JP2018092851A - Led drive power supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an LED drive power supply device capable of preventing breakdown of an LED, by blocking an overcurrent to an LED circuit at the time of high voltage.SOLUTION: In an LED drive power supply device 1 for supplying power from an AC power supply 2, while converting through a magnetic flux control transformer 4, to an LED circuit 3, the magnetic flux control transformer 4 is constituted of an input winding 7 consisting of a first core 5 and a second core 6 composed of a magnetic substance, and a winding wound commonly on the primary side of a first core 5 and a second core 6, and being connected with an AC power supply 2, an output winding 9 consisting of a winding wound around the secondary side of the first core 5, and being connected with the LED circuit 3, a control winding 12 consisting of a winding wound around the secondary side of the second core 6, and being connected with a current control circuit 15 for controlling the current flowing to the LED circuit 3, and a power supply winding 16 consisting of a winding wound commonly on the primary side of the first core 5 and the second core 6, and supplying power to the current control circuit 15.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an LED drive power supply apparatus suitable as an LED illumination power supply, and more particularly to a technique for preventing LED breakage at high voltage during LED AC drive lighting.

  As a conventional illumination power source, for example, a high-frequency lighting device disclosed in Patent Document 1 is known. This device is composed of a current transformer in which a primary winding and a secondary winding are wound around a core. The primary winding is connected to a high-frequency power source, and the secondary winding is connected to a lighting load. Then, the input voltage supplied from the high-frequency power source is converted by a current transformer, and the illumination load is turned on by supplying a rated current to the illumination load.

JP-A-6-325879

  However, the conventional illumination power source such as the high-frequency lighting device of Patent Document 1 has the following problems.

(1) When the input voltage supplied from the power supply changes, the output current supplied from the current transformer also changes.
(2) When the resistance of the lighting load changes, the current flowing through the lighting load also changes.
(3) When the input voltage is constant, the output voltage and current cannot be controlled (large power cannot be controlled with small power).

  Therefore, the present invention has been made to solve such a problem, and the object of the present invention is to keep the output current constant even when the input voltage or the load resistance changes. An object of the present invention is to provide an LED drive power supply device that can prevent an overcurrent to the LED circuit and prevent the LED from being damaged.

  In order to achieve the above object, the present invention provides an LED drive power supply device that converts electric power from an AC power supply with a magnetic flux control transformer and supplies the converted power to an LED circuit, wherein the magnetic flux control transformer is a first made of a magnetic material. And an input winding connected to the AC power source, and a winding wound around the primary side of the first core and the second core. A winding wound around the secondary side of the core, and an output winding connected to the LED circuit and a winding wound around the secondary side of the second core, and flows to the LED circuit A control winding connected to a current control circuit for controlling current and a winding wound in common on the primary side of the first core and the second core, and supplies power to the current control circuit A power winding, and comprising It is characterized in.

  In the present invention, the AC power supply is a three-phase AC power supply, and includes three magnetic flux control transformers of U phase, V phase, and W phase as the magnetic flux control transformer, the U-phase input winding, and the V The phase input winding and the W phase input winding are respectively connected between the U-V input terminals, the V-W input terminals, and the W-U input terminals of the three-phase AC power supply, The phase output winding, the V phase output winding, and the W phase output winding are respectively connected between the U-V output terminals, the V-W output terminals, and the W-U connected to the LED circuit. Connected between output terminals, the U-phase control winding, the V-phase control winding, and the W-phase control winding are respectively connected between the U-V control terminals connected to the current control circuit, V -Connected between W control terminals and between W-U control terminals, provided in the W-phase magnetic flux control transformer. It is also possible to power windings adapted to be connected to the current control circuit.

  According to the LED drive power supply device of the present invention, the following effects can be obtained.

(1) Even if the input voltage supplied from the AC power supply changes, the output current supplied from the LED drive power supply device does not change.
(2) Even if the load resistance changes, the current flowing through the load does not change.
(3) By controlling a control current smaller than the load current, it is possible to control a large power with a small power.

