WO2012045933A1 - Device for controlling the operation of flashing indicators for a vehicle - Google Patents

Abstract

This device comprises a commercial low-power component which is capable of replicating, on the output port thereof, the weak signal present in the LED circuits (SMARTFET: smart highside power switch PROFET) that are used for the LEDs, which is coupled to a diagnostic circuit that controls a cut-off convertor to which the power consumption of the conventional incandescent lamps to the on-board computer is simulated, while restoring the current to the power system on board the vehicle.

Description

 DEVICE FOR CONTROLLING THE OPERATION OF INDICATORS FOR A VEHICLE

The invention relates to the electrical architecture of motor vehicles and more specifically the control of the proper functioning of certain components.

 Its purpose is to control the operation of light-emitting diode (LED) bulbs commonly used for flashing lights for a vehicle. The device is composed of at least one low-power component, capable of controlling SMARTFET (Smart High Side Power Switch) type electronic systems in English, at least one switching power converter, and than a diagnostic circuit.

 The bulbs of conventional flashing lights are incandescent and usually consume between 20 and 30 Watt depending on the type. This type of bulb gives way more and more to light-emitting diode bulbs, much less consuming, more reliable and now less expensive.

 As for incandescent bulbs, the legislation requires to be able to have on each vehicle a detection of failure (absence or breakage) of flashing light bulbs at the four corners of vehicles.

 When incandescent bulbs are used, this detection is easily achievable: a simple consumption measurement of the circuits including the bulbs allows the detection of a burned or missing bulb. On the other hand, even if the light-emitting diode bulbs work properly, the measurement of the consumption inevitably results in a failure diagnosis, since the consumption of these latter is much lower than that of a conventional lamp, the current being not detected by the control.

The inaccuracy of the current measurements and the tolerances on the power of the lamps do not facilitate the diagnosis. In addition, the diagnostic operation of an LED lamp is even more complicated in mixed circuits, comprising at least one lamp containing a light emitting diode bulbs among a plurality of incandescent bulbs.

 Currently, it is the calculator dedicated to the functions of the passenger compartment, Unity

UCH, which drives the three flashing lights right and three left of the vehicle.

 It has already been envisaged to use power resistors behaving as equivalent charges, which simulate the presence of incandescent lamps. However, this has the disadvantage of unnecessarily dissipating energy.

 It is also possible to integrate the function diagnostic function in the computer, as for other lamps in the vehicle, but this integration proves to be very expensive, because it amounts to developing a new cabin calculator. However, the computers are produced in large series, and, being masked computers, any modification involves high costs.

 An object of the present invention is to detect weak currents in flashing lights with LED bulbs, without resorting to the development of new functions in the computer, while avoiding excessive costs of integration.

 For this purpose, the invention proposes that the control device comprises at least one low power component, at least one switching power converter and at least one diagnostic circuit. The low power component retrieving the information of the current flowing in the light circuits on its diagnostic output, transmits this information to the diagnostic circuit.

 The advantages of the invention are:

 - control the operation of the light-emitting diode bulbs used in the flashing circuits of a vehicle,

 - monitor and detect their malfunction, and

 - alert the driver in case of breakage or absence of bulb

According to other features of the invention: the diagnostic circuit comprises a switch driven by the output signal of the low-power component, which causes the circuit to close on receipt of the failure information,

 - The diagnostic circuit comprises a resistance circuit, downstream of the switch whose closure causes the change of the current at its output, and

 - The switching power converter comprises an enabling signal developed by the diagnostic circuit and, depending on its value, carries on its output a current variation which is detected by the UCH computer.

 Other characteristics and advantages of the invention will appear on reading the detailed description which follows, for the understanding of which, reference will be made to the appended drawings in which:

 - Figure 1 shows the block diagram of the system,

 FIG. 2 represents the inputs and outputs of the proposed device; FIG. 3 represents the development of the signal sent to the switching converter 3 within the device;

 FIG. 4 shows the change in voltage of the voltage converter within the device as a result of the malfunction, and

 - Figure 5 shows a flow diagram of the operation with the sequence of exchanges.

