JP2009170167A - Lighting device, display device and guide lamp - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce cost, by miniaturizing a lighting device, by reducing the number of part items, in the lighting device used by switching a plurality of DC power circuits. <P>SOLUTION: The DC power circuits 111 and 112 generate DC voltage. A power source selecting circuit 160 selects one from the DC power circuits 111 and 112, and operates the selected DC power circuit. A light source circuit 140 turns on a light source by inputting DC voltage generated by the DC power circuit selected by the power source selecting circuit 140, A current detecting circuit 150 measures an electric current flowing in the light source circuit 140, and generates first detection voltage and second detection voltage. The DC power circuit 111 generates the DC voltage having a voltage value determined based on a voltage value of the input second detection voltage by inputting the second detection voltage generated by the current detecting circuit 150. The DC power circuit 112 generates the DC voltage having a voltage value determined based on a voltage value of the input first detection voltage by inputting the first detection voltage generated by the current detecting circuit 150. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a lighting device for lighting a light source that emits light by a DC voltage.

A lighting device that lights a light source such as a light emitting diode (LED) is generated by feeding back the current measurement circuit that measures the current flowing through the light source and the measurement result of the current measurement circuit in order to keep the current flowing through the light source constant. Some of them have a DC power supply circuit for adjusting the DC voltage.
Some DC power supply circuits generate a DC voltage from an AC voltage supplied from a commercial power supply and others, and generate a DC voltage having a different voltage value from a DC voltage supplied from a rechargeable battery or the like.
JP 2006-286339 A JP 2003-152224 A JP 2004-39684 A

When lighting a light source that needs to be turned on even during a power failure, such as a guide light, a plurality of DC power supply circuits are switched and used depending on the situation. For example, during normal operation, a DC power supply circuit that generates a DC voltage from an AC voltage from a commercial power supply is operated, and during a power outage, a DC power supply circuit that generates a DC voltage from a DC voltage with a different voltage value from a rechargeable battery, etc. To work.
Since the plurality of DC power supply circuits may have different characteristics, a plurality of current measurement circuits corresponding to the plurality of DC power supply circuits are required.
The present invention has been made, for example, in order to solve the above-described problems. Even when a plurality of DC power supply circuits are switched and used, there is no need to provide a plurality of current measurement circuits. The purpose is to reduce the number of points and reduce the size and cost of the lighting device.

The lighting device according to this invention is
A plurality of DC power supply circuits for generating a DC voltage;
Selecting at least one DC power supply circuit from the plurality of DC power supply circuits, and operating the selected DC power supply circuit; and
A light source circuit having a light source that receives the direct current voltage generated by the direct current power supply circuit selected by the power source selection circuit and emits light by the input direct current voltage;
The current flowing through the light source circuit is measured, a first detection voltage having a first voltage value determined based on the measured current value is generated, and determined based on the measured current value. A current measurement circuit for generating a second detection voltage having a second voltage value different from the voltage value;
The first DC power supply circuit among the plurality of DC power supply circuits receives the first detection voltage generated by the current measurement circuit and has a voltage value determined based on the voltage value of the input first detection voltage. Generate DC voltage,
Of the plurality of DC power supply circuits, a second DC power supply circuit receives the second detection voltage generated by the current measurement circuit and has a voltage value determined based on the voltage value of the input second detection voltage. A DC voltage is generated.

  According to the lighting device of the present invention, the current measurement circuit generates a plurality of detection voltages each having a voltage value determined based on the current value of the current flowing through the light source circuit, and each of the plurality of DC power supply circuits includes the current measurement circuit. Since any one of the plurality of detection voltages generated by 150 is input and a DC voltage having a voltage value determined by the voltage value of the input detection voltage is generated, any DC power supply circuit is operating. Even if it is a case, there exists an effect that the electric current value of the electric current which flows through a light source circuit can be made substantially constant.

Embodiment 1 FIG.
The first embodiment will be described with reference to FIGS.

FIG. 1 is a view showing the appearance of a guide light 800 in this embodiment.
The guide light 800 is used by being attached to an indoor ceiling 810 or a wall.
The guide light 800 has a display board 200 on which an evacuation guide pattern is drawn. The guide lamp 800 shown in this figure is a double-sided lamp having the display board 200 on the front side and the back side, but may be a single-sided lamp with the display board 200 only on the front side.
The guide light 800 includes a lighting device 100 (not shown).
The lighting device 100 turns on a light source (not shown) such as a disaster prevention lamp or a light emitting diode (LED), illuminates the display board 200, and displays an evacuation guidance pattern drawn on the display board 200.
It should be noted that the symbol drawn on the display board 200 is not necessarily a symbol representing evacuation guidance. That is, the guide light 800 may be used as a display device that displays general symbols.

FIG. 2 is a block configuration diagram showing a circuit block configuration of the lighting device 100 according to this embodiment.
The lighting device 100 includes a plurality of DC power supply circuits 111 to 112, a light source circuit 140, a current measurement circuit 150, and a power supply selection circuit 160.

The DC power supply circuits 111 to 112 generate a DC voltage. Although only two DC power supply circuits 111 to 112 are shown in this figure, there may be three or more DC power supply circuits.
The power supply selection circuit 160 selects at least one DC power supply circuit from the DC power supply circuits 111 to 112, and operates the selected DC power supply circuit.
The light source circuit 140 includes a light source such as a lamp or an LED. The light source circuit 140 receives the DC voltage generated by the DC power supply circuit selected by the power supply selection circuit 160 and causes the light source to emit light by the input DC voltage.

  The current measurement circuit 150 measures the current flowing through the light source circuit 140 and generates a detection voltage having a voltage value determined based on the measured current value. For example, the current measurement circuit 150 generates a detection voltage having a voltage value proportional to the current value of the measured current. The current measurement circuit 150 generates a plurality of detection voltages. The current measurement circuit 150 generates detection voltages that are 2 or more and the number of DC power supply circuits or less. For example, when there are three DC power supply circuits, the current measurement circuit 150 generates two or three detection voltages. The plurality of detection voltages generated by the current measurement circuit 150 have different voltage values. For example, the current measurement circuit 150 generates a plurality of detection voltages having different ratios between the measured current value of the current and the voltage value of the detection voltage.

The DC power supply circuit 111 inputs one detection voltage among a plurality of detection voltages generated by the current measurement circuit 150.
The DC power supply circuit 112 inputs another detection voltage among the plurality of detection voltages generated by the current measurement circuit 150.
The DC power supply circuits 111 to 112 generate a DC voltage having a voltage value determined based on the voltage value of the input detection voltage (feedback signal). The DC power supply circuits 111 to 112 generate a DC voltage having a voltage value that has an inverse correlation with the voltage value of the input detection voltage. That is, if the voltage value of the input detection voltage increases, the voltage value of the generated DC voltage decreases. For example, the DC power supply circuits 111 to 112 generate a DC voltage having a voltage value obtained by subtracting, from a predetermined reference output voltage value, a voltage value proportional to the difference between the input detection voltage value and a predetermined reference voltage value. .
Between the voltage value of the detection voltage input by the DC power supply circuit 111 and the voltage value of the generated DC voltage, and the voltage value of the detection voltage input by the DC power supply circuit 112 and the voltage value of the generated DC voltage The relationship may be the same or different.

