EP3026680A1 - Linear actuator and use of same - Google Patents

Abstract

The invention relates to a linear actuator, the at least one magnetic elastomer composite of an elastomer and magnetizable particles and an inner and an outer yoke and at least one coil and / or at least one permanent magnet or at least one switchable hard magnet for generating at least one magnetic circuit, the one Interruption contains. The linear actuator is used for the controlled movement, adjustment or adjustment of a wide variety of objects, as well as for the generation of movement in robots as well as for tactile tactile elements.

Description

The invention relates to a linear actuator, the at least one magnetic elastomer composite of an elastomer and magnetizable particles and an inner and an outer yoke and at least one coil and / or at least one permanent magnet or at least one switchable hard magnet for generating at least one magnetic circuit, the one Interruption contains. The linear actuator is used for the controlled movement, adjustment or adjustment of a wide variety of objects, as well as for the generation of movement in robots as well as for tactile tactile elements.

In many technical systems, linear motion is to be electrically controlled over a relatively short distance. Such a requirement arises, for example, when adjusting flaps or optical elements such as mirrors or lighting elements. Another application for such linear drives for short distances concerns the locking or unlocking of Doors, windows, etc. Even in robotics, such linear movements occur when, for example, an object is to be gripped and subsequently positioned (pick and place). Finally, more and more actuators are desired for human-machine interfaces with haptic feedback, in which a movement can be sensed with the fingers on a user interface, which provides the user with information z. B. mediated by a successful input.

For these applications, actuators are needed that perform a linear movement over a relatively short distance of a few millimeters or centimeters. As a rule, the path of the movement to be covered should be flexible and precise. The stroke of such a linear actuator should thus be electrically controlled.

For adjusting mirrors or flaps electric motors are usually used, which initially generate a rotational movement, which is then translated via a gear in a linear movement. This requires a relatively high technical effort for a relatively simple movement. An alternative is the use of electromagnetic actuators (voice coil). However, these are difficult to control and thus limited in their positioning accuracy. Although piezo actuators can position very precisely and also generate large forces, the travel ranges for the mentioned applications are too small. In order to use piezoelectric actuators for this, displacement amplifiers must be integrated, which significantly increases the effort. In addition, piezo actuators alone are already expensive and also require relatively high electrical drive voltages.

Because of this situation, there is a great need for new actuators that can perform the stated task of precisely controlled linear motion over a distance of a few millimeters or centimeters. The present invention solves the problem with the aid of magnetically controllable materials, so-called magneto-active polymers.

Magneto-active polymers (MAP) are composite materials made of an elastomer matrix filled with magnetic or magnetizable particles. For this reason, they are referred to below as magnetic elastomer composites. When applying a magnetic field, it comes on the one hand to a reversible stiffening of the material. On the other hand, deformation of the magnetic elastomer composite along the field lines occurs in the magnetic field. Will enter the air gap between two Magnetjochteilen Magnetic field generated, so pulls a magnetic Elastomerkomposit that does not bridge the gap in the unmagnetized state, in the length, so now takes a bridging. This effect is already known.

For the realization of a linear actuator, however, this movement is not well suited as a result of the deformation, since the magnet yoke parts make both sides of the magnetic elastomer composite inaccessible and the movement difficult to control. Furthermore, it is known that an annular elastomeric elastomer composite radially expand in an inner or outer annular gap between an inner and an outer yoke of a magnetic circuit and thus can close the annular gap. In this way, annular valves can be realized. Another use of this radial expansion of magnetic elastomer composites in the magnetic field is in electrically controllable locking and releasing devices. Such a device is described in the patent DE 2012 202 418 described.

With the known from the prior art deformation mechanisms of magnetic elastomer composites in the magnetic field can not produce precisely controllable linear movements.

Proceeding from this, it was an object of the present invention to provide a linear actuator with which a precisely controllable linear movement is executable, the path to be covered should be flexibly predetermined and precisely executed, so that the stroke of the linear actuator is electrically controlled.

