EP0966183A1 - Lamp and method of operating such lamp - Google Patents

Abstract

The light source (1) has an interface (2) which measures parameters and provides an input command and control. The microprocessor (14) has an autonomous clock input (19) and a nonvolatile read/write memory. Information about the lamp is memorized, measurements are taken and the light source input adjusted to retain optimum operation. Maintenance information is held in memory and information on the light exchanged with a central unit.

Description

The present invention relates to a lamp and a method of operation of such a lamp in which light is produced by a Electric power. It has applications in lighting or signaling.

Lighting or signaling devices in which light is produced by an electric current are known since the XIXth century. Various physical means are used to produce light. Through example, by Joule effect for the filament lamp, electronic phenomena for gas discharge tubes, electronic recombinations in the semiconductor devices such as light emitting diodes. Each of these means and therefore devices using them have characteristics different which means that they are chosen according to the intended application. These characteristics are, for example, the service life which can vary depending on conditions of use, efficiency and light intensity which can also decrease over time.

In some applications, there must be a reliable light source which ensures a minimum light intensity, a defect in the light source cannot be tolerated. This is the case, for example, for signaling rail, road or sea. In such cases where simple maintenance remedy of replacing a defective lamp is considered unacceptable, we provide preventive maintenance which consists in changing systematically all light sources after a period of statistically determined operation. Besides the fact that this maintenance is costly in personnel, it can be risky, especially in the case of maritime signaling, which is costly in material since the source is still generally functional. It also requires management cumbersome and expensive to record and track the parameters of each source and in particular its date of manufacture, installation and its duration operation. This is particularly the case for light sources of type road signs where many lamps often of different type are used under varying operating conditions making a very random estimation of their lifespan.

On the other hand, we are sometimes led to replace the light sources of a certain type by another, this is the case of traffic lights or filament lamps can be replaced with discharge tubes or again by light emitting diodes. Because of this, the different types of light sources are not used in their conditions of optimal functioning except to modify the cabinets each time order lights with the cost that this entails. If there is no modification of the cabinet this complicates the management of the lamp fleet because their lifetimes becomes more random. So even replacing a lamp having a light emitting diode light source by another can pose problems because the conduction thresholds and the luminous efficiency of light emitting diodes may vary from model to model color. If the operating conditions are not optimal, management preventive or even curative maintenance due to accelerated mortality, will be complicated if not impossible.

The present invention therefore proposes to solve the problems associated with management of light sources by optimizing the operation of lamps and light sources. It allows optimization of the maintenance. It thus reduces costs, increases reliability. It also allows simplified interchangeability of light sources in different applications.

The invention relates to a lamp forming a light source, said lamp light being produced by an electric current.

• de contrôler et de commander la lampe,
• de mesurer les paramètres de fonctionnement de ladite lampe,
• de mémoriser les caractéristiques et les paramètres de fonctionnement de ladite lampe,
• d'échanger des informations concernant ladite lampe avec l'extérieur.

According to the invention, the lamp includes electronic means allowing:

• to control and command the lamp,
• to measure the operating parameters of said lamp,
• memorize the characteristics and operating parameters of said lamp,
• to exchange information concerning said lamp with the outside.

• une interface de commande de la source de lumière,
• une interface de mesure,
• une unité de traitement et de calcul,
• une unité de mémorisation,
• une interface bidirectionnelle d'échange d'informations.
• une horloge autonome.
• les moyens électroniques comportent un micro processeur ou un microcontrôleur.
• les moyens de mémorisation comportent une unité de mémorisation non volatile permettant la lecture et l'écriture.
• l'interface de mesure est reliée à au moins un capteur de lumière.
• l'interface de mesure est reliée à au moins l'interface de commande afin de mesurer les paramètres de fonctionnement de ladite lampe et préférentiellement le courant et la tension appliqués à la source de lumière.
• l'interface d'échange permet d'envoyer et de recevoir des informations sur une ligne physique, ladite ligne physique pouvant être la ligne d'alimentation ou une liaison spécialisée.
• l'interface d'échange permet d'envoyer et de recevoir des informations par un champ électromagnétique lumineux ou hertzien et préférentiellement infrarouge ou radio électrique.
• la lumière est produite par l'utilisation de semi-conducteur du type diode électroluminescente.

