"A transformer and a related method of assembly"
Field of the invention
The present invention relates to (electrical) transformers.
Description of the related art
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 many American countries) is transformed into an output voltage of 6, 12 or 24 volts. Transformers are also frequently used as output isolating transformers in electronic converters for halogen lamps to produce a 12 volt output voltage.
So-called "toroidal" transformers are frequently used for the applications mentioned in the foregoing. In these prior art transformers, the walls of the bobbin must have a thickness of about 1mm for working voltages of up to 250 volts to fulfil the requirement SELV (Safety Extra Low Voltage) as stated in EN 61347 (General and Safety requirements).
Thick copper wires are also currently used for the secondary windings. These wires exhibit a sufficient rigidity to permit automatic placement during assembly of the transformers. The ends of the primary winding are conversely soldered to associated pins. This is particularly the case for electronic transformers for halogen lamps. These are in fact step-down transformers, i.e. transformers where the voltage at the secondary winding is lower than the voltage at the primary winding, thus leading to a higher current at the secondary winding with respect to the current at the primary winding. This leads to thinner wires at the primary that must be soldered to the pins in order to have a sufficient degree of rigidity. A bobbin having quite a simple structure is typically selected, with the main purposes of permitting fixing the pins and the secondary wires and supporting the magnetic part of the transformer. In some cases this inevitably involves the need of using a triple insulated wire for the secondary winding with the additional provision of a layer of insulating tape. In order to meet the requirements of standards such as EN 61347 regarding SELV, since the secondary winding is external, all components related to
the primary must be placed at 3mm from the secondary winding if they are not isolated, very close to it if they are basic isolated. In the remainder of cases, all components related to the primary side must be placed at a distance of at least 3mm from the winding, if they have a basic insulation and at least 6mm if such an insulation is not provided.
Additionally, these transformers are critical from the point of view of electromagnetic compatibility (EMC) and require complicated thermal protection, all these being factors that militate against the cost-effectiveness of the final solution.
Additional critical factors that need to be taken into account are related to: mounting the transformer on a very small substrate (such as narrow printed circuit board or PCB), placing the transformer very close to other components arranged on the same board, such as e.g. components referred to the primary side of the transformer, provided with or without a basic insulation and placed at a distance of less than 1 mm, as well as letting the conductive copper tracks connected to the secondary winding run on the so-called component side of the board, namely the side of the board onto which the components are mounted, - reducing the height of the final product, and permitting a fully automated assembly of the transformer.
For instance, typical requirements to be met in present-day applications are a maximum height of the transformer from the substrate less than 14.5mm, a power handling capacity of 75 Watts in nominal working conditions (European mains voltages) and the ability of fixing the ends of the wires of the windings in order to avoid problems likely to arise during the assembly phase of the transformer in production.
Object and summary of the invention
While a good deal of these problems and needs are already tackled by the transformer disclosed in EP-B-O 793 243, after which the preamble of claim 1 was patterned, the need is still felt for further improved arrangements.
The object of the present invention is thus to provide a transformer adapted to fully satisfactorily meet the requirements set forth in the foregoing.
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 invention also relates to a corresponding method of assembly. The claims form an integral part of the disclosure of the invention provided herein.
A particularly preferred embodiment of the invention uses an EFD (or EFF) core in the place of a ferrite core. An EFD core is a sort of E core, which is however "flatter" than an E core, the effective area being equal. In that way a power of the order of 75 Watts can be delivered in nominal European halotronic working conditions with the maximum height from the substrate of less than 14.5mm.
A particularly preferred embodiment of the invention provides for the presence of a bobbin around this kind of core that permits the whole transformer component to be in compliance with SELV (Safety Extra Low Voltage) insulation requirements.
The components referred to the primary side can be placed very close to transformer and the secondary tracks can run on the component side of the board since the secondary winding is reinforced insulated (following EN 61347) from the core, this being the more external conductive part of the component.
Preferably, the transformer of the invention includes two winding chambers that are separated and placed close to each other. Still preferably, the structure is an asymmetric one, namely insulation is provided at one chamber (usually the secondary winding chamber), in the form of reinforced insulation, contrary to the arrangement of EP-B-0793 243, where double insulation is used. Insulation is preferably provided also outside the core (e.g. via extensions of a cover cap associated with the bobbin), and not just within.