  FIG. 3 is a circuit diagram showing a circuit configuration of the lighting device 100 according to this embodiment.

  The lighting device 100 receives an AC voltage from an AC power source such as a commercial power source AC (for example, 100 V to 254 V, 50 Hz to 60 Hz).

The DC power supply circuit 111 (AC input power supply circuit) generates a DC voltage from the AC voltage input by the lighting device 100.
The DC power supply circuit 111 has, for example, two voltage input terminals, a ground terminal, a feedback input terminal, and a voltage output terminal. The ground terminal is electrically connected to the common ground wiring. The DC power supply circuit 111 inputs the AC voltage input by the lighting device 100 as a potential difference between the two voltage input terminals. The DC power supply circuit 111 inputs the detection voltage generated by the current measurement circuit 150 as a potential difference between the feedback input terminal and the ground terminal. The DC power supply circuit 111 outputs the generated DC voltage as a potential difference between the voltage output terminal and the ground terminal.

The DC power supply circuit 111 includes, for example, a diode bridge DB, a capacitor C21, and a DC-DC conversion circuit DC11.
The diode bridge DB performs full-wave rectification on the input AC voltage to generate a pulsating voltage.
The capacitor C21 is charged by the pulsating voltage generated by the diode bridge DB, smoothes the pulsating voltage, and reduces the AC component.
The DC-DC conversion circuit DC11 receives the pulsating voltage charged in the capacitor C21, and generates a DC voltage from the input pulsating voltage. The DC-DC conversion circuit DC11 receives the detection voltage generated by the current measurement circuit 150, and determines the voltage value of the DC voltage to be generated based on the voltage value of the input detection voltage. The DC-DC conversion circuit DC11 may be configured by, for example, a step-down chopper circuit, a circuit including a three-terminal regulator, or a general-purpose IC.

  Control power supply circuit 170 generates a DC voltage (hereinafter referred to as “DC control voltage”) from the AC voltage input by lighting device 100. The voltage value of the DC control voltage generated by the control power supply circuit 170 is substantially constant (for example, 5V). In this figure, the control power supply circuit 170 directly inputs the AC voltage input by the lighting device 100. However, the control power supply circuit 170 may input the pulsating voltage that is full-wave rectified by the diode bridge DB. .

  The rechargeable battery B22 is charged with a DC control voltage generated by the control power circuit 170. The rechargeable battery B22 is an emergency power source at the time of a power failure.

The DC power supply circuit 112 (DC input power supply circuit) generates a DC voltage from the voltage charged in the rechargeable battery B22 (hereinafter referred to as “charging voltage”).
The DC power supply circuit 112 has, for example, a ground terminal, a voltage input terminal, a feedback input terminal, and a voltage output terminal. The ground terminal is electrically connected to the common ground wiring. The ground terminal is electrically connected to the ground terminal of the DC power supply circuit 111 through a common ground wiring. The DC power supply circuit 112 inputs the charging voltage charged in the rechargeable battery B22 as a potential difference between the voltage input terminal and the ground terminal. The DC power supply circuit 112 inputs the detection voltage generated by the current measurement circuit 150 as a potential difference between the feedback input terminal and the ground terminal. The DC power supply circuit 112 outputs the generated DC voltage as a potential difference between the voltage output terminal and the ground terminal.

The DC power supply circuit 112 includes, for example, a DC-DC conversion circuit DC12.
The DC-DC conversion circuit DC12 inputs a charging voltage charged in the rechargeable battery B22, and generates a DC voltage from the input charging voltage. The DC-DC conversion circuit DC12 receives the detection voltage generated by the current measurement circuit 150, and determines the voltage of the DC voltage to be generated based on the voltage value of the input detection voltage. The DC-DC conversion circuit DC12 receives a control signal for controlling whether or not to generate a DC voltage. The DC-DC conversion circuit DC12 generates a DC voltage when the input control signal is a signal representing generation of a DC voltage. The DC-DC conversion circuit DC12 does not generate a DC voltage when the input control signal is a signal indicating the generation stop of the DC voltage. The control signal input by the DC-DC converter circuit DC12 represents, for example, the generation of a DC voltage if the potential is higher than a predetermined potential, and the generation stop of the DC voltage if the potential is lower than the predetermined potential. The DC-DC conversion circuit DC12 may be configured by, for example, a boost chopper circuit or the like, or may be configured by a general-purpose IC.

The light source circuit 140 is a circuit having a light source. The light source includes one or a plurality of light emitting diodes L41 to L42 that are electrically connected in series. The light source circuit 140 may be a circuit in which a plurality of light sources are electrically connected in parallel. Further, the light source circuit 140 is a switching circuit for controlling turning on / off of the light emitting diode, a detection circuit for detecting a failure of the light emitting diode, and a current for flowing through a plurality of light sources connected in parallel. A current mirror circuit or the like may be included.
The light source circuit 140 has a high potential side terminal (first terminal) and a low potential side terminal (second terminal). The high potential side terminal is electrically connected to the voltage output terminal of the DC power supply circuit 111 via the diode D31, and is also electrically connected to the voltage output terminal of the DC power supply circuit 112 via the diode D32. Thus, the light source circuit 140 inputs the DC voltage generated by the DC power supply circuit 111 or the DC power supply circuit 112 when either the DC power supply circuit 111 or the DC power supply circuit 112 is operating.
The DC voltage input by the light source circuit 140 is applied to the light source, and the light emitting diodes L41 and L42 emit light.

  The current measurement circuit 150 measures the current flowing through the light source circuit 140 and generates a plurality of detection voltages. The current measurement circuit 150 includes, for example, a ground terminal, a current input terminal, a first detection voltage output terminal, and a second detection voltage output terminal. The ground terminal is electrically connected to the common ground wiring. The ground terminal is electrically connected to the ground terminal of the DC power supply circuit 111 and the ground terminal of the DC power supply circuit 112 through a common ground wiring. The current input terminal is electrically connected to the low potential side terminal of the light source circuit 140. Thus, the current supplied from the DC power supply circuit 111 or the DC power supply circuit 112 to the light source circuit 140 enters the current measurement circuit 150 from the current input terminal, flows through the current measurement circuit 150, exits from the ground terminal, and is supplied to the DC power supply circuit. Return to 111 or the DC power supply circuit 112. The current measurement circuit 150 outputs the first detection voltage among the generated detection voltages as a potential difference between the first detection voltage output terminal and the ground terminal. The current measurement circuit 150 outputs the second detection voltage among the generated detection voltages as a potential difference between the second detection voltage output terminal and the ground terminal.

