EP2073223A1 - Switchable magnet assembly as confirmation element for a valve or other function elements - Google Patents

Abstract

The assembly (1) has a field coil (4) arranged in a magnetizable housing, an armature (6) axially moved to a bearing during current impact of the field coil. The armature has an axial tappet (7) led into the bearing and directed in a direction of actuation of an actuator. A yoke (5) encloses one of front sides of the housing, and a cone-shaped guiding unit (9) encloses another front side of the housing. The anchor and/ or yoke and/or cone-shaped guiding unit and/or bearing are surrounded by a magnetically conductive, medium permeable material.

Description

The invention relates to a switchable magnet arrangement as an actuator or actuator for a valve or other functional elements having a magnetizable housing, an at least partially arranged in the magnetizable housing exciter coil, an axially energized when energizing the excitation coil armature, an armature piston and in the direction of actuation of the Actuator directed axial actuating rod comprises a one of the end faces of the housing final yoke and the other end face of the housing final cone-shaped guide body, wherein the guide body has an axial passage for the actuating rod.

Such a magnet arrangement is for example from DE 102 38 840 A1 known as camshaft adjuster.

At the connections of electromagnetically driven valves prevail certain connection pressures. These can have undesirable repercussions on the position of the valve. To prevent this, the pressure level of a connection is led into the magnet and ensures that the surfaces on which the pressure acts are the same, so that pressure equalization is possible is. To transfer this pressure into the interior of the armature space, the parts arranged inside the magnet, such as the armature piston and / or the cone and sometimes also the yoke, are provided with longitudinal and / or transverse bores. The preparation of these pressure equalization holes, especially in the anchor piston and the cone, is complicated and expensive. Another additional disadvantage can but be that when the transverse holes are not symmetrically arranged, this can lead to asymmetrical force effects of the electromagnet and thus increased switching hysteresis.

Such electromagnets are e.g. used in automotive engineering as a proportional solenoid for camshaft adjustment. The proportional, speed-dependent adjustment of the intake / exhaust camshaft in car engines is used to increase torque at low speeds and to reduce pollutant and fuel consumption. The proportional solenoid used in conjunction with a 4/2-way proportional valve in the engine compartment is bolted directly to the cylinder head.

The input signal of the magnet is the pulse-width-modulated supply voltage of the vehicle electrical system. By changing the duty cycle of the voltage, the valve piston position, or the oil volume flow is variably controlled via the proportional solenoid.

By changing the volume flow, the intake and exhaust camshafts are adjusted relative to the crankshaft. This adjustment affects the timing of the exhaust and intake valves. The main advantage of a camshaft adjustment is the reduction of exhaust emissions and the improvement of the torque curve.

The proportional solenoid is characterized by a low Bautellanzahl and easy installation.

From the EP 1 667 177 A1 It is known to make the anchor piston partly from a sintered material. This applies in particular to the axial region of the armature piston, which serves as a cover for the anchor rod. It is proposed a combination of sintered non-magnetic material with magnetic iron material, thus the magnetic properties (extension of the flux in the anchor) and at the same time to obtain improved properties against wear for the anchor rod. The EP 1 667 177 A1 Although it discloses that the sintered magnetic material should have a porosity of 15% or less, this porosity is by no means sufficient to ensure sufficient flow through of the sintered material necessary for rapid pressure equalization. A possible pressure equalization or special flow characteristics are in the EP 1 667177 A1 also not mentioned or suggested.

The DE 83 17 753 U1 discloses an electromagnetic actuator, the pressure body can also be prepared by sintering, but here a binder for sealing the residual porosity of the sintered pressure body is proposed, so that the possibility of flow through the sintered pressure hull goes to zero. Again, a possible pressure equalization or special flow characteristics are neither mentioned nor suggested.

Based on this prior art, it is the object of the invention to realize the pressure balance in the magnet without compensation holes in the anchor piston and / or in the cone.

The object is achieved by the features of claim 1. Instead of the armature piston, yoke or cone made of solid material, according to the invention, at least one of these components is formed or at least surrounded by a magnetically conductive material which is permeable to pressure compensation for media such as air or oil (gases or liquids). The thickness and / or area of the cover and its porosity depends on the required pressure compensation and field of application.

Porosities between 20% and 90% are required regularly to ensure sufficient flow and thus the required pressure compensation.

