JP6668648B2 - Indicator light device - Google Patents

Description

  The present invention relates to an indicator light device.

  2. Description of the Related Art Conventionally, a plurality of light emitting diodes are used in an indicator light device such as a direction indicator. Such an indicator light device is equipped with a disconnection detection function (for example, see Patent Documents 1 to 3).

  The disconnection detection function determines that a disconnection occurs when the current flowing through the light emitting diode falls below a certain value. In such a disconnection detection function, the determination value for disconnection detection is constant regardless of the output load. Therefore, when a state occurs in which only part of the lamp is turned on as in a sequential turn, that is, when the output load fluctuates, it is necessary to secure an input current of a certain value or more so that the current does not become less than the determination value of disconnection detection. There is.

JP 2004-168076 A JP 2005-116683 A JP 2011-57023 A

  Therefore, in order to secure an input current equal to or more than a certain value in consideration of a change in the output load, a certain certain pseudo load is required at a minimum. However, when the pseudo load current flowing in the pseudo load is set to a constant value, power consumption is excessively increased, and therefore, power consumption cannot be reduced.

  In a constant voltage power supply circuit included in the indicator lamp device, specifically, in a DC-DC circuit, an input current changes with a change in an input voltage. For example, as the input voltage decreases, the input current increases, but as the input voltage increases, the input current decreases. Therefore, if the determination value of the disconnection detection is a constant value, even if the constant voltage power supply circuit can correctly detect the disconnection based on the input current at the rated voltage, the disconnection may be erroneously detected at a voltage other than the rated voltage. There is.

  Therefore, in the related arts described in Patent Documents 1 to 3, when the output load fluctuates, malfunction may not be prevented without consuming extra power.

  The present invention has been made to solve the conventional problem, and an object of the present invention is to prevent a malfunction without excessively consuming power even when an output load fluctuates. It is to provide an indicator light device that can perform the following.

In order to achieve the above object, an indicator lamp device according to the present invention includes a constant voltage power supply circuit, a light emitting circuit which is in series with the constant voltage power supply circuit, and emits light by power supplied from the constant voltage power supply circuit, A pseudo load circuit that is in parallel with the constant voltage power supply circuit and the light emitting circuit and compensates for a decrease in the input current of the constant voltage power supply circuit with a pseudo load current; and drives the light emitting circuit and the pseudo load circuit, respectively. A driving circuit for controlling the pseudo load circuit, wherein the pseudo load current fluctuates according to a pseudo load reference voltage, and the light emitting circuit includes a plurality of light emitting elements connected in parallel, As the drive circuit, the number of lighting of the light emitting element is reduced, the pseudo load current increases, as the number of lighting of the light emitting element is increased, decrease the dummy load current, the light emitting element As the number of lighting increases, is characterized in that to increase the voltage of the disconnection detection threshold.

According to this indicator light device, even when the output load fluctuates, malfunction can be prevented without consuming extra power. Further, it is possible to prevent a malfunction due to a change in output load while reducing power consumption. Furthermore, even when the output current flowing through the output load fluctuates, it is possible to determine the output load, that is, the disconnection of the light emitting circuit functioning as the output circuit.

  Further, in the indicator light device according to the present invention, it is preferable that the drive circuit increases the pseudo load current as the input current decreases, and decreases the pseudo load current as the input current increases. .

  According to this indicator light device, it is possible to control the pseudo load current based on the fluctuation of the input voltage.

  The indicator lamp device according to the present invention may further include a current detection unit configured to detect an output current flowing from the constant voltage power supply circuit to the light emitting circuit, and the driving circuit may be configured to detect an output current based on a detection result of the current detection unit. When the obtained output current signal voltage flowing into the light emitting circuit is lower than the disconnection detection threshold voltage, it is preferable to turn off all the light emitting elements.

  According to this display lamp device, it is possible to realize the function of turning off all lights when one lamp is disconnected, which is required by law.

  Further, in the display lamp device according to the present invention, it is preferable that the drive circuit increases the voltage of the overcurrent detection threshold as the number of lighting of the light emitting element increases.

