EP2356664A1

EP2356664A1 - Method for producing an electromagnetic actuating device, particularly for actuating valves, and actuating device produced according to the method

Info

Publication number: EP2356664A1
Application number: EP09752127A
Authority: EP
Inventors: Martin Bill; Christoph Meyer
Original assignee: Hydac Electronic GmbH
Current assignee: Hydac Electronic GmbH
Priority date: 2008-12-10
Filing date: 2009-11-13
Publication date: 2011-08-17
Also published as: WO2010066327A1; US20110226974A1; DE102008061414A1; DE102008061414B4

Abstract

The invention relates to a method for producing an electromagnetic actuating device, particularly for actuating valves, an armature (3) being formed within a pole tube (1) guiding an armature space (11) by configuring a mechanical connection between a pole body (13) and at least one further part (9, 15) of the pole tube (1), such as the pole core (9), characterized in that the mechanical connection is formed by thermal shrinking, such that the tube body (13) is heated and pressed onto the further part (9, 15).

Description

Method for producing an electromagnetic

Actuating device, in particular for actuating valves, as well as actuating device produced by the method

The invention relates to a method for producing an electromagnetic actuating device, in particular for actuating valves, in which a pole tube guiding a magnet armature within an armature space is formed by forming a mechanical connection between a tubular body and at least one further part of the pole tube, e.g. Polkern, is formed. Furthermore, the invention relates to an actuator produced by the method.

Such electromagnetic actuators, which are referred to in the jargon as proportional solenoids or solenoids, are freely available on the market in a variety of embodiments. A trained as a switching magnet device of this kind is described for example in DE 103 27 209 B3. In such devices, the armature carries out a displacement movement in the pole tube upon electrical excitation of the associated coil winding. If the energization of the coil winding is omitted, the magnet armature is reset to a starting position at regular intervals via a return spring. In most cases, the restoring force acts on the armature via the actuator connected to the armature, which is formed substantially bolt-like and extending through the pole core and a respective actuation operation triggers, for example in an externally connected valve for guiding fluid flows. The return spring can be arranged in the actuating device itself and / or preferably on the valve which may be actuated.

The reliability depends in such actuators to a large extent on the fact that the pole tube is structurally designed so that it meets the operational requirements, especially in long-term operation. Accordingly, particular importance is to be attached to the formation of mechanical connections between functionally essential elements of the pole tube during manufacture. In the prior art joining methods, such as welded joints, or connections by crimping or crimping are applied in this regard. If the required safety of the mechanical connections is to be ensured, such methods must be carried out carefully and in a time-consuming manner, which causes relatively high production costs.

In view of this, the object of the invention is to provide a method with which such actuating devices can be produced in a simple and comparatively cost-effective manner, which nonetheless are distinguished by a particularly high degree of operational reliability.

According to the invention this object is achieved by a method having the features of claim 1 in its entirety.

Accordingly, a significant feature of the invention is that in the manufacture of the pole tube mechanical connections between a tubular body and at least one pole tube associated further part are formed by thermal shrinkage, wherein the tubular body is heated and pressed onto the relevant further part. The Realization of connections by thermal shrinking allows not only a rational, ie fast and cheap production, but also leads to particularly good mechanical properties of the pole tube formed from several parts, so that despite low manufacturing costs high reliability of the actuator is guaranteed.

The inventive method also enables the particularly efficient production of multi-part pile tubes in such a way that the tubular body is connected by thermal shrinking both with the pole core formed by a first rotary member and with a second rotary member forming the displacement guide of the magnet armature by the heated tubular body to outer Lateral surfaces of both turned parts is pressed.

For operation of the actuator at a high pressure level can be used in the preparation of the compounds so that an adhesive, preferably a sealant and / or filler-forming adhesive is applied to joints before pressing the heated tubular body. This ensures that tightness and pressure resistance of the connections are guaranteed even at high pressure levels.

With regard to the realization of a magnetic decoupling, it may be favorable to form the tubular body from a non-magnetic metal.

Preferably, the procedure in such a case is that Polkern and a second rotary member to form a magnetic decoupling causing an air gap forming space are connected to each other via the tubular body.

