JP2010153343A - Lighting fixture for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To certainly detect a fault of a cooling fan. <P>SOLUTION: A lighting fixture for vehicle 1 includes: light source units 30-1 to 30-N respectively having LEDs 40-1 to 40-N; the cooling fan 50 for cooling the LEDs 40-1 to 40-N; and a control unit 10 that controls a fan driving current for driving the cooling fan 50 and a current for driving the light sources and that includes a control part 18 performing determination processing about the cooling fan 50. The control part 18 receives a pulse signal transmitted from the cooling fan 50 and synchronized with a rotational frequency of the cooling fan 50, and determines that the cooling fan 50 is faulty when a high-level period or a low-level period in a single cycle of the pulse signal is at least equal to or longer than a first time period. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a technical field for controlling driving of a cooling fan that suppresses heat generation of a semiconductor light source in a vehicular lamp.

  In general, a vehicular lamp includes a plurality of light source units each having a light emitting diode (LED) as a semiconductor light source and a current supply unit that supplies a drive current to the LEDs, and a plurality of light source units via power lines. And a control unit having a plurality of switch means for controlling the dimming of each LED and a control unit for controlling on / off of each switch means, and a cooling fan for cooling the LEDs.

  The cooling fan has a function of preventing high temperature of the LED due to heat generated from the LED by sending wind generated by rotation of the propeller in the cooling fan to the LED side (see, for example, Patent Document 1).

  The control unit controls turning on and off of the LEDs and dimming, and also controls the rotational drive of the cooling fan.

JP 2001-216803 A

  By the way, if the number of rotations of the cooling fan decreases due to deterioration over time, or if the rotation stops for some reason, the drive current to the cooling fan decreases and the number of rotations decreases. The function to prevent is reduced.

  The above-described conventional vehicular lamp does not have a function of detecting an abnormality of the cooling fan based on a factor indicating an abnormal state of the cooling fan, for example, the number of rotations of the cooling fan. It cannot be detected.

  Therefore, an object of the present invention is to reliably detect an abnormality in a cooling fan.

  A vehicular lamp according to an aspect of the present invention includes a light source unit including a semiconductor light source and a current supply unit that supplies a light source driving current to the semiconductor light source, a cooling fan that cools the semiconductor light source, and the cooling fan. A control unit including a control unit that controls the fan driving current to be driven and the light source driving current and performs a determination process on the cooling fan, and the control unit is sent from the cooling fan and is connected to the cooling fan. A pulse signal synchronized with the rotational speed is received, and when the high level period or low level period in one cycle of the pulse signal is at least the first time or more, it is determined that the cooling fan is abnormal It is.

  Therefore, whether or not the cooling fan is abnormal is determined based on the length of the high level period or the low level period in one cycle of the pulse signal sent from the cooling fan.

  The vehicle lamp according to the present invention includes a light source unit having a semiconductor light source and a current supply unit that supplies a light source driving current to the semiconductor light source, a cooling fan that cools the semiconductor light source, and a fan drive that drives the cooling fan. And a control unit including a control unit that controls the current and the light source driving current and performs a determination process on the cooling fan, and the control unit is sent from the cooling fan and synchronized with the number of rotations of the cooling fan. When the high-level period or the low-level period in one cycle of the pulse signal is at least the first time or more, it is determined that the cooling fan is abnormal.

  Therefore, the abnormality of the cooling fan can be reliably detected.

  In the invention described in claim 2, the control unit repeatedly performs the determination process, and the control unit determines whether the cooling fan is abnormal. Since it is determined that the cooling fan is normal when the low level period is shorter than the second time shorter than the first time, an abnormality of the cooling fan can be reliably detected.

  In the invention described in claim 3, the high-level period or the low-level period in one period of the pulse signal is measured a predetermined number of times in a predetermined period, and the control unit is configured to receive the Mth (M is 2). (The integer) The cooling fan is abnormal when the high level period or the low level period measured at the time is longer than the high level period or the low level period measured at the (M-1) th time, respectively. Therefore, it is possible to reliably detect an abnormality due to deterioration with time of the cooling fan.

