BG65841B1 - Led signal lamps and method for reliable control of led signal lamps - Google Patents

Abstract

The intelligent LED signal lamp for open-air signaling in a railway signaling equipment with LED diodes (4) is divided into three independent LED sections (9), the light from two only of the LED sections (9) being sufficient to satisfy the respective standards concerning the optical characteristics of such lamps. The functionality of each LED diode (4) is checked in three independent ways. The functionality is checked of the electronics for management and control of each section (9) of the LED signal lamp, as well as the functionality of the power supply source (11), so as to detect all troubles and avoid any malfunction of the LED signal lamp, the basic safety principles being observed concerning the permissive signal and the warning signal.

Description

Technical field

The invention relates to outdoor LED signaling lamps, which are applicable in railway signaling, and are especially intended for the security equipment of railway crossings and / or stations and signaling equipment on lines, the LEDs being divided into sections comprising blocks for control and control and for power supply.

In addition, the invention relates to a method for the reliable control of LED signal lamps, during which the functionality of the LED is monitored and the functionality of the electronics to control and control each section of the LED signal lamp is controlled.

BACKGROUND OF THE INVENTION

At present, outdoor signaling lamps used in Ceske drahy (Czech Railways) are in most cases incandescent lamps. Incandescent lamps are unsuitable for use in security equipment because of their low reliability; due to their actual construction and the principle of light. There are two ways to eliminate this feature and to increase the reliability of rail operations.

Use of double-wire bulbs in railway crossing security equipment, i. in the warning boards. When the main bulb is burned, the spare is automatically switched on.

In other areas of outdoor signaling, i. for signals, in the event of a single bulb burning, the low pass signal principle is used.

The relatively high energy consumption of incandescent lamps is another important consideration when using these light sources.

The control and all logic for the control of the incandescent lamps are located mainly outside the rooms for the signal and warning panels. Suitable electronics are created through relay circuits for older types of equipment, or through a combination of processor systems incorporating a contact or contactless interface for newer types. When verifying that the light is on, the light bulb monitoring principle is used. The warning panels also use optical sensors located in the lamps, the output of which gives information about the light of the bulbs. Relay or processor logic checks the operation of the lamps on the basis of this output information and, when the lamp wires are burned, switches on the backup wire of the respective warning light bulb or illuminates the low-pass signal bulb.

The electric power supply of incandescent lamps is provided by 230V / 50HZ AC due to the minimum loss of current over long distances. The current is then transformed into the supply voltage 12V / 20W of the signal lamps with the help of a transformer located at or near the semaphore.

The nominal power supply of incandescent lamps in the warning boards is provided by the control of the supply voltage - relay or processor, which controls the warning panels. This power supply is DC 24 V. The dual-wire bulbs on the warning panels are 2 x 12V, 20W.

As a result of the aforementioned reasons, the first lamps with integrated LEDs began to appear in Ceske drahy. So far, this is only observed in speed indicators that represent a number (symbol) or line (symbol). The on / off switching of the light is controlled by switching the power on or off. Its control is carried out by a single current relay, the exclusion of which indicates the presence of insufficient current - unsatisfactory condition of the lamp during its illumination. The principle connection of LEDs in the design of this lamp is the classic series parallel connection with direct interplay of individual LEDs. diodes.

Among foreign companies engaged in the production of LED lamps for rail

65841 Bl signaling equipment are "Alstom", "Ansaldo", "Safetran", "Westinghouse", "Percept" and others.

In addition, these lamps typically use a combination of sequential parallel coupling of individual LEDs, split by some manufacturers into two parallel sections with independent power and control. To ensure maximum compatibility with incandescent lamps, they are controlled by turning on the power while keeping the lamp on and off with the lamp off. The supply voltage of these lamps varies from manufacturer to manufacturer, and depending on the type of lamp, the supply current may be constant or variable. The supply voltage of these LED lamps, and therefore the control itself, is usually two-wire, with no duplicate option.

The control of the lighting of LED lamps in the products of these foreign companies is usually resolved by checking the total current consumed by the low-sensitivity lamp; resulting in a malfunction of a larger number of LEDs. The reliability of the LEDs themselves is of particular importance here. By connecting two parallel sections of LEDs powered by two independent sources, each of these sources is naturally malfunctioned.