 In FIG. 1, the diagram functionally reproduces a compound circuit:

- a computer (UCH) 2,

 - turn signal actuators 7,

 - the proposed device 1, and

 - boxes of bulbs, including light-emitting diode bulbs

(6a, 6b, 6d, 6e)

 In the device 1, in addition to the low power components (in the example shown, the component 5g, dedicated to the left of the vehicle and the component 5d, dedicated to the right), and the diagnostic circuit 4 there is a converter switching energy 3.

In Figure 2 we find the same control device 1. Represented, the inputs / outputs of the operation control system light-emitting diode bulbs in the flashing light circuit of a vehicle. On the left of the diagram, the inputs from the computer: the battery voltage e, the signal of the right flashing d, and the signal of the left flashing g (both from the UCH). On the right of the diagram, the outputs for the bulbs 6 at the four corners of the vehicle (right and left b c), wing repeaters f, and the battery voltage a.

 FIG. 3 shows the interaction between the diagnostic circuit 4 and the converter 3. The switching power converter 3 is an electrical device that makes it possible to obtain a DC voltage or a DC current, of different value from FIG. a first voltage, or a first direct current. In a vehicle, it is usually placed between the battery and the electrical equipment. The diagnostic circuit 4 comprises a switch such as a transistor T and a resistance circuit, R1, R2, R3. R1 is connected in parallel with R2, which is connected in series with R3. The switch shown is a transistor T, driven by the output of the components 5, which in case of failure of the bulbs 6, adds the resistor R1 to the resistance circuit R2 and R3, connected to the setpoint of the converter 3. The resistor R4 is mounted in series on the output of the converter 3 to provide the output current regulation.

FIG. 4 shows how the diagnostic outputs d1, d2, coming from the components 5g1 and 5g2, combine to drive the transistor T. The outputs S1 and S2, which supply the left and right front light-emitting diode bulbs respectively, are also observed 6d and 6e. SMARTFET components are low-power components, usually used to protect electronic circuits from excessive temperatures caused by short circuits. According to the invention, they are used for driving the circuits traversed by weak currents. Indeed, these components can make the difference between the absence of signal and the presence of weak currents. There are two types of these components: the analog components, which give a current measurement and the digital components that give here directly the failure information. In the context of the invention, the latter will therefore preferably be used because their signal output, which replicates the value of the signals that supply the bulbs 6, allows direct control of the diagnostic circuit 4.

 The computer 2 receives all the signals from the passenger compartment of the vehicle, including the signals resulting from the operation of the flashing lever. When the turn signal actuator 7, right or left, is actuated to turn on respectively the LED indicators, right front 6a and rear 6b, and left front 6c and rear 6d, the information is transmitted to the device 1.

 The diagnostic circuit 4 (composed of a transistor and three resistors R1 to R3) receives the output signals of the components 5, d1 and d2, ("diagnosis output signal"), and sends its own output signal to the port 3 of the voltage converter 3. The combination of the received signals, d1, d2, from the component 5d, drives the transistor T of the diagnostic circuit 3, which behaves like a switch when it is actuated by a fault signal . The representative signal of good operation (presence of weak current) makes it possible to exclude the resistor R1. The circuit which parallels the resistance R1 to the resistor R2 is then open, and only the resistor R2 is in series with the resistor R3. In case of failure (absence of current), a signal representative of malfunction is sent to the switch T which closes. The resistor R3 is then in series of the set R1, R2 connected in parallel. This circuit closure has the effect of changing the input current of the enabling port 3a of the voltage converter 3 which reacts changing the value of its output accordingly. According to the signal received on its authorization port, the converter 3 controls its output current, towards the computer:

 - In the event of all the indicators running correctly, the inverter circulates a current of a high level. This current simulates a consumption of the two incandescent flashing lights (front and rear) in operation;

- In the event of a flashing lamp failure, the converter modifies the current at its output by raising it to a low level. This current simulates the consumption of a single incandescent flashing lamp in operation. The decrease in consumption signals to the computer, the existence of a failure. The latter alerts the driver of the vehicle, for example by a signal light on the dashboard. In both situations, the current is restored to the on-board vehicle network.

In other words, in the event of a malfunctioning flashing light, the proposed device detects that the current consumed is less than the expected value, and indicates on its output that there is a fault.

