DE102008034524A1 - emergency pack - Google Patents

Abstract

The invention relates to an emergency lighting unit (3) which is to be connected to an operating device (2) powered by a supply source (1) and comprises at least one lighting LED (4). For this purpose, in addition a status LED (7) can be provided which signals a proper or faulty operation of the illumination LED (4). In order to be able to detect a reduction of the light intensity of the illumination LED (4) due to aging, for example, by conventional self-tests, the emergency light unit (3) should comprise at least a first photosensor (6) and a control circuit part (5). The photosensor (6) reports to the control circuit part (5) falls below a minimum illuminance of the illumination LED (4), with the result that the control circuit part (5) generates a detectable by a self-test program error condition.

Description

The The invention relates to an emergency light unit which is connected to one of a Supply source is fed to connect the operating device and at least one illumination LED.

at Emergency lighting in general and LED emergency lighting in particular is required, that self-tests at regular intervals carried out become. It is logged in particular whether during a Self tests a current, an interruption error or a short circuit fault occured. If a permissible current flows, is concluded with an LED emergency lighting on that the LED (hereinafter, for the sake of simplicity, only "LED" is used, even if the light source is formed by several LEDs is) works correctly. Meanwhile, this kind of self-test can be done do not detect when the luminosity of the LED decreases, for example due to aging.

Of the Invention is based on the object, the last described Disadvantage to avoid.

The The invention is characterized by an at least one lighting LED having emergency light unit solved, which is characterized by the features of claim 1.

After that the illumination LED is assigned a photosensor whose output signal is evaluated by a control circuit to determine if the light emitted by the illumination LED a certain minimum illuminance or a certain minimum luminous flux below. The result of this test can then be used to adjust the emergency lighting unit so that they pass through the self-test program recognizes a recognizable error state.

It is known, an emergency light unit of the type described above additionally with at least one status LED to provide the correct or faulty function of the lighting LED displays.

Of the Invention is still based on the object, malfunction determine the status LED and / or the brightness of the status LED to the brightness of the ambient light or the illumination LED adapt.

The Another object is an emergency light unit with the features of claim 2 solved. Also this solution provides for the use of a photosensor, in this case in cooperation with a control circuit for function control and / or brightness control of the status LED is used.

According to claim 3 it is also possible in addition to a first photosensor additionally a further photosensor provide, in which case the further photosensor for function control and / or Brightness control of the status LED is used.

claim 4 relates to a development of the case that the status LED and the illumination LED is monitored by a single photo sensor become. In this case, the light of each of the two LEDs can be time multiplexed be blasted on the photosensor, in which case the evaluation the output signal of the photosensor by the control circuit in same time division must be done.

As already mentioned, It is known in the art that the operating device is a self-test program contains which the supplied and controlled by him lighting LED in at regular intervals checks for a short circuit or open failure. In accordance with it will now according to claim 5 proposed for further development of the emergency lighting unit according to claim 1, that the control circuit part then artificially creates a short-circuit or interruption defect in the lighting LED containing Circuit generated when the first photosensor is below the minimum luminous flux or the minimum illuminance determines, so that the operating device and the latter Undershoot cases as error conditions recognizes.

One Disadvantage of the known emergency lighting systems can consist in that the human eye at a certain distance the less brightly lit status LED from the much brighter lighting LED no longer can differentiate. According to claim 6, it is therefore proposed that the lighting LED and the status LED be spatially such Separated from each other, that is a secure perception about one given distance still possible is. Alternative or additional can the illumination LED and the status LED according to claim 7 by a partition, preferably a reflector wall are separated from each other, so that the status LED is shadowed by the illumination LED.

A other measure to avoid the last-mentioned disadvantage can according to claim 8 insist that the brightness of the status LED to the brightness the lighting LED is adjusted. When the lighting LED with greater Brightness shines, so should the status LED with increased brightness Emit light.

Claim 9 relates to the possibility of monitoring the status of the status LED and suggests that a detected by the other photosensor Brightness defect of the status LED causes the control circuit part to control the illumination LED so that it emits an optical signal, for example in the form of flashing.

According to claim 10 may be a photosensor active photodiode or a passively working photoresistor are used, wherein as supply voltage for the passive photoresistor an external voltage, such as the supply voltage for the illumination LED or the supply voltage for the status LED offering.

