JP2006261032A - Discharge lamp lighting device and vehicular lighting fixture - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a discharge lamp lighting device which judges certainly the type of a discharge lamp without adding an excess stress to the discharge lamp or adversely affecting reliability and lifetime, and protects the lighting device and the lamp when an incompatible lamp is erroneously installed. <P>SOLUTION: When a detection part 7 detects that at least one connection portion is disconnected, the discharge lamp 5 is lighted by a discrimination power control mode for discriminating the type of the discharge lamp 5, and the type of the discharge lamp 5 is discriminated by a discharge lamp discrimination part 6b, and a judgement part 6h judges whether the discharge lamp 5 installed is compatible or incompatible to the lighting device, and the judgement result is stored in a storage part 6c, and when compatible, a power conversion part 23 is driven by a prescribed power control according to the type of the lamp 5 based on the output of a voltage detection part 6v and a current detection part 6i; and when incompatible, the discharge lamp 5 is controlled so as not to be lighted until the detection part 7 detects again that the connection portion is disconnected. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a discharge lamp lighting device and a vehicular lamp having a function of identifying a high-intensity discharge lamp such as a connected metal halide lamp and performing a treatment when a non-conforming lamp is connected.

  High-intensity discharge lamps such as metal halide lamps are used for in-vehicle headlamps because of their luminous flux. Conventional metal halide lamps for vehicles have mainly been of a type in which mercury is enclosed in order to set a higher luminous flux at the start and a higher voltage between the electrodes at the time of starting. Mercury-enclosed lamps are generally referred to as D1 and D2 lamps, and the D1 lamp is a type having a built-in igniter for generating a pulse at start-up. On the other hand, from the viewpoint of environmental problems, there is a mercury-free lamp that does not enclose mercury and substitutes other halogen compounds for its role, and the scale is expanding in the future. Mercury-free lamps are generally referred to as D3 and D4 lamps, and the D3 lamp is a type that incorporates an igniter for generating a pulse at the time of starting.

  However, mercury-free lamps are characterized by a low discharge voltage when lit, and it is necessary to rapidly vaporize the substituted halogen compound in order to realize a rapid rise in luminous flux at start-up. There is a feature that requires large electric power. From these characteristics, in order to start up the mercury-filled lamp and the mercury-free lamp with the light rising characteristics with respect to substantially the same time, it is necessary to perform power-on control suitable for each as shown in FIG. In addition, FIGS. 33B and 33C show how the output voltage and output current change at that time.

  As a ballast for supplying power to the lamp as shown in FIG. 33A, a configuration as shown in FIG. 34 is given as an example. This includes a DC power source 1, a DC-DC converter unit 2 that steps up and down the voltage from the DC power source 1 to a voltage required by the discharge lamp 5, and a DC output voltage of the DC-DC converter unit 2 into a low-frequency rectangular wave. The inverter unit 3 for conversion, the igniter unit 4 for generating a voltage of several tens of kV for starting the lamp, the discharge lamp 5, and the output voltage and output current of the DC-DC converter unit 2 are detected, and the output power becomes the target power. Thus, the control unit 6 is configured to control the DC-DC converter unit 2.

  Hereinafter, the circuit configuration of each part will be described. The primary side winding P1 of the transformer T1 of the DC-DC converter unit 2 and the switching element Q1 are connected in series with the DC power source 1. A diode D1 and a smoothing capacitor C1 are connected in series to the secondary winding S1 of the transformer T1. The direction of the diode D1 is a direction in which the current generated in the secondary winding S1 of the transformer T1 is stopped when the switching element Q1 is turned on and a voltage is applied to the primary winding P1 of the transformer T1. is there. When the switching element Q1 is turned on / off at a high frequency, a DC voltage obtained by converting the DC voltage of the DC power supply 1 is obtained in the capacitor C1. The DC-DC converter unit 2 is configured as described above.

  A full bridge circuit composed of switching elements Q2 to Q5 is connected in parallel with the smoothing capacitor C1 of the DC-DC converter unit 2. The switching elements Q2 to Q5 are switched on at low frequencies alternately by switching elements Q2, Q5 and Q3, Q4 arranged in a diagonal direction by a full bridge control circuit (not shown), so that the DC voltage of the capacitor C1 is reduced to a low frequency. Convert to rectangular wave voltage and output. The inverter unit 3 is configured as described above.

  Subsequently, in parallel with the output of the full bridge circuit, a capacitor Cs, a series circuit of the primary side winding P2 of the transformer T2 and the spark gap SG1, and a series circuit of the secondary side winding S2 of the transformer T2 and the discharge lamp 5 And are connected. The igniter section 4 is composed of the above circuit excluding the discharge lamp 5.

  The control unit 6 inputs the output voltage and output current detection value of the DC-DC converter unit 2, and in the current target calculation unit 61, the electric power to be supplied to the discharge lamp 5 that is the output of the power target storage unit 62. The output current target value is obtained by dividing the target output power target value by the output voltage detection value. Further, the output current target value and the detected output current value are compared by the error amplifier 63, and an output control signal is output so that the difference does not occur. The pulse width of the switching element Q1 of the DC-DC converter unit 2 is variably controlled by a PWM control circuit (not shown) according to the output control signal.

  The output power target value from the power target storage unit 62 is determined when the lamp is already warmed by the start lamp state (output at the time of restart) which is the output from the lamp state detection unit 64 (at the time of restart). The output power target value is set lower than when the lamp is not warmed according to the state (at the time of initial start) (the output power target value starts at t0 in the figure at the time of initial start, but at the time of restart, for example, controlled to start at t1).

  The circuit operation of the conventional example will be described below. When the power supply is turned on and the switching element Q1 is turned on, a current flows through the primary side winding P1 of the transformer T1 and the switching element Q1. However, since no current flows through the secondary winding S1 of the transformer T1 due to the diode D1, the energy is stored in the transformer T1. Next, when the switching element Q1 is turned off, a current flows through the route of the secondary winding S1, the capacitor C1, and the diode D1 of the transformer T1, and the energy stored in the transformer T1 is transferred to the smoothing capacitor C1.

  Before the lamp starts, since the discharge lamp 5 is in an open state, the voltage of the capacitor C1 rises, and the full bridge inverter is fixed with the switching elements Q2 and Q5 being ON and the switching elements Q3 and Q4 being OFF. As a result, the voltage of the capacitor Cs also increases. When the voltage exceeds a predetermined voltage, the spark gap SG1 breaks down, the voltage is instantaneously applied to the primary winding P2 of the transformer T2, and the voltage is multiplied by the turns ratio to the secondary winding S2 of the transformer T2. Applied high voltage. The discharge lamp 5 breaks down by this high voltage (about several tens of kV). At that moment, a current flows from the DC-DC converter section 2 to the discharge lamp 5, and the discharge lamp 5 shifts to arc discharge.

  After the discharge lamp 5 is turned on, the output power target value from the power target storage unit 62 is divided by the output voltage detection value in the current target calculation unit 61 while alternating the output polarity of the full bridge inverter at predetermined time intervals. The output current target value is obtained. The output current target value is compared with the detected output current value by the error amplifier 63, and the pulse width of the switching element Q1 of the DC-DC converter unit 2 is controlled by the output control signal corresponding to the error amount, and the output is made. Adjust. As described above, stable lighting of the discharge lamp 5 is realized.

  As means for judging the type of the connected lamp from the electrical characteristics, lamp shape, etc. of FIGS. 33 (a), (b), (c) and applying the output power suitable for the lamp to the lamp. Japanese Patent Laid-Open No. 2003-249392 discloses a technique for storing electrical characteristics at the time of previous lighting, determining a lamp type from the result, and applying output power suitable for the lamp. .

Japanese Patent Application Laid-Open No. 2003-338391 determines the type of lamp connected from these electrical characteristics every time it is turned on, and performs identifiable output control as a measure when a non-conforming lamp is mounted. A method of keeping the lamp on is disclosed.
JP 2003-249392 A JP 2003-338391 A

  In the prior art disclosed in Japanese Patent Application Laid-Open No. 2003-338391, when a non-conforming lamp is mounted, output control is performed so as to be identifiable, and the lamp is turned on. When trying to turn on the mercury-free lamp, it is necessary to flow about twice as much current as that of the mercury-filled lamp, and there is a problem that the load on the ballast increases. In addition, as an identifiable output control, if the output (lamp current) is limited to eliminate the load on the ballast, the lamp will become unstable, and if it is done at every lighting, the lamp life will be adversely affected. There is.

  In addition, in the prior art disclosed in Japanese Patent Application Laid-Open No. 2003-249392, a switch circuit for switching the turn ratio is added to the secondary winding of the DC-DC converter in order to apply output power suitable for the lamp. . In this way, if the mercury-filled lamp and the mercury-free lamp are lit in multiple ways with one ballast, the circuit tends to increase in size and the cost also increases.

  Moreover, in the prior art disclosed in Japanese Patent Laid-Open Nos. 2003-338391 and 2003-249392, the lamp is determined for each lighting, and the determination for each lighting is short because the lighting time is short. In this case, it is considered that the criterion for judgment changes depending on the environment, such as when the lamp temperature at the time of restart or when the lamp temperature is different. There is a problem that an excessive stress is applied to the lamp due to misjudgment, which adversely affects reliability and life.