L'invention concerne aussi un dispositif pour échanger des informations.In different embodiments of the invention, the following means, which can be combined according to various technically possible combinations, are used:

• a light source control interface,
• a measurement interface,
• a processing and calculation unit,
• a storage unit,
• a bidirectional information exchange interface.
• an autonomous clock.
• the electronic means include a microprocessor or a microcontroller.
• the storage means include a non-volatile storage unit for reading and writing.
• the measurement interface is connected to at least one light sensor.
• the measurement interface is connected to at least the control interface in order to measure the operating parameters of said lamp and preferably the current and the voltage applied to the light source.
• the exchange interface makes it possible to send and receive information over a physical line, said physical line possibly being the supply line or a dedicated link.
• the exchange interface makes it possible to send and receive information by a light or microwave electromagnetic field and preferably infrared or radio electric.
• light is produced by the use of semiconductor type light emitting diode.

The invention also relates to a device for exchanging information.

According to the invention the device is compatible with the lamp according to one any of the preceding claims.

The invention also relates to a method of operating a lamp. comprising a light source, said light being produced by a current electric.

According to the invention during its manufacture and use, information about said lamp is stored in means electronic devices of the storage unit type in said lamp and preferably information concerning the date of manufacture, the type lamp, manufacturer, installation date, specifications and operating parameters.

• la source de lumière est contrôlée et commandée en fonction d'au moins une ou plusieurs variables qui sont :
• une ou plusieurs informations mémorisées dans une unité de mémorisation,
• un ou plusieurs paramètres résultant de la surveillance des paramètres de fonctionnement de ladite lampe,
• une ou plusieurs informations échangées avec l'extérieur,
• lesdits contrôles, commandes, surveillance, mémorisation et échange d'informations étant assurés par des moyens électroniques inclus dans la lampe.
• la mémorisation se fait à des intervalles de temps réguliers lors du fonctionnement.
• la mémorisation s'effectue en fonction du résultat d'un contrôle.
• lorsque le contrôle détecte une anomalie d'un premier type correspondant en une différence dépassant un premier seuil entre les caractéristiques mémorisées de ladite lampe et les paramètres de fonctionnement mesurés, une information de défaut d'un premier type est mémorisée, ladite information de défaut comportant au moins les informations temporelles et le type du défaut, un signal de défaut d'un premier type étant envoyé sur l'interface d'échange.
• lorsque le contrôle détecte une anomalie d'un second type correspondant en une différence dépassant un second seuil entre les caractéristiques mémorisées de ladite lampe et les paramètres de fonctionnement mesurés, une information de défaut d'un second type est mémorisée, ladite information de défaut comprenant au moins une information temporelle et le type de défaut, l'émission de lumière est arrêtée, un signal de défaut d'un second type étant envoyé sur l'interface d'échange.
• des informations sont mémorisées dans ladite lampe concernant des opérations de maintenance et préférentiellement au moins des informations temporelles et le type d'opération de maintenance.
• l'intensité lumineuse de la lampe est contrôlée et commandée en fonction de la luminosité ambiante entre deux limites d'intensité lumineuse, la limite basse correspondante à l'intensité minimum autorisée et la limite haute correspondant à l'intensité maximum admissible pour ladite lampe.
• la diminution de l'intensité lumineuse n'est obtenue que pour une durée de réduction de luminosité ambiante dépassant un seuil et un délai prédéterminé.
• lors de l'établissement du courant électrique dans la source de lumière, la montée en tension est progressive.
• dans le cas d'une alimentation par courant alternatif, la mise en marche de la source lumière s'effectue au passage à 0 de la tension.
• lorsque la source de lumière est un dispositif semi-conducteur du type diode électroluminescente, ledit dispositif est alimenté par des impulsions de courant modulé en amplitude dans le temps.

In different embodiments of the invention, the following means, which can be combined according to various technically possible combinations, are used:

• the light source is controlled and controlled according to at least one or more variables which are:
• one or more pieces of information stored in a storage unit,
• one or more parameters resulting from the monitoring of the operating parameters of said lamp,
• one or more information exchanged with the outside,
• said controls, commands, monitoring, storage and exchange of information being carried out by electronic means included in the lamp.
• memorization takes place at regular time intervals during operation.
• memorization is carried out according to the result of a check.
• when the control detects an anomaly of a first corresponding type in a difference exceeding a first threshold between the stored characteristics of said lamp and the measured operating parameters, fault information of a first type is memorized, said fault information comprising at least the time information and the type of fault, a fault signal of a first type being sent to the exchange interface.
• when the control detects an anomaly of a second corresponding type in a difference exceeding a second threshold between the stored characteristics of said lamp and the measured operating parameters, fault information of a second type is stored, said fault information comprising at least one piece of time information and the type of fault, the light emission is stopped, a fault signal of a second type being sent to the exchange interface.
• information is stored in said lamp concerning maintenance operations and preferably at least time information and the type of maintenance operation.
• the light intensity of the lamp is controlled and controlled as a function of the ambient brightness between two limits of light intensity, the low limit corresponding to the minimum authorized intensity and the high limit corresponding to the maximum admissible intensity for said lamp.
• the reduction in light intensity is only obtained for a period of reduction in ambient brightness exceeding a threshold and a predetermined time.
• when the electric current is established in the light source, the voltage increase is progressive.
• in the case of an AC power supply, the light source is switched on when the voltage changes to 0.
• when the light source is a semiconductor device of the light-emitting diode type, said device is powered by amplitude-modulated current pulses over time.

