DE102015206035A1 - Actuator device, hydraulic device, hydraulic system - Google Patents

Abstract

The invention relates to an actuator device (1), in particular for a hydraulic application, with a displaceable piston (5), to which an electroactive polymer actuator (9) is assigned for its displacement in an actuating direction (8), and to a magnetic device (15) Support of polymer actuator (9). It is provided that the piston (5) is slidably mounted on the polymer actuator (9) in the actuation direction, and that the magnet device (15) is assigned to the piston (5) such that it is in at least one actuation state of the polymer actuator (9). regardless of the polymer actuator (9) is displaced by magnetic force.

Description

The invention relates to an actuator device, in particular for a hydraulic application, with a displaceable in particular in a hydraulic chamber piston, which is assigned to its displacement in an actuating direction an electroactive polymer actuator, and with a magnetic device for supporting the Polymeraktuators.

Furthermore, the invention relates to a hydraulic device with such a device and a hydraulic system with a corresponding hydraulic device.

State of the art

Electroactive polymer actuators (EAP actuators) are already in use for many hydraulic applications such as pumps, valves or the like. From the DE 10 2005 051 444 A1 For example, it is already known to effect a brake force boost by means of an electroactive polymer actuator. From the US 8,072,121 B2 In addition, a transducer with electroactive polymer actuator is already known, which is also associated with a magnetic device consisting of two magnetically attracting elements, one stationary and the other is connected to the polymer actuator to support from a Mindestauslenkung or actuation of the polymer actuator this , As soon as the polymer actuator with its magnetic element gets into the magnetic field of the stationarily arranged magnetic element, an additional force, namely a magnetic force is exerted on the polymer actuator, by which the polymer actuator is supported during its actuation, so that it provides a high actuating force until the end of its actuation path.

Disclosure of the invention

By virtue of the actuator device according to the invention, the advantage is achieved that an actuation path usually provided by the polymer actuator, ie the distance that the piston can be displaced through the polymer actuator, is widened or enlarged in a simple manner. As a result, the actuator device receives a higher flexibility and the actuation force, which generally decreases with polymer actuators with the actuation path, is maintained until the end by actuator device according to the invention or even increased with increasing distance. This is inventively achieved in that the piston is slidably mounted in the actuating direction on the polymer actuator, and that the magnetic device is associated with the piston such that it is displaceable in at least one actuation state of the polymer actuator independently of the polymer actuator. This ensures that the piston is magnetically displaceable independently of the actuation of the polymer actuator in at least one operating state of the polymer actuator. In particular, it is provided that the magnetic device acts in particular when the polymer actuator has been actuated and has reached its maximum deflection, in which the piston is displaced maximally by the polymer actuator. At least in this location, the magnetic device acts to further displace the piston independently of the polymer actuator, thereby increasing the overall travel of the piston. The piston may be a hydraulic piston displaceable in a hydraulic chamber or a mechanical piston which, for example, mechanically directly actuates a valve, a flap or another element.

According to an advantageous embodiment of the invention it is provided that the magnetic device is designed and / or arranged such that it then attracts the piston, and only if the polymer actuator is actuated or has been. This ensures that an actuation of the actuator device only takes place when the electroactive polymer actuator is actuated. As previously mentioned, the piston is movably mounted on the polymer actuator, and the magnet means is arranged or adapted to exert a force on the piston only when the polymer actuator has been actuated and the piston has been displaced into the effective range of the magnet device ,

According to a preferred development of the invention, it is provided that the magnet device has at least one permanent magnet fixedly arranged on the housing side, which cooperates with a magnetic element arranged on the piston or with the then magnetically formed piston when the polymer actuator has been actuated. By providing one or at least one permanent magnet, a particularly energy-saving actuation of the actuator device is ensured, which furthermore requires no additional electrical control, apart from the activation of the polymer actuator. In this way, a particularly compact and cost-saving design of the actuator device can be provided.

Furthermore, it is preferably provided that the permanent magnet is arranged opposite the piston, in particular in or on the hydraulic chamber. The permanent magnet can be arranged, for example, in front of or behind a housing wall, in particular inside or outside the hydraulic chamber, provided that it is ensured that a magnetic field with the piston or can cooperate with a magnetic element arranged on the piston when the piston has been pushed through the polymer actuator correspondingly far, for example, into the hydraulic chamber. The permanent magnet is designed or aligned in such a way that a magnetic field acts attractively on the piston in order to further draw it in particular into the hydraulic chamber.

