WO1999014989A1

WO1999014989A1 - Control device for airport lighting systems

Info

Publication number: WO1999014989A1
Application number: PCT/DE1998/002715
Authority: WO
Inventors: Francis Caus; Jean-Claude Vandevoorde
Original assignee: Siemens Aktiengesellschaft
Priority date: 1997-09-18
Filing date: 1998-09-14
Publication date: 1999-03-25

Abstract

The invention relates to a control device for airport lighting systems. The inventive device enables the current delivered to downstream lighting installations to be adjusted in addition to equalization of said current to the adjusted level or to changes thereof. In order to design a safer and more reliable control system of this type, controlled input segments of the lighting installations are supplied with control and monitoring signals that are similar in content by two separate independent buses (3,4). The controlled input segments enable a separate plausibility test and/or control conformity test to be carried out on the control signals from one bus (3) and on the control signals from the other bus (4). If non-plausibility and/or non-conformity is determined for the control signals from one bus (3) or the other bus (4), control signals from the second bus (4) or the first bus (3) can act as a base for operation of the controlled input segments.

Description

description

Control device for airport lighting systems

Airport lighting systems and related device parts require a coordinated control system that is flexible and very reliable at the same time. The flexibility is necessary due to possible changes and expansions to the airport facilities in operation; This flexibility is currently based on the use of fieldbuses and similar means of communication.

Such bus devices form common communication paths for controlling and monitoring a plurality of controlled devices and therefore represent individual critical danger points which affect all connected devices. This results in an unacceptable level of risk, since the number of devices connected to the same bus device increases both the probability of failure and the extent of the damage to be expected, because all connected devices can be affected by a defect.

Solutions for this problem are known from the prior art, in which a plurality of control units or microcomputers are connected to the communication medium, a selection then being carried out between their output signals and a valid output signal being selected.

In addition to the considerable additional technical and economic effort associated with such solutions, it should be noted that additional control units or microcomputers mean additional failure risks, so that the solutions described above are more complicated and only partially safer. The invention therefore relates to a control device for lighting systems in airports, for example airport lighting systems, flashing fire systems, obstacle marking and lighting systems, apron and area irradiation systems, landing lights, identification and other beacons, airport beacons, aircraft safety cable and network systems, individual lighting for aircraft lines, etc. with Controlled input parts for regulating the current supplied to the lighting devices and for equalizing the current supplied to the downstream lighting devices at the control level or when the control level changes.

As already mentioned, the requirements for the reliability and operational safety of such at airports, e.g. on runways, used lighting and lighting systems and on their control devices, whereby the matters to be controlled, regulated and monitored are becoming more and more complicated. It is only possible to ensure the long-term safety of people and materials in the air and on the ground if the reliability and operational safety of lighting and signaling systems at airports can be increased accordingly.

The invention has for its object to develop the generic control device for lighting systems of airports described above such that it can meet increased requirements with regard to their operational safety and reliability and on the other hand contributes to a considerable extension of the life of its downstream lighting devices.

This object is achieved in that the controlled input parts associated with the control device by means of two separate, mutually independent buses Content-like control and monitoring signals can be acted on, that by means of the controlled input parts, a separate plausibility and / or conformity check of the control signals from one bus and the control signals from the other bus can be carried out, and that in the event of non-plausibility and / or non-conformity being ascertained the control signals of one or the other bus, the operation of the controlled input parts, the control signals of the other or the one bus can be used as a basis. Due to the redundant introduction of the control signals from the control device according to the invention into the controlled input parts, it can be ensured that reliable and correct operation of the controlled input parts and thus of the control device is also maintained in a case in which the one or the other Busses in the controlled input parts control signals are subject to interference or falsified. On the basis of the plausibility check, which takes place internally within the controlled input parts, it can be determined whether the control signals of one or the control signals of the other bus are falsified or disturbed. If the control signals of one or the other bus malfunction, the undisturbed control signals of the other bus are automatically taken into account when operating the controlled input parts. The downstream lighting devices are thus more reliable than in the prior art with the current strength provided for them, which depends on the time of day and weather or Light conditions can vary, applied. According to the invention, the controlled input parts assigned to the control device are therefore quasi redundant

Multidrop bus control system, which meets the increased safety and reliability requirements in today's operating conditions, since one of the two buses is automatically switched to the functioning bus in the event of a malfunction or failure. Basically, it is possible to use existing ones Controlled input parts, which are controlled and monitored by means of a bus, can be retrofitted according to the invention by means of a further bus and corresponding supplementary components. If necessary, the parameters controlled and / or monitored by the two buses of the controlled input parts can be expanded or adapted as requirements change.