• la figure 1 est un schéma fonctionnel d'une lampe selon l'invention,
• la figure 2 une vue d'un dispositif d'échange d'informations utilisable avec ladite lampe réalisée selon l'invention et,
• la figure 3 une coupe d'une lampe selon un exemple de mise en oeuvre de l'invention.

The present invention will be better understood on reading the following description of a particular embodiment given by way of nonlimiting example, where

• FIG. 1 is a functional diagram of a lamp according to the invention,
• FIG. 2 a view of an information exchange device usable with said lamp produced according to the invention and,
• Figure 3 a section of a lamp according to an exemplary implementation of the invention.

In a particular embodiment of a lamp according to the invention represented in FIG. 1, and which presents a large number of functionalities, a microcontroller 14 comprising at least one unit, a microprocessor 6, a memory unit 5 for storing an operating program and the lamp parameters, a control interface 3, a measure 4, and a communication interface 7 is used. This microcontroller 14 is supplied by the general supply 13 of the lamp possibly by a regulating device not shown here.

In this particular mode, an autonomous power supply 20 connected to the general power supply 13 is provided to ensure a safeguard of the data and the operation of a clock 19 which provides the microcontroller information on date, time (hour, minute, second). The interface of command 3 sends command commands to the controller power 2 and the light source 1. The measurement interface 4 is connected to the power control device 2 so that the microcontroller can measure the operating parameters of the control device power 2 and light source 1. On the measurement interface 4 is connected light source 1 so that the microcontroller can follow the parameters of operation of the light source, in particular, the intensity and the voltage supplied to it by the power control device 2. On the measurement interface 4, light sensors are connected: a sensor 15 of the light intensity produced by the light source 1, a sensor 16 of ambient light, a temperature sensor 17. Finally, on the interface of measure 4 is connected to the general supply 13 by a link 18 so that the microcontroller can follow the power supply voltage.

The bidirectional communication interface 7 is connected to a bus 12 specifically adapted to convey information via a adapter device 11. The bidirectional communication interface 7 is connected to the power supply by an adapter device 10 in order to be able to exchange carrier current information. Communication interface bidirectional 7 is connected to an adapter device 9 in order to allow exchange of information in radio form. Finally, the interface of bidirectional communication 7 is connected to an adapter device 8 in order to ability to exchange information in the form of a two-way link infrared. These different electronic elements are devices classics made up of discrete elements and / or integrated semiconductors. It is possible in other simpler embodiments to limit the communication possibilities by keeping only one, for example, by carrier current. On the other hand, the autonomous power supply 20 can be deleted in the case where the memory unit of the microcontroller 14 is of the type EEPROM, which is an electrically erasable memory and which allows keep the data even in the event of a power failure. Otherwise, the clock 19 can be omitted in case the time information can be supplied on demand or regularly on the communication interface. The measurement interface 4 will conventionally be a digital analog converter multiplexed integrated in the microcontroller. The number of sensors can also be reduced, the light intensity sensor emitted by the light source can be omitted for example in the case of a diode source where the light intensity can be estimated by the measurement of the voltage and intensity consumed by the light source. Of even the ambient light sensor can be removed if the intensity light does not need to be modulated according to the ambient light.

The internal lamp program and therefore its method of operation is designed to memorize the parameters of the lamp and the light source (date of manufacture, installation, type, voltages and minimum, maximum intensities ...) and its normal operation (duration ...) and abnormal (recording of anomalies, emission of an alert message ...) and maintenance parameters (date, type, etc.). This program is also designed to respond to maintenance operations which include lamp and light source operation. This program is also designed to optimize and control the operation of the lamp and the light source according to the parameters recorded and memorized as well, that possibly, that information exchanged on the interface of communication. Thus the operation can be optimized according to the characteristics of the light source and environmental conditions, for example, ambient light, regardless of the voltage supplied by the power source. This therefore increases the duration of lamp life because the light intensity emitted which can be reduced during nocturnal periods. On the other hand, putting the source into operation light which can be optimized, for example, in the case of a source luminous filament type, the voltage increase upon ignition may be progressive in order to take into account variations in the resistance of the filament in depending on its temperature, in the case of a diode type light source light-emitting, its power supply can be amplitude-modulated over time, increasing the subjective visual efficiency of the source.

