FR2957469A1 - LED light emitter's failure status storage system for headlight of vehicle, has switching units authorizing and prohibiting power supply of power circuit and control units in closed and open states, respectively - Google Patents

Abstract

The system has control units (2) converting a control signal (S0) indicating presence of failure of LED light emitters (D) of a power circuit (1), into a command signal (S1). A capacitive circuit of memory units of the control units has a capacitor (C1) discharged by a discharge resistor (Rd). Actuating units (4) switches switching units (K1, K2) to open/closed sate when voltage at terminals of the capacitor is higher/lower than a preset value (Vt). The switching units respectively authorize and prohibit power supply of the power circuit and the control units in the closed and open states. The capacitor is charged by the command signal.

Description

The present invention relates to a system for storing a fault in a power circuit, the power circuit being of the type comprising at least one light emitter associated with a vehicle light, and equipped with means for detecting a fault. a failure of the light emitter (s), the detection means being designed to deliver a control signal indicating the presence of a failure. A storage system known from the state of the art comprises: power circuit control means designed to receive the control signal and convert it into a control signal, said control means comprising means for storing said control signal; control signal, - power supply means designed to supply the power circuit and the control means, - switching means having at least one closed state and at least one open state which respectively allows and interrupts the power supply power circuit and control means, - actuating means adapted to switch from the closed state to the open state, and vice versa, the switching means.

In particular, it is known from the state of the art to use control means incorporating a flash type memory for storing the control signal. A flash type memory is non-volatile insofar as the control signal remains stored even if the control means are no longer powered by the power supply means, for example when the switching means are switched in the state opened by the actuating means. However, such storage means can not be implemented on pre-existing control means, making these storage means incompatible. Indeed, such storage means require replacing the existing control means by control means incorporating a flash type memory. This lack of compatibility is detrimental in terms of costs when it is necessary to implement new safety rules involving memorization of faults associated with the lights of a vehicle.

Moreover, such storage means require powering the control means to read the control signal stored in the flash type memory. The present invention aims to overcome the aforementioned disadvantages and relates to a system for storing a fault in a power circuit, comprising: a power circuit comprising at least one light emitter associated with a vehicle light, and equipped with means for detecting a failure of the one or more light emitters, the detecting means being designed to deliver a control signal indicating the presence of a failure, - power circuit control means adapted to receive the signal control means and converting it into a control signal, said control means including means for storing said control signal, power supply means for supplying the power circuit and the control means, means for switching having at least one closed state and at least one open state which respectively allows and interrupts the power supply of the power circuit and control means, actuating means adapted to switch from the closed state to the open state, and vice versa, the switching means, characterized in that the storage means comprise a capacitive circuit arranged to receiving the control signal, and comprising at least one capacitor and at least one discharge resistor, the capacitor being arranged to be charged by the control signal and to discharge through the discharge resistor, and that the means The actuating means are configured to switch the switching means in the open state or in the closed state when the capacitor has a voltage at its terminals respectively greater than or less than a predetermined value. Thus, such a capacitive circuit makes it possible to memorize the control signal in a nonvolatile manner by means of the charge of the capacitor. The presence of such actuating means coupled to the capacitive circuit 35 makes it possible to interrupt the power supply of the power circuit when a fault has been detected, for security reasons. Indeed, when a failure has been detected, the capacitor is in the charging phase until a voltage is present at its terminals greater than a predetermined value. In addition, such a storage system does not require powering the control means to determine the state of charge of the capacitor of the capacitive circuit and read by itself the stored control signal. Moreover, such a capacitive circuit can be implemented easily on pre-existing control means, making the storage system according to the invention compatible. In one embodiment, the actuating means comprise at least one voltage comparator, preferably of the transistor type, having an input connected to the capacitive circuit and an output connected to the switching means, the voltage comparator being designed to compare the voltage across the capacitor to a predetermined value. Thus, such a voltage comparator makes it possible to easily determine the state of charge of the capacitor of the capacitive circuit, and this with a limited power consumption. According to a particular embodiment, the storage means comprise a discharge circuit designed to discharge the capacitor of the capacitive circuit in the absence of the control signal. Thus, such a discharge circuit makes it possible to dispense with phenomena of inadvertent charging of the capacitor, due in particular to parasitic currents, in the absence of failure, and for safety reasons. Advantageously, the system comprises an electrical energy storage circuit connected to the power supply means and to the control means. According to one embodiment, the storage circuit comprises at least one capacitor arranged to be loaded by the supply means and to supply the control means during its discharge. Thus, such a storage circuit temporarily supplies the control means when the switching means are switched in the open state by the actuating means. In a particular embodiment, the capacitor and the discharge resistor of the capacitive circuit are connected in parallel.