  According to this indicator light device, even if the output current flowing through the output load fluctuates, it is possible to determine the output load, that is, the overcurrent of the light emitting circuit functioning as the output circuit.

  The indicator lamp device according to the present invention may further include a current detection unit configured to detect an output current flowing from the constant voltage power supply circuit to the light emitting circuit, and the driving circuit may be configured to detect an output current based on a detection result of the current detection unit. When the obtained output current signal voltage flowing into the light emitting circuit is equal to or higher than the overcurrent detection threshold voltage, it is preferable to turn off all the light emitting elements.

  According to this indicator light device, the light emitting circuit can be appropriately protected.

In the display lamp device according to the present invention, wherein the drive circuit, said input current, said sum of the dummy load current, be adjusted to less than the current of the disconnection detection threshold current or more and the overcurrent detection threshold Is preferred.

  According to this indicator light device, erroneous detection of disconnection can be prevented.

  Further, in the indicator lamp device according to the present invention, the current detection unit includes a resistance element provided on a circuit that supplies the output current from the constant voltage power supply circuit to the light emitting circuit, and the driving circuit includes the driving circuit, Preferably, the output current signal voltage is obtained from a potential difference between both ends of the resistance element.

  According to this indicator light device, the output current flowing into the light emitting circuit can be obtained with a simple configuration.

  According to the present invention, even when the output load fluctuates, malfunction can be prevented without excessively consuming power consumption.

It is a figure showing an example of functional composition of indicator light device 1 concerning an embodiment. It is a figure showing an example of the circuit composition of indicator light device 1 concerning an embodiment. FIG. 6 is a diagram illustrating an example of setting an abnormality detection reference voltage. It is a figure showing an example of setting of a dummy load reference voltage.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings, but the present invention is not limited to the following embodiments.

  FIG. 1 is a diagram illustrating an example of a functional configuration of the indicator light device 1 according to the embodiment. As shown in FIG. 1, the indicator light device 1 includes a constant voltage power supply circuit 30, a light emitting circuit 40, a dummy load circuit 50, a drive circuit 60, and the like. In addition, the indicator light device 1 includes a current detection unit 70 between the constant voltage power supply circuit 30 and the light emitting circuit 40.

  The constant voltage power supply circuit 30 supplies a stable DC power supply, and includes, for example, a DC-DC converter. The light emitting circuit 40 is in series with the constant voltage power supply circuit 30 and emits light by power supplied from the constant voltage power supply circuit 30.

  The pseudo load circuit 50 has a parallel relationship with the constant voltage power supply circuit 30 and the light emitting circuit 40, and compensates for a decrease in the input current Iin1 of the constant voltage power supply circuit 30 with the pseudo load current Iin2. In the dummy load circuit 50, the dummy load current Iin2 varies according to the dummy load reference voltage.

  The drive circuit 60 controls each drive of the light emitting circuit 40 and the dummy load circuit 50. The drive circuit 60 increases the pseudo load current Iin2 while adjusting the pseudo load reference voltage based on the lighting state of the light emitting circuit 40 and the power supply voltage of the constant voltage power supply circuit 30.

  Specifically, the drive circuit 60 mainly includes a CPU (not shown), a ROM, a RAM, and an I / O interface, and the CPU executes various programs corresponding to processing contents from the ROM or the memory (not shown). Is read out, developed in the RAM, and cooperated with the developed various programs to control the operation of each part of the drive circuit 60.

  In other words, the drive circuit 60 controls the operation of the indicator light device 1 and can be realized by a microcomputer mainly composed of a CPU, a ROM, a RAM, and an I / O interface (not shown). Various functions are realized by the drive circuit 60 executing a predetermined control program.

  Next, a detailed configuration of the indicator light device 1 will be described. FIG. 2 is a diagram illustrating an example of a circuit configuration of the indicator light device 1 according to the embodiment. As shown in FIG. 2, the light emitting circuit 40 includes a plurality of light emitting elements D1 to D4 connected in parallel.

