EP0941634A1 - Device for the monitoring, control and regulation of flush lights of an airport lighting system - Google Patents

Abstract

In an appliance for the monitoring, control and regulation of flush lights of a street lighting system, each flush light has at least one lamp (10). The flush light has a transmitter-receiver device (3) with a microcontroller, which is connected, via a power supply line (6) and a router (8), with a control centre (2) which has a transmitter-receiver section and a control computer. The transmitter-receiver device (3) can receive control commands from the control centre. In order to configure such a street lighting system and/or its device for the monitoring, control and regulation of flush lights with minimum technical-constructive and economic expenditure, the microcontroller of each flush light is part of a local operating network (LON) (1), which, furthermore, has application specific components, e.g. switch and monitoring elements.

Description

description

Device for monitoring, controlling and regulating underfloor lights of an airport lighting system

The invention relates to a device for monitoring, controlling and regulating underfloor lights of an airport lighting system, in which each underfloor light has at least one lamp, each of which is associated with a transmitter / receiver device with a microcontroller, which is connected to a via a power supply line and a router Control center, which has a transmitting / receiving part and a control computer, is connected and can be acted upon from there with control commands.

The present invention is based on the object, on the basis of the above-mentioned prior art, to provide a device for monitoring, controlling and regulating underfloor lights of an airport lighting system, by means of which a large number of lamps in underfloor lights are particularly advantageous, but nevertheless can be controlled, monitored and regulated centrally without the need for additional lines, whereby high demands are placed on the security-relevant transmission technology and the hardware-related design of the components used decentrally.

According to the invention, this object is achieved in that the microcontrollers of the underfloor lights are components of a LON (locally operating network) which has application-specific components, for example switching and monitoring elements. The device according to the invention is particularly cheap on small airports, heliports, mobile airport equipment, field airports, landing sites and the like. applicable. In a preferred embodiment of the invention, the microcontroller is designed as a one-chip controller, which leads to considerable savings in terms of the technical-constructive and the economic outlay.

The microcontroller advantageously has an EEPROM, a RAM, three CPU, a clocking and control block with clock / timer elements, an application input / output block and a communication port, the EEPROM, the RAM, the three CPU , the application input / output block and the

Communication port by means of an internal address bus and an internal data bus and the EEPROM, the RAM, the three CPU, the application input / output block, the communication port and the clocking and control block are connected to each other by means of a timing and control line .

The EEPROM of the microcontroller expediently has 512 bytes, wherein network parameters and application programs can be stored in it.

The three CPUs of the microcontroller should advantageously each be designed as an 8-bit CPU.

This makes it possible to use one of the three CPUs of the microcontroller for application programs.

The other two CPUs of the microcontroller can be used for LONTALK protocol processing, with the processable protocols having all seven layers of the reference model according to ISO / OSI.

The application input / output block can advantageously be used as a parallel interface to an external microprocessor with eight data and three control lines. According to one embodiment of the invention, the application input / output block of the microcontroller has a 16-bit load register, a counting device, an intermediate store (latch), a clock source (clock source), four 20 mA sink curves. rent pens four, a programmable pull-ups and possibly other elements.

The communication port of the microcontroller advantageously has five network interface pins, by means of which it connects to a baseband medium, e.g. can be connected to a twisted pair cable or to an external transceiver.

The microcontroller can have a low-voltage detector and reset circuit, by means of which faulty operation or faults in the EEPROM can be prevented if the applied voltage is less than 4.1 VDL +/- 300 mV tolerance.

If the microcontroller does not have a ROM, it is useful if it has an external memory interface. The RAM of the microcontroller can then have advantageous 2048 bytes.

According to a further embodiment of the invention, the microcontroller has a RAM with 1024 or 2048 bytes and a ROM with 10240 bytes.

Each microcontroller has a unique, captive identification number, by means of which the lamp function status can be linked to an address, which preferably has 48 bits and for which 6 bytes of the EEPROM can be used. The microcontroller should expediently have a service pen, so that an effective network device is possible.

Each underfloor light should have a lamp brightness control circuit that sets a specified lamp current setpoint via a pulse width modulation element and adjusts the actual value that is set.

