properties. Finally, the carrier points 14 another plug connection 18 on, from which connections to the induction coils 12a and 12b walk. However, this is basically easy to realize for the skilled person and plays no role for the invention.

The 2 in the plan view also shows the double mirror-symmetrical arrangement of the ferrites 20a and 20a ' at the bottom of the carrier 14 in appropriate pockets 15 , In recesses 22 in the ferrites are coil springs 29 arranged. This will be explained in more detail below. In addition, it is easy to see how the ferrites 15 by means of retaining lugs 16 in the pockets 15 are held, both the ferrites 20a in circular sector form as well as the rectangular ferrites 20a ' , In these rectangular ferrites 20a ' However, no spring means are provided.

In the 3 and 4 is a ferrite 20a shown in an enlarged perspective view. It is still the circle sector shape to recognize. Furthermore, along the longitudinal edges in each case two retaining recesses 21 provided as oblique depressions. These are from the appropriately trained retaining lugs 16 on the carrier 14 overrun, leaving a kind of latching and form-fitting attachment of the ferrite 20a on the carrier 14 and thus below the induction heating coils 12a and 12b given is.

In a middle area is at the bottom of the ferrite 20a a circular recess 23 intended. Their diameter can be at a total length of the ferrite 20a vary from about 10 cm between 2 cm and 3.5 cm. It has a flat recess floor 23 but that does not have to be that way. Such a ferrite becomes advantageous 20a produced in the desired shape in the production, particularly advantageous by pressing. In one of the basic forms of ferrite 20a corresponding shape that already exists, and in which also the retaining recesses 21 be formed, then only needs an additional punch for the production of the recess 22 to be provided. A depth of the recess 22 can be about half the thickness of the ferrite 20a be. It can generally be between 10% and 80% or even 90% of the thickness of the ferrite.

In the 4 is to be seen as a feather 29 into the recess 22 is used. The feather 29 is essentially designed as a helical spring, but also slightly spiral. That in the recess 22 located end of the spring 29 has a larger diameter than the free upstanding end. This allows the spring 29 generally have a more stable shape even when squeezed. Furthermore, it can be compressed very flat, so that their height is in extreme cases only one diameter of a wire winding, as it is when pressed together, so to speak, with their turns.

It is shown how it is possible to drill a kind 26 or a cutout on the side of the recess 22 provided. In this, a radially outwardly projecting section 30 the feather 29 protrude. So can a turn of the spring 29 in the recess 22 be avoided. A possible fixation can also by placing adhesive exactly in this hole 26 respectively.

Alternatively to a radially outward to the recess 22 outgoing hole 26 could also be a hole in the recess bottom 23 into it, in which case the protruding section 30 the feather 29 would not be radially outward, but just substantially perpendicular to the surface of the ferrite 20a or at right angles to the recess bottom 23 , Such an embodiment would have the same effect as previously described.

Here is the recess 22 introduced rectangular into the ferrite, so to speak. A circumferential wall of the recess 22 is perpendicular to the recess bottom 23 and perpendicular to the surrounding surface of the ferrite 20a , The feather 29 So you can easily into the recess 22 can be used, but could even with a rotation by means of the bore 26 be easily pulled out again.

In a variation of a ferrite 120a according to the 5 to 7 is provided that from the outside an elongated recess 122 is provided in the manner of a wide slot. This has an undercut 124 to the recess floor 123 on, especially the side view of the 7 shows. In such an elongated undercut recess 122 can be a suitably trained spring 129 be inserted from the outside into the slot thus formed until the spring 129 at the end of the recess 122 or at the desired location. Through the undercut 124 can the spring 129 actually hardly out of the recess 122 be pulled and thus sits permanently stable. Also this spring 129 is similar to the spring 29 from the 3 and 4 , designed as a kind of combined coil spring and coil spring. It is very advantageous if this spring 129 at the broad lower end a unique, substantially circular circulation is provided as a kind of ring, without a helical shape and without only a minimal spiral shape. This allows the spring 129 very good in the undercut recess 122 being held.

