• 专利附录
  • 专利说明
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  • 类似技术
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    • 专利摘要:
    A lighting circuit (2) for flashing a light emitting unit (3) having a plurality of light source systems (PL1 to PL3) is provided with an abnormality detection unit (22) which generates an anomaly information (Sdt, Pdt ') upon detection of an anomaly even in one of the different light source systems (PL1 to PL3), and a holding circuit (23) which maintains the same anomaly information (Pte, Pt ') during a period when the lighting circuit (2) is energized with a blinking signal. The lighting circuit (2) supplies one or more control currents to the different light source systems (PL1 to PL3) according to the blinking signal and ceases to supply one or more control currents to all the source systems of the light source. light (PL1 to PL3) as a function of the anomaly information (Sdt, Pdt ') which is held by the holding circuit (23).
    公开号:FR3046330A1
    申请号:FR1663449
    申请日:2016-12-28
    公开日:2017-06-30
    发明作者:Shinji Ohta
    申请人:Koito Manufacturing Co Ltd;
    IPC主号:
    专利说明:

    TECHNICAL AREA
    The present invention relates to a lighting circuit and a flashing vehicle light.
    PRIOR ART
    Among the vehicle lights, there are the change of direction lights (hereinafter flashing lights) intended to inform nearby drivers, etc.. a next turn to the left or right of the vehicle. And the change of direction lights include those that use multiple light sources such as light-emitting diodes (LEDs).
    For example, JP-A-2015-81000 describes a configuration in which a plurality of light emitting diode group systems are connected to each other in parallel. JP-A-2015-145224 discloses a sequentially illuminated type flashing light in which a plurality of light sources are sequentially illuminated.
    Furthermore, for vehicle lights to be allowed in some countries, their lighting operation must meet various laws of this country. For example, to satisfy the relative laws established in North America, a flashing light must be stopped as a whole even when only a portion of its different light sources have suffered a disconnection failure. For this purpose, it is necessary to use a configuration which ensures execution of a necessary command by detecting a disconnection in each light source before starting a flashing light. However, this raises a problem in that a control circuit is made complex and the size and cost increased.
    To achieve sequential illumination using multiple light sources in a flashing light, there are disconnections of a portion of the light sources in the case where a sequential lighting operation is completed half way or the part of the light sources does not light up. Such an imperfect sequential lighting operation seems bad and lowers the product value and may disable the flashing function. Thus, it is desirable to stop the flashing light as a whole even when only a portion of the light sources have suffered from a disconnection failure. However, as in the case described above, this raises the problem that a control circuit is made complex and the size and cost are increased.
    SUMMARY OF THE INVENTION
    The present invention has been made in the circumstances above, and an object of the present invention is therefore to provide a lighting circuit which is of a simple circuit configuration and can stop a flashing light as a whole in the case of an anomaly such as disconnections of a part of the light sources.
    [Means for solving problems] [0007] The present invention provides a lighting circuit for flashing a light emitting unit having a plurality of light source systems, which includes an abnormality detection unit which generates abnormality information when detecting an anomaly even in only one of the different light source systems, and a holding circuit that maintains the abnormality information during a period when the illumination circuit is powered with a flashing signal. The illumination circuit supplies a control current or currents to the different light source systems according to the blinking signal and ceases to supply current or control currents to all the light source systems in accordance with the anomaly information maintained by the holding circuit.
    If an anomaly such as a disconnection has occurred in even one of the different light source systems (light source elements such as light emitting diodes) that constitute the light emitting unit, all the source systems of light are prevented from being turned on according to the fault information maintained by the holding circuit.
    The above lighting circuit may be such that the abnormality detection unit detects a disconnection in each of the different light source systems which are connected to each other in parallel in the light emitting unit, and generates anomaly information when detecting a disconnection anomaly even in a single one of the different light source systems.
    The term "light source system" means a light source or multiple serially connected light sources that extinguish due to a disconnection of the light source or one of the light sources. Even if part of the parallel-connected light source systems suffer from disconnection, other normal light source systems may light up. However, this lighting circuit prevents other normal light source systems from being turned on.
    The illumination circuit above may further comprise a sequential illumination control unit which delivers a current or control currents to the different light source systems in a progressive manner in a period where it is necessary to blink. the light emitting unit.
    This lighting circuit relates to a case where the different light source systems are lit sequentially, that is to say where sequential illumination is achieved. In this case, if a portion of the light source systems suffer from disconnection, each sequence of a sequential illumination operation is terminated halfway or part of the light source systems does not light up. It is therefore appropriate to prevent other normal light source systems from being turned on.
    The lighting circuit above may be such that the flashing of the light emitting unit is in synchronism with the flashing signal. In this case, the lighting circuit operates according to the flashing signal which indicates a flashing cycle.
