DE102008023953B4 - Manually operable actuator and its use - Google Patents

Abstract

Manually operable actuating device (60) with an actuating member (18; 46) designed for manual movement relative to a stationary section (12, 14; 22, 24; 26, 28; 34, 38) along at least one direction of movement and means (62) for Generating an electronically evaluable actuation output signal associated with at least one position of the movement element relative to the stationary section, the actuation element and the stationary section being implemented by means of an electromagnetic unit, the actuation element cooperating with an armature unit (18; 42) of the electromagnetic unit or part of it the same and the stationary section is realized by a core area of the electromagnetic unit, means (50) are provided for detecting the position of the armature unit relative to the core area and an electronic control unit (62) cooperates with the means (50) for detecting the distance that, depending on a first elect ronically evaluable distance detection signal the control unit outputs a predetermined force against the direction of movement on the armature unit exerting control signal to the electromagnetic unit and ...

Description

The present invention relates to a manually operable actuating device according to the preamble of the main claim.

Such a device is well known in the art and is widely used, for example, as a command input or interface device for manually actuating virtually any electronic device, vehicle, machine, or the like.

Originally from military technology come so-called forced feedback systems, which, in response to a person operating the actuator, impose this force, which typically, in the manner of an actuation resistance or a counterforce, a current operating situation (eg: rudder force of an aircraft ) corresponds. This could then be simulated, without effective mechanical connection, acting on the operating element counterforce.

Specifically, for the purpose of generating such a force as feedback to the actuator, various approaches are known and also dealt with in the patent literature; So there are in addition to the force (resistance) generation by so-called rheological fluids, also forced feedback systems by friction systems, eg. B. friction wheels or friction disks), or by means of suitably controlled servomotors.

As a result, in addition to consumer electronics applications (eg, driving or flight simulators where a joystick to be manipulated by the player (operator) has been provided with appropriate technology), numerous automotive applications in particular are taking advantage of this technology. By way of example only, this application may be mentioned as a shift lever of an automatic transmission, a (mechanically decoupled) accelerator pedal or a universal selection and actuation button (iDrive from BMW).

However, all of these principles have in common that they are typically mechanically and constructively involved in the realization, in particular with regard to the haptic responsible, controlled force generation, and in addition, it proves to be potentially disadvantageous that practically has a separate system for each application a specific actuation and force behavior (ie a specific force-displacement characteristic in the operation) must be developed and implemented.

From the US 2006/0109254 A1 is a manually operable actuator according to the preamble of the main claim known.

From the DE 42 25 533 A1 an actuator in the form of an electrical displacement sensor is known which has a plunger coil means, ie a coil set immersed in the core.

For further relevant prior art is on the AT 144 526 B as well as on the DE 20 2006 019 698 U1 directed.

Object of the present invention is therefore to improve a generic, especially tactile effective actuator for manual handling by an operator in terms of a simple mechanical-constructive feasibility and universal applicability (thus suitable configurability for any purpose).

The object is achieved by the device having the features of the main claim; advantageous developments are described in the subclaims. Independent protection within the scope of the invention is claimed for the use according to independent claim 9.

In an advantageous manner according to the invention, first the stationary section and the actuating member guided relative thereto along a path in the direction of movement are realized as parts of an electromagnetic unit, wherein the actuating member designed for engagement or actuation by the operator is part of the movable armature acting on this) and the armature then interacts electromagnetically with the stationary core area.

According to the invention, means for detecting the position of the armature unit are provided such that along the path at least one position detection signal (position signal) can be generated, preferably a path-proportional, electronically processable signal for the downstream electronic control unit is available along the entire effective path. This is initially able to generate from the (first) electronically evaluable position detection signal, a control signal for the electromagnetic unit, which imposes a counterforce (resistance) of the armature unit, according to a predetermined (ideally as preset or presettable according to a table or function) force -way characteristic. For example, it is possible to generate at a predetermined position along the way a mechanically noticeable pressure point, namely a local force maximum in the force-displacement curve, which by controlling the electronic Control unit, according to predetermined (preferably stored) parameters by suitable control of the electromagnetic unit (in particular imprinting a correspondingly strong coil current) can be generated.

Additionally and in accordance with the invention, the control unit is capable of detecting the occurrence of a predetermined event in response to a received (second) path detection signal, e.g. B. the intended triggering of a switching operation after reaching a predetermined shift stroke (corresponding travel), whereupon then in the intended manner, the control unit can generate the intended actuation output signal.

In this way, the possibility arises to advantageously configure a generic and for many different applications non-specific to be provided electromagnetic unit only by appropriate programming (specification or imprinting the intended force-displacement characteristic) for a specific application or even, depending on other Parameters to vary the haptic effective behavior of the device in the manner described.

