EP3312853A1 - Electromagnet - Google Patents

Abstract

The invention relates to an electromagnet, in particular for actuating a valve. The electromagnet has a bobbin which carries windings of an electric current conducting wire. A Tubusrohr is at least partially disposed in the interior of the bobbin. The first longitudinal section of the tube tube is supported in a stabilizing body. The second longitudinal section of the tube tube is held by a core.

Description

The invention relates to an electromagnet, in particular for actuating a valve, wherein the electromagnet has a coil body which carries windings of an electric current-conducting wire, and a tube tube, at least partially, is arranged inside the coil body and the tube tube forms an armature space, in which an anchor is mounted longitudinally movable and acts on a, mounted in a core of the electromagnet ram.

For setting the magnetic properties of the electromagnet, it is known the tube tube in one piece, but from different sections to produce. These sections differ in their properties of the line or leadership of the magnetic field lines (magnetic conductivity).

The end sections of the tube tube are made of materials / metals with good or better magnetic conductivity. Between these sections is a piece of a material / metal with poor or less magnetic conductivity.

These sections are welded together and must be post-machined afterwards to ensure a corresponding precision, since the inner surface of the Tubusrohres serves as a support surface of the armature in the armature space.

It is an object of the present invention to find an arrangement that allows a more cost-effective production.

To solve this problem, the invention is based on an electromagnet as described above and suggests that the first longitudinal section of Tubusrohres is supported in a stabilizing body and the second longitudinal section of Tubusrohres is held by the core and the stabilizing body and the core axially, based on the Coil longitudinal axis of the bobbin, are spaced.

Cleverly, the stabilizing body or the core consists of a material with good / high magnetic conductivity. The stabilizer body and the core are spaced apart and are connected by the tube tube, wherein the tube tube is formed of a material with poor / low magnetic conductivity. In this case, the three elements stabilizing body, Tubusrohr and core not necessarily mechanically fixed together, for example, to be welded, the tightness of the electromagnet, in particular the Anchor space is achieved by a correspondingly dense configuration of the tube tube alone.

For example, the stabilizing body is placed on the first longitudinal section (facing the first longitudinal end) of the tube tube and supports it therefrom, the core is also placed on the second longitudinal section (facing the second longitudinal end) of the tube tube and held so. A correspondingly high pressure ensures sufficient mechanical cohesion, which can be achieved cost-effectively with corresponding production methods.

The trick of the invention is that a clever arrangement of the individual components core tube yoke with stabilizing body allows to dispense with the complex to be performed welding or soldering according to the prior art. Core and yoke are preferably made of soft magnetic material, the material of Tubusrohres has a low magnetic conductivity. The individual components are preferably homogeneous in themselves (without the invention to be limited thereto) and positioned axially so cleverly to each other that prevail by the spacing on the one hand and the selection of material on the other hand at the working air gap favorable magnetic conditions that improve the efficiency.

The proposal according to the invention completely avoids welding or soldering or, if such a connection is required, allows it to be carried out in such a way that no post machining machining is necessary. It is advisable to note that welding or soldering influences the magnetic properties as well as the strength properties. The proposal according to the invention not only reduces the production costs, but also avoids an impairment of the magnetic or other properties of the electromagnet.

The result is a cheaper manufacturable electromagnet, which has better mechanical and magnetic properties.

In a preferred embodiment of the proposal, it is provided that the tube tube is open on both sides. The tube tube, strictly speaking the inside of the tube tube, serves as a guide for the anchor. It is known to form the tube tube as a section of a profile product, for example a tube. This is a convenient way to realize the Tubusrohr, which is sometimes also referred to as pole tube.

Alternatively, it is provided that the tube tube is pot-shaped and is open on one side. Since, according to the proposal according to the invention, the tube tube no longer has to assume a mechanical holding task, therefore, a thin-walled embodiment of the tube tube is also possible. The small wall thickness of the Tubusrohres but also makes it possible to design the Tubusrohr itself differently and to realize, for example, as a one-piece cup-shaped element and so give the Tubusrohr further properties. "Integral" here means that the Tubusrohr consists of one piece, although it is composed of several individual elements, with different properties, for example, their magnetic properties, assembled and welded, for example. In the context of the disclosure of this application, a "pot-like tube tube" is therefore to be subsumed at least one tube piece (possibly also with different diameters) and a tube tube bottom closing the tube end. The Tubusrohrboden closes preferably completely, possibly even only partially, one side of the Tubusrohres, preferably the first longitudinal portion of Tubusrohres, which stands in the stabilizing body.