But it is also possible to produce the anchor piston and / or the yoke and / or the bearings and / or the cone-shaped guide body of the magnetically conductive, media-permeable material to ensure optimum pressure equalization.

It has proved to be advantageous if the magnetically conductive, media-permeable material is an open-pored, magnetically conductive, foam-like material, for example sintered metal.

According to the invention, the running surfaces of the armature piston can be machined.

In particular, the switchable magnet arrangement can be a lifting magnet, for example a proportional magnet.

In a particularly advantageous manner, the open-pore, magnetically conductive, foam-like material may contain sintered, iron-containing, possibly mixed with further alloying elements material.

The switchable magnet arrangement can be used according to the invention as a proportional magnet for adjusting the camshaft or as an actuator for a variable throttle. They are used as actuators in pneumatic, hydraulic and air conditioning systems.

Fig. 1

einen erfindungsgemäßen Proportionalmagneten und

Fig.2

eine weitere Ausführungsform eines erfindungsgemäßen Proportionalmag- neten.

The invention is explained in more detail with reference to embodiments shown in the drawing. Show it:

Fig. 1

a proportional magnet according to the invention and

Fig.2

a further embodiment of a proportional magnet according to the invention.

In the FIG. 1 is a switchable magnet arrangement 1 according to the invention, for example, a proportional magnet for camshaft adjustment, shown with a magnetizable cup-shaped housing part 2, in which a, mounted on a bobbin 3, for example plastic excitation coil 4 is arranged. A substantially plate-shaped magnetizable yoke 5 terminates the open cup-shaped housing part 2 in the axial direction. In the center of the field coil 4, an armature 6 is mounted axially movable. Centrally in the armature 6, a plunger 7 is arranged as an actuating rod, whose front, out of the magnet assembly facing end 8 as actually switching element for other functional parts, such as a valve spool, is used.

The plunger 7 is also held axially movable in a fixedly fitted guide body 9. This is cone-shaped and held in the axial direction below at a distance to axially extending flange portions 10 of the yoke 5.

The guide body 9 is held in a recess 11 in the bottom part of the cup-shaped housing part 2 and connects radially directly to the edge region 12 of the recess 11. This ensures the magnetic flux between these parts.

Due to the axial distance between the cone-shaped guide body 9 and the flange portions 10 of the yoke 5 results here for the magnetic field lines to be bridged air gap. When energizing the exciter coil 4 acts an axial force on the armature 6, so that it executes a stroke and in this movement entrains with it the pressed plunger 7, which acts for example on a valve spool and this adjusted.

The armature 6 with the plunger 7 held therein and the cone-shaped guide body 9 are held in a pressure-tight armature space 13. This is sealed by a thin-walled sleeve 14. The sleeve 14 is fixed axially on the recess 11 surrounding edge portion 12 of the cup-shaped housing part 2, for example, welded with a laser welding process, and thus enables the direct radial contacting of cup-shaped housing part 2 and cone-shaped guide body 9 to ensure an uninterrupted magnetic flux.

The connection between the sleeve 14 and the cup-shaped housing part 2 is in the DE 102 38 840 A1 described in detail. The sleeve 14 itself may consist of a non-magnetizable stainless steel or the like. It has only a mechanical and sealing, but usually no magnetic function. The sleeve 14 is provided with a shoulder 15, on which on the one hand in the pressure-tight armature space 13 of the conical guide body 9 and on the other hand supported in the outer space of the bobbin 3.

The thus assembled parts can be inserted into an injection mold and held by molding with plastic compound 16 firmly together. In this case, one or more hold-down means are provided in the injection molding device, through which the yoke 5 are pressed onto the cup-shaped housing part 2, so that no interruption of the magnetic flux between the said parts can occur in the magnet assembly 1 thus produced. By embedding in the plastic compound 16 gives a stable magnet assembly 1 with low weight.

In the production of the upper part of the housing by means of the plastic compound 16 created by injection molding a connection flange for the entire magnet assembly 1 can be injected simultaneously, with fastening lugs 17, such as holes for mounting screws, are formed in the plastic mass 18 by appropriate design of the injection mold. A cast-in metal reinforcement 18 in the attachment lugs 17 can increase their stability. In addition to the mechanical fastening lugs 17, a plug 19 for electrical contacting of the excitation coil 4 in the plastic compound 16 is also integrated. This results in a particularly compact design using a minimum of components. Even in an externally vibration-prone continuous operation a stable contention of all cast parts is guaranteed. The plastic compound 16 additionally insulates the current-carrying parts from and to the outside.