Preferably, the capacitor and the discharge resistor of the capacitive circuit are configured so that the capacitive circuit has a time constant greater than or equal to ten seconds. Thus, the charging time of the capacitor of the capacitive circuit is long enough to prevent a specific surge at the terminals of said capacitor does not lead to an inadvertent interruption of the power supply of the power circuit. Other features and advantages will appear in the following description of an embodiment of a storage system according to the invention, given by way of non-limiting example, with reference to the accompanying drawings in which FIG. a schematic view of a storage system according to the invention. The storage system illustrated in FIG. 1 comprises: a power circuit 1 comprising a light-emitting diode-type emitter D associated with a vehicle light (not shown), and equipped with means for detecting a failure of the light emitter D, the detection means 10 being designed to deliver a control signal SO indicating the presence of a failure, - control means 2 of the power circuit 1, designed to receive the control signal SO and converting it into a control signal S1, said control means 2 comprising storage means 3 of said control signal S1, - power supply means Val, Va2 designed respectively to feed the power circuit 1 and the control means 2, - switching means K1, K2 having at least one closed state and at least one open state which respectively allows and interrupts the power supply of the power circuit 1 and control means 2, 30 - actuating means 4 adapted to switch from the closed state to the open state, and vice versa, the switching means K1, K2. The power circuit 1 further comprises switching means KO having at least one closed state and at least one open state which respectively allows and interrupts the passage of a supply current I supplied by the power supply means Val. in the power circuit 1. As a non-limiting example, two power transistors (not shown) can be coupled to form the switching means KO. The control means 2 are designed to switch from the closed state to the open state, and vice versa, the switching means KO in order to modulate the power supply current I in the power circuit 1. The control means 2 can be made, by way of non-limiting example, in the form of an element selected from the group comprising a microcontroller, a digital signal processor, a programmable gate array and a specific application integrated circuit.

The means for detecting a failure of the light emitter D comprise a measuring member 10 of the feed current I. The detection means may also comprise a voltage measuring member (not shown) at the terminals of the Moreover, it is understood that the power circuit 1 can be equipped with a matrix of light emitters D, each associated with a vehicle light. The detection means are then adapted to detect a fault in the matrix of light emitters D. The power supply means Val, Va2 can be connected to a battery of the vehicle having a nominal voltage of 28 V. The power supply means Val electric can be directly connected to the battery. The power supply means Va2 can be connected to the battery via a voltage step-down (not shown) so that the power supply means Va2 provide a voltage of the order of 5 V.

The storage means of the control signal S1 comprise a capacitive circuit 3 receiving the control signal S1. The control signal S1 sent by the control means 2 is a DC voltage of the order of 5 V. The capacitive circuit 3 comprises a capacitor C1 and a discharge resistor Rd connected in parallel. The capacitor is charged by the control signal S1 and discharges through the discharge resistor Rd. The capacitor C1 and the discharge resistor Rd are configured so that the capacitive circuit 3 has a time constant greater than or equal to 10 s. Such a time constant can be obtained when the capacitor C1 has a capacity of the order of 10 pF with a discharge resistance Rd of the order of 1 M0.

According to a not shown embodiment, the storage means comprise a discharge circuit designed to discharge the capacitor C1 in the absence of the control signal S1. The actuating means comprise a voltage comparator 4, preferably of the transistor type, having an input connected to the capacitive circuit 3 and an output connected to the switching means K1, K2. The voltage comparator 4 is designed to compare the voltage across the capacitor C1 to a predetermined value Vt, Vt being for example of the order of 3 V.