  According to the present invention, in order to solve the above-described problem, as shown in FIG. 1, the power supply is connected to a power supply unit 1s including a DC power supply 1 and a lighting switch S, and the input from the power supply unit 1s is performed. A power conversion unit 23 that converts power into power necessary for the discharge lamp 5, an igniter unit 4 that is connected to the discharge lamp 5 and generates a high-pressure pulse necessary for starting the discharge lamp 5, the power supply unit 1s, and the power It is detected that at least one of the connection part CN1 of the conversion part 23, the connection part CN2 of the power conversion part 23 and the igniter part 4, and the connection part CN3 of the igniter part 4 and the discharge lamp 5 is disconnected. A discharge lamp lighting device including a detection unit 7 and a control unit 6 that controls power supplied to the discharge lamp 5, wherein the control unit 6 detects a voltage supplied to the discharge lamp 5. And the electric power supplied to the discharge lamp 5 A current detection unit 6i for detecting the discharge lamp, a discharge lamp determination unit 6b for determining the type of the discharge lamp 5 based on the output of at least one of the voltage detection unit 6v or the current detection unit 6i, and the discharge lamp determination unit 6b. A determination unit 6h for determining whether the determined discharge lamp 5 is suitable for the lighting device; and a storage unit 6c for storing a determination result by the determination unit 6h. When the lighting switch S is OFF, When the detection unit 7 detects that at least one connection unit is disconnected, the control unit 6 is in a determination power control mode for determining the type of the discharge lamp 5 when the lighting switch S is turned on. After the power conversion unit 23 is driven and the discharge lamp determination unit 6b determines the type of the discharge lamp 5, if the determination unit 6h determines that the discharge lamp 5 is suitable, the determination result is stored in the storage unit 6c. In The power converter 23 is driven according to the outputs of the voltage detector 6v and the current detector 6i with predetermined power control according to the stored type of the discharge lamp 5, and the discharge lamp 5 is turned on. When the determination unit 6h determines that the discharge lamp 5 is not suitable, the determination result is stored in the storage unit 6c, and the detection unit 7 is turned on when the lighting switch S is turned on next time. Until the drive of the power conversion unit 23 is stopped until it is detected that at least one connection unit is disconnected.

  According to the present invention, when the detection unit detects that the connecting portion is disconnected, the discharge lamp is turned on in the determination power control mode for determining the type of the discharge lamp, and the type of the discharge lamp is determined. It is determined whether the mounted discharge lamp is compatible with the lighting device or not, and the determination result is recorded in the storage unit. In the case of non-conformity, the discharge lamp is turned off until the detection unit detects that the connection unit has been disconnected again. By avoiding lighting, the problem of adversely affecting the reliability and life of the lighting device and the discharge lamp by determining the type of the discharge lamp every time it is lit can be solved. In addition, there is an effect that the apparatus can be provided in a small size and at a low cost as compared with a lighting apparatus capable of lighting different types of discharge lamps in a multi-compatible manner.

(Basic configuration)
FIG. 1 shows an overall circuit configuration of a basic example of the present invention. This discharge lamp lighting device is connected to a power supply unit 1 s composed of a DC power source 1 and a discharge lamp lighting switch S, and converts power input from the power supply unit 1 s into power necessary for the discharge lamp 5. Unit 23, an igniter unit 4 connected to the discharge lamp 5 to generate a high-pressure pulse necessary for starting the discharge lamp 5, the power supply unit 1s and the power conversion unit 23, the power conversion unit 23, the igniter unit 4, and the igniter unit 4 And a detector 7 for detecting the connection state (whether the connection has been disconnected) of the connection parts CN1, CN2 and CN3 of the discharge lamp 5 and a control part 6 for appropriately controlling the power supplied to the discharge lamp 5. .

  The controller 6 detects a voltage supplied to the discharge lamp 5, a voltage detector 6 v (output is shown as Vla), and a current detector 6 i (detects an output shown as Ila) that detects a current supplied to the discharge lamp 5. ), And an output power control unit 6a that provides a drive signal to the power conversion unit 23 so that appropriate power is supplied to the discharge lamp 5 in accordance with the detected values of Vla and Ila.

  Further, the control unit 6 only detects that the connection between the connection portions CN1, CN2, and CN3 is disconnected by the detection unit 7, or when the discharge lamp 5 is turned on for the first time and the detection unit 7 Only when it is detected that the connection portions CN1, CN2 and CN3 are disconnected, the power supplied to the discharge lamp 5 becomes the power set in advance in the control portion 6 in order to determine the type of the discharge lamp 5. Thus, a drive signal is given to the power converter 23 to light the discharge lamp 5. Then, the control unit 6 determines the type of the lit discharge lamp 5 based on the Vla or Ila value (or both values) detected at that time, a discharge lamp determination unit 6b, a discharge lamp Determination unit 6h for determining whether the result (type of the discharge lamp) determined by the determination unit 6b is suitable for the lighting device, the result determined by the determination unit 6h (“adaptation” or “non-conformity” of the discharge lamp) Has a storage unit 6c.

  Then, the control unit 6 stores the memory at the time of normal discharge lamp lighting (when the discharge lamp is initially turned on and when the connection unit CN1, CN2, CN3 is detected to be disconnected by the detection unit 7). Depending on the determination result of “conformity” or “nonconformity” of the discharge lamp 5 stored in the unit 6c, in the case of “conformity”, the predetermined supply power is set in advance (for the conforming discharge lamp). In addition, a drive signal is given to the power conversion unit 23, the discharge lamp 5 is turned on, and in the case of “non-conformity”, until the detection unit 7 detects the disconnection of the connection units CN1, CN2, and CN3 again. The driving of the power converter 23 is stopped.

  With the above configuration and operation, for example, even when the discharge lamp 5 is replaced, the detection unit 7 detects that the discharge lamp 5 has been detached, and in that case, in order to determine the type of the discharge lamp 5 in advance. Since the discharge lamp 5 is lit with the set power, there is no excessive stress applied to the discharge lamp as described in the conventional example, and there is no negative influence on reliability and life, and the discharge lamp is surely provided. Can be determined.

  Further, it is determined whether or not the type of the connected discharge lamp is suitable for the lighting device, the determination result is stored in the storage unit 7c, and it is determined that whether or not the power conversion unit 23 is driven based on the determination result. When a discharge lamp is connected, the lighting operation is not performed until the discharge lamp is replaced again, and when a suitable discharge lamp is connected, a preset suitable discharge lamp is not connected. Therefore, since the lighting control is performed with the predetermined target power, the discharge lamp can be quickly turned on. As a result, problems such as the increase in size and cost of the apparatus in the conventional example described above can be solved.

(Embodiment 1)
FIG. 2 shows the overall circuit configuration of the first embodiment of the present invention. This discharge lamp lighting device is connected to a power supply unit 1 s composed of a DC power source 1 and a discharge lamp lighting switch S, and converts power input from the power supply unit 1 s into power necessary for the discharge lamp 5. Unit 23, an igniter unit 4 that is connected to the discharge lamp 5 through a discharge lamp connection socket (connection unit CN 3) and generates a high-pressure pulse necessary for starting the discharge lamp 5, and a discharge lamp provided in the socket It is comprised by the detection part 7 of the removal | desorption state and the control part 6.

  The power conversion unit 23 includes a DC-DC converter unit 2 and an inverter unit 3. The DC-DC converter unit 2 converts an input voltage from the power supply unit 1s into a voltage necessary for lighting a discharge lamp, and an inverter. The unit 3 alternates the voltage converted by the DC-DC converter unit 2 at a low frequency and converts it into a rectangular wave voltage.

  The control unit 6 determines the output voltage and output current of the DC-DC converter unit 2 based on the values of Vla and Ila obtained as inputs of the voltage detection unit 6v and the current detection unit 6i described in the basic configuration of FIG. The signal which drives the switching element (it consists of FET etc.) of the DC-DC converter part 2 is given.

  The inverter unit 3 has a full bridge configuration using four stones such as FETs and IGBTs, and is driven by a signal from the control unit 6.

  The detection unit 7 provided in the socket has an impedance value that changes when the discharge lamp 5 is detached from the socket. By checking the impedance value of the detection unit 7 from the control unit 6, the discharge lamp from the socket 5 can be detected.

  FIG. 3 shows a flowchart of the operating state of the discharge lamp lighting device of the first embodiment. This will be described with reference to the “power-on” flowchart in FIG. When the lighting switch S is turned on and power is supplied to the lighting device. For example, when the input voltage to the power conversion unit 23 exceeds a predetermined value (for example, 9 V), it is regarded as “power on”. The process proceeds to step # 1.

  In step # 1 of “detection of detection unit impedance”, the impedance value of the detection unit 7 provided in the socket is checked. To check the impedance value, a predetermined voltage is applied from the control unit 6 to the detection unit 7 via a predetermined resistance, and the voltage generated in the detection unit 7 at that time (the predetermined voltage is divided by the predetermined resistance value and the detection unit impedance value). For example, by measuring a pressed voltage value).

  In step # 2 of “impedance change (determination)”, branching to “Yes” if it is determined that the value confirmed above is different from the value at the previous confirmation, and to “None” if it is determined to be substantially the same. . As a result, when it is determined that the impedance change is “none”, the operation of checking the contents of the storage unit (# 3) is performed, and the lighting for determining the type of the discharge lamp is performed only when the impedance change is determined to be “present”. The process proceeds to operation (# 10), and the compatibility of the valve type is determined. Even when the discharge lamp is lit for the first time, in order to always shift to step # 10 of “discharge lamp type determination lighting”, for example, a value other than the range that the detection unit impedance value can take is set as the value at the time of the previous check. Just set it.

  In step # 10 of “Discharge lamp type determination lighting / compatibility determination”, if the impedance change is determined to be “present” in step # 2 of “impedance change (determination)”, the control unit 6 releases it in advance. A drive signal is given to the power conversion unit 23 to turn on the discharge lamp 5 so that the target power set for lighting type determination lighting is turned on, and the discharge lamp 5 of the lighted discharge lamp 5 is turned on according to the value of Vla detected at that time. The type is determined, and it is determined whether the determined result (the type of the discharge lamp 5, D2 or D4 in the present embodiment) is suitable for the lighting device. The details of the discharge lamp type determination lighting method will be described later.

  In step # 11 of “record determination result storage unit”, the result of “conformity” or “nonconformity” of the discharge lamp type determined in step # 10 is recorded in the storage unit 6c.

  In step # 12 of “confirm storage section (determination)”, the contents recorded in the storage section 6c are confirmed. If “conforming”, “continuous lighting operation” (# 13) is performed. Branches to “light-off operation” (# 15).

  In step # 15 of “turn-off operation”, if the lamp is “nonconforming” in step # 12, a discharge lamp turn-off and circuit stop processing such as a drive signal stop is performed.

  In step # 13 of “continuous lighting operation”, in the case of “conformity” in step # 12, the discharge lamp 5 is discriminated after the lighting operation of the discharge lamp type in step # 10 of “discharge lamp type determination lighting / compatibility determination”. The electric power supply operation is continued, and the discharge lamp 5 is shifted to the stable lighting state as it is.