This lamp brightness control circuit is advantageously designed for load dependency and line length compensation of the drop voltage or the voltage drop.

A switching power supply is advantageously provided which has a toroidal core transformer as the separating element which, in cooperation with the pulse width modulation element, determines the transmitted power.

Furthermore, each underfloor light is expediently provided with a disconnection circuit, which brings about a rapid disconnection in the event of impermissible currents and after troubleshooting, e.g. by lamp replacement, this separation cancels.

A measuring circuit is provided, via which a disconnection and a re-connection can be detected by the microcontroller.

Advantageously, all lamp functions can be detected by means of the measuring circuit and entered into the microcontroller, in which the actual lamp values are comparable with the lamp setpoints.

If low-voltage halogen lamps are used for the underfloor lights, it is expedient if each underfloor light has a supply circuit by means of which the lamp current can be adapted to the supply voltage. Each underfloor light should advantageously have an actuator circuit, by means of which a signal can be generated, by means of which the true functional state of the lamp, for example lamp defect, line break or short circuit, can be reported back.

Each underfloor light should also be provided with a further supply circuit for the microcontroller, which ensures that a differentiated message can be sent to the LON in the event of faults in the lamp circuit.

In an advantageous embodiment of the invention, function data on the state of the individual circuits can be reported to the control center by means of the microcontroller, which leads to considerable savings in maintenance and repair.

To further facilitate maintenance and repair, it is advantageous if the individual underfloor lights are connected to the main power supply line via a detachable connection, in particular via a pressurized water-protected first plug connection, which is preferably designed as a shock-proof plug connection.

The lamp of the underfloor light can have an internal second plug connection, which is preferably designed as a two-pole FAA plug connection, and by means of which it is connected to elements of the underfloor light connected upstream of it.

The individual underfloor lights can expediently be lifted out of their seat in the underground and separated from the main power supply line by means of the first plug connection.

The affiliation of individual underfloor lights to predefinable underfloor fire groups or underfloor fire chains, the respective affiliation via the power supply line is configurable, ensures a great variability and adaptability of the airport lighting system to different requirements.

The communication on the power supply line should be feasible in the C-band according to CENELEC, so that the standards applicable in Europe can be met.

The underfloor lights are advantageously connected in parallel on the power supply line.

To simplify the construction of the underfloor light, the microcontrollers and the other switching and monitoring components of the underfloor light, which are connected upstream of the lamp, are arranged on a circuit board which is adapted to the shape of a housing of the underfloor light and is fastened in the underfloor light so that it is shock and vibration-proof.

Each underfloor light advantageously has a module part which has the microcontroller and the switching and monitoring components connected upstream of the lamp of the underfloor light. This part of the module enables quick repairs in the event of malfunctions, since it can be easily replaced.

For this purpose, it is advantageous if the module part of each underfloor light can be connected to the main power supply line by means of the pressurized water-protected plug connection and to the lamp of the underfloor light by means of the internal second plug connection.

In order to suppress interference with regard to the received signal, it is expedient if the module part of each underfloor light has a metallic, earthed housing. If the circuit board is crescent-shaped, it can be arranged around the lamp of the underfloor light, which results in a flat design of the underfloor light.

In order to prevent moisture from penetrating into the module part and leading to malfunctions in the underfloor light, it is advantageous if the module part is cast in watertight, a cable tail being provided for each of the two plug connections.

The module part is advantageously arranged next to or around the lamp of the underfloor light, and the housing can be adapted to the crescent-shaped configuration of the circuit board.

With the device described above, 65 watt lamps can be used with sufficient light output.

The inventive device means that an almost potential-free operation of the underfloor light is possible with minimal energy consumption, with very low energy consumption occurring in standby mode.