Similar to in 4 represented or closed 4 explains a hole on the recess 122 be provided, either perpendicular to the recess bottom 123 in or across or parallel to it. A corresponding bent projecting portion of the spring 129 could then intervene and a fixation of the spring 129 cause. Furthermore, it prevents the spring 129 push out again easily. Above all, a hole in the recess floor 123 in with direction perpendicular to the recess bottom 123 is considered suitable for this.

Based on 3 to 7 It is easy to imagine how other types of springs could be provided instead of a helical spring with a slightly helical shape substantially identical to those shown here, in particular completely different types. On the one hand, it could be springs in U-shape or so-called Z-springs, which have a spring direction transversely away from the surface of the ferrite. Alternatively, it could be voluminous spring body, for example in block form, but then have a much worse ratio between minimum height and maximum height. Furthermore, springs made of wire or metal wire in the form shown here can better tolerate the higher temperatures that can permanently result under an induction hob.

In the 8th is an induction hob according to the invention 33 to recognize in a kind of schematic sectional view. Under a hob plate 34 there is a housing 36 , or it is at a bottom 35 the hob plate 34 attached, for example glued or screwed to glued retaining rails. The housing 36 has a housing bottom 37 on which a component carrier 39 rests with extensive course. On this component carrier 39 again, the induction heater 11 placed or stored. By means of the plug connection 18 becomes an electrical contact between induction heater 11 and component carriers 39 made, as from the aforementioned EP 14198247.0 is known. It is via the plug connection 18 but no significant holding and / or pressure transmitted. The essential support of the induction heater 11 down against the component carrier 39 done via the springs 29 that are in the ferrites 20a sit or are secured in recesses therein. So press the ferrites 20a turn the carrier 14 upwards, where they are arranged. This will cause the on the wearer 14 overhead induction heating coil 12a pushed upwards and then lies with the intermediate cover 17 on the bottom 35 the hob plate 34 at. By the resilient or spring-loaded system of induction heating 11 on the bottom 35 the hob plate 34 is both a very small and a constant distance maintained. This is beneficial and of importance for heating one on the hob plate 34 above the induction heating coil 12a set up saucepan.

Not necessarily to scale 8th also shows why a small overall height of the spring means or of the metal wire coil springs 29 is important. So can a distance the bottom of the ferrites 20a to the component carrier 39 be very small, advantageously be a few millimeters, for example, only 2 mm to 4 mm. Nevertheless, a sufficiently elastic or resilient and strong pressing can take place.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 14198247 [0003, 0029, 0040, 0051]

Claims (18)