  In the invention described in claim 4, when it is determined that the cooling fan is abnormal, an abnormality flag indicating abnormality is stored in the storage unit of the control unit and counted up, and the count value is Since the notification signal having the abnormality flag is sent from the control unit when the predetermined threshold value or more is reached, it is possible to improve the accuracy of the cooling fan abnormality detection and the notification accuracy.

  In the invention described in claim 5, when it is determined that the cooling fan is abnormal or normal, an abnormality flag indicating abnormality or a normal flag indicating normal is stored as a determination flag in the control unit. Is counted up to a predetermined count value determined in advance, and the control unit determines whether the determination flag is the abnormal flag or the normal flag for each count, and the total count When the ratio of the number of the abnormality flags to the number exceeds a predetermined ratio, a notification signal having the abnormality flag is transmitted from the control unit.

  Accordingly, it is possible to further improve the accuracy of detecting the abnormality of the cooling fan.

  Embodiments of the vehicular lamp according to the present invention will be described below. FIG. 1 is a diagram showing a circuit configuration of a vehicular lamp according to an embodiment of the present invention.

  The vehicular lamp 1 includes a control unit 10, N (N is an integer of 1 or more) light source units 30-1 to 30 -N, and a cooling fan 50.

  The control unit 10 includes an input circuit 15, a control unit 18, a constant voltage circuit 19 that supplies a fan driving current Sf to the cooling fan 50, and N switch elements SW- 1 to SW-N. ing. The control unit 18 includes a CPU (Central Processing Unit) 16 that sends on / off signals to the switch elements SW-1 to SW-N and the switch elements (not shown) of the constant voltage circuit 19, and a memory (not shown). ).

  The input circuit 15 mainly includes a noise filter and a surge protection element (surge absorber / power Zener) such as a dump surge. Therefore, application of an overvoltage surge to the cooling fan 50 can be prevented. As the switch elements SW-1 to SW-N, it is preferable to use semiconductor elements such as FETs (Field effect transistors) and IGBTs (Insulated Gate Bipolar Transistors).

The control unit 10 is provided with power terminals 21 and 23, a signal input terminal 25, (N + 1) power output terminals 35-1 to 35- (N + 1), and a power output terminal 36 on the GND (ground) side. . The power supply terminal 21 is connected to the plus terminal of an in-vehicle battery (DC power supply) mounted on the vehicle via the power input terminal 20, and the power supply terminal 23 is connected to the minus terminal of the in-vehicle battery via the power input terminal 22 ( GND). The signal input terminal 25 is connected to a communication signal input terminal 24, and communication signals with a control device (not shown) for controlling various functions attached to the vehicle are input to and output from the communication signal input terminal 24. It has become so. N power output terminals 35-1 to 35-N are connected to N switch elements SW-1 to SW-N, respectively. The constant voltage circuit 19 is turned on / off in response to an on / off signal from the CPU 16. It has a switch element (not shown) and is connected to the cooling fan 50 via a power supply output terminal 35- (N + 1).

  Each of the light source units 30-1 to 30-N includes a switching regulator 32-1 to 32-N as a current supply unit, a control circuit 33-1 to 33-N, and a light emitting diode (LED: Light) as a semiconductor light source. Emitting Diode) 40-1 to 40-N. The switching regulators 32-1 to 32-N include a transformer or a coil, a capacitor, a diode, and an NMOS (Negative channel Metal Oxide Semiconductor) transistor. The LEDs 40-1 to 40-N are used as light sources for various vehicle lamps such as a headlamp, a stop & tail lamp, a fog lamp, and a turn signal lamp.

  Each switching regulator 32-1 to 32-N has a function of supplying a drive current S1 to the LEDs 40-1 to 40-N, respectively. Inside the switching regulators 32-1 to 32-N, shunt resistors (not shown) are provided as circuit elements for detecting currents supplied to the LEDs 40-1 to 40-N and controlling the current values. Is provided.

  Each control circuit 33-1 to 33-N controls the drive current S1 supplied to each LED 40-1 to 40-N so that the voltage across the shunt resistor is constant.

  The light source units 30-1 to 30-N are provided with input terminals 45-1 to 45-N, respectively. The input terminals 45-1 to 45-N are connected to power supply output terminals 35-1 to 35-N, respectively. The light source units 30-1 to 30-N are provided with input terminals 46-1 to 46-N, respectively. The input terminals 46-1 to 46-N are connected to the power output terminal 36.