The figure which shows the example which applied the LED drive power supply device of this invention to the single phase alternating current power supply. The figure which shows an example of the current control circuit in the LED drive power supply device of this invention. The figure which shows the example which applied the LED drive power supply device of this invention to the three-phase alternating current power supply. The figure which shows the relationship between the input voltage and electric current value in the LED drive power supply device of this invention. The figure which shows the operating voltage (current) in the single phase alternating current power supply in the LED drive power supply device of this invention. The figure which shows the operating voltage (current) in the three-phase alternating current power supply in the LED drive power supply device of this invention.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

  As shown in FIG. 1, an LED drive power supply device 1 according to the present invention is a power supply device that drives an LED circuit 3 with electric power input from an AC power supply 2 (single-phase AC power supply 2a in this embodiment). In the embodiment, the input voltage is converted by the magnetic flux control transformer 4 adopting the toroidal transformer and supplied to the LED circuit 3. The magnetic flux control transformer 4 includes two cores, a first core 5 made of a ring-shaped magnetic body (iron core) and a second core 6 made of the same ring-shaped magnetic body (iron core). Has been. In the example shown in the figure, a toroidal transformer composed of a ring-shaped core is adopted. Alternatively, an EI transformer composed of an E-type core and an I-type core may be adopted.

  The first core 5 is an output (Main) core, and the second core 6 is a control (Sub) core. The two cores 5 and 6 are provided with a winding (hereinafter referred to as “input winding”) 7 in which a copper wire is wound N times in common on both primary sides. The input winding 7 is connected to the single-phase AC power source 2a through the input terminal 8. In the illustrated example, only one first core 5 is provided, but two or more cores for output (Main) may be provided.

On the secondary side of the first core 5, a winding 9 (hereinafter referred to as “output winding”) 9 in which a copper wire is wound N ₁ times is provided. This output winding 9 is connected to the LED circuit 3 via an output terminal 11 connected to the single-phase rectifier circuit 10. In addition, the LED circuit 3 of this embodiment is an LED lighting apparatus formed by connecting a plurality of LEDs in series.

In contrast, the secondary side of the second core 6, a copper wire N ₂ times wound winding (hereinafter this is called "control winding") 12 is provided. This control winding 12 is connected to a current control circuit 15 via a control terminal 14 connected to a single-phase rectifier circuit 13. The current control circuit 15 of the present embodiment is a constant current circuit that is connected to the LED circuit 3 and controls the current flowing through the LED to be constant. As an example of this constant current circuit, a current value limiting circuit including a bias resistor (R1), an FET (Q1), a transistor (Q2), and a current limiting resistor (R2) can be adopted as shown in FIG.

  Further, the first core 5 and the second core 6 have a winding (hereinafter referred to as “power winding”) 16 in which a copper wire is wound in common on the primary side of both the input winding 7. It is provided separately. The power supply winding 16 is connected to the current control circuit 15 via the AC-DC conversion circuit 17, and supplies the electric power converted from alternating current to direct current by the AC-DC conversion circuit 17 to the current control circuit 15. , Functioning as a power generation transformer section for driving the current control circuit 15. The first core 5 and the second core 6 may be made of different materials. Moreover, about the 2nd core 6, characteristics, such as a saturation magnetic flux density, can be changed by providing a gap or making it a material with high magnetic permeability.

  Here, in the above-described embodiment, the example in which the LED drive power supply device 1 of the present invention is applied to the single-phase AC power supply 2a has been described, but instead, this is applied to a three-phase AC power supply 2b as shown in FIG. You can also. This example is an LED drive power supply device 1 adopting a parallel system, and includes three magnetic flux control transformers 4a, 4b, and 4c of U phase, V phase, and W phase.

