DE102012223737A1 - Black-out device i.e. sunscreen device, has black-out unit including controllable micro guarding area and/or controllable micro pass band, where micro guarding area includes controllable transparency - Google Patents

Abstract

The device (10a) includes a black-out unit (12a) including a controllable micro guarding area (14a) and/or controllable micro pass band (16a). The micro guarding area has controllable transparency. The black-out unit includes a magneto-rheological material and an electroactive material, which is partially formed as an electroactive polymer. The black-out unit includes a field generating unit (24a), which is adapted to produce field. An independent claim is also included for a technique for driving a black-out device.

Description

Disclosure of the invention

A darkening device, in particular a sun protection device, having at least one darkening unit, which has at least one controllable micro-shielding region and / or at least one controllable micro-passband, is proposed. For example, the darkening unit has at least one surface with at least one perforation. Likewise, the darkening unit could have an area in which controllable micro-shielding regions and controllable micro-passage regions are arranged next to one another. It is also conceivable that the controllable micro-shield region and the controllable micro-passband are integrally formed. A "blackout unit" is to be understood in particular as meaning a unit which is intended to at least partially obscure at least one area of at least one material. In particular, the darkening unit is provided to at least partially prevent the passage of electromagnetic radiation, preferably of solar radiation, in particular of electromagnetic radiation from a wavelength range between 200 nm and 1200 nm, through the area. Preferably, the blackout unit is designed as a controllable blackout unit. The dimming unit is preferably provided to darken the area as a function of at least one activation. In particular, the blackout unit has the controllable micro-shielding area. The darkening unit preferably has the controllable micro-passband. In particular, the blackout unit has the activatable micro-shielding area and the controllable micro-passband area. A "micro-passband" should be understood to mean, in particular, a range which is intended to at least partially enable the passage of the electromagnetic radiation through the micro-passband. In particular, the micro-passband has a dimension in a range of only 1 mm to 1 μm inclusive. A "micro-shielding region" is to be understood in particular to mean a region which is intended to at least partially prevent the passage of the electromagnetic radiation through the micro-shielding region. In particular, the micro-shielding region has a dimension in a range of only 1 mm to 1 μm inclusive. A "controllable" area is to be understood in particular to mean a region which is intended to be specifically controlled, preferably regulated, in particular influenced. In particular, by means of the control at least one property of the range can be changed to a proportion of more than 50%, preferably more than 60% and in particular more than 70%. By the phrase "at least partially preventing" electromagnetic radiation from passing through the region, it should be understood in particular that passing through more than 70%, preferably more than 80% and especially more than 90%, of one is prevented on one side of the area incoming electromagnetic radiation through the area. In particular, of the electromagnetic radiation arriving at the side of the area, a proportion of less than 30%, preferably less than 20%, and in particular less than 10%, reaches a side of the area facing away from one side of the area. By the phrase "to at least partially enable electromagnetic radiation to pass through the region", it should be understood, in particular, that passing through more than 70%, preferably more than 80%, more preferably more than 90%, of one on one side of the area allows incoming electromagnetic radiation through the area. In particular, less than 30%, preferably less than 20% and in particular less than 10% of the passage of the region is prevented by the electromagnetic radiation arriving on one side of the region. By "provided" is intended to be understood in particular specially programmed, designed and / or equipped. By means of an embodiment according to the invention, it is advantageously possible to selectively control individual regions of the darkening unit, as a result of which a flexible, comfortable darkening unit can be achieved.

It is also proposed that the micro-shielding area has controllable transparency. In particular, the micro-shielding region is provided to change a transparency of the micro-shielding region as a function of at least one characteristic. Preferably, the obscuring unit has at least one control unit which is provided to control the transparency of the micro-shielding area. A "transparency" is to be understood, in particular, as a property of at least one material, preferably optical, of allowing the passage of the electromagnetic radiation through the material at least partially. A "control unit" is to be understood in particular as a unit having at least one control unit. A "control unit" is to be understood in particular as meaning a unit having a processor unit and a memory unit as well as an operating program stored in the memory unit. In principle, the control unit can have a plurality of interconnected control units, which are preferably provided to communicate with each other via a bus system, such as in particular a CAN bus system. By an embodiment of the invention Advantageously, the transparency of the micro-shielding region can be selectively controlled, as a result of which a flexible shielding region with a selectively variable transparency can advantageously be achieved.