  The two input terminals of the cooling fan 50 are connected to the power output terminal 35- (N + 1) and the power output terminal 36 via the signal line L2 and the signal line L1, respectively.

  When an ON signal is sent from the CPU 16 to the N switch elements SW-1 to SW-N and the switch elements of the constant voltage circuit 19, the switch elements SW-1 to SW-N and the switch elements of the constant voltage circuit 19 are turned on. The driving current S2 is supplied to each of the switching regulators 32-1 to 32-N, and at the same time, the fan driving current Sf is supplied to the cooling fan 50 via the signal line L2.

  When the driving current S2 is supplied to each of the switching regulators 32-1 to 32-N, the LED driving current S1 is supplied to the LEDs 40-1 to 40-N, and the LEDs 40-1 to 40-N are turned on. When the fan drive current Sf is supplied to the cooling fan 50, the cooling fan 50 is driven to rotate. The driving and stopping of the cooling fan 50 are controlled by turning on and off the switching elements of the constant voltage circuit 19 based on programs stored in the memory of the control unit 18, respectively. The rotational speed of the cooling fan 50 may be controlled by turning on / off the switching element of the constant voltage circuit 19 at a high speed and changing the duty ratio of on / off.

While the cooling fan 50 is driven to rotate, an FG signal S _FG (Frequency Generator Signal) is detected. The FG signal S _FG is a pulse signal synchronized with the number of revolutions of the cooling fan 50 and is input to the CPU 16 via the FG signal line L3 and used for detecting an abnormality of the cooling fan 50.

The FG signal S _FG becomes a high level or a low level when the rotor (not shown) of the cooling fan 50 stops (locks) as the rotation speed of the cooling fan 50 decreases and the high level period or the low level period becomes longer. The signal is fixed to.

  Below, the 1st example of the abnormality detection process of the abnormality detection program memorize | stored in the memory of the control part 18 is demonstrated with reference to the flowchart of FIG.

  First, it is determined whether or not there is an operation (rotation drive) instruction for the cooling fan 50 (step S101). If there is an operation instruction for the cooling fan 50, it is determined whether or not a predetermined time has elapsed since the cooling fan 50 started to rotate (step S102). The reason why the determination in step S102 is performed is that the rotational speed of the cooling fan 50 gradually increases from the start of driving to the steady rotational speed, and thus the cooling fan from the start of driving to the steady rotational speed. This is because 50 may be determined to be abnormal (incorrect determination). Therefore, when the predetermined time corresponding to the time until the rotation speed of the cooling fan 50 reaches the steady rotation speed has not elapsed (No in step 102), the abnormality detection process is not executed.

After the elapse of a predetermined time, the FG signal S _FG is detected every predetermined period to determine whether the FG signal S _FG is at a high level or a low level (step S103). If the FG signal S _FG is at a high level, the count is incremented (step S104). Thereafter, when the FG signal S _FG becomes a low level, the count is cleared and the count value returns to the initial value (default). When the FG signal S _FG is at a low level, the count is incremented (step S105). When the FG signal S _FG becomes a high level thereafter, the count is cleared and the count value returns to the initial value (default).

  It is determined whether or not the abnormality flag is 0 after counting up in step S104 or step S105 (step S106). The abnormality flag is a determination flag included in a notification signal sent from the CPU 16 to the control device attached to the vehicle, and is information indicating that the cooling fan 50 is abnormal. When the abnormality flag is 0 (abnormal flag = 0), it means that the normal flag is set and the cooling fan 50 is normal. When the abnormal flag is 1 (abnormal flag = 1), the abnormal flag (hereinafter, “Abnormal flag = 1” is called “Abnormal flag 1”), which means that the cooling fan 50 is abnormal.

If it is determined that the abnormality flag is 0, it is determined whether or not the count value counted up in step S104 or step S105 is greater than or equal to a predetermined first threshold value (step S107). The case where the count value is equal to or greater than the predetermined first threshold means an abnormal state in which the high level period or the low level period of the FG signal S _FG is continued for the predetermined first time or longer.