    The present invention also provides a vehicle direction change lamp having a direction change light emitting unit having a plurality of light source systems; and any of the lighting circuits above.
    With this configuration, the vehicle direction change light has the function that all light source systems are prevented from being turned on when an anomaly is detected in a portion of the light source systems.
    The present invention can realize a lighting circuit which is of a simple circuit configuration and can stop a lighting unit as a whole in the case of an anomaly such as disconnections of a part of the sources from light. When used as a lighting circuit of a turn signal light, this lighting circuit is suitable for miniaturization of a turntable and cost reduction.
    BRIEF DESCRIPTION OF THE DRAWINGS
    [0013] [Figure 1] Figure 1 is a block diagram showing the configuration of a vehicle light according to a first embodiment of the present invention. [Figure 2] Figures 2A-21 are timing diagrams illustrating how the vehicle light according to the first embodiment is operating.
    [Figure 3] Figure 3 is a block diagram showing the configuration of a vehicle light according to a second embodiment of the present invention.
    [Figure 4] Figs. 4A-4F are timing diagrams illustrating how the vehicle light according to the second embodiment operates.
    [Figure 5] Figure 5 is a block diagram showing the configuration of a vehicle light according to a third embodiment of the present invention.
    DETAILED DESCRIPTION
    [0014] <First embodiment>
    A vehicle light 1 according to a first embodiment will be described with reference to the drawings. The first embodiment relates to a flashing light in which a plurality of light source systems are connected to each other in parallel and all light sources are prevented from lighting when a portion of the light sources has suffered a disconnection. Each of the light source systems connected to each other in parallel means a light source or several light sources connected in series.
    Each of the embodiments relates to the case where the light sources are light emitting diodes. However, in the embodiments, the light sources are not limited to light emitting diodes and may be other semiconductor light emitting devices such as laser diodes or organic light emitting devices. bulb light sources such as incandescent lamps, halogen lamps, discharge lamps, or neon lamps.
    Figure 1 shows the configuration of the vehicle light 1 according to a first embodiment. The vehicle light 1, which is a flashing light, is equipped with a lighting circuit 2 and a direction change light emitting unit 3 (hereinafter referred to as "light emission unit 3"). "). For example, the lighting circuit 2 consists of different electronic components mounted on a lighting stage. The light emitting unit 3 comprises a plurality of light sources (light emitting elements) arranged on a light source board.
    In the embodiment, the light emitting unit 3 has three light source systems PL1, PL2, and PL3 which are connected to each other in parallel. The term "light source system" means a light source or several serially connected light sources that turn off due to a disconnection of the light source or one of the light sources.
    In the PLI light source system, a series connection of light-emitting diodes 3a and 3b exists between a terminal 52 and ground. In the PL2 light source system, a series connection of light emitting diodes 3c and 3d exists between a terminal 53 and ground. In the light source system PL3, a series connection of light emitting diodes 3e and 3f exists between a terminal 54 and ground. The light emitting unit 3 having three light source systems is just one example, it can have two light source systems or four or more light source systems.
    The lighting circuit 2 receives energy from a change of direction fire supply 90. The change of direction fire supply 90 is provided on the vehicle side, and is a unit that delivers a change-over light supply voltage to the lighting circuit 2. The change-over light supply 90 delivers a pulse supply voltage (switch-on power supply voltage) Vt for a direction change flash during a change of direction switching period which is indicated by a change of direction switch signal St.
    The lighting circuit 2 is equipped with a control unit 21, an abnormality detection unit 22, and a holding circuit 23. The control unit 21 is equipped with three units constant current control circuit 11 which correspond to the respective three light source systems PL1, PL2, and PL3. Each constant current control unit 11 comprises a DC-DC converter such as a switching regulator and a regulating control circuit therefor. Each constant current control unit 11 generates an output voltage by performing a voltage conversion on a change of direction lamp supply voltage Vt and causes a control current Id corresponding to the output voltage to flow through the outputs. electroluminescent diodes of the associated light source system.
    The control currents Id are delivered by the constant current control units 11 to the light source systems PL1, PL2, and PL3 through terminals 42, 43, 44 of the lighting circuit 2 and terminals 52, 53. and 54 of the light emitting unit 3, respectively.
    An anomaly information Sdt 'may be input into the terminals 11a of the respective constant current control units 11. For example, each constant current control unit 11 identifies a low level voltage (L level) appearing on its terminal 11a as anomaly information Sdt '. Upon receipt of the fault information Sdt ', each constant current control unit 11 stops constant current control and thereby stops supplying a control current Id to the light emitting unit 3.
    The light emitting unit 3 is equipped with three disconnection detecting units 12 which correspond to the three respective light source systems PL1, PL2, and PL3. Each disconnect detection unit 12 detects a disconnection anomaly, i.e. a state where no control current Id flows in a high level period (level H) of a power supply voltage. change of direction light Vt (i.e. periods when a control current Id should flow through the light emitting unit 3). For this purpose, each disconnection detection unit 12 controls, for example, the output voltage of the corresponding constant current control unit 11.
