The present invention relates to an induction cooking hob with illumination equipment according to the preamble of claim 1.
On the induction cooking hob the heating elements, i.e. the inductions coils, are arranged within a chassis and below a panel of said induction cooking hob. The heating elements and the corresponding heating zones are not visible by the user. Thus, the user cannot see the positions and sizes of the heating zones. Further, since the inductions coils do not radiate any heat, the user cannot determine if the heating elements are activated or not.
In known induction cooking hobs with illumination equipment the light sources are installed in a very complex way. For example, light sources with reflectors are used below the panel of the induction cooking hob. In other solutions, illuminating rings made out of light guiding material or multiple single light emitting diodes enclose the heating zones.
It is an object of the present invention to provide an induction cooking hob with illumination equipment, which has low complexity and low cost of materials.
The object of the present invention is achieved by the induction cooking hob according to claim 1.
According to the present invention the intermediate layer between the induction coils and the stove top material comprises a plurality of cut-outs arranged according to a predetermined pattern within the heating zone, and the chassis comprises at least one light emitting diode arranged in a central portion of the induction coil, wherein the light emitting diode corresponds with at least one cut-out.
The main idea of the present invention is the arranging of the light emitting diode (LED) in the centre of the induction coil and the one or more corresponding cut-outs. This constellation allows an illumination of the heating zone on the induction cooking hob from below. The inventive induction cooking hob has a low complexity, since only the light emitting diode and a corresponding transmitting portion are required.
According to a preferred embodiment of the present invention the intermediate layer represents a printed layer applied at the lower side of the panel. The printed layer may be realized by low cost of materials.
Preferably, the printed layer is a dark coloured layer, in particular a black coloured layer. In this case, the cut-outs may be formed as blank portions of the printed layer. The dark or black coloured layer and the blank portions increase the contrast between the cut-outs and the remaining area of the panel. It should be noted, that this layer described in this context as printed, might be applied in any other feasible way.
Alternatively or additionally, the intermediate layer comprises or includes a sheet arranged between the panel and the chassis. In this case the positions of the cut-outs are independent of the panel. The panel can be designed independent of the sizes and positions of the heating zones.
In particular, the sheet is made of at least one dielectric material.
According to a preferred embodiment of the present invention the sheet is or comprises a mica layer. The mica layer is a sheet made of dielectric material.
Preferably, the cut-outs in the mica layer may be filled by a transparent dielectric material. For example, the cut-outs in the mica layer are filled by a foil or layer made of polyimide.
Further, the light emitting diode is fastened by a support element having low heat conductivity. Advantageously already present support elements are used, for example the support element of a temperature sensor. The support element may be used as an optical device and guide the light emitted by the LED more efficiently to the panel.
In particular, the cut-outs are shaped as slots, wherein said slots are arranged according to a predetermined pattern. For example the slots form a symbol.
Preferably, the panel is a glass ceramic panel.
Novel and inventive features of the present invention are set forth in the appended claims.
The present invention will be described in further detail with reference to the drawings, in which
The chassis 12 comprises four induction coils 16 arranged as a two-by-two matrix. The induction coils 16 are formed as circular disks. In the centre of each induction coil 16 there is a circular hole. The induction coils 16 have different sizes.
The chassis 12 comprises further electronic circuits 28 for generating high frequency currents for the induction coils 16. The electronic circuits 28 are arranged below the induction coils 16.
In the circular hole in the centre of each induction coil 16 there is a light emitting diode 24. The light emitting diode 24 is fastened at the chassis 12 by a support element 26. The support element 26 has such a geometric structure, that only a little heat is transferred to the light emitting diode 24. Further, the support element 26 is made of a material with low heat conductivity. These properties of the support element 26 prevent a destruction of the light emitting diode 24.
In this example, only one light emitting diode 24 is arranged within the circular hole in the centre of each induction coil 16. In general, one or more light emitting diodes 24 may be arranged within the circular hole in the centre of the induction coil 16. Further, light emitting diodes 24 with different colours may be provided. Moreover, one or more RGB light emitting diodes 24 may be arranged within the circular hole.