A common feature of the above-mentioned control and control systems for LED lamps is undoubtedly their higher reliability compared to incandescent lamps, based on the common and physically determined fact that a light bulb is far less reliable than a larger number of LEDs, in this case about 200 diodes included in a single lamp. The increase in reliability, performance required, compared to incandescent lamps, has not been observed. The system is simply a 1 in 1 ("lool") system with limited ability to monitor the LED's current through power consumption. Moreover, in these decisions, the access and diagnosis systems are located in the remote location using only the principle of control by contacting the lights or contactless control of the remote switching on of the lights. This requires a large amount of cables, which seriously affects the overall value of the signaling equipment.

For example, in EP 132 4641, the applicant Westinghouse Brake & Signal Holdings Ltd., United Kingdom, has solved the task of electrical configuration and current monitoring in the LED of the signaling device. The signal lamp (semaphore), intended principally for the direct replacement of an incandescent lamp in a signaling device, in terms of power and control, shall consist of at least two separate LEDs, with their own control circuits connected in parallel. . In parallel to the power supply of the lamp, an automatic ballast resistor, sized so that the current passing through these LED fields, causes the LED lamp to draw power, such as a filament lamp. Checking the functionality of the current relay lamp is the same as for a filament lamp. The automatic circuit of the ballast resistor always includes a pair of optical connectors for one LED field. The inconsistent action of the LED fields, i. when one or more LED fields are off, it is rated by the independent relay as an "unsettled alarm". The verification in the scheme is not performed under the “safe malfunction” scheme. So the main role here falls to the observer, for example the engineer, who checks the randomly illuminated LED field. For this reason, the individual LED fields must be positioned in the lamp in such a way that when any of them is damaged, it can be seen with the naked eye.

Valuable in this solution is the ability to simply replace an existing incandescent lamp with an LED signal lamp without the need for a redesign of the signal lamp control and control circuit. The principle of this solution is based on the same consumption of the LED signal lamp and the incandescent lamp, i. no energy is saved. In this invention, the control circuit is less reliable than the circuit used to check the illumination of incandescent lamps. Human factor based reliability because the control scheme used

65841 LED illumination test tub is not of the type "safe malfunction", ie. circuit with own safety. Detection of an unlit field by the LED light is done by the engineer only through visual observation. In the event of a faulty LED field, the optical parameters of the signal lamp are obviously not fulfilled.

The Czech device according to model 14 134 of the owner of Betamont sro, Czech Republic describes the connection of the electronic control circuit in the warning boards of the railway crossing system, which solves the task of supplying and checking the lights in the warning boards, consisting of a matrix of illuminated LEDs. diodes. The matrix of illuminated LEDs is divided into two independent consecutive branches, each of which is connected to an independent power source. The verification of the LEDs' illumination is performed by monitoring the current flowing through the serial branch of the LEDs by a reliable measuring circuit. The current in each branch is monitored individually. Checking the luminous current is supplemented by a voltage check between the two LED sections performed by another measuring circuit. The current checking of the two LED sectors and the voltage check are jointly performed in a reliable intersection circuit whose output static signal is intended to activate the resultant safety relay of Group I. An output static signal is only generated when all input signals are triggered by the output signals of the reliable measurement circuits, ie. by checking the LED currents in both sectors and checking the voltage.

In addition, this solution makes it possible to replace the incandescent lamp with an LED lamp without any changes to the control panels of the warning panel, except for minor changes to the control circuit which check that the warning lamps are illuminated. .

The downside of this solution is the low alert threshold. The first failed LED lamp is already a malfunction. Another drawback is the static output control signal at a time when both warning lamps are on, leading to low information reliability. This solution applies only to the warning lamps, the supply voltage being only 12V and the permissible voltage range not defined.

JP 2000172986 Owner Nippon Signal Co. Ltd., Japan, describes the solution of a fault detector in signal lamps that can detect faults, ie. disconnection of LEDs and dimming of their lamps as a result of aging. The LED signaling lamps are connected in series in parallel. Each consecutive branch has an LED to monitor the light intensity of the signal. This tracking LED is from the same production series as the signal LED. The following LED is located on the same base as the signal LEDs. The luminous intensity of the following LED is scanned, through an optical connector, from the verification circuit. Assuming that due to the same production technology, all LEDs age the same and that their luminous intensity decreases over time in the same way, the luminous intensity of the signal LEDs is determined or rather estimated, and thus the maximum value of their luminous intensity is determined. . If any of the group LEDs fails, the follow-up LED goes out and the test circuit registers it. The outputs from the verification circuits of all sectors with groups of LEDs are fed into one signal block, the output of which is fed to the signal relay.