    Each disconnect detection unit 12 delivers an abnormality detection information Pdt to its output terminal 12a. For example, upon detecting the occurrence of an abnormality in the corresponding light source system PL1, PL2, or PL3, a disconnect detection unit 12 sets the voltage of terminal 12a to a low level.
    The holding circuit 23 maintains (stores) the signal level of the anomaly detection information Sdt generated by a disconnection detection unit 12 of the anomaly detection unit 22 so that it is maintained for at least one flashing instruction period for the light emitting unit 3 (i.e., a period when the control unit 21 receives a pulse power supply voltage of change of direction Vt), and delivers a resultant anomaly detection information Sdt 'to all constant current control units 11 of the control unit 21.
    To perform the above operation, for example, as shown in FIG. 1, the holding circuit 23 consists of a bipolar pnp transistor 17, a MOSFET transistor (metal oxide field effect transistor). semiconductor) 18 (hereinafter referred to as field effect transistor 18), resistors R1 to R5, capacitors C1 and C2, and diodes D1 to D3.
    The emitter of the bipolar transistor 17 is connected to a line having a voltage VI. A parallel connection of the capacitor C2 and the resistor R3 is connected between the emitter and the base of the bipolar transistor 17. The anode of the diode D1 is connected to the collector of the bipolar transistor 17, and the cathode of the diode D1 is connected to the gate of the field effect transistor 18 via the resistor R1. The resistor R2 is connected between the gate of the field effect transistor 18 and the ground, and the capacitor C1 is connected to the resistor R2 in parallel. The drain of the field effect transistor 18 is connected to the base of the bipolar transistor 17 via the resistor R4, and the source of the field effect transistor 18 is grounded.
    The base of the bipolar transistor 17 is connected to the anode of the diode D2 via the resistor R5, and the cathode of the diode D2 is connected to the terminals 12a of all the disconnection detection units 12 of the unit. The drain of the field effect transistor 18 is connected to the cathode of the diode D3, and the anode of the diode D3 is connected to the terminal 11a of all the constant current control units 11. of the control unit 21.
    The holding circuit 23 operates as follows. If at least one of the different disconnect detection units 12 of the abnormality detection unit 22 detects a disconnection, the terminal 12a of this disconnection detection unit 12 is set low. In response, a base current flows through the bipolar transistor 17 and the bipolar transistor 17 is turned on. Thus, a charging current flows in the capacitor C1 via the path of the diode DI and the resistor R1. As the charge of the capacitor C1 progresses, the gate voltage of the field effect transistor 18 exceeds its threshold voltage at a certain time and the field effect transistor 18 is turned on. As a result, a current flows along the path of the diode D3 and the field effect transistor 18, so that the terminals 11a of the constant current control units 11 are set low. This state is maintained until the gate voltage of the field effect transistor 18 is lowered by a discharge of the capacitor C1 and the field effect transistor 18 is turned off after high voltage return of the terminal 12a. of the disconnection detection unit 12 which detected the disconnection. That is, if even a disconnect detection unit 12 generates anomaly detection information Sdt (i.e., the voltage of terminal 12a is set low) , anomaly information Sdt 'obtained by maintaining the signal level of the anomaly detection information Sdt is transmitted to all the constant current control units 11 of the control unit 21. In response, all the constant-current control units 11 of the control unit 21 stop supplying control currents Id to the light-emitting unit 3.
    The manner in which the vehicle light 1 according to the first embodiment operates will be described with reference to Figs. 2A-21 using comparative examples. Fig. 2A shows flashing instruction periods Tt which are determined by a change of direction switch signal S1. The change of direction switch signal S 1 is a signal which specifies periods of flashing of the vehicle light 1 which is a flashing light, and is delivered to the turn signal light supply 90 in response to a manipulation of a turn indicator lever or a hazard indicator switch by a driver. In FIGS. 2A-21, the flash instruction periods Tt during which the flashing light must flash are the period of time t1 at time t2 and the period after time t3.
    FIG. 2B shows the change of direction fire supply voltages Vt which are supplied by the change-over light supply 90 to the lighting circuit 2. The change-over light supply 90 delivers, in each flicker instruction period Tt, a change-over light supply voltage Vt which consists of pulses whose cycle is equal to a flicker cycle and which have, for example, a duty cycle of 50% .
    It is assumed that a disconnection occurs in one of the light source systems PL1, PL2, and PL3 at time tx.
    Figure 2C shows a pulse waveform indicating the ON / OFF states of the light source system when disconnection occurs. This light source system flashes according to the changeover light supply voltage Vt up to time tx. After the onset of the time tx disconnection, this light source system is naturally kept stopped regardless of the value of the change of direction fire supply voltage Vt.
