JP2014078361A - Led lighting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an LED lighting device that can be reliably turned on whether a fluorescent lamp luminaire is of a starter type, a rapid start type or an inverter type without requiring modifications to the fluorescent lamp luminaire.SOLUTION: In the LED lighting device, a DC current rectified in an input section 10 is supplied to a plurality of light emitting diode elements 21, 22. A coil L and a terminal path 5-4 of an intelligent power device IC are connected in series with the plurality of light emitting diode elements 21, 22, and the terminal path 5-4 is switched on/off. The coil L has an inductance determined so as to satisfy a first condition of reproducing a pseudo fluorescent lamp filament and a second condition of maintaining a current value supplied to the plurality of light emitting diode elements 21, 22 via a recovery diode D in an off state.

Description

  The present invention relates to an LED illuminating device that can be applied to any fluorescent lamp illuminator of a starter type, a rapid start type, and an inverter type.

  Conventionally, as this type of LED lighting device, as shown in Patent Document 1 below, only one pair of input terminals (cap pins) connected to a socket of a fluorescent lamp lighting fixture is used. A device in which a plurality of light emitting diodes and a choke coil are connected in series is known.

JP 2010-34012 A

  However, in the conventional LED lighting device, in order to turn on the LED lighting device with only one of the pair of input terminals (cap pins), it is necessary to modify the fluorescent lamp lighting fixture in advance to a configuration corresponding to the LED lighting device. There is.

  Specifically, it is necessary to remove the ballast that constitutes the fluorescent lamp lighting fixture and modify the AC power supply so that it is connected between one input terminal. Further, if necessary, it is necessary to insulate the other input terminal side from which the ballast is removed.

  Here, it is possible to attach the LED lighting device to the fluorescent lighting fixture without removing the ballast, but in this case the protection function of the ballast works and the LED lighting device does not turn on or turns on. However, there is a problem that disappears.

  In view of the above circumstances, the LED lighting device of the present invention does not require modification of the fluorescent lamp lighting fixture, and can reliably turn on any of the fluorescent lamp lighting fixtures of the starter type, the rapid start type, and the inverter type. An object of the present invention is to provide an LED lighting device that can be used.

In order to achieve the above object, the LED lighting device of the present invention is an LED lighting device that can support any of the fluorescent lamp lighting fixtures of the starter type, the rapid start type, and the inverter type,
One pair of input terminals and the other pair of input terminals connected to the socket of the fluorescent lamp luminaire; and
One diode bridge and the other diode bridge respectively connected to the one pair of input terminals and the other pair of input terminals;
A capacitor connected in parallel between the output terminals between the one diode bridge and the other diode bridge;
Between the one diode bridge and the other diode bridge, connected in parallel between these output terminals, a plurality of light emitting diode elements connected in series, and
A coil connected in series with the plurality of light emitting diode elements between the one diode bridge and the other diode bridge;
A switching element connected in series with the coil between the one diode bridge and the other diode bridge;
A resistor connected in series with the switching element between the one diode bridge and the other diode bridge;
A recovery diode that is connected in series to the coil and connected in parallel to the switching element, and that constitutes a closed circuit with the coil and the plurality of light emitting diode elements,
The switching element is an intelligent power device that is turned on and off according to an applied current value of the plurality of light emitting diode elements.
The coil adjusts the current applied to the plurality of light emitting diode elements flowing in the closed circuit when the switching element is OFF, and the filament of the fluorescent lamp when the fluorescent lamp is attached to the fluorescent lamp luminaire Is reproduced in a pseudo manner.

  According to the LED lighting device of the present invention, one pair of input terminals and the other pair of input terminals are respectively connected to the two sockets of the fluorescent lamp luminaire, and both the pair of one and the other are connected via the socket. AC power is supplied to the input terminal.

  First, power supplied from an AC power source is rectified by one and the other diode bridge connected to two pairs of input terminals, and the rectified DC current is supplied to a plurality of light emitting diodes connected in series. The

  The direct current supplied to the plurality of light emitting diodes is adjusted by turning on and off the switching element according to the current value. At this time, current is supplied from the coil to the closed circuit via the recovery diode at the timing when the switching element is turned OFF. Therefore, for example, the inductance of the coil is adjusted according to the current value supplied to the closed circuit.

  Here, the inventor of the present application, due to earnest test research, when the LED lighting device is mounted without remodeling the fluorescent lamp lighting fixture, the ballast protection function works, and the LED lighting device has a problem. I found out.

  Further, the inventor of the present application pays attention to the fact that the ballast protection function is based on the detection of filament continuity when a fluorescent lamp is mounted on a fluorescent lamp luminaire. It was conceived that the LED lighting device can be reliably turned on even with a conventional fluorescent lamp illuminator by reproducing the above.

  Therefore, for example, the inductance of the coil of the present invention is adjusted to a value that simulates the value of the current flowing in the closed circuit when the switching element is OFF and the filament of the fluorescent lamp.