  In step # 14 of “power off (determination)”, the lighting switch S is turned off and the power supply to the lighting device is cut off. For example, the input voltage to the power conversion unit 23 falls below a predetermined value (for example, 6V). If it is determined that the power is off, the process proceeds to YES and proceeds to step # 6 of “light-off operation”. Otherwise, the process proceeds to NO, and “continuous lighting operation” (# 13) is performed until power-off determination is made.

  In step # 3 of “confirm storage section”, the contents recorded in the storage section 6c are confirmed. If “conformity”, “predetermined power lighting operation” (# 4) is performed; Branch to “maintain state” (# 8).

  In step # 4 of “predetermined power lighting operation”, a predetermined target provided in advance according to the type of the discharge lamp (D2 or D4 in this embodiment) stored in the storage unit 6c described in the basic configuration of FIG. The discharge lamp 5 is turned on with electric power. The details of the lighting operation will be described later together with the discharge lamp type determination method.

  In step # 5 of “power off (determination)”, the lighting switch S is turned off and the power supply to the lighting device is cut off. For example, the input voltage to the power conversion unit 23 falls below a predetermined value (for example, 6V). If it is determined that the power is off, the process proceeds to YES. Otherwise, the process proceeds to NO, and the lighting operation (predetermined power lighting operation: step # 4) is performed until it is determined that the power is off.

  In step # 6 of the “turn-off operation”, the discharge lamp 5 is turned off and the circuit is stopped by stopping the driving signal and the like based on the power-off determination (# 5) described above.

  In step # 7 of “power on (determination)”, the lighting switch S is turned on and power is supplied to the lighting device again. For example, the input voltage to the power converter 23 exceeds a predetermined value (for example, 9V). In this case, it is considered that the power is on, the process proceeds to YES, and the detection unit impedance is confirmed (# 1). Otherwise, go to NO and continue monitoring the power supply.

  In step # 8 of “maintenance of extinguished state”, the state of extinguishing the discharge lamp due to the stop of the drive signal or the like is maintained.

  In step # 9 of “power off (determination)”, the lighting switch S is turned off, the power supply to the lighting device is cut off, and for example, the input voltage to the power conversion unit 23 is from a predetermined value (for example, 6V). If the power is lowered, it is considered that the power is off, and the process proceeds to YES. Otherwise, the process proceeds to NO, and the light-off state is maintained until a power-off determination is made.

  If the power supply to the lighting device is completely lost due to power interruption or the like, and the electrical circuit operation of the lighting device is completely stopped in such a case, the “power supply” in FIG. The operation starts from step # 0 of “ON”.

  Next, the operation of steps # 20 to # 22 in FIG. 3 will be described. In step # 20 of “discharge lamp attachment / detachment detection”, the attachment / detachment state of the discharge lamp 5 is monitored by the detection unit 7 provided in the socket. In step # 21 of “desorption (determination)”, depending on whether or not the discharge lamp 5 is attached / detached, the presence / absence of the discharge lamp 5 is changed to step # 22 of “variable detection unit impedance”. Monitoring is performed at step # 20 of "Discharge lamp desorption detection". In step # 22 of “variable detection unit impedance”, when the discharge lamp 5 is attached / detached, the impedance value of the position sensor provided in the detection unit 7 is changed. A specific example regarding the operations of Steps # 20 to # 22 in FIG. 3 will be described later.

  FIG. 4 shows the discharge lamp type discrimination method of the first embodiment. FIG. 4A is a curve that defines a predetermined supply power for each type of discharge lamp used in step # 4 of “predetermined power lighting operation” during normal lighting. The horizontal axis represents the elapsed time after lighting, and the vertical axis Represents the target value of the power supplied to the discharge lamp 5. In order to quickly and smoothly start up the light when the discharge lamp is turned on, it is necessary to supply power suitable for the type of the discharge lamp 5, and here, target power regulation curves for the mercury-filled lamp D2 and the mercury-free lamp D4 are used. It is shown. For example, in the case of mercury enclosed lamp D2, the maximum power value is 75 W and the duration is about 2 seconds, and in the case of mercury free lamp D4, the maximum power value is 90 W and the duration is about 8 seconds. Incidentally, the stable state is the case of a lamp with a rating of 35 W.

  FIG. 4B shows the state of rising of a typical lamp voltage (discharge lamp voltage) of various types of discharge lamps during normal lighting. The mercury enclosed lamp D2 suddenly rises in lamp voltage due to the action of mercury after lighting and reaches a stable state, but the mercury-free lamp D4 has no mercury, so the lamp voltage rises slowly after lighting. In addition, the lamp voltage in a stable lighting state is as low as about half that of the mercury-filled lamp D2. (The rated lamp voltage of the mercury enclosed lamp D2 is 85V, and the mercury-free lamp D4 is 42V.)

  FIG. 4C shows a method for determining the type of discharge lamp. In the present embodiment, the supplied power at the time of discharge lamp type determination in step # 10 of “discharge lamp type determination lighting” is the same target as the target power regulation curve for the mercury-filled lamp D2 shown in FIG. It is a power regulation curve. Using this target power regulation curve, a typical ramp voltage rise when the mercury-filled lamp D2 or the mercury-free lamp D4 is lit in the processing step # 10 of the "discharge lamp type determination lighting" described above. These are also shown in FIG. 4 (c).

  In the present embodiment, as described above, the same target power regulation curve as the target power regulation curve for the mercury-filled lamp D2 is used. Therefore, when the mercury-filled lamp D2 is lit, the same as in FIG. When the mercury-free lamp D4 is lit, the supplied power is low, and the ramp voltage rises more slowly than shown in FIG. 4B.

  Next, a method for determining the type of the discharge lamp in this embodiment will be described with reference to FIG. In FIG. 4C, the lamp voltages when the mercury-filled lamp D2 at the time point t1 and t2 after the lighting in the above-described “discharge lamp type determination lighting” processing step # 10 is turned on are V1 and V2. The lamp voltages when the mercury-free lamp D4 is turned on are indicated as V1 ′ and V2 ′.

  In the present embodiment, the determination of the discharge lamp type in the processing step # 10 of “discharge lamp type determination lighting” is performed based on the amount of change in lamp voltage during the time t1 to t2. That is, (V2−V1) or (V2′−V1 ′) is obtained by the control unit 6, and when the value (change amount of the lamp voltage) is larger than a predetermined value, the type of the discharge lamp is enclosed with mercury. If it is determined as the mold lamp D2 and is smaller than the predetermined value, the type of the discharge lamp is determined as the mercury-free lamp D4. (For example, the elapsed time after lighting t1 and t2 is 1 second and 3 seconds, respectively, and a predetermined value for determining the type of the discharge lamp based on the amount of change in the lamp voltage is 5V.)

  In the above, when the lighting device is used for the mercury enclosed lamp D2, the mercury enclosed lamp D2 is a “compatible” discharge lamp, and the mercury free lamp D4 is a “nonconforming” discharge lamp.

  Conversely, when the lighting device is for the mercury-free lamp D4, the mercury-free lamp D4 is a “compatible” discharge lamp, and the mercury-filled lamp D2 is a “nonconforming” discharge lamp.

  FIG. 5 shows an example of the discharge lamp attachment / detachment detection unit 7 of the first embodiment. In Fig.5 (a), about the schematic shape of the discharge lamp 5 used for a vehicle headlamp, the general shape of the conventional socket 70 used for a discharge lamp connection, and the connection terminal for electrical connection, This is shown schematically. FIG. 5D shows the appearance of the discharge lamp 5 from the back side in addition to the side view.

  The discharge lamp 5 has a base part 51 for fitting into a socket 70, a central electrode 53 connected to one of the electrodes of the arc tube 52 at the center of the base part 51, and light emission around the base part 51. In the state where the outer peripheral electrode 54 is connected to the other electrode of the tube 52 and the discharge lamp 5 is attached to the socket 70, the center electrode 53 of the discharge lamp 5 is in contact with the center electrode connection terminal 73 of the socket 70, and the discharge lamp When the outer peripheral electrode 54 of 5 is in contact with the outer peripheral electrode connecting terminal 74 of the socket 70, electrical connection is made, and these are connected to the igniter section 4 by electric wires.

  Further, by inserting the socket fixing projection 55 of the discharge lamp 5 into the discharge lamp fixing notch 75 provided in the socket 70 and then rotating and fitting it, the socket 70 of the discharge lamp 5 can be securely attached to the socket 70. It can be installed.

  5 (b) and 5 (c), the configuration of the socket 70 according to the present embodiment is divided into two cases: a state in which the discharge lamp is not attached to the socket 70 and a state in which the socket 70 is attached, in order to explain the main part operation. It is shown. The part illustrated in the upper part of the socket 70 is an example of the detection part 7 of the discharge lamp removal | desorption state in this embodiment. However, only the main components of the detection unit 7 are shown, and the others are omitted.

  The detection unit 7 has a discharge lamp attachment / detachment detection protrusion 71 that is movable in the left-right direction in the drawing by being pressed by the discharge lamp base 51 when the discharge lamp 5 is mounted, and the discharge lamp attachment / detachment detection protrusion 71. When the discharge lamp is not mounted, it is returned to the direction protruding from the socket 70 (right direction in the figure) by the spring 72 (state in FIG. 5B), and when the discharge lamp is mounted, it is stored in the socket 70 (see FIG. 5). It becomes movable to the left in the middle) (state shown in FIG. 5C).

  In addition, a variable resistor 77 whose impedance value sequentially changes as the rotating column portion 76 rotates is disposed adjacent to the discharge lamp attachment / detachment detecting projection 71, and the rotating column portion 76 has a spiral shape. On the other hand, the discharge lamp attachment / detachment detection projection 71 is provided with a spiral groove 71a, and the butterfly groove 71a is provided with a discharge lamp attachment / detachment detection projection 71. When it is movable in the direction in which it is housed in the socket 70 (left direction in the figure), it is hung on the spiral groove provided in the rotary column 76 and protrudes from the socket 70 (right direction in the figure). ) Is not hung on the spiral groove due to its shape or elasticity.

  With the above configuration, when the discharge lamp 5 is mounted in the socket 70, the rotating column portion 76 rotates, the impedance value of the variable resistor 77 changes, and when the discharge lamp 5 is removed from the socket 70, the variable resistor 77 Since the impedance value is not changed, the impedance value of the detection unit 7 changes when the discharge lamp 5 is replaced. The variable resistor 77 is connected to the control unit 6 by an electric wire for impedance detection.

