Method for assembling an induction heating device

Abstract

A method for assembling an induction heating device includes the steps of interposing at least one ferrite bar between a coil assembly and a support plate, and snap engaging a central polymeric fastening element on the support plate. At least one end of the ferrite bar is inserted in a radial seat of the central polymeric fastening element. The coil assembly is snap engaged with the central polymeric fastening element in order to sandwich the ferrite bars between the support plate and the coil assembly.

Claims

1. An induction heating device, comprising: a planar central element having a plurality of radial seats; at least one ferrite bar, wherein each of the radial seats is dimensioned to receive an end of the at least one ferrite bar with a predetermined degree of interference so that the at least one ferrite bar extends radially from and centered on the planar central element; a base disposed below the planar central element; and a coil assembly disposed above the planar central element, opposite the base; wherein the at least one ferrite bar is radially retained by the respective radial seat of the planar central element, and wherein the at least one ferrite bar is vertically retained between the coil assembly and the base.

2. The induction heating device of claim 1, wherein the at least one ferrite bar is radially retained by the predetermined degree of interference of the respective radial seat.

3. The induction heating device of claim 1, wherein the at least one ferrite bar is radially retained by an interference fit at the respective radial seat.

4. The induction heating device of claim 3, wherein the interference fit is defined by the predetermined degree of interference of the respective radial seat.

5. The induction heating device of claim 1 wherein the at least one ferrite bar is sandwiched between the coil assembly and the base.

6. The induction heating device of claim 1, wherein the planar central element presents a flat central portion having a polygonal shape and thickness corresponding to thickness of the at least one ferrite bar.

7. The induction heating device of claim 1, wherein the planar central element is snap-engageable with the base.

8. The induction heating device of claim 7, wherein the planar central element is snap-engageable with the coil assembly.

9. The induction heating device of claim 1, wherein the radial retaining by the respective radial seat and the vertical retaining between the coil assembly and the base stabilize the at least one ferrite bar during operation of the induction heating device, acting in opposition to forces acting on the at least one ferrite bar during induction heating device operation.

10. The induction heating device of claim 1 wherein the base and the coil assembly are attached to the planar central element without glue.

11. An induction cooktop, comprising: a plurality of ferrite bars; a central element having a plurality of radial seats dimensioned to receive and locate ends of the plurality of ferrite bars with a predetermined degree of interference so that the plurality of ferrite bars extend radially from and centered on the central element, the predetermined degree of interference radially retaining the plurality of ferrite bars; a glass support plate positioned below the central element and engaged with the central element; a coil assembly positioned above the central element and engaged with the central element; wherein the plurality of ferrite bars are vertically sandwiched between the coil assembly and the glass support plate.

12. The induction cooktop of claim 11, wherein the plurality of ferrite bars radially retained by an interference fit at the radial seat.

13. The induction cooktop of claim 12, wherein the interference fit is defined by the predetermined degree of interference of the respective radial seat.

14. The induction cooktop of claim 11 wherein the plurality of ferrite bars is vertically retained between the coil assembly and the glass support plate.

15. The induction cooktop of claim 11, wherein the central element presents a flat central portion having a polygonal shape and thickness corresponding to thickness of the plurality of ferrite bars.

16. The induction cooktop of claim 11, wherein the central element is snap-engageable with the glass support plate.

17. The induction cooktop of claim 16, wherein the central element is snap-engageable with the coil assembly.

18. The induction cooktop of claim 11, wherein the radial retaining by the respective radial seat and the vertical retaining between the coil assembly and the glass support plate stabilize the plurality of ferrite bars during operation of the induction cooktop, acting in opposition to forces acting on the plurality of ferrite bars during induction cooktop operation.

19. The induction cooktop of claim 11 wherein the glass support plate and the coil assembly are engaged with the central element without glue.

20. The induction cooktop of claim 11, wherein a thermal insulation layer is interposed between the coil assembly and the glass support plate.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further advantages and features according to the present invention will be clear from the following detailed description, provided as a not limiting example, with reference to the attached drawings, in which:

(2) FIG. 1 is a perspective view of a key component of the induction heating device according to the invention;

(3) FIG. 2 is an exploded view, partially cross sectioned, of an induction heating device according to the invention, which includes component of FIG. 1;

(4) FIG. 3 is a perspective view from the bottom of the induction heating device of FIG. 2, in an assembled configuration;

(5) FIG. 4 is an enlarged perspective view of a central portion of the device of FIG. 2, in an assembled configuration,

(6) FIG. 5 is a schematic top view of how the key component of FIG. 1 is used for fitting the ferrite bars; and

(7) FIGS. 6 and 7 are schematic views similar to FIG. 5 showing different solutions for different layouts for ferrite bars position according to different coil sizes.

DETAILED DESCRIPTION

(8) With reference to the drawings, the induction heating device comprises a central component K composed of a co-injection of two different materials. With reference to FIG. 1, the component K comprises a plastic body 2 of thermoplastic material, on which is co-injected a central part of rubber, the sensor holder 1. The plastic body 2 is made of thermoplastic or thermosetting polymer having a high Young's modulus.