According to the invention, the reliability and the economic outlay are optimized by the redundant solution with two different buses and a single input part with two different and separate inputs. Since a failure of a bus is detected by the control device, a repair or replacement can be carried out before the entire system fails.

The plausibility and / or conformity check of the control signals entered by the buses into the controlled input parts can expediently be carried out by means of a microprocessor, which can be designed as a simple processor and can have a separate control input for each of the two buses. If a plausibility and / or conformity check of the control signals coming from the two buses results in a fault or falsification of the control signals present at one of the two control inputs, the microprocessor automatically switches over to the control input at which those control signals are present, their plausibility and / or Conformity check has led to a positive result.

The microprocessor of the controlled input parts of the control device according to the invention expediently has a digital control input for one bus and a serial control input for the other bus. In an advantageous embodiment, the control inputs of the microprocessor are dual and are isolated from one another. The isolation of the two control inputs from one another prevents systematic damage to both control inputs, the isolation of the two control inputs also acting against earth and against the further microprocessor circuits.

In an advantageous embodiment of the controlled input parts of the control device according to the invention, the digital control input of the microprocessor is preceded by an asynchronous receiver / transmitter, the output signals of which are fed to the digital control input of the microprocessor and which is preceded by a transmitter / receiver which is galvanically isolated, works dual and on a first bus input assigned to a bus is connected.

The serial control input of the microprocessor is preceded by a further transmitter / receiver, which is galvanically isolated, works dual and is connected to a second bus input assigned to the other bus. The further transmitter / receiver can be designed more or less identically with the first-mentioned transmitter / receiver, which is assigned to the digital control input of the microprocessor. Due to the asymmetrical design of the input areas of the microprocessor assigned to the digital or serial control input, despite the largely identical design of the two transmitters / receivers, there is, if at all, only a very low probability that a total failure will occur in the event of a limit signal.

The microprocessor, the asynchronous receiver / transmitter, the two transmitters / receivers and the two can be advantageous Bus inputs can be implemented as part of a flat module, which in turn can be easily installed. If the controlled input part is reset to the operating state which is provided in the event that both buses operate without interference, with the control signals of one or the other bus being used as the basis for the operation of the controlled input part, then it is ensured that always then, if it is possible, the controlled input part works in the safest mode of operation.

If the controlled input parts of the control device according to the invention are designed as work units of a control and monitoring circuit having a plurality of such controlled input parts designed as work units, a main unit being installed on a substation of the control and monitoring circuit, of which the individual work units are installed by means of the two buses can be called up at predefinable times for status information and control, highly functional and reliable control and monitoring circuits for very large and complicated systems can be implemented with comparatively little technical effort.

If the controlled input parts of the control device according to the invention are components of a control and monitoring circuit whose components upstream of the controlled input parts are of redundant design, this control and monitoring circuit can be made extremely reliable, although only one microprocessor is provided within each of the controlled input parts , which can be a comparatively simple communication processor. Advantageously, conventional field buses, for example MOD buses, PROFI buses, CAN buses or the like, can be used with the controlled input parts of the control device according to the invention. This and the availability of comparatively less expensive telecommunication and computer technology make it possible to manufacture the control device according to the invention with a comparatively low and accordingly justifiable economic outlay.

Installation and a possible emergency exchange are associated with comparatively little effort, since simple connectors can be used for the control and monitoring inputs.

The controlled input parts of the control device according to the invention can be combined with different consumers, e.g. with switching devices, high voltage devices, irrigation controls, fuel controls and the like.

In addition, a control device equipped with these controlled input parts is very flexible, since the controlled input parts can be used to regulate and monitor different downstream lighting devices provided in a local area, the control of these different lighting devices using the same two buses or one of these both buses can be made.

The invention is explained in more detail below with reference to an embodiment with reference to the drawing, in which the parts of an embodiment of the control device according to the invention that are essential for the invention are shown in principle. A controlled input part of the control device according to the invention shown in the single figure has two bus inputs 1, 2; bus input 1 is assigned to a first bus 3, whereas bus input 2 is assigned to a second bus 4.

A tranceiver 7 and a universal asynchronous receiver / transmitter 8 are arranged between the first bus 3 connected to the bus input 1 and a digital control input 5 of a microprocessor 6.

Between the bus input 2 assigned to the second bus 4 and a serial control input 9 of the microprocessor 6, the arrangement shown in the single figure has a further transmitter / receiver 10. The transmitter / receiver 10 can be identical to the transmitter / receiver 7.