Since the generation of the counter force according to the invention works on the basis of an electromagnetic actuator, also the mechanical realization is relatively simple and proven, in addition, high reliability can be combined with a large usable range of forces.

In the context of the present invention, it has initially proved to be advantageous for further development according to the invention to embody the anchor unit according to the invention as a plunger anchor, in addition to realize this plunger anchor by means of a coil unit which cooperates magnetically with the stationary core area.

In terms of design, it is particularly preferred to provide a permanent magnet unit in the core region, which then acts on the coil as a conductor through which current flows, based on the otherwise known principle of the Lorentz force, and exerts a force on it.

Especially the continuing education chosen principle of the plunger coil offers many advantages in view of the intended use; not only allows the small moving mass (ie the coil armature) high accelerations and thus favorable dynamic properties, also a comparatively compact, short in the stroke direction realization, and in particular when further training the coil length (anchor length) is set up so that regardless of the Anchor position is always the same number of coil turns in the air gap, a virtually linear force characteristic can be achieved (so that then the force generation is not dependent on the position of the actuator along the actuation path). However, embodiments of the invention are also included, in which an actuator characteristic with current and coil position dependent force is intended and used.

While, according to a first preferred variant of the invention, the coil unit which preferably acts as an armature engages over the core-side permanent magnet unit at least in sections (ie at least partially surrounds a centric-internal permanent magnet section in the manner of a pot), it is alternatively preferred and advantageous that, more preferably radially magnetized , Annular form permanent magnet unit and provide so that this surrounds the outside of the shell side of the armature coil. It is also not excluded in principle within the scope of the invention that the armature has a permanent magnet unit which cooperates with a stationary coil unit. In general, moreover, the permanent magnet unit can be magnetized axially or radially.

In order to achieve a suitably aspired force-displacement characteristic, it may be advantageous according to the invention to bias the actuating member against the force of a restoring spring (eg designed as a compression spring), which in this respect, even in an energized state of an armature coil, a disengaged position as an unactuated state can define.

While it is within the scope of preferred embodiments of the invention to provide the movement according to the invention along the direction of movement in one dimension, it is equally encompassed by the invention to detect multi-dimensional movements according to the invention and to provide them with predetermined counterforces, for example using a two-dimensional in one plane operable joysticks as actuator.

Also in the context of the present invention, the force-travel characteristic to be set by the control unit or to be impressed on the actuator can be arbitrarily complex and, in extension of the example described above, a plurality of force maxima following one another along the actuation path (eg for generating a plurality of successive pressure points). Similarly, it is contemplated by the present invention to predetermine a plurality of digital or analog events to be triggered by the (at least one) second path detection signal.

The inherent flexibility of the present invention thus makes the manually operable actuator of the present invention ideally suited for a variety of different applications and uses, even within the same use by appropriately predetermined, selectable or (re) programmable parameterization, adapting to different operating conditions is possible; As an example, the variant is called, when using the present invention as an interface to a computer with the purpose of realizing a complex control lever for a computer game make a (pre-) adjustment to different individual user needs, such as desired drag, time of a switching trip, etc.

Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawings; these show in

1 a schematic view of the electromagnetic unit for implementing the manually operated actuator according to a first embodiment of the present invention;

2 . 3 Further basic structural configurations as variants to the principle of 1 ;

4 . 5 a detailed representation of a concrete realization of the invention shown in the sectional view according to a first embodiment, with or without spring,

6 an external view in the closed state (perspective) of the embodiment according to 4 ;

7 an exploded view of essential components of the embodiment of 4 . 6 ;

8th a block diagram of a typical wiring of the mechanical components by means of embodiment 5 to 7 and

9 an exemplary representation of a force-displacement curve, as by suitable pre-configuration of the control device according to 8th in the embodiment of 5 to 7 can be implemented.

The 1 to 3 show in the side sectional view 3 exemplary variants for the realization of the electromagnetic unit as part of the manually operated actuator in the context of preferred embodiments of the present invention. More specifically, the respective electromagnetic units show a stationary component consisting of a soft iron section and a permanent magnet interacting therewith, and, movable relative to this stationary unit, a unit consisting of coil carrier and coil in the direction of a respective axis 10 is movably mounted. On this unit consisting of bobbin and coil, the (manual) operation is effective.

More specifically, the first variant according to 1 a stationary unit consisting of a cylindrical, axially magnetized permanent magnet 12 , which in the manner shown by a hollow cylindrical soft iron body 14 surrounded so that the radially symmetric body 14 in the axial direction on both sides of the poles of the permanent magnet 12 connects and a ring slot 16 is formed, in which a (disc-shaped) coil carrier 18 with hollow cylindrical coil winding 20 can dive. In the manner of an actuator, an operator applies an axially directed force to the bobbin 18 from, wherein - depending on the current state of the coil 20 - A counterforce and / or rest position of the movable unit from bobbin 18 and coil 20 in the case 14 can be found. The unit according to 1 (As well as the other units) then act in a manner not shown in these figures, with a realized by means of a magnetic field detector position detection unit, which the relative displacement or immersion depth of the movable unit in the soft iron housing 14 recorded and for (again not shown) provides electronic evaluation.

