JP5932497B2 - LED lighting device - Google Patents

Description

  The present invention relates to an LED lighting device using an LED as a light source.

  The present invention relates to variable color temperature of an LED lighting device, and more particularly to an LED lighting device that changes the color temperature without using an external signal such as PWM output. In Patent Document 1, there are only two types of LED elements, two wiring / control circuits, and the color temperature can be changed by moving only one parameter, which is close to black body radiation. A variable color light emitting diode module and a variable color light emitting diode lighting fixture that do not require adjustment are described.

JP 2005-1000079 A

  In the LED lighting device with variable color temperature, a power source capable of controlling the brightness independently for each light color of the LED is required. Therefore, one appliance requires power supplies corresponding to the number of light colors, and the LED lighting device cannot be reduced in size. In particular, indirect lighting requires a reduction in the size of the appliance, and is difficult to realize.

The LED lighting device of this invention is
A plurality of LED groups consisting of a plurality of electrically connected LEDs;
A selection circuit unit that selects at least one LED group from the plurality of LED groups and forms a series connection unit that is a series connection of the selected LED groups when the plurality of LED groups are selected;
When only one LED group is selected by the selection circuit unit, a first provisional current is provisionally supplied to the only one LED group as a current supply target, and the selection circuit unit is turned on. When the series connection portion is formed by the above, the second connection current having the same magnitude as the first provisional current is provisionally supplied to the series connection portion as a current supply target, and the first connection current is lit. A voltage generated in only one LED group by the provisional current or a voltage generated in the series connection part by the second provisional current is detected, and a current corresponding to the detected voltage is the current supply target. And a power supply device that flows through the only one group of LEDs or the series connection portion that is the current supply target.

  According to the present invention, output adjustment can be performed by combining LEDs of different light colors with a single power source. Therefore, since the color temperature can be switched while the luminous flux is maintained and the number of power supplies mounted can be reduced, an inexpensive and small color temperature variable LED lighting device can be provided.

1 is a configuration diagram of an LED illumination system 1 according to Embodiment 1. FIG. The figure which shows the output waveform of the LED power supply device 3 with a voltage determination function in FIG. The block diagram of the LED illumination system 1 which lights only the 1st LED unit 5 of Embodiment 1. FIG. The figure which shows the output waveform of the LED power supply device 3 with a voltage determination function in FIG. The block diagram of the LED lighting system 1 which lights only the 2nd LED unit 7 of Embodiment 1. FIG. The figure which shows the output waveform of the LED power supply device 3 with a voltage determination function in FIG. The block diagram which shows the structure of the LED lighting system 1 which can change color temperature by the external switching of Embodiment 2. FIG. The block diagram which shows the structure of the LED illumination system 1 which can change color temperature with the remote control signal of Embodiment 2. FIG. FIG. 10 is a diagram illustrating a configuration of an LED light source device 4-30 according to a third embodiment. The figure which shows the current pathway of LED light source device 4-30 of Embodiment 3. FIG. The figure which shows the current pathway of LED light source device 4-30 of Embodiment 3. FIG. FIG. 10 is a diagram illustrating a configuration of an LED light source device 4-31 according to a third embodiment. The figure which shows the current pathway of LED light source device 4-31 of Embodiment 3. FIG. The figure which shows the current pathway of LED light source device 4-31 of Embodiment 3. FIG. FIG. 4 is a diagram showing a configuration of an LED light source device 4-32 of a third embodiment. The figure which shows the current pathway of LED light source device 4-32 of Embodiment 3. FIG. The figure which shows the current pathway of LED light source device 4-32 of Embodiment 3. FIG. FIG. 10 shows a configuration of an LED light source device 4-33 of Embodiment 3. The figure which shows the electric current path of LED light source device 4-33 of Embodiment 3. FIG. The figure which shows the electric current path of LED light source device 4-33 of Embodiment 3. FIG. FIG. 10 is a diagram illustrating a configuration of an LED light source device 4-40 according to a fourth embodiment. The figure which shows the electric current path of LED light source device 4-40 of Embodiment 4. FIG. The figure which shows the electric current path of LED light source device 4-40 of Embodiment 4. FIG.