  Specifically, the resistance element R1, the light emitting element D1, and the switching element TR1 are connected in series, and the light emitting element D1 is turned on by driving the switching element TR1. Further, the resistance element R2, the light emitting element D2, and the switching element TR2 are connected in series, and the driving of the switching element TR2 turns on the light emitting element D2. Further, the resistance element R3, the light emitting element D3, and the switching element TR3 are connected in series, and the light emitting element D3 is turned on by driving the switching element TR3. Further, the resistance element R4, the light emitting element D4, and the switching element TR4 are connected in series, and the driving of the switching element TR4 turns on the light emitting element D1.

  Note that the light-emitting elements D1 to D4 are referred to as light-emitting elements D unless otherwise specified. In addition, when the resistance elements R1 to R4 are not particularly distinguished, they are referred to as resistance elements R. In addition, when each of the switching elements TR1 to TR4 is not particularly distinguished, it is referred to as a switching element TR. Switching element TR is formed of a bipolar transistor.

  In the pseudo load circuit 50, the resistance element R100, the switching element Q1, and the resistance element R101 are connected in series, and the driving of the switching element Q1 adjusts the pseudo load current Iin2. Specifically, the switching element Q1 is composed of a MOSFET, and by adjusting the gate voltage applied to the gate of the switching element Q1, the switching element Q1 functions as a variable resistor, and the pseudo load current Iin2 can be adjusted. .

  The current detecting section 70 detects an output current flowing from the constant voltage power supply circuit 30 to the light emitting circuit 40. Specifically, the current detection unit 70 includes a resistance element R10 provided on a circuit that supplies an output current from the constant voltage power supply circuit 30 to the light emitting circuit 40. Therefore, the output current flowing into the light emitting circuit 40 is obtained from the potential difference between both ends of the resistance element R10.

  The drive circuit 60 increases the pseudo load current Iin2 as the lighting state of the plurality of light emitting elements D decreases as the lighting number of the light emitting elements D decreases. The drive circuit 60 sets the lighting state of the plurality of light emitting elements D and decreases the pseudo load current Iin2 as the number of lighting of the light emitting elements D increases.

  Specifically, the drive circuit 60 includes a signal input unit 61 and a signal output unit 66. The signal input unit 61 receives a lighting signal. The lighting signal may be an analog signal or a digital signal. The signal output unit 66 acquires a lighting signal from the signal input unit 61. The signal output unit 66 lights the light emitting element D according to the lighting signal acquired from the signal input unit 61.

  The drive circuit 60 includes a pseudo load reference voltage setting unit 64 and a comparator 65. The dummy load reference voltage setting unit 64 acquires the lighting signal from the signal input unit 61, and adjusts the gate voltage of the switching element Q1 based on the comparison result between the dummy load reference voltage and the gate voltage of the switching element Q1 by the comparator 65. Then, the pseudo load current Iin2 is controlled.

  The constant voltage power supply circuit 30 controls the input current Iin1 according to the number of lighting of the light emitting element D. Specifically, as the number of light-emitting elements D increases, the output current flowing through resistance element R10 increases, so that input current Iin1 of constant voltage power supply circuit 30 increases.

  On the other hand, as the lighting number of the light emitting element D decreases, the output current flowing through the resistance element R10 decreases, so that the input current Iin1 of the constant voltage power supply circuit 30 decreases.

  The input current Iin is the sum of the input current Iin1 and the pseudo load current Iin2. When the input current Iin decreases below the preset operation set value due to the decrease in the input current Iin1, there is a possibility that the disconnection state is erroneously determined. Therefore, the drive circuit 60 increases the pseudo load current Iin2 in order to avoid an erroneous determination of disconnection due to a decrease in the input current Iin.

  That is, the drive circuit 60 increases the pseudo load current Iin2 as the input current Iin1 decreases. On the other hand, the drive circuit 60 decreases the pseudo load current Iin2 as the input current Iin1 increases.

  Specifically, the drive circuit 60 includes a comparator 62. The comparator 62 calculates a potential difference between both ends of the resistance element R10. The signal input unit 61 obtains an output current signal voltage flowing into the light emitting circuit 40 based on a potential difference between both ends of the resistance element R10 acquired from the comparator 62.

