EP3146207A1

EP3146207A1 - Linear actuator and method for operating such a linear actuator

Info

Publication number: EP3146207A1
Application number: EP15747991.6A
Authority: EP
Inventors: Georg Bachmaier; Marco CYRIACKS; Reinhard Freitag; Andreas GÖDECKE
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2014-07-31
Filing date: 2015-07-20
Publication date: 2017-03-29
Also published as: KR101996661B1; KR20170024060A; CN106662085A; US20170218758A1; US10731464B2; JP2017530287A; JP6452802B2; CN106662085B; DE102014215110A1; WO2016016031A1

Abstract

The linear actuator comprises a double-chamber solenoid pump comprising at least one pump coil, a multi-way valve and at least one pump armature that can be moved by energizing the at least one pump coil and is provided with a switching armature by means of which the multi-way valve can be switched and which can be moved by energizing the at least one pump coil. In the method, both the switching armature and the pump armature are moved by energizing the pump coil.

Description

description

Linear actuator and method of operating such

linear actuator

The invention relates to a linear actuator and a method for operating such a linear actuator. In certain fields of application, for example when adjusting gas valves, when controlling chokes, for positioning drives such as pick & place and other robots, for linear actuators in automation or in the healthcare sector, in particular for patient beds or treatment devices, linear actuators are required that can be used both in the micrometer range are accurate, as well as long strokes of a few centimeters can reach.

It is desirable if such linear actuators are designed as small as possible and, if possible electrical and for a long time ^¬ rooms without wear and robust as possible against widri ^¬ gen environment, in particular pollution,

are operable. In particular, it is desirable if ^such linear actuators are easily interconnectable. So it is necessary in complex actuator configurations to place a variety of linear actuators. Therefore, such a linear actuator should have as few electrical wires or wire connections for electrical connection in order to keep the total number of required lines low.

Linear actuators are known in numerous training courses. For example, stepping motors are known which are sorted ^¬ but often only limited accuracy. Furthermore, pneumatic and hydraulic linear drives are known, which are connected via a two-way valve to a compressed air reservoir or via a hydraulic pump. Even in these embodiments, a precise control is difficult. Furthermore, electrodynamic linear motors are known, which are designed as electric drive ^¬ machine. They are fast and accurate but have a complex structure on a regular basis and are not sufficiently space-efficient. can be trained. Linear actuators based on piezocrystals or magnetostrictive materials, on the other hand, are used in special areas, but are only designed for very small travel distances. Piezo motors based on friction contacts are capable of larger strokes, but are often limited in life and susceptible to environmental influences. Furthermore, artificial muscles based on electrostatic action mechanisms are known, but limited in terms of maximum strength and life.

It is therefore an object of the invention to provide a linear actuator, which is improved against this background of the prior art. In particular, the linear actuator should be as compact as possible be formed and / or be as simple as possible electrically contacted. It is another object of the invention a method for operating such

To provide linear actuator.

This object is achieved with a linear actuator having the features specified in claim 1 and with a method having the features specified in claim 15. Preferred embodiments of the invention will become apparent from the accompanying dependent claims, the following description and the drawings.

The linear actuator according to the invention comprises a solenoid pump, in particular a Doppelkammersolenoidpumpe. Zweckmäßigerwei ^¬ se of the linear actuator according to the invention comprises a hydraulically connected to the solenoid pump hydraulic cylinder, a hydraulic piston having WEL rather. By means of

Solenoid pump, the hydraulic piston in the hydraulic cylinder and be driven out. Advantageously, the linear actuator according to the invention comprises a solenoid pump with the ver ^¬ bundenes reservoir for supply or discharge of hydraulic oil.

According to the invention, in the linear actuator, the solenoid pump has at least one pump coil, a multi-way valve and at least one pump anchor, which by means of energization of at least a pump coil is movable. Furthermore, in the linear actuator according to the invention, the solenoid pump comprises a switching armature, by means of which the multi-way valve can be switched. The switching is in accordance with Inventive ^¬ anchor by means of supplying current to the at least one pumping coil Move ^¬ Lich at the solenoid pump of the linear actuator.