A transformer as described herein can be automatically mounted (i.e. located on a substrate such as a PCB) even the secondary wire is a Litz wire, which is rather flexible. The end terminals of the secondary windings are preferably soldered together with the pins, thus giving rise to thick pins that are stable and can be fixed as a normal pin. The operation of soldering the winding wire to the pins is facilitated by the preferred provision of apertures in the form of e.g. notches (dead-holes) in the
- A - transformers casing. These notches retain the wire securely in place in possible cooperation with beak formations provided in the casing itself.
Preferable the bobbin exhibit additional affixing pins for fastening the bobbin to the printed circuit board. These additional pins are necessary when the electrical connection pins with the soldered-on ends of the secondary winding are getting too thick for the additional fixing of the bobbin to the printed circuit board.
Brief description of the annexed drawings
The invention will now be described, by way of example only, by referring to the enclosed figures of drawing, wherein: figure 1 is general perspective view of a transformer of the type described herein, figure 2 is a lateral perspective view of a transformer as described herein with one of the elements included in the transformer removed for clarity of illustration, figure 3 is a front perspective view of the transformer shown in figure 2, with again the same element shown removed for the sake of clarity, and figure 4 is a bottom perspective view of the bobbin of the transformer described herein.
Detailed description of an exemplary embodiment of the invention
In the drawings, reference 1 designates as a whole a transformer adapted for use, e.g. in connection with the halogen lamps. Such a transformer is usually intended to operate in a frequency range higher than the mains frequency and includes the basic following elements: a bobbin, typically comprised of a moulded insulating material such as e.g. polyethylene, and including primary and secondary winding bodies defining respective primary and secondary winding chambers 21 and 22, primary and secondary windings 31 and 32 wound around the primary and secondary winding bodies in the primary and secondary winding chambers 21 and 22, respectively; and a ferromagnetic core arranged over the bobbin 2 in such a way to cooperate with the primary and secondary windings 31 and 32 to create the mutual impedance arrangement underlying operation of the transformer.
The two winding chambers 21 and 22 are thus separated and placed close to each other, i.e. side-by-side.
Throughout figures 1 to 3, the windings 31 , and 32 as well as the core 4 are schematically shown in dashed/chain lines only in order to facilitate clearer representation and understanding of the features of the bobbin 2. In figure 4 only the bobbin 2 is shown.
The transformer 1 described herein is particularly adapted to operate with cores of the EFD type (sometimes referred to also as EFF cores by some manufacturers in the Far East).
A particularly preferred embodiment of the arrangement described herein provides for the core 4 to be ferrite core of the EFD 25 type. This core type slightly differs from standard E-type cores due to having a lowered profile while maintaining the same effective area (Ae). Resorting to such a core is advantageous in that it leads to a transformer 1 having a lower thickness (height) overall while maintaining a good power handling capacity.
The arrangement described herein adopts such a core type while ensuring full compliance with insulation requirements as dictated by standards such as EN 61347 concerning the so-called SELV (Safety Extra Low Voltage) insulation requirement.
Essentially, the arrangement described herein provides such a level of insulation by providing reinforced insulation of the secondary winding 32 with respect to the primary winding 31 and the ferrite core 4. In that way, any electronic components related to the primary winding 31 can be mounted very close to the ferrite core 4
(this fact can be best appreciated in figure 2). As used herein, "very close" means distances lower than 1 mm or even just the distance enough to avoid that such components may come in direct contact with each other (that is "touch" each other).
By way of direct comparison, it will be appreciated that the arrangement described herein differs from the arrangement disclosed in EP-B-O 793 243 i.a. in that such prior art arrangement involves a double insulation between the primary and secondary windings. This is provided by basic insulation between the ferrite core and the primary winding plus supplementary insulation between the ferrite core and the secondary winding.
In the arrangement described herein, the reinforced level of insulation (SELV) is achieved with an insulation thickness of at least 1mm between the primary winding 31 and the secondary winding 32 and between the secondary winding 32 and the ferrite core. Additionally, an air "creepage" and a given clearance are provided between the primary winding 31 and the secondary winding 32, on the one side, and between the secondary winding 32 and the ferrite core 4, on the other hand.