In addition, it is proposed that the darkening unit has at least one movable shielding element and / or at least one movable passage element. In particular, the blackout unit has the movable shielding element. Preferably, the obscuring unit has the movable passage member. In particular, the obscuring unit has the movable shielding element and the movable passage element. A "movable element" is to be understood in particular an element which is intended to change at least one geometry of the element and / or at least one position of the element. In particular, when projecting under a constant projection direction of the element into a plane, the element is intended to change an amount of an area covered by the element by more than 3%, preferably more than 5% and in particular more than 10%. Preferably, when projecting under the constant projection direction into the plane, the element is intended to change a position in the plane by more than 1 cm, preferably by more than 5 cm and in particular by more than 10 cm. By means of an embodiment according to the invention, the shielding element and / or the obscuration element can advantageously be moved and thus an arrangement of the two elements relative to one another can be changed, whereby flexibility can be increased.

Furthermore, it is proposed that the darkening unit comprises at least one magnetorheological material. In particular, the magneto-rheological material is at least partially formed as a magneto-rheological fluid. By the notion that the magneto-rheological material is "at least partially formed as a magneto-rheological fluid" is to be understood in particular that the magneto-rheological material to a mass fraction of more than 70%, preferably more than 80% and in particular more than 90% of the magneto-rheological fluid is formed. By a "magnetorheological material" is meant in particular a suspension of magnetic particles, preferably having a size in the range of a few microns, in a carrier. In particular, the magnetorheological material is intended to have at least one, preferably rheological, material property upon application of a magnetic field of less than 0.1 T, preferably less than 0.01 T and in particular less than 0.001 T, preferably rapid, in particular reversible, to change. Preferably, a change in the material property can be influenced by a variation of the field. In particular, the change in material property is proportional to a magnitude of the applied field. Preferably, when the field is applied, material property changes of several hundred percent can be achieved. In particular, the magneto-rheological material is provided, after switching off the applied field in its initial state, in particular in its state before application of the field, preferably quickly return. In particular, the particles are dispersed in the carrier at a volume fraction between 5% and 50% of a total volume of the magnetorheological material. Preferably, the particles are formed as ferromagnetic and / or paramagnetic particles. For example, the particles are formed as iron, iron oxide, iron nitride, iron carbide, carbonyl iron, nickel, cobalt, chromium oxide and / or a combination of at least one of the aforementioned materials with at least one further material. For example, the carrier is formed as polyalphaolefins, natural rubber, silicone, polybutadiene, polyethylene, polyisoprene and / or a combination of at least one of the aforementioned materials with at least one further element. A "suspension" is to be understood as meaning in particular a, preferably heterogeneous, mixture of substances comprising at least one carrier material and particles dispersed in the carrier material, preferably having a particle size of less than 100 μm, preferably less than 50 μm and in particular less than 10 μm , For example, the carrier material is formed as a liquid or a solid, in particular an elastomer. By "fast" in particular a period of a few milliseconds should be understood. A "magneto-rheological fluid" is to be understood as meaning, in particular, a magneto-rheological material in which the carrier is designed as a fluid. By means of an embodiment according to the invention, a material can advantageously be used which can be controlled in a targeted and simple manner.