It is advantageously provided that the first longitudinal section has a curved Tubusrohrboden. The curvature can be executed in the inner pot, facing away from the yoke, or to the outside. The Tubusrohr leads the anchor and the Tubusrohrboden thus formed describes an end position of the armature. Usually, the yoke is made of soft magnetic material, it still has a certain magnetization even when the current through the coil and the formation of a small gap or gap by the curvature between the end-side anchor surface, which faces the Tubusrohrboden and the core, prevents sticking or adherence of the anchor, thus ensuring a reliable function.

Furthermore, it is advantageously provided in the proposal that the second longitudinal section has an expansion, and the tube tube with the expansion on the core, in particular the guide pin of the core, is placed.

Such a configuration makes it possible to form the anchor as a cylinder. In the core end facing the armature space, the core preferably has a ring-like configuration, which has at its open end a control cone, via which the force-stroke characteristic of the electromagnet is adjusted. Due to the proposed widening, the tube tube in the region of the core is widened in diameter in such a way that it is pushed onto this control cone, which here is part of the guide pin of the core. It also forms a pot-like structure at the core in the area of the guide pin. The inside of the core with the guide pin and the control cone integrated into it then takes on the leadership task for the anchor in this area. Due to the expansion, it is further achieved that the armature can interact directly with the control cone when the coil is energized.

Alternatively, it is provided that a truncated cone is integrally formed on the end of the armature, that is, the armature consists of at least two different geometric basic bodies, a cylinder in the central portion and an end-side truncated cone. With such a variant, it is possible to dispense with the expansion. For example, then the second longitudinal section is placed on the core.

Furthermore, it is provided that for the attachment of the Tubusrohres on the core an interference fit, gluing, welding or a positive connection is provided. The proposal includes a variety of possible types of connection, as the Tubusrohr is reliably attached to the core. There are also relatively simple and therefore cost-effective to implement variants (for example, press-fitting or bonding) possible, resulting in a sufficiently mechanically stable and dense composite. In a positive-locking composite, the core or the guide pin preferably has a circumferential groove or groove, and the end region of the first longitudinal section has an on-board filling or convex region which projects into this groove or groove.

By using a weld, a media- or pressure-tight composite is also possible at the same time, which is particularly favorable in valve applications where medium is located in the anchor space.

Furthermore, it is provided that the guide pin carries an O-ring seal in a circumferential groove in order to close the gap between the tube tube and the guide pin. The use of an O-ring seal is a proven sealant, which is an inexpensive alternative to welding, especially in mechanical joining techniques, such as press-fitting or positive-locking bonding.

Furthermore, it is provided that the tube tube is designed as a deep-drawn part. The thermoforming methods available in the art today make it possible to produce parts with high precision such that the inner sides can be used as guide surfaces, for example for the supports of an anchor. Furthermore, by the proposed deep drawing step, any formation of Tubusrohrbodens possible. In addition, the deep drawing is a cheaper manufacturing step.

In an advantageous embodiment, it is provided that the tube tube consists of a material with low magnetic conductivity.

For example, this is e.g. an austenitic steel is provided. Preferably, materials having a relative permeability <10 are used.

Various variants are proposed below, how to implement the stabilizing body. The variants described have advantages with regard to the costs of production or with regard to precision. The high variety of this detail is an advantage of this proposal.

First, it is favorable provided that the stabilizing body is open on both sides. In this advantageous embodiment, the tube tube and the stabilizing body form a tube-in-tube system. For example, the yoke carries an annular groove into which the edge of the stabilizing body is inserted, the tube tube being connected to the core as described above. This results in a simple but accurate construction.

In a further preferred embodiment it is provided that the stabilizing body is pot-shaped. In this proposal, for example, a corresponding material is deep-drawn or produced as a milled part, whereby the pot-like structure of the stabilizing body provides the soil itself.

The stabilizing body can be prepared as a separate component (for example as a piece of pipe, cut off from a profiled product) and then connected to the yoke, whereby the yoke then forms the bottom of the stabilizing body. It is therefore advantageous that the stabilizing body is designed as a component separate from the yoke and mechanically firmly connected thereto.

Clever way is also envisaged that the stabilizing body is integrally formed on the yoke. Also in this case, a welding is preferably provided, the number of components is reduced, a part of the hole thus forms the stabilizing body.

Advantageously, it is provided that the stabilizing body consists of a material with good or high magnetic conductivity. Soft magnetic materials are preferably used.

