EP1291828A2 - Electroluminescent semiconductor for testing luminescent security features mounted in a housing - Google Patents

Abstract

Checking device for luminescent security markings placed in or on valuable objects, whereby a UV electro-luminescent semiconductor solid state body (2) and or a infrared electro- luminescent semiconductor solid state body (3) are arranged in a housing so that the emitted radiation excites a security marking. A key (9) is provided for switching the device on an off that has a clearly audible and traceable click when switched on.

Description

The present invention relates to a device for the verification of luminescent security features based on in one housing built-in UV and infrared light-emitting luminescent diodes (LEDs).

Luminescent security features for the value and security area have been used for a long time. To the security features on the affected security and valuables are attached with Reliable efforts to make acceptable efforts visible have already been varied Efforts have been made to implement appropriate procedures and devices to develop.

In most cases, the objective was to check banknotes, Credit or check cards at sales outlets for the development of corresponding ones Methods and devices specified. As salesrooms or Points of sale are viewed in all conceivable places where Wertoder Security documents, such as Banknotes, credit and bank cards as well as identity papers and the like sold, traded, changed and to be controlled. To provide reliable evidence of the authenticity of the affected value and security documents to the relevant group of people Efforts have been made to provide Methods and devices for making these luminescent visible To achieve security elements.

The prior art shows DE 94 03 794 U with the title "Security - Test device ". A test device for securities in a correspondingly large housing that is suitable for the Discharge lamp, a UV light source, and a white light source. The UV light source therefore requires a large dimension for the housing, whereby this loses handiness. Although using a specially for this developed discharge lamp with dimensions 60mm length and 9mm Diameter already created an easy-to-use testing device to it However, it is still easy to have at hand at all times somewhat bulky. The operation of the discharge lamp also requires one Minimum operating time, which requires preheating the tube.

WO 93/07590 A describes a banknote checking device that is U-shaped is trained, and is quite complex. For example, it points out Running rollers for pulling a bill through the banknote validator while checking the bill. This results in a lot of effort both in terms of development as well as production and use of the banknote validator. Furthermore, this test procedure requires a high level time expenditure that is no longer adequate these days.

US 4,567,370 A shows an authentication device for patterns. For this will use a mercury vapor UV lamp for checking the samples used. The disadvantage here too is the unsatisfactorily long operating time when using the device in addition to its large dimensions.

EP 537 513 A1 shows a device for checking banknotes. This is an excitation for security elements by means of LEDs or IR LEDs caused. A UV test area is not mentioned in this document, so that this spectral range of the security elements seems to be left out. A The answers to the banknotes are recorded by a CCD camera, which forwards the detected signals for evaluation. Here too apply di Disadvantages of high development and manufacturing costs, relative large dimensions and a lot of time when checking the Paper money.

The state of the art also shows DE 296 07 075 U1, and DE 197 01 513 A1. DE 296 07 075 U1 shows a luminescence sensor disclosed. The luminescence switch is intended for this purpose, in the UV range To emit light signals and in a surveillance area Reflected object, reflected in the visible wavelength range Detect signals and with a dedicated evaluation unit evaluate. To do this, the luminescence switch is semi-transparent Mirror equipped by which the reflected signals for detection and Go through the evaluation unit. The ray path from the semi-transparent mirror to the object to be tested and the beam path of the reflections are in an axis. There is a lens unit for focusing in this beam path arranged.

Between the semi-transparent mirror and the receiving unit are to Processing the reflected signals is another series of lenses and Filters arranged to enable spectrum limitation.

The device is thus very complex and the method for Detection and evaluation of the reflections from the object to be tested as such is very complex. So you have the disadvantage that in addition to Transmitting unit a radiation deflecting unit in the form of a semi-transparent Mirror and a receiving and evaluation unit are required. This means an enormous effort, both technical and financial Respect. Due to the high level of technology, there is also a appropriate sensitivity of the device, which must be observed.

DE 197 01 513 A1 describes a test method and a test device for the Authenticity control of authenticity marks. The process uses two Sending sources for the emission of radiation to a specific target. The the two radiation sources are arranged side by side and are thus in a certain angle of incidence to the object, from which reflections be delivered. These reflections are detected by a detector and evaluated. The two radiation sources are time-division multiplexed by operated a control unit. So the method and the device also depend on the detection of the reflections, and are therefore very natural in nature consuming. Here too the argumentation applies that both technically and Financially great efforts must be made to achieve this to realize technical teaching.