In the following the invention is explained in more detail by means of embodiments with reference to the drawing. Show it:

1 shows a basic illustration of a device according to the invention for monitoring, controlling and regulating underfloor lights of an airport lighting system; 2 shows a block diagram of a module part and a lamp of an underfloor light; 3 shows the spatial arrangement of underfloor lights, with multiple underfloor lights being provided; 4 shows a microcontroller of an underfloor light of the device according to the invention; 5 shows a schematic diagram of the underfloor light and its connection to the power supply line; 6 shows a plan view of a module part of the device according to the invention; 7 shows a bottom view of the module part shown in FIG. 6; 8 shows a plan view of an underfloor fire of the device according to the invention;

9 shows a sectional view of an underfloor light of the device according to the invention; and FIG. 10 shows a plan view of a modified underfloor light of the device according to the invention.

A device shown in principle in Fig. 1 for monitoring, controlling and regulating underfloor lights of an airport lighting system is subdivided into data communication within a LON (Local Operating Network) 1, into the control and monitoring by means of a central unit designed as a PC 2 in the exemplary embodiment shown, and the Function of a module part 3 shown in detail in FIG. 2, of which each underfloor light 4 has one.

The data communication between the module part 3 of the underfloor light 4 and the PC 2 forming the center is implemented in the LON.

All seven ISO / OSI protocol layers are fulfilled because they are implemented in terms of hardware and software in the microprocessors used in the facility for monitoring, controlling and regulating underfloor lights. It is possible to choose different communication media that can be combined and mixed, for example optical fibers, twisted two-wire lines (TWP) 5, the power supply network 6 and radio links 7 can be used as communication media.

The transmission method is based on a differential Manchester code with a bit synchronization that can be adapted to the respective communication medium. A CSMA procedure with access priorities realizes the collision avoidance. Priorities can be assigned for important messages.

The transition between the different communication media used is realized by means of routers 8.

While data communication within operating buildings preferably takes place via twisted two-wire lines 5, since a high transmission rate is required there, routers 8 are installed in the area of the main low-voltage distributors, by means of which data protocols can be coupled into one or more supply networks 6. Thus, in the case of spatially arranged low-voltage networks with Intermediate medium voltage transformers have a star-shaped feed into the distribution level.

In the module part 3 of the underfloor light 4, shown in FIG. 2, the transmitters 9 for the power supply line 6 and the routers 8 via the twisted two-wire lines 5 to the LON 1 operate in the C-band according to CENELEC, which is approved for Europe.

The PC 2 forming the central unit takes over the central configuration, control and monitoring of the lights of the underfloor lights 4 which may have several lamps 10 about the module parts 3 of the same. It is possible to integrate several PC 2 without hierarchy at different locations in the LON, which then work redundantly and can monitor each other.

Remote access via modem connections or ISDN is possible.

After the random installation of the module parts 3, each module part 3 is configured with the PC 2 with regard to its affiliation with the underfloor fire chains 11, 12, 13, 14, 15, 16 shown in FIG. The corresponding data are loaded into the respective module parts 3 of the underfloor lights 4, where they are stored captively. Due to the overlapping underfloor fire chains 11, 12, 13, 14, underfloor lights 4A are provided, which belong to different underfloor fire chains and underfloor fire chain groups.

A graphic interface on the PC 2 takes over the representation of the module parts 3, different colors of the symbols of the module parts 3 signaling the different operating and error states of the module parts 3 with their connected lamps 10.

A history function enables the on-time of all module parts 3 and the ones assigned to them to be recorded

Lamps 10 and automatically gives maintenance instructions for replacing lamps. The lamp work is taken as a basis here, since there is an extension of the service life when operating below the nominal data. All history and maintenance data are stored in a file that can be output from the system of the facility. Operating times, malfunctions and selection messages of the module parts 3 can be freely combined with a PC 2 in groups and arranged according to priorities; these can be forwarded via data traffic with other control room computers. processed and automatically forwarded to the maintenance companies.

With a PC 2, the assembly date of the respective lamp 10 and the total operating time can be determined from each module part 3 according to the working history.

To replace defective module parts 3, a "service terminal" function is available, with which the new module part 3 is assigned the data of the defective module part 3 by a PC 2, so that the work within the airport lighting system is solely based on changing the Module part 3 limited.

All module parts 3 can be individually controlled by the PC 2 for test purposes with variable illuminance levels.