It is also proposed that the darkening unit comprises at least one electroactive material. An "electroactive material" is to be understood in particular as meaning a material that can be influenced by means of at least one, preferably external, stimulus. In particular, the electroactive material is intended to have piezoelectric, pyroelectric and / or electrostrictive properties upon the action of the stimulus. In particular, the stimulus is designed as an electrical stimulus, preferably an electric field of less than 200 V / m, preferably less than 100 V / m and in particular less than 50 V / m. Preferably, the stimulus is formed as a mechanical stimulus, preferably as a force of less than 50 N, preferably less than 10 N and in particular less than 1 N. In particular, a property change is proportional to an amount of the stimulus. In particular, the electroactive material is faster than 1 s, preferably faster than 0.1 s and in particular faster than 0.01 s operable with changes in stimulus of the stimulus. In particular, the electroactive material is intended, upon the action of the electrical stimulus, to change at least one material property of the electroactive material by more than 5%, preferably more than 15%, in particular more than 30% and most preferably more than 40%. Preferably, the electroactive material is provided to change at least one transparency of the electroactive material upon the action of the electrical stimulus. In particular, the electroactive material is intended to mechanically deform upon exposure to the electrical stimulus. Preferably, the electroactive material is provided to induce a, preferably electromechanical, change in shape in the electroactive material by the action of the electrical stimulus by a mass shift, in particular an ion shift. In particular, the electroactive material is intended to induce the, preferably electromechanical, change in shape upon the action of the electrical stimulus by a, preferably electrical, charge transfer in the electroactive material. Preferably, changes in shape of several hundred percent can be achieved by the action of the electrical stimulus. In particular, the electroactive material is intended to generate an electrical voltage upon the action of the mechanical stimulus, preferably in the event of a change in shape due to the mechanical stimulus. Preferably, the electroactive material is formed as a laminate of at least two electrodes and at least one intermediate layer, preferably arranged between the electrodes. In particular, the intermediate layer is at least partially formed from a dielectric material. Preferably, the electrodes are intended to follow a change in shape of the electroactive material, in particular the intermediate layer. A "piezoelectric property" of a material should, in particular, be understood to mean a property which, upon the action of a mechanical stimulus on the material, results in at least one, preferably electrical, polarization change of more than 1%, preferably more than 3% and in particular more than 5%. induced. In particular, the piezoelectric property of the material is intended, upon the occurrence of a, preferably elastic, change in shape of the material induced by the action of a mechanical stimulus on the material, to have at least one, preferably electrical, voltage of more than 0.01 V, preferably more than 0.05 V and in particular more than 0.1 V to induce the material. A "pyroelectric property" of a material is to be understood in particular to mean a property which, upon the action of a thermal stimulus on the material, in particular a change in temperature, at least one, preferably electrical, polarization change of more than 1%, preferably more than 3% and especially induced by more than 5%. In particular, the polarization change is designed as a, preferably electrical, voltage. Preferably, a material having the pyroelectric property simultaneously has the piezoelectric property. An "electrostrictive property" of a material is to be understood in particular to mean a property which, upon the action of an electrical stimulus on the material, induces at least a change in shape of more than 1%, preferably more than 3% and in particular more than 5%. A "change of shape" is to be understood in particular as meaning a deformation and / or extension change. A "laminate" should in particular be understood to mean an element having at least two layers arranged next to one another. In particular, the layers are arranged flat against each other, preferably glued. By means of an embodiment according to the invention, the darkening unit can advantageously have a material whose transparency can be influenced in a targeted manner, as a result of which a flexible, comfortable darkening unit can be achieved.

In addition, it is proposed that the electroactive material is at least partially formed as an electroactive polymer. An "electroactive polymer" is to be understood as meaning in particular an electroactive material in which the material is formed as a polymer. By the term that the electroactive material is "at least partially formed as an electroactive polymer", it should be understood in particular that the electroactive material to a mass fraction of more than 70%, preferably more than 80% and in particular more than 90% of the electroactive material is formed of an electroactive polymer. By means of an embodiment according to the invention, an electroactive polymer can advantageously be used as the electroactive material, as a result of which a material adapted to specific needs can advantageously be used.