This applies only to the control of the supply current of several branches of LEDs, which determines whether current is flowing or not. The decrease in the intensity of the LED lamp as a result of its aging is also estimated. The proposed scheme does not answer the question of short-circuiting the diode (s) from the clone of each group and does not increase the lamp availability. However, the scheme for controlling the glow of the lamp diodes is not resolved on the principle of "safe malfunction".

SUMMARY OF THE INVENTION

The disadvantages mentioned above are the percentages

65841 Bl transients or substantially reduced by the intelligent LED signal lamp according to the present invention, the essence of which is that the LED signal lamp is divided into three independent and electrically independent sections of the LED diode, in which even the dim light only of two sections is sufficient to comply with the relevant standards regarding the optical characteristics of the lamps, whilst maintaining the reliability of switching signals and warning signals. Each of the three LED sections has an independent wiring diagram, each LED section contains three independent control units, each output of the independent control unit is fed to the control circuit of another LED section and each control circuit is provided with a disconnecting element with power to adjacent LED sections.

The main advantage of this invention is that this intelligent LED signal lamp operates on the principle of the system "2O3," ie. two out of three.

According to the present invention, the advantages of this smart LED signal lamp are the following:

- it enhances the readiness of external light signaling in railway transport (A = 0.999999), both with regard to road and motorway users in the interlocking (security) equipment of railway crossings, and with regard to railway transport in stations, lines and railway crossing security equipment;

- it enhances the functional reliability of light signals and warning panels;

- it limits the cost of fully wiring security equipment;

- it limits the cost of maintaining light signals and warning panels;

- Enabling modern control systems for security equipment;

- the reliability of the control, checking and control of the luminance of each individual lamp of the main systems is increased.

The advantage is that at least one current control unit that allows the LEDs to be checked in the easiest way is an independent control unit. The voltage control unit or optical control unit may also be an independent control unit.

At least one LED control and monitoring circuit, which represents the optimal connection of the other control and control functions in the control of the LEDs in a single circuit, may be an independent control unit.

The independent control unit can also be created by two LED control units and one LED control and monitoring circuit, which is an appropriate configuration for LED traffic lights.

It is advisable to have a control processor that integrates the control and evaluation functions of all control elements into one control circuit. The control circuit may also consist of discrete semiconductor circuits or relay circuits.

In one particular successful configuration, tested for a long time, the output signal from the independent current control unit is output to the control processor of the first adjacent LED section, the output signal from the second independent current control block is fed to the second adjacent LED section, and the circuit to control and monitor the LED function performs independent verification and independent evaluation of the status of all LEDs in the lamp.

The LED power cut-off unit is the power cut-off element of the LED sections. This interrupting element does not allow confusing signal lights to be displayed, which can lead to a hazardous road situation, for example spontaneous illumination of a multi-direction switch signal.

Each of the three sections is provided with a bidirectional data communication link to the main system (upper configuration), which is used for command transmission and diagnostic information.

Duplicate physical communication link to transmit data with concurrent active state, increasing readiness

65841 Bl

LED lamps are an advantage.

Each LED section has a control circuit, provided with a two-way side line, through which the control circuits of the other two LED sections are connected.

The power source is connected to two power systems, which ensures the stability of the LED signal lamps. That is; The LED signal lamp is adapted to be powered by two independent external power systems, which increases the reliability of the equipment.

According to the present invention, the method of reliably controlling this smart LED beacon consists in controlling the LEDs, separated into three separate electrically independent sections, continuously and simultaneously, by three independent control units, and at the same time by continuously checking the functionality of the control and control electronics of each section of the LED signal lamp. These checks identify any faults that have occurred in any of the circuits (including, the LED tell-tale control circuit, the LED tell-tale control circuit, the power circuit and the LED circuit). The malfunction is then reported to the main indication system. The LED signal lamp fully retains its functionality in accordance with the relevant standards, complying with the safety principles of the switch signal and the warning signal.

According to the invention, the main advantage of this method is that the low light of only two sections is sufficient to satisfy the relevant norms with respect to the optical characteristics of the LED tell-tale, so that an accidental malfunction does not lead to a loss of functionality of the entire LED warning light. The division of LEDs into three electrically independent sections ensures the independence of the sections. Continuous and simultaneous inspection of the LED is a guarantee for the safe monitoring of the LED signal lamp. A malfunction found in one of the sections is reported to the main system where it is identified and evaluated. It is essential that a fault in one section of the LEDs does not cause the entire lamp to malfunction.