  If the count value is greater than or equal to the predetermined first threshold, the cooling fan 50 is determined to be abnormal and becomes an abnormal flag 1 (step S108), and the abnormal flag 1 is stored in the memory. Further, when the count value is less than the predetermined first threshold value, it is determined to be normal and the abnormality flag is maintained at 0.

  It should be noted that the operation of the cooling fan 50 returns to the normal state after it is determined that the cooling fan 50 is abnormal, and the cooling fan 50 is determined to be normal in the detection process described later, or the cooling fan Except when the operation of 50 is reset, the state where the abnormality flag 1 is kept is maintained. Further, when there is no operation (rotation drive) instruction to the cooling fan 50 (No in step S101), and the abnormality flag is set at that time, the abnormality flag is cleared (step S109). A normal flag is stored in the memory.

  When the FG signal line L3 is disconnected, the FG terminal (not shown) of the cooling fan 50 is in an open collector state. For example, if the control unit 10 is pulled up with a power supply voltage of 5V. The high level signal continues to be input to the CPU 16. Therefore, the disconnection of the FG signal line L3 can be detected based on the processing flow shown in FIG.

  When the FG signal line L3 is grounded, the input / output terminal (not shown) of the CPU 16 is fixed at the low level and the low level signal is continuously input to the CPU 16, so that the disconnection of the FG signal line L3 described above is performed. Similarly to the case, the ground fault of the FG signal line L3 can be detected based on the processing flow shown in FIG.

  As described above, the abnormality of the cooling fan 50 can be reliably detected by executing the abnormality detection process by the abnormality detection program described above.

  Here, in the above-described embodiment, the example in which the abnormality detection process is executed using software such as the abnormality detection program has been described. However, a hardware such as the abnormality detection circuit 17 (see FIG. 3) is used instead of the abnormality detection program. The abnormality detection process can be performed in the same manner as described above using the wear.

  Hereinafter, referring to FIG. 3, the configuration and operation of the abnormality detection circuit 17 that detects an abnormality of the cooling fan 50 and an abnormality caused by a ground fault, a short circuit, and an open of the FG signal line L3 and sends an abnormality detection signal Sc. explain.

  The abnormality detection circuit 17 is provided in the control unit 18. The input side of the abnormality detection circuit 17 is connected to the cooling fan 50 via the FG signal line L3, and the output side is connected to the switch elements SW-1 to SW-N and the switch element of the constant voltage circuit 19 or the CPU 16. .

  The abnormality detection circuit 17 includes a differentiating circuit including a capacitor C3 and a resistor R4, an integrating circuit including a capacitor C4 and a resistor R6, a PNP transistor Tr1, and NPN transistors Tr2 and Tr3. The base of the PNP transistor Tr1 is connected to the anode of the diode D1 through the resistor R1, and the collector is connected to the base of the NPN transistor Tr2 through the capacitor C3 and the resistor R4. The emitter of the NPN transistor Tr2 is connected to the base of the NPN transistor Tr3 via resistors R6 and R7.

When the cooling fan 50 and the FG signal line L3 are normal, a pulse-shaped FG signal _SFG is output from the cooling fan 50, and the PNP transistor Tr1 is repeatedly turned on and off. The FG signal _SFG is turned off when it is at a high level, and turned on when it is at a low level.

A differentiating circuit including the capacitor C3 and the resistor R4 outputs a differential signal obtained by differentiating the FG signal _SFG . The differential signal has a rising edge (hereinafter referred to as “first differential edge”) immediately after the FG signal S _FG shifts from the low level to the high level, and immediately after the transition from the high level to the low level. The falling portion is a signal that becomes a falling edge (hereinafter referred to as “second differential edge”).

  The NPN transistor Tr2 is turned on by the first differential edge and the second differential edge, and is otherwise turned off.

  An integrating circuit comprising a capacitor C4 and a resistor R6 outputs an integrated signal obtained by integrating the differential signal. This integration signal has rising edges (hereinafter referred to as “first integration edges”) and falling edges (hereinafter referred to as “second integration edges”) corresponding to the first differential edge and the second differential edge, respectively. ").). Immediately after the first integration edge is output, the signal output falls according to the time constant determined by the capacitor C4 and the resistor R6, and immediately after the second integration edge is output, the time is determined by the capacitor C4 and the resistor R6. The signal output increases according to the constant.