Furthermore, it is proposed that the darkening unit has an area whose partial darkening distribution can be changed as a function of at least one parameter. In particular, the surface has at least two surface subareas, each having a selectively variable transparency. Preferably, individual surface subregions of the surface have a specifically variable transparency. For example, at first a surface partial region is intransparent and a further surface region which is at a distance from the one surface region is transparent and, after a change as a function of the parameter, is transparent Area subarea transparent and the other surface area intransparent. In particular, the obscuration distribution can be controlled by the control unit. Preferably, the control unit is provided to control the parameter, in particular to influence. By "partial" should be understood in particular partially. A "darkening distribution" of the surface should in particular be understood to mean a geometric arrangement of the micro-shielding region and the micro-transmission region relative to one another on the surface. In particular, the darkening distribution is formed as a geometric arrangement of at least two surface subregions of the surface of differing transparency, preferably relative to one another. A "partial darkening distribution" of the surface is to be understood in particular as a darkening distribution of the surface in which the surface has at least two surface subareas which are intended to set a transparency of one of the surface subregions independent of a transparency of a further one of the surface subregions in at least one state. In particular, the transparency of a respective one of the surface subregions in the state is free, in particular independent, changeable, preferably controllable, in particular influenceable. A "parameter" should be understood to mean, in particular, a variable, depending on which the darkening distribution can be changed. For example, the parameter is designed as a, preferably predefined, period of time. In particular, the parameter is designed as a, preferably external, stimulus. Preferably, the characteristic is designed as a, preferably electrical, voltage. In particular, the parameter is designed as a magnetic field. By means of an embodiment according to the invention, it is advantageously possible to change a darkening distribution as a function of the characteristic variable and thus to achieve a flexible darkening unit. In addition, a partial darkening can advantageously be achieved in areas in which, in principle, a sunshade is arranged.

It is also proposed that the blackout unit has at least one field-generating unit which is intended to generate at least one field. In particular, the field generation unit is intended to generate at least one electric field. Preferably, the field is formed as an electric field. In particular, the field generation unit is intended to generate at least one magnetic field. Preferably, the field is formed as a magnetic field. In particular, the field generating unit is controllable by the control unit. Preferably, the field generation unit is provided to generate the characteristic for the change in the blackout distribution. In particular, the parameter is designed as the field. Preferably, the control unit is provided to control the parameter by means of the field generation unit, in particular to generate. A "field generating unit" is to be understood in particular as a unit which is intended to generate an inner and / or an outer field. In particular, the field-generating unit is provided to influence by means of the field at least one unit, in particular the blackout unit, specifically, preferably on schedule, in particular consciously. An "inner field" is to be understood in particular as a field within the unit. An "external field" is to be understood as meaning, in particular, a field outside the unit. In particular, the field generation unit is intended to generate the external field outside the unit. By means of an embodiment according to the invention, the blackout unit can advantageously generate the field by means of the field-generating unit, as a result of which flexible activation of the micro-shielding region and / or of the micro-passband can be realized.

In addition, a darkening, in particular a sunscreen, proposed with a darkening device according to the invention. By an embodiment according to the invention can advantageously be equipped with a darkening Verdunklungsvorrichtung invention and thus a flexible, comfortable darkening can be achieved.

Furthermore, a method is proposed for operating a darkening device according to the invention, in which at least one micro-shielding region and / or at least one micro-passband region is actuated. By means of an embodiment according to the invention, the dimming device can advantageously be operated safely, precisely, reproducibly and conveniently.

The darkening device according to the invention should not be limited to the application and embodiment described above. In particular, in order to fulfill a mode of operation described herein, the darkening device according to the invention can have a number deviating from a number of individual elements, components and units mentioned herein.

drawing

Further advantages emerge from the following description of the drawing. In the drawing, three embodiments of the invention are shown. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

Show it:

1 a detail of a darkening according to the invention with a darkening device according to the invention in a plan view in a greatly enlarged view,

2 a detail of another embodiment of a darkening according to the invention with a darkening device according to the invention in a plan view in a greatly enlarged view and

3 a section of a further embodiment of a darkening according to the invention with a darkening device according to the invention in a plan view in a greatly enlarged view.

