WO2007110336A1 - Laser detection indicating apparatus with an organic photoactive material - Google Patents

Abstract

The invention relates to a laser beam detector, in particular a laser beam detector which can be applied in a cost-effective manner and over a large area. The laser beam detector comprises a substrate (1) having two electrodes (2, 6) and at least one layer (5) of organic photoactive material. The indicating device can be produced using mass production and can be realized on flexible substrates and/or in semitransparent form, if necessary. Practically all surfaces of objects and/or people which/who can be exposed to a laser beam can thus be equipped with such an indicating apparatus.

Description

description

DISPLAY DEVICE FOR LASER DETECTION WITH AN ORGANIC PHOTOACTIVE MATERIAL.

The invention relates to a laser beam detector, in particular a cost-effective and large-area applicable laser beam detector.

Many modern weapon systems work with the help of laser-guided systems (precision weapons). The prerequisite for using these systems is a laser beam that illuminates the target. The modulation of the light beam with a bestimm ^¬ th frequency allows the laser seeker head of a bomb or Ent ^¬ fernungsmesseinrichtung to recognize which of several possibly illuminated targets is your own. This laser beam can emanate either from a ground-based soldier equipped with a laser aiming light, from another aircraft or helicopter, or even from the attacking aircraft itself, when equipped with an appropriate laser aiming system. If the target is illuminated with the laser be ^¬ and the seeker has captured the reflection, the weapon can be thrown off. Now follows the light reflected from the target laser beam, a continuous and sta ^¬ bile illumination of the target is very important. A "wandering" target illumination forces the target detection device to correct the bomb trajectory.

In addition, there is the so-called laser radar, whereby the target region is scanned with the help of a laser and potential targets are independently recognized by the system.

Therefore, it is important that devices are provided which indicate the impact of a laser beam on an object or egg ^¬ ne person.

Although a laser beam detector is known from US Pat. No. 5,923,029, but which has a complicated structure and is certainly too costly to manufacture in order to cover a large area. to be portable. In addition, this laser beam detector can be applied neither on flexible nor on moldable substrates.

The object of the invention is therefore to provide a display device indicating whether a laser beam is directed to an object and / or a person. Furthermore, it is an object of the invention to provide the display device so that it can be applied over a large area and produced inexpensively.

This object is achieved by the subject matter of the claims to the ^¬ connexion with the description.

The invention relates to a display device for laser detection, comprising at least the following structure:

A substrate, thereon at least two electrodes with at least one layer of organic photoactive material in between, wherein at least one of the two electrodes and, if the substrate is on the same side of the at least one organic photoactive layer as this electrode, also the substrate, at least in the relevant radiation range, is transparent.

Surprisingly, it has been found that in the field of photoactive layers the reliability of the organic semiconductor materials is so close to that of the typical inorganic semiconductor materials that use of the organic semiconductor materials is also acceptable for such sensitive areas.

To that extent in the novel nature, or ^¬ ganic semiconductor electronics of the display device will enable the large-scale laser detection, the only usable electric ^¬ technology, since the conventional semiconductor technology would never have such a large area to apply. Inorganic photodetectors are ren Although similar efficiency as the organic Photodetekto ^¬, but, due to the complex coating not treatment technologies suitable for mass production on Substra- in the square centimeter range or even in the square meter range.

In addition, the present invention recognizes for the first time how important the large-area applicability is even on flexible, bent or also flexible and shapeable substrates for this technical field. Be at ^¬ play, in people with the helmets display devices may according to the invention equipped with simple coating so that an early warning of the soldiers is possible. Likewise, the display devices may be mounted as equipment on curved vehicle surfaces.

Finally, organic display devices are after a

Embodiment of the invention also semitransparent feasible, so that when both substrate, and organic semiconductors and the encapsulation in the visible range are sufficiently transparent, the windows of buildings or vehicles are protected with this technology.

When equipping large surfaces with such display devices in the form of, for example, tiles or webs, it will normally be sufficient to use simple electronics for the detection of the signal, since it is often sufficient to determine that an object or a person is ever one of them Laser is illuminated. In a second step, however, the electronics could then in principle also locate on which diode element the signal was detected and thereby narrow down the location of the laser.

According to an advantageous embodiment, the laser detector is still protected against moisture, mechanical damage, other radiation and or gases by an encapsulation. The encapsulation, if it is in front of the organic photoactive layer, is also transparent to the radiation to be detected. The radiation to be detected of the laser used for targeting is often in the near infrared range.

The substrate may be, for example, glass, quartz or synthetic support material. For example, however, the object itself or its housing, ie, for example, in the case of large-area potential targets such as house facades, trains, vehicles, aircraft, ships, and other surfaces thereof, may be the substrate, so that the lower electrode, directly onto the surface of the object, the organic photoactive

Layer and then the upper electrode and possibly the encapsulation is applied.

According to a further advantageous embodiment, however, the substrate is also a flexible substrate, for example made of a foil made of metal or a polymer film such as PET, PE, etc.

The conductive layers or the electrode layers may be made of metal, which may also be applied transparently via certain application methods. On the other hand, the electrodes may also be made of a conductive organic material. Finally, it is possible to apply conductive, possibly even transparent layers of metal oxides. A classic example of the metal oxide electrode is the ITO electrode made of indium tin oxide, that is, an indium tin oxide layer that is transparent.

By "transparency", is meant in this context that the layer is at least for the radiation to be detected transpa rent ^¬, the transparency can of course also to visible light and / or reflect radiation other ranges.