In the linear actuator according to the invention, a bidirectional pump flow can be accomplished by means of the multiway valve. For this purpose, the multiway valve is expediently connected fluidically to the inlet and the outlet of the solenoid pump. For this purpose, the linear actuator according to the invention expediently comprises such a multi-way valve which, in conjunction with the inlet and the outlet of the solenoid pump, enables a bidirectional pump flow. By means of the bidirectional pump flow, the hydraulic piston guided in the hydraulic cylinder can be guided bidirectionally. To change the pump flow direction, the multi-way valve can be switched. Erfindungs ^¬ according to the circuit of the multi-way valve with the

Current supply of the at least one pump coil take place, which is in any case energized to the movement of the at least one pump anchor. In contrast, previously known linear actuators regularly comprise a separate pump and a multi-way valve. For ei ^¬ ne pump and a multi-way valve but each own drive is required, consequently, in each case an electrical control and therefore, at least, a pair of wires. The present invention, however, integrates a solenoid pump and a multi-way valve prematurely in a single device, wherein in particular a magnetic flux used in the invention is used both for operating the pump and at the same time for switching the multi-way valve. When inventive

Linear actuator thus results in a particularly low electrical Verschaltungsaufwand. At the same time can be made with ei ^¬ nem linear actuator with a solenoid pump, a high-precision adjustment, the adjustment is fundamentally ^¬ Lich not limited. Furthermore, solenoid pumps require no large space and can be used over long periods without wear and especially robust against adverse environmental conditions, such as soiling. Due to the extremely low wiring effort, only a few electrical cables or wires or wire connections are required, especially for configurations with several linear actuators.

In particular, only a single pair of electrical wires or a single wire connection pair is required for the linear actuator according to the invention. The cabling effort is therefore low in the linear actuator according to the invention and the reliability is particularly high.

Furthermore, the linear actuator of the present invention uses preferably on ^¬ ask a simple solenoid pump a

Double solenoid pump. In this case, the volume flow does not drop continuously to zero. Accordingly, pulsations in Vo ^¬ volume flow and pressure and the associated disadvantages such as Ge ^¬ räuschbildung, or increased wear by stimulated

Vibrations are avoided.

Advantageously, the solenoid pump, preferably the double solenoid pump, comprises pot magnets. Such solenoids ha ^¬ ben opposite otherwise frequently existing yoke disks the advantage that typically a fluidic damping yoke disks increases disproportionately to the yoke shortly before whipping. Typical solenoid pumps require additional damping devices or operate a special effort to reduce noise and vibration (see, for example, EP1985857). In this development, in which the solenoid pump or

Double solenoid pump comprises pot magnets, such a function mechanism is already integrated advantageous.

Conveniently, in the linear actuator according to the invention, the multi-way valve is a 4/2-way valve or the multi-way valve has a 4/2-way valve. In this way, the pump flow of the solenoid pump is particularly easy to reverse by the input and output of the solenoid pump are connected to the switchable inputs and outputs of the 4/2-way valve. Suitably, with solenoid pump of the linear actuator according to the invention, the multi-way valve can be switched by means of movement of the switching ^¬ anchor. Preferably, this is the multi-way valve with the switching armature motion coupled so that a movement of the switching armature leads to a spatial offset of the inputs and outputs of the multi-way valve relative to the input and output of the solenoid pump of the linear actuator according to the invention. In this way, the multi-way valve can be switched very easily.

Suitably, in the case of the solenoid pump of the linear actuator according to the invention, the pump armature is magnetically flux-coupled or flux-coupled to a pump coil yoke, the switch armature being magnetically flux-coupled or flux-coupled to the pump coil yoke. Due to the magnetic flux coupling or Flußgekoppelheit the Pumpspulenj ochs with the pump anchor on the one hand and on the other with the switching armature can be a movement of the switching armature by energizing the at least one pump coil realize particularly simple.