Alternatively, it is preferably provided that the permanent magnet is assigned to a guided in particular from the hydraulic chamber out to the polymer actuator piston rod of the piston. In this case, the permanent magnet can also exert a repulsive magnetic force on the piston so as to further shift it in the direction of the hydraulic chamber, in particular. This also results in the already mentioned advantages.

Furthermore, it is preferably provided that the magnetic device comprises a magnetic ring with the at least one permanent magnet, wherein the piston rod is passed through a gap of the magnetic ring. As a result, magnetic forces can be exerted on the piston in a particularly targeted manner and the piston can be guided safely.

According to a preferred embodiment of the invention, it is provided that the polymer actuator has a piston rod guide for the piston rod at its free, end facing the piston. The piston rod is thus mounted in the piston rod guide, wherein the piston rod guide displaceably supports the piston rod in the direction of actuation of the polymer actuator, so that the movement initially generated by the polymer actuator is continued by the magnetic device when the piston rod is pulled away from the polymer actuator on the piston rod guide.

Furthermore, it is preferably provided that the piston rod guide has a stop, in particular axial impact, for the piston, by means of which the piston can be displaced backward by the polymer actuator. In particular, when the magnetic device has one or more permanent magnets for generating the magnetic force, it is necessary that the piston is actively moved from the operating position to a retracted initial position or is movable. The stop of the polymer actuator or the piston rod guide ensures that when the polymer actuator is no longer energized or energized, it retracts the piston rod or in particular displaces it out of the hydraulic chamber into its initial position against the magnetic force of the magnetic device. The magnetic device or the permanent magnet (s) are expediently designed such that their magnetic force is insufficient to hold the polymer actuator in the actuated position when it is not energized. Expediently, the piston rod guide has a further stop for the piston, which, however, acts in the other direction, so that by means of the further stop the polymer actuator displaces the piston in the direction of the hydraulic chamber in a form-fitting manner during its actuation.

The hydraulic device according to the invention with the features of claim 9 is characterized by the device according to the invention. This results in the already mentioned advantages. Other features and advantages will be apparent from the above. In particular, the hydraulic device is designed as a piston pump or valve device.

The hydraulic system of a motor vehicle according to the invention with the features of claim 10 is characterized by the hydraulic device according to the invention. In particular, the hydraulic system is designed as a brake system of a motor vehicle, resulting in the previously explained advantages for the brake system. In particular, it is ensured by the inventive device in the hydraulic system according to the invention that larger actuation paths of the piston than previously possible, so for example, a higher volume of brake fluid promoted or in a shorter time a desired pressure can be built up as before.

In the following, the invention will be explained in more detail with reference to the drawing. Show this

1 an actuator device for a hydraulic system of a motor vehicle in a simplified representation in the initial state,

2 the actuator device in the actuated state,

3 a further embodiment of the actuator device in a simplified representation,

4 a diagram for explaining the advantages of the actuator device and

5 a further embodiment of the actuator device in a simplified representation.

1 shows an actuator device 1 for a hydraulic system not shown in detail 2 that a pump 3 has, which is designed as a piston pump. This is indicated by the pump 3 a housing 4 in which a piston 5 is axially displaceable. there forms the housing 4 together with the piston 5 a hydraulic chamber 6 , the fluid inlet, not shown here, as well as a fluid outlet 7 assigned. Will the piston 5 in the hydraulic chamber 6 driven in, as by an arrow 8th indicated, it will be in the hydraulic chamber 6 located fluid volume is subjected to a compressive force, through which the fluid volume from the hydraulic chamber 6 through the fluid drain 7 is expelled.

To operate the pump 3 is the actuator device 1 provided the piston 5 , as well as the piston 5 associated electroactive polymer actuator 9 having. By applying an electrical voltage, the electroactive polymer actuator changes shape, causing the piston 5 axially in the housing 4 can relocate. The piston 5 has a piston rod 10 on, coming out of the case 4 is led out and in a piston rod guide 11 of the polymer actuator 9 is slidably mounted. Here is the piston guide 11 formed such that the piston rod 10 in their longitudinal extent in or on the polymer actuator 9 is relocatable. Here is the piston guide 11 at a free end 12 of the polymer actuator 9 arranged, which upon actuation or when applying a voltage to the polymer actuator 9 towards the case 4 moved as if by an arrow 13 indicated. The piston rod 10 has an axial stop 14 on, with the free end face 12 of the polymer actuator 9 cooperates, so that this in its operation against the axial stop 14 pushes and thereby the piston 5 in the hydraulic chamber 6 according to arrow 8th inside moves. On the free end 12 opposite side is the polymer actuator 9 firmly anchored or arranged.