The current measurement circuit 150 includes, for example, a resistor R51 and a resistor R52.
The resistor R51 (first resistor circuit) is a fixed resistor having two terminals. One terminal (first terminal) of the resistor R51 is electrically connected to the current input terminal and the first detection voltage output terminal. The other terminal (second terminal) of the resistor R51 is electrically connected to the second detection voltage output terminal.
The resistor R52 (second resistor circuit) is a fixed resistor having two terminals. One terminal (first terminal) of the resistor R52 is electrically connected to the second detection voltage output terminal. The other terminal (second terminal) of the resistor R52 is electrically connected to the ground terminal.
That is, the current measurement circuit 150 is a circuit in which two resistors R51 to R52 are electrically connected in series. R ₁ a fixed resistance value of the resistor _R51, the resistor R ₂ a fixed resistance value of _R52, the current value of the current flowing through the light source circuit 140 and I _1, the voltage value of the first detection voltage current measurement circuit 150 generates voltage value V ₂ of V ₁ and the second detection voltage is expressed by the following equation.

  The DC power supply circuit 112 (first DC power supply circuit) inputs the first detection voltage generated by the current measurement circuit 150. The second detection voltage generated by the current measuring circuit 150 is input by the DC power supply circuit 111 (second DC power supply circuit). Conversely, the DC power supply circuit 111 (first DC power supply circuit) inputs the first detection voltage, and the DC power supply circuit 112 (second DC detection circuit) inputs the second detection voltage. May be.

  The power supply selection circuit 160 selects one of the DC power supply circuits 111 to 112 and operates the selected DC power supply circuit. Note that the power supply selection circuit 160 in this example does not actively switch between operation and stop by controlling the DC power supply circuit 111, but detects whether or not the DC power supply circuit 111 is operating, and the DC power supply circuit 111. The DC power supply circuit 112 is stopped when is operated, and the DC power supply circuit 112 is operated when the DC power supply circuit 111 is not operated.

The power supply selection circuit 160 includes a power failure detection circuit 161 and a power failure selection circuit 162.
The power failure detection circuit 161 detects whether or not the AC voltage is supplied from the AC power source such as the commercial power source AC based on the AC voltage input from the AC power source such as the commercial power source AC by the lighting device 100.
When an AC voltage is supplied from an AC power supply such as a commercial power supply AC (hereinafter referred to as “normal time”), the DC power supply circuit 111 operates and generates a DC voltage. When an AC voltage is not supplied from an AC power source such as the above (hereinafter referred to as “when a power failure occurs”), the DC power supply circuit 111 does not operate and a DC voltage is not generated. The power failure detection circuit 161 detects whether or not the DC power supply circuit 111 is operating by detecting whether or not an AC voltage is supplied from an AC power supply such as a commercial power supply AC.
The power failure detection circuit 161 outputs a power failure signal indicating the detection result.

The power failure selection circuit 162 inputs the power failure signal output by the power failure detection circuit 161. The power failure selection circuit 162 generates a control signal to be input to the DC-DC conversion circuit DC12 based on the detection result of the power failure detection circuit 161 represented by the input power failure signal.
When the power failure detection circuit 161 detects that an AC voltage is supplied from an AC power source such as a commercial power source AC (that is, in a normal state), the power failure selection circuit 162 performs DC-DC conversion of the DC power circuit 112. A control signal for stopping the circuit DC12 is generated. When the power failure detection circuit 161 detects that an AC voltage is not supplied from an AC power source such as the commercial power source AC (that is, during a power failure), the power failure selection circuit 162 operates the DC-DC converter circuit DC12. Generate a control signal.

The control signal generated by the power failure selection circuit 162 is input to the DC-DC conversion circuit DC12. The DC-DC converter circuit DC12 generates a DC voltage based on the input control signal, or stops generating the DC voltage.
In this way, the power supply selection circuit 160 selects any one of the DC power supply circuits 111 to 112 and operates the selected DC power supply circuit.

The lighting device 100 includes a microcomputer COM.
The microcomputer COM stores a program in a nonvolatile memory such as a built-in (or external) ROM, and executes the stored program.
The microcomputer COM operates using the DC control voltage generated by the control power circuit 170 as a power source. Further, when an AC voltage is not supplied from an AC power source such as a commercial power source AC due to a power failure or the like, the voltage charged in the rechargeable battery B22 is used as a power source.

  The microcomputer COM implements the power failure selection circuit 162 by executing a program. Note that the microcomputer COM may implement not only the power failure selection circuit 162 but also other circuits. Conversely, the power failure selection circuit 162 and other circuits are not realized by the microcomputer COM, but may be realized by an analog circuit, a digital circuit, an analog / digital mixed circuit, or the like composed of analog parts or digital parts. .

The voltage value of the DC voltage generated by the DC-DC converter circuit DC11 and the DC-DC converter circuit DC12 and input to the light source circuit 140 is, for example, about 10V to 20V.
The average voltage value of the pulsating voltage input by the DC-DC conversion circuit DC11 is, for example, about 100V to 254V. Therefore, the DC-DC conversion circuit DC11 steps down the input pulsating voltage to generate a DC voltage.
On the other hand, the voltage value of the charging voltage charged in the rechargeable battery B22 input by the DC-DC converter circuit DC12 is the same as the voltage value of the operating power supply voltage of the microcomputer COM, and is about 5V, for example. Therefore, the DC-DC conversion circuit DC12 boosts the input charging voltage to generate a DC voltage.

  Thus, the DC / DC conversion circuit DC11 and the DC / DC conversion circuit DC12 have different configurations. For this reason, in many cases, even when the DC-DC converter circuit DC11 and the DC-DC converter circuit DC12 input detection voltages having the same voltage value, different DC voltages are generated. In particular, when the DC-DC converter circuit DC11 and the DC-DC converter circuit DC12 are configured using a general-purpose IC, an optimum IC is selected in consideration of the standard, performance, price, reliability, etc. of the general-purpose IC, Since the DC-DC converter circuit DC11 and the DC-DC converter circuit DC12 are configured, the characteristics of the DC-DC converter circuit DC11 and the DC-DC converter circuit DC12 may be different.

FIG. 4 is a characteristic graph showing the relationship between the detection voltage input by the DC power supply circuit 111 and the DC power supply circuit 112 and the generated DC voltage in this embodiment.
The horizontal axis indicates the detection voltage input by the DC / DC conversion circuit DC11 and the DC / DC conversion circuit DC12. The vertical axis represents the DC voltage V _OUT1 (solid line) generated by the DC-DC conversion circuit DC11 and the DC voltage V _OUT2 (broken line) generated by the DC-DC conversion circuit DC12.