Advantageously, at least two pump och coils are available, each with a Pumpspulenj at the solenoid pump of the linear actuator according to Inventive ^¬, wherein the pump armature coils between the or between at least two Pumpspulenj ochen is movable. Expediently, in each case one pump coil, each having one pump coil hole and one chamber each, belongs to it

Dual chamber solenoid pump engineered solenoid pump. In a preferred embodiment of the invention

Linear actuator in the solenoid pump at least one flow guiding means is present, by means of which the Pumpspulenj oche are connected to each other flux-conducting. In a further advantageous embodiment of the invention

Linear actuators are integrally formed in the solenoid pump as described above flux guide together with the Pumpspulenj ochen. This development results in a particularly simple structure. In a particularly advantageous further development of the linear actuator according to the invention with the solenoid pump, the flow guiding means, or at least one of the Pumpspulenj comprises eek ei ^¬ NEN permanent magnet or it is attached to the flow director or at least one of a permanent magnet arranged Pumpspulenj eek. In this development of the method according to the invention, the permanent magnet can be taken as the flow generating Ele ^¬ ment, which attenuates or with the at least one pumping coil induced magnetic flux enhanced. In this way, a magnetic degree of freedom for switching can be opened by means of the formwork in which the tanker OF INVENTION ^¬ linear actuator to the invention.

In an expedient development of the linear actuator according to the invention one magneti ^¬ rule flow is at the solenoid pump of the switching armature with ^¬ means of caused by the permanent magnet, in particular guided by the flow guiding means can be fixed. Accordingly, a further degree of freedom is opened for the supply of BEWE ^¬ scarf tanker.

Conveniently, in the Doppelkammersolenoidpumpe of the linear actuator according to the invention, the at least one pump coil is electrically connected and / or the at least one pump coil is arranged such that the ^¬ caused by this magnetic flux that magnetic flux, which has been caused by the at least one permanent magnet, at least in a region of the Flußleit- means and / or counteracts at least one Pumpspulenj ochs ^¬ . In particular, the magnetic flux, which has been at least caused by the ^¬ means of a permanent magnet, are canceled. Accordingly, it is possible to switch by means of the at least one pump coil.

Ideally, the solenoid pump of the linear actuator according to the invention has only a single pair of wires or wire connection pair, by means of which the solenoid pump is electrically connected. In this way, the electrical wiring tion and / or Ansteueraufwand the solenoid pump of the inventions ^{¬ to the} invention linear actuator and thus the wiring complexity of the linear actuator according to the invention significantly reduced. In particular, the single pair of wires or Aderan ^¬ circuit is electrically couple to the at least one contact or the pump coil.

In an expedient development are in the

Solenoid pump of the linear actuator according to the invention at least two pumping coils present, which are formed in Topfmagnetform, wherein expediently the pump anchor and / or the switching ^¬ anchor is guided transversely to the pot bottoms of the pot magnet shape or are movable. Accordingly, a particularly simple and compact spatial structure can be realized.

Advantageously, in the solenoid pump of the Invention ^¬ linear actuator according diodes present, are transferred by means of which positive signal portions of a Toggle lying on the wire pair or wire pair connection signal of a first pumping coil and negative signal parts of a second pump coil to be transmitted.

In the inventive method for operating a

Linear actuator is provided by the energization of the at least one pump coil of the solenoid pump of the switching armature in a vorgese ^¬ Hene position of the position of the multi-way valve and moves while maintaining the intended position by energizing the at least one pump coil of the pump armature. In this way, on the one hand, the switching armature can be made, so that the multi-way valve is set suitable for pump operation, in which position the pump armature is movable and pumps the solenoid pump in the intended direction of operation. In an expedient development of the invention

Method, the at least one pump coil to the movement of the pump armature is energized in terms of amount lower than the movement of the switching armature. About the amplitude of the control of the Consequently, at least one pump coil can be adjusted, if only the pump anchor or also the switching anchor should be moved.