The actuator device 1 also has a magnetic device 15 which is adapted to the polymer actuator 9 to support. In this case, the magnetic device 15 in this case, a permanent magnet 16 on that in the case 4 on the piston 5 is arranged opposite side.

In this case, the magnetic field or the permanent magnet 16 aligned so that it is the piston 5 attracts magnetically. The piston 5 is accordingly made of magnetic material and / or has at least one element made of magnetically produced material which, as soon as it enters the magnetic field of the permanent magnet 16 has penetrated the piston 5 further into the housing 4 according to arrow 8th inside moves. Here is the piston 5 due to the movable mounting of the piston rod 10 in the piston rod guide 11 through the magnetic device 15 independent of the polymer actuator 9 movable.

2 shows the actuator device 1 in the actuated state, where off 1 already known elements are provided with the same reference numerals, so that reference is made to the description described above.

Will the polymer actuator 9 when subjected to a voltage, its free end moves 12 , as previously mentioned, in the direction of the housing 4 , being the free end 12 maximum shift by one way x. The path x depends on the design of the polymer actuator 9 and can not be expanded during operation. The polymer actuator 9 urges the piston 5 , as previously mentioned, according to arrow 8th in the hydraulic chamber 6 into it. At the same time the piston gets 5 in the magnetic field of the permanent magnet 16 , which then the piston 5 continue to draw to itself, so that the piston 5 a path y in the hydraulic chamber 6 in the direction of the arrow 8th travels from the path x of the polymer actuator 9 and the way r, the piston 5 relative to the polymer actuator 9 overcomes, yields, as in 2 shown.

The advantageous embodiment of the actuator device 1 thus allows a greater range of motion of the piston 5 than before, allowing a larger volume through the pump 3 as previously promoted, wherein the polymer actuator 9 through the magnetic device 15 is supported during operation. In particular, it is achieved that the actuating force acting on the piston 5 acts with increasing displacement due to the advantageously arranged permanent magnet 16 increases to the end, so that the fluid with high force or high pressure from the housing 4 is driven. While the actuation force of the polymer actuator 9 decreases with increasing distance x, decreases the force of the permanent magnet 16 on the piston 5 acts, so that a high volume is promoted and at the same time a high hydraulic pressure is ensured. Of course it is also possible, more than just a permanent magnet 16 provide to increase the actuation force and / or the actuating travel. It is also conceivable, in contrast to the present embodiment, the one or more permanent magnets outside the hydraulic chamber 6 to be arranged on the housing.

Another benefit stemming from the actuator device 1 is that if only a small amount of travel is needed, only the polymer actuator 9 can be operated. Here also the polymer actuator may 9 only be actuated so far that the piston 5 not in the magnetic field of the permanent magnet 16 device. The then necessary energy to the polymer actuator 9 to hold in a position of use is relatively low. For situations where a higher force or a higher Hydraulic pressure are necessary, the polymer actuator 9 so actuated that the piston 5 in the magnetic field of the permanent magnet 16 or the magnetic device 15 device.

As an alternative to the present exemplary embodiment, it is also conceivable to use the magnetic device 15 form as an electromagnetic device that generates a magnetic field during electrical energization. This allows the operation of the piston 5 even further improved and in particular targeted, regardless of a position or an operating state of the polymer actuator 9 ,

3 shows an alternative embodiment of the actuator device 1 in a simplified sectional view. Elements already known from the preceding figures are provided with the same reference numbers, so that reference is made to the description above. In the following, essentially only the differences will be discussed.

In contrast to the previously described embodiments, it is provided in the present case that the magnetic device 15 a magnetic ring 17 which is stationary between the polymer actuator 9 and the housing 4 is held. The magnetic ring 17 has two permanent magnets 18 . 19 on that a magnetic flux, as through lines 20 is implied cause. The piston rod 10 is through a gap 21 of the magnet ring 17 passed through. The free end 12 of the polymer actuator 9 in the present case forms a section of the magnetic ring 17 in the unactuated state spaced from the rest of the magnetic ring 17 lies, in particular to the permanent magnets 18 . 19 which are in the fixed section of the magnet ring 17 lie. The piston rod 10 is, as previously mentioned, the front or the free end 12 of the polymer actuator 9 assigned.