In contrast to 1 shows the variant of the electromagnetic unit according to 2 an (axially magnetized) hollow cylindrical-annular permanent magnet 22 , which together with a soft iron core 24 which forms a bottom or cover section on both sides of the magnetic poles and has an axial soft iron connection section which forms a stationary unit. The movable unit consisting of coil carrier 18 and cylindrical coil 20 is like in the example of 1 as a plunger coil by axial (manual) operation in the interior of the soft iron housing into movable.

As another possible variant opposite 1 and 2 (again with unchanged movable unit of bobbins 18 and coil 20 ) shows the embodiment of 3 a soft iron core element 26 which in the manner shown forms a centric, cylindrical center region and a hollow cylindrical outer wall, connected by a bottom section, and wherein a (here radially magnetized) permanent magnet 28 annular inside the hollow cylindrical shell portion of the soft iron core 26 is applied. Again, the coil section 20 in the inner space formed between permanent magnet and soft iron core to corresponding application of force in the axial direction 10 plunge.

All variants shown for the electromagnetic unit (which are not to be provided as a final extent) have the advantageous feature in common that with a favorable high power consumption and simplified integrated path detection (eg via a Hall sensor as an electromagnetic field detector on the coil or on the coil carrier) a structurally simple and reliable electromagnetic unit can be created, which also in geometric terms minimizing the housing dimensions - both in the axial and in the radial direction - allows.

With reference to the 4 to 7 In the following, a first constructive embodiment of the manually operable actuating device will be described, which describes the functional principle of the 1 for the electromagnetic unit.

In a two-part hollow cylindrical housing consisting of a lower housing shell 30 (typically realized as a plastic injection molded part) and an upper housing cover 32 , in turn realized as a plastic injection molded part and for snapping with the body 30 engineered, is first, according to the soft iron body 14 in 1 , an iron shell element 34 Made of soft iron material stationary in the housing 30 provided on the bottom surface in the in 4 respectively. 5 shown manner, the cylindrical and axially magnetized permanent magnet 12 surrounded by a plastic guide sleeve 36 , sits up.

On the permanent magnet 12 again sits an iron cover 38 (Accordingly in this respect the cover portion of the soft iron housing 14 in 1 ), on which optional a spiral compression spring 40 in a suitably sized recess in the lid 38 can be placed.

Like the juxtaposition of 4 and 5 clarifies, is the provision of the spring 40 a preferred, but not necessary variant in the realization of the embodiment.

The from the units 34 . 12 . 36 . 38 formed stationary unit cooperates with a movable unit consisting of a plastic bobbin 42 , which in the in 4 respectively. 5 shown lateral sectional view of a hollow cylindrical coil section with seated winding 44 and an axially upwardly extending operating portion 46 having one piece sitting. One in the direction of the housing cover 32 on the spool carrier seated disc-shaped circuit board 48 carries one (corresponding to a plunger movement of the bobbin 42 relative to the permanent magnet 12 movable) Hall sensor 50 and is sized so that the engaging portion 46 of the bobbin a central hole in the circuit board 48 passes through and another center hole 52 in the housing cover 32 emerges from the housing.

In the in 6 As shown in the assembled state of the components, a cylindrical unit, from which for moving (operating) of the bobbin of the section 46 protrudes. In the 4 to 7 not shown in detail is also the coil unit 44 wired for external contacting, as well as an electrical contact of the Hall sensor 50 is provided.

The 8th illustrates a possible wiring of the reference numerals 60 represented and the embodiment of the 4 to 7 corresponding actuator. This is how the block diagram of 8th can be removed, first with a central electronic control unit 62 (For example, realized by means of a microprocessor or controller), which on the one hand, the position-dependent magnetic field signal x (t) of the Hall sensor 50 receives and on the other hand generates a control voltage U (x, t), which via an amplifier or driver unit 64 and a temperature compensation unit 66 at the coil unit 44 the actuator 60 is applied. Furthermore, the control unit (processor) receives 62 from a (parameter) memory unit 68 Control parameters, including data related to a spring characteristic (in the case of using a spring 40 (see. 4 ), digitally stored actuator characteristics in the form of a force-displacement diagram of the unit 60 and a (suitably predetermined) intended force characteristic for realizing the desired haptic F (x).

This is illustrated by an operating diagram in 9 in which, on the left vertical axis, the force acting on an actuator, both when "pushing", ie moving in the operating portion 46 in the housing, as well as when "releasing" (ie Rausbewegen) causes in the manner of a hysteresis curve, and wherein the right vertical axis represents an exemplary plotted switch voltage, which indicates a turn-on state by corresponding voltage level at the shown on and off timing, while the remaining Times (or associated path positions of the bobbin) a switch off with 0 volts is indicated.