Embodiment 1 FIG.
FIG. 1 is a system configuration diagram showing a configuration of an LED illumination system. The LED illumination system 1 (LED illumination device) includes an LED power supply device 3 with a voltage determination function (power supply device) and an LED light source device 4 capable of varying the color temperature.

  The LED light source device 4 capable of changing the color temperature includes a first LED unit 5, a second LED unit 7, and a selector switch 9 (selection circuit unit) that switches connection between the first LED unit 5 and the second LED unit 7. With. The change-over switch 9 switches the contacts to bring the first LED unit 5 and the second LED unit 7 into a connected state, the first LED unit 5 is short-circuited, or the second LED unit 7 is short-circuited.

  The first LED unit 5 includes four LEDs 6a to 6d, and the color temperature (light color) of the LEDs 6a to 6d is, for example, 5000K.

  The second LED unit 7 includes four LEDs 8a to 8d, and the color temperature (light color) of the LEDs 8a to 8d is, for example, 3000K.

  The voltage from the commercial power supply 2 is input to the LED power supply device 3 with a voltage determination function, a DC power supply is generated by the LED power supply device 3 with the voltage determination function, and the second LED 5000a LED 6a to 6d of the first LED unit 5 and the second power supply. The LEDs 8a to 8d for 3000K of the LED unit 7 are turned on.

  At this time, the changeover switch contact 10c in the changeover switch 9 is not connected to the changeover switches 10a and 10b, and the 5000K LEDs 6a to 6d of the first LED unit 5 and the 3000K of the second LED unit 7 are used. The LEDs 8a to 8d are all connected in series.

FIG. 2 is an output waveform diagram of the LED power supply device 3 with a voltage determination function in the connected state of FIG.
Since the 5000K LEDs 6a to 6d of the first LED unit 5 and the 3000K LEDs 8a to 8d of the second LED unit 7 are all connected in series, the output voltage (output voltage 1) of the LED light source device 4 becomes high. . For this reason, the LED power supply device 3 with a voltage determination function determines the output voltage, determines to drive with a low output current (output current 1), and turns on the LED light source device 4.

  Thus, the 5000K LEDs 6a to 6d of the first LED unit 5 and the 3000K LEDs 8a to 8d of the second LED unit 7 are all connected in series, so that the LEDs 6a to 6d and the LEDs 8a to 8d emit light. The color temperature of the emitted light can be switched to, for example, 4000K.

(Lighting only for 5000K)
Next, a case where the LED lighting system 1 turns on only the first LED unit 5 for 5000K will be described. FIG. 3 is a configuration diagram when only the first LED unit 5 for 5000K is turned on.

  The voltage from the commercial power supply 2 is input to the LED power supply device 3 with a voltage determination function, and a DC power supply is generated by the LED power supply device 3 with the voltage determination function, and the LEDs 6a to 6d for 5000K of the first LED unit 5 are turned on. .

  At this time, the changeover switch contact 10c in the changeover switch 9 is connected to the changeover switch 10b. Accordingly, only the 5000K LEDs 6a to 6d of the first LED unit 5 are lit, and the 3000K LEDs 8a to 8d of the second LED unit 7 are short-circuited by the changeover switch contacts 10b and 10c, so that they are not lit.

  FIG. 4 is an output waveform diagram of the LED power supply device 3 with a voltage determination function in the connected state of FIG. Since the LEDs 6a to 6d for 5000K of the first LED unit 5 are turned on, the output voltage (output voltage 2) of the LED light source device 4 is lowered. For this reason, the LED power supply device 3 with a voltage determination function determines the output voltage (output voltage 2) in this state, determines to drive with a high output current (output current 2), and turns on the LED light source device 4. .

  By causing an output current higher than the output current in the case of FIG. 2 to flow through the 5000K LEDs 6a to 6d of the first LED unit 5, the luminous flux can be made the same as the connection state of FIG. Furthermore, by turning on only the LEDs 6a to 6d for 5000K, the color temperature of light can be set to 5000K.