  The drive circuit 60 increases the disconnection detection threshold as the number of light-emitting elements D increases. Specifically, the drive circuit 60 includes an abnormality detection threshold value setting unit 63. The abnormality detection threshold setting unit 63 acquires a lighting signal from the signal input unit 61 and changes the setting of the disconnection detection threshold according to the number of lighting of the light emitting element D. In other words, the input current Iin1 increases as the number of light-emitting elements D increases, so the drive circuit 60 sets a disconnection detection threshold corresponding to the increase in the number of light-emitting elements D.

  The drive circuit 60 turns off all of the plurality of light emitting elements D when the output current signal voltage flowing into the light emitting circuit 40 obtained based on the detection result of the current detection unit 70 is less than the disconnection detection threshold. That is, when the current flowing through the light emitting circuit 40 is insufficient, the specified light distribution is not satisfied. Therefore, the drive circuit 60 turns off all the light emitting elements D in order to satisfy the function of turning off all lights when one lamp is disconnected.

  Specifically, the abnormality detection threshold setting unit 63 obtains the output current signal voltage flowing into the light emitting circuit 40 based on the potential difference between both ends of the resistance element R10 acquired from the signal input unit 61. The abnormality detection threshold setting unit 63 compares the output current signal voltage flowing into the light emitting circuit 40 with the voltage of the disconnection detection threshold. The abnormality detection threshold setting unit 63 outputs to the signal output unit 66 whether or not the output current signal voltage flowing into the light emitting circuit 40 is lower than the disconnection detection threshold voltage. If the output current signal voltage flowing into the light emitting circuit 40 is lower than the disconnection detection threshold voltage, the signal output unit 66 controls all of the switching elements TR1 to TR4 to the off state. Thus, all of the light emitting elements D1 to D4 are turned off.

  The drive circuit 60 increases the voltage of the overcurrent detection threshold as the number of lighting of the light emitting element D increases. Specifically, the abnormality detection threshold setting unit 63 acquires a lighting signal from the signal input unit 61, and changes the setting of the voltage of the overcurrent detection threshold according to the number of lighting of the light emitting element D. That is, since the input current Iin1 increases as the number of light-emitting elements D increases, the drive circuit 60 sets the voltage of the overcurrent detection threshold corresponding to the increase in the number of light-emitting elements D.

  The drive circuit 60 turns off all of the plurality of light emitting elements D when the output current signal voltage flowing into the light emitting circuit 40 obtained based on the detection result of the current detection unit 70 is equal to or higher than the overcurrent detection threshold voltage. I do. That is, when an overcurrent flows through the light emitting circuit 40, the power may exceed the rated power of the indicator light device 1. Therefore, the drive circuit 60 turns off all the light emitting elements D in order to satisfy the function of turning off all lights when one lamp is disconnected.

  Specifically, the abnormality detection threshold setting unit 63 obtains the output current signal voltage flowing into the light emitting circuit 40 based on the potential difference between both ends of the resistance element R10 acquired from the signal input unit 61. The abnormality detection threshold setting unit 63 compares the output current signal voltage flowing into the light emitting circuit 40 with the voltage of the overcurrent detection threshold. The abnormality detection threshold setting unit 63 outputs to the signal output unit 66 whether or not the output current signal voltage flowing into the light emitting circuit 40 is equal to or higher than the overcurrent detection threshold. If the output current signal voltage flowing into the light emitting circuit 40 is equal to or higher than the overcurrent detection threshold voltage, the signal output unit 66 controls all of the switching elements TR1 to TR4 to the off state. Thus, all of the light emitting elements D1 to D4 are turned off.

  The drive circuit 60 adjusts the sum of the input current Iin1 and the pseudo load current Iin2 to be equal to or more than the disconnection detection threshold current and less than the overcurrent detection threshold current. That is, when causing the light emitting circuit 40 to perform an operation in which the output load fluctuates as in a sequential turn, the drive circuit 60 secures a current equal to or higher than the disconnection detection threshold current and suppresses the current to a current lower than the overcurrent detection threshold current. Therefore, the pseudo load circuit 50 is operated based on the power supply voltage of the constant voltage power supply circuit 30 and the lighting state of the light emitting circuit 40.

