DE102019113552A1 - LED LIGHTING DEVICE AND LAMP - Google Patents

Abstract

A light emitting diode (LED) lighting device (30) which causes a plurality of LED loads (21-24), each having a different emission color, to emit light, includes a power supply circuit (31); a selection circuit (32) that causes the power supply circuit (31) to power the plurality of LED loads (21-24) by sequentially and cyclically selecting the plurality of LED loads (21-24); and a control circuit (33) that controls a selection made by the selection circuit (32) such that at least two power supply intervals during which the power supply circuit (31) powers each of the plurality of LED loads (21-24) , of multiple power supply intervals in a cycle during which the multiple LED loads (21-24) are sequentially selected in sequence.

Description

[Technical field]

The present invention relates to a light-emitting diode (LED) lighting device that causes LED loads, each having a different emission color, to emit light, and a lamp.

[General state of the art]

Patent Literature (PTL) 1 discloses a lighting device capable of dimming and attenuating by (i) causing LEDs, each having a different emission color, to be sequentially switched and emit light, and (ii) one Intensity and a mixing ratio of each emission color can be set.

[Literature]

[Patent Literature]

[PTL 1]
Japanese unexamined patent application with publication no. From 2,004 to 311,635.

SUMMARY OF THE INVENTION

[Technical problem]

However, the previous conventional technique sometimes causes flickering to occur when, for example, illuminating light is dark due to dimming. The color flickering here is light with a color from the LEDs, which occurs, for example, in the case of a rapidly moving object, such as the blades of a fan, and causes a person to see this color under the illuminating light. Color flicker can cause a person to feel uncomfortable or feel that something is wrong in cases where the color flicker is intense.

Accordingly, the present invention aims to provide an LED lighting device and lamp that reduce color flicker that easily occurs when lighting light is dark due to dimming.

[The solution of the problem]

To solve the previous problem, an LED lighting device in the present invention that causes a plurality of LED loads each having a different emission color to emit light includes a power supply circuit that powers the plurality of LED loads; a selection circuit that causes the power supply circuit to power the plurality of LED loads by sequentially and cyclically selecting the plurality of LED loads; and a control circuit that controls a selection made by the selection circuit such that at least two power supply intervals during which the power supply circuit powers each of the plurality of LED loads from a plurality of power supply intervals in a cycle during which the plurality of LED lights Loads are selected sequentially in sequence or one by one, are continuous.

Advantageous Effects of Invention

An LED lighting device and a lamp in the present invention can reduce color flickering that simply occurs when lighting light is dark due to dimming.

list of figures

• 1 FIG. 12 is a block diagram showing a configuration example of a lamp including an LED lighting device according to the embodiment 1 shows;
• 2 10 is a diagram showing current waveforms of the lamp including the LED lighting device according to the embodiment 1 shows;
• 3 FIG. 12 is a block diagram showing a circuit configuration example of the lamp including the LED lighting device according to the embodiment 1 shows;
• 4 12 is a diagram showing current waveforms and voltage waveforms of each part of the lamp that includes the LED lighting device according to the embodiment 1 shows;
• 5 FIG. 12 is a diagram showing a current waveform of the lamp including the LED lighting device according to the embodiment 2 shows;
• 6 FIG. 12 is a diagram showing a current waveform of the lamp including the LED lighting device according to the embodiment 3 shows;
• 7 10 is a diagram showing a current waveform and a timer output of the lamp including the LED lighting device according to the embodiment 4 shows;
• 8A FIG. 12 is a diagram showing an outside area example of the lamp including the LED lighting device according to each of the embodiments; FIG.
• 8B 11 is a diagram showing another outdoor example of the lamp including the LED lighting device according to each of the embodiments;
• 8C FIG. 14 is a diagram showing yet another outdoor example of the lamp including the LED lighting device according to each of the embodiments;
• 9 Fig. 12 is a diagram showing a configuration of a lamp in a comparative example; and
• 10 Fig. 12 is a diagram showing current waveforms of the lamp in the comparative example.

DESCRIPTION OF EMBODIMENTS

Underlying Knowledge Forming the Basis of the Present Invention

The inventors have identified the following problem in connection with a lighting device that is described in the "General Prior Art" section.

A lamp according to the inventors' knowledge will first be described as a comparative example.

9 12 is a diagram showing a configuration of the lamp in the comparative example according to the inventors' knowledge. The lamp in the drawing includes a power supply circuit 90 , LED loads 91 - 94 and switching elements SW3 - SW6 , The power supply circuit 90 contains switching elements SW1 and SW2 and a coil L0 and is a so-called step-down type DC (DC) to DC converter. The switching elements SW1 and SW2 are only switched off from each other. The sink L0 stores and discharges energy from the connection points of the switching elements SW1 and SW2 is fed.