The invention will be explained in more detail with reference to an embodiment shown in the drawing. It zei ^¬ gen:

1 shows a linear actuator according to the invention with a

Doppelkammersolenoidpumpe, which has a multi-way valve for adjusting the pumping direction, which is connected on the one hand with a reservoir and the other with a hydraulic cylinder with a hydraulic piston, schematically in a schematic diagram;

Figure 2, the Doppelkammersolenoidpumpe of the invention

Linear actuator according to Figure 1 schematically in longitudinal ^{¬ section} in a first (A) and a second (B) switching position due to the driving of a first and a second pump coil;

FIG. 3 shows the control of the first and second pump coils schematically in a diagrammatic representation;

4 shows the Doppelkammersolenoidpumpe according to Figure 2 in two

Switch positions of the switching armature schematically in longitudinal section; Figure 5 shows the switching principle of the switching armature in a schematic ^¬ tical representation of Doppelkammersolenoidpumpe according to Figure 2 schematically in longitudinal section;

Figure 6 shows the energization of the first and the second pump coil for controlling the pump armature and the switching armature schematically in diagrammatic representation; Figure 7 shows the linear actuator according to the invention according to Figure 1 schematically in longitudinal section;

Figure 8 shows the electrical wiring of the linear actuator according to Figures 1 and 7 schematically in one

Schematic diagram;

9 shows the input signal for driving the linear actuator and the coil signals according to the wiring of the linear actuator according to Figure 8 in a schematic, dia ^¬ grammatischer representation.

FIG. 10 shows the pump armature of the linear actuator according to the invention. Figure 1 (A) schematically in a perspective view and see the pump anchor gem. Fig. 10

(A) in an arrangement together with a flux guiding means of the linear actuator according to the invention. Fig. 1 schematically in a perspective view;

11 shows an alternative embodiment of a erfindungsge ^¬ MAESSEN linear actuator with a one-piece pump anchor schematically in a schematic diagram and Figure 12 shows a further alternative embodiment of an inventive ^¬ linear actuator schematically in a schematic diagram.

The linear actuator shown in Figure 1 comprises a

Doppelkammersolenoidpumpe 10 with a two-way valve 20, by means of which hydraulic fluid is pumped from a reservoir 30 into a working space of a hydraulic cylinder 40. In the hydraulic cylinder 40, a hydraulic piston 50 is guided linearly movable. By positioning the two-way valve 20 in the respective other switching position, the pump ^¬ direction of the Doppelkammersolenoidpumpe 10 can be reversed, so that hydraulic fluid from the working space of Hydraulikzylin- ders 40 back into the reservoir 30 is pumped. Accordingly, the hydraulic piston 50 is advanced or reset.

The structure of the dual chamber solenoid pump 10 is shown in more detail in FIGS. 2A and 2B: The dual chamber solenoid pump 10 includes two pumping coils 60 and 70. The pumping coils 60 and 70 are each in the form of a pot magnet. Between the pumping coil 60 and 70, a magnetic pumping anchor 80 is located, which is guided in the direction 90 perpendicular to the pot bottom planes of the pumping coils 60, 70. The pump armature 80 comprises two soft magnetic perforated disks 100, 110, which are connected by a non-magnetic connecting tube 120 with ^¬ each other, which extends with its Längserstre ^¬ is discovered in the direction 90 perpendicular to the cup bottom levels of the pumping coil 60, 70th The perforated plates 100, 110 are each suspended freely oscillating on membranes 130, limit the per ^¬ weils hydraulic chambers 140, 150 and seal.

The hydraulic chambers 140 and 150 have feeds 160, 170, which in each case on both sides of the pumping anchor 80 via

Check valves 180, 190 open into the hydraulic chambers 140, 150. Furthermore, the hydraulic chambers 140, 150 have designs 200, 210, which execute from the hydraulic chambers 140, 150 via check valves 220, 230. The feeders 160, 170 and the embodiments 200, 210 are each merged on the input and output sides to form a common inlet 240 and a common outlet 250.