A host computer can call up 2 freely programmable scenarios for controlling the underfloor fire chains 11, 12, 13, 14, 15, 16 via a PC; however, the PC 2 can also act as a master computer. The computer coupling to external systems is implemented, for example, by an RS 232 interface.

The module part 3 shown in FIG. 2 in its block diagram serves to control and monitor one lamp 10 of an underfloor light 4.

In the series lamp circuit with the lamp 10, an isolating circuit 17 is provided, which is quick in the event of impermissible currents

Separation of the lamp circuit part downstream of it and the lamp 10 of the underfloor light 4 which is also downstream from it ensures. After a fault has been rectified, for example by means of a lamp replacement, the isolating circuit 17 switches the lamp circuit on again. The separation of the lamp circuit downstream of the isolating circuit 17 is detected by a microcontroller 19 via a measuring circuit 18, since there is an impermissible deviation of the actual value from the target value via a connecting line 20 in the microcontroller 19. This inadmissible deviation is available in the power supply line 6 or in the LON 1 by means of the transmitter 9. The same function applies to the return of the lamp circuit from the fault, for example after the lamp replacement has ended.

A supply circuit 21 adjusts the lamp voltage to the supply voltage when using low-voltage halogen lamps. Potential isolation can then be provided in such a lamp circuit.

An actuator circuit 22 enables the level of the current flowing through the output to be influenced by the lamp 10 when the lamp circuit is terminated. The actuator circuit 22 receives its manipulated variable via a connecting line 23 from the microcontroller 19, in which a constant comparison of the current setpoint value with the lamp current actual value is carried out becomes. With this procedure, not only is the returned actual lamp current value checked, but the true functional state of the lamp 10 is also reported via the transformer 9 into the energy supply line 6 or the LON 1.

The microcontroller 19 contains the captive network address of the module part 3; the lamp function state is provided with it there, so that identification in the PC 2 forming the center is made possible.

A second supply circuit 24, which works separately from the lamp series circuit formed by the isolating circuit 17, the supply circuit 21, the actuator circuit 22 and the measuring circuit 18, is used to supply energy to the microprocessor. Controller 19 and the transmitter 9 and thus ensures that in the event of faults in the lamp series circuit, that is to say also in the event of a separation thereof, a differentiated message is sent to the LON 1 or to the energy supply line 6.

The desired functional operating state, which the microcontroller 19 from the transmitter 9 from the supply network 6 or the LON 1, e.g. received by the PC 2 as an instruction, the microcontroller 19 can acknowledge via a connecting line 26, it must execute the instruction and then report the true state of the functional data via a connecting line 25 and the transmitter 9 into the LON 1 with address.

The module part 3 shown in principle in FIG. 2 serves in the case of the airport lighting system according to the invention as a transmitter / receiver device for the underfloor light 4 and stands over the LON 1, router 8 and the twisted two-wire lines 5 with the PC 2 acting as the central unit, which has a corresponding transmitting / receiving part and has a control computer in connection.

The microcontroller 19 of the module part 3 is designed as a one-chip controller. The microcontroller 19 has an EEPROM 27, a RAM 28, three CPUs 29, 30, 31, a clocking and control block 32, an application input / output block

33 and a communication port 34, which can connect to the LON via the transmitter 9 described in FIG.

The EEPROM 27, the RAM 28, the three CPU 29, 30, 31, the application input / output block and the communication port 34 are by means of an internal 16-bit address bus 35 and by means of an internal 8-bit - Data bus 36 connected to each other. The EEPROM 27, the RAM 28, the three CPU 29, 30, 31, the application input / output block 33, the communication port 34 and the clocking and control block 32 are by means of a timing and control line 37 connected to each other.

The EEPROM 27 of the microcontroller 19 has at least 512 bytes. Network parameters and application programs can be stored in it.

The three CPU 29, 30, 31 of the microcontroller 19 are each designed as an 8-bit CPU. The first CPU 29 is used for application programs.

The two other CPU 30, 31 of the microcontroller 19 are used for LONTALK protocol processing.

The application input / output block 33 of the microcontroller 19 has eleven input / output connections 38 to 45 or 46, 47, 48, of which eight 38 to 45 can be used as data lines and three 46, 47, 48 as control lines if the application

Input / output block 33 is used as a parallel interface to an external microprocessor.

