This application is based on Japanese Patent Application No. 2013-204639 filed on Sep. 30, 2013, the contents of which are hereby incorporated by reference.
1. Field of the Invention
The present invention relates to an LED (light emitting diode) power supply device equipped with a dimming function.
2. Description of Related Art
In recent years, LED power supply devices have been required not only to be energy saving but also to be capable of producing stylish illumination, and advanced dimming systems have been attracting increasing attention. It is easy to differentiate a good dimming function from a bad one, and thus, to make a product more attractive to consumers, it is necessary to achieve high-level dimming control.
As examples of the conventional technology related to the foregoing, JP-A-2011-108668 and JP-A-2011-187205 can be cited.
However, a minimum value of a dimming ratio (=a rate of a target output current to a maximum output current) that can be set by means of conventional LED power supply devices is about 5%. Thus, in comparison of dimming between an LED lighting apparatus and an incandescent light bulb, the LED lighting apparatus has a problem that it goes out more steeply than the incandescent light bulb when fully turned off, and dimming of the LED lighting apparatus is not smooth (see
Moreover, LED power supply devices have been required to have a high efficiency (for example, 80% or higher), a high power factor (for example, 0.9 or higher [AC 100-200 V]), and an increased maximum output current value (for example, 1050 mA), and to acquire the PSE (product safety electrical appliance and materials) mark, for example.
In view of the above described problems found by the inventor of the present application, an object of the invention disclosed in the present specification is to provide an LED power supply device capable of performing fine dimming control.
To achieve the above object, an LED power supply device disclosed herein includes a DC dimmer circuit that performs dimming control of an LED such that the higher a reference voltage variably controlled according to a dimming signal is, the smaller an output current flowing in the LED is.
Other features, components, steps, advantages, and characteristics of the present invention will be disclosed in the following detailed description of the best mode for carrying out the present invention and relevant attached drawings.
<Selection of Power Supply System>
In the one-converter method (see an upper section of the figure), a power factor improvement circuit, a constant current circuit, and a dimming function portion are all provided together in the primary circuit system 1p. Merits of the one-converter method include its high power supply efficiency and its low cost (a simple circuit configuration). On the other hand, demerits of the one-converter method include that dimming is difficult therewith.
In the two-converter method (see a lower section of the figure), the power factor improvement circuit is provided in the primary circuit system 1p, and the constant current circuit and the dimming function portion are provided in the secondary circuit system 1s. Merits of the two-converter method include that dimming is easy therewith. On the other hand, demerits of the one-converter method include its low power supply efficiency and its high cost (a complicated circuit configuration).
In view of these facts, it can be said that, for highly efficient dimming, the one-converter method should be selected to be adopted in the power supply system of the LED power supply device 1.
<Selection of Dimming Method>
In the burst dimming (see a lower section in the figure), by periodically turning on/off an LED current having a constant current value to increase/decrease a time average of the LED current, and thereby the dimming of the LED 2 is performed. That is, when an on-duty (rate of ON time in a cycle) of the LED current is large, the LED 2 becomes bright, and when the on-duty of the LED current is small, the LED 2 becomes dim. Merits of the burst dimming include that it makes fine dimming control easy. On the other hand, demerits of the burst dimming include that it generates a stroboscopic effect and noise, and existence of the PSE standard.
In view of these facts, it can be said that, for higher versatility, as the dimming method for LED power supply devices, it is desirable to select the DC dimming which has fewer demerits.
<LED Power Supply Device>
In the one-converter LED power supply device 1, the driver IC 12 and the microcomputer 13 are both provided in the primary circuit system 1p, and the current monitor 11 alone is provided in the secondary circuit system 1s.
As shown in a lower section of the figure, it is also possible to use a microcomputer 14 where the driver IC 12 and the microcomputer 13 are integrated to achieve integrated digital control of power supply and dimming. Adoption of these configurations makes it possible not only to enhance ability to respond to users' needs regarding the power supply specifications but also to reduce the number of components and cost.