With the magnet assembly 1, a control element can be formed, in which the valve slide is no longer formed as a unit with the armature 6 of the magnet assembly 1, but is decoupled from this. As a result, the axial height can be significantly reduced. The valve spool can be acted upon by the plunger 7 in the printing operation against a return spring. To seal the connection between magnet assembly 1 and valve, an O-ring 20 may serve.

According to the invention, the armature 6, the yoke 5 and / or the bearings 24 and 26 and / or the conical guide body 9, which are usually made in a spanender manner of solid material, at least partially be made of an open-pored, magnetically conductive, foam-like material , which is especially media-permeable. This can be achieved, for example, in that these components, the armature 6, the yoke 5 and / or the guide body 9, are created by sintering.

By virtue of the fact that these components obtain an open-pore structure due to the use of a material produced in a sintering process, an internal pressure equalization in the armature space is ensured, which can take place inside the components, without additional bores having to be introduced. Required treads for the anchor 6 can be edited if necessary. The impact speed of the movable armature 6 at its impact surfaces is mainly dependent on the pore size of the porous material used.

As a suitable open-pored, magnetically conductive, foam-like material, for example, the known from a brochure of the company Hoeganaes with the note 0001-AsPA sintered iron-containing material in a phosphorus alloy with the trade name Ancorsteel ^® can be used, which may be provided for use in such magnet ,

In the FIG. 2 a further embodiment of a switchable magnet assembly 21 according to the invention is shown, which may be, for example, a proportional solenoid for camshaft adjustment. The magnetizable cup-shaped housing part 2, the bobbin 3 and the exciter coil 4 can as well as the article according to FIG. 1 be constructed. A cup-shaped magnetizable yoke 22 closes the open cup-shaped housing 2 in the axial direction, wherein the yoke 22 and the cup-shaped housing part 2 are held in the axial direction at a distance. A plunger 23 is held in the center of the cup-shaped magnetizable yoke 22 by a sintered bearing 24 inserted in an opening of a projecting bushing 25. Furthermore, the plunger 23 is guided in a arranged in the center of the cone-shaped guide body 9 abutment 26 made of sintered material. An armature 27 surrounds the plunger 23 and is connected to it for example by welding points. The armature 27 has in its yoke 22 side facing an annular, the plunger 23 surrounded depression, in which engages the protruding bearing bush 25.

In this embodiment of the switchable magnet assembly 21, the plunger 23 is supported only in the cone-shaped guide body 9 and in the yoke 22 in the two sintered bearings 24 and 26. One of the two sintered bearings 24 or 26 is mounted in a sintered yoke 22, made in a sintering process in which iron-containing material is sintered, and wherein the sintered bearing materials used are media-permeable, i. H. Gas and / or liquid are permeable. During the axial stroke of the armature and thus the movement of the plunger 23 of the armature space 13 is changed between the armature 27 and the housing part 2, wherein the pressure in this armature space 13 to possibly changed to the sintered bearing 24 out. By this pumping movement oil can be pumped back and forth, possibly even through the sintered yoke 22 therethrough. It is important to ensure that the porosity of the sintered material may not be particularly large, since certain magnetic properties are required here. The combination of sintered bearings 24 and 26 and sintered yoke 22 results in improved oil lubrication of the sintered bearings 24 and 26, thereby increasing the life. The sintered abutment 26 can store oil in its pores in the contact area with the plunger 23, and thereby ensure oil lubrication of the rod-rod bearing in the first place. The porous sintered yoke 22, however, ensures the exchange of oil from the armature space 13 of the armature 27 to the rear sintered bearing 24. Without this arrangement, the sintered bearing 24 would have only the gap between sintered bearing 24 and anchor rod 23 for the exchange / pressure compensation available.

Due to the embodiments of the switchable magnet assembly according to the invention to obtain a robust bearing having a higher durability due to improved mating a hard piston wall with the sintered bronze. Also, the switchable magnet assembly gets a better hysteresis due to reduced friction of the armature 6 or 27 and / or the plunger 7 or 23.