A Another proposal for further development of the emergency light unit according to the invention exists according to claim 11 in that the first and / or the second photosensor in addition to Configuration, programming or addressing of the emergency lighting unit hernagezogen, which is done by a separate light source can, for example, by an infrared remote control.

A another possibility for the use of photosensors according to claim 12 is that the first and / or second photosensor is / are used as a smoke detector.

claim 13 concerns a practical embodiment of the fundamental Proposed solution Claim 1, which consists in that the control circuit part a with the lighting LED connected in series transistor, which - if the first Photosensor falls below the minimum luminous flux or the Minimum illuminance signals - from the control circuit is controlled in the spear state, whereby the self-test program detects an interruption failure.

claim 14 concerns a practical realization of the fundamental proposed solution according to claim 2 or 3 and is that the control circuit part includes a transistor connected in series with the status LED whose Pass-through resistance through the variable parameter (photosensor current) the first or further photosensor is determined such that the on-resistance the lower and the brightness of the status LED increases, the greater the illuminance or the luminous flux of the incident on the first and second light sensor Ambient light is.

embodiments The invention will be described below with reference to the drawings.

It demonstrate:

1 a schematic diagram of an operating unit connected emergency light unit according to the prior art;

2 a first embodiment of the emergency light unit according to the invention with a lighting LED, a first photosensor and a control circuit;

3 a second embodiment of the invention, which is opposite to in 2 shown embodiment differs in that here also a status LED is provided;

4 a third embodiment of the invention, which differs from the in 3 shown embodiment differs in that a further photosensor is provided;

5 a fourth embodiment of the invention, in which the illumination LED and the status LED cooperate with only one photosensor;

6 the embodiment according to 2 in a more concrete embodiment;

7 a somewhat more concrete design of the control circuit part for an emergency light unit, in which the status LED is adjusted in its brightness to the ambient light.

1 shows an emergency light unit 3 according to the prior art, which is a lighting LED 4 and a status LED 7 includes. The lighting LED 4 serves for emergency lighting. The status LED 7 To indicate whether the illumination LED is working properly or is defective. The two LEDs 4 and 7 be separate from a control gear 2 supplied with operating voltages that the operating device 2 from the voltage of a voltage source 1 generated. In the present case, the voltage source 1 drawn as a battery. In 1 and in the following 2 to 5 only one illumination LED or one status LED is shown in each case. In fact, however, in practice usually several LEDs are switched together.

By As the illumination LED ages, the luminous flux can become lower and fall below a required minimum value. When falling below the Required minimum illuminance is not the emergency light functionality given.

How this problem can be remedied shows 2 , Here the emergency light unit points 3 next to a lighting LED 4 a first photosensor 6 on. The lighting LED 4 and the photosensor 6 become one of the emergency light unit 3 belonging control circuit part 5 controlled. The control circuit part 5 in turn is from the operating device 2 energized and controlled.

The first photosensor 6 captures the brightness (direct or indirect) of the illumination LED 4 , The first photosensor 6 can be designed as an active component (photodiode) or as a passive component (photoresistor). In the case of training as a photodiode this generates under illumination dependent on the illuminance or the luminous flux photocurrent, the control circuit part 5 is supplied. In the case of training as a photoresistor, the resistance is varied by the striking luminous flux or the illuminance. In one case, therefore, the photocurrent and in another case, the photoresistor forms one of the luminous flux or the illuminance of the illumination LED 4 dependent parameter to the control circuit part 5 is passed on. The control circuit part 5 now reproduces one of those errors that can be detected by the previously mentioned self-test program of the operating device. This is an interruption failure (no current) or a short circuit (no voltage) at the output of the illumination LED 4 ,

6 shows, as below a minimum luminous flux or a minimum illuminance of the illumination LED 4 an interrupt error is simulated. The first photosensor 6 is here designed as a photoresistor, with another resistance 9 forms a voltage divider. Deviating from 2 are in 6 two series-connected illumination LEDs 4 provided with a transistor 10 are connected in series. The base of the transistor 10 lies at the point of the voltage divider. If that of the two illumination LEDs 4 on the first photosensor 6 falling light falls below a minimum illuminance or a minimum luminous flux, the resistance of the photosensor increases 6 with the result that the base voltage of the transistor 10 is reduced, to the extent that the transistor 10 becomes practically non-conductive. The self-test program of the operating device evaluates this as an interruption defect. In this way, therefore, a brightness error of the two illumination LEDs 4 detected.

