EP0453643A1 - Diagnostic method for decentralized light signalling systems - Google Patents

Abstract

A light signalling system has a signal safeguarding and evaluation module in a node control unit and a plurality of peripheral lamp switches and sensors designated as POSITIVE modules, pedestrian pushbuttons, vehicle detectors and associated data transmitters and receivers, as well as transformers and rectifiers for associated signal generators with signalling lamps on respective signalling poles, it being possible to connect the node control unit to the modules using a power and data line. With a mains-independent diagnosis unit which is provided for this purpose, the individual modules and the lamps, connected thereto, and other elements can be completely tested directly on the signalling pole with respect to their operativeness and the correct wiring, connection to the node control unit not being required. After the connection of the individual modules to the node control unit, the connection from the node control unit to the modules and the amber flashing function for the roads for which forward travel is not authorised is tested, the diagnosis unit being connected to the node control unit and the addresses of all the modules being identified and displayed. Afterwards, the individual modules are tested with reference to a position plan by entering module type and address.

Description

The invention relates to a diagnostic method for decentralized traffic signal systems for road traffic with a signal protection and evaluation module in a node control unit and with several peripheral modules called PLUS modules and sensors, pedestrian push buttons, vehicle detectors and associated data transmitters and receivers, and with transformers and Rectifiers for associated signal generators with signal lamps on respective signal masts, the node control device being connectable to the modules with an energy and data line.

For light signal systems with decentralized signal lamp switches, a method for signal protection is described in German patent application P 39 10 864.3, the light signal system having features as shown in the preamble of claim 1. The diagnostic method according to the invention is provided for such light signal systems.

Before a traffic light system can be put into operation, it must be checked for functionality and correct wiring. The signal paths from the lamp switch to the lamp must also be checked. So far, when checking for correct wiring and function of the signal lamps, the signal transmitters had to be covered, the cover having a small hole for each signal transmitter chamber. The node control device must also be connected. The individual lamps were switched on from the control unit. Another man checked whether the lamp that was now switched on was actually lit by looking through the hole in the signaling lamp in question and a correct lighting up of the man on the control unit announced. Then the covers had to be removed. Such a check of the light signal system is laborious and extremely complex, which also leads to very high maintenance costs.

The object of the invention is to avoid the disadvantages described above and to provide a diagnostic method for decentralized light signal systems which allows a reliable test which can be carried out with little expenditure of time.

This object is achieved in a decentralized light signal system described at the outset with the characterizing features of claim 1 and claim 7.

In the diagnostic method according to the invention, the individual modules and the lamps and other elements connected to them are completely checked for functionality and correct wiring directly on the signal mast using a dedicated, network-independent diagnostic device. A connection from the individual modules to the node control device is not required. This includes checking the function of the modules, the correctness of the addresses according to the site plan, the function and the location of the lamps. Since the diagnostic device is battery operated, no mains voltage is required, so that the node control device does not have to be connected yet. The signal generators do not have to be covered, because the man who carries out the test on the signal mast can immediately see the right signal generator lighting up.

The method according to the invention has the advantage that the effort for checking the signal paths and testing the modules is considerably reduced and that troubleshooting is simplified. The module to be tested is expediently connected to the diagnostic device and the type of module and the corresponding addresses are entered via a keyboard according to a predetermined site plan. The test process is then started and the test result is shown and acknowledged on a display of the diagnostic device. This way it will also be the turn after all the lamps connected to a module have been tested for their correct connection and functionality, the lamp under test lighting up briefly, for example for 250 msec. The signaling chamber is generally open so that the brief flashing can be observed well. At the same time, testing the lamp on the diagnostic device indicates that the lamp is controlled correctly and the switching information is correctly reported. Further details and advantages result from the subclaims and the description.

A particular advantage of the diagnostic method according to the invention is that after the module test has been completed, the connection to the node control device is established and the connection and the data transmission from the control device to the individual modules can then be tested on the control device. Since the data supply for the signal protection in the node control device has already been checked in the factory, the light signal system can advantageously be put into operation after this test without risk.

With the diagnostic method according to the invention, the functionality of the system can be fully tested with just one man before the system is started up or maintenance is carried out.

Before commissioning, the PLUS module test is carried out on the mast immediately after installation. The modules to be tested are either assigned to the lamp switches and sensors, the pedestrian push buttons or the vehicle detectors. With the aid of the diagnostic device provided, the modules and the lamps connected to them are completely checked. This includes checking the function of the modules, the correctness of the address according to the site plan, the function and the location of the lamps. The diagnostic device is expediently portable, splash-proof and battery-operated. This enables the modules and the lamps and elements connected to them to be tested during assembly when the mains voltage is not connected. The diagnostic device is connected to a module or to the data line of the node control device via a longer, flexible cable, so that a convenient location for the diagnosis can be found even in exposed installation locations.