In preferred embodiments, the second rotary part, which forms the actual displacement guide for the anchor, with a Hubbegrenzung of the armature forming closed end provided.

In this case, it is possible to proceed in such a way that a separate end part is attached to the second rotary part as the stroke limiter, or that the second rotary part is formed with an end part which is integral with it. The second rotary member in this case has the form of a hollow cylinder which is open at one end and closed at the other end by a bottom. In embodiments in which the stroke limiting end forming part is a separate component, the second rotary member can be formed as a hollow cylinder whose one end is provided by means of a flare with the separate, forming the stroke limiter end part.

The invention also provides an actuating device produced by the method according to one of claims 1 to 11, having the features of claim 12 in its entirety.

The invention with reference to embodiments shown in the drawings will be explained in detail. Show it:

Figure 1 is a schematically slightly simplified drawn longitudinal section only of the pole tube with therein arranged armature of an embodiment of the actuator according to the invention. Fig. 2 a of FIG. 1 corresponding longitudinal section of a second

Embodiment;

3 shows a schematically simplified longitudinal section of the longitudinal section adjoining the pole core only of the pole tube without magnet armature according to a further exemplary embodiment of the actuating device according to the invention; Fig. 4 shows a comparison with FIG. 3 greatly enlarged partial section of the designated in Fig. 3 with IV district and

FIG. 5 shows a partial section of the district indicated by V in FIG. 4, greatly enlarged compared to FIG.

In the drawing, of the respective electromagnetic actuator only the pole tube is shown, which is designated as a whole by 1 and in which a magnet armature 3 is movably guided, on which a rod-like actuating member 5 is mounted, extending through a central bore 7 of a pole core 9 extends therethrough to the outside. An at least partially surrounding the pole tube 1 coil housing with befindliches inside coil winding and electrical connection elements is not shown in the drawing, since it may be formed in a conventional, suitable, familiar to those skilled in the way. Also, in the simplified graphic representation, no particular shape characteristics of the rod-like actuating member 5 are shown, as in the prior art, see. DE 10 2004 028 871 A1, may be provided in order to form a fluid connection in the armature space 11 located in the pole tube 1 along the actuating part 5.

In the embodiments shown in the drawing, the pole tube 1 is formed of three main parts, namely the pole core 9 produced as a rotating part, a tubular body 13 made of non-magnetic metal and a second, a hollow cylinder defining rotary member 15. This forms inside the armature space 1 1 and the Displacement guide for the armature 3, which is provided on its outer circumference with its cylinder jacket surface interrupting lubrication grooves 17. In the position of the armature 3 shown in FIGS. 1 and 2, this is in its left-hand end position in the drawing in abutment against the bottom surface 19 of a circular cylindrical recess 21, located at the inner end of the Polkernes 9 is located. The pole core 9 as the first rotary part and the second rotary part 15 forming the actual displacement guide of the magnet armature 3 are mechanically fixed to one another via the non-magnetic tubular body 13 in such a way that an intermediate space between the end of the pole core 9 and an air gap 23 forms Rotating part 15 is formed. At the air gap 23, the pole core 9 forms a control edge 25. This is formed by the tip end edge of the recess 21 in the pole core 9 in that adjoins the end edge 21, an inclined surface 27. The air gap 23 on the pole core 9 causes a magnetic decoupling of the connected via the tubular body 13 parts of the pole tube. 1

The position of the magnet armature 3 shown in FIGS. 1 and 2 corresponds to the operating state of the energized coil winding. If the energization is omitted, the armature 3 moves under the influence of the return spring in the drawing to the right in a defined by a stroke limit end position. In order to form the stroke limitation, in the example of FIG. 1 there is provided an end body 29 which is connected to the rotary part 15 and which is anchored at the end of the rotary part 15 by means of a hinge 31.