 FIG. 5 is a logic diagram of the process in the event of malfunction of a light-emitting diode bulb to the left of the vehicle, front or rear; this process is identical for the right side.

 Computer 2 controls the LED indicators (front, rear and repeater) on the right and left sides of the vehicle. Following the activation of the flashing lever of the vehicle by the driver, the computer activates the turn signals (for example left turn signals). Step A.

 The fault detection is linked to the presence of weak currents in the circuits of the light-emitting diode bulbs: the component 5 concerned recognizes the presence of current and at the output, the signals corresponding to the front and rear turn signals combine. The combined signal is sent into the diagnostic circuit 4. Step B.

 In case of good operation, hypothesis H1, the computer is informed of a high current level, which is the simulated consumption of two incandescent flashing lamps. Step C. The calculator considers that the turn signals work properly. Step D

 When there is failure of at least one flashing hypothesis H2, the voltage converter 3 sends the computer 2, a low level current, simulating the consumption of a single incandescent lamp. Step E

 The decrease in consumption signals to the computer the existence of a malfunction. The warning signal is reproduced on the driver's dashboard. Step F.

The control is the same for the turn signals on the right and left side. In conclusion, the proposed device detects the malfunction of at least one light-emitting diode bulb used in the flashing circuits of a vehicle, and alerts the driver. This result is obtained through the judicious use of a switching converter coupled to SMARTFET-type components, without resorting to the development of new functions in an existing computer, which avoids any additional cost of integration.

Claims

1. Device (1) for controlling the operation of the light-emitting diode lamps (6) in a vehicle having a computer (2) dedicated to the functions of the passenger compartment and to the lamps of the vehicle, characterized in that it comprises at least one low-power component (5d, 5g) which produces low-current output signals (S1, S2, S3, S4) for supplying the light-emitting diode bulbs (6), and which reproduces these signals to a light-emitting circuit diagnostic (4) which controls a switching voltage converter (3) simulating the consumption of at least one incandescent bulb.

2. Control device (1) according to claim 1, characterized in that the switching power converter (3) simulates two different levels of current to the computer according to the good, or the malfunction of the light-emitting diode bulbs. (6).

3. Control device (1) according to claim 1 or 2, characterized in that the simulation of the consumption of incandescent bulbs depends on a regulated current level on the output of the switching power converter (3) thanks to a series resistance (R4) of measurement.

4. Control device (1) according to any one of the preceding claims, characterized in that the switching power converter (3) echoes the current changes received on its authorization port, in its output signal to the computer 2.

5. Control device (1) according to any one of the preceding claims, characterized in that, in the event of proper operation of all the light-emitting diode bulbs (6) of the flashing circuit, the converter (3) simulates the consumption of at least two incandescent lamps.

6. Control device (1) according to any one of the preceding claims, characterized in that in case of malfunction of at least light-emitting diode bulb (6) of the circuit flashers, the converter (3) changes its output value of in order to simulate to the computer the consumption of a single incandescent lamp.

7. Control device (1) according to any one of the preceding claims, characterized in that the diagnostic circuit (4) consists of a resistance circuit downstream of a switch T, whose opening or closing causes a modification of its output current to the switching converter (3).

8. Control device (1) according to any one of the preceding claims, characterized in that the low power component (5) replicates the absence of current in the circuit of a light-emitting diode bulb (6), on its diagnostic output, causing the switch T of the diagnostic circuit (4) to close.

9. Control device (1) according to any one of the preceding claims, characterized in that flashing circuits of a vehicle on the right side and on the left side are applied to the light-emitting diode bulbs (6), by introducing a plurality of components (5) and logic gates.

10. A method of controlling the operation of the light-emitting diode bulb bulbs of a vehicle, with the aid of a device according to one of the preceding claims, characterized in that,

- In the event of the correct operation of all the LED bulbs in the turn signal circuit, the converter (3) causes the device to consume an equivalent of at least two incandescent lamps. - In the event of a malfunction of a light-emitting diode bulb in the turn signal circuit, the converter consumes the equivalent of a single incandescent lamp.

1 1. Control method, according to claim 10, characterized in that the computer informs the driver of the failure of a LED flashing light (6) by sending a signal on the dashboard of the vehicle.