The previously known and available methods and devices for However, luminescent security features are not yet visible so mature that they are easy and uncomplicated to use enable reliable detection of the security features.

The present invention is therefore based on the object of a device for the verification of luminescent security features put which in and / or on value and security documents and Objects are arranged, the verification without health Damage to the user and those in the immediate vicinity located people should be feasible.

The characteristic features of the independent claim 1.

It is important for the present invention that for the verification of the concerned Security features which are in and / or on value and security documents and objects are arranged to ensure their authenticity when checked by means of a suitable test procedure with a corresponding test device to demonstrate that the process is easy to use, with the aim of making it visible the security features both radiation in the ultraviolet wavelength range as well as in the infrared wavelength range using the down-conversion effect is used. Down conversion is the following Effect understood that specially doped, luminescent material Radiation, which occurs in the non-visible area, is excited, and a jump according to the doping of the luminescent material experiences the energy band, and in the visible spectral range after the Convergence of the energy state emits radiation. This radiation can can be detected by the human eye, whereby the detection of the Presence of security features on security and to be checked Provides valuable documents and objects.

There are two different ways to create a luminescent effect Materials application. On the one hand, it is luminescent material with imperceptible afterglow, which is called fluorescent and the second type of luminescent material, which has the effect of a Afterglow is called phosphorizing.

For the use of security features in security and However, value documents and objects do not matter which of the two luminescent materials is used. Only that is decisive Evidence of the presence of security features.

To stimulate the luminescent security features, it is necessary to use UV light to focus on the luminescent security features, what so far bulky fluorescent tubes were used. These fluorescent tubes were wired due to the high performance and also showed unwieldy dimensions, which are not easy and handy to use permitted. It is important in the present invention that through the use Luminescent diodes working in the UV range have the possibility of a To build test facility, which is in a very handy version with small Dimensions, e.g. in the form of a keychain. This gives the first time the possibility of a test facility cable-free and easy to transport and use.

The energy supply for the operation of the LEDs used can due to the low power consumption compared to the tubes, definitely via batteries, so-called button cells. Through this Power supply, it is guaranteed that the test equipment for Verification of luminescent security elements regardless of location can be done. Another advantage is that the test facility can be transported easily and based on the small dimensions and associated light weight available to everyone at all times can stand by this testing facility, like other everyday utensils Is always at hand.

It is important in the present invention that several diodes are combined are arranged so that they form a bundle which approximately in a same beam direction its at least partially outside the visible Radiate radiation in the wavelength range. The use of several LEDs for the purpose of emitting radiation, which at least partly, outside the visible spectral range, lies in the fact that by bundling the emission of rays achieves a higher luminance which is a more intense visualization of the luminescent Security features enabled.

As another essential safety feature of the present Under this bundle of light-emitting diodes, the invention is at least one light-emitting diode arranged, which emits light in the visible range, creating a first Security feature, namely an optical operating display, is used. Another additional security device of the present invention is that optionally also an acoustic operating display which shows LEDs working in the invisible spectral range. By the introduction of these safety features is avoided that intentional or unintentional, eye injuries from burning the Optic nerves on the retina caused by imperceptible ones Radiation and thereby not triggering the fluid reflex of the eye, is avoided.

Another advantage of the present invention over those previously Fluorescent lamps used is that the life of the LEDs are a multiple of the life of fluorescent lamps. Especially when the fluorescent lamps are switched on and off frequently Lifespan of this is significantly reduced, creating an average Lifespan of approximately 1000 operating hours for the fluorescent lamps is far below. The lifespan of the LEDs, however, is one Multiples of 1000 operating hours.

This results in the advantages that in the present invention Cable-independent, can be used anytime and anywhere, with a long service life equipped, test facility can be manufactured.

The realization of this completely new concept, which Use of UV light-emitting diodes (UV-LED's) provides this high flexibility for the Use case reached. The UV LEDs are in their design and in their electrical characteristics comparable to conventional light emitting diodes. LEDs for the visible wave range (wavelength 400 nanometers to 700 nanometers) and for the near infrared range (IR; wavelength 700 Nanometers to 1000 nanometers) have been in use for a long time. You will be in the technology above all as display elements (blue, green, yellow and red LEDs) or used in remote controls, light barriers (IR LEDs). The Desire for ever shorter wavy LEDs is justified by the fact that the optical storage density of data, for example on CD or DVD decreasing wavelength is getting bigger.

