DE202018103181U1 - Operating device with heat conduction structure - Google Patents

Abstract

Operating device (1) for a luminaire, in particular for an LED luminaire, wherein the operating device (1) comprises:
a spool (2) with a spool core (3), and
a heat conduction structure (4, 4 ') which is in surface contact with the spool core (3) for conducting the heat emitted by the spool core (3) away from the spool core (3) during operation of the spool (2).

Description

The invention relates to an operating device for a lamp, in particular for an LED lamp.

Operating devices of the type mentioned are used to operate bulbs, especially LEDs, for example, to provide the lamp with a certain voltage and / or a certain current. Further exemplary applications are the pulse width modulation, the adjustment of the brightness (in particular dimming) and / or the general control of the lighting means. For this purpose, among other things coils are used, for example in a transformer to provide energy and / or store, so that the lamp is operated accordingly. Other applications of coils in such an operating device are e.g. Power correction (PFC) coils, coils in an LLC converter / converter, power input choke coils, flyback converter coils, or general energy storage coils.

It is known that the coils or coil combinations, for example transformers, or magnetic components generally do not work lossless and thus emit undesirable heat or waste heat. In particular, the windings and the coil core of the coil give off a lot of heat. This heat must be dissipated as well as possible, so that it does not affect other electrical and / or electronic components, since the undesirable high temperatures, in particular the life of the respective electrical and / or electronic component and thus the operating device can shorten. Especially capacitive components are sensitive to such high temperatures. In the prior art, it is known, by means of thermal paste, in particular by means of so-called TIM (thermal interface materials) gap pads, to direct the waste heat directly to the housing of the operating device or the lamp. However, this is not very effective and also relatively expensive.

The invention is based on the object to eliminate the above-mentioned disadvantages of the prior art, ie in particular to conduct the heat of coils more efficient or generally to optimize the heat generation of such devices.

The object is achieved for the operating device by the features of the independent claim. Advantageous developments are the subject of the dependent claims.

An operating device according to the invention for a luminaire, in particular for an LED luminaire, has a coil with a coil core, and a heat conduction structure which is in surface contact with the coil core, away from the coil core by the heat emitted by the coil core during operation of the coil to lead.

In other words, during operation of the coil, the coil core generates waste energy in the form of waste heat, which is efficiently transferred to the heat conduction structure by the heat conducting structure that is in surface contact, thereby efficiently cooling the coil core. That is, the flat contact of the heat conduction structure with the coil core, the heat according to a desired, namely defined by the heat conduction path - in particular to a heat dissipating and / or heat dissipating element of the lamp such as a heat sink of the lamp - be efficiently conducted. Thus, on the one hand, the coil core is cooled or the heat away from it, and on the other hand prevents other electrical and / or electronic components or generally components of the operating device are affected by this heat. The efficiency of the cooling of the spool core is thus improved. In addition, the service life or reliability of the operating device is therefore also increased, since waste heat of the coil core influences the components of the operating device, in particular the components located in the vicinity of the coil, less. Consequently, the operating device can also be used in higher ambient temperatures.

The operating device may further comprise a printed circuit board, wherein the coil is provided with the Wärmeleitstruktur on a first side of the printed circuit board such that the heat conducting structure, the heat emitted by the bobbin heat from the bobbin and the first side away to a side facing away from the first side of the printed circuit board passes. Since on the side of the coil or on the first side (front) of the circuit board usually sensitive electrical and / or electronic components such as capacitive components are provided, these components are now due to dissipation of heat through the heat conduction structure on the second side or Back of the PCB no longer affected. Thus, in particular the components of the operating device are spared by the waste heat of the coil. And since the coil is therefore also less exposed to their heat, it can now be reduced in size.

It is preferred if the coil core is arranged between standing in area contact with the coil core walls of the heat conduction structure. Thus, the heat conduction structure can be easily put on the spool core to automatically be in surface contact with the spool core. In addition, the surface which is in contact with the heat conduction structure is the area which gives off heat increased, so that the efficiency of heat dissipation and cooling is improved.