This object is achieved by the linear actuator with the features of claim 1. The other dependent claims show advantageous developments. Uses according to the invention are specified in claims 14 and 15.

According to the invention, a linear actuator comprising at least one magnetic elastomer composite containing at least one elastomer and magnetizable particles is provided. Furthermore, the linear actuator includes an inner and an outer yoke and at least one coil and / or at least one permanent magnet or at least one switchable hard magnet for generating at least one magnetic circuit having an interruption. The magnetic elastomer composite is deformable when applying or changing the magnetic field such that a linear actuator movement is triggered and the distance of the actuator movement through the The strength of the magnetic field is continuously and / or reversibly controllable.

The invention therefore provides a linear actuator which enables such a precisely controllable linear movement. For this purpose, a linear actuator is described with a special magnetic circuit in which a magnetic elastomer composite is attracted by the magnetic circuit lying on one side, while the other side of the magnetic Elastomerkomposits is freely accessible. Due to the magnetic attraction, the magnetic elastomer composite deforms, whereby the deformation and thus also the Aktorstellweg increase with increasing magnetic field strength or magnetic flux density. When switching off the magnetic field or reducing the magnetic field strength of the magnetic elastomer composite deforms back. The elastomer acts as an inherent return spring.

The magnetic elastomer composite may take various forms in the linear actuator.

A preferred embodiment of the invention provides that the magnetic elastomer composite is disc-shaped and the magnetic field is aligned substantially perpendicular to its base surface and the deformation of the magnetic elastomer composite in the form of a curvature of the magnetic elastomer composite dictates the direction of the actuator movement. The disk-shaped magnetic Elastomerkomposit is connected, for example, with a largely closed cylindrical magnetic circuit of a coil, an inner and an outer yoke. In this case, the outer yoke, on which the magnetic elastomer composite rests, protrudes. When the magnetic field is switched on, the middle part of the magnetic elastomer composite is attracted to the inner yoke, causing the deformation. When switching off the magnetic field, a recovery of the disc-shaped magnetic Elastomerkomposits. The strength of the magnetic field determines the degree of deformation.

In another preferred embodiment, the inner yoke protrudes and the magnetic elastomer composite rests thereon. In this case, when the magnetic field is switched on, the outer part of the magnetic elastomer composite is attracted to the outer yoke, resulting in a corresponding deformation. When the magnetic field is switched off, a reverse deformation of the disc-shaped magnetic elastomer composite takes place here as well. The strength of the magnetic field in turn determines the Degree of deformation.

A further preferred embodiment provides that the magnetic elastomer composite is substantially disk-shaped and has a larger or smaller pane thickness toward the center of the pane, in particular in the form of an outward or inward curvature on the side facing the inner yoke, wherein the Slice thickness changes steadily or gradually. It is preferred that the inner yoke has a concave or convex curvature substantially corresponding to the disc shape. The shape matching between the elastomer composite and the inner yoke enhances the actuation force.

It is further preferred that the magnetic elastomer composite with at least one mechanical and / or hydraulic element, in particular selected from the group consisting of a rod, a stamp, a thread, a hydraulic fluid, a bag filled with liquid or gas and combinations thereof, via which the deformation in a linear movement of the linear actuator is transferable.

The linear actuator preferably has a coil or a coil and a permanent magnet or a coil and a switchable hard magnet.