  The spiral groove 71a may have a structure such as a retracting structure inside the discharge lamp desorption detection projection 71.

  With the above configuration and operation, in the first embodiment, even when the discharge lamp is replaced, the detection unit detects that the discharge lamp has been detached, and in that case, to determine the type of the discharge lamp. Since the discharge lamp is lit with the same supply power regulation curve as when a mercury-filled lamp is lit in advance, excessive stress is applied to the discharge lamp as described in the conventional example, and the reliability and life are adversely affected. In addition, the type of the discharge lamp can be reliably determined.

  Further, it is determined whether or not the type of the connected discharge lamp is suitable for the lighting device, the determination result is recorded in the storage unit, and in order to determine whether or not to drive the power conversion unit based on the result, If a lamp is connected, it will remain off until the discharge lamp is replaced again, and if a suitable discharge lamp is connected, a predetermined target power for a suitable discharge lamp set in advance will be maintained. (When the lighting device is a mercury-filled lamp, the target power regulation curve for the mercury-filled lamp, and when the lighting device is a mercury-free lamp, the lighting control is performed) As a result, the discharge lamp can be turned on promptly. As a result, problems such as the increase in size and cost of the apparatus in the conventional example described above can be solved.

  In addition, when the lighting device is for a mercury-filled lamp, the lighting operation for determining the type of the discharge lamp is performed with the same supply power regulation curve as when the mercury-filled lamp is lit. Even at times, a quick rise of light can be obtained.

  In the present embodiment, the detection unit is provided in the socket for connecting the discharge lamp, and when the discharge lamp is detached from the socket, the case where the discharge lamp type determination lighting is performed is described as an example. As described in the basic configuration of FIG. 1, the same configuration is applied to each of the other connection portions CN1 and CN2, so that the discharge lamp type determination lighting is performed when the connection is disconnected. You can also.

  For example, by performing discharge lamp type determination lighting according to the connection state of the power conversion unit 23 and the igniter unit 4, excessive stress is released even when only the power conversion unit 23 of the discharge lamp lighting device is replaced. It is possible to eliminate the addition to the electric lamp 5 and the adverse effects on reliability and life.

  Further, the present invention can be used for the discharge lamps D1, D3 and the like for automobile headlamps in which the igniter unit 4 is built in the discharge lamp 5 and sockets in which the igniter unit 4 is built. An effect can be obtained.

  The configuration of the detection unit is not limited to that described in the first embodiment, and any other configuration may be used as long as it functions similarly.

  Further, in the basic configuration of FIG. 1 and the first embodiment of FIG. 2, the control unit 6 may use a microcomputer or the like, or may be configured by other circuit means. When a microcomputer is used, there are advantages such as easy handling of different types of discharge lamps.

  As the storage unit 6c, a non-volatile memory IC may be used, or a microcomputer having a similar function may be used.

  Note that step # 1 of “detection of detection unit impedance” may be performed not only once but a plurality of times to make it less susceptible to noise and the like. If it is determined that there is an impedance change in Step # 2 of “Impedance Change (Judgment)”, the impedance is checked again to determine whether or not the impedance change is confirmed multiple times (set For a predetermined number of times). By doing so, it is possible to make more accurate determination without being affected by disturbances such as noise.

  Further, the curve of the target supply power to the discharge lamp in the processing step # 10 of “discharge lamp type determination lighting” is the predetermined power curve of the mercury-filled lamp D2 and the predetermined power curve of the mercury-free lamp D4 in the first embodiment. The predetermined power curve of the mercury-enclosed lamp D2 with the lower output power was used, but the maximum supply current value to the discharge lamp specified for each type of discharge lamp does not exceed the lower value similarly. If power control is performed in this manner, it is more preferable because application of excessive stress to the discharge lamp can be prevented.

  In this embodiment, the case where the discrimination of the discharge lamp type is performed based on the lamp voltage of the discharge lamp is exemplified. However, as shown in the description of the prior art, there is a difference in the lamp current of the discharge lamp between the discharge lamps of different types. Therefore, the type of the discharge lamp may be determined based on the lamp current of the discharge lamp. Further, the type of the discharge lamp may be determined based on both the lamp voltage and the lamp current. By confirming the difference between the characteristics of the both, it is possible to more reliably determine the type of the discharge lamp.

  An example of another configuration of the detection unit 7 will be described below. FIG. 6 shows the configuration of another discharge lamp attachment / detachment detection unit. FIG. 6 (a) is when the discharge lamp is not mounted, and FIG. 6 (b) is when the discharge lamp is mounted. In the present configuration of the detection unit, a discharge lamp attachment / detachment detection rotation unit 78 is provided, and when the discharge lamp 5 is inserted into and removed from the socket 70, the rotation unit 78 hits the discharge lamp base 51, and the discharge lamp It is comprised so that it may rotate by the operation | movement of 5 insertion / extraction. The operation of the main part is shown in FIG. As shown in FIG. 7, the rotation part 78 is provided with a rotation lock mechanism (not shown) and can rotate in the right direction (clockwise), but can rotate in the left direction (counterclockwise). Therefore, only when the discharge lamp 5 is inserted into the socket 70, the rotating part 78 rotates. By this rotation operation, a variable resistor or the like (not shown) is varied, and the impedance value of the detection unit 7 is changed.

(Embodiment 1-2)
FIG. 8 shows a discharge lamp type discrimination method according to Embodiment 1-2 of the present invention. This embodiment is different from the above-described first embodiment in that the lighting method at the time of discharge lamp type determination is changed from predetermined power control to predetermined current control.

  A representative example of a change in lamp current with respect to an elapsed time after lighting when each of a mercury-filled lamp and a mercury-free lamp is lit at a predetermined power suitable for each type of discharge lamp shown in FIG. This is shown in FIG. As shown in FIG. 8B, when the lamp is lit at a predetermined power, a larger lamp current flows from immediately after the lamp is lit to when it is steadily lit than the mercury-filled lamp.

  Therefore, in the present embodiment, lighting at the time of discharge lamp type determination is performed in accordance with the lamp current characteristics of the mercury-enclosed lamp (as shown in FIG. 8B) as shown in FIG. 8C (for example, The lamp is lit with a predetermined current control at a target value of the lamp current (substantially equivalent). The determination of the type of discharge lamp is performed with the difference in lamp voltage change during the period t1 and t2 shown in FIG. 8C (same as in the first embodiment).

  In this embodiment, compared to the first embodiment, the lighting method for determining the type of the discharge lamp is set to a predetermined current control, so that the lighting device is for a mercury-filled lamp, and the mercury-free lamp is installed by mistake. Since the value of the current (lamp current) that flows through the device when the discharge lamp type is determined to be turned on can be made lower and the same value as when a normal mercury-enclosed lamp is lit, the stress on the device is more This makes it possible to reduce the size of the apparatus and solve problems such as an increase in size and cost.

  In this embodiment, the target current value of the predetermined current control is made variable according to the elapsed time after lighting, but it may be turned on with a constant target current value. In this case, the target current value may be set to about the upper limit (for example, 0.5 A) of the lamp current that can be taken during normal lighting when, for example, a mercury-filled lamp is lit.

  Further, as in the first embodiment, even when the lighting method at the time of determining the discharge lamp type is the predetermined power control, the supply current according to the lamp current characteristics of the mercury-enclosed lamp (shown in FIG. 8B) By setting the upper limit value (limit value), the current that flows in the device during lamp type discrimination lighting when the lighting device is for a mercury-filled lamp and the mercury-free lamp is installed by mistake (lamp) Since the value of (current) can be set to the same value as when the mercury-enclosed lamp is lit, the same effect can be obtained.

(Embodiment 2)
FIG. 9 shows the operation of the discharge lamp lighting device according to the second embodiment of the present invention. The differences from the first embodiment described above are only the discharge lamp type determination lighting / compatibility determination 2 in step α, the circuit operation stop in step β, and the lighting operation after determination in step γ. I will omit it.

FIG. 10 shows a flowchart of the discharge lamp type determination lighting / compatibility determination 2 in step α.
The operation will be described below with reference to the flowchart of FIG.

In the step of α0, an initial value of time (TIME) is set from the lamp state.
In the α1 step, control is performed during no-load operation in order to turn on the lamp after the power is turned on.
In the step α2, it is determined whether the lamp is lit, and the no-load operation is repeated until the lamp is lit.
In the α3 step, time (TIME) is counted.

In the α4 step, the power target value (S_WLA) of the mercury-enclosed lamp is read using time (TIME) as a variable.
In step α5, the output voltage value and output current value are read.
In the step of α6, the output current target value is calculated by dividing the power target value (S_WLA) by the lamp voltage (Vla).

  In step α7, it is determined whether or not the time (TIME) exceeds a predetermined time T2 (for example, 60 seconds) (determines whether or not the lamp has been stabilized). If α8) has elapsed, the type of discharge lamp is determined (α9).

  In the step α8, the lighting control is performed by comparing the output current target value and the output current (Ila), and control is performed so that the power of the power target value is applied to the lamp.

  In step α9, it is determined whether the lamp is mercury-filled or mercury-free depending on whether the lamp voltage is equal to or higher than a predetermined voltage V2 (for example, 63 V). In the case of the mercury-encapsulated type, the process proceeds to # 11a, and in the case of mercury-free, the process proceeds to # 11b.

  # 11a and # 11b are details of step # 11 of recording of the determination result storage unit in FIG. 9, and the determination result storage unit records whether the mounted lamp is compatible with or not compatible with the lighting device. In this example, since the lighting device is for a mercury-filled lamp, if Vla ≧ predetermined voltage V2, the process proceeds to # 11a and “conformity” is recorded in the determination result storage unit, and Vla <predetermined voltage. In the case of V2, the process proceeds to # 11b and “nonconformity” is recorded in the determination result storage unit. If the lighting device is for a mercury-free lamp, the conformity / nonconformity of # 11a and # 11b is reversed.

The step of confirming the storage unit content in # 12 is the same as that in the first embodiment.
In step β, the circuit operation is stopped for a moment (notifying the operator of the completion of determination).
In step γ, a lighting operation after determination (power-on at restart) is performed.