In the case of traffic lights controlled by a centralized cabinet, the independence of the operating conditions of the lamp and the light source in relation to its supply voltage allows use lamps with different types of light sources on the same control cabinet without having to modify it. It will be possible to have a light emitting diode lamp whose brightness can be regulated by modulation of electrical pulses over time, or even amplitude, in the lamp in question associated with a discharge lamp or with filaments on the same cabinet which will provide only one tension power to all lamps. This voltage can be periodic in depending on the signaling cycle or continues, in the latter case, the order on and off depending on the cycle will be transmitted by current carrier. This optimization of the lamp operating mode is possible because the type of lamp, i.e. the characteristics of its source of light are recorded during its manufacture in the memory unit. So, even in the case of light emitting diode, optimization will be possible between lamps made from various types of light emitting diode because their operating parameters will be known and stored during the lamp manufacturing. Thus, lamps of different colors can be used independently of the general supply voltage. The program contained in the lamp therefore allows regular monitoring and control operating parameters and can detect preventively the end of his life. For example, in the case of discharge tubes, the end of life is announced by difficulties in ignition or by a decrease significant of the brightness which is therefore recorded in the lamp and which can therefore be sent to the communication interface for alert. Likewise in in the case of a light source of the light-emitting diode type, it will be possible to regularly monitor the number of elements presenting a defect by the simple measurement and monitoring of the intensity absorbed by the light source or by measuring and monitoring the light intensity produced. In some cases, where the security must be optimal, the lamp will even be able to directly inform a management and maintenance center. Indeed, in the case of the road signs, many light control cabinets are linked to a traffic regulation and control center by links IT. This type of secure application is not limited to traffic road, we can consider it in the case of railway signaling where some security lights have two light sources, the second taking over from the first when the first has a fault. It is therefore possible to use two lamps exchanging information so that the switching from one to the other can be done while informing a centralized management. The programs thus developed are classic and they may even be modified during the life of the lamp by through the communication interface and an adapted memory of the EEPROM type.

Adapted to the management of such a lamp, Figure 2 shows the device exchange of information usable by a maintenance team for the lamp management. In this embodiment which presents a large number of functionalities, the device 21 includes means for view and enter data. To exchange information with a lamp according to the invention, the device 21 comprises an antenna 26, a device allowing 25 bidirectional infrared transmissions, a connector to be connected to a bus 12 and, finally, a connector 23 to connect to the supply of the lamp 13 to ensure an exchange by carrier current. This device is autonomous and has an internal power source but due to the presence of the connector 23, it is possible to supply it by the general supply 13 and / or to recharge the means internal autonomous power supply of the rechargeable battery type. A connector 22 for exchanging information with a computer system external is also provided on the device 21. Such a device 21 and / or the system computer connected to connector 22 allows to follow in a simple and efficient the stock of lamps. In particular, we can quickly detect particular problems on a batch of lamps, and thus perform maintenance preventive on the lamps of this batch and, possibly, modify the mode of manufacture of lamps or change supplier.

A lamp produced according to the invention is shown in section on the Figure 3. A conventional base 33 allows the lamp to be inserted into a socket standard. At the end of the base 33, two contacts 34 provide the power general 13 of the lamp. The lamp body 30 contains a printed circuit 31 supporting on a first face light-emitting diodes 35 and on a second side, the discrete and integrated electronic circuits. In this mode embodiment, a protection and regulation device 32 is provided on the general power supply 13. An ambient light sensor 16 is arranged on the front of the lamp. Similarly, a device 8 for transmission reception infrared consisting of a light emitting diode and a photodiode receiver, is arranged on the front of the lamp. A light sensor 15 directed towards the light source consisting of light-emitting diodes 35 allows to measure the light intensity emitted by the lamp. The lamp shown in Figure 3 is a light emitting diode model. It is however envisaged in the context of the invention, a lamp comprising filament type light sources which can be arranged in a way equivalent or a lamp comprising as light source a single spiral discharge tube arranged towards the front of the lamp. In such a lamp, information is exchanged by carrier current. Through elsewhere this model of lamp having a base is only one mode of particular embodiment of the invention. It is indeed possible to carry out lamps where the base is replaced by simple flying wires or by another connection system, for example domino or jumper type or screw bar.