  As a result, the LED lighting device of the present invention does not require modification of the fluorescent lamp lighting fixture, and can be reliably turned on with any of the fluorescent lamp lighting fixtures of the starter type, the rapid start type, and the inverter type.

The circuit diagram which shows the structure of the LED lighting apparatus of this embodiment.

  With reference to FIG. 1, the structure of the LED lighting apparatus of this embodiment is demonstrated.

  The LED illuminating device of the present embodiment is an LED illuminating device that is compatible with any of the starter type, the rapid start type, and the inverter type fluorescent lamp illuminating device, and includes an input unit 10, a light emitting unit 20, And a light emission adjusting unit 30.

  First, the input unit 10 is connected to one pair of input terminals 11 and the other pair of input terminals 12 connected to two sockets (not shown) of the fluorescent lamp luminaire, and to the one pair of input terminals 11. One diode bridge DB1, the other diode bridge DB2 connected to the other pair of input terminals 12, and a capacitor C connected in parallel between one diode bridge DB1 and the other diode bridge DB2. With.

  One pair of input terminals 11 are terminals that are electrically connected to the socket of the fluorescent lamp luminaire by the base pins 11a and 11b, and the other pair of input terminals 12 are fluorescent lamp illumination by the base pins 12a and 12b. A terminal that is electrically connected to the socket of the instrument.

  A surge absorber Z is provided between the terminals of the pair of input terminals 11, and the surge absorber Z absorbs a high voltage such as lightning or static electricity applied between the terminals.

  Also, fuses F1 and F2 are attached to the other pair of input terminals 12 corresponding to the cap pins 12a and 12b, respectively, and overvoltage or overcurrent is applied to the other pair of input terminals 12 by the fuses F1 and F2. Is applied, the continuity is cut off to prevent overvoltage or overcurrent from being applied to the light emitting unit 20 and the light emission adjusting unit 30.

  One diode bridge DB1 is composed of a diode bridge element, and rectifies an alternating current power supplied to the pair of input terminals 11 via the cap pins 11a and 11b to make a direct current.

  Similarly, the other diode bridge DB2 is composed of a diode bridge element, and rectifies the AC power supplied to the other pair of input terminals 12 via the cap pins 12a and 12b to generate a DC current.

  The capacitor C is a ceramic capacitor, and is connected in parallel between the output terminals of the diode bridge DB1 and between the output terminals of the diode bridge DB2, and the pulse of the DC current converted by the capacitor C by the diode bridges DB1 and DB2 is used. Smooth the flow.

  Next, the light emitting unit 20 includes a plurality of light emitting diode elements 21 and 22 that are connected in parallel between the output terminals of the diode bridge DB1 and between the output terminals of the diode bridge DB2, and the elements are connected in series.

In the present embodiment, the plurality of light emitting diode elements 21 and 22 are connected in parallel to each other, but according to the supply current between the output terminals of the diode bridge DB1 and between the output terminals of the diode bridge DB2. If the supply current is small, do not parallel
When the supply current is large, a plurality of them are connected in parallel.

  Next, the light emission adjusting unit 30 includes a coil L, an intelligent power device IC, and a recovery diode D, all of which are provided between one and the other diode bridges DB1 and DB2.

  The coil L is connected to the plurality of light emitting diode elements 21 and 22 in series. The inductance design value of the coil L will be described later in detail.

  The intelligent power device IC is an IC element that performs current / voltage control between the terminals 1 to 8. In the present embodiment, the intelligent power device IC has a function as a switching element that turns ON / OFF between the terminals 5-4.

  Here, the terminal 6 of the intelligent power device IC includes the output terminal of one diode bridge DB1 and the output terminal of the other diode bridge DB2 (more precisely, the positive terminal of the output terminal of one diode bridge DB1 and the other diode bridge DB2). Therefore, the applied current values of the plurality of light emitting diode elements 21 and 22 can be monitored, and the terminals 5-4 can be turned ON / OFF accordingly.

  The ON / OFF operation condition / duty ratio between the terminals 5-4 is determined by the fixed resistors R1, R2, the variable resistor VR and the capacitors C1-C3 connected to each terminal of the intelligent power device IC.

  Specifically, the ON / OFF duty ratio between the terminals 5-4 is set by the fixed resistor R1. Further, the ON / OFF operation condition between the terminals 5-4 is set from the voltage drop due to the fixed resistor R2. That is, since the voltage drop of the fixed resistor R2 changes according to the applied current values of the plurality of light emitting diode elements 21 and 22, a plurality of light emitting diodes can be obtained by setting a threshold in advance for the voltage drop value. The terminal 5-4 can be turned ON / OFF according to the actual applied current value of the elements 21 and 22.

  Further, the reference voltage of the terminal 1 of the intelligent power device IC is divided by the variable resistor VR, and is input to the terminal 3, whereby the reference current value between the terminals 8-3 is set.

