The present invention relates to (electrical) transformers.
Transformers are used in several areas e.g. in power supply units for halogen lamps, wherein an input line voltage (e.g. the typical 220-240 volt mains voltage of most European countries, while 100-120 volts are typical values for American countries) is transformed into an output voltage of 6, 12 or 24 volts, which must be isolated from the mains according to specific safety standards for this sort of device.
Transformers having symmetric three-chamber winding structures offer a number of distinct advantages over transformers having conventional two-chamber windings.
These advantages include, e.g., a significant reduction of proximity losses within the windings, a flux equilibrium within the core (which nulls the magnetic field in the outer leg(s) of the core and thus reduces the core losses), a higher quality factor of the leakage inductance (up to 70) due to the symmetrical field distribution which enables such a transformer to be used also as real resonance inductor for soft-switching circuits, and finally a reduced electromagnetic noise emission.
Thus, when using three windings i.e. three coils, the same power can be transferred by using a core of smaller size.
European Patent Application No. 05425091.5, which forms part of the prior art under the provisions of Art. 54.3 EPC, discloses a transformer including a plurality of windings wound on an insulating bobbin, which in turn includes a plurality of coil formers each having at least one respective winding wound thereon. Each coil former includes two separating end walls providing insulation of the respective winding, and at least one of the end walls of the coil formers has a protruding portion extending in correspondence with a neighbouring coil former. The protruding portion in question may include a wall extension at least partly covering the respective winding provided in the neighbouring coil former, and/or a pin stand.
Such a prior art transformer, having a three-winding configuration is thus formed by three separated “discs”, which together form the coil former, plus a cap.
Manufacturing such a transformer structure thus requires:
Despite the inherent advantages related to the prior art arrangement referred to in the foregoing, the applicant have determined that room still exists for further improvement primarily related to:
The object of the present invention is to provide such an improvement. According to the present invention, that object is achieved by means of a transformer having the features set forth in the claims that follow. The claims are an integral part of the disclosure of the invention as provided herein.
A preferred embodiment of the arrangement described herein is thus a multi-chamber transformer including:
Such a preferred embodiment of the arrangement described herein leads to an optimization in the construction of e.g. a “three chamber” transformer of the type considered in the foregoing, wherein the primary winding is wound in the central part of the coil former while the secondary winding is comprised of two windings arranged laterally of the primary winding. The two secondary, lateral windings are connected in series or in parallel depending on the requirements of the circuit.
In such a preferred embodiment the transformer is essentially comprised of two basic elements, namely a coil former with three winding chambers for the primary winding and the two secondary windings, respectively, plus a protective cap.
The invention will now be described, by way of example only, by referring to the enclosed figures of drawing, wherein:
The exemplary embodiment of a transformer described herein has the basic feature of including a single coil former generally indicated as 100. The designation “coil former” is primarily intended to highlight the role this element plays in providing winding chambers for respective windings (“coils”) of the transformer.
Throughout the annexed figures of drawing, the coil former 100 is shown without expressly illustrating the windings wound thereon. The outer contours of these windings are however shown in phantom lines in
These include a primary winding P wound on the central part of the coil former 100, and a pair of secondary windings comprised of two windings S1 and S2 wound on the coil former 100 laterally of the primary winding P.
The two secondary, lateral windings S1 and S2 are connected in series or in parallel depending on the requirements of the circuit. While a transformer including three windings is described herein by way of example, those of skill in the art will promptly appreciate that the arrangement described herein may be extended to include also e.g. two or four windings or more, that is any plural number of windings.
The coil former 100 is essentially comprised of a tubular body 102, typically of a rectangular cross section, of an electrically insulating material of any type currently used to produce bobbins for transformers and having a thickness complying with safety insulation standards. Plastic moulded materials (such as e.g. Polyamide, Polycarbonate, or Polybutylene-Terephtalate) with a resistivity of at least 3*109 Ohm*cm are exemplary of such a material. The windings P, S1, and S2 are comprised of electrically conductive wire such as e.g. copper wire either or the single wire type or of the braided (i.e. Litz wire) type.
In the final transformer assembly the windings P, S1, and S2 wound on the core former 100 are arranged side-by-side on a common core. This is typically comprised of one of the legs (usually the main, central leg) of a ferromagnetic (e.g. ferrite) core C.
The individual windings are confined axially by insulating flanges 104, 106 constituting integral parts of the coil former.
Specifically the insulating flanges in question include:
The two inner insulating flanges 106 thus separate (i.e. create the required creepage distances and thickness) the primary winding with respect to the secondary windings S1 and S2. As better detailed in the following, the two inner insulating flanges 106 are provided with a groove 106a to give rise to a labyrinth coupling with mating flanges provided in the cap 200 described below.