(Lighting only for 3000K)
Next, the LED illumination system 1 when only the second LED unit 7 for 3000K is turned on will be described. FIG. 5 is a configuration diagram when only the second LED unit 7 for 3000K is turned on.

  The voltage from the commercial power source 2 is input to the LED power source device 3 with a voltage determination function, a DC power source is generated by the LED power source, and the 3000K LEDs 8a to 8d of the second LED unit 7 are turned on.

  At this time, the changeover switch contact 10c in the changeover switch 9 is connected to the changeover switch 10a. Accordingly, only the 3000K LEDs 8a to 8d of the second LED unit 7 are lit, and the 5000K LEDs 6a to 6d of the first LED unit 5 are short-circuited by the changeover switch contacts 10a and 10c, so that they are not lit.

  FIG. 6 is an output waveform diagram of the LED power supply device 3 with a voltage determination function in the connected state of FIG. Since the LEDs 8a to 8d for the 3000K of the second LED unit 7 are turned on, the output voltage (output voltage 2) of the LED light source device 4 is lowered. Therefore, the LED power supply device 3 with a voltage determination function is output in this state. The voltage (output voltage 2) is determined, it is determined to drive with a high output current (output current 2), and the LED light source device 4 is turned on.

  By causing a high output current to flow through the 3000K LEDs 8a to 8d of the second LED unit 7, the luminous flux can be made the same as in the connection state of FIG. 1, and only the 3000K LEDs 8a to 8d are lit. Thus, the color temperature of light can be set to 3000K.

Embodiment 2. FIG.
FIG. 7 is a system configuration diagram showing the configuration of the LED lighting system 1 that can change the color temperature by external switching. In the second embodiment, the connection between the first LED unit 5 and the second LED unit 7 is switched to the LED lighting system 1 of the first embodiment via the external changeover switch 12. The color temperature can be switched from the outside without operating the selector switch 9 provided in the apparatus 4.

  Thus, with the configuration of FIG. 7, it is possible to provide an inexpensive and space-saving LED illumination device with a variable color temperature without reducing the number of LED power supplies and without connecting a color temperature controller or the like.

  Moreover, as shown in FIG. 8, the LED power supply device 3 with a voltage determination function may include a selection instruction signal receiving unit. That is, the remote controller (color temperature controller) transmits a selection instruction signal for instructing selection of a predetermined LED unit (one of the first LED unit and the second LED unit, or both). When the selection instruction signal receiving unit receives a selection instruction signal from the remote controller, the LED power supply device 3 with a voltage determination function may select the LED unit indicated by the selection instruction signal by controlling the changeover switch 9. .

Embodiment 3 FIG.
The LED lighting system 1 according to Embodiment 3 will be described with reference to FIGS. In the third embodiment, a step dimming function is added to the LED lighting system 1 of the first embodiment. In the LED lighting system 1 according to the third embodiment, the same configurations and functions as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.

(Configuration of LED lighting system 1)
FIG. 9 is a circuit diagram illustrating the LED lighting system 1 according to the third embodiment. The LED lighting system 1 (lighting fixture) has the same configuration as the LED lighting system 1 of the first embodiment, but the configuration of the LED light source device is different from that of the LED lighting system 1 of the first embodiment. For this reason, the code | symbol of an LED light source device is changed like LED light source device 4-30 in Embodiment 3 with respect to LED light source device 4 of Embodiment 1. FIG. The LED lighting system 1 includes an LED power supply device 3 with a voltage determination function that receives a commercial power supply 2 and converts it into a DC voltage, and an LED light source device 4 (light source) that is lit by power supplied from the LED power supply device 3 with a voltage determination function. Unit).

(LED power supply device 3 with voltage judgment function)
The LED power supply device 3 with a voltage determination function detects a voltage output from the constant current circuit 3a and a constant current circuit 3a that converts the input commercial power supply 2 (AC voltage) into a DC voltage and outputs a predetermined constant current. And a voltage detection circuit 3b for instructing the constant current circuit 3a a current value of a predetermined constant current to be output from the constant current circuit 3a according to the detected voltage.