For a long time, it was not possible to produce short-wave, blue LEDs, because no suitable technology was available for series production. First The Nichia company has been providing corresponding light-emitting diodes for about 5 years that this technological gap with the production of series products Generation of blue light emitting or laser diodes closes. By a Further development of this technology has now succeeded in first samples of To produce LEDs of even shorter wavelengths.

These LEDs work in a wavelength range of 370 nanometers and thus have a wavelength similar to that of commercially available UV lamps (Wavelength 375 nanometers).

geringe Abmessungen (Standard-LED-Gehäuse ca. Höhe: 6,2 mm, Durchmesser 5 mm), geringe Leistungeaufnahme von ungefähr 60 Milliwatt, hohe optische Leistung von ungefähr 750 Milliwatt und eine lange Lebensdauer von ungefähr 2000 Betriebsstunden. Daraus ergibt sich, daß die Leuchtdiode ungefähr eine doppelt so lange Lebensdauer aufweist, wie eine Leuchtstoffröhre, deren Lebensdauer aufgrund hoher Ein- und Ausschalthäufigkeit noch zusätzlich deutlich reduziert wird.

The advantages of such UV LEDs compared to a UV fluorescent lamp are:

small dimensions (standard LED housing approx. height: 6.2 mm, diameter 5 mm), low power consumption of approximately 60 milliwatts, high optical power of approximately 750 milliwatts and a long service life of approximately 2000 operating hours. The result of this is that the light-emitting diode has a service life that is approximately twice as long as that of a fluorescent tube, the service life of which is additionally significantly reduced due to the high frequency of switching on and off.

Another advantage of the light-emitting diodes over the fluorescent tubes is in that the light emitting diodes immediately provide their full optical power as soon as they are energized. The fluorescent tube however, it takes a certain amount of time to ignite the gas and thus to achieve their luminosity and operational readiness. In order to the disadvantage of the waiting time between are automatically connected Switch-on time and the first operational state of the fluorescent tube as well as the disadvantage of the significantly higher power consumption.

A power supply is required for the correct operation of these LEDs between 3.5 volts and 4.5 volts necessary. This power supply can using appropriately sized batteries for a satisfactorily long time Service life can be achieved.

A consistently intense luminosity can be achieved by using a Constant current source for the supply of the UV LEDs can be achieved. Care the transistors used to ensure that the UV LEDs are always the same Voltage drops, which results in constant luminosity when used. By using such a constant current source, it is also possible Use battery voltages above 4.5 volts, which are caused by the electronics the correspondingly required values are limited. With the previously specified Data thus generates a power consumption of approximately 10 milliamperes. Under These operating conditions have a lifespan of approximately 2000 Operating hours according to the manufacturer's specification. When using conventional alkaline batteries of the type LR44 (1.5 volts) result in a Operating time of approximately 12 hours. One sets for checking one Security and value document for a period of 10 seconds a number of test operations, which is 4320 operations.

The different rapid decay behavior of the individual luminescent Use colors that are used as security features to advantage can, the present invention provides that the suggestion for delivery luminescent radiation caused by the infrared or ultraviolet Radiation, by pulse method for the supplied operating voltage used LED's is influenced so that different colors the correspondingly excited luminescence security features on the value and Sign off security documents and objects. Background this changing color spectrum of the luminescent features emitted radiation is the superposition of emitted luminescent Radiation from different frequency ranges due to use of different colors, the individual decay constants of different Order of magnitude. It is advantageous to use luminescent colors which have significantly different decay constants. This results in the advantage is that with pulsed or intermittent and / or modulated Form of power supply for the relevant LED's different Emission characteristics of the security features are generated. This Characteristics are expressed in the fact that, for example, in the case of unpulsed or unmodulated form of voltage supply both of the at least two different luminescent colors used their maximum Have reflection. This results in a mixture of colors, which in Ratio of the amount of security features applied and their Retroreflective intensity depending on its retroreflective power and its Decay constant occurs. With the pulse method now starting or intermittent and / or modulating change in the voltage supply the LEDs are also directly dependent on this type of voltage Supply voltage the radiation of infrared and ultraviolet radiation on the security features. The ultraviolet or infrared radiation, which from the semiconductor solid-state elements is therefore directly from the Voltage dependent, since this immediately reaches its full radiant power when applied of a corresponding voltage and this until the switch-off time maintained. Thus, the luminescent security features in the Form of the supplied operating voltage from the infrared and ultraviolet Radiation irradiated. Due to the intermittent and / or modulated form of this Power supply are now the retroreflective characteristics of the for Security features used luminescent colors depending on their Decay constants recorded by the eye. For example, if the color A only Has 1/10 of the decay constant of color B, so is corresponding intermittent and / or modulated form of the supply voltage for the LEDs it is possible to influence the radiation characteristics of color A that - compared to the radiation intensity of color B - it goes to zero. Thereby there is a retroreflective effect which only reveals the color B. Now the pulse ratio of the operating voltage changes so that the Pulse ratio has significantly longer switch-on than switch-off periods, so again sends the color A, which is just a much smaller one Radiation constant shows as the color B, again perceptible to the eye Radiation. This results in a frequency mix of the retroreflection according to the relationship between the colors A and B, which results in a Perceive color change of the emitted luminescent colors for the eye leaves.