By suitable parameterization of the unit in 8th is according to the in 9 Realized force-displacement curve realized by a corresponding force specification, a mechanical switching point (about 0.075 cm way) is set and at about 0.21 cm closing the switch is effected by corresponding processor functionality. The predetermined hysteresis then ensures that upon release (ie emergence of the engagement area 46 from the actuator) of the switch (to a shorter switching path) opens.

It is noteworthy that in principle any, corresponding haptically effective switching or actuating paths can be set up by this technology, wherein the coil carrier (or its section 46 ) is guided as an actuator only on the magnet and is held solely by its magnetic holding force.

As described, the linear movement generates an electrically variable signal which is further processed in the evaluation electronics as a function of the respective path or a respective (immersion) position. If this current position or the path corresponds to a predetermined value, then a signal or another functionality (for example, that in the 8th shown "el.Signal") are triggered, along the actuation path, any number of points are definable, in which about the processor emits electrical signals to the environment. This is possible both when pressing (pressing) and when releasing.

At the same time, the user when pressing (or when releasing) feel a counterforce, which can be set almost anywhere within the scope of the electromagnetic actuator. This depends on the magnitude and direction of the coil current, which in turn is in the in 8th shown manner via the control unit (impressed) is. Additionally, the optional compression spring 40 , in the form of a superimposed spring characteristic, allow further functionality.

This results in that the device shown is suitable for a large number of setting, actuation and / or operating purposes, the spectrum of applications of switching tasks in automotive, automation, computer or medical technology to any (especially the haptic effect exploiting) applications such as in the field of simulation, device control, computer games od. Like. Enough.

Claims (9)

Manually operable actuator ( 60 ) with a manual movement relative to a stationary section ( 12 . 14 ; 22 . 24 ; 26 . 28 ; 34 . 38 ) along at least one direction of movement formed actuator ( 18 ; 46 ) and funds ( 62 ) for generating an electronically evaluable, at least one position of the movement member relative to the stationary portion associated actuating output signal, wherein the actuating member and the stationary portion are realized by means of an electromagnetic unit, the actuator frictionally with an anchor unit ( 18 ; 42 ) of the electromagnetic unit or is part thereof and the stationary section is realized by a core region of the electromagnetic unit, means ( 50 ) are provided for detecting the position of the armature unit relative to the core region and an electronic control unit ( 62 ) so with the means ( 50 ) cooperates for path detection, that in response to a first electronically evaluable position detection signal, the control unit outputs a predetermined force against the direction of movement on the armature unit exerting control signal to the electromagnetic unit and in response to a second electronically evaluable position detection signal, the control unit ( 62 ) generates the actuating output signal, characterized in that the core region is a permanent magnet unit ( 12 ; 22 ; 28 ), the permanent magnet unit ( 22 ; 28 ) is provided in the core region radially at the edge and in such a way that upon actuation of the actuating member ( 18 ; 46 ) the permanent magnet unit on the shell side, at least in sections, a coil unit ( 20 ) of the anchor unit, and the means for position detection as magnetic field detecting means ( 50 ) configured to convert a detected magnetic field signal of the core region into the path-proportional path detection signal. Apparatus according to claim 1, characterized in that the armature unit can be controlled by the control unit coil unit ( 44 ) formed for electromagnetic interaction with the stationary core region. Apparatus according to claim 2, characterized in that the coil unit in an operating state of the actuating member ( 46 ) at least partially overlaps the core area. Device according to one of claims 1 to 3, characterized in that the permanent magnet unit ( 12 ) is centrally provided in the core area and / or so that upon actuation of the actuating member, the permanent magnet unit is at least partially enclosed by a coil unit of the anchor unit. Apparatus according to claim 1, characterized in that the armature unit comprises permanent magnet means which are designed to cooperate with a stationary coil unit on or in the core area. Device according to one of claims 1 to 5, characterized in that the armature unit against the actuating force of a return spring ( 40 ), in particular pressure spring, is held in an unactuated state corresponding disengagement position. Device according to one of claims 1 to 6, characterized in that the device is designed as a haptic interface so that an actuation of the actuator in the direction of movement at least one position along the way a predetermined, manually perceptible local maximum force in a force-displacement Characteristic of the actuator arises. Apparatus according to claim 7, characterized in that the local force maximum by electronic configuration, in particular control and / or programming of the control unit, adjustable and / or changeable. Use of the manually operable actuating device according to one of claims 1 to 8 as an operating element, in particular switches, in motor vehicles, for the operation of control cabinets, in devices of consumer electronics and computer technology or medical technology.

Images