    Lighting modes in which the other light source systems, ie normal non-disconnected light source systems, the embodiment and the comparative examples operate in this situation will be described below. Fig. 2D, 2E, 2H, and 21 also show pulse waveforms indicating ON / OFF states.
    First, Figure 2D shows a lighting mode of a case where no particular measure is taken for the detection of a disconnection (Comparative Example I). For example, this is a case where the different light source systems PL1, PL2, and PL3 are connected to each other in parallel as shown in FIG. anomaly detection 22 nor the holding circuit 23 is provided.
    Since the PLI, PL2, and PL3 light source systems are parallel to each other, even if a light source system suffers from disconnection, Id control currents continue to flow through the other systems. of normal light source. Thus, as shown in Fig. 2D, normal light source systems continue to flash during the blink instruction period Tt. However, this operation does not satisfy the relative laws established in North America.
    FIG. 2E shows a comparative example II in which none of the light source systems PL1 to PL3 are lit during the detection of a disconnection in a certain light source system and no function similar to the function of the holding circuit 23 used in the embodiment is provided. The disconnection detection unit 12 corresponding to the light source system where the disconnection has occurred delivers anomaly detection information Pd as shown in Fig. 2F. This lighting mode can be considered as a mode in which this anomaly detection information Sdt is delivered to all constant current control units 11 as it is.
    This causes the normal light source systems to operate in the lighting mode shown in Fig. 2E. That is, they are stopped with a short delay after the disconnect is detected at time tx. In the remaining portion of the flash instruction period Tt, the disconnection is detected in the same light source system, the constant current control unit 11 receives anomaly detection information Sdt, and no PLI to PL3 light source systems are turned on. However, normal light source systems are turned on instantly during the delay period. In this way, in normal light source systems, instantaneous light emission occurs repeatedly in the flash cycle in each flash instruction period Tt. Thus, Comparative Example II does not satisfy the relative laws established in North America either.
    Figure 21 shows a comparative example III in which all light source systems PL1 to PL3 are kept stopped after detection of a disconnection in a certain light source system. For example, an occurrence / non-occurrence of a disconnection is detected in each light source system before a start of the illumination (for example in a rising edge of a Vt changeover supply voltage) . If a disconnect failure is detected even in a light source system, all PLI to PL3 light source systems are prevented from being turned on. This operation satisfies the relative laws. However, to implement this way of detecting disconnection, a complicated control circuit and a large lighting circuit are necessary and an increase in cost is inevitable.
    Because of the foregoing, in the embodiment, with the configuration shown in Fig. 1, each normal light source system operates in an illumination mode shown in Fig. 2H.
    It is assumed that a disconnection occurs in the PLI light source system at time tx. As a result, as shown in Fig. 2F, low level anomaly detection information Sdt is produced at time tx. Since the disconnect detection unit 12 sets the voltage of the terminal 12a low by detecting that no control current Id flows during the period when a control current Id should be delivered (i.e. the run period of the blink instruction period Tt), the fault detection information Pd continues to appear as a low level voltage during the run period with a short time delay.
    This anomaly detection information Sdt is kept low for a certain time because of the above-described operation of the holding circuit 23, and the resulting anomalous detection information Sdt 'shown in FIG. delivered to the constant current control units 11.
    While the low level fault information Sdt 'continues, the constant current control unit 11 corresponding to the normal light source systems PL2 and PL3 performs a current output stop command, so that the PL2 and PL3 light source systems are kept stopped.
    As a result, when a disconnection occurs in the PLI light source system, the normal light source systems PL2 and PL3 operate in the illumination mode shown in Fig. 2H. Thus, once the light source systems PL2 and PL3 are extinguished with the short time delay with respect to the time tx, they are kept stopped until the end of the flash instruction period Tt without any emission of instant light.
    In the next flash instruction period Tt from time t3, the normal light source systems PL2 and PL3 are lit for a short time (instantaneously) because Id control currents flow through them to that the anomaly detection information Pdt is first set low. However, the PL2 and PL3 light source systems are then kept stopped, i.e., during the remainder of the flicker instruction period Tt. Thus, an operation is performed where none of the PLI, PL2, and PL3 light source systems are turned on after detecting a disconnection even in part of them.
    To perform the above operation, the holding circuit 23 generates anomaly information Sdt 'while maintaining the signal level of the anomaly detection information Sdt generated by a disconnection detection unit. 12 of the abnormality detection unit 22 so that it is maintained at least during a flash instruction period Tt. In the example of FIG. 2H, the time constant circuit (C1 and R2) is assumed such that the signal level of the anomaly detection information Sdt is maintained for a time ti. It is sufficient for this time constant circuit to be designed so that the on state of the field effect transistor 18 can be maintained for at least one period (period tq) which is the low level period of the voltage of change of direction light supply Vt plus delay relative to detection from disconnection to stop of control current Id, after switching of anomaly detection information Pte from low level to high level .