The diagnostic device is operated, for example, menu-driven via a keyboard and a display. The type of test, the type of module, the addresses and the lamps to be tested are selected and the test procedure is triggered by pressing a start button. After the test has been completed, the test result is shown on the display and acknowledged acoustically. In the diagnostic method according to the invention, additional tests can be carried out automatically, invisibly for the examiner, for example whether a module only reacts to its preset address and not additionally to others. In addition, it is tested whether the sum check of the telegram traffic is working properly. The entire hardware is therefore largely tested with this diagnostic procedure. The diagnostic device itself is monitored so that it is ensured that all of these tests can also be carried out. The level of the command and message telegrams is also measured in all of these test procedures. It is also checked whether there is a terminating resistor in the data line or not, if so, whether it has the required value. The results of the level measurement and the terminating resistance measurements are shown on the display.

When the modules are checked, which is carried out directly on the signal mast, the functionality of the modules is first tested. The lamp connector does not have to be yet be plugged in. For the lamp test, the lamp connector is plugged in when the signaling chamber is open. The lamps now connected to the module are now tested in sequence by selecting a lamp on the diagnostic device and triggering the test process by pressing a button. The lamp to be tested lights up once for 250 msec. on. The installation of the lamp in the correct chamber can thus be checked. At the same time, it is tested whether the module controls the lamp correctly and reports the switching information.

For the modules for pedestrian push buttons, in addition to the lamp test, the display of the push button messages can be selected and tested. When the vehicle detectors are checked, the detector messages are tested and displayed. After completing the test of all modules, the plugs of the data line and the power supply are connected by the control unit and the open signal transmitters are closed. A test for data transmission from the control unit to the individual modules and vice versa can then be carried out.

In this so-called line test, a line is checked that can have up to 15 modules. For this purpose, the diagnostic device is plugged into the node control device, the data connection to the actual control device being interrupted by opening, for example, a disconnect terminal. With the diagnostic procedure now carried out, the data traffic to the individual modules of a line takes place only through the diagnostic device. In this test, the addresses of all modules connected to a line are first determined. These addresses, determined and determined by the diagnostic device, can now be checked using the site plan. Then the data transmission to the individual modules is diagnosed. The transmission and reception levels are displayed. It is also checked for the correct termination of the line with a correct terminating resistor. With this diagnostic procedure tests are also carried out to determine whether the roads with no right of way have the correct yellow flashing function, for example if the control electronics of the node device fail. Since the corresponding lamps have already been checked beforehand, it is only necessary to test whether the necessary feedback for the yellow flashing is displayed on the diagnostic device.

The diagnostic procedure also allows listening in when the system is fully operational. The diagnostic device is connected to the node control unit. The messages from the loop detectors, the messages from the pedestrian push button modules can be displayed, the respective levels of the module telegrams are measured and the activated modules are displayed in terms of addresses.

With the diagnostic method according to the invention, a very reliable and quick check of the light signal system before commissioning, for maintenance or even during operation is possible.

Claims (10)

Diagnostic procedures for decentralized traffic light systems for road traffic with a signal protection and evaluation module in a node control unit and with several peripheral light switches and sensors, called PLUS modules, pedestrian push buttons, vehicle detectors and associated data transmitters and receivers, as well as with transformers and rectifiers for the associated ones Signal generator with signal lamps on respective signal masts, the node control device being connectable to the modules with an energy and data line,
characterized in that with a dedicated, network-independent diagnostic device the individual modules and the lamps and other elements connected to them are completely checked for functionality and correct wiring directly on the signal mast, the connection to the node control device being unnecessary. Diagnostic method according to claim 1,
characterized in that the module to be tested is connected to the diagnostic device, that the type of module, the corresponding addresses are entered according to a predetermined site plan and the test process is started via a keyboard, the test result being shown and acknowledged on a display of the diagnostic device . Diagnostic method according to claim 1 or 2,
characterized in that the diagnostic device is tested in sequence with all lamps belonging to a module for their correct connection and their functionality, the tested lamp lighting up briefly and at the same time indicating that the module has actuated the lamp correctly and has correctly reported the switching information . Diagnostic method according to claim 1 or 2,
characterized in that the diagnostic device controls the reaction of the module to foreign addresses. Diagnostic method according to claim 1 or 2,
characterized in that the respective modules for pedestrian push button, push button display and associated lamps are tested with the diagnostic device. Diagnostic method according to claim 1 or 2,
characterized in that the respective modules for vehicle detectors are tested with the diagnostic device and the corresponding data messages are displayed. Diagnostic method according to the preamble of claim 1,
characterized in that after the connection of the individual modules to the node control device, the connection of the node control device to the modules and the yellow flashing function for the streets not authorized to drive in is checked, the diagnostic device being connected to the node control device and the addresses of all of them Modules are determined and displayed, and that after checking the determined addresses using a site plan, the individual modules are tested by entering the module type and address. Diagnostic method according to claim 7,
characterized in that the termination of the connecting line is measured with the diagnostic device and a deviation from the predetermined value is displayed. Diagnostic method according to claim 7,
characterized in that the traffic between the node control device and the individual modules is checked with the diagnostic device in the light signal system in operation. Diagnostic method according to one of the preceding claims,
characterized in that the levels of the command and report telegrams are measured in the various test procedures and levels which are too low are displayed accordingly.