  Next, a specific description will be given of the correlation between the current detection voltage, which is the output current flowing into the light emitting circuit 40, which is obtained based on the potential difference between both ends of the resistance element R10, and the number of lighting of the light emitting element D. FIG. 3 is a diagram illustrating a setting example of the abnormality detection reference voltage. The abnormality detection reference voltage includes an overcurrent detection threshold voltage and a disconnection detection threshold voltage. As shown in FIG. 3, as the number of lighting of the light emitting element D increases, each of the voltage of the overcurrent detection threshold and the voltage of the disconnection detection threshold is set to an increased value. That is, the abnormality detection reference voltage is set stepwise according to the lighting signal.

  Next, the correlation between the pseudo load reference voltage and the number of lighting of the light emitting element D will be specifically described. FIG. 4 is a diagram illustrating a setting example of the pseudo load reference voltage. As shown in FIG. 4, as the number of lighting of the light emitting element D increases, the pseudo load reference voltage is set to a reduced value. Also, when the power supply voltage of the constant voltage power supply circuit 30 rises, the input current Iin1 decreases. To compensate for the decrease in the input current Iin1, the pseudo load reference voltage is set to an increased value compared to the normal operation voltage. As a result, the pseudo load current Iin2 increases. That is, the pseudo load reference voltage is set stepwise according to the lighting signal.

  As described above, the indicator lamp device 1 compensates for the decrease in the input current Iin1 by the pseudo load circuit 50 based on the lighting state of the light emitting circuit 40.

  Specifically, the indicator lamp device 1 does not uniformly set the pseudo load current Iin2 flowing through the pseudo load circuit 50 to a constant value in order to increase the pseudo load current Iin2 in consideration of the lighting state of the light emitting circuit 40. Thereby, the display lamp device 1 does not consume extra power, so that low power consumption can be achieved.

  In other words, the indicator lamp device 1 compensates for the decrease in the input current Iin1 with the pseudo load current Iin2 flowing through the pseudo load circuit 50 based on the lighting state of the light emitting circuit 40, thereby providing the input current Iin1 and the pseudo load current Since an appropriate input current Iin equal to or more than a certain sum is secured with the sum of Iin2, even if the output load fluctuates, malfunction can be prevented without excessively consuming power consumption.

  In addition, the indicator light device 1 increases the pseudo load current Iin2 as the number of lighting of the light emitting element D decreases, and decreases the pseudo load current Iin2 as the number of lighting of the light emitting element D increases. An appropriate input current Iin can be secured. As a result, the indicator light device 1 can prevent malfunction due to a change in output load while reducing power consumption.

  In addition, the indicator light device 1 increases the pseudo load current Iin2 as the input current Iin1 decreases, and decreases the pseudo load current Iin2 as the input current Iin1 increases. Thereby, the indicator light device 1 can control the pseudo load current Iin2 based on the fluctuation of the input current Iin1.

  In addition, the display lamp device 1 increases the voltage of the disconnection detection threshold as the number of lighting of the light emitting element D increases. Therefore, even if the output current flowing through the output load fluctuates, the output load, that is, the output The disconnection of the light emitting circuit 40 functioning as a circuit can be determined.

  In addition, when the output current signal voltage flowing from the constant voltage power supply circuit 30 to the light emitting circuit 40 is lower than the disconnection detection threshold voltage, the indicator light device 1 turns off all the light emitting elements D to be required by law. The function of turning off all lights when one lamp is disconnected can be realized.

  In addition, since the indicator light device 1 increases the voltage of the overcurrent detection threshold as the number of lighting of the light emitting element D increases, even when the output current flowing through the output load fluctuates, the output load, that is, An overcurrent of the light emitting circuit 40 functioning as an output circuit can be determined.

  In addition, when the output current signal voltage flowing from the constant voltage power supply circuit 30 to the light emitting circuit 40 is equal to or higher than the overcurrent detection threshold voltage, the indicator light device 1 turns off all the light emitting elements D, thereby turning off the light emitting circuit 40. Can be properly protected.

  In addition, the indicator light device 1 adjusts the sum of the input current Iin1 of the constant voltage power supply circuit 30 and the pseudo load current Iin2 to be equal to or more than the disconnection detection threshold current and less than the overcurrent detection threshold current, so that the output load is adjusted. , The input current Iin equal to or higher than a certain value is secured, so that erroneous detection of disconnection can be prevented.