The heat conduction structure may be a wall closed at least around the coil core. On the one hand, therefore, the heat conduction structure when placing the heat conduction structure can be easily, in particular automatically brought into surface contact with the spool core. On the other hand, the area of the heat conduction structure is increased, which in turn benefits the cooling. Because of the closed surrounding wall also good thermal insulation of the components provided outside the wall can be effected. In addition, through the opening, which defines the wall, air can reach the coil or the coil core, so that the convective heat transfer between the air and the coil core and thus the efficiency of the cooling is improved.

The heat conduction structure may be a hood or cap covering at least the coil core, which preferably has a substantially U-shaped cross section. Through the openings, the hood or the preferably defined U-shaped cross-section, thus air can flow, in particular to improve the convective heat transfer within the hood. In addition, thus, the coil core is covered to above the bobbin, so spared in particular in this direction components of the operating device of waste heat of the bobbin. In addition, the heat dissipating surface is thus increased, which in turn benefits the more efficient cooling of the spool core. In addition, the heat conduction structure can thus be simply placed or plugged, preferably clamped, onto the coil or the coil core.

The heat-conducting structure preferably has a mounting section for mounting the heat-conducting structure in the operating device, in particular on the printed circuit board, and / or on the coil. By preferably integrally providing the mounting portion, the heat conduction structure can thus be simply connected to or mounted on the operating device and / or the coil, for example via a material, force and / or positive connection. It is preferred if the free ends of the hood or the foot of the wall have or have the mounting portion, so that the heat conduction structure can be particularly easily mounted.

The heat conduction structure, preferably the mounting portion, may have legs for dissipating heat, preferably in the direction of the second side of the circuit board. By providing the legs, in turn, the heat-dissipating surface can be increased, which in turn benefits the cooling effect of the heat-conducting structure. In addition, the legs have an advantageous design to be connected to other heat-dissipating elements. It is preferred if the legs pass through the circuit board. Thus, it can be effected in a particularly advantageous manner by means of the legs that heat from the front (the first side) to the back (the second side) of the circuit board (direct) is passed. In addition, because of the passage of the legs through the circuit board, the legs can be used simultaneously as fastening means for fixing the heat conduction structure on the circuit board.

Preferably, the legs are adapted to be connected to a heat-dissipating and / or heat-distributing element of a luminaire and / or the operating device. Thus, the legs can be used to direct the waste heat of the coil core on these heat-dissipating and / or heat-distributing elements directly, so in particular to guide away from heat-sensitive components of the operating device. The legs are preferably connected to a heat-dissipating and / or heat-distributing element of the operating device. This ensures that the heat emitted by the coil core and transferred to the heat conduction structure is conducted only to this heat dissipating and / or heat distributing element.

The heat-dissipating and / or heat-distributing element is preferably a heat sink or other large-area component for the release of heat. As a result, the waste heat can be emitted in a particularly advantageous manner from the operating device, for example to the ambient air, in order thus to effect efficient cooling.

The heat conduction structure may be made of a material comprising metal, preferably copper and / or aluminum. These materials have a particularly high thermal conductivity, so that they are particularly suitable for efficient cooling of the spool core or for the heat conduction by means of the heat conduction structure. Alternatively or additionally, the material (only) consist of (designed for high heat conduction) plastic or have plastic. The heat conduction structure can thus be provided in addition to the cooling of the coil core simultaneously to electrically isolate the coil.

In a preferred embodiment, the spool core is a ferrite core. Ferrite is particularly advantageously able to conduct the magnetic flux of the coil.