The application / input / output block 33 has a 16-bit load register, a counting device and a buffer

(Latch), a clock source (clock source), four 20mA sink curling pins, four programmable pull-ups and possibly other elements.

The communication port 34 of the microcontroller 19 has five

Network interface pins 49, by means of which it can be connected to a baseband medium, for example a twisted two-wire line, or to an external transceiver. The clocking and control block 32 has a control block 50, a clock / timer block 51; the microcontroller may further include a low voltage detector and reset circuit 52.

The latter prevents erroneous operation or incorrect EEPROM values if the applied voltage is below a minimum voltage.

The control block 50 of the service block 32 has a reset and a service connection.

The clock / timer block 51 has a connection via which standard clock inputs of 20 MHz, 10 MHz, 5 MHz, 2.5 MHz, 1.25 MHz and 625 kHz are possible.

Two programmable 16-bit counters or timers are provided.

In the illustrated embodiment of the microcontroller 19, it can be connected to an external memory interface 53, which is shown in FIG. 4 only by the corresponding reference symbol. In this embodiment, the RAM 28 of the microcontroller 19 has 2048 bytes.

In a further embodiment of the microcontroller 19, not shown in FIG. 4, no connection to an external memory interface is provided; the RAM 28 of the microcontroller 19 has 1024 bytes and a ROM additionally provided in the microcontroller 19 has 10240 bytes.

In the microcontroller 19 of each module part 3 there is a unique identification number which is stored in a captive manner and by means of which a network address of the respective lamp 10 of the Underfloor fire 4 can be linked; the identification number has 48 bits; 6 bytes of EEPROM 27 can be used for this.

The microcontroller 19 also has a service pin.

5 shows the connection of an underfloor light 4 to the power supply line 6. A sleeve or a branch 54 is provided on the energy supply line 6, the branching cable section 55 of which via a

Schuko plug connection trained pressure water protected first connector 56 is connected to the module part 3 of the underfloor light 4. For this purpose, the module part 3 has a cable section 57, at the free end of which the first plug 56 on the module part side is provided.

On its side facing the lamp 10 of the underfloor light 4, the module part 3 likewise has a cable section 58, at the free end of which a second plug-in connection 59 inside the underfloor light is provided, by means of which the module part 3 can be connected to the lamp 10. The second connector 59 is designed as a two-pole FAA connector.

Because of the easily detachable plug connections 56, 59, by means of which the module part 3 is connected on the one hand to the power supply line 6 and on the other hand to the lamp 10 of the underfloor light 4, any maintenance, repair or replacement work is easily separated of the module part 3 or the lamp 10 from the underfloor fire 4 is possible.

FIGS. 6 and 7 show a top view and a bottom view of a circuit board 60 having the functional elements of the module part 3. The circuit board 60 has a curved configuration so that, as can be seen in FIGS. there, is more or less crescent-shaped. Due to this crescent-shaped design of the circuit board 60, the module part 3 can be arranged around the lamp 10 practically at the same level as the lamp 10 of the underfloor light 4. This results in an overall particularly flat design of the underfloor light 4.

The circuit board 60 with the functional elements arranged on it is advantageously provided with a metallic housing 61, which is shown in FIG. 8 only in principle by the dashed line. In addition, the circuit board 60 with the functional elements arranged on it can be cast in plastic in order to avoid any malfunctions due to moisture or the like. sure to rule out.

The cable ends 57, 58 protrude from the metallic housing 61 of the circuit board 60 or the module part 3, by means of which the module part 3 can be connected on the one hand to the lamp 10 of the underfloor light 4 shown in FIG. 8 and on the other hand to the power supply line 6 not shown in FIG is.

The underfloor light 4 has a housing 62 which can be lifted out of its seat in the ground and can be separated from the power supply line 6 by the first plug connection 56.

As a lamp 10 e.g. a 45 watt lamp can be used.

8, two lamps 10 are provided, so that two module parts 3 can also be used.

