DE202017101659U1 - Structure for an inductive power component - Google Patents

Abstract

A structure for an inductive power component, wherein the inductive power component comprises at least one insulated winding, characterized in that the winding is disposed within a frame, which frame is filled with a ferromagnetic core material that substantially surrounds the winding, so that only the external electrical Connections of the winding are visible to the outside.

Description

Technical area

The subject of the present invention is a structure for an inductive power component.

Background of the invention

A general development trend of power electronic devices, e.g. Frequency converters, is an increase in power density. Because of the internal losses in all components that handle electrical power, one condition for increasing power density is the utilization of effective cooling techniques, such as liquid or forced air cooling.

Filter baffles used in frequency converters to limit current harmonics are typical power components that produce significant power losses. Filter chokes are inductive components where most of the power dissipation is produced in current conducting windings, and remarkably also in ferromagnetic core parts.

The core parts of inductive components are usually standardized and manufactured in large volumes. Thus, the normal way, when designing a filter choke for a new application, is to select a suitable core from the manufacturer catalog and make a special winding around it. The construction is usually not easy from the cooling point of view, e.g. Due to the embedded inner turns of the winding and because of the irregular outer shape of the unit. Known ways to cool high performance windings are, for. B. to make them from copper tubes with circulating water therein or to embed thermally well conductive strips between the turns and to cool the outer ends of these strips by any external arrangement.

The known solutions to arrange effective cooling, z. Liquid cooling for inductive power components are quite complicated and expensive, including usually certain technical limitations. The shapes of commercially available core parts can also be limiting in trying to optimize the parts of the magnetic circuit.

Summary of the invention

The present invention provides a novel power inductor structure which avoids the disadvantages of the known technology and permits structure optimization from both the refrigeration and the magnetic circuit design point of view. The present invention also provides a novel process for the manufacture of the new inductor structure. The scope of protection is defined in the independent claims and the preferred embodiments in the dependent claims.

The basic characteristic feature of the inductor structure according to the present invention is that the electromagnetic parts, i. H. Winding and magnetic core, the inductor are arranged within a frame, z. A box-like metal housing, wherein the insulated winding structure is surrounded by ferromagnetic material forming the magnetic core of the inductor. The magnetic properties of the core can be optimized by tuning the core shape, e.g. By using additional non-magnetic parts within a rectangular frame or using a specially designed frame.

• 1. Montieren innerer Teile innerhalb des Rahmens,
• 2. Montieren der Wicklung innerhalb des Rahmens,
• 3. Füllen des Rahmens beim Fluid eines ferromagnetischen Materials, und
• 4. Aushärten des ferromagnetischen Materials.

The manufacturing method according to the present invention comprises the following steps:

• 1. mounting inner parts within the frame,
• 2. mounting the winding within the frame,
• 3. filling the frame with the fluid of a ferromagnetic material, and
• 4. curing the ferromagnetic material.

The inductor of the present invention may be cooled by a liquid circulation and / or forced air circulation. In a liquid filled embodiment, the unit may include tubing within the frame, and connectors in the outer surface for connecting the tubing to external fluid circulation. In another embodiment, the fluid piping is integrated into the frame structure. In an embodiment with forced air cooling, the outer surface of the frame has cooling fins from which the heat is transferred to the outer cooling air. In some embodiments, the inductor may be cooled by both liquid circulation and forced air circulation.

The inductor structure of the present invention is mechanically robust and its cooling can be made efficient. The magnetic properties of the inductor can be optimized by shaping the magnetic core according to needs.

Description of the drawings

Below, the invention will be described in more detail using examples with reference to the attached figures, in which

1 shows a main circuit of a frequency converter drive,

2 shows an inductor structure according to the prior art,

3 shows an inductor structure according to the present invention,

4A shows parts of an inductor structure according to the present invention,

4B shows a cross section of an inductor structure according to the present invention,

5 shows a manufacturing process flowchart according to the present invention, and

6A and 6B show cross-sections of frame according to the present invention.

Detailed description of the invention

1 FIG. 12 is a simplified main diagram of a known and typical variable speed motor drive wherein a frequency converter is used to control the shaft rotation speed of an AC motor. The frequency converter FC in this example comprises a diode bridge rectifier REC, which directs the three-phase supply voltage L ₁ , L ₂ , L ₃ into a constant DC link voltage, which is filtered by a capacitor C _DC , and a three-phase inverter unit INU, consisting of IGBT switches and freewheeling diodes, for generating an adjustable three-phase output voltage U, V, W for supplying the motor M. Inductive components are normally used on both sides of the rectifier to filter the harmonics of the supply phase current. A motor drive may also have special filters containing inductive power components, e.g. B. so-called LCL filters on the power side of a regenerative drive and a sine wave filter on the motor side. The structure of inductive components of the present invention can be used in all these types of inductor applications as well as in transformers, although the examples below show only DC filter _smoothing chokes L _DC , as in FIG 1 shown.