    [0032] <Second embodiment>
    Figure 3 shows the configuration of a vehicle light IA according to a second embodiment. The components that are the same as in Figure 1 carry the same references, and descriptions of these will be omitted. The vehicle light IA shown in Figure 3 is a flashing light in which a sequential illumination is achieved.
    In this embodiment, a light emitting unit 3A is a series connection of six light emitting diodes 3a to 3f. When all the light-emitting diodes 3a to 3f are lit, a control current Id flows from a control unit 21A to the light-emitting diodes 3f, 3e, 3d, 3c, 3b, and 3a in that order.
    Since the light-emitting diodes 3a to 3f are connected to each other in series and form part of the same system, a control circuit 21A has only a constant current control unit 11. An abnormality detection unit 22A detects a disconnection anomaly in light-emitting diodes 3a to 3f. Since the light-emitting diodes 3a to 3f are connected to each other in series and form part of the same system, the abnormality detection unit 22A has only one disconnection detecting unit 12 for monitoring the output of the constant current control unit 11.
    The holding circuit 23 has the same configuration as in the first embodiment. The holding circuit 23 maintains, for a prescribed time, the signal level of the anomaly detection information Sdt appearing on the terminal 12a of the disconnection detection unit 12 of the anomaly detection unit 22A. , and outputs a resultant anomaly information Sdt 'to the terminal 11a of the constant current control unit 11. The constant current control unit 11 stops the output of a control current Id in response to the anomaly information Sdt '.
    The terminals 61-67 are terminals provided on the side of the lighting circuit 2A and the terminals 71 to 77 are terminals provided on the side of the light emitting unit 3A. The terminals 61 and 71 are connected to each other, the terminals 62 and 72 are connected to each other, the terminals 63 and 73 are connected to each other, the terminals 64 and 74 are connected to each other, the terminals 65 and 75 are connected to each other, the terminals 66 and 76 are connected to each other, and the terminals 67 and 77 are connected to one another. one to another.
    The cathode of the light-emitting diodes 3a and the terminals 61 and 71 are grounded. The anode of the light-emitting diodes 3a and the cathode of the light-emitting diodes 3b are connected to the terminal 72, the anode of the light-emitting diodes 3b and the cathode of the light-emitting diodes 3c are connected to the terminal 73, the anode of the light-emitting diodes 3c and the cathode of the light-emitting diodes 3d are connected to the terminal 74, the anode of the light-emitting diodes 3d and the cathode of the light-emitting diodes 3e are connected to the terminal 75, and the anode of the light-emitting diodes 3e and the cathode of the light-emitting diodes 3f are connected to the terminal 76. The anode of the light-emitting diodes 3f is connected to the terminal 77.
    The lighting circuit 2A is equipped with a sequential lighting control unit 24 having a bypass switching unit 13 and a switching control unit 14.
    In the branch switching unit 13, switches 13a to 13f that use a MOSFET, for example, are connected to each other in series. The switch 13a is connected between the terminals 61 and 62, the switch 13b is connected between the terminals 62 and 63, the switch 13c is connected between the terminals 63 and 64, the switch 13d is connected between the terminals 64 and 65, the switch 13e is connected between the terminals 65 and 66, and the switch 13f is connected between the terminals 66 and 67. Connected in this manner, the switches 13a to 13f are branches of the light emitting diodes 3a to 3f, respectively.
    The switching control unit 14 controls the switches 13a to 13f for high level periods of each pulse-change voltage supply voltage Vt which lasts a flash instruction period Tt (see FIG. 4A) of the flashing light. For example, the switching control unit 14 controls the switches 13a to 13f in the following manner (periods (1) to (6)) as a function of the timing signals that are generated based on each pulse of each voltage. Pulsing pulse power supply Vt. In the initial state in which none of the light emitting diodes 3a to 3f are lit, the switching control unit 14 turns on all the switches 13a to 13f. (1) stops the switch 13a; the light-emitting diode 3a is on. (2) stops the switch 13b; the light-emitting diodes 3a and 3b are lit. (3) stops the switch 13c; the light-emitting diodes 3a to 3c are lit. (4) stops the switch 13d; the light-emitting diodes 3a to 3d are lit. (5) stops the switch 13e; the light-emitting diodes 3a to 3e are lit. (6) stops the switch 13f; all light-emitting diodes 3a to 3f are lit.
    As described above, the switches 13a to 13f are stopped in the order indicated by the arrow DSK in each period when the constant current control unit 11 is supplied with the high voltage voltage of a voltage Vt direction change power supply and thus delivers a control current Id, so that a sequential illumination is achieved.