(Configuration of LED light source device 4-30)
LED light source device 4-30
(1) a first LED unit 5 having one end connected to the LED power supply device 3 with a voltage determination function and a color temperature of 5000K;
(2) a second LED unit 7 having one end connected to the other end of the first LED unit 5 and a color temperature of 3000 K;
(3) a changeover switch 9 connected between the output terminals of the LED power supply device 3 with a voltage determination function;
(4) It has the step light control switch 13 (LED exclusion part) connected to the 1st LED unit 5 and the 2nd LED unit 7.

  In the LED light source device 4-30, the first LED unit 5 includes five LEDs 6a to 6e connected in series. In the second LED unit 7, five LEDs 8a to 8e are connected in series. The LEDs constituting the first LED unit 5 (second LED unit 7) are LED 6a (LED 8a), LED 6b (LED 8b),... LED 6e (LED 8e) in order from the changeover switch 9 side. The order of the LEDs is the same for the LED light source devices 4-31 to 4-33 and 4-40 described later. The number of LEDs constituting the first LED unit 5 and the second LED unit 7 is not limited to 5, but may be 4 or less, or 6 or more.

(Changeover switch 9)
As shown in FIG. 9, the changeover switch 9 includes three changeover switch contacts 10a, 10b, and 10c, and the operation of the switch can be switched in the following three patterns.
These three patterns
(1) Pattern 1 in which the changeover switch contacts 10a to 10c are connected.
(2) Pattern 2 in which the changeover switch contacts 10b-10c are in a connected state,
(3) Pattern 3 in which the changeover switch contact 10c is not connected to any of the changeover switch contacts 10a and 10b.

  As shown in FIG. 9, the changeover switch contact 10 a is connected to a connection point 21 between the LED power supply device 3 with a voltage determination function and the first LED unit 5. The changeover switch contact 10 b is connected to a connection point 22 between the LED power supply device 3 with a voltage determination function and the second LED unit 7. The changeover switch contact 10 c is connected to a connection point 23 between the first LED unit 5 and the second LED unit 7.

(Stage dimming switch 13)
The step dimming switch 13 includes the midpoint of any of the series-connected LEDs 6a to 6e constituting the first LED unit 5 (in the third embodiment, the connection point 24 between the LED 6c and the LED 6d), A first-stage dimming switch 13a connected between the other end 25 of the LED unit 5 (on the opposite side to the LED power supply device 3 with a voltage determination function) and a series-connected LED 8a constituting the second LED unit 7 To 8e (in the third embodiment, the connection point 25 between the LED 8c and the LED 8d) and one end of the second LED unit 7 (on the opposite side to the LED power supply device 3 with a voltage determination function), And a second-stage dimming switch 13b connected between the two. The switch operations of the first-stage dimming switch 13a and the second-stage dimming switch 13b are linked, and both switches are switched on / off simultaneously.

  Next, the lighting state of the LED light source device 4-30 when the selector switch 9 and the step dimmer switch 13 are switched will be described. When the step dimmer switch 13 (the first step dimmer switch 13a and the second step dimmer switch 13b) is in the OFF state, it is the same as that of the first embodiment (FIGS. 1, 3, 5, etc.). Will be omitted and the step dimming switch 13 will be described in detail. In addition, the loop of the electric current which is output from the LED power supply device 3 with a voltage determination function and flows into the LED light source device 4 when the step dimmer switch 13 is in the off state is shown in FIGS. Indicated. Since the step dimming switch 13 is OFF in FIG. 10, (a), (b), and (c) in FIG. 10 correspond to FIGS. 1, 5, and 3, respectively. In FIGS. 10A, 10B, and 10C, solid line portions indicate lines through which current flows, and broken line portions indicate lines through which no current flows.

  (A ′), (b ′), and (c ′) in FIG. 11 are diagrams in which the stage dimming switch 13 is in an on state with respect to the state of each changeover switch 9 in FIGS. It is.

(A. Operation when both changeover switch 9 and step dimming switch 13 are on)
First, the case where the changeover switch 9 is on (the pattern 1; 10a-10c is connected) and the step dimmer switch 13 is on will be described with reference to FIG.