2 Fig. 10 shows an inductive component L _DC , as a known structural example of a filter-smoothing choke used in high-power frequency converters. The electromagnetic parts of the smoothing reactor are on top of a liquid-filled base plate 24 mounted, which can be connected to an external liquid cooling circulation through connectors 25 , The smoothing reactor has a magnetic core 22 with a center column 23 on, around which the winding 21 is wound (the electrical connections of the winding are not shown). To cause the winding to cool, there are some metal strips 26 acting as a thermal conductor from the winding 21 to the cooling base 24 work, have been arranged between the winding rounds.

The cooling of this type of construction according to the prior art is not good, z. Due to the long thermal path from the upper edge of the coil to the radiator. Mechanically, this structure is not robust and may require additional supporting parts in vibrating environments (eg in ships).

3 shows an inductive component L _DC1 as an example of a filter smoothing reactor according to the present invention. The winding of the smoothing reactor is within a frame 31 mounted so that only electrical connections 33 are visible to the outside. The frame is made with a ferromagnetic material 32 filled, which completely surrounds the winding.

In a liquid cooling arrangement, as in the examples of 3 - 4 As shown, the tubing for fluid circulation is located within the frame in the core material, leaving only the external fluid connections 34 are visible.

4A - 4B demonstrate the internal structure and manufacturing concept of an inductive component 3 as modified cross-sectional figures.

In 4A the dashed line shows an example such as the liquid cooling piping 35 within the frame 31 can be arranged; ie at the upper part near the rear wall and at the lower part near the front wall of the frame. The insulated winding package W is then inserted into the frame and between the casing, as indicated by the thick arrow.

4B shows the winding (without insulation) inside the frame 31 , guide parts 36 , which are preferably made of a material of both magnetically and electrically weak conductivity are used for positioning the winding package at the desired position.

5 shows a flowchart of the manufacturing method according to the present invention. In the first step, all parts which have an effect on the shape of the magnetic core and / or which have an effect on the winding position and possible cooling parts are mounted inside the frame. Next, the insulated winding package is mounted in its final place, and the frame is filled with a ferromagnetic filler 32 filled, which is flowable in this phase, z. B. as paste or wet sand. After filling, the ferromagnetic material is hardened by heating; ie by holding the inductor unit in a heating chamber at a temperature and for a time as required for the ferromagnetic material properties.

The final result after heating is a compact inductor structure wherein the ferromagnetic material forms the magnetic core of the inductor. The shape of the core can be optimized, for. B. by arranging non-iron guide parts within the frame before filling. It is also possible to optimize the core shape using a frame shape different from the rectangular prism as shown in the example above, e.g. B. a box with rounded corners, as in 6B shown.

6A and 6B show examples of alternative frame cross-sectional shapes according to the present invention.

6A shows a cross section of a frame wall 61 in which the piping 72 is integrated into the frame structure for the cooling liquid circulation.

6B shows a cross section of an air-cooled frame wall 63 , the outer cooling fins 64 between which the outer air flow can be directed. The embodiment of 6B also has inner ribs 65 which improve the heat transfer from the magnetic core to the frame. Because the inner fins are well exposed to nuclear magnetic flux, they can also be used to generate controlled power losses to attenuate possible resonances at high frequencies. It is possible to influence the resonance attenuation also by appropriately selecting the frame material (e.g., aluminum attenuates well at about 1 kHz and graphite at frequencies higher than 100 kHz).

The embodiments of the invention described above are provided as examples only. Those skilled in the art will appreciate many modifications, changes and substitutions that could be made without departing from the scope of the present invention. Although a DC filter smoothing choke of a frequency converter is used in the examples described above, the invention can be used in many other applications, e.g. In AC filter smoothing chokes, sine filter smoothing chokes, power transformers, etc. The claims of the present invention are intended to cover all such modifications, changes, and substitutions, as they fall within the spirit and scope of the invention.

Claims (7)

A structure for an inductive power component, wherein the inductive power component comprises at least one insulated winding, characterized in that the winding is disposed within a frame, which frame is filled with a ferromagnetic core material which substantially surrounds the winding, so that only the external electrical power Connections of the winding are visible to the outside. A structure for an inductive power component according to claim 1, characterized in that the winding is positioned inside the frame using guide members formed of a material which are both magnetically and electrically weakly conductive. Structure for an inductive power component according to claim 1 or 2, characterized in that a piping for a liquid circulation is embedded in the ferromagnetic core material. Structure for an inductive power component according to claim 1 or 2, characterized in that a piping for a liquid circulation is integrated into the frame. Structure for an inductive power component according to one of the preceding claims 1 to 4, characterized in that the frame has external fins for air cooling. A structure for an inductive power component according to any one of the preceding claims 1 to 5, characterized in that the frame has internal fins for improving heat transfer from the core to the frame and / or for generating power losses at predetermined frequencies. Inductive power component according to one of the preceding claims, characterized in that the inductive power component is used to filter mains harmonic or motor current harmonics in a frequency converter.

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