The magnetic elastomer composite preferably contains as matrix material at least one elastomer which is preferably selected from the group consisting of silicone, fluorosilicone, polyurethane (PUR), polynorbornene, natural rubber (NR), styrene-butadiene (SBR), isobutylene-isoprene (IIR), Ethylene-propylene-diene terpolymer (EPDM / EPM), poly-chlorobutadiene (CR), chlorosulfonated polyethylene (CSM), acrylonitrile-butadiene (NBR), hydrogenated acrylonitrile-butadiene (HNBR), a fluororubber such as Viton, a thermoplastic elastomer such as styrene-styrene thermoplastic copolymers (styrene-butadiene-styrene (SBS), styrene-ethylene-butadiene-styrene (SEBS), styrene-ethylene-propylene-styrene (SEPS), styrene-ethylene-ethylene-propylene) Styrene (SEEPS) or styrene-isoprene-styrene (SIS) copolymer), partially crosslinked polyolefin-based blends (of ethylene-propylene-diene rubber and polypropylene (EPDM / PP), of nitrile-butadiene rubber and Polypropylene (NBR / PP) or of ethylene-propylene-diene rubber and polyethylene (EPDM / PE )) or thermoplastic urethane copolymers (aromatic hard segment and ester soft segment (TPU-ARES), aromatic hard segment and ether soft segment (TPU-ARET) or aromatic hard segment and ester / ether soft segment (TPU-AREE)) and mixtures, blends or alloys thereof.

Preferred magnetic particles are particles selected from the group consisting of iron, in particular carbonyl iron, cobalt, nickel, iron alloys, in particular iron-cobalt alloys or iron-nickel alloys, iron oxides, in particular magnetite or ferrite, preferably manganese zinc ferrite, aluminum-nickel alloys. Cobalt alloys and mixtures thereof selected. The average size of the magnetic particles is preferably less than 100 microns.

In a further variant according to the invention, the magnetic elastomer composite according to the invention preferably contains magnetizable elements or shaped bodies which differ from the magnetizable particles, the size of the elements or shaped bodies preferably exceeding the size of the particles by a factor of 10, particularly preferably by a factor of 100 , These magnetizable elements enhance the magnetic attractive forces on the magnetic elastomer composite. Alternatively, several or many magnetizable elements may be secured in or on the magnetic elastomer composite. The magnetizable element or elements may be made of soft magnetic materials, in particular iron, preferably carbonyl iron, cobalt, nickel, iron alloys, preferably iron-cobalt alloys or iron-nickel alloys, iron oxides, preferably magnetite or ferrite, particularly preferably manganese zinc ferrite, or hard magnetic materials, in particular aluminum-nickel-cobalt, neodymium-iron-boron or samarium-cobalt or mixtures thereof.

The magnetic elastomer composite may also consist of a bellows with concentric folds. By unfolding the deformation in the magnetic field is facilitated. Another possibility is that the disk-shaped magnetic elastomer composite on one side has a bulge. In this way, there is a stronger magnetic attraction in the magnetic field. In addition, the inner yoke and / or the coil may have a complementary concavity into which the bulge of magnetic elastomer composite moves. In this way, a stronger deformation movement of the magnetic Elastomerkomposits take place.

The deformation of the magnetic Elastomerkomposits in the magnetic field can be used directly as a linear movement. In this case, when the magnetic field is turned on, the actuation takes place inwardly from the outside of the magnetic elastomer composite. However, the deformation movement can be transferred by a mechanical transfer to the other side of the magnetic circuit. For transmission, for example, a rod or a punch is inserted, which is passed through the inner yoke. Alternatively, this can also be a hydraulic medium can be used, which transmits the movement of the magnetic Elastomerkomposits to the other side of the magnetic circuit. The mechanical transmission can alternatively be done by the outer yoke.

The magnetic field for driving the magnetic elastomer composite is usually generated by a coil. However, the magnetic circuit may also include a permanent magnet which generates a magnetic field without electrical energy. An additional coil can then either selectively weaken or even compensate or amplify this magnetic field. By the permanent magnet in this way a basic setting of the linear actuator is defined with a certain deformation of the magnetic Elastomerkomposits. By the compensation of the magnetic field of the permanent magnet through the coil so the switching behavior with respect to a magnetic circuit is reversed only with coil. Preferably, the permanent magnet is made of neodymium-iron-boron or samarium-cobalt.

It is also possible to integrate a switchable hard magnet in the magnetic circuit. In this case, the hard magnet is provided with a permanent magnetization by a magnetic field generated by the coil for a short time. In this way, the magnetic elastomer composite is deformed and the linear actuator moves to a defined position. In this arrangement, electrical energy is needed only for changing the actuator position by giving the switchable hard magnet another magnetization. Preferably, the switchable hard magnet made of aluminum-nickel-cobalt or a ferrite. For the switchable hard magnet, materials with a coercive force of less than 100 kA / m and a saturation magnetization of more than 600 mT are preferred.