Between the two conductive layers of the laser beam detector is the layer of organic photoactiv ^¬ vem material. The term "organic material" here includes all types of organic, organometallic and / or inorganic plastics, which in English, for example, with "plastics" be designated. These are all types of materials, with the exception of semiconductors, which form the classical diodes (germanium, silicon), and the typical metallic conductor. A limitation in the dogmatic sense on organic material as a carbon-containing material is not provided by the ^¬, but is also the broad use of, for example silicones and other compounds intended classic as the inorganic substances referred to. For example, there are inorganic hybrid plastic materials whose range of properties has not yet been fully explored and their

Is not be ruled usability for these photoactive layers ^¬ close. Furthermore, the term should not be restricted in terms of molecular size, in particular to polymeric and / or oligomeric materials, but it is also quite possible to use "small molecules".

The organic photoactive material can, for example, a buik Heterjunction sen blend of a hole transporting material (for example polythiophene), and an electron transported tierendem material (such. As a fullerene derivative) umfas ^¬. All components of the blend can contribute to the absorption and thus to the spectral sensitivity of the sensor. By suitable choice of the blend components and their mixing ratio, the adaptation of the spectral sensitivity to the light source to be detected is possible.

A particular advantage of the display device according to the invention is the cost-effective production method of organi ^¬ rule semiconductor systems, especially in comparison to the see inorganic semiconductor systems. Many organic photoactive

Layers can be applied from solution. As a result, established cost-effective methods for coating large areas can be used. Examples of these are doctoring, spin coating, spray coating and / or printing processes.

Typically, the organic layer is brushed on the first electrode is applied, under some circumstances the peripheral region can be released single ^¬ Lich or subsequently by organic nical material to allow for sealing or encapsulation.

For protection against moisture and oxygen, for example, the component is either adhesively ^{bonded to} another substrate or sealed with a thin-film encapsulation (a layer system of organic and / or inorganic barrier layers).

For recognition of the laser irradiation of buildings, plants, tanks, aircraft and / or vehicles in front of a potential attack large area display devices of the invention are widely as possible applied to the surfaces of the Au ^¬ ßenwände. Advantageous dimensions of the individual surface diodes are in the range of a few cm * 2 (square centimeter) to several square meters. These single area display devices or photodiodes or laser beam detectors can be mounted on the surfaces similar to tiles or wallpaper sheets. For detecting a laser irradiation in the course of an attack the Elect ^¬ are clear couple the respective tiles or sheets, for example, via wires / lines connected and or or the like to an electronic circuit which detects the change of the diode current as a signal upon irradiation at any point. The display device may be as set out in the form of a tile or a sheet member as a flat finished ^¬.

According to one embodiment of the invention, a high-resolution detection of the illuminated object or of the illuminated person is possible. For this purpose, the organic display devices are produced in the form of pixelated panels with which a higher spatially resolved signal can be obtained by active matrix or passive matrix control. The active organic layer can also be unstructured, only the electrodes are structured differently depending on the driving method. For active matrix control In addition, the integration of one transistor per pixel may be necessary.

Basically it is also possible to measure with the organic basier- th display apparatus according to the invention, the signal of a laser on time-resolved, for example if can be drawn from the modu ^¬ lationsfrequenz conclusions about the type of laser or the weapon.

The figure shows an example of the structure of a display device according to an embodiment of the invention, wherein there are two active organic layers, a hole transporter and the photoactive layer. The encapsulation is not visible on the image, but would encompass the entire device so that it forms the "capsule" with the substrate.

Details of the figure: Below is the substrate 1, for example a transparent or semitransparent flexible thin film. On the substrate, the lower electromagnet ^¬ is de 2, for example, an ITO, or a metal electrode, wherein ^¬ play followed by an optional hole transport layer 4. Then lies the at least one photoconductive so pho ^¬ toaktive organic layer here a as buik Heterjunction as a blend of hole-transporting and an electron-transporting material, for example of polythiophene as a hole transporter and a fullerene derivative as electron-transporting layer 5 is formed. About the organic ^¬ rule photoactive layer 3, the upper electrode is 6. Between the upper electrode 6 and the lower electrode 2, there is an electrical contact. 7

The invention provides a large-area display device ^¬ is first provided for detecting a laser beam. The display device is massenfertigungstaug ^¬ Lich, inexpensive to produce, on flexible substrates and / or optionally semitransparent realized. Virtually all surfaces of objects and / or per- son, who may be exposed to a laser beam, equipped with such a display device.

Claims

claims 1. Display device for laser detection, the following structure at least comprising: a substrate, thereon at least two electrodes with at least one layer of organic photoactive material in between, wherein at least one of the two electrodes and, if the substrate on the same side of the at least one orga ^¬ African photoactive layer, such as this electrode, and the substrate is at least transparent in the relevant radiation range, so that a penetration from the outside Strah ^¬ lung in the display device in an electrical signal converted is. 2. Display device according to claim 1, wherein the substrate is a flexible substrate. 3. Display device according to claim 1 or 2, wherein the substrate is part of the object protected by the display device or its housing. 4. Display device according to one of the preceding claims, comprising an encapsulation. 5. Display device according to one of the preceding claims, wherein the layer of photoactive material comprises a blend of ^{¬ at} least two components, a hole-transporting and an electron-transporting. 6. Display device according to one of the preceding claims, the ten by the selection and the mixing ratio of Components in Blend ^¬ with spectral sensitivity of which is adapted to be detected laser source. 7. Display device according to one of the preceding claims, which comprises an area of at least a few cm ² . A display device according to any one of the preceding claims, having an active matrix or passive matrix drive. 9. Display device according to one of the preceding claims, wherein from the signal, the modulation frequency of the received Radiation is derivable. 10. Display device according to one of the preceding claims, which is a flat prefabricated component. 11. Display device according to one of the preceding claims, which is semitransparent.