It is preferred if the heat-conducting structure has cooling ribs. Thus, the heat-conducting structure has an optimized for the heat transfer or for the heat dissipation, so in particular enlarged surface. The cooling fins are preferably provided integral with the heat conduction structure or the heat conduction structure is preferably such (aus) shaped that it forms the cooling fins. The cooling ribs are preferably provided on at least one side of the heat conduction structure, which faces away from the coil core, so that the heat of the coil core can be easily conducted away from the coil core. Preferably, the cooling fins are provided distributed on the surface of the heat conduction structure (evenly). Furthermore, it is preferred if the cooling ribs are provided on the complete surface of the heat conduction structure, wherein this surface preferably comprises the surface of the heat conduction structure, which faces away from the coil core, and / or comprises the surface of the heat conduction structure, which faces the coil core.

The coil may for example be a transformer coil, wherein the coil core is designed as a transformer core. A transformer coil, in particular its transformer core, is known to cause high waste heat due to the conversion of voltage. The aforementioned Wärmeleitstruktur is therefore particularly advantageous manner to dissipate this waste heat efficiently, ie in particular not to influence the transformer or other components with the waste heat.

The transformer core may include a first portion for electromagnetic interaction with a primary winding, a second portion for electromagnetic interaction with a secondary winding, and a third portion for connecting the first portion to the second portion to control the magnetic flux between the first and second portions to lead. The heat conduction structure is then in surface contact with the third section. Since the third portion is exposed from any winding and also has a large heat dissipating surface, the heat conduction structure can be brought into (full) surface contact with this (entire) surface, which contributes to the improvement in the efficiency of heat dissipation and cooling, respectively. In addition, the third portion is easily accessible from outside the coil, so that the heat conduction structure can be easily brought into surface contact with the transformer core.

The invention further relates to a luminaire, in particular an LED luminaire, comprising a luminous means, preferably an LED, and an operating device as described above for operating the luminous means.

• 1 eine schematische perspektivische Ansicht eines (Ausschnitts eines) Ausführungsbeispiels einer ersten Ausführungsform des erfindungsgemäßen Betriebsgeräts,
• 2 eine Seitenansicht des in 1 gezeigten Ausführungsbeispiels,
• 3 eine schematische perspektivische Ansicht eines (Ausschnitts eines) Ausführungsbeispiels einer zweiten Ausführungsform des erfindungsgemäßen Betriebsgeräts, und
• 4 das in 3 gezeigte Betriebsgerät in einer perspektivischen Ansicht von unten.

The invention will be described by way of example with reference to the figures, in which advantageous embodiments of the invention are shown. In the figures show:

• 1 1 is a schematic perspective view of a (detail of) an embodiment of a first embodiment of the operating device according to the invention,
• 2 a side view of the in 1 shown embodiment,
• 3 a schematic perspective view of a (detail of) an embodiment of a second embodiment of the operating device according to the invention, and
• 4 this in 3 shown operating device in a perspective view from below.

The figures described below show by way of example two embodiments of a control gear according to the invention 1 , It is not the entire operating device recognizable, but for the sake of simplicity, only a schematic excerpt. The operating device 1 Applies to a luminaire, in particular an LED luminaire. By means of the operating device 1 a light (not shown in detail) can be operated, in particular so that the light emits light in a desired manner. Exemplary applications of the operating device 1 are the supply of voltage and / or current, pulse width modulation, the setting of the brightness (in particular dimming) and / or the general control of the bulbs.

As can be seen in the figures, the operating device 1 a transformer coil 2 with a transformer core 3 on, wherein a Wärmeleitstruktur 4 . 4 ' in area contact with the transformer core 3 stands to the transformer core 3 to cool or those of the transformer core 3 during operation of the transformer or the transformer coil 2 delivered heat from the transformer core 3 to lead away.

The heat conduction structure 4 . 4 ' but not on a transformer coil 2 with transformer core 3 limited. Rather, the heat conduction structure is suitable 4 . 4 ' for any coil with coil core used in an operating device. Examples are power correction (PFC) coils, coils in an LLC converter / converter, power input choke coils, flyback converter coils, or general energy storage coils. The description thus applies analogously to a coil with a coil core.