Finally, the linear actuator can also have two magnetic circuits, which can be electrically controlled separately. In this case, the magnetic elastomer composite is preferably between the two magnetic circuits and may optionally be from one or the other magnetic circuit be attracted. Since there is no accessibility from the outside, the movement of the magnetic Elastomerkomposits will be transferred by the already shown mechanical or hydraulic transmission to the outside.

In another embodiment, the magnetic elastomer composite may be used to control a property change by a linear actuator movement, which property change, for example, results in a change in a surface structure. The change in the structure of the at least one surface causes the surface to transform into a control surface. An activation signal generates a magnetic field via a coil, as a result of which the magnetic elastomer composite is changed in its shape and a control surface becomes visible. By deactivating the magnetic field, the magnetic elastomer composite returns to its original shape, with the operating surface reverting to the initial surface. This reversible moldable surfaces for covering, for example, switches, sensors, controls, etc. are possible.

The linear actuators according to the invention are used for controlled movement, adjustment or adjustment of flaps, doors, mirrors, optical elements, in particular radiation sources. Likewise, the linear actuators can be used to generate movements in robots as well as tactile tactile elements.

Reference to the embodiments illustrated in the following figures, the subject invention is to be explained in more detail, without wishing to limit this to the specific embodiments shown here.

Magnetischer Stahl, Jochteil 1

Hydraulisches Medium 2

Magnetischer Elastomerkomposit 3

Spule, Elektromagnet 4

Magnetfeld 5

Permanentmagnet 6

Unmagnetisierter Hartmagnet 7

Magnetisierter Hartmagnet 8

Nicht-magnetisches Material 9 In the following legend, the components shown in the individual figures are designated. Figure component description reference numeral

Magnetic steel, yoke part 1

Hydraulic medium 2

Magnetic elastomer composite 3

Coil, electromagnet 4

magnetic field 5

permanent magnet 6

Unmagnetized hard magnet 7

Magnetized hard magnet 8th

Non-magnetic material 9

Fig. 1

einen Linearaktor mit Verformung von magnetischem Elastomerkomposit im Magnetfeld

Fig. 2

einen Linearaktor mit Verformung von magnetischem Elastomerkomposit im Magnetfeld, wobei das Innenjoch länger als das Außenjoch ist und sich der magnetische Elastomerkomposit durch die Anziehung zum Außenjoch verformt

Fig. 3

einen Linearaktor mit Magnetkreis mit Spule und mit Auswölbung auf magnetischem Elastomer-Komposit

Fig. 4

einen Linearaktor mit Magnetkreis mit Spule und mit Auswölbung auf magnetischem Elastomer-Komposit sowie Einwölbung in Magnetinnenjoch

Fig. 5

einen Linearaktor mit Verformung von magnetischem Elastomerkomposit im Magnetfeld und Übertragung der Bewegung auf Membran durch hydraulische Flüssigkeit

Fig. 6

einen Linearaktor mit Verformung von magnetischem Elastomerkomposit im Magnetfeld und Übertragung der Bewegung durch hydraulische Flüssigkeit und Stempel

Fig. 7

einen Linearaktor mit Verformung von magnetischem Elastomerkomposit im Magnetfeld und Übertragung der Bewegung auf Membran durch hydraulische Flüssigkeit; magnetischer Elastomerkomposit enthält magnetischen Formkörper

Fig. 8

einen Linearaktor mit Verformung von magnetischem Elastomerkomposit im Magnetfeld und Übertragung der Bewegung durch hydraulische Flüssigkeit und Stempel; magnetischer Elastomerkomposit enthält magnetischen Formkörper