(9) The shape of the component K recalls that of a snowflake, since it comprises a central portion 10 shaped as a regular polygon, for instance an hexagon (where the rubber or similar elastomeric material is centrally co-injected), on whose apexes 10a are integrally formed other regular auxiliary polygons 12, in the shown example triangles.

(10) Such shape is due to the main technical purpose of the component K, i.e. to constrain the ends of ferrite bars 4 in the position required to channel or concentrate the electromagnetic field. Between each side 10b of the hexagon defining the central portion 10 of the component K and two facing sides 12a of two adjacent auxiliary triangles 12 it is defined a quadrangular seat 14 (open on top and bottom) for an end 4a of a ferrite bar 4. In the example shown in FIGS. 1, 2 and 4, the central component K defines six seats 14 for the ferrite bars, but of course it can be formed with a different number of seats (as shown in FIGS. 6 and 7). The thickness of the portion 10 corresponds to the thickness of the ferrite bars 4, so that all such components can be sandwiched between other components of the induction heater (as it will be clear from the following description) in a very precise way in terms of final thickness. Moreover, the dimension of the seats 14 (which allows the assembly of the ferrite bars 4 with a predetermined degree of interference), together with the stiffness of the thermoplastic or thermosetting material allows a very stable position of the ferrite bars 4, despite the forces acting on them during normal operation.

(11) The sensor holder 1 is a co-injection of rubber, with a total height slightly higher than the thickness of the central portion 10, because the holder 1 needs to generate a spring effect to keep a sensor 8 (FIGS. 2 and 4) pressed on the bottom face of the glass (not shown) of the induction cooktop.

(12) The central portion 10 of the component K is also provided with a plurality of elastic hooks 16 and 18 which are oriented parallel to the central symmetry axis of the component K. A first crown of upper hooks 16 can be seen in FIGS. 1 and 2, while a second crown of lower hooks 18 can be seen in FIG. 3.

(13) FIG. 2 shows the entire induction heater assembly with the central component K. A copper coil 6 is stuck on a mica layer 5 with glue and they form a single component. The coil is assembled in the following sequence: the central component K is connected to an aluminum base or plate 3 through the lower crown of hooks 18 with a light pressure in order to allow a snap-engaging action of the hooks 18 on a circular edge 22a of a central hole 22 of the base 3 (FIG. 3). The central hole 22 with its edge 22a can be replaced by small slots (not shown) which can be snap-engaged by the lower crowns of hooks 18 for reaching the same technical result. The dimension of the elastic hooks 18 is selected in order to fix in a stable way the component K on the aluminum base 3 without the use of any glue. At this point of the assembly process, the ferrite bars 4 are collocated with interference in the defined seats 14, obtaining a configuration (shown in FIG. 5) in which the ferrite bars 4 are radially centered on the component K as rays of a star. Then the mica layer 5 and the copper coil 6 assembly is positioned on the central component K and with a little pressure (similarly to what already done for the base 3), connected with the upper hooks 16 so that they snap-engage with a circular edge 24a of a central hole 24 of the coil assembly, visible in FIG. 4. The component K is interposed and in contact with the aluminum base 3 and with the coil assembly, particularly with the mica layer 5 thereof.

(14) A thermal insulation layer 7, for instance of rock wool, is then placed on the copper coil 6 and a temperature sensor 8, for instance a NTC sensor, is joined to the central component K through its insertion in corresponding joints 26 (FIG. 4) on the sensor holder 1 of the central component K, so that a mechanical constraint of the rock wool 7 is obtained. The rock wool layer 7 is preferably provided with a central hole 7a so that the sensor 8 is interposed between the sensor holder 1 and the ceramic glass of the induction cooktop.

(15) The embodiment shown in FIG. 6 differs from the above in the different number of ferrite bars (eight instead of six) in order to match a different size of the coil and in the different shape of the central component K′ (octagonal and not hexagonal). Moreover the ferrite bars 4 and 40 have two different dimensions, with the longer bars 4 closer to the sensor holder 1.

(16) In the embodiment shown in FIG. 7 (for a coil having a large size) the central component K″ has an overall pentagon shape and it is adapted to house ten ferrite bars 4 and 42, also in this case of different length.

(17) The solution according to the invention, independently on which embodiment is used, has many benefits in terms of cost reduction and improved assembly procedure.

(18) First of all, it is possible to get rid of the glue required, in the known solution, to position the ferrite bars on the aluminum base. Accordingly, there is also a decrease of the assembly time of the induction heating device and of the ferrite bars, by replacing the glue with snap-engaging fastener as hooks integral with a central simple component. There is a more accurate positioning of the ferrite bars, with a reduction in position variability caused by the unreliable quantity (and thickness) of the glue, and therefore a better control of the electromagnetic field in the working conditions of the induction heating device. It is also possible to avoid the use of glue required to position the mica layer on the ferrite, with a decrease of connection time of the mica layer by replacing the glue with snap-engaging fasteners.

(19) Last but not least it is possible to easily integrate the temperature sensor holder with a decrease of the number of components, increasing the stability of the sensor holder because it is no longer connected with fasteners, but it is part of a single body.