Lighting device 100, a current value I ₁ of the current flowing in the light source circuit 140 is constant (e.g., light-emitting diodes is determined by the rated current value of) the voltage of the DC voltage DC power supply circuit 111 and the DC power supply circuit 112 so that the generated Control the value.
Here, the DC voltage generated by the DC power supply circuit 111 or the DC power supply circuit 112 is about V ₀ (for example, it is determined by the voltage-current characteristics of the light emitting diodes, but an accurate value can be known in advance due to variations in the characteristics of the light emitting diodes, etc. The current value of the current I ₁ flowing through the light source circuit 140 becomes a desired value I ₀ .

In normal times, the DC power supply circuit 111 generates a DC voltage. At this time, the detection voltage input by the DC-DC converter circuit DC11 needs to be about _VIN1 .
At the time of a power failure, the DC power supply circuit 112 generates a DC voltage. At this time, the detection voltage input by the DC-DC converter circuit DC12 needs to be about _VIN2 .

Therefore, in this embodiment, of the two detection voltages generated by the current measurement circuit 150, the first detection voltage is input to the DC / DC conversion circuit DC12, and the second detection voltage is input to the DC / DC conversion circuit DC11. To enter.
Further, the resistance value _{R 2} of the resistance value _{R 1} and the resistor R52 of the resistor R51, sets a value calculated from the following equation.

In normal times, the DC power supply circuit 111 generates a DC voltage, and a current flows through the light source circuit 140. If the voltage value V _OUT1 of the DC voltage generated by the DC power supply circuit 111 is low and the current value I ₁ of the current flowing through the light source circuit 140 is smaller than the desired value I ₀ , the current measurement circuit 150 generates a second value. Since the detected voltage value V ₂ = R ₂ × I ₁ is smaller than the design value V _IN1 = R ₂ × I ₀ , the DC power supply circuit 111 increases the voltage value V _OUT1 of the generated DC voltage. Conversely, if the voltage value V _OUT1 of the DC voltage generated by the DC power supply circuit 111 is high and the current value I ₁ of the current flowing through the light source circuit 140 is greater than the desired value I ₀ , the current measurement circuit 150 generates Since the voltage value V ₂ = R ₂ × I ₁ of the second detection voltage is larger than the design value V _IN1 = R ₂ × I ₀ , the DC power supply circuit 111 decreases the voltage value V _OUT1 of the generated DC voltage. As a result, the current value I ₁ of the current flowing through the light source circuit 140 becomes substantially equal to the desired value I ₀ .

At the time of a power failure, the DC power supply circuit 112 generates a DC voltage, and a current flows through the light source circuit 140. Now, the DC power supply circuit 112 is lower the voltage value V _OUT2 of the DC voltage to be generated when the current value I ₁ of the current flowing in the light source circuit 140 is a desired value I ₀ is smaller than a first current measuring circuit 150 generates Since the detected voltage value V ₁ = (R ₁ + R ₂ ) × I ₁ is smaller than the design value V _IN2 = (R ₁ + R ₂ ) × I ₀ , the DC power supply circuit 112 generates the voltage of the DC voltage to be generated. _{Increase the} value V _OUT2 . Conversely, the DC power supply circuit 112 has a higher voltage value V _OUT2 of the DC voltage to be generated when the current value I ₁ of the current flowing in the light source circuit 140 is greater than the desired value I _0, the current measurement circuit 150 generates Since the voltage value V ₁ = (R ₁ + R ₂ ) × I _{1 of} one detection voltage is larger than the design value V _IN2 = (R ₁ + R ₂ ) × I ₀ , the DC power supply circuit 112 has a DC voltage to be generated The voltage value V _OUT2 is reduced. As a result, the current value I ₁ of the current flowing through the light source circuit 140 becomes substantially equal to the desired value I ₀ .

  As described above, the current measurement circuit 150 generates a plurality of detection voltages having voltage values determined by the current value of the current flowing through the light source circuit 140, and the plurality of DC power supply circuits 111 to 112 generate the current measurement circuit 150, respectively. Any one of the detected voltages is input, and a DC voltage having a voltage value determined by the voltage value of the input detection voltage is generated. Therefore, any DC power supply circuit is in operation. However, the current value of the current flowing through the light source circuit 140 can be made substantially constant.

In this _example, has been described towards the _{V IN2} from _{V IN1} is _high, if more of _{V IN1} is greater than _{V IN2} is the first detection voltage current measuring circuit 150 is generated by the DC power supply circuit 111 The DC power supply circuit 112 may be configured to input the second detection voltage that is input and generated by the current measurement circuit 150.

Since the current measurement circuit 150 always generates a plurality of detection voltages, it is not necessary to switch the level of the detection voltage when the DC power supply circuit that generates the DC voltage is switched. On the other hand, the current measurement circuit 150 generates only one detection voltage, and the current measurement circuit 150 inputs a signal representing the operating DC power supply circuit, and generates the detection voltage based on the input signal. When the current level is switched, a detection voltage that is not compatible with the operating DC power supply circuit is generated due to the operation delay of the current measurement circuit 150, and an overcurrent may flow through the light source circuit 140.
Since the current measurement circuit 150 of this embodiment always generates a plurality of detection voltages, an operation delay does not occur and an overcurrent can be prevented from flowing through the light source circuit 140.

  Furthermore, the current measurement circuit 150 generates two detection voltages with a very simple configuration of two fixed resistors. Thus, since the configuration of the current measuring circuit 150 is very simple and can be configured with inexpensive parts, the lighting device 100 can be downsized, and the manufacturing cost of the lighting device 100 can be kept low.

  The lighting device 100 is normally supplied with power from an AC power supply such as a commercial power supply AC, and the DC power supply circuit 111 generates a DC voltage to turn on the light source and charge the rechargeable battery B22. Using the voltage charged in the rechargeable battery B22 as a power source, the DC power supply circuit 112 generates a DC voltage and turns on the light source. Since the current measurement circuit 150 generates a plurality of detection voltages corresponding to the difference in characteristics between the DC power supply circuit 111 and the DC power supply circuit 112, even if the DC power supply circuit that generates the DC voltage is switched, the light source circuit 140 is changed. The flowing current can always be constant.

In addition, you may set to the electric current value from which the electric current sent through the light source circuit 140 at the time of normal and the electric current sent through the light source circuit 140 at the time of a power failure differ. For example, to preserve the battery B22 in the event of a power failure, the current value I ₀₂ of the current flowing through the light source circuit 140 in the event of a power failure, to normal may be smaller than the current value I ₀₁ of the current flowing through the light source circuit 140 when, conversely , the current value I ₀₂ at the time of the power failure may be larger than the current value I ₀₁ at the time of normal.
In that case, the resistance value R ₂ of the resistance value R ₁ and the resistor R52 of the resistor R51 is set to a value calculated by the following equation.