(In the case of FIG. 11 (b ′)) As shown in FIG. 11 (b ′), when the changeover switch contact 10a and the changeover switch contact 10c are connected, the current output from the LED power supply device 3 with a voltage determination function is Instead of flowing to the first LED unit 5, it flows to the step dimmer switch 13 via the changeover switch 9.

  Since the stage dimmer switch 13 (second stage dimmer switch 13b) is on, no current flows through the LEDs 8d and 8e, and a current flows through the LED power supply device 3 with a voltage determination function via the LEDs 8a to 8c.

  Accordingly, among the LEDs 8a to 8e constituting the second LED unit 7, the LEDs 8a to 8c are lit. Since the LED power supply device 3 with a voltage determination function is a constant current circuit, it tries to flow a constant current to each LED regardless of the number of LEDs constituting the second LED unit 7. At this time, since the number of LEDs to be lit changes (decreases), the total value of the forward voltage Vf of each LED changes, and the voltage value output from the LED power supply device 3 with a voltage determination function changes.

  The voltage detection circuit 3b of the LED power supply device 3 with a voltage determination function detects a voltage value output from the LED power supply device 3 with a voltage determination function, and outputs a control signal indicating a current value corresponding to the detected voltage value as a constant current. Output to the circuit 3a. The constant current circuit 3a outputs it to the LED light source device 4-30 so as to obtain a current value based on the input control signal.

  Accordingly, among the LEDs 8a to 8e constituting the second LED unit 7, the LEDs 8a to 8c are turned on, and the current flowing through the LEDs 8a to 8c is based on a control signal output from the voltage detection circuit 3b.

  That is, since the LED power supply device 3 with a voltage determination function is a constant current circuit, a constant current (current based on a control signal) flows through each LED regardless of the number of LEDs constituting the second LED unit 7. Therefore, if the number of LEDs to be lit changes, the brightness as the LED light source device 4-30 (lighting fixture 1) also changes.

Therefore, since the second LED unit 7 is turned on by turning on the changeover switch 9 (10a-10c connection), the color temperature can be changed.
Further, the brightness can be changed (dimmed) by turning on the step dimmer switch 13.

  Next, the case where the changeover switch 9 shown in FIG. 11C 'is on (the pattern 2; 10b-10c is connected) and the step dimmer switch 13 is on will be described.

(In the case of FIG. 11 (c ′))
The changeover switch contact 10b and the changeover switch contact 10c are connected,
In addition, when the step dimmer switch 13 is in the on state, the current output from the LED power supply device 3 with a voltage determination function flows into the first LED unit 5 and passes through the connection point 24 and the first step dimmer switch 13a. Return to the LED power supply device 3 with a determination function.

  That is, in the pattern 1, the current flows through the LEDs 8 a to 8 c of the second LED unit 7, but the pattern LED 2 is different in that the current flows through the LEDs 6 a to 6 c of the first LED unit 5. Since the operation of the other LED power supply device 3 with a voltage determination function (constant current circuit 3a, voltage detection circuit 3b) is the same, description thereof is omitted.

  Finally, with reference to FIG. 11 (a '), a case where the changeover switch 9 is off (the pattern 3) and the step dimmer switch 13 is on will be described.

(In the case of FIG. 11 (a ′))
When the changeover switch contacts 10 a and 10 b are not connected to the changeover switch contact 10 c, the current output from the LED power supply device 3 with a voltage determination function is the connection point 24 of the first LED unit 5, the step dimmer switch 13. And it flows through the connection point 25 of the second LED unit 7 to the LED power supply device 3 with a voltage determination function (feeds back).

  Since a current flows through the step dimmer switch 13, no current flows through the LEDs 6 d and 6 e constituting the first LED unit 5 and the LEDs 8 d and 8 e constituting the second LED unit 7, so that they do not light up.

  Therefore, the currents output from the LED power supply device 3 with the voltage determination function are the LEDs 6a to 6c and the LEDs 8a to 8c, and the voltage output from the LED power supply device 3 with the voltage determination function is the forward voltage of the six LEDs. This is the total value of Vf.