Induction heater ( 11 ), in particular for an induction hob ( 33 ), comprising: - an induction heating coil ( 12a , b), - a carrier ( 14 ) for the induction heating coil and - at least one ferrite ( 20a , b, 20'a , b, 120a ), wherein the at least one ferrite is arranged on the carrier on one side, in particular on a flat side, of the induction heating coil, - a spring means ( 29 . 129 ) on the induction heating device for spring-loaded pressing the induction heating device on a cover ( 34 ) above, characterized in that - the spring means ( 29 . 129 ) directly on a ferrite ( 20a , b, 120a ) are held, - for holding the spring means on the ferrite a recess ( 22 . 122 ) and / or a projection on the ferrite are provided. Induction heater according to claim 1, characterized in that the spring means ( 29 . 129 ) with a positive connection directly to the ferrite ( 20a , b, 120a ), wherein the positive connection is formed in a direction transverse to the spring direction or along the surface of the ferrite, against which the spring means bears against the ferrite. Induction heater according to claim 1 or 2, characterized in that the ferrite ( 20a , b, 20'a , b, 120a ) is substantially flat, in particular with a basic geometric shape such as approximated triangle or approximate quadrilateral, in particular trapezoid or rectangle. Induction heater according to one of the preceding claims, characterized in that the recess ( 22 . 122 ) and / or the projection for mounting on a underside of the ferrite ( 20a , b, 120a ) away from the induction heating coil ( 12 ) are provided pointing. Induction heater according to one of the preceding claims, characterized in that a projection for holding a distance of at least 50% of the minimum width of the projection of an edge of the ferrite. Induction heater according to one of claims 1 to 4, characterized in that a recess ( 22 ) for holding the spring means ( 29 ), wherein the recess is at a distance of at least the minimum thickness of the ferrite ( 20a , b) from an edge of the ferrite. Induction heater according to one of claims 1 to 4, characterized in that a recess ( 122 ) for holding the spring means ( 129 ) is provided and the recess up to an edge of the ferrite ( 120a ) or the recess is open towards an edge side of the ferrite. Induction heater according to one of the preceding claims, characterized in that a recess ( 22 . 122 ) for holding the spring means ( 29 . 129 ) in the ferrite ( 20a , b, 120a ) is provided, wherein the recess has a plane-parallel to both sides of the flat ferrite Ausnehmungsboden. Induction heater according to one of the preceding claims, characterized in that in the ferrite ( 20a ) a bore is provided, preferably as a blind bore ( 26 ), in particular in a recess ( 22 ) for holding the spring means ( 29 ), wherein preferably a protruding section ( 30 ) the spring means ( 29 ) is held in the bore to secure the spring means against displacement. Induction heater according to one of the preceding claims, characterized in that the spring means ( 29 . 129 ) are formed as a wire spring, in particular as a metal wire spring, preferably as a helical spring, wherein in particular a diameter of a helical spring between 10% and 50% of the maximum extent of the ferrite ( 20a , b, 20'a , b, 120a , b) amounts to. Induction heater according to one of the preceding claims, characterized in that the spring means ( 29 . 129 ) are formed as a helical spring with decreasing diameter, wherein preferably a wider end of the helical spring on the ferrite ( 20a , b, 20'a , b, 120a , b) is present. Induction heater according to one of claims 1 to 9, characterized in that the spring means are designed as a leaf spring, preferably with at least one kink or at least one bend. Induction heater according to one of claims 1 to 9, characterized in that the spring means are formed as a block-shaped spring body, preferably consisting of a bulky elastic plastic material. Induction heater according to one of the preceding claims, characterized in that the recess ( 122 ) and / or the projection has an undercut ( 124 ) of a portion of the spring means ( 129 ) is engaged behind the form-fitting attachment of the spring means to the ferrite ( 120a ) as a captive attachment during assembly of the induction heating device ( 11 ) by holding the spring means against a movement perpendicular to the surface of the ferrite. Induction heater according to claim 14, characterized in that an undercut recess ( 122 ), in particular up to a side edge of the ferrite ( 120a ), wherein the spring means ( 129 ) at least partially the undercut ( 124 ) are arranged engaging behind in the recess, in particular secured against lateral pushing out by a projection arranged on a recess bottom. Induction heater according to one of the preceding claims, characterized in that a height of the unloaded spring means ( 29 . 129 ) is twice to twenty times greater than the maximum thickness of the ferrite ( 20a , b, 120a ). Induction hob ( 33 ) with at least one induction heating device ( 11 ) according to one of the preceding claims, characterized in that under a cooktop plate ( 34 ) as a cover of the induction heating device ( 11 ) a housing bottom ( 37 ) is arranged on the cooking plate ( 34 ), wherein the induction heating device is pressed from below against the hob plate from the spring means ( 29 ), which protrude against the caseback ( 37 ). Induction hob according to claim 17, characterized in that the induction heating coil ( 12a ), optionally with a thermal barrier coating ( 17 ), directly to a bottom ( 35 ) of the hob plate ( 34 ) is pressed, wherein the spring means ( 29 ) indirectly against the housing bottom ( 37 ) are pressed, in particular via intermediate units ( 39 ) of the induction hob ( 11 ).

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