The underfloor light shown in section in FIG. 9 has a lamp 10 which is controlled via the module part 3. The module part 3 is slightly below the lamp 10 in the vertical direction arranged. It is connected via the cable ends 57, 58, which protrude from the module part 3, on the one hand to the energy supply line 6, not shown in FIG. 9, and on the other hand to the lamp 10 via a Schuko plug connection 59.

The underfloor light shown in FIG. 10 has only one lamp 10, which is designed as an all-round radiation lamp. The module part 3 is connected to the power supply line 6 (not shown in FIG. 10) via the cable end 59, the module part 3 is connected to the lamp 10 via the cable end 58. The housing 62 of the underfloor light is, as in the embodiment according to FIG. 8, can be brought into releasable engagement with the base by means of screw connections 63.

Claims

claims

1. Device for monitoring, controlling and regulating underfloor lights (4) of an airport lighting system, in which each underfloor light (4) has at least one lamp (10), each of which is associated with a transmitter / receiver device (3) with a microcontroller (19), which is connected via a power supply line (6) and a router (8) to a center (2) which has a transmitting / receiving part and a control computer and can be acted upon from there with control commands, characterized in that the microcontroller (19) Underfloor lights (4) are components of a LON (1), which are application-specific components, e.g. Switching and monitoring elements.

2. Device according to claim 1, wherein the microcontroller (19) is designed as a one-chip controller.

3. Device according to claim 1 or 2, wherein the microcontroller (19) an EEPROM (27), a RAM (28), three CPU (29,

30, 31), a clocking and control block (32) with a control block (50) and a clock / timer block (51), an application input / output block (33) and a communication port (34), the EEPROM (27), the RAM (28), the three CPU (29,30,31), the application input / output block (33) and the communication port (34) by means of an internal address bus (35) and an internal data bus (36) and the EEPROM (27), the RAM (28), the three CPU (29,30,31), the application input / output block (33), the communication port (34) and the clocking and control block (32) are connected to one another by means of a timing and control line (37).

4. Device according to claim 3, wherein the EEPROM (27) of the microcontroller (19) has at least 512 bytes and in network parameters and application programs can be saved.

5. Device according to claim 3 or 4, wherein the three CPU (29, 30, 31) of the microcontroller (19) are each designed as an 8-bit CPU.

6. Device according to one of claims 3 to 5, in which a CPU (29) of the microcontroller (19) is used for application programs.

7. Device according to one of claims 3 to 6, in which the two other CPU (30, 31) of the microcontroller (19) are used for LONTALK protocol processing.

8. Device according to one of claims 3 to 7, in which the application input / output block (33) of the microcontroller

(19) has eleven input / output connections (38-45,46,47,48).

9. Device according to claim 8, in which the application

Input / output block (33) can be used as a parallel interface to an external microprocessor with eight data and three control lines.

10. Device according to one of claims 3 to 9, in which the application input / output block (33) of the microcontroller (19) a 16-bit load register, a counting device, a buffer, a clock source, four 20 mA sink Current pens, four programmable pull-ups and possibly other elements.

11. Device according to one of claims 3 to 10, wherein the communication port (34) of the microcontroller (19) has five network interface pins (49) by means of which it is connected a baseband medium or can be connected to an external transceiver.

12. Device according to one of claims 3 to 11, wherein the microcontroller (19) has a low-voltage detector and reset circuit (52).

13. Device according to one of claims 3 to 12, wherein the microcontroller (19) to an external memory interface (53) can be connected.

14. Device according to one of claims 3 to 13, wherein the RAM (28) of the microcontroller (19) has 2048 bytes.

15. Device according to one of claims 3 to 12, wherein the microcontroller (19) has a RAM with 1024 or 2048 bytes and a ROM with 10240 bytes.

16. Device according to one of claims 3 to 15, whose microcontrollers (19) each have a unique, captive identification number, by means of which the respective lamp functional state can be linked to an address which preferably has 48 bits and for the 6 bytes of the EEPROM (27) can be used.

17. Device according to one of claims 3 to 16, the microcontroller (19) having a service pin.

18. Device according to one of claims 1 to 17, which has a lamp brightness control circuit that sets a predetermined lamp current setpoint via a pulse width modulation element and adjusts the actual value that is set.