Characterized in that the quotient of the wall thickness of the Tubusrohres and the wall thickness of the stabilizing body is between 10 and 70%, preferably between 20 and 50%, particularly preferably between 25 and 40%.

The proposal according to the invention aims to distribute the known in the prior art complex structure of Tubusrohres or pole tube to individual, specialized on this components. Since now a separate stabilizing body is provided for the stabilization of the Tubusrohres, the Tubusrohr itself be realized filigree, since this then focuses only on the management task of the anchor. The Tubusrohr can therefore be advantageously reduced in its wall thickness, as described, which saves space and weight.

In a preferred embodiment of the proposal it is provided that extends in the spacing between the core and the stabilizing body of the central portion of the Tubusrohres, the first longitudinal portion which is inserted in the stabilizing body, with the second longitudinal portion which is placed on the guide pin, combines.

The middle section connects the two longitudinal sections. Advantageously, a ring-like guide pin is provided with the end control cone on the core. The spacing of the stabilizing body from the core has the effect that this material has very little influence on the magnetic properties of the control cone when the coil is energized. In the middle section, the area of expansion of the Tubusrohres begins. Since the material of the Tubusrohres little or no effect on the magnetic field, this spacing is doubly effective, since the spacing or clearance provides space for expansion while minimally affecting the magnetic properties of the control cone.

Furthermore, the invention also includes the use of the electromagnet for the purpose of an electromagnetically controlled valve, for example pressure control valve.

Fig. 1

einen Schnitt durch den erfindungsgemäßen Elektromagneten

In the drawing, the invention is shown schematically in particular in one embodiment. Show it:

Fig. 1

a section through the electromagnet according to the invention

The disclosures contained in the entire description are mutatis mutandis to the same parts with the same reference numerals or identical component names transferable. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and are to be transferred to the new situation mutatis mutandis when a change in position. Furthermore, individual features or combinations of features from the illustrated and described different embodiments may represent for themselves, inventive or inventive solutions.

In FIG. 1 the electromagnet 1 according to the invention is shown in section.

The electromagnet 1 has a bobbin 2, which carries a plurality of windings 20 of a wire. If an electric current flows through this wire of the windings 20, a magnetic field is produced which acts on an armature 4 and moves it against the force of a restoring spring, not shown. The return spring is disposed, for example, in the valve member actuated by the plunger 10 (also not shown).

The bobbin 2 has a coil longitudinal axis 21, the armature 4 is movable parallel to this coil longitudinal axis 21. Inside the bobbin 2, the tube tube 3 is arranged. The tube tube 3 forms, or limits the armature space 30, which receives the armature 4.

The armature 4 acts on a plunger 10 which is movably mounted in the core 5 of the electromagnet 1. The movement of the armature 4 is out of the electromagnet 1 via the plunger 10 directed. For this purpose, the plunger 10 is movably mounted in the bore 50 of the core 5. In the fallen, not energized state, as in FIG. 1 is shown, the return spring, not shown, presses on the plunger 10, the anchor 4 upwards, between the armature space bottom 34 and the lower edge 40 of the armature 4, the air gap 33 is formed. In this case, the armature space floor 34 is also a boundary surface of the core 5.

The tube tube 3 is divided into at least two longitudinal sections, the first longitudinal section 31 and the second longitudinal section 32, which extend in particular to the respective ends of the tube tube 3. The middle section 35 is located between the two longitudinal sections 31, 32. The longitudinal sections 31, 32 extend as far as the respective ends of the tube tube 3.

The tube tube 3 is open on one side in the embodiment shown here, the second, lower open longitudinal section 32 is pushed onto the guide pin 51 of the core 5. Of course, the invention also includes solutions in which the tube tube 3 is open on both sides.

The first longitudinal section 31 of the Tubusrohres 3 is closed by a Tubusrohrboden 36 pressure-tight. The longitudinal portion 31 is formed pot-shaped so far. In the embodiment shown here, the longitudinal section 31 is inserted into a likewise pot-like stabilizing body 6. This stabilizing body 6 closes off the upper end of the bobbin 2.

The Tubusrohr 3 has the task to provide a pressure-tight armature space 30 and the stabilizing body 6 with the core 5, to be precise, the guide pin 51 of the core 5 to connect.

According to the invention, the stabilizing body 6 and also the core 5, in particular the guide pin 51, are made of a material which has good or high magnetic conductivity. Such a design significantly supports the leadership of the magnetic field generated by the current-carrying coil and increases the overall efficiency of the device.

