FR2949037A1 - Electronic lighting device i.e. off-ground taxi track marking light, for guiding airplane during landing and take-off operations, has optical module with current-current converter, and cords connecting device to electrical marking loop - Google Patents

Abstract

The device (100) has an insulating body (110) including a light source constituted by LEDs for lighting environment of the device, and an optical module (121) adapted to the light source for providing a predetermined lighting. The optical module includes a current-current converter and an electronic power supply circuit that powers the light source. Connection cords (190) connect the device to an electrical marking loop. The optical module is fixed on the insulating body, and the power supply circuit is over-molded in a polyurethane resin.

Description

FIELD OF THE INVENTION The present invention relates to the field of beaconing lights and more specifically to transformers for above-ground beaconing lights such as traffic lane markings on runways of runways. airports.

STATE OF THE ART In the field of marking airport runways, it is known to use above ground marker lights. A beacon light includes a transformer having a primary circuit and a secondary circuit. The primary circuit of the transformer is connected to a power line to supply the beacon light. The secondary circuit of the transformer is connected to a lamp. However, the use of such a system requires substantial installation work. Indeed, in the first place primary cables associated with the primary circuits must be installed and buried in trenches. Then the transformers are placed in pits above the primary cables. Finally, the secondary cables connecting the secondary circuits to the lamps are installed in trenches and ducts. To overcome these disadvantages of implementation, it is known to use a transformer-fire. This transformer-fire combines in the same structure a markup transformer, a halogen lamp and a colored verrine to obtain a particular photometry, that is to say special optical characteristics. The beacon transformer has a single magnetic circuit on which the primary and secondary circuits are wound. Thus, the only necessary installation work concerns the laying of the primary cable which can be either fixed on the ground or buried in the ground. No additional installation is required.

The evolution of lighting technology now allows the use of a light-emitting diode (LED). The LED has a life of about 50,000 to 100,000 hours. Thus, the halogen lamp can be replaced by an LED to allow a longer life of the beacon light. However, this change of the halogen lamp for an LED also causes a change in the electronic circuit previously associated with the halogen lamp. Indeed, the modified electronic circuit associated with the LED includes a current-voltage converter and a pulse width modulation converter to provide a continuous intensity to the LED. Such an electronic circuit comprises hundreds of components, such as microprocessors and electrolytic capacitors. This multitude of components causes significant production costs. In addition, since these circuits are associated with LEDs that have a long life, these circuits must also be reliable over such a period. It is extremely expensive and difficult to obtain such longevity for electronic circuits provided with critical components such as those previously described. SUMMARY OF THE INVENTION The present invention aims to solve some of the disadvantages described above. The object of the present invention relates to an electronic lighting device comprising an insulating body, said body comprising a light source comprising a light-emitting diode for illuminating the environment of the electronic lighting device, optical means adapted to the source of the light. light for providing a predetermined illumination, an electronic supply circuit for supplying the light source, said circuit comprising at least one current converter and said electronic lighting device comprising an electronic supply circuit and being characterized in that the Current converter is a current-to-current converter.

According to one embodiment, the optical means are sealed on the insulating body to make the optical means and insulating body assembly indémontable and sealed. According to another embodiment, the optical means are overmolded in a polyurethane resin. According to another embodiment, the device comprises an electronic control device for producing a variation of the intensity of the light source as a function, for example, of the value of the supply current. According to another embodiment, the device comprises a self-reflecting device so that in the absence of electric current, the device provides a self-reflecting function.

BRIEF DESCRIPTION OF THE DRAWINGS The objects, objects and features of the invention will become more apparent upon reading the following description with reference to the drawings, in which: - Figure 1 shows a perspective view of the lighting device according to the invention, as an exemplary embodiment; FIG. 2 represents a diagram of the electronic circuit relating to the operation of the lighting device according to the invention, by way of exemplary embodiment. DETAILED DESCRIPTION OF ONE EMBODIMENT FIG. 1 shows a lighting device 100. This lighting device is located, for example, around the airport runways in order to allow aircraft guidance during landing and lift-off.

The lighting device 100 comprises different elements. Thus, the device 100 comprises a body 110 of cylindrical shape. The body 110 is made of an insulating and waterproof material such as polyurethane or epoxy. The body 110 is obtained by molding. A sleeve 120 covers a part of the body 110. The sleeve 120 is made of a retro-reflective material, of blue color for example. Thus, the sleeve 120 ensures a self-reflective beacon function, in the absence of any electric current within the lighting device 100.