  Therefore, at this time, the output voltage output from the LED power supply device 3 with a voltage determination function lights all of the LEDs 6a to 6e and the LEDs 8a to 8e (or either one of the LEDs 6a to 6e or the LEDs 8a to 8e). It is different from the output voltage of the LED power supply device 3 with a voltage determination function when Moreover, it differs from the output voltage of the LED power supply device 3 with a voltage determination function when only the LEDs 8a to 8c (LEDs 6a to 6c) are lit as in the pattern 1 (pattern 2).

  Therefore, the voltage detection circuit 3b outputs a control signal indicating a current value based on the output voltage output from the LED power supply device 3 with a voltage determination function at this time.

  In this way, regardless of whether the change-over switch 9 is on or off, the lighting state of the LED light source device 4 can be switched between all-light lighting and dimming lighting by turning the step dimmer switch 13 on and off.

  Moreover, as shown in FIG. 12, you may change the lighting ratio of LED which comprises the 1st LED unit 5 which lights at the time of step light control, and LED which comprises the 2nd LED unit 7. FIG. This LED light source device is called an LED light source device 4-31 because the number of LEDs is different from that of the LED light source device 4-30 in FIG. Accordingly, in FIG. 12, there are three LEDs 6a to 6c on the left side of the connection point 24 of the first LED unit 5, three LEDs 6d to 6f on the right side, and the second LED unit 7 The connection points 24 and 25 are arranged so that there are four LEDs 8a to 8d on the left side of the connection point 25 and two LEDs 8e and 8f on the right side. FIGS. 13A, 13B, and 13C show that the change-over switch 9 is off, on (10a-10c connection), and on (10b-10c connection) when the step dimmer switch 13 is off. This corresponds to (a), (b), and (c) of FIG. 14A, 14B, and 14C show the case where the step dimmer switch 13 is turned on with respect to FIG. 13, and is the same as FIG.

  For example, when dimming (darkening) in a state where the color temperature is high, human eyes may feel uncomfortable (have an impression of a gloomy atmosphere).

  Accordingly, the number of LEDs lit by the LEDs configuring the second LED unit 7 (3000K) is made larger than the number of LEDs lit by the LEDs configuring the first LED unit 5 (5000K) during step dimming. As a result, the color temperature at the time of all light, for example, 4000K can be set to 3500K at the time of step dimming. Thus, by making the color temperature at the time of step dimming lower than the color temperature at the time of all light, it is possible to reduce a person's feeling of discomfort.

  Further, the step dimming switch 13 is connected to a position (connection point 24 in FIG. 13) where the number of LEDs among the LEDs connected in series constituting the first LED unit 5 and the second LED unit 7 is equally divided. Then, when the step dimmer switch 13 is turned on in a state where the changeover switch contact 10c of the changeover switch 9 is not connected to the changeover switch 10a and the changeover switch 10b, the total number of LEDs becomes the first LED unit 5 (or This is the same as the number of LEDs in the second LED unit 7). That is, when the first LED unit 5 is composed of 6 LEDs and the second LED unit 7 is also composed of 6 LEDs, the first LED unit 5 is lit alone, the second LED unit 7 is lit alone, the first LED In any case where the unit 5 and the second LED unit 7 are turned on by half the number of LEDs by the step dimmer switch 13, the number of LEDs is 6, and the total forward voltage of the LEDs is the same. The determination circuit 3b cannot determine from the forward voltage whether it is step dimming. Therefore, as shown in FIG. 15 or FIG. 18, resistors 31a and 31b (FIG. 15) and Zener diodes 32a and 32b are inserted into the step dimmer switch 13. An LED light source device having a configuration using the resistors 31a and 31b is referred to as an LED light source device 4-32. An LED light source device using the Zener diodes 32a and 32b is referred to as an LED light source device 4-33. FIGS. 16A, 16B, and 16C show the configuration of FIG. 15 in which the change-over switch 9 is turned off, turned on (10a-10c connection), turned on while the step dimmer switch 13 is turned off. The state of (10b-10c connection) is shown. FIGS. 17A, 17B, and 17C show a case where the step dimmer switch 13 is turned on with respect to FIGS. 16A, 16B, and 16C. FIGS. 19 and 20 show cases where Zener diodes 32a and 32b are used, and correspond to FIGS.

