DE102018115584A1 - light monitoring - Google Patents

Abstract

The invention relates to a control unit for a luminaire unit of a lighting system, the control unit comprising a data processing unit, in particular a non-volatile memory for storing a luminaire identifier and at least one output for at least one illuminant or at least one illuminant source and at least one input for receiving control codes, the After receiving control codes, the control unit controls the at least one lamp and / or the at least one lamp source, in particular switches it on and off, the lamp unit having continuous operating power consumption with the at least one lamp switched on in continuous operation, with the control unit being the actual power consumption of the lamp unit after receiving at least one predetermined control code can be raised via the continuous operating power consumption.

Description

The present invention relates to a control unit for a luminaire unit of a lighting system, the control unit comprising a data processing unit, in particular a non-volatile memory for storing a luminaire identifier and at least one output for at least one illuminant or at least one illuminant source and at least one input for receiving control codes, wherein the control unit, after receiving control codes, controls the at least one lamp and / or the at least one lamp source, in particular switches it on and off, the lamp unit having continuous operating power consumption with the at least one switched-on lamp in continuous operation.

Lighting systems such as emergency power lighting systems are used, among other things, in large construction projects. There is a need to be able to monitor and control such a system as simply and centrally as possible and, if necessary, to recognize and locate faulty lights or other components or to influence system settings. Thanks to the central control and monitoring, the maintenance effort can be kept low and the lighting system can thus be operated at low cost.

In the case of emergency power lighting systems in particular, there is a need for central monitoring to ensure that the lamps are functional at all times. Due to the fact that the illuminants are normally switched off, the inoperability cannot be noticed by a person deliberately noticing a defective illuminant. Depending on the size of the system, personal monitoring of each individual luminaire unit is generally not possible for such systems. Emergency power lighting systems usually have their own supply network that is independent of the normal house network.

Various systems and methods are known which provide the monitoring and control of an emergency lighting system.

From the DE 198 32 550 A1 An emergency power lighting system is known, in which a control unit called a data processing unit is connected between the lamps and the connections of these lamps, which control unit can control the lamps and has a memory. The control units are programmable via the supply voltage applied, and each control unit or the corresponding illuminants can be assigned a luminaire identifier which is stored in the memory. To monitor the functionality of the emergency power lighting system (mode 7 ), the control units are programmed in such a way that they switch on the respective lamps at the same time as all other control units at the start of the monitoring routine and switch them off again after a time assigned to the lamp identification, which is not the same for any two control units. The current or the power consumption is measured across the entire emergency power lighting system, so that the occurrence of a drop in power at the time of switching off a lamp can be used to determine whether the lamp is functional.

Disadvantageously, this method or such an emergency power lighting system only works without measurement errors if the power drop when a lamp is switched off is large enough to be reliably detected. Since more and more light sources with very low nominal powers, such as LEDs or OLEDs, are being used, the power drop in such systems can be small and, especially in large emergency power lighting systems, can no longer be reliably detected due to long cable runs.

The invention is therefore based on the object of providing means and / or methods which ensure the detectability of a load drop resulting from switching off a lamp or a lamp unit, that is to say the unit consisting of lamp and control unit, even in the case of lamps with low power consumption.

This object is achieved in a control unit with the features of the preamble of claim 1 in that the ACTUAL power consumption of the lamp unit can be raised by means of the control unit after receiving at least one predetermined control code via the continuous operating power consumption.

In this way, an increased power drop can be generated which can be reliably detected, while the advantages of low power consumption continue to exist in continuous operation, in particular the low energy consumption of the entire lighting system. An increase in the ACTUAL power consumption over the continuous operating power consumption only has to exist for a very short period of time, so that components do not have to be designed for continuous operation with an increased ACTUAL power consumption.

The invention provides various options for how the actual power consumption can be increased. For example, the control unit can control an illuminant source, which in turn changes the supply of the illuminants in such a way that the Power consumption of the lamps increases. This illuminant source can be, for example, a current source of the lamp unit, the control unit being able to raise the current output by the current source and thus flowing through the illuminant, so that the power consumption of the illuminant increases. Since such a light source is necessary to supply the light in any case, no additional component has to be advantageously provided. It is both in the sense of the invention if the illuminant source is arranged within the control unit and influences the outputs of the control unit, and also that the illuminant source is arranged outside the control unit, in particular between the control unit and the illuminant.