The LED loads 91 - 94 each have a different emission color.

The switching elements SW3 - SW6 are switched on sequentially within one cycle.

10 Fig. 12 is a diagram showing current waveforms of the lamp in the comparative example. The vertical axis in the drawing indicates the coil current. The coil current is the output current of the power supply circuit 90 leading to each of the LED loads across the coil L0 is fed. The horizontal axis indicates the time. The top of the drawing indicates a relatively light condition. The bottom of the drawing indicates a dark state due to dimming. The color α, the color β, the color y, the color δ each give the emission colors of the LED loads 91 - 94 on. The emission colors of the LED loads 91 - 94 are for example red, green, blue and white.

As in 10 is illustrated, the LED loads radiate 91 - 94 sequentially turns off light sequentially during cycle Ts. This process is known as rotating lighting. In 10 the cycle Ts is fixed and is a switching frequency of the switching elements SW3 - SW6 shown in a case where the frequency is fixed. If light is dimmed while the switching frequency is fixed, an on-time becomes shorter and at the same time the pause interval Tx becomes longer. As the pause interval Tx becomes longer, the human eye can perceive a flickering color during the rotating illumination.

Color flicker is a phenomenon in which emission colors appear scattered due to the presence of a fast moving object under illuminating light, e.g. B. when a person's hands are quickly swung under illuminating light or blades of a fan that is rotating. In the case of color flicker, colors appear broken through in a fast-moving object because the pause interval Tx is longer. Such color flickering can cause discomfort and the feeling that something is wrong.

To solve such a problem, an LED lighting device according to an aspect in the present invention that causes a plurality of LED loads each having a different emission color to emit light includes a power supply circuit that supplies the plurality of LED loads with current provided; a selection circuit that causes the power supply circuit to power the plurality of LED loads by sequentially and cyclically selecting the plurality of LED loads; and a control circuit that controls a selection made by the selection circuit such that at least two power supply intervals during which the power supply circuit powers each of the plurality of LED loads from a plurality of power supply intervals in a cycle during which the plurality of LED lights Loads are selected sequentially in sequence, are continuous.

This makes it possible to reduce colors that appear broken in a fast moving object by having power supply intervals that are continuous, i. that is, the color flicker can be reduced.

Hereinafter, embodiments in the present invention will be described in detail with reference to the drawings.

It should be noted that each of the embodiments described below shows a comprehensive or specific example in the present invention. Numerical values, shapes, materials, components, the placement and connection of the components, steps and their sequence and the like are only examples and are not intended to limit the present invention. Components in the following embodiments that are not mentioned in any of the independent claims that define the broadest concepts are described as optional elements.

Embodiment 1

Configuration of the LED lighting device and light

First, a configuration example of the lamp 100 including the LED lighting device 30 according to the embodiment 1 described.

1 is a block diagram showing the configuration example of the lamp 100 including the LED lighting device 30 according to the embodiment 1 shows. The lamp 100 in the drawing, an AC (DC) power supply 10 includes a light source 20 and an LED lighting device 30 ,

The AC-DC power supply 10 is connected to a 100 V mains power supply, for example, is supplied with alternating current and converts the alternating current into direct current.

The light source 20 includes LED loads 21 - 24 , The LED loads 21 - 24 each have a different emission color. The emission colors of the LED loads 21 - 24 Examples are red (R), green (G), blue (B) and white (W).

The LED lighting device 30 causes the LED loads 21 - 24 , which each have a different emission color, emit light. The LED lighting device 30 includes the power supply circuit 31 , the selection circuit 32 and the control circuit 33 for this reason.

The power supply circuit 31 converts the direct current from the AC-DC power supply 10 into direct current with a different voltage and is a DC-DC converter that converts the direct current of the light source 20 supplies.

The selection circuit 32 causes the power supply circuit 31 The LED loads are powered by the LED loads 21 - 24 sequentially and cyclically. The selection circuit 32 contains switching elements M3 - M6 for this reason. The switching elements M3 - M6 are each in line with an LED load of the LED loads 21 - 24 connected. In 1 is the switching element, for example M3 in line with the LED load 21 connected. The switching element M4 is in series with the LED load 22 connected. The switching element M5 is in series with the LED load 23 connected. The switching element M6 is in series with the LED load 24 connected. These switching elements M3 - M6 are controlled, for example, in such a way that they are only switched on from each other. The LED loads shine with it 21 - 24 exclusively, ie, one after the other, lights off.

