DE102011015948A1 - Optical component e.g. smart glass, for use on roof of vehicle, has fluid layer arranged on electrode, and another electrode arranged on fluid layer, where electrodes are formed as inert metallic grid - Google Patents

Abstract

The component (1) has an electrode (4) arranged on a transparent carrier layer (2), and a fluid layer (6) provided with suspended particles and arranged on the electrode. Another electrode (5) is arranged on the fluid layer, and another carrier layer (3) is arranged on the latter electrode. The electrodes are formed as an inert metallic grid and made of silver and/or copper material. The carrier layers are made of plastic material such as polycarbonate, polymethyl methacrylate or poly ethylene terephthalate, and/or glasses. The electrodes are formed as a reflective layer. An independent claim is also included for a method for manufacturing an optical component.

Description

The invention relates to an optical component which is reversibly variable in its transparency by an electrical potential, according to the type defined in the preamble of claim 1. The invention also relates to a method for producing such a component.

So-called smart windows are known from the general state of the art. Such smart windows or smart glasses consist essentially of two transparent carrier layers and two transparent electrodes arranged thereon and an active region arranged therebetween. This active region may preferably be formed as a fluid layer or polymer matrix with suspended particles suspended therein. If a corresponding potential is applied to the electrodes, an alignment of the suspended suspended particles and thus a transparency of the component occurs. If the electrical potential is reduced or switched off completely, the suspended suspended particles will become statistically distributed, as a result of which light entering through the carrier layers will absorb correspondingly and the component will become dark. By means of such structures, for example window panes or other optical components can be switched electrically between full transparency and a dark (eg dark blue) state. This can z. For example, it can be prevented that thermal radiation passes through a disk and, for example, unnecessarily heats up a vehicle equipped with such disks unnecessarily.

The problem with such optical components lies in the fact that the commonly used transparent electrodes are very sensitive. In particular, a slight bending of the component is already sufficient in order to generate cracks in the transparent electrode and thus adversely affect the functionality. On the one hand, such bending and the associated risk of crack formation can already be achieved by a different expansion behavior of the different materials when the component is heated or cooled, and on the other hand, during assembly. Because of this fragility of the transparent electrodes, comparatively stable and therefore heavy and expensive carrier layers of glass are usually used in order to make the overall structure for storage and assembly so manageable that it can be moved and mounted without the immediate risk of damage. Another reason for the use of glass is that the transparent electrodes usually by temperature-intensive process -. As sputtering - are applied to the substrate and many plastics are not sufficiently temperature resistant. Due to the aforementioned material-specific requirements, a forming of a component semifinished product is possible only within very narrow limits, so that such components are usually designed planar.

Furthermore, from the US 5,903,382 a structure is known in which between two carrier layers and electrodes and an electrolyte is introduced. With an appropriate voltage or corresponding potential between the electrodes, active deposition of particles on one of the electrodes occurs, whereby a change in the color and / or the transparency of the structure is achieved. This construction is so far reversible that the particles which have undergone a chemical bond to the electrode migrate back into the solution by reversing the potential and thus change the color and transparency of the structure again. The problem with this structure, which uses a metallic grid as one of the electrodes, is essentially that the electrode is actively involved in the electrochemical process and thereby some wear of the electrode occurs over time. The electrochemical classification behind this structure also causes a very slow response compared to the components described above with a fluid layer having suspended therein suspended particles, since the electrochemical processes for attaching the substances to the electrode grid and re-dispersing them into the solution are comparatively tedious and cause long switching times.

The object of the present invention is now to avoid these disadvantages and to provide such an optical component, which is easy and safe to handle, and which has a high mechanical flexibility. In addition, a more complex, especially non-planar design should be possible.

According to the invention this object is achieved by the features mentioned in the characterizing part of claim 1. Further advantageous embodiments of the optical component according to the invention will become apparent from the dependent therefrom dependent claims.

The essence of the invention is to replace the hitherto conventional transparent electrode by an electrode which is formed from an inert metallic grid. Under inert in the sense of the present invention, a metallic lattice is understood, which is not involved in electrochemical processes in the optical component, which thus fulfills only the functionality of an electrode of a capacitor and not, as in the last-mentioned prior art, as electrochemical active component is involved. This construction with an electrode made of an inert metallic grid has the advantage that the metallic grid, for example based on silver or copper, can be produced with high conductivity. It can be realized extremely thin, so there is no visual impairment due to the metallic grid. Nevertheless, it has a very high conductivity and its mesh size can easily and easily be adapted to the respective requirements. The metallic grid is very flexible compared to a conductive transparent layer, which offers the decisive advantage that the carrier layers can be designed correspondingly thinner and more flexible. In particular, it is possible for the first time by means of the component according to the invention to produce the carrier layers from a flexible, deformable plastic material, and thus to achieve a high degree of flexibility of the device during assembly. In particular, curved structures can also be realized with the electrical component according to the invention during assembly.

The metallic grid as an electrode also allows better conductivity than the usual transparent electrically conductive layers. This makes it possible to realize a better switchability between the individual states as a further advantage of the component according to the invention. In particular, the degree of transparency can be set much easier. For switching between full transparency and a dark (eg, dark blue) state, a relatively high voltage is necessary to align the suspended particles (electric field).

Another advantage is that electrical resistance of the structure can be realized by the resistance in the metallic grid of the electrode. In particular, at very low temperatures, as may occur, for example, in roofs of vehicles at correspondingly low ambient temperatures, this is a decisive advantage, since a much faster switching can be realized by the heating of the component according to the invention, as in the previous components, which at Low ambient temperatures react very slowly. This can also be used to defrost the disc.