The embodiment according to 3 serves the solution of the following problem. The status LED must have a minimum light level to be able to be seen during daytime and at high altitudes. Also, a sufficient light intensity is necessary to recognize it in addition to a point light source, which is the case with an LED and a compact lighting design. On the other hand, the status LED should not be too bright because it may be too light. B. at night could cause an undesirable lighting effect.

In 3 becomes the light of the status LED 7 from the first light sensor 6 detected. Alternatively, it is according to 4 possible, another light sensor 8th to be provided for detecting the light of the status LED 7 serves while the first light sensor 6 for detecting the light of the illumination LED 4 serves. According to 5 It is also possible, the light of both the illumination LED 4 as well as the light of the status LED 7 only by a light sensor 6 capture. In this case, the transmission of light to the light sensor 6 done in time multiplex. The evaluation by the control circuit part 5 then also takes place in the time multiplex.

7 now shows a practical embodiment that allows light from two status LEDs 7a and 7b ( 7a is red and 7b is green) to match the ambient light. The ambient light will be as well as the light of the two status LEDs 7a and 7b on the other photosensor 8th directed, which in turn is designed as a photoresistor. Again, the photosensor forms 8th with a resistance 11 a voltage divider. Each of the two status LEDs 7a and 7b is with a transistor 12 respectively. 13 connected in series. The base connections of the two transistors 12 . 13 lie at the point of the voltage divider. As the ambient light brightens, the resistance of the photosensor decreases 8th with the result that the base voltage of the two transistors 12 . 13 elevated. The flow resistance of the two transistors 12 . 13 diminishes as a result, with the result that the two status LEDs 7a and 7b give off more light. The result is that the light intensity of the two status LEDs 7a . 7b adapted to the light intensity of the ambient light.

If above from "emergency unit" the speech this is also to be understood as meaning that the control circuit part, the LEDs and the photosensors are designed as an integrated circuit can and thus form a unity.

Claims (15)