In particular, it has been found that the magnetic properties, in particular the current-force characteristic of the electromagnet 1 can be favorably influenced by a conical configuration of the upper edge 52 of the guide pin 51, which laterally limits the air gap 33.

By the conical configuration of the upper edge 52 naturally reduces the material thickness of the air gap 33 laterally limiting material of the guide pin 51. The stabilizing body 6 does not follow in the axial direction (relative to the coil longitudinal axis 21) seamlessly against the upper edge of the guide pin 51, but is slightly spaced, this area is spanned by the central portion 35 of the Tubusrohres 3. The stabilizing body 6 and the core 5 are axially spaced relative to the coil longitudinal axis 21 and are interconnected by the tube tube 3, in particular its central portion 35.

The core 5 or the guide pin 51, like the stabilizing body 6, is formed from a material which has good or high magnetic conductivity. The stabilizing body 6 here has the additional task of mechanically supporting the upper, first longitudinal section 31 of the tube tube 3 (which has the tube tube bottom 36), which is advantageous in particular in high-pressure applications. At high Otherwise, the material thickness of the tube tube 3, which is naturally formed from a material with low or poor magnetic conductivity, would have to be increased, but this would adversely affect the overall magnetic properties. The use of the stabilizing body 6 thus combines a high compressive strength with good magnetic properties.

The arrangement is chosen such that the first longitudinal section 31 of the tube tube 3 is inserted into the pot-like stabilizing body 6. The dropped anchor 4 is then not directly on the body bottom 60 of the stabilizing body 6, but is slightly spaced from this, the Tubusrohrboden 36 acts here as an air gap and reduces the detachment forces of the armature 4. It is also provided, the Tubusrohrboden 36 not straight but curved inwardly form whereby the distance of the fallen anchor 4 to the body bottom 60 increases significantly above the material thickness of Tubusrohrmateriales.

Furthermore, it is provided that the tube tube 3, starting in the central portion 35 and then in the second longitudinal portion 32, which cooperates with the core 5, cone-like (facing away from Tubusrohrboden 36) is widened. This widening 39 begins in the middle section 35 and also extends into the second longitudinal section 32. This has the advantage that material of the core 5 with high magnetic conductivity is available in the region of the air gap 33 and the magnetic properties are optimized there.

However, it is clear that the approach according to the invention can also be implemented with a continuous cylindrical tube tube 3.

The stabilizing body 6 is embedded or mounted in the yoke 11 of the electromagnet 1. The yoke 11 closes the electromagnet 1 on the opposite side of the core 5 Bobbin 2 from. In the embodiment shown here, the stabilizing body 6 is formed separately from the yoke 11. But it is also possible to realize the stabilizing body 6 in one piece, as part of the yoke 11, both solutions are part of the invention. Of course, it is also possible to use the stabilizing body 6 in the interior of the Tubusrohres 3.

The wall thickness of Tubusrohres 3 is selected according to the application of the electromagnet. If a high pressure resistance is required because the solenoid 1 drives a valve, a wall thickness of up to 0.8 mm (or even more) is used. At lower pressures, the wall thickness can be reduced accordingly to 0.3 mm (or even less). The tube tube 3 is formed, for example, as a cold-formed, deep-drawn component, which has the same wall thickness everywhere. Alternatively, it is provided that the magnetic properties can be influenced in a targeted manner by changing the wall thickness. This applies in particular in the region of the middle section 35 or the first longitudinal section 31, here at the area of the cone 52 in which a reduction or increase in the wall thickness is alternatively provided with respect to the other areas of the tube tube.

It is preferably provided that the wall thickness of Tubusrohres 3 15, 20, 25, 30, 35, 40, 45, 50, 55, 60 or 65% of the wall thickness of the stabilizing body 6.

In a preferred embodiment, it is provided that the first longitudinal section 31 and the second longitudinal section 32 20, 25, 30, 35, 40, 45, 50, 55, 60% of the total length of the tube tube 3 has. The central portion 35 is 5, 10, 15, or 20% of the total length of the Tubusrohres 3, of course, the three elements, first and second longitudinal section 31,32 and Central portion 35 have an overall length of 100%. It is clear that the longitudinal sections of 31, 32 can also have different lengths.

In order to achieve a tight connection of the core 5 to the tube tube 3, a circumferential or annular groove 59 is provided on the guide pin 51, which receives a seal 53. It seals the gap between the inside of the tube tube 3 and the outside of the guide 51.