The dashed line in the single figure separates the area outside the controlled input part from the input part. An output line 11 of the microprocessor 6 leads to the main switching arrangements of the downstream area, not otherwise shown.

The controlled input part of the control device according to the invention and thus the microprocessor 6 is acted upon by the first bus 3 and by the second bus 4 with mutually corresponding control signals. The following different cases are accordingly conceivable in the operation of the controlled input part provided with the circuit shown in the single figure:

- Both buses 3, 4 are in good condition. The transmitter / receiver 7 receives control signals from the first bus 3 through the bus input 1; the transmitter / receiver 10 receives through the bus input 2 control signals from the second bus 4. From the transmitter / receiver 7 the control signals get through the universal asynchronous receiver / transmitter (UART) 8 to the digital control input 5 of the microprocessor 6. From the transmitter / receiver 10 the control signals get through the Serial control input 9 to the microprocessor 6. The microprocessor 6 subjects the control signals input to it through the digital control input or the serial control input 9 to a separate plausibility and / or conformity check, in which possible transmission errors can also be determined. Since both buses 3, 4 are working properly, the controlled input part can be operated both on the basis of the control signals coming from bus 3 and on the basis of the control signals coming from bus 4. Depending on the internal preselection within the controlled input section, the control signals originating from bus 3 or bus 4 are therefore made the basis for the operation of the controlled input section and data are input into bus 3 or bus 4 for monitoring purposes.

- Bus 3 is not working properly, Bus 4 is working properly.

The transceiver 10 receives correct control signals from the bus 4 through the bus input 2 and forwards them to the serial control input 9 of the microprocessor 6 of the controlled input part. These control signals are from the microprocessor

6 analyzed and, since the bus 4 is working properly, determined as correct.

Transmitter / receiver 7 receives faulty control signals from faulty bus 3 through bus input 1. These faulty control signals pass through the transmitter / receiver

7 downstream universal asynchronous receivers / transmitters 8. Thus, faulty control signals are reached by the digital Control input 5 the microprocessor 6, which analyzes these control signals and detects them as faulty control signals as a result of the plausibility and / or conformity check.

It is decided in the microprocessor 6 that the operation of the controlled input part takes place on the basis of the control signals input by the bus 4 operating properly. Corresponding signals are sent through the output line 11 of the microprocessor 6 to the areas downstream of the controlled input part.

A "caution" signal is output in a suitable form by means of the correctly operating bus 4, by means of which the faulty operation of the bus 3 is indicated. Data used for monitoring purposes are transmitted from the controlled input part to the upstream areas of the control circuit by means of the properly operating bus 4.

- The bus 3 is working properly and the bus 4 is working incorrectly.

Transmitter / receiver 7 receives from bus 3 through the bus input

1 correct control signals and passes them via the asynchronous receiver / transmitter 8 connected to the digital control input 5 of the microprocessor 6; these control signals are subjected to a plausibility and / or conformity check in the microprocessor 6 and, since the bus 3 is working properly, are determined to be error-free or correct.

Transmitter / receiver 10 receives from bus 4 through the bus input

2 faulty control signals that arrive at the serial control input 9 of the microprocessor 6. These control signals are subjected to a plausibility and / or conformity check in the microprocessor 6, the result of which shows that the control signals are faulty. In the microprocessor 6 therefore decided that by the correctly working bus

3 control signals input into the controlled input part are used as a basis for the operation of the controlled input part. Corresponding signals are input by the microprocessor 6 through its output line 11 into the areas downstream of the controlled input part. A "caution" signal is output by the bus 3, by means of which it is indicated that the bus 4 is malfunctioning. Data for monitoring purposes are forced from the control and monitoring circuit upstream from the controlled input part by the correctly operating bus 3 on the bus 3 passed on.

Both bus 3 and bus 4 are not working properly.

The digital control input 5 of the microprocessor 6 receives faulty control signals from the faulty first bus 3 via the asynchronous receiver / transmitter 8, the transmitter / receiver 7 and the bus input 1; The serial control input 9 of the microprocessor 6 receives faulty control signals from the faulty second bus 4 via the transmitter / receiver 10 and the bus input 2. The microprocessor 6 uses the separately performed plausibility and / or conformity checks to determine that both the bus and the bus 3 and the control signals from bus 4 are faulty. The microprocessor 6 therefore ends the signal delivery to the buses 3,

4 and also releases a local control lock designed in a known manner. Neither the faulty control signals originating from bus 3 nor from bus 4 are used as a basis for the operation of the area of the controlled input section downstream of microprocessor 6. Instead, the controlled input part either maintains its previous operating state or else it is based on a predefined condition for the failure of both buses 3, 4. drive state over; in principle, it may be possible to maintain the previous operating state or to switch to the previously determined operating state, it then being possible to make a corresponding internal preselection in the microprocessor 6 as a function of other parameters.