In this case, the characteristics of the DC-DC conversion circuit DC11 and the characteristics of the DC-DC conversion circuit DC12 may be the same or different.
As described above, the lighting device 100 can cope with a case where the current value of the current flowing through the light source circuit 140 is to be changed when the DC power supply circuit that generates the DC voltage is switched.

  In addition, since at least part of the circuit of the lighting device 100 is realized by the microcomputer COM, the number of parts can be reduced, and the lighting device 100 can be reduced in size and manufacturing cost. Since the voltage value of the DC control voltage generated by the control power supply circuit 170 is the same as the voltage value of the charging voltage charged in the rechargeable battery B22, the microcomputer COM is normally supplied with power from the control power supply circuit 170. In the event of a power failure, the power supply is supplied from the rechargeable battery B22.

The light source is not necessarily a light emitting diode, and may be another light source.
Since the brightness of a light emitting diode is determined by the flowing current and the voltage-current characteristics vary, it is necessary to control the current in order to keep the brightness constant. According to the lighting device 100, currents close to the design values at the normal time and during a power failure can be passed through the light source circuit 140.

The lighting device 100 described above includes a lamp or LED for disaster prevention, an emergency power source (rechargeable battery B22), and a normal power source (commercial power source AC), and the lamp or LED ( In a lighting circuit capable of lighting a light source), two DC-DC converters (DC-DC) having different power supply and different operation reference voltages from a current detection resistor (current measurement circuit 150) that determines a lamp current flowing through the light source circuit 140. Control signals (detection signals) for the conversion circuit DC11 and the DC-DC conversion circuit DC12) can be obtained.
The current measurement circuit 150 normally obtains a control signal (detection signal) of a DC-DC converter (DC-DC conversion circuit DC11) that rectifies a commercial power supply (commercial power supply AC) and converts it into a predetermined DC voltage value. The lamp current flowing through the light source circuit 140 is determined.
In addition, the current measuring circuit 150 obtains a control signal (detection signal) of a DC-DC converter (DC-DC conversion circuit DC12) that converts the emergency power supply (rechargeable battery B22) into a predetermined DC voltage value in the event of a power failure. The lamp current flowing through the light source circuit 140 is determined.
As a result, even when operating a plurality of DC-DC converters (DC-DC conversion circuits DC11, DC12) having different operation reference voltages for normal use (normal time) and emergency (during power failure) The current measurement circuit 150 can take out each control signal (detection signal).

Embodiment 2. FIG.
Embodiment 2 will be described with reference to FIG.

FIG. 5 is a circuit diagram showing a circuit configuration of lighting device 100 according to this embodiment.
In addition, the same code | symbol is attached | subjected about the part which is common in the lighting device 100 demonstrated in Embodiment 1, and description is abbreviate | omitted here.

  The lighting device 100 in this embodiment receives power from a direct current power source such as an emergency direct current power supply BA as well as an alternating current power source such as a commercial power source AC to light the light source.

The lighting device 100 includes a DC power supply circuit 113.
The DC power supply circuit 113 (DC input power supply circuit) generates a DC voltage from a DC voltage (hereinafter referred to as “emergency voltage”) input from the emergency DC power supply BA to the lighting device 100.
The DC power supply circuit 113 has, for example, a ground terminal, a voltage input terminal, a feedback input terminal, and a voltage output terminal. The ground terminal is electrically connected to the common ground wiring. The ground terminal is electrically connected to the ground terminals of the DC power supply circuit 111, the DC power supply circuit 112, and the current measurement circuit 150 through a common ground wiring. The DC power supply circuit 113 inputs an emergency voltage as a potential difference between the voltage input terminal and the ground terminal. The DC power supply circuit 113 inputs the detection voltage generated by the current measurement circuit 150 as a potential difference between the feedback input terminal and the ground terminal. The DC power supply circuit 113 outputs the generated DC voltage as a potential difference between the voltage output terminal and the ground terminal.

The DC power supply circuit 113 includes, for example, a DC-DC conversion circuit DC13.
The DC-DC conversion circuit DC13 receives an emergency voltage and generates a DC voltage from the input emergency voltage. The DC-DC conversion circuit DC13 receives the detection voltage generated by the current measurement circuit 150, and determines the voltage of the DC voltage to be generated based on the voltage value of the input detection voltage. The DC-DC converter circuit DC13 receives a control signal for controlling whether or not to generate a DC voltage. The DC-DC conversion circuit DC13 generates a DC voltage when the input control signal is a signal representing generation of a DC voltage. The DC-DC conversion circuit DC13 does not generate a DC voltage when the input control signal is a signal indicating the generation stop of the DC voltage.

  The high potential side terminal of the light source circuit 140 is further electrically connected to the voltage output terminal of the DC power supply circuit 113 via the diode D33.

The current measurement circuit 150 further has a third detection voltage output terminal. The current measurement circuit 150 generates a third detection voltage and outputs the generated third detection voltage as a potential difference between the third detection voltage output terminal and the ground terminal.
The current measurement circuit 150 includes, for example, three resistors R51 to R53.
The resistors R52 and R53 are fixed resistors that are electrically connected in series. In the series circuit (second resistor circuit) of the resistor R52 and the resistor R53, one terminal (first terminal) is electrically connected to the second detection voltage output terminal, and the other terminal (second terminal) is grounded. A connection point between the resistor R52 and the resistor R53 is electrically connected to the third detection voltage output terminal.

The DC power supply circuit 112 inputs the first detection voltage generated by the current measurement circuit 150. The DC power supply circuit 113 inputs the second detection voltage generated by the current measurement circuit 150. The DC power supply circuit 111 inputs the third detection voltage generated by the current measurement circuit 150.
This is an example, and any detected voltage may be input to any DC power supply circuit.

  The power supply selection circuit 160 selects one of the DC power supply circuits 111 to 113 and operates the selected DC power supply circuit. Note that, as in the first embodiment, the power supply selection circuit 160 in this example does not control the DC power supply circuit 111 to actively switch between operation and stop, but determines whether or not the DC power supply circuit 111 is operating. When the DC power supply circuit 111 is detected, the DC power supply circuit 112 and the DC power supply circuit 113 are stopped, and when the DC power supply circuit 111 is not operated, the DC power supply circuit 112 or the DC power supply circuit 113 is operated. .