In the figures it can be seen that the transformer coil 2 a transformer core 3 and a transformer body 6 having. The transformer core 3 For example, it is made of ferrite, but it can be made of any material that is suitable for conducting magnetic flux. The transformer core 2 has a first section to the electromagnetic Cooperating with a primary winding, and a second portion for electromagnetic interaction with a secondary winding. These are preferably in the transformer body 6 recorded and thus not visible. The one with the transformer core 3 cooperating windings cause voltage to be converted, in particular from a high voltage on the primary winding side to a lower voltage on the secondary winding side, the latter usually being provided for operating the lamp with the lower voltage. Visible is also a third section 3a connecting the first section to the second section to direct the magnetic flux between the first and second sections. The third section 3a is not in the transformer body 6 provided and thus for the heat conduction structure 4 easily accessible. That is, when placing the heat conduction structure 4 on the transformer coil 2 enters the heat conduction structure 4 preferably (only) in surface contact with the third section 3a ,

The operating device 1 can also have a printed circuit board (PCB) 5 have, wherein the transformer coil 2 with the heat conduction structure 4 . 4 ' on a first side or on the front of the circuit board 5 is provided. As in 4 well recognizable, can the circuit board 5 in particular have an opening, via which from the back of the circuit board 5 from a connection 8th the transformer coil 2 for connecting a light source and / or a voltage source to the transformer coil 2 is accessible. Moreover, in 4 recognizable that the transformer coil 2 several pins 9 may have, which preferably by the circuit board 9 pass through and the transformer coil 2 electrically connected to electrical and / or electronic components of the circuit board.

In general, the heat conduction structure has 4 . 4 ' preferably an embodiment that the heat conduction structure 4 . 4 ' that from the transformer core 3 delivered heat from the transformer core 3 and the first side or the front side of the printed circuit board 5 away to a first side facing away from the second side or to the back of the circuit board 5 passes. Thus, the waste heat, which in the operation of the transformer coil 2 is discharged from components on the first side of the circuit board 5 are provided, advantageously directed away, in particular such that the of the transformer core 3 emitted heat does not affect these components.

In the 1 and 2 is an example of a heat conduction structure 4 according to a first embodiment. It can be seen that the heat conduction structure 4 two walls 11 . 12 each in face-to-face contact with the transformer core 3 , preferably with its third section 3a , standing, taking the transformer core 3 between the walls 11 . 12 is arranged. Furthermore, it can be seen that this arrangement takes place, for example, by the heat conduction structure 4 is formed as a hood, in a plan view and / or at least one side view, preferably in two side views of the transformer coil 2 at least seen the transformer core 3 and preferably the complete transformer coil 2 covers. The heat conduction structure 4 may also have another side wall 13 comprising at least the transformer core 3 and preferably the transformer coil 2 in plan view of the transformer coil 2 seen covers. The other side wall 13 is preferably provided to be in contact with the transformer body 6 to stand. Thus, the heat conduction structure 4 in one the side walls 11 . 12 . 13 having seen section having a substantially U-shaped cross-section. The heat conduction structure 4 thus forms a hood, which simply on the transformer coil 2 can be placed so that at the same time the hood, especially the side walls 11 . 12 in flat contact with the transformer core 3 , in particular with its third section 3a , reach.

The heat conduction structure 4 is preferably in a further side view, preferably in two further side views, of the transformer coil 2 seen (cf., for example 2 ), so that through this opening (s) at least part of the transformer coil 2 , Preferably at least the transformer core 3 or the complete transformer coil 2 , through the heat conduction structure 4 not covered or visible. Thus, for example, air can flow through these two openings in order to advantageously support the cooling effect, in particular by convective heat transfer. However, it can also be provided that the heat conduction structure 4 or the hood, the transformer coil 2 covering in all side views and in plan view, thus the area of the heat conduction structure 4 for cooling even further.