As an example, the color A is green and the color B is blue pulsed power supply the reflection of the security elements Color blue / green. With a pulsating and / or modulating form The voltage supply will change over time the color A - i.e. green - always between the voltage switched on and off weaker and the color blue would remain constant. This modulation can go so far be driven until the reflection of the color green has completely subsided is. In this case, the color would now be blue, based on its large size Decay constant, still emit visible radiation.

The present invention now provides that the modulation method for Operating voltage of the LED's are optional when checking the value and Security documents and objects vary. This allows the whole Frequency spectrum of the applied security features can be checked. This is shown by a change in the retroreflective colors, which change results from the sum of the retroreflective frequencies.

Another alternative power supply results from the use of a DC / DC inverter. This IC is able to multiply the voltage of a battery. In this way it is possible to develop electronics for the UV LEDs that only need one or two LR44 batteries.
This embodiment is an alternative to the embodiment with the constant current source.

Regarding the housing design for the installation of the UV LEDs and the Corresponding energy supply, several embodiments were developed developed. An embodiment of this housing is designed so that it due to its small dimensions on the keychain in your pocket can be worn without hindering the owner. The ergonomics of the UV LEDs prevent accidental operation when carried in bags is prevented. Care was also taken to ensure that the button for the Operation of the control device for both right and left-handers is equally convenient to use. A clear audible and noticeable switching click also ensures that the user has no unintended Commissioning of the control device completed.

The core housing is made of acrylonitrile butodiene styrene copylymere (ABS) thermoplastic injection molding process. Are preferred elastomeric elements are used so that the function of the test facility Floor traps from hip or shoulder height, even on hard floors, such as Stone floors or the like, is not affected.

The high breaking strength of the test facility achieved in this way is another Security feature of the present invention. Another feature of Safe operation of the test device lies in the fact that the housing design is carried out that it is sealed splash-proof. In the further are the UV LEDs arranged in the housing so that scratching by protruding elements is avoided and so the opening angle of approximately 10 ° of the emitting UV and / or IR light is retained at all times.

Another embodiment of the present invention provides that this as stationary device is built. This stationary UV LED lamp comes with several LEDs are equipped to provide a uniform, intensive illumination guarantee. This verifier can optionally be equipped with a UV filter his. This filter can remove the annoying, visible, blue light components of the UV LEDs reduce and thus an improved visibility of the luminescence enable. In addition, the color fastness of the luminescence restored compared to that with UV lamp.

In order to enable a corresponding value and security product or object to be recognized when it is introduced into the control position, it is provided to install a proximity sensor. This proximity sensor switches on the power supply for the LEDs when a value and security product or object is detected. This enables the control process described above to be triggered.
The UV-LED verifier is therefore equipped with a sensor that detects whether a security document to be checked is under the device. The UV LEDs are only switched on in this case. Such a sensor could be implemented using a simple light barrier. The advantage of this solution is that the UV LEDs are only switched on when they are needed. The service life in this operation is significantly increased and exceeds that of a stationary UV lamp, with which such operation is not possible, many times over. In addition, you get a reduced energy consumption and less UV rays than with continuous operation, as is usual for the UV lamps.

Another interesting possibility arises from the combination of UV LEDs and infrared LEDs. In addition to those under UV light luminescent Security features are also increasingly used feature materials that under irradiation with infrared light in the visible lighting area (down-conversion or anti-stocks) converge. A combination of UV and IR LEDs is therefore sensible, since it checks both security features in this way can be.