Fig. 9

einen Linearaktor mit magnetischem Elastomerkomposit als Faltenbalg, der sich durch das Magnetfeld entfaltet; Übertragung der Bewegung auf Membran durch hydraulische Flüssigkeit

Fig. 10

einen Linearaktor mit magnetischem Elastomerkomposit als Faltenbalg, der sich durch das Magnetfeld entfaltet; Übertragung der Bewegung durch hydraulische Flüssigkeit und Stempel

Fig. 11

einen Linearaktor mit Elektromagnet und schaltbarem Hartmagnet in Magnetkreis; Verformung von magnetischem Elastomerkomposit im Magnetfeld und Übertragung der Bewegung auf Membran durch hydraulische Flüssigkeit

Fig. 12

einen Linearaktor mit Elektromagnet und schaltbarem Hartmagnet in Magnetkreis; Verformung von magnetischem Elastomerkomposit im Magnetfeld und Übertragung der Bewegung durch hydraulische Flüssigkeit und Stempel

Fig. 13

einen Linearaktor mit Elektromagnet und Permanentmagnet in Magnetkreis; Verformung von magnetischem Elastomerkomposit im Magnetfeld

Fig. 14

einen Linearaktor mit Auswölbung von magnetischem Elastomerkomposit und Einwölbung von Magnetkreis einschließlich Elektromagnet auf der zum magnetischen Elastomerkomposit hinweisenden Seite; Übertragung der Bewegung durch Stempel

Fig. 15

einen Linearaktor mit Auswölbung von magnetischem Elastomerkomposit und Einwölbung von Magnetkreis einschließlich Elektromagnet auf der zum magnetischen Elastomerkomposit hinweisenden Seite; magnetischer Elastomerkomposit enthält magnetischen Formkörper; Übertragung der Bewegung durch Stempel.

Fig. 16

einen Linearaktor, bei dem sich der magnetische Elastomerkomposit zwischen zwei Jochteilen befindet, sich im Magnetfeld ausdehnt und dabei die Bewegung durch einen Stempel durch das Innenjoch nach außen überträgt.

The figures show:

Fig. 1

a linear actuator with deformation of magnetic elastomer composite in the magnetic field

Fig. 2

a linear actuator with deformation of magnetic elastomer composite in the magnetic field, wherein the inner yoke is longer than the outer yoke and deforms the magnetic Elastomerkomposit by the attraction to the outer yoke

Fig. 3

a linear actuator with magnetic circuit with coil and with bulge on magnetic elastomer composite

Fig. 4

a linear actuator with magnetic circuit with coil and with bulge on magnetic elastomer composite and concavity in Magnetinnenjoch

Fig. 5

a linear actuator with deformation of magnetic elastomer composite in the magnetic field and transmission of the movement to diaphragm by hydraulic fluid

Fig. 6

a linear actuator with deformation of magnetic elastomer composite in the magnetic field and transmission of movement by hydraulic fluid and plunger

Fig. 7

a linear actuator with deformation of magnetic elastomer composite in the magnetic field and transmission of the movement to diaphragm by hydraulic fluid; magnetic elastomer composite contains magnetic shaped body

Fig. 8

a linear actuator with deformation of magnetic elastomer composite in the magnetic field and transmission of movement by hydraulic fluid and piston; magnetic elastomer composite contains magnetic shaped body

Fig. 9

a linear actuator with magnetic elastomer composite as a bellows, which unfolds through the magnetic field; Transfer of movement to diaphragm by hydraulic fluid

Fig. 10

a linear actuator with magnetic elastomer composite as a bellows, which unfolds through the magnetic field; Transmission of movement by hydraulic fluid and piston

Fig. 11

a linear actuator with electromagnet and switchable hard magnet in magnetic circuit; Deformation of magnetic elastomer composite in the magnetic field and transfer of movement to membrane by hydraulic fluid

Fig. 12

a linear actuator with electromagnet and switchable hard magnet in magnetic circuit; Deformation of magnetic elastomer composite in the magnetic field and transmission of movement by hydraulic fluid and plunger

Fig. 13

a linear actuator with electromagnet and permanent magnet in magnetic circuit; Deformation of magnetic elastomer composite in the magnetic field

Fig. 14

a linear actuator with a protrusion of magnetic elastomer composite and a doming of magnetic circuit including electromagnet on the side facing the magnetic elastomer composite; Transmission of the movement by stamp

Fig. 15

a linear actuator with a protrusion of magnetic elastomer composite and a doming of magnetic circuit including electromagnet on the side facing the magnetic elastomer composite; magnetic elastomer composite contains magnetic shaped body; Transmission of the movement by stamp.