As in 2 Recognizable, the transformer coil 2 further legs 7 which, through the circuit board 5 pass. Preferably, the bobbin 6 the legs 7 on. In the embodiment shown here are several, preferably five of the legs 7 intended. In a similar way, the circuit board 5 have a plurality, preferably five openings, through which in each case one of the legs 7 passes. The legs 7 are provided to increase the total heat-emitting surface, so as to serve as a heat sink, so that the transformer core 3 is cooled better. The legs 7 can with the bobbin 6 , in particular with a region of the bobbin 6 which is on the circuit board 5 rests, by means of force and / or positive means such as a clip connection can be connected. The legs 7 preferably have such a design that this with a heat-dissipating and / or heat-distributing element of the lamp and / or the operating device 1 can be connected. An example of such a heat-dissipating and / or heat-distributing element is an unillustrated heat sink. The heat-dissipating and / or heat-distributing element can also be a metallic core of the printed circuit board 5 be. However, the aforementioned element may also be any other large-area component for the release of heat to the ambient air.

It is preferred if the free ends of the hood or the distal ends of the walls 11 . 12 each have legs as described above to the waste heat of the transformer core 3 derive. That for the legs 7 The above applies analogously to the legs of the free ends of the hood.

The heat conduction structure 4 can also have a mounting section 14 have to the heat conduction structure 4 in the operating device 1 to assemble or fasten. For this purpose, the mounting section 14 have any fastening means which a material, non-positive and / or positive fastening between Wärmeleitstruktur 4 and transformer core 3 can effect, for example, a clip connection. Preferably, the walls 11 . 12 provided such that the transformer core 3 with the walls 11 . 12 at least comes into force, so the transformer core 3 for example between the walls 11 . 12 is clamped. Alternatively or additionally, the free or distal end of the side walls can also 11 . 12 So those sides of the sidewalls 11 . 12 , which the circuit board 5 opposite, the mounting section 14 exhibit.

The 3 and 4 show an example of a Wärmeleitstruktur 4 ' according to a second embodiment. The heat conduction structure 4 ' has two walls 21 . 22 on, in surface contact with the transformer core 3 stand, with the transformer core 3 between these walls 21 . 22 is arranged. The heat conduction structure 4 ' differs from the heat conduction structure 4 in particular to the effect that the heat conduction structure 4 ' has a wall which at least the transformer core 3 closed surrounds. That is, the heat conduction structure 4 ' has further, preferably two side walls 23 . 24 on which the side walls 21 . 22 connect together so that the closed surrounding wall results. The other side walls 23 . 24 are preferably also in surface contact with the transformer core 3 , The heat conduction structure 4 ' thus forms a closed wall, which is easy on the transformer coil 2 can be placed so that at the same time the wall, in particular the side walls 21 . 22 and / or the side walls 23 . 24 in flat contact with the transformer core 3 , in particular with its third section 3a , reach. This results in a top view of the heat conduction structure 4 ' or the transformer coil 2 seen a substantially rectangular cross-section of the Wärmeleitstruktur 4 ' , The heat conduction structure 4 ' however, is not limited to such a cross section. In particular, other cross sections are suitable, which at least a two-dimensional contact with the transformer core 3 can cause, so polygonal and / or round cross-sections.

The wall of the heat conduction structure 4 ' So at least surround the transformer core 3 closed so that the wall in each side view of the transformer coil 2 the transformer core 3 covers. The wall defines an opening through which the transformer coil 2 partially passes. In plan view or looking at the first side of the circuit board 5 Thus, at least part of the transformer coil is seen 2 , Preferably at least the transformer core 3 or the complete transformer coil 2 , through the heat conduction structure 4 ' not covered or visible. Preferably, the heat conduction structure 4 ' or the side walls 21 - 24 a height so that in side view of the transformer coil 2 seen the transformer core 3 is covered, but part of the transformer coil, preferably a part of the transformer body 6 , about the heat conduction structure 4 ' protrudes and is therefore visible.