19. Device according to claim 18, the lamp brightness control circuit is designed for load dependency and line length compensation of the voltage.

20. Device according to claim 18 or 19, which has a switching power supply, which has a toroidal core transformer as a separating element which, in cooperation with the pulse width modulation element, determines the transmitted power.

21. Device according to one of claims 1 to 20, which has a disconnection circuit (17) which brings about a rapid disconnection in the event of impermissible currents and after fault rectification, e.g. by replacing the lamp, which cancels the separation.

22. Device according to claim 21, which has a measuring circuit (18), via which a disconnection and a re-connection from the microcontroller (19) can be detected.

23. Device according to claim 22, by means of the measuring circuit (18) of which all lamp functions can be detected and entered into the microcontroller (19), in which the actual lamp values are comparable with the lamp setpoints.

24. Device according to one of claims 1 to 23, which has a supply circuit (21) by means of which the lamp current can be adapted to the supply voltage when using low-voltage halogen lamps.

25. Device according to one of claims 1 to 24, which has an actuator circuit (22) by means of which a signal can be generated, by means of which the true functional state of the lamp (10), but also a line break or short circuit, can be reported back.

26. Device according to one of claims 1 to 25, which has a second supply circuit (24), which is assigned to the microcontroller (19), by means of which it is ensured that a differentiated message can be sent to the LON (1) in the event of faults in the lamp circuit is.

27. Device according to one of claims 1 to 26, in which by means of the microcontroller (19) function data on the state of the individual circuits can be reported to the control center (2).

28. The device as claimed in one of claims 1 to 27, in which the individual underfloor lights (4) are connected to the main power supply line (6) via a detachable connection, in particular via a pressurized water-protected first plug connection (56) on a cable section (55) ) are connected.

29. Device according to one of claims 1 to 28, wherein the lamp (10) of the underfloor light (4) by means of an internal second plug connection (59), preferably a two-pole FAA plug connection, is connected to upstream elements of the underfloor light (4) .

30. Device according to claim 28 or 29, in which the individual underfloor lights (4) can be lifted out of their seat in the ground and can be separated from the power supply line (6) by means of the first plug connection (56).

31. Device according to one of claims 1 to 30, in which the affiliation of individual underfloor lights (4; 4A) to predefinable underfloor fire groups or underfloor fire chains (11, 12, 13, 14, 15, 16) can be determined via the energy supply line (6).

32. Device according to one of claims 1 to 31, in which the communication on the energy supply line (6) in the C-band according to CENELEC can be carried out.

33. Device according to one of claims 1 to 32, the underfloor light (4) on the power supply line (6) are arranged.

34. Device according to one of claims 1 to 33, in which the microcontroller (19) and the further switching and monitoring elements (17, 18, 19, 21, 22, 24, 9) upstream of the lamp (10) of the underfloor light (4 ) are arranged on a circuit board (60) which is adapted to the shape of a housing (62) of the underfloor light (4) and is fastened in the underfloor light (4) in a shockproof and vibration-proof manner.

35. Device according to one of claims 1 to 34, wherein each underfloor light (4) has a module part (3) which the microcontroller (19) and the lamp (10) of the underfloor light (4) upstream switching and monitoring components (17,18,21,22,24,9).

36. Device according to claim 35, wherein the module part (3) of each underfloor light (4) by means of the pressurized water-protected first plug connection (56) to the power supply line (6) and by means of the internal second plug connection (59) to the lamp (10) of the underfloor light (4) can be connected.

37. Device according to claim 35 or 36, in which the module part (3) of each underfloor light (4) is a metallic earthed one

Has housing (61).

38. Device according to one of claims 34 to 37, wherein the circuit board (60) is sickle-shaped.

39. Device according to one of claims 35 to 38, in which the module part (3) is cast in a watertight manner and a cable tail or cable section (57, 58) is provided for each of the two plug connections (56, 59).

40. Device according to one of claims 35 to 39, wherein the module part (3) next to or around the lamp (10) of the underfloor light is arranged approximately in its level.

41. Device according to one of claims 1 to 40, in which 45-watt lamps are used as lamps (10).