Fig. 16

a linear actuator, in which the magnetic elastomer composite is located between two yoke parts, expanding in the magnetic field, thereby transmitting the movement through a punch through the inner yoke to the outside.

embodiments

The first embodiment shows a linear actuator with a magnetic circuit with a coil. The outer yoke on which the magnetic elastomer composite rests is longer than the inner yoke, whereby the magnetic circuit between the inner yoke and the disc-shaped magnetic elastomer composite has an interruption ( FIG. 1 , Left). When a current is applied in the coil, a magnetic field is generated by which the magnetic elastomer composite is attracted to the inner yoke and deforms ( FIG. 1 , right). The amount of deformation is continuously controllable by the strength of the applied magnetic field across the coil current. When the magnetic field is switched off, the magnetic elastomer composite is restored to its original form.

In the second embodiment, the outer yoke is shorter than the inner yoke. As a result, the disc-shaped magnetic elastomer composite rests on the inner yoke (FIG. FIG. 2 , Left). Upon application of the magnetic field, the magnetic elastomer composite is attracted to the outer yoke and deforms accordingly ( FIG. 2 , right).

The third Ausführungsbespiel again shows a linear actuator with a shorter inner yoke. Here, the magnetic elastomer composite on the inner yoke side facing a bulge on FIG. 3 , Left). When the magnetic field is applied, the magnetic elastomer composite is attracted by the inner yoke with a stronger force than without a bulge. The amount of deformation, on the other hand, is limited by the bulge ( FIG. 3 , right).

In the fourth embodiment, the inner yoke has a concavity which is complementary to the bulge on the magnetic elastomer composite ( FIG. 4 , Left). When the magnetic field is applied, therefore, the bulge on the magnetic elastomer composite can penetrate into the indentation in the inner yoke ( FIG. 4 , right).

The fifth embodiment shows a linear actuator with a shorter inner yoke, which is traversed by a channel which is sealed at the upper end by a membrane. The space between the magnetic elastomer composite and the inner yoke and the channel are filled with a hydraulic fluid ( FIG. 5 , Left). When the magnetic field is applied, the magnetic elastomer composite deforms in the direction of the inner yoke, displacing the hydraulic fluid from the intermediate space. The hydraulic fluid is pushed upwards through the channel, deforming the upper membrane ( FIG. 5 , right).

In the sixth embodiment, the channel is only partially filled with a hydraulic fluid. Above the liquid surface there is a rod ( FIG. 6 , Left). When the magnetic field is applied, the hydraulic fluid pushes the rod up and out of the yoke ( FIG. 6 , right).

The embodiment according to Fig. 7 shows how the fifth embodiment, a linear actuator in which the deformation of the magnetic Elastomerkomposits is transmitted by a hydraulic fluid upwards. By a magnetic magnetic steel magnetic body attached to the underside of the magnetic elastomer composite, the attraction force on the inner yoke is greatly increased. Thereby Also increases the pressure exerted on the hydraulic fluid pressure and thus the Aktuationskraft accordingly.

In the embodiment according to Fig. 8 Also, a magnetic molding is attached to the magnetic elastomer composite to enhance the actuation force. Here, however, the force is first transmitted hydraulically and then via a rod, as in the sixth embodiment.

In the ninth embodiment, the magnetic elastomer composite has the form of a bellows ( FIG. 9 , Left). When the magnetic field is applied, the bellows unfolds and pushes up a hydraulic fluid, which in turn deforms a diaphragm.