For mounting the heat conduction structure 4 ' in the operating device 1 or to the transformer coil 2 can the heat conduction structure 4 ' a the mounting section 14 corresponding mounting section 14 ' exhibit. That for the assembly section 14 The above applies to the mounting section 14 ' the heat conduction structure 4 ' analogous. In particular, the side walls 21 . 22 and / or the side walls 23 . 24 be provided such that the transformer core 3 at least comes into force with these, so the transformer core 3 between these is preferably clamped. Alternatively or additionally, the foot of the wall or the side walls 21 -24, so those sides of the wall, which the circuit board 5 opposite, the mounting section 14 ' exhibit. The mounting section 14 ' can fastening means for material, force, and / or positive fastening with the circuit board 5 have, for example, a clip connection.

As in particular in 4 easily recognizable, the heat conduction structure can 4 ' , Preferably the mounting portion or foot of the wall, a plurality, preferably 10 to 40 , especially preferred 20 to 30 , Ideally 28 leg 25 for dissipating heat, preferably in the direction of the second side of the circuit board 5 , exhibit. Visible is that the legs 25 according to the (closed) cross-section of the wall on the Wärmeleitstruktur 4 ' or on the wall of the Wärmeleitstruktur 4 ' can be provided. In a similar way, the circuit board 5 have several openings, through each of which one of the legs 25 pass through, so that the legs 25 protruding from the second side. This will allow the legs 25 also for mounting or fixing the heat conduction structure 4 ' on the circuit board 5 used, for example, by the legs 25 in each case in positive and / or positive connection with the respective opening of the printed circuit board 5 stands. The legs 25 may each be designed to with a heat-dissipating and / or heat-distributing element of a lamp and / or the operating device 1 to be connected. The heat-dissipating and / or heat-distributing element is for example a non-illustrated heat sink. The heat-dissipating and / or heat-distributing element can also be a metallic core of the printed circuit board 5 be. However, the heat-dissipating and / or heat-distributing element can also be any other large-area component which is suitable for the release of heat to the ambient air.

The legs 25 but not necessarily through the circuit board 5 pass. The legs 25 are in particular provided to conduct heat in an advantageous manner, in particular in the direction of a heat sink. Thus, it is to be prevented that other components, for example, on the first side of the circuit board 5 are impaired. Through the legs 25 In particular, the heat-emitting surface is increased overall. Thus, the legs serve 25 also as an additional heat sink to the transformer core 3 better to cool.

The heat conduction structure 4 . 4 ' is preferably made of a material which is good heat-conducting. For this purpose, in particular metal, preferably copper and / or aluminum is suitable. However, it is also conceivable that the material alternatively or additionally comprises plastic or (only) made of plastic, thus, for example, an electrical insulation transformer coil 2 to effect. Preferably, the heat conduction structure 4 . 4 ' as a unit with the coil core or transformer core 3 educated.

The heat conduction structure 4 . 4 ' may also have cooling ribs not shown in detail. The cooling fins are preferably at least on one side of the heat conduction structure 4 . 4 ' provided, which the coil core or transformer core 3 is remote, so for example on the outside of one or more, preferably each of the walls 11 - 13 respectively. 21 - 24 , Preferably, the cooling fins on the surface or the walls 11 - 13 respectively. 21 - 24 the heat conduction structure 4 . 4 ' (evenly) distributed. It is further preferred if the cooling fins on the entire surface of the heat conduction structure 4 . 4 ' is provided, this surface preferably the surface of the heat conduction structure 4 . 4 ' includes, which faces away from the coil core, ie in particular the outside of one or more, preferably each of the walls 11 - 13 respectively. 21 - 24 , and / or the surface of the Wärmeleitstruktur 4 . 4 ' comprises, which faces the spool core, that is in particular directed to the spool core (inside) side of one or more, preferably each of the walls 11 - 13 respectively. 21 - 24 ,

The invention is not limited to the embodiments described above. In particular, all features can be combined with each other in any advantageous manner. In particular, the legs provided according to the second embodiment 25 also in a corresponding manner on the Wärmeleitstruktur 4 be provided. In addition, it can be provided that the heat conduction structure 4 instead of the side walls 11 . 12 the closed surrounding wall or the side walls 21 - 24 the heat conduction structure 4 ' having.