The voltage comparator 4 is configured to switch the switching means K1, K2 in the open state or in the closed state when the capacitor C1 has a voltage at its terminals respectively greater than or less than the predetermined value Vt. Furthermore, the system comprises an electrical energy storage circuit connected to the electrical power supply means Va2 of the control means 2 and to the control means 2. The storage circuit comprises a capacitor C2 arranged to be loaded by the power supply means. power supply Va2 and to supply the control means 2 during its discharge.

In normal operation, that is to say in the absence of failure of the light emitter D, the switching means K1, K2 are switched to the closed state. The capacitor C2 is charged by the power supply means Va2 while the capacitor C1 is discharged. In the event of a failure of the light emitter D, the measuring device 10 detects the failure and delivers a control signal SO to the control means 2. The control means 2 convert this control signal SO into a control signal S1 . This control signal S1 (DC voltage of 5 V) is transmitted to the capacitive circuit 3 and charges the capacitor C1. When the voltage across the capacitor C1 exceeds the predetermined value Vt, the voltage comparator 4 switches the switching means. K1, K2 in the open state. The power circuit 1 is no longer powered. The control means 2 are then powered by the capacitor C2 during a discharge phase, and continue to transmit the control signal S1 to the capacitive circuit 3.

When the capacitor C2 can no longer supply the control means 2 so as to obtain a control signal C1 having a DC voltage of 5 V, the capacitor C1 begins to discharge through the discharge resistor Rd. When the voltage at the terminals of Cl decreases until a value less than the predetermined value Vt is obtained, the voltage comparator 4 switches the switching means K1, K2 to the closed state. The power circuit 1 is powered again. The capacitor C2 is charged by the power supply means Va2. Of course, the embodiment of the invention described above is not limiting in nature. Details and improvements can be made in other embodiments without departing from the scope of the invention.

Claims (7)

REVENDICATIONS1. A system for storing a fault in a power circuit (1) comprising: - a power circuit (1) comprising at least one light emitter (D) associated with a vehicle light and equipped with detecting (10) a failure of the one or more light emitters, the detecting means (10) being adapted to deliver a control signal (SO) indicating the presence of a failure, - control means (2) of the power circuit (1), adapted to receive the control signal (SO) and convert it into a control signal (S1), said control means (2) comprising means for storing said control signal (S1), - Power supply means (Val, Va2) designed to supply the power circuit (1) and the control means (2), - switching means (K1, K2) having at least one closed state and at least an open state which respectively allows and interrupts the power supply of the power circuit (1) and control means (2), - actuating means (4) adapted to switch from the closed state to the open state, and vice versa, the switching means (K1, K2), characterized in that the storage means comprise a capacitive circuit (3) arranged to receive the control signal (S1), and comprising at least one capacitor (C1) and at least one discharge resistor (Rd), the capacitor (C1) being arranged to be charged by the control signal (S1) and to discharge through the discharge resistor (Rd), and in that the actuating means (4) are configured to switch the switching means (K1 , K2) in the open state or in the closed state when the capacitor (C1) has a voltage at its terminals respectively greater than or less than a predetermined value (Vt). 35 2. System according to claim 1, characterized in that the actuating means comprise at least one voltage comparator (4), preferably transistor type, having an input connected to the capacitive circuit (3) and an output connected to the means. switch (K1, K2), the voltage comparator (4) being arranged to compare the voltage across the capacitor (C1) to a predetermined value (Vt). 3. System according to claim 1 or 2, characterized in that the storage means comprise a discharge circuit designed to discharge the capacitor (Cl) of the capacitive circuit (3) in the absence of the control signal (S1). 4. System according to one of claims 1 to 3, characterized in that it comprises an electrical energy storage circuit connected to the power supply means and the control means. 15 5. System according to claim 4, characterized in that the storage circuit comprises at least one capacitor (C2) arranged to be charged by the power supply means (Va2) and to supply the control means (2) during its discharge. 20 6. System according to one of claims 1 to 5, characterized in that the capacitor (C1) and the discharge resistor (Rd) of the capacitive circuit (3) are connected in parallel. 7. System according to one of claims 1 to 6, characterized in that the capacitor (C1) and the discharge resistor (Rd) of the capacitive circuit (3) are configured so that the capacitive circuit (3) has a constant of time greater than or equal to ten seconds. 10