<Current Monitor (First Configuration Example)>
On receiving the input of the feedback signal FB, the driver IC 12 (not shown in
Here, in the DC dimmer circuit 10 using the current monitor 11 of the first configuration example, dimming is performed by means of voltage control, and the output current Io becomes smaller according as the reference voltage V+ is lowered. However, a lower reference voltage V+ invites increased liability to be influenced by noise, and this makes it difficult to set the dimming ratio to a small value (see
For example, when VREF=1.2V, R1=1 kΩ, and RDIM=1 kΩ (max), if RDIM is reduced to 1% (=10Ω), the reference voltage V+ falls to 12 mV and becomes more liable to be influenced by noise, and accordingly, flickers occur in the LED 2. Thus, it can be said that, with the DC dimmer circuit 10 using the current monitor 11 of the first configuration example, it is difficult to perform fine dimming control.
<Current Monitor (Second Configuration Example)>
An anode of a photo diode that forms the photo coupler PC1 is connected to an output terminal of the buffer BUF. A cathode of the photo diode is connected to a ground terminal. A collector of a photo-transistor that forms the photo coupler PC1 is connected via the resistor R6 to a second internal power supply terminal (=VREF2). An emitter of the photo-transistor is connected to an anode of the diode D2, a first terminal of the resistor R5, and to a first terminal of the capacitor C1. Second terminals of the resistor R5 and the capacitor C1 are both connected to the ground terminal.
The photo coupler PC1 performs current output in accordance with the dimming signal DIM input thereto from the microcomputer 13 via the buffer BUF. The capacitor C1 smooths the current output form the photo coupler PC1 to generate a dimming current IDIM. That is, in the current monitor 11 of the present configuration example, the photo coupler PC1, the capacitor C1, and the resistors R5 and R6 function as a current DAC (digital to analog converter) that converts the dimming signal DIM which is PWM driven into the dimming current IDIM which is an analog current.
The sense resistor Rs is provided on a path through which the output current Io flows. The resistors R1 and R2 are connected in series between a first internal power supply terminal (=VREF1) and a low-potential terminal (=−Io×Rs) of the sense resistor Rs, and a current I1 flows through the resistors R1 an R2 via the path. As a result, at a connection node between the resistors R1 and R2, there appears a detection voltage Vs (=I1×R2−Io×Rs) in accordance with the output current Io. That is, in the current monitor 11 of the present configuration example, the sense resistor Rs and the resistors R1 and R2 function as a detection voltage generation portion that generates the detection voltage Vs according to the output current Io. Here, the smaller the output current Io is, the higher a voltage value of the detection voltage Vs becomes, and the larger the output current Io is, the lower the voltage value of the detection voltage Vs becomes.
The resistors R3 and R4 are connected in series between the first internal power supply terminal and a high-potential terminal (=GND) of the sense resistor Rs, and a current I2 flows in the resistors R3 an R4 via the path. Moreover, the connection node between the resistor R3 and the resistor R4 is connected also to a cathode of the diode D2 (corresponding to an output terminal of the current DAC), and, in the resistor R4, there flows a sum current (=I2+IDIM) that is obtained by adding the current I2 to the dimming current IDIM. As a result, at the connection node between the resistor R3 and the resistor R4, there appears a reference voltage V+ (=(I2+IDIM)×R4) in accordance with the dimming current IDIM. That is, in the current monitor 11 of the present configuration example, the resistors R3 and R4 function as a reference voltage generation portion that generates the reference voltage V+ according to the dimming current IDIM.
As in the above-described first configuration example, the operational amplifier AMP amplifies a difference between the reference voltage V+ applied to its non-inverting input terminal (+) and the detection voltage Vs applied to its inverting input terminal (−) to generate a feedback signal FB.
Furthermore, as in the above-described first configuration example, on receiving input of the feedback signal FB, the driver IC 12 (not shown in
An important point here is that the dimming control of the LED 2 is performed not such that the lower the reference voltage V+ variably controlled according to the dimming signal DIM is, the smaller the output current Io becomes, but such that the higher the reference voltage V+ is, the smaller the output current Io becomes.