    In the above configuration, if even a single light-emitting diode suffers from a disconnection failure, each sequence of a sequential illumination operation is terminated half-way. For example, it is assumed that a disconnection occurred in light emitting diode 3c. In this case, a control current
    Id flows during periods (1) and (2) because the switch 13c corresponding to the light emitting diode 3c is on. However, a control current Id does not flow and the light emitting unit 3 is not lit as a whole during the period (3). Each sequence of the sequential directional change illumination operation is completed halfway and the sequential directional change illumination operation appears very poor.
    Due to the foregoing, in the embodiment, anomaly information Sdt 'is supplied to the constant current control unit 11 from the hold circuit 23 which deals with the detection information. anomaly Pte, so that a wrong operation of sequential directional change lighting is avoided.
    The manner in which the vehicle light IA according to the second embodiment operates will be described with reference to Figs. 4A-4F using a comparative example. Like FIGS. 2A and 2B, FIGS. 4A and 4B show flashing instruction periods Tt and the changeover light supply voltages Vt, respectively.
    Fig. 4C shows a lighting mode of a case where each sequence of a sequential illumination operation is completed half way as described above (Comparative Example I). Each of the steps shown in Fig. 4C means an additional ignition of a light emitting diode. It is assumed that the light-emitting diode 3c suffers from a disconnection failure at time tx. After the occurrence of the disconnection failure, an operation where light-emitting diodes are lit only during periods (1) and (2) is repeated.
    The same lighting mode as shown in Fig. 4C occurs in a case where anomaly detection information Sdt is supplied to the constant current control unit 11 as it is. This is because anomaly detection information Sdt is kept low for periods (3) - (6) and returns to the high level before a start of the next sequence.
    In the embodiment, anomaly information Sdt '(see FIG. 4E) is generated by the holding circuit 23 by processing the anomaly detection information Sdt (see FIG. 4D). and is supplied to the constant current control unit 11, so that an illumination mode shown in Fig. 4F is realized. More particularly, assuming that the light emitting diode 3c suffers from a time-out disconnection tx, a sequential illumination operation is continued until time tx and none of the light-emitting diodes 3a-3f are subsequently lit due to the fact that anomaly information Pdt '(see Fig. 4E) causes the constant current control unit 11 to stop the output of a control current Id [0041] During the next flash instruction period Tt (starting at the time t3) after detecting the disconnection, light-emitting diodes are normally lit in periods (1) and (2), i.e. until abnormality detection information Sdt is first leveled down. However, since a disconnection failure is detected in the period (3), none of the light emitting diodes 3a to 3f are lit during the period (3). Thus, the second embodiment is devoid of a case where an incomplete lighting sequence which is caused by disconnections of a portion of the light emitting diodes 3a to 3f is repeated.
    [0042] <Third embodiment>
    Figure 5 shows the configuration of a vehicle light IB according to a third embodiment. The vehicle light IB shown in Figure 5 is a flashing light in which a sequential illumination is performed as in the second embodiment. In this embodiment, light emitting diodes 3a to 3f are connected to each other in parallel and constitute respective light source systems PL1 to PL6.
    A control unit 21B is equipped with six constant current control units 11 which correspond to the six respective light source systems PL1 to PL6. An abnormality detection unit 22B is provided with six disconnect detection units 12 for monitoring the outputs of the constant current control units 11, respectively.
    As in the first embodiment, even if only one disconnect detection unit 12 detects a disconnection anomaly, the voltage of its terminal 12a is set low and low level anomaly detection information is detected. input to a holding circuit 23. The anomaly information Sdt 'obtained by maintaining the signal level of the abnormality detection information Sdt is supplied to all the constant current control units 11.
    Terminals 81 to 86 on the lighting circuit side are provided to correspond to the respective light source systems PL1 to PL6, and are connected to terminals 91 to 96 of the corresponding light emitting unit side 3B. one by one. The terminals 91 to 96 are connected to the anodes of the light emitting diodes 3a to 3f, respectively, and the cathodes of the light emitting diodes 3a to 3f are grounded.
    The lighting circuit 2B is equipped with a sequential lighting control unit 25 having a sequential switching unit 15 and a switching control unit 16. The sequential switching unit 15 is equipped with switches 15a. at 15f which uses a MOSFET transistor, for example. The switch 15a turns on or off the control power supply Id of the light source system PLI. Likewise, the switches 15b to 15f turn on or off the control current supply Id of the light source systems PL2 to PL6, respectively.
    The switching control unit 16 performs a switch-on command of the switches 15a to 15f in the order indicated by the arrow DSK in each high-level period of each pulse-change pulse power supply voltage. direction Vt (ie each blink instruction period Tt of the flashing light). As a result, sequential light is produced in such a way that the start of the light-emitting diode 3a, the start of the light-emitting diodes 3a and 3b, the starting of the light-emitting diodes 3a to 3c, the setting of in operation of the light-emitting diodes 3a to 3d, the starting of the light-emitting diodes 3a to 3e, and the starting of all the light-emitting diodes 3a to 3f occur in this order.