Description of the embodiments

1 shows a section of a darkening according to the invention 26a with a darkening device according to the invention 10a in a first embodiment of the invention in a plan view in a greatly enlarged view. The darkening 26a is designed as a sunscreen. The darkening 26a is designed as a double-walled disc. The darkening device 10a is inside the blackout 26a arranged. And that is the darkening device 10a between the two discs of the obscuration 26a arranged. The darkening 26a includes the dimming device 10a with a blackout unit 12a which has several controllable micro-shield areas 14a and a plurality of controllable micro-pass regions 16a having. In 1 For the sake of clarity, only one of the micro-shield areas is in each case 14a and one of the micro-pass regions 16a provided with reference numerals. In the following, only one of the micro-shield areas will be respectively 14a and one of the micro-pass regions 16a described since they are each formed identically and differ substantially only in one arrangement.

The blackout unit 12a has a control unit 28a , which is intended to the micro-shield area 14a as well as the micro-passband 16a head for. The microscreen area 14a has a controllable transparency. And that is the microscreen area 14a provided, depending on a characteristic, the transparency of the micro-shielding area 14a to change. The control unit 28a is intended to increase the transparency of the microscreen area 14a to control. The blackout unit 12a has an area 22a whose partial darkening distribution can be changed depending on the parameter. The area 22a fills one of the blackout 26a essentially spanned level. The control unit 28a is on a side edge of the surface 22a arranged. And that encloses the control unit 28a the area 22a Completely. The control unit 28a is as a frame of the plane 22a educated. Both the control unit 28a as well as the area 22a are inside the blackout 26a arranged.

The blackout unit 12a has a field generation unit 24a which is intended to create a field. The characteristic is designed as the field. The field generation unit 24a is intended by the control unit 28a to be operated. The control unit 28a is integral with the field generation unit 24a educated. The field generation unit 24a is at the side edge of the surface 22a arranged. And that encloses the field generation unit 24a the area 22a Completely. The field generation unit 24a is as a frame of the plane 22a educated. The area 22a has individual surface subareas 30a on whose darkening distribution can be changed depending on the characteristic. And that is a transparency of the subareas 30a changeable depending on the parameter.

Also provided is a method for operating the darkening device according to the invention 10a in which the microshield areas 14a and micro-pass areas 16a be controlled. In a first method step receives the control unit 28a a command of which the area sub-areas 30a the area 22a the transparency is to be changed and to what extent. In a further method step, the control unit operates 28a the field generation unit 24a , then the field at the desired or the area of the subregions 30a generated. This will increase the transparency of the subarea area 30a changed to the desired extent.

In the present embodiment, the blackout unit comprises 12a an electroactive material. The microscreen area 14a the blackout unit 12a is partially formed of the electroactive material. The electroactive material is partially formed as an electroactive polymer. As already mentioned, the microscreen area 14a the controllable transparency. The transparency of the microscreen area 14 is controllable depending on the parameter. The control unit 28a is intended for use by the field generation unit 24a to control the characteristic. The field generation unit 24a is intended to generate an electric field. The field is designed as an electric field. The area 22a includes a variety of power lines 32a , Two adjacent power lines 32a are aligned parallel to each other. power lines 32a , which are on a side edge of the area 22a start are orthogonal to power lines 32a aligned, one at the one side edge of the surface 22a adjacent side edge of the area 22a kick off. The power lines 32a shape a rectangular pattern. The power lines 32a limit the respective subareas 30a the area 22a , Within each of the subareas 30a There are a total of six microshield areas 14a arranged. Each of the area subareas 30a is by means of the control unit 28a targeted and individually controllable.

In 1 is a transparency of each of the micro-shield areas 14a characterized by a respective hatching. A micro screen area 14a Hatching is darkened and designed to partially prevent passage of electromagnetic radiation in a region of visible light. A micro screen area 14a while avoiding hatching, it is transparent and intended to allow electromagnetic radiation to pass in a range of visible light.