The control circuit 33 controls the selection circuit 32 to sequentially and cyclically the LED loads 21 - 24 to be selected in order. The control circuit 33 controls a selection made by the selection circuit 32 is performed such that at least two power supply intervals during which the power supply circuit 31 each of the LED loads 21 - 24 powered by multiple power supply intervals in one cycle during which the LED loads 21 - 24 sequentially selected in sequence, are continuous. For example, the control circuit 33 the selection circuit 32 control in such a way that N Power supply intervals accordingly N LED loads are continuous; and a pause interval during which none of the LED loads are powered comes immediately before and immediately after N Power supply intervals that are continuous. N is an integer of at least 3, and 1 shows an example of N = 4.

2 is a diagram showing an example of current waveforms of the lamp 100 that the LED lighting device 30 includes, according to the embodiment 1 shows. In 2 is the power supply circuit 31 a switching power supply, which contains a coil, and supplies the LED loads 21 - 24 over the coil with electricity. In the upper part and the lower part of the drawing, the vertical axis indicates the coil current, ie current, from the power supply circuit 31 one of the LED loads is applied. The horizontal axis indicates the time. The upper part of the drawing shows a waveform of the coil current when a dimming rate is a first value. The lower part of the drawing shows a waveform of the coil current when the dimming rate is a second value that is lower than the first value.

In 2 the interval Ts indicates a lighting cycle during which the LED loads 21 - 24 emit light sequentially in sequence. The light cycle ts here is fixed. The colors α . β . γ and δ give the emission colors of the LED loads 21 - 24 and are for example red (R), green (G), blue (B) and white (W).

The interval Ta is a power supply interval during which the power supply circuit 31 the LED load 21 that are the emission color α has powered. The intervals Tb . tc and td are similar to power supply intervals during which the power supply circuit 31 the LED loads 22 . 23 . 24 powered.

The interval Tx is a pause interval during which none of the LED loads is supplied with power.

As illustrated in the drawing, the pause interval is Tx as an interval in the lighting cycle ts compiled, even if the dimming rate changes, as illustrated in the upper part and the lower part of the drawing. The four power supply intervals Ta - td are continuous and there is no interval between them. In 2 the color flicker can be compared to the comparative example shown in 10 is shown to be reduced.

A more concrete circuit example of the lamp 100 that the LED lighting device 30 will be described next.

3 Fig. 12 is a block diagram showing the circuit configuration example of the lamp 100 that the LED lighting device 30 includes, according to the embodiment 1 shows. As in 3 is illustrated, includes the lamp 100 a light source 20 and an LED lighting device 30 , In 3 is however the in 1 shown AC-DC power supply 10 omitted.

The LED load 21 at the light source 20 is in series with the switching element M3 connected is controlled to light due to the fact that the switching element M3 is switched on and off, radiate and there is a stronger current and a light intensity increases, the longer the switching element M3 is switched on.

The LED load 21 in 3 contains the LEDs as the more concrete circuit example d1 - d3 , the smoothing capacitor C2 that is parallel to the LEDs d1 - d3 is switched, the reverse current protection diode There that is connected in series with a parallel circuit that is the LEDs d1 - d3 and the smoothing capacitor C2 involves and the resistance R2 to discharge the power when the power is turned off.

The LEDs d1 - d3 are connected in series with light emission elements with the same emission color and are in series with the switching element M3 connected.

The smoothing capacitor C2 smoothes the coil current coming from the coil L1 across the diode There is fed.

The diode There prevents the current from the smoothing capacitor C2 back to the coil L1 flows. In other words, the diode leads There an electrical charge in the smoothing capacitor C2 is charged, only the LEDs d1 - d3 to.

The resistance R2 has a high resistance value and discharges the electrical charge of the smoothing capacitor C2 after the switching element M3 is switched from ON to OFF.

The LED loads 22 - 24 have the same configuration as the LED load 21 with the exception of the emission color. It should be noted that the LED load 21 not at least one of the smoothing capacitor C2 , the reverse current protection diode There and resistance R2 must contain. The same applies to the LED loads 22 - 24 ,

The power supply circuit 31 in the LED lighting device 30 is an example of a step-down chopper circuit in 3 , Strictly speaking, the power supply circuit includes 31 the controller 34 , the high-voltage integrated circuit (HVIC) 35 , the input resistors R6 and R7 who have favourited Switching Elements M1 and M2 and the coil L1 ,

The regulator 34 receives the direct current from the AC-DC power supply 10 and supplies HVIC 35 and the control circuit 33 with a stabilized power supply voltage.

The HVIC 35 leads the switching elements M1 and M2 via the input resistance R6 and R7 according to control of the control circuit 33 a gate signal too. The gate signal of the switching elements M1 and M2 becomes cyclical and only active at high speed.

