The present invention relates to a light emitting diode (LED) lighting device for lighting a semiconductor light source composed of an LED element.
LED (Light Emitting Diode) elements as a semiconductor light source are widely used for a vehicle light, a traffic light, and an illumination light. In such purposes, since the light emission amount of a single LED element is small, it is general to light a plurality of LED elements simultaneously, to obtain a required light emission amount.
In a conventional LED lighting device, a converter is connected in series to an LED unit composed of one or a plurality of LED elements connected in series, and further, a single DC power supply is connected to both ends of an LED circuit block composed of the LED unit and the converter. The converter is composed of a switching element, a diode, and a reactor, and constant current control is performed for current flowing in the LED unit by turning on or off the switching element, thereby lighting the LED unit. In addition, a plurality of the LED circuit blocks are connected in parallel to the DC power supply, and the plurality of LED circuit blocks are operated by a single DC power supply (for example, Patent Document 1).
Patent Document 1: Japanese Laid-Open Patent Publication No. 2006-147184 (FIG. 1)
In the above conventional LED lighting device, the LED circuit blocks are operated by a single constant voltage source, and the anode side of the diode is connected to a reference potential of the constant voltage source. In this case, particularly, if the series connection number of LED elements composing the LED unit increases, LED voltage which is the sum of forward voltage drops of the LED elements becomes high, and required voltage for lighting the LED unit becomes high. As a result, withstand voltage of each switching element composing the converter becomes high, and further, ripple of reactor current (=LED current) also increases, thereby causing a problem that the circuit scale is enlarged and the cost increases.
The present invention has been made to solve the above problem, and an object of the present invention is to provide an LED lighting device with a small size and low cost that, even in the case where voltage for driving an LED unit is high, can decrease withstand voltage of each switching element composing a converter and decrease ripple of reactor current.
An LED lighting device according to the present invention includes: a first bus having first bus voltage; a second bus having second bus voltage lower than the first bus voltage; an LED circuit block composed of: a series connection body connected to the first bus and formed by a switching element, a reactor, and an LED unit having one or a plurality of LED elements connected in series; and a diode connected between the second bus and a connection point between the switching element and the reactor; and a control circuit for performing ON/OFF control for the switching element so that LED current flowing in the LED unit is within a rated current range. In the case where the LED unit is lit, voltage applied between both ends of series connection of the reactor and the LED unit becomes the first bus voltage, when the switching element is ON, and becomes voltage lower than the first bus voltage, that is determined based on the first bus voltage and the second bus voltage, when the switching element is OFF.
In the LED lighting device of the present invention, the first bus voltage and the second bus voltage are supplied to the LED circuit block, and in the case where the LED unit is lit, voltage applied between both ends of series connection of the reactor and the LED unit becomes the first bus voltage, when the switching element is ON, and becomes voltage lower than the first bus voltage, that is determined based on the first bus voltage and the second bus voltage, when the switching element is OFF. Therefore, a switching element having lower withstand voltage than in the conventional case can be used, and if tolerable ripple of LED current (=reactor current) is the same, the reactor can also be downsized, whereby downsizing and cost reduction of the LED lighting device can be realized.
Hereinafter, an LED lighting device according to embodiment 1 of the present invention will be described based on the drawings.
In
An LED circuit block 3a1 includes a switching element Qa1 such as FET (Field Effect Transistor), a reactor La1, an LED unit LEDa1 composed of one or a plurality of LED elements connected in series, and a diode Da1. In addition, n (n is a natural number equal to or greater than 1) number of LED circuit blocks having the same configuration as the LED circuit block 3a1, i.e., the LED circuit blocks 3a1 to 3an are connected in parallel, to the first bus 100 and the second bus 200.
Next, the detailed configuration of the LED circuit block 3a1 will be described. The first bus 100 of the constant voltage source 1 is connected to a first end of the switching element Qa1. On the other hand, a cathode terminal of the diode Da1 and a first end of the reactor La1 are connected to a second end of the switching element Qa1. An anode terminal of the diode Da1 is connected to the second bus 200. A second end of the reactor La1 is connected to an anode side terminal of the LED unit LEDa1 composed of one or a plurality of LED elements connected in series. A cathode side terminal of the LED unit LEDa1 is connected to a reference potential of the constant voltage source 1.