A value for such clearance is at least 6mm, while increased values of 6.4mm may be taken into account when complying with the American norm UL 1310 (Standard for Safety for Class 2 Power Units). This norm is claimed by the American Subject UL 879A in order to cover LED (light emitting diodes) kits for field installations, where the transformer 1 can be used.
Specifically, a protective cover cap of an electrically insulating material 52 is provided and adapted to be associated with the secondary winding chamber. The cap 52 is typically comprised of the same electrically insulating material that comprises the other parts of the bobbin. The cap 52 will thus be considered in all respects as a part of the bobbin 2 of the transformer.
The thickness for all the walls surrounding the secondary chamber wherein the secondary winding 32 is wound is thus selected as having a minimum thickness of no less than 1mm, while 1.5mm is a preferred thickness for the lateral walls of the chambers due to a presence of labyrinths as better described in the following. In the exemplary embodiment shown herein, the cover cap 52 has approximately an "omega" or "mesa" shape overall (this can best appreciated in the front view of figure 3) and the lateral walls of the secondary winding chamber are thus defined by the lateral walls 520 of the cap 52.
The thickness of the walls between the primary and secondary windings 31 , 32 which walls are designated 320 in figure 2 is typically 0.5mm.
In order to ensure the desired creepage of 6-6.4mm a labyrinth is created at both ends of the secondary winding 32 by creating interpenetrating walls portions of those parts of the bobbin structure situated at the ends of the secondary winding chamber and complementary wall formations provided in the cap 52.
Specifically, a first set of interpenetrating walls is created by causing the wall 320 between the primary and secondary windings 31 , and 32 to be provided with a groove 321 adapted to interpenetratingly cooperate with a protruding wall 521 provided at the inner (i.e. proximal) side of the cap 52. The presence of the wall 521 and its interpenetrating relationship with the groove 321 provided in the wall 320 are best appreciated in the plan view of figure 4.
A thoroughly similar labyrinth arrangement is provided at the opposite, outer (i.e. distal) end of the secondary winding 32 by providing an end wall 322 having a central notch or groove 323 adapted to interpenetratingly cooperate with another wall 522 protruding from the internal surface of the cap 52 as best appreciated in figure 3.
The labyrinth arrangement associated with the central wall 320 has a typical nominal length of about 6.7mm, which is enough to provide an effective creepage distance between the primary and secondary windings 31 , 32 in excess of 6.4mm. The labyrinth arrangement associated with the wall 322 is usually arranged in order to provide a nominal creepage distance of about 6.5mm.
Another factor ensuring the desired level of insulation is given by controlling the distance between the core 4 and the connection pins 6 associated with the secondary winding. Such pins are usually located protruding from the lower surface of the bobbin 2. These can be provided by resorting to any standard techniques known for that purpose, e.g. in the form of metal pins inserted in the plastic mould for the bobbin. Alternatively, the pins 6 can be provided in the form of integral parts of the bobbin plastic mould over which the ends of the wire of the secondary winding are wound and soldered. Such an arrangement is described in EP 04425772.3 filed on 13 October 2004 in the name of the same Applicants.
A similar arrangement can be resorted to for the connection pins associated with the primary winding 21. In the exemplary embodiment shown herein, the primary pins, designated 7 as a whole, are to the number of four while the secondary 6 are to the number of two. This is simply dictated by the fact the primary winding 22 may in fact be arranged to include different tap/contact points in order to render the transformer 1 adapted to operate with different input voltages while providing the same output voltage. If there is no need for that, the placement of the primary pins can be chosen at convenience.
Turning again to the point of the distance between the secondary pins 6 and the core 4, a typical value in the arrangement shown is of at least 7.2mm, which appears to be thoroughly satisfactory for the application contemplated and ensuring SELV insulation.
Another factor that plays a role in determining the level insulation of the transformer described herein is given by the path between the secondary pins 6 (and the secondary winding 32) and the ferrite core 4 within the transformer.
This again includes a labyrinth formation essentially determined by two lateral L-shaped extensions 524 that extends at both sides of the cap 52. These extensions are covered by the notch 324 when the cap is inserted in its position. The length of the path through the labyrinth that is established between the secondary winding and the ferrite core or between a possible secondary track on the component side of the board and the ferrite core is far more than 6.4mm.