It is a possible backlash-free arrangement of the first longitudinal section 31 of the Tubusrohres 3 provided in the pot-like stabilizing body 6.

Anchor bores 40 are provided in the armature 4 extending parallel to the longitudinal axis of the coil 21, which allow rapid pressure equalization during the movement of the armature 4.

The tube tube 3 is connected in an advantageous variant with the stabilizing body 6 and the core 5 / guide pin 51 by conventional connection means. This may be, for example, press-fitting, caulking, gluing, bracing (e.g., through a housing), soldering, or the like.

The claims now filed with the application and later are without prejudice to the attainment of further protection.

If, on closer examination, in particular also of the relevant prior art, it appears that one or the other feature is beneficial for the purpose of the invention, but not crucial, it is of course already desired to have a formulation which is such a feature , in particular in the main claim, no longer having. Also one such sub-combination is covered by the disclosure of this application.

It should further be noted that the embodiments and variants of the invention described in the various embodiments and shown in the figures can be combined with one another as desired. Here, one or more features are arbitrarily interchangeable. These feature combinations are also disclosed with.

The references cited in the dependent claims indicate the further development of the subject matter of the main claim by the features of the respective subclaim. However, these are not to be understood as a waiver of obtaining independent, objective protection for the features of the dependent claims.

Features which have been disclosed only in the description or also individual features from claims which comprise a plurality of features can at any time be taken over as being of essential importance for the purpose of differentiation from the prior art in the independent claim (s), even then, if such features have been mentioned in connection with other features or achieve particularly favorable results in connection with other features.

Claims (15)

Electromagnet, in particular for actuating a valve, wherein the electromagnet (1) has a coil body (2) which carries windings (20) of an electric current-conducting wire, and a tube tube (3) is arranged at least partially inside the coil body (2) and the tube tube (3) forms an armature space (30) in which an armature (4) is mounted so as to be longitudinally movable and acts on a plunger (10) mounted in a core (5) of the electromagnet (1) and the first longitudinal section (FIG. 31) of the tube tube (3) in a stabilizing body (6) and the second longitudinal portion (32) of the Tubusrohres (3) is held by the core (5) and the stabilizing body (6) and the core (5) axially, based on the Coil longitudinal axis (21) of the bobbin (2), are spaced. Electromagnet according to claim 1, characterized in that the tube tube (3) is open on both sides. Electromagnet according to one of the preceding claims, characterized in that the tube tube (3) is pot-shaped and is open on one side. Electromagnet according to one of the preceding claims, characterized in that the first longitudinal portion (31) has a curved Tubusrohrboden (36). Electromagnet according to one of the preceding claims, characterized in that the second longitudinal section (32) has a widening, and the tube tube (3) with the widening (39) on the core (5), in particular the guide pin (51) of the core (5 ) is attached. Electromagnet according to one of the preceding claims, characterized in that for fastening the Tubusrohres (3) on the core (5) is provided a press fit, gluing, welding or a form-locking bond. Electromagnet according to one of the preceding claims, characterized in that the guide pin (51) in a circumferential groove (59) carries an O-ring seal (53) to close the gap between the tube tube (3) and the guide pin (51) , Electromagnet according to one of the preceding claims, characterized in that the tube tube (3) is designed as a deep-drawn part. Electromagnet according to one of the preceding claims, characterized in that the tube tube (3) consists of a material with poor or low magnetic conductivity. Electromagnet according to one of the preceding claims, characterized in that the stabilizing body (6) is open on both sides. Electromagnet according to one of the preceding claims, characterized in that the stabilizing body (6) is pot-shaped. Electromagnet according to one of the preceding claims, characterized in that the stabilizing body (6) as the yoke (11) separated, with this mechanically fixed component is formed or the stabilizing body (6) is integrally formed on the yoke (11). Electromagnet according to one of the preceding claims, characterized in that the stabilizing body (6) consists of a material with good or high magnetic conductivity. Electromagnet according to one of the preceding claims, characterized in that the quotient of the wall thickness of the Tubusrohres (3) and the wall thickness of the stabilizing body (6) between 10 and 70%, preferably between 20 and 50%, particularly preferably between 25 and 40%. Electromagnet according to one of the preceding claims, characterized in that in the spacing between the core (5) and the stabilizing body (6) the central portion (35) of the tube tube (3) extends, which comprises the first longitudinal portion (31) which in the Stabilizing body (6) is inserted, with the second longitudinal portion (32) which is placed on the guide pin (51) connects.

Images