  When the step dimmer switch 13 is connected to a position where the number of LEDs is equally divided among the serially connected LEDs constituting the first LED unit 5 and the second LED unit 7, FIG. 15 and FIG. Thus, the resistors 31a and 31b or the Zener diodes 32a and 32b may be inserted. By this insertion, the constant current circuit 3a outputs the voltage output from the constant current circuit 3a when the step dimmer switch 13 is turned off and the changeover switch contact 10c is connected to the changeover switch contact 10a (or changeover switch contact 10b). When the voltage is different between the voltage to be switched ((b), (c) in FIG. 16 or (b), (c) in FIG. 19) and the step dimming in which the step dimming switch 13 is turned on. Good. Thereby, the voltage detection circuit 3b can detect a voltage value indicating step dimming.

Embodiment 4 FIG.
The LED lighting system 1 according to the fourth embodiment will be described with reference to FIGS. The fourth embodiment is a modification of the third embodiment. The LED lighting system 1 of Embodiment 4 differs from the LED light source device 4 of Embodiment 1 in the configuration of the LED light source device 4-40.

  The step dimming switch 13 according to the above-described third embodiment switches the step dimming by turning on / off the two switches (first stage dimming switch 13a, second stage dimming switch 13b) in conjunction with each other. However, the step dimming switch 15 according to the fourth embodiment switches the step dimming with a single switch.

  FIG. 21 is a circuit diagram showing the LED lighting system 1 according to the fourth embodiment. FIG. 22 shows a state in which the step dimmer switch 15 is in an off state and the change-over switch 9 is in an off state, an on state (10a-10c connection), and an on state (10b-10c connection). 23, 22 (a), (b), and (c) show a case where the step dimmer switch 15 is on. The step dimmer switch 15 and the diodes 16a and 16b have the function of the step dimmer switch 13 (the step dimmer switch 15 and the diodes 16a and 16b constitute an LED exclusion unit).

  As in the first to third embodiments, the LED lighting system 1 (LED lighting device) is supplied with the commercial power source 2 and converted to a DC voltage. The LED power source device 3 with a voltage determination function and the LED power source with the voltage determination function LED light source device 4-40 that is turned on by the power supplied from the device 3.

  The LED light source device 4-40 has a first LED unit 5 having a color temperature of 5000K, one end of which is connected to the LED power supply device 3 with a voltage determination function, and a color having one end connected to the other end of the first LED unit 5. A stage connected to the second LED unit 7 having a temperature of 3000 K, a changeover switch 9 connected between the output terminals of the LED power supply device 3 with a voltage determination function, and the first LED unit 5 and the second LED unit 7 It has a dimming switch 15 and a bypass circuit 16 (series connection of diodes 16a and 16b).

  As shown in FIG. 21, the step dimming switch 15 is provided between the LED rows constituting the first LED unit 5 (connection point 26) and between the LED rows constituting the second LED unit 7 (connection point 27). Connected to.

  As shown in FIG. 21, the bypass circuit 16 includes two diodes 16a and 16b connected in series, and one diode 16a has a cathode terminal between the LED strings constituting the first LED unit 5 (connection point 28). ), The anode terminal is connected to the changeover switch contact 10c, and the other diode 16b has a cathode terminal connected to the changeover switch contact 10c, and an anode terminal between the LED rows constituting the second LED unit 7 (connection point 29). ).

  Next, although the lighting state (current flow) of the first LED unit 5 and the second LED unit 7 will be described, the step dimmer switch 15 is in an off state ((a) to (c) shown in FIG. 22). In this case, the description is omitted because it is the same as in the first to third embodiments.

  Next, with reference to FIG. 23 (b '), the case where the step dimmer switch 15 is in the on state and the changeover switch contact 10c is connected to the changeover switch contact 10a will be described.

(In the case of FIG. 23 (b ′))
The current output from the constant current circuit 3a flows from the changeover switch contact 10a to the bypass circuit 16 via the changeover switch contact 10c, and the second LED passes through the diode 16a of the bypass circuit 16 and the step dimming switch 15. It flows to the unit 7 (LEDs 8c, 8b, 8a).