The tubular body 13 covers the pole core 9 and the rotary member 15 connecting surfaces 33 and 35, which are each formed by circular cylindrical depressions in the outer surface of pole core 9 and rotary member 15. In this case, the depth of the recesses forming the connecting surfaces 33 and 35 is adapted to the wall thickness of the tubular body 13 such that the tubular body 13, when in position on the connecting surfaces 33, 35, continues on its outer side without recesses the circular cylindrical outer contour of the pole tube 1 , As can be seen from the drawing, the wall thickness of the tubular body 13 is substantially less than that of the wood-cylindrical rotary member 15, wherein the thickness ratio is preferably in the range of 1: 6 to 1: 3. In the example shown in FIGS. 1 and 2, this is

Size ratio approximately 1: 4. Due to the relatively low conditions wall thickness of the tubular body 13 and the resulting small depth of the connecting surface 35 forming depression, the material cross-section of the rotary member 15 is reduced only slightly in the region of the connecting surface 35.

In the manufacture of the pole tube 1, the mechanical connection of the tubular body 13 to the connecting surface 33 of the pole core 9 and to the connecting surface 35 of the rotary member 15 is carried out in such a manner that the tubular body 13 is thermally shrunk onto the pole core 9 and the rotary member 15 , The procedure is such that the tubular body 13 is heated to a temperature in the range of about 180 ⁰ C and pressed onto the connecting surfaces 33 and 35 on the pole core 9 and the rotary member 15, wherein pole core 9 and rotary member 15 are preferably at a temperature , which corresponds to the ambient level. Depending on the thermal expansion properties of the metallic materials involved, a cooling of pole core 9 and / or rotary part 15 to a lower temperature may also be provided in order to optimize the process of shrinking. With regard to the reliability in long-term operation and changing temperature conditions occurring during use, it is advantageous if the thermal expansion of the tubular body 13 of the thermal expansion of pole core 9 and rotary member 15 is similar.

The compound formed by thermal shrinkage at the pole core 9 and rotary member 15 is sufficiently tight and pressure-resistant at least at a not very high pressure level. In order to ensure a particularly secure connection for applications in which high pressures occur, the procedure is preferably such that an adhesive is applied to the connecting surfaces 33 and 35 on the pole core 9 and the rotary member 15 before the heated tubular body 13 is pressed. In addition to the holding force generated by the shrinkage thereby a splice and a seal at the connecting surfaces 33 and 35 is generated. As a special a suitable adhesive and / or filler adhesive has proven suitable, in particular an acrylate-based high temperature adhesive.

The illustrated in Fig. 2 embodiment of the pole tube 1 produced by the method according to the invention differs from the example of FIG. 1 only by an alternative design of the rotary member 15 forming the sliding guide for the armature 3. Unlike in the example of FIG the rotary member 15 is designed as a closed at one end cylindrical pot, which forms the integral with the pot Tofpboden end portion 37 with its circular, flat inner bottom surface 39, the armature space 11 and a stroke limiter for defining the right in the drawing end position of the armature. 3 forms, which occupies this right-hand end position in the absence of energization of the coil winding. Otherwise, the exemplary embodiment of FIG. 2 corresponds to the example described above, in particular with regard to the connections formed by shrinking between tubular body 13 and polar body 9 and rotary part 15.

In the further exemplary embodiment shown in FIGS. 3 to 5, in contrast to the examples described above, the tubular body 13 does not have a smooth surface on its inner side, but has in its central longitudinal region a ring body 51 projecting radially inward relative to the longitudinal axis 10, which is bounded axially by inclined surfaces 53, which, fitting at oblique end edges of pole core 9 and rotary member 15, the gap between pole core 9 and rotary member 15 fills as a filler suitably. The annular body 51 forms a field-influencing control edge at the space serving for magnetic decoupling.