  By performing the operation of the above flowchart, each electrical characteristic changes as shown in FIG. About 60 seconds when power is supplied to the mercury-enclosed lamp so that no stress is applied to either the mercury-free lamp or the mercury-enclosed lamp during the period of the discharge lamp type determination lighting / compatibility determination 2 in step α. Both lamps are stable, and the lamp voltage is rated so that a mercury-enclosed lamp is 85V and a mercury-free lamp is 42V. Therefore, the type of lamp is determined at step α9 in the flowchart of FIG. Thereafter, when it is determined that the lamp is suitable in the first embodiment, the lighting operation is continued as it is. However, in this embodiment, in order to temporarily stop the circuit operation in step β, as shown in FIG. , The luminous flux falls abruptly (flashes) for a moment. Then, the lighting operation at the time of restart is performed as the lighting operation after determination.

  According to the present embodiment, it is possible to notify the outside that the discharge lamp type determination has been completed by abruptly dropping the luminous flux, and the discharge lamp type determination can be performed even though the operator has not completed the discharge lamp type determination. It is possible to prevent erroneous determination that the type determination has ended. Thereby, the certainty of discharge lamp classification discrimination can be increased.

  In this embodiment, the signal for which the discharge lamp type determination has been completed is expressed in the form of circuit operation stop, but an output to the external panel (instrument display, external LED, etc.) or a signal for which the determination has been completed by communication is output. May be.

  In addition, when outputting to the outside that the discrimination is completed by output to the external panel or communication, at the same time, the discrimination result (conformity or nonconformity: for example, the external LED lights blue when conforming, red when nonconforming) When output, it is possible to further prevent erroneous determination of the end of discharge lamp determination.

  In the present embodiment, after the discharge lamp type determination lighting / compatibility determination 2 (step α) and the circuit operation stop (β), the lighting operation (γ) is performed again, but without performing the lighting operation, The same effect can be obtained more clearly even when the flow goes from the turn-off operation to the flow of waiting for power-on (steps # 6 and # 7).

  In the present embodiment, the discharge lamp type determination is performed based on whether or not the lamp voltage value exceeds the predetermined voltage V2 in step α9 in the flowchart of FIG. It may be judged by whether or not 6A) is exceeded. For example, if it is 0.6 A or more, it is determined as a mercury-free lamp, and if it is less than 0.6 A, it is determined as a mercury sealed lamp.

(Embodiment 3)
12 and 13 show Embodiment 3 of the present invention. In the third embodiment, only the detection method by the detection unit 7 and the type determination method of the discharge lamp 5 are changed from the first embodiment. FIG. 14 shows a flowchart of the operating state of the lighting device. The description of the same points as in the first embodiment will be omitted below.

  Regarding the detection unit 7, in the third embodiment, the power conversion unit 23, the control unit 6, the detection switch Sa (see FIG. 13) provided on the outer surface of the case 8 that houses the detection unit 7, and the switch Sa are switched to change the impedance. A circuit (resistors Ra and Rb) that changes, and an impedance value detector 7s that outputs a signal notifying the controller 6 that the impedance value has changed are configured. When the switch Sa is switched between the A side and the B side, the impedance value is also switched between Ra and Rb, and the impedance value detection unit 7s detects a change in impedance and outputs a signal notifying the output power control unit 6a of the change in impedance. To do. The output power control unit 6a determines that at least a part of the connection units CN1 and CN2 of the lighting device has been disconnected by receiving this signal.

  That is, in the third embodiment, when the user and the installer of the lighting device install or replace the lighting device (when at least one of the connection portions of the lighting device is removed), the discharge lamp is switched by switching the switch Sa. The type is determined to confirm the suitability of the discharge lamp for the lighting device.

  Note that the switch Sa may be a general opening / closing switch because the state may be changed by switching. Further, the switch Sa may be installed anywhere as long as it is outside the case that houses the lighting device, such as a case that houses the igniter unit 4. Further, when it is assumed that the detection switch Sa can be switched many times by the user and the installer, instead of the resistors Ra and Rb, for example, the impedance can be changed so that the number of changes in impedance with respect to the switch Sa is increased. A resistor or the like may be used.

  14 differs from the flowchart of FIG. 3 of the first embodiment in that steps # 1a, # 2a and # 20a, # 21a of the flowchart of FIG. Yes.

  Next, as a method for determining the type of the discharge lamp 5 (step # 10a), in this third embodiment, after the power supply from the power supply unit 1s is started by the lighting switch S, the discharge lamp is determined according to the minimum value of the discharge lamp voltage. 5 is used. For example, a 35 W mercury sealed lamp (D2 lamp) is assumed as a suitable discharge lamp, and a 35 W mercury-free lamp (D4 lamp) is assumed as a discharge lamp that is erroneously mounted (determined as non-conforming).

  Further, in the determination power control mode for determining the type of lamp, in consideration of the power stress applied to the lamp, as shown in FIG. 15A, for the mercury-enclosed lamp (D2) having a smaller input power. The lamp is turned on by the power regulation curve (same as in the first embodiment). In this case, the lamp voltages of the mercury-filled lamp and the mercury-free lamp change as shown in FIG. 15B with respect to the elapsed time.

  Here, focusing on the minimum voltage of each lamp voltage, the voltage of the mercury-filled lamp (D2) is lower than that of the mercury-free lamp (D4) only for a few seconds after the power is turned on. That is, the relationship between the mercury-filled lamp voltage minimum value Vd2_min and the mercury-free lamp voltage minimum value Vd4_min is Vd2_min <Vd4_min. Accordingly, by setting the lamp type determination threshold value Vth to be Vd2_min <Vth <Vd4_min, when the minimum value of each lamp voltage during the lamp lighting period is smaller than Vth, the mercury-enclosed lamp (D2), Vth If larger, it can be determined as a mercury-free lamp (D4).

  As described above, in the third embodiment, since a part of the detection operation (switching operation of the switch Sa) is performed by the user and the installer of the lighting device, the detection unit 7 requires a more complicated mechanism. Compared to 1, the detection unit 7 can be realized with a simpler configuration, and thus the size and cost of the apparatus can be reduced.

  Further, the voltage detection method at the time of discrimination of the discharge lamp type is performed within a few seconds after the start of lighting of the discharge lamp, and the discrimination is performed based on the instantaneous value of the voltage, so that complicated calculation is not required. Therefore, there is an advantage that the type of the discharge lamp can be determined in a shorter time after the power is turned on.

Embodiment 3-2
In the third embodiment, the following settings may be considered. In the embodiment 3-2, when the switch Sa is switched to the A side, “discharge lamp type determination lighting” is forcibly performed, the type of the discharge lamp is determined, and it is determined whether or not the lamp is a suitable lamp. A series of operations for recording the determination result in the storage unit 6c is performed. On the other hand, when the switch Sa is switched to the B side, the contents recorded in the storage unit 6c are checked, and when it is determined that the lamp is suitable, “predetermined power lighting operation” is performed, and the lamp is determined to be non-compliant. In this case, “light-off operation is maintained” (same as after branching from # 3 to # 8 in the first embodiment).

  That is, when the lighting device user and the installer install or replace the lighting device (at least when any of the connecting portions is removed), first, the type of the discharge lamp 5 is changed by switching the switch Sa to the A side. After the determination (if it becomes incompatible, replace it with a compatible one and perform “discharge lamp type determination lighting” again), and switch the switch Sa to the B side to obtain a normal discharge lamp lighting operation.

  Thereby, in Embodiment 3-2, since most of detection operation is performed by the user and installation person of a lighting device, it is possible to make a detection part a simpler structure compared with Embodiment 3. In addition, since the operation of the lighting device is specified by the switching position of the switch Sa, and the ease of handling of the device is improved for the user and the installer of the device, the compatibility of the discharge lamp is more reliably confirmed. There is a merit that

(Embodiment 3-3)
As Embodiment 3-3, consider the case where the detection switch Sb is provided in the case of the igniter section 4 as shown in FIG. As shown in FIG. 17, the protruding portion 55, which is a part of the contact point between the discharge lamp 5 and the igniter unit 4, is configured to fit in 55 ′ in the drawing when connected to the igniter unit 4. Here, if the lock mechanism having the mechanism of FIG. 18 is used, the discharge lamp 5 maintains a fixed state unless the switch Sb is pressed. That is, the discharge lamp 5 cannot be replaced unless the switch Sb is pressed. In the figure, 41 is a detection projection, 42 is a spring, and 43 is a case or resin. In addition, in the mechanism shown in the first embodiment (FIG. 5B), if the discharge lamp attachment / detachment detection protrusion 71 is a switch Sb, in addition to the same effects as those shown in FIGS. There is an advantage that the replacement of the discharge lamp 5 can be reliably detected.

(Embodiment 4)
Embodiment 4 is shown in FIGS. In the fourth embodiment, the detection method by the detection unit 7 is changed from the first embodiment. FIG. 21 shows a flowchart of the operating state of the lighting device. The description of the same points as in the first embodiment will be omitted below.

  In the fourth embodiment, a connection detection line w including a detection resistor Ra is provided as a detection unit 7 that detects that each connection unit CN1, CN2, CN3 is disconnected, as shown by a bold line portion in FIG. One end of the line w is directly connected to the DC power source 1 of the power supply unit 1s, and is connected to the detection resistor Ra via each connection portion CN1, CN2, CN3 of the lighting device. Moreover, since the control power supply 6e of the control part 6 is also secured from the DC power supply 1, the voltage change of the detection part 7 by the control part 6 can be detected even when the lighting switch S is in the OFF state (any of the connection parts of the lighting device). Can be detected at any time).

  For example, as shown in FIG. 20, four-wire connectors CNa and CNb are used as the connectors of the connection portions CN1, CN2 and CN3. The input line 1 a is connected to the positive electrode of the DC power source 1 through the lighting switch S, and the output line 1 b is connected to the negative electrode of the DC power source 1. The connection detection line w-1 is connected to the positive electrode of the DC power supply 1, and the connection detection line w-2 is connected to the non-grounded end of the detection resistor Ra.