  Further, the reference current value is stabilized by the capacitors C1 and C3, and the ON / OFF duty ratio between the terminals 5-4 is set by the capacitor C2.

  The recovery diode D is a fast recovery diode element with a fast recovery time, and the positive electrode side is connected in series to the coil L and is connected in parallel to the terminal 5-4 of the intelligent power device IC. Further, the negative electrode side of the recovery diode D is connected to the positive electrode side of the input unit 10, and constitutes a closed circuit with the coil L and the plurality of light emitting diode elements 21 and 22.

  Next, the operation of the LED lighting device configured as described above will be described.

  First, the AC power supplied to the input unit 10 via one and the other pair of input terminals 11 and 12 is rectified into a DC current by the one and the other diode bridges DB1 and DB2, and a plurality of the light sources 20 A direct current is supplied to the light emitting diode elements 21 and 22, and the light emitting diode elements 21 and 22 are turned on.

  At this time, the applied current values of the plurality of light emitting diode elements 21 and 22 are monitored as reference current values between the terminals 6-3 of the intelligent power device IC, and ON / OFF between the terminals 5-4 based on the reference current values. The terminal 5-4 is turned ON / OFF according to the operating conditions and the duty ratio.

  This is an outline of the operation of the LED lighting device.

  Next, details of the operation of the LED lighting device will be described.

  First, at the start of lighting, the terminals 5-4 of the intelligent power device IC are ON, and a direct current is supplied to the coil L via the plurality of light emitting diode elements 21 and 22.

  Here, the inventor of the present application has made a ballast protection function for a fluorescent lamp illuminator when the LED illuminator is attached without remodeling the fluorescent lamp illuminator, and the LED illuminator functions. It has been found that problems occur in

  In particular, the ballast protective function often detects filament continuity when a fluorescent lamp is attached by passing a weak current through an illuminator attached to the fluorescent lamp luminaire prior to lighting.

  Therefore, in this embodiment, the coil L is set so as to satisfy the first condition that the inductance value is a pseudo reproduction of the filament when the fluorescent lamp is attached to the fluorescent lamp luminaire.

  Next, when the protection function of the ballast of the fluorescent lamp luminaire is cleared, AC power necessary for lighting the fluorescent lamp is supplied from the fluorescent lamp luminaire, and thereby the light emitting diode elements 21 and 22 are lit.

  During lighting, the terminals 5-4 of the intelligent power device IC are turned ON / OFF according to the applied current values of the plurality of light emitting diode elements 21, 22.

  Here, when the terminal 5-4 of the intelligent power device IC is turned OFF, current is supplied from the coil L to the closed circuit via the recovery diode D at that timing. For this reason, the coil L is set so as to satisfy the second condition that it is an inductance value to which a current necessary for maintaining the lighting of the plurality of light emitting diode elements 21 and 22 is supplied.

  Thereby, the stable lighting of the plurality of light emitting diode elements 21 and 22 is maintained.

  As described above in detail, according to the LED lighting device of the present embodiment, any fluorescent lamp lighting fixture of the starter type, the rapid start type, and the inverter type can be reliably used without requiring modification of the fluorescent lighting fixture. Can be turned on.

DESCRIPTION OF SYMBOLS 10 ... Input part, 11 ... One pair of input terminals, 12 ... The other pair of input terminals, 21, 22 ... Light emitting diode element, DB1 ... One diode bridge, DB2 ... The other diode bridge, C ... Capacitor, L ... coil, D ... recovery diode, IC ... intelligent power device (switching element).

Claims (1)

It is an LED lighting device that can correspond to any of the fluorescent lamp lighting fixtures of the starter type, the rapid start type, and the inverter type,
One pair of input terminals and the other pair of input terminals connected to the socket of the fluorescent lamp luminaire; and
One diode bridge and the other diode bridge respectively connected to the one pair of input terminals and the other pair of input terminals;
A capacitor connected in parallel between the output terminals between the one diode bridge and the other diode bridge;
Between the one diode bridge and the other diode bridge, connected in parallel between these output terminals, a plurality of light emitting diode elements connected in series, and
A coil connected in series with the plurality of light emitting diode elements between the one diode bridge and the other diode bridge;
A switching element connected in series with the coil between the one diode bridge and the other diode bridge;
A resistor connected in series with the switching element between the one diode bridge and the other diode bridge;
A recovery diode that is connected in series to the coil and connected in parallel to the switching element, and that constitutes a closed circuit with the coil and the plurality of light emitting diode elements,
The switching element is an intelligent power device that is turned on and off according to an applied current value of the plurality of light emitting diode elements.
The coil adjusts the current applied to the plurality of light emitting diode elements flowing in the closed circuit when the switching element is OFF, and the filament of the fluorescent lamp when the fluorescent lamp is attached to the fluorescent lamp luminaire LED lighting device characterized by reproducing the above in a pseudo manner.