  Of the three magnetic flux control transformers 4a, 4b and 4c, the U-phase input winding 7a is connected between the U-V input terminals 8a and 8b, and the V-phase input winding 7b is connected to the V-W input terminals 8b and 8c. The W-phase input winding 7c is connected between the W-U input terminals 8c and 8a. The U-phase output winding 9a is connected between the U-V output terminals 11a and 11b, the V-phase output winding 9b is connected between the V-W output terminals 11b and 11c, and the W-phase output winding 9c is The W-U output terminals 11 c and 11 a are connected to each other, and these output terminals 11 a, 11 b and 11 c are connected to the LED circuit 3 via the three-phase rectifier circuit 18. The U-phase control winding 12a is connected between the U-V control terminals 14a and 14b, the V-phase control winding 12b is connected between the V-W control terminals 14b and 14c, and the W-phase control winding 12c is The W-U control terminals 14 c and 14 a are connected to each other, and these control terminals 14 a, 14 b and 14 c are connected to the current control circuit 15 via the three-phase rectifier circuit 19.

  A power winding 16 is provided in the W-phase magnetic flux control transformer 4c. The power supply winding 16 is connected to the current control circuit 15 via the AC-DC conversion circuit 17, and supplies the electric power converted from alternating current to direct current by the AC-DC conversion circuit 17 to the current control circuit 15. . Since other configurations are the same as those in the above-described embodiment, the same components are denoted by the same reference numerals, and detailed description thereof is omitted.

According to the LED driving power supply device 1 of the present invention, by providing the current control circuit 15 to the second core 6 of Sub, even if the input voltage V rises and the control current I ₂ to the specified value or more does not rise. For this reason, the increase in the output voltage V ₁ reflected in Main is suppressed, and the output current I ₁ flowing through the LED circuit 3 is also limited, so that the LED can be prevented from being damaged. This operation will be described below with reference to the drawings.

In FIG. 4, the horizontal axis represents the input voltage V, and the vertical axis represents the current value. When the input voltage V is small, the sub current control circuit 15 is not operating (non-operating region). Therefore, as the input voltage V increases, the Sub control voltage V ₂ and the control current I ₂ , and the Main output voltage V ₁ and the output current I ₁ also increase, and the LED of the LED circuit 3 lights up. Here, when the input voltage V further increases and becomes larger, the sub current control circuit 15 operates, the sub control voltage V ₂ becomes a specified value, and the increase stops, and the control current I ₂ is set as the current. The value becomes constant (constant current operation region). Thus, increasing the output voltage V ₁ of the Main becomes the predetermined value is stopped, is also constant output current I _1. Therefore, since no overcurrent flows through the LED circuit 3, the LED can be prevented from being damaged.

  FIG. 5 shows the operating voltage (current) in the single-phase AC power source 2a, and FIG. 6 shows the operating voltage (current) in the three-phase AC power source 2b. Both figures show the waveform after full-wave rectification.

As shown in FIG. 5A, when the input voltage V is equal to or higher than the reference value set by the current control circuit 15, the current control circuit 15 operates and the Sub control voltage V ₂ (control current I ₂ ) is The peak value above the reference value is cut and flattened. As a result, the peak value of the main output voltage V ₁ (output current I ₁ ) is also flattened, so that overcurrent flowing to the LED circuit 3 is prevented.

As shown in FIG. 5B, when the input voltage V is a reference value, the current control circuit 15 is on the verge of operation but is not operating. For this reason, the sub control voltage V ₂ (control current I ₂ ) and the main output voltage V ₁ (output current I ₁ ) have a flat peak portion, and are full-wave rectified by the main single-phase rectifier circuit 10. The applied voltage (current) is applied to the LED circuit 3. As shown in FIG. 5C, when the input voltage V is equal to or lower than the reference value, the current control circuit 15 is not operating, and thus the same as in FIG. 5B.

  FIG. 6 shows the operating voltage when the input voltage V is the reference value of the current control circuit 15 in the case of the three-phase AC power source 2b. As shown in the figure, when the input voltage V is a reference value, the current control circuit 15 does not operate, so that the voltage (current) rectified by the main three-phase rectifier circuit 18 is supplied to the LED circuit 3. And applied. The operation when the input voltage V is not less than the reference value and not more than the reference value is the same as that of the single-phase AC power source 2a shown in FIG.