From the view of Figure 2 it will be further appreciated that the vertical height of the cover cap 52 has a maximum value in correspondence with the central wall 320 and gradually decreases towards the distal end of the cap 52 to reach a minimum value in correspondence with the end wall 322, thus avoiding to any obtrusive affect with respect to the secondary pins 6.
The possible expected presence of secondary connection tracks on the component side of the PCB onto which the transformer 1 is mounted is to be taken into account in order to ensure full SELV compliance of the transformer described herein for any possible application.
The cap 52 is designed in such a way to take up the overall "omega" or "mesa" shape. As best appreciated in the views of Figures 1 and 2, the extensions ("beaks") 523 do not extend just in correspondence with the cap length 52 but also extend in a longitudinal direction of the transformer to envelope or embrace the core 4 for the complete extension thereof, thus supporting the core at its "secondary" end.
In that way a air path between the possible secondary track and the ferrite core largely in excess of 6.4mm can be easily obtained e.g. by selectively varying the heights of the vertical parts of the lateral protrusions 523. It is easily possible to let the beaks 523 become two walls that encircle the entire outer legs of the ferrite core
in order to shield the ferrite from components referred to the secondary side placed in the proximity of the transformer. In this way the extensions 523 will have a general C-shape that embrace the outer leg of the core 4.
As regards connecting the ends of the windings 31 , 32 to the respective set of pins 6, 7 this description will implicitly assume that the case considered is a step-down application. In step-down applications the wire of the primary winding 31 is relatively thin and thus flexible while adapted to retain a given shape. For such a wire the arrangement described preferably resorts to standard arrangement e.g. by winding and soldering the wire to the pins 7.
In step-up applications (i.e. those applications where the voltage at the secondary winding is higher than the voltage at the primary winding, thus leading to a lower current at the secondary winding with respect to the current at the primary winding), what has been stated in the foregoing will generally apply to the same transformer when considering the secondary winding 32 as a primary winding and vice versa for the winding 31.
In typical step-down applications, the wire of the secondary winding 32 (and this will apply to the wire of the primary winding in the case of step-up applications) can be of three types: a copper wire covered by an insulating enamel, a Litz wire, or a conductor comprised of a braid of very thin wires.
A copper wire covered by an enamel is per se rather rigid, not unlike a pin by itself, whereby the respective ends can be extended through the base portion of the bobbin 2 and play the role of the pins 6 themselves thus permitting automated assembly of the transformer 1.
Conversely, a Litz wire, or - even worse - a braid of very thin wires is intrinsically non rigid, which by necessity requires it to be wound around a pin or in any case fixed onto the pin in order to create a rigid member (pin) adapted to extend through the mounting hole in the printed circuit board. This however leads to a situation where a high current may flow through a very thin pin thus increasing the temperature of the components in that area. Directly connecting a Litz wire to the tracks/strips provided in the board may reduce the temperatures in the secondary winding of 5-10°C. This currently leads to most transformers having a Litz wire secondary winding to be assembled manually by an operator.
In the arrangement described herein, two apertures in the form of notches (i.e. dead-holes) 8 are provided in the bobbin in the vicinity of the secondary pins 6.
Preferably, the apertures 8 are directly produced during the moulding process of the bobbin 2.
The ends of the secondary winding 32 (schematically indicated as W and assumed to be comprised of Litz wire or a braid of thin wires) are thus passed through the notches 8 to be soldered to the pins 6. The apertures/notches 8 permit the ends W to be safely kept in a fixed position while the wire ends W are being soldered to be the pin 6 to give rise to a rather massive arrangement.
In this latter respect, it will appreciated that molten solder, once brought to the usual soldering temperatures used by winding machines for connecting the end of the windings to the pins, is a highly polar liquid. It intrinsically tends to fill the interstices between the wires (as those comprising e.g. a Litz wire or a wire braid). When removed from the soldering bath the wire ends will thus be in fact compacted and made solidary with the metallic pins 6.
By resorting to that arrangement, a transformer 1 may be produced that is adapted to be easily assembled in an automated way. This while also benefiting from the advantages mentioned in terms of reducing the temperature at the connecting points with the PCB strips and the components located nearby.
Consequently, without prejudice to the underlying principles of the invention, the details and embodiments may vary 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.