The coil former 100 is intended to be coupled with a cover cap designated 200 as a whole. The protective cap 200 comprises an insulating material and is coupled with the coil former 100 in order to at least partially cover the windings P, S1, and S2. The cover cap 200 includes a top wall 202 that, in the exemplary embodiment shown, is a partial (i.e. apertured) top wall. The cap 200 also includes lateral walls (see the walls 204, 206 of
After the final assembly of the transformer, the various elements described form sufficient wall thickness, creepage and clearance distances to ensure proper insulation of the windings P, S1, and S2.
Specifically, the tubular core 102 of the coil former 100 (essentially in the form of a hollow spindle) will provide the insulation between the individual coils of the windings P, S1, and S2 and the core ferromagnetic core C.
The inner insulating flanges 106, together with homologous matching flanges (not shown) protruding from the inner surface of the cap 200 and adapted to engage the grooves 106a to form a labyrinth arrangement therebetween, will ensure lateral insulation between the primary winding P and the lateral windings S1 and S2.
The outer insulating flanges 104, plus the lateral walls (e.g. 206) and the top wall 202 of the cap 200 will generally provide insulation of the windings P, S1, and S2 to the surrounding space. This is essentially achieved by having the sum of their thicknesses reach a value greater or equal to the value required from the insulation standard
In order to minimize the overall dimensions of the transformer, and especially the “height” thereof, the lower side of the coils/windings P, S1, and S2 near the common circuit supporting substrate (PCB)—in other words the bench side of the coils—stands significantly closer to the circuit substrate than e.g. half the maximum required creepage without protruding completely to and through the circuit support.
This is thanks to the provision of lower flange walls in the cap 200 such as the insulating extensions 208 and 210 shown in
When the coil former 100 and the cap 200 are assembled (see e.g.
In these conditions, the insulating extensions 208, that are located on one side of the cap 200, penetrate in between the pairs of inner and outer insulating flanges 106, 104 arranged at each side of the primary winding P. The insulating extensions 208 thus form, in the space below the skirt wall 212, two bridge-like barriers that insulate to the outside the winding spaces where the secondary windings S1 and S2 are arranged.
The insulating extensions 210, which are located on the other side of the cap 200, penetrate into the grooves 106a provided in the inner insulating flanges 106. The extensions 210 thus form in the space below the skirt wall 212 two extensions of the flanges 106 that insulate the winding space of the primary winding P with respect to the winding spaces where the secondary windings S1 and S2 are arranged.
The extensions 208 and 210 extend essentially in the direction of the “bench” or PCB where the transformer is mounted to provide the sufficient creepage and clearance distances between the neighbouring winding chambers for the windings P, S1, and S2.
The protective cap 200 has thus two extensions 210 cooperating with the two insulating flanges 106 to provide insulation between the first winding P and the two seconds windings S1, S2, wherein the two extensions 210 are placed opposite with respect to the insulating wall 208. The insulating wall 208 extends from the skirt wall 212 away from the windings P, S1, and S2.
A basic advantage of the arrangement illustrated in the drawing lies in that the three windings or coils P, S1, and S2 can be wound on the one-piece coil former 100, thus producing three windings that are already assembled.
In order to permit proper wiring of the transformer the ends or terminals of the wires comprising the three windings P, S1, and S2 must be preferably accessible at the lateral sides of the coil-former 100. Similarly, these terminals cannot be arranged in correspondence with the two inner flanges 106: the space to be provided for clamping the wires would in fact be obtrusive to the wire winding process over (i.e. around) the coil former 100.
For that reason, in the arrangement described herein the two ends, designated P1 and P2 (see
However, the paths of extension the two ends, P1 and P2 of the central primary winding P are selected in order that, once the cap 200 is coupled to the coil former 100, these paths will lie on the opposite (outer) sides of the insulating, bridge-like extensions 208 with respect to the secondary windings S1 and S2.
In that way the distance through insulation between the primary winding P and the secondary windings S1 and S2 will be easily reduced down to the value, which is required by the standard SELV norms.
When the cap 200 is coupled to the coil former 100 the path toward the bottom side, schematically indicated by the arrow PF in
The arrangement just described ensures—over the whole transformer structure—the desired insulation (e.g. in compliance with SELV requirements) between the primary and secondary sides.
Consequently, without prejudice to the underlying principles of the invention, the details and embodiments may vary, even significantly, with respect to what has been described and shown, by way of example only, without departing from the scope of the invention, as defined by the annexed claims. Exemplary of such possible variants are i.a.:
Number | Date | Country | Kind |
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05425867 | Dec 2005 | EP | regional |
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PCT/EP2006/068981 | 11/28/2006 | WO | 00 | 6/4/2008 |
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WO2007/065811 | 6/14/2007 | WO | A |
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