  The NPN transistor Tr3 is turned on by the first integration edge and the second integration edge, and is otherwise turned off.

  Here, when the cooling fan 50 is in an abnormal state as described above, for example, when the number of rotations of the cooling fan 50 is reduced, the cycle of the integration signal described above becomes longer, so The interval to the first integration edge in the period becomes longer. Accordingly, the NPN transistor Tr3 is turned off while the charging time of the capacitor C4 is long and the capacitor C4 is not sufficiently charged, and a voltage signal having a predetermined voltage value is used as the abnormality detection signal Sc as the switch elements SW-1 to SW-N and the constant voltage. It is sent to the switch element of the voltage circuit 19.

  The switch elements SW-1 to SW-N and the switch elements of the constant voltage circuit 19 are turned off in response to the abnormality detection signal Sc. When the switch elements SW-1 to SW-N and the switch elements of the constant voltage circuit 19 are turned off, the supply of the drive currents S2 to the switching regulators 32-1 to 32-N is stopped and simultaneously the cooling fan 50 is supplied. Supply of the fan drive current Sf is stopped.

  When the supply of the drive current S2 to the switching regulators 32-1 to 32-N is stopped, the supply of the LED drive current S1 to the LEDs 40-1 to 40-N is stopped and the LEDs 40-1 to 40-N are turned off. To do. When the supply of the fan drive current Sf to the cooling fan 50 is stopped, the rotational drive of the cooling fan 50 is stopped.

  For example, when the FG signal line L3 is grounded, short-circuited, or disconnected (opened), the abnormality detection signal Sc is output from the abnormality detection circuit 17 to the switch elements SW-1 to SW-N and the constant voltage circuit in the same manner as described above. It is sent to 19 switch elements.

  As described above, abnormality detection by the abnormality detection circuit 17 described above makes it possible to reliably detect abnormality of the cooling fan 50, ground fault, short circuit, and disconnection of the FG signal line L3, and the LEDs 40-1 to 40-. N can be turned off, and the rotation drive of the cooling fan 50 can be stopped. Here, the abnormality detection signal Sc may be temporarily input to the CPU 16, and the LEDs 40-1 to 40 -N and the cooling fan 50 may be stopped from the CPU 16.

  Next, a case where the determination process of the CPU 16 is started again after it is determined in step S108 of FIG. 2 that the cooling fan 50 is abnormal will be described. In the following description, it is assumed that the cooling fan 50 has returned to normal before the determination process of the CPU 16 starts again after the abnormality determination.

  If it is determined in step S108 that the cooling fan 50 is abnormal, the determination flag is the abnormality flag 1.

  After it is determined in step S108 that the cooling fan 50 is abnormal, steps S102 to S104 or steps S102, S103, and S105 are performed again. In step S106, the abnormality flag is set to 1, and it is determined that the abnormality flag is not 0 (No in step S106).

Next, it is determined whether or not the count value counted up in step S104 or step S105 is less than a predetermined second threshold (second time) (step S110). The case where the count value is less than the predetermined second threshold means a normal state in which the high level period or the low level period of the FG signal S _FG is not continued for a predetermined second time.

Note that, in order to determine whether or not the determination in step S110 is normal, the predetermined second threshold is set in advance so as to be a value lower than the predetermined first threshold. That is, the second time is set to be shorter than the first time. The reason is that the high of the FG signal S _FG outputted when a high level period or low level period of the FG signal S _FG outputted are each cooling fan 50 is abnormal when the cooling fan 50 is normal This is because the normal determination cannot be made unless the second time is shorter than the first time because it is shorter than the level period or the low level period.

  When the count value is less than the predetermined second threshold, it is determined that the cooling fan 50 is normal, the abnormality flag is cleared (step S111), and the normal flag is stored in the memory. If the count value is greater than or equal to a predetermined second threshold, it is determined that there is an abnormality and the state of the abnormality flag 1 is maintained.