Will the polymer actuator 9 pressed, he pushes the piston 5 , as previously described, in the hydraulic chamber 6 until the free end 12 in the effective range of the magnetic ring 17 or the permanent magnet 18 . 19 so that the magnetic flux 20 is generated, the piston rod 10 from the magnetic ring 17 expels, so the piston 5 in the hydraulic chamber 6 is driven further than he alone by the polymer actuator 9 could be moved.

Furthermore, the piston rod guide 11 an axial stop 22 up, with a radial bias 23 the piston rod 10 interacts and the maximum displacement of the piston 5 in the direction of the arrow 8th limited. Will the activation of the polymer actuator 9 stopped, the tension as reduced, so the polymer actuator retracts 9 against the direction of the arrow 13 back. Through the axial stop 22 , with the lead 23 cooperates, it ensures that the polymer actuator 9 the piston 5 from the hydraulic chamber 6 with withdraws, against the magnetic force of the magnetic device 15 , The magnetic force of the permanent magnet 16 may therefore be selected so large that the polymer actuator 9 capable of doing this is the piston 5 independently withdraw from the outsourced position to its original position. Indicates the magnet device 15 Instead of the permanent magnet on an electromagnet, the consideration of the height of the magnetic force and the retraction force of the polymer actuator 9 not relevant anymore.

wobei sich die magnetische Energie W_m wie folgt ergibt:

The magnetic circuit may include various elements such as an air gap, permanent magnets, magnetic materials / elements, and the like. The movement of the piston rod 10 affects the reluctance of the magnetic circuit. The force-motion characteristic of the magnetic circuit can be described as a function of the magnetic energy taking into account the displacement of the moving parts as follows:

where the magnetic energy W _{m is} as follows:

Here, MMF stands for the magnetic force generated by the permanent magnet 18 . 19 or an electromagnet is generated, and R is the resulting reluctance (magnetic resistance) of the magnetic circuit. The reluctance of the magenta magnetic permeability conductor μ (x) of the cross-sectional area A (x) and length l is given by: R = 1 / μA.

In the assumption that MMF deals with the displacement of the piston 5 or the piston rod 10 not changed, the following results:

The dependence of the reluctance on the displacement determines the force-motion characteristic of the magnetic circuit. There may be different configurations with permanent magnets and / or electromagnets, air gap and magnetically conductive elements with variable Cross-sectional areas and / or magnetic conductivities are provided in order to achieve an optimum result.

4 shows a diagram in which a force F over the movement path y of the piston 5 is applied. In the 4 The values shown here are to be understood as purely exemplary.

A first line L1 shows the linear force curve of the polymer actuator 9 whose power decreases with increasing distance. A second line L2 shows the course of the force over the path of movement resulting from the magnet device 15 results. As can be seen in the diagram, the magnetic force acts only from a minimum travel x _{min of} the polymer actuator 9 , A third line L3 shows the sum of the piston 5 acting forces depending on its position. It can be seen that while the force of the polymer actuator 9 decreases, these by the force of the magnetic device 15 is overcompensated in the direction of a maximum movement path y _max , so that until reaching the maximum movement path y _max a high actuation force for operating the pump 3 is available. The maximum movement path y _max is in particular by a mechanical stop, in particular of the piston 5 in / at the hydraulic chamber 6 Are defined. The total force acting on the piston 5 acts, falls below in the present embodiment, never the minimum force of F _min = 10 N. Depending on the application, the lines L1 and L2 can of course be designed differently, for example, a total higher actuation force F, a total lower actuation force F or another force curve to obtain.

5 shows a further embodiment of the actuator device 1 in which the hydraulic device is not considered a piston pump 3 but as a valve or valve device 24 is trained. It is provided that the valve device 24 a pilot valve 25 as well as through the pilot valve 25 operated main valve 26 having.

The pilot valve 25 shows the piston 5 on, which is not formed in this case as a pump piston, but as a control piston and arranged axially displaceable in a hydraulic actuating chamber. By moving the piston 5 in its axial extension are different to the hydraulic chamber 4 leading connections connected or disconnected to a main valve piston 27 of the main valve 26 axially displace to release or closing hydraulic connections. The principle of a pilot valve with a main valve is basically known and will therefore not be explained in detail.