In order to maintain the independence of the operation information of each LED, it is desirable that the operation of the LEDs in each section be controlled and controlled by an independent control circuit based on information from the main system and diagnostic information from that section from both adjacent sections.

For the consistent and guaranteed safe operation of the LED, it is desirable that the control circuit receive arbitrary information on the operation of the LEDs from each of the three sections from three independent sources, namely: from the control and monitoring circuit of the LEDs from the respective section, through the two-way side link from the control circuit of each of the other two sections, and from the two-way side connection to the control circuit of the third remaining section. Each control circuit of each random section receives information transmitted from the bidirectional side link for the operation of the LEDs in the other two sections of the current control unit in those adjacent sections. The performance of each LED is evaluated independently of all three control circuits, the results being exchanged through a two-way side link.

Regardless of the information from the main system, in case of failure of one section of the LED signal lamp of the switch signal, and even if there is a discrepancy in the information from the control circuits of the other two sections, these control circuits interrupt the supply of LEDs from the section with a malfunction. This makes it possible to turn off the power of each section with LEDs from the control circuit of an adjacent section without the logical coordination of the other sections so that no unwanted illumination of even one section of the LED of the switch signal is obtained.

Regardless of the information from the main system, in the event of failure of one of the sections of the LED warning light of the warning signal, after coordination of the information from the control circuits of the other two sections, these control circuits interrupt the supply of LEDs from the section with the

65841 Bl malfunction. In case of unintended illumination of one section of the LED warning lamp of the warning signal, the switching off of the LEDs from this section is triggered after the control circuits of the other sections are coordinated. The possibility of switching off even one section of LEDs as a result of a fault in a control circuit is excluded.

The control circuit is connected to the main system bidirectionally, mainly through a reliable data link, which is physically duplicated with a parallel link for transmitting the active state data. This ensures that the necessary signals are transmitted, even when one of the communication lines fails.

Each section of the LED beacon is powered separately to maintain the “2oo3” system, ie. system two out of three.

The power source creates three separate power circuits for the LED signal section sections of two input power systems, with the failure of each of the two input power systems causing only one of the three independent power circuits of the LED lamp sections to malfunction, which is the optimal solution for the choice of the system.

Explanation of the annexed figures

The following is a detailed exemplary description of the invention, illustrated with the accompanying drawings, in which:

Figure 1 shows a block diagram of one section of an LED signal lamp;

Figure 2 is a block diagram of an LED signal lamp.

Embodiments of the invention

Figure 1 shows a schematic block diagram of one of the three sections 9 of the smart LED signal lamp, with power supply 1 of the LEDs 4, and with two sequentially configured current control units 3 in the LEDs. The output signals 2 of the current control units 3 are transmitted to the adjacent LED section 9 (Fig. 2). The control of the LEDs 4 of the LED section 9 is provided by the control and control circuit 5 which is connected to the control processor 7. Through a communication line 6 through which the output signals from the control units 3 are transmitted to the LEDs, the control circuit, by means of the control processor 7, triggers a power outage from block 13 of the adjacent section 9, which is composed of LEDs. The operation of the entire section 9 of the LEDs is controlled by a bidirectional communication link 8 to the main system.

Figure 2 shows the connection of the three sections 9. The sections 9 are connected through the lateral bidirectional communication links 6, as well as through the outputs 2 of the control units of the LEDs, and further - through the unit 13 for controlling the power failure. of LEDs. The power circuits 12 of the LED sections 9 are created in the power unit 11 of the two independent power systems 10.

All LEDs 4 of one LED signal lamp are divided into three independent sections 9 of the LEDs, and are positioned in such a way that the illumination of only two of these three sections 9 of the LEDs ensures that all requirements complying with the standards for the optical characteristics of the lamp. The LEDs 4 are controlled by the circuits 5 for the control and control of the LEDs, which actuate the mutually independent power supply 1 of the sections 9 of the LEDs. interruption or short circuit of any LED 4 does not in any way affect the illumination of the remaining LEDs 4, as well as their optical parameters and their reliability. In addition, these LED control circuits 5 make it possible to monitor their operation. Any malfunction of a connected LED 4, i. an interruption and even a short circuit is established and this information is transmitted to the control processor 7. Each section 9 of the LED lamp has its own independent control processor 7. The independent control processor 7 processes the command information coming from the main system, for example, " turn on the light, "" turn on the light "," turn off the light ", etc. At the same time, the independent control processor