  Accordingly, by setting the second time shorter than the first time, a difference (margin) between the first time and the second time is provided, and abnormality determination is performed in two stages of the first threshold value and the second threshold value. Can be done. For this reason, even if there is variation in the number of rotations or the rotation cycle at the time of each product of the cooling fan 50, abnormality detection can be reliably performed, and the accuracy of abnormality detection can be improved. For example, there are a cooling fan A and a cooling fan B that have different rotation speeds in a normal state, and if the cooling fan A is less than a first threshold, no abnormality is detected and the cooling fan B is equal to or greater than the second threshold. In the case where an abnormality is detected at less than the above, both of the above-described two-stage abnormality detection processes can reliably detect the abnormality.

  In addition, in order to take into account variations in the number of rotations or the rotation cycle for each product, the number of rotations or the rotation cycle is measured in advance for each product of the cooling fan 50 in the assembly process of the vehicular lamp 1. The first threshold value and the second threshold value are determined according to the number of rotations or the rotation cycle. The determined first threshold value and second threshold value data are stored in the memory.

  Next, a second example of the abnormality detection process of the abnormality detection program stored in the memory of the control unit 18 will be described with reference to the flowchart of FIG.

  The cycle A is stored in the memory in advance so that the processing cycle of the processing flow of FIG. 4 (the cycle of one routine: hereinafter referred to as “cycle A”) is sufficiently longer than the processing cycle of the processing flow of FIG. ing.

  First, the rotation cycle of the cooling fan 50 that is currently operating is stored in the memory (step S201). The rotation period of the cooling fan 50 is measured every period A.

  Next, the current rotation cycle of the cooling fan 50 is compared with the previously stored rotation cycle (step S202). If the current rotation cycle is longer, the count value is incremented (step S203), and it is determined whether the count value is equal to or greater than a predetermined value (step S204). If the current rotation cycle is shorter, the count is cleared (step S207).

  If the count value is greater than or equal to a predetermined value, it is determined whether or not the current rotation period is greater than or equal to a predetermined period (step S205). The predetermined value and the data of the predetermined cycle are stored in advance in the memory. If the current rotation cycle is greater than or equal to the predetermined cycle, it is determined that the cooling fan 50 is abnormal (step S206). As a result, it is possible to detect an abnormality that causes the FG signal to be in a state in which the high level period or the low level period continues for a certain time or more due to deterioration of the cooling fan 50 over time.

  Next, after it is determined that the cooling fan 50 is abnormal (abnormal flag = 1) in the abnormality detection process (see FIG. 2), a notification signal including the abnormal flag 1 is used to control various functions attached to the vehicle. An example of processing (abnormal treatment) to be sent to the control device will be described with reference to the flowchart of FIG.

  The program processing in FIG. 5 is started after, for example, the abnormality determination in step S108 of the program processing in FIG.

  First, it is determined whether or not the abnormality flag is 1 (whether or not the abnormality flag is 1) (step S301). If the abnormality flag is 1, the count value is incremented (step S302). ).

  Next, it is determined whether or not the count value is greater than or equal to a predetermined value (step S303). If the count value is greater than or equal to the predetermined value, the abnormality treatment is executed (step S304). If the abnormality flag is not 1, the count is cleared (step S305).

  Therefore, a predetermined time elapses after the abnormality determination of the cooling fan 50 is determined, and then the abnormality treatment is performed. Therefore, it is possible to improve the accuracy of detecting the abnormality of the cooling fan 50 and the accuracy of notification.

  Next, referring to the flowchart of FIG. 6 for another example of the abnormality treatment after it is determined in the abnormality detection process (see FIG. 2) that the cooling fan 50 is abnormal (abnormal flag = 1). explain.

  The program processing in FIG. 6 is started after, for example, the abnormality determination in step S108 of the program processing in FIG.

  First, the count value is counted up (step S401). It is determined whether or not the abnormality flag is 1 for each count until the count value reaches 9 (steps S402, S403, S406,..., S409). If the count value is greater than 9, the count is cleared (step S414).

  When the count value is 0 and the abnormality flag is 1, the variable 0 = 1 is set (step S404), and when the abnormality flag is not 1, the variable 0 is set (step S405). Subsequently, when the count value is 1 and the abnormality flag is 1, variable 1 = 1 is set (step S407), and when the abnormality flag is not 1, variable 1 = 0 is set (step S408). In this way, processing similar to the above is performed until the count value reaches 9.