At the inner radius of the soft magnetic perforated disks 100, 110, the hydraulic chambers 140, 150 are sealed by a nonmagnetic pipe 260, on which the pump armature 80 slides back and forth.

The pumping action is illustrated in Figure 3 actuation of the pumping coil 60, 70 is moved (as shown per ^¬ weils the current I of the current supply to the left pumping coil 60 (curve EK) or the right pumping coil 70 (curve CC) over time t ): Alternately, either the left pump coil 60 or the right pump coil 70 is energized. As a result of the magnetic

Reluctance principle, so the effort to properly close the magnetic flux, the pump armature 80 is alternately pulled to the left or to the right. The arrows 270, 280 form the underlying magnetic flux through the respective pumping coil 60, 70 partially circumferentially surrounding pump ^¬ coil yoke 290, 300 from which each of the pumping coil 60, 70 on its, by the other pumping coil 70, 60 abgewand ^¬ th sides , each partially surrounds. By the movement of the pump armature 80 to the left or to the right, the interim ^¬ rule pumping coil 60, 70 and pump armature 80 is reduced located hydrauli cal ^¬ volume alternately and enlarged. This hydraulic volume with hydraulic fluid, in the exemplary embodiment illustrated Darge ^¬ silicone oil or Glitzerin, ge ^¬ filled. The pulsating pressure changes thus result in a unidirectional flow of the hydraulic oil from the inlet 240 to the outlet 250.

In order to change the direction of the unidirectional flow, as shown in Figure 1, a two-way valve 20 is provided in the form of a 4/2-way valve, which is moved by a switching ^¬ anchor 310 and thus switched. The switching armature 310 is integrated into the dual chamber solenoid pump 10 as shown in Figure 4:

In the center in the direction 90 perpendicular to the pot bottom planes, a non-magnetic guide rod 320 is guided through the non-magnetic tube 260. This nichtmagneti ^¬ cal guide rod 320 can in the direction 90 perpendicular to the pot bottom planes, in the illustration in Figure 4 horizontally, slide. On the non-magnetic guide rod 320, a switching armature 310 of soft magnetic material is attached. To the switching armature 310 in the horizontal direction, ie in

Direction 90, pump coil yoke 290 and pump coil yoke 300 are radially remote from the nonmagnetic connection tube 120 in the horizontal direction 90 via a flux guide. tel 330 connected. In the radial direction, the flux guide 330 has projections 340 which extend radially in the direction of the non-magnetic connecting tube 120. At their inner radial end, a radially extending bar magnet 350 is fixed to the protrusion 340. Further, the switching armature 310 corresponding Before ^¬ cracks 360 that extend in the horizontal direction so far on the switching armature 310 along that they always overlap 360 in the horizontal direction nor with the radially inwardly directed projections 340 of the flow guiding means 330, when the switching armature 310 to the left or the right Pumpspulenjoch 290 och 300 abuts Pumpspulenj (Figu ^¬ ren 4A and 4B). When the switching armature 310 is in the left-hand position as shown in FIG. 4A, the magnetic flux of the bar magnet 350 is guided mainly through the (minimum) air gap through the left pump coil yoke 290 due to the lower magnetic reluctance on that side , As a result, a holding force is generated there, which holds the switching armature 310 in this position. Analogously, according to Figure 4B, the switching armature is held in the right position, that is, both in the left position of the switching armature 310 and in the right position of the switching armature 310, the switching armature 310 is held in its respective position.

In order to move the switching armature 310 from one position to the next position, as shown in FIG. 6, a high current signal HSS is used for a short time. By way of example, it will now be explained how the switching armature 310 is moved to the right by means of this short-time high current signal HSS:

The right pump coil 70 is briefly acted upon by a high current signal HSS. As a result of this current signal HSS, the temperature of the right-hand pump coil 70 increases for a short time (ie, the pump coils 60, 70 are not actually designed for longer operating periods for currents as high as those achieved in the current signal HSS). Alternatively, in further, not specifically illustrated embodiments For example, pumping coils 60, 70 may be designed for such high currents.