  By adopting the configuration of FIG. 19, regardless of the operation of the lighting switch S, voltage is continuously generated at both ends of the detection resistor Ra unless the connection portions CN1, CN2, CN3 are removed. Here, when any of the connection portions CN1, CN2, and CN3 is removed, the power supply to the detection resistor Ra is cut off. At this time, the detection unit 7 detects a change in the voltage across the detection resistor Ra by the voltage detection circuit 7v, and outputs a signal notifying the change in the voltage across the detection resistor Ra to the control unit 6.

  21 is different from the flowchart of FIG. 3 of the first embodiment in that steps # 1b, # 2b and # 20b, # 21b of the flowchart of FIG. is doing. Further, the difference is that the detection unit 7 sends a block detection signal to the control unit 6 at step # 22b.

  Note that it can be detected not only the voltage value across the detection resistor Ra but also the value of the current flowing through the detection resistor Ra that one of the connection parts CN1, CN2 and CN3 is disconnected. That is, if all connections are maintained, a predetermined current determined by the DC power supply voltage and the resistance value of the detection resistor Ra flows through the detection resistor Ra, but if any of the connection portions CN1, CN2, and CN3 is disconnected, the current flows. What is necessary is just to detect that becomes 0.

  Therefore, when power supply from the power supply unit 1s is started, “discharge lamp type determination lighting” is performed only when it is detected that any of the connection units CN1, CN2, and CN3 is disconnected by the above configuration (# 10). As a result of the discharge lamp type determination lighting, the determination result of the compatibility of the discharge lamp is recorded in the storage unit 6c (# 11), and when it is determined that the lamp is compatible, “continuous lighting operation” (# 13) is performed. Is determined to be non-conforming, the “light-out operation” is performed (# 15).

  If it is not detected that the connection unit has been disconnected, the contents recorded in the storage unit 6c are checked (# 3). If it is determined that the lamp is suitable, “predetermined power lighting operation” (# 4) If the lamp is determined to be non-conforming, “off operation maintenance” (# 8) is obtained.

  As described above, in the fourth embodiment, since power is secured in the control unit 6 and the detection unit 7, the detection unit 7 does not need a complicated mechanism as in the first embodiment, and is a relatively simple circuit. In addition, it is possible to reliably detect the disconnection of the connection portions CN1, CN2, and CN3 with the socket configuration.

(Embodiment 5)
Embodiment 5 is shown in FIGS. In the fifth embodiment, the setting of the connection detection line w in the fourth embodiment is changed. FIG. 24 shows a flowchart of the operating state of the lighting device. In addition, about the same structure as Embodiment 4, the overlapping description is abbreviate | omitted.

  In the fifth embodiment, as the detection unit 7 that detects that any of the connection units CN1, CN2, and CN3 is disconnected, a connection detection line w including a detection resistor Ra is provided as shown by a thick line portion in FIG. One end of the connection detection line w is directly connected to the DC power source 1 of the power supply unit 1s, and is connected to the detection resistor Ra via each connection unit CN1, CN2, CN3 of the lighting device. Moreover, since the control power supply 6e of the control part 6 is also secured from the DC power supply 1, the voltage change of the detection part 7 by the control part 6 can be detected even when the lighting switch S is in the OFF state (any of the connection parts of the lighting device). Can be detected at any time).

  Hereinafter, the connector of the connection part CN1 between the power supply part 1s and the power conversion part 23 will be described as an example. The switch Sa provided in the connector of the connection portion CN1 is closed to the A side as shown in FIG. 22 in a state where the connection portion CN1 is connected, and no power is supplied to the detection resistor Ra. Here, when the connection portion CN1 between the power supply unit 1s and the power conversion unit 23 is disconnected, the switch Sa is closed to the B side, so that power supply to the detection resistor Ra is started.

  As the connection parts CN1, CN2, CN3, it is conceivable to use, for example, 4-wire connectors CNa, CNb as shown in FIG. However, by configuring the terminals of the connection detection line w of the power supply side connector as shown in FIG. 23, for example, when the connector is not connected, the terminals of the connection detection line w are short-circuited (contacted). ) State. On the other hand, when the connector is connected, the terminal of the connection detection line w is in an open state (connected to the terminal of the load side connector). The connectors of the connection parts CN2 and CN3 can also be realized with the same configuration.

  When all the connection parts CN1, CN2, CN3 are connected, the switches Sa, Sb, Sc of FIG. 22 are in the illustrated state, and no current flows through the detection resistor Ra. When any of the connection portions CN1, CN2, and CN3 is disconnected, the corresponding switches Sa, Sb, and Sc are in a state opposite to the illustrated state, and a current flows through the detection resistor Ra.

  As described above, when it is detected that any of the connection parts CN1, CN2, and CN3 is removed by using the configurations of FIGS. 22 and 23, when power supply is started from the power supply part 1s, “Discharge lamp type discrimination lighting” is set (# 10). As a result of the discharge lamp type determination lighting, the determination result of the compatibility of the discharge lamp is recorded in the storage unit 6c (# 11), and when it is determined that the lamp is compatible, “continuous lighting operation” (# 13) is performed. Is determined to be non-conforming, the “light-out operation” is performed (# 15).

  If it is not detected that the connection unit has been disconnected, the contents recorded in the storage unit 6c are checked (# 3). If it is determined that the lamp is suitable, “predetermined power lighting operation” (# 4) If the lamp is determined to be non-conforming, “off operation maintenance” (# 8) is obtained.

  24 is different from the flowchart of FIG. 3 of the first embodiment in that steps # 1c, # 2c and # 20c, # 21c of the flowchart of FIG. is doing. Further, the difference is that the detection unit 7 is configured to send a continuity detection signal to the control unit 6 in step # 22c.

(Embodiment 5-2)
Next, FIG. 25 and FIG. 26 show Embodiment 5-2. In the embodiment 5-2, the power conversion unit 23 is always supplied with power from the DC power source 1, and the lighting switch S connected to the DC power source 1 through a different path is turned on. The lighting operation of the discharge lamp 5 is started.

  The power conversion unit 23 includes a DC-DC converter unit 2 that converts a power supply voltage into a voltage required for the discharge lamp 5 and a full-bridge inverter unit 3 that converts an output voltage of the DC-DC converter unit 2 into an alternating current. Composed. Further, a connection socket 70 is provided as a connection part CN3 for connecting the igniter part 4 and the discharge lamp 5, and a detection part 7 for detecting that the discharge lamp 5 has been removed is provided in the connection socket 70.

  In the embodiment 5-2, the connection detection line w ′ shown in the embodiment 5 and a power supply line for supplying power necessary for lighting the discharge lamp 5 (DC power supply 1, power conversion unit 23, igniter unit 4, connection) Socket 70 and connection line of discharge lamp 5).

  26, as shown in FIG. 26, the center electrode connecting terminal 73 and the outer peripheral electrode connecting terminal 74 of the socket 70 (the structure of the socket itself is the same as that of the first embodiment) are the same as the socket 70 and the discharge lamp 5. When the discharge lamp 5 is connected to the socket 70, it is in an open state (connected to the terminals 53 and 54 of the discharge lamp 5) when not connected. The socket 70 can be applied as the connector CN3 (switch Sc) of the fifth embodiment.

  Here, in Embodiment 5-2, since the power is always supplied to the power conversion unit 23, the control unit 6 can drive the power conversion unit 23. Therefore, when the DC-DC converter unit 2 is driven with the switch elements Q2 and Q5 (or Q3 and Q4) of the inverter unit 3 closed while the lighting switch S is turned off, the connection of the center electrode of the socket 70 is performed. If the connection terminal 73 and the peripheral electrode connection terminal 74 are in a short-circuited state, almost no voltage is generated at the output end of the DC-DC converter unit 2 (to the extent that a slight voltage due to circuit impedance is generated). If the center electrode connection terminal 73 and the outer electrode connection terminal 74 are in an open state, a voltage is generated at the output end of the DC-DC converter unit 2 (at this time, almost no current flows, so the loss is extremely small). Therefore, it is possible to determine whether or not the socket 70 and the discharge lamp 5 are connected by detecting the voltage value or current value of the output terminal of the DC-DC converter unit 2 at this time.

  With the above configuration, when the detection unit 7 detects that the socket 70 and the discharge lamp 5 are not connected, when the power supply is started from the power supply unit 1s, “discharge lamp type determination lighting” is performed. As a result of the discharge lamp type determination lighting, the determination result of the suitability of the discharge lamp is recorded in the storage unit 6c, and when it is determined that the lamp is suitable, “continuous lighting operation” is performed, and when it is determined that the lamp is nonconforming “Lights off”.

  If it is not detected that the connecting part has been disconnected, the contents recorded in the storage unit 6c are checked. If it is determined that the lamp is suitable, the “predetermined power lighting operation” is performed, and the lamp is determined to be nonconforming. If it is, the “lighting off operation is maintained”.

  As described above, in the fifth embodiment, compared to the fourth embodiment, power is supplied to the connection detection line only when one of the connection portions is disconnected. Therefore, there is an effect of reducing power consumption in the connection detection line.

  Furthermore, in Embodiment 5-2, it is not necessary to newly provide a connection detection line, and the cost and size of the lighting device can be further reduced.

(Embodiment 6)
FIG. 27 shows a block diagram of the sixth embodiment. A difference from the fourth embodiment is a switch Q6 in series with the resistor Ra and a drive signal from the control unit 6 that operates to turn off the switch Q6 during the discharge lamp lighting operation.

  FIG. 28 shows an operation flow of this embodiment. Steps # 01 and # 02 are added to the flow of FIG. Step # 01 is a step of outputting a connection detection line interruption detection stop signal. When the power is turned on, the switch Q6 is turned off. Step # 02 is a step of outputting a connection detection line interruption detection start signal. After the light is turned off, the switch Q6 is turned on while waiting for the next power ON.

  A difference from the fourth embodiment is that an OFF signal of the switch Q6 is output during the lighting operation (memory discrimination type operation). By doing so, the flow # 20b to # 22b of (connection detection line interruption detection) → (interruption determination) → (detection part interruption signal output), which has always been performed in the fourth embodiment, is not performed. Others are the same as those of the fourth embodiment, and redundant description is omitted.