The switching elements M1 and M2 are a high-side transistor and a low-side transistor for mutually connecting a supplied DC voltage from the AC-DC power supply 10 and a floor height with the coil L1 ,

The sink L1 stores and discharges electrical energy according to the switching of the switching elements M1 and M2 ,

The selection circuit 32 includes the input resistances R8 - R11 and the switching elements M3 - M6 ,

The switching element M3 is in series with the LED load 21 connected. A gate signal that switching element M3 instructs to be turned on and off by the control circuit 33 into a gate of the switching element M3 via the input resistance R8 entered. The switching element M3 is switched on and off according to the gate signal.

The switching elements M4 - M6 are similar to the switching element M3 , The control circuit 33 can also be a microcontroller unit or microcomputer unit (MCU) with a built-in processor, memory and timer 36 include. The timer 36 measures different types of cyclic time. For example, the timer 36 for measuring the cycle periods during which the LED loads 21 - 24 be sequentially selected in order using power supply intervals, pause intervals, and the like.

Configuration of the LED lighting device and light

Next is an example of operation of the lamp 100 including the LED lighting device 30 according to the embodiment 1 described.

4 FIG. 12 is a diagram showing current waveforms and voltage waveforms of each part of the lamp including the LED lighting device according to the embodiment 1 shows. The horizontal axis in the drawing indicates the time. The vertical axis gives the current or voltage in each part of the lamp 100 on. The coil current IL indicates the current flowing through the coil L1 flows, ie the current flowing from the power supply circuit 31 to one of the LED loads. In the drawing, intervals during which the coil current IL flows are power supply intervals. The power supply interval Ta indicates an interval during which the power supply circuit 31 the LED load 21 powered. Similarly, the power supply interval Tb-Td indicates intervals during which the power supply circuit 31 the LED loads 22 - 24 each supplied with electricity. The emission colors of the LED loads 21 - 24 are red, green, blue and white, respectively.

The gate voltage V0 gives a voltage input from the control circuit 33 into the gate of the switching element M1 via the HVIC 35 on. If the gate voltage V0 is high, the switching element M1 switched on. The coil current IL increases at intervals with a high level of gate voltage V0 to. At this point the coil is saving L1 electrical energy as magnetic energy. If the gate voltage V0 is low, the switching element M1 switched off. Immediately after the switching element M1 is switched from ON to OFF, the coil discharges L1 the stored energy, ie the stored energy becomes the LED load 21 fed while the coil current IL decreases to 0 due to a counter electromotive force of the coil L1 , As a result, the power supply interval Ta becomes longer than the intervals with a high level of the gate voltage V0 , The coil current IL is a triangular wave in the drawing. The power interval Ta during which the power supply circuit 31 the LED load is powered, corresponds to an interval of a triangular wave.

The gate voltage Vr gives a voltage input from the control circuit 33 into the gate of the switching element M3 on. When the gate voltage Vr is high, the switching element M3 switched on, ie, the corresponding LED load 21 selected. An interval with a high level of gate voltage Vr is controlled so that it is the interval with a high level of gate voltage V0 includes and is a period of time that is the triangular wave of the corresponding coil current IL includes. The gate voltages Vg . Vb and vw are similar to the gate voltage Vr , It should be noted that between the mutual intervals with a high level of gate voltages Vr . Vg . Vb and vw downtime is arranged during which the four gate voltages are low.

The LED current Ir indicates the current flowing through the LEDs d1 - d3 within the LED load 21 flows. After the power supply interval Ta, ie after the power supply from the power supply circuit 31 to the LED load 21 the LED current flows Ir still, although it decreases without becoming 0. This depends on the smoothing capacitor C2 and the reverse current protection diode There from.

The LED currents Ig, Ib and Iw are similar to the LED current Ir ,

As in 4 the power supply intervals Ta-Td are continuous. In other words, the control circuit controls 33 the gate voltage V0 such that the power supply intervals Ta-Td are continuous. The power supply interval Ta ends when the coil current IL decreases to 0. The control circuit 33 detects when the coil current IL decreases to 0, and encounters the next pulse of the gate voltage V0 on when the control circuit 33 recognizes that the coil current IL 0 is. The pause interval Tx is compiled as an interval in the lighting cycle Ts.

This enables color flicker to be reduced compared to when there are pause intervals between the power supply intervals since the power supply intervals Ta-Td are continuous.

It should be noted that a coloring, during which a color of the illuminating light in the lamp 100 is set by changing a brightness ratio of the emission colors. To be precise, leads in 4 the control circuit 33 coloring by changing a ratio of four pulse widths of the gate voltage V0 during the power supply intervals Ta - td by. Dimming, during which the brightness of the illuminating light in the luminaire 100 is set by changing the brightness of the emission colors while maintaining the brightness of the emission colors with a fixed ratio. To be precise, leads in 4 the control circuit 33 dimming by increasing and decreasing the four pulse widths of the gate voltage V0 through while the four pulse widths of the gate voltage V0 during the power supply intervals Ta - td be maintained with a fixed ratio.