While in the embodiments of FIGS. 1 and 2, the tubular body 13 rests against the connecting surfaces 33 and 35 of the pole core 9 and the rotary member 15 at both connecting regions with smooth-surfaced inner wall and fixed thereto by thermal shrinking, optionally with the use of an additional bonding method, another difference of the example of FIGS. 3 and 5 is that, as can be seen only from FIGS. 4 and 5, the respective connecting part 55 of the pipe - Body 13 to form a toothing on the connecting surface 33 on the pole core 9 and the connecting surface 35 abuts the rotary member 15. FIG. 5 shows that this toothing is formed by a stepped surface shape of the connection surface 33 on the pole core 9 and on the surface of the connection part 55 resting thereon. The same applies to the not visible in Fig. 4 and 5 connecting surface 35 on the rotary member 15. At the connecting surfaces 33 and 35 an undercut 57 is formed for this purpose, which can be seen only in Fig. 5 and forms a stop shoulder for a step 59, which is formed at the beginning of the end portion of the inner surface of the connecting part 55 of the tubular body 13. This engagement forms a securing of the connection against different thermal expansions. To avoid a possible static overdetermination, as shown in FIG. 5, at the end of the connecting part 55 a small free space 61 is provided between the adjacent surface of the pole core 9. The same applies to the end face of the connecting part 55 and the rotational part 15 not visible in FIGS. 4 and 5. Instead of the toothing by only one undercut 57 and one step 59, another surface design could be provided, for example microgrooves and corresponding depressions on the abutting surfaces or similar surface structures.

Claims

Patent claims

1. A method for producing an electromagnetic actuator, in particular for actuating valves, wherein a magnet armature (3) within an armature space (1 1) leading pole tube (1) by forming a mechanical connection between a tubular body (13) and at least one other Part (9, 15) of the pole tube (1), eg Polkern (9) is formed, characterized in that the mechanical connection is formed by thermal shrinkage in such a way that the tubular body (13) is heated and pressed onto the further part (9, 15).

2. The method according to claim 1, characterized in that the tubular body (13) is connected by thermal shrinkage both with the pole core formed by a first rotary part (9) and with a sliding guide of the magnet armature (3) forming second rotary member (15) in that the heated tubular body (13) is pressed onto outer lateral surfaces (33, 35) of both rotary parts (9, 15).

3. The method according to claim 1 or 2, characterized in that an adhesive, preferably a sealant and / or filler forming adhesive is applied to joints before pressing the heated tubular body (13).

4. The method according to claim 3, characterized in that a high temperature acrylate-based adhesive is applied.

5. The method according to any one of claims 1 to 4, characterized in that the tubular body (13) is formed of a non-magnetic metal.

6. The method according to claim 5, characterized in that the pole core (9) and the second rotary part (15) to form a magnetic decoupling causing gap over the tubular body (13) are interconnected.

7. The method according to claim 6, characterized in that the magnetic decoupling causing gap by releasing an air gap (23) between the pole core (9) and tubular body (13) is formed.

8. The method according to claim 6, characterized in that on the tubular body (13), based on the longitudinal axis (10) of the pole tube (1), radially inwardly projecting annular body (51) is formed, which as the filler of the space whose shape and Dimension is adapted and forms a control edge for the magnetic field at the intermediate space.

9. The method according to any one of claims 2 to 8, characterized in that the second rotary member (15) with a stroke limitation of the armature (3) forming the closed end (29, 37) is provided.

10. The method according to claim 9, characterized in that the second rotary member (15) is formed with an integral with it end portion (37).

11.A method according to claim 9, characterized in that the second rotary member (15) is formed as a hollow cylinder, one end of which is provided by means of a flare (31) with a separate, the stroke limitation forming end portion (29).

12. According to the method according to one of claims 1 to 11 prepared actuating device, in particular for actuating valves, the a pole tube (1) carrying an armature (3) within an armature space (11) with a tubular body (13), which is thermally shrinked with a further part (9, 15) of the pole tube (1), eg pole core (9), mechanically connected.

13. Actuator according to claim 12, characterized in that the tubular body (13) with both the pole core (9) on a connecting surface (33) and with a the sliding guide of the magnet armature (3) forming the rotary member (15) on a connecting surface (35 ) connected is.

14. Actuating device according to claim 12, characterized in that at least one connecting surface (33, 35) has a stepped surface shape (57) which, in cooperation with a correspondingly stepped shape (59) of the adjacent surface of the tubular body (13)

Securing against an axial relative movement along the respective connecting surface (33, 35) forms.

15. Actuator according to claim 14, characterized in that on each connecting surface (33, 35) has a step (57) for the interaction with a respective stage (59) on the tubular body (13) are present.