In the execution example according to Fig. 10 the hydraulic fluid is partially replaced by a rod again.

In the eleventh embodiment, the magnetic circuit includes, in addition to the electromagnet, an annular switchable hard magnet made of an aluminum-nickel-cobalt alloy, which is initially not magnetized ( FIG. 11 , Left). When generating a magnetic field through the coil of the hard magnet is magnetized and retains the magnetization even after switching off the coil current at ( FIG. 11 , right). Thus, the deformation of the magnetic Elastomerkomposits, the displacement of the hydraulic fluid upward and the deformation of the overlying membrane are obtained without further electrical energy must be supplied through the coil. Only for a change in the Aktuationszustandes electrical energy must be supplied through the coil to change the magnetization of the hard magnet.

In the embodiment according to Fig. 12 the hydraulic fluid is again partially replaced by a rod compared to the eleventh embodiment.

In the thirteenth embodiment, the magnetic circuit includes, in addition to the electromagnet, a ring-shaped permanent magnet made of a samarium-cobalt alloy. The magnetic field generated by the permanent magnet deforms the magnetic elastomer composite without the supply of electrical energy ( FIG. 13 , Left). An additional magnetic field generated by the coil can amplify the field of the permanent magnet and thus increase the deformation of the magnetic elastomer composite ( FIG. 13 , Middle). By reversing the current direction in the coil, the additional magnetic field can also weaken the field of the permanent magnet and thereby reduce or even cancel the deformation of the magnetic elastomer composite ( FIG. 13 , right).

The embodiment according to Fig. 14 shows a compact form of a linear actuator with magnetic elastomer composite. Here, the magnetic elastomer composite is tapered with a flattened tip ( Fig. 14 , Left). The coil winding has a triangular cross-section which is largely complementary to the conical shape of the magnetic elastomer composite. When the magnetic field is applied through the coil, the magnetic elastomer composite deforms and pushes up a short rod ( Fig. 14 , right). With such a linear actuator relatively high Aktuationskräfte can be generated.

In the embodiment according to Fig. 15 the linear actuator is constructed similarly as in the embodiment according to Fig. 14 , However, the magnetic elastomer composite here contains a magnetic molding. As a result, the force of attraction on the inner yoke and thus the Aktuationskraft is reinforced again.

In the sixteenth embodiment according to Fig. 16 For example, the magnetic elastomer composite has the shape of a cylinder. It is located in the linear actuator between a lower and an upper yoke part, but fills the intermediate space between yoke parts only partially ( Fig. 16 , Left). Upon application of the magnetic field, the magnetic elastomer composite is attracted by both yoke parts and expands in length upwards. This moves a rod upwards through the inner yoke ( Fig. 16 , right).

Claims (15)