In the in 4 The example shown is the switching element M1 the power supply circuit 31 controlled such that it is within a period in which one of the LED loads from the selection circuit 32 is selected, is switched on. In other words, the switching operation is in the power supply circuit 31 , which is a switching power supply, and the selection process in the selection circuit 32 synchronized.

It should be noted that the lighting cycle ts cyclically too fast to be noticed by people. For example, a frequency that is an inverse of the lighting cycle ts is at least 100 Hz.

“Cyclically too fast to be noticed by people” here means “flicker that is not noticed by people.” One measure against flickering in the LED lighting device is, for example, a comment regarding the Electrical Appliance and Material Safety Act (PSE ), "Concerning the Order for Enforcement of the Electrical Appliances and Materials Safety Act (valid from July 1, 2012)" (Product Safety Division, Commerce and Distribution Policy Group, Ministry of Economy, Trade and Industry). “Measure against flicker of optical output” on page 28 of the comment explains the frequency that achieves the effect corresponding to the "optical output at which no flicker is perceived" as follows. The commentary explains that in order to achieve the “optical output with no flicker”, it is either necessary (1) that the optical output with a repetition frequency of 100 Hz has no gaps or (2) that the repetition frequency is at least 500 Hz ,

The lamp 100 in the present embodiment must achieve the previous point (1) because the example in 4 shows no gaps in the optical output. In this case, the frequency can be the reciprocal of the lighting cycle ts is at least 100 Hz.

If the lamp 100 the smoothing capacitors C2 - C5 and the like in 3 not included, there are gaps in the optical output and the previous point ( 2 ) be achieved. In this case, the frequency can be the reciprocal of the lighting cycle ts is at least 500 Hz.

As previously described, the LED lighting device includes 30 according to the embodiment 1 that causes the LED loads 21 - 24 , each having a different emission color, emitting light, the power supply circuit 31 that the LED loads 21 - 24 powered; the selection circuit 32 that causes the power supply circuit 31 the LED loads 21 - 24 powered by the LED loads 21 - 24 selects sequentially and cyclically in order; and the control circuit 33 making a selection made by the selection circuit 32 is performed in such a way that controls at least two power supply intervals during which the power supply circuit 31 each of the LED loads 21 - 24 powered by multiple power supply intervals in one cycle during which the LED loads 21 - 24 sequentially selected in sequence, are continuous.

This enables color flicker to be reduced by making the power supply intervals continuous. In other words, if there is a fast-moving object under the illuminating light, emission colors that appear broken in a fast-moving object can be reduced.

The LED loads can be N LED loads, where N is an integer of at least 3; the control circuit 33 can the selection circuit 32 control in such a way that N Power supply intervals according to the N LED loads are continuous; and a pause interval during which none of the LED loads are powered occurs immediately before and immediately after the N power supply intervals, which are continuous.

This makes it possible to reduce colors that appear broken in a fast-moving object, since the power supply intervals corresponding to any emission color and the power supply interval corresponding to other colors are continuous, i. that is, the color flicker can be further reduced.

A frequency that is an inverse of the cycle during which the LED loads are sequentially selected can be at least 100 Hz.

This enables it to be harder for people to perceive the flicker caused by the LED loads that emit light cyclically.

The power supply circuit 31 can be a switching power supply that the coil L1 includes, and can handle the LED loads 21 - 24 over the coil L1 supply with electricity.

This enables the power supply circuit to be made more efficient and inexpensive and to be scaled down.

The control circuit 33 can cause the switching operation in the power supply circuit 31 , which is a switching power supply, and the selection process in the selection circuit 32 be synchronized.

The selection circuit 32 can the switching elements M3 - M6 include the switching elements M3 - M6 can each be in series with a corresponding one of the LED loads 21 - 24 be switched, and the control circuit 33 can sequentially and cyclically match the corresponding of the LED loads 21 - 24 by sequentially and cyclically switching on one of the switching elements M3 - M6 choose.

This enables the selection circuit to be caused 32 works quickly with a simple configuration.

The cycle during which the LED loads 21 - 24 sequentially selected in sequence can be set independently of a dimming rate.

This makes dimming easy.

The lamp 100 according to the embodiment 1 includes the previous LED lighting device 30 and the LED loads 21 - 24 ,

The LED loads 21 - 24 each contain at least one LED (e.g. d1 ), the smoothing capacitor C2 , which is connected in parallel to the at least one LED, and the reverse current protection diode There , which is connected in series to a parallel circuit, the at least one LED and the smoothing capacitor C2 includes.