  Therefore, although current flows through the LEDs 8a to 8c constituting the second LED unit 7, the current does not flow through the first LED unit 5, and the LED does not light up. Further, the LEDs 8d and 8e constituting the second LED unit 7 are not lit because no current flows.

  Next, with reference to FIG. 23 (c ′), a description will be given of a case where the step dimmer switch 15 is in the ON state and the changeover switch contact 10c is connected to the changeover switch contact 10b. ).

(In the case of FIG. 23 (c ′))
The current output from the constant current circuit 3a flows to the step dimmer switch 15 via the first LED unit 5, and further flows from the diode 16b of the bypass circuit 16 and the changeover switch contact 10c to the changeover switch contact 10b.

  Therefore, although current flows through the LEDs 6a to 6c constituting the first LED unit 5, the second LED unit 7 does not flow and no LED is lit. Further, the LEDs 6d and 6e constituting the first LED unit 5 are not lit because no current flows.

  Finally, referring to FIG. 23 (a ′), when the step dimmer switch 15 is in the on state and the changeover switch contact 10c is in the off state not connected to the changeover switch contact 10a and the changeover switch contact 10b. Will be explained. In this case, similarly to the pattern 3 of the third embodiment, the current flows through the LEDs 6a to 6c of the first LED unit 5 and the LEDs 8a to 8c of the second LED unit 7, and lights up.

  Thus, by providing the bypass circuit 16, the step dimming switch 15 can be made into one single switch.

  As mentioned above, although Embodiment 1-4 was demonstrated, you may implement combining 2 or more among these embodiments. Alternatively, one of these embodiments may be partially implemented. Alternatively, two or more of these embodiments may be partially combined.

  DESCRIPTION OF SYMBOLS 1 LED lighting system, 2 Commercial power supply, 3 LED power supply device with a voltage determination function, 4 LED light source device, 5 1st LED unit, 6a-6f LED, 7 2nd LED unit, 8a-8f LED, 9 changeover switch, 10a -10c change-over switch contact, 11 different shaped device, 12 external change-over switch, 13-stage dimmer switch, 13a first-stage dimmer switch, 13b second-stage dimmer switch, 14 light source unit, 15-stage dimmer switch, 16 bypass Circuit, 16a, 16b Diode.

Claims (5)

A plurality of LED groups composed of a plurality of electrically connected LEDs;
A selection circuit unit that selects at least one LED group from the plurality of LED groups and forms a series connection unit that is a series connection of the selected LED groups when the plurality of LED groups are selected;
When only one LED group is selected by the selection circuit unit, a first provisional current is provisionally supplied to the only one LED group as a current supply target to light it, and the selection circuit unit When the series connection portion is formed, a second provisional current having a magnitude substantially the same as the first provisional current is provisionally supplied to the series connection portion as a current supply target, and the first provisional current is lit. A voltage generated in only one LED group by current or a voltage generated in the series connection by the second provisional current is detected, and a current corresponding to the detected voltage is the current supply target. An LED illumination device comprising: a single power source device that flows through the LED group or the series connection portion that is the current supply target. The plurality of LED groups are:
The LED lighting device according to claim 1, comprising a first LED group having a predetermined color temperature and a second LED group having a color temperature different from that of the first LED group. The plurality of LED groups are:
Both are LED units with different color temperatures,
The selection circuit unit includes:
3. The LED lighting device according to claim 1, wherein selection of all of the plurality of LED groups and selection of one LED group of the plurality of LED groups are possible. The LED lighting device further includes:
4. The LED according to claim 3, further comprising: an LED excluding unit that excludes a part of the LEDs constituting the LED group selected by the selection circuit unit from the current supply target by the power supply device. 5. Lighting device. The selection circuit unit includes:
5. The display device according to claim 1, further comprising a selection instruction signal receiving unit that receives a selection instruction signal instructing selection of the predetermined LED group, wherein the LED group instructed by the selection instruction signal is selected. LED illuminating device of description.

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