These different forms of implementation of the invention are given to as examples and cannot limit its scope.

Claims (18)

Lighting device comprising a light source (1), said light being produced by an electric current, and electronic means, said electronic means comprising microprocessors or microcontrollers and allowing the control and command of said source by an interface of control (2), measurements by a measurement interface (4), information exchange, characterized in that said light source and the electronic means are grouped in a single interchangeable assembly forming a lamp and comprising a microprocessor or microcontroller (14), the electronic means further comprising: an autonomous clock (19), a non-volatile storage unit (5) for reading and writing, and said electronic means being configured for: memorize information concerning said lamp and preferably the date of manufacture, the type of lamp, the manufacturer, the date of installation, memorize the operating characteristics of said light source, measure the operating parameters of said light source, memorize the operating parameters of said light source, control and control said light source as a function of the operating characteristics and parameters so that the light source is in an optimal operating condition independently of the power source, memorize the maintenance parameters of said lamp, exchange information concerning said light source with the outside. Device according to claim 1, characterized in that the interface of measurement (4) is connected to at least one light sensor (15; 16). Device according to any one of the preceding claims, characterized in that the measurement interface (4) is connected to the interface of command (2) to measure the operating parameters of said light source and preferably the current and voltage applied to the light source. Device according to any one of the preceding claims, characterized in that the exchange interface (7, 10, 11) makes it possible to send and receive information on a physical line, said physical line being able to be the supply line (13) or a dedicated link (12). Device according to any one of the preceding claims, characterized in that the exchange interface (7, 8, 9) makes it possible to send and receive information by a light electromagnetic field or wireless and preferably infrared or radio electric. Device according to any one of the preceding claims, characterized in that the light is produced by the use of semiconductor of the light-emitting diode type (35). Operating method characterized in that for a device according to any one of the preceding claims, during the manufacture and use of the lamp, information concerning said lamp is stored in electronic means of the storage unit type (5 ) non-volatile allowing reading and writing, and preferably: information concerning the date of manufacture, the type of lamp, the manufacturer, the date of installation, the operating characteristics of said light source; the operating parameters of said light source; parameters relating to maintenance operations and preferably at least time information and the type of maintenance operation. Method according to claim 7, characterized in that: the light source is controlled and controlled according to at least one or more variables which are: one or more pieces of information stored in a storage unit (5), one or more parameters resulting from the monitoring of the operating parameters of said light source, one or more information exchanged with the outside, said controls, commands, monitoring, storage and exchange of information being carried out by electronic means included in the lamp. Method according to claim 7 or 8, characterized in that the memorization is done at regular time intervals during the lamp operation. Process according to any one of Claims 7 to 9, characterized in that the storage takes place as a function of the result of a control. Process according to any one of Claims 7 to 10, characterized in that when the control detects an anomaly of a first corresponding type in a difference exceeding a first threshold between the memorized characteristics of said lamp and the parameters of measured operation, fault information of a first type is stored, said fault information comprising at least the information time and the type of fault, a fault signal of a first type being sent to the exchange interface. Process according to any one of Claims 7 to 11, characterized in that when the control detects an anomaly of a second corresponding type in a difference exceeding a second threshold between the memorized characteristics of said lamp and the parameters of measured operation, fault information of a second type is stored, said fault information comprising at least one piece of information time and the type of fault, the light emission is stopped, a signal fault of a second type being sent on the exchange interface. Process according to any one of Claims 7 to 12, characterized in that in the case of a lamp comprising at least one sensor light (16), the light intensity of the lamp is controlled and controlled as a function of the ambient brightness between two light intensity limits, the lower limit corresponding to the minimum permitted intensity and the upper limit corresponding to the maximum admissible intensity for said lamp. Process according to any one of Claims 7 to 13, characterized in that in the case of a lamp comprising a light (16), the decrease in light intensity is only obtained for a ambient light reduction time exceeding a threshold and a delay predetermined. Process according to any one of Claims 7 to 14, characterized in that when the electric current is established in the light source, the voltage increase is gradual. Process according to any one of Claims 6 to 14, characterized in that in the case of an AC supply, the the light source is switched on when the voltage changes to 0. Process according to any one of Claims 6 to 15, characterized in that when the light source is a semiconductor device of the light-emitting diode type, said device is powered by amplitude-modulated current pulses over time. Device (21) for exchanging information, characterized in that it is suitable for the lamp and the method according to any one of previous claims.

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