It should be noted that a combination of the emission colors of the LED loads 91 - 94 is not limited to red, green, blue and white.

Embodiment 2

An example in which the pause interval is compiled as an interval in the lighting cycle Ts is in the embodiment 1 have been described. It becomes an example in which a pause interval comes immediately before and immediately after at least one power supply interval and the other power supply intervals are continuous 2 to be discribed.

Configuration of the LED lighting device and light

A configuration of the lamp 100 according to the embodiment 2 can be the same as in the 1 and 3 , However, control of the selection circuit differs 32 through the control circuit 33 , The present embodiment will be described focusing on the following difference.

The control circuit 33 controls the selection circuit 32 such that it determines a pause interval during which none of the LED loads are supplied with the current immediately before and immediately after at least one of the power supply intervals. In other words, the control circuit controls 33 the selection circuit 32 such that none of the power supply intervals corresponding to the LED loads is continuous and there are at least two pause intervals. For example, the previous at least one power supply interval may be a power supply interval of a white LED load. In other words, a pause interval may come immediately before and immediately after the white LED load power interval.

The LED loads 21 - 24 do not have to be four LED loads and can also be at least three LED loads.

Configuration of the LED lighting device and light

Next is an example of operation of the lamp 200 including the LED lighting device 30 according to the embodiment 2 to be discribed.

5 is a diagram showing a current waveform of the lamp 100 including the LED lighting device 30 according to the embodiment 2 shows. The drawing differs of 2 in that the pause interval Tx immediately before and immediately after the power supply interval td the color δ comes. The present embodiment will be described focusing on the following difference.

In 5 are the three power supply intervals Ta . Tb and tc the color α , the color β and the color γ continuous and is the power supply interval td the color δ not consistent with other power supply intervals. The break intervals Tx and Ty come immediately before and immediately after the power supply interval td the color δ ,

The color δ can be white. It is believed that the color δ in 5 causes flickering of color more easily than the other colors, but the feeling that something is wrong that is perceived by humans is weaker compared to when other primary colors appear broken, even if the white appears broken.

With the LED lighting device 30 according to the embodiment 2 are the LED loads 21 - 24 at least three LED loads; and controls the control circuit 33 the selection circuit 32 such that a pause interval during which none of the LED loads is supplied with power comes immediately before and immediately after at least one of the power supply intervals.

This configuration also enables the color flicker to be reduced because the power supply intervals are continuous.

At least one of the LED loads corresponding to the at least one of the power supply intervals can be an LED load that emits white light.

This makes it possible to make the color flicker more difficult to occur even if a pause interval comes immediately before and immediately after the power supply interval corresponding to the white color because the feeling that something is wrong is weaker than that due to the color flicker other primary colors, even if white light appears broken through on a fast moving object.

It should be noted that the pause interval Tx can have the same duration as the pause interval Ty or can have a different duration.

Embodiment 3

An example in which the pause interval is compiled as an interval in the lighting cycle Ts is in the embodiment 1 have been described. An example in which each power supply interval is continuous with at least one other power supply interval and at least two pause intervals are arranged in the embodiment 3 to be discribed.

Configuration of the LED lighting device and light

A configuration of the lamp 100 according to the embodiment 3 can be the same as in 1 and 3 , However, control of the selection circuit differs 32 through the control circuit 33 , The present invention will be described focusing on the following difference.

The light source 20 includes N LED loads. N = N1 + N2, where N an integer of at least 4 is N1 an integer of at least 2 is and N2 is an integer of at least 2. 1 and 3 show an example of N = 4.

The control circuit 33 controls the selection circuit 32 to realize the following items (a) to (d). (A) N1 Power supply intervals accordingly N1 LED loads are continuous. (B) N2 Power supply intervals accordingly N2 LED loads are continuous. (c) A pause interval during which none of the LED loads is powered occurs immediately before and immediately after the N1 Power intervals that the N1 LED loads correspond and are continuous. (d) A pause interval occurs immediately before and immediately after the N2 Power intervals that the N2 LED loads correspond and are continuous.

Configuration of the LED lighting device and light

Next is an example of operation of the lamp 300 including the LED lighting device 30 according to the embodiment 3 described.

6 is a diagram showing a current waveform of the lamp 100 including the LED lighting device 30 according to the embodiment 3 shows. The drawing shows a case where N = 4, N1 = 2 and N2 = 2. The drawing differs from 2 mainly in that the pause interval Tx between the power interval Tb the color β and the power supply interval Tc the color y is arranged. The present invention will be described focusing on the following difference.