    When a sequential illumination operation is performed, even if only one light emitting diode suffers from a disconnection failure, each sequence of the sequential illumination operation misses the start of the light emitting diode 3c; that is to say that the start of the light emitting diode 3a, the start of the light emitting diodes 3a and 3b, the start of the light emitting diodes 3a and 3b (the light emitting diode 3c is not lit) , switching on the light-emitting diodes 3a to 3d excluding the light-emitting diode 3c, switching on the light-emitting diodes 3a to 3e excluding the light-emitting diode 3c, and switching on the light-emitting diodes 3a at 3f excluding light-emitting diode 3c occur in this order. This sequential change of direction lighting operation seems very bad.
    Due to the foregoing, in the embodiment, anomalous information Sdt 'is supplied by the holding circuit 23 to the entire constant current control unit 11 so that none of the light-emitting diodes 3a to 3f are not lit if a disconnection failure is detected even in one of the light-emitting diodes 3a to 3f. For this purpose, the disconnect detection units 12, the holding circuit 23, and the constant current control units 22 operate in the same manner as in the first embodiment. As a result, a sequential lighting operation that looks bad is avoided.
    [0048] <Abstract>
    In each of the first to third embodiments described above, the lighting circuit 2, 2A, or 2B brings the light emitting unit 3, 3A, or 3B having the different light sources (light-emitting diodes 3a). to 3f) to flash. The illumination circuit 2, 2A, or 2B is equipped with the anomaly detection unit 22, 22A or 22B to generate anomaly detection information Pdt by detecting an abnormality even in one of the different light sources and the holding circuit 23 for holding the signal level of the abnormality detection information Pt during each period when a flashing signal (Vt fire supply voltage) is issued. While one or more control currents Id are delivered to the different light sources as a function of the flashing signal (supply voltage of the change-over light Vt), each light source is prevented from being supplied with a current Id control in response to the anomaly information Sdt 'which is maintained by the holding circuit 23. More particularly, the control unit 21, 21A, or 21B delivers one or more Id control currents to different sources of light, and stops supplying a control current Id to each light source in response to the fault information Sdt 'held by the holding circuit 23.
    If an anomaly such as a disconnection is detected even in a single light source of the light emitting unit 3, 3A, or 3B comprising the different light sources (light-emitting diodes 3a to 3f), all the sources of light light are prevented from being lit. For this purpose, the control unit 21, 21A, or 21B prevents the switching on of all the light sources in response to anomalous information Sdt 'delivered from the holding circuit 23. In this way, can realize the lighting circuit 1, IA, or IB having a simple configuration that prevents normal light sources from being lit instantly in each switching period in the direction of change of direction (flashing period). This promotes miniaturization and cost reduction of lighting circuits.
    In the first and third embodiments, the abnormality detection unit 22 or 22B detects a disconnection in each of the different light source systems (PL1 to PL3 or PLI to PL6) and generates information. of anomaly detection Pte if there is detection of a disconnection anomaly even in a single light source system. Although some of the different light source systems that are connected to each other in parallel suffer from disconnection, the other light source systems can be turned on. However, other normal light source systems are also prevented from being turned on. In this way, an operation can be carried out in which all the light source systems are prevented from being switched on when a part of them is disconnected. This operation satisfies, for example, the relative laws established in North America.
    In the second and third embodiments, the sequential illumination control unit 24 (the bypass switch 13 and the switch control unit 14) or the sequential illumination control unit is provided. 25 (the sequential switching unit 15 and the switching control unit 16) which causes one or more control currents Id to flow from the control unit 21 or 21B to the various light sources of the unit light emission 3 or 3B in a progressive manner in each flash period.
    Due to the sequential illumination configuration in which the different light source systems are sequentially lit, if a portion of the different light source systems suffer from disconnection, each sequence of a sequential illumination operation is completed halfway or the part of the different light source systems does not turn on. Because of this, other normal light source systems are also prevented from being turned on. In this way, an event can be avoided where a sequential illumination operation that appears to be bad is performed when a portion of the light source systems have suffered a disconnection. The value of the product (fire) can thus be increased.
    In each embodiment, receiving Vt direction change power supply voltages which are a blinking signal, the lighting circuit 2, 2A, or 2B brings the light emission unit. 3, 3A, or 3B flashing in synchronism with the flashing signal. More particularly, by receiving pulsed directional changeover light supply voltages Vt for a change of direction flash, the control unit 21, 21A, or 21B delivers one or more control currents Id to the light emitting unit 3, 3A, or 3B based on the pulsed Vt pulse changeover power supply voltages.