65841 Bl further processes information from circuits 5 for the control and control of LEDs from "its" section 9. At the same time, the independent control processor 7 processes the information received through the side communication links 6 between the three control processors 7 as well as the information from the outputs 2 of the control units 3 of the current in the LEDs of the two adjacent sections 9 with the LEDs. The current control units 3 in the LEDs scan the total current consumed by the respective section 9 with the LEDs. The processing of all this information leads to a clear and definite determination of the information on the operation and immediate state of each individual LED 4, of each separate control and monitoring circuit 5 and of each control processor 7.

Each control processor 7 has the ability to permanently interrupt the power supply of the LEDs 4 from the adjacent sections 9 through a power supply interruption unit 13 to the LEDs 4 which emit a switch signal independently of the other control processors 7, such that the corresponding LED section 9 the switch signal light does not illuminate at the moment it should be off due to a malfunction of part of the decision-making or access equipment including the control processors 7 and the control and monitoring circuits 5 the performance of LED diodes.

The two control processors 7 are triggered after their matching (ie, after their logical matching) to permanently interrupt the power supply of the LEDs 4 of the third section 9, which emit a warning signal through the power supply interruption unit 13 of the LEDs 4, so not to exclude more than one section 9 of the LEDs emitting the warning signal due to a malfunction of the decision-making or access equipment including the control processors 7 and the circuits 5 for controlling and monitoring the operation of the LED s.

The power supply of the individual sections 9 of the LED lamp, including the control and monitoring electronics, is done separately, ie. the output of the power source unit 11 are three independent power supply circuits 12 of the LED sections 9. The two input voltages of the power supply systems 10, i. different or unified power systems, including any combination of alternating current and / or DC elements, as necessary, are converted, within power supply 11, into the three input power circuits 12 of LED sections 9 so that the interruption in the supply of the input voltage of any of the power systems 10 causes only 1/3 of the input power circuits 12 of the LED sections 9 to malfunction, thus complying with all requirements regarding the optical performance standards of a given so light. The operation of the individual required power supply circuits 11 is continuously checked by the control processors 7 of the individual LED sections 9.

Command information received through communication link 8 from the main system (eg "turn on the light", "turn on the light", "turn off the light", etc.) and at the same time diagnostic information sent to the higher system via the link E (for example, "light is on", "light is off", "malfunctioning state", "malfunction" and its type, etc.) is transmitted exclusively through a communication link for data transmission 8. This connection 8 is physically duplicated through two independent links, k both are active at the same time.

The specific example configuration is one of many possible. Many other configurations are possible within the scope of the claims.

Use of the invention

Red and white LED warning lamps for warning signs in railway level crossing equipment.

Red, yellow, green, blue and white LED warning lights for the basic signals (i.e., entry, departure, on-the-road, block section and safety signals), basic warning signals, basic repeating warning signals, maneuver signals, repetitive maneuver signals, camshaft signals, recurrent camshaft signals and baffle signals

65841 Bl station and line signaling equipment.

List of characters used

LED Power Supply Unit (4) Output of Current Control Units (3) of LED Diodes of LED Current Control Unit

LEDs circuits for control and function control of LEDs side communication line control processor communication line with main system section with LEDs power supply systems of the power supply unit (11) power supply unit with electric current power supply scheme of the LED section (9) power supply unit of adjacent LED section (9).

Claims (19)