  In the indicator lamp device 1, the current detection unit 70 is provided on a circuit that supplies an output current from the constant voltage power supply circuit 30 to the light emitting circuit 40, and the current detection unit 70 includes a resistance element R10. The output current signal voltage flowing into the light emitting circuit 40 is obtained from the potential difference between both ends of R10. Thereby, the indicator light device 1 can obtain the output current flowing into the light emitting circuit 40 with a simple configuration.

  As described above, according to the indicator lamp device 1 according to the present embodiment, the constant voltage power supply circuit 30 and the light emission that emits light by the power supplied from the constant voltage power supply circuit 30 are in series with the constant voltage power supply circuit 30. A circuit 40, a pseudo-load circuit 50 that is in a parallel relationship with the constant-voltage power supply circuit 30 and the light-emitting circuit 40, and supplements a decrease in the input current Iin1 of the constant-voltage power supply circuit 30 with the pseudo-load current Iin2; And a driving circuit 60 for controlling the driving of each of the circuits 50. The pseudo load circuit 50 changes the pseudo load current Iin2 in accordance with the pseudo load reference voltage. The pseudo load current Iin2 is increased while adjusting the pseudo load reference voltage based on the lighting state.

  Thereby, even if the output load fluctuates, the indicator light device 1 can prevent a malfunction without excessively consuming the power consumption.

  Further, according to the indicator light device 1 according to the present embodiment, the light emitting circuit 40 includes the plurality of light emitting elements D connected in parallel, and the driving circuit 60 sets the lighting state of the light emitting element D to the lighting state of the light emitting element D. The pseudo load current Iin2 is increased as the number of lights decreases, and the pseudo load current Iin2 is decreased as the number of lights of the light emitting element D increases.

  As a result, the indicator light device 1 can prevent malfunction due to a change in output load while reducing power consumption.

  Further, according to the indicator light device 1 according to the present embodiment, the drive circuit 60 increases the pseudo load current Iin2 as the input current Iin1 decreases, and decreases the pseudo load current Iin2 as the input current Iin1 increases. It is to let.

  Thereby, the indicator light device 1 can control the pseudo load current Iin2 based on the fluctuation of the input current Iin1.

  Further, according to the indicator light device 1 according to the present embodiment, the drive circuit 60 increases the voltage of the disconnection detection threshold as the number of light-emitting elements D increases.

  As a result, the display lamp device 1 can determine the output load, that is, the disconnection of the light emitting circuit 40 functioning as the output circuit, even when the output current flowing through the output load fluctuates.

  Further, according to the indicator lamp device 1 according to the present embodiment, the current detection unit 70 that detects the output current flowing from the constant voltage power supply circuit 30 to the light emitting circuit 40 is further provided. When the output current signal voltage flowing into the light emitting circuit 40 obtained based on the detection result is lower than the disconnection detection threshold voltage, all the light emitting elements D are turned off.

  As a result, the indicator light device 1 can realize the all-lights-out function at the time of disconnection of one lamp required by law.

  Further, according to the indicator light device 1 according to the present embodiment, the drive circuit 60 increases the voltage of the overcurrent detection threshold as the number of light-emitting elements D increases.

  Accordingly, the indicator light device 1 can determine the output load, that is, the overcurrent of the light emitting circuit 40 functioning as an output circuit, even when the output current flowing to the output load fluctuates.

  Further, according to the indicator light device 1 according to the present embodiment, the current detection unit 70 that detects the output current flowing from the constant voltage power supply circuit 30 to the light emitting circuit 40 is further provided. When the output current signal voltage flowing into the light emitting circuit 40 obtained based on the detection result is equal to or higher than the overcurrent detection threshold voltage, all the light emitting elements D are turned off.

  Thereby, the indicator light device 1 can appropriately protect the light emitting circuit 40.

  Further, according to the indicator light device 1 according to the present embodiment, the drive circuit 60 adjusts the sum of the input current Iin1 and the pseudo load current Iin2 to be equal to or more than the disconnection detection threshold current and less than the overcurrent detection threshold current. Is what you do.