    Since the flashing cycle is determined by the pulses of the Vt light change supply voltages, the lighting circuit 2, 2A, or 2B does not need to control the flashing light change cycle. direction, which is preferable for the simplification of the configuration of the lighting circuit 2, 2A, or 2B.
    In each embodiment, the holding circuit 23 maintains the abnormality information signal level Sdt 'to be delivered to the control unit 21, 21A, or 21B by means of the time constant circuit. . Since the abnormality information signal level Sdt 'is stored for a prescribed time using the time constant circuit, the holding circuit 23 may consist of a simple circuit without using a timer, a counter, or equivalent.
    Although the anomaly detection unit 22, 22A, or 22B has the disconnection detection units 12, it may be provided with short-circuit detection units for detecting a short circuit anomaly. in the light emitting unit 3, 3A, or 3B instead of or in addition to the disconnection detecting units 12. That is, it is also possible to form a lighting circuit which prevents all light sources from being turned on when a portion of the light sources is rendered incapable of lighting due to a short circuit fault.
    Although in each embodiment the lighting circuit 2, 2A, or 2B is powered with a flash signal (Vt of the changeover light supply voltage Vt) from the outside, a blinking signal can be generated by a signal generation circuit provided within the lighting circuit 2, 2A, or 2B. In this case, the lighting circuit 2, 2A, or 2B can be configured in such a way that it receives a lighting instruction signal (for example a battery voltage) as a signal for the blinking of the light. light emitting unit 3, 3A, or 3B and the signal generating circuit generates a flashing signal only during periods when the lighting instruction signal is received.
    The lighting circuit according to the present invention can be applied not only to vehicle direction change lights but also to various other lights that flash like traffic lights installed near the roads and display lights installed. in buildings and vehicles.
    权利要求:
    Claims (5)
    [1" id="c-fr-0001]
    A lighting circuit (2) for flashing a light emitting unit (3) having a plurality of light source systems (PL1 to PL3; PLI to PL6), characterized in that it comprises: a an abnormality detection unit (22) which generates anomaly information (Sdt, Sdt ') upon detection of an anomaly even in only one of the different light source systems (PLI to PL3; PLI to PL6); and a holding circuit (23) which maintains the abnormality information (Sdt, Sdt ') during a period when the lighting circuit (2) is supplied with a flashing signal, wherein: the lighting circuit (2) supplies a control current or currents (Id) to the different light source systems (PL1 to PL3; PLI to PL6) as a function of the flashing signal and stops supplying a control current or currents (Id) to all the light source systems (PL1 to PL3, PLI to PL6) as a function of the anomaly information (Sdt, Sdt ') held by the holding circuit (23).
    [2" id="c-fr-0002]
    The lighting circuit (2) according to claim 1, wherein the abnormality detecting unit (22) detects a disconnection in each of the different light source systems (PL1 to PL3; PLI to PL6) which are connected to each other in parallel in the light emitting unit (3), and generates anomaly information (Sdt, Sdt ') upon detection of a disconnection anomaly even in only one of the different light source systems (PL1 to PL3, PLI to PL6).
    [3" id="c-fr-0003]
    The illumination circuit (2) according to claim 1 or 2, further comprising a sequential illumination control unit (21) which supplies a control current or currents (Id) to the different light source systems ( PL1 to PL3; PLI to PL6) progressively in a period where the light emission unit (3) must be flashed.
    [4" id="c-fr-0004]
    4. Lighting circuit (2) according to any one of claims 1 to 3, wherein the lighting circuit (2) blinks the light emitting unit (3) in synchronism with the blinking signal. .
    [5" id="c-fr-0005]
    A vehicle flashing light characterized in that it comprises: a direction change light emitting unit (3) having a plurality of light source systems (PL1 to PL3; PLI to PL6); and the lighting circuit (2) according to any one of claims 1 to 4.
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    同族专利:
    公开号 | 公开日
    JP6800581B2|2020-12-16|
    US20170182941A1|2017-06-29|
    FR3046330B1|2020-11-20|
    US10081301B2|2018-09-25|
    JP2017119449A|2017-07-06|
    CN107105537B|2019-01-18|
    DE102016226260A1|2017-06-29|
    CN107105537A|2017-08-29|
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    法律状态:
    2017-10-27| PLFP| Fee payment|Year of fee payment: 2 |
    2017-12-29| PLSC| Publication of the preliminary search report|Effective date: 20171229 |
    2018-10-29| PLFP| Fee payment|Year of fee payment: 3 |
    2019-10-31| PLFP| Fee payment|Year of fee payment: 4 |
    2020-10-29| PLFP| Fee payment|Year of fee payment: 5 |
    2021-11-15| PLFP| Fee payment|Year of fee payment: 6 |
    优先权:
    申请号 | 申请日 | 专利标题
    JP2015255865A|JP6800581B2|2015-12-28|2015-12-28|Lighting circuit, turn signal lamp for vehicles|
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