Furthermore, it is possible for the control unit or the illuminant to have at least one load resistor to increase the ACTUAL power consumption, which is assigned to the lamp unit. The load resistance can be connected in series with the illuminant, for example, the control unit then controlling the switches with which the load resistance can be switched on. In this way, advantageously no lamp is exposed to a power consumption that is higher than the nominal power consumption, so that the lamps are not overused. Alternatively, the load resistor can also be connected in parallel with the lamp.

Instead of a load resistor, the lamp unit can also have a plurality of redundant lamps which can be switched on and off by the control unit to change the actual power consumption. At least one lamp is switched on during normal operation of the lighting system and at least one lamp is only switched on for the test routine. When using LEDs, for example, the assignment of which illuminant is switched on in continuous operation and which illuminant is used for briefly increasing the power consumption during a test routine can then advantageously be exchanged as soon as aging effects to a certain extent on that previously determined for continuous operation Illuminants can be seen. Such aging effects in LEDs are, for example, the reduction in the color temperature or the brightness of the emitted light. Above certain limit values, old LEDs are no longer suitable for normal operation of the lighting system. However, the aged LEDs are still suitable for changing the actual power consumption, since the power consumption does not change due to the aging effects. A change of all LEDs is advantageously only necessary when all LEDs have successively reached their aging limit, so that the maintenance effort is reduced. To monitor the signs of aging, a sensor can be provided on the lamp unit, for example, which measures the brightness and / or color temperature of the respectively switched on lamp.

In a preferred embodiment, the control unit can be controlled and / or programmed via the supply voltage applied to the control unit. The applied voltage can be modulated for the transmission of control codes or the voltage applied to the supply network can be switched on and off at certain time intervals. In this way, the supply network, which is required to operate the lighting units, can advantageously also be used to control the control unit, and no further components have to be provided for this purpose.

Alternatively, it is also conceivable that the input for receiving control codes is a receiver for radio signals, a radio transmitter also being provided in the lighting system. The radio transmitter can be arranged on a central unit of the lighting system, for example, while each control unit has its own, in particular identifiable radio signal receiver. It is then advantageous to transmit the control codes independently of the supply network. In this way, a system could be created from self-sufficient individual luminaire units, each of which is connected to an already existing supply network and in which a separate supply network for the lighting system can then be dispensed with. Such an embodiment comes into question if it is not an emergency power lighting system or if there is no need for a separate, autonomous supply network for the lighting system.

In one embodiment variant of the invention, the lighting system has a central unit from which the control of the lighting system is based. For this purpose, the central unit is connected to each lamp unit, in particular via a supply network or radio connections. The central unit has measuring devices for measuring the power consumption of the lighting system and / or possibly means for switching or modulating the supply voltage for controlling the control unit. Insofar as the central unit is connected to the lighting units via a supply network, it is also connected to a voltage source, such as an emergency power generator or a battery unit, which provides the voltage to be applied to the supply network. The central unit can thus combine all functions that only need to be present once in the system.

The control unit according to the invention can be part of an emergency power lighting system. Since in such a case the illuminants do not normally illuminate and therefore a defective illuminant regular functionality tests are essential, but their functionality is particularly important. As a result, the advantages of a centrally controllable and testable system described above are particularly effective.

In a particularly preferred embodiment, at least one program with at least one program routine is stored in the control unit, a program routine increasing the ACTUAL power consumption of the lamp unit and switching off the lamp unit after a time which is dependent in particular on the lamp identification. Due to the very low latency times in a digital program memory, the test time and thus the time in which any overdriving of individual components takes place can be kept low. Additional programs can also be stored in the program memory, for example for the automatic assignment of the luminaire identification when setting up the lighting system.

A function test of a lighting system with a control unit according to the invention can be carried out using the following method:

The routine is started in the central unit according to a routine schedule or upon a manually entered command. The central unit then transmits an execution command by means of a control code to the control units of each lamp unit. This can be done via the supply network insofar as the lighting units are connected to the central unit via one. It is conceivable, for example, that the central unit transmits a control code by means of voltage modulation or by switching the supply voltage on and off, so that, as far as the central unit is connected to the supply network via switching means, the control code consists of a sequence of switching operations of these switching means. It is also conceivable for the control code to be transmitted by radio signal, in so far as transmitting and receiving devices are provided on the central unit and each control unit.

After receiving the control codes, one or each control unit according to the invention raises the actual power consumption of the lighting units and switches on the respective illuminant. Thereafter, the control units switch off the illuminant again after a predetermined time, which is dependent on the lamp identification stored in them. The predetermined time is not the same for any two lighting units of the lighting system. The luminaire identification of each luminaire unit is also stored in the central unit and possibly linked to further information on the respective luminaire unit, such as the installation location in the building. The time period assigned to the respective lamp identification until the lamp is switched off is also stored in the central unit. If necessary, the data stored in the central unit can be synchronized with the data stored in the control units before the start of the routine.