In 6 are (a) N1 Power supply intervals Ta and Tb accordingly N1 LED loads 21 and 22 continuous. (B) N2 Power intervals tc and td corresponding N2 LED loads 23 and 24 are continuous. (c) The interval between breaks Ty and Tx , during which none of the LED loads are supplied with power, come immediately before and immediately after the N1 Power intervals Ta and Tb who the N1 LED loads 21 and 22 correspond and are continuous. (d) The interval between breaks Tx and Ty occur immediately before and immediately after N2 Power intervals tc and td who the N2 LED loads 23 and 24 correspond and are continuous.

In the example of 6 break the color α and the color β with a fast moving object because of the power supply intervals Ta and Tb are continuous. The color y and the color δ do not easily break through on a fast moving object because of the power supply intervals tc and td are continuous. A mix of colors α and the color β and a mix of colors y and the color δ can break through because of the interval Tx between power supply intervals Tb and tc is arranged, however, break the color β and the color γ not easy through.

With the LED lighting device 30 according to the embodiment 3 are the LED loads 21 - 24 N LED loads, where N is an integer of at least 3 is; and if N = N1 + N2, where N an integer of at least 4 is N1 an integer of at least 2 is and N2 an integer of at least 2 controls the control circuit 33 the selection circuit 32 such that (i) N1 Power supply intervals accordingly N1 LED loads are continuous, (ii) N2 Power supply intervals accordingly N2 LED loads are continuous, (iii) a pause interval during which none of the multiple LED loads are powered immediately before and immediately after N1 Power supply intervals that the N1 LED loads correspond and are continuous, and (iv) a pause interval immediately before and immediately after the N2 Power supply intervals that the N2 LED loads correspond and are continuous.

This enables color flicker to be reduced even if none of the power supply intervals is continuous.

Embodiment 4

An example in which a duration of the lighting cycle using the timer 36 is measured in the embodiment 4 described.

Configuration of the LED lighting device and light

A configuration of the lamp 100 according to the embodiment 4 can be the same as in 3 , The control circuit 33 however, includes a microcontroller unit or microcomputer unit (MCU) with a processor, memory and timer 36 that are built in. The timer 36 is used to measure the duration of the cycle during which the LED loads 21 - 24 can be selected sequentially in sequence.

Configuration of the LED lighting device and light

Next is an example of operation of the lamp 100 including the LED lighting device 30 according to the embodiment 4 described.

7 is a diagram showing a current waveform of the lamp 100 including the LED lighting device 30 according to the embodiment 4 shows. The drawing is an example of the same lighting process as in 2 , the lighting cycle by the timer 36 is set. As in the lower part of 7 is illustrated is the timer 36 programmed to output a signal that times out each time the lighting cycle Ts has elapsed. The control circuit 33 controls the selection circuit 32 such that the LED loads 21 - 24 light up sequentially whenever a timeout occurs.

With the LED lighting device 30 according to the embodiment 4 can the control circuit 33 include a microcomputer that runs the timer 36 and a duration of the cycle during which the LED loads are sequentially selected using the timer 36 measure up.

This enables the control circuit 33 , the selection circuit 32 Cyclic and easy to control to flexibly and easily set the lighting cycle.

It should be noted that the timer 36 also the power supply intervals Ta - td and the pause interval Tx and not just the lighting cycle ts can measure. The timer 36 may include one timer circuit and may also include multiple timer circuits.

Embodiment 5

Examples of the lamp 100 including the LED lighting device 30 according to each of the previous embodiments are in the embodiment 5 with reference to 8A to 8C described.

8A is a diagram showing an outdoor example of the lamp 100 including the LED lighting device 30 according to each of the embodiments. 8A shows an outer area of a ceiling spotlight 100a as an example of the lamp 100 ,

The ceiling spotlight 100a includes a circuit box 101 , a light body 102 and wiring 103a , In the circuit box 101 is the entire LED lighting device 30 or a part thereof according to any of the previous embodiments. The light body 102 is with the light source 20 fitted. The wiring 103a connects the circuit box 101 and the light source 20 within the light body 102 electric.

8B is a diagram showing another outdoor example of the lamp 100 including the LED lighting device 30 according to each of the embodiments. 8B shows an outer area of a ceiling spotlight 100b as an example of the lamp 100 , The ceiling spotlight 100b contains the circuit box 101b , the light body 102b and the wiring 103b , The circuit box 101b , the light body 102b and the wiring 103b are similar to the circuit box 101 , the light body 102 and the wiring 103a in 8A ,

8C is a diagram showing yet another outdoor example of the lamp 100 including the LED lighting device 30 according to each of the embodiments. 8C shows an outer area of a ceiling spotlight 100c as an example of the lamp 100 , The ceiling spotlight 100c contains the circuit box 101c and the light body 102c , These are also similar to the control box 101 and the light body 102 in 8A ,

The same results are obtained as in each of the previous embodiments in the embodiment 5 achieved.