Therefore, before resuming the normal pumping sequence (see also Figure 4), the right pumping coil 70 may degas during a short wait.

The magnetic behavior during the switching process is shown in FIG. 5: Although the high current initially causes the pump armature 80 to be pulled to the side of the right-hand pump coil 70, as well as in the pumping sequence. However, the energization of the pump coil 70 is so high that the magnetic circuit through the right Pumpspulenj och 300 and the pump armature 80 (the right pump coil 70 circumferentially surrounding thin arrows 400) rapidly supersaturated. The magnetic flux will therefore also flow via the flux guide 330 of the bistable actuator. Gestri ^¬ chelt is the magnetic flux F shown, the opposite to the flow of the bar magnet 350 on the holding side of Schaltan ^¬ kers 310 flows. By a suitable choice of the current amplitude during the energization of the pump coil 70, it can be achieved that the flow of the pump coil 70 is the same as the magnetic flux F of the bar magnet 350. As a result, the holding force of the switching armature 310 is effectively canceled. On the other hand flows (thick, solid), a magnetic flux 410 via the large air gap 360 to the right of the switching armature 310. This flow generates an attractive force that pulls the Schaltan ^¬ ker 310 finally to the right. Then the power can be turned off and the switching armature 310 remains stable through the flow path shown in Figure 4B.

A switching process is thus characterized by a short overshoot

Energization, ie initiated by a short-term current signal HSS with excessive amplitude. The Gesamtaktor is finally connected according to the schematic diagram in Fig. 1. Together with the intended two-way valve 20, this is shown schematically in Fig. 7, which corresponds to FIG. 1. In order to transmit the current signals, which act on two pumping coils (pumping coil 60 and pumping coil 70) as shown in FIGS. 3 and 6, via a single pair of wires, the circuit shown in FIG. 8 is used: A signal source SQ supplies a single input signal ES with positive and negative Sig ^¬ nalkomponenten. The linear actuator comprises two diodes D1, D2, by means of which the positive signal component EK is switched to the pump coil 60 and the negative signal component ZK to the pump coil 70. This is shown by way of example in FIG. 9.

The split pump armature as shown in FIG. 2 80 be ^¬ is of two magnetic perforated disks 100, 110 and a non-magnetic connecting pipe 120. For stability reasons, the connection of the two perforated discs 100 carried 110 with further stabilizing connection parts 500, which in addition to the non-magnetic Connecting tube 120 are arranged as supporting cylindrical elements between the perforated discs 100, 110.

The protrusions shown in Fig. 4 340 Flussleitmit- means of 330 lying between the perforated plates 100, 110 and need as in Fig. 10 (B) is not necessary rotationally be executed metric, but may be about from 4 gegenei ^¬ Nander at a right Angle staggered directions radially project on the non-magnetic connecting tube 120.

. As shown in Figure 11, a two-part armature can also be completely avoided: for example, the pump armature can be realized ^λ 80 ^λ is the only washer 100 hole. However, then the pump anchor must be performed 80 ^x at the inner radius, for example ^¬ here by another bellows. Then, however, the magnetic flux can be led out only "backwards" from the pump coils 60 70 ^λ in the direction of the bistable switching armature 310 ^λ . Therefore, here is a magnetic bottleneck ENG ^¬ built. The linear actuator according to the invention is formed to be thin and elongate, that is "pin-like" in a further embodiment. As shown in Fig. 12 are used instead of welded bellows Längsbälge LB, and the two-part pump armature 80 ^{λ λ} is both at the inner radius and the outer radius with the longitudinal ^¬ bellows LB mounted. the guide is implemented using a plurality of non magnetic ^¬ diagram guide rods FS. Otherwise, the structure, in particular magnetically, completely identical to Figure

Claims

claims

1. linear actuator,

comprising a solenoid pump (10), in particular a

Doppelkammersolenoidpumpe (10), with at least one pump coil (60, 70), a multi-way valve (20), at least one Pumpan ^¬ ker (80), which is movable by energizing the at least one Pumpspu ^¬ le (60, 70) and with a switching armature (310), by means of which the multi-way valve (20) is switchable and which by means of energization of the at least one pump coil (60, 70) is movable.