Based on the detection result of the power failure detection circuit 161, the power failure selection circuit 162 supplies a control signal (hereinafter referred to as “second control signal”) to the DC / DC conversion circuit DC 12 and a DC / DC conversion circuit DC 13. An input control signal (hereinafter referred to as “third control signal”) is generated. In the normal time, the power failure selection circuit 162 generates a second control signal for stopping the operation of the DC-DC conversion circuit DC12 and a third control signal for stopping the operation of the DC-DC conversion circuit DC13. In the case of a power failure, the power failure selection circuit 162 determines whether to operate the DC power supply circuit 112 or the DC power supply circuit 113. When it is determined that the DC power supply circuit 112 is to be operated, the power failure selection circuit 162 has a second control signal for operating the DC-DC conversion circuit DC12, and a third control signal for stopping the operation of the DC-DC conversion circuit DC13. Is generated. Conversely, when it is determined that the DC power supply circuit 113 is to be operated, the power failure selection circuit 162 is configured to stop the operation of the DC-DC conversion circuit DC12 and the third control signal to operate the DC-DC conversion circuit DC13. And a control signal.
For example, the power failure selection circuit 162 operates the DC power supply circuit 113 until a predetermined time elapses after the power failure, and operates the DC power supply circuit 112 when the power failure continues thereafter. Alternatively, the power supply selection circuit 160 has an emergency voltage measurement circuit that measures the voltage value of the emergency voltage input from the emergency DC power supply BA, and the voltage value of the emergency voltage measured by the emergency voltage measurement circuit is predetermined. The DC power supply circuit 113 may be operated when the voltage value is equal to or higher than the voltage value, and the DC power supply circuit 112 may be operated when the voltage value of the emergency voltage is less than a predetermined voltage value.

  Thus, immediately after a power failure, the charging voltage charged in the rechargeable battery B22 is used only as a power source for the microcomputer COM, and an external emergency DC power supply BA is used as a power source for lighting the light source. Thereafter, when the voltage of the external emergency DC power supply BA decreases, the rechargeable battery B22 is also used as a power source for lighting the light source. Thereby, the light source can be lit for a longer time during a power failure.

The resistance value _{R 1,} the resistance value _{R 2} of the resistor R52, the resistance value _{R 3} of the resistor R53 of the resistor R51 is set to a value calculated by the following equation.

_{Here, V IN1, V IN2, V} IN3 , respectively DC - DC converter circuit DC11, DC - DC converter circuit DC12, DC - voltage value of the DC voltage DC converter circuit DC13 is generated by the detection voltage becomes _{V 0} It is a voltage value, and it is assumed that V _IN1 <V _IN3 <V _IN2 .
If the magnitude relationship between V _IN1 , V _IN2 and V _IN3 is different from the above, the detection voltage input by the DC-DC conversion circuits DC11 to DC13 is changed to correspond to the order of V _IN1 , V _IN2 and V _IN3. You just have to do it. For example, if V _IN1 is the largest among V _IN1 , V _IN2 , and V _IN3 , the DC-DC conversion circuit DC11 is connected to input the first detection voltage, and if V _IN3 is the largest. The DC-DC conversion circuit DC13 may be connected so as to input the first detection voltage.

The lighting device 100 of this embodiment switches on three DC power supply circuits to light a light source. The current measurement circuit 150 generates three detection voltages, and the three DC power supply circuits each input one of the three detection voltages, and adjusts the generated DC voltage based on the input detection voltage. .
In this way, even when the three DC power supply circuits are switched and the light source is turned on, the current measurement circuit 150 generates the three detection voltages. Therefore, no matter which DC power supply circuit is operating, The current value of the current flowing through the light source circuit 140 can be made substantially constant.

  The current measurement circuit 150 generates three detection voltages with a very simple configuration of three fixed resistors. In general, the current measurement circuit 150 can be configured if there are as many fixed resistors as the number of detection voltages to be generated. Thus, since the configuration of the current measuring circuit 150 is very simple and can be configured with inexpensive parts, the lighting device 100 can be downsized, and the manufacturing cost of the lighting device 100 can be kept low.

  The lighting device 100 described above has a power supply from a current detection resistor (current measurement circuit 150) that determines a lamp current in a lighting circuit capable of lighting the lamp or LED by supplying power from three or more power supply systems. It is possible to obtain control signals for a plurality of DC-DC converters (DC-DC converter circuits DC11 to DC13) having different operation reference voltages.

Embodiment 3 FIG.
The third embodiment will be described with reference to FIG.

FIG. 6 is a circuit diagram showing a circuit configuration of lighting device 100 according to this embodiment.
In addition, the same code | symbol is attached | subjected about the part which is common in the lighting device 100 demonstrated in Embodiment 1, and description is abbreviate | omitted here.

The light source circuit 140 includes a first light source having light emitting diodes L41 to L42 and a second light source having light emitting diodes L43 to L44.
The first light source is, for example, a circuit in which a switching circuit SW45, a light emitting diode L41, a light emitting diode L42, and a resistor R47 are electrically connected in series.
The second light source is, for example, a circuit in which a switching circuit SW46, a light emitting diode L43, a light emitting diode L44, and a resistor R48 are electrically connected in series.
The light source circuit 140 is a circuit in which a first light source and a second light source are electrically connected in parallel.

  The switching circuits SW45 and SW46 have a first terminal electrically connected to the high potential side terminal of the light source circuit 140, a second terminal, and a control input terminal. The second terminal of the switching circuit SW45 is electrically connected to the anode terminal of the light emitting diode L41, and the second terminal of the switching circuit SW46 is electrically connected to the anode terminal of the light emitting diode L43. The switching circuits SW45 and SW46 receive a control signal from the control input terminal, and conduct or insulate between the first terminal and the second terminal based on the input control signal.

The current measurement circuit 150 further has a control input terminal. The current measurement circuit 150 receives a control signal from a control input terminal, and changes the relationship (voltage-current characteristics) between the measured current value and a plurality of detection voltages to be generated based on the input control signal.
The current measurement circuit 150 includes, for example, a resistor R51, a resistor R52, a resistor R54, and a transistor Q55.
The resistor R54 is a fixed resistor having two terminals. One terminal (first terminal) of the resistor R54 is electrically connected to the current input terminal and the first detection voltage output terminal of the current measurement circuit 150.
The transistor Q55 (switching circuit) is an NPN type bipolar transistor having three terminals. The collector terminal of the transistor Q55 is electrically connected to the other terminal (second terminal) of the resistor R54. The base terminal of the transistor Q55 is electrically connected to the control input terminal of the current measurement circuit 150. The emitter terminal of the transistor Q55 is electrically connected to the ground terminal of the current measurement circuit 150.
That is, a circuit (third resistance circuit) in which the resistor R54 and the transistor Q55 are electrically connected in series is electrically connected in parallel with a circuit in which the resistor R51 and the resistor R52 are electrically connected in series.
The transistor Q55 receives a control signal from the base terminal. When the base-emitter voltage of the transistor Q55 is larger than a predetermined voltage (for example, 0.6 V) by the input control signal, the collector-emitter of the transistor Q55 is conducted, and the base-emitter voltage of the transistor Q55 is When the voltage is smaller than the predetermined voltage, the collector and emitter of the transistor Q55 are insulated.