  As described above, according to the LED drive power supply device 1 of the present invention, the current control circuit 15 is provided on the Sub side of the magnetic flux control transformer 4, so that the drive voltage (current) output to the Main side when the input voltage is high. ) Is restricted, overcurrent does not flow through the LED circuit 3, and damage to the LED can be prevented. Further, since the power supply winding 16 is integrated with the magnetic flux control transformer 4 as a power supply generating transformer unit for driving the current control circuit 15, it is not necessary to provide a separate power supply, so that the entire apparatus can be downsized. it can. Furthermore, by setting the voltage of the current control circuit 15 to the standard (recommended) value of the LED, a system without energy loss can be constructed.

  In addition, according to this invention, it can utilize suitably as a power supply in LED lighting apparatus with a large power supply fluctuation | variation like the ship power generator mounted in the country and area where overseas electric power infrastructure is insufficient, or a fishing boat. For example, in the case of a ship generator, since there is a generated voltage higher than the notation, if the specified current of the sub current control circuit 15 is set to be small, overcurrent damage to the LED can be prevented. However, since the drive current is small, the brightness of the LED lighting device is reduced. Therefore, it is optimal to set the specified value of the current control circuit 15 calculated from the vicinity of the rated value of the LED characteristics in consideration of the LED overcurrent damage and the brightness efficiency.

1: LED drive power supply device 2: AC power supply 2a: Single-phase AC power supply 2b: Three-phase AC power supply 3: LED circuit 4: Magnetic flux control transformer 4a: U-phase magnetic flux control transformer 4b: V-phase magnetic flux control transformer 4c: W Phase magnetic flux control transformer 5: First core 6: Second core 7: Input winding 7a: U-phase input winding 7b: V-phase input winding 7c: W-phase input winding 8: Input terminal 8a: U-phase input terminal 8b: V-phase input terminal 8c: W-phase input terminal 9: Output winding 9a: U-phase output winding 9b: V-phase output winding 9c: W-phase output winding 10: Single-phase rectifier circuit 11: Output terminal 11a: U-phase output terminal 11b: V-phase output terminal 11c: W-phase output terminal 12: Control winding 12a: U-phase control winding 12b: V-phase control Winding 12c: W-phase control winding 13: Single-phase rectifier circuit 14: Control terminal 1 4a: U-phase control terminal 14b: V-phase control terminal 14c: W-phase control terminal 15: Current control circuit 16: Power supply winding 17: AC-DC conversion circuit 18: Three-phase rectifier circuit 19: Three-phase rectifier circuit

Claims (2)

An LED drive power supply device that converts electric power from an AC power supply with a magnetic flux control transformer and supplies the converted power to an LED circuit,
The magnetic flux control transformer includes a first core and a second core made of a magnetic material,
An input winding connected to the AC power source, the winding being wound in common on the primary side of the first core and the second core;
An output winding comprising a winding wound around the secondary side of the first core and connected to the LED circuit;
A control winding comprising a winding wound around the secondary side of the second core and connected to a current control circuit for controlling a current flowing in the LED circuit;
A power supply winding that is configured by a winding wound in common on the primary side of the first core and the second core, and that supplies power to the current control circuit. LED drive power supply. In the LED drive power supply device according to claim 1,
The AC power supply is a three-phase AC power supply,
The magnetic flux control transformer includes three magnetic flux control transformers of U phase, V phase, and W phase,
The U-phase input winding, the V-phase input winding, and the W-phase input winding are respectively connected between the U-V input terminal, the V-W input terminal, and the W- Connected between U input terminals,
The U-phase output winding, the V-phase output winding, and the W-phase output winding are respectively connected between the U-V output terminals, V-W output terminals, and W connected to the LED circuit. -Connected between U output terminals,
The U-phase control winding, the V-phase control winding, and the W-phase control winding are respectively connected between the U-V control terminals connected to the current control circuit, between the V-W control terminals, and Connected between W-U control terminals,
An LED drive power supply device, wherein a power supply winding provided in the W-phase magnetic flux control transformer is connected to the current control circuit.