Claims 1. Outdoor LED signaling lamps for railway signaling lamps, designed in particular for interlocking railway level crossing equipment and / or for signaling equipment at stations and along lines in which the LEDs (4) are divided into sections (9) comprising control and control circuits and a power supply (11), characterized in that it is divided into three independent and electrically independent sections (9) by the LEDs (4), each of the three LED sections (9) having an independent circuit (12) and each of the LED sections (9) contains three independent circuits control unit, wherein each of the outputs of the independent control units is connected to a different LED section control circuit and each LED section (9) is provided with a power disconnecting element (1) at each adjacent section. LED signal lamp according to claim 1, characterized in that at least one control unit (3) of the current in the LEDs is an independent control unit. LED signal lamp according to claim 1, characterized in that at least one circuit (5) for controlling and monitoring the operation of the LEDs is an independent control unit. LED signal lamp according to claim 1, characterized in that the control circuit is a control processor (7). LED signal lamp according to claim 1, characterized in that the interrupting power supply element (1) is a power interruption unit (13) for each of the adjacent LED sections (9) which is connected to the control circuits on both adjacent LED sections (9). LED signal lamp according to claim 1, characterized in that each LED section (9) has its own control circuit provided with a bidirectional communication link for transmitting data (8) to the main system. An LED signal lamp according to claim 6, characterized in that the data link (8) is physically duplicated with a parallel active data transmission link. LED signal lamp according to claim 1, characterized in that each section (9) of the LED lamp has a control circuit provided with a bidirectional communication side link (6) for connection to the control circuits of the other two LED sections (9) ). LED signal lamp according to claim 1, characterized in that the power supply unit (11) of the wiring diagram is connected to two power systems (10). An LED signal lamp according to claim 2 or 3, characterized in that it has three independent control units composed of the two current control units (3) in the LEDs; and from one circuit (5) for controlling and controlling the function of the LEDs. LED signal lamp according to claim 10, characterized in that one of the independent current control units (3) in the LEDs has its own output (2) which is connected to the control circuit of one of the adjacent LED sections (9) ), wherein the outputs (2) of the other independent current control units (3) are connected to the control circuit of the second adjacent LED section (9) and the circuit (5) to control and monitor the operation of the LEDs for control of LEDs (4) from the real LED section (9), is connected to the control circuit of the real LED section (9) both outputs (2) of the control units 65841 Bl currents of the other two LED sections (9) are connected to this control circuit. LED signal lamp according to claim 1, characterized in that the interrupting element of the power supply unit (1) of the LEDs (4) is a power supply unit (13) for interrupting the supply of the LEDs. 13. The method for reliable control of the LED signal lamp according to claims 1 to 12, during which the functionality of the LEDs (4) and the control of the electronics operation for controlling and controlling each section of the LED lamp characterized by by checking the functionality of the LED signal lamp by checking each circuit of the LEDs (4) continuously and simultaneously by three independent control units, at the same time by continuously checking the operation of the control electronics ection and control of each section, simultaneously by continuously checking the operation of the control and control electronics of each section (9) of the LED signal lamp; these checks identify any malfunction that has occurred in any of the circuits, including the LED tell-tale control circuit, the LED tell-tale control unit circuit, the power supply circuit (11), and The LEDs (4) are then transmitted to the main indication system, while the LED lamp remains fully functional. Method according to claim 13, characterized in that the operation of the LEDs (4) in each section (9) is controlled and controlled by a separate control circuit based on the information from the main system and the diagnostic information from one section (9) both sections (9). A method according to claim 14, characterized in that the control circuit receives arbitrarily the operation information of each LED (4) from each section (9) of the three sections (9) from three independent sources, namely: of circuit (5) for controlling and monitoring the function of the LEDs of this section (9); via the two-way lateral communication line (6) of the control circuit of any section (9) of the other two LED sections (9); via the bidirectional lateral communication link (6) from the control circuit of the remaining last third LED section (9), each control circuit of each section (9) receiving information transmitted via the bidirectional lateral link (6) for the operation of the LEDs (4) from the other two LED sections (9) of the control units (3) of the adjacent sections (9). Method according to claim 13, characterized in that, regardless of the information from the main system, in case of failure of one section (9) of the LED signal lamp for the switch signal, or even in the absence of coordination of the information of the control circuits of the other two sections (9), these control circuits interrupt the power supply (1) of the LEDs (4) for the faulty section (9). A method according to claim 13, characterized in that, regardless of the information from the main system, in case of failure of one section (9) of the LED warning lamp, after coordination of the information from the control circuits of the other two sections ( 9), these control circuits interrupt the power supply (1) of the section (9) of the LEDs (4) with the fault detected. A method according to claim 13, characterized in that the control circuit communicates to the main system in two ways exclusively through a reliable two-way communication communication link (8), which is preferentially physically duplicated by a parallel active data transmission link . A method according to claim 13, characterized in that the power source (11) with electrical current has three separate power circuits (12) in sections (9) of the LED signal lamp of the two input power systems (10), such as a malfunction of one of the two input power systems (10) causes only one of the three independent power circuits (12) of the LED (section) sections (9) to malfunction, while the LED signal lamp remains fully functional.