The collector of the transistor Q55 - in a state in which the emitter is insulated, the voltage value V ₂ of the first voltage value V ₁ and the second detection voltage of the detection voltage current measuring circuit 150 is generated in the embodiment " This is the same as that described using Equation 1 ”.
The collector of the transistor Q55 - in a state in which the emitter is conducting, the voltage value V ₂ of the first voltage value V ₁ and the second detection voltage of the detection voltage current measuring circuit 150 is generated, the resistance value of the resistor R54 the When R _4, represented by the following equation.

Here, assuming that R ₄ = R ₁ + R ₂ is set,

That is, the voltage values V ₁ and V ₂ of the first detection voltage and the second detection voltage generated by the current measurement circuit 150 in a state where the collector and emitter of the transistor Q55 are conductive are the collector-emitter of the transistor Q55. The voltage values V ₁ and V ₂ of the first detection voltage and the second detection voltage generated by the current measurement circuit 150 in a state where they are insulated are each half.

  The lighting device 100 further includes a failure detection circuit 181, a lighting number determination circuit 182, and a control signal generation circuit 183. In this example, the failure detection circuit 181, the lighting number determination circuit 182, and the control signal generation circuit 183 are realized by the microcomputer COM executing a program. However, the failure detection circuit 181, the lighting number determination circuit 182, and the control signal generation circuit 183 may be realized by an analog circuit / digital circuit / analog / digital mixed circuit constituted by analog parts or digital parts.

The failure detection circuit 181 detects a failure of the first light source or the second light source by detecting currents respectively flowing through the first light source and the second light source constituting the light source circuit 140.
The failure detection circuit 181 detects the current flowing through the first light source, for example, by measuring the potential at the connection point between the cathode terminal of the light emitting diode L42 and the resistor R47. Similarly, the failure detection circuit 181 detects the current flowing through the second light source by measuring the potential at the connection point between the cathode terminal of the light emitting diode L44 and the resistor R48. When the light emitting diode L41 or the light emitting diode L42 is opened due to a failure (open failure), the current flowing through the first light source becomes 0, so the failure detection circuit 181 detects that the first light source has failed. Similarly, when the light emitting diode L43 or the light emitting diode L44 is opened due to a failure, the current flowing through the second light source becomes 0, so the failure detection circuit 181 detects that the second light source has failed.

When the failure detection circuit 181 detects a failure of the first light source or the second light source, the lighting number determination circuit 182 determines that the light source where the failure is detected is turned off and only the remaining light sources are turned on. The lighting number determination circuit 182 generates control signals for controlling the switching circuit SW45 and the switching circuit SW46 according to the determination result. The control signal generated by the lighting number determination circuit 182 is input to the switching circuit SW45 and the switching circuit SW46, and is conducted or insulated based on the input control signal.
For example, the failure detection circuit 181 detects that the first light source (light emitting diode L41 or light emitting diode L42) has failed and that the second light source (light emitting diode L43 or light emitting diode L44) has not failed. In this case, the lighting number determination circuit 182 generates a control signal for insulating the switching circuit SW45 and a control signal for making the switching circuit SW46 conductive.

The control signal generation circuit 183 generates a control signal for conducting or insulating the transistor Q55 based on the determination result of the lighting number determination circuit 182. The transistor Q55 receives the control signal generated by the control signal generation circuit 183, and conducts or insulates between the collector and the emitter based on the input control signal.
When the lighting number determination circuit 182 determines that both the first light source and the second light source are turned on, the control signal generation circuit 183 generates a control signal that makes the transistor Q55 conductive. Further, when the lighting number determination circuit 182 determines that only one of the first light source and the second light source is turned on, the control signal generation circuit 183 generates a control signal that insulates the transistor Q55.

Thereby, when the lighting number determination circuit 182 lights both the first light source and the second light source, the voltage value V1 of the _first detection voltage and the voltage of the second detection voltage generated by the current measurement circuit 150 are displayed. the value V ₂ is a value calculated by the equation shown in "6". Further, when the lighting number determination circuit 182 turns on only one of the first light source and the second light source, the voltage value V ₁ of the first detection voltage generated by the current measurement circuit 150 and the second detection voltage are generated. voltage value V ₂ of a value calculated by the equation shown in the "number 1".

DC power supply circuit 111 and the DC power supply circuit 112, the voltage value _{V 2} of the first voltage value _{V 1} or the second detection voltage of the detection voltage current measuring circuit 150 is generated, the predetermined target value _{V IN1} or _{V IN2} Since the voltage value of the DC voltage to be generated is adjusted so as to approach the current value, the current value I ₁ of the current flowing through the light source circuit 140 when only one of the first light source and the second light source is turned on is comprising a light source and a second light source to half the current value I ₁ when both are turned. Accordingly, the current flowing through the light source to be lit is substantially the same whether only one of the first light source and the second light source is lit or when both the first light source and the second light source are lit. Become. This relationship is independent of whether the DC power supply circuit 111 is operating to generate a DC voltage or whether the DC power supply circuit 112 is operating to generate a DC voltage, and which DC power supply circuit is operating. Even if there is.

As described above, when a part of the light source fails, the lighting device 100 turns off the failed light source and continues lighting other light sources. For example, when the light emitting diode L41 or the light emitting diode L42 fails, the light emitting diode L41 and the light emitting diode L42 are turned off, and the light emitting diode L43 and the light emitting diode L44 continue to be lit.
The current measurement circuit 150 includes a resistor R54 (fixed resistor) and a transistor Q55 (switching circuit) electrically connected in series (third resistor circuit), a resistor R51 (first resistor circuit) and a resistor R52 ( The second resistor circuit) is electrically connected in parallel with the circuit electrically connected in series. When all the light sources are turned on, the collector-emitter of the transistor Q55 is made conductive. When only a part of the light sources is turned on, the collector-emitter of the transistor Q55 is insulated to keep the current flowing through the light source constant. can do.

  In the fully lit state and the partially lit state, the voltage values of the first detection voltage and the second detection voltage generated by the current measurement circuit 150 change, but the voltage value of the first detection voltage and the second detection voltage are changed. The ratio of the voltage to the voltage value does not change. Therefore, even if any DC power supply circuit generates a DC voltage, the current flowing through the light source to be lit is constant.

  In this example, the lighting number determination circuit 182 determines the number of light sources to be turned on when a failure is detected. However, lighting a part of the light sources is not limited to when the light source has failed. For example, it may be configured to switch between full lighting and partial lighting when a button for inputting a user instruction is pressed.