Through the development of this stationary device, both stationary and portable test equipment possible.

Are UV and IR luminescent security features in one graphic Element integrated, so are both by using both wavelength ranges Security features verifiable. The two differ different security features through different colors. Thus it results a simple and eye-catching verification of the existing Security features.

Based on the following description of the figures, the present invention, based on several embodiments of the present invention, described.

Figur 1:

eine Schnittdarstellung einer Ausführungsform der IR- und UV-LED-Prüfeinrichtung,

Figur 2:

eine Draufsicht nach Figur 1,

Figur 3:

eine Schnittdarstellung einer weiteren Ausführungsform nach Figur 1,

Figur 4:

eine senkrechte Schnittdarstellung nach Figur 4,

Figur 5:

eine Schnittdarstellung im Schnitt A-A nach Figur 3,

Figur 6:

eine Schnittdarstellung im Schnitt B-B nach Figur 3,

Figur 7:

den inneren Aufbau der Prüfeinrichtung nach Figur 3,

Figur 8:

den inneren Aufbau der Prüfeinrichtung nach Figur 4, und

Figur 9:

den inneren Aufbau der Prüfeinrichtung nach Figur 6.

Show it:

Figure 1:

1 shows a sectional illustration of an embodiment of the IR and UV LED test device,

Figure 2:

2 shows a top view according to FIG. 1,

Figure 3:

2 shows a sectional illustration of a further embodiment according to FIG. 1,

Figure 4:

3 shows a vertical sectional view according to FIG. 4,

Figure 5:

3 shows a sectional illustration in section AA according to FIG. 3,

Figure 6:

3 shows a sectional illustration in section BB according to FIG. 3,

Figure 7:

the internal structure of the test device according to Figure 3,

Figure 8:

the internal structure of the test device according to Figure 4, and

Figure 9:

the internal structure of the test device according to Figure 6.

FIG. 1 shows a UV-IR-LED pointer, which has 5 UV-LEDs in a housing 2, IR-LEDs 3, LEDs in the visible wave range 4, and batteries 6 includes. There is also an acoustic display 12 and a button 9 in it Representation of this embodiment of the present invention recognizable. at Pressing the button 9 on the electronics energy on the batteries 6 on the LEDs 2,3,4 voltage in the intended operating voltage level delivered and this stimulated to glow. Furthermore, the acoustic display 12 for emitting a signal by actuating with the appropriate spring force provided button 9 causes. Through this acoustic signal, as well the LED in the visible wave range ensures that none invisible radiation can escape from the LED's without warning signals be delivered in both optical and acoustic form. The levy The optical signal is used to trigger the closing reflex of the eye muscles. The emission of the ultraviolet or infrared radiation from the UV / IR LEDs is used to stimulate the luminescent security features of the items to be checked Valuable and security documents and objects. Because of the suggestion by ultraviolet or infrared light is found on the security features a down-conversion energy transfer takes place which the Security features for radiation in the visible wavelength range.

Figure 2 shows a plan view of the embodiment of Figure 1, the Top view is from the direction in which the emitted radiation from the LED's is directed. With this arrangement, several LEDs can be seen, which in one bundled state on the front side of the housing 5 of the UV-IR LED pointer are arranged.

Figure 3 shows a sectional view of a further embodiment of the Present invention, the LED combination UV-LED 2, IR-LED 3 and LEDs in the visible wave range 4 are shown as a single unit. Furthermore, the electronics 8 are the buttons 9 and the batteries 6 with the contacts 7 recognizable in the housing 5. The mode of operation of this embodiment corresponds in principle the mode of operation of the previously described embodiment.

FIG. 4 shows a vertical sectional illustration according to FIG. 3. In this The ergonomic design of the handy UV / IR LED pointer is clear in form recognizable. The arrangement of the components housing 5, battery 6 with contact 7 and button 9 with cover 11 and the heart, the LEDs 2,3,4, clearly presented. At the bottom of the case is an ergonomic one Grip recess 10 recognizable. There is also an opening 13 for receiving one Ring or a similar attachment in the housing 5 can be seen. The button 9, which is arranged within the housing, with the cover 11, the is splash-proof, actuated. This illustration is good too recognizable that an actuation of the button can only take place if deliberately on the cover 11 lying lower than the rest of the housing the button 9 pressure is exerted. This pressure needs a certain one Exertion of force, which ensures that an unintentional actuation of the UV / IR LED pointers is avoided.