In 2 and 3 in each case a further embodiment of the invention is shown. The following descriptions and the drawings are essentially limited to the differences between the exemplary embodiments, with reference in principle to the same reference components, in particular with respect to components with the same reference numerals, to the drawings and / or the description of the other embodiments, in particular 1 , can be referenced. To distinguish the embodiments, the letter a is the reference numerals of the embodiment in 1 readjusted. In the embodiments of the 2 and 3 the letter a is replaced by the letters b and c.

2 shows a section of a further embodiment of a darkening according to the invention 26b with a darkening device according to the invention 10b in a plan view in a greatly enlarged view. The darkening 26b includes the dimming device 10b with a blackout unit 12b which has several controllable micro-shield areas 14b and a plurality of controllable micro-pass regions 16b having. In 2 For the sake of clarity, only one of the micro-shield areas is in each case 14b and one of the micro-pass regions 16b provided with reference numerals. In contrast to the embodiment of 1 is in the embodiment of 2 the darkening device 10a formed as a perforation. Analogous to the embodiment of the 1 includes the blackout unit 12b a control unit 28b , which is intended to be a field generating unit 24b to press. In addition, the blackout unit includes 12b the field generation unit 24b which is intended to generate a field. The blackout unit 12b has an area 22b whose partial darkening distribution can be changed depending on the parameter. The characteristic is formed as the field, wherein the field is formed as an electric field. Analogous to the embodiment of the 1 is the area 22b by means of power lines 32b in subareas 30b divided. Again includes the blackout unit 12b an electroactive material, wherein the electroactive material is partially formed as an electroactive polymer.

In a difference to the blackout unit 12a of the embodiment of 1 indicates the blackout unit 12b several movable shielding elements 18b and a plurality of movable passage members 20b on. The micro passbands 16b are integral with the passage elements 20b educated. The microshield areas 14b are integral with the shielding elements 18b educated. The microshield areas 14b together form a blackout element 34b out. The darkening element 34b and the micro-passbands 16b together form the perforation. The area 22b is by means of the power lines 32b in the subareas 30b divided. By means of the control unit 28 are the individual surface areas 30b specifically controlled. The microshield areas 14b are intended to produce a change in shape as a function of the parameter. And that are the microshield areas 14b intended to expand in the presence of the characteristic. If the field is on one of the subareas 30b on, so stretch in the area of the area 30b located Mikroabschirmbereiche 14b out. And indeed, the micro-shield areas stretch 14b into one of the micro-pass areas 16b occupied space out. With expansion of the microshield areas 14b shrink the micro passbands 16b , As a result, there is a darkening of the corresponding area of the area 30b realizable. In the absence of the field, the micro-shield areas are reversed 14b and hence the micro-passbands 16b back to an original shape and arrangement.

3 shows a section of a further embodiment of a darkening according to the invention 26c with a darkening device according to the invention 10c in a plan view in a greatly enlarged view. The darkening 26c includes the dimming device 10c with a blackout unit 12c which has several controllable micro-shield areas 14c and a plurality of controllable micro-pass regions 16c having. In 3 For the sake of clarity, only one of the micro-shield areas is in each case 14c and one of the micro-pass regions 16c provided with reference numerals. The blackout unit 12c includes a control unit 28c , which is intended to be a field generating unit 24c to press. In addition, the blackout unit includes 12c the field generation unit 24c which is intended to generate a field. The blackout unit 12c has an area 22c whose partial darkening distribution can be changed depending on the parameter. The characteristic is designed as the field.

Analogous to the embodiment of the 2 indicates the blackout unit 12c several movable shielding elements 18c and a plurality of movable passage members 20c on. The micro passbands 16c are integral with the passage elements 20c educated. The microshield areas 14c are integral with the shielding elements 18c educated.