In this example, the sheet 20 is a mica layer. In general, the sheet 20 is made of a dielectric material. The cut-outs 22 in the mica layer 20 are filled by a transparent dielectric material. In particular the cut-outs 22 in the mica layer 20 are filled by a foil made of polyimide. For example, the cut-outs 22 in the mica layer 20 are filled by KaptonĀ®.
The sheet 20 comprises a plurality of cut-outs 22. In this example, the cut-outs 22 are formed as slots. There are four groups of eight cut-outs 22 in each case. The eight cut-outs 22 of each group form a star-shaped arrangement. Each group of cut-outs 22 corresponds with one of the heating zones 14.
Additionally, the panel 10 is arranged on the chassis 12 in
Further, the size of the cut-out 22 may indicate the size and/or the power of the corresponding heating zone 14 and inductions coil 16. This can be realized by a relative long cut-out 22 representing a big heating zone 14. In a similar way, a relative short cut-out 22 may represent a small heating zone 14.
Additionally, one or more ferrite elements may be arranged below the induction coils 16. For example, said ferrite elements have elongated forms and extend radially with respect to the induction coils 16.
Further, an outer light guide element may be arranged outside the induction coil 16 in order to indicate the size of said induction coil 16 and/or for design reasons. In this case, at least one connecting light guide element may be arranged between the light emitting diode 24 and said outer light guide. In a special case the outer light guide element has a circular form and encloses the induction coil 16. The at least one connecting light guide element may be arranged between the ferrite elements, for example.
The panel 10 is arranged above the chassis 12 and covers said chassis 12. At the lower side of the panel 10 a printed layer 18 is applied. The induction cooking hob of the third embodiment comprises no sheet 20, but the printed layer 18 at the lower side of the panel 10 has the same function as said sheet 20.
The printed layer 18 in the third embodiment has a similar pattern as the sheets 20 in the first and second embodiments. The printed layer 18 is obtained by applying a dark colour, preferably a black colour, at the lower side of the panel 10. The cut-outs 22 are realized by blank portions in the printed layer 18.
The chassis 12 comprises induction coils 16. One of the induction coils 16 is shown in
In the centre of the induction coil 16 there is a circular hole with the light emitting diode 24. The light emitting diode 24 is fastened at the chassis 12 by the support element 26. The support element 26 is formed in such a way, that only a little heat is transferred to the light emitting diode 24. The support element 26 is made of a material with low heat conductivity. These properties of the support element 26 prevent a destruction of the light emitting diode 24.
In particular, the support element 26 is an elongated and thin element extending horizontally within or below the circular hole of the induction coil 16. The support element 26 may be fastened below the circular hole of the induction coil 16 or below the induction coil 16 itself. The elongated support element 26 can be fastened either at its both ends or at one of its ends. In said first case the light emitting diode 24 may be attached at a central portion of the elongated support element 26. In said latter case the light emitting diode 24 may be attached at the other end of the elongated support element 26.
The light emitting diode 24 is cooled by an air stream. Said air stream may be a natural air stream and/or an air stream generated by at least one fan. Usually, the natural air stream and/or the fan are present in the cooking hob. When the light emitting diode 24 is not in a direct contact with the air stream, then the support element 26 is preferably made of metal, so that the thermal conductivity of the metal support element 26 can be used.
In the above examples the light source in the centre of the induction coil 16 is the light emitting diode 24. In general, also other light sources than light emitting diode 24 are suitable.
The present invention allows that the user can recognize the heating zones 14 by the light from the light emitting diode 24. The cost of materials is relative low. The induction cooking hob according to the present invention has a low complexity.
10 panel
12 chassis
14 heating zone
16 induction coil
18 printed layer
20 sheet
22 cut-out
24 light emitting diode
26 support element
28 electronic circuit
Number | Date | Country | Kind |
---|---|---|---|
10007089.5 | Jul 2010 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP11/03407 | 7/8/2011 | WO | 00 | 10/18/2012 |