FIG. 3 shows an appearance of a guide light 800 in the first embodiment. FIG. 3 is a block configuration diagram illustrating a configuration of a circuit block of the lighting device 100 according to the first embodiment. FIG. 2 is a circuit diagram showing a circuit configuration of lighting device 100 according to Embodiment 1. FIG. 3 is a characteristic graph illustrating a relationship between a detection voltage input by the DC power supply circuit 111 and the DC power supply circuit 112 according to Embodiment 1 and a generated DC voltage. FIG. 6 is a circuit diagram showing a circuit configuration of lighting device 100 according to Embodiment 2. FIG. 6 is a circuit diagram showing a circuit configuration of lighting device 100 according to Embodiment 3.

Explanation of symbols

  100 lighting device, 111 to 113 DC power supply circuit, 140 light source circuit, 150 current measurement circuit, 160 power supply selection circuit, 161 power failure detection circuit, 162 power failure selection circuit, 170 control power supply circuit, 181 failure detection circuit, 182 lighting number judgment Circuit, 183 control signal generation circuit, 200 display board, 800 guide light, 810 ceiling, AC commercial power supply, B22 rechargeable battery, BA emergency DC power supply, C21 capacitor, COM microcomputer, D31-D33 diode, DB diode bridge, DC11 ~ DC13 DC-DC conversion circuit, L41 ~ L44 light emitting diode, Q55 transistor, R47 ~ R48, R51 ~ R54 resistance, SW45 ~ SW46 switching circuit.

Claims (12)

A plurality of DC power supply circuits for generating a DC voltage;
Selecting at least one DC power supply circuit from the plurality of DC power supply circuits, and operating the selected DC power supply circuit; and
A light source circuit having a light source that receives the direct current voltage generated by the direct current power supply circuit selected by the power source selection circuit and emits light by the input direct current voltage;
The current flowing through the light source circuit is measured, a first detection voltage having a first voltage value determined based on the measured current value is generated, and determined based on the measured current value. A current measurement circuit for generating a second detection voltage having a second voltage value different from the voltage value;
The first DC power supply circuit among the plurality of DC power supply circuits receives the first detection voltage generated by the current measurement circuit and has a voltage value determined based on the voltage value of the input first detection voltage. Generate DC voltage,
Of the plurality of DC power supply circuits, a second DC power supply circuit receives the second detection voltage generated by the current measurement circuit and has a voltage value determined based on the voltage value of the input second detection voltage. A lighting device that generates a DC voltage. The plurality of DC power supply circuits have a ground terminal electrically connected to each other, and a voltage output terminal that outputs the generated DC voltage as a potential difference with respect to the ground terminal,
The light source circuit has a first terminal electrically connected to voltage output terminals of the plurality of DC power supply circuits, and a second terminal,
The current measurement circuit is
A first resistance circuit having a first terminal electrically connected to a second terminal of the light source circuit, and a second terminal;
A second resistor circuit having a first terminal electrically connected to a second terminal of the first resistor circuit and a second terminal electrically connected to a ground terminal of the plurality of DC power supply circuits; ,
The voltage generated at the first terminal of the first resistance circuit is the first detection voltage,
2. The lighting device according to claim 1, wherein a voltage generated at a first terminal of the second resistance circuit is used as the second detection voltage. The lighting device has three or more DC power supply circuits,
The second resistance circuit is a circuit in which a plurality of fixed resistors are electrically connected in series,
The current measurement circuit uses a voltage generated at a connection point of the plurality of fixed resistors of the second resistance circuit as a third detection voltage,
A third DC power supply circuit among the plurality of DC power supply circuits receives the third detection voltage generated by the current measurement circuit and has a voltage value determined based on the voltage value of the input third detection voltage. The lighting device according to claim 2, wherein a DC voltage is generated. The current measurement circuit further includes:
A circuit in which a fixed resistor and a switching circuit are electrically connected in series, the first terminal electrically connected to the second terminal of the light source circuit, and the first terminal electrically connected to the ground terminal of the plurality of DC power supply circuits 4. The lighting device according to claim 2, further comprising a third resistor circuit having a second terminal and a control signal terminal for inputting a control signal for controlling the switching circuit. The light source circuit is a circuit having a plurality of light sources electrically connected in parallel,
The lighting device further includes:
A lighting number determination circuit that determines whether all of the plurality of light sources are turned on or only a part of the plurality of light sources is turned on;
Based on the determination result of the lighting number determination circuit, when all of the plurality of light sources are turned on, a control signal is generated for conducting the switching circuit of the current measurement circuit, and only some of the plurality of light sources are selected. The lighting device according to claim 4, further comprising a control signal generation circuit that generates a control signal that insulates the switching circuit of the current measurement circuit when the lighting is performed. The lighting device further includes a failure detection circuit that detects a failure of the light source when any one of the plurality of light sources fails.
6. The lighting according to claim 5, wherein the lighting number determination circuit determines that only some of the plurality of light sources are lit when the failure detection circuit detects a failure of the light source. apparatus. The lighting device receives an AC voltage from an AC power source,
At least one DC power supply circuit among the DC power supply circuits is an AC input power supply circuit that generates the DC voltage from an AC voltage input from the AC power supply,
The power supply selection circuit is
A power failure detection circuit for detecting whether or not an AC voltage is input from the AC power source;
A power failure selection circuit that selects at least one DC power supply circuit from among DC power supply circuits other than the AC input power supply circuit when the power failure detection circuit detects that an AC voltage is not input from the AC power supply; The lighting device according to any one of claims 1 to 6, further comprising: The lighting device further includes:
A control power supply circuit that generates a DC control voltage from an AC voltage input from the AC power supply;
A rechargeable battery charged by a DC control voltage generated by the control power circuit;
At least one DC power supply circuit among the DC power supply circuits is a DC input power supply circuit that generates the DC voltage from the voltage charged in the rechargeable battery,
The power failure selection circuit selects at least one DC power supply circuit from the DC input power supply circuit when the power failure detection circuit detects that no AC voltage is input from the AC power supply. The lighting device according to claim 7. The lighting device further includes:
The program is stored, and the DC control voltage generated by the control power circuit is operated as a power source. When no AC voltage is input from the AC power source, the voltage charged in the rechargeable battery is operated and stored as a power source. Having a microcomputer for executing the program;
The lighting device according to claim 8, wherein the power failure selection circuit is realized by the microcomputer executing the program.   The lighting device according to any one of claims 1 to 9, wherein the light source is one or a plurality of light emitting diodes electrically connected in series. A lighting device according to any one of claims 1 to 10,
And a display panel illuminated by light emitted from the light source. A lighting device according to any one of claims 1 to 10,
A guide light, comprising: a display plate that is illuminated by light emitted from the light source and displays a design for evacuation guidance.

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