The individual time periods until a lamp is switched off are preferably dimensioned such that sufficient time passes between two switch-offs, so that the measurement of the load drop can be assigned to a lamp unit without any doubt. The power consumption of the entire system is measured in the central unit during the entire process. After the last luminaire unit has been switched off, the function test is ended and the power consumption of the luminaire units is reset to the continuous operating state by the respective control units. If necessary, a protocol is finally generated and saved in the central unit.

If the central unit does not detect a load drop at a point in time at which a switch-off process of a lamp unit is stored in the data stored in it and a load drop is expected at this point in time, a message is generated that this lamp unit seems to have a defect or having.

The invention is explained in more detail below with reference to figures in which preferred exemplary embodiments of the invention are shown.

• 1: Ein Beleuchtungssystem in einer ersten Ausführungsform mit erfindungsgemäßen Leuchteneinheiten mit erfindungsgemäßen Steuereinheiten in schematischer Darstellung, wobei eine Steuerung der Leuchteneinheiten über die Versorgungsspannung des Beleuchtungsnetzes erfolgt;
• 2: ein Beleuchtungssystem in einer zweiten Ausführungsform mit erfindungsgemäßen Leuchteneinheiten mit erfindungsgemäßen Steuereinheiten in schematischer Darstellung, wobei die Steuerung der Leuchteneinheiten bzw. der Steuereinheiten per Funk erfolgt;
• 3: eine Leuchteneinheit in einer ersten Ausführungsform mit erfindungsgemäßer Steuereinheit in schematischer Darstellung;
• 4: eine Leuchteneinheit in einer zweiten Ausführungsform mit erfindungsgemäßer Steuereinheit in schematischer Darstellung.

Show it:

• 1 : A lighting system in a first embodiment with lighting units according to the invention with control units according to the invention in a schematic representation, the lighting units being controlled via the supply voltage of the lighting network;
• 2 : a lighting system in a second embodiment with lighting units according to the invention with control units according to the invention in a schematic representation, the lighting units or the control units being controlled by radio;
• 3 : a lamp unit in a first embodiment with a control unit according to the invention in a schematic representation;
• 4 : A lighting unit in a second embodiment with a control unit according to the invention in a schematic representation.

1 shows a lighting system 1 with one with a voltage source 7 related central processing unit 2 on which a supply network 3 connected. On the supply network 3 are multiple lighting units 4 arranged, each a control unit 5 as well as an illuminant 6 , for example in the form of LEDs. Inside the central unit 2 is a central control unit 10 arranged, which comprises several functions: it serves, among other things, as a control unit for the control units 5 , For this purpose, program routines and information about the individual control units are in the central control unit 5 stored, such as the lamp identification of the control units 5 , When a program routine is called up, control codes are sent to all or specifically addressed control units 5 transfer. In the central control unit 10 is also a write memory for those on the measuring devices 11a . 11b recorded data for power consumption in the lighting system 1 intended. The measuring devices 11a . 11b are each a voltage measuring device 11a and a current meter 11b , from the two measurement results of which the power consumption of all lighting units 4 in the lighting system 1 can be calculated, or by the central control unit 10 is calculated. The central control unit also includes 10 an interface for entering control commands and outputting messages. The transfer of control codes from the central unit 2 to the control units 5 happens over the supply network 3 , eg via voltage modulation.

2 shows a further embodiment of a lighting system 1 according to 1 , the control codes are not on the supply network 3 are transmitted, but for the transmission of control codes in the central unit 2 a radio transmitter 14 is arranged and on the control units 5 one radio receiver each 15 is arranged.

In 3 is a lamp unit 4 shown, compared to that in 1 embodiment shown another illuminant 6a as a means of increasing the power consumption of the lamp unit 4 on the control unit 5 is arranged. Any lamp 6 . 6a can be switched individually or both lamps 6 . 6a can be connected in series with each other. Each of the two lamps is for that 6 . 6a by means of the switches 23 . 23a can be bridged, the switch 23 . 23a through the switching unit 20 which in turn is controlled by the control unit 5 is controlled, controlled.

The control unit 5 has a power supply 17 and a memory 18 on that to power all components of the control unit 5 on the one hand and the illuminant 6 . 6a serve on the other. The storage capacity of the memory 18 is designed the control unit 5 even if not via the supply network 3 supply voltage for a certain period of time.