Claims (15)

Operating device (1) for a luminaire, in particular for an LED luminaire, wherein the operating device (1) comprises: a spool (2) with a spool core (3), and a heat conduction structure (4, 4 ') which is in surface contact with the spool core (3) for conducting the heat emitted by the spool core (3) away from the spool core (3) during operation of the spool (2). Control gear (1) to Claim 1 , further comprising a printed circuit board (5), wherein the coil (2) with the Wärmeleitstruktur (4, 4 ') on a first side of the printed circuit board (5) is provided such that the Wärmeleitstruktur (4, 4') that of the bobbin (3) conducts heat emitted from the spool core (3) and the first side away to a second side of the printed circuit board (5) remote from the first side. Control gear (1) to Claim 1 or 2 in which the coil core (3) is arranged between walls (11, 12, 21, 22, 23, 24) of the heat conduction structure (4, 4 ') which are in surface contact with the coil core (3). Operating device (1) according to one of the preceding claims, wherein the heat-conducting structure (4 ') at least the coil core (3) closed surrounding wall (21, 22, 23, 24). Operating device (1) according to one of the preceding claims, wherein the heat-conducting structure (4) is at least one of the coil core (3) covering hood, which preferably has a substantially U-shaped cross-section. Operating device (1) according to one of the preceding claims, wherein the heat-conducting structure (4, 4 ') has a mounting section for mounting the heat-conducting structure (4, 4') in the operating device (1), in particular on the printed circuit board (5), and / or the coil (2), wherein preferably the free ends of the hood or the foot of the wall (21, 22, 23, 24) has the mounting portion. Operating device (1) according to one of the preceding claims, wherein the heat conduction structure (4, 4 '), preferably the mounting portion, legs (25) for dissipating heat, preferably in the direction of the second side of the circuit board (5). Control gear (1) to Claim 7 with the legs (25) passing through the circuit board. Control gear (1) to Claim 7 or 8th wherein the legs (25) are adapted to be connected to a heat-dissipating and / or heat-distributing element of a luminaire and / or the operating device, wherein the legs (25) are preferably connected to a heat-dissipating and / or heat-distributing element of the operating device. Control gear (1) to Claim 9 wherein the heat-dissipating and / or heat-distributing element is a heat sink or other large-area component for the delivery of heat. Operating device (1) according to one of the preceding claims, wherein the heat-conducting structure (4, 4 ') is made of a material which comprises metal, preferably copper and / or aluminum, and / or plastic. Operating device (1) according to one of the preceding claims, wherein the coil core (3) is a ferrite core. Operating device (1) according to one of the preceding claims, wherein the heat-conducting structure (4, 4 ') has cooling ribs. Operating device (1) according to one of the preceding claims, wherein the coil (2) is a transformer coil, and wherein the coil core (3) is designed as a transformer core, wherein the transformer core (3) preferably comprises: a first portion for electromagnetic interaction with a primary winding, a second electromagnetic interaction portion with a secondary winding, and a third portion (3a) for connecting the first portion to the second portion to conduct the magnetic flux between the first and second portions, wherein the heat conducting structure (4, 4 ') is in surface contact with the third section (3a). Luminaire, in particular LED luminaire, comprising a luminous means, preferably an LED, and an operating device (1) according to one of the preceding claims for operating the luminous means, wherein the heat conducting structure (4, 4 ') preferably with a heat-dissipating and / or heat-distributing element of Luminaire such as a heat sink of the lamp is connected.

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