In a preferred embodiment of the optical component according to the invention, it is also provided that the at least one electrode is formed as a grid printed on one of the carrier layers. This preferred construction allows for a very simple production of the component according to the invention, since the electrode can be applied to one or both of the carrier layers, for example by screen printing or the like. Thus, carrier layers can be prefabricated with electrodes, which can then be connected to each other via the layer of suspended suspended particles to the final component simply and efficiently.

Further advantageous embodiments of the invention will become apparent from the remaining dependent claims and will become apparent from the embodiment, which will be described below with reference to the figures.

Showing:

1 a schematic diagram of the structure according to the invention in a first switching state; and

2 a schematic diagram of the structure according to the invention in a second switching state;

In the presentation of the 1 is a schematic diagram of the optical component according to the invention 1 to recognize. This should be designed as a so-called smart glass or smart window. The in 1 shown section consists of a first carrier layer 2 and a second carrier layer 3 , These carrier layers 2 . 3 are as transparent carrier layers 2 . 3 formed and may for example be made of glass, but in particular of plastic materials, such as polycarbonate (PC), polymethylmethacrylate (PMMA), polyethylene terephthalate (PET) or the like. On these two carrier layers 2 . 3 is each an electrode 4 . 5 applied. This can be glued, vapor-deposited or more preferably printed by a screen printing process. The electrodes 4 . 5 consist of metallic lattices, which with a highly conductive metallic material, such as silver, copper or the like, on the carrier layers 2 . 3 are applied. The electrodes 4 . 5 are in the mesh size and the strength of the individual strands of the grid designed so that they ensure sufficient electrical conductivity and also the optical transparency of the component 1 not adversely affect. Between these two electrodes is then a fluid layer 6 arranged with suspended particles suspended therein. This is known per se from the general state of the art; DE 102008030441 B3 the applicant, which describes such a layer by way of example.

The construction, especially when using carrier layers 2 . 3 is made of flexible plastic materials, is very flexible and easy to handle and assemble. The existing in the constructions of the prior art danger that the electrode in bending of the structure damaged is largely excluded here. The high flexibility of the electrodes 4 . 5 allows, for example, a structure of the component 1 , which can be brought into a curved shape during assembly. In addition, it is compared to the use of relatively heavy and fragile glasses as support layers 2 . 3 especially easy. In particular, when used in vehicles created by the flexible carrier layers 2 . 3 In addition, a decisive safety advantage, since in the case of an accident does not have to be expected with glass splinters.

The electrodes 4 . 5 can be controlled with an electric potential, which is symbolized here by a voltage U. In the fluid layer 6 suspended particles are suspended in the de-energized state of the electrodes 4 . 5 are arranged with evenly distributed in all spatial directions alignments, as in 1 is shown. The component 1 therefore absorbs through the transparent carrier layers 2 . 3 falling light so that it appears dark. In this state, the optical component 1 be used as a screen and also prevents the incidence of heat radiation, for example, in a with such a component 1 equipped vehicle, so that a thermal heating of the same can be significantly reduced.

By applying a potential U, those in the fluid layer become 6 suspended suspended particles are increasingly aligned with increasing potential, so that they all point in a spatial direction, as in 2 is indicated. The incident light is then no longer absorbed, but passes through the component 1 through, so that at full potential a complete or almost completely transparent component 1 arises.

The optical component 1 is thus switchable by a suitable potential regarding its transparency. Since the suspended suspended particles are aligned more strongly with increasing potential, the structure can be influenced almost arbitrarily in its transparency, so that not only can be switched back and forth between a fully transparent and a dark state, but ideally also between intermediate states in which the suspended particles are suspended Suspended particles have different degrees of orientation, ie the degree of alignment varies.

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

• US 5903382 [0004]
• DE 102008030441 B3 [0015]

Claims (7)

Optical component ( 1 ), which is reversibly variable in its transparency by an electrical potential, with a first transparent carrier layer ( 2 ), a first electrode ( 4 ), a fluid layer ( 6 ) with suspended particles suspended therein, a second electrode ( 5 ) and a second carrier layer arranged thereon ( 3 ), characterized in that at least one of the electrodes ( 4 . 5 ) is formed as an inert metallic grid. Optical component ( 1 ) according to claim 1, characterized in that the at least one electrode ( 4 . 5 ) Has silver and / or copper. Optical component formed as an inert metallic grid ( 1 ) according to claim 1 or 2, characterized in that both electrodes ( 4 . 5 ) are formed as an inert metallic grid. Optical component ( 1 ) according to one of claims 1, 2 or 3, characterized in that at least one of the carrier layers ( 2 . 3 ) consists of a plastic material, in particular of PC, PMMA or PET, or consists of glass. Optical component ( 1 ) according to one of claims 1 to 4, characterized in that at least one of the electrodes ( 4 . 5 ) than on one of the carrier layers ( 2 . 3 ) is formed on printed grid. Optical component ( 1 ) according to one of claims 1 to 5, characterized in that one of the electrodes ( 4 . 5 ) is formed as a reflective layer. Method for producing an optical component ( 1 ) according to one of the preceding claims, characterized in that the electrodes ( 4 . 5 ) on the respective carrier layer ( 2 . 3 ), the two coated carrier layers ( 2 . 3 ) with the electrodes ( 4 . 5 ) with the fluid layer ( 6 ) are joined and connected with floating particles suspended therein, preferably by roll calendering.

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