Emergency light unit ( 3 ) connected to one of a supply source ( 1 ) powered operating device ( 2 ) and at least one illumination LED ( 4 ), characterized by, one directly or indirectly from the illumination LED ( 4 ) illuminated first photosensor ( 6 ), wherein at least one operating parameter (current, voltage or resistance) of the photosensor ( 6 ) through the on the photosensor ( 6 ) falling light, and one with the first photosensor ( 6 ) connected control circuit part ( 5 ), which evaluates the variable parameter to determine if that of the illumination LED ( 4 ) light - under direct lighting - a certain minimum luminous flux or - in indirect lighting - falls below a certain minimum illuminance. ( 2 . 4 . 5 u. 6 ) Emergency light unit ( 3 ) connected to one of a supply source ( 1 ) powered operating device ( 2 ) and at least one illumination LED ( 4 ) and at least one status LED ( 7 ) indicating the correct or faulty operation of the illumination LED ( 4 ), indicated by a directly or indirectly from the status LED ( 7 ) and / or the first light sensor ( 6 ), wherein at least one operating parameter (current, voltage or resistance) of the photosensor ( 6 ) through the on the photosensor ( 6 ) falling light, and one with the first photosensor ( 6 ) connected control circuit part ( 5 ), which evaluates the variable parameter, wherein the control circuit part ( 5 ) evaluates the variable parameter of the first photosensor for purposes of function control and / or brightness control of the status LED. ( 3 ) Emergency light unit ( 3 ) according to claim 1, with at least one status LED ( 7 ) indicating the correct or faulty operation of the illumination LED ( 4 ), indicated by a directly or indirectly from the status LED ( 7 ) and / or the ambient light illuminated further photosensor ( 8th ) connected to the control circuit part ( 5 ), wherein at least one operating parameter (current, voltage or resistance) of the further photosensor is applied by the sensor to the other photosensor ( 8th ) falling light is variable, and wherein the control circuit part ( 5 ) the variable parameter of the further photosensor ( 8th ) for the purpose of function control and / or brightness control of the status LED. ( 4 ) Emergency light unit ( 3 ) according to claim 1, with at least one status LED ( 7 ) indicating the correct or faulty operation of the illumination LED ( 4 ), characterized in that the first photosensor ( 6 ) also from the status LED ( 7 ) is illuminated directly or indirectly in order, via the variable operating parameter, also the operating state of the status LED ( 7 ), whereby the illumination of the first photosensor ( 6 ) through the illumination LED ( 4 ) on the one hand and the status LED ( 7 ) on the other hand by the control circuit part ( 5 ) takes place in the time division multiplex, and wherein the evaluation of the variable operating parameter by the control circuit part ( 5 ) also takes place in this time multiplex. ( 5 ) Emergency light unit ( 3 ) according to claim 1, wherein the operating device ( 2 ) is equipped with a self-test program, which controls the supplied and controlled illumination LED ( 4 ) is periodically checked for a short-circuit or open-circuit defect, characterized in that the control circuit part ( 5 ) artificially a short circuit or interruption defect on the illumination LED ( 4 ) when the first photosensor ( 6 ) detects a drop below the minimum luminous flux or the minimum illuminance, so that the operating device ( 2 ) can also detect the last-mentioned error conditions. ( 5 ) Emergency light unit ( 3 ) one of claims 2 to 5, characterized in that the illumination LED ( 4 ) and the status LED ( 7 ) are spatially separated from each other so as to be perceived separately from the human eye over a predetermined distance. Emergency light unit ( 3 ) according to one of claims 2 to 6, characterized in that the illumination LED ( 4 ) and the status LED ( 7 ) are separated from each other by a partition, preferably a reflector wall, such that the status LED ( 7 ) from the illumination LED ( 4 ) is shadowed. Emergency light unit ( 3 ) according to claim 1, characterized in that the control circuit part ( 5 ) the variable parameter of the first photosensor ( 6 ) evaluates the brightness of the status LED ( 7 ) depending on the brightness of the illumination LED ( 4 ) controls. ( 3 . 4 u. 5 ) Emergency light unit ( 3 ) according to claim 3, characterized in that a through the further photosensor ( 8th ) detected brightness defect of the status LED ( 7 ) the control circuit part ( 5 ), the illumination LED ( 4 ) so that it emits an optical signal, for example in the form of flashing. Emergency light unit ( 3 ) according to one of the preceding claims, characterized in that as photosensor ( 4 . 7 ) an actively operating photodiode or a passive photoresistor is used, wherein as the supply voltage for the passive photoresistor, an external voltage, such as the supply voltage for the illumination LED ( 4 ) or the supply voltage for the status LED ( 8th ) is used. Emergency light unit ( 3 ) according to one of the preceding claims, characterized in that the first ( 4 ) and / or the second ( 7 ) Photosensor in addition to the configuration, programming or addressing of the emergency light unit ( 3 ) is used by a separate light source, for example by means of an infrared light remote control. Emergency light unit ( 3 ) after one of the previously ste existing claims, characterized in that the first ( 4 ) and / or second ( 7 ) Photosensor is additionally used as a smoke detector. Emergency light unit ( 3 ) according to claim 1, characterized in that the control circuit part ( 5 ) one with the illumination LED ( 4 ) in series transistor ( 10 ), which - if the first photosensor ( 6 ) below the minimum luminous flux or the minimum illuminance signaled by the control circuit ( 5 ) is controlled to the lock state, whereby the self-test program detects a breakage failure. ( 6 ) Emergency light unit ( 3 ) according to claim 2 or 3, characterized in that the control circuit part ( 5 ) one with the status LED ( 7a . 7b ) in series transistor ( 12 . 13 ), whose forward resistance through the variable parameter of the first or further photosensor ( 6 . 8th ), such that the forward resistance is lower and the brightness of the status LED ( 7a . 7b ) so that the greater the illuminance or the luminous flux of the first or second light sensor ( 4 . 8th ) incident ambient light. ( 7 ) Emergency light unit ( 3 ) according to one of the preceding claims, characterized in that the control circuit part ( 5 ) and the LED / LEDs ( 4 . 7 ) and the photosensor (s) ( 6 . 8th ) are implemented in integrated circuit.