  During the lighting operation, it is unlikely that the connecting portion is disconnected, and keeping the current flowing through the connection detection line w during the lighting operation leads to an increase in power consumption. Therefore, if the switch Q6 in series with the resistor Ra is turned off as in the present embodiment, the current flowing through the connection detection line w can be stopped during the lighting operation, reducing unnecessary current and reducing power consumption. Can be reduced.

(Embodiment 7)
FIG. 29 shows the configuration of the seventh embodiment. One end of the connection detection line w of the fourth embodiment is extended to the front panel 101, and the connection detection line w can be blocked by a switch Sw provided on the front panel 101. Except for the provision of the switch Sw, the other configuration and operation are the same as those in the fourth embodiment, and a duplicate description is omitted.

  If this switch Sw is not present, it will remain on until a disconnection is detected again if it is determined that it is a non-conforming lamp due to unexpected noise, etc. Regardless of the ON / OFF state of the switch S, the state where the lamp is not lit continues. At this time, in order to actually detect the disconnection of the connection point, depending on the configuration of the vehicle 100 and the like, it is necessary to temporarily remove the headlamp device 105 (including the discharge lamp 5) from the vehicle 100. There are problems such as taking a lot of time.

  According to the present embodiment, since it can be performed when it is desired to perform discharge lamp type discrimination lighting, when it falls into the state as described above, it can be easily switched to the discrimination lighting mode again. The workability and safety in the case can be improved.

  In the present embodiment, a method of providing the reconfirmation start switch Sw on the connection detection line w has been described as a method of determining the discharge lamp type. However, if the same effect can be obtained, the discharge lamp can be obtained by in-vehicle communication. Even if a method such as causing the lighting device to determine the discharge lamp type, or causing the lighting switch S to be turned ON / OFF in a state where the lamp is not lit multiple times, the discharge lamp type is determined. Good.

(Embodiment 8)
FIG. 30 shows the overall circuit configuration of the eighth embodiment. In the present lighting device, in a state where the power supply unit 1s and the connection portion CN1 between the lighting devices are connected, power is always supplied from the DC power source 1 to the power conversion unit 23, and the discharge lamp 5 Is turned on / off by a lighting switch S provided separately. Specifically, when the lighting switch S is on, the DC power supply voltage is applied to the controller 6 of the lighting device, and when the lighting switch S is off, the DC power supply voltage is applied to the controller 6 of the lighting device. No longer joins. In response to the change of the lighting signal, the control unit 6 determines whether the discharge lamp 5 is turned on or off, and drives the power conversion unit 23. The connection part CN1 is constituted by a connector or the like.

  FIG. 31 shows an operation flow of the discharge lamp lighting device according to the eighth embodiment. This flowchart is shown in a form opposite to the flowchart (FIG. 3) of the operation state of the discharge lamp lighting device shown in the first embodiment, and the operationally different portions are clearly indicated by bold lines.

Hereinafter, the operation flow will be described in order.
In step # 0 ′ of “lighting switch on”, the lighting switch S of the power supply unit 1s is turned on, and when the lighting signal corresponding to “lighting switch on” is given to the control unit 6, It is considered that the switch is turned on, and the process proceeds to the next step # 1 ′.

In step # 1 ′ of “power connection history confirmation”, the contents of the history indicating the state of power connection described later are confirmed.
In the determination step # 2 ′ of “power connection history”, a branch is made depending on whether the content confirmed above is set or clear. As a result, in the case of a set, when it is determined that the type of the discharge lamp mounted in the “step to check the contents of the memory” in the next step is appropriate, the normal lighting operation is performed, and the lamp is lit quickly and clear. In this case, the process proceeds to a lighting operation for determining the type of the discharge lamp 5.

  In the determination step # 3 of “confirm storage unit content”, as described above, the content of whether the type of the mounted discharge lamp recorded in the storage unit is compatible or not is confirmed. The process proceeds to “lighting operation” (# 4), and in the case of non-conformity, the process proceeds to “maintain extinction state” (# 8 ′).

Step # 4 of the “predetermined power lighting operation” is the same as that in the first embodiment, and a description thereof will be omitted here.
In the determination step # 5 ′ of “lighting switch off”, when the lighting switch S of the power supply unit 1s is turned off and a lighting signal corresponding to the lighting switch off is given to the control unit 6, the lighting switch is turned on. Considering that the switch is off, proceed to YES, otherwise proceed to NO, and perform the lighting operation (predetermined power lighting operation) until it is determined that the lighting switch is off.

  In step # 6 of the “light-off operation”, the discharge lamp is turned off and the circuit is stopped by stopping the driving signal and the like based on the above-described determination of turning off the lighting switch.

  In determination step # 7 ′ of “lighting switch on”, when the lighting switch S of the power supply unit 1s is turned on and a lighting signal corresponding to the lighting switch on is given to the control unit 6, the lighting switch is turned on. It is regarded as ON, and the process proceeds to YES to perform a “predetermined power lighting operation” (here, the place to return is different from the flow of the first embodiment). Otherwise, proceed to NO and continue monitoring the lighting signal.

  If the power supply to the lighting device is completely lost due to power interruption, etc., and the electrical circuit operation of the lighting device is completely stopped in such a case, the lighting switch is turned on after the next power connection. The operation starts from “switch-on for lighting” which is the first step # 0 ′ of the flowchart of FIG.

  In step # 10 of “Discharge lamp type determination lighting / compatibility determination”, in the determination step # 2 ′ of “Power connection history”, if the confirmation result is clear, the control unit 6 uses the discharge lamp type determination lighting in advance. The drive signal is given to the power conversion unit 23 so that the target power set to be set to, and the discharge lamp 5 is lit. What is the type of the lit discharge lamp 5 depending on the value of the lamp voltage Vla detected at that time? Determine if it exists. And it is determined whether a discharge lamp suits a lighting device. The discharge lamp type determination lighting method is the same as that of the first embodiment.

In step # 11 of “record determination result storage unit”, the result of compatibility determination in “discharge lamp type determination lighting / compatibility determination” is recorded in the storage unit.
In step # 11 ′ of “power connection history set”, the contents of the power connection history are set.

  At the determination step # 12 of “confirm storage unit content”, the content of whether the type of discharge lamp in the storage unit is conforming or nonconforming is confirmed. If conforming, “continuous lighting operation” (# 13) is determined. Shifts to “light-out operation” (# 15).

  In step # 13 of “continuous lighting operation”, the power supply operation is continuously performed to the discharge lamp 5, and the discharge lamp 5 is shifted to the stable lighting state as it is.

  In determination step # 14 ′ of “lighting switch off”, the lighting switch S of the power supply unit 1s is turned off, and the lighting switch off when the lighting signal corresponding to the lighting switch off is given to the control unit 6 Therefore, the process proceeds to YES, proceeds to “extinguishing operation” (# 6), otherwise proceeds to NO, and performs “continuous lighting operation” (# 13) until the lighting switch-off determination is made.

  In step # 8 'of "maintain off state", the output operation to the discharge lamp 5 is stopped and the off state is maintained. When the contents of the storage unit are incompatible, the light-off state is maintained as a result.

  Next, in step # 20 'of "Power connection state detection", the control unit 6 monitors the power connection state (whether the connection with the power source has been disconnected).

  In the judgment step # 21 ′ of “Power off”, “Yes” is indicated when the connection with the power source is cut off, and “No” is indicated otherwise to Step # 22 ′ of “Clear power connection history”. Subsequently, the state of the power connection (whether the connection with the power source has been disconnected) is monitored in step # 20 ′ of “power connection state detection”.

In step # 22 ′ of “clear power connection history”, if the power is turned off, the contents of the power connection history are cleared.
Next, the specific contents of the determination of “power connection history” (whether or not the power is turned off) will be described.

  In this embodiment, the normal power is always supplied to the discharge lamp lighting device, and the discharge lamp 5 is turned on / off by operating a lighting signal to the control unit 6 with the lighting switch S. Although not shown, the power is always supplied to the control unit 6. For example, when the control unit 6 is configured using a microcomputer or the like, the power connection history is stored in the memory of the microcomputer (memory that can be written / read out together). Thus, it can be configured to check with a RAM that holds the recorded value while the power is supplied to the microcomputer. Specifically, when the power is supplied to the lighting device for the first time after being connected to the power source, the memory of the microcomputer is initialized (initialization is performed). By providing such a memory for recording the power connection history, the memory portion is also initialized when the power is supplied for the first time. This is the “clear” state in the flowchart.

  Then, the series of operations of “power supply connection state detection” in step # 20 ′ and “power supply disconnection (determination)” in step # 21 ′ described in the flowchart of FIG. 31 is performed according to the state of this memory. As described above, when the power is supplied for the first time, the “clear” state is initialized, and step # 10 of “discharge lamp type determination lighting / compatibility determination” in the flowchart of FIG. Only when # 11 is executed, in step # 11 ′ of the subsequent “power connection history set”, the contents of the memory are set to the “set” state. After that, unless the power supply is interrupted, this “ Maintain the "set" state (do not rewrite to "clear").

  With the above configuration and operation, the contents of the power connection history (memory contents) are in a “clear” state when power is supplied for the first time, and then the lighting switch S is turned on. After steps # 10 and # 11 of “determination” and “record determination result storage unit” are executed and the determination result of suitability / non-conformity of the discharge lamp 5 is recorded in the storage unit, it becomes “set”. It is possible to check the history of the memory using a memory.

  As described above, the present invention can be easily implemented by using a configuration such as using a memory of a microcomputer. In addition, although description is omitted here, the lighting and determination method for determining the type of the discharge lamp may be the same as in the first embodiment, for example.

  In the present embodiment, when the discharge lamp is turned on for the first time after the connection portion CN1 (configured by a connector or the like) with the power supply portion 1s is removed, the discharge lamp type determination operation is always performed, and excessive stress is applied to the discharge lamp 5. The discharge lamp 5 is turned on without adding, the type of the discharge lamp 5 is determined, and the discharge lamp 5 is turned on promptly or non-conforming when a suitable discharge lamp is mounted using the result from the next time. When the discharge lamp is mounted, the extinguished state is maintained (the lighting operation is not performed), so that it is possible to prevent the occurrence of the problem described in the conventional example.

  By using each of the first to eighth embodiments described above for a discharge lamp lighting device for a vehicle headlamp, a highly reliable vehicle lamp (vehicle headlamp device) can be obtained.