Linear actuator comprising at least one magnetic elastomer composite containing at least one elastomer and magnetizable particles, an inner and an outer yoke and at least one coil and / or at least one permanent magnet and / or at least one switchable hard magnet for generating at least one magnetic circuit having an interruption in which the magnetic elastomer composite is deformable upon application or modification of the magnetic field such that a linear actuator movement is triggered and the distance of the actuator movement is continuously and / or reversibly controllable by the strength of the magnetic field. Linear actuator according to claim 1,
characterized in that the magnetic field acting on the magnetic elastomer composite is inhomogeneous. Linear actuator according to one of the preceding claims,
characterized in that the magnetic elastomer composite is disc-shaped and the magnetic field is oriented substantially perpendicular to its base surface and the deformation of the magnetic elastomer composite in the form of a curvature of the magnetic elastomer composite dictates the direction of the actuator movement. Linear actuator according to one of the preceding claims,
characterized in that the magnetic elastomer composite is substantially disk-shaped and has towards the center of the disc toward a larger or smaller pane thickness, in particular in the form of a bulge to the outside or a concave inward on the inner yoke facing side, wherein the pane thickness steadily or gradually changes. Linear actuator according to the preceding claim,
characterized in that the inner or the outer yoke has a substantially corresponding to the disc shape concave or convex curvature. Linear actuator according to one of the preceding claims,
characterized in that the magnetic elastomer composite is provided with at least one mechanical and / or hydraulic element, in particular selected from the group consisting of a rod, a punch, a thread, a hydraulic fluid, a bag filled with liquid or gas and combinations thereof, is coupled, via which the deformation in a linear movement of the linear actuator is transferable. Linear actuator according to one of the preceding claims,
characterized in that the linear actuator comprises a coil and a permanent magnet or a coil and a switchable hard magnet, preferably of an aluminum-nickel-cobalt alloy, of a ferrite or of another material having a coercive force of less than 100 kA / m and a saturation magnetization of more than 600 mT. Linear actuator according to one of the preceding claims,
characterized in that the at least one elastomer is selected from the group consisting of silicone, fluorosilicone, polyurethane (PUR), polynorbornene, natural rubber (NR), styrene-butadiene (SBR), isobutylene-isoprene (IIR), ethylene-propylene-diene Terpolymer (EPDM / EPM), poly-chlorobutadiene (CR), chlorosulfonated polyethylene (CSM), acrylonitrile-butadiene (NBR), hydrogenated acrylonitrile-butadiene (HNBR), a fluororubber such as Viton, a thermoplastic Elastomer such as thermoplastic styrene copolymers (styrene-butadiene-styrene (SBS), styrene-ethylene-butadiene-styrene (SEBS), styrene-ethylene-propylene-styrene (SEPS), styrene-ethylene-ethylene) Propylene-styrene (SEEPS) or styrene-isoprene-styrene (SIS) copolymer), partially crosslinked polyolefin-based blends (of ethylene-propylene-diene rubber and polypropylene (EPDM / PP), of nitrile-butadiene-rubber) Rubber and polypropylene (NBR / PP) or of ethylene-propylene-diene rubber and polyethylene (EPDM / PE)) or thermoplastic urethane copolymers (aromatic hard segment and ester soft segment (TPU-ARES), aromatic hard segment and ether soft segment ( TPU-ARET) or aromatic hard segment and ester / ether soft segment (TPU-AREE)) as well as mixtures, blends or alloys thereof. Linear actuator according to one of the preceding claims,
characterized in that the magnetisable particles are selected from materials consisting of iron, in particular carbonyl iron, cobalt, nickel, iron alloys, in particular iron-cobalt alloys or iron-nickel alloys, iron oxides, in particular magnetite or ferrite, preferably manganese zinc ferrite, aluminum-nickel Cobalt alloys and mixtures thereof, wherein the average particle size is preferably less than 100 microns. Linear actuator according to one of the preceding claims,
characterized in that the magnetic elastomer composite additionally has magnetizable elements or shaped bodies which differ from the magnetizable particles, the size of the elements preferably exceeding the size of the particles by a factor of 10, particularly preferably by a factor of 100. Linear actuator according to one of the preceding claims,
characterized in that the magnetizable particles and the magnetizable elements or moldings isotropic or anisotropic are arranged in the magnetic elastomer composite. Linear actuator according to one of the preceding claims,
characterized in that the magnetizable elements or shaped bodies of soft magnetic materials, in particular iron, preferably carbonyl iron, cobalt, nickel, iron alloys, preferably iron-cobalt alloys or iron-nickel alloys, iron oxides, preferably magnetite or ferrite, particularly preferably manganese zinc ferrite, or hard magnetic materials, in particular aluminum-nickel-cobalt, neodymium-iron-boron or samarium-cobalt or mixtures thereof. Linear actuator according to one of the preceding claims,
characterized in that the magnetic elastomer composite has the form of a bellows which at least partially unfolds or folds upon application or alteration of a magnetic field. Use of the linear actuator according to one of the preceding claims for the controlled movement, adjustment or adjustment of flaps, doors, mirrors, optical elements, in particular radiation sources. Use of the linear actuator according to one of the preceding claims for generating movements in robots as well as for tactile feelable elements.

Images