The device 100 also comprises an optical module 121 represented by a dome in FIG. 1. The optical module is releasably sealed to the body 110. The optical module 121 comprises a light-emitting diode (LED) 160 represented in FIG. Optical module 121 can be releasably sealed by trapping a dry gas. Thus, no internal condensation can be created during temperature variations outside the device 100. The optical module 121 also comprises an electronic circuit 200 shown in Figure 2. This circuit 200 is used to power the LED 160 to illuminate the device. Lighting device 100. Circuit 200 includes a usable single-brightness converter of 1.5A to 6.6A. The circuit 200 uses a current-to-current conversion process. This process avoids the use of micro-processor converters or electrolytic capacities. The circuit 200 makes it possible to produce a light flux that varies little with the value of the supply current. The lighting device 100 thus provides a beaconing light function. The electronic components of the circuit 200 are overmolded in a polyurethane resin. The circuit also includes connecting cords 190. These cords connect the circuit 200 to a power source (not shown) located outside the device 100. The cords 190 represent standardized means of connection to an electrical loop of markup. In the situation where two cords are each provided with a unipolar connector, the cords are called primary and the markup loop is primary. In the situation where a cord is provided with a bipolar connector, the cord is said secondary and the markup loop is secondary. These cords are also overmolded in a polyurethane resin. The overmolding ensures a seal in case of bad weather as well as a security protection with regard to people.

The device 100 also includes a transformer (not shown). This transformer, necessary for the adaptation of the current of the loop to the D.E.L supply circuit, is an integral part of the device 100 and is directly connectable, both to the primary loops and secondary loops. Thus, no transformer external to the device 100 is necessary. As shown in Figure 1, the device 100 is provided with a ground attachment 150. In the presence of primary cords, the cords 190 can pass outside of this attachment. In the presence of a secondary cord, the cord can pass inside this attachment. This attachment 150 is connected to the body 110 by means of a screwed ring 170. This ring is screwed in a frangible manner. Thus, the ring has a material weakness to allow a separation of the body 110 and the attachment 150 during a collision between the lighting device 100 and an external object such as an aircraft. The attachment 150 comprises for example a metal foot to be sealed in a floor such as concrete or a foot to be stitched on soft ground. The lighting device 100 can also be screwed directly onto a transportable metal support.

The lighting device does not require any specific technical maintenance. Only the sleeve 120 optionally requires external cleaning or replacement in case of significant degradation.

The lighting device 100 generates a relatively low power consumption, less than 1 OVoltAmpères. The lighting device 100 is unmountable, robust and waterproof. The life of the lighting device 100 is about 50,000 hours.

The device 100 according to the invention thus combines different functions. The device 100 includes the previously mentioned fire-transformer function. This function guarantees a simple and inexpensive installation. The device 100 also includes the self-reflective tag function. This function ensures emergency lighting in case of failure. The device 100 also includes the LED fire function. This function guarantees a low power consumption and a long life of the device 100.

According to another embodiment of the device 100 according to the invention, an electronic power supply regulator can be used to produce a variation of the intensity of the light emitted by the lighting device 100. The regulator can be integrated into the within the electronic circuit 200 for example. The device 100 according to the invention uses an electronic circuit 200 which implements a current-current conversion process. Consequently, the associated electronic components are components of simple structure such as diode bridges, robust bipolar transistors, resistors. This type of component structure avoids a large number of malfunctions frequently related to the structure of the components. Thus, the use of these components makes it possible to extend the life of the device 100. The combination of these components and the use of the LED guarantees a longer life of the device 100 than that of the lighting devices according to FIG. prior art. The device 100 according to the invention does not allow access to the electronic circuit 200 or to any component located inside the body 110. The technical characteristics of the lighting device meet the requirements of the International Civil Aviation Organization ( ICAO), the Federal Aviation Administration (FAA) and the International Electrotechnical Commission (IEC). The previously described embodiments are given by way of example only. 25

Claims (5)

An electronic lighting device (100) comprising an insulating body (110), said body comprising: - a light source comprising a light-emitting diode (160) for illuminating the environment of the electronic lighting device (100), - a an optical module (121) adapted to the light source for providing a predetermined illumination, said optical module (121) comprising an electronic supply circuit (200) for supplying the light source, said circuit (200) comprising at least one converter current, - connection means (190) for connecting the electronic lighting device (110) to an electric lighting loop, said electronic lighting device (100) and being characterized in that the power converter is a current-to-current converter. 2. Device (100) according to claim 1, characterized in that the optical module (121) is sealed to the insulating body (110). 3. Device (100) according to claims 1 or 2, characterized in that the circuit (200) is overmolded in a polyurethane resin. 25 4. Device (100) according to one of the preceding claims, characterized in that the device (100) comprises a device 10 5. 56. 7.Control electronics to produce a variation of the intensity of the light source. Device (100) according to one of the preceding claims, characterized in that the electronic supply circuit (200) is overmolded with the body (110), so as to create a sealed and indémontable assembly formed by the electronic circuit of power supply (200) and the body (110). Device (100) according to one of the preceding claims, characterized in that the device (100) comprises a retro-reflective device so that in the absence of electric current, the device (100) provides a retro-reflective function. Device (100) according to one of the preceding claims, characterized in that the device (100) comprises a transformer.