2. Linear actuator according to claim 1,

in which the multi-way valve (20) is or has a 4/2-way valve.

3. Linear actuator according to one of the preceding claims, wherein the multi-way valve (20) by means of movement of the switching armature (310) is switchable.

4. linear actuator according to one of the preceding claims, wherein the pump armature (80) with a Pumpspulenj och (290, 300) is magnetically flux-coupled or flux-coupled in the solenoid pump (10), wherein the switching armature (310) with the pump spool yoke (290, 300 ) is magnetically flux-coupled or flux-coupled.

5. Linear actuator according to one of the preceding claims, wherein the solenoid pump (10) at least two pumping coils (60, 70) each having a Pumpspulenj och (290, 300), where ^¬ in the pump coil armature (80) between or between at least two Pump coil yoke (290, 300) is movable.

6. Linear actuator according to one of the preceding claims, wherein in the solenoid pump (10) at least one flow-guiding means (330) is present, by means of which the Pumpspu ^¬ lenjoche (290, 300) are flux-conductively connected.

7. Linear actuator according to one of the preceding claims, wherein the solenoid pump (10) flux guide (330) and pump ^¬ coil yokes (290, 300) are integrally formed with each other.

8. linear actuator according to any one of the preceding claims, wherein the solenoid pump (10), the flow guiding means (330) or at least one of the Pumpspulenj eek (290, 300) comprises a Perma ^¬ mag- nets (350) or on said at least one per- manentmagnet (350) is arranged.

9. Linear actuator according to one of the preceding claims, wherein the solenoid pump (10) of the switching armature (310) by means of one of the permanent magnet (350) caused, in particular by the flux (330) guided magnetic flux can be fixed.

10. Linear actuator according to one of the preceding claims, wherein the solenoid pump (10) the at least one pump coil (60, 70) is electrically connected and / or arranged such that thereby caused this magnetic flux to that which by the at least one permanent magnet (350) has been caused, at least in a region of the Flußleitmittels (330) and / or counteracts at least one Pumpspulenj ochs (290, 300).

11. Linear actuator according to one of the preceding claims, whose solenoid pump (10) has only a single pair of wires, by means of which the solenoid pump (10) is electrically connected.

12. Linear actuator according to one of the preceding claims, wherein the solenoid pair (10), the single pair of wires is electrically contacted on the at least one or the pumping coils (60, 70).

13. Linear actuator according to one of the preceding claims, in whose solenoid pump (10) at least two pumping coils (60, 70) are provided, which are formed in Topfmagnetform, expediently the pump armature (80) and / or the

Switching armature (310) is guided transversely to the pot bottoms of the pot magnet shape movable / are.

14. Linear actuator according to one of the preceding claims, in whose solenoid pump (10) diodes (D1, D2) are present, by means of which positive signal parts of a signal applied to the wire pair or wire pair pair signal of a first (60) of

Pump coils (60, 70) are transmitted and negative Signaltei ^¬ le a second (70) of the pump coils (60, 70) are transmitted.

15. A method for operating a linear actuator according to one of the preceding claims,

in which by means of energization of the at least one pump coil (60, 70) of the switching armature (310) in an intended position to the position of the multi-way valve (20) is provided and while maintaining the intended position by energizing the at least one pump coil (60, 70) of the pump armature (80) is moved.

16. Method according to the preceding claim,

in which the at least one pump coil (60, 70) for the movement ^{¬ movement of} the pump armature (80) is energized less in amount than to move the switching armature (310).