It should be noted that the LEDs d1 - d12 inside the light source 20 are not only so-called LEDs, but also solid-state light emission elements, e.g. B. organic light emitting diodes (OLEDs) or laser LEDs.

An LED lighting device according to one or more aspects in the present disclosure has been described above based on the embodiments, but the present disclosure is not limited to the previous. Shapes obtained by various combinations of the components in the various embodiments that can be designed by a person skilled in the art that are within the scope of the essence of the present disclosure may also be included in the scope of the one or more aspects of the present disclosure ,

While the foregoing has described one or more embodiments and / or other examples, it should be understood that various modifications can be made in this regard, and that the subject matter disclosed herein can be implemented in various forms and examples, and that they can be used in numerous applications, only a few of which have been described herein. The following claims are intended to claim all modifications and variations that come within the true scope of the present teachings.

LIST OF REFERENCE NUMBERS

21, 22, 23, 24

LED load

30

LED lighting device

31

Power supply circuit

32

select circuit

33

control circuit

36

timer

100

lamp

C2, C3, C4,

C5 smoothing capacitor

d1-d12

LED

Da, Db, Dc,

DdDiode

L1

Kitchen sink

M3, M4, M5,

M6 switching element

Claims (12)

Light-emitting diodes (LED) - lighting device that causes a plurality of LED loads, each having a different emission color, to emit light, the LED lighting device comprising: a power supply circuit that powers the plurality of LED loads; a selection circuit that causes the power supply circuit to power the plurality of LED loads by sequentially and cyclically selecting the plurality of LED loads; and a control circuit that controls a selection made by the selection circuit such that at least two power supply intervals during which the power supply circuit powers each of the plurality of LED loads from a plurality of power supply intervals in a cycle during which the plurality of LED lights Loads are selected sequentially in sequence, are continuous. LED lighting device after Claim 1 , wherein the plurality of LED loads are at least three LED loads, and the control circuit controls the selection circuit in such a way that a pause interval during which none of the plurality of LED loads is supplied with power occurs immediately before and immediately after at least one of the plurality of power supply intervals , LED lighting device after Claim 2 wherein at least one of the plurality of LED loads corresponding to the at least one of the plurality of power supply intervals is an LED load that emits white light. LED lighting device after Claim 1 , wherein the plurality of LED loads are N LED loads, and when N = N1 + N2, where N is an integer of at least 4, N1 is an integer of at least 2 and N2 is an integer of at least 2, the Control circuit controls the selection circuit so that: N1 power supply intervals corresponding to N1 LED loads are continuous; N2 power supply intervals are continuous according to N2 LED loads; a pause interval during which none of the plurality of LED loads is powered immediately before and immediately after the N1 power supply intervals that correspond to the N1 LED loads and are continuous; and a pause interval comes immediately before and immediately after the N2 power supply intervals that correspond to the N2 LED loads and are continuous. LED lighting device after Claim 1 , wherein the plurality of LED loads are N LED loads, where N is an integer of at least 3, and the control circuit controls the selection circuit so that: N power supply intervals corresponding to N LED loads are continuous; and a pause interval during which none of the plurality of LED loads is powered comes immediately before and immediately after the N power supply intervals, which are continuous. LED lighting device according to one of the Claims 1 to 5 wherein the control circuit includes a microcomputer having a timer and measures a duration of the cycle during which the plurality of LED loads are sequentially selected using the timer. LED lighting device according to one of the Claims 1 to 6 , wherein a frequency that is an inverse of the cycle during which the plurality of LED loads are sequentially selected is at least 100 Hz. LED lighting device according to one of the Claims 1 to 7 , wherein the power supply circuit is a switching power supply that includes a coil and supplies the plurality of LED loads with power via the coil. LED lighting device according to one of the Claims 1 to 8th , wherein the selection circuit includes a plurality of switching elements, the plurality of switching elements each connected in series with a corresponding one of the plurality of LED loads, and the control circuit sequentially and cyclically selects the corresponding one of the plurality of LED loads by sequentially and cyclically switching on one of the plurality of switching elements. LED lighting device after Claim 9 , the cycle during which the plurality of LED loads are sequentially selected in succession is fixed regardless of a dimming rate. Luminaire comprising: the LED lighting device according to one of the Claims 1 to 10 ; and the multiple LED loads. Afterglow Claim 11 wherein the multiple LED loads each include: at least one LED; a smoothing capacitor connected in parallel with the at least one LED; and a reverse current protection diode connected in series with a parallel circuit that the contains at least one LED and the smoothing capacitor.

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