  Next, it is determined whether or not to perform the abnormality treatment based on the ratio of “0” and “1” in all the variables (0 to 9). Specifically, the ratio of the number of abnormal flags 1 in all counts (0 to 9) to the total count number (the sum of the number of abnormal flags 1 and the number of normal flags: 10 in this example) is a predetermined ratio or more. It is determined whether or not (step S412). When the ratio of the number of the abnormality flag 1 to the total count is equal to or greater than a predetermined ratio, the abnormality treatment of the cooling fan 50 is executed (step S413).

  Therefore, the abnormality flag 1 determination process of the cooling fan 50 is performed a plurality of times within a predetermined time, and the abnormality treatment is executed only when the ratio of the abnormality flag 1 with respect to the total count number exceeds a predetermined ratio. The accuracy of abnormality detection and notification accuracy of the fan 50 can be further increased. In the example of FIG. 6 described above, the case where the variables are 0 to 9 has been described. However, if more variables are used, more accurate abnormality detection and notification can be performed.

  Next, in addition to notifying abnormality to the vehicle, the specific contents of the abnormality treatment will be described with reference to FIG. The configuration of the control unit 10 shown in FIG. 7 is the same as that of the control unit 10 shown in FIG. 1 except that the switch element SW− (N + 1) is connected in parallel to the constant voltage circuit 19. The constant voltage circuit 19 (series regulator) includes a switch element (not shown). The switch element incorporated in the constant voltage circuit 19 has a function of stopping the operation of the constant voltage circuit 19 in response to an off signal from the CPU 16.

  As an abnormality treatment when the cooling fan 50 is abnormal, in addition to sending the above notification signal to the vehicle (abnormal notification), a fan drive current supplied to the cooling fan 50 at the same time as the abnormality determination of the cooling fan 50 is performed. There is a process to increase.

  The constant voltage circuit 19 in the control unit 10 outputs a constant voltage (for example, 5 V) in order to stabilize the driving of the cooling fan 50.

  For example, when the rotational speed decreases due to deterioration with time of the cooling fan 50 and an abnormality is determined, the CPU 16 sends an OFF signal to the switch element built in the constant voltage circuit 19 to stop the constant voltage circuit 19 and at the same time switch An ON signal is sent to the element SW- (N + 1) to turn on the switch element SW- (N + 1). Thereby, the battery voltage Vin (= 12 V) is supplied to the cooling fan 50. Therefore, when it is determined that the cooling fan 50 is abnormal, the drive voltage is increased to increase the rotational speed, thereby extending the life of the cooling fan 50 and the LEDs 40-1 to 40- associated with the decrease in the rotational speed. It is possible to suppress deterioration of N due to heat.

  Next, in the above-described embodiment, when the LEDs 40-1 to 40-N are infrared LEDs, in general, a color for turning on a red LED for turning off the red color of the infrared LED (white LED). An erasing circuit 27 (see FIG. 8) is used.

  However, when the LED output line L4 (see FIG. 8) of the red LED of the achromatic circuit 27 is disconnected, grounded, or short-circuited, the achromatic circuit 27 does not operate normally and the red color of the infrared LED may be erased. Can not.

  In the following, referring to FIG. 8, the configuration of the achromatic circuit 27 that detects an abnormality caused by the disconnection, ground fault, or short circuit of the LED output line L4 of the red LED of the achromatic circuit 27 and sends an abnormality detection signal Sk. The operation will be described.

  The achromatic circuit 27 is provided in the control unit 18. The input side of the achromatic circuit 27 is connected to a red-erasing LED (white LED) via an LED output line L4, and the output side is connected to the switch elements SW-1 to SW-N.

  The achromatic circuit 27 includes an anomaly detection unit including a PMOS transistor Tr4, an NPN transistor Tr5, resistors R11 to R15, and a Zener diode ZD1, a current detection unit including PNP transistors Tr6 and Tr7, and resistors R16 to R19, An NPN transistor Tr8 that sends out an abnormality detection signal Sk is provided.

  When the LED output line L4 is disconnected, the NPN transistor Tr5 is turned on and the PMOS transistor Tr4 is also turned on, but no current flows through the resistor R16 and the NPN transistor Tr8 is turned off. Therefore, a voltage signal having a predetermined voltage value is sent to the switch elements SW-1 to SW-N as the abnormality detection signal Sk.