After a predetermined period of time has elapsed, a main unit to which the controlled input part in question is assigned in the monitoring and control circuit issues an ALARM signal which indicates that the controlled input part in question can no longer be controlled by buses 3, 4 .

Suitable, well-coordinated time blocks for the main unit and for the work units are introduced between this main unit and the work units or controlled input parts assigned to it.

If the control signals which are transmitted by the buses 3, 4 are restored or if the buses 3, 4 are working properly again, this situation is detected; the mode of operation of the controlled input part, as described for the case that both the bus 3 and the bus 4 are working properly, is resumed. This always ensures that the controlled input part is operated in the most reliable and safe mode of operation, if this is possible.

Claims

claims

1. Control device for airport lighting systems, e.g. Airport lighting systems, flashing fire systems, obstacle marking and lighting systems, landing lights, identification and other beacons, airport beacons, aircraft safety cable and network systems, individual lighting for the aircraft line, etc., with controlled input parts for regulating the downstream lighting equipment and to even out the downstream Luminous devices supplied current at the control level or in the event of a change in the control level, characterized in that the controlled input parts assigned to the control device can be acted upon by means of two independent separate buses (3, 4) with the content-like control and monitoring signals, that by means of the controlled Input parts a separate plausibility and / or conformity check of the control signals from one bus (3) and the control signals from the other bus (4) can be carried out i st, and that if the non-plausibility and / or non-conformity of the control signals of one (3) or the other bus (4) is determined, the operation of the controlled input parts is based on the control signals of the other (4) or the one bus (3) are.

2. Control device according to claim 1, the controlled input parts of which have a single microprocessor (6) by means of which the separate plausibility and / or conformity check of the control signals input by the buses (3, 4) into the controlled input parts can be carried out.

3. Control device according to claim 2, wherein the microprocessor (6) of the controlled input parts for each bus (3, 4) has a separate control input (5, 9).

4. Control device according to claim 3, wherein the microprocessor (6) of the controlled input parts for the one bus

(3) a digital control input (5) and for the other bus

(4) has a serial control input (9).

5. Control device according to claim 3 or 4, wherein the control inputs (5, 9) of the microprocessor (6) of the g input parts are dual and isolated from each other, from earth and from the rest of the microprocessor (6).

6. Control device according to claim 4 or 5, in which the digital control input (5) of the microprocessor (6) is preceded by an asynchronous receiver / transmitter (8), the output signal of which is fed to the digital control input (5) of the microprocessors (6) and which is preceded by a transmitter / receiver (7) which is galvanically isolated, works dual and is connected to a first bus input (1) assigned to a bus (3).

7. Control device according to one of claims 4 to 6, wherein the serial control input (9) of the microprocessor (6) is preceded by a further transmitter / receiver (10), which is galvanically isolated, works dual and on one the other bus (4 ) assigned second bus input (2) is connected.

8. Control device according to claim 7, in which the microprocessor (6), the asynchronous receiver / transmitter (8), the two transmitters / receivers (7, 10) and the two bus inputs (1, 2) are combined in a printed circuit board.

9. Control device according to one of claims 1 to 8, the controlled input parts of which can be reset to the operating state which is provided for in the event that both buses (3, 4) operate fault-free when a fault is eliminated, the control signals of one (3) or the other bus (4) then being used as the basis for the operation of the controlled input part.

10. Control device according to one of claims 1 to 9, the controlled input parts of which are constructed as work units of a control and monitoring circuit having a plurality of such work units, a main unit being installed on a substation of the control and monitoring circuit, by means of which the two buses (3 , 4) the individual

Working units can be called up at predefinable times for status information and control.

11. Control device according to one of claims 1 to 10, whose controlled input parts are components of a control and

Are monitoring circuit, the components upstream of the controlled input parts are designed redundantly.

12. Control device according to one of claims 1 to 11, in which as field buses (3, 4) conventional field buses, e.g. MOD buses,

PROFI buses, CAN buses or the like. can be used.

13. Control device according to one of claims 1 to 12, the controlled input parts of which have simple connectors as control and monitoring inputs.

14. Control device according to one of claims 1 to 13, the controlled input parts of which can be combined with different consumers.

15. Control device according to one of claims 1 to 14, by means of whose controlled input parts different downstream consumers provided in a local area can be monitored and regulated.