Thus, in the DC dimmer circuit 10 using the current monitor 11 of the second configuration example, dimming is performed by means of current control using the photo coupler PC1, and the output current Io becomes smaller according as the reference voltage V+ is raised. Consequently, even when the dimming ratio is set small, the reference voltage V+ becomes less liable to be influenced by noise (see
<Software Trimming>
Where the current monitor 11 of the second configuration example is used, there may be a trade-off such that it is possible to achieve a dimming ratio of 0.1%, but on the other hand, due to the introduction of the buffer BUF and the photo coupler PC1, the dimming signal ratio (duty value) when the output current Io is at a zero value varies from product to product (see
A first factor responsible for the trade-off is variation in a power supply voltage VDD supplied to the buffer BUF. If the power supply voltage VDD varies, the pulse peak value of the dimming signal DIM transmitted to the photo coupler PC1 from the buffer BUF varies and a forward current IF of the photo coupler PC1 also varies, and this in turn causes variation in the dimming current IDIM, and furthermore, the output current Io is caused to greatly vary in value. For example, if the power supply voltage VDD varies by 10 mV (0.3%), it causes the output current Io to vary by about 7 mA (see
Unfortunately, however, it is difficult to eliminate these factors by taking measures in terms of hardware. Thus, here, variation in dimming (±10%), which cannot be eliminated by taking measures in terms of hardware, is eliminated by software trimming by using the microcomputer 13.
In doing so, the microcomputer 13 detects, by using an initial version of the dimming table, a dimming signal ratio when the output current ratio is zero, and then corrects the dimming table TBL1 such that the detected value is equal to a target value (see
Through such software trimming, it is possible to match the dimming signal ratio when the output current Io is at a zero value to the target value (90%, for example) with respect to all products, and this makes it possible to significantly reduce the variation in dimming (±10%→±3%) (see
For example, when a plurality of LED light sources are turned on simultaneously, the LED light sources actually start to shine at different timings before the software trimming, and this makes them look awkward in comparison with incandescent light bulbs. On the other hand, after the software trimming, the timings at which the LED light sources start to shine are almost the same, and this allows the LED light sources to demonstrate a behavior similar to that of incandescent light bulbs. An LED lighting apparatus using these LED light sources are the most suitable as a substitute for a large number of incandescent light bulbs provided for stage effects in a large hall.
Adoption of the above configurations makes it possible to achieve dimming that is smoother than conventionally performed dimming and that is close to dimming performed with incandescent light bulbs (see
<Detailed Configuration>
Specifically, IC31 in
The dimming signal DIM output from an RC1 pin of IC101 (the microcomputer 13) is input to the photo coupler PC32. The feedback signal FB output from a PC pin of IC31 (the operational amplifier AMP) is input to an FB pin of IC81 (corresponding to the driver IC 12) via the photo coupler PC31. IC81 outputs a gate signal from its OUT pin according to the feedback signal FB, and thereby performs on/off control of an output switch Q1 connected to primary coils 34T and 35T of a transformer T1 (corresponding to the transformer TR1).
With this configuration, it is possible to eliminate variation in dimming resulting from variation in components of the diode D35.
In addition to the above embodiments, it is possible to add various modifications to the various technical features disclosed in the present specification without departing the spirit of the technological creation. In other words, it should be understood that the above embodiments are examples in all respects and are not limiting; the technological scope of the present invention is not indicated by the above description of the embodiments but by the claims; and all modifications within the scope of the claims and the meaning equivalent to the claims are covered.
The invention disclosed herein is applicable to, for example, lighting equipment for use in facilities where the dimming function is required for saving energy and lighting equipment for household use where sophisticated dimming is required.
Number | Date | Country | Kind |
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2013204639 | Sep 2013 | JP | national |
Number | Date | Country | |
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Parent | 14499972 | Sep 2014 | US |
Child | 15000340 | US |