Patent Application
20200227189
The invention relates to an electromagnet.
This section provides background information related to the present disclosure which is not necessarily prior art.
Electromagnets, which transform an electrical current into a mechanical force, are known, for example, from the publication DE 10 2012 022 254 B3.
Such electromagnets generally comprise a stator and an armature, the stator comprising a magnet coil for the creation of a magnetic flux and a flux-conducting element.
An important flux-conducting element is the pole core, which is adjacent to the armature and delimits a variable axial air gap between it and the armature.
The force of the magnet acts on the air gap.
In order to achieve a force proportionate to the current in a certain stroke range independent of the stroke, a pole core having an integrally formed cone is used.
Other essential flux-guiding elements are the core flange, the housing and the yoke, which guide the magnetic flux around the magnet coil and to the armature.
The yoke advantageously also holds the armature.
In older known designs of proportionally acting electromagnets, the yoke and the pole core, as well as a spacer ring, are soldered together and together form a pole tube.
In these designs, the spacer ring is manufactured from a metallic material having a very low magnetic conductivity, while the yoke and the pole core are manufactured from a material having a very high magnetic conductivity.
The low magnetic conductivity of the spacer ring is required in order to prevent a magnetic short circuit across the axial air gap.
The embodiment described above having a soldered pole tube achieves an outstanding linearity of the conversion between current and force as well as a low hysteresis of the force in the case of a variable stroke, but it has high manufacturing costs.
An alternative known embodiment has a pole tube made of austenitic iron that serves to support the armature. This design can be manufactured at low cost, but it has a significantly higher hysteresis of the force in the case of a variable stroke.
An electromagnet is to be described that has a very low hysteresis of the force while having a variable stroke with low manufacturing cost.
The low hysteresis of the force in the case of a variable stroke is achieved by geometric design of the yoke and the pole core in such a manner as is typical in the example with the rolled pole tube and by support of the armature in the yoke.
In any case, no metallic spacer ring is used between the yoke and the pole core. Instead of this, the intermediate space between the yoke and the pole core is filled with plastic.
Instead of connecting a magnet coil to its own coil core made of plastic via a pole tube, a coil core is used here that comprises the yoke, the pole core, a pole plate and the plastic mass.
The plastic mass also achieves the object of connecting the metallic parts of the coil core with each other.
The yoke has a flange that is integrally formed or is pressed on as a separate component.
In the molding or casting process, the intermediate space between the yoke and the pole core is filled with the plastic mass.
The coil core thus produced is wound around by the magnet coil and enclosed by a housing that also has the property of an iron counter plate.
The winding of the coil core deforms the inner diameter thereof, which therefore must be reworked mechanically by reaming after the winding, because this inner diameter serves to support the armature. Next, the armature rod is connected into the pole core and the armature is joined into the yoke.
Finally, the yoke is provided with an end plate provided with holes, either by welding the plate onto the yoke or by pressing the plate into the yoke.
Electromagnets of the described type are used for actuating fluid valves or couplings, preferentially in motor vehicles or in mobile working machines.
The drawings described herein are for illustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure.
Corresponding reference numerals indicate corresponding parts throughout the several views of the drawings.
Example embodiments will now be described more fully with reference to the accompanying drawings.
The electromagnet (1) according to
The coil core (6) includes the yoke (7), the pole core (4) and the core flange (14), the coil core (6) being manufactured by jointly overmolding or overcasting the yoke (7), the pole core (4) and the core flange (14) with a plastic mass (8), and the axial intermediate space (10) between the yoke (7) and the pole core (4) also being filled with the plastic mass.
The pole core (4) is surrounded by a core flange (14) that guides the magnetic flux from the housing (3) to the pole core (4). Alternatively, the pole core (4) and the core flange (14) are designed as one piece.
The yoke (7) including the armature (5) is equipped with a flange (15) that guides the magnetic flux from the housing (3) to the armature (5). Alternatively, the flange (15) and the yoke (7) are two parts that are joined by compression.
An end plate (12) is welded onto the yoke (7), which serves as a stop for the armature (5) and has one hole or a plurality of holes (13). As an alternative to welding, the end plate (12) is joined by compression into the yoke (7).
The housing (3) comprises the magnet coil (2) and the yoke (7).
At least the following steps are provided for production of the electromagnets:
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2015 011 238.4 | Aug 2015 | DE | national |
This application is a 371 National Stage of International Application No. PCT/EP2016/001332, filed on Aug. 2, 2016, which claims the benefit of and priority to German Patent Application 10 2015 011 238.4 filed on Aug. 25, 2015. The entire disclosures of the above applications are incorporated by reference herein.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2016/001332 | 8/2/2016 | WO | 00 |