A control circuit 2 detects LED current ILED flowing in each LED unit (LEDa1 to LEDan), and performs ON/OFF control for each switching element (Qa1 to Qan) so that each LED current ILED is within a rated current range, thereby performing constant current control. Detection of LED current ILED can be realized by interposing a shunt resistor between each LED unit (LEDa1 to LEDan) and the reference potential and detecting voltage drop occurring in the shunt resistor when current flows, as disclosed in the above conventional technique, for example. It is noted that in
In addition, the control circuit 2 detects the first bus voltage V1 and the second bus voltage V2, and performs voltage control for the first bus voltage V1 and the second bus voltage V2 so as to satisfy a condition described later. It is noted that in
Next, with reference to
In addition, although not shown in
Next, concrete operation of the LED lighting device will be described in order.
The LED lighting device according to embodiment 1 of the present invention has a feature that the range of the first bus voltage V1, the second bus voltage V2, or the LED voltage VLED is set such that, when each LED unit (LEDa1 to LEDan) is lit, the first bus voltage V1, the second bus voltage V2, and the LED voltage VLED satisfy the following relationship.
V2<VLED_min and VLED_max<V1 (1)
By thus setting them, the LED lighting device operates as described below. It is noted that operations of the LED circuit blocks (3a1 to 3an) are basically the same, so the LED circuit block 3a1 will be described here as an example.
First, when the control circuit 2 turns on the gate signal for the switching element Qa1, the switching element Qa1 is turned on, so that energy is supplied from the constant voltage source 1 to the LED circuit block 3a1. At this time, both-end voltage Vsw of the switching element Qa1 becomes zero, and voltage of [V1−V2] is applied as reverse voltage between both ends of the diode Da1. In addition, voltage of [VLon=V1−VLED] is applied between both ends of the reactor La1, whereby LED current (=reactor current) gradually increases. Then, the LED voltage VLED is applied between both ends of the LED unit LEDa1, whereby the LED unit LEDa1 is lit. During a period in which the switching element Qa1 is ON, energy is stored in the reactor La1. The energy stored in the reactor La1 is used as energy for maintaining the LED current within the rated current range during a period in which the switching element Qa1 is off.
When the LED current has increased and reached the upper limit of the rated current, the control circuit 2 turns off the gate signal for the switching element Qa1, whereby the switching element Qa1 is turned off. As a result, the first bus voltage V1 is applied to the first end of the switching element Qa1, and meanwhile, as the diode Da1 is turned on, the second bus voltage V2 is applied to the second end side of the switching element Qa1. Therefore, the both-end voltage Vow of the switching element Qa1 becomes [VSW=V1−V2]. In addition, between both ends of the reactor La1, voltage of [VLoff=VLED−V2] is applied in a direction opposite to the previous direction. That is, between both ends of the reactor La1, voltage of [VL=VLon+VLoff=V1−V2] is applied in accordance with ON and OFF of the switching element Qa1. Then, LED current continues to flow in the LED unit LEDa1, and LED voltage VLED continues to be applied between both ends thereof, whereby the LED unit LEDa1 is lit.
As energy stored in the reactor La1 decreases, when the LED current has decreased and reached the lower limit of the rated current, the control circuit 2 turns on the gate signal for the switching element Qa1 again, thereby turning on the switching element Qa1. Hereafter, the series of operations described above is repeated, so that LED voltage VLED is always applied between both ends of the LED unit LEDa1 and LED current within the rated current range continues to flow, whereby lighting of the LED unit LEDa1 is maintained. The other LED circuit blocks also perform the same operation.