FIG. 5 shows a sectional view through section A-A of FIG. 3. In this illustration, the arrangement of four batteries 6 in the housing 5 shown. These batteries are used to supply power to the UV LEDs IR-LED's, as well as the LED in the visible wave range and the acoustic Operating display 12.

Figure 6 shows a sectional view according to section B-B of Figure 3. Here is in Housing 5 on the left side of the recessed grip 10 can be seen, which also in the Figure 4 is shown in the lower left area. Furthermore, the button is in the middle 9 and the LED unit 2, 3, 4 for the LEDs. There are also parts the electronics 8 recognizable.

In Figure 7, the internal structure of this embodiment is the present Invention recognizable. Similar to Figure 3 is on the left side Group representation for the LEDs 2,3,4 with their connections shown. Furthermore is centrally in the middle of the button 9 with the electronic surrounding all around Components 8 recognizable. In the right part of this illustration are four batteries 6 shown in the form of button cells, which by contacts 7 with the Electronics 8 are connected.

In Figure 8, this representation is rotated by 90 °, which on the left side Commonly shown unit for the LEDs 2,3,4 with their connections Connection with the necessary electronics is shown. In the middle is a electronic component 8 recognizable, behind which by a higher Structure recognizable button 9 is positioned. To the right of this are contacts 7 and the batteries 6 shown.

FIG. 9 shows a front view of this inner part of this embodiment of the present invention. In the middle in the middle is the single unit shown combination of LEDs 2,3,4 recognizable. The button 9 is located behind it and an electronic component 8. In the upper and lower area, the contacts 7 recognizable with their connections to the board.

The embodiments of the present invention thus described are not to be understood as restrictive, on the contrary, they are only a part the various possible embodiments of the present invention.

Drawing Legend

1

UV / IR LED pointer

2

UV LED

3

IR LED

4

LED visible wave range

5

casing

6

battery

7

contacts

8th

electronics

9

button

10

grip

11

cover

12

acoustic display

Claims (11)

Device for controlling luminescent security features, which are arranged in and / or on valuable and security products and objects, at least one UV-electroluminescent semiconductor solid element (2) and / or at least one IR-electroluminescent semiconductor solid element (3) being arranged in a housing, wherein the radiation thus generated stimulates the luminescent safety features to light up, characterized in that a button (9) is provided for starting up the device, which emits a clearly audible and perceptible switching click. Apparatus according to claim 1, characterized in that the button (9) by means of a cover (11), which is arranged recessed relative to the rest of the housing (5), through the electrical contact for the operation of the electroluminescent semiconductor composite combination (2, 3) Overcomes the spring force of the button. Device according to one of claims 1 or 2, characterized in that the energy supply for the electroluminescent semiconductor solid-state elements (2, 3) is based on batteries or rechargeable batteries and a constant current source which ensures a constant current supply to the fluorescent semiconductor solid-state elements and / or alternatives Energy source, such as a solar module, a piezo transducer and the like, takes place. Device according to one of claims 1 or 2, characterized in that the energy supply for the electroluminescent semiconductor solid elements (2, 3) takes place on the basis of energy sources and a DC / DC converter which converts the voltage from the energy source used to the required operating voltage for the electroluminescent elements Solid state semiconductor elements converts. Device according to one of claims 1 to 4, characterized in that the device is arranged in an easily manageable, approximately matchbox-sized housing (5). Device according to one of claims 1 to 5, characterized in that the housing (5) of the device is made of unbreakable, elastomeric materials. Device according to claim 6, characterized in that the housing (5) of the device is made of acrylonitrylbutodiene-styrene copolymers (ABS) materials. Device according to one of claims 1 to 7, characterized in that the housing (5) of the device is splash-proof. Device according to one of claims 1 to 8, characterized in that the LEDs (2-4) are arranged in the housing (5) in such a way that scratching by protruding elements is avoided. Device according to one of claims 1 to 10, characterized in that the electroluminescent solid semiconductor elements (2, 3) are designed in such a way that they emit bundled radiation. Device according to one of claims 1 to 9, characterized in that in addition to the electroluminescent semiconductor solid-state elements (2, 3), a light-emitting element (4) is arranged in the housing (5), the emission of which lies in the visible wavelength range, and at the same time as that with the invisible radiation is activated.

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