  Thereby, the indicator light device 1 can prevent erroneous detection of disconnection.

  Further, according to the indicator lamp device 1 according to the present embodiment, the current detection unit 70 includes the resistance element R10 provided on a circuit that supplies an output current from the constant voltage power supply circuit 30 to the light emitting circuit 40, and includes a driving circuit Reference numeral 60 denotes an output current signal voltage obtained from the potential difference between both ends of the resistance element R10.

  Thereby, the indicator light device 1 can obtain the output current flowing into the light emitting circuit 40 with a simple configuration.

  As described above, the indicator lamp device 1 according to the present invention has been described based on the embodiment. However, the present invention is not limited to this, and may be modified without departing from the spirit of the present invention.

  For example, although an example of the light emitting circuit 40 in which four light emitting elements D are provided in parallel has been described, the light emitting circuit 40 in which five or more light emitting elements D are provided in parallel may be used. Further, a light emitting element D in which a plurality of light emitting elements D in which a plurality of light emitting elements D are connected in series may be provided. In short, it is only necessary that the total light emission amount of the light emitting element D is variably controlled like a sequential turn.

  Also, an example has been described in which various functions are realized by the drive circuit 60 executing a predetermined control program. However, the present invention is not limited to this, and the drive circuit 60 may realize various functions by a wired logic circuit. Good.

REFERENCE SIGNS LIST 1 indicator light device 30 constant voltage power supply circuit 40 light emitting circuit 50 pseudo load circuit 60 drive circuit 61 signal input unit 62, 65 comparator 63 abnormality detection threshold setting unit 64 pseudo load reference voltage setting unit 66 signal output unit 70 current detection unit

Claims (7)

A constant voltage power supply circuit,
A light emitting circuit which is in series with the constant voltage power supply circuit, and emits light by power supplied from the constant voltage power supply circuit;
A pseudo-load circuit that is in parallel with the constant-voltage power supply circuit and the light-emitting circuit, and compensates for a decrease in the input current of the constant-voltage power supply circuit with a pseudo load current;
A drive circuit for controlling the drive of each of the light emitting circuit and the pseudo load circuit,
The pseudo load circuit,
The pseudo load current fluctuates according to a pseudo load reference voltage,
The light emitting circuit,
Multiple light-emitting elements connected in parallel
With
The driving circuit includes:
As the lighting number of the light emitting element decreases, the pseudo load current increases,
As the number of lighting of the light emitting element increases, the pseudo load current is reduced,
The indicator lamp device according to claim 1, wherein the voltage of the disconnection detection threshold is increased as the number of lighting of the light emitting element increases . The driving circuit includes:
Increasing the pseudo load current as the input current decreases;
The indicator light device according to claim 1 , wherein the pseudo load current is decreased as the input current increases. A current detection unit that detects an output current flowing into the light emitting circuit from the constant voltage power supply circuit,
The driving circuit includes:
Billing output current signal voltage flowing to the light emitting circuit obtained based on a detection result of the current detecting unit, if the less than the voltage of the disconnection detection threshold value, characterized in that it turns off all of the light emitting element Item 3. The indicator light device according to item 1 or 2 . The driving circuit includes:
The display lamp device according to claim 2 , wherein the voltage of the overcurrent detection threshold is increased as the number of lighting of the light emitting element increases. A current detection unit that detects an output current flowing into the light emitting circuit from the constant voltage power supply circuit,
The driving circuit includes:
When an output current signal voltage flowing into the light emitting circuit obtained based on a detection result of the current detection unit is equal to or higher than the overcurrent detection threshold voltage, all of the light emitting elements are turned off. The indicator light device according to claim 4 . The driving circuit includes:
6. The display lamp device according to claim 5 , wherein a total sum of the input current and the pseudo load current is adjusted to be equal to or more than the current of the disconnection detection threshold and less than the current of the overcurrent detection threshold. The current detector,
It comprises a resistance element provided on a circuit for supplying the output current from the constant voltage power supply circuit to the light emitting circuit,
The driving circuit includes:
The display lamp device according to claim 6 , wherein the output current signal voltage is obtained from a potential difference between both ends of the resistance element.

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