In a difference to the embodiments of the 1 and 2 the field is formed as a magnetic field. The blackout unit 12a includes a magneto-rheological material. The magneto-rheological material is within the darkening 26c arranged, with the obscuration 26c is designed as a double-walled disc. And that is the magneto-rheological material between two discs of the darkening 26c arranged. The magneto-rheological material is essentially designed as a magneto-rheological fluid. The magneto-rheological fluid is understood to mean a suspension of magnetic particles in a carrier, wherein the carrier is formed as a liquid. The microshield areas 14c are formed as the magnetic particles. The micro passbands 16c are formed as liquid particles. In the following, only one of the micro-shield areas will be respectively 14c and one of the micro-pass regions 16c described since they are each formed identically and differ substantially only in one arrangement.

The microscreen area 14c is intended, depending on the characteristic a position within the area 22c to change. In addition, the microscreen area 14c provided, depending on the characteristic any position within the area 22c to accept. In the present embodiment, a surface part area 30c in the middle of the area 22c darkens. The area subarea 30c includes a plurality of microshield regions 14c , which due to a change in the characteristic to the position of the surface portion 30c are arranged. This is the area of the area 30c darkens. If the area 22c On the other hand, it should be made transparent, then the micro-shielding areas 14c by means of the characteristic at a certain position, for example at a side edge, of the surface 22c arranged. This particular position is through the microscreen areas 14c darkens, leaving a remaining part of the area 22c is transparent.

Analogous to the preceding embodiments of the 1 and 2 are the field generation unit 24c and the control unit 28c integrally formed and on a side edge of the surface 22c arranged. This includes the field generation unit 24c and the control unit 28c the area 22c Completely. The field generation unit 24c is intended to produce a field whose field lines are substantially perpendicular to the surface 22c are aligned. The field generation unit 24c includes a plurality of juxtaposed coils (not shown), which are each individually controllable. Around the micro screen areas 14c in the area subarea 30c To move, coils are first placed on one side of the surface 22c activated to the micro-shield areas 14c to move away from the specific position. Then the micro-shield areas move 14c in the direction of the surface partial area 30c , To the movement of the micro-shield areas 14c to stop and the micro screen areas 14c in the area subarea 30c To keep coils are activated on one side opposite one side. In such a way, a position of the surface portion is 30c adjustable.

A person skilled in the art will also apply the embodiments described above and their respective features in combination. For example, it is conceivable that a darkening device according to the embodiment of the 1 with a darkening device according to the embodiment of 3 combined. Likewise, further combinations are conceivable. In particular, further combinations between the embodiments are conceivable. Preferably, further combinations of the exemplary embodiments appearing appropriate to a person skilled in the art are conceivable.

Claims (10)

Dimming device, in particular sun protection device, with at least one dimming unit ( 12a C) which comprise at least one controllable micro-shielding region ( 14a C) and / or at least one controllable micro-passband ( 16a -C). Dimming device according to claim 1, characterized in that the micro-shielding region ( 14a ) has controllable transparency. Dimming device according to one of the preceding claims, characterized in that the dimming unit ( 12b . 12c ) at least one movable shielding element ( 18b . 18c ) and / or at least one movable passage element ( 20b . 20c ) having. Dimming device according to claim 3, characterized in that the darkening unit ( 12c ) comprises at least one magneto-rheological material. Dimming device according to one of the preceding claims, characterized in that the dimming unit ( 12a . 12b ) comprises at least one electroactive material. Dimming device according to claim 5, characterized in that the electroactive material is at least partially formed as an electroactive polymer. Dimming device according to one of the preceding claims, characterized in that the dimming unit ( 12a -C) an area ( 22a C) whose partial darkening distribution can be changed as a function of at least one parameter. Dimming device according to one of the preceding claims, characterized in that the dimming unit ( 12a (C) at least one field-generating unit ( 24a -C), which is intended to generate at least one field. Darkening, especially sunscreen, with a darkening device ( 10a C) according to any one of claims 1 to 8. Method for operating a darkening device ( 10a C) according to one of Claims 1 to 8, in which at least one micro-shielding region ( 14a C) and / or at least one micro-passband ( 16a -C) is controlled.

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