  When the LED output line L4 is grounded or short-circuited, the NPN transistor Tr5 is turned off and the PMOS transistor Tr4 is also turned off. No current flows through the resistor R16, and the NPN transistor Tr8 is turned off. Therefore, a voltage signal having a predetermined voltage value is sent to the switch elements SW-1 to SW-N as the abnormality detection signal Sk.

  The switch elements SW-1 to SW-N are turned off in response to the abnormality detection signal Sk. When the switch elements SW-1 to SW-N are turned off, the supply of the drive currents S2 to the switching regulators 32-1 to 32-N is stopped.

  When the supply of the drive current S2 to the switching regulators 32-1 to 32-N is stopped, the supply of the LED drive current S1 to the LEDs 40-1 to 40-N is stopped and the LEDs 40-1 to 40-N are turned off. To do.

  As described above, abnormality detection by the above-described achromatic circuit 27 is performed to reliably detect abnormality due to disconnection, ground fault, and short circuit of the LED output line L4, and turn off the LEDs 40-1 to 40-N. Can do.

  The above-described embodiment is merely an example of a preferred embodiment of the present invention, and the present invention can be implemented with various modifications without departing from the gist thereof.

It is the figure which showed the circuit structure of the vehicle lamp which concerns on embodiment of this invention. It is the flowchart which showed the 1st example of the abnormality detection program of the cooling fan. It is the figure which showed the structure of the abnormality detection circuit. It is the flowchart which showed the 2nd example of the abnormality detection program of the cooling fan. It is the flowchart which showed an example of the program which performs abnormality treatment. It is the flowchart which showed the other example of the program which performs abnormality treatment. It is a figure for demonstrating the method of the abnormality treatment after an abnormality detection process. It is the figure which showed the structure of the achromatic circuit.

DESCRIPTION OF SYMBOLS 1 ... Vehicle lamp, 10 ... Control unit, 18 ... Control part, 30-1-30-N ... Light source unit, 32-1-1-N ... Switching regulator (current supply part), 40-1-40-N ... LED (semiconductor light source), 50 ... cooling fan

Claims (5)

A light source unit having a semiconductor light source and a current supply unit for supplying a light source driving current to the semiconductor light source;
A cooling fan for cooling the semiconductor light source;
A control unit including a control unit for controlling the fan driving current and the light source driving current for driving the cooling fan and performing a determination process for the cooling fan,
The control unit receives a pulse signal sent from the cooling fan and synchronized with the number of rotations of the cooling fan, and a high level period or a low level period in one cycle of the pulse signal is at least a first time or more. In this case, it is determined that the cooling fan is abnormal. The control unit repeatedly performs the determination process,
In the determination process after determining that the cooling fan is abnormal, the control unit performs the cooling when the high level period or the low level period is shorter than a second time shorter than the first time. The vehicle lamp according to claim 1, wherein the vehicle fan is determined to be normal. The high level period or the low level period in one cycle of the pulse signal is measured a predetermined number of times in a predetermined cycle,
The control unit is configured such that the high level period or the low level period measured at the Mth (M is an integer of 2 or more) time is the (M-1) th time when the high level period or the low level period is measured. The vehicle lamp according to claim 1, wherein the cooling fan is determined to be abnormal when longer than a period. When it is determined that the cooling fan is abnormal, an abnormality flag indicating abnormality is stored in the storage unit of the control unit and counted up,
4. The vehicular lamp according to claim 1, wherein a notification signal having the abnormality flag is transmitted from the control unit when a count value is equal to or greater than a predetermined threshold value. 5. When it is determined that the cooling fan is abnormal or normal, an abnormality flag indicating abnormality or a normal flag indicating normal is stored as a determination flag in the storage unit of the control unit and predetermined predetermined It is counted up until it reaches the count value,
Whether the determination flag is the abnormal flag or the normal flag is determined for each count by the control unit,
The notification signal having the abnormality flag is sent from the control unit when the ratio of the number of the abnormality flag to the total count becomes a predetermined ratio or more. Vehicle lamps.

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