For actuating the piston 5 the pilot valve has the actuator device 1 and another actuator device 28 on, each one end of the piston 5 assigned. The actuator device 25 In the present case, it is conventionally designed with an electromagnet for actuating the piston 5 , On the opposite side is the piston 5 the advantageous actuator device 1 assigned according to the present embodiment, the polymer actuator 9 as well as the magnetic device 15 having. The polymer actuator 9 is in its end 12 especially with the piston 5 connected so that with the polymer actuator 9 The piston 5 at least over the path of movement x of the polymer actuator 9 is relocatable. According to the present embodiment, it is provided that the permanent magnet 16 in the central cavity of the polymer actuator designed as a roller actuator 9 is arranged so that the magnetic device 15 in the - opposite direction compared to the previous embodiments, namely, such that they the piston 5 in the direction of the polymer actuator 9 magnetically attracts once the end 12 of the polymer actuator 9 with the piston 5 close enough to the permanent magnet 16 has arrived.

According to a further embodiment (not shown here), it is preferably provided that the actuator device 28 like the actuator device 1 is formed and according to a polymer actuator 9 for actuating the piston 5 and a magnetic device 15 having. In this case, so if the piston 5 from two sides in each case by the advantageous actuator device 1 is operable become the Aktorvorrichtungen 1 suitably controlled as follows:
To the piston 5 to hold in its middle rest position, both become polymer actuators 9 biased. In this case, the polymer actuators 9 be partially charged or discharged. To the pilot piston 5 in the paper plane then to move to the left, for example, the left polymer actuator is discharged, so this the piston 5 pulls in his direction, and the right polymer actuator 9 charged, so he the piston 5 in the direction of the left polymer actuator. When moving the piston 5 in the opposite direction, the procedure is reversed accordingly. The magnet 16 the respective magnetic device 15 is expediently positioned such that even at maximum stroke or movement path no mechanical contact between the permanent magnet 16 and pistons 5 arises or can arise.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102005051444 A1 [0003]
• US8072121 B2 [0003]

Claims (10)

Actuator device ( 1 ), in particular for a hydraulic application, with a displaceable piston ( 5 ), to its shift into an operating direction ( 8th ) an electroactive polymer actuator ( 9 ) and with a magnetic device ( 15 ) in support of the polymer actuator ( 9 ), characterized in that the piston ( 5 ) in the actuation direction slidably on the polymer actuator ( 9 ) is mounted, and that the magnetic device ( 15 ) the piston ( 5 ) is assigned such that in at least one actuation state of the polymer actuator ( 9 ) independently of the polymer actuator ( 9 ) is displaced by magnetic force. Actuator device according to claim 1, characterized in that the magnetic device ( 15 ) is designed and / or arranged in such a way that it engages the piston ( 5 ) is actuated only when the polymer actuator ( 9 ) was pressed. Actuator device according to one of the preceding claims, characterized in that the magnetic device ( 15 ) at least one stationary permanent magnet ( 16 . 18 . 19 ) having. Actuator device according to one of the preceding claims, characterized in that the permanent magnet ( 16 ) the piston ( 5 ) is arranged opposite one another. Actuator device according to one of the preceding claims, characterized in that the permanent magnet ( 18 . 19 ) one to the polymer actuator ( 9 ) guided piston rod ( 10 ) of the piston ( 5 ) assigned. Actuator device according to one of the preceding claims, characterized in that the magnetic device ( 15 ) a magnetic ring ( 17 ) with the at least one permanent magnet ( 18 . 19 ), wherein the piston rod ( 10 ) through an air gap ( 21 ) of the magnet ring ( 17 ) is guided. Actuator device according to one of the preceding claims, characterized in that the polymer actuator ( 9 ) at its free, the piston ( 5 ) associated end ( 12 ) a piston rod guide ( 11 ) for the piston rod ( 10 ) having. Actuator device according to one of the preceding claims, characterized in that the piston rod guide ( 11 ) an axial stop ( 22 ) for the piston ( 5 ), by means of which the piston ( 5 ) through the polymer actuator ( 9 ) is zurückverlagerbar. Hydraulic device, in particular piston pump ( 3 ) or valve, characterized by an actuator device ( 1 ) according to one or more of claims 1 to 8. Hydraulic system of a motor vehicle, in particular brake system, with a hydraulic device according to claim 9.

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