In the control unit 5 is still a data processing unit 19 arranged, from which all control commands of the control unit originate and on the power supply 17 and or the switching unit 20 impact. The data processing unit 19 has, in particular, a non-volatile data memory for storing program codes, which is stored by the central unit 2 or by the central control unit 10 is programmable or addressable. The data processing unit 19 processes control codes that the control unit 5 over the entrance 21a . 21b then receives and controls the outputs during the execution of the stored program routines 22a . 22b via the power supply or the output 22c direct and thus the switching unit 20 which in turn are the switches 23 . 23a head for.

In the in 4 illustrated embodiment is the control unit 5 not with the supply network 3 but with its own voltage source 25 connected. In addition, the control unit points 5 the signal input 21c on which the radio receiver 15 is connected to receive control codes. It is also conceivable that the control unit 5 or the data processing unit 19 the entrance 21c used as an output and the radio receiver 15 also has a transmission function so that the control unit sends information to the central unit 2 or the central control unit 10 can transmit back. For example, before the execution of a program routine, synchronization in the control units 5 every lamp unit 4 Information stored with that in the central control unit 10 stored information take place, especially the luminaire identifications.

To change the power consumption of the lamp unit 4 controls the control unit 5 the power supply 17 so that's the only illuminant 6 is operated with different currents. The power supply 17 can therefore generate different currents.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included 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.

Patent literature cited

• DE 19832550 A1 [0005]

Claims (13)

Control unit (5) for a lighting unit (4) of a lighting system (1), the control unit (5) comprising a data processing unit (19), a non-volatile memory (18) for storing a lighting identification and at least one output (22a, 22b) for comprises at least one illuminant (6) or at least one illuminant source (17) and at least one input (21a, 21b) for receiving control codes, the control unit (5) after receiving control codes the at least one illuminant (6) and / or the controls at least one light source (17), in particular switches on and off, the light unit (4) having continuous operating power consumption (P _duration ) in continuous operation with the at least one switched on light means (6), characterized in that by means of the control unit (5) the ACTUAL power consumption (P _ist ) of the lamp unit (4) after receiving at least one predetermined control code for the continuous operating power (P _duration ) can be raised. Control unit (5) after Claim 1 , characterized in that the illuminant (6) is an LED, in particular an LED with a power consumption of less than 2 watts. Control unit (5) after Claim 1 or 2 , characterized in that the control unit (5) controls the light source (17), which is a current source. Control unit (5) according to one of the preceding claims, characterized in that the control unit (5) or the lighting system (1) has at least one load resistor to increase the ACTUAL power consumption (P _ist ), which can be connected to the lamp unit (4). Control unit (5) according to one of the preceding claims, characterized in that the lighting unit (4) has a plurality of lamps (6, 6a) which are changed by the control unit (5) to change the ACTUAL power consumption (P _ist ), in particular in series, are switchable. Control unit (5) according to one of the preceding claims, characterized in that the control unit (5) can be controlled and / or programmed, in particular can receive control codes, via the supply voltage applied to the control unit (5). Control unit (5) according to one of the preceding claims, characterized in that the input (21a, 21b) for receiving control codes is a receiver (15) for radio signals. Control unit (5) according to one of the preceding claims, characterized in that the control unit (5) is a control unit (5) for a lighting unit (4) of an emergency power lighting system. Control unit (5) according to one of the preceding claims, characterized in that at least one program with at least one program routine is stored in the control unit (5), a program routine increasing the ACTUAL power consumption (P _ist ) of the lamp unit (4) and the lamp unit (4) switches off after a time that is dependent in particular on the lamp identification. Luminaire unit (4) of a lighting system (1), characterized in that it has at least one control unit (5) according to one of the preceding claims and at least one illuminant (6). Lighting system (1), characterized in that there is at least one lamp unit (4) Claim 11 , and a central unit (2) for controlling the lighting system (1) with measuring devices (11a, 11b) for measuring the power consumption of the lighting system (1). Lighting system (1) after Claim 11 , characterized by a central unit (2) which has means for switching the supply voltage for controlling and / or programming the control unit (5). Method for determining the functionality of a lighting unit (4) of a lighting system (1) according to one of the preceding claims, characterized in that a program routine stored in the control units (5) is started via the central unit (2), by means of which the power consumption of the lighting units ( 4) is increased and the lamp units (4) switch off the lamps (6) and / or the load resistors after a time, in particular depending on their lamp identification, the power consumption of the lighting system (1) being measured by the central unit (2).

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