  FIG. 32 shows an example of the configuration of a vehicle headlamp lamp in which the discharge lamp lighting device according to Embodiment 8 described above is used for a vehicle lamp. In this configuration, the illustrated discharge lamp lighting device (the main body portion) has a circular bottom surface, and is rotationally fitted (specifically, fitted into a discharge lamp mounting and replacement hole provided on the back of the lamp. (The structure is not specified and omitted), and an O-ring 94 (ring-shaped rubber part) is provided between them for waterproofing. It is attached by rotation in the right direction (clockwise) and removed by rotation in the left direction (counterclockwise). In FIG. 32, the case where D2 and D4 described above are used as the discharge lamp is described as an example, and the socket 70 is used for connection with the discharge lamp 5.

  FIG. 32A is a view of the lamp viewed from the side, and FIGS. 32B and 32C are views of the lamp viewed from the back. In the figure, 81 is a lighting device main body, 82 is a rotation prevention projection, 83 is a power connection line, 84 is a socket connection line, 91 is a front lens, 92 is a reflector, 93 is a lamp cover, and 94 is an O-ring. .

  The lighting device main body 81 is connected to the power supply unit 1s and the power supply connector CN1, and is supplied with a power supply and a lighting signal. The lamp is provided with a rotation preventing projection 82 so that the lighting device main body 81 cannot be removed when the power supply connector CN1 is connected to the lighting device main body 81. The rotation in the direction (the rotation in the left direction) cannot be performed unless the power supply connector CN1 is removed from the lighting device main body 81 (unless it is pulled out).

  According to this configuration, when replacing the discharge lamp 5, it is necessary to remove the power connector CN1 from the lighting device body 81. Therefore, when replacing the discharge lamp, the power supply unit 1s, the discharge lamp lighting device, When the above-mentioned discharge lamp lighting device is used here, the discharge lamp type determining lighting operation is always performed after the discharge lamp replacement, and higher reliability can be obtained.

  In this embodiment, D2 and D4 are illustrated as discharge lamps, but the present invention can be similarly applied to D1, D3, and the like. In addition, in the case of D2, D4, etc., the discharge lamp lighting device includes a configuration having an igniter portion in the socket.

  Furthermore, the discharge lamp lighting device main body has a circular shape and is illustrated and described with respect to a configuration in which the discharge lamp lighting device is rotationally fitted to the back of the lamp. Not as long. For example, the main body of the discharge lamp lighting device is installed in the lower part of the lamp, and a separate cover is provided in the hole for mounting and replacing the discharge lamp. When the cover is removed, the power supply to the lighting device is always opened. It may be configured such that

It is a block circuit diagram which shows the basic composition of this invention. It is a block circuit diagram which shows the structure of Embodiment 1 of this invention. It is a flowchart which shows operation | movement of Embodiment 1 of this invention. It is a wave form diagram for operation | movement description of Embodiment 1 of this invention. It is explanatory drawing which shows the structural example of the discharge lamp attachment / detachment detection part of Embodiment 1 of this invention. It is explanatory drawing which shows the other structural example of the discharge lamp attachment / detachment detection part of Embodiment 1 of this invention. It is operation | movement explanatory drawing of the discharge lamp attachment / detachment detection part of Embodiment 1 of this invention. It is a wave form diagram for explanation of operation of Embodiment 1-2 of the present invention. It is a flowchart which shows operation | movement of Embodiment 2 of this invention. It is a flowchart which shows the principal part operation | movement of Embodiment 2 of this invention. It is a wave form diagram for explanation of operation of Embodiment 2 of the present invention. It is a block circuit diagram which shows the structure of Embodiment 3 of this invention. It is a schematic perspective view which shows the installation place of the switch for a detection used for Embodiment 3 of this invention. It is a flowchart which shows operation | movement of Embodiment 3 of this invention. It is explanatory drawing which shows the classification determination method of the discharge lamp in Embodiment 3 of this invention. It is a schematic perspective view which shows the external appearance of the igniter part used for Embodiment 3-3 of this invention. It is the schematic which shows the structure of the connection part of the discharge lamp and igniter part in Embodiment 3-3 of this invention. It is a schematic sectional drawing which shows the structure of the detection part used for Embodiment 3-3 of this invention. It is a block circuit diagram which shows the structure of Embodiment 4 of this invention. It is a perspective view which shows the structure of the connector used for Embodiment 4 of this invention. It is a flowchart which shows operation | movement of Embodiment 4 of this invention. It is a block circuit diagram which shows the structure of Embodiment 5 of this invention. It is a principal part perspective view which shows the structure of the connector used for Embodiment 5 of this invention. It is a flowchart which shows operation | movement of Embodiment 5 of this invention. It is a block circuit diagram which shows the structure of Embodiment 5-2 of this invention. It is explanatory drawing which shows the structural example of the discharge lamp attaching / detaching part of Embodiment 5-2 of this invention. It is a block circuit diagram which shows the structure of Embodiment 6 of this invention. It is a flowchart which shows operation | movement of Embodiment 6 of this invention. It is explanatory drawing which shows the principal part structure of Embodiment 7 of this invention. It is a block circuit diagram which shows the structure of Embodiment 8 of this invention. It is a flowchart which shows the whole operation | movement of Embodiment 8 of this invention. It is explanatory drawing which shows the structure of the lamp | ramp for vehicle headlamps using Embodiment 8 of this invention. It is operation | movement explanatory drawing of the discharge lamp lighting device of a prior art example. It is a circuit diagram of the discharge lamp lighting device of a prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 DC power supply 5 Discharge lamp 6 Control part 6b Discharge lamp discrimination | determination part 6c Storage | storage part 6h Judgment part 7 Detection part

Claims (16)

Connected to a power supply unit composed of a DC power supply and a lighting switch, and converts the input power from the power supply unit into power required for the discharge lamp, and connected to the discharge lamp to start the discharge lamp At least one of an igniter that generates a necessary high-voltage pulse, a connection between the power supply unit and the power converter, a connection between the power converter and the igniter, and a connection between the igniter and the discharge lamp. A discharge lamp lighting device comprising a detection unit for detecting that one connection unit has been disconnected and a control unit for controlling power supplied to the discharge lamp, wherein the control unit detects a voltage supplied to the discharge lamp. A voltage detection unit that detects the current supplied to the discharge lamp, a discharge lamp determination unit that determines the type of the discharge lamp based on the output of at least one of the voltage detection unit or the current detection unit, and , Said release A determination unit that determines whether or not the discharge lamp determined by the lamp determination unit is compatible with the lighting device; and a storage unit that stores a determination result by the determination unit, wherein at least one connection unit in the detection unit When detecting the disconnection, the control unit drives the power conversion unit in the determination power control mode for determining the type of the discharge lamp, and the discharge lamp determination unit determines the type of the discharge lamp. Thereafter, when the determination unit determines that the discharge lamp is suitable, the determination result is stored in the storage unit, and the voltage detection unit and the current are controlled with predetermined power control according to the type of the stored discharge lamp. According to the output of the detection unit, the power conversion unit is driven to control the lighting of the discharge lamp. When the determination unit determines that the discharge lamp is not suitable, the determination result is stored in the storage unit. And the detection unit Until it is detected that at least one connecting portion is deviated, the discharge lamp lighting apparatus, characterized in that control to stop the driving of the power conversion unit. The discharge lamp lighting device according to claim 1, wherein the control unit outputs a signal indicating completion of discrimination after the type of the discharge lamp is discriminated by the discharge lamp discriminating unit. The discharge lamp lighting device according to claim 1, wherein the detection unit includes an impedance variable circuit whose impedance value changes only when at least one connection unit is removed. The detection unit includes a switching switch unit provided outside a case containing at least one of the power conversion unit or the igniter unit, and at least one connection unit is disconnected by switching the switching switch unit. The discharge lamp lighting device according to claim 1, wherein the discharge lamp lighting device is configured to detect this. It has a connection detection line connected from the DC power source to at least one of the power conversion unit, the igniter unit, and the discharge lamp, and the detection unit has at least one connection due to a change in impedance value of the connection detection line. The discharge lamp lighting device according to claim 1, wherein the discharge lamp lighting device is configured to detect that the unit is detached. 6. The discharge lamp lighting device according to claim 5, wherein electric power is supplied from the DC power source to the connection detection line only when at least one connection portion is disconnected. The control unit drives the power conversion unit in the determination power control mode only when it has been continuously confirmed that the at least one connection unit has been disconnected for a predetermined number of times. The discharge lamp lighting device according to any one of the above. The discharge lamp lighting device according to claim 1, wherein the detection unit is invalidated during a period in which the discharge lamp is lit. 9. The power control mode for determination is power control with the lowest power applied to a discharge lamp among power controls for lighting a discharge lamp assumed to be erroneously mounted. A discharge lamp lighting device according to claim 1. The discharge lamp lighting device according to any one of claims 1 to 9, wherein the determination power control mode is power control in which a discharge lamp current is set to a predetermined value. The discharge lamp determining unit determines the type of the discharge lamp based on a discharge lamp voltage value or a discharge lamp current value after a first predetermined time has elapsed after power supply from the power supply unit is started. The discharge lamp lighting device according to any one of claims 1 to 10. The discharge lamp discriminating unit is a discharge lamp voltage that changes between when a second predetermined time elapses and when a third predetermined time elapses after power supply from the power supply unit is started. The discharge lamp lighting device according to any one of claims 1 to 10, wherein the type of the discharge lamp is determined based on a change amount of the discharge lamp current. The discharge lamp determination unit determines the type of the discharge lamp based on the minimum value of the discharge lamp voltage value after power supply from the power supply unit is started. Discharge lamp lighting device. When the determination unit determines that the discharge lamp is not suitable and the reset signal is input to the control unit in a state where the driving of the power conversion unit is stopped, the discharge lamp determination unit determines the type of the discharge lamp. The discharge lamp lighting device according to any one of claims 1 to 13. The vehicle lamp which has a discharge lamp lighting device in any one of Claims 1-14. The vehicular lamp having the discharge lamp lighting device according to any one of claims 1 to 15, comprising a configuration in which the connection between the DC power source and the power conversion unit is surely cut off when the discharge lamp is replaced.

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