In addition, you get a solid yoke with improved magnetic efficiency, so that the same magnetic force, the installation height of the magnet can be reduced.

Characterized in that the material of armature 6 or 27, yoke 5 or 22 and / or conical guide body 9 according to the invention is designed to medially permeable, the components receive an open-porous structure, which ensures an internal pressure equalization in the armature space 13. The desired pressure compensation can take place inside the components. Required treads for the anchor 6 or 27 can be edited if necessary.

Since the material itself ensures the desired pressure equalization, expensive and therefore expensive manufacturing processes, such as the introduction of transverse bores, can be dispensed with. An attachment of other components, such as spacers, etc., is still possible, blind hole, in the anchor 6 or 27, in the guide body 9 or yoke 5 or 22 are mounted anti-adhesive discs, can even be created directly in the sintering process itself, so that itself the effort for post-processing reduced.

In particular, with respect to the storage of the projecting from the armature plunger 7 or 23 as an actuating rod, there are significant advantages in the use of the open-pore material. Additional bearings or wear protection layers can be dispensed with, at least for hydraulic applications, since the open-pored structure of the surface allows to store lubricants which can be replenished after consumption from spaces inside the armature 6 or 27, the guide body 9 or the yoke 5 or 22 ,

A material that has been produced in a sintering process, can also be used only in such a way that the armature 6 or 27, the guide body 9 and, if necessary, the yoke 5 or 22 are only partially surrounded by porous material. Dependent on the required pressure compensation and field of application shall be chosen to cover the non-sintered parts.

LIST OF REFERENCE NUMBERS

1.

magnet assembly

Second

cup-shaped housing part

Third

coil carrier

4th

excitation coil

5th

yoke

6th

anchor

7th

tappet

8th.

The End

9th

Guide body (cone)

10th

Flange area of the yoke

11th

recess

12th

border area

13th

armature space

14th

shell

15th

shoulder

16th

Plastic compound

17th

fastening lugs

18th

metal reinforcement

19th

plug

20th

O-ring

21st

magnet assembly

22nd

yoke

23rd

tappet

24th

camp

25th

bearing bush

26th

thrust bearing

27th

anchor

Claims (9)

Switchable magnet arrangement (1, 21) as an actuating element or actuator for a valve or other functional elements with a magnetizable housing, an exciter coil (4) arranged at least partially in the magnetizable housing, one in the bearing (24) axially energized by the excitation coil (4). movable armature (6, 27), which in the direction of actuation of the actuator directed, in a bearing (26) guided axial plunger (7, 23), one of the end sides of the housing final yoke (5, 22) and a other end side of the housing terminating conical guide body (9), wherein the guide body (9) has an axial passage for the plunger (7, 23),
characterized,
that the armature (6, 27) and / or the yoke (5, 22) and / or the conical guide body (9) and / or the bearing (24, 26) is at least surrounded by or surrounds a magnetically conductive, media-permeable material , Switchable magnet arrangement (1, 21) according to claim 1,
characterized,
in that the armature (6, 27) and / or the yoke (5, 22) and / or the conical guide body (9) and / or the bearing (24, 26) consists of the magnetically conductive, material permeable to matter. Switchable magnet arrangement (1, 21) according to claim 1 or 2,
characterized,
that the magnetically conductive, medium-permeable material is an open-pored, magnetically conductive, foam-like material. Switchable magnet arrangement (1, 21) according to claim 3,
characterized,
that the open-pored material is sintered metal. Switchable magnet arrangement (1, 21) according to one of Claims 1 to 4,
characterized,
that the running surfaces of the armature (6, 27) are machined. Switchable magnet arrangement (1, 21) according to one of claims 3 to 5,
characterized,
in that the open-pore, magnetically conductive, foam-like material is a sintered, iron-containing material, possibly mixed with further alloying elements. Switchable magnet arrangement (1, 21) according to one of Claims 1 to 6,
characterized,
in that the switchable magnet arrangement (1, 21) is a proportional magnet. Switchable magnet arrangement (1, 21) according to one of Claims 1 to 7,
characterized,
that it is used as an actuator of a variable throttle for hydraulic, pneumatic and similar systems. Switchable magnet arrangement (1, 21) according to one of Claims 1 to 8,
characterized,
that it is used as a proportional magnet for camshaft adjustment.

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