Next, the operation effect of the LED lighting device according to embodiment 1 will be described in comparison with an LED lighting device of a reference example shown in
The configuration of the LED lighting device of the reference example is different from the LED lighting device according to embodiment 1 in the following two points. The first point is that a constant voltage source 4 of the LED lighting device of the reference example outputs only one kind of voltage, i.e., the first bus voltage V1, and the second point is that anode terminals of diodes (Db1 to Dbn) of the LED lighting device of the reference example are connected to a reference potential of the constant voltage source 4. A control circuit 5 detects LED current flowing in an LED unit LEDb1 and performs ON/OFF control for a switching element Qb1 so that the LED current is within a rated current range, thereby performing constant current control. In such an LED lighting device of the reference example, when the above-described constant current control is performed and thereby each LED unit (LEDb1 to LEDbn) is lit, both-end voltage of each LED unit (LEDb1 to LEDbn) becomes LED voltage VLED, and this is the same as in embodiment 1, but the first bus voltage V1 is applied between both ends of each switching element (Qb1 to Qbn) and between both ends of each reactor (Lb1 to Lbn).
On the other hand, as described above, the LED lighting device according to embodiment 1 of the present invention can reduce both-end voltages of the switching elements (Qa1 to Qan) and the reactors (La1 to Lan) by the amount due to the second bus voltage V2, as compared to the case of the LED lighting device of the reference example.
As described above, the LED lighting device according to embodiment 1 of the present invention sets the range of the first bus voltage V1, second bus voltage V2, or the LED voltage VLED such that, when each LED unit (LEDa1 to LEDan) is lit, the first bus voltage V1, the second bus voltage V2, and the LED voltage VLED satisfy the following relationship.
V2<VLED_min and VLED_max<V1 (1)
Thus, it becomes possible to reduce voltages applied to the switching element and the reactor, as compared to the case of conventional LED lighting devices including the reference example. Therefore, a switching element having lower withstand voltage than those in conventional devices including the reference example can be used, and if tolerable ripple of LED current (=reactor current) is the same, the reactor can also be downsized, whereby an LED lighting device with a small size and low cost can be provided.
In addition, in the LED lighting device according to embodiment 1 of the present invention, in the case of extinguishing the LED units (LEDa1 to LEDan), the switching elements (Qa1 to Qan) may be turned off, and further, the second bus voltage V2 may be set as V2≦VLED_f.
Further, in ON/OFF control for the switching elements (Qa1 to Qan) by the control circuit 2, as described above, an upper limit and a lower limit may be set for the LED current, and each switching element (Qa1 to Qan) may be turned on or off every time the LED current reaches the upper limit or the lower limit, or instead, the duty (=ON time/ON-OFF period) of each switching element (Qa1 to Qan) may be controlled so that the average value of the LED current becomes predetermined current. In addition, for each LED unit (LEDa1 to LEDan), a capacitor may be interposed in parallel, whereby ripple of current flowing in each LED unit (LEDa1 to LEDan) may be reduced.
Next, an LED lighting device according to embodiment 2 of the present invention will be described based on the drawings.
In the circuit configuration of the LED lighting device in
First, as in embodiment 1, the constant voltage source 1 outputs DC voltage that is first bus voltage V1 through the first bus 100, and outputs DC voltage that is second bus voltage V2 through the second bus voltage 200, thereby supplying required voltage for lighting an LED element. It is noted that a relationship of first bus voltage V1>second bus voltage V2>0 is satisfied. The first bus 100 is connected to an anode side terminal of an LED unit LEDc1. In addition, a cathode side terminal of the LED unit LEDc1 is connected to a first end of a reactor Lc1, and a second end of the reactor Lc1 is connected to a first end of a switching element Qc1. Further, a second end of the switching element Qc1 is connected to the reference potential of the constant voltage source 1. In addition, an anode terminal of the diode Dc1 is connected to a connection point between the reactor Lc1 and the switching element Qc1, and a cathode terminal of the diode Dc1 is connected to the second bus 200. The second bus 200 allows suck of current.
A control circuit 6 detects LED current ILED flowing in each LED unit (LEDc1 to LEDcn) and performs ON/OFF control for each switching element (Qc1 to Qcn) so that each LED current ILED is within a rated current range, thereby performing constant current control. Detection of LED current is performed on the anode side or the cathode side of each LED unit (LEDc1 to LEDcn), and for example, an amplifier or the like adapted for current detection on the high-voltage side can be used. It is noted that in
In addition, the control circuit 2 detects the first bus voltage V1 and the second bus voltage V2, and performs voltage control for the first bus voltage V1 and the second bus voltage V2 so as to satisfy a condition described later. It is noted that in
Next, with reference to
The LED lighting device according to embodiment 2 of the present invention has a feature that the range of the first bus voltage V1, the second bus voltage V2, or the LED voltage VLED is set such that, when each LED unit (LEDc1 to LEDcn) is lit, the first bus voltage V1, the second bus voltage V2, and the above-described LED voltage VLED satisfy the following relationship.
V1−V2<VLED_min and VLED_max<V1 (2)
By thus setting them, the LED lighting device operates as described below. It is noted that operations of the LED circuit blocks (3c1 to 3cn) are basically the same, so the LED circuit block 3c1 will be described here as an example.
First, when the control circuit 6 turns on the gate signal for the switching element Qc1, the switching element Qc1 is turned on, so that energy is supplied from the constant voltage source 1 to the LED circuit block 3c1. At this time, both-end voltage Vsw of the switching element Qc1 becomes zero, and the second bus voltage V2 is applied as reverse voltage between both ends of the diode Dc1. In addition, voltage of [VLon=V1−VLED] is applied between both ends of the reactor Lc1, whereby LED current (=reactor current) gradually increases. Then, the LED voltage VLED is applied to the LED unit LEDc1, whereby the LED unit LEDc1 is lit. During a period in which the switching element Qc1 is ON, energy is stored in the reactor Lc1. The energy stored in the reactor Lc1 is used as an energy source for maintaining the LED current within the rated current range during a period in which the switching element Qc1 is off.
When the LED current has increased and reached the upper limit of the rated current, the control circuit 6 turns off the gate signal for the switching element Qc1, whereby the switching element Qc1 is turned off. As a result, the both-end voltage Vsw of the switching element Qc1 becomes the second bus voltage V2. In addition, between both ends of the reactor Lc1, voltage of [VLoff=VLED−(V1−V2)] is applied in a direction opposite to the previous direction. That is, between both ends of the reactor Lc1, voltage of [VL=VLon+VLoff=V2] is applied in accordance with ON and OFF of the switching element Qc1. Then, LED current continues to flow in the LED unit LEDc1, and LED voltage VLED continues to be applied between both ends thereof, whereby the LED unit LEDc1 is lit. Further, a current route at this time is as shown by a broken-line arrow P, and energy is regenerated to the constant voltage source 1.
As energy stored in the reactor Lc1 decreases, when the LED current has decreased and reached the lower limit of the rated current, the control circuit 6 turns on the gate signal for the switching element Qc1 again, thereby turning on the switching element Qc1. Hereafter, the series of operations described above is repeated, so that LED voltage VLED is always applied between both ends of the LED unit LEDc1 and LED current within the rated current range continues to flow, whereby lighting of the LED unit LEDc1 is maintained. The other LED circuit blocks also perform the same operation.
As described above, the LED lighting device according to embodiment 2 of the present invention sets the range of the first bus voltage V1, second bus voltage V2, or the LED voltage VLED such that, when each LED unit (LEDc1 to LEDcn) is lit, the first bus voltage V1, the second bus voltage V2, and the LED voltage VLED satisfy the following relationship.
V1−V2<VLED_min and VLED_max<V1 (2)
Thus, it becomes possible to reduce voltages applied to the switching element and the reactor to the second bus voltage V2 (<V1), as compared to the case of the LED lighting device of the reference example described in
In addition, in the LED lighting device according to embodiment 2, in the case of extinguishing the LED units (LEDc1 to LEDcn), the switching elements (Qc1 to Qcn) may be turned off, and further, the first bus voltage V1 or the second bus voltage V2 may be set so as to satisfy [V1−V2≦VLED_f].
Further, in control for the switching elements (Qc1 to Qcn) by the control circuit 6, as described above, an upper limit and a lower limit may be set for the LED current, and each switching element (Qc1 to Qcn) may be turned on or off every time the LED current reaches the upper limit or the lower limit, or instead, the duty (=ON time/ON-OFF period) of each switching element (Qc1 to Qcn) may be controlled so that the average value of the LED current becomes predetermined current. In addition, for each LED unit (LEDc1 to LEDcn), a capacitor may be interposed in parallel, whereby ripple of current flowing in each LED unit (LEDc1 to LEDcn) may be reduced.
Next, an LED lighting device according to embodiment 3 of the present invention will be described based on the drawings.
The LED lighting device according to embodiment 3 assumes use in a vehicle, and is composed of a constant voltage source 7, the LED circuit blocks (3a1 to 3an) described in embodiment 1, and a control circuit 11. The basic configurations of these components are the same as in the LED lighting device according to embodiment 1, and the constant voltage source 7 corresponds to the constant voltage source 1 of embodiment 1 with its configuration specified. In addition, the control circuit 11 is obtained by adding a function of controlling converters composing the constant voltage source 7 to the function of the control circuit 2 of embodiment 1. Therefore, the voltage conditions for lighting and extinguishing each LED unit (LEDa1 to LEDan) of the LED lighting device according to embodiment 3, and a waveform at each section during operation thereof are the same as in the LED lighting device according to embodiment 1. Therefore, the description of their operations is omitted, and the configuration of the constant voltage source 7 and the function of the control circuit 11 will be described.
Since the LED lighting device according to embodiment 3 of the present invention assumes use in a vehicle, it is necessary to generate, from battery voltage VB outputted from a battery 8, the first bus voltage V1 and the second bus voltage V2 having the following voltage relationship described in the LED lighting device of embodiment 1.
V2<VLED_min and VLED_max<V1 (1)
Here, if the series connection number of LED elements composing each LED unit (LEDa1 to LEDan) is large and [battery voltage VB<LED voltage VLED_max] is satisfied, each LED unit (LEDa1 to LEDan) cannot be lit. Therefore, a first converter 10 is provided on the output side of the battery 8, thereby stepping up the battery voltage VB and providing the first bus voltage V1 that is higher than VLED_max. In the case where the battery voltage VB is higher than the LED voltage VLED_max, the first converter 10 may perform step-down operation or the first converter 10 itself may be omitted. In addition, the second bus voltage V2 is generated by a second converter 9 provided between the anode terminals of the diodes (Da1 to Dan) and an output terminal of the battery 8. Here, the second converter 9 receives an input from the battery voltage VB side and allows flow-out of current to the second bus 200 side.
The control circuit 11 detects voltages of the first bus voltage V1 and the second bus voltage V2, and controls the first converter 10 and the second converter 9 so that these voltages satisfy the voltage condition of embodiment 1. It is noted that in
As described above, according to embodiment 3 of the present invention, the constant voltage source has the battery, the first converter, and the second converter, and the control circuit performs control so that output of the first converter becomes the first bus voltage V1 and output of the second converter becomes the second bus voltage V2. Therefore, particularly, for use in a vehicle, the same effect as in the LED lighting device of embodiment 1 can be obtained.
Next, an LED lighting device according to embodiment 4 of the present invention will be described based on the drawings.
The LED lighting device according to embodiment 4 assumes use in a vehicle, and is composed of the constant voltage source 7, the LED circuit blocks (3c1 to 3cn) described in embodiment 2, and a control circuit 12. The basic configurations of these components are the same as in the LED lighting device according to embodiment 2, and the constant voltage source 7 corresponds to the constant voltage source 1 of embodiment 2 with its configuration specified. In addition, the control circuit 12 is obtained by adding a function of controlling converters composing the constant voltage source 7 to the function of the control circuit 6 of embodiment 2. Therefore, the voltage conditions for lighting and extinguishing each LED unit (LEDc1 to LEDcn) of the LED lighting device according to embodiment 4, and a waveform at each section during operation thereof are the same as in the LED lighting device according to embodiment 2. Therefore, the description of their operations is omitted, and the functions of the constant voltage source 7 and the control circuit 12 will be described.
Since the LED lighting device according to embodiment 4 of the present invention assumes use in a vehicle, it is necessary to generate, from battery voltage VB outputted from the battery 8, the first bus voltage V1 and the second bus voltage V2 having the following voltage relationship described in the LED lighting device of embodiment 2.
V1−V2<VLED_min and VLED_max<V1 (2)
Here, if the series connection number of LED elements composing each LED unit (LEDc1 to LEDcn) is large and [battery voltage VB<LED voltage VLED_max] is satisfied, each LED unit (LEDc1 to LEDcn) cannot be lit. Therefore, the first converter 10 is provided on the output side of the battery 8, thereby stepping up the battery voltage VB and providing the first bus voltage V1 that is higher than VLED_max. In the case where the battery voltage VB is higher than the LED voltage VLED_max, the first converter 10 may perform step-down operation or the first converter 10 itself may be omitted. In addition, the second bus voltage V2 is generated by the second converter 9 provided between the cathode terminals of the diodes (Dc1 to Dcn) and the output terminal of the battery 8. Here, the second converter 9 receives an input from the second bus 200 side and outputs the battery voltage VB, and allows suck of current from the second bus 200 side.
As described above, the LED lighting device according to embodiment 4 of the present invention includes, as the constant voltage source, the battery, the first converter, and the second converter which are connected to the output terminal of the battery. And the control circuit performs control so that output of the first converter becomes the first bus voltage V1 and output of the second converter becomes the second bus voltage V2. Therefore, particularly, for use in a vehicle, the same effect as in the LED lighting device of embodiment 2 can be obtained.
Next, an LED lighting device according to embodiment 5 of the present invention will be described based on the drawings.
In the LED lighting device according to embodiment 5 of the present invention, since the second bus voltage V2 is fixed at the battery voltage VB, the effect of reducing withstand voltages of composing elements, obtained in this case is not as large as in the LED lighting device of embodiment 3. However, since the second converter 9 is removed and the function of controlling the second converter 9 is removed from the control circuit 14, circuitry downsizing and simplification of the control circuit can be realized more than in embodiment 3.
Next, an LED lighting device according to embodiment 6 of the present invention will be described based on the drawings.
In the LED lighting device according to embodiment 6 of the present invention, since the second bus voltage V2 is fixed at the battery voltage VB, the effect of reducing withstand voltages of composing elements, obtained in this case is not as large as in the LED lighting device of embodiment 4. However, since the second converter 9 is removed and the function of controlling the second converter 9 is removed from the control circuit 14, circuitry downsizing and simplification of the control circuit can be realized more than in embodiment 4.
Next, an LED lighting device according to embodiment 7 of the present invention will be described based on the drawings.
V2<VLED<V1 (3)
The same applies also in the case where only one LED circuit block 3c1 is provided in the LED lighting device of embodiment 2 shown in
V1−V2<VLED<V1 (3)
The same applies also in the other embodiments 3 to 6.
It is noted that, within the scope of the present invention, the above embodiments may be freely combined with each other, or each of the above embodiments may be modified or abbreviated as appropriate.
Number | Date | Country | Kind |
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2012-060082 | Mar 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/050238 | 1/9/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/136823 | 9/19/2013 | WO | A |
Number | Name | Date | Kind |
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20100264836 | Godbole | Oct 2010 | A1 |
20100283397 | Chen | Nov 2010 | A1 |
20110062889 | Hoogzaad | Mar 2011 | A1 |
20120032613 | Liu et al. | Feb 2012 | A1 |
20130015774 | Briggs | Jan 2013 | A1 |
20130026933 | Gao | Jan 2013 | A1 |
Number | Date | Country |
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2006-147184 | Jun 2006 | JP |
2012-004054 | Jan 2012 | JP |
2011152480 | Dec 2011 | WO |
Entry |
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Combined Office Action and Search Report issued on Jun. 1, 2015 in Chinese Patent Application No. 201380014511.2 with partial English translation and English translation of category of documents. |
International Search Report issued Apr. 2, 2013, in PCT/JP13/050238, filed Jan. 9, 2013. |
Office Action issued Jan. 14, 2016 in Chinese Patent Application No. 201380014511.2 (with partial English translation). |
Office Action mailed Jul. 1, 2016 in Chinese Patent Application No. 201380014511.2 (with English